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/-
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.Analysis.Convex.StrictConvexBetween
import Mathlib.Analysis.InnerProductSpace.Convex
import Mathlib.Analysis.Normed.Affine.Convex
import Mathlib.Geometry.Euclidean.Basic
/-!
# Spheres
This file defines and proves basic results about spheres and cospherical sets of points in
Euclidean affine spaces.
## Main definitions
* `EuclideanGeometry.Sphere` bundles a `center` and a `radius`.
* `EuclideanGeometry.Sphere.IsDiameter` is the property of two points being the two endpoints
of a diameter of a sphere.
* `EuclideanGeometry.Sphere.ofDiameter` constructs the sphere on a given diameter.
* `EuclideanGeometry.Cospherical` is the property of a set of points being equidistant from some
point.
* `EuclideanGeometry.Concyclic` is the property of a set of points being cospherical and
coplanar.
-/
noncomputable section
open RealInnerProductSpace
namespace EuclideanGeometry
variable {V : Type*} (P : Type*)
open Module
/-- A `Sphere P` bundles a `center` and `radius`. This definition does not require the radius to
be positive; that should be given as a hypothesis to lemmas that require it. -/
@[ext]
structure Sphere [MetricSpace P] where
/-- center of this sphere -/
center : P
/-- radius of the sphere: not required to be positive -/
radius : ℝ
variable {P}
section MetricSpace
variable [MetricSpace P]
instance [Nonempty P] : Nonempty (Sphere P) :=
⟨⟨Classical.arbitrary P, 0⟩⟩
instance : Coe (Sphere P) (Set P) :=
⟨fun s => Metric.sphere s.center s.radius⟩
instance : Membership P (Sphere P) :=
⟨fun s p => p ∈ (s : Set P)⟩
theorem Sphere.mk_center (c : P) (r : ℝ) : (⟨c, r⟩ : Sphere P).center = c :=
rfl
theorem Sphere.mk_radius (c : P) (r : ℝ) : (⟨c, r⟩ : Sphere P).radius = r :=
rfl
|
@[simp]
| Mathlib/Geometry/Euclidean/Sphere/Basic.lean | 74 | 75 |
/-
Copyright (c) 2020 Thomas Browning. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Thomas Browning, Junyan Xu
-/
import Mathlib.Data.Fintype.Order
import Mathlib.FieldTheory.IntermediateField.Adjoin.Basic
/-!
# Extension of field embeddings
`IntermediateField.exists_algHom_of_adjoin_splits'` is the main result: if E/L/F is a tower of
field extensions, K is another extension of F, and `f` is an embedding of L/F into K/F, such
that the minimal polynomials of a set of generators of E/L splits in K (via `f`), then `f`
extends to an embedding of E/F into K/F.
## Reference
[Isaacs1980] *Roots of Polynomials in Algebraic Extensions of Fields*,
The American Mathematical Monthly
-/
open Polynomial
namespace IntermediateField
variable (F E K : Type*) [Field F] [Field E] [Field K] [Algebra F E] [Algebra F K] {S : Set E}
/-- Lifts `L → K` of `F → K` -/
structure Lifts where
/-- The domain of a lift. -/
carrier : IntermediateField F E
/-- The lifted RingHom, expressed as an AlgHom. -/
emb : carrier →ₐ[F] K
variable {F E K}
namespace Lifts
instance : PartialOrder (Lifts F E K) where
le L₁ L₂ := ∃ h : L₁.carrier ≤ L₂.carrier, ∀ x, L₂.emb (inclusion h x) = L₁.emb x
le_refl L := ⟨le_rfl, by simp⟩
le_trans L₁ L₂ L₃ := by
rintro ⟨h₁₂, h₁₂'⟩ ⟨h₂₃, h₂₃'⟩
refine ⟨h₁₂.trans h₂₃, fun _ ↦ ?_⟩
rw [← inclusion_inclusion h₁₂ h₂₃, h₂₃', h₁₂']
le_antisymm := by
rintro ⟨L₁, e₁⟩ ⟨L₂, e₂⟩ ⟨h₁₂, h₁₂'⟩ ⟨h₂₁, h₂₁'⟩
obtain rfl : L₁ = L₂ := h₁₂.antisymm h₂₁
congr
exact AlgHom.ext h₂₁'
noncomputable instance : OrderBot (Lifts F E K) where
bot := ⟨⊥, (Algebra.ofId F K).comp (botEquiv F E)⟩
bot_le L := ⟨bot_le, fun x ↦ by
obtain ⟨x, rfl⟩ := (botEquiv F E).symm.surjective x
simp_rw [AlgHom.comp_apply, AlgHom.coe_coe, AlgEquiv.apply_symm_apply]
exact L.emb.commutes x⟩
noncomputable instance : Inhabited (Lifts F E K) :=
⟨⊥⟩
variable {L₁ L₂ : Lifts F E K}
theorem le_iff : L₁ ≤ L₂ ↔
∃ h : L₁.carrier ≤ L₂.carrier, L₂.emb.comp (inclusion h) = L₁.emb := by
simp_rw [AlgHom.ext_iff]; rfl
theorem eq_iff_le_carrier_eq : L₁ = L₂ ↔ L₁ ≤ L₂ ∧ L₁.carrier = L₂.carrier :=
⟨fun eq ↦ ⟨eq.le, congr_arg _ eq⟩, fun ⟨le, eq⟩ ↦ le.antisymm ⟨eq.ge, fun x ↦ (le.2 ⟨x, _⟩).symm⟩⟩
theorem eq_iff : L₁ = L₂ ↔
∃ h : L₁.carrier = L₂.carrier, L₂.emb.comp (inclusion h.le) = L₁.emb := by
rw [eq_iff_le_carrier_eq, le_iff]
exact ⟨fun h ↦ ⟨h.2, h.1.2⟩, fun h ↦ ⟨⟨h.1.le, h.2⟩, h.1⟩⟩
theorem lt_iff_le_carrier_ne : L₁ < L₂ ↔ L₁ ≤ L₂ ∧ L₁.carrier ≠ L₂.carrier := by
rw [lt_iff_le_and_ne, and_congr_right]; intro h; simp_rw [Ne, eq_iff_le_carrier_eq, h, true_and]
theorem lt_iff : L₁ < L₂ ↔
∃ h : L₁.carrier < L₂.carrier, L₂.emb.comp (inclusion h.le) = L₁.emb := by
rw [lt_iff_le_carrier_ne, le_iff]
exact ⟨fun h ↦ ⟨h.1.1.lt_of_ne h.2, h.1.2⟩, fun h ↦ ⟨⟨h.1.le, h.2⟩, h.1.ne⟩⟩
theorem le_of_carrier_le_iSup {ι} {ρ : ι → Lifts F E K} {σ τ : Lifts F E K}
(hσ : ∀ i, ρ i ≤ σ) (hτ : ∀ i, ρ i ≤ τ) (carrier_le : σ.carrier ≤ ⨆ i, (ρ i).carrier) :
σ ≤ τ :=
le_iff.mpr ⟨carrier_le.trans (iSup_le fun i ↦ (hτ i).1), algHom_ext_of_eq_adjoin _
(carrier_le.antisymm (iSup_le fun i ↦ (hσ i).1)|>.trans <| iSup_eq_adjoin _ _) fun x hx ↦
have ⟨i, hx⟩ := Set.mem_iUnion.mp hx
((hτ i).2 ⟨x, hx⟩).trans ((hσ i).2 ⟨x, hx⟩).symm⟩
/-- `σ : L →ₐ[F] K` is an extendible lift ("extendible pair" in [Isaacs1980]) if for every
intermediate field `M` that is finite-dimensional over `L`, `σ` extends to some `M →ₐ[F] K`.
In our definition we only require `M` to be finitely generated over `L`, which is equivalent
if the ambient field `E` is algebraic over `F` (which is the case in our main application).
We also allow the domain of the extension to be an intermediate field that properly contains `M`,
since one can always restrict the domain to `M`. -/
def IsExtendible (σ : Lifts F E K) : Prop :=
∀ S : Finset E, ∃ τ ≥ σ, (S : Set E) ⊆ τ.carrier
section Chain
variable (c : Set (Lifts F E K)) (hc : IsChain (· ≤ ·) c)
/-- The union of a chain of lifts. -/
noncomputable def union : Lifts F E K :=
let t (i : ↑(insert ⊥ c)) := i.val.carrier
have hc := hc.insert fun _ _ _ ↦ .inl bot_le
have dir : Directed (· ≤ ·) t := hc.directedOn.directed_val.mono_comp _ fun _ _ h ↦ h.1
⟨iSup t, (Subalgebra.iSupLift (toSubalgebra <| t ·) dir (·.val.emb) (fun i j h ↦
AlgHom.ext fun x ↦ (hc.total i.2 j.2).elim (fun hij ↦ (hij.snd x).symm) fun hji ↦ by
rw [AlgHom.comp_apply, ← inclusion]
dsimp only [coe_type_toSubalgebra]
rw [← hji.snd (inclusion h x), inclusion_inclusion, inclusion_self, AlgHom.id_apply x])
_ rfl).comp
(Subalgebra.equivOfEq _ _ <| toSubalgebra_iSup_of_directed dir)⟩
theorem le_union ⦃σ : Lifts F E K⦄ (hσ : σ ∈ c) : σ ≤ union c hc :=
have hσ := Set.mem_insert_of_mem ⊥ hσ
let t (i : ↑(insert ⊥ c)) := i.val.carrier
⟨le_iSup t ⟨σ, hσ⟩, fun x ↦ by
dsimp only [union, AlgHom.comp_apply]
exact Subalgebra.iSupLift_inclusion (K := (toSubalgebra <| t ·))
(i := ⟨σ, hσ⟩) x (le_iSup (toSubalgebra <| t ·) ⟨σ, hσ⟩)⟩
theorem carrier_union : (union c hc).carrier = ⨆ i : c, i.1.carrier :=
le_antisymm (iSup_le <| by rintro ⟨i, rfl|hi⟩; exacts [bot_le, le_iSup_of_le ⟨i, hi⟩ le_rfl]) <|
iSup_le fun i ↦ le_iSup_of_le ⟨i, .inr i.2⟩ le_rfl
/-- A chain of lifts has an upper bound. -/
theorem exists_upper_bound (c : Set (Lifts F E K)) (hc : IsChain (· ≤ ·) c) :
∃ ub, ∀ a ∈ c, a ≤ ub := ⟨_, le_union c hc⟩
theorem union_isExtendible [alg : Algebra.IsAlgebraic F E]
[Nonempty c] (hext : ∀ σ ∈ c, σ.IsExtendible) :
(union c hc).IsExtendible := fun S ↦ by
let Ω := adjoin F (S : Set E) →ₐ[F] K
have ⟨ω, hω⟩ : ∃ ω : Ω, ∀ π : c, ∃ θ ≥ π.1, ⟨_, ω⟩ ≤ θ ∧ θ.carrier = π.1.1 ⊔ adjoin F S := by
by_contra!; choose π hπ using this
have := finiteDimensional_adjoin (S := (S : Set E)) fun _ _ ↦ (alg.isIntegral).1 _
have ⟨π₀, hπ₀⟩ := hc.directed.finite_le π
have ⟨θ, hθπ, hθ⟩ := hext _ π₀.2 S
rw [← adjoin_le_iff] at hθ
let θ₀ := θ.emb.comp (inclusion hθ)
have := (hπ₀ θ₀).trans hθπ
exact hπ θ₀ ⟨_, θ.emb.comp <| inclusion <| sup_le this.1 hθ⟩
⟨le_sup_left, this.2⟩ ⟨le_sup_right, fun _ ↦ rfl⟩ rfl
choose θ ge hθ eq using hω
have : IsChain (· ≤ ·) (Set.range θ) := by
| simp_rw [← restrictScalars_adjoin_eq_sup, restrictScalars_adjoin] at eq
rintro _ ⟨π₁, rfl⟩ _ ⟨π₂, rfl⟩ -
wlog h : π₁ ≤ π₂ generalizing π₁ π₂
· exact (this _ _ <| (hc.total π₁.2 π₂.2).resolve_left h).symm
refine .inl (le_iff.mpr ⟨?_, algHom_ext_of_eq_adjoin _ (eq _) ?_⟩)
· rw [eq, eq]; exact adjoin.mono _ _ _ (Set.union_subset_union_left _ h.1)
rintro x (hx|hx)
| Mathlib/FieldTheory/Extension.lean | 151 | 157 |
/-
Copyright (c) 2017 Robert Y. Lewis. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Robert Y. Lewis, Keeley Hoek
-/
import Mathlib.Algebra.NeZero
import Mathlib.Data.Int.DivMod
import Mathlib.Logic.Embedding.Basic
import Mathlib.Logic.Equiv.Set
import Mathlib.Tactic.Common
import Mathlib.Tactic.Attr.Register
/-!
# The finite type with `n` elements
`Fin n` is the type whose elements are natural numbers smaller than `n`.
This file expands on the development in the core library.
## Main definitions
### Induction principles
* `finZeroElim` : Elimination principle for the empty set `Fin 0`, generalizes `Fin.elim0`.
Further definitions and eliminators can be found in `Init.Data.Fin.Lemmas`
### Embeddings and isomorphisms
* `Fin.valEmbedding` : coercion to natural numbers as an `Embedding`;
* `Fin.succEmb` : `Fin.succ` as an `Embedding`;
* `Fin.castLEEmb h` : `Fin.castLE` as an `Embedding`, embed `Fin n` into `Fin m`, `h : n ≤ m`;
* `finCongr` : `Fin.cast` as an `Equiv`, equivalence between `Fin n` and `Fin m` when `n = m`;
* `Fin.castAddEmb m` : `Fin.castAdd` as an `Embedding`, embed `Fin n` into `Fin (n+m)`;
* `Fin.castSuccEmb` : `Fin.castSucc` as an `Embedding`, embed `Fin n` into `Fin (n+1)`;
* `Fin.addNatEmb m i` : `Fin.addNat` as an `Embedding`, add `m` on `i` on the right,
generalizes `Fin.succ`;
* `Fin.natAddEmb n i` : `Fin.natAdd` as an `Embedding`, adds `n` on `i` on the left;
### Other casts
* `Fin.divNat i` : divides `i : Fin (m * n)` by `n`;
* `Fin.modNat i` : takes the mod of `i : Fin (m * n)` by `n`;
-/
assert_not_exists Monoid Finset
open Fin Nat Function
attribute [simp] Fin.succ_ne_zero Fin.castSucc_lt_last
/-- Elimination principle for the empty set `Fin 0`, dependent version. -/
def finZeroElim {α : Fin 0 → Sort*} (x : Fin 0) : α x :=
x.elim0
namespace Fin
@[simp] theorem mk_eq_one {n a : Nat} {ha : a < n + 2} :
(⟨a, ha⟩ : Fin (n + 2)) = 1 ↔ a = 1 :=
mk.inj_iff
@[simp] theorem one_eq_mk {n a : Nat} {ha : a < n + 2} :
1 = (⟨a, ha⟩ : Fin (n + 2)) ↔ a = 1 := by
simp [eq_comm]
instance {n : ℕ} : CanLift ℕ (Fin n) Fin.val (· < n) where
prf k hk := ⟨⟨k, hk⟩, rfl⟩
/-- A dependent variant of `Fin.elim0`. -/
def rec0 {α : Fin 0 → Sort*} (i : Fin 0) : α i := absurd i.2 (Nat.not_lt_zero _)
variable {n m : ℕ}
--variable {a b : Fin n} -- this *really* breaks stuff
theorem val_injective : Function.Injective (@Fin.val n) :=
@Fin.eq_of_val_eq n
/-- If you actually have an element of `Fin n`, then the `n` is always positive -/
lemma size_positive : Fin n → 0 < n := Fin.pos
lemma size_positive' [Nonempty (Fin n)] : 0 < n :=
‹Nonempty (Fin n)›.elim Fin.pos
protected theorem prop (a : Fin n) : a.val < n :=
a.2
lemma lt_last_iff_ne_last {a : Fin (n + 1)} : a < last n ↔ a ≠ last n := by
simp [Fin.lt_iff_le_and_ne, le_last]
lemma ne_zero_of_lt {a b : Fin (n + 1)} (hab : a < b) : b ≠ 0 :=
Fin.ne_of_gt <| Fin.lt_of_le_of_lt a.zero_le hab
lemma ne_last_of_lt {a b : Fin (n + 1)} (hab : a < b) : a ≠ last n :=
Fin.ne_of_lt <| Fin.lt_of_lt_of_le hab b.le_last
/-- Equivalence between `Fin n` and `{ i // i < n }`. -/
@[simps apply symm_apply]
def equivSubtype : Fin n ≃ { i // i < n } where
toFun a := ⟨a.1, a.2⟩
invFun a := ⟨a.1, a.2⟩
left_inv := fun ⟨_, _⟩ => rfl
right_inv := fun ⟨_, _⟩ => rfl
section coe
/-!
### coercions and constructions
-/
theorem val_eq_val (a b : Fin n) : (a : ℕ) = b ↔ a = b :=
Fin.ext_iff.symm
theorem ne_iff_vne (a b : Fin n) : a ≠ b ↔ a.1 ≠ b.1 :=
Fin.ext_iff.not
theorem mk_eq_mk {a h a' h'} : @mk n a h = @mk n a' h' ↔ a = a' :=
Fin.ext_iff
-- syntactic tautologies now
/-- Assume `k = l`. If two functions defined on `Fin k` and `Fin l` are equal on each element,
then they coincide (in the heq sense). -/
protected theorem heq_fun_iff {α : Sort*} {k l : ℕ} (h : k = l) {f : Fin k → α} {g : Fin l → α} :
HEq f g ↔ ∀ i : Fin k, f i = g ⟨(i : ℕ), h ▸ i.2⟩ := by
subst h
simp [funext_iff]
/-- Assume `k = l` and `k' = l'`.
If two functions `Fin k → Fin k' → α` and `Fin l → Fin l' → α` are equal on each pair,
then they coincide (in the heq sense). -/
protected theorem heq_fun₂_iff {α : Sort*} {k l k' l' : ℕ} (h : k = l) (h' : k' = l')
{f : Fin k → Fin k' → α} {g : Fin l → Fin l' → α} :
HEq f g ↔ ∀ (i : Fin k) (j : Fin k'), f i j = g ⟨(i : ℕ), h ▸ i.2⟩ ⟨(j : ℕ), h' ▸ j.2⟩ := by
subst h
subst h'
simp [funext_iff]
/-- Two elements of `Fin k` and `Fin l` are heq iff their values in `ℕ` coincide. This requires
`k = l`. For the left implication without this assumption, see `val_eq_val_of_heq`. -/
protected theorem heq_ext_iff {k l : ℕ} (h : k = l) {i : Fin k} {j : Fin l} :
HEq i j ↔ (i : ℕ) = (j : ℕ) := by
subst h
simp [val_eq_val]
end coe
section Order
/-!
### order
-/
theorem le_iff_val_le_val {a b : Fin n} : a ≤ b ↔ (a : ℕ) ≤ b :=
Iff.rfl
/-- `a < b` as natural numbers if and only if `a < b` in `Fin n`. -/
@[norm_cast, simp]
theorem val_fin_lt {n : ℕ} {a b : Fin n} : (a : ℕ) < (b : ℕ) ↔ a < b :=
Iff.rfl
/-- `a ≤ b` as natural numbers if and only if `a ≤ b` in `Fin n`. -/
@[norm_cast, simp]
theorem val_fin_le {n : ℕ} {a b : Fin n} : (a : ℕ) ≤ (b : ℕ) ↔ a ≤ b :=
Iff.rfl
theorem min_val {a : Fin n} : min (a : ℕ) n = a := by simp
theorem max_val {a : Fin n} : max (a : ℕ) n = n := by simp
/-- The inclusion map `Fin n → ℕ` is an embedding. -/
@[simps -fullyApplied apply]
def valEmbedding : Fin n ↪ ℕ :=
⟨val, val_injective⟩
@[simp]
theorem equivSubtype_symm_trans_valEmbedding :
equivSubtype.symm.toEmbedding.trans valEmbedding = Embedding.subtype (· < n) :=
rfl
/-- Use the ordering on `Fin n` for checking recursive definitions.
For example, the following definition is not accepted by the termination checker,
unless we declare the `WellFoundedRelation` instance:
```lean
def factorial {n : ℕ} : Fin n → ℕ
| ⟨0, _⟩ := 1
| ⟨i + 1, hi⟩ := (i + 1) * factorial ⟨i, i.lt_succ_self.trans hi⟩
```
-/
instance {n : ℕ} : WellFoundedRelation (Fin n) :=
measure (val : Fin n → ℕ)
@[deprecated (since := "2025-02-24")]
alias val_zero' := val_zero
/-- `Fin.mk_zero` in `Lean` only applies in `Fin (n + 1)`.
This one instead uses a `NeZero n` typeclass hypothesis.
-/
@[simp]
theorem mk_zero' (n : ℕ) [NeZero n] : (⟨0, pos_of_neZero n⟩ : Fin n) = 0 := rfl
/--
The `Fin.zero_le` in `Lean` only applies in `Fin (n+1)`.
This one instead uses a `NeZero n` typeclass hypothesis.
-/
@[simp]
protected theorem zero_le' [NeZero n] (a : Fin n) : 0 ≤ a :=
Nat.zero_le a.val
@[simp, norm_cast]
theorem val_eq_zero_iff [NeZero n] {a : Fin n} : a.val = 0 ↔ a = 0 := by
rw [Fin.ext_iff, val_zero]
theorem val_ne_zero_iff [NeZero n] {a : Fin n} : a.val ≠ 0 ↔ a ≠ 0 :=
val_eq_zero_iff.not
@[simp, norm_cast]
theorem val_pos_iff [NeZero n] {a : Fin n} : 0 < a.val ↔ 0 < a := by
rw [← val_fin_lt, val_zero]
/--
The `Fin.pos_iff_ne_zero` in `Lean` only applies in `Fin (n+1)`.
This one instead uses a `NeZero n` typeclass hypothesis.
-/
theorem pos_iff_ne_zero' [NeZero n] (a : Fin n) : 0 < a ↔ a ≠ 0 := by
rw [← val_pos_iff, Nat.pos_iff_ne_zero, val_ne_zero_iff]
@[simp] lemma cast_eq_self (a : Fin n) : a.cast rfl = a := rfl
@[simp] theorem cast_eq_zero {k l : ℕ} [NeZero k] [NeZero l]
(h : k = l) (x : Fin k) : Fin.cast h x = 0 ↔ x = 0 := by
simp [← val_eq_zero_iff]
lemma cast_injective {k l : ℕ} (h : k = l) : Injective (Fin.cast h) :=
fun a b hab ↦ by simpa [← val_eq_val] using hab
theorem last_pos' [NeZero n] : 0 < last n := n.pos_of_neZero
theorem one_lt_last [NeZero n] : 1 < last (n + 1) := by
rw [lt_iff_val_lt_val, val_one, val_last, Nat.lt_add_left_iff_pos, Nat.pos_iff_ne_zero]
exact NeZero.ne n
end Order
/-! ### Coercions to `ℤ` and the `fin_omega` tactic. -/
open Int
theorem coe_int_sub_eq_ite {n : Nat} (u v : Fin n) :
((u - v : Fin n) : Int) = if v ≤ u then (u - v : Int) else (u - v : Int) + n := by
rw [Fin.sub_def]
split
· rw [natCast_emod, Int.emod_eq_sub_self_emod, Int.emod_eq_of_lt] <;> omega
· rw [natCast_emod, Int.emod_eq_of_lt] <;> omega
theorem coe_int_sub_eq_mod {n : Nat} (u v : Fin n) :
((u - v : Fin n) : Int) = ((u : Int) - (v : Int)) % n := by
rw [coe_int_sub_eq_ite]
split
· rw [Int.emod_eq_of_lt] <;> omega
· rw [Int.emod_eq_add_self_emod, Int.emod_eq_of_lt] <;> omega
theorem coe_int_add_eq_ite {n : Nat} (u v : Fin n) :
((u + v : Fin n) : Int) = if (u + v : ℕ) < n then (u + v : Int) else (u + v : Int) - n := by
rw [Fin.add_def]
split
· rw [natCast_emod, Int.emod_eq_of_lt] <;> omega
· rw [natCast_emod, Int.emod_eq_sub_self_emod, Int.emod_eq_of_lt] <;> omega
theorem coe_int_add_eq_mod {n : Nat} (u v : Fin n) :
((u + v : Fin n) : Int) = ((u : Int) + (v : Int)) % n := by
rw [coe_int_add_eq_ite]
split
· rw [Int.emod_eq_of_lt] <;> omega
· rw [Int.emod_eq_sub_self_emod, Int.emod_eq_of_lt] <;> omega
-- Write `a + b` as `if (a + b : ℕ) < n then (a + b : ℤ) else (a + b : ℤ) - n` and
-- similarly `a - b` as `if (b : ℕ) ≤ a then (a - b : ℤ) else (a - b : ℤ) + n`.
attribute [fin_omega] coe_int_sub_eq_ite coe_int_add_eq_ite
-- Rewrite inequalities in `Fin` to inequalities in `ℕ`
attribute [fin_omega] Fin.lt_iff_val_lt_val Fin.le_iff_val_le_val
-- Rewrite `1 : Fin (n + 2)` to `1 : ℤ`
attribute [fin_omega] val_one
/--
Preprocessor for `omega` to handle inequalities in `Fin`.
Note that this involves a lot of case splitting, so may be slow.
-/
-- Further adjustment to the simp set can probably make this more powerful.
-- Please experiment and PR updates!
macro "fin_omega" : tactic => `(tactic|
{ try simp only [fin_omega, ← Int.ofNat_lt, ← Int.ofNat_le] at *
omega })
section Add
/-!
### addition, numerals, and coercion from Nat
-/
@[simp]
theorem val_one' (n : ℕ) [NeZero n] : ((1 : Fin n) : ℕ) = 1 % n :=
rfl
@[deprecated val_one' (since := "2025-03-10")]
theorem val_one'' {n : ℕ} : ((1 : Fin (n + 1)) : ℕ) = 1 % (n + 1) :=
rfl
instance nontrivial {n : ℕ} : Nontrivial (Fin (n + 2)) where
exists_pair_ne := ⟨0, 1, (ne_iff_vne 0 1).mpr (by simp [val_one, val_zero])⟩
theorem nontrivial_iff_two_le : Nontrivial (Fin n) ↔ 2 ≤ n := by
rcases n with (_ | _ | n) <;>
simp [Fin.nontrivial, not_nontrivial, Nat.succ_le_iff]
section Monoid
instance inhabitedFinOneAdd (n : ℕ) : Inhabited (Fin (1 + n)) :=
haveI : NeZero (1 + n) := by rw [Nat.add_comm]; infer_instance
inferInstance
@[simp]
theorem default_eq_zero (n : ℕ) [NeZero n] : (default : Fin n) = 0 :=
rfl
instance instNatCast [NeZero n] : NatCast (Fin n) where
natCast i := Fin.ofNat' n i
lemma natCast_def [NeZero n] (a : ℕ) : (a : Fin n) = ⟨a % n, mod_lt _ n.pos_of_neZero⟩ := rfl
end Monoid
theorem val_add_eq_ite {n : ℕ} (a b : Fin n) :
(↑(a + b) : ℕ) = if n ≤ a + b then a + b - n else a + b := by
rw [Fin.val_add, Nat.add_mod_eq_ite, Nat.mod_eq_of_lt (show ↑a < n from a.2),
Nat.mod_eq_of_lt (show ↑b < n from b.2)]
theorem val_add_eq_of_add_lt {n : ℕ} {a b : Fin n} (huv : a.val + b.val < n) :
(a + b).val = a.val + b.val := by
rw [val_add]
simp [Nat.mod_eq_of_lt huv]
lemma intCast_val_sub_eq_sub_add_ite {n : ℕ} (a b : Fin n) :
((a - b).val : ℤ) = a.val - b.val + if b ≤ a then 0 else n := by
split <;> fin_omega
lemma one_le_of_ne_zero {n : ℕ} [NeZero n] {k : Fin n} (hk : k ≠ 0) : 1 ≤ k := by
obtain ⟨n, rfl⟩ := Nat.exists_eq_succ_of_ne_zero (NeZero.ne n)
cases n with
| zero => simp only [Nat.reduceAdd, Fin.isValue, Fin.zero_le]
| succ n => rwa [Fin.le_iff_val_le_val, Fin.val_one, Nat.one_le_iff_ne_zero, val_ne_zero_iff]
lemma val_sub_one_of_ne_zero [NeZero n] {i : Fin n} (hi : i ≠ 0) : (i - 1).val = i - 1 := by
obtain ⟨n, rfl⟩ := Nat.exists_eq_succ_of_ne_zero (NeZero.ne n)
rw [Fin.sub_val_of_le (one_le_of_ne_zero hi), Fin.val_one', Nat.mod_eq_of_lt
(Nat.succ_le_iff.mpr (nontrivial_iff_two_le.mp <| nontrivial_of_ne i 0 hi))]
section OfNatCoe
@[simp]
theorem ofNat'_eq_cast (n : ℕ) [NeZero n] (a : ℕ) : Fin.ofNat' n a = a :=
rfl
@[simp] lemma val_natCast (a n : ℕ) [NeZero n] : (a : Fin n).val = a % n := rfl
/-- Converting an in-range number to `Fin (n + 1)` produces a result
whose value is the original number. -/
theorem val_cast_of_lt {n : ℕ} [NeZero n] {a : ℕ} (h : a < n) : (a : Fin n).val = a :=
Nat.mod_eq_of_lt h
/-- If `n` is non-zero, converting the value of a `Fin n` to `Fin n` results
in the same value. -/
@[simp, norm_cast] theorem cast_val_eq_self {n : ℕ} [NeZero n] (a : Fin n) : (a.val : Fin n) = a :=
Fin.ext <| val_cast_of_lt a.isLt
-- This is a special case of `CharP.cast_eq_zero` that doesn't require typeclass search
@[simp high] lemma natCast_self (n : ℕ) [NeZero n] : (n : Fin n) = 0 := by ext; simp
@[simp] lemma natCast_eq_zero {a n : ℕ} [NeZero n] : (a : Fin n) = 0 ↔ n ∣ a := by
simp [Fin.ext_iff, Nat.dvd_iff_mod_eq_zero]
@[simp]
theorem natCast_eq_last (n) : (n : Fin (n + 1)) = Fin.last n := by ext; simp
theorem le_val_last (i : Fin (n + 1)) : i ≤ n := by
rw [Fin.natCast_eq_last]
exact Fin.le_last i
variable {a b : ℕ}
lemma natCast_le_natCast (han : a ≤ n) (hbn : b ≤ n) : (a : Fin (n + 1)) ≤ b ↔ a ≤ b := by
rw [← Nat.lt_succ_iff] at han hbn
simp [le_iff_val_le_val, -val_fin_le, Nat.mod_eq_of_lt, han, hbn]
lemma natCast_lt_natCast (han : a ≤ n) (hbn : b ≤ n) : (a : Fin (n + 1)) < b ↔ a < b := by
rw [← Nat.lt_succ_iff] at han hbn; simp [lt_iff_val_lt_val, Nat.mod_eq_of_lt, han, hbn]
lemma natCast_mono (hbn : b ≤ n) (hab : a ≤ b) : (a : Fin (n + 1)) ≤ b :=
(natCast_le_natCast (hab.trans hbn) hbn).2 hab
lemma natCast_strictMono (hbn : b ≤ n) (hab : a < b) : (a : Fin (n + 1)) < b :=
(natCast_lt_natCast (hab.le.trans hbn) hbn).2 hab
end OfNatCoe
end Add
section Succ
/-!
### succ and casts into larger Fin types
-/
lemma succ_injective (n : ℕ) : Injective (@Fin.succ n) := fun a b ↦ by simp [Fin.ext_iff]
/-- `Fin.succ` as an `Embedding` -/
def succEmb (n : ℕ) : Fin n ↪ Fin (n + 1) where
toFun := succ
inj' := succ_injective _
@[simp]
theorem coe_succEmb : ⇑(succEmb n) = Fin.succ :=
rfl
@[deprecated (since := "2025-04-12")]
alias val_succEmb := coe_succEmb
@[simp]
theorem exists_succ_eq {x : Fin (n + 1)} : (∃ y, Fin.succ y = x) ↔ x ≠ 0 :=
⟨fun ⟨_, hy⟩ => hy ▸ succ_ne_zero _, x.cases (fun h => h.irrefl.elim) (fun _ _ => ⟨_, rfl⟩)⟩
theorem exists_succ_eq_of_ne_zero {x : Fin (n + 1)} (h : x ≠ 0) :
∃ y, Fin.succ y = x := exists_succ_eq.mpr h
@[simp]
theorem succ_zero_eq_one' [NeZero n] : Fin.succ (0 : Fin n) = 1 := by
cases n
· exact (NeZero.ne 0 rfl).elim
· rfl
theorem one_pos' [NeZero n] : (0 : Fin (n + 1)) < 1 := succ_zero_eq_one' (n := n) ▸ succ_pos _
theorem zero_ne_one' [NeZero n] : (0 : Fin (n + 1)) ≠ 1 := Fin.ne_of_lt one_pos'
/--
The `Fin.succ_one_eq_two` in `Lean` only applies in `Fin (n+2)`.
This one instead uses a `NeZero n` typeclass hypothesis.
-/
@[simp]
theorem succ_one_eq_two' [NeZero n] : Fin.succ (1 : Fin (n + 1)) = 2 := by
cases n
· exact (NeZero.ne 0 rfl).elim
· rfl
-- Version of `succ_one_eq_two` to be used by `dsimp`.
-- Note the `'` swapped around due to a move to std4.
/--
The `Fin.le_zero_iff` in `Lean` only applies in `Fin (n+1)`.
This one instead uses a `NeZero n` typeclass hypothesis.
-/
@[simp]
theorem le_zero_iff' {n : ℕ} [NeZero n] {k : Fin n} : k ≤ 0 ↔ k = 0 :=
⟨fun h => Fin.ext <| by rw [Nat.eq_zero_of_le_zero h]; rfl, by rintro rfl; exact Nat.le_refl _⟩
-- TODO: Move to Batteries
@[simp] lemma castLE_inj {hmn : m ≤ n} {a b : Fin m} : castLE hmn a = castLE hmn b ↔ a = b := by
simp [Fin.ext_iff]
@[simp] lemma castAdd_inj {a b : Fin m} : castAdd n a = castAdd n b ↔ a = b := by simp [Fin.ext_iff]
attribute [simp] castSucc_inj
lemma castLE_injective (hmn : m ≤ n) : Injective (castLE hmn) :=
fun _ _ hab ↦ Fin.ext (congr_arg val hab :)
lemma castAdd_injective (m n : ℕ) : Injective (@Fin.castAdd m n) := castLE_injective _
lemma castSucc_injective (n : ℕ) : Injective (@Fin.castSucc n) := castAdd_injective _ _
/-- `Fin.castLE` as an `Embedding`, `castLEEmb h i` embeds `i` into a larger `Fin` type. -/
@[simps apply]
def castLEEmb (h : n ≤ m) : Fin n ↪ Fin m where
toFun := castLE h
inj' := castLE_injective _
@[simp, norm_cast] lemma coe_castLEEmb {m n} (hmn : m ≤ n) : castLEEmb hmn = castLE hmn := rfl
/- The next proof can be golfed a lot using `Fintype.card`.
It is written this way to define `ENat.card` and `Nat.card` without a `Fintype` dependency
(not done yet). -/
lemma nonempty_embedding_iff : Nonempty (Fin n ↪ Fin m) ↔ n ≤ m := by
refine ⟨fun h ↦ ?_, fun h ↦ ⟨castLEEmb h⟩⟩
induction n generalizing m with
| zero => exact m.zero_le
| succ n ihn =>
obtain ⟨e⟩ := h
rcases exists_eq_succ_of_ne_zero (pos_iff_nonempty.2 (Nonempty.map e inferInstance)).ne'
with ⟨m, rfl⟩
refine Nat.succ_le_succ <| ihn ⟨?_⟩
refine ⟨fun i ↦ (e.setValue 0 0 i.succ).pred (mt e.setValue_eq_iff.1 i.succ_ne_zero),
fun i j h ↦ ?_⟩
simpa only [pred_inj, EmbeddingLike.apply_eq_iff_eq, succ_inj] using h
lemma equiv_iff_eq : Nonempty (Fin m ≃ Fin n) ↔ m = n :=
⟨fun ⟨e⟩ ↦ le_antisymm (nonempty_embedding_iff.1 ⟨e⟩) (nonempty_embedding_iff.1 ⟨e.symm⟩),
fun h ↦ h ▸ ⟨.refl _⟩⟩
@[simp] lemma castLE_castSucc {n m} (i : Fin n) (h : n + 1 ≤ m) :
i.castSucc.castLE h = i.castLE (Nat.le_of_succ_le h) :=
rfl
@[simp] lemma castLE_comp_castSucc {n m} (h : n + 1 ≤ m) :
Fin.castLE h ∘ Fin.castSucc = Fin.castLE (Nat.le_of_succ_le h) :=
rfl
@[simp] lemma castLE_rfl (n : ℕ) : Fin.castLE (le_refl n) = id :=
rfl
@[simp]
theorem range_castLE {n k : ℕ} (h : n ≤ k) : Set.range (castLE h) = { i : Fin k | (i : ℕ) < n } :=
Set.ext fun x => ⟨fun ⟨y, hy⟩ => hy ▸ y.2, fun hx => ⟨⟨x, hx⟩, rfl⟩⟩
@[simp]
theorem coe_of_injective_castLE_symm {n k : ℕ} (h : n ≤ k) (i : Fin k) (hi) :
((Equiv.ofInjective _ (castLE_injective h)).symm ⟨i, hi⟩ : ℕ) = i := by
rw [← coe_castLE h]
exact congr_arg Fin.val (Equiv.apply_ofInjective_symm _ _)
theorem leftInverse_cast (eq : n = m) : LeftInverse (Fin.cast eq.symm) (Fin.cast eq) :=
fun _ => rfl
theorem rightInverse_cast (eq : n = m) : RightInverse (Fin.cast eq.symm) (Fin.cast eq) :=
fun _ => rfl
@[simp]
theorem cast_inj (eq : n = m) {a b : Fin n} : a.cast eq = b.cast eq ↔ a = b := by
simp [← val_inj]
@[simp]
theorem cast_lt_cast (eq : n = m) {a b : Fin n} : a.cast eq < b.cast eq ↔ a < b :=
Iff.rfl
@[simp]
theorem cast_le_cast (eq : n = m) {a b : Fin n} : a.cast eq ≤ b.cast eq ↔ a ≤ b :=
Iff.rfl
/-- The 'identity' equivalence between `Fin m` and `Fin n` when `m = n`. -/
@[simps]
def _root_.finCongr (eq : n = m) : Fin n ≃ Fin m where
toFun := Fin.cast eq
invFun := Fin.cast eq.symm
left_inv := leftInverse_cast eq
right_inv := rightInverse_cast eq
@[simp] lemma _root_.finCongr_apply_mk (h : m = n) (k : ℕ) (hk : k < m) :
finCongr h ⟨k, hk⟩ = ⟨k, h ▸ hk⟩ := rfl
@[simp]
lemma _root_.finCongr_refl (h : n = n := rfl) : finCongr h = Equiv.refl (Fin n) := by ext; simp
@[simp] lemma _root_.finCongr_symm (h : m = n) : (finCongr h).symm = finCongr h.symm := rfl
@[simp] lemma _root_.finCongr_apply_coe (h : m = n) (k : Fin m) : (finCongr h k : ℕ) = k := rfl
lemma _root_.finCongr_symm_apply_coe (h : m = n) (k : Fin n) : ((finCongr h).symm k : ℕ) = k := rfl
/-- While in many cases `finCongr` is better than `Equiv.cast`/`cast`, sometimes we want to apply
a generic theorem about `cast`. -/
lemma _root_.finCongr_eq_equivCast (h : n = m) : finCongr h = .cast (h ▸ rfl) := by subst h; simp
/-- While in many cases `Fin.cast` is better than `Equiv.cast`/`cast`, sometimes we want to apply
a generic theorem about `cast`. -/
theorem cast_eq_cast (h : n = m) : (Fin.cast h : Fin n → Fin m) = _root_.cast (h ▸ rfl) := by
subst h
ext
rfl
/-- `Fin.castAdd` as an `Embedding`, `castAddEmb m i` embeds `i : Fin n` in `Fin (n+m)`.
See also `Fin.natAddEmb` and `Fin.addNatEmb`. -/
def castAddEmb (m) : Fin n ↪ Fin (n + m) := castLEEmb (le_add_right n m)
@[simp]
lemma coe_castAddEmb (m) : (castAddEmb m : Fin n → Fin (n + m)) = castAdd m := rfl
lemma castAddEmb_apply (m) (i : Fin n) : castAddEmb m i = castAdd m i := rfl
/-- `Fin.castSucc` as an `Embedding`, `castSuccEmb i` embeds `i : Fin n` in `Fin (n+1)`. -/
def castSuccEmb : Fin n ↪ Fin (n + 1) := castAddEmb _
@[simp, norm_cast] lemma coe_castSuccEmb : (castSuccEmb : Fin n → Fin (n + 1)) = Fin.castSucc := rfl
lemma castSuccEmb_apply (i : Fin n) : castSuccEmb i = i.castSucc := rfl
theorem castSucc_le_succ {n} (i : Fin n) : i.castSucc ≤ i.succ := Nat.le_succ i
@[simp] theorem castSucc_le_castSucc_iff {a b : Fin n} : castSucc a ≤ castSucc b ↔ a ≤ b := .rfl
@[simp] theorem succ_le_castSucc_iff {a b : Fin n} : succ a ≤ castSucc b ↔ a < b := by
rw [le_castSucc_iff, succ_lt_succ_iff]
@[simp] theorem castSucc_lt_succ_iff {a b : Fin n} : castSucc a < succ b ↔ a ≤ b := by
rw [castSucc_lt_iff_succ_le, succ_le_succ_iff]
theorem le_of_castSucc_lt_of_succ_lt {a b : Fin (n + 1)} {i : Fin n}
(hl : castSucc i < a) (hu : b < succ i) : b < a := by
simp [Fin.lt_def, -val_fin_lt] at *; omega
theorem castSucc_lt_or_lt_succ (p : Fin (n + 1)) (i : Fin n) : castSucc i < p ∨ p < i.succ := by
simp [Fin.lt_def, -val_fin_lt]; omega
theorem succ_le_or_le_castSucc (p : Fin (n + 1)) (i : Fin n) : succ i ≤ p ∨ p ≤ i.castSucc := by
rw [le_castSucc_iff, ← castSucc_lt_iff_succ_le]
exact p.castSucc_lt_or_lt_succ i
theorem eq_castSucc_of_ne_last {x : Fin (n + 1)} (h : x ≠ (last _)) :
∃ y, Fin.castSucc y = x := exists_castSucc_eq.mpr h
@[deprecated (since := "2025-02-06")]
alias exists_castSucc_eq_of_ne_last := eq_castSucc_of_ne_last
theorem forall_fin_succ' {P : Fin (n + 1) → Prop} :
(∀ i, P i) ↔ (∀ i : Fin n, P i.castSucc) ∧ P (.last _) :=
⟨fun H => ⟨fun _ => H _, H _⟩, fun ⟨H0, H1⟩ i => Fin.lastCases H1 H0 i⟩
-- to match `Fin.eq_zero_or_eq_succ`
theorem eq_castSucc_or_eq_last {n : Nat} (i : Fin (n + 1)) :
(∃ j : Fin n, i = j.castSucc) ∨ i = last n := i.lastCases (Or.inr rfl) (Or.inl ⟨·, rfl⟩)
@[simp]
theorem castSucc_ne_last {n : ℕ} (i : Fin n) : i.castSucc ≠ .last n :=
Fin.ne_of_lt i.castSucc_lt_last
theorem exists_fin_succ' {P : Fin (n + 1) → Prop} :
(∃ i, P i) ↔ (∃ i : Fin n, P i.castSucc) ∨ P (.last _) :=
⟨fun ⟨i, h⟩ => Fin.lastCases Or.inr (fun i hi => Or.inl ⟨i, hi⟩) i h,
fun h => h.elim (fun ⟨i, hi⟩ => ⟨i.castSucc, hi⟩) (fun h => ⟨.last _, h⟩)⟩
/--
The `Fin.castSucc_zero` in `Lean` only applies in `Fin (n+1)`.
This one instead uses a `NeZero n` typeclass hypothesis.
-/
@[simp]
theorem castSucc_zero' [NeZero n] : castSucc (0 : Fin n) = 0 := rfl
@[simp]
theorem castSucc_pos_iff [NeZero n] {i : Fin n} : 0 < castSucc i ↔ 0 < i := by simp [← val_pos_iff]
/-- `castSucc i` is positive when `i` is positive.
The `Fin.castSucc_pos` in `Lean` only applies in `Fin (n+1)`.
This one instead uses a `NeZero n` typeclass hypothesis. -/
alias ⟨_, castSucc_pos'⟩ := castSucc_pos_iff
/--
The `Fin.castSucc_eq_zero_iff` in `Lean` only applies in `Fin (n+1)`.
This one instead uses a `NeZero n` typeclass hypothesis.
-/
@[simp]
theorem castSucc_eq_zero_iff' [NeZero n] (a : Fin n) : castSucc a = 0 ↔ a = 0 :=
Fin.ext_iff.trans <| (Fin.ext_iff.trans <| by simp).symm
/--
The `Fin.castSucc_ne_zero_iff` in `Lean` only applies in `Fin (n+1)`.
This one instead uses a `NeZero n` typeclass hypothesis.
-/
theorem castSucc_ne_zero_iff' [NeZero n] (a : Fin n) : castSucc a ≠ 0 ↔ a ≠ 0 :=
not_iff_not.mpr <| castSucc_eq_zero_iff' a
theorem castSucc_ne_zero_of_lt {p i : Fin n} (h : p < i) : castSucc i ≠ 0 := by
cases n
· exact i.elim0
· rw [castSucc_ne_zero_iff', Ne, Fin.ext_iff]
exact ((zero_le _).trans_lt h).ne'
theorem succ_ne_last_iff (a : Fin (n + 1)) : succ a ≠ last (n + 1) ↔ a ≠ last n :=
not_iff_not.mpr <| succ_eq_last_succ
theorem succ_ne_last_of_lt {p i : Fin n} (h : i < p) : succ i ≠ last n := by
cases n
· exact i.elim0
· rw [succ_ne_last_iff, Ne, Fin.ext_iff]
exact ((le_last _).trans_lt' h).ne
@[norm_cast, simp]
theorem coe_eq_castSucc {a : Fin n} : (a : Fin (n + 1)) = castSucc a := by
ext
exact val_cast_of_lt (Nat.lt.step a.is_lt)
theorem coe_succ_lt_iff_lt {n : ℕ} {j k : Fin n} : (j : Fin <| n + 1) < k ↔ j < k := by
simp only [coe_eq_castSucc, castSucc_lt_castSucc_iff]
@[simp]
theorem range_castSucc {n : ℕ} : Set.range (castSucc : Fin n → Fin n.succ) =
({ i | (i : ℕ) < n } : Set (Fin n.succ)) := range_castLE (by omega)
@[simp]
theorem coe_of_injective_castSucc_symm {n : ℕ} (i : Fin n.succ) (hi) :
((Equiv.ofInjective castSucc (castSucc_injective _)).symm ⟨i, hi⟩ : ℕ) = i := by
rw [← coe_castSucc]
exact congr_arg val (Equiv.apply_ofInjective_symm _ _)
/-- `Fin.addNat` as an `Embedding`, `addNatEmb m i` adds `m` to `i`, generalizes `Fin.succ`. -/
@[simps! apply]
def addNatEmb (m) : Fin n ↪ Fin (n + m) where
toFun := (addNat · m)
inj' a b := by simp [Fin.ext_iff]
/-- `Fin.natAdd` as an `Embedding`, `natAddEmb n i` adds `n` to `i` "on the left". -/
@[simps! apply]
def natAddEmb (n) {m} : Fin m ↪ Fin (n + m) where
toFun := natAdd n
inj' a b := by simp [Fin.ext_iff]
theorem castSucc_castAdd (i : Fin n) : castSucc (castAdd m i) = castAdd (m + 1) i := rfl
theorem castSucc_natAdd (i : Fin m) : castSucc (natAdd n i) = natAdd n (castSucc i) := rfl
theorem succ_castAdd (i : Fin n) : succ (castAdd m i) =
if h : i.succ = last _ then natAdd n (0 : Fin (m + 1))
else castAdd (m + 1) ⟨i.1 + 1, lt_of_le_of_ne i.2 (Fin.val_ne_iff.mpr h)⟩ := by
split_ifs with h
exacts [Fin.ext (congr_arg Fin.val h :), rfl]
theorem succ_natAdd (i : Fin m) : succ (natAdd n i) = natAdd n (succ i) := rfl
end Succ
section Pred
/-!
### pred
-/
theorem pred_one' [NeZero n] (h := (zero_ne_one' (n := n)).symm) :
Fin.pred (1 : Fin (n + 1)) h = 0 := by
simp_rw [Fin.ext_iff, coe_pred, val_one', val_zero, Nat.sub_eq_zero_iff_le, Nat.mod_le]
theorem pred_last (h := Fin.ext_iff.not.2 last_pos'.ne') :
pred (last (n + 1)) h = last n := by simp_rw [← succ_last, pred_succ]
theorem pred_lt_iff {j : Fin n} {i : Fin (n + 1)} (hi : i ≠ 0) : pred i hi < j ↔ i < succ j := by
rw [← succ_lt_succ_iff, succ_pred]
theorem lt_pred_iff {j : Fin n} {i : Fin (n + 1)} (hi : i ≠ 0) : j < pred i hi ↔ succ j < i := by
rw [← succ_lt_succ_iff, succ_pred]
theorem pred_le_iff {j : Fin n} {i : Fin (n + 1)} (hi : i ≠ 0) : pred i hi ≤ j ↔ i ≤ succ j := by
rw [← succ_le_succ_iff, succ_pred]
theorem le_pred_iff {j : Fin n} {i : Fin (n + 1)} (hi : i ≠ 0) : j ≤ pred i hi ↔ succ j ≤ i := by
rw [← succ_le_succ_iff, succ_pred]
theorem castSucc_pred_eq_pred_castSucc {a : Fin (n + 1)} (ha : a ≠ 0)
(ha' := castSucc_ne_zero_iff.mpr ha) :
(a.pred ha).castSucc = (castSucc a).pred ha' := rfl
theorem castSucc_pred_add_one_eq {a : Fin (n + 1)} (ha : a ≠ 0) :
(a.pred ha).castSucc + 1 = a := by
cases a using cases
· exact (ha rfl).elim
· rw [pred_succ, coeSucc_eq_succ]
theorem le_pred_castSucc_iff {a b : Fin (n + 1)} (ha : castSucc a ≠ 0) :
b ≤ (castSucc a).pred ha ↔ b < a := by
rw [le_pred_iff, succ_le_castSucc_iff]
theorem pred_castSucc_lt_iff {a b : Fin (n + 1)} (ha : castSucc a ≠ 0) :
(castSucc a).pred ha < b ↔ a ≤ b := by
rw [pred_lt_iff, castSucc_lt_succ_iff]
theorem pred_castSucc_lt {a : Fin (n + 1)} (ha : castSucc a ≠ 0) :
(castSucc a).pred ha < a := by rw [pred_castSucc_lt_iff, le_def]
theorem le_castSucc_pred_iff {a b : Fin (n + 1)} (ha : a ≠ 0) :
b ≤ castSucc (a.pred ha) ↔ b < a := by
rw [castSucc_pred_eq_pred_castSucc, le_pred_castSucc_iff]
theorem castSucc_pred_lt_iff {a b : Fin (n + 1)} (ha : a ≠ 0) :
castSucc (a.pred ha) < b ↔ a ≤ b := by
rw [castSucc_pred_eq_pred_castSucc, pred_castSucc_lt_iff]
theorem castSucc_pred_lt {a : Fin (n + 1)} (ha : a ≠ 0) :
castSucc (a.pred ha) < a := by rw [castSucc_pred_lt_iff, le_def]
end Pred
section CastPred
/-- `castPred i` sends `i : Fin (n + 1)` to `Fin n` as long as i ≠ last n. -/
@[inline] def castPred (i : Fin (n + 1)) (h : i ≠ last n) : Fin n := castLT i (val_lt_last h)
@[simp]
lemma castLT_eq_castPred (i : Fin (n + 1)) (h : i < last _) (h' := Fin.ext_iff.not.2 h.ne) :
castLT i h = castPred i h' := rfl
@[simp]
lemma coe_castPred (i : Fin (n + 1)) (h : i ≠ last _) : (castPred i h : ℕ) = i := rfl
@[simp]
theorem castPred_castSucc {i : Fin n} (h' := Fin.ext_iff.not.2 (castSucc_lt_last i).ne) :
castPred (castSucc i) h' = i := rfl
@[simp]
theorem castSucc_castPred (i : Fin (n + 1)) (h : i ≠ last n) :
castSucc (i.castPred h) = i := by
rcases exists_castSucc_eq.mpr h with ⟨y, rfl⟩
rw [castPred_castSucc]
theorem castPred_eq_iff_eq_castSucc (i : Fin (n + 1)) (hi : i ≠ last _) (j : Fin n) :
castPred i hi = j ↔ i = castSucc j :=
⟨fun h => by rw [← h, castSucc_castPred], fun h => by simp_rw [h, castPred_castSucc]⟩
@[simp]
theorem castPred_mk (i : ℕ) (h₁ : i < n) (h₂ := h₁.trans (Nat.lt_succ_self _))
(h₃ : ⟨i, h₂⟩ ≠ last _ := (ne_iff_vne _ _).mpr (val_last _ ▸ h₁.ne)) :
castPred ⟨i, h₂⟩ h₃ = ⟨i, h₁⟩ := rfl
@[simp]
theorem castPred_le_castPred_iff {i j : Fin (n + 1)} {hi : i ≠ last n} {hj : j ≠ last n} :
castPred i hi ≤ castPred j hj ↔ i ≤ j := Iff.rfl
/-- A version of the right-to-left implication of `castPred_le_castPred_iff`
that deduces `i ≠ last n` from `i ≤ j` and `j ≠ last n`. -/
@[gcongr]
theorem castPred_le_castPred {i j : Fin (n + 1)} (h : i ≤ j) (hj : j ≠ last n) :
castPred i (by rw [← lt_last_iff_ne_last] at hj ⊢; exact Fin.lt_of_le_of_lt h hj) ≤
castPred j hj :=
h
@[simp]
theorem castPred_lt_castPred_iff {i j : Fin (n + 1)} {hi : i ≠ last n} {hj : j ≠ last n} :
castPred i hi < castPred j hj ↔ i < j := Iff.rfl
/-- A version of the right-to-left implication of `castPred_lt_castPred_iff`
that deduces `i ≠ last n` from `i < j`. -/
@[gcongr]
theorem castPred_lt_castPred {i j : Fin (n + 1)} (h : i < j) (hj : j ≠ last n) :
castPred i (ne_last_of_lt h) < castPred j hj := h
theorem castPred_lt_iff {j : Fin n} {i : Fin (n + 1)} (hi : i ≠ last n) :
castPred i hi < j ↔ i < castSucc j := by
rw [← castSucc_lt_castSucc_iff, castSucc_castPred]
theorem lt_castPred_iff {j : Fin n} {i : Fin (n + 1)} (hi : i ≠ last n) :
j < castPred i hi ↔ castSucc j < i := by
rw [← castSucc_lt_castSucc_iff, castSucc_castPred]
theorem castPred_le_iff {j : Fin n} {i : Fin (n + 1)} (hi : i ≠ last n) :
castPred i hi ≤ j ↔ i ≤ castSucc j := by
rw [← castSucc_le_castSucc_iff, castSucc_castPred]
theorem le_castPred_iff {j : Fin n} {i : Fin (n + 1)} (hi : i ≠ last n) :
j ≤ castPred i hi ↔ castSucc j ≤ i := by
rw [← castSucc_le_castSucc_iff, castSucc_castPred]
@[simp]
theorem castPred_inj {i j : Fin (n + 1)} {hi : i ≠ last n} {hj : j ≠ last n} :
castPred i hi = castPred j hj ↔ i = j := by
simp_rw [Fin.ext_iff, le_antisymm_iff, ← le_def, castPred_le_castPred_iff]
theorem castPred_zero' [NeZero n] (h := Fin.ext_iff.not.2 last_pos'.ne) :
castPred (0 : Fin (n + 1)) h = 0 := rfl
theorem castPred_zero (h := Fin.ext_iff.not.2 last_pos.ne) :
castPred (0 : Fin (n + 2)) h = 0 := rfl
@[simp]
theorem castPred_eq_zero [NeZero n] {i : Fin (n + 1)} (h : i ≠ last n) :
Fin.castPred i h = 0 ↔ i = 0 := by
rw [← castPred_zero', castPred_inj]
@[simp]
theorem castPred_one [NeZero n] (h := Fin.ext_iff.not.2 one_lt_last.ne) :
castPred (1 : Fin (n + 2)) h = 1 := by
cases n
· exact subsingleton_one.elim _ 1
· rfl
theorem succ_castPred_eq_castPred_succ {a : Fin (n + 1)} (ha : a ≠ last n)
(ha' := a.succ_ne_last_iff.mpr ha) :
(a.castPred ha).succ = (succ a).castPred ha' := rfl
theorem succ_castPred_eq_add_one {a : Fin (n + 1)} (ha : a ≠ last n) :
(a.castPred ha).succ = a + 1 := by
cases a using lastCases
· exact (ha rfl).elim
· rw [castPred_castSucc, coeSucc_eq_succ]
theorem castpred_succ_le_iff {a b : Fin (n + 1)} (ha : succ a ≠ last (n + 1)) :
(succ a).castPred ha ≤ b ↔ a < b := by
rw [castPred_le_iff, succ_le_castSucc_iff]
theorem lt_castPred_succ_iff {a b : Fin (n + 1)} (ha : succ a ≠ last (n + 1)) :
b < (succ a).castPred ha ↔ b ≤ a := by
rw [lt_castPred_iff, castSucc_lt_succ_iff]
theorem lt_castPred_succ {a : Fin (n + 1)} (ha : succ a ≠ last (n + 1)) :
a < (succ a).castPred ha := by rw [lt_castPred_succ_iff, le_def]
theorem succ_castPred_le_iff {a b : Fin (n + 1)} (ha : a ≠ last n) :
succ (a.castPred ha) ≤ b ↔ a < b := by
rw [succ_castPred_eq_castPred_succ ha, castpred_succ_le_iff]
theorem lt_succ_castPred_iff {a b : Fin (n + 1)} (ha : a ≠ last n) :
b < succ (a.castPred ha) ↔ b ≤ a := by
rw [succ_castPred_eq_castPred_succ ha, lt_castPred_succ_iff]
theorem lt_succ_castPred {a : Fin (n + 1)} (ha : a ≠ last n) :
a < succ (a.castPred ha) := by rw [lt_succ_castPred_iff, le_def]
theorem castPred_le_pred_iff {a b : Fin (n + 1)} (ha : a ≠ last n) (hb : b ≠ 0) :
castPred a ha ≤ pred b hb ↔ a < b := by
rw [le_pred_iff, succ_castPred_le_iff]
theorem pred_lt_castPred_iff {a b : Fin (n + 1)} (ha : a ≠ 0) (hb : b ≠ last n) :
pred a ha < castPred b hb ↔ a ≤ b := by
rw [lt_castPred_iff, castSucc_pred_lt_iff ha]
theorem pred_lt_castPred {a : Fin (n + 1)} (h₁ : a ≠ 0) (h₂ : a ≠ last n) :
pred a h₁ < castPred a h₂ := by
rw [pred_lt_castPred_iff, le_def]
end CastPred
section SuccAbove
variable {p : Fin (n + 1)} {i j : Fin n}
/-- `succAbove p i` embeds `Fin n` into `Fin (n + 1)` with a hole around `p`. -/
def succAbove (p : Fin (n + 1)) (i : Fin n) : Fin (n + 1) :=
if castSucc i < p then i.castSucc else i.succ
/-- Embedding `i : Fin n` into `Fin (n + 1)` with a hole around `p : Fin (n + 1)`
embeds `i` by `castSucc` when the resulting `i.castSucc < p`. -/
lemma succAbove_of_castSucc_lt (p : Fin (n + 1)) (i : Fin n) (h : castSucc i < p) :
p.succAbove i = castSucc i := if_pos h
lemma succAbove_of_succ_le (p : Fin (n + 1)) (i : Fin n) (h : succ i ≤ p) :
p.succAbove i = castSucc i :=
succAbove_of_castSucc_lt _ _ (castSucc_lt_iff_succ_le.mpr h)
/-- Embedding `i : Fin n` into `Fin (n + 1)` with a hole around `p : Fin (n + 1)`
embeds `i` by `succ` when the resulting `p < i.succ`. -/
lemma succAbove_of_le_castSucc (p : Fin (n + 1)) (i : Fin n) (h : p ≤ castSucc i) :
p.succAbove i = i.succ := if_neg (Fin.not_lt.2 h)
lemma succAbove_of_lt_succ (p : Fin (n + 1)) (i : Fin n) (h : p < succ i) :
p.succAbove i = succ i := succAbove_of_le_castSucc _ _ (le_castSucc_iff.mpr h)
lemma succAbove_succ_of_lt (p i : Fin n) (h : p < i) : succAbove p.succ i = i.succ :=
succAbove_of_lt_succ _ _ (succ_lt_succ_iff.mpr h)
lemma succAbove_succ_of_le (p i : Fin n) (h : i ≤ p) : succAbove p.succ i = i.castSucc :=
succAbove_of_succ_le _ _ (succ_le_succ_iff.mpr h)
@[simp] lemma succAbove_succ_self (j : Fin n) : j.succ.succAbove j = j.castSucc :=
succAbove_succ_of_le _ _ Fin.le_rfl
lemma succAbove_castSucc_of_lt (p i : Fin n) (h : i < p) : succAbove p.castSucc i = i.castSucc :=
succAbove_of_castSucc_lt _ _ (castSucc_lt_castSucc_iff.2 h)
lemma succAbove_castSucc_of_le (p i : Fin n) (h : p ≤ i) : succAbove p.castSucc i = i.succ :=
succAbove_of_le_castSucc _ _ (castSucc_le_castSucc_iff.2 h)
@[simp] lemma succAbove_castSucc_self (j : Fin n) : succAbove j.castSucc j = j.succ :=
succAbove_castSucc_of_le _ _ Fin.le_rfl
lemma succAbove_pred_of_lt (p i : Fin (n + 1)) (h : p < i)
(hi := Fin.ne_of_gt <| Fin.lt_of_le_of_lt p.zero_le h) : succAbove p (i.pred hi) = i := by
rw [succAbove_of_lt_succ _ _ (succ_pred _ _ ▸ h), succ_pred]
lemma succAbove_pred_of_le (p i : Fin (n + 1)) (h : i ≤ p) (hi : i ≠ 0) :
succAbove p (i.pred hi) = (i.pred hi).castSucc := succAbove_of_succ_le _ _ (succ_pred _ _ ▸ h)
@[simp] lemma succAbove_pred_self (p : Fin (n + 1)) (h : p ≠ 0) :
succAbove p (p.pred h) = (p.pred h).castSucc := succAbove_pred_of_le _ _ Fin.le_rfl h
lemma succAbove_castPred_of_lt (p i : Fin (n + 1)) (h : i < p)
(hi := Fin.ne_of_lt <| Nat.lt_of_lt_of_le h p.le_last) : succAbove p (i.castPred hi) = i := by
rw [succAbove_of_castSucc_lt _ _ (castSucc_castPred _ _ ▸ h), castSucc_castPred]
lemma succAbove_castPred_of_le (p i : Fin (n + 1)) (h : p ≤ i) (hi : i ≠ last n) :
succAbove p (i.castPred hi) = (i.castPred hi).succ :=
succAbove_of_le_castSucc _ _ (castSucc_castPred _ _ ▸ h)
lemma succAbove_castPred_self (p : Fin (n + 1)) (h : p ≠ last n) :
succAbove p (p.castPred h) = (p.castPred h).succ := succAbove_castPred_of_le _ _ Fin.le_rfl h
/-- Embedding `i : Fin n` into `Fin (n + 1)` with a hole around `p : Fin (n + 1)`
never results in `p` itself -/
@[simp]
lemma succAbove_ne (p : Fin (n + 1)) (i : Fin n) : p.succAbove i ≠ p := by
rcases p.castSucc_lt_or_lt_succ i with (h | h)
· rw [succAbove_of_castSucc_lt _ _ h]
exact Fin.ne_of_lt h
· rw [succAbove_of_lt_succ _ _ h]
exact Fin.ne_of_gt h
@[simp]
lemma ne_succAbove (p : Fin (n + 1)) (i : Fin n) : p ≠ p.succAbove i := (succAbove_ne _ _).symm
/-- Given a fixed pivot `p : Fin (n + 1)`, `p.succAbove` is injective. -/
lemma succAbove_right_injective : Injective p.succAbove := by
rintro i j hij
unfold succAbove at hij
split_ifs at hij with hi hj hj
· exact castSucc_injective _ hij
· rw [hij] at hi
cases hj <| Nat.lt_trans j.castSucc_lt_succ hi
· rw [← hij] at hj
cases hi <| Nat.lt_trans i.castSucc_lt_succ hj
· exact succ_injective _ hij
/-- Given a fixed pivot `p : Fin (n + 1)`, `p.succAbove` is injective. -/
lemma succAbove_right_inj : p.succAbove i = p.succAbove j ↔ i = j :=
succAbove_right_injective.eq_iff
/-- `Fin.succAbove p` as an `Embedding`. -/
@[simps!]
def succAboveEmb (p : Fin (n + 1)) : Fin n ↪ Fin (n + 1) := ⟨p.succAbove, succAbove_right_injective⟩
@[simp, norm_cast] lemma coe_succAboveEmb (p : Fin (n + 1)) : p.succAboveEmb = p.succAbove := rfl
@[simp]
lemma succAbove_ne_zero_zero [NeZero n] {a : Fin (n + 1)} (ha : a ≠ 0) : a.succAbove 0 = 0 := by
rw [Fin.succAbove_of_castSucc_lt]
· exact castSucc_zero'
· exact Fin.pos_iff_ne_zero.2 ha
lemma succAbove_eq_zero_iff [NeZero n] {a : Fin (n + 1)} {b : Fin n} (ha : a ≠ 0) :
a.succAbove b = 0 ↔ b = 0 := by
rw [← succAbove_ne_zero_zero ha, succAbove_right_inj]
lemma succAbove_ne_zero [NeZero n] {a : Fin (n + 1)} {b : Fin n} (ha : a ≠ 0) (hb : b ≠ 0) :
a.succAbove b ≠ 0 := mt (succAbove_eq_zero_iff ha).mp hb
/-- Embedding `Fin n` into `Fin (n + 1)` with a hole around zero embeds by `succ`. -/
@[simp] lemma succAbove_zero : succAbove (0 : Fin (n + 1)) = Fin.succ := rfl
lemma succAbove_zero_apply (i : Fin n) : succAbove 0 i = succ i := by rw [succAbove_zero]
@[simp] lemma succAbove_ne_last_last {a : Fin (n + 2)} (h : a ≠ last (n + 1)) :
a.succAbove (last n) = last (n + 1) := by
rw [succAbove_of_lt_succ _ _ (succ_last _ ▸ lt_last_iff_ne_last.2 h), succ_last]
lemma succAbove_eq_last_iff {a : Fin (n + 2)} {b : Fin (n + 1)} (ha : a ≠ last _) :
a.succAbove b = last _ ↔ b = last _ := by
rw [← succAbove_ne_last_last ha, succAbove_right_inj]
lemma succAbove_ne_last {a : Fin (n + 2)} {b : Fin (n + 1)} (ha : a ≠ last _) (hb : b ≠ last _) :
a.succAbove b ≠ last _ := mt (succAbove_eq_last_iff ha).mp hb
/-- Embedding `Fin n` into `Fin (n + 1)` with a hole around `last n` embeds by `castSucc`. -/
@[simp] lemma succAbove_last : succAbove (last n) = castSucc := by
ext; simp only [succAbove_of_castSucc_lt, castSucc_lt_last]
lemma succAbove_last_apply (i : Fin n) : succAbove (last n) i = castSucc i := by rw [succAbove_last]
/-- Embedding `i : Fin n` into `Fin (n + 1)` using a pivot `p` that is greater
results in a value that is less than `p`. -/
lemma succAbove_lt_iff_castSucc_lt (p : Fin (n + 1)) (i : Fin n) :
p.succAbove i < p ↔ castSucc i < p := by
rcases castSucc_lt_or_lt_succ p i with H | H
· rwa [iff_true_right H, succAbove_of_castSucc_lt _ _ H]
· rw [castSucc_lt_iff_succ_le, iff_false_right (Fin.not_le.2 H), succAbove_of_lt_succ _ _ H]
exact Fin.not_lt.2 <| Fin.le_of_lt H
lemma succAbove_lt_iff_succ_le (p : Fin (n + 1)) (i : Fin n) :
p.succAbove i < p ↔ succ i ≤ p := by
rw [succAbove_lt_iff_castSucc_lt, castSucc_lt_iff_succ_le]
/-- Embedding `i : Fin n` into `Fin (n + 1)` using a pivot `p` that is lesser
results in a value that is greater than `p`. -/
lemma lt_succAbove_iff_le_castSucc (p : Fin (n + 1)) (i : Fin n) :
p < p.succAbove i ↔ p ≤ castSucc i := by
rcases castSucc_lt_or_lt_succ p i with H | H
· rw [iff_false_right (Fin.not_le.2 H), succAbove_of_castSucc_lt _ _ H]
exact Fin.not_lt.2 <| Fin.le_of_lt H
· rwa [succAbove_of_lt_succ _ _ H, iff_true_left H, le_castSucc_iff]
lemma lt_succAbove_iff_lt_castSucc (p : Fin (n + 1)) (i : Fin n) :
p < p.succAbove i ↔ p < succ i := by rw [lt_succAbove_iff_le_castSucc, le_castSucc_iff]
/-- Embedding a positive `Fin n` results in a positive `Fin (n + 1)` -/
lemma succAbove_pos [NeZero n] (p : Fin (n + 1)) (i : Fin n) (h : 0 < i) : 0 < p.succAbove i := by
by_cases H : castSucc i < p
· simpa [succAbove_of_castSucc_lt _ _ H] using castSucc_pos' h
· simp [succAbove_of_le_castSucc _ _ (Fin.not_lt.1 H)]
lemma castPred_succAbove (x : Fin n) (y : Fin (n + 1)) (h : castSucc x < y)
(h' := Fin.ne_last_of_lt <| (succAbove_lt_iff_castSucc_lt ..).2 h) :
(y.succAbove x).castPred h' = x := by
rw [castPred_eq_iff_eq_castSucc, succAbove_of_castSucc_lt _ _ h]
lemma pred_succAbove (x : Fin n) (y : Fin (n + 1)) (h : y ≤ castSucc x)
(h' := Fin.ne_zero_of_lt <| (lt_succAbove_iff_le_castSucc ..).2 h) :
(y.succAbove x).pred h' = x := by simp only [succAbove_of_le_castSucc _ _ h, pred_succ]
lemma exists_succAbove_eq {x y : Fin (n + 1)} (h : x ≠ y) : ∃ z, y.succAbove z = x := by
obtain hxy | hyx := Fin.lt_or_lt_of_ne h
exacts [⟨_, succAbove_castPred_of_lt _ _ hxy⟩, ⟨_, succAbove_pred_of_lt _ _ hyx⟩]
@[simp] lemma exists_succAbove_eq_iff {x y : Fin (n + 1)} : (∃ z, x.succAbove z = y) ↔ y ≠ x :=
⟨by rintro ⟨y, rfl⟩; exact succAbove_ne _ _, exists_succAbove_eq⟩
/-- The range of `p.succAbove` is everything except `p`. -/
@[simp] lemma range_succAbove (p : Fin (n + 1)) : Set.range p.succAbove = {p}ᶜ :=
Set.ext fun _ => exists_succAbove_eq_iff
@[simp] lemma range_succ (n : ℕ) : Set.range (Fin.succ : Fin n → Fin (n + 1)) = {0}ᶜ := by
rw [← succAbove_zero]; exact range_succAbove (0 : Fin (n + 1))
/-- `succAbove` is injective at the pivot -/
lemma succAbove_left_injective : Injective (@succAbove n) := fun _ _ h => by
simpa [range_succAbove] using congr_arg (fun f : Fin n → Fin (n + 1) => (Set.range f)ᶜ) h
/-- `succAbove` is injective at the pivot -/
@[simp] lemma succAbove_left_inj {x y : Fin (n + 1)} : x.succAbove = y.succAbove ↔ x = y :=
succAbove_left_injective.eq_iff
@[simp] lemma zero_succAbove {n : ℕ} (i : Fin n) : (0 : Fin (n + 1)).succAbove i = i.succ := rfl
lemma succ_succAbove_zero {n : ℕ} [NeZero n] (i : Fin n) : succAbove i.succ 0 = 0 := by simp
/-- `succ` commutes with `succAbove`. -/
@[simp] lemma succ_succAbove_succ {n : ℕ} (i : Fin (n + 1)) (j : Fin n) :
i.succ.succAbove j.succ = (i.succAbove j).succ := by
obtain h | h := i.lt_or_le (succ j)
· rw [succAbove_of_lt_succ _ _ h, succAbove_succ_of_lt _ _ h]
· rwa [succAbove_of_castSucc_lt _ _ h, succAbove_succ_of_le, succ_castSucc]
/-- `castSucc` commutes with `succAbove`. -/
@[simp]
lemma castSucc_succAbove_castSucc {n : ℕ} {i : Fin (n + 1)} {j : Fin n} :
i.castSucc.succAbove j.castSucc = (i.succAbove j).castSucc := by
rcases i.le_or_lt (castSucc j) with (h | h)
· rw [succAbove_of_le_castSucc _ _ h, succAbove_castSucc_of_le _ _ h, succ_castSucc]
· rw [succAbove_of_castSucc_lt _ _ h, succAbove_castSucc_of_lt _ _ h]
|
/-- `pred` commutes with `succAbove`. -/
lemma pred_succAbove_pred {a : Fin (n + 2)} {b : Fin (n + 1)} (ha : a ≠ 0) (hb : b ≠ 0)
| Mathlib/Data/Fin/Basic.lean | 1,138 | 1,140 |
/-
Copyright (c) 2024 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov
-/
import Mathlib.Algebra.Order.Ring.Int
import Mathlib.Data.Nat.Cast.Order.Basic
import Mathlib.Order.Interval.Set.OrdConnected
import Mathlib.Order.Nat
import Mathlib.Order.UpperLower.Basic
/-!
# Images of intervals under `Nat.cast : ℕ → ℤ`
In this file we prove that the image of each `Set.Ixx` interval under `Nat.cast : ℕ → ℤ`
is the corresponding interval in `ℤ`.
-/
open Set
namespace Nat
@[simp]
theorem range_cast_int : range ((↑) : ℕ → ℤ) = Ici 0 :=
Subset.antisymm (range_subset_iff.2 Int.ofNat_nonneg) CanLift.prf
theorem image_cast_int_Icc (a b : ℕ) : (↑) '' Icc a b = Icc (a : ℤ) b :=
(castOrderEmbedding (α := ℤ)).image_Icc (by simp [ordConnected_Ici]) a b
theorem image_cast_int_Ico (a b : ℕ) : (↑) '' Ico a b = Ico (a : ℤ) b :=
(castOrderEmbedding (α := ℤ)).image_Ico (by simp [ordConnected_Ici]) a b
theorem image_cast_int_Ioc (a b : ℕ) : (↑) '' Ioc a b = Ioc (a : ℤ) b :=
(castOrderEmbedding (α := ℤ)).image_Ioc (by simp [ordConnected_Ici]) a b
theorem image_cast_int_Ioo (a b : ℕ) : (↑) '' Ioo a b = Ioo (a : ℤ) b :=
| (castOrderEmbedding (α := ℤ)).image_Ioo (by simp [ordConnected_Ici]) a b
| Mathlib/Data/Nat/Cast/SetInterval.lean | 37 | 38 |
/-
Copyright (c) 2019 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel
-/
import Mathlib.Analysis.Analytic.Within
import Mathlib.Analysis.Calculus.FDeriv.Analytic
import Mathlib.Analysis.Calculus.ContDiff.FTaylorSeries
/-!
# Higher differentiability
A function is `C^1` on a domain if it is differentiable there, and its derivative is continuous.
By induction, it is `C^n` if it is `C^{n-1}` and its (n-1)-th derivative is `C^1` there or,
equivalently, if it is `C^1` and its derivative is `C^{n-1}`.
It is `C^∞` if it is `C^n` for all n.
Finally, it is `C^ω` if it is analytic (as well as all its derivative, which is automatic if the
space is complete).
We formalize these notions with predicates `ContDiffWithinAt`, `ContDiffAt`, `ContDiffOn` and
`ContDiff` saying that the function is `C^n` within a set at a point, at a point, on a set
and on the whole space respectively.
To avoid the issue of choice when choosing a derivative in sets where the derivative is not
necessarily unique, `ContDiffOn` is not defined directly in terms of the
regularity of the specific choice `iteratedFDerivWithin 𝕜 n f s` inside `s`, but in terms of the
existence of a nice sequence of derivatives, expressed with a predicate
`HasFTaylorSeriesUpToOn` defined in the file `FTaylorSeries`.
We prove basic properties of these notions.
## Main definitions and results
Let `f : E → F` be a map between normed vector spaces over a nontrivially normed field `𝕜`.
* `ContDiff 𝕜 n f`: expresses that `f` is `C^n`, i.e., it admits a Taylor series up to
rank `n`.
* `ContDiffOn 𝕜 n f s`: expresses that `f` is `C^n` in `s`.
* `ContDiffAt 𝕜 n f x`: expresses that `f` is `C^n` around `x`.
* `ContDiffWithinAt 𝕜 n f s x`: expresses that `f` is `C^n` around `x` within the set `s`.
In sets of unique differentiability, `ContDiffOn 𝕜 n f s` can be expressed in terms of the
properties of `iteratedFDerivWithin 𝕜 m f s` for `m ≤ n`. In the whole space,
`ContDiff 𝕜 n f` can be expressed in terms of the properties of `iteratedFDeriv 𝕜 m f`
for `m ≤ n`.
## Implementation notes
The definitions in this file are designed to work on any field `𝕜`. They are sometimes slightly more
complicated than the naive definitions one would guess from the intuition over the real or complex
numbers, but they are designed to circumvent the lack of gluing properties and partitions of unity
in general. In the usual situations, they coincide with the usual definitions.
### Definition of `C^n` functions in domains
One could define `C^n` functions in a domain `s` by fixing an arbitrary choice of derivatives (this
is what we do with `iteratedFDerivWithin`) and requiring that all these derivatives up to `n` are
continuous. If the derivative is not unique, this could lead to strange behavior like two `C^n`
functions `f` and `g` on `s` whose sum is not `C^n`. A better definition is thus to say that a
function is `C^n` inside `s` if it admits a sequence of derivatives up to `n` inside `s`.
This definition still has the problem that a function which is locally `C^n` would not need to
be `C^n`, as different choices of sequences of derivatives around different points might possibly
not be glued together to give a globally defined sequence of derivatives. (Note that this issue
can not happen over reals, thanks to partition of unity, but the behavior over a general field is
not so clear, and we want a definition for general fields). Also, there are locality
problems for the order parameter: one could image a function which, for each `n`, has a nice
sequence of derivatives up to order `n`, but they do not coincide for varying `n` and can therefore
not be glued to give rise to an infinite sequence of derivatives. This would give a function
which is `C^n` for all `n`, but not `C^∞`. We solve this issue by putting locality conditions
in space and order in our definition of `ContDiffWithinAt` and `ContDiffOn`.
The resulting definition is slightly more complicated to work with (in fact not so much), but it
gives rise to completely satisfactory theorems.
For instance, with this definition, a real function which is `C^m` (but not better) on `(-1/m, 1/m)`
for each natural `m` is by definition `C^∞` at `0`.
There is another issue with the definition of `ContDiffWithinAt 𝕜 n f s x`. We can
require the existence and good behavior of derivatives up to order `n` on a neighborhood of `x`
within `s`. However, this does not imply continuity or differentiability within `s` of the function
at `x` when `x` does not belong to `s`. Therefore, we require such existence and good behavior on
a neighborhood of `x` within `s ∪ {x}` (which appears as `insert x s` in this file).
## 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`. To
avoid ambiguities with the two tops, the theorems name use either `infty` or `omega`.
These notations are scoped in `ContDiff`.
## Tags
derivative, differentiability, higher derivative, `C^n`, multilinear, Taylor series, formal series
-/
noncomputable section
open Set Fin Filter Function
open scoped NNReal Topology ContDiff
universe u uE uF uG uX
variable {𝕜 : Type u} [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 uX} [NormedAddCommGroup X] [NormedSpace 𝕜 X]
{s s₁ t u : Set E} {f f₁ : E → F} {g : F → G} {x x₀ : E} {c : F} {m n : WithTop ℕ∞}
{p : E → FormalMultilinearSeries 𝕜 E F}
/-! ### Smooth functions within a set around a point -/
variable (𝕜) in
/-- A function is continuously differentiable up to order `n` within a set `s` at a point `x` if
it admits continuous derivatives up to order `n` in a neighborhood of `x` in `s ∪ {x}`.
For `n = ∞`, we only require that this holds up to any finite order (where the neighborhood may
depend on the finite order we consider).
For `n = ω`, we require the function to be analytic within `s` at `x`. The precise definition we
give (all the derivatives should be analytic) is more involved to work around issues when the space
is not complete, but it is equivalent when the space is complete.
For instance, a real function which is `C^m` on `(-1/m, 1/m)` for each natural `m`, but not
better, is `C^∞` at `0` within `univ`.
-/
def ContDiffWithinAt (n : WithTop ℕ∞) (f : E → F) (s : Set E) (x : E) : Prop :=
match n with
| ω => ∃ u ∈ 𝓝[insert x s] x, ∃ p : E → FormalMultilinearSeries 𝕜 E F,
HasFTaylorSeriesUpToOn ω f p u ∧ ∀ i, AnalyticOn 𝕜 (fun x ↦ p x i) u
| (n : ℕ∞) => ∀ m : ℕ, m ≤ n → ∃ u ∈ 𝓝[insert x s] x,
∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn m f p u
lemma HasFTaylorSeriesUpToOn.analyticOn
(hf : HasFTaylorSeriesUpToOn ω f p s) (h : AnalyticOn 𝕜 (fun x ↦ p x 0) s) :
AnalyticOn 𝕜 f s := by
have : AnalyticOn 𝕜 (fun x ↦ (continuousMultilinearCurryFin0 𝕜 E F) (p x 0)) s :=
(LinearIsometryEquiv.analyticOnNhd _ _ ).comp_analyticOn
h (Set.mapsTo_univ _ _)
exact this.congr (fun y hy ↦ (hf.zero_eq _ hy).symm)
lemma ContDiffWithinAt.analyticOn (h : ContDiffWithinAt 𝕜 ω f s x) :
∃ u ∈ 𝓝[insert x s] x, AnalyticOn 𝕜 f u := by
obtain ⟨u, hu, p, hp, h'p⟩ := h
exact ⟨u, hu, hp.analyticOn (h'p 0)⟩
lemma ContDiffWithinAt.analyticWithinAt (h : ContDiffWithinAt 𝕜 ω f s x) :
AnalyticWithinAt 𝕜 f s x := by
obtain ⟨u, hu, hf⟩ := h.analyticOn
have xu : x ∈ u := mem_of_mem_nhdsWithin (by simp) hu
exact (hf x xu).mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert _ _) hu)
theorem contDiffWithinAt_omega_iff_analyticWithinAt [CompleteSpace F] :
ContDiffWithinAt 𝕜 ω f s x ↔ AnalyticWithinAt 𝕜 f s x := by
refine ⟨fun h ↦ h.analyticWithinAt, fun h ↦ ?_⟩
obtain ⟨u, hu, p, hp, h'p⟩ := h.exists_hasFTaylorSeriesUpToOn ω
exact ⟨u, hu, p, hp.of_le le_top, fun i ↦ h'p i⟩
theorem contDiffWithinAt_nat {n : ℕ} :
ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x,
∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn n f p u :=
⟨fun H => H n le_rfl, fun ⟨u, hu, p, hp⟩ _m hm => ⟨u, hu, p, hp.of_le (mod_cast hm)⟩⟩
/-- When `n` is either a natural number or `ω`, one can characterize the property of being `C^n`
as the existence of a neighborhood on which there is a Taylor series up to order `n`,
requiring in addition that its terms are analytic in the `ω` case. -/
lemma contDiffWithinAt_iff_of_ne_infty (hn : n ≠ ∞) :
ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x,
∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn n f p u ∧
(n = ω → ∀ i, AnalyticOn 𝕜 (fun x ↦ p x i) u) := by
match n with
| ω => simp [ContDiffWithinAt]
| ∞ => simp at hn
| (n : ℕ) => simp [contDiffWithinAt_nat]
theorem ContDiffWithinAt.of_le (h : ContDiffWithinAt 𝕜 n f s x) (hmn : m ≤ n) :
ContDiffWithinAt 𝕜 m f s x := by
match n with
| ω => match m with
| ω => exact h
| (m : ℕ∞) =>
intro k _
obtain ⟨u, hu, p, hp, -⟩ := h
exact ⟨u, hu, p, hp.of_le le_top⟩
| (n : ℕ∞) => match m with
| ω => simp at hmn
| (m : ℕ∞) => exact fun k hk ↦ h k (le_trans hk (mod_cast hmn))
/-- In a complete space, a function which is analytic within a set at a point is also `C^ω` there.
Note that the same statement for `AnalyticOn` does not require completeness, see
`AnalyticOn.contDiffOn`. -/
theorem AnalyticWithinAt.contDiffWithinAt [CompleteSpace F] (h : AnalyticWithinAt 𝕜 f s x) :
ContDiffWithinAt 𝕜 n f s x :=
(contDiffWithinAt_omega_iff_analyticWithinAt.2 h).of_le le_top
theorem contDiffWithinAt_iff_forall_nat_le {n : ℕ∞} :
ContDiffWithinAt 𝕜 n f s x ↔ ∀ m : ℕ, ↑m ≤ n → ContDiffWithinAt 𝕜 m f s x :=
⟨fun H _ hm => H.of_le (mod_cast hm), fun H m hm => H m hm _ le_rfl⟩
theorem contDiffWithinAt_infty :
ContDiffWithinAt 𝕜 ∞ f s x ↔ ∀ n : ℕ, ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_iff_forall_nat_le.trans <| by simp only [forall_prop_of_true, le_top]
@[deprecated (since := "2024-11-25")] alias contDiffWithinAt_top := contDiffWithinAt_infty
theorem ContDiffWithinAt.continuousWithinAt (h : ContDiffWithinAt 𝕜 n f s x) :
ContinuousWithinAt f s x := by
have := h.of_le (zero_le _)
simp only [ContDiffWithinAt, nonpos_iff_eq_zero, Nat.cast_eq_zero,
mem_pure, forall_eq, CharP.cast_eq_zero] at this
rcases this with ⟨u, hu, p, H⟩
rw [mem_nhdsWithin_insert] at hu
exact (H.continuousOn.continuousWithinAt hu.1).mono_of_mem_nhdsWithin hu.2
theorem ContDiffWithinAt.congr_of_eventuallyEq (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s x := by
match n with
| ω =>
obtain ⟨u, hu, p, H, H'⟩ := h
exact ⟨{x ∈ u | f₁ x = f x}, Filter.inter_mem hu (mem_nhdsWithin_insert.2 ⟨hx, h₁⟩), p,
(H.mono (sep_subset _ _)).congr fun _ ↦ And.right,
fun i ↦ (H' i).mono (sep_subset _ _)⟩
| (n : ℕ∞) =>
intro m hm
let ⟨u, hu, p, H⟩ := h m hm
exact ⟨{ x ∈ u | f₁ x = f x }, Filter.inter_mem hu (mem_nhdsWithin_insert.2 ⟨hx, h₁⟩), p,
(H.mono (sep_subset _ _)).congr fun _ ↦ And.right⟩
theorem Filter.EventuallyEq.congr_contDiffWithinAt (h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : f₁ x = f x) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun H ↦ H.congr_of_eventuallyEq h₁.symm hx.symm, fun H ↦ H.congr_of_eventuallyEq h₁ hx⟩
|
theorem ContDiffWithinAt.congr_of_eventuallyEq_insert (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : f₁ =ᶠ[𝓝[insert x s] x] f) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr_of_eventuallyEq (nhdsWithin_mono x (subset_insert x s) h₁)
(mem_of_mem_nhdsWithin (mem_insert x s) h₁ :)
theorem Filter.EventuallyEq.congr_contDiffWithinAt_of_insert (h₁ : f₁ =ᶠ[𝓝[insert x s] x] f) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun H ↦ H.congr_of_eventuallyEq_insert h₁.symm, fun H ↦ H.congr_of_eventuallyEq_insert h₁⟩
| Mathlib/Analysis/Calculus/ContDiff/Defs.lean | 229 | 237 |
/-
Copyright (c) 2024 Andrew Yang. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Andrew Yang
-/
import Mathlib.RingTheory.Ideal.Cotangent
import Mathlib.RingTheory.Localization.Away.Basic
import Mathlib.RingTheory.MvPolynomial.Tower
import Mathlib.RingTheory.TensorProduct.Basic
import Mathlib.RingTheory.Extension
/-!
# Generators of algebras
## Main definition
- `Algebra.Generators`: A family of generators of a `R`-algebra `S` consists of
1. `vars`: The type of variables.
2. `val : vars → S`: The assignment of each variable to a value.
3. `σ`: A set-theoretic section of the induced `R`-algebra homomorphism `R[X] → S`, where we
write `R[X]` for `R[vars]`.
- `Algebra.Generators.Hom`: Given a commuting square
```
R --→ P = R[X] ---→ S
| |
↓ ↓
R' -→ P' = R'[X'] → S
```
A hom between `P` and `P'` is an assignment `X → P'` such that the arrows commute.
- `Algebra.Generators.Cotangent`: The cotangent space wrt `P = R[X] → S`, i.e. the
space `I/I²` with `I` being the kernel of the presentation.
## TODOs
Currently, Lean does not see through the `vars` field of terms of `Generators R S` obtained
from constructions, e.g. composition. This causes fragile and cumbersome proofs, because
`simp` and `rw` often don't work properly. `Generators R S` (and `Presentation R S`, etc.) should
be refactored in a way that makes these equalities reducibly def-eq, for example
by unbundling the `vars` field or making the field globally reducible in constructions using
unification hints.
-/
universe w u v
open TensorProduct MvPolynomial
variable (R : Type u) (S : Type v) [CommRing R] [CommRing S] [Algebra R S]
/-- A family of generators of a `R`-algebra `S` consists of
1. `vars`: The type of variables.
2. `val : vars → S`: The assignment of each variable to a value in `S`.
3. `σ`: A section of `R[X] → S`. -/
structure Algebra.Generators where
/-- The type of variables. -/
vars : Type w
/-- The assignment of each variable to a value in `S`. -/
val : vars → S
/-- A section of `R[X] → S`. -/
σ' : S → MvPolynomial vars R
aeval_val_σ' : ∀ s, aeval val (σ' s) = s
/-- An `R[X]`-algebra instance on `S`. The default is the one induced by the map `R[X] → S`,
but this causes a diamond if there is an existing instance. -/
algebra : Algebra (MvPolynomial vars R) S := (aeval val).toAlgebra
algebraMap_eq :
algebraMap (MvPolynomial vars R) S = aeval (R := R) val := by rfl
namespace Algebra.Generators
attribute [instance] algebra
variable {R S}
variable (P : Generators.{w} R S)
/-- The polynomial ring wrt a family of generators. -/
protected
abbrev Ring : Type (max w u) := MvPolynomial P.vars R
/-- The designated section of wrt a family of generators. -/
def σ : S → P.Ring := P.σ'
/-- See Note [custom simps projection] -/
def Simps.σ : S → P.Ring := P.σ
initialize_simps_projections Algebra.Generators (σ' → σ)
@[simp]
lemma aeval_val_σ (s) : aeval P.val (P.σ s) = s := P.aeval_val_σ' s
noncomputable instance {R₀} [CommRing R₀] [Algebra R₀ R] [Algebra R₀ S] [IsScalarTower R₀ R S] :
IsScalarTower R₀ P.Ring S := IsScalarTower.of_algebraMap_eq' <|
P.algebraMap_eq ▸ ((aeval (R := R) P.val).comp_algebraMap_of_tower R₀).symm
@[simp]
lemma algebraMap_apply (x) : algebraMap P.Ring S x = aeval (R := R) P.val x := by
simp [algebraMap_eq]
@[simp]
lemma σ_smul (x y) : P.σ x • y = x * y := by
rw [Algebra.smul_def, algebraMap_apply, aeval_val_σ]
lemma σ_injective : P.σ.Injective := by
intro x y e
rw [← P.aeval_val_σ x, ← P.aeval_val_σ y, e]
lemma algebraMap_surjective : Function.Surjective (algebraMap P.Ring S) :=
(⟨_, P.algebraMap_apply _ ▸ P.aeval_val_σ ·⟩)
section Construction
/-- Construct `Generators` from an assignment `I → S` such that `R[X] → S` is surjective. -/
@[simps val, simps -isSimp vars]
noncomputable
def ofSurjective {vars} (val : vars → S) (h : Function.Surjective (aeval (R := R) val)) :
Generators R S where
vars := vars
val := val
σ' x := (h x).choose
aeval_val_σ' x := (h x).choose_spec
/-- If `algebraMap R S` is surjective, the empty type generates `S`. -/
noncomputable def ofSurjectiveAlgebraMap (h : Function.Surjective (algebraMap R S)) :
Generators.{w} R S :=
ofSurjective PEmpty.elim <| fun s ↦ by
use C (h s).choose
simp [(h s).choose_spec]
/-- The canonical generators for `R` as an `R`-algebra. -/
noncomputable def id : Generators.{w} R R := ofSurjectiveAlgebraMap <| by
rw [id.map_eq_id]
exact RingHomSurjective.is_surjective
/-- Construct `Generators` from an assignment `I → S` such that `R[X] → S` is surjective. -/
noncomputable
def ofAlgHom {I} (f : MvPolynomial I R →ₐ[R] S) (h : Function.Surjective f) :
Generators R S :=
ofSurjective (f ∘ X) (by rwa [show aeval (f ∘ X) = f by ext; simp])
/-- Construct `Generators` from a family of generators of `S`. -/
noncomputable
def ofSet {s : Set S} (hs : Algebra.adjoin R s = ⊤) : Generators R S := by
refine ofSurjective (Subtype.val : s → S) ?_
rwa [← AlgHom.range_eq_top, ← Algebra.adjoin_range_eq_range_aeval,
Subtype.range_coe_subtype, Set.setOf_mem_eq]
variable (R S) in
/-- The `Generators` containing the whole algebra, which induces the canonical map `R[S] → S`. -/
@[simps]
noncomputable
def self : Generators R S where
vars := S
val := _root_.id
σ' := X
aeval_val_σ' := aeval_X _
/-- The extension `R[X₁,...,Xₙ] → S` given a family of generators. -/
@[simps]
noncomputable
def toExtension : Extension R S where
Ring := P.Ring
σ := P.σ
algebraMap_σ := by simp
section Localization
variable (r : R) [IsLocalization.Away r S]
/-- If `S` is the localization of `R` away from `r`, we obtain a canonical generator mapping
to the inverse of `r`. -/
@[simps val, simps -isSimp vars σ]
noncomputable
def localizationAway : Generators R S where
vars := Unit
val _ := IsLocalization.Away.invSelf r
σ' s :=
letI a : R := (IsLocalization.Away.sec r s).1
letI n : ℕ := (IsLocalization.Away.sec r s).2
C a * X () ^ n
aeval_val_σ' s := by
rw [map_mul, algHom_C, map_pow, aeval_X]
simp only [← IsLocalization.Away.sec_spec, map_pow, IsLocalization.Away.invSelf]
rw [← IsLocalization.mk'_pow, one_pow, ← IsLocalization.mk'_one (M := Submonoid.powers r) S r]
rw [← IsLocalization.mk'_pow, one_pow, mul_assoc, ← IsLocalization.mk'_mul]
rw [mul_one, one_mul, IsLocalization.mk'_pow]
simp
end Localization
variable {T} [CommRing T] [Algebra R T] [Algebra S T] [IsScalarTower R S T]
/-- Given two families of generators `S[X] → T` and `R[Y] → S`,
we may construct the family of generators `R[X, Y] → T`. -/
@[simps val, simps -isSimp vars σ]
noncomputable
def comp (Q : Generators S T) (P : Generators R S) : Generators R T where
vars := Q.vars ⊕ P.vars
val := Sum.elim Q.val (algebraMap S T ∘ P.val)
σ' x := (Q.σ x).sum (fun n r ↦ rename Sum.inr (P.σ r) * monomial (n.mapDomain Sum.inl) 1)
aeval_val_σ' s := by
have (x : P.Ring) : aeval (algebraMap S T ∘ P.val) x = algebraMap S T (aeval P.val x) := by
rw [map_aeval, aeval_def, coe_eval₂Hom, ← IsScalarTower.algebraMap_eq, Function.comp_def]
conv_rhs => rw [← Q.aeval_val_σ s, ← (Q.σ s).sum_single]
simp only [map_finsuppSum, map_mul, aeval_rename, Sum.elim_comp_inr, this, aeval_val_σ,
aeval_monomial, map_one, Finsupp.prod_mapDomain_index_inj Sum.inl_injective, Sum.elim_inl,
one_mul, single_eq_monomial]
variable (S) in
/-- If `R → S → T` is a tower of algebras, a family of generators `R[X] → T`
gives a family of generators `S[X] → T`. -/
@[simps val, simps -isSimp vars]
noncomputable
def extendScalars (P : Generators R T) : Generators S T where
vars := P.vars
val := P.val
σ' x := map (algebraMap R S) (P.σ x)
aeval_val_σ' s := by simp [@aeval_def S, ← IsScalarTower.algebraMap_eq, ← @aeval_def R]
/-- If `P` is a family of generators of `S` over `R` and `T` is an `R`-algebra, we
obtain a natural family of generators of `T ⊗[R] S` over `T`. -/
@[simps! val, simps! -isSimp vars]
noncomputable
def baseChange {T} [CommRing T] [Algebra R T] (P : Generators R S) : Generators T (T ⊗[R] S) := by
apply Generators.ofSurjective (fun x ↦ 1 ⊗ₜ[R] P.val x)
intro x
induction x using TensorProduct.induction_on with
| zero => exact ⟨0, map_zero _⟩
| tmul a b =>
let X := P.σ b
use a • MvPolynomial.map (algebraMap R T) X
simp only [LinearMapClass.map_smul, X, aeval_map_algebraMap]
have : ∀ y : P.Ring,
aeval (fun x ↦ (1 ⊗ₜ[R] P.val x : T ⊗[R] S)) y = 1 ⊗ₜ aeval (fun x ↦ P.val x) y := by
intro y
induction y using MvPolynomial.induction_on with
| C a =>
rw [aeval_C, aeval_C, TensorProduct.algebraMap_apply, algebraMap_eq_smul_one, smul_tmul,
algebraMap_eq_smul_one]
| add p q hp hq => simp [map_add, tmul_add, hp, hq]
| mul_X p i hp => simp [hp]
rw [this, P.aeval_val_σ, smul_tmul', smul_eq_mul, mul_one]
| add x y ex ey =>
obtain ⟨a, ha⟩ := ex
obtain ⟨b, hb⟩ := ey
use (a + b)
rw [map_add, ha, hb]
/-- Given generators `P` and an equivalence `ι ≃ P.vars`, these
are the induced generators indexed by `ι`. -/
@[simps -isSimp vars]
noncomputable def reindex (P : Generators.{w} R S) {ι : Type*} (e : ι ≃ P.vars) :
Generators R S where
vars := ι
val := P.val ∘ e
σ' := rename e.symm ∘ P.σ
aeval_val_σ' s := by
conv_rhs => rw [← P.aeval_val_σ s]
rw [← MvPolynomial.aeval_rename]
simp
lemma reindex_val (P : Generators.{w} R S) {ι : Type*} (e : ι ≃ P.vars) :
(P.reindex e).val = P.val ∘ e :=
rfl
end Construction
variable {R' S'} [CommRing R'] [CommRing S'] [Algebra R' S'] (P' : Generators R' S')
variable {R'' S''} [CommRing R''] [CommRing S''] [Algebra R'' S''] (P'' : Generators R'' S'')
section Hom
section
variable [Algebra R R'] [Algebra R' R''] [Algebra R' S'']
variable [Algebra S S'] [Algebra S' S''] [Algebra S S'']
/-- Given a commuting square
R --→ P = R[X] ---→ S
| |
↓ ↓
R' -→ P' = R'[X'] → S
A hom between `P` and `P'` is an assignment `I → P'` such that the arrows commute.
Also see `Algebra.Generators.Hom.equivAlgHom`.
-/
@[ext]
structure Hom where
/-- The assignment of each variable in `I` to a value in `P' = R'[X']`. -/
val : P.vars → P'.Ring
aeval_val : ∀ i, aeval P'.val (val i) = algebraMap S S' (P.val i)
attribute [simp] Hom.aeval_val
variable {P P'}
/-- A hom between two families of generators gives
an algebra homomorphism between the polynomial rings. -/
noncomputable
def Hom.toAlgHom (f : Hom P P') : P.Ring →ₐ[R] P'.Ring := MvPolynomial.aeval f.val
variable [Algebra R S'] [IsScalarTower R R' S'] [IsScalarTower R S S'] in
@[simp]
lemma Hom.algebraMap_toAlgHom (f : Hom P P') (x) : MvPolynomial.aeval P'.val (f.toAlgHom x) =
algebraMap S S' (MvPolynomial.aeval P.val x) := by
suffices ((MvPolynomial.aeval P'.val).restrictScalars R).comp f.toAlgHom =
(IsScalarTower.toAlgHom R S S').comp (MvPolynomial.aeval P.val) from
DFunLike.congr_fun this x
apply MvPolynomial.algHom_ext
intro i
simp [Hom.toAlgHom]
@[simp]
lemma Hom.toAlgHom_X (f : Hom P P') (i) : f.toAlgHom (.X i) = f.val i :=
MvPolynomial.aeval_X f.val i
lemma Hom.toAlgHom_C (f : Hom P P') (r) : f.toAlgHom (.C r) = .C (algebraMap _ _ r) :=
MvPolynomial.aeval_C f.val r
lemma Hom.toAlgHom_monomial (f : Generators.Hom P P') (v r) :
f.toAlgHom (monomial v r) = r • v.prod (f.val · ^ ·) := by
rw [toAlgHom, aeval_monomial, Algebra.smul_def]
variable [Algebra R S'] [IsScalarTower R R' S'] [IsScalarTower R S S'] in
/-- Giving a hom between two families of generators is equivalent to
giving an algebra homomorphism between the polynomial rings. -/
@[simps]
noncomputable
def Hom.equivAlgHom :
Hom P P' ≃ { f : P.Ring →ₐ[R] P'.Ring //
∀ x, aeval P'.val (f x) = algebraMap S S' (aeval P.val x) } where
toFun f := ⟨f.toAlgHom, f.algebraMap_toAlgHom⟩
invFun f := ⟨fun i ↦ f.1 (.X i), fun i ↦ by simp [f.2]⟩
left_inv f := by ext; simp
right_inv f := by ext; simp
variable (P P')
/-- The hom from `P` to `P'` given by the designated section of `P'`. -/
@[simps]
def defaultHom : Hom P P' := ⟨P'.σ ∘ algebraMap S S' ∘ P.val, fun x ↦ by simp⟩
instance : Inhabited (Hom P P') := ⟨defaultHom P P'⟩
/-- The identity hom. -/
@[simps]
protected noncomputable def Hom.id : Hom P P := ⟨X, by simp⟩
@[simp]
lemma Hom.toAlgHom_id : Hom.toAlgHom (.id P) = AlgHom.id _ _ := by ext1; simp
variable {P P' P''}
/-- The composition of two homs. -/
@[simps]
noncomputable def Hom.comp [IsScalarTower R' R'' S''] [IsScalarTower R' S' S'']
[IsScalarTower S S' S''] (f : Hom P' P'') (g : Hom P P') : Hom P P'' where
val x := aeval f.val (g.val x)
aeval_val x := by
rw [IsScalarTower.algebraMap_apply S S' S'', ← g.aeval_val]
induction g.val x using MvPolynomial.induction_on with
| C r => simp [← IsScalarTower.algebraMap_apply]
| add x y hx hy => simp only [map_add, hx, hy]
| mul_X p i hp => simp only [map_mul, hp, aeval_X, aeval_val]
@[simp]
lemma Hom.comp_id [Algebra R S'] [IsScalarTower R R' S'] [IsScalarTower R S S'] (f : Hom P P') :
f.comp (Hom.id P) = f := by ext; simp
end
@[simp]
lemma Hom.id_comp [Algebra S S'] (f : Hom P P') : (Hom.id P').comp f = f := by
ext; simp [Hom.id, aeval_X_left]
variable [Algebra R R'] [Algebra R' R''] [Algebra R' S'']
variable [Algebra S S'] [Algebra S' S''] [Algebra S S'']
@[simp]
lemma Hom.toAlgHom_comp_apply
[Algebra R R''] [IsScalarTower R R' R''] [IsScalarTower R' R'' S'']
[IsScalarTower R' S' S''] [IsScalarTower S S' S'']
(f : Hom P P') (g : Hom P' P'') (x) :
(g.comp f).toAlgHom x = g.toAlgHom (f.toAlgHom x) := by
induction x using MvPolynomial.induction_on with
| C r => simp only [← MvPolynomial.algebraMap_eq, AlgHom.map_algebraMap]
| add x y hx hy => simp only [map_add, hx, hy]
| mul_X p i hp => simp only [map_mul, hp, toAlgHom_X, comp_val]; rfl
variable {T} [CommRing T] [Algebra R T] [Algebra S T] [IsScalarTower R S T]
/-- Given families of generators `X ⊆ T` over `S` and `Y ⊆ S` over `R`,
there is a map of generators `R[Y] → R[X, Y]`. -/
@[simps]
noncomputable
def toComp (Q : Generators S T) (P : Generators R S) : Hom P (Q.comp P) where
val i := X (.inr i)
aeval_val i := by simp
lemma toComp_toAlgHom (Q : Generators S T) (P : Generators R S) :
(Q.toComp P).toAlgHom = rename Sum.inr := rfl
/-- Given families of generators `X ⊆ T` over `S` and `Y ⊆ S` over `R`,
there is a map of generators `R[X, Y] → S[X]`. -/
@[simps]
noncomputable
def ofComp (Q : Generators S T) (P : Generators R S) : Hom (Q.comp P) Q where
val i := i.elim X (C ∘ P.val)
aeval_val i := by cases i <;> simp
lemma ofComp_toAlgHom_monomial_sumElim (Q : Generators S T) (P : Generators R S) (v₁ v₂ a) :
(Q.ofComp P).toAlgHom (monomial (Finsupp.sumElim v₁ v₂) a) =
monomial v₁ (aeval P.val (monomial v₂ a)) := by
dsimp only [← comp_vars]
rw [Hom.toAlgHom_monomial, monomial_eq]
simp only [MvPolynomial.algebraMap_apply, ofComp_val, aeval_monomial]
rw [Finsupp.prod_sumElim]
simp only [Function.comp_def, Sum.elim_inl, Sum.elim_inr, ← map_pow, ← map_finsuppProd,
C_mul, Algebra.smul_def, MvPolynomial.algebraMap_apply, mul_assoc]
nth_rw 2 [mul_comm]
lemma toComp_toAlgHom_monomial (Q : Generators S T) (P : Generators R S) (j a) :
(Q.toComp P).toAlgHom (monomial j a) =
monomial (Finsupp.sumElim 0 j) a := by
convert rename_monomial _ _ _
ext f (i₁ | i₂) <;>
simp [Finsupp.mapDomain_notin_range, Finsupp.mapDomain_apply Sum.inr_injective]
@[simp]
lemma toAlgHom_ofComp_rename (Q : Generators S T) (P : Generators R S) (p : P.Ring) :
(Q.ofComp P).toAlgHom ((rename Sum.inr) p) = C (algebraMap _ _ p) :=
have : (Q.ofComp P).toAlgHom.comp (rename Sum.inr) =
(IsScalarTower.toAlgHom R S Q.Ring).comp (IsScalarTower.toAlgHom R P.Ring S) := by ext; simp
DFunLike.congr_fun this p
lemma toAlgHom_ofComp_surjective (Q : Generators S T) (P : Generators R S) :
Function.Surjective (Q.ofComp P).toAlgHom := by
intro p
induction p using MvPolynomial.induction_on with
| C a =>
use MvPolynomial.rename Sum.inr (P.σ a)
simp only [Hom.toAlgHom, ofComp, Generators.comp, MvPolynomial.aeval_rename,
Sum.elim_comp_inr]
simp_rw [Function.comp_def, ← MvPolynomial.algebraMap_eq, ← IsScalarTower.toAlgHom_apply R,
← MvPolynomial.comp_aeval]
simp
| add p q hp hq =>
obtain ⟨p, rfl⟩ := hp
obtain ⟨q, rfl⟩ := hq
use p + q
simp
| mul_X p i hp =>
obtain ⟨(p : MvPolynomial (Q.vars ⊕ P.vars) R), rfl⟩ := hp
use p * MvPolynomial.X (R := R) (Sum.inl i)
simp [Algebra.Generators.ofComp, Algebra.Generators.Hom.toAlgHom]
/-- Given families of generators `X ⊆ T`, there is a map `R[X] → S[X]`. -/
@[simps]
noncomputable
def toExtendScalars (P : Generators R T) : Hom P (P.extendScalars S) where
| val := X
aeval_val i := by simp
variable {P P'} in
/-- Reinterpret a hom between generators as a hom between extensions. -/
| Mathlib/RingTheory/Generators.lean | 461 | 465 |
/-
Copyright (c) 2018 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Kevin Kappelmann
-/
import Mathlib.Algebra.Order.Floor.Defs
import Mathlib.Algebra.Order.Floor.Ring
import Mathlib.Algebra.Order.Floor.Semiring
deprecated_module (since := "2025-04-13")
| Mathlib/Algebra/Order/Floor.lean | 1,323 | 1,323 | |
/-
Copyright (c) 2021 Benjamin Davidson. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Benjamin Davidson
-/
import Mathlib.Analysis.SpecialFunctions.Log.NegMulLog
import Mathlib.Analysis.SpecialFunctions.NonIntegrable
import Mathlib.Analysis.SpecialFunctions.Pow.Deriv
import Mathlib.Analysis.SpecialFunctions.Trigonometric.ArctanDeriv
import Mathlib.MeasureTheory.Integral.IntervalIntegral.IntegrationByParts
/-!
# Integration of specific interval integrals
This file contains proofs of the integrals of various specific functions. This includes:
* Integrals of simple functions, such as `id`, `pow`, `inv`, `exp`, `log`
* Integrals of some trigonometric functions, such as `sin`, `cos`, `1 / (1 + x^2)`
* The integral of `cos x ^ 2 - sin x ^ 2`
* Reduction formulae for the integrals of `sin x ^ n` and `cos x ^ n` for `n ≥ 2`
* The computation of `∫ x in 0..π, sin x ^ n` as a product for even and odd `n` (used in proving the
Wallis product for pi)
* Integrals of the form `sin x ^ m * cos x ^ n`
With these lemmas, many simple integrals can be computed by `simp` or `norm_num`.
This file also contains some facts about the interval integrability of specific functions.
This file is still being developed.
## Tags
integrate, integration, integrable, integrability
-/
open Real Set Finset
open scoped Real Interval
variable {a b : ℝ} (n : ℕ)
namespace intervalIntegral
open MeasureTheory
variable {f : ℝ → ℝ} {μ : Measure ℝ} [IsLocallyFiniteMeasure μ] (c d : ℝ)
/-! ### Interval integrability -/
@[simp]
theorem intervalIntegrable_pow : IntervalIntegrable (fun x => x ^ n) μ a b :=
(continuous_pow n).intervalIntegrable a b
theorem intervalIntegrable_zpow {n : ℤ} (h : 0 ≤ n ∨ (0 : ℝ) ∉ [[a, b]]) :
IntervalIntegrable (fun x => x ^ n) μ a b :=
(continuousOn_id.zpow₀ n fun _ hx => h.symm.imp (ne_of_mem_of_not_mem hx) id).intervalIntegrable
/-- See `intervalIntegrable_rpow'` for a version with a weaker hypothesis on `r`, but assuming the
measure is volume. -/
theorem intervalIntegrable_rpow {r : ℝ} (h : 0 ≤ r ∨ (0 : ℝ) ∉ [[a, b]]) :
IntervalIntegrable (fun x => x ^ r) μ a b :=
(continuousOn_id.rpow_const fun _ hx =>
h.symm.imp (ne_of_mem_of_not_mem hx) id).intervalIntegrable
/-- See `intervalIntegrable_rpow` for a version applying to any locally finite measure, but with a
stronger hypothesis on `r`. -/
theorem intervalIntegrable_rpow' {r : ℝ} (h : -1 < r) :
IntervalIntegrable (fun x => x ^ r) volume a b := by
suffices ∀ c : ℝ, IntervalIntegrable (fun x => x ^ r) volume 0 c by
exact IntervalIntegrable.trans (this a).symm (this b)
have : ∀ c : ℝ, 0 ≤ c → IntervalIntegrable (fun x => x ^ r) volume 0 c := by
intro c hc
rw [intervalIntegrable_iff, uIoc_of_le hc]
have hderiv : ∀ x ∈ Ioo 0 c, HasDerivAt (fun x : ℝ => x ^ (r + 1) / (r + 1)) (x ^ r) x := by
intro x hx
convert (Real.hasDerivAt_rpow_const (p := r + 1) (Or.inl hx.1.ne')).div_const (r + 1) using 1
field_simp [(by linarith : r + 1 ≠ 0)]
apply integrableOn_deriv_of_nonneg _ hderiv
· intro x hx; apply rpow_nonneg hx.1.le
· refine (continuousOn_id.rpow_const ?_).div_const _; intro x _; right; linarith
intro c; rcases le_total 0 c with (hc | hc)
· exact this c hc
· rw [IntervalIntegrable.iff_comp_neg, neg_zero]
have m := (this (-c) (by linarith)).smul (cos (r * π))
rw [intervalIntegrable_iff] at m ⊢
refine m.congr_fun ?_ measurableSet_Ioc; intro x hx
rw [uIoc_of_le (by linarith : 0 ≤ -c)] at hx
simp only [Pi.smul_apply, Algebra.id.smul_eq_mul, log_neg_eq_log, mul_comm,
rpow_def_of_pos hx.1, rpow_def_of_neg (by linarith [hx.1] : -x < 0)]
/-- The power function `x ↦ x^s` is integrable on `(0, t)` iff `-1 < s`. -/
lemma integrableOn_Ioo_rpow_iff {s t : ℝ} (ht : 0 < t) :
IntegrableOn (fun x ↦ x ^ s) (Ioo (0 : ℝ) t) ↔ -1 < s := by
refine ⟨fun h ↦ ?_, fun h ↦ by simpa [intervalIntegrable_iff_integrableOn_Ioo_of_le ht.le]
using intervalIntegrable_rpow' h (a := 0) (b := t)⟩
contrapose! h
intro H
have I : 0 < min 1 t := lt_min zero_lt_one ht
have H' : IntegrableOn (fun x ↦ x ^ s) (Ioo 0 (min 1 t)) :=
H.mono (Set.Ioo_subset_Ioo le_rfl (min_le_right _ _)) le_rfl
have : IntegrableOn (fun x ↦ x⁻¹) (Ioo 0 (min 1 t)) := by
apply H'.mono' measurable_inv.aestronglyMeasurable
filter_upwards [ae_restrict_mem measurableSet_Ioo] with x hx
simp only [norm_inv, Real.norm_eq_abs, abs_of_nonneg (le_of_lt hx.1)]
rwa [← Real.rpow_neg_one x, Real.rpow_le_rpow_left_iff_of_base_lt_one hx.1]
exact lt_of_lt_of_le hx.2 (min_le_left _ _)
have : IntervalIntegrable (fun x ↦ x⁻¹) volume 0 (min 1 t) := by
rwa [intervalIntegrable_iff_integrableOn_Ioo_of_le I.le]
simp [intervalIntegrable_inv_iff, I.ne] at this
/-- See `intervalIntegrable_cpow'` for a version with a weaker hypothesis on `r`, but assuming the
measure is volume. -/
theorem intervalIntegrable_cpow {r : ℂ} (h : 0 ≤ r.re ∨ (0 : ℝ) ∉ [[a, b]]) :
IntervalIntegrable (fun x : ℝ => (x : ℂ) ^ r) μ a b := by
by_cases h2 : (0 : ℝ) ∉ [[a, b]]
· -- Easy case #1: 0 ∉ [a, b] -- use continuity.
refine (continuousOn_of_forall_continuousAt fun x hx => ?_).intervalIntegrable
exact Complex.continuousAt_ofReal_cpow_const _ _ (Or.inr <| ne_of_mem_of_not_mem hx h2)
rw [eq_false h2, or_false] at h
rcases lt_or_eq_of_le h with (h' | h')
· -- Easy case #2: 0 < re r -- again use continuity
exact (Complex.continuous_ofReal_cpow_const h').intervalIntegrable _ _
-- Now the hard case: re r = 0 and 0 is in the interval.
refine (IntervalIntegrable.intervalIntegrable_norm_iff ?_).mp ?_
· refine (measurable_of_continuousOn_compl_singleton (0 : ℝ) ?_).aestronglyMeasurable
exact continuousOn_of_forall_continuousAt fun x hx =>
Complex.continuousAt_ofReal_cpow_const x r (Or.inr hx)
-- reduce to case of integral over `[0, c]`
suffices ∀ c : ℝ, IntervalIntegrable (fun x : ℝ => ‖(x : ℂ) ^ r‖) μ 0 c from
(this a).symm.trans (this b)
intro c
rcases le_or_lt 0 c with (hc | hc)
· -- case `0 ≤ c`: integrand is identically 1
have : IntervalIntegrable (fun _ => 1 : ℝ → ℝ) μ 0 c := intervalIntegrable_const
rw [intervalIntegrable_iff_integrableOn_Ioc_of_le hc] at this ⊢
refine IntegrableOn.congr_fun this (fun x hx => ?_) measurableSet_Ioc
dsimp only
rw [Complex.norm_cpow_eq_rpow_re_of_pos hx.1, ← h', rpow_zero]
· -- case `c < 0`: integrand is identically constant, *except* at `x = 0` if `r ≠ 0`.
apply IntervalIntegrable.symm
rw [intervalIntegrable_iff_integrableOn_Ioc_of_le hc.le]
rw [← Ioo_union_right hc, integrableOn_union, and_comm]; constructor
· refine integrableOn_singleton_iff.mpr (Or.inr ?_)
exact isFiniteMeasureOnCompacts_of_isLocallyFiniteMeasure.lt_top_of_isCompact
isCompact_singleton
· have : ∀ x : ℝ, x ∈ Ioo c 0 → ‖Complex.exp (↑π * Complex.I * r)‖ = ‖(x : ℂ) ^ r‖ := by
intro x hx
rw [Complex.ofReal_cpow_of_nonpos hx.2.le, norm_mul, ← Complex.ofReal_neg,
Complex.norm_cpow_eq_rpow_re_of_pos (neg_pos.mpr hx.2), ← h',
rpow_zero, one_mul]
refine IntegrableOn.congr_fun ?_ this measurableSet_Ioo
rw [integrableOn_const]
refine Or.inr ((measure_mono Set.Ioo_subset_Icc_self).trans_lt ?_)
exact isFiniteMeasureOnCompacts_of_isLocallyFiniteMeasure.lt_top_of_isCompact isCompact_Icc
/-- See `intervalIntegrable_cpow` for a version applying to any locally finite measure, but with a
stronger hypothesis on `r`. -/
theorem intervalIntegrable_cpow' {r : ℂ} (h : -1 < r.re) :
IntervalIntegrable (fun x : ℝ => (x : ℂ) ^ r) volume a b := by
suffices ∀ c : ℝ, IntervalIntegrable (fun x => (x : ℂ) ^ r) volume 0 c by
exact IntervalIntegrable.trans (this a).symm (this b)
have : ∀ c : ℝ, 0 ≤ c → IntervalIntegrable (fun x => (x : ℂ) ^ r) volume 0 c := by
intro c hc
rw [← IntervalIntegrable.intervalIntegrable_norm_iff]
· rw [intervalIntegrable_iff]
apply IntegrableOn.congr_fun
· rw [← intervalIntegrable_iff]; exact intervalIntegral.intervalIntegrable_rpow' h
· intro x hx
rw [uIoc_of_le hc] at hx
dsimp only
rw [Complex.norm_cpow_eq_rpow_re_of_pos hx.1]
· exact measurableSet_uIoc
· refine ContinuousOn.aestronglyMeasurable ?_ measurableSet_uIoc
refine continuousOn_of_forall_continuousAt fun x hx => ?_
rw [uIoc_of_le hc] at hx
refine (continuousAt_cpow_const (Or.inl ?_)).comp Complex.continuous_ofReal.continuousAt
rw [Complex.ofReal_re]
exact hx.1
intro c; rcases le_total 0 c with (hc | hc)
· exact this c hc
· rw [IntervalIntegrable.iff_comp_neg, neg_zero]
have m := (this (-c) (by linarith)).const_mul (Complex.exp (π * Complex.I * r))
rw [intervalIntegrable_iff, uIoc_of_le (by linarith : 0 ≤ -c)] at m ⊢
refine m.congr_fun (fun x hx => ?_) measurableSet_Ioc
dsimp only
have : -x ≤ 0 := by linarith [hx.1]
rw [Complex.ofReal_cpow_of_nonpos this, mul_comm]
simp
/-- The complex power function `x ↦ x^s` is integrable on `(0, t)` iff `-1 < s.re`. -/
theorem integrableOn_Ioo_cpow_iff {s : ℂ} {t : ℝ} (ht : 0 < t) :
IntegrableOn (fun x : ℝ ↦ (x : ℂ) ^ s) (Ioo (0 : ℝ) t) ↔ -1 < s.re := by
refine ⟨fun h ↦ ?_, fun h ↦ by simpa [intervalIntegrable_iff_integrableOn_Ioo_of_le ht.le]
using intervalIntegrable_cpow' h (a := 0) (b := t)⟩
have B : IntegrableOn (fun a ↦ a ^ s.re) (Ioo 0 t) := by
apply (integrableOn_congr_fun _ measurableSet_Ioo).1 h.norm
intro a ha
simp [Complex.norm_cpow_eq_rpow_re_of_pos ha.1]
rwa [integrableOn_Ioo_rpow_iff ht] at B
@[simp]
theorem intervalIntegrable_id : IntervalIntegrable (fun x => x) μ a b :=
continuous_id.intervalIntegrable a b
theorem intervalIntegrable_const : IntervalIntegrable (fun _ => c) μ a b :=
continuous_const.intervalIntegrable a b
theorem intervalIntegrable_one_div (h : ∀ x : ℝ, x ∈ [[a, b]] → f x ≠ 0)
(hf : ContinuousOn f [[a, b]]) : IntervalIntegrable (fun x => 1 / f x) μ a b :=
(continuousOn_const.div hf h).intervalIntegrable
@[simp]
theorem intervalIntegrable_inv (h : ∀ x : ℝ, x ∈ [[a, b]] → f x ≠ 0)
(hf : ContinuousOn f [[a, b]]) : IntervalIntegrable (fun x => (f x)⁻¹) μ a b := by
simpa only [one_div] using intervalIntegrable_one_div h hf
@[simp]
theorem intervalIntegrable_exp : IntervalIntegrable exp μ a b :=
continuous_exp.intervalIntegrable a b
@[simp]
theorem _root_.IntervalIntegrable.log (hf : ContinuousOn f [[a, b]])
(h : ∀ x : ℝ, x ∈ [[a, b]] → f x ≠ 0) :
IntervalIntegrable (fun x => log (f x)) μ a b :=
(ContinuousOn.log hf h).intervalIntegrable
/-- See `intervalIntegrable_log'` for a version without any hypothesis on the interval, but
assuming the measure is volume. -/
@[simp]
theorem intervalIntegrable_log (h : (0 : ℝ) ∉ [[a, b]]) : IntervalIntegrable log μ a b :=
IntervalIntegrable.log continuousOn_id fun _ hx => ne_of_mem_of_not_mem hx h
/-- The real logarithm is interval integrable (with respect to the volume measure) on every
interval. See `intervalIntegrable_log` for a version applying to any locally finite measure,
but with an additional hypothesis on the interval. -/
@[simp]
theorem intervalIntegrable_log' : IntervalIntegrable log volume a b := by
-- Log is even, so it suffices to consider the case 0 < a and b = 0
apply intervalIntegrable_of_even (log_neg_eq_log · |>.symm)
intro x hx
-- Split integral
apply IntervalIntegrable.trans (b := 1)
· -- Show integrability on [0…1] using non-negativity of the derivative
rw [← neg_neg log]
apply IntervalIntegrable.neg
apply intervalIntegrable_deriv_of_nonneg (g := fun x ↦ -(x * log x - x))
· exact (continuous_mul_log.continuousOn.sub continuous_id.continuousOn).neg
· intro s ⟨hs, _⟩
norm_num at *
simpa using (hasDerivAt_id s).sub (hasDerivAt_mul_log hs.ne.symm)
· intro s ⟨hs₁, hs₂⟩
norm_num at *
exact (log_nonpos_iff hs₁.le).mpr hs₂.le
· -- Show integrability on [1…t] by continuity
apply ContinuousOn.intervalIntegrable
apply Real.continuousOn_log.mono
apply Set.not_mem_uIcc_of_lt zero_lt_one at hx
simpa
@[simp]
theorem intervalIntegrable_sin : IntervalIntegrable sin μ a b :=
continuous_sin.intervalIntegrable a b
@[simp]
theorem intervalIntegrable_cos : IntervalIntegrable cos μ a b :=
continuous_cos.intervalIntegrable a b
theorem intervalIntegrable_one_div_one_add_sq :
IntervalIntegrable (fun x : ℝ => 1 / (↑1 + x ^ 2)) μ a b := by
refine (continuous_const.div ?_ fun x => ?_).intervalIntegrable a b
· fun_prop
· nlinarith
@[simp]
theorem intervalIntegrable_inv_one_add_sq :
IntervalIntegrable (fun x : ℝ => (↑1 + x ^ 2)⁻¹) μ a b := by
field_simp; exact mod_cast intervalIntegrable_one_div_one_add_sq
/-! ### Integrals of the form `c * ∫ x in a..b, f (c * x + d)` -/
section
@[simp]
theorem mul_integral_comp_mul_right : (c * ∫ x in a..b, f (x * c)) = ∫ x in a * c..b * c, f x :=
smul_integral_comp_mul_right f c
@[simp]
theorem mul_integral_comp_mul_left : (c * ∫ x in a..b, f (c * x)) = ∫ x in c * a..c * b, f x :=
smul_integral_comp_mul_left f c
@[simp]
theorem inv_mul_integral_comp_div : (c⁻¹ * ∫ x in a..b, f (x / c)) = ∫ x in a / c..b / c, f x :=
inv_smul_integral_comp_div f c
@[simp]
theorem mul_integral_comp_mul_add :
(c * ∫ x in a..b, f (c * x + d)) = ∫ x in c * a + d..c * b + d, f x :=
smul_integral_comp_mul_add f c d
@[simp]
theorem mul_integral_comp_add_mul :
(c * ∫ x in a..b, f (d + c * x)) = ∫ x in d + c * a..d + c * b, f x :=
smul_integral_comp_add_mul f c d
@[simp]
theorem inv_mul_integral_comp_div_add :
(c⁻¹ * ∫ x in a..b, f (x / c + d)) = ∫ x in a / c + d..b / c + d, f x :=
inv_smul_integral_comp_div_add f c d
@[simp]
theorem inv_mul_integral_comp_add_div :
(c⁻¹ * ∫ x in a..b, f (d + x / c)) = ∫ x in d + a / c..d + b / c, f x :=
inv_smul_integral_comp_add_div f c d
@[simp]
theorem mul_integral_comp_mul_sub :
(c * ∫ x in a..b, f (c * x - d)) = ∫ x in c * a - d..c * b - d, f x :=
smul_integral_comp_mul_sub f c d
@[simp]
theorem mul_integral_comp_sub_mul :
(c * ∫ x in a..b, f (d - c * x)) = ∫ x in d - c * b..d - c * a, f x :=
smul_integral_comp_sub_mul f c d
@[simp]
theorem inv_mul_integral_comp_div_sub :
(c⁻¹ * ∫ x in a..b, f (x / c - d)) = ∫ x in a / c - d..b / c - d, f x :=
inv_smul_integral_comp_div_sub f c d
@[simp]
theorem inv_mul_integral_comp_sub_div :
(c⁻¹ * ∫ x in a..b, f (d - x / c)) = ∫ x in d - b / c..d - a / c, f x :=
inv_smul_integral_comp_sub_div f c d
end
end intervalIntegral
open intervalIntegral
/-! ### Integrals of simple functions -/
theorem integral_cpow {r : ℂ} (h : -1 < r.re ∨ r ≠ -1 ∧ (0 : ℝ) ∉ [[a, b]]) :
(∫ x : ℝ in a..b, (x : ℂ) ^ r) = ((b : ℂ) ^ (r + 1) - (a : ℂ) ^ (r + 1)) / (r + 1) := by
rw [sub_div]
have hr : r + 1 ≠ 0 := by
rcases h with h | h
· apply_fun Complex.re
rw [Complex.add_re, Complex.one_re, Complex.zero_re, Ne, add_eq_zero_iff_eq_neg]
exact h.ne'
· rw [Ne, ← add_eq_zero_iff_eq_neg] at h; exact h.1
by_cases hab : (0 : ℝ) ∉ [[a, b]]
· apply integral_eq_sub_of_hasDerivAt (fun x hx => ?_)
(intervalIntegrable_cpow (r := r) <| Or.inr hab)
refine hasDerivAt_ofReal_cpow_const' (ne_of_mem_of_not_mem hx hab) ?_
contrapose! hr; rwa [add_eq_zero_iff_eq_neg]
replace h : -1 < r.re := by tauto
suffices ∀ c : ℝ, (∫ x : ℝ in (0)..c, (x : ℂ) ^ r) =
(c : ℂ) ^ (r + 1) / (r + 1) - (0 : ℂ) ^ (r + 1) / (r + 1) by
rw [← integral_add_adjacent_intervals (@intervalIntegrable_cpow' a 0 r h)
(@intervalIntegrable_cpow' 0 b r h), integral_symm, this a, this b, Complex.zero_cpow hr]
ring
intro c
apply integral_eq_sub_of_hasDeriv_right
· refine ((Complex.continuous_ofReal_cpow_const ?_).div_const _).continuousOn
rwa [Complex.add_re, Complex.one_re, ← neg_lt_iff_pos_add]
· refine fun x hx => (hasDerivAt_ofReal_cpow_const' ?_ ?_).hasDerivWithinAt
· rcases le_total c 0 with (hc | hc)
· rw [max_eq_left hc] at hx; exact hx.2.ne
· rw [min_eq_left hc] at hx; exact hx.1.ne'
· contrapose! hr; rw [hr]; ring
· exact intervalIntegrable_cpow' h
theorem integral_rpow {r : ℝ} (h : -1 < r ∨ r ≠ -1 ∧ (0 : ℝ) ∉ [[a, b]]) :
∫ x in a..b, x ^ r = (b ^ (r + 1) - a ^ (r + 1)) / (r + 1) := by
have h' : -1 < (r : ℂ).re ∨ (r : ℂ) ≠ -1 ∧ (0 : ℝ) ∉ [[a, b]] := by
cases h
· left; rwa [Complex.ofReal_re]
· right; rwa [← Complex.ofReal_one, ← Complex.ofReal_neg, Ne, Complex.ofReal_inj]
have :
(∫ x in a..b, (x : ℂ) ^ (r : ℂ)) = ((b : ℂ) ^ (r + 1 : ℂ) - (a : ℂ) ^ (r + 1 : ℂ)) / (r + 1) :=
integral_cpow h'
apply_fun Complex.re at this; convert this
· simp_rw [intervalIntegral_eq_integral_uIoc, Complex.real_smul, Complex.re_ofReal_mul, rpow_def,
← RCLike.re_eq_complex_re, smul_eq_mul]
rw [integral_re]
refine intervalIntegrable_iff.mp ?_
rcases h' with h' | h'
· exact intervalIntegrable_cpow' h'
· exact intervalIntegrable_cpow (Or.inr h'.2)
· rw [(by push_cast; rfl : (r : ℂ) + 1 = ((r + 1 : ℝ) : ℂ))]
simp_rw [div_eq_inv_mul, ← Complex.ofReal_inv, Complex.re_ofReal_mul, Complex.sub_re, rpow_def]
theorem integral_zpow {n : ℤ} (h : 0 ≤ n ∨ n ≠ -1 ∧ (0 : ℝ) ∉ [[a, b]]) :
∫ x in a..b, x ^ n = (b ^ (n + 1) - a ^ (n + 1)) / (n + 1) := by
replace h : -1 < (n : ℝ) ∨ (n : ℝ) ≠ -1 ∧ (0 : ℝ) ∉ [[a, b]] := mod_cast h
exact mod_cast integral_rpow h
@[simp]
theorem integral_pow : ∫ x in a..b, x ^ n = (b ^ (n + 1) - a ^ (n + 1)) / (n + 1) := by
simpa only [← Int.natCast_succ, zpow_natCast] using integral_zpow (Or.inl n.cast_nonneg)
/-- Integral of `|x - a| ^ n` over `Ι a b`. This integral appears in the proof of the
Picard-Lindelöf/Cauchy-Lipschitz theorem. -/
theorem integral_pow_abs_sub_uIoc : ∫ x in Ι a b, |x - a| ^ n = |b - a| ^ (n + 1) / (n + 1) := by
rcases le_or_lt a b with hab | hab
· calc
∫ x in Ι a b, |x - a| ^ n = ∫ x in a..b, |x - a| ^ n := by
rw [uIoc_of_le hab, ← integral_of_le hab]
_ = ∫ x in (0)..(b - a), x ^ n := by
simp only [integral_comp_sub_right fun x => |x| ^ n, sub_self]
refine integral_congr fun x hx => congr_arg₂ Pow.pow (abs_of_nonneg <| ?_) rfl
rw [uIcc_of_le (sub_nonneg.2 hab)] at hx
exact hx.1
_ = |b - a| ^ (n + 1) / (n + 1) := by simp [abs_of_nonneg (sub_nonneg.2 hab)]
· calc
∫ x in Ι a b, |x - a| ^ n = ∫ x in b..a, |x - a| ^ n := by
rw [uIoc_of_ge hab.le, ← integral_of_le hab.le]
_ = ∫ x in b - a..0, (-x) ^ n := by
simp only [integral_comp_sub_right fun x => |x| ^ n, sub_self]
refine integral_congr fun x hx => congr_arg₂ Pow.pow (abs_of_nonpos <| ?_) rfl
rw [uIcc_of_le (sub_nonpos.2 hab.le)] at hx
exact hx.2
_ = |b - a| ^ (n + 1) / (n + 1) := by
simp [integral_comp_neg fun x => x ^ n, abs_of_neg (sub_neg.2 hab)]
@[simp]
theorem integral_id : ∫ x in a..b, x = (b ^ 2 - a ^ 2) / 2 := by
have := @integral_pow a b 1
norm_num at this
exact this
theorem integral_one : (∫ _ in a..b, (1 : ℝ)) = b - a := by
simp only [mul_one, smul_eq_mul, integral_const]
theorem integral_const_on_unit_interval : ∫ _ in a..a + 1, b = b := by simp
@[simp]
theorem integral_inv (h : (0 : ℝ) ∉ [[a, b]]) : ∫ x in a..b, x⁻¹ = log (b / a) := by
have h' := fun x (hx : x ∈ [[a, b]]) => ne_of_mem_of_not_mem hx h
rw [integral_deriv_eq_sub' _ deriv_log' (fun x hx => differentiableAt_log (h' x hx))
(continuousOn_inv₀.mono <| subset_compl_singleton_iff.mpr h),
log_div (h' b right_mem_uIcc) (h' a left_mem_uIcc)]
@[simp]
theorem integral_inv_of_pos (ha : 0 < a) (hb : 0 < b) : ∫ x in a..b, x⁻¹ = log (b / a) :=
integral_inv <| not_mem_uIcc_of_lt ha hb
@[simp]
theorem integral_inv_of_neg (ha : a < 0) (hb : b < 0) : ∫ x in a..b, x⁻¹ = log (b / a) :=
integral_inv <| not_mem_uIcc_of_gt ha hb
theorem integral_one_div (h : (0 : ℝ) ∉ [[a, b]]) : ∫ x : ℝ in a..b, 1 / x = log (b / a) := by
simp only [one_div, integral_inv h]
theorem integral_one_div_of_pos (ha : 0 < a) (hb : 0 < b) :
∫ x : ℝ in a..b, 1 / x = log (b / a) := by simp only [one_div, integral_inv_of_pos ha hb]
theorem integral_one_div_of_neg (ha : a < 0) (hb : b < 0) :
∫ x : ℝ in a..b, 1 / x = log (b / a) := by simp only [one_div, integral_inv_of_neg ha hb]
@[simp]
theorem integral_exp : ∫ x in a..b, exp x = exp b - exp a := by
rw [integral_deriv_eq_sub']
· simp
· exact fun _ _ => differentiableAt_exp
· exact continuousOn_exp
theorem integral_exp_mul_complex {c : ℂ} (hc : c ≠ 0) :
(∫ x in a..b, Complex.exp (c * x)) = (Complex.exp (c * b) - Complex.exp (c * a)) / c := by
have D : ∀ x : ℝ, HasDerivAt (fun y : ℝ => Complex.exp (c * y) / c) (Complex.exp (c * x)) x := by
intro x
conv => congr
rw [← mul_div_cancel_right₀ (Complex.exp (c * x)) hc]
apply ((Complex.hasDerivAt_exp _).comp x _).div_const c
simpa only [mul_one] using ((hasDerivAt_id (x : ℂ)).const_mul _).comp_ofReal
rw [integral_deriv_eq_sub' _ (funext fun x => (D x).deriv) fun x _ => (D x).differentiableAt]
· ring
· fun_prop
/-- Helper lemma for `integral_log`: case where `a = 0` and `b` is positive. -/
lemma integral_log_from_zero_of_pos (ht : 0 < b) : ∫ s in (0)..b, log s = b * log b - b := by
-- Compute the integral by giving a primitive and considering it limit as x approaches 0 from the
-- right. The following lines were suggested by Gareth Ma on Zulip.
rw [integral_eq_sub_of_hasDerivAt_of_tendsto (f := fun x ↦ x * log x - x)
(fa := 0) (fb := b * log b - b) (hint := intervalIntegrable_log')]
· abel
· exact ht
· intro s ⟨hs, _ ⟩
simpa using (hasDerivAt_mul_log hs.ne.symm).sub (hasDerivAt_id s)
· simpa [mul_comm] using ((tendsto_log_mul_rpow_nhdsGT_zero zero_lt_one).sub
(tendsto_nhdsWithin_of_tendsto_nhds Filter.tendsto_id))
· exact tendsto_nhdsWithin_of_tendsto_nhds (ContinuousAt.tendsto (by fun_prop))
/-- Helper lemma for `integral_log`: case where `a = 0`. -/
lemma integral_log_from_zero {b : ℝ} : ∫ s in (0)..b, log s = b * log b - b := by
rcases lt_trichotomy b 0 with h | h | h
· -- If t is negative, use that log is an even function to reduce to the positive case.
conv => arg 1; arg 1; intro t; rw [← log_neg_eq_log]
rw [intervalIntegral.integral_comp_neg, intervalIntegral.integral_symm, neg_zero,
integral_log_from_zero_of_pos (Left.neg_pos_iff.mpr h), log_neg_eq_log]
ring
· simp [h]
· exact integral_log_from_zero_of_pos h
@[simp]
theorem integral_log : ∫ s in a..b, log s = b * log b - a * log a - b + a := by
rw [← intervalIntegral.integral_add_adjacent_intervals (b := 0)]
· rw [intervalIntegral.integral_symm, integral_log_from_zero, integral_log_from_zero]
ring
all_goals exact intervalIntegrable_log'
@[deprecated (since := "2025-01-12")]
alias integral_log_of_pos := integral_log
@[deprecated (since := "2025-01-12")]
alias integral_log_of_neg := integral_log
@[simp]
theorem integral_sin : ∫ x in a..b, sin x = cos a - cos b := by
rw [integral_deriv_eq_sub' fun x => -cos x]
· ring
· norm_num
· simp only [differentiableAt_neg_iff, differentiableAt_cos, implies_true]
· exact continuousOn_sin
@[simp]
theorem integral_cos : ∫ x in a..b, cos x = sin b - sin a := by
rw [integral_deriv_eq_sub']
· norm_num
· simp only [differentiableAt_sin, implies_true]
· exact continuousOn_cos
theorem integral_cos_mul_complex {z : ℂ} (hz : z ≠ 0) (a b : ℝ) :
(∫ x in a..b, Complex.cos (z * x)) = Complex.sin (z * b) / z - Complex.sin (z * a) / z := by
apply integral_eq_sub_of_hasDerivAt
swap
· apply Continuous.intervalIntegrable
exact Complex.continuous_cos.comp (continuous_const.mul Complex.continuous_ofReal)
intro x _
have a := Complex.hasDerivAt_sin (↑x * z)
have b : HasDerivAt (fun y => y * z : ℂ → ℂ) z ↑x := hasDerivAt_mul_const _
have c : HasDerivAt (Complex.sin ∘ fun y : ℂ => (y * z)) _ ↑x := HasDerivAt.comp (𝕜 := ℂ) x a b
have d := HasDerivAt.comp_ofReal (c.div_const z)
simp only [mul_comm] at d
convert d using 1
conv_rhs => arg 1; rw [mul_comm]
rw [mul_div_cancel_right₀ _ hz]
theorem integral_cos_sq_sub_sin_sq :
∫ x in a..b, cos x ^ 2 - sin x ^ 2 = sin b * cos b - sin a * cos a := by
simpa only [sq, sub_eq_add_neg, neg_mul_eq_mul_neg] using
integral_deriv_mul_eq_sub (fun x _ => hasDerivAt_sin x) (fun x _ => hasDerivAt_cos x)
continuousOn_cos.intervalIntegrable continuousOn_sin.neg.intervalIntegrable
theorem integral_one_div_one_add_sq :
(∫ x : ℝ in a..b, ↑1 / (↑1 + x ^ 2)) = arctan b - arctan a := by
refine integral_deriv_eq_sub' _ Real.deriv_arctan (fun _ _ => differentiableAt_arctan _)
(continuous_const.div ?_ fun x => ?_).continuousOn
· fun_prop
· nlinarith
@[simp]
theorem integral_inv_one_add_sq : (∫ x : ℝ in a..b, (↑1 + x ^ 2)⁻¹) = arctan b - arctan a := by
simp only [← one_div, integral_one_div_one_add_sq]
section RpowCpow
open Complex
theorem integral_mul_cpow_one_add_sq {t : ℂ} (ht : t ≠ -1) :
(∫ x : ℝ in a..b, (x : ℂ) * ((1 : ℂ) + ↑x ^ 2) ^ t) =
((1 : ℂ) + (b : ℂ) ^ 2) ^ (t + 1) / (2 * (t + ↑1)) -
((1 : ℂ) + (a : ℂ) ^ 2) ^ (t + 1) / (2 * (t + ↑1)) := by
have : t + 1 ≠ 0 := by contrapose! ht; rwa [add_eq_zero_iff_eq_neg] at ht
apply integral_eq_sub_of_hasDerivAt
· intro x _
have f : HasDerivAt (fun y : ℂ => 1 + y ^ 2) (2 * x : ℂ) x := by
convert (hasDerivAt_pow 2 (x : ℂ)).const_add 1
simp
have g :
∀ {z : ℂ}, 0 < z.re → HasDerivAt (fun z => z ^ (t + 1) / (2 * (t + 1))) (z ^ t / 2) z := by
intro z hz
convert (HasDerivAt.cpow_const (c := t + 1) (hasDerivAt_id _)
(Or.inl hz)).div_const (2 * (t + 1)) using 1
field_simp
ring
convert (HasDerivAt.comp (↑x) (g _) f).comp_ofReal using 1
· field_simp; ring
· exact mod_cast add_pos_of_pos_of_nonneg zero_lt_one (sq_nonneg x)
· apply Continuous.intervalIntegrable
refine continuous_ofReal.mul ?_
apply Continuous.cpow
· exact continuous_const.add (continuous_ofReal.pow 2)
· exact continuous_const
· intro a
norm_cast
exact ofReal_mem_slitPlane.2 <| add_pos_of_pos_of_nonneg one_pos <| sq_nonneg a
theorem integral_mul_rpow_one_add_sq {t : ℝ} (ht : t ≠ -1) :
(∫ x : ℝ in a..b, x * (↑1 + x ^ 2) ^ t) =
(↑1 + b ^ 2) ^ (t + 1) / (↑2 * (t + ↑1)) - (↑1 + a ^ 2) ^ (t + 1) / (↑2 * (t + ↑1)) := by
have : ∀ x s : ℝ, (((↑1 + x ^ 2) ^ s : ℝ) : ℂ) = (1 + (x : ℂ) ^ 2) ^ (s : ℂ) := by
intro x s
norm_cast
rw [ofReal_cpow, ofReal_add, ofReal_pow, ofReal_one]
exact add_nonneg zero_le_one (sq_nonneg x)
rw [← ofReal_inj]
convert integral_mul_cpow_one_add_sq (_ : (t : ℂ) ≠ -1)
· rw [← intervalIntegral.integral_ofReal]
congr with x : 1
rw [ofReal_mul, this x t]
· simp_rw [ofReal_sub, ofReal_div, this a (t + 1), this b (t + 1)]
push_cast; rfl
· rw [← ofReal_one, ← ofReal_neg, Ne, ofReal_inj]
exact ht
end RpowCpow
open Nat
/-! ### Integral of `sin x ^ n` -/
theorem integral_sin_pow_aux :
(∫ x in a..b, sin x ^ (n + 2)) =
(sin a ^ (n + 1) * cos a - sin b ^ (n + 1) * cos b + (↑n + 1) * ∫ x in a..b, sin x ^ n) -
(↑n + 1) * ∫ x in a..b, sin x ^ (n + 2) := by
let C := sin a ^ (n + 1) * cos a - sin b ^ (n + 1) * cos b
have h : ∀ α β γ : ℝ, β * α * γ * α = β * (α * α * γ) := fun α β γ => by ring
have hu : ∀ x ∈ [[a, b]],
HasDerivAt (fun y => sin y ^ (n + 1)) ((n + 1 : ℕ) * cos x * sin x ^ n) x :=
fun x _ => by simpa only [mul_right_comm] using (hasDerivAt_sin x).pow (n + 1)
have hv : ∀ x ∈ [[a, b]], HasDerivAt (-cos) (sin x) x := fun x _ => by
simpa only [neg_neg] using (hasDerivAt_cos x).neg
have H := integral_mul_deriv_eq_deriv_mul hu hv ?_ ?_
· calc
(∫ x in a..b, sin x ^ (n + 2)) = ∫ x in a..b, sin x ^ (n + 1) * sin x := by
simp only [_root_.pow_succ]
_ = C + (↑n + 1) * ∫ x in a..b, cos x ^ 2 * sin x ^ n := by simp [H, h, sq]; ring
_ = C + (↑n + 1) * ∫ x in a..b, sin x ^ n - sin x ^ (n + 2) := by
simp [cos_sq', sub_mul, ← pow_add, add_comm]
_ = (C + (↑n + 1) * ∫ x in a..b, sin x ^ n) - (↑n + 1) * ∫ x in a..b, sin x ^ (n + 2) := by
rw [integral_sub, mul_sub, add_sub_assoc] <;>
apply Continuous.intervalIntegrable <;> fun_prop
all_goals apply Continuous.intervalIntegrable; fun_prop
/-- The reduction formula for the integral of `sin x ^ n` for any natural `n ≥ 2`. -/
theorem integral_sin_pow :
(∫ x in a..b, sin x ^ (n + 2)) =
(sin a ^ (n + 1) * cos a - sin b ^ (n + 1) * cos b) / (n + 2) +
(n + 1) / (n + 2) * ∫ x in a..b, sin x ^ n := by
field_simp
convert eq_sub_iff_add_eq.mp (integral_sin_pow_aux n) using 1
ring
@[simp]
theorem integral_sin_sq : ∫ x in a..b, sin x ^ 2 = (sin a * cos a - sin b * cos b + b - a) / 2 := by
field_simp [integral_sin_pow, add_sub_assoc]
theorem integral_sin_pow_odd :
(∫ x in (0)..π, sin x ^ (2 * n + 1)) = 2 * ∏ i ∈ range n, (2 * (i : ℝ) + 2) / (2 * i + 3) := by
induction' n with k ih; · norm_num
rw [prod_range_succ_comm, mul_left_comm, ← ih, mul_succ, integral_sin_pow]
norm_cast
simp [-cast_add, field_simps]
theorem integral_sin_pow_even :
(∫ x in (0)..π, sin x ^ (2 * n)) = π * ∏ i ∈ range n, (2 * (i : ℝ) + 1) / (2 * i + 2) := by
induction' n with k ih; · simp
rw [prod_range_succ_comm, mul_left_comm, ← ih, mul_succ, integral_sin_pow]
norm_cast
simp [-cast_add, field_simps]
theorem integral_sin_pow_pos : 0 < ∫ x in (0)..π, sin x ^ n := by
rcases even_or_odd' n with ⟨k, rfl | rfl⟩ <;>
simp only [integral_sin_pow_even, integral_sin_pow_odd] <;>
refine mul_pos (by norm_num [pi_pos]) (prod_pos fun n _ => div_pos ?_ ?_) <;>
norm_cast <;>
omega
theorem integral_sin_pow_succ_le : (∫ x in (0)..π, sin x ^ (n + 1)) ≤ ∫ x in (0)..π, sin x ^ n := by
let H x h := pow_le_pow_of_le_one (sin_nonneg_of_mem_Icc h) (sin_le_one x) (n.le_add_right 1)
refine integral_mono_on pi_pos.le ?_ ?_ H <;> exact (continuous_sin.pow _).intervalIntegrable 0 π
theorem integral_sin_pow_antitone : Antitone fun n : ℕ => ∫ x in (0)..π, sin x ^ n :=
antitone_nat_of_succ_le integral_sin_pow_succ_le
/-! ### Integral of `cos x ^ n` -/
theorem integral_cos_pow_aux :
(∫ x in a..b, cos x ^ (n + 2)) =
(cos b ^ (n + 1) * sin b - cos a ^ (n + 1) * sin a + (n + 1) * ∫ x in a..b, cos x ^ n) -
(n + 1) * ∫ x in a..b, cos x ^ (n + 2) := by
let C := cos b ^ (n + 1) * sin b - cos a ^ (n + 1) * sin a
have h : ∀ α β γ : ℝ, β * α * γ * α = β * (α * α * γ) := fun α β γ => by ring
have hu : ∀ x ∈ [[a, b]],
HasDerivAt (fun y => cos y ^ (n + 1)) (-(n + 1 : ℕ) * sin x * cos x ^ n) x :=
fun x _ => by
simpa only [mul_right_comm, neg_mul, mul_neg] using (hasDerivAt_cos x).pow (n + 1)
have hv : ∀ x ∈ [[a, b]], HasDerivAt sin (cos x) x := fun x _ => hasDerivAt_sin x
have H := integral_mul_deriv_eq_deriv_mul hu hv ?_ ?_
· calc
(∫ x in a..b, cos x ^ (n + 2)) = ∫ x in a..b, cos x ^ (n + 1) * cos x := by
simp only [_root_.pow_succ]
_ = C + (n + 1) * ∫ x in a..b, sin x ^ 2 * cos x ^ n := by simp [C, H, h, sq, -neg_add_rev]
_ = C + (n + 1) * ∫ x in a..b, cos x ^ n - cos x ^ (n + 2) := by
simp [sin_sq, sub_mul, ← pow_add, add_comm]
_ = (C + (n + 1) * ∫ x in a..b, cos x ^ n) - (n + 1) * ∫ x in a..b, cos x ^ (n + 2) := by
rw [integral_sub, mul_sub, add_sub_assoc] <;>
apply Continuous.intervalIntegrable <;> fun_prop
all_goals apply Continuous.intervalIntegrable; fun_prop
/-- The reduction formula for the integral of `cos x ^ n` for any natural `n ≥ 2`. -/
theorem integral_cos_pow :
(∫ x in a..b, cos x ^ (n + 2)) =
(cos b ^ (n + 1) * sin b - cos a ^ (n + 1) * sin a) / (n + 2) +
(n + 1) / (n + 2) * ∫ x in a..b, cos x ^ n := by
field_simp
convert eq_sub_iff_add_eq.mp (integral_cos_pow_aux n) using 1
ring
@[simp]
theorem integral_cos_sq : ∫ x in a..b, cos x ^ 2 = (cos b * sin b - cos a * sin a + b - a) / 2 := by
field_simp [integral_cos_pow, add_sub_assoc]
/-! ### Integral of `sin x ^ m * cos x ^ n` -/
/-- Simplification of the integral of `sin x ^ m * cos x ^ n`, case `n` is odd. -/
theorem integral_sin_pow_mul_cos_pow_odd (m n : ℕ) :
(∫ x in a..b, sin x ^ m * cos x ^ (2 * n + 1)) = ∫ u in sin a..sin b, u^m * (↑1 - u ^ 2) ^ n :=
have hc : Continuous fun u : ℝ => u ^ m * (↑1 - u ^ 2) ^ n := by fun_prop
calc
(∫ x in a..b, sin x ^ m * cos x ^ (2 * n + 1)) =
∫ x in a..b, sin x ^ m * (↑1 - sin x ^ 2) ^ n * cos x := by
simp only [_root_.pow_zero, _root_.pow_succ, mul_assoc, pow_mul, one_mul]
congr! 5
rw [← sq, ← sq, cos_sq']
_ = ∫ u in sin a..sin b, u ^ m * (1 - u ^ 2) ^ n := by
-- Note(kmill): Didn't need `by exact`, but elaboration order seems to matter here.
exact integral_comp_mul_deriv (fun x _ => hasDerivAt_sin x) continuousOn_cos hc
/-- The integral of `sin x * cos x`, given in terms of sin².
See `integral_sin_mul_cos₂` below for the integral given in terms of cos². -/
@[simp]
theorem integral_sin_mul_cos₁ : ∫ x in a..b, sin x * cos x = (sin b ^ 2 - sin a ^ 2) / 2 := by
simpa using integral_sin_pow_mul_cos_pow_odd 1 0
@[simp]
theorem integral_sin_sq_mul_cos :
∫ x in a..b, sin x ^ 2 * cos x = (sin b ^ 3 - sin a ^ 3) / 3 := by
have := @integral_sin_pow_mul_cos_pow_odd a b 2 0
norm_num at this; exact this
@[simp]
theorem integral_cos_pow_three :
∫ x in a..b, cos x ^ 3 = sin b - sin a - (sin b ^ 3 - sin a ^ 3) / 3 := by
have := @integral_sin_pow_mul_cos_pow_odd a b 0 1
norm_num at this; exact this
/-- Simplification of the integral of `sin x ^ m * cos x ^ n`, case `m` is odd. -/
theorem integral_sin_pow_odd_mul_cos_pow (m n : ℕ) :
(∫ x in a..b, sin x ^ (2 * m + 1) * cos x ^ n) = ∫ u in cos b..cos a, u^n * (↑1 - u ^ 2) ^ m :=
have hc : Continuous fun u : ℝ => u ^ n * (↑1 - u ^ 2) ^ m := by fun_prop
calc
(∫ x in a..b, sin x ^ (2 * m + 1) * cos x ^ n) =
-∫ x in b..a, sin x ^ (2 * m + 1) * cos x ^ n := by rw [integral_symm]
_ = ∫ x in b..a, (↑1 - cos x ^ 2) ^ m * -sin x * cos x ^ n := by
simp only [_root_.pow_succ, pow_mul, _root_.pow_zero, one_mul, mul_neg, neg_mul,
integral_neg, neg_inj]
congr! 5
rw [← sq, ← sq, sin_sq]
_ = ∫ x in b..a, cos x ^ n * (↑1 - cos x ^ 2) ^ m * -sin x := by congr; ext; ring
_ = ∫ u in cos b..cos a, u ^ n * (↑1 - u ^ 2) ^ m :=
integral_comp_mul_deriv (fun x _ => hasDerivAt_cos x) continuousOn_sin.neg hc
/-- The integral of `sin x * cos x`, given in terms of cos².
See `integral_sin_mul_cos₁` above for the integral given in terms of sin². -/
theorem integral_sin_mul_cos₂ : ∫ x in a..b, sin x * cos x = (cos a ^ 2 - cos b ^ 2) / 2 := by
simpa using integral_sin_pow_odd_mul_cos_pow 0 1
@[simp]
theorem integral_sin_mul_cos_sq :
∫ x in a..b, sin x * cos x ^ 2 = (cos a ^ 3 - cos b ^ 3) / 3 := by
have := @integral_sin_pow_odd_mul_cos_pow a b 0 2
norm_num at this; exact this
|
@[simp]
theorem integral_sin_pow_three :
∫ x in a..b, sin x ^ 3 = cos a - cos b - (cos a ^ 3 - cos b ^ 3) / 3 := by
| Mathlib/Analysis/SpecialFunctions/Integrals.lean | 789 | 792 |
/-
Copyright (c) 2019 Calle Sönne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Calle Sönne
-/
import Mathlib.Analysis.SpecialFunctions.Trigonometric.Basic
import Mathlib.Analysis.Normed.Group.AddCircle
import Mathlib.Algebra.CharZero.Quotient
import Mathlib.Topology.Instances.Sign
/-!
# The type of angles
In this file we define `Real.Angle` to be the quotient group `ℝ/2πℤ` and prove a few simple lemmas
about trigonometric functions and angles.
-/
open Real
noncomputable section
namespace Real
/-- The type of angles -/
def Angle : Type :=
AddCircle (2 * π)
-- The `NormedAddCommGroup, Inhabited` instances should be constructed by a deriving handler.
-- https://github.com/leanprover-community/mathlib4/issues/380
namespace Angle
instance : NormedAddCommGroup Angle :=
inferInstanceAs (NormedAddCommGroup (AddCircle (2 * π)))
instance : Inhabited Angle :=
inferInstanceAs (Inhabited (AddCircle (2 * π)))
/-- The canonical map from `ℝ` to the quotient `Angle`. -/
@[coe]
protected def coe (r : ℝ) : Angle := QuotientAddGroup.mk r
instance : Coe ℝ Angle := ⟨Angle.coe⟩
instance : CircularOrder Real.Angle :=
QuotientAddGroup.circularOrder (hp' := ⟨by norm_num [pi_pos]⟩)
@[continuity]
theorem continuous_coe : Continuous ((↑) : ℝ → Angle) :=
continuous_quotient_mk'
/-- Coercion `ℝ → Angle` as an additive homomorphism. -/
def coeHom : ℝ →+ Angle :=
QuotientAddGroup.mk' _
@[simp]
theorem coe_coeHom : (coeHom : ℝ → Angle) = ((↑) : ℝ → Angle) :=
rfl
/-- An induction principle to deduce results for `Angle` from those for `ℝ`, used with
`induction θ using Real.Angle.induction_on`. -/
@[elab_as_elim]
protected theorem induction_on {p : Angle → Prop} (θ : Angle) (h : ∀ x : ℝ, p x) : p θ :=
Quotient.inductionOn' θ h
@[simp]
theorem coe_zero : ↑(0 : ℝ) = (0 : Angle) :=
rfl
@[simp]
theorem coe_add (x y : ℝ) : ↑(x + y : ℝ) = (↑x + ↑y : Angle) :=
rfl
@[simp]
theorem coe_neg (x : ℝ) : ↑(-x : ℝ) = -(↑x : Angle) :=
rfl
@[simp]
theorem coe_sub (x y : ℝ) : ↑(x - y : ℝ) = (↑x - ↑y : Angle) :=
rfl
theorem coe_nsmul (n : ℕ) (x : ℝ) : ↑(n • x : ℝ) = n • (↑x : Angle) :=
rfl
theorem coe_zsmul (z : ℤ) (x : ℝ) : ↑(z • x : ℝ) = z • (↑x : Angle) :=
rfl
theorem coe_eq_zero_iff {x : ℝ} : (x : Angle) = 0 ↔ ∃ n : ℤ, n • (2 * π) = x :=
AddCircle.coe_eq_zero_iff (2 * π)
@[simp, norm_cast]
theorem natCast_mul_eq_nsmul (x : ℝ) (n : ℕ) : ↑((n : ℝ) * x) = n • (↑x : Angle) := by
simpa only [nsmul_eq_mul] using coeHom.map_nsmul x n
@[simp, norm_cast]
theorem intCast_mul_eq_zsmul (x : ℝ) (n : ℤ) : ↑((n : ℝ) * x : ℝ) = n • (↑x : Angle) := by
simpa only [zsmul_eq_mul] using coeHom.map_zsmul x n
theorem angle_eq_iff_two_pi_dvd_sub {ψ θ : ℝ} : (θ : Angle) = ψ ↔ ∃ k : ℤ, θ - ψ = 2 * π * k := by
simp only [QuotientAddGroup.eq, AddSubgroup.zmultiples_eq_closure,
AddSubgroup.mem_closure_singleton, zsmul_eq_mul', (sub_eq_neg_add _ _).symm, eq_comm]
rw [Angle.coe, Angle.coe, QuotientAddGroup.eq]
simp only [AddSubgroup.zmultiples_eq_closure,
AddSubgroup.mem_closure_singleton, zsmul_eq_mul', (sub_eq_neg_add _ _).symm, eq_comm]
@[simp]
theorem coe_two_pi : ↑(2 * π : ℝ) = (0 : Angle) :=
angle_eq_iff_two_pi_dvd_sub.2 ⟨1, by rw [sub_zero, Int.cast_one, mul_one]⟩
@[simp]
theorem neg_coe_pi : -(π : Angle) = π := by
rw [← coe_neg, angle_eq_iff_two_pi_dvd_sub]
use -1
simp [two_mul, sub_eq_add_neg]
@[simp]
theorem two_nsmul_coe_div_two (θ : ℝ) : (2 : ℕ) • (↑(θ / 2) : Angle) = θ := by
rw [← coe_nsmul, two_nsmul, add_halves]
@[simp]
theorem two_zsmul_coe_div_two (θ : ℝ) : (2 : ℤ) • (↑(θ / 2) : Angle) = θ := by
rw [← coe_zsmul, two_zsmul, add_halves]
theorem two_nsmul_neg_pi_div_two : (2 : ℕ) • (↑(-π / 2) : Angle) = π := by
rw [two_nsmul_coe_div_two, coe_neg, neg_coe_pi]
theorem two_zsmul_neg_pi_div_two : (2 : ℤ) • (↑(-π / 2) : Angle) = π := by
rw [two_zsmul, ← two_nsmul, two_nsmul_neg_pi_div_two]
theorem sub_coe_pi_eq_add_coe_pi (θ : Angle) : θ - π = θ + π := by
rw [sub_eq_add_neg, neg_coe_pi]
@[simp]
theorem two_nsmul_coe_pi : (2 : ℕ) • (π : Angle) = 0 := by simp [← natCast_mul_eq_nsmul]
@[simp]
theorem two_zsmul_coe_pi : (2 : ℤ) • (π : Angle) = 0 := by simp [← intCast_mul_eq_zsmul]
@[simp]
theorem coe_pi_add_coe_pi : (π : Real.Angle) + π = 0 := by rw [← two_nsmul, two_nsmul_coe_pi]
theorem zsmul_eq_iff {ψ θ : Angle} {z : ℤ} (hz : z ≠ 0) :
z • ψ = z • θ ↔ ∃ k : Fin z.natAbs, ψ = θ + (k : ℕ) • (2 * π / z : ℝ) :=
QuotientAddGroup.zmultiples_zsmul_eq_zsmul_iff hz
theorem nsmul_eq_iff {ψ θ : Angle} {n : ℕ} (hz : n ≠ 0) :
n • ψ = n • θ ↔ ∃ k : Fin n, ψ = θ + (k : ℕ) • (2 * π / n : ℝ) :=
QuotientAddGroup.zmultiples_nsmul_eq_nsmul_iff hz
theorem two_zsmul_eq_iff {ψ θ : Angle} : (2 : ℤ) • ψ = (2 : ℤ) • θ ↔ ψ = θ ∨ ψ = θ + ↑π := by
have : Int.natAbs 2 = 2 := rfl
rw [zsmul_eq_iff two_ne_zero, this, Fin.exists_fin_two, Fin.val_zero,
Fin.val_one, zero_smul, add_zero, one_smul, Int.cast_two,
mul_div_cancel_left₀ (_ : ℝ) two_ne_zero]
theorem two_nsmul_eq_iff {ψ θ : Angle} : (2 : ℕ) • ψ = (2 : ℕ) • θ ↔ ψ = θ ∨ ψ = θ + ↑π := by
simp_rw [← natCast_zsmul, Nat.cast_ofNat, two_zsmul_eq_iff]
theorem two_nsmul_eq_zero_iff {θ : Angle} : (2 : ℕ) • θ = 0 ↔ θ = 0 ∨ θ = π := by
convert two_nsmul_eq_iff <;> simp
theorem two_nsmul_ne_zero_iff {θ : Angle} : (2 : ℕ) • θ ≠ 0 ↔ θ ≠ 0 ∧ θ ≠ π := by
rw [← not_or, ← two_nsmul_eq_zero_iff]
theorem two_zsmul_eq_zero_iff {θ : Angle} : (2 : ℤ) • θ = 0 ↔ θ = 0 ∨ θ = π := by
simp_rw [two_zsmul, ← two_nsmul, two_nsmul_eq_zero_iff]
theorem two_zsmul_ne_zero_iff {θ : Angle} : (2 : ℤ) • θ ≠ 0 ↔ θ ≠ 0 ∧ θ ≠ π := by
rw [← not_or, ← two_zsmul_eq_zero_iff]
theorem eq_neg_self_iff {θ : Angle} : θ = -θ ↔ θ = 0 ∨ θ = π := by
rw [← add_eq_zero_iff_eq_neg, ← two_nsmul, two_nsmul_eq_zero_iff]
theorem ne_neg_self_iff {θ : Angle} : θ ≠ -θ ↔ θ ≠ 0 ∧ θ ≠ π := by
rw [← not_or, ← eq_neg_self_iff.not]
theorem neg_eq_self_iff {θ : Angle} : -θ = θ ↔ θ = 0 ∨ θ = π := by rw [eq_comm, eq_neg_self_iff]
theorem neg_ne_self_iff {θ : Angle} : -θ ≠ θ ↔ θ ≠ 0 ∧ θ ≠ π := by
rw [← not_or, ← neg_eq_self_iff.not]
theorem two_nsmul_eq_pi_iff {θ : Angle} : (2 : ℕ) • θ = π ↔ θ = (π / 2 : ℝ) ∨ θ = (-π / 2 : ℝ) := by
have h : (π : Angle) = ((2 : ℕ) • (π / 2 : ℝ):) := by rw [two_nsmul, add_halves]
nth_rw 1 [h]
rw [coe_nsmul, two_nsmul_eq_iff]
-- Porting note: `congr` didn't simplify the goal of iff of `Or`s
convert Iff.rfl
rw [add_comm, ← coe_add, ← sub_eq_zero, ← coe_sub, neg_div, ← neg_sub, sub_neg_eq_add, add_assoc,
add_halves, ← two_mul, coe_neg, coe_two_pi, neg_zero]
theorem two_zsmul_eq_pi_iff {θ : Angle} : (2 : ℤ) • θ = π ↔ θ = (π / 2 : ℝ) ∨ θ = (-π / 2 : ℝ) := by
rw [two_zsmul, ← two_nsmul, two_nsmul_eq_pi_iff]
theorem cos_eq_iff_coe_eq_or_eq_neg {θ ψ : ℝ} :
cos θ = cos ψ ↔ (θ : Angle) = ψ ∨ (θ : Angle) = -ψ := by
constructor
· intro Hcos
rw [← sub_eq_zero, cos_sub_cos, mul_eq_zero, mul_eq_zero, neg_eq_zero,
eq_false (two_ne_zero' ℝ), false_or, sin_eq_zero_iff, sin_eq_zero_iff] at Hcos
rcases Hcos with (⟨n, hn⟩ | ⟨n, hn⟩)
· right
rw [eq_div_iff_mul_eq (two_ne_zero' ℝ), ← sub_eq_iff_eq_add] at hn
rw [← hn, coe_sub, eq_neg_iff_add_eq_zero, sub_add_cancel, mul_assoc, intCast_mul_eq_zsmul,
mul_comm, coe_two_pi, zsmul_zero]
· left
rw [eq_div_iff_mul_eq (two_ne_zero' ℝ), eq_sub_iff_add_eq] at hn
rw [← hn, coe_add, mul_assoc, intCast_mul_eq_zsmul, mul_comm, coe_two_pi, zsmul_zero,
zero_add]
· rw [angle_eq_iff_two_pi_dvd_sub, ← coe_neg, angle_eq_iff_two_pi_dvd_sub]
rintro (⟨k, H⟩ | ⟨k, H⟩)
· rw [← sub_eq_zero, cos_sub_cos, H, mul_assoc 2 π k, mul_div_cancel_left₀ _ (two_ne_zero' ℝ),
mul_comm π _, sin_int_mul_pi, mul_zero]
rw [← sub_eq_zero, cos_sub_cos, ← sub_neg_eq_add, H, mul_assoc 2 π k,
mul_div_cancel_left₀ _ (two_ne_zero' ℝ), mul_comm π _, sin_int_mul_pi, mul_zero,
zero_mul]
theorem sin_eq_iff_coe_eq_or_add_eq_pi {θ ψ : ℝ} :
sin θ = sin ψ ↔ (θ : Angle) = ψ ∨ (θ : Angle) + ψ = π := by
constructor
· intro Hsin
rw [← cos_pi_div_two_sub, ← cos_pi_div_two_sub] at Hsin
rcases cos_eq_iff_coe_eq_or_eq_neg.mp Hsin with h | h
· left
rw [coe_sub, coe_sub] at h
exact sub_right_inj.1 h
right
rw [coe_sub, coe_sub, eq_neg_iff_add_eq_zero, add_sub, sub_add_eq_add_sub, ← coe_add,
add_halves, sub_sub, sub_eq_zero] at h
exact h.symm
· rw [angle_eq_iff_two_pi_dvd_sub, ← eq_sub_iff_add_eq, ← coe_sub, angle_eq_iff_two_pi_dvd_sub]
rintro (⟨k, H⟩ | ⟨k, H⟩)
· rw [← sub_eq_zero, sin_sub_sin, H, mul_assoc 2 π k, mul_div_cancel_left₀ _ (two_ne_zero' ℝ),
mul_comm π _, sin_int_mul_pi, mul_zero, zero_mul]
have H' : θ + ψ = 2 * k * π + π := by
rwa [← sub_add, sub_add_eq_add_sub, sub_eq_iff_eq_add, mul_assoc, mul_comm π _, ←
mul_assoc] at H
rw [← sub_eq_zero, sin_sub_sin, H', add_div, mul_assoc 2 _ π,
mul_div_cancel_left₀ _ (two_ne_zero' ℝ), cos_add_pi_div_two, sin_int_mul_pi, neg_zero,
mul_zero]
theorem cos_sin_inj {θ ψ : ℝ} (Hcos : cos θ = cos ψ) (Hsin : sin θ = sin ψ) : (θ : Angle) = ψ := by
rcases cos_eq_iff_coe_eq_or_eq_neg.mp Hcos with hc | hc; · exact hc
rcases sin_eq_iff_coe_eq_or_add_eq_pi.mp Hsin with hs | hs; · exact hs
rw [eq_neg_iff_add_eq_zero, hs] at hc
obtain ⟨n, hn⟩ : ∃ n, n • _ = _ := QuotientAddGroup.leftRel_apply.mp (Quotient.exact' hc)
rw [← neg_one_mul, add_zero, ← sub_eq_zero, zsmul_eq_mul, ← mul_assoc, ← sub_mul, mul_eq_zero,
eq_false (ne_of_gt pi_pos), or_false, sub_neg_eq_add, ← Int.cast_zero, ← Int.cast_one,
← Int.cast_ofNat, ← Int.cast_mul, ← Int.cast_add, Int.cast_inj] at hn
have : (n * 2 + 1) % (2 : ℤ) = 0 % (2 : ℤ) := congr_arg (· % (2 : ℤ)) hn
rw [add_comm, Int.add_mul_emod_self_right] at this
exact absurd this one_ne_zero
/-- The sine of a `Real.Angle`. -/
def sin (θ : Angle) : ℝ :=
sin_periodic.lift θ
@[simp]
theorem sin_coe (x : ℝ) : sin (x : Angle) = Real.sin x :=
rfl
@[continuity]
theorem continuous_sin : Continuous sin :=
Real.continuous_sin.quotient_liftOn' _
/-- The cosine of a `Real.Angle`. -/
def cos (θ : Angle) : ℝ :=
cos_periodic.lift θ
@[simp]
theorem cos_coe (x : ℝ) : cos (x : Angle) = Real.cos x :=
rfl
@[continuity]
theorem continuous_cos : Continuous cos :=
Real.continuous_cos.quotient_liftOn' _
theorem cos_eq_real_cos_iff_eq_or_eq_neg {θ : Angle} {ψ : ℝ} :
cos θ = Real.cos ψ ↔ θ = ψ ∨ θ = -ψ := by
induction θ using Real.Angle.induction_on
exact cos_eq_iff_coe_eq_or_eq_neg
theorem cos_eq_iff_eq_or_eq_neg {θ ψ : Angle} : cos θ = cos ψ ↔ θ = ψ ∨ θ = -ψ := by
induction ψ using Real.Angle.induction_on
exact cos_eq_real_cos_iff_eq_or_eq_neg
theorem sin_eq_real_sin_iff_eq_or_add_eq_pi {θ : Angle} {ψ : ℝ} :
sin θ = Real.sin ψ ↔ θ = ψ ∨ θ + ψ = π := by
induction θ using Real.Angle.induction_on
exact sin_eq_iff_coe_eq_or_add_eq_pi
theorem sin_eq_iff_eq_or_add_eq_pi {θ ψ : Angle} : sin θ = sin ψ ↔ θ = ψ ∨ θ + ψ = π := by
induction ψ using Real.Angle.induction_on
exact sin_eq_real_sin_iff_eq_or_add_eq_pi
@[simp]
theorem sin_zero : sin (0 : Angle) = 0 := by rw [← coe_zero, sin_coe, Real.sin_zero]
theorem sin_coe_pi : sin (π : Angle) = 0 := by rw [sin_coe, Real.sin_pi]
theorem sin_eq_zero_iff {θ : Angle} : sin θ = 0 ↔ θ = 0 ∨ θ = π := by
nth_rw 1 [← sin_zero]
rw [sin_eq_iff_eq_or_add_eq_pi]
simp
theorem sin_ne_zero_iff {θ : Angle} : sin θ ≠ 0 ↔ θ ≠ 0 ∧ θ ≠ π := by
rw [← not_or, ← sin_eq_zero_iff]
@[simp]
theorem sin_neg (θ : Angle) : sin (-θ) = -sin θ := by
induction θ using Real.Angle.induction_on
exact Real.sin_neg _
theorem sin_antiperiodic : Function.Antiperiodic sin (π : Angle) := by
intro θ
induction θ using Real.Angle.induction_on
exact Real.sin_antiperiodic _
@[simp]
theorem sin_add_pi (θ : Angle) : sin (θ + π) = -sin θ :=
sin_antiperiodic θ
@[simp]
theorem sin_sub_pi (θ : Angle) : sin (θ - π) = -sin θ :=
sin_antiperiodic.sub_eq θ
@[simp]
theorem cos_zero : cos (0 : Angle) = 1 := by rw [← coe_zero, cos_coe, Real.cos_zero]
theorem cos_coe_pi : cos (π : Angle) = -1 := by rw [cos_coe, Real.cos_pi]
@[simp]
theorem cos_neg (θ : Angle) : cos (-θ) = cos θ := by
induction θ using Real.Angle.induction_on
exact Real.cos_neg _
theorem cos_antiperiodic : Function.Antiperiodic cos (π : Angle) := by
intro θ
induction θ using Real.Angle.induction_on
exact Real.cos_antiperiodic _
@[simp]
theorem cos_add_pi (θ : Angle) : cos (θ + π) = -cos θ :=
cos_antiperiodic θ
@[simp]
theorem cos_sub_pi (θ : Angle) : cos (θ - π) = -cos θ :=
cos_antiperiodic.sub_eq θ
theorem cos_eq_zero_iff {θ : Angle} : cos θ = 0 ↔ θ = (π / 2 : ℝ) ∨ θ = (-π / 2 : ℝ) := by
rw [← cos_pi_div_two, ← cos_coe, cos_eq_iff_eq_or_eq_neg, ← coe_neg, ← neg_div]
theorem sin_add (θ₁ θ₂ : Real.Angle) : sin (θ₁ + θ₂) = sin θ₁ * cos θ₂ + cos θ₁ * sin θ₂ := by
induction θ₁ using Real.Angle.induction_on
induction θ₂ using Real.Angle.induction_on
exact Real.sin_add _ _
theorem cos_add (θ₁ θ₂ : Real.Angle) : cos (θ₁ + θ₂) = cos θ₁ * cos θ₂ - sin θ₁ * sin θ₂ := by
induction θ₂ using Real.Angle.induction_on
induction θ₁ using Real.Angle.induction_on
exact Real.cos_add _ _
@[simp]
theorem cos_sq_add_sin_sq (θ : Real.Angle) : cos θ ^ 2 + sin θ ^ 2 = 1 := by
induction θ using Real.Angle.induction_on
exact Real.cos_sq_add_sin_sq _
theorem sin_add_pi_div_two (θ : Angle) : sin (θ + ↑(π / 2)) = cos θ := by
induction θ using Real.Angle.induction_on
exact Real.sin_add_pi_div_two _
theorem sin_sub_pi_div_two (θ : Angle) : sin (θ - ↑(π / 2)) = -cos θ := by
induction θ using Real.Angle.induction_on
exact Real.sin_sub_pi_div_two _
theorem sin_pi_div_two_sub (θ : Angle) : sin (↑(π / 2) - θ) = cos θ := by
induction θ using Real.Angle.induction_on
exact Real.sin_pi_div_two_sub _
theorem cos_add_pi_div_two (θ : Angle) : cos (θ + ↑(π / 2)) = -sin θ := by
induction θ using Real.Angle.induction_on
exact Real.cos_add_pi_div_two _
theorem cos_sub_pi_div_two (θ : Angle) : cos (θ - ↑(π / 2)) = sin θ := by
induction θ using Real.Angle.induction_on
exact Real.cos_sub_pi_div_two _
theorem cos_pi_div_two_sub (θ : Angle) : cos (↑(π / 2) - θ) = sin θ := by
induction θ using Real.Angle.induction_on
exact Real.cos_pi_div_two_sub _
theorem abs_sin_eq_of_two_nsmul_eq {θ ψ : Angle} (h : (2 : ℕ) • θ = (2 : ℕ) • ψ) :
|sin θ| = |sin ψ| := by
rw [two_nsmul_eq_iff] at h
rcases h with (rfl | rfl)
· rfl
· rw [sin_add_pi, abs_neg]
theorem abs_sin_eq_of_two_zsmul_eq {θ ψ : Angle} (h : (2 : ℤ) • θ = (2 : ℤ) • ψ) :
|sin θ| = |sin ψ| := by
simp_rw [two_zsmul, ← two_nsmul] at h
exact abs_sin_eq_of_two_nsmul_eq h
theorem abs_cos_eq_of_two_nsmul_eq {θ ψ : Angle} (h : (2 : ℕ) • θ = (2 : ℕ) • ψ) :
|cos θ| = |cos ψ| := by
rw [two_nsmul_eq_iff] at h
rcases h with (rfl | rfl)
· rfl
· rw [cos_add_pi, abs_neg]
theorem abs_cos_eq_of_two_zsmul_eq {θ ψ : Angle} (h : (2 : ℤ) • θ = (2 : ℤ) • ψ) :
|cos θ| = |cos ψ| := by
simp_rw [two_zsmul, ← two_nsmul] at h
exact abs_cos_eq_of_two_nsmul_eq h
@[simp]
theorem coe_toIcoMod (θ ψ : ℝ) : ↑(toIcoMod two_pi_pos ψ θ) = (θ : Angle) := by
rw [angle_eq_iff_two_pi_dvd_sub]
refine ⟨-toIcoDiv two_pi_pos ψ θ, ?_⟩
rw [toIcoMod_sub_self, zsmul_eq_mul, mul_comm]
@[simp]
theorem coe_toIocMod (θ ψ : ℝ) : ↑(toIocMod two_pi_pos ψ θ) = (θ : Angle) := by
rw [angle_eq_iff_two_pi_dvd_sub]
refine ⟨-toIocDiv two_pi_pos ψ θ, ?_⟩
rw [toIocMod_sub_self, zsmul_eq_mul, mul_comm]
/-- Convert a `Real.Angle` to a real number in the interval `Ioc (-π) π`. -/
def toReal (θ : Angle) : ℝ :=
(toIocMod_periodic two_pi_pos (-π)).lift θ
theorem toReal_coe (θ : ℝ) : (θ : Angle).toReal = toIocMod two_pi_pos (-π) θ :=
rfl
theorem toReal_coe_eq_self_iff {θ : ℝ} : (θ : Angle).toReal = θ ↔ -π < θ ∧ θ ≤ π := by
rw [toReal_coe, toIocMod_eq_self two_pi_pos]
ring_nf
rfl
theorem toReal_coe_eq_self_iff_mem_Ioc {θ : ℝ} : (θ : Angle).toReal = θ ↔ θ ∈ Set.Ioc (-π) π := by
rw [toReal_coe_eq_self_iff, ← Set.mem_Ioc]
theorem toReal_injective : Function.Injective toReal := by
intro θ ψ h
induction θ using Real.Angle.induction_on
induction ψ using Real.Angle.induction_on
simpa [toReal_coe, toIocMod_eq_toIocMod, zsmul_eq_mul, mul_comm _ (2 * π), ←
angle_eq_iff_two_pi_dvd_sub, eq_comm] using h
@[simp]
theorem toReal_inj {θ ψ : Angle} : θ.toReal = ψ.toReal ↔ θ = ψ :=
toReal_injective.eq_iff
@[simp]
theorem coe_toReal (θ : Angle) : (θ.toReal : Angle) = θ := by
induction θ using Real.Angle.induction_on
exact coe_toIocMod _ _
theorem neg_pi_lt_toReal (θ : Angle) : -π < θ.toReal := by
induction θ using Real.Angle.induction_on
exact left_lt_toIocMod _ _ _
theorem toReal_le_pi (θ : Angle) : θ.toReal ≤ π := by
induction θ using Real.Angle.induction_on
convert toIocMod_le_right two_pi_pos _ _
ring
theorem abs_toReal_le_pi (θ : Angle) : |θ.toReal| ≤ π :=
abs_le.2 ⟨(neg_pi_lt_toReal _).le, toReal_le_pi _⟩
theorem toReal_mem_Ioc (θ : Angle) : θ.toReal ∈ Set.Ioc (-π) π :=
⟨neg_pi_lt_toReal _, toReal_le_pi _⟩
@[simp]
theorem toIocMod_toReal (θ : Angle) : toIocMod two_pi_pos (-π) θ.toReal = θ.toReal := by
induction θ using Real.Angle.induction_on
rw [toReal_coe]
exact toIocMod_toIocMod _ _ _ _
@[simp]
theorem toReal_zero : (0 : Angle).toReal = 0 := by
rw [← coe_zero, toReal_coe_eq_self_iff]
exact ⟨Left.neg_neg_iff.2 Real.pi_pos, Real.pi_pos.le⟩
@[simp]
theorem toReal_eq_zero_iff {θ : Angle} : θ.toReal = 0 ↔ θ = 0 := by
nth_rw 1 [← toReal_zero]
exact toReal_inj
@[simp]
theorem toReal_pi : (π : Angle).toReal = π := by
rw [toReal_coe_eq_self_iff]
exact ⟨Left.neg_lt_self Real.pi_pos, le_refl _⟩
@[simp]
theorem toReal_eq_pi_iff {θ : Angle} : θ.toReal = π ↔ θ = π := by rw [← toReal_inj, toReal_pi]
theorem pi_ne_zero : (π : Angle) ≠ 0 := by
rw [← toReal_injective.ne_iff, toReal_pi, toReal_zero]
exact Real.pi_ne_zero
@[simp]
theorem toReal_pi_div_two : ((π / 2 : ℝ) : Angle).toReal = π / 2 :=
toReal_coe_eq_self_iff.2 <| by constructor <;> linarith [pi_pos]
@[simp]
theorem toReal_eq_pi_div_two_iff {θ : Angle} : θ.toReal = π / 2 ↔ θ = (π / 2 : ℝ) := by
rw [← toReal_inj, toReal_pi_div_two]
@[simp]
theorem toReal_neg_pi_div_two : ((-π / 2 : ℝ) : Angle).toReal = -π / 2 :=
toReal_coe_eq_self_iff.2 <| by constructor <;> linarith [pi_pos]
@[simp]
theorem toReal_eq_neg_pi_div_two_iff {θ : Angle} : θ.toReal = -π / 2 ↔ θ = (-π / 2 : ℝ) := by
rw [← toReal_inj, toReal_neg_pi_div_two]
theorem pi_div_two_ne_zero : ((π / 2 : ℝ) : Angle) ≠ 0 := by
rw [← toReal_injective.ne_iff, toReal_pi_div_two, toReal_zero]
exact div_ne_zero Real.pi_ne_zero two_ne_zero
theorem neg_pi_div_two_ne_zero : ((-π / 2 : ℝ) : Angle) ≠ 0 := by
rw [← toReal_injective.ne_iff, toReal_neg_pi_div_two, toReal_zero]
exact div_ne_zero (neg_ne_zero.2 Real.pi_ne_zero) two_ne_zero
theorem abs_toReal_coe_eq_self_iff {θ : ℝ} : |(θ : Angle).toReal| = θ ↔ 0 ≤ θ ∧ θ ≤ π :=
⟨fun h => h ▸ ⟨abs_nonneg _, abs_toReal_le_pi _⟩, fun h =>
(toReal_coe_eq_self_iff.2 ⟨(Left.neg_neg_iff.2 Real.pi_pos).trans_le h.1, h.2⟩).symm ▸
abs_eq_self.2 h.1⟩
theorem abs_toReal_neg_coe_eq_self_iff {θ : ℝ} : |(-θ : Angle).toReal| = θ ↔ 0 ≤ θ ∧ θ ≤ π := by
refine ⟨fun h => h ▸ ⟨abs_nonneg _, abs_toReal_le_pi _⟩, fun h => ?_⟩
by_cases hnegpi : θ = π; · simp [hnegpi, Real.pi_pos.le]
rw [← coe_neg,
toReal_coe_eq_self_iff.2
⟨neg_lt_neg (lt_of_le_of_ne h.2 hnegpi), (neg_nonpos.2 h.1).trans Real.pi_pos.le⟩,
abs_neg, abs_eq_self.2 h.1]
theorem abs_toReal_eq_pi_div_two_iff {θ : Angle} :
|θ.toReal| = π / 2 ↔ θ = (π / 2 : ℝ) ∨ θ = (-π / 2 : ℝ) := by
rw [abs_eq (div_nonneg Real.pi_pos.le two_pos.le), ← neg_div, toReal_eq_pi_div_two_iff,
toReal_eq_neg_pi_div_two_iff]
theorem nsmul_toReal_eq_mul {n : ℕ} (h : n ≠ 0) {θ : Angle} :
(n • θ).toReal = n * θ.toReal ↔ θ.toReal ∈ Set.Ioc (-π / n) (π / n) := by
nth_rw 1 [← coe_toReal θ]
have h' : 0 < (n : ℝ) := mod_cast Nat.pos_of_ne_zero h
rw [← coe_nsmul, nsmul_eq_mul, toReal_coe_eq_self_iff, Set.mem_Ioc, div_lt_iff₀' h',
le_div_iff₀' h']
theorem two_nsmul_toReal_eq_two_mul {θ : Angle} :
((2 : ℕ) • θ).toReal = 2 * θ.toReal ↔ θ.toReal ∈ Set.Ioc (-π / 2) (π / 2) :=
mod_cast nsmul_toReal_eq_mul two_ne_zero
theorem two_zsmul_toReal_eq_two_mul {θ : Angle} :
((2 : ℤ) • θ).toReal = 2 * θ.toReal ↔ θ.toReal ∈ Set.Ioc (-π / 2) (π / 2) := by
rw [two_zsmul, ← two_nsmul, two_nsmul_toReal_eq_two_mul]
theorem toReal_coe_eq_self_sub_two_mul_int_mul_pi_iff {θ : ℝ} {k : ℤ} :
(θ : Angle).toReal = θ - 2 * k * π ↔ θ ∈ Set.Ioc ((2 * k - 1 : ℝ) * π) ((2 * k + 1) * π) := by
rw [← sub_zero (θ : Angle), ← zsmul_zero k, ← coe_two_pi, ← coe_zsmul, ← coe_sub, zsmul_eq_mul, ←
mul_assoc, mul_comm (k : ℝ), toReal_coe_eq_self_iff, Set.mem_Ioc]
exact ⟨fun h => ⟨by linarith, by linarith⟩, fun h => ⟨by linarith, by linarith⟩⟩
theorem toReal_coe_eq_self_sub_two_pi_iff {θ : ℝ} :
(θ : Angle).toReal = θ - 2 * π ↔ θ ∈ Set.Ioc π (3 * π) := by
convert @toReal_coe_eq_self_sub_two_mul_int_mul_pi_iff θ 1 <;> norm_num
theorem toReal_coe_eq_self_add_two_pi_iff {θ : ℝ} :
(θ : Angle).toReal = θ + 2 * π ↔ θ ∈ Set.Ioc (-3 * π) (-π) := by
convert @toReal_coe_eq_self_sub_two_mul_int_mul_pi_iff θ (-1) using 2 <;> norm_num
theorem two_nsmul_toReal_eq_two_mul_sub_two_pi {θ : Angle} :
((2 : ℕ) • θ).toReal = 2 * θ.toReal - 2 * π ↔ π / 2 < θ.toReal := by
nth_rw 1 [← coe_toReal θ]
rw [← coe_nsmul, two_nsmul, ← two_mul, toReal_coe_eq_self_sub_two_pi_iff, Set.mem_Ioc]
exact
⟨fun h => by linarith, fun h =>
⟨(div_lt_iff₀' (zero_lt_two' ℝ)).1 h, by linarith [pi_pos, toReal_le_pi θ]⟩⟩
theorem two_zsmul_toReal_eq_two_mul_sub_two_pi {θ : Angle} :
((2 : ℤ) • θ).toReal = 2 * θ.toReal - 2 * π ↔ π / 2 < θ.toReal := by
rw [two_zsmul, ← two_nsmul, two_nsmul_toReal_eq_two_mul_sub_two_pi]
theorem two_nsmul_toReal_eq_two_mul_add_two_pi {θ : Angle} :
((2 : ℕ) • θ).toReal = 2 * θ.toReal + 2 * π ↔ θ.toReal ≤ -π / 2 := by
nth_rw 1 [← coe_toReal θ]
rw [← coe_nsmul, two_nsmul, ← two_mul, toReal_coe_eq_self_add_two_pi_iff, Set.mem_Ioc]
refine
⟨fun h => by linarith, fun h =>
⟨by linarith [pi_pos, neg_pi_lt_toReal θ], (le_div_iff₀' (zero_lt_two' ℝ)).1 h⟩⟩
theorem two_zsmul_toReal_eq_two_mul_add_two_pi {θ : Angle} :
((2 : ℤ) • θ).toReal = 2 * θ.toReal + 2 * π ↔ θ.toReal ≤ -π / 2 := by
rw [two_zsmul, ← two_nsmul, two_nsmul_toReal_eq_two_mul_add_two_pi]
@[simp]
theorem sin_toReal (θ : Angle) : Real.sin θ.toReal = sin θ := by
conv_rhs => rw [← coe_toReal θ, sin_coe]
@[simp]
theorem cos_toReal (θ : Angle) : Real.cos θ.toReal = cos θ := by
conv_rhs => rw [← coe_toReal θ, cos_coe]
theorem cos_nonneg_iff_abs_toReal_le_pi_div_two {θ : Angle} : 0 ≤ cos θ ↔ |θ.toReal| ≤ π / 2 := by
nth_rw 1 [← coe_toReal θ]
rw [abs_le, cos_coe]
refine ⟨fun h => ?_, cos_nonneg_of_mem_Icc⟩
by_contra hn
rw [not_and_or, not_le, not_le] at hn
refine (not_lt.2 h) ?_
rcases hn with (hn | hn)
· rw [← Real.cos_neg]
refine cos_neg_of_pi_div_two_lt_of_lt (by linarith) ?_
linarith [neg_pi_lt_toReal θ]
· refine cos_neg_of_pi_div_two_lt_of_lt hn ?_
linarith [toReal_le_pi θ]
theorem cos_pos_iff_abs_toReal_lt_pi_div_two {θ : Angle} : 0 < cos θ ↔ |θ.toReal| < π / 2 := by
rw [lt_iff_le_and_ne, lt_iff_le_and_ne, cos_nonneg_iff_abs_toReal_le_pi_div_two, ←
and_congr_right]
rintro -
rw [Ne, Ne, not_iff_not, @eq_comm ℝ 0, abs_toReal_eq_pi_div_two_iff, cos_eq_zero_iff]
theorem cos_neg_iff_pi_div_two_lt_abs_toReal {θ : Angle} : cos θ < 0 ↔ π / 2 < |θ.toReal| := by
rw [← not_le, ← not_le, not_iff_not, cos_nonneg_iff_abs_toReal_le_pi_div_two]
| theorem abs_cos_eq_abs_sin_of_two_nsmul_add_two_nsmul_eq_pi {θ ψ : Angle}
(h : (2 : ℕ) • θ + (2 : ℕ) • ψ = π) : |cos θ| = |sin ψ| := by
| Mathlib/Analysis/SpecialFunctions/Trigonometric/Angle.lean | 628 | 629 |
/-
Copyright (c) 2014 Microsoft Corporation. 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.Algebra.Ring.Int.Defs
import Mathlib.Data.Nat.Bitwise
import Mathlib.Data.Nat.Cast.Order.Basic
import Mathlib.Data.Nat.PSub
import Mathlib.Data.Nat.Size
import Mathlib.Data.Num.Bitwise
/-!
# Properties of the binary representation of integers
-/
open Int
attribute [local simp] add_assoc
namespace PosNum
variable {α : Type*}
@[simp, norm_cast]
theorem cast_one [One α] [Add α] : ((1 : PosNum) : α) = 1 :=
rfl
@[simp]
theorem cast_one' [One α] [Add α] : (PosNum.one : α) = 1 :=
rfl
@[simp, norm_cast]
theorem cast_bit0 [One α] [Add α] (n : PosNum) : (n.bit0 : α) = (n : α) + n :=
rfl
@[simp, norm_cast]
theorem cast_bit1 [One α] [Add α] (n : PosNum) : (n.bit1 : α) = ((n : α) + n) + 1 :=
rfl
@[simp, norm_cast]
theorem cast_to_nat [AddMonoidWithOne α] : ∀ n : PosNum, ((n : ℕ) : α) = n
| 1 => Nat.cast_one
| bit0 p => by dsimp; rw [Nat.cast_add, p.cast_to_nat]
| bit1 p => by dsimp; rw [Nat.cast_add, Nat.cast_add, Nat.cast_one, p.cast_to_nat]
@[norm_cast]
theorem to_nat_to_int (n : PosNum) : ((n : ℕ) : ℤ) = n :=
cast_to_nat _
@[simp, norm_cast]
theorem cast_to_int [AddGroupWithOne α] (n : PosNum) : ((n : ℤ) : α) = n := by
rw [← to_nat_to_int, Int.cast_natCast, cast_to_nat]
theorem succ_to_nat : ∀ n, (succ n : ℕ) = n + 1
| 1 => rfl
| bit0 _ => rfl
| bit1 p =>
(congr_arg (fun n ↦ n + n) (succ_to_nat p)).trans <|
show ↑p + 1 + ↑p + 1 = ↑p + ↑p + 1 + 1 by simp [add_left_comm]
theorem one_add (n : PosNum) : 1 + n = succ n := by cases n <;> rfl
theorem add_one (n : PosNum) : n + 1 = succ n := by cases n <;> rfl
@[norm_cast]
theorem add_to_nat : ∀ m n, ((m + n : PosNum) : ℕ) = m + n
| 1, b => by rw [one_add b, succ_to_nat, add_comm, cast_one]
| a, 1 => by rw [add_one a, succ_to_nat, cast_one]
| bit0 a, bit0 b => (congr_arg (fun n ↦ n + n) (add_to_nat a b)).trans <| add_add_add_comm _ _ _ _
| bit0 a, bit1 b =>
(congr_arg (fun n ↦ (n + n) + 1) (add_to_nat a b)).trans <|
show (a + b + (a + b) + 1 : ℕ) = a + a + (b + b + 1) by simp [add_left_comm]
| bit1 a, bit0 b =>
(congr_arg (fun n ↦ (n + n) + 1) (add_to_nat a b)).trans <|
show (a + b + (a + b) + 1 : ℕ) = a + a + 1 + (b + b) by simp [add_comm, add_left_comm]
| bit1 a, bit1 b =>
show (succ (a + b) + succ (a + b) : ℕ) = a + a + 1 + (b + b + 1) by
rw [succ_to_nat, add_to_nat a b]; simp [add_left_comm]
theorem add_succ : ∀ m n : PosNum, m + succ n = succ (m + n)
| 1, b => by simp [one_add]
| bit0 a, 1 => congr_arg bit0 (add_one a)
| bit1 a, 1 => congr_arg bit1 (add_one a)
| bit0 _, bit0 _ => rfl
| bit0 a, bit1 b => congr_arg bit0 (add_succ a b)
| bit1 _, bit0 _ => rfl
| bit1 a, bit1 b => congr_arg bit1 (add_succ a b)
theorem bit0_of_bit0 : ∀ n, n + n = bit0 n
| 1 => rfl
| bit0 p => congr_arg bit0 (bit0_of_bit0 p)
| bit1 p => show bit0 (succ (p + p)) = _ by rw [bit0_of_bit0 p, succ]
theorem bit1_of_bit1 (n : PosNum) : (n + n) + 1 = bit1 n :=
show (n + n) + 1 = bit1 n by rw [add_one, bit0_of_bit0, succ]
@[norm_cast]
theorem mul_to_nat (m) : ∀ n, ((m * n : PosNum) : ℕ) = m * n
| 1 => (mul_one _).symm
| bit0 p => show (↑(m * p) + ↑(m * p) : ℕ) = ↑m * (p + p) by rw [mul_to_nat m p, left_distrib]
| bit1 p =>
(add_to_nat (bit0 (m * p)) m).trans <|
show (↑(m * p) + ↑(m * p) + ↑m : ℕ) = ↑m * (p + p) + m by rw [mul_to_nat m p, left_distrib]
theorem to_nat_pos : ∀ n : PosNum, 0 < (n : ℕ)
| 1 => Nat.zero_lt_one
| bit0 p =>
let h := to_nat_pos p
add_pos h h
| bit1 _p => Nat.succ_pos _
theorem cmp_to_nat_lemma {m n : PosNum} : (m : ℕ) < n → (bit1 m : ℕ) < bit0 n :=
show (m : ℕ) < n → (m + m + 1 + 1 : ℕ) ≤ n + n by
intro h; rw [Nat.add_right_comm m m 1, add_assoc]; exact Nat.add_le_add h h
theorem cmp_swap (m) : ∀ n, (cmp m n).swap = cmp n m := by
induction' m with m IH m IH <;> intro n <;> obtain - | n | n := n <;> unfold cmp <;>
try { rfl } <;> rw [← IH] <;> cases cmp m n <;> rfl
theorem cmp_to_nat : ∀ m n, (Ordering.casesOn (cmp m n) ((m : ℕ) < n) (m = n) ((n : ℕ) < m) : Prop)
| 1, 1 => rfl
| bit0 a, 1 =>
let h : (1 : ℕ) ≤ a := to_nat_pos a
Nat.add_le_add h h
| bit1 a, 1 => Nat.succ_lt_succ <| to_nat_pos <| bit0 a
| 1, bit0 b =>
let h : (1 : ℕ) ≤ b := to_nat_pos b
Nat.add_le_add h h
| 1, bit1 b => Nat.succ_lt_succ <| to_nat_pos <| bit0 b
| bit0 a, bit0 b => by
dsimp [cmp]
have := cmp_to_nat a b; revert this; cases cmp a b <;> dsimp <;> intro this
· exact Nat.add_lt_add this this
· rw [this]
· exact Nat.add_lt_add this this
| bit0 a, bit1 b => by
dsimp [cmp]
have := cmp_to_nat a b; revert this; cases cmp a b <;> dsimp <;> intro this
· exact Nat.le_succ_of_le (Nat.add_lt_add this this)
· rw [this]
apply Nat.lt_succ_self
· exact cmp_to_nat_lemma this
| bit1 a, bit0 b => by
dsimp [cmp]
have := cmp_to_nat a b; revert this; cases cmp a b <;> dsimp <;> intro this
· exact cmp_to_nat_lemma this
· rw [this]
apply Nat.lt_succ_self
· exact Nat.le_succ_of_le (Nat.add_lt_add this this)
| bit1 a, bit1 b => by
dsimp [cmp]
have := cmp_to_nat a b; revert this; cases cmp a b <;> dsimp <;> intro this
· exact Nat.succ_lt_succ (Nat.add_lt_add this this)
· rw [this]
· exact Nat.succ_lt_succ (Nat.add_lt_add this this)
@[norm_cast]
theorem lt_to_nat {m n : PosNum} : (m : ℕ) < n ↔ m < n :=
show (m : ℕ) < n ↔ cmp m n = Ordering.lt from
match cmp m n, cmp_to_nat m n with
| Ordering.lt, h => by simp only at h; simp [h]
| Ordering.eq, h => by simp only at h; simp [h, lt_irrefl]
| Ordering.gt, h => by simp [not_lt_of_gt h]
@[norm_cast]
theorem le_to_nat {m n : PosNum} : (m : ℕ) ≤ n ↔ m ≤ n := by
rw [← not_lt]; exact not_congr lt_to_nat
end PosNum
namespace Num
variable {α : Type*}
open PosNum
theorem add_zero (n : Num) : n + 0 = n := by cases n <;> rfl
theorem zero_add (n : Num) : 0 + n = n := by cases n <;> rfl
theorem add_one : ∀ n : Num, n + 1 = succ n
| 0 => rfl
| pos p => by cases p <;> rfl
theorem add_succ : ∀ m n : Num, m + succ n = succ (m + n)
| 0, n => by simp [zero_add]
| pos p, 0 => show pos (p + 1) = succ (pos p + 0) by rw [PosNum.add_one, add_zero, succ, succ']
| pos _, pos _ => congr_arg pos (PosNum.add_succ _ _)
theorem bit0_of_bit0 : ∀ n : Num, n + n = n.bit0
| 0 => rfl
| pos p => congr_arg pos p.bit0_of_bit0
theorem bit1_of_bit1 : ∀ n : Num, (n + n) + 1 = n.bit1
| 0 => rfl
| pos p => congr_arg pos p.bit1_of_bit1
@[simp]
theorem ofNat'_zero : Num.ofNat' 0 = 0 := by simp [Num.ofNat']
theorem ofNat'_bit (b n) : ofNat' (Nat.bit b n) = cond b Num.bit1 Num.bit0 (ofNat' n) :=
Nat.binaryRec_eq _ _ (.inl rfl)
@[simp]
theorem ofNat'_one : Num.ofNat' 1 = 1 := by erw [ofNat'_bit true 0, cond, ofNat'_zero]; rfl
theorem bit1_succ : ∀ n : Num, n.bit1.succ = n.succ.bit0
| 0 => rfl
| pos _n => rfl
theorem ofNat'_succ : ∀ {n}, ofNat' (n + 1) = ofNat' n + 1 :=
@(Nat.binaryRec (by simp [zero_add]) fun b n ih => by
cases b
· erw [ofNat'_bit true n, ofNat'_bit]
simp only [← bit1_of_bit1, ← bit0_of_bit0, cond]
· rw [show n.bit true + 1 = (n + 1).bit false by simp [Nat.bit, mul_add],
ofNat'_bit, ofNat'_bit, ih]
simp only [cond, add_one, bit1_succ])
@[simp]
theorem add_ofNat' (m n) : Num.ofNat' (m + n) = Num.ofNat' m + Num.ofNat' n := by
induction n
· simp only [Nat.add_zero, ofNat'_zero, add_zero]
· simp only [Nat.add_succ, Nat.add_zero, ofNat'_succ, add_one, add_succ, *]
@[simp, norm_cast]
theorem cast_zero [Zero α] [One α] [Add α] : ((0 : Num) : α) = 0 :=
rfl
@[simp]
theorem cast_zero' [Zero α] [One α] [Add α] : (Num.zero : α) = 0 :=
rfl
@[simp, norm_cast]
theorem cast_one [Zero α] [One α] [Add α] : ((1 : Num) : α) = 1 :=
rfl
@[simp]
theorem cast_pos [Zero α] [One α] [Add α] (n : PosNum) : (Num.pos n : α) = n :=
rfl
theorem succ'_to_nat : ∀ n, (succ' n : ℕ) = n + 1
| 0 => (Nat.zero_add _).symm
| pos _p => PosNum.succ_to_nat _
theorem succ_to_nat (n) : (succ n : ℕ) = n + 1 :=
succ'_to_nat n
@[simp, norm_cast]
theorem cast_to_nat [AddMonoidWithOne α] : ∀ n : Num, ((n : ℕ) : α) = n
| 0 => Nat.cast_zero
| pos p => p.cast_to_nat
@[norm_cast]
theorem add_to_nat : ∀ m n, ((m + n : Num) : ℕ) = m + n
| 0, 0 => rfl
| 0, pos _q => (Nat.zero_add _).symm
| pos _p, 0 => rfl
| pos _p, pos _q => PosNum.add_to_nat _ _
@[norm_cast]
theorem mul_to_nat : ∀ m n, ((m * n : Num) : ℕ) = m * n
| 0, 0 => rfl
| 0, pos _q => (zero_mul _).symm
| pos _p, 0 => rfl
| pos _p, pos _q => PosNum.mul_to_nat _ _
theorem cmp_to_nat : ∀ m n, (Ordering.casesOn (cmp m n) ((m : ℕ) < n) (m = n) ((n : ℕ) < m) : Prop)
| 0, 0 => rfl
| 0, pos _ => to_nat_pos _
| pos _, 0 => to_nat_pos _
| pos a, pos b => by
have := PosNum.cmp_to_nat a b; revert this; dsimp [cmp]; cases PosNum.cmp a b
exacts [id, congr_arg pos, id]
@[norm_cast]
theorem lt_to_nat {m n : Num} : (m : ℕ) < n ↔ m < n :=
show (m : ℕ) < n ↔ cmp m n = Ordering.lt from
match cmp m n, cmp_to_nat m n with
| Ordering.lt, h => by simp only at h; simp [h]
| Ordering.eq, h => by simp only at h; simp [h, lt_irrefl]
| Ordering.gt, h => by simp [not_lt_of_gt h]
@[norm_cast]
theorem le_to_nat {m n : Num} : (m : ℕ) ≤ n ↔ m ≤ n := by
rw [← not_lt]; exact not_congr lt_to_nat
end Num
namespace PosNum
@[simp]
theorem of_to_nat' : ∀ n : PosNum, Num.ofNat' (n : ℕ) = Num.pos n
| 1 => by erw [@Num.ofNat'_bit true 0, Num.ofNat'_zero]; rfl
| bit0 p => by
simpa only [Nat.bit_false, cond_false, two_mul, of_to_nat' p] using Num.ofNat'_bit false p
| bit1 p => by
simpa only [Nat.bit_true, cond_true, two_mul, of_to_nat' p] using Num.ofNat'_bit true p
end PosNum
namespace Num
@[simp, norm_cast]
theorem of_to_nat' : ∀ n : Num, Num.ofNat' (n : ℕ) = n
| 0 => ofNat'_zero
| pos p => p.of_to_nat'
lemma toNat_injective : Function.Injective (castNum : Num → ℕ) :=
Function.LeftInverse.injective of_to_nat'
@[norm_cast]
theorem to_nat_inj {m n : Num} : (m : ℕ) = n ↔ m = n := toNat_injective.eq_iff
/-- This tactic tries to turn an (in)equality about `Num`s to one about `Nat`s by rewriting.
```lean
example (n : Num) (m : Num) : n ≤ n + m := by
transfer_rw
exact Nat.le_add_right _ _
```
-/
scoped macro (name := transfer_rw) "transfer_rw" : tactic => `(tactic|
(repeat first | rw [← to_nat_inj] | rw [← lt_to_nat] | rw [← le_to_nat]
repeat first | rw [add_to_nat] | rw [mul_to_nat] | rw [cast_one] | rw [cast_zero]))
/--
This tactic tries to prove (in)equalities about `Num`s by transferring them to the `Nat` world and
then trying to call `simp`.
```lean
example (n : Num) (m : Num) : n ≤ n + m := by transfer
```
-/
scoped macro (name := transfer) "transfer" : tactic => `(tactic|
(intros; transfer_rw; try simp))
instance addMonoid : AddMonoid Num where
add := (· + ·)
zero := 0
zero_add := zero_add
add_zero := add_zero
add_assoc := by transfer
nsmul := nsmulRec
instance addMonoidWithOne : AddMonoidWithOne Num :=
{ Num.addMonoid with
natCast := Num.ofNat'
one := 1
natCast_zero := ofNat'_zero
natCast_succ := fun _ => ofNat'_succ }
instance commSemiring : CommSemiring Num where
__ := Num.addMonoid
__ := Num.addMonoidWithOne
mul := (· * ·)
npow := @npowRec Num ⟨1⟩ ⟨(· * ·)⟩
mul_zero _ := by rw [← to_nat_inj, mul_to_nat, cast_zero, mul_zero]
zero_mul _ := by rw [← to_nat_inj, mul_to_nat, cast_zero, zero_mul]
mul_one _ := by rw [← to_nat_inj, mul_to_nat, cast_one, mul_one]
one_mul _ := by rw [← to_nat_inj, mul_to_nat, cast_one, one_mul]
add_comm _ _ := by simp_rw [← to_nat_inj, add_to_nat, add_comm]
mul_comm _ _ := by simp_rw [← to_nat_inj, mul_to_nat, mul_comm]
mul_assoc _ _ _ := by simp_rw [← to_nat_inj, mul_to_nat, mul_assoc]
left_distrib _ _ _ := by simp only [← to_nat_inj, mul_to_nat, add_to_nat, mul_add]
right_distrib _ _ _ := by simp only [← to_nat_inj, mul_to_nat, add_to_nat, add_mul]
instance partialOrder : PartialOrder Num where
lt_iff_le_not_le a b := by simp only [← lt_to_nat, ← le_to_nat, lt_iff_le_not_le]
le_refl := by transfer
le_trans a b c := by transfer_rw; apply le_trans
le_antisymm a b := by transfer_rw; apply le_antisymm
instance isOrderedCancelAddMonoid : IsOrderedCancelAddMonoid Num where
add_le_add_left a b h c := by revert h; transfer_rw; exact fun h => add_le_add_left h c
le_of_add_le_add_left a b c :=
show a + b ≤ a + c → b ≤ c by transfer_rw; apply le_of_add_le_add_left
instance linearOrder : LinearOrder Num :=
{ le_total := by
intro a b
transfer_rw
apply le_total
toDecidableLT := Num.decidableLT
toDecidableLE := Num.decidableLE
-- This is relying on an automatically generated instance name,
-- generated in a `deriving` handler.
-- See https://github.com/leanprover/lean4/issues/2343
toDecidableEq := instDecidableEqNum }
instance isStrictOrderedRing : IsStrictOrderedRing Num :=
{ zero_le_one := by decide
mul_lt_mul_of_pos_left := by
intro a b c
transfer_rw
apply mul_lt_mul_of_pos_left
mul_lt_mul_of_pos_right := by
intro a b c
transfer_rw
apply mul_lt_mul_of_pos_right
exists_pair_ne := ⟨0, 1, by decide⟩ }
@[norm_cast]
theorem add_of_nat (m n) : ((m + n : ℕ) : Num) = m + n :=
add_ofNat' _ _
@[norm_cast]
theorem to_nat_to_int (n : Num) : ((n : ℕ) : ℤ) = n :=
cast_to_nat _
@[simp, norm_cast]
theorem cast_to_int {α} [AddGroupWithOne α] (n : Num) : ((n : ℤ) : α) = n := by
rw [← to_nat_to_int, Int.cast_natCast, cast_to_nat]
theorem to_of_nat : ∀ n : ℕ, ((n : Num) : ℕ) = n
| 0 => by rw [Nat.cast_zero, cast_zero]
| n + 1 => by rw [Nat.cast_succ, add_one, succ_to_nat, to_of_nat n]
@[simp, norm_cast]
theorem of_natCast {α} [AddMonoidWithOne α] (n : ℕ) : ((n : Num) : α) = n := by
rw [← cast_to_nat, to_of_nat]
@[norm_cast]
theorem of_nat_inj {m n : ℕ} : (m : Num) = n ↔ m = n :=
⟨fun h => Function.LeftInverse.injective to_of_nat h, congr_arg _⟩
-- The priority should be `high`er than `cast_to_nat`.
@[simp high, norm_cast]
theorem of_to_nat : ∀ n : Num, ((n : ℕ) : Num) = n :=
of_to_nat'
@[norm_cast]
theorem dvd_to_nat (m n : Num) : (m : ℕ) ∣ n ↔ m ∣ n :=
⟨fun ⟨k, e⟩ => ⟨k, by rw [← of_to_nat n, e]; simp⟩, fun ⟨k, e⟩ => ⟨k, by simp [e, mul_to_nat]⟩⟩
end Num
namespace PosNum
variable {α : Type*}
open Num
-- The priority should be `high`er than `cast_to_nat`.
@[simp high, norm_cast]
theorem of_to_nat : ∀ n : PosNum, ((n : ℕ) : Num) = Num.pos n :=
of_to_nat'
@[norm_cast]
theorem to_nat_inj {m n : PosNum} : (m : ℕ) = n ↔ m = n :=
⟨fun h => Num.pos.inj <| by rw [← PosNum.of_to_nat, ← PosNum.of_to_nat, h], congr_arg _⟩
theorem pred'_to_nat : ∀ n, (pred' n : ℕ) = Nat.pred n
| 1 => rfl
| bit0 n =>
have : Nat.succ ↑(pred' n) = ↑n := by
rw [pred'_to_nat n, Nat.succ_pred_eq_of_pos (to_nat_pos n)]
match (motive :=
∀ k : Num, Nat.succ ↑k = ↑n → ↑(Num.casesOn k 1 bit1 : PosNum) = Nat.pred (n + n))
pred' n, this with
| 0, (h : ((1 : Num) : ℕ) = n) => by rw [← to_nat_inj.1 h]; rfl
| Num.pos p, (h : Nat.succ ↑p = n) => by rw [← h]; exact (Nat.succ_add p p).symm
| bit1 _ => rfl
@[simp]
theorem pred'_succ' (n) : pred' (succ' n) = n :=
Num.to_nat_inj.1 <| by rw [pred'_to_nat, succ'_to_nat, Nat.add_one, Nat.pred_succ]
@[simp]
theorem succ'_pred' (n) : succ' (pred' n) = n :=
to_nat_inj.1 <| by
rw [succ'_to_nat, pred'_to_nat, Nat.add_one, Nat.succ_pred_eq_of_pos (to_nat_pos _)]
instance dvd : Dvd PosNum :=
⟨fun m n => pos m ∣ pos n⟩
@[norm_cast]
theorem dvd_to_nat {m n : PosNum} : (m : ℕ) ∣ n ↔ m ∣ n :=
Num.dvd_to_nat (pos m) (pos n)
theorem size_to_nat : ∀ n, (size n : ℕ) = Nat.size n
| 1 => Nat.size_one.symm
| bit0 n => by
rw [size, succ_to_nat, size_to_nat n, cast_bit0, ← two_mul]
erw [@Nat.size_bit false n]
have := to_nat_pos n
dsimp [Nat.bit]; omega
| bit1 n => by
rw [size, succ_to_nat, size_to_nat n, cast_bit1, ← two_mul]
erw [@Nat.size_bit true n]
dsimp [Nat.bit]; omega
theorem size_eq_natSize : ∀ n, (size n : ℕ) = natSize n
| 1 => rfl
| bit0 n => by rw [size, succ_to_nat, natSize, size_eq_natSize n]
| bit1 n => by rw [size, succ_to_nat, natSize, size_eq_natSize n]
theorem natSize_to_nat (n) : natSize n = Nat.size n := by rw [← size_eq_natSize, size_to_nat]
theorem natSize_pos (n) : 0 < natSize n := by cases n <;> apply Nat.succ_pos
/-- This tactic tries to turn an (in)equality about `PosNum`s to one about `Nat`s by rewriting.
```lean
example (n : PosNum) (m : PosNum) : n ≤ n + m := by
transfer_rw
exact Nat.le_add_right _ _
```
-/
scoped macro (name := transfer_rw) "transfer_rw" : tactic => `(tactic|
(repeat first | rw [← to_nat_inj] | rw [← lt_to_nat] | rw [← le_to_nat]
repeat first | rw [add_to_nat] | rw [mul_to_nat] | rw [cast_one] | rw [cast_zero]))
/--
This tactic tries to prove (in)equalities about `PosNum`s by transferring them to the `Nat` world
and then trying to call `simp`.
```lean
example (n : PosNum) (m : PosNum) : n ≤ n + m := by transfer
```
-/
scoped macro (name := transfer) "transfer" : tactic => `(tactic|
(intros; transfer_rw; try simp [add_comm, add_left_comm, mul_comm, mul_left_comm]))
instance addCommSemigroup : AddCommSemigroup PosNum where
add := (· + ·)
add_assoc := by transfer
add_comm := by transfer
instance commMonoid : CommMonoid PosNum where
mul := (· * ·)
one := (1 : PosNum)
npow := @npowRec PosNum ⟨1⟩ ⟨(· * ·)⟩
mul_assoc := by transfer
one_mul := by transfer
mul_one := by transfer
mul_comm := by transfer
instance distrib : Distrib PosNum where
add := (· + ·)
mul := (· * ·)
left_distrib := by transfer; simp [mul_add]
right_distrib := by transfer; simp [mul_add, mul_comm]
instance linearOrder : LinearOrder PosNum where
lt := (· < ·)
lt_iff_le_not_le := by
intro a b
transfer_rw
apply lt_iff_le_not_le
le := (· ≤ ·)
le_refl := by transfer
le_trans := by
intro a b c
transfer_rw
apply le_trans
le_antisymm := by
intro a b
transfer_rw
apply le_antisymm
le_total := by
intro a b
transfer_rw
apply le_total
toDecidableLT := by infer_instance
toDecidableLE := by infer_instance
toDecidableEq := by infer_instance
@[simp]
theorem cast_to_num (n : PosNum) : ↑n = Num.pos n := by rw [← cast_to_nat, ← of_to_nat n]
@[simp, norm_cast]
theorem bit_to_nat (b n) : (bit b n : ℕ) = Nat.bit b n := by cases b <;> simp [bit, two_mul]
@[simp, norm_cast]
theorem cast_add [AddMonoidWithOne α] (m n) : ((m + n : PosNum) : α) = m + n := by
rw [← cast_to_nat, add_to_nat, Nat.cast_add, cast_to_nat, cast_to_nat]
@[simp 500, norm_cast]
theorem cast_succ [AddMonoidWithOne α] (n : PosNum) : (succ n : α) = n + 1 := by
rw [← add_one, cast_add, cast_one]
@[simp, norm_cast]
theorem cast_inj [AddMonoidWithOne α] [CharZero α] {m n : PosNum} : (m : α) = n ↔ m = n := by
rw [← cast_to_nat m, ← cast_to_nat n, Nat.cast_inj, to_nat_inj]
@[simp]
theorem one_le_cast [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] (n : PosNum) :
(1 : α) ≤ n := by
rw [← cast_to_nat, ← Nat.cast_one, Nat.cast_le (α := α)]; apply to_nat_pos
@[simp]
theorem cast_pos [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] (n : PosNum) : 0 < (n : α) :=
lt_of_lt_of_le zero_lt_one (one_le_cast n)
@[simp, norm_cast]
theorem cast_mul [NonAssocSemiring α] (m n) : ((m * n : PosNum) : α) = m * n := by
rw [← cast_to_nat, mul_to_nat, Nat.cast_mul, cast_to_nat, cast_to_nat]
@[simp]
theorem cmp_eq (m n) : cmp m n = Ordering.eq ↔ m = n := by
have := cmp_to_nat m n
-- Porting note: `cases` didn't rewrite at `this`, so `revert` & `intro` are required.
revert this; cases cmp m n <;> intro this <;> simp at this ⊢ <;> try { exact this } <;>
simp [show m ≠ n from fun e => by rw [e] at this;exact lt_irrefl _ this]
@[simp, norm_cast]
theorem cast_lt [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] {m n : PosNum} :
(m : α) < n ↔ m < n := by
rw [← cast_to_nat m, ← cast_to_nat n, Nat.cast_lt (α := α), lt_to_nat]
@[simp, norm_cast]
theorem cast_le [Semiring α] [LinearOrder α] [IsStrictOrderedRing α] {m n : PosNum} :
(m : α) ≤ n ↔ m ≤ n := by
rw [← not_lt]; exact not_congr cast_lt
end PosNum
namespace Num
variable {α : Type*}
open PosNum
theorem bit_to_nat (b n) : (bit b n : ℕ) = Nat.bit b n := by
cases b <;> cases n <;> simp [bit, two_mul] <;> rfl
theorem cast_succ' [AddMonoidWithOne α] (n) : (succ' n : α) = n + 1 := by
rw [← PosNum.cast_to_nat, succ'_to_nat, Nat.cast_add_one, cast_to_nat]
theorem cast_succ [AddMonoidWithOne α] (n) : (succ n : α) = n + 1 :=
cast_succ' n
@[simp, norm_cast]
theorem cast_add [AddMonoidWithOne α] (m n) : ((m + n : Num) : α) = m + n := by
rw [← cast_to_nat, add_to_nat, Nat.cast_add, cast_to_nat, cast_to_nat]
@[simp, norm_cast]
theorem cast_bit0 [NonAssocSemiring α] (n : Num) : (n.bit0 : α) = 2 * (n : α) := by
rw [← bit0_of_bit0, two_mul, cast_add]
@[simp, norm_cast]
theorem cast_bit1 [NonAssocSemiring α] (n : Num) : (n.bit1 : α) = 2 * (n : α) + 1 := by
rw [← bit1_of_bit1, bit0_of_bit0, cast_add, cast_bit0]; rfl
@[simp, norm_cast]
theorem cast_mul [NonAssocSemiring α] : ∀ m n, ((m * n : Num) : α) = m * n
| 0, 0 => (zero_mul _).symm
| 0, pos _q => (zero_mul _).symm
| pos _p, 0 => (mul_zero _).symm
| pos _p, pos _q => PosNum.cast_mul _ _
theorem size_to_nat : ∀ n, (size n : ℕ) = Nat.size n
| 0 => Nat.size_zero.symm
| pos p => p.size_to_nat
theorem size_eq_natSize : ∀ n, (size n : ℕ) = natSize n
| 0 => rfl
| pos p => p.size_eq_natSize
theorem natSize_to_nat (n) : natSize n = Nat.size n := by rw [← size_eq_natSize, size_to_nat]
@[simp 999]
theorem ofNat'_eq : ∀ n, Num.ofNat' n = n :=
Nat.binaryRec (by simp) fun b n IH => by tauto
theorem zneg_toZNum (n : Num) : -n.toZNum = n.toZNumNeg := by cases n <;> rfl
theorem zneg_toZNumNeg (n : Num) : -n.toZNumNeg = n.toZNum := by cases n <;> rfl
theorem toZNum_inj {m n : Num} : m.toZNum = n.toZNum ↔ m = n :=
⟨fun h => by cases m <;> cases n <;> cases h <;> rfl, congr_arg _⟩
@[simp]
theorem cast_toZNum [Zero α] [One α] [Add α] [Neg α] : ∀ n : Num, (n.toZNum : α) = n
| 0 => rfl
| Num.pos _p => rfl
@[simp]
theorem cast_toZNumNeg [SubtractionMonoid α] [One α] : ∀ n : Num, (n.toZNumNeg : α) = -n
| 0 => neg_zero.symm
| Num.pos _p => rfl
@[simp]
theorem add_toZNum (m n : Num) : Num.toZNum (m + n) = m.toZNum + n.toZNum := by
cases m <;> cases n <;> rfl
end Num
namespace PosNum
open Num
theorem pred_to_nat {n : PosNum} (h : 1 < n) : (pred n : ℕ) = Nat.pred n := by
unfold pred
cases e : pred' n
· have : (1 : ℕ) ≤ Nat.pred n := Nat.pred_le_pred ((@cast_lt ℕ _ _ _).2 h)
rw [← pred'_to_nat, e] at this
exact absurd this (by decide)
· rw [← pred'_to_nat, e]
rfl
theorem sub'_one (a : PosNum) : sub' a 1 = (pred' a).toZNum := by cases a <;> rfl
theorem one_sub' (a : PosNum) : sub' 1 a = (pred' a).toZNumNeg := by cases a <;> rfl
theorem lt_iff_cmp {m n} : m < n ↔ cmp m n = Ordering.lt :=
Iff.rfl
theorem le_iff_cmp {m n} : m ≤ n ↔ cmp m n ≠ Ordering.gt :=
not_congr <| lt_iff_cmp.trans <| by rw [← cmp_swap]; cases cmp m n <;> decide
end PosNum
namespace Num
variable {α : Type*}
open PosNum
theorem pred_to_nat : ∀ n : Num, (pred n : ℕ) = Nat.pred n
| 0 => rfl
| pos p => by rw [pred, PosNum.pred'_to_nat]; rfl
theorem ppred_to_nat : ∀ n : Num, (↑) <$> ppred n = Nat.ppred n
| 0 => rfl
| pos p => by
rw [ppred, Option.map_some, Nat.ppred_eq_some.2]
rw [PosNum.pred'_to_nat, Nat.succ_pred_eq_of_pos (PosNum.to_nat_pos _)]
rfl
theorem cmp_swap (m n) : (cmp m n).swap = cmp n m := by
cases m <;> cases n <;> try { rfl }; apply PosNum.cmp_swap
theorem cmp_eq (m n) : cmp m n = Ordering.eq ↔ m = n := by
have := cmp_to_nat m n
-- Porting note: `cases` didn't rewrite at `this`, so `revert` & `intro` are required.
revert this; cases cmp m n <;> intro this <;> simp at this ⊢ <;> try { exact this } <;>
simp [show m ≠ n from fun e => by rw [e] at this; exact lt_irrefl _ this]
@[simp, norm_cast]
theorem cast_lt [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] {m n : Num} :
(m : α) < n ↔ m < n := by
rw [← cast_to_nat m, ← cast_to_nat n, Nat.cast_lt (α := α), lt_to_nat]
@[simp, norm_cast]
theorem cast_le [Semiring α] [LinearOrder α] [IsStrictOrderedRing α] {m n : Num} :
(m : α) ≤ n ↔ m ≤ n := by
rw [← not_lt]; exact not_congr cast_lt
@[simp, norm_cast]
theorem cast_inj [Semiring α] [PartialOrder α] [IsStrictOrderedRing α] {m n : Num} :
(m : α) = n ↔ m = n := by
rw [← cast_to_nat m, ← cast_to_nat n, Nat.cast_inj, to_nat_inj]
theorem lt_iff_cmp {m n} : m < n ↔ cmp m n = Ordering.lt :=
Iff.rfl
theorem le_iff_cmp {m n} : m ≤ n ↔ cmp m n ≠ Ordering.gt :=
not_congr <| lt_iff_cmp.trans <| by rw [← cmp_swap]; cases cmp m n <;> decide
theorem castNum_eq_bitwise {f : Num → Num → Num} {g : Bool → Bool → Bool}
(p : PosNum → PosNum → Num)
(gff : g false false = false) (f00 : f 0 0 = 0)
(f0n : ∀ n, f 0 (pos n) = cond (g false true) (pos n) 0)
(fn0 : ∀ n, f (pos n) 0 = cond (g true false) (pos n) 0)
(fnn : ∀ m n, f (pos m) (pos n) = p m n) (p11 : p 1 1 = cond (g true true) 1 0)
(p1b : ∀ b n, p 1 (PosNum.bit b n) = bit (g true b) (cond (g false true) (pos n) 0))
(pb1 : ∀ a m, p (PosNum.bit a m) 1 = bit (g a true) (cond (g true false) (pos m) 0))
(pbb : ∀ a b m n, p (PosNum.bit a m) (PosNum.bit b n) = bit (g a b) (p m n)) :
∀ m n : Num, (f m n : ℕ) = Nat.bitwise g m n := by
intros m n
obtain - | m := m <;> obtain - | n := n <;>
try simp only [show zero = 0 from rfl, show ((0 : Num) : ℕ) = 0 from rfl]
· rw [f00, Nat.bitwise_zero]; rfl
· rw [f0n, Nat.bitwise_zero_left]
cases g false true <;> rfl
· rw [fn0, Nat.bitwise_zero_right]
cases g true false <;> rfl
· rw [fnn]
have this b (n : PosNum) : (cond b (↑n) 0 : ℕ) = ↑(cond b (pos n) 0 : Num) := by
cases b <;> rfl
have this' b (n : PosNum) : ↑ (pos (PosNum.bit b n)) = Nat.bit b ↑n := by
cases b <;> simp
induction' m with m IH m IH generalizing n <;> obtain - | n | n := n
any_goals simp only [show one = 1 from rfl, show pos 1 = 1 from rfl,
show PosNum.bit0 = PosNum.bit false from rfl, show PosNum.bit1 = PosNum.bit true from rfl,
show ((1 : Num) : ℕ) = Nat.bit true 0 from rfl]
all_goals
repeat rw [this']
rw [Nat.bitwise_bit gff]
any_goals rw [Nat.bitwise_zero, p11]; cases g true true <;> rfl
any_goals rw [Nat.bitwise_zero_left, ← Bool.cond_eq_ite, this, ← bit_to_nat, p1b]
any_goals rw [Nat.bitwise_zero_right, ← Bool.cond_eq_ite, this, ← bit_to_nat, pb1]
all_goals
rw [← show ∀ n : PosNum, ↑(p m n) = Nat.bitwise g ↑m ↑n from IH]
rw [← bit_to_nat, pbb]
@[simp, norm_cast]
theorem castNum_or : ∀ m n : Num, ↑(m ||| n) = (↑m ||| ↑n : ℕ) := by
apply castNum_eq_bitwise fun x y => pos (PosNum.lor x y) <;>
(try rintro (_ | _)) <;> (try rintro (_ | _)) <;> intros <;> rfl
@[simp, norm_cast]
theorem castNum_and : ∀ m n : Num, ↑(m &&& n) = (↑m &&& ↑n : ℕ) := by
apply castNum_eq_bitwise PosNum.land <;> intros <;> (try cases_type* Bool) <;> rfl
@[simp, norm_cast]
theorem castNum_ldiff : ∀ m n : Num, (ldiff m n : ℕ) = Nat.ldiff m n := by
apply castNum_eq_bitwise PosNum.ldiff <;> intros <;> (try cases_type* Bool) <;> rfl
@[simp, norm_cast]
theorem castNum_xor : ∀ m n : Num, ↑(m ^^^ n) = (↑m ^^^ ↑n : ℕ) := by
apply castNum_eq_bitwise PosNum.lxor <;> intros <;> (try cases_type* Bool) <;> rfl
@[simp, norm_cast]
theorem castNum_shiftLeft (m : Num) (n : Nat) : ↑(m <<< n) = (m : ℕ) <<< (n : ℕ) := by
cases m <;> dsimp only [← shiftl_eq_shiftLeft, shiftl]
· symm
apply Nat.zero_shiftLeft
simp only [cast_pos]
induction' n with n IH
· rfl
simp [PosNum.shiftl_succ_eq_bit0_shiftl, Nat.shiftLeft_succ, IH, pow_succ, ← mul_assoc, mul_comm,
-shiftl_eq_shiftLeft, -PosNum.shiftl_eq_shiftLeft, shiftl, mul_two]
@[simp, norm_cast]
theorem castNum_shiftRight (m : Num) (n : Nat) : ↑(m >>> n) = (m : ℕ) >>> (n : ℕ) := by
obtain - | m := m <;> dsimp only [← shiftr_eq_shiftRight, shiftr]
· symm
apply Nat.zero_shiftRight
induction' n with n IH generalizing m
· cases m <;> rfl
have hdiv2 : ∀ m, Nat.div2 (m + m) = m := by intro; rw [Nat.div2_val]; omega
obtain - | m | m := m <;> dsimp only [PosNum.shiftr, ← PosNum.shiftr_eq_shiftRight]
· rw [Nat.shiftRight_eq_div_pow]
symm
apply Nat.div_eq_of_lt
simp
· trans
· apply IH
change Nat.shiftRight m n = Nat.shiftRight (m + m + 1) (n + 1)
rw [add_comm n 1, @Nat.shiftRight_eq _ (1 + n), Nat.shiftRight_add]
apply congr_arg fun x => Nat.shiftRight x n
simp [-add_assoc, Nat.shiftRight_succ, Nat.shiftRight_zero, ← Nat.div2_val, hdiv2]
· trans
· apply IH
change Nat.shiftRight m n = Nat.shiftRight (m + m) (n + 1)
rw [add_comm n 1, @Nat.shiftRight_eq _ (1 + n), Nat.shiftRight_add]
apply congr_arg fun x => Nat.shiftRight x n
simp [-add_assoc, Nat.shiftRight_succ, Nat.shiftRight_zero, ← Nat.div2_val, hdiv2]
@[simp]
theorem castNum_testBit (m n) : testBit m n = Nat.testBit m n := by
cases m with dsimp only [testBit]
| zero =>
rw [show (Num.zero : Nat) = 0 from rfl, Nat.zero_testBit]
| pos m =>
rw [cast_pos]
induction' n with n IH generalizing m <;> obtain - | m | m := m
<;> simp only [PosNum.testBit]
· rfl
· rw [PosNum.cast_bit1, ← two_mul, ← congr_fun Nat.bit_true, Nat.testBit_bit_zero]
· rw [PosNum.cast_bit0, ← two_mul, ← congr_fun Nat.bit_false, Nat.testBit_bit_zero]
· simp [Nat.testBit_add_one]
· rw [PosNum.cast_bit1, ← two_mul, ← congr_fun Nat.bit_true, Nat.testBit_bit_succ, IH]
· rw [PosNum.cast_bit0, ← two_mul, ← congr_fun Nat.bit_false, Nat.testBit_bit_succ, IH]
end Num
namespace Int
/-- Cast a `SNum` to the corresponding integer. -/
def ofSnum : SNum → ℤ :=
SNum.rec' (fun a => cond a (-1) 0) fun a _p IH => cond a (2 * IH + 1) (2 * IH)
instance snumCoe : Coe SNum ℤ :=
⟨ofSnum⟩
end Int
instance SNum.lt : LT SNum :=
⟨fun a b => (a : ℤ) < b⟩
instance SNum.le : LE SNum :=
⟨fun a b => (a : ℤ) ≤ b⟩
| Mathlib/Data/Num/Lemmas.lean | 1,374 | 1,375 | |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Mario Carneiro, Yury Kudryashov
-/
import Mathlib.Data.Set.SymmDiff
import Mathlib.Order.SuccPred.Relation
import Mathlib.Topology.Irreducible
/-!
# Connected subsets of topological spaces
In this file we define connected subsets of a topological spaces and various other properties and
classes related to connectivity.
## Main definitions
We define the following properties for sets in a topological space:
* `IsConnected`: a nonempty set that has no non-trivial open partition.
See also the section below in the module doc.
* `connectedComponent` is the connected component of an element in the space.
We also have a class stating that the whole space satisfies that property: `ConnectedSpace`
## On the definition of connected sets/spaces
In informal mathematics, connected spaces are assumed to be nonempty.
We formalise the predicate without that assumption as `IsPreconnected`.
In other words, the only difference is whether the empty space counts as connected.
There are good reasons to consider the empty space to be “too simple to be simple”
See also https://ncatlab.org/nlab/show/too+simple+to+be+simple,
and in particular
https://ncatlab.org/nlab/show/too+simple+to+be+simple#relationship_to_biased_definitions.
-/
open Set Function Topology TopologicalSpace Relation
universe u v
variable {α : Type u} {β : Type v} {ι : Type*} {π : ι → Type*} [TopologicalSpace α]
{s t u v : Set α}
section Preconnected
/-- A preconnected set is one where there is no non-trivial open partition. -/
def IsPreconnected (s : Set α) : Prop :=
∀ u v : Set α, IsOpen u → IsOpen v → s ⊆ u ∪ v → (s ∩ u).Nonempty → (s ∩ v).Nonempty →
(s ∩ (u ∩ v)).Nonempty
/-- A connected set is one that is nonempty and where there is no non-trivial open partition. -/
def IsConnected (s : Set α) : Prop :=
s.Nonempty ∧ IsPreconnected s
theorem IsConnected.nonempty {s : Set α} (h : IsConnected s) : s.Nonempty :=
h.1
theorem IsConnected.isPreconnected {s : Set α} (h : IsConnected s) : IsPreconnected s :=
h.2
theorem IsPreirreducible.isPreconnected {s : Set α} (H : IsPreirreducible s) : IsPreconnected s :=
fun _ _ hu hv _ => H _ _ hu hv
theorem IsIrreducible.isConnected {s : Set α} (H : IsIrreducible s) : IsConnected s :=
⟨H.nonempty, H.isPreirreducible.isPreconnected⟩
theorem isPreconnected_empty : IsPreconnected (∅ : Set α) :=
isPreirreducible_empty.isPreconnected
theorem isConnected_singleton {x} : IsConnected ({x} : Set α) :=
isIrreducible_singleton.isConnected
theorem isPreconnected_singleton {x} : IsPreconnected ({x} : Set α) :=
isConnected_singleton.isPreconnected
theorem Set.Subsingleton.isPreconnected {s : Set α} (hs : s.Subsingleton) : IsPreconnected s :=
hs.induction_on isPreconnected_empty fun _ => isPreconnected_singleton
/-- If any point of a set is joined to a fixed point by a preconnected subset,
then the original set is preconnected as well. -/
theorem isPreconnected_of_forall {s : Set α} (x : α)
(H : ∀ y ∈ s, ∃ t, t ⊆ s ∧ x ∈ t ∧ y ∈ t ∧ IsPreconnected t) : IsPreconnected s := by
rintro u v hu hv hs ⟨z, zs, zu⟩ ⟨y, ys, yv⟩
have xs : x ∈ s := by
rcases H y ys with ⟨t, ts, xt, -, -⟩
exact ts xt
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: use `wlog xu : x ∈ u := hs xs using u v y z, v u z y`
cases hs xs with
| inl xu =>
rcases H y ys with ⟨t, ts, xt, yt, ht⟩
have := ht u v hu hv (ts.trans hs) ⟨x, xt, xu⟩ ⟨y, yt, yv⟩
exact this.imp fun z hz => ⟨ts hz.1, hz.2⟩
| inr xv =>
rcases H z zs with ⟨t, ts, xt, zt, ht⟩
have := ht v u hv hu (ts.trans <| by rwa [union_comm]) ⟨x, xt, xv⟩ ⟨z, zt, zu⟩
exact this.imp fun _ h => ⟨ts h.1, h.2.2, h.2.1⟩
/-- If any two points of a set are contained in a preconnected subset,
then the original set is preconnected as well. -/
theorem isPreconnected_of_forall_pair {s : Set α}
(H : ∀ x ∈ s, ∀ y ∈ s, ∃ t, t ⊆ s ∧ x ∈ t ∧ y ∈ t ∧ IsPreconnected t) :
IsPreconnected s := by
rcases eq_empty_or_nonempty s with (rfl | ⟨x, hx⟩)
exacts [isPreconnected_empty, isPreconnected_of_forall x fun y => H x hx y]
/-- A union of a family of preconnected sets with a common point is preconnected as well. -/
theorem isPreconnected_sUnion (x : α) (c : Set (Set α)) (H1 : ∀ s ∈ c, x ∈ s)
(H2 : ∀ s ∈ c, IsPreconnected s) : IsPreconnected (⋃₀ c) := by
apply isPreconnected_of_forall x
rintro y ⟨s, sc, ys⟩
exact ⟨s, subset_sUnion_of_mem sc, H1 s sc, ys, H2 s sc⟩
theorem isPreconnected_iUnion {ι : Sort*} {s : ι → Set α} (h₁ : (⋂ i, s i).Nonempty)
(h₂ : ∀ i, IsPreconnected (s i)) : IsPreconnected (⋃ i, s i) :=
Exists.elim h₁ fun f hf => isPreconnected_sUnion f _ hf (forall_mem_range.2 h₂)
theorem IsPreconnected.union (x : α) {s t : Set α} (H1 : x ∈ s) (H2 : x ∈ t) (H3 : IsPreconnected s)
(H4 : IsPreconnected t) : IsPreconnected (s ∪ t) :=
sUnion_pair s t ▸ isPreconnected_sUnion x {s, t} (by rintro r (rfl | rfl | h) <;> assumption)
(by rintro r (rfl | rfl | h) <;> assumption)
theorem IsPreconnected.union' {s t : Set α} (H : (s ∩ t).Nonempty) (hs : IsPreconnected s)
(ht : IsPreconnected t) : IsPreconnected (s ∪ t) := by
rcases H with ⟨x, hxs, hxt⟩
exact hs.union x hxs hxt ht
theorem IsConnected.union {s t : Set α} (H : (s ∩ t).Nonempty) (Hs : IsConnected s)
(Ht : IsConnected t) : IsConnected (s ∪ t) := by
rcases H with ⟨x, hx⟩
refine ⟨⟨x, mem_union_left t (mem_of_mem_inter_left hx)⟩, ?_⟩
exact Hs.isPreconnected.union x (mem_of_mem_inter_left hx) (mem_of_mem_inter_right hx)
Ht.isPreconnected
/-- The directed sUnion of a set S of preconnected subsets is preconnected. -/
theorem IsPreconnected.sUnion_directed {S : Set (Set α)} (K : DirectedOn (· ⊆ ·) S)
(H : ∀ s ∈ S, IsPreconnected s) : IsPreconnected (⋃₀ S) := by
rintro u v hu hv Huv ⟨a, ⟨s, hsS, has⟩, hau⟩ ⟨b, ⟨t, htS, hbt⟩, hbv⟩
obtain ⟨r, hrS, hsr, htr⟩ : ∃ r ∈ S, s ⊆ r ∧ t ⊆ r := K s hsS t htS
have Hnuv : (r ∩ (u ∩ v)).Nonempty :=
H _ hrS u v hu hv ((subset_sUnion_of_mem hrS).trans Huv) ⟨a, hsr has, hau⟩ ⟨b, htr hbt, hbv⟩
have Kruv : r ∩ (u ∩ v) ⊆ ⋃₀ S ∩ (u ∩ v) := inter_subset_inter_left _ (subset_sUnion_of_mem hrS)
exact Hnuv.mono Kruv
/-- The biUnion of a family of preconnected sets is preconnected if the graph determined by
whether two sets intersect is preconnected. -/
theorem IsPreconnected.biUnion_of_reflTransGen {ι : Type*} {t : Set ι} {s : ι → Set α}
(H : ∀ i ∈ t, IsPreconnected (s i))
(K : ∀ i, i ∈ t → ∀ j, j ∈ t → ReflTransGen (fun i j => (s i ∩ s j).Nonempty ∧ i ∈ t) i j) :
IsPreconnected (⋃ n ∈ t, s n) := by
let R := fun i j : ι => (s i ∩ s j).Nonempty ∧ i ∈ t
have P : ∀ i, i ∈ t → ∀ j, j ∈ t → ReflTransGen R i j →
∃ p, p ⊆ t ∧ i ∈ p ∧ j ∈ p ∧ IsPreconnected (⋃ j ∈ p, s j) := fun i hi j hj h => by
induction h with
| refl =>
refine ⟨{i}, singleton_subset_iff.mpr hi, mem_singleton i, mem_singleton i, ?_⟩
rw [biUnion_singleton]
exact H i hi
| @tail j k _ hjk ih =>
obtain ⟨p, hpt, hip, hjp, hp⟩ := ih hjk.2
refine ⟨insert k p, insert_subset_iff.mpr ⟨hj, hpt⟩, mem_insert_of_mem k hip,
mem_insert k p, ?_⟩
rw [biUnion_insert]
refine (H k hj).union' (hjk.1.mono ?_) hp
rw [inter_comm]
exact inter_subset_inter_right _ (subset_biUnion_of_mem hjp)
refine isPreconnected_of_forall_pair ?_
intro x hx y hy
obtain ⟨i : ι, hi : i ∈ t, hxi : x ∈ s i⟩ := mem_iUnion₂.1 hx
obtain ⟨j : ι, hj : j ∈ t, hyj : y ∈ s j⟩ := mem_iUnion₂.1 hy
obtain ⟨p, hpt, hip, hjp, hp⟩ := P i hi j hj (K i hi j hj)
exact ⟨⋃ j ∈ p, s j, biUnion_subset_biUnion_left hpt, mem_biUnion hip hxi,
mem_biUnion hjp hyj, hp⟩
/-- The biUnion of a family of preconnected sets is preconnected if the graph determined by
whether two sets intersect is preconnected. -/
theorem IsConnected.biUnion_of_reflTransGen {ι : Type*} {t : Set ι} {s : ι → Set α}
(ht : t.Nonempty) (H : ∀ i ∈ t, IsConnected (s i))
(K : ∀ i, i ∈ t → ∀ j, j ∈ t → ReflTransGen (fun i j : ι => (s i ∩ s j).Nonempty ∧ i ∈ t) i j) :
IsConnected (⋃ n ∈ t, s n) :=
⟨nonempty_biUnion.2 <| ⟨ht.some, ht.some_mem, (H _ ht.some_mem).nonempty⟩,
IsPreconnected.biUnion_of_reflTransGen (fun i hi => (H i hi).isPreconnected) K⟩
/-- Preconnectedness of the iUnion of a family of preconnected sets
indexed by the vertices of a preconnected graph,
where two vertices are joined when the corresponding sets intersect. -/
theorem IsPreconnected.iUnion_of_reflTransGen {ι : Type*} {s : ι → Set α}
(H : ∀ i, IsPreconnected (s i))
(K : ∀ i j, ReflTransGen (fun i j : ι => (s i ∩ s j).Nonempty) i j) :
IsPreconnected (⋃ n, s n) := by
rw [← biUnion_univ]
exact IsPreconnected.biUnion_of_reflTransGen (fun i _ => H i) fun i _ j _ => by
simpa [mem_univ] using K i j
theorem IsConnected.iUnion_of_reflTransGen {ι : Type*} [Nonempty ι] {s : ι → Set α}
(H : ∀ i, IsConnected (s i))
(K : ∀ i j, ReflTransGen (fun i j : ι => (s i ∩ s j).Nonempty) i j) : IsConnected (⋃ n, s n) :=
⟨nonempty_iUnion.2 <| Nonempty.elim ‹_› fun i : ι => ⟨i, (H _).nonempty⟩,
IsPreconnected.iUnion_of_reflTransGen (fun i => (H i).isPreconnected) K⟩
section SuccOrder
open Order
variable [LinearOrder β] [SuccOrder β] [IsSuccArchimedean β]
/-- The iUnion of connected sets indexed by a type with an archimedean successor (like `ℕ` or `ℤ`)
such that any two neighboring sets meet is preconnected. -/
theorem IsPreconnected.iUnion_of_chain {s : β → Set α} (H : ∀ n, IsPreconnected (s n))
(K : ∀ n, (s n ∩ s (succ n)).Nonempty) : IsPreconnected (⋃ n, s n) :=
IsPreconnected.iUnion_of_reflTransGen H fun _ _ =>
reflTransGen_of_succ _ (fun i _ => K i) fun i _ => by
rw [inter_comm]
exact K i
/-- The iUnion of connected sets indexed by a type with an archimedean successor (like `ℕ` or `ℤ`)
such that any two neighboring sets meet is connected. -/
theorem IsConnected.iUnion_of_chain [Nonempty β] {s : β → Set α} (H : ∀ n, IsConnected (s n))
(K : ∀ n, (s n ∩ s (succ n)).Nonempty) : IsConnected (⋃ n, s n) :=
IsConnected.iUnion_of_reflTransGen H fun _ _ =>
reflTransGen_of_succ _ (fun i _ => K i) fun i _ => by
rw [inter_comm]
exact K i
/-- The iUnion of preconnected sets indexed by a subset of a type with an archimedean successor
(like `ℕ` or `ℤ`) such that any two neighboring sets meet is preconnected. -/
theorem IsPreconnected.biUnion_of_chain {s : β → Set α} {t : Set β} (ht : OrdConnected t)
(H : ∀ n ∈ t, IsPreconnected (s n))
(K : ∀ n : β, n ∈ t → succ n ∈ t → (s n ∩ s (succ n)).Nonempty) :
IsPreconnected (⋃ n ∈ t, s n) := by
have h1 : ∀ {i j k : β}, i ∈ t → j ∈ t → k ∈ Ico i j → k ∈ t := fun hi hj hk =>
ht.out hi hj (Ico_subset_Icc_self hk)
have h2 : ∀ {i j k : β}, i ∈ t → j ∈ t → k ∈ Ico i j → succ k ∈ t := fun hi hj hk =>
ht.out hi hj ⟨hk.1.trans <| le_succ _, succ_le_of_lt hk.2⟩
have h3 : ∀ {i j k : β}, i ∈ t → j ∈ t → k ∈ Ico i j → (s k ∩ s (succ k)).Nonempty :=
fun hi hj hk => K _ (h1 hi hj hk) (h2 hi hj hk)
refine IsPreconnected.biUnion_of_reflTransGen H fun i hi j hj => ?_
exact reflTransGen_of_succ _ (fun k hk => ⟨h3 hi hj hk, h1 hi hj hk⟩) fun k hk =>
⟨by rw [inter_comm]; exact h3 hj hi hk, h2 hj hi hk⟩
/-- The iUnion of connected sets indexed by a subset of a type with an archimedean successor
(like `ℕ` or `ℤ`) such that any two neighboring sets meet is preconnected. -/
theorem IsConnected.biUnion_of_chain {s : β → Set α} {t : Set β} (hnt : t.Nonempty)
(ht : OrdConnected t) (H : ∀ n ∈ t, IsConnected (s n))
(K : ∀ n : β, n ∈ t → succ n ∈ t → (s n ∩ s (succ n)).Nonempty) : IsConnected (⋃ n ∈ t, s n) :=
⟨nonempty_biUnion.2 <| ⟨hnt.some, hnt.some_mem, (H _ hnt.some_mem).nonempty⟩,
IsPreconnected.biUnion_of_chain ht (fun i hi => (H i hi).isPreconnected) K⟩
end SuccOrder
/-- Theorem of bark and tree: if a set is within a preconnected set and its closure, then it is
preconnected as well. See also `IsConnected.subset_closure`. -/
protected theorem IsPreconnected.subset_closure {s : Set α} {t : Set α} (H : IsPreconnected s)
(Kst : s ⊆ t) (Ktcs : t ⊆ closure s) : IsPreconnected t :=
fun u v hu hv htuv ⟨_y, hyt, hyu⟩ ⟨_z, hzt, hzv⟩ =>
let ⟨p, hpu, hps⟩ := mem_closure_iff.1 (Ktcs hyt) u hu hyu
let ⟨q, hqv, hqs⟩ := mem_closure_iff.1 (Ktcs hzt) v hv hzv
let ⟨r, hrs, hruv⟩ := H u v hu hv (Subset.trans Kst htuv) ⟨p, hps, hpu⟩ ⟨q, hqs, hqv⟩
⟨r, Kst hrs, hruv⟩
/-- Theorem of bark and tree: if a set is within a connected set and its closure, then it is
connected as well. See also `IsPreconnected.subset_closure`. -/
protected theorem IsConnected.subset_closure {s : Set α} {t : Set α} (H : IsConnected s)
(Kst : s ⊆ t) (Ktcs : t ⊆ closure s) : IsConnected t :=
⟨Nonempty.mono Kst H.left, IsPreconnected.subset_closure H.right Kst Ktcs⟩
/-- The closure of a preconnected set is preconnected as well. -/
protected theorem IsPreconnected.closure {s : Set α} (H : IsPreconnected s) :
IsPreconnected (closure s) :=
IsPreconnected.subset_closure H subset_closure Subset.rfl
/-- The closure of a connected set is connected as well. -/
protected theorem IsConnected.closure {s : Set α} (H : IsConnected s) : IsConnected (closure s) :=
IsConnected.subset_closure H subset_closure <| Subset.rfl
/-- The image of a preconnected set is preconnected as well. -/
protected theorem IsPreconnected.image [TopologicalSpace β] {s : Set α} (H : IsPreconnected s)
(f : α → β) (hf : ContinuousOn f s) : IsPreconnected (f '' s) := by
-- Unfold/destruct definitions in hypotheses
rintro u v hu hv huv ⟨_, ⟨x, xs, rfl⟩, xu⟩ ⟨_, ⟨y, ys, rfl⟩, yv⟩
rcases continuousOn_iff'.1 hf u hu with ⟨u', hu', u'_eq⟩
rcases continuousOn_iff'.1 hf v hv with ⟨v', hv', v'_eq⟩
-- Reformulate `huv : f '' s ⊆ u ∪ v` in terms of `u'` and `v'`
replace huv : s ⊆ u' ∪ v' := by
rw [image_subset_iff, preimage_union] at huv
replace huv := subset_inter huv Subset.rfl
rw [union_inter_distrib_right, u'_eq, v'_eq, ← union_inter_distrib_right] at huv
exact (subset_inter_iff.1 huv).1
-- Now `s ⊆ u' ∪ v'`, so we can apply `‹IsPreconnected s›`
obtain ⟨z, hz⟩ : (s ∩ (u' ∩ v')).Nonempty := by
refine H u' v' hu' hv' huv ⟨x, ?_⟩ ⟨y, ?_⟩ <;> rw [inter_comm]
exacts [u'_eq ▸ ⟨xu, xs⟩, v'_eq ▸ ⟨yv, ys⟩]
rw [← inter_self s, inter_assoc, inter_left_comm s u', ← inter_assoc, inter_comm s, inter_comm s,
← u'_eq, ← v'_eq] at hz
exact ⟨f z, ⟨z, hz.1.2, rfl⟩, hz.1.1, hz.2.1⟩
/-- The image of a connected set is connected as well. -/
protected theorem IsConnected.image [TopologicalSpace β] {s : Set α} (H : IsConnected s) (f : α → β)
(hf : ContinuousOn f s) : IsConnected (f '' s) :=
⟨image_nonempty.mpr H.nonempty, H.isPreconnected.image f hf⟩
theorem isPreconnected_closed_iff {s : Set α} :
IsPreconnected s ↔ ∀ t t', IsClosed t → IsClosed t' →
s ⊆ t ∪ t' → (s ∩ t).Nonempty → (s ∩ t').Nonempty → (s ∩ (t ∩ t')).Nonempty :=
⟨by
rintro h t t' ht ht' htt' ⟨x, xs, xt⟩ ⟨y, ys, yt'⟩
rw [← not_disjoint_iff_nonempty_inter, ← subset_compl_iff_disjoint_right, compl_inter]
intro h'
have xt' : x ∉ t' := (h' xs).resolve_left (absurd xt)
have yt : y ∉ t := (h' ys).resolve_right (absurd yt')
have := h _ _ ht.isOpen_compl ht'.isOpen_compl h' ⟨y, ys, yt⟩ ⟨x, xs, xt'⟩
| rw [← compl_union] at this
exact this.ne_empty htt'.disjoint_compl_right.inter_eq,
by
rintro h u v hu hv huv ⟨x, xs, xu⟩ ⟨y, ys, yv⟩
rw [← not_disjoint_iff_nonempty_inter, ← subset_compl_iff_disjoint_right, compl_inter]
intro h'
have xv : x ∉ v := (h' xs).elim (absurd xu) id
have yu : y ∉ u := (h' ys).elim id (absurd yv)
have := h _ _ hu.isClosed_compl hv.isClosed_compl h' ⟨y, ys, yu⟩ ⟨x, xs, xv⟩
rw [← compl_union] at this
exact this.ne_empty huv.disjoint_compl_right.inter_eq⟩
theorem Topology.IsInducing.isPreconnected_image [TopologicalSpace β] {s : Set α} {f : α → β}
(hf : IsInducing f) : IsPreconnected (f '' s) ↔ IsPreconnected s := by
refine ⟨fun h => ?_, fun h => h.image _ hf.continuous.continuousOn⟩
rintro u v hu' hv' huv ⟨x, hxs, hxu⟩ ⟨y, hys, hyv⟩
rcases hf.isOpen_iff.1 hu' with ⟨u, hu, rfl⟩
rcases hf.isOpen_iff.1 hv' with ⟨v, hv, rfl⟩
replace huv : f '' s ⊆ u ∪ v := by rwa [image_subset_iff]
| Mathlib/Topology/Connected/Basic.lean | 311 | 329 |
/-
Copyright (c) 2015 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura, Jeremy Avigad, Mario Carneiro
-/
import Mathlib.Algebra.BigOperators.Ring.List
import Mathlib.Data.Nat.GCD.Basic
import Mathlib.Data.Nat.Prime.Basic
import Mathlib.Data.List.Prime
import Mathlib.Data.List.Sort
import Mathlib.Data.List.Perm.Subperm
/-!
# Prime numbers
This file deals with the factors of natural numbers.
## Important declarations
- `Nat.factors n`: the prime factorization of `n`
- `Nat.factors_unique`: uniqueness of the prime factorisation
-/
assert_not_exists Multiset
open Bool Subtype
open Nat
namespace Nat
/-- `primeFactorsList n` is the prime factorization of `n`, listed in increasing order. -/
def primeFactorsList : ℕ → List ℕ
| 0 => []
| 1 => []
| k + 2 =>
let m := minFac (k + 2)
m :: primeFactorsList ((k + 2) / m)
decreasing_by exact factors_lemma
@[simp]
theorem primeFactorsList_zero : primeFactorsList 0 = [] := by rw [primeFactorsList]
@[simp]
theorem primeFactorsList_one : primeFactorsList 1 = [] := by rw [primeFactorsList]
@[simp]
theorem primeFactorsList_two : primeFactorsList 2 = [2] := by simp [primeFactorsList]
theorem prime_of_mem_primeFactorsList {n : ℕ} : ∀ {p : ℕ}, p ∈ primeFactorsList n → Prime p := by
match n with
| 0 => simp
| 1 => simp
| k + 2 =>
intro p h
let m := minFac (k + 2)
have : (k + 2) / m < (k + 2) := factors_lemma
have h₁ : p = m ∨ p ∈ primeFactorsList ((k + 2) / m) :=
List.mem_cons.1 (by rwa [primeFactorsList] at h)
exact Or.casesOn h₁ (fun h₂ => h₂.symm ▸ minFac_prime (by simp)) prime_of_mem_primeFactorsList
theorem pos_of_mem_primeFactorsList {n p : ℕ} (h : p ∈ primeFactorsList n) : 0 < p :=
Prime.pos (prime_of_mem_primeFactorsList h)
theorem prod_primeFactorsList : ∀ {n}, n ≠ 0 → List.prod (primeFactorsList n) = n
| 0 => by simp
| 1 => by simp
| k + 2 => fun _ =>
let m := minFac (k + 2)
have : (k + 2) / m < (k + 2) := factors_lemma
| show (primeFactorsList (k + 2)).prod = (k + 2) by
have h₁ : (k + 2) / m ≠ 0 := fun h => by
have : (k + 2) = 0 * m := (Nat.div_eq_iff_eq_mul_left (minFac_pos _) (minFac_dvd _)).1 h
rw [zero_mul] at this; exact (show k + 2 ≠ 0 by simp) this
rw [primeFactorsList, List.prod_cons, prod_primeFactorsList h₁,
Nat.mul_div_cancel' (minFac_dvd _)]
theorem primeFactorsList_prime {p : ℕ} (hp : Nat.Prime p) : p.primeFactorsList = [p] := by
have : p = p - 2 + 2 := Nat.eq_add_of_sub_eq hp.two_le rfl
rw [this, primeFactorsList]
simp only [Eq.symm this]
| Mathlib/Data/Nat/Factors.lean | 72 | 82 |
/-
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.Algebra.Star.Basic
import Mathlib.Data.Set.Finite.Basic
import Mathlib.Data.Set.Lattice.Image
import Mathlib.Algebra.Group.Pointwise.Set.Basic
/-!
# Pointwise star operation on sets
This file defines the star operation pointwise on sets and provides the basic API.
Besides basic facts about how the star operation acts on sets (e.g., `(s ∩ t)⋆ = s⋆ ∩ t⋆`),
if `s t : Set α`, then under suitable assumption on `α`, it is shown
* `(s + t)⋆ = s⋆ + t⋆`
* `(s * t)⋆ = t⋆ + s⋆`
* `(s⁻¹)⋆ = (s⋆)⁻¹`
-/
namespace Set
open Pointwise
local postfix:max "⋆" => star
variable {α : Type*} {s t : Set α} {a : α}
/-- The set `(star s : Set α)` is defined as `{x | star x ∈ s}` in the locale `Pointwise`.
In the usual case where `star` is involutive, it is equal to `{star s | x ∈ s}`, see
`Set.image_star`. -/
protected def star [Star α] : Star (Set α) := ⟨preimage Star.star⟩
scoped[Pointwise] attribute [instance] Set.star
@[simp]
theorem star_empty [Star α] : (∅ : Set α)⋆ = ∅ := rfl
@[simp]
theorem star_univ [Star α] : (univ : Set α)⋆ = univ := rfl
@[simp]
theorem nonempty_star [InvolutiveStar α] {s : Set α} : s⋆.Nonempty ↔ s.Nonempty :=
star_involutive.surjective.nonempty_preimage
theorem Nonempty.star [InvolutiveStar α] {s : Set α} (h : s.Nonempty) : s⋆.Nonempty :=
nonempty_star.2 h
@[simp]
theorem mem_star [Star α] : a ∈ s⋆ ↔ a⋆ ∈ s := Iff.rfl
theorem star_mem_star [InvolutiveStar α] : a⋆ ∈ s⋆ ↔ a ∈ s := by simp only [mem_star, star_star]
@[simp]
theorem star_preimage [Star α] : Star.star ⁻¹' s = s⋆ := rfl
@[simp]
theorem image_star [InvolutiveStar α] : Star.star '' s = s⋆ := by
simp only [← star_preimage]
rw [image_eq_preimage_of_inverse] <;> intro <;> simp only [star_star]
@[simp]
theorem inter_star [Star α] : (s ∩ t)⋆ = s⋆ ∩ t⋆ := preimage_inter
@[simp]
theorem union_star [Star α] : (s ∪ t)⋆ = s⋆ ∪ t⋆ := preimage_union
@[simp]
theorem iInter_star {ι : Sort*} [Star α] (s : ι → Set α) : (⋂ i, s i)⋆ = ⋂ i, (s i)⋆ :=
preimage_iInter
@[simp]
theorem iUnion_star {ι : Sort*} [Star α] (s : ι → Set α) : (⋃ i, s i)⋆ = ⋃ i, (s i)⋆ :=
preimage_iUnion
@[simp]
theorem compl_star [Star α] : sᶜ⋆ = s⋆ᶜ := preimage_compl
@[simp]
instance [InvolutiveStar α] : InvolutiveStar (Set α) where
star := Star.star
star_involutive s := by simp only [← star_preimage, preimage_preimage, star_star, preimage_id']
@[simp]
theorem star_subset_star [InvolutiveStar α] {s t : Set α} : s⋆ ⊆ t⋆ ↔ s ⊆ t :=
Equiv.star.surjective.preimage_subset_preimage_iff
theorem star_subset [InvolutiveStar α] {s t : Set α} : s⋆ ⊆ t ↔ s ⊆ t⋆ := by
rw [← star_subset_star, star_star]
theorem Finite.star [InvolutiveStar α] {s : Set α} (hs : s.Finite) : s⋆.Finite :=
hs.preimage star_injective.injOn
theorem star_singleton {β : Type*} [InvolutiveStar β] (x : β) : ({x} : Set β)⋆ = {x⋆} := by
ext1 y
rw [mem_star, mem_singleton_iff, mem_singleton_iff, star_eq_iff_star_eq, eq_comm]
protected theorem star_mul [Mul α] [StarMul α] (s t : Set α) : (s * t)⋆ = t⋆ * s⋆ := by
simp_rw [← image_star, ← image2_mul, image_image2, image2_image_left, image2_image_right,
star_mul, image2_swap _ s t]
protected theorem star_add [AddMonoid α] [StarAddMonoid α] (s t : Set α) : (s + t)⋆ = s⋆ + t⋆ := by
simp_rw [← image_star, ← image2_add, image_image2, image2_image_left, image2_image_right,
star_add]
@[simp]
instance [Star α] [TrivialStar α] : TrivialStar (Set α) where
star_trivial s := by
rw [← star_preimage]
ext1
simp [star_trivial]
protected theorem star_inv [Group α] [StarMul α] (s : Set α) : s⁻¹⋆ = s⋆⁻¹ := by
ext
simp only [mem_star, mem_inv, star_inv]
protected theorem star_inv' [GroupWithZero α] [StarMul α] (s : Set α) : s⁻¹⋆ = s⋆⁻¹ := by
ext
simp only [mem_star, mem_inv, star_inv₀]
end Set
|
@[simp]
lemma StarMemClass.star_coe_eq {S α : Type*} [InvolutiveStar α] [SetLike S α]
| Mathlib/Algebra/Star/Pointwise.lean | 125 | 127 |
/-
Copyright (c) 2017 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Tim Baumann, Stephen Morgan, Kim Morrison, Floris van Doorn
-/
import Mathlib.Tactic.CategoryTheory.Reassoc
/-!
# Isomorphisms
This file defines isomorphisms between objects of a category.
## Main definitions
- `structure Iso` : a bundled isomorphism between two objects of a category;
- `class IsIso` : an unbundled version of `iso`;
note that `IsIso f` is a `Prop`, and only asserts the existence of an inverse.
Of course, this inverse is unique, so it doesn't cost us much to use choice to retrieve it.
- `inv f`, for the inverse of a morphism with `[IsIso f]`
- `asIso` : convert from `IsIso` to `Iso` (noncomputable);
- `of_iso` : convert from `Iso` to `IsIso`;
- standard operations on isomorphisms (composition, inverse etc)
## Notations
- `X ≅ Y` : same as `Iso X Y`;
- `α ≪≫ β` : composition of two isomorphisms; it is called `Iso.trans`
## Tags
category, category theory, isomorphism
-/
universe v u
-- morphism levels before object levels. See note [CategoryTheory universes].
namespace CategoryTheory
open Category
/-- An isomorphism (a.k.a. an invertible morphism) between two objects of a category.
The inverse morphism is bundled.
See also `CategoryTheory.Core` for the category with the same objects and isomorphisms playing
the role of morphisms. -/
@[stacks 0017]
structure Iso {C : Type u} [Category.{v} C] (X Y : C) where
/-- The forward direction of an isomorphism. -/
hom : X ⟶ Y
/-- The backwards direction of an isomorphism. -/
inv : Y ⟶ X
/-- Composition of the two directions of an isomorphism is the identity on the source. -/
hom_inv_id : hom ≫ inv = 𝟙 X := by aesop_cat
/-- Composition of the two directions of an isomorphism in reverse order
is the identity on the target. -/
inv_hom_id : inv ≫ hom = 𝟙 Y := by aesop_cat
attribute [reassoc (attr := simp)] Iso.hom_inv_id Iso.inv_hom_id
/-- Notation for an isomorphism in a category. -/
infixr:10 " ≅ " => Iso -- type as \cong or \iso
variable {C : Type u} [Category.{v} C] {X Y Z : C}
namespace Iso
@[ext]
theorem ext ⦃α β : X ≅ Y⦄ (w : α.hom = β.hom) : α = β :=
suffices α.inv = β.inv by
cases α
cases β
cases w
cases this
rfl
calc
α.inv = α.inv ≫ β.hom ≫ β.inv := by rw [Iso.hom_inv_id, Category.comp_id]
_ = (α.inv ≫ α.hom) ≫ β.inv := by rw [Category.assoc, ← w]
_ = β.inv := by rw [Iso.inv_hom_id, Category.id_comp]
/-- Inverse isomorphism. -/
@[symm]
def symm (I : X ≅ Y) : Y ≅ X where
hom := I.inv
inv := I.hom
@[simp]
theorem symm_hom (α : X ≅ Y) : α.symm.hom = α.inv :=
rfl
@[simp]
theorem symm_inv (α : X ≅ Y) : α.symm.inv = α.hom :=
rfl
@[simp]
theorem symm_mk {X Y : C} (hom : X ⟶ Y) (inv : Y ⟶ X) (hom_inv_id) (inv_hom_id) :
Iso.symm { hom, inv, hom_inv_id := hom_inv_id, inv_hom_id := inv_hom_id } =
{ hom := inv, inv := hom, hom_inv_id := inv_hom_id, inv_hom_id := hom_inv_id } :=
rfl
@[simp]
theorem symm_symm_eq {X Y : C} (α : X ≅ Y) : α.symm.symm = α := rfl
theorem symm_bijective {X Y : C} : Function.Bijective (symm : (X ≅ Y) → _) :=
Function.bijective_iff_has_inverse.mpr ⟨_, symm_symm_eq, symm_symm_eq⟩
@[simp]
theorem symm_eq_iff {X Y : C} {α β : X ≅ Y} : α.symm = β.symm ↔ α = β :=
symm_bijective.injective.eq_iff
theorem nonempty_iso_symm (X Y : C) : Nonempty (X ≅ Y) ↔ Nonempty (Y ≅ X) :=
⟨fun h => ⟨h.some.symm⟩, fun h => ⟨h.some.symm⟩⟩
/-- Identity isomorphism. -/
@[refl, simps]
def refl (X : C) : X ≅ X where
hom := 𝟙 X
inv := 𝟙 X
instance : Inhabited (X ≅ X) := ⟨Iso.refl X⟩
theorem nonempty_iso_refl (X : C) : Nonempty (X ≅ X) := ⟨default⟩
@[simp]
theorem refl_symm (X : C) : (Iso.refl X).symm = Iso.refl X := rfl
/-- Composition of two isomorphisms -/
@[simps]
def trans (α : X ≅ Y) (β : Y ≅ Z) : X ≅ Z where
hom := α.hom ≫ β.hom
inv := β.inv ≫ α.inv
@[simps]
instance instTransIso : Trans (α := C) (· ≅ ·) (· ≅ ·) (· ≅ ·) where
trans := trans
/-- Notation for composition of isomorphisms. -/
infixr:80 " ≪≫ " => Iso.trans -- type as `\ll \gg`.
@[simp]
theorem trans_mk {X Y Z : C} (hom : X ⟶ Y) (inv : Y ⟶ X) (hom_inv_id) (inv_hom_id)
(hom' : Y ⟶ Z) (inv' : Z ⟶ Y) (hom_inv_id') (inv_hom_id') (hom_inv_id'') (inv_hom_id'') :
Iso.trans ⟨hom, inv, hom_inv_id, inv_hom_id⟩ ⟨hom', inv', hom_inv_id', inv_hom_id'⟩ =
⟨hom ≫ hom', inv' ≫ inv, hom_inv_id'', inv_hom_id''⟩ :=
rfl
@[simp]
theorem trans_symm (α : X ≅ Y) (β : Y ≅ Z) : (α ≪≫ β).symm = β.symm ≪≫ α.symm :=
rfl
@[simp]
theorem trans_assoc {Z' : C} (α : X ≅ Y) (β : Y ≅ Z) (γ : Z ≅ Z') :
(α ≪≫ β) ≪≫ γ = α ≪≫ β ≪≫ γ := by
ext; simp only [trans_hom, Category.assoc]
@[simp]
theorem refl_trans (α : X ≅ Y) : Iso.refl X ≪≫ α = α := by ext; apply Category.id_comp
@[simp]
theorem trans_refl (α : X ≅ Y) : α ≪≫ Iso.refl Y = α := by ext; apply Category.comp_id
@[simp]
theorem symm_self_id (α : X ≅ Y) : α.symm ≪≫ α = Iso.refl Y :=
ext α.inv_hom_id
@[simp]
theorem self_symm_id (α : X ≅ Y) : α ≪≫ α.symm = Iso.refl X :=
ext α.hom_inv_id
@[simp]
theorem symm_self_id_assoc (α : X ≅ Y) (β : Y ≅ Z) : α.symm ≪≫ α ≪≫ β = β := by
rw [← trans_assoc, symm_self_id, refl_trans]
@[simp]
theorem self_symm_id_assoc (α : X ≅ Y) (β : X ≅ Z) : α ≪≫ α.symm ≪≫ β = β := by
rw [← trans_assoc, self_symm_id, refl_trans]
theorem inv_comp_eq (α : X ≅ Y) {f : X ⟶ Z} {g : Y ⟶ Z} : α.inv ≫ f = g ↔ f = α.hom ≫ g :=
⟨fun H => by simp [H.symm], fun H => by simp [H]⟩
theorem eq_inv_comp (α : X ≅ Y) {f : X ⟶ Z} {g : Y ⟶ Z} : g = α.inv ≫ f ↔ α.hom ≫ g = f :=
(inv_comp_eq α.symm).symm
theorem comp_inv_eq (α : X ≅ Y) {f : Z ⟶ Y} {g : Z ⟶ X} : f ≫ α.inv = g ↔ f = g ≫ α.hom :=
⟨fun H => by simp [H.symm], fun H => by simp [H]⟩
theorem eq_comp_inv (α : X ≅ Y) {f : Z ⟶ Y} {g : Z ⟶ X} : g = f ≫ α.inv ↔ g ≫ α.hom = f :=
(comp_inv_eq α.symm).symm
theorem inv_eq_inv (f g : X ≅ Y) : f.inv = g.inv ↔ f.hom = g.hom :=
have : ∀ {X Y : C} (f g : X ≅ Y), f.hom = g.hom → f.inv = g.inv := fun f g h => by rw [ext h]
⟨this f.symm g.symm, this f g⟩
theorem hom_comp_eq_id (α : X ≅ Y) {f : Y ⟶ X} : α.hom ≫ f = 𝟙 X ↔ f = α.inv := by
rw [← eq_inv_comp, comp_id]
theorem comp_hom_eq_id (α : X ≅ Y) {f : Y ⟶ X} : f ≫ α.hom = 𝟙 Y ↔ f = α.inv := by
rw [← eq_comp_inv, id_comp]
theorem inv_comp_eq_id (α : X ≅ Y) {f : X ⟶ Y} : α.inv ≫ f = 𝟙 Y ↔ f = α.hom :=
hom_comp_eq_id α.symm
theorem comp_inv_eq_id (α : X ≅ Y) {f : X ⟶ Y} : f ≫ α.inv = 𝟙 X ↔ f = α.hom :=
comp_hom_eq_id α.symm
theorem hom_eq_inv (α : X ≅ Y) (β : Y ≅ X) : α.hom = β.inv ↔ β.hom = α.inv := by
rw [← symm_inv, inv_eq_inv α.symm β, eq_comm]
rfl
/-- The bijection `(Z ⟶ X) ≃ (Z ⟶ Y)` induced by `α : X ≅ Y`. -/
@[simps]
def homToEquiv (α : X ≅ Y) {Z : C} : (Z ⟶ X) ≃ (Z ⟶ Y) where
toFun f := f ≫ α.hom
invFun g := g ≫ α.inv
left_inv := by aesop_cat
right_inv := by aesop_cat
/-- The bijection `(X ⟶ Z) ≃ (Y ⟶ Z)` induced by `α : X ≅ Y`. -/
@[simps]
def homFromEquiv (α : X ≅ Y) {Z : C} : (X ⟶ Z) ≃ (Y ⟶ Z) where
toFun f := α.inv ≫ f
invFun g := α.hom ≫ g
left_inv := by aesop_cat
right_inv := by aesop_cat
end Iso
/-- `IsIso` typeclass expressing that a morphism is invertible. -/
class IsIso (f : X ⟶ Y) : Prop where
/-- The existence of an inverse morphism. -/
out : ∃ inv : Y ⟶ X, f ≫ inv = 𝟙 X ∧ inv ≫ f = 𝟙 Y
/-- The inverse of a morphism `f` when we have `[IsIso f]`.
-/
noncomputable def inv (f : X ⟶ Y) [I : IsIso f] : Y ⟶ X :=
Classical.choose I.1
namespace IsIso
@[simp]
theorem hom_inv_id (f : X ⟶ Y) [I : IsIso f] : f ≫ inv f = 𝟙 X :=
(Classical.choose_spec I.1).left
@[simp]
theorem inv_hom_id (f : X ⟶ Y) [I : IsIso f] : inv f ≫ f = 𝟙 Y :=
(Classical.choose_spec I.1).right
-- FIXME putting @[reassoc] on the `hom_inv_id` above somehow unfolds `inv`
-- This happens even if we make `inv` irreducible!
-- I don't understand how this is happening: it is likely a bug.
-- attribute [reassoc] hom_inv_id inv_hom_id
-- #print hom_inv_id_assoc
-- theorem CategoryTheory.IsIso.hom_inv_id_assoc {X Y : C} (f : X ⟶ Y) [I : IsIso f]
-- {Z : C} (h : X ⟶ Z),
-- f ≫ Classical.choose (_ : Exists fun inv ↦ f ≫ inv = 𝟙 X ∧ inv ≫ f = 𝟙 Y) ≫ h = h := ...
@[simp]
theorem hom_inv_id_assoc (f : X ⟶ Y) [I : IsIso f] {Z} (g : X ⟶ Z) : f ≫ inv f ≫ g = g := by
simp [← Category.assoc]
@[simp]
theorem inv_hom_id_assoc (f : X ⟶ Y) [I : IsIso f] {Z} (g : Y ⟶ Z) : inv f ≫ f ≫ g = g := by
simp [← Category.assoc]
end IsIso
lemma Iso.isIso_hom (e : X ≅ Y) : IsIso e.hom :=
⟨e.inv, by simp, by simp⟩
lemma Iso.isIso_inv (e : X ≅ Y) : IsIso e.inv := e.symm.isIso_hom
attribute [instance] Iso.isIso_hom Iso.isIso_inv
open IsIso
/-- Reinterpret a morphism `f` with an `IsIso f` instance as an `Iso`. -/
noncomputable def asIso (f : X ⟶ Y) [IsIso f] : X ≅ Y :=
⟨f, inv f, hom_inv_id f, inv_hom_id f⟩
-- Porting note: the `IsIso f` argument had been instance implicit,
-- but we've changed it to implicit as a `rw` in `Mathlib.CategoryTheory.Closed.Functor`
-- was failing to generate it by typeclass search.
@[simp]
theorem asIso_hom (f : X ⟶ Y) {_ : IsIso f} : (asIso f).hom = f :=
rfl
-- Porting note: the `IsIso f` argument had been instance implicit,
-- but we've changed it to implicit as a `rw` in `Mathlib.CategoryTheory.Closed.Functor`
-- was failing to generate it by typeclass search.
@[simp]
theorem asIso_inv (f : X ⟶ Y) {_ : IsIso f} : (asIso f).inv = inv f :=
rfl
namespace IsIso
-- see Note [lower instance priority]
instance (priority := 100) epi_of_iso (f : X ⟶ Y) [IsIso f] : Epi f where
left_cancellation g h w := by
rw [← IsIso.inv_hom_id_assoc f g, w, IsIso.inv_hom_id_assoc f h]
-- see Note [lower instance priority]
instance (priority := 100) mono_of_iso (f : X ⟶ Y) [IsIso f] : Mono f where
right_cancellation g h w := by
rw [← Category.comp_id g, ← Category.comp_id h, ← IsIso.hom_inv_id f,
← Category.assoc, w, ← Category.assoc]
@[aesop apply safe (rule_sets := [CategoryTheory])]
theorem inv_eq_of_hom_inv_id {f : X ⟶ Y} [IsIso f] {g : Y ⟶ X} (hom_inv_id : f ≫ g = 𝟙 X) :
inv f = g := by
apply (cancel_epi f).mp
simp [hom_inv_id]
theorem inv_eq_of_inv_hom_id {f : X ⟶ Y} [IsIso f] {g : Y ⟶ X} (inv_hom_id : g ≫ f = 𝟙 Y) :
inv f = g := by
apply (cancel_mono f).mp
simp [inv_hom_id]
|
@[aesop apply safe (rule_sets := [CategoryTheory])]
| Mathlib/CategoryTheory/Iso.lean | 317 | 318 |
/-
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]
theorem encard_lt_encard_iff_encard_diff_lt_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_lt_add_iff_right h.encard_lt_top.ne]
theorem encard_union_le (s t : Set α) : (s ∪ t).encard ≤ s.encard + t.encard := by
rw [← encard_union_add_encard_inter]; exact le_self_add
theorem finite_iff_finite_of_encard_eq_encard (h : s.encard = t.encard) : s.Finite ↔ t.Finite := by
rw [← encard_lt_top_iff, ← encard_lt_top_iff, h]
theorem infinite_iff_infinite_of_encard_eq_encard (h : s.encard = t.encard) :
s.Infinite ↔ t.Infinite := by rw [← encard_eq_top_iff, h, encard_eq_top_iff]
theorem Finite.finite_of_encard_le {s : Set α} {t : Set β} (hs : s.Finite)
(h : t.encard ≤ s.encard) : t.Finite :=
encard_lt_top_iff.1 (h.trans_lt hs.encard_lt_top)
lemma Finite.eq_of_subset_of_encard_le' (ht : t.Finite) (hst : s ⊆ t) (hts : t.encard ≤ s.encard) :
s = t := by
rw [← zero_add (a := encard s), ← encard_diff_add_encard_of_subset hst] at hts
have hdiff := WithTop.le_of_add_le_add_right (ht.subset hst).encard_lt_top.ne hts
rw [nonpos_iff_eq_zero, encard_eq_zero, diff_eq_empty] at hdiff
exact hst.antisymm hdiff
theorem Finite.eq_of_subset_of_encard_le (hs : s.Finite) (hst : s ⊆ t)
(hts : t.encard ≤ s.encard) : s = t :=
(hs.finite_of_encard_le hts).eq_of_subset_of_encard_le' hst hts
theorem Finite.encard_lt_encard (hs : s.Finite) (h : s ⊂ t) : s.encard < t.encard :=
(encard_mono h.subset).lt_of_ne fun he ↦ h.ne (hs.eq_of_subset_of_encard_le h.subset he.symm.le)
theorem encard_strictMono [Finite α] : StrictMono (encard : Set α → ℕ∞) :=
fun _ _ h ↦ (toFinite _).encard_lt_encard h
theorem encard_diff_add_encard (s t : Set α) : (s \ t).encard + t.encard = (s ∪ t).encard := by
rw [← encard_union_eq disjoint_sdiff_left, diff_union_self]
theorem encard_le_encard_diff_add_encard (s t : Set α) : s.encard ≤ (s \ t).encard + t.encard :=
(encard_mono subset_union_left).trans_eq (encard_diff_add_encard _ _).symm
theorem tsub_encard_le_encard_diff (s t : Set α) : s.encard - t.encard ≤ (s \ t).encard := by
rw [tsub_le_iff_left, add_comm]; apply encard_le_encard_diff_add_encard
theorem encard_add_encard_compl (s : Set α) : s.encard + sᶜ.encard = (univ : Set α).encard := by
rw [← encard_union_eq disjoint_compl_right, union_compl_self]
end Lattice
section InsertErase
variable {a b : α}
theorem encard_insert_le (s : Set α) (x : α) : (insert x s).encard ≤ s.encard + 1 := by
rw [← union_singleton, ← encard_singleton x]; apply encard_union_le
theorem encard_singleton_inter (s : Set α) (x : α) : ({x} ∩ s).encard ≤ 1 := by
rw [← encard_singleton x]; exact encard_le_encard inter_subset_left
theorem encard_diff_singleton_add_one (h : a ∈ s) :
(s \ {a}).encard + 1 = s.encard := by
rw [← encard_insert_of_not_mem (fun h ↦ h.2 rfl), insert_diff_singleton, insert_eq_of_mem h]
theorem encard_diff_singleton_of_mem (h : a ∈ s) :
(s \ {a}).encard = s.encard - 1 := by
rw [← encard_diff_singleton_add_one h, ← WithTop.add_right_inj WithTop.one_ne_top,
tsub_add_cancel_of_le (self_le_add_left _ _)]
theorem encard_tsub_one_le_encard_diff_singleton (s : Set α) (x : α) :
s.encard - 1 ≤ (s \ {x}).encard := by
rw [← encard_singleton x]; apply tsub_encard_le_encard_diff
theorem encard_exchange (ha : a ∉ s) (hb : b ∈ s) : (insert a (s \ {b})).encard = s.encard := by
rw [encard_insert_of_not_mem, encard_diff_singleton_add_one hb]
simp_all only [not_true, mem_diff, mem_singleton_iff, false_and, not_false_eq_true]
theorem encard_exchange' (ha : a ∉ s) (hb : b ∈ s) : (insert a s \ {b}).encard = s.encard := by
rw [← insert_diff_singleton_comm (by rintro rfl; exact ha hb), encard_exchange ha hb]
theorem encard_eq_add_one_iff {k : ℕ∞} :
s.encard = k + 1 ↔ (∃ a t, ¬a ∈ t ∧ insert a t = s ∧ t.encard = k) := by
refine ⟨fun h ↦ ?_, ?_⟩
· obtain ⟨a, ha⟩ := nonempty_of_encard_ne_zero (s := s) (by simp [h])
refine ⟨a, s \ {a}, fun h ↦ h.2 rfl, by rwa [insert_diff_singleton, insert_eq_of_mem], ?_⟩
rw [← WithTop.add_right_inj WithTop.one_ne_top, ← h,
encard_diff_singleton_add_one ha]
rintro ⟨a, t, h, rfl, rfl⟩
rw [encard_insert_of_not_mem h]
/-- Every set is either empty, infinite, or can have its `encard` reduced by a removal. Intended
for well-founded induction on the value of `encard`. -/
theorem eq_empty_or_encard_eq_top_or_encard_diff_singleton_lt (s : Set α) :
s = ∅ ∨ s.encard = ⊤ ∨ ∃ a ∈ s, (s \ {a}).encard < s.encard := by
refine s.eq_empty_or_nonempty.elim Or.inl (Or.inr ∘ fun ⟨a,ha⟩ ↦
(s.finite_or_infinite.elim (fun hfin ↦ Or.inr ⟨a, ha, ?_⟩) (Or.inl ∘ Infinite.encard_eq)))
rw [← encard_diff_singleton_add_one ha]; nth_rw 1 [← add_zero (encard _)]
exact WithTop.add_lt_add_left hfin.diff.encard_lt_top.ne zero_lt_one
end InsertErase
section SmallSets
theorem encard_pair {x y : α} (hne : x ≠ y) : ({x, y} : Set α).encard = 2 := by
rw [encard_insert_of_not_mem (by simpa), ← one_add_one_eq_two,
WithTop.add_right_inj WithTop.one_ne_top, encard_singleton]
theorem encard_eq_one : s.encard = 1 ↔ ∃ x, s = {x} := by
refine ⟨fun h ↦ ?_, fun ⟨x, hx⟩ ↦ by rw [hx, encard_singleton]⟩
obtain ⟨x, hx⟩ := nonempty_of_encard_ne_zero (s := s) (by rw [h]; simp)
exact ⟨x, ((finite_singleton x).eq_of_subset_of_encard_le (by simpa) (by simp [h])).symm⟩
theorem encard_le_one_iff_eq : s.encard ≤ 1 ↔ s = ∅ ∨ ∃ x, s = {x} := by
rw [le_iff_lt_or_eq, lt_iff_not_le, ENat.one_le_iff_ne_zero, not_not, encard_eq_zero,
encard_eq_one]
theorem encard_le_one_iff : s.encard ≤ 1 ↔ ∀ a b, a ∈ s → b ∈ s → a = b := by
rw [encard_le_one_iff_eq, or_iff_not_imp_left, ← Ne, ← nonempty_iff_ne_empty]
refine ⟨fun h a b has hbs ↦ ?_,
fun h ⟨x, hx⟩ ↦ ⟨x, ((singleton_subset_iff.2 hx).antisymm' (fun y hy ↦ h _ _ hy hx))⟩⟩
obtain ⟨x, rfl⟩ := h ⟨_, has⟩
rw [(has : a = x), (hbs : b = x)]
theorem encard_le_one_iff_subsingleton : s.encard ≤ 1 ↔ s.Subsingleton := by
rw [encard_le_one_iff, Set.Subsingleton]
tauto
theorem one_lt_encard_iff_nontrivial : 1 < s.encard ↔ s.Nontrivial := by
rw [← not_iff_not, not_lt, Set.not_nontrivial_iff, ← encard_le_one_iff_subsingleton]
theorem one_lt_encard_iff : 1 < s.encard ↔ ∃ a b, a ∈ s ∧ b ∈ s ∧ a ≠ b := by
rw [← not_iff_not, not_exists, not_lt, encard_le_one_iff]; aesop
theorem exists_ne_of_one_lt_encard (h : 1 < s.encard) (a : α) : ∃ b ∈ s, b ≠ a := by
by_contra! h'
obtain ⟨b, b', hb, hb', hne⟩ := one_lt_encard_iff.1 h
apply hne
rw [h' b hb, h' b' hb']
theorem encard_eq_two : s.encard = 2 ↔ ∃ x y, x ≠ y ∧ s = {x, y} := by
refine ⟨fun h ↦ ?_, fun ⟨x, y, hne, hs⟩ ↦ by rw [hs, encard_pair hne]⟩
obtain ⟨x, hx⟩ := nonempty_of_encard_ne_zero (s := s) (by rw [h]; simp)
rw [← insert_eq_of_mem hx, ← insert_diff_singleton, encard_insert_of_not_mem (fun h ↦ h.2 rfl),
← one_add_one_eq_two, WithTop.add_right_inj (WithTop.one_ne_top), encard_eq_one] at h
obtain ⟨y, h⟩ := h
refine ⟨x, y, by rintro rfl; exact (h.symm.subset rfl).2 rfl, ?_⟩
rw [← h, insert_diff_singleton, insert_eq_of_mem hx]
theorem encard_eq_three {α : Type u_1} {s : Set α} :
encard s = 3 ↔ ∃ x y z, x ≠ y ∧ x ≠ z ∧ y ≠ z ∧ s = {x, y, z} := by
refine ⟨fun h ↦ ?_, fun ⟨x, y, z, hxy, hyz, hxz, hs⟩ ↦ ?_⟩
· obtain ⟨x, hx⟩ := nonempty_of_encard_ne_zero (s := s) (by rw [h]; simp)
rw [← insert_eq_of_mem hx, ← insert_diff_singleton,
encard_insert_of_not_mem (fun h ↦ h.2 rfl), (by exact rfl : (3 : ℕ∞) = 2 + 1),
WithTop.add_right_inj WithTop.one_ne_top, encard_eq_two] at h
obtain ⟨y, z, hne, hs⟩ := h
refine ⟨x, y, z, ?_, ?_, hne, ?_⟩
· rintro rfl; exact (hs.symm.subset (Or.inl rfl)).2 rfl
· rintro rfl; exact (hs.symm.subset (Or.inr rfl)).2 rfl
rw [← hs, insert_diff_singleton, insert_eq_of_mem hx]
rw [hs, encard_insert_of_not_mem, encard_insert_of_not_mem, encard_singleton] <;> aesop
theorem Nat.encard_range (k : ℕ) : {i | i < k}.encard = k := by
convert encard_coe_eq_coe_finsetCard (Finset.range k) using 1
· rw [Finset.coe_range, Iio_def]
rw [Finset.card_range]
end SmallSets
theorem Finite.eq_insert_of_subset_of_encard_eq_succ (hs : s.Finite) (h : s ⊆ t)
(hst : t.encard = s.encard + 1) : ∃ a, t = insert a s := by
rw [← encard_diff_add_encard_of_subset h, add_comm, WithTop.add_left_inj hs.encard_lt_top.ne,
encard_eq_one] at hst
obtain ⟨x, hx⟩ := hst; use x; rw [← diff_union_of_subset h, hx, singleton_union]
theorem exists_subset_encard_eq {k : ℕ∞} (hk : k ≤ s.encard) : ∃ t, t ⊆ s ∧ t.encard = k := by
revert hk
refine ENat.nat_induction k (fun _ ↦ ⟨∅, empty_subset _, by simp⟩) (fun n IH hle ↦ ?_) ?_
· obtain ⟨t₀, ht₀s, ht₀⟩ := IH (le_trans (by simp) hle)
simp only [Nat.cast_succ] at *
have hne : t₀ ≠ s := by
rintro rfl; rw [ht₀, ← Nat.cast_one, ← Nat.cast_add, Nat.cast_le] at hle; simp at hle
obtain ⟨x, hx⟩ := exists_of_ssubset (ht₀s.ssubset_of_ne hne)
exact ⟨insert x t₀, insert_subset hx.1 ht₀s, by rw [encard_insert_of_not_mem hx.2, ht₀]⟩
simp only [top_le_iff, encard_eq_top_iff]
exact fun _ hi ↦ ⟨s, Subset.rfl, hi⟩
theorem exists_superset_subset_encard_eq {k : ℕ∞}
(hst : s ⊆ t) (hsk : s.encard ≤ k) (hkt : k ≤ t.encard) :
∃ r, s ⊆ r ∧ r ⊆ t ∧ r.encard = k := by
obtain (hs | hs) := eq_or_ne s.encard ⊤
· rw [hs, top_le_iff] at hsk; subst hsk; exact ⟨s, Subset.rfl, hst, hs⟩
obtain ⟨k, rfl⟩ := exists_add_of_le hsk
obtain ⟨k', hk'⟩ := exists_add_of_le hkt
have hk : k ≤ encard (t \ s) := by
rw [← encard_diff_add_encard_of_subset hst, add_comm] at hkt
exact WithTop.le_of_add_le_add_right hs hkt
obtain ⟨r', hr', rfl⟩ := exists_subset_encard_eq hk
refine ⟨s ∪ r', subset_union_left, union_subset hst (hr'.trans diff_subset), ?_⟩
rw [encard_union_eq (disjoint_of_subset_right hr' disjoint_sdiff_right)]
section Function
variable {s : Set α} {t : Set β} {f : α → β}
theorem InjOn.encard_image (h : InjOn f s) : (f '' s).encard = s.encard := by
rw [encard, ENat.card_image_of_injOn h, encard]
theorem encard_congr (e : s ≃ t) : s.encard = t.encard := by
rw [← encard_univ_coe, ← encard_univ_coe t, encard_univ, encard_univ, ENat.card_congr e]
theorem _root_.Function.Injective.encard_image (hf : f.Injective) (s : Set α) :
(f '' s).encard = s.encard :=
hf.injOn.encard_image
theorem _root_.Function.Embedding.encard_le (e : s ↪ t) : s.encard ≤ t.encard := by
rw [← encard_univ_coe, ← e.injective.encard_image, ← Subtype.coe_injective.encard_image]
exact encard_mono (by simp)
theorem encard_image_le (f : α → β) (s : Set α) : (f '' s).encard ≤ s.encard := by
obtain (h | h) := isEmpty_or_nonempty α
· rw [s.eq_empty_of_isEmpty]; simp
rw [← (f.invFunOn_injOn_image s).encard_image]
apply encard_le_encard
exact f.invFunOn_image_image_subset s
theorem Finite.injOn_of_encard_image_eq (hs : s.Finite) (h : (f '' s).encard = s.encard) :
InjOn f s := by
obtain (h' | hne) := isEmpty_or_nonempty α
· rw [s.eq_empty_of_isEmpty]; simp
rw [← (f.invFunOn_injOn_image s).encard_image] at h
rw [injOn_iff_invFunOn_image_image_eq_self]
exact hs.eq_of_subset_of_encard_le' (f.invFunOn_image_image_subset s) h.symm.le
theorem encard_preimage_of_injective_subset_range (hf : f.Injective) (ht : t ⊆ range f) :
(f ⁻¹' t).encard = t.encard := by
rw [← hf.encard_image, image_preimage_eq_inter_range, inter_eq_self_of_subset_left ht]
lemma encard_preimage_of_bijective (hf : f.Bijective) (t : Set β) : (f ⁻¹' t).encard = t.encard :=
encard_preimage_of_injective_subset_range hf.injective (by simp [hf.surjective.range_eq])
theorem encard_le_encard_of_injOn (hf : MapsTo f s t) (f_inj : InjOn f s) :
s.encard ≤ t.encard := by
rw [← f_inj.encard_image]; apply encard_le_encard; rintro _ ⟨x, hx, rfl⟩; exact hf hx
theorem Finite.exists_injOn_of_encard_le [Nonempty β] {s : Set α} {t : Set β} (hs : s.Finite)
(hle : s.encard ≤ t.encard) : ∃ (f : α → β), s ⊆ f ⁻¹' t ∧ InjOn f s := by
classical
obtain (rfl | h | ⟨a, has, -⟩) := s.eq_empty_or_encard_eq_top_or_encard_diff_singleton_lt
· simp
· exact (encard_ne_top_iff.mpr hs h).elim
obtain ⟨b, hbt⟩ := encard_pos.1 ((encard_pos.2 ⟨_, has⟩).trans_le hle)
have hle' : (s \ {a}).encard ≤ (t \ {b}).encard := by
rwa [← WithTop.add_le_add_iff_right WithTop.one_ne_top,
encard_diff_singleton_add_one has, encard_diff_singleton_add_one hbt]
obtain ⟨f₀, hf₀s, hinj⟩ := exists_injOn_of_encard_le hs.diff hle'
simp only [preimage_diff, subset_def, mem_diff, mem_singleton_iff, mem_preimage, and_imp] at hf₀s
use Function.update f₀ a b
rw [← insert_eq_of_mem has, ← insert_diff_singleton, injOn_insert (fun h ↦ h.2 rfl)]
simp only [mem_diff, mem_singleton_iff, not_true, and_false, insert_diff_singleton, subset_def,
mem_insert_iff, mem_preimage, ne_eq, Function.update_apply, forall_eq_or_imp, ite_true, and_imp,
mem_image, ite_eq_left_iff, not_exists, not_and, not_forall, exists_prop, and_iff_right hbt]
refine ⟨?_, ?_, fun x hxs hxa ↦ ⟨hxa, (hf₀s x hxs hxa).2⟩⟩
· rintro x hx; split_ifs with h
· assumption
· exact (hf₀s x hx h).1
exact InjOn.congr hinj (fun x ⟨_, hxa⟩ ↦ by rwa [Function.update_of_ne])
termination_by encard s
theorem Finite.exists_bijOn_of_encard_eq [Nonempty β] (hs : s.Finite) (h : s.encard = t.encard) :
∃ (f : α → β), BijOn f s t := by
obtain ⟨f, hf, hinj⟩ := hs.exists_injOn_of_encard_le h.le; use f
convert hinj.bijOn_image
rw [(hs.image f).eq_of_subset_of_encard_le (image_subset_iff.mpr hf)
(h.symm.trans hinj.encard_image.symm).le]
end Function
section ncard
open Nat
/-- A tactic (for use in default params) that applies `Set.toFinite` to synthesize a `Set.Finite`
term. -/
syntax "toFinite_tac" : tactic
macro_rules
| `(tactic| toFinite_tac) => `(tactic| apply Set.toFinite)
/-- A tactic useful for transferring proofs for `encard` to their corresponding `card` statements -/
syntax "to_encard_tac" : tactic
macro_rules
| `(tactic| to_encard_tac) => `(tactic|
simp only [← Nat.cast_le (α := ℕ∞), ← Nat.cast_inj (R := ℕ∞), Nat.cast_add, Nat.cast_one])
/-- The cardinality of `s : Set α` . Has the junk value `0` if `s` is infinite -/
noncomputable def ncard (s : Set α) : ℕ := ENat.toNat s.encard
theorem ncard_def (s : Set α) : s.ncard = ENat.toNat s.encard := rfl
theorem Finite.cast_ncard_eq (hs : s.Finite) : s.ncard = s.encard := by
rwa [ncard, ENat.coe_toNat_eq_self, ne_eq, encard_eq_top_iff, Set.Infinite, not_not]
lemma ncard_le_encard (s : Set α) : s.ncard ≤ s.encard := ENat.coe_toNat_le_self _
theorem Nat.card_coe_set_eq (s : Set α) : Nat.card s = s.ncard := by
obtain (h | h) := s.finite_or_infinite
· have := h.fintype
rw [ncard, h.encard_eq_coe_toFinset_card, Nat.card_eq_fintype_card,
toFinite_toFinset, toFinset_card, ENat.toNat_coe]
have := infinite_coe_iff.2 h
rw [ncard, h.encard_eq, Nat.card_eq_zero_of_infinite, ENat.toNat_top]
theorem ncard_eq_toFinset_card (s : Set α) (hs : s.Finite := by toFinite_tac) :
s.ncard = hs.toFinset.card := by
rw [← Nat.card_coe_set_eq, @Nat.card_eq_fintype_card _ hs.fintype,
@Finite.card_toFinset _ _ hs.fintype hs]
theorem ncard_eq_toFinset_card' (s : Set α) [Fintype s] :
s.ncard = s.toFinset.card := by
simp [← Nat.card_coe_set_eq, Nat.card_eq_fintype_card]
lemma cast_ncard {s : Set α} (hs : s.Finite) :
(s.ncard : Cardinal) = Cardinal.mk s := @Nat.cast_card _ hs
theorem encard_le_coe_iff_finite_ncard_le {k : ℕ} : s.encard ≤ k ↔ s.Finite ∧ s.ncard ≤ k := by
rw [encard_le_coe_iff, and_congr_right_iff]
exact fun hfin ↦ ⟨fun ⟨n₀, hn₀, hle⟩ ↦ by rwa [ncard_def, hn₀, ENat.toNat_coe],
fun h ↦ ⟨s.ncard, by rw [hfin.cast_ncard_eq], h⟩⟩
theorem Infinite.ncard (hs : s.Infinite) : s.ncard = 0 := by
rw [← Nat.card_coe_set_eq, @Nat.card_eq_zero_of_infinite _ hs.to_subtype]
@[gcongr]
theorem ncard_le_ncard (hst : s ⊆ t) (ht : t.Finite := by toFinite_tac) :
s.ncard ≤ t.ncard := by
rw [← Nat.cast_le (α := ℕ∞), ht.cast_ncard_eq, (ht.subset hst).cast_ncard_eq]
exact encard_mono hst
theorem ncard_mono [Finite α] : @Monotone (Set α) _ _ _ ncard := fun _ _ ↦ ncard_le_ncard
@[simp] theorem ncard_eq_zero (hs : s.Finite := by toFinite_tac) :
s.ncard = 0 ↔ s = ∅ := by
rw [← Nat.cast_inj (R := ℕ∞), hs.cast_ncard_eq, Nat.cast_zero, encard_eq_zero]
@[simp, norm_cast] theorem ncard_coe_Finset (s : Finset α) : (s : Set α).ncard = s.card := by
rw [ncard_eq_toFinset_card _, Finset.finite_toSet_toFinset]
theorem ncard_univ (α : Type*) : (univ : Set α).ncard = Nat.card α := by
rcases finite_or_infinite α with h | h
· have hft := Fintype.ofFinite α
rw [ncard_eq_toFinset_card, Finite.toFinset_univ, Finset.card_univ, Nat.card_eq_fintype_card]
rw [Nat.card_eq_zero_of_infinite, Infinite.ncard]
exact infinite_univ
@[simp] theorem ncard_empty (α : Type*) : (∅ : Set α).ncard = 0 := by
rw [ncard_eq_zero]
theorem ncard_pos (hs : s.Finite := by toFinite_tac) : 0 < s.ncard ↔ s.Nonempty := by
rw [pos_iff_ne_zero, Ne, ncard_eq_zero hs, nonempty_iff_ne_empty]
protected alias ⟨_, Nonempty.ncard_pos⟩ := ncard_pos
theorem ncard_ne_zero_of_mem {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) : s.ncard ≠ 0 :=
((ncard_pos hs).mpr ⟨a, h⟩).ne.symm
theorem finite_of_ncard_ne_zero (hs : s.ncard ≠ 0) : s.Finite :=
s.finite_or_infinite.elim id fun h ↦ (hs h.ncard).elim
theorem finite_of_ncard_pos (hs : 0 < s.ncard) : s.Finite :=
finite_of_ncard_ne_zero hs.ne.symm
theorem nonempty_of_ncard_ne_zero (hs : s.ncard ≠ 0) : s.Nonempty := by
rw [nonempty_iff_ne_empty]; rintro rfl; simp at hs
@[simp] theorem ncard_singleton (a : α) : ({a} : Set α).ncard = 1 := by
simp [ncard]
theorem ncard_singleton_inter (a : α) (s : Set α) : ({a} ∩ s).ncard ≤ 1 := by
rw [← Nat.cast_le (α := ℕ∞), (toFinite _).cast_ncard_eq, Nat.cast_one]
apply encard_singleton_inter
@[simp]
theorem ncard_prod : (s ×ˢ t).ncard = s.ncard * t.ncard := by
simp [ncard, ENat.toNat_mul]
@[simp]
theorem ncard_powerset (s : Set α) (hs : s.Finite := by toFinite_tac) :
(𝒫 s).ncard = 2 ^ s.ncard := by
have h := Cardinal.mk_powerset s
rw [← cast_ncard hs.powerset, ← cast_ncard hs] at h
norm_cast at h
section InsertErase
@[simp] theorem ncard_insert_of_not_mem {a : α} (h : a ∉ s) (hs : s.Finite := by toFinite_tac) :
(insert a s).ncard = s.ncard + 1 := by
rw [← Nat.cast_inj (R := ℕ∞), (hs.insert a).cast_ncard_eq, Nat.cast_add, Nat.cast_one,
hs.cast_ncard_eq, encard_insert_of_not_mem h]
theorem ncard_insert_of_mem {a : α} (h : a ∈ s) : ncard (insert a s) = s.ncard := by
rw [insert_eq_of_mem h]
theorem ncard_insert_le (a : α) (s : Set α) : (insert a s).ncard ≤ s.ncard + 1 := by
obtain hs | hs := s.finite_or_infinite
· to_encard_tac; rw [hs.cast_ncard_eq, (hs.insert _).cast_ncard_eq]; apply encard_insert_le
rw [(hs.mono (subset_insert a s)).ncard]
exact Nat.zero_le _
theorem ncard_insert_eq_ite {a : α} [Decidable (a ∈ s)] (hs : s.Finite := by toFinite_tac) :
ncard (insert a s) = if a ∈ s then s.ncard else s.ncard + 1 := by
by_cases h : a ∈ s
· rw [ncard_insert_of_mem h, if_pos h]
· rw [ncard_insert_of_not_mem h hs, if_neg h]
theorem ncard_le_ncard_insert (a : α) (s : Set α) : s.ncard ≤ (insert a s).ncard := by
classical
refine
s.finite_or_infinite.elim (fun h ↦ ?_) (fun h ↦ by (rw [h.ncard]; exact Nat.zero_le _))
rw [ncard_insert_eq_ite h]; split_ifs <;> simp
@[simp] theorem ncard_pair {a b : α} (h : a ≠ b) : ({a, b} : Set α).ncard = 2 := by
rw [ncard_insert_of_not_mem, ncard_singleton]; simpa
@[simp] theorem ncard_diff_singleton_add_one {a : α} (h : a ∈ s)
(hs : s.Finite := by toFinite_tac) : (s \ {a}).ncard + 1 = s.ncard := by
to_encard_tac; rw [hs.cast_ncard_eq, hs.diff.cast_ncard_eq,
encard_diff_singleton_add_one h]
@[simp] theorem ncard_diff_singleton_of_mem {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) :
(s \ {a}).ncard = s.ncard - 1 :=
eq_tsub_of_add_eq (ncard_diff_singleton_add_one h hs)
theorem ncard_diff_singleton_lt_of_mem {a : α} (h : a ∈ s) (hs : s.Finite := by toFinite_tac) :
(s \ {a}).ncard < s.ncard := by
rw [← ncard_diff_singleton_add_one h hs]; apply lt_add_one
theorem ncard_diff_singleton_le (s : Set α) (a : α) : (s \ {a}).ncard ≤ s.ncard := by
obtain hs | hs := s.finite_or_infinite
· apply ncard_le_ncard diff_subset hs
convert zero_le (α := ℕ) _
exact (hs.diff (by simp : Set.Finite {a})).ncard
theorem pred_ncard_le_ncard_diff_singleton (s : Set α) (a : α) : s.ncard - 1 ≤ (s \ {a}).ncard := by
rcases s.finite_or_infinite with hs | hs
· by_cases h : a ∈ s
· rw [ncard_diff_singleton_of_mem h hs]
rw [diff_singleton_eq_self h]
apply Nat.pred_le
convert Nat.zero_le _
rw [hs.ncard]
theorem ncard_exchange {a b : α} (ha : a ∉ s) (hb : b ∈ s) : (insert a (s \ {b})).ncard = s.ncard :=
congr_arg ENat.toNat <| encard_exchange ha hb
theorem ncard_exchange' {a b : α} (ha : a ∉ s) (hb : b ∈ s) :
(insert a s \ {b}).ncard = s.ncard := by
rw [← ncard_exchange ha hb, ← singleton_union, ← singleton_union, union_diff_distrib,
@diff_singleton_eq_self _ b {a} fun h ↦ ha (by rwa [← mem_singleton_iff.mp h])]
lemma odd_card_insert_iff {a : α} (ha : a ∉ s) (hs : s.Finite := by toFinite_tac) :
Odd (insert a s).ncard ↔ Even s.ncard := by
rw [ncard_insert_of_not_mem ha hs, Nat.odd_add]
simp only [Nat.odd_add, ← Nat.not_even_iff_odd, Nat.not_even_one, iff_false, Decidable.not_not]
lemma even_card_insert_iff {a : α} (ha : a ∉ s) (hs : s.Finite := by toFinite_tac) :
Even (insert a s).ncard ↔ Odd s.ncard := by
rw [ncard_insert_of_not_mem ha hs, Nat.even_add_one, Nat.not_even_iff_odd]
end InsertErase
variable {f : α → β}
theorem ncard_image_le (hs : s.Finite := by toFinite_tac) : (f '' s).ncard ≤ s.ncard := by
to_encard_tac; rw [hs.cast_ncard_eq, (hs.image _).cast_ncard_eq]; apply encard_image_le
theorem ncard_image_of_injOn (H : Set.InjOn f s) : (f '' s).ncard = s.ncard :=
congr_arg ENat.toNat <| H.encard_image
theorem injOn_of_ncard_image_eq (h : (f '' s).ncard = s.ncard) (hs : s.Finite := by toFinite_tac) :
Set.InjOn f s := by
rw [← Nat.cast_inj (R := ℕ∞), hs.cast_ncard_eq, (hs.image _).cast_ncard_eq] at h
exact hs.injOn_of_encard_image_eq h
theorem ncard_image_iff (hs : s.Finite := by toFinite_tac) :
(f '' s).ncard = s.ncard ↔ Set.InjOn f s :=
⟨fun h ↦ injOn_of_ncard_image_eq h hs, ncard_image_of_injOn⟩
theorem ncard_image_of_injective (s : Set α) (H : f.Injective) : (f '' s).ncard = s.ncard :=
ncard_image_of_injOn fun _ _ _ _ h ↦ H h
theorem ncard_preimage_of_injective_subset_range {s : Set β} (H : f.Injective)
(hs : s ⊆ Set.range f) :
(f ⁻¹' s).ncard = s.ncard := by
rw [← ncard_image_of_injective _ H, image_preimage_eq_iff.mpr hs]
theorem fiber_ncard_ne_zero_iff_mem_image {y : β} (hs : s.Finite := by toFinite_tac) :
{ x ∈ s | f x = y }.ncard ≠ 0 ↔ y ∈ f '' s := by
refine ⟨nonempty_of_ncard_ne_zero, ?_⟩
rintro ⟨z, hz, rfl⟩
exact @ncard_ne_zero_of_mem _ ({ x ∈ s | f x = f z }) z (mem_sep hz rfl)
(hs.subset (sep_subset _ _))
@[simp] theorem ncard_map (f : α ↪ β) : (f '' s).ncard = s.ncard :=
ncard_image_of_injective _ f.inj'
@[simp] theorem ncard_subtype (P : α → Prop) (s : Set α) :
{ x : Subtype P | (x : α) ∈ s }.ncard = (s ∩ setOf P).ncard := by
convert (ncard_image_of_injective _ (@Subtype.coe_injective _ P)).symm
ext x
simp [← and_assoc, exists_eq_right]
theorem ncard_inter_le_ncard_left (s t : Set α) (hs : s.Finite := by toFinite_tac) :
(s ∩ t).ncard ≤ s.ncard :=
ncard_le_ncard inter_subset_left hs
theorem ncard_inter_le_ncard_right (s t : Set α) (ht : t.Finite := by toFinite_tac) :
(s ∩ t).ncard ≤ t.ncard :=
ncard_le_ncard inter_subset_right ht
theorem eq_of_subset_of_ncard_le (h : s ⊆ t) (h' : t.ncard ≤ s.ncard)
(ht : t.Finite := by toFinite_tac) : s = t :=
ht.eq_of_subset_of_encard_le' h
(by rwa [← Nat.cast_le (α := ℕ∞), ht.cast_ncard_eq, (ht.subset h).cast_ncard_eq] at h')
|
theorem subset_iff_eq_of_ncard_le (h : t.ncard ≤ s.ncard) (ht : t.Finite := by toFinite_tac) :
s ⊆ t ↔ s = t :=
| Mathlib/Data/Set/Card.lean | 726 | 728 |
/-
Copyright (c) 2020 Markus Himmel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Markus Himmel
-/
import Mathlib.CategoryTheory.Comma.Basic
/-!
# The category of arrows
The category of arrows, with morphisms commutative squares.
We set this up as a specialization of the comma category `Comma L R`,
where `L` and `R` are both the identity functor.
## Tags
comma, arrow
-/
namespace CategoryTheory
universe v u
-- morphism levels before object levels. See note [CategoryTheory universes].
variable {T : Type u} [Category.{v} T]
section
variable (T)
/-- The arrow category of `T` has as objects all morphisms in `T` and as morphisms commutative
squares in `T`. -/
def Arrow :=
Comma.{v, v, v} (𝟭 T) (𝟭 T)
-- The `Category` instance should be constructed by a deriving handler.
-- https://github.com/leanprover-community/mathlib4/issues/380
instance : Category (Arrow T) := commaCategory
-- Satisfying the inhabited linter
instance Arrow.inhabited [Inhabited T] : Inhabited (Arrow T) where
default := show Comma (𝟭 T) (𝟭 T) from default
end
namespace Arrow
@[ext]
lemma hom_ext {X Y : Arrow T} (f g : X ⟶ Y) (h₁ : f.left = g.left) (h₂ : f.right = g.right) :
f = g :=
CommaMorphism.ext h₁ h₂
@[simp]
theorem id_left (f : Arrow T) : CommaMorphism.left (𝟙 f) = 𝟙 f.left :=
rfl
@[simp]
theorem id_right (f : Arrow T) : CommaMorphism.right (𝟙 f) = 𝟙 f.right :=
rfl
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/10688): added to ease automation
@[simp, reassoc]
theorem comp_left {X Y Z : Arrow T} (f : X ⟶ Y) (g : Y ⟶ Z) :
(f ≫ g).left = f.left ≫ g.left := rfl
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/10688): added to ease automation
@[simp, reassoc]
theorem comp_right {X Y Z : Arrow T} (f : X ⟶ Y) (g : Y ⟶ Z) :
(f ≫ g).right = f.right ≫ g.right := rfl
/-- An object in the arrow category is simply a morphism in `T`. -/
@[simps]
def mk {X Y : T} (f : X ⟶ Y) : Arrow T where
left := X
right := Y
hom := f
@[simp]
theorem mk_eq (f : Arrow T) : Arrow.mk f.hom = f := by
cases f
rfl
theorem mk_injective (A B : T) :
Function.Injective (Arrow.mk : (A ⟶ B) → Arrow T) := fun f g h => by
cases h
rfl
theorem mk_inj (A B : T) {f g : A ⟶ B} : Arrow.mk f = Arrow.mk g ↔ f = g :=
(mk_injective A B).eq_iff
instance {X Y : T} : CoeOut (X ⟶ Y) (Arrow T) where
coe := mk
lemma mk_eq_mk_iff {X Y X' Y' : T} (f : X ⟶ Y) (f' : X' ⟶ Y') :
Arrow.mk f = Arrow.mk f' ↔
∃ (hX : X = X') (hY : Y = Y'), f = eqToHom hX ≫ f' ≫ eqToHom hY.symm := by
constructor
· intro h
refine ⟨congr_arg Comma.left h, congr_arg Comma.right h, ?_⟩
have := (eqToIso h).hom.w
dsimp at this
rw [Comma.eqToHom_left, Comma.eqToHom_right] at this
rw [reassoc_of% this, eqToHom_trans, eqToHom_refl, Category.comp_id]
· rintro ⟨rfl, rfl, h⟩
simp only [eqToHom_refl, Category.comp_id, Category.id_comp] at h
rw [h]
lemma ext {f g : Arrow T}
(h₁ : f.left = g.left) (h₂ : f.right = g.right)
(h₃ : f.hom = eqToHom h₁ ≫ g.hom ≫ eqToHom h₂.symm) : f = g :=
(mk_eq_mk_iff _ _).2 (by aesop)
@[simp]
lemma arrow_mk_comp_eqToHom {X Y Y' : T} (f : X ⟶ Y) (h : Y = Y') :
Arrow.mk (f ≫ eqToHom h) = Arrow.mk f :=
ext rfl h.symm (by simp)
@[simp]
lemma arrow_mk_eqToHom_comp {X' X Y : T} (f : X ⟶ Y) (h : X' = X) :
Arrow.mk (eqToHom h ≫ f) = Arrow.mk f :=
ext h rfl (by simp)
/-- A morphism in the arrow category is a commutative square connecting two objects of the arrow
category. -/
@[simps]
def homMk {f g : Arrow T} (u : f.left ⟶ g.left) (v : f.right ⟶ g.right)
(w : u ≫ g.hom = f.hom ≫ v := by aesop_cat) : f ⟶ g where
left := u
right := v
w := w
/-- We can also build a morphism in the arrow category out of any commutative square in `T`. -/
@[simps]
def homMk' {X Y : T} {f : X ⟶ Y} {P Q : T} {g : P ⟶ Q} (u : X ⟶ P) (v : Y ⟶ Q)
(w : u ≫ g = f ≫ v := by aesop_cat) :
Arrow.mk f ⟶ Arrow.mk g where
left := u
right := v
w := w
-- `w_mk_left` is not needed, as it is a consequence of `w` and `mk_hom`.
@[reassoc (attr := simp)]
theorem w_mk_right {f : Arrow T} {X Y : T} {g : X ⟶ Y} (sq : f ⟶ mk g) :
sq.left ≫ g = f.hom ≫ sq.right :=
sq.w
@[reassoc]
theorem w {f g : Arrow T} (sq : f ⟶ g) : sq.left ≫ g.hom = f.hom ≫ sq.right := by
simp
theorem isIso_of_isIso_left_of_isIso_right {f g : Arrow T} (ff : f ⟶ g) [IsIso ff.left]
[IsIso ff.right] : IsIso ff where
out := by
let inverse : g ⟶ f := ⟨inv ff.left, inv ff.right, (by simp)⟩
apply Exists.intro inverse
aesop_cat
/-- Create an isomorphism between arrows,
by providing isomorphisms between the domains and codomains,
and a proof that the square commutes. -/
@[simps!]
def isoMk {f g : Arrow T} (l : f.left ≅ g.left) (r : f.right ≅ g.right)
(h : l.hom ≫ g.hom = f.hom ≫ r.hom := by aesop_cat) : f ≅ g :=
Comma.isoMk l r h
/-- A variant of `Arrow.isoMk` that creates an iso between two `Arrow.mk`s with a better type
signature. -/
abbrev isoMk' {W X Y Z : T} (f : W ⟶ X) (g : Y ⟶ Z) (e₁ : W ≅ Y) (e₂ : X ≅ Z)
(h : e₁.hom ≫ g = f ≫ e₂.hom := by aesop_cat) : Arrow.mk f ≅ Arrow.mk g :=
Arrow.isoMk e₁ e₂ h
theorem hom.congr_left {f g : Arrow T} {φ₁ φ₂ : f ⟶ g} (h : φ₁ = φ₂) : φ₁.left = φ₂.left := by
rw [h]
@[simp]
theorem hom.congr_right {f g : Arrow T} {φ₁ φ₂ : f ⟶ g} (h : φ₁ = φ₂) : φ₁.right = φ₂.right := by
rw [h]
theorem iso_w {f g : Arrow T} (e : f ≅ g) : g.hom = e.inv.left ≫ f.hom ≫ e.hom.right := by
have eq := Arrow.hom.congr_right e.inv_hom_id
rw [Arrow.comp_right, Arrow.id_right] at eq
rw [Arrow.w_assoc, eq, Category.comp_id]
theorem iso_w' {W X Y Z : T} {f : W ⟶ X} {g : Y ⟶ Z} (e : Arrow.mk f ≅ Arrow.mk g) :
g = e.inv.left ≫ f ≫ e.hom.right :=
iso_w e
section
variable {f g : Arrow T} (sq : f ⟶ g)
instance isIso_left [IsIso sq] : IsIso sq.left where
out := by
apply Exists.intro (inv sq).left
simp only [← Comma.comp_left, IsIso.hom_inv_id, IsIso.inv_hom_id, Arrow.id_left,
eq_self_iff_true, and_self_iff]
simp
instance isIso_right [IsIso sq] : IsIso sq.right where
out := by
apply Exists.intro (inv sq).right
simp only [← Comma.comp_right, IsIso.hom_inv_id, IsIso.inv_hom_id, Arrow.id_right,
eq_self_iff_true, and_self_iff]
simp
lemma isIso_of_isIso {X Y : T} {f : X ⟶ Y} {g : Arrow T} (sq : mk f ⟶ g) [IsIso sq] [IsIso f] :
IsIso g.hom := by
rw [iso_w' (asIso sq)]
infer_instance
lemma isIso_hom_iff_isIso_hom_of_isIso {f g : Arrow T} (sq : f ⟶ g) [IsIso sq] :
IsIso f.hom ↔ IsIso g.hom :=
⟨fun _ => isIso_of_isIso sq, fun _ => isIso_of_isIso (inv sq)⟩
lemma isIso_iff_isIso_of_isIso {W X Y Z : T} {f : W ⟶ X} {g : Y ⟶ Z} (sq : mk f ⟶ mk g) [IsIso sq] :
IsIso f ↔ IsIso g :=
isIso_hom_iff_isIso_hom_of_isIso sq
lemma isIso_hom_iff_isIso_of_isIso {Y Z : T} {f : Arrow T} {g : Y ⟶ Z} (sq : f ⟶ mk g) [IsIso sq] :
IsIso f.hom ↔ IsIso g :=
isIso_hom_iff_isIso_hom_of_isIso sq
@[simp]
theorem inv_left [IsIso sq] : (inv sq).left = inv sq.left :=
IsIso.eq_inv_of_hom_inv_id <| by rw [← Comma.comp_left, IsIso.hom_inv_id, id_left]
@[simp]
theorem inv_right [IsIso sq] : (inv sq).right = inv sq.right :=
IsIso.eq_inv_of_hom_inv_id <| by rw [← Comma.comp_right, IsIso.hom_inv_id, id_right]
theorem left_hom_inv_right [IsIso sq] : sq.left ≫ g.hom ≫ inv sq.right = f.hom := by
simp only [← Category.assoc, IsIso.comp_inv_eq, w]
theorem inv_left_hom_right [IsIso sq] : inv sq.left ≫ f.hom ≫ sq.right = g.hom := by
simp only [w, IsIso.inv_comp_eq]
instance mono_left [Mono sq] : Mono sq.left where
right_cancellation {Z} φ ψ h := by
let aux : (Z ⟶ f.left) → (Arrow.mk (𝟙 Z) ⟶ f) := fun φ =>
{ left := φ
right := φ ≫ f.hom }
have : ∀ g, (aux g).right = g ≫ f.hom := fun g => by dsimp
show (aux φ).left = (aux ψ).left
congr 1
rw [← cancel_mono sq]
apply CommaMorphism.ext
· exact h
· rw [Comma.comp_right, Comma.comp_right, this, this, Category.assoc, Category.assoc]
rw [← Arrow.w]
simp only [← Category.assoc, h]
instance epi_right [Epi sq] : Epi sq.right where
left_cancellation {Z} φ ψ h := by
| let aux : (g.right ⟶ Z) → (g ⟶ Arrow.mk (𝟙 Z)) := fun φ =>
{ right := φ
left := g.hom ≫ φ }
| Mathlib/CategoryTheory/Comma/Arrow.lean | 255 | 257 |
/-
Copyright (c) 2023 Yaël Dillies, Sara Rousta. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies
-/
import Mathlib.Data.Set.Finite.Lattice
import Mathlib.Order.Interval.Finset.Defs
import Mathlib.Order.UpperLower.Closure
/-!
# Upper and lower sets in a locally finite order
In this file we characterise the interaction of `UpperSet`/`LowerSet` and `LocallyFiniteOrder`.
-/
namespace Set
variable {α : Type*} [Preorder α] {s : Set α}
protected theorem Finite.upperClosure [LocallyFiniteOrderTop α] (hs : s.Finite) :
| (upperClosure s : Set α).Finite := by
rw [coe_upperClosure]
exact hs.biUnion fun _ _ => finite_Ici _
| Mathlib/Order/UpperLower/LocallyFinite.lean | 22 | 25 |
/-
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.CharP.Reduced
import Mathlib.RingTheory.IntegralDomain
-- TODO: remove Mathlib.Algebra.CharP.Reduced and move the last two lemmas to Lemmas
/-!
# Roots of unity
We define roots of unity in the context of an arbitrary commutative monoid,
as a subgroup of the group of units.
## Main definitions
* `rootsOfUnity n M`, for `n : ℕ` is the subgroup of the units of a commutative monoid `M`
consisting of elements `x` that satisfy `x ^ n = 1`.
## Main results
* `rootsOfUnity.isCyclic`: the roots of unity in an integral domain form a cyclic group.
## Implementation details
It is desirable that `rootsOfUnity` is a subgroup,
and it will mainly be applied to rings (e.g. the ring of integers in a number field) and fields.
We therefore implement it as a subgroup of the units of a commutative monoid.
We have chosen to define `rootsOfUnity n` for `n : ℕ` and add a `[NeZero n]` typeclass
assumption when we need `n` to be non-zero (which is the case for most interesting statements).
Note that `rootsOfUnity 0 M` is the top subgroup of `Mˣ` (as the condition `ζ^0 = 1` is
satisfied for all units).
-/
noncomputable section
open Polynomial
open Finset
variable {M N G R S F : Type*}
variable [CommMonoid M] [CommMonoid N] [DivisionCommMonoid G]
section rootsOfUnity
variable {k l : ℕ}
/-- `rootsOfUnity k M` is the subgroup of elements `m : Mˣ` that satisfy `m ^ k = 1`. -/
def rootsOfUnity (k : ℕ) (M : Type*) [CommMonoid M] : Subgroup Mˣ where
carrier := {ζ | ζ ^ k = 1}
one_mem' := one_pow _
mul_mem' _ _ := by simp_all only [Set.mem_setOf_eq, mul_pow, one_mul]
inv_mem' _ := by simp_all only [Set.mem_setOf_eq, inv_pow, inv_one]
@[simp]
theorem mem_rootsOfUnity (k : ℕ) (ζ : Mˣ) : ζ ∈ rootsOfUnity k M ↔ ζ ^ k = 1 :=
Iff.rfl
/-- A variant of `mem_rootsOfUnity` using `ζ : Mˣ`. -/
theorem mem_rootsOfUnity' (k : ℕ) (ζ : Mˣ) : ζ ∈ rootsOfUnity k M ↔ (ζ : M) ^ k = 1 := by
rw [mem_rootsOfUnity]; norm_cast
@[simp]
theorem rootsOfUnity_one (M : Type*) [CommMonoid M] : rootsOfUnity 1 M = ⊥ := by
ext1
simp only [mem_rootsOfUnity, pow_one, Subgroup.mem_bot]
@[simp]
lemma rootsOfUnity_zero (M : Type*) [CommMonoid M] : rootsOfUnity 0 M = ⊤ := by
ext1
simp only [mem_rootsOfUnity, pow_zero, Subgroup.mem_top]
theorem rootsOfUnity.coe_injective {n : ℕ} :
Function.Injective (fun x : rootsOfUnity n M ↦ x.val.val) :=
Units.ext.comp fun _ _ ↦ Subtype.eq
/-- Make an element of `rootsOfUnity` from a member of the base ring, and a proof that it has
a positive power equal to one. -/
@[simps! coe_val]
def rootsOfUnity.mkOfPowEq (ζ : M) {n : ℕ} [NeZero n] (h : ζ ^ n = 1) : rootsOfUnity n M :=
⟨Units.ofPowEqOne ζ n h <| NeZero.ne n, Units.pow_ofPowEqOne _ _⟩
@[simp]
theorem rootsOfUnity.coe_mkOfPowEq {ζ : M} {n : ℕ} [NeZero n] (h : ζ ^ n = 1) :
((rootsOfUnity.mkOfPowEq _ h : Mˣ) : M) = ζ :=
rfl
theorem rootsOfUnity_le_of_dvd (h : k ∣ l) : rootsOfUnity k M ≤ rootsOfUnity l M := by
obtain ⟨d, rfl⟩ := h
intro ζ h
simp_all only [mem_rootsOfUnity, pow_mul, one_pow]
theorem map_rootsOfUnity (f : Mˣ →* Nˣ) (k : ℕ) : (rootsOfUnity k M).map f ≤ rootsOfUnity k N := by
rintro _ ⟨ζ, h, rfl⟩
simp_all only [← map_pow, mem_rootsOfUnity, SetLike.mem_coe, MonoidHom.map_one]
@[norm_cast]
theorem rootsOfUnity.coe_pow [CommMonoid R] (ζ : rootsOfUnity k R) (m : ℕ) :
(((ζ ^ m :) : Rˣ) : R) = ((ζ : Rˣ) : R) ^ m := by
rw [Subgroup.coe_pow, Units.val_pow_eq_pow_val]
/-- The canonical isomorphism from the `n`th roots of unity in `Mˣ`
to the `n`th roots of unity in `M`. -/
def rootsOfUnityUnitsMulEquiv (M : Type*) [CommMonoid M] (n : ℕ) :
rootsOfUnity n Mˣ ≃* rootsOfUnity n M where
toFun ζ := ⟨ζ.val, (mem_rootsOfUnity ..).mpr <| (mem_rootsOfUnity' ..).mp ζ.prop⟩
invFun ζ := ⟨toUnits ζ.val, by
simp only [mem_rootsOfUnity, ← map_pow, EmbeddingLike.map_eq_one_iff]
exact (mem_rootsOfUnity ..).mp ζ.prop⟩
left_inv ζ := by simp only [toUnits_val_apply, Subtype.coe_eta]
right_inv ζ := by simp only [val_toUnits_apply, Subtype.coe_eta]
map_mul' ζ ζ' := by simp only [Subgroup.coe_mul, Units.val_mul, MulMemClass.mk_mul_mk]
section CommMonoid
variable [CommMonoid R] [CommMonoid S] [FunLike F R S]
/-- Restrict a ring homomorphism to the nth roots of unity. -/
def restrictRootsOfUnity [MonoidHomClass F R S] (σ : F) (n : ℕ) :
rootsOfUnity n R →* rootsOfUnity n S :=
{ toFun := fun ξ ↦ ⟨Units.map σ (ξ : Rˣ), by
rw [mem_rootsOfUnity, ← map_pow, Units.ext_iff, Units.coe_map, ξ.prop]
exact map_one σ⟩
map_one' := by ext1; simp only [OneMemClass.coe_one, map_one]
map_mul' := fun ξ₁ ξ₂ ↦ by
ext1; simp only [Subgroup.coe_mul, map_mul, MulMemClass.mk_mul_mk] }
@[simp]
theorem restrictRootsOfUnity_coe_apply [MonoidHomClass F R S] (σ : F) (ζ : rootsOfUnity k R) :
(restrictRootsOfUnity σ k ζ : Sˣ) = σ (ζ : Rˣ) :=
rfl
/-- Restrict a monoid isomorphism to the nth roots of unity. -/
nonrec def MulEquiv.restrictRootsOfUnity (σ : R ≃* S) (n : ℕ) :
rootsOfUnity n R ≃* rootsOfUnity n S where
toFun := restrictRootsOfUnity σ n
invFun := restrictRootsOfUnity σ.symm n
left_inv ξ := by ext; exact σ.symm_apply_apply _
right_inv ξ := by ext; exact σ.apply_symm_apply _
map_mul' := (restrictRootsOfUnity _ n).map_mul
@[simp]
theorem MulEquiv.restrictRootsOfUnity_coe_apply (σ : R ≃* S) (ζ : rootsOfUnity k R) :
(σ.restrictRootsOfUnity k ζ : Sˣ) = σ (ζ : Rˣ) :=
rfl
@[simp]
theorem MulEquiv.restrictRootsOfUnity_symm (σ : R ≃* S) :
(σ.restrictRootsOfUnity k).symm = σ.symm.restrictRootsOfUnity k :=
rfl
end CommMonoid
section IsDomain
-- The following results need `k` to be nonzero.
variable [NeZero k] [CommRing R] [IsDomain R]
theorem mem_rootsOfUnity_iff_mem_nthRoots {ζ : Rˣ} :
ζ ∈ rootsOfUnity k R ↔ (ζ : R) ∈ nthRoots k (1 : R) := by
simp only [mem_rootsOfUnity, mem_nthRoots (NeZero.pos k), Units.ext_iff, Units.val_one,
Units.val_pow_eq_pow_val]
variable (k R)
/-- Equivalence between the `k`-th roots of unity in `R` and the `k`-th roots of `1`.
This is implemented as equivalence of subtypes,
because `rootsOfUnity` is a subgroup of the group of units,
whereas `nthRoots` is a multiset. -/
def rootsOfUnityEquivNthRoots : rootsOfUnity k R ≃ { x // x ∈ nthRoots k (1 : R) } where
toFun x := ⟨(x : Rˣ), mem_rootsOfUnity_iff_mem_nthRoots.mp x.2⟩
invFun x := by
refine ⟨⟨x, ↑x ^ (k - 1 : ℕ), ?_, ?_⟩, ?_⟩
all_goals
rcases x with ⟨x, hx⟩; rw [mem_nthRoots <| NeZero.pos k] at hx
simp only [← pow_succ, ← pow_succ', hx, tsub_add_cancel_of_le NeZero.one_le]
simp only [mem_rootsOfUnity, Units.ext_iff, Units.val_pow_eq_pow_val, hx, Units.val_one]
left_inv := by rintro ⟨x, hx⟩; ext; rfl
right_inv := by rintro ⟨x, hx⟩; ext; rfl
variable {k R}
@[simp]
theorem rootsOfUnityEquivNthRoots_apply (x : rootsOfUnity k R) :
(rootsOfUnityEquivNthRoots R k x : R) = ((x : Rˣ) : R) :=
rfl
@[simp]
theorem rootsOfUnityEquivNthRoots_symm_apply (x : { x // x ∈ nthRoots k (1 : R) }) :
(((rootsOfUnityEquivNthRoots R k).symm x : Rˣ) : R) = (x : R) :=
rfl
variable (k R)
instance rootsOfUnity.fintype : Fintype (rootsOfUnity k R) := by
classical
exact Fintype.ofEquiv { x // x ∈ nthRoots k (1 : R) } (rootsOfUnityEquivNthRoots R k).symm
instance rootsOfUnity.isCyclic : IsCyclic (rootsOfUnity k R) :=
isCyclic_of_subgroup_isDomain ((Units.coeHom R).comp (rootsOfUnity k R).subtype) coe_injective
theorem card_rootsOfUnity : Fintype.card (rootsOfUnity k R) ≤ k := by
classical
calc
Fintype.card (rootsOfUnity k R) = Fintype.card { x // x ∈ nthRoots k (1 : R) } :=
Fintype.card_congr (rootsOfUnityEquivNthRoots R k)
_ ≤ Multiset.card (nthRoots k (1 : R)).attach := Multiset.card_le_card (Multiset.dedup_le _)
_ = Multiset.card (nthRoots k (1 : R)) := Multiset.card_attach
_ ≤ k := card_nthRoots k 1
variable {k R}
theorem map_rootsOfUnity_eq_pow_self [FunLike F R R] [MonoidHomClass F R R] (σ : F)
(ζ : rootsOfUnity k R) :
∃ m : ℕ, σ (ζ : Rˣ) = ((ζ : Rˣ) : R) ^ m := by
obtain ⟨m, hm⟩ := MonoidHom.map_cyclic (restrictRootsOfUnity σ k)
rw [← restrictRootsOfUnity_coe_apply, hm, ← zpow_mod_orderOf, ← Int.toNat_of_nonneg
(m.emod_nonneg (Int.natCast_ne_zero.mpr (pos_iff_ne_zero.mp (orderOf_pos ζ)))),
zpow_natCast, rootsOfUnity.coe_pow]
exact ⟨(m % orderOf ζ).toNat, rfl⟩
end IsDomain
section Reduced
variable (R) [CommRing R] [IsReduced R]
-- @[simp] -- Porting note: simp normal form is `mem_rootsOfUnity_prime_pow_mul_iff'`
theorem mem_rootsOfUnity_prime_pow_mul_iff (p k : ℕ) (m : ℕ) [ExpChar R p] {ζ : Rˣ} :
ζ ∈ rootsOfUnity (p ^ k * m) R ↔ ζ ∈ rootsOfUnity m R := by
simp only [mem_rootsOfUnity', ExpChar.pow_prime_pow_mul_eq_one_iff]
/-- A variant of `mem_rootsOfUnity_prime_pow_mul_iff` in terms of `ζ ^ _` -/
@[simp]
theorem mem_rootsOfUnity_prime_pow_mul_iff' (p k : ℕ) (m : ℕ) [ExpChar R p] {ζ : Rˣ} :
ζ ^ (p ^ k * m) = 1 ↔ ζ ∈ rootsOfUnity m R := by
rw [← mem_rootsOfUnity, mem_rootsOfUnity_prime_pow_mul_iff]
end Reduced
end rootsOfUnity
section cyclic
namespace IsCyclic
/-- The isomorphism from the group of group homomorphisms from a finite cyclic group `G` of order
`n` into another group `G'` to the group of `n`th roots of unity in `G'` determined by a generator
`g` of `G`. It sends `φ : G →* G'` to `φ g`. -/
noncomputable
def monoidHomMulEquivRootsOfUnityOfGenerator {G : Type*} [CommGroup G] {g : G}
(hg : ∀ (x : G), x ∈ Subgroup.zpowers g) (G' : Type*) [CommGroup G'] :
(G →* G') ≃* rootsOfUnity (Nat.card G) G' where
toFun φ := ⟨(IsUnit.map φ <| Group.isUnit g).unit, by
simp only [mem_rootsOfUnity, Units.ext_iff, Units.val_pow_eq_pow_val, IsUnit.unit_spec,
← map_pow, pow_card_eq_one', map_one, Units.val_one]⟩
invFun ζ := monoidHomOfForallMemZpowers hg (g' := (ζ.val : G')) <| by
simpa only [orderOf_eq_card_of_forall_mem_zpowers hg, orderOf_dvd_iff_pow_eq_one,
← Units.val_pow_eq_pow_val, Units.val_eq_one] using ζ.prop
left_inv φ := (MonoidHom.eq_iff_eq_on_generator hg _ φ).mpr <| by
simp only [IsUnit.unit_spec, monoidHomOfForallMemZpowers_apply_gen]
right_inv φ := Subtype.ext <| by
simp only [monoidHomOfForallMemZpowers_apply_gen, IsUnit.unit_of_val_units]
map_mul' x y := by
| simp only [MonoidHom.mul_apply, MulMemClass.mk_mul_mk, Subtype.mk.injEq, Units.ext_iff,
IsUnit.unit_spec, Units.val_mul]
/-- The group of group homomorphisms from a finite cyclic group `G` of order `n` into another
| Mathlib/RingTheory/RootsOfUnity/Basic.lean | 268 | 271 |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Mario Carneiro, Yury Kudryashov
-/
import Mathlib.Data.Set.SymmDiff
import Mathlib.Order.SuccPred.Relation
import Mathlib.Topology.Irreducible
/-!
# Connected subsets of topological spaces
In this file we define connected subsets of a topological spaces and various other properties and
classes related to connectivity.
## Main definitions
We define the following properties for sets in a topological space:
* `IsConnected`: a nonempty set that has no non-trivial open partition.
See also the section below in the module doc.
* `connectedComponent` is the connected component of an element in the space.
We also have a class stating that the whole space satisfies that property: `ConnectedSpace`
## On the definition of connected sets/spaces
In informal mathematics, connected spaces are assumed to be nonempty.
We formalise the predicate without that assumption as `IsPreconnected`.
In other words, the only difference is whether the empty space counts as connected.
There are good reasons to consider the empty space to be “too simple to be simple”
See also https://ncatlab.org/nlab/show/too+simple+to+be+simple,
and in particular
https://ncatlab.org/nlab/show/too+simple+to+be+simple#relationship_to_biased_definitions.
-/
open Set Function Topology TopologicalSpace Relation
universe u v
variable {α : Type u} {β : Type v} {ι : Type*} {π : ι → Type*} [TopologicalSpace α]
{s t u v : Set α}
section Preconnected
/-- A preconnected set is one where there is no non-trivial open partition. -/
def IsPreconnected (s : Set α) : Prop :=
∀ u v : Set α, IsOpen u → IsOpen v → s ⊆ u ∪ v → (s ∩ u).Nonempty → (s ∩ v).Nonempty →
(s ∩ (u ∩ v)).Nonempty
/-- A connected set is one that is nonempty and where there is no non-trivial open partition. -/
def IsConnected (s : Set α) : Prop :=
s.Nonempty ∧ IsPreconnected s
theorem IsConnected.nonempty {s : Set α} (h : IsConnected s) : s.Nonempty :=
h.1
theorem IsConnected.isPreconnected {s : Set α} (h : IsConnected s) : IsPreconnected s :=
h.2
theorem IsPreirreducible.isPreconnected {s : Set α} (H : IsPreirreducible s) : IsPreconnected s :=
fun _ _ hu hv _ => H _ _ hu hv
theorem IsIrreducible.isConnected {s : Set α} (H : IsIrreducible s) : IsConnected s :=
⟨H.nonempty, H.isPreirreducible.isPreconnected⟩
theorem isPreconnected_empty : IsPreconnected (∅ : Set α) :=
isPreirreducible_empty.isPreconnected
theorem isConnected_singleton {x} : IsConnected ({x} : Set α) :=
isIrreducible_singleton.isConnected
theorem isPreconnected_singleton {x} : IsPreconnected ({x} : Set α) :=
isConnected_singleton.isPreconnected
theorem Set.Subsingleton.isPreconnected {s : Set α} (hs : s.Subsingleton) : IsPreconnected s :=
hs.induction_on isPreconnected_empty fun _ => isPreconnected_singleton
/-- If any point of a set is joined to a fixed point by a preconnected subset,
then the original set is preconnected as well. -/
theorem isPreconnected_of_forall {s : Set α} (x : α)
(H : ∀ y ∈ s, ∃ t, t ⊆ s ∧ x ∈ t ∧ y ∈ t ∧ IsPreconnected t) : IsPreconnected s := by
rintro u v hu hv hs ⟨z, zs, zu⟩ ⟨y, ys, yv⟩
have xs : x ∈ s := by
rcases H y ys with ⟨t, ts, xt, -, -⟩
exact ts xt
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: use `wlog xu : x ∈ u := hs xs using u v y z, v u z y`
cases hs xs with
| inl xu =>
rcases H y ys with ⟨t, ts, xt, yt, ht⟩
have := ht u v hu hv (ts.trans hs) ⟨x, xt, xu⟩ ⟨y, yt, yv⟩
exact this.imp fun z hz => ⟨ts hz.1, hz.2⟩
| inr xv =>
rcases H z zs with ⟨t, ts, xt, zt, ht⟩
have := ht v u hv hu (ts.trans <| by rwa [union_comm]) ⟨x, xt, xv⟩ ⟨z, zt, zu⟩
exact this.imp fun _ h => ⟨ts h.1, h.2.2, h.2.1⟩
/-- If any two points of a set are contained in a preconnected subset,
then the original set is preconnected as well. -/
theorem isPreconnected_of_forall_pair {s : Set α}
(H : ∀ x ∈ s, ∀ y ∈ s, ∃ t, t ⊆ s ∧ x ∈ t ∧ y ∈ t ∧ IsPreconnected t) :
IsPreconnected s := by
rcases eq_empty_or_nonempty s with (rfl | ⟨x, hx⟩)
exacts [isPreconnected_empty, isPreconnected_of_forall x fun y => H x hx y]
/-- A union of a family of preconnected sets with a common point is preconnected as well. -/
theorem isPreconnected_sUnion (x : α) (c : Set (Set α)) (H1 : ∀ s ∈ c, x ∈ s)
(H2 : ∀ s ∈ c, IsPreconnected s) : IsPreconnected (⋃₀ c) := by
apply isPreconnected_of_forall x
rintro y ⟨s, sc, ys⟩
exact ⟨s, subset_sUnion_of_mem sc, H1 s sc, ys, H2 s sc⟩
theorem isPreconnected_iUnion {ι : Sort*} {s : ι → Set α} (h₁ : (⋂ i, s i).Nonempty)
(h₂ : ∀ i, IsPreconnected (s i)) : IsPreconnected (⋃ i, s i) :=
Exists.elim h₁ fun f hf => isPreconnected_sUnion f _ hf (forall_mem_range.2 h₂)
theorem IsPreconnected.union (x : α) {s t : Set α} (H1 : x ∈ s) (H2 : x ∈ t) (H3 : IsPreconnected s)
(H4 : IsPreconnected t) : IsPreconnected (s ∪ t) :=
sUnion_pair s t ▸ isPreconnected_sUnion x {s, t} (by rintro r (rfl | rfl | h) <;> assumption)
(by rintro r (rfl | rfl | h) <;> assumption)
theorem IsPreconnected.union' {s t : Set α} (H : (s ∩ t).Nonempty) (hs : IsPreconnected s)
(ht : IsPreconnected t) : IsPreconnected (s ∪ t) := by
rcases H with ⟨x, hxs, hxt⟩
exact hs.union x hxs hxt ht
theorem IsConnected.union {s t : Set α} (H : (s ∩ t).Nonempty) (Hs : IsConnected s)
(Ht : IsConnected t) : IsConnected (s ∪ t) := by
rcases H with ⟨x, hx⟩
refine ⟨⟨x, mem_union_left t (mem_of_mem_inter_left hx)⟩, ?_⟩
exact Hs.isPreconnected.union x (mem_of_mem_inter_left hx) (mem_of_mem_inter_right hx)
Ht.isPreconnected
/-- The directed sUnion of a set S of preconnected subsets is preconnected. -/
theorem IsPreconnected.sUnion_directed {S : Set (Set α)} (K : DirectedOn (· ⊆ ·) S)
(H : ∀ s ∈ S, IsPreconnected s) : IsPreconnected (⋃₀ S) := by
rintro u v hu hv Huv ⟨a, ⟨s, hsS, has⟩, hau⟩ ⟨b, ⟨t, htS, hbt⟩, hbv⟩
obtain ⟨r, hrS, hsr, htr⟩ : ∃ r ∈ S, s ⊆ r ∧ t ⊆ r := K s hsS t htS
have Hnuv : (r ∩ (u ∩ v)).Nonempty :=
H _ hrS u v hu hv ((subset_sUnion_of_mem hrS).trans Huv) ⟨a, hsr has, hau⟩ ⟨b, htr hbt, hbv⟩
have Kruv : r ∩ (u ∩ v) ⊆ ⋃₀ S ∩ (u ∩ v) := inter_subset_inter_left _ (subset_sUnion_of_mem hrS)
exact Hnuv.mono Kruv
/-- The biUnion of a family of preconnected sets is preconnected if the graph determined by
whether two sets intersect is preconnected. -/
theorem IsPreconnected.biUnion_of_reflTransGen {ι : Type*} {t : Set ι} {s : ι → Set α}
(H : ∀ i ∈ t, IsPreconnected (s i))
(K : ∀ i, i ∈ t → ∀ j, j ∈ t → ReflTransGen (fun i j => (s i ∩ s j).Nonempty ∧ i ∈ t) i j) :
IsPreconnected (⋃ n ∈ t, s n) := by
let R := fun i j : ι => (s i ∩ s j).Nonempty ∧ i ∈ t
have P : ∀ i, i ∈ t → ∀ j, j ∈ t → ReflTransGen R i j →
∃ p, p ⊆ t ∧ i ∈ p ∧ j ∈ p ∧ IsPreconnected (⋃ j ∈ p, s j) := fun i hi j hj h => by
induction h with
| refl =>
refine ⟨{i}, singleton_subset_iff.mpr hi, mem_singleton i, mem_singleton i, ?_⟩
rw [biUnion_singleton]
exact H i hi
| @tail j k _ hjk ih =>
obtain ⟨p, hpt, hip, hjp, hp⟩ := ih hjk.2
refine ⟨insert k p, insert_subset_iff.mpr ⟨hj, hpt⟩, mem_insert_of_mem k hip,
mem_insert k p, ?_⟩
rw [biUnion_insert]
refine (H k hj).union' (hjk.1.mono ?_) hp
rw [inter_comm]
exact inter_subset_inter_right _ (subset_biUnion_of_mem hjp)
refine isPreconnected_of_forall_pair ?_
intro x hx y hy
obtain ⟨i : ι, hi : i ∈ t, hxi : x ∈ s i⟩ := mem_iUnion₂.1 hx
obtain ⟨j : ι, hj : j ∈ t, hyj : y ∈ s j⟩ := mem_iUnion₂.1 hy
obtain ⟨p, hpt, hip, hjp, hp⟩ := P i hi j hj (K i hi j hj)
exact ⟨⋃ j ∈ p, s j, biUnion_subset_biUnion_left hpt, mem_biUnion hip hxi,
mem_biUnion hjp hyj, hp⟩
/-- The biUnion of a family of preconnected sets is preconnected if the graph determined by
whether two sets intersect is preconnected. -/
theorem IsConnected.biUnion_of_reflTransGen {ι : Type*} {t : Set ι} {s : ι → Set α}
(ht : t.Nonempty) (H : ∀ i ∈ t, IsConnected (s i))
(K : ∀ i, i ∈ t → ∀ j, j ∈ t → ReflTransGen (fun i j : ι => (s i ∩ s j).Nonempty ∧ i ∈ t) i j) :
IsConnected (⋃ n ∈ t, s n) :=
⟨nonempty_biUnion.2 <| ⟨ht.some, ht.some_mem, (H _ ht.some_mem).nonempty⟩,
IsPreconnected.biUnion_of_reflTransGen (fun i hi => (H i hi).isPreconnected) K⟩
/-- Preconnectedness of the iUnion of a family of preconnected sets
indexed by the vertices of a preconnected graph,
where two vertices are joined when the corresponding sets intersect. -/
theorem IsPreconnected.iUnion_of_reflTransGen {ι : Type*} {s : ι → Set α}
(H : ∀ i, IsPreconnected (s i))
(K : ∀ i j, ReflTransGen (fun i j : ι => (s i ∩ s j).Nonempty) i j) :
IsPreconnected (⋃ n, s n) := by
rw [← biUnion_univ]
exact IsPreconnected.biUnion_of_reflTransGen (fun i _ => H i) fun i _ j _ => by
simpa [mem_univ] using K i j
theorem IsConnected.iUnion_of_reflTransGen {ι : Type*} [Nonempty ι] {s : ι → Set α}
(H : ∀ i, IsConnected (s i))
(K : ∀ i j, ReflTransGen (fun i j : ι => (s i ∩ s j).Nonempty) i j) : IsConnected (⋃ n, s n) :=
⟨nonempty_iUnion.2 <| Nonempty.elim ‹_› fun i : ι => ⟨i, (H _).nonempty⟩,
IsPreconnected.iUnion_of_reflTransGen (fun i => (H i).isPreconnected) K⟩
section SuccOrder
open Order
variable [LinearOrder β] [SuccOrder β] [IsSuccArchimedean β]
/-- The iUnion of connected sets indexed by a type with an archimedean successor (like `ℕ` or `ℤ`)
such that any two neighboring sets meet is preconnected. -/
theorem IsPreconnected.iUnion_of_chain {s : β → Set α} (H : ∀ n, IsPreconnected (s n))
(K : ∀ n, (s n ∩ s (succ n)).Nonempty) : IsPreconnected (⋃ n, s n) :=
IsPreconnected.iUnion_of_reflTransGen H fun _ _ =>
reflTransGen_of_succ _ (fun i _ => K i) fun i _ => by
rw [inter_comm]
exact K i
/-- The iUnion of connected sets indexed by a type with an archimedean successor (like `ℕ` or `ℤ`)
such that any two neighboring sets meet is connected. -/
theorem IsConnected.iUnion_of_chain [Nonempty β] {s : β → Set α} (H : ∀ n, IsConnected (s n))
(K : ∀ n, (s n ∩ s (succ n)).Nonempty) : IsConnected (⋃ n, s n) :=
IsConnected.iUnion_of_reflTransGen H fun _ _ =>
reflTransGen_of_succ _ (fun i _ => K i) fun i _ => by
rw [inter_comm]
exact K i
/-- The iUnion of preconnected sets indexed by a subset of a type with an archimedean successor
(like `ℕ` or `ℤ`) such that any two neighboring sets meet is preconnected. -/
theorem IsPreconnected.biUnion_of_chain {s : β → Set α} {t : Set β} (ht : OrdConnected t)
(H : ∀ n ∈ t, IsPreconnected (s n))
(K : ∀ n : β, n ∈ t → succ n ∈ t → (s n ∩ s (succ n)).Nonempty) :
IsPreconnected (⋃ n ∈ t, s n) := by
have h1 : ∀ {i j k : β}, i ∈ t → j ∈ t → k ∈ Ico i j → k ∈ t := fun hi hj hk =>
ht.out hi hj (Ico_subset_Icc_self hk)
have h2 : ∀ {i j k : β}, i ∈ t → j ∈ t → k ∈ Ico i j → succ k ∈ t := fun hi hj hk =>
ht.out hi hj ⟨hk.1.trans <| le_succ _, succ_le_of_lt hk.2⟩
have h3 : ∀ {i j k : β}, i ∈ t → j ∈ t → k ∈ Ico i j → (s k ∩ s (succ k)).Nonempty :=
fun hi hj hk => K _ (h1 hi hj hk) (h2 hi hj hk)
refine IsPreconnected.biUnion_of_reflTransGen H fun i hi j hj => ?_
exact reflTransGen_of_succ _ (fun k hk => ⟨h3 hi hj hk, h1 hi hj hk⟩) fun k hk =>
⟨by rw [inter_comm]; exact h3 hj hi hk, h2 hj hi hk⟩
/-- The iUnion of connected sets indexed by a subset of a type with an archimedean successor
(like `ℕ` or `ℤ`) such that any two neighboring sets meet is preconnected. -/
theorem IsConnected.biUnion_of_chain {s : β → Set α} {t : Set β} (hnt : t.Nonempty)
(ht : OrdConnected t) (H : ∀ n ∈ t, IsConnected (s n))
(K : ∀ n : β, n ∈ t → succ n ∈ t → (s n ∩ s (succ n)).Nonempty) : IsConnected (⋃ n ∈ t, s n) :=
⟨nonempty_biUnion.2 <| ⟨hnt.some, hnt.some_mem, (H _ hnt.some_mem).nonempty⟩,
IsPreconnected.biUnion_of_chain ht (fun i hi => (H i hi).isPreconnected) K⟩
end SuccOrder
/-- Theorem of bark and tree: if a set is within a preconnected set and its closure, then it is
preconnected as well. See also `IsConnected.subset_closure`. -/
protected theorem IsPreconnected.subset_closure {s : Set α} {t : Set α} (H : IsPreconnected s)
(Kst : s ⊆ t) (Ktcs : t ⊆ closure s) : IsPreconnected t :=
fun u v hu hv htuv ⟨_y, hyt, hyu⟩ ⟨_z, hzt, hzv⟩ =>
let ⟨p, hpu, hps⟩ := mem_closure_iff.1 (Ktcs hyt) u hu hyu
let ⟨q, hqv, hqs⟩ := mem_closure_iff.1 (Ktcs hzt) v hv hzv
let ⟨r, hrs, hruv⟩ := H u v hu hv (Subset.trans Kst htuv) ⟨p, hps, hpu⟩ ⟨q, hqs, hqv⟩
⟨r, Kst hrs, hruv⟩
/-- Theorem of bark and tree: if a set is within a connected set and its closure, then it is
connected as well. See also `IsPreconnected.subset_closure`. -/
protected theorem IsConnected.subset_closure {s : Set α} {t : Set α} (H : IsConnected s)
(Kst : s ⊆ t) (Ktcs : t ⊆ closure s) : IsConnected t :=
⟨Nonempty.mono Kst H.left, IsPreconnected.subset_closure H.right Kst Ktcs⟩
/-- The closure of a preconnected set is preconnected as well. -/
protected theorem IsPreconnected.closure {s : Set α} (H : IsPreconnected s) :
IsPreconnected (closure s) :=
IsPreconnected.subset_closure H subset_closure Subset.rfl
/-- The closure of a connected set is connected as well. -/
protected theorem IsConnected.closure {s : Set α} (H : IsConnected s) : IsConnected (closure s) :=
IsConnected.subset_closure H subset_closure <| Subset.rfl
/-- The image of a preconnected set is preconnected as well. -/
protected theorem IsPreconnected.image [TopologicalSpace β] {s : Set α} (H : IsPreconnected s)
(f : α → β) (hf : ContinuousOn f s) : IsPreconnected (f '' s) := by
-- Unfold/destruct definitions in hypotheses
rintro u v hu hv huv ⟨_, ⟨x, xs, rfl⟩, xu⟩ ⟨_, ⟨y, ys, rfl⟩, yv⟩
rcases continuousOn_iff'.1 hf u hu with ⟨u', hu', u'_eq⟩
rcases continuousOn_iff'.1 hf v hv with ⟨v', hv', v'_eq⟩
-- Reformulate `huv : f '' s ⊆ u ∪ v` in terms of `u'` and `v'`
replace huv : s ⊆ u' ∪ v' := by
rw [image_subset_iff, preimage_union] at huv
replace huv := subset_inter huv Subset.rfl
rw [union_inter_distrib_right, u'_eq, v'_eq, ← union_inter_distrib_right] at huv
exact (subset_inter_iff.1 huv).1
-- Now `s ⊆ u' ∪ v'`, so we can apply `‹IsPreconnected s›`
obtain ⟨z, hz⟩ : (s ∩ (u' ∩ v')).Nonempty := by
refine H u' v' hu' hv' huv ⟨x, ?_⟩ ⟨y, ?_⟩ <;> rw [inter_comm]
exacts [u'_eq ▸ ⟨xu, xs⟩, v'_eq ▸ ⟨yv, ys⟩]
rw [← inter_self s, inter_assoc, inter_left_comm s u', ← inter_assoc, inter_comm s, inter_comm s,
← u'_eq, ← v'_eq] at hz
exact ⟨f z, ⟨z, hz.1.2, rfl⟩, hz.1.1, hz.2.1⟩
/-- The image of a connected set is connected as well. -/
protected theorem IsConnected.image [TopologicalSpace β] {s : Set α} (H : IsConnected s) (f : α → β)
(hf : ContinuousOn f s) : IsConnected (f '' s) :=
⟨image_nonempty.mpr H.nonempty, H.isPreconnected.image f hf⟩
theorem isPreconnected_closed_iff {s : Set α} :
IsPreconnected s ↔ ∀ t t', IsClosed t → IsClosed t' →
s ⊆ t ∪ t' → (s ∩ t).Nonempty → (s ∩ t').Nonempty → (s ∩ (t ∩ t')).Nonempty :=
⟨by
rintro h t t' ht ht' htt' ⟨x, xs, xt⟩ ⟨y, ys, yt'⟩
rw [← not_disjoint_iff_nonempty_inter, ← subset_compl_iff_disjoint_right, compl_inter]
intro h'
have xt' : x ∉ t' := (h' xs).resolve_left (absurd xt)
have yt : y ∉ t := (h' ys).resolve_right (absurd yt')
have := h _ _ ht.isOpen_compl ht'.isOpen_compl h' ⟨y, ys, yt⟩ ⟨x, xs, xt'⟩
rw [← compl_union] at this
exact this.ne_empty htt'.disjoint_compl_right.inter_eq,
by
rintro h u v hu hv huv ⟨x, xs, xu⟩ ⟨y, ys, yv⟩
rw [← not_disjoint_iff_nonempty_inter, ← subset_compl_iff_disjoint_right, compl_inter]
intro h'
have xv : x ∉ v := (h' xs).elim (absurd xu) id
have yu : y ∉ u := (h' ys).elim id (absurd yv)
have := h _ _ hu.isClosed_compl hv.isClosed_compl h' ⟨y, ys, yu⟩ ⟨x, xs, xv⟩
rw [← compl_union] at this
exact this.ne_empty huv.disjoint_compl_right.inter_eq⟩
theorem Topology.IsInducing.isPreconnected_image [TopologicalSpace β] {s : Set α} {f : α → β}
(hf : IsInducing f) : IsPreconnected (f '' s) ↔ IsPreconnected s := by
refine ⟨fun h => ?_, fun h => h.image _ hf.continuous.continuousOn⟩
rintro u v hu' hv' huv ⟨x, hxs, hxu⟩ ⟨y, hys, hyv⟩
rcases hf.isOpen_iff.1 hu' with ⟨u, hu, rfl⟩
rcases hf.isOpen_iff.1 hv' with ⟨v, hv, rfl⟩
replace huv : f '' s ⊆ u ∪ v := by rwa [image_subset_iff]
rcases h u v hu hv huv ⟨f x, mem_image_of_mem _ hxs, hxu⟩ ⟨f y, mem_image_of_mem _ hys, hyv⟩ with
⟨_, ⟨z, hzs, rfl⟩, hzuv⟩
exact ⟨z, hzs, hzuv⟩
@[deprecated (since := "2024-10-28")]
alias Inducing.isPreconnected_image := IsInducing.isPreconnected_image
/- TODO: The following lemmas about connection of preimages hold more generally for strict maps
(the quotient and subspace topologies of the image agree) whose fibers are preconnected. -/
theorem IsPreconnected.preimage_of_isOpenMap [TopologicalSpace β] {f : α → β} {s : Set β}
(hs : IsPreconnected s) (hinj : Function.Injective f) (hf : IsOpenMap f) (hsf : s ⊆ range f) :
IsPreconnected (f ⁻¹' s) := fun u v hu hv hsuv hsu hsv => by
replace hsf : f '' (f ⁻¹' s) = s := image_preimage_eq_of_subset hsf
obtain ⟨_, has, ⟨a, hau, rfl⟩, hav⟩ : (s ∩ (f '' u ∩ f '' v)).Nonempty := by
refine hs (f '' u) (f '' v) (hf u hu) (hf v hv) ?_ ?_ ?_
· simpa only [hsf, image_union] using image_subset f hsuv
· simpa only [image_preimage_inter] using hsu.image f
· simpa only [image_preimage_inter] using hsv.image f
· exact ⟨a, has, hau, hinj.mem_set_image.1 hav⟩
theorem IsPreconnected.preimage_of_isClosedMap [TopologicalSpace β] {s : Set β}
(hs : IsPreconnected s) {f : α → β} (hinj : Function.Injective f) (hf : IsClosedMap f)
(hsf : s ⊆ range f) : IsPreconnected (f ⁻¹' s) :=
isPreconnected_closed_iff.2 fun u v hu hv hsuv hsu hsv => by
replace hsf : f '' (f ⁻¹' s) = s := image_preimage_eq_of_subset hsf
obtain ⟨_, has, ⟨a, hau, rfl⟩, hav⟩ : (s ∩ (f '' u ∩ f '' v)).Nonempty := by
refine isPreconnected_closed_iff.1 hs (f '' u) (f '' v) (hf u hu) (hf v hv) ?_ ?_ ?_
· simpa only [hsf, image_union] using image_subset f hsuv
· simpa only [image_preimage_inter] using hsu.image f
· simpa only [image_preimage_inter] using hsv.image f
· exact ⟨a, has, hau, hinj.mem_set_image.1 hav⟩
theorem IsConnected.preimage_of_isOpenMap [TopologicalSpace β] {s : Set β} (hs : IsConnected s)
{f : α → β} (hinj : Function.Injective f) (hf : IsOpenMap f) (hsf : s ⊆ range f) :
IsConnected (f ⁻¹' s) :=
⟨hs.nonempty.preimage' hsf, hs.isPreconnected.preimage_of_isOpenMap hinj hf hsf⟩
theorem IsConnected.preimage_of_isClosedMap [TopologicalSpace β] {s : Set β} (hs : IsConnected s)
{f : α → β} (hinj : Function.Injective f) (hf : IsClosedMap f) (hsf : s ⊆ range f) :
IsConnected (f ⁻¹' s) :=
⟨hs.nonempty.preimage' hsf, hs.isPreconnected.preimage_of_isClosedMap hinj hf hsf⟩
theorem IsPreconnected.subset_or_subset (hu : IsOpen u) (hv : IsOpen v) (huv : Disjoint u v)
(hsuv : s ⊆ u ∪ v) (hs : IsPreconnected s) : s ⊆ u ∨ s ⊆ v := by
specialize hs u v hu hv hsuv
obtain hsu | hsu := (s ∩ u).eq_empty_or_nonempty
· exact Or.inr ((Set.disjoint_iff_inter_eq_empty.2 hsu).subset_right_of_subset_union hsuv)
· replace hs := mt (hs hsu)
simp_rw [Set.not_nonempty_iff_eq_empty, ← Set.disjoint_iff_inter_eq_empty,
disjoint_iff_inter_eq_empty.1 huv] at hs
exact Or.inl ((hs s.disjoint_empty).subset_left_of_subset_union hsuv)
theorem IsPreconnected.subset_left_of_subset_union (hu : IsOpen u) (hv : IsOpen v)
(huv : Disjoint u v) (hsuv : s ⊆ u ∪ v) (hsu : (s ∩ u).Nonempty) (hs : IsPreconnected s) :
s ⊆ u :=
Disjoint.subset_left_of_subset_union hsuv
(by
by_contra hsv
rw [not_disjoint_iff_nonempty_inter] at hsv
obtain ⟨x, _, hx⟩ := hs u v hu hv hsuv hsu hsv
exact Set.disjoint_iff.1 huv hx)
theorem IsPreconnected.subset_right_of_subset_union (hu : IsOpen u) (hv : IsOpen v)
(huv : Disjoint u v) (hsuv : s ⊆ u ∪ v) (hsv : (s ∩ v).Nonempty) (hs : IsPreconnected s) :
s ⊆ v :=
hs.subset_left_of_subset_union hv hu huv.symm (union_comm u v ▸ hsuv) hsv
/-- If a preconnected set `s` intersects an open set `u`, and limit points of `u` inside `s` are
contained in `u`, then the whole set `s` is contained in `u`. -/
theorem IsPreconnected.subset_of_closure_inter_subset (hs : IsPreconnected s) (hu : IsOpen u)
(h'u : (s ∩ u).Nonempty) (h : closure u ∩ s ⊆ u) : s ⊆ u := by
have A : s ⊆ u ∪ (closure u)ᶜ := by
intro x hx
by_cases xu : x ∈ u
· exact Or.inl xu
· right
intro h'x
exact xu (h (mem_inter h'x hx))
apply hs.subset_left_of_subset_union hu isClosed_closure.isOpen_compl _ A h'u
exact disjoint_compl_right.mono_right (compl_subset_compl.2 subset_closure)
theorem IsPreconnected.prod [TopologicalSpace β] {s : Set α} {t : Set β} (hs : IsPreconnected s)
(ht : IsPreconnected t) : IsPreconnected (s ×ˢ t) := by
apply isPreconnected_of_forall_pair
rintro ⟨a₁, b₁⟩ ⟨ha₁, hb₁⟩ ⟨a₂, b₂⟩ ⟨ha₂, hb₂⟩
refine ⟨Prod.mk a₁ '' t ∪ flip Prod.mk b₂ '' s, ?_, .inl ⟨b₁, hb₁, rfl⟩, .inr ⟨a₂, ha₂, rfl⟩, ?_⟩
· rintro _ (⟨y, hy, rfl⟩ | ⟨x, hx, rfl⟩)
exacts [⟨ha₁, hy⟩, ⟨hx, hb₂⟩]
· exact (ht.image _ (by fun_prop)).union (a₁, b₂) ⟨b₂, hb₂, rfl⟩
⟨a₁, ha₁, rfl⟩ (hs.image _ (Continuous.prodMk_left _).continuousOn)
theorem IsConnected.prod [TopologicalSpace β] {s : Set α} {t : Set β} (hs : IsConnected s)
(ht : IsConnected t) : IsConnected (s ×ˢ t) :=
⟨hs.1.prod ht.1, hs.2.prod ht.2⟩
theorem isPreconnected_univ_pi [∀ i, TopologicalSpace (π i)] {s : ∀ i, Set (π i)}
(hs : ∀ i, IsPreconnected (s i)) : IsPreconnected (pi univ s) := by
rintro u v uo vo hsuv ⟨f, hfs, hfu⟩ ⟨g, hgs, hgv⟩
classical
rcases exists_finset_piecewise_mem_of_mem_nhds (uo.mem_nhds hfu) g with ⟨I, hI⟩
induction I using Finset.induction_on with
| empty =>
refine ⟨g, hgs, ⟨?_, hgv⟩⟩
simpa using hI
| insert i I _ ihI =>
rw [Finset.piecewise_insert] at hI
have := I.piecewise_mem_set_pi hfs hgs
refine (hsuv this).elim ihI fun h => ?_
set S := update (I.piecewise f g) i '' s i
have hsub : S ⊆ pi univ s := by
refine image_subset_iff.2 fun z hz => ?_
rwa [update_preimage_univ_pi]
exact fun j _ => this j trivial
have hconn : IsPreconnected S :=
(hs i).image _ (continuous_const.update i continuous_id).continuousOn
have hSu : (S ∩ u).Nonempty := ⟨_, mem_image_of_mem _ (hfs _ trivial), hI⟩
have hSv : (S ∩ v).Nonempty := ⟨_, ⟨_, this _ trivial, update_eq_self _ _⟩, h⟩
refine (hconn u v uo vo (hsub.trans hsuv) hSu hSv).mono ?_
exact inter_subset_inter_left _ hsub
@[simp]
theorem isConnected_univ_pi [∀ i, TopologicalSpace (π i)] {s : ∀ i, Set (π i)} :
IsConnected (pi univ s) ↔ ∀ i, IsConnected (s i) := by
simp only [IsConnected, ← univ_pi_nonempty_iff, forall_and, and_congr_right_iff]
refine fun hne => ⟨fun hc i => ?_, isPreconnected_univ_pi⟩
rw [← eval_image_univ_pi hne]
exact hc.image _ (continuous_apply _).continuousOn
/-- The connected component of a point is the maximal connected set
that contains this point. -/
def connectedComponent (x : α) : Set α :=
⋃₀ { s : Set α | IsPreconnected s ∧ x ∈ s }
open Classical in
/-- Given a set `F` in a topological space `α` and a point `x : α`, the connected
component of `x` in `F` is the connected component of `x` in the subtype `F` seen as
a set in `α`. This definition does not make sense if `x` is not in `F` so we return the
empty set in this case. -/
def connectedComponentIn (F : Set α) (x : α) : Set α :=
if h : x ∈ F then (↑) '' connectedComponent (⟨x, h⟩ : F) else ∅
theorem connectedComponentIn_eq_image {F : Set α} {x : α} (h : x ∈ F) :
connectedComponentIn F x = (↑) '' connectedComponent (⟨x, h⟩ : F) :=
dif_pos h
theorem connectedComponentIn_eq_empty {F : Set α} {x : α} (h : x ∉ F) :
connectedComponentIn F x = ∅ :=
dif_neg h
theorem mem_connectedComponent {x : α} : x ∈ connectedComponent x :=
mem_sUnion_of_mem (mem_singleton x) ⟨isPreconnected_singleton, mem_singleton x⟩
theorem mem_connectedComponentIn {x : α} {F : Set α} (hx : x ∈ F) :
x ∈ connectedComponentIn F x := by
simp [connectedComponentIn_eq_image hx, mem_connectedComponent, hx]
theorem connectedComponent_nonempty {x : α} : (connectedComponent x).Nonempty :=
⟨x, mem_connectedComponent⟩
theorem connectedComponentIn_nonempty_iff {x : α} {F : Set α} :
(connectedComponentIn F x).Nonempty ↔ x ∈ F := by
rw [connectedComponentIn]
split_ifs <;> simp [connectedComponent_nonempty, *]
theorem connectedComponentIn_subset (F : Set α) (x : α) : connectedComponentIn F x ⊆ F := by
rw [connectedComponentIn]
split_ifs <;> simp
theorem isPreconnected_connectedComponent {x : α} : IsPreconnected (connectedComponent x) :=
isPreconnected_sUnion x _ (fun _ => And.right) fun _ => And.left
theorem isPreconnected_connectedComponentIn {x : α} {F : Set α} :
IsPreconnected (connectedComponentIn F x) := by
rw [connectedComponentIn]; split_ifs
· exact IsInducing.subtypeVal.isPreconnected_image.mpr isPreconnected_connectedComponent
· exact isPreconnected_empty
theorem isConnected_connectedComponent {x : α} : IsConnected (connectedComponent x) :=
⟨⟨x, mem_connectedComponent⟩, isPreconnected_connectedComponent⟩
theorem isConnected_connectedComponentIn_iff {x : α} {F : Set α} :
IsConnected (connectedComponentIn F x) ↔ x ∈ F := by
simp_rw [← connectedComponentIn_nonempty_iff, IsConnected, isPreconnected_connectedComponentIn,
and_true]
theorem IsPreconnected.subset_connectedComponent {x : α} {s : Set α} (H1 : IsPreconnected s)
(H2 : x ∈ s) : s ⊆ connectedComponent x := fun _z hz => mem_sUnion_of_mem hz ⟨H1, H2⟩
theorem IsPreconnected.subset_connectedComponentIn {x : α} {F : Set α} (hs : IsPreconnected s)
(hxs : x ∈ s) (hsF : s ⊆ F) : s ⊆ connectedComponentIn F x := by
have : IsPreconnected (((↑) : F → α) ⁻¹' s) := by
refine IsInducing.subtypeVal.isPreconnected_image.mp ?_
rwa [Subtype.image_preimage_coe, inter_eq_right.mpr hsF]
have h2xs : (⟨x, hsF hxs⟩ : F) ∈ (↑) ⁻¹' s := by
rw [mem_preimage]
exact hxs
have := this.subset_connectedComponent h2xs
rw [connectedComponentIn_eq_image (hsF hxs)]
refine Subset.trans ?_ (image_subset _ this)
rw [Subtype.image_preimage_coe, inter_eq_right.mpr hsF]
theorem IsConnected.subset_connectedComponent {x : α} {s : Set α} (H1 : IsConnected s)
(H2 : x ∈ s) : s ⊆ connectedComponent x :=
H1.2.subset_connectedComponent H2
theorem IsPreconnected.connectedComponentIn {x : α} {F : Set α} (h : IsPreconnected F)
(hx : x ∈ F) : connectedComponentIn F x = F :=
(connectedComponentIn_subset F x).antisymm (h.subset_connectedComponentIn hx subset_rfl)
theorem connectedComponent_eq {x y : α} (h : y ∈ connectedComponent x) :
connectedComponent x = connectedComponent y :=
eq_of_subset_of_subset (isConnected_connectedComponent.subset_connectedComponent h)
(isConnected_connectedComponent.subset_connectedComponent
(Set.mem_of_mem_of_subset mem_connectedComponent
(isConnected_connectedComponent.subset_connectedComponent h)))
theorem connectedComponent_eq_iff_mem {x y : α} :
connectedComponent x = connectedComponent y ↔ x ∈ connectedComponent y :=
⟨fun h => h ▸ mem_connectedComponent, fun h => (connectedComponent_eq h).symm⟩
theorem connectedComponentIn_eq {x y : α} {F : Set α} (h : y ∈ connectedComponentIn F x) :
connectedComponentIn F x = connectedComponentIn F y := by
have hx : x ∈ F := connectedComponentIn_nonempty_iff.mp ⟨y, h⟩
simp_rw [connectedComponentIn_eq_image hx] at h ⊢
obtain ⟨⟨y, hy⟩, h2y, rfl⟩ := h
simp_rw [connectedComponentIn_eq_image hy, connectedComponent_eq h2y]
theorem connectedComponentIn_univ (x : α) : connectedComponentIn univ x = connectedComponent x :=
subset_antisymm
(isPreconnected_connectedComponentIn.subset_connectedComponent <|
mem_connectedComponentIn trivial)
(isPreconnected_connectedComponent.subset_connectedComponentIn mem_connectedComponent <|
subset_univ _)
theorem connectedComponent_disjoint {x y : α} (h : connectedComponent x ≠ connectedComponent y) :
Disjoint (connectedComponent x) (connectedComponent y) :=
Set.disjoint_left.2 fun _ h1 h2 =>
h ((connectedComponent_eq h1).trans (connectedComponent_eq h2).symm)
theorem isClosed_connectedComponent {x : α} : IsClosed (connectedComponent x) :=
closure_subset_iff_isClosed.1 <|
isConnected_connectedComponent.closure.subset_connectedComponent <|
subset_closure mem_connectedComponent
theorem Continuous.image_connectedComponent_subset [TopologicalSpace β] {f : α → β}
(h : Continuous f) (a : α) : f '' connectedComponent a ⊆ connectedComponent (f a) :=
(isConnected_connectedComponent.image f h.continuousOn).subset_connectedComponent
((mem_image f (connectedComponent a) (f a)).2 ⟨a, mem_connectedComponent, rfl⟩)
theorem Continuous.image_connectedComponentIn_subset [TopologicalSpace β] {f : α → β} {s : Set α}
{a : α} (hf : Continuous f) (hx : a ∈ s) :
f '' connectedComponentIn s a ⊆ connectedComponentIn (f '' s) (f a) :=
(isPreconnected_connectedComponentIn.image _ hf.continuousOn).subset_connectedComponentIn
(mem_image_of_mem _ <| mem_connectedComponentIn hx)
(image_subset _ <| connectedComponentIn_subset _ _)
theorem Continuous.mapsTo_connectedComponent [TopologicalSpace β] {f : α → β} (h : Continuous f)
(a : α) : MapsTo f (connectedComponent a) (connectedComponent (f a)) :=
mapsTo'.2 <| h.image_connectedComponent_subset a
theorem Continuous.mapsTo_connectedComponentIn [TopologicalSpace β] {f : α → β} {s : Set α}
(h : Continuous f) {a : α} (hx : a ∈ s) :
MapsTo f (connectedComponentIn s a) (connectedComponentIn (f '' s) (f a)) :=
mapsTo'.2 <| image_connectedComponentIn_subset h hx
theorem irreducibleComponent_subset_connectedComponent {x : α} :
irreducibleComponent x ⊆ connectedComponent x :=
isIrreducible_irreducibleComponent.isConnected.subset_connectedComponent mem_irreducibleComponent
@[mono]
theorem connectedComponentIn_mono (x : α) {F G : Set α} (h : F ⊆ G) :
connectedComponentIn F x ⊆ connectedComponentIn G x := by
by_cases hx : x ∈ F
· rw [connectedComponentIn_eq_image hx, connectedComponentIn_eq_image (h hx), ←
show ((↑) : G → α) ∘ inclusion h = (↑) from rfl, image_comp]
exact image_subset _ ((continuous_inclusion h).image_connectedComponent_subset ⟨x, hx⟩)
· rw [connectedComponentIn_eq_empty hx]
exact Set.empty_subset _
/-- A preconnected space is one where there is no non-trivial open partition. -/
class PreconnectedSpace (α : Type u) [TopologicalSpace α] : Prop where
/-- The universal set `Set.univ` in a preconnected space is a preconnected set. -/
isPreconnected_univ : IsPreconnected (univ : Set α)
export PreconnectedSpace (isPreconnected_univ)
/-- A connected space is a nonempty one where there is no non-trivial open partition. -/
class ConnectedSpace (α : Type u) [TopologicalSpace α] : Prop extends PreconnectedSpace α where
/-- A connected space is nonempty. -/
toNonempty : Nonempty α
attribute [instance 50] ConnectedSpace.toNonempty -- see Note [lower instance priority]
-- see Note [lower instance priority]
theorem isConnected_univ [ConnectedSpace α] : IsConnected (univ : Set α) :=
⟨univ_nonempty, isPreconnected_univ⟩
lemma preconnectedSpace_iff_univ : PreconnectedSpace α ↔ IsPreconnected (univ : Set α) :=
⟨fun h ↦ h.1, fun h ↦ ⟨h⟩⟩
lemma connectedSpace_iff_univ : ConnectedSpace α ↔ IsConnected (univ : Set α) :=
⟨fun h ↦ ⟨univ_nonempty, h.1.1⟩,
fun h ↦ ConnectedSpace.mk (toPreconnectedSpace := ⟨h.2⟩) ⟨h.1.some⟩⟩
theorem isPreconnected_range [TopologicalSpace β] [PreconnectedSpace α] {f : α → β}
(h : Continuous f) : IsPreconnected (range f) :=
@image_univ _ _ f ▸ isPreconnected_univ.image _ h.continuousOn
theorem isConnected_range [TopologicalSpace β] [ConnectedSpace α] {f : α → β} (h : Continuous f) :
IsConnected (range f) :=
⟨range_nonempty f, isPreconnected_range h⟩
theorem Function.Surjective.connectedSpace [ConnectedSpace α] [TopologicalSpace β]
{f : α → β} (hf : Surjective f) (hf' : Continuous f) : ConnectedSpace β := by
rw [connectedSpace_iff_univ, ← hf.range_eq]
exact isConnected_range hf'
instance Quotient.instConnectedSpace {s : Setoid α} [ConnectedSpace α] :
ConnectedSpace (Quotient s) :=
Quotient.mk'_surjective.connectedSpace continuous_coinduced_rng
theorem DenseRange.preconnectedSpace [TopologicalSpace β] [PreconnectedSpace α] {f : α → β}
(hf : DenseRange f) (hc : Continuous f) : PreconnectedSpace β :=
⟨hf.closure_eq ▸ (isPreconnected_range hc).closure⟩
theorem connectedSpace_iff_connectedComponent :
ConnectedSpace α ↔ ∃ x : α, connectedComponent x = univ := by
constructor
· rintro ⟨⟨x⟩⟩
exact
⟨x, eq_univ_of_univ_subset <| isPreconnected_univ.subset_connectedComponent (mem_univ x)⟩
· rintro ⟨x, h⟩
haveI : PreconnectedSpace α :=
⟨by rw [← h]; exact isPreconnected_connectedComponent⟩
exact ⟨⟨x⟩⟩
theorem preconnectedSpace_iff_connectedComponent :
PreconnectedSpace α ↔ ∀ x : α, connectedComponent x = univ := by
constructor
· intro h x
exact eq_univ_of_univ_subset <| isPreconnected_univ.subset_connectedComponent (mem_univ x)
· intro h
rcases isEmpty_or_nonempty α with hα | hα
· exact ⟨by rw [univ_eq_empty_iff.mpr hα]; exact isPreconnected_empty⟩
· exact ⟨by rw [← h (Classical.choice hα)]; exact isPreconnected_connectedComponent⟩
@[simp]
theorem PreconnectedSpace.connectedComponent_eq_univ {X : Type*} [TopologicalSpace X]
[h : PreconnectedSpace X] (x : X) : connectedComponent x = univ :=
preconnectedSpace_iff_connectedComponent.mp h x
instance [TopologicalSpace β] [PreconnectedSpace α] [PreconnectedSpace β] :
PreconnectedSpace (α × β) :=
⟨by
rw [← univ_prod_univ]
exact isPreconnected_univ.prod isPreconnected_univ⟩
instance [TopologicalSpace β] [ConnectedSpace α] [ConnectedSpace β] : ConnectedSpace (α × β) :=
⟨inferInstance⟩
instance [∀ i, TopologicalSpace (π i)] [∀ i, PreconnectedSpace (π i)] :
PreconnectedSpace (∀ i, π i) :=
⟨by rw [← pi_univ univ]; exact isPreconnected_univ_pi fun i => isPreconnected_univ⟩
instance [∀ i, TopologicalSpace (π i)] [∀ i, ConnectedSpace (π i)] : ConnectedSpace (∀ i, π i) :=
⟨inferInstance⟩
-- see Note [lower instance priority]
instance (priority := 100) PreirreducibleSpace.preconnectedSpace (α : Type u) [TopologicalSpace α]
[PreirreducibleSpace α] : PreconnectedSpace α :=
⟨isPreirreducible_univ.isPreconnected⟩
-- see Note [lower instance priority]
instance (priority := 100) IrreducibleSpace.connectedSpace (α : Type u) [TopologicalSpace α]
[IrreducibleSpace α] : ConnectedSpace α where toNonempty := IrreducibleSpace.toNonempty
theorem Subtype.preconnectedSpace {s : Set α} (h : IsPreconnected s) : PreconnectedSpace s where
isPreconnected_univ := by
rwa [← IsInducing.subtypeVal.isPreconnected_image, image_univ, Subtype.range_val]
theorem Subtype.connectedSpace {s : Set α} (h : IsConnected s) : ConnectedSpace s where
toPreconnectedSpace := Subtype.preconnectedSpace h.isPreconnected
toNonempty := h.nonempty.to_subtype
theorem isPreconnected_iff_preconnectedSpace {s : Set α} : IsPreconnected s ↔ PreconnectedSpace s :=
⟨Subtype.preconnectedSpace, fun h => by
simpa using isPreconnected_univ.image ((↑) : s → α) continuous_subtype_val.continuousOn⟩
theorem isConnected_iff_connectedSpace {s : Set α} : IsConnected s ↔ ConnectedSpace s :=
⟨Subtype.connectedSpace, fun h =>
⟨nonempty_subtype.mp h.2, isPreconnected_iff_preconnectedSpace.mpr h.1⟩⟩
end Preconnected
| Mathlib/Topology/Connected/Basic.lean | 1,311 | 1,313 | |
/-
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, Jeremy Avigad
-/
import Mathlib.Data.Set.Finite.Basic
import Mathlib.Data.Set.Finite.Range
import Mathlib.Data.Set.Lattice
import Mathlib.Topology.Defs.Filter
/-!
# Openness and closedness of a set
This file provides lemmas relating to the predicates `IsOpen` and `IsClosed` of a set endowed with
a topology.
## Implementation notes
Topology in mathlib heavily uses filters (even more than in Bourbaki). See explanations in
<https://leanprover-community.github.io/theories/topology.html>.
## References
* [N. Bourbaki, *General Topology*][bourbaki1966]
* [I. M. James, *Topologies and Uniformities*][james1999]
## Tags
topological space
-/
open Set Filter Topology
universe u v
/-- A constructor for topologies by specifying the closed sets,
and showing that they satisfy the appropriate conditions. -/
def TopologicalSpace.ofClosed {X : Type u} (T : Set (Set X)) (empty_mem : ∅ ∈ T)
(sInter_mem : ∀ A, A ⊆ T → ⋂₀ A ∈ T)
(union_mem : ∀ A, A ∈ T → ∀ B, B ∈ T → A ∪ B ∈ T) : TopologicalSpace X where
IsOpen X := Xᶜ ∈ T
isOpen_univ := by simp [empty_mem]
isOpen_inter s t hs ht := by simpa only [compl_inter] using union_mem sᶜ hs tᶜ ht
isOpen_sUnion s hs := by
simp only [Set.compl_sUnion]
exact sInter_mem (compl '' s) fun z ⟨y, hy, hz⟩ => hz ▸ hs y hy
section TopologicalSpace
variable {X : Type u} {ι : Sort v} {α : Type*} {x : X} {s s₁ s₂ t : Set X} {p p₁ p₂ : X → Prop}
lemma isOpen_mk {p h₁ h₂ h₃} : IsOpen[⟨p, h₁, h₂, h₃⟩] s ↔ p s := Iff.rfl
@[ext (iff := false)]
protected theorem TopologicalSpace.ext :
∀ {f g : TopologicalSpace X}, IsOpen[f] = IsOpen[g] → f = g
| ⟨_, _, _, _⟩, ⟨_, _, _, _⟩, rfl => rfl
protected theorem TopologicalSpace.ext_iff {t t' : TopologicalSpace X} :
t = t' ↔ ∀ s, IsOpen[t] s ↔ IsOpen[t'] s :=
⟨fun h _ => h ▸ Iff.rfl, fun h => by ext; exact h _⟩
theorem isOpen_fold {t : TopologicalSpace X} : t.IsOpen s = IsOpen[t] s :=
rfl
variable [TopologicalSpace X]
theorem isOpen_iUnion {f : ι → Set X} (h : ∀ i, IsOpen (f i)) : IsOpen (⋃ i, f i) :=
isOpen_sUnion (forall_mem_range.2 h)
theorem isOpen_biUnion {s : Set α} {f : α → Set X} (h : ∀ i ∈ s, IsOpen (f i)) :
IsOpen (⋃ i ∈ s, f i) :=
isOpen_iUnion fun i => isOpen_iUnion fun hi => h i hi
theorem IsOpen.union (h₁ : IsOpen s₁) (h₂ : IsOpen s₂) : IsOpen (s₁ ∪ s₂) := by
rw [union_eq_iUnion]; exact isOpen_iUnion (Bool.forall_bool.2 ⟨h₂, h₁⟩)
lemma isOpen_iff_of_cover {f : α → Set X} (ho : ∀ i, IsOpen (f i)) (hU : (⋃ i, f i) = univ) :
IsOpen s ↔ ∀ i, IsOpen (f i ∩ s) := by
refine ⟨fun h i ↦ (ho i).inter h, fun h ↦ ?_⟩
rw [← s.inter_univ, inter_comm, ← hU, iUnion_inter]
exact isOpen_iUnion fun i ↦ h i
@[simp] theorem isOpen_empty : IsOpen (∅ : Set X) := by
rw [← sUnion_empty]; exact isOpen_sUnion fun a => False.elim
theorem Set.Finite.isOpen_sInter {s : Set (Set X)} (hs : s.Finite) (h : ∀ t ∈ s, IsOpen t) :
IsOpen (⋂₀ s) := by
induction s, hs using Set.Finite.induction_on with
| empty => rw [sInter_empty]; exact isOpen_univ
| insert _ _ ih =>
simp only [sInter_insert, forall_mem_insert] at h ⊢
exact h.1.inter (ih h.2)
theorem Set.Finite.isOpen_biInter {s : Set α} {f : α → Set X} (hs : s.Finite)
(h : ∀ i ∈ s, IsOpen (f i)) :
IsOpen (⋂ i ∈ s, f i) :=
sInter_image f s ▸ (hs.image _).isOpen_sInter (forall_mem_image.2 h)
theorem isOpen_iInter_of_finite [Finite ι] {s : ι → Set X} (h : ∀ i, IsOpen (s i)) :
IsOpen (⋂ i, s i) :=
(finite_range _).isOpen_sInter (forall_mem_range.2 h)
theorem isOpen_biInter_finset {s : Finset α} {f : α → Set X} (h : ∀ i ∈ s, IsOpen (f i)) :
IsOpen (⋂ i ∈ s, f i) :=
s.finite_toSet.isOpen_biInter h
@[simp]
theorem isOpen_const {p : Prop} : IsOpen { _x : X | p } := by by_cases p <;> simp [*]
theorem IsOpen.and : IsOpen { x | p₁ x } → IsOpen { x | p₂ x } → IsOpen { x | p₁ x ∧ p₂ x } :=
IsOpen.inter
@[simp] theorem isOpen_compl_iff : IsOpen sᶜ ↔ IsClosed s :=
⟨fun h => ⟨h⟩, fun h => h.isOpen_compl⟩
theorem TopologicalSpace.ext_iff_isClosed {X} {t₁ t₂ : TopologicalSpace X} :
t₁ = t₂ ↔ ∀ s, IsClosed[t₁] s ↔ IsClosed[t₂] s := by
rw [TopologicalSpace.ext_iff, compl_surjective.forall]
simp only [@isOpen_compl_iff _ _ t₁, @isOpen_compl_iff _ _ t₂]
alias ⟨_, TopologicalSpace.ext_isClosed⟩ := TopologicalSpace.ext_iff_isClosed
theorem isClosed_const {p : Prop} : IsClosed { _x : X | p } := ⟨isOpen_const (p := ¬p)⟩
@[simp] theorem isClosed_empty : IsClosed (∅ : Set X) := isClosed_const
@[simp] theorem isClosed_univ : IsClosed (univ : Set X) := isClosed_const
lemma IsOpen.isLocallyClosed (hs : IsOpen s) : IsLocallyClosed s :=
⟨_, _, hs, isClosed_univ, (inter_univ _).symm⟩
lemma IsClosed.isLocallyClosed (hs : IsClosed s) : IsLocallyClosed s :=
⟨_, _, isOpen_univ, hs, (univ_inter _).symm⟩
theorem IsClosed.union : IsClosed s₁ → IsClosed s₂ → IsClosed (s₁ ∪ s₂) := by
simpa only [← isOpen_compl_iff, compl_union] using IsOpen.inter
theorem isClosed_sInter {s : Set (Set X)} : (∀ t ∈ s, IsClosed t) → IsClosed (⋂₀ s) := by
simpa only [← isOpen_compl_iff, compl_sInter, sUnion_image] using isOpen_biUnion
theorem isClosed_iInter {f : ι → Set X} (h : ∀ i, IsClosed (f i)) : IsClosed (⋂ i, f i) :=
isClosed_sInter <| forall_mem_range.2 h
theorem isClosed_biInter {s : Set α} {f : α → Set X} (h : ∀ i ∈ s, IsClosed (f i)) :
IsClosed (⋂ i ∈ s, f i) :=
isClosed_iInter fun i => isClosed_iInter <| h i
@[simp]
theorem isClosed_compl_iff {s : Set X} : IsClosed sᶜ ↔ IsOpen s := by
rw [← isOpen_compl_iff, compl_compl]
alias ⟨_, IsOpen.isClosed_compl⟩ := isClosed_compl_iff
theorem IsOpen.sdiff (h₁ : IsOpen s) (h₂ : IsClosed t) : IsOpen (s \ t) :=
IsOpen.inter h₁ h₂.isOpen_compl
theorem IsClosed.inter (h₁ : IsClosed s₁) (h₂ : IsClosed s₂) : IsClosed (s₁ ∩ s₂) := by
rw [← isOpen_compl_iff] at *
rw [compl_inter]
exact IsOpen.union h₁ h₂
theorem IsClosed.sdiff (h₁ : IsClosed s) (h₂ : IsOpen t) : IsClosed (s \ t) :=
IsClosed.inter h₁ (isClosed_compl_iff.mpr h₂)
theorem Set.Finite.isClosed_biUnion {s : Set α} {f : α → Set X} (hs : s.Finite)
(h : ∀ i ∈ s, IsClosed (f i)) :
IsClosed (⋃ i ∈ s, f i) := by
simp only [← isOpen_compl_iff, compl_iUnion] at *
exact hs.isOpen_biInter h
lemma isClosed_biUnion_finset {s : Finset α} {f : α → Set X} (h : ∀ i ∈ s, IsClosed (f i)) :
IsClosed (⋃ i ∈ s, f i) :=
s.finite_toSet.isClosed_biUnion h
theorem isClosed_iUnion_of_finite [Finite ι] {s : ι → Set X} (h : ∀ i, IsClosed (s i)) :
IsClosed (⋃ i, s i) := by
simp only [← isOpen_compl_iff, compl_iUnion] at *
exact isOpen_iInter_of_finite h
theorem isClosed_imp {p q : X → Prop} (hp : IsOpen { x | p x }) (hq : IsClosed { x | q x }) :
IsClosed { x | p x → q x } := by
simpa only [imp_iff_not_or] using hp.isClosed_compl.union hq
theorem IsClosed.not : IsClosed { a | p a } → IsOpen { a | ¬p a } :=
isOpen_compl_iff.mpr
/-!
### Limits of filters in topological spaces
In this section we define functions that return a limit of a filter (or of a function along a
filter), if it exists, and a random point otherwise. These functions are rarely used in Mathlib,
most of the theorems are written using `Filter.Tendsto`. One of the reasons is that
`Filter.limUnder f g = x` is not equivalent to `Filter.Tendsto g f (𝓝 x)` unless the codomain is a
Hausdorff space and `g` has a limit along `f`.
-/
section lim
/-- If a filter `f` is majorated by some `𝓝 x`, then it is majorated by `𝓝 (Filter.lim f)`. We
formulate this lemma with a `[Nonempty X]` argument of `lim` derived from `h` to make it useful for
types without a `[Nonempty X]` instance. Because of the built-in proof irrelevance, Lean will unify
this instance with any other instance. -/
theorem le_nhds_lim {f : Filter X} (h : ∃ x, f ≤ 𝓝 x) : f ≤ 𝓝 (@lim _ _ (nonempty_of_exists h) f) :=
Classical.epsilon_spec h
/-- If `g` tends to some `𝓝 x` along `f`, then it tends to `𝓝 (Filter.limUnder f g)`. We formulate
this lemma with a `[Nonempty X]` argument of `lim` derived from `h` to make it useful for types
without a `[Nonempty X]` instance. Because of the built-in proof irrelevance, Lean will unify this
instance with any other instance. -/
theorem tendsto_nhds_limUnder {f : Filter α} {g : α → X} (h : ∃ x, Tendsto g f (𝓝 x)) :
Tendsto g f (𝓝 (@limUnder _ _ _ (nonempty_of_exists h) f g)) :=
le_nhds_lim h
theorem limUnder_of_not_tendsto [hX : Nonempty X] {f : Filter α} {g : α → X}
(h : ¬ ∃ x, Tendsto g f (𝓝 x)) :
limUnder f g = Classical.choice hX := by
simp_rw [Tendsto] at h
simp_rw [limUnder, lim, Classical.epsilon, Classical.strongIndefiniteDescription, dif_neg h]
end lim
end TopologicalSpace
| Mathlib/Topology/Basic.lean | 1,321 | 1,324 | |
/-
Copyright (c) 2022 Julian Berman. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Julian Berman
-/
import Mathlib.GroupTheory.PGroup
import Mathlib.LinearAlgebra.Quotient.Defs
/-!
# Torsion groups
This file defines torsion groups, i.e. groups where all elements have finite order.
## Main definitions
* `Monoid.IsTorsion` a predicate asserting `G` is torsion, i.e. that all
elements are of finite order.
* `CommGroup.torsion G`, the torsion subgroup of an abelian group `G`
* `CommMonoid.torsion G`, the above stated for commutative monoids
* `Monoid.IsTorsionFree`, asserting no nontrivial elements have finite order in `G`
* `AddMonoid.IsTorsion` and `AddMonoid.IsTorsionFree` the additive versions of the above
## Implementation
All torsion monoids are really groups (which is proven here as `Monoid.IsTorsion.group`), but since
the definition can be stated on monoids it is implemented on `Monoid` to match other declarations in
the group theory library.
## Tags
periodic group, aperiodic group, torsion subgroup, torsion abelian group
## Future work
* generalize to π-torsion(-free) groups for a set of primes π
* free, free solvable and free abelian groups are torsion free
* complete direct and free products of torsion free groups are torsion free
* groups which are residually finite p-groups with respect to 2 distinct primes are torsion free
-/
variable {G H : Type*}
namespace Monoid
variable (G) [Monoid G]
/-- A predicate on a monoid saying that all elements are of finite order. -/
@[to_additive "A predicate on an additive monoid saying that all elements are of finite order."]
def IsTorsion :=
∀ g : G, IsOfFinOrder g
/-- A monoid is not a torsion monoid if it has an element of infinite order. -/
@[to_additive (attr := simp) "An additive monoid is not a torsion monoid if it
has an element of infinite order."]
theorem not_isTorsion_iff : ¬IsTorsion G ↔ ∃ g : G, ¬IsOfFinOrder g := by
rw [IsTorsion, not_forall]
end Monoid
open Monoid
/-- Torsion monoids are really groups. -/
@[to_additive "Torsion additive monoids are really additive groups"]
noncomputable def IsTorsion.group [Monoid G] (tG : IsTorsion G) : Group G :=
{ ‹Monoid G› with
inv := fun g => g ^ (orderOf g - 1)
inv_mul_cancel := fun g => by
rw [← pow_succ, tsub_add_cancel_of_le, pow_orderOf_eq_one]
exact (tG g).orderOf_pos }
section Group
variable [Group G] {N : Subgroup G} [Group H]
/-- Subgroups of torsion groups are torsion groups. -/
@[to_additive "Subgroups of additive torsion groups are additive torsion groups."]
theorem IsTorsion.subgroup (tG : IsTorsion G) (H : Subgroup G) : IsTorsion H := fun h =>
Submonoid.isOfFinOrder_coe.1 <| tG h
/-- The image of a surjective torsion group homomorphism is torsion. -/
@[to_additive AddIsTorsion.of_surjective
"The image of a surjective additive torsion group homomorphism is torsion."]
theorem IsTorsion.of_surjective {f : G →* H} (hf : Function.Surjective f) (tG : IsTorsion G) :
IsTorsion H := fun h => by
obtain ⟨g, hg⟩ := hf h
rw [← hg]
exact f.isOfFinOrder (tG g)
/-- Torsion groups are closed under extensions. -/
@[to_additive AddIsTorsion.extension_closed "Additive torsion groups are closed under extensions."]
theorem IsTorsion.extension_closed {f : G →* H} (hN : N = f.ker) (tH : IsTorsion H)
(tN : IsTorsion N) : IsTorsion G := fun g => by
obtain ⟨ngn, ngnpos, hngn⟩ := (tH <| f g).exists_pow_eq_one
have hmem := MonoidHom.mem_ker.mpr ((f.map_pow g ngn).trans hngn)
lift g ^ ngn to N using hN.symm ▸ hmem with gn h
obtain ⟨nn, nnpos, hnn⟩ := (tN gn).exists_pow_eq_one
exact isOfFinOrder_iff_pow_eq_one.mpr <| ⟨ngn * nn, mul_pos ngnpos nnpos, by
rw [pow_mul, ← h, ← Subgroup.coe_pow, hnn, Subgroup.coe_one]⟩
/-- The image of a quotient is torsion iff the group is torsion. -/
@[to_additive AddIsTorsion.quotient_iff
"The image of a quotient is additively torsion iff the group is torsion."]
theorem IsTorsion.quotient_iff {f : G →* H} (hf : Function.Surjective f) (hN : N = f.ker)
(tN : IsTorsion N) : IsTorsion H ↔ IsTorsion G :=
⟨fun tH => IsTorsion.extension_closed hN tH tN, fun tG => IsTorsion.of_surjective hf tG⟩
/-- If a group exponent exists, the group is torsion. -/
@[to_additive ExponentExists.is_add_torsion
"If a group exponent exists, the group is additively torsion."]
theorem ExponentExists.isTorsion (h : ExponentExists G) : IsTorsion G := fun g => by
obtain ⟨n, npos, hn⟩ := h
exact isOfFinOrder_iff_pow_eq_one.mpr ⟨n, npos, hn g⟩
/-- The group exponent exists for any bounded torsion group. -/
@[to_additive IsAddTorsion.exponentExists
"The group exponent exists for any bounded additive torsion group."]
theorem IsTorsion.exponentExists (tG : IsTorsion G)
(bounded : (Set.range fun g : G => orderOf g).Finite) : ExponentExists G :=
exponent_ne_zero.mp <|
(exponent_ne_zero_iff_range_orderOf_finite fun g => (tG g).orderOf_pos).mpr bounded
/-- Finite groups are torsion groups. -/
@[to_additive is_add_torsion_of_finite "Finite additive groups are additive torsion groups."]
theorem isTorsion_of_finite [Finite G] : IsTorsion G :=
ExponentExists.isTorsion .of_finite
end Group
section Module
-- A (semi/)ring of scalars and a commutative monoid of elements
variable (R M : Type*) [AddCommMonoid M]
namespace AddMonoid
/-- A module whose scalars are additively torsion is additively torsion. -/
theorem IsTorsion.module_of_torsion [Semiring R] [Module R M] (tR : IsTorsion R) : IsTorsion M :=
fun f =>
isOfFinAddOrder_iff_nsmul_eq_zero.mpr <| by
obtain ⟨n, npos, hn⟩ := (tR 1).exists_nsmul_eq_zero
exact ⟨n, npos, by simp only [← Nat.cast_smul_eq_nsmul R _ f, ← nsmul_one, hn, zero_smul]⟩
/-- A module with a finite ring of scalars is additively torsion. -/
theorem IsTorsion.module_of_finite [Ring R] [Finite R] [Module R M] : IsTorsion M :=
(is_add_torsion_of_finite : IsTorsion R).module_of_torsion _ _
end AddMonoid
end Module
section CommMonoid
variable (G) [CommMonoid G]
namespace CommMonoid
/-- The torsion submonoid of a commutative monoid.
(Note that by `Monoid.IsTorsion.group` torsion monoids are truthfully groups.)
-/
@[to_additive addTorsion "The torsion submonoid of an additive commutative monoid."]
def torsion : Submonoid G where
carrier := { x | IsOfFinOrder x }
one_mem' := IsOfFinOrder.one
mul_mem' hx hy := hx.mul hy
variable {G}
/-- Torsion submonoids are torsion. -/
@[to_additive "Additive torsion submonoids are additively torsion."]
theorem torsion.isTorsion : IsTorsion <| torsion G := fun ⟨x, n, npos, hn⟩ =>
⟨n, npos,
Subtype.ext <| by
dsimp
rw [mul_left_iterate]
change _ * 1 = 1
rw [_root_.mul_one, SubmonoidClass.coe_pow, Subtype.coe_mk,
(isPeriodicPt_mul_iff_pow_eq_one _).mp hn]⟩
variable (G) (p : ℕ) [hp : Fact p.Prime]
/-- The `p`-primary component is the submonoid of elements with order prime-power of `p`. -/
@[to_additive (attr := simps)
"The `p`-primary component is the submonoid of elements with additive
order prime-power of `p`."]
def primaryComponent : Submonoid G where
carrier := { g | ∃ n : ℕ, orderOf g = p ^ n }
one_mem' := ⟨0, by rw [pow_zero, orderOf_one]⟩
mul_mem' hg₁ hg₂ :=
exists_orderOf_eq_prime_pow_iff.mpr <| by
obtain ⟨m, hm⟩ := exists_orderOf_eq_prime_pow_iff.mp hg₁
obtain ⟨n, hn⟩ := exists_orderOf_eq_prime_pow_iff.mp hg₂
exact
⟨m + n, by
rw [mul_pow, pow_add, pow_mul, hm, one_pow, Monoid.one_mul, mul_comm, pow_mul, hn,
one_pow]⟩
variable {G} {p}
/-- Elements of the `p`-primary component have order `p^n` for some `n`. -/
@[to_additive primaryComponent.exists_orderOf_eq_prime_nsmul
"Elements of the `p`-primary component have additive order `p^n` for some `n`"]
theorem primaryComponent.exists_orderOf_eq_prime_pow (g : CommMonoid.primaryComponent G p) :
∃ n : ℕ, orderOf g = p ^ n := by
obtain ⟨_, hn⟩ := g.property
rw [orderOf_submonoid g] at hn
exact ⟨_, hn⟩
/-- The `p`- and `q`-primary components are disjoint for `p ≠ q`. -/
@[to_additive "The `p`- and `q`-primary components are disjoint for `p ≠ q`."]
theorem primaryComponent.disjoint {p' : ℕ} [hp' : Fact p'.Prime] (hne : p ≠ p') :
Disjoint (CommMonoid.primaryComponent G p) (CommMonoid.primaryComponent G p') :=
Submonoid.disjoint_def.mpr <| by
rintro g ⟨_ | n, hn⟩ ⟨n', hn'⟩
· rwa [pow_zero, orderOf_eq_one_iff] at hn
· exact
absurd (eq_of_prime_pow_eq hp.out.prime hp'.out.prime n.succ_pos (hn.symm.trans hn')) hne
end CommMonoid
open CommMonoid (torsion)
namespace Monoid.IsTorsion
variable {G}
/-- The torsion submonoid of a torsion monoid is `⊤`. -/
@[to_additive (attr := simp) "The additive torsion submonoid of an additive torsion monoid is `⊤`."]
theorem torsion_eq_top (tG : IsTorsion G) : torsion G = ⊤ := by ext; tauto
/-- A torsion monoid is isomorphic to its torsion submonoid. -/
@[to_additive "An additive torsion monoid is isomorphic to its torsion submonoid."]
def torsionMulEquiv (tG : IsTorsion G) : torsion G ≃* G :=
(MulEquiv.submonoidCongr tG.torsion_eq_top).trans Submonoid.topEquiv
| @[to_additive]
theorem torsionMulEquiv_apply (tG : IsTorsion G) (a : torsion G) :
| Mathlib/GroupTheory/Torsion.lean | 237 | 238 |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Mario Carneiro
-/
import Mathlib.Data.Set.Constructions
import Mathlib.Order.Filter.AtTopBot.CountablyGenerated
import Mathlib.Topology.Constructions
import Mathlib.Topology.ContinuousOn
/-!
# Bases of topologies. Countability axioms.
A topological basis on a topological space `t` is a collection of sets,
such that all open sets can be generated as unions of these sets, without the need to take
finite intersections of them. This file introduces a framework for dealing with these collections,
and also what more we can say under certain countability conditions on bases,
which are referred to as first- and second-countable.
We also briefly cover the theory of separable spaces, which are those with a countable, dense
subset. If a space is second-countable, and also has a countably generated uniformity filter
(for example, if `t` is a metric space), it will automatically be separable (and indeed, these
conditions are equivalent in this case).
## Main definitions
* `TopologicalSpace.IsTopologicalBasis s`: The topological space `t` has basis `s`.
* `TopologicalSpace.SeparableSpace α`: The topological space `t` has a countable, dense subset.
* `TopologicalSpace.IsSeparable s`: The set `s` is contained in the closure of a countable set.
* `FirstCountableTopology α`: A topology in which `𝓝 x` is countably generated for
every `x`.
* `SecondCountableTopology α`: A topology which has a topological basis which is
countable.
## Main results
* `TopologicalSpace.FirstCountableTopology.tendsto_subseq`: In a first-countable space,
cluster points are limits of subsequences.
* `TopologicalSpace.SecondCountableTopology.isOpen_iUnion_countable`: In a second-countable space,
the union of arbitrarily-many open sets is equal to a sub-union of only countably many of these
sets.
* `TopologicalSpace.SecondCountableTopology.countable_cover_nhds`: Consider `f : α → Set α` with the
property that `f x ∈ 𝓝 x` for all `x`. Then there is some countable set `s` whose image covers
the space.
## Implementation Notes
For our applications we are interested that there exists a countable basis, but we do not need the
concrete basis itself. This allows us to declare these type classes as `Prop` to use them as mixins.
## TODO
More fine grained instances for `FirstCountableTopology`,
`TopologicalSpace.SeparableSpace`, and more.
-/
open Set Filter Function Topology
noncomputable section
namespace TopologicalSpace
universe u
variable {α : Type u} {β : Type*} [t : TopologicalSpace α] {B : Set (Set α)} {s : Set α}
/-- A topological basis is one that satisfies the necessary conditions so that
it suffices to take unions of the basis sets to get a topology (without taking
finite intersections as well). -/
structure IsTopologicalBasis (s : Set (Set α)) : Prop where
/-- For every point `x`, the set of `t ∈ s` such that `x ∈ t` is directed downwards. -/
exists_subset_inter : ∀ t₁ ∈ s, ∀ t₂ ∈ s, ∀ x ∈ t₁ ∩ t₂, ∃ t₃ ∈ s, x ∈ t₃ ∧ t₃ ⊆ t₁ ∩ t₂
/-- The sets from `s` cover the whole space. -/
sUnion_eq : ⋃₀ s = univ
/-- The topology is generated by sets from `s`. -/
eq_generateFrom : t = generateFrom s
/-- If a family of sets `s` generates the topology, then intersections of finite
subcollections of `s` form a topological basis. -/
theorem isTopologicalBasis_of_subbasis {s : Set (Set α)} (hs : t = generateFrom s) :
IsTopologicalBasis ((fun f => ⋂₀ f) '' { f : Set (Set α) | f.Finite ∧ f ⊆ s }) := by
subst t; letI := generateFrom s
refine ⟨?_, ?_, le_antisymm (le_generateFrom ?_) <| generateFrom_anti fun t ht => ?_⟩
· rintro _ ⟨t₁, ⟨hft₁, ht₁b⟩, rfl⟩ _ ⟨t₂, ⟨hft₂, ht₂b⟩, rfl⟩ x h
exact ⟨_, ⟨_, ⟨hft₁.union hft₂, union_subset ht₁b ht₂b⟩, sInter_union t₁ t₂⟩, h, Subset.rfl⟩
· rw [sUnion_image, iUnion₂_eq_univ_iff]
exact fun x => ⟨∅, ⟨finite_empty, empty_subset _⟩, sInter_empty.substr <| mem_univ x⟩
· rintro _ ⟨t, ⟨hft, htb⟩, rfl⟩
exact hft.isOpen_sInter fun s hs ↦ GenerateOpen.basic _ <| htb hs
· rw [← sInter_singleton t]
exact ⟨{t}, ⟨finite_singleton t, singleton_subset_iff.2 ht⟩, rfl⟩
theorem isTopologicalBasis_of_subbasis_of_finiteInter {s : Set (Set α)} (hsg : t = generateFrom s)
(hsi : FiniteInter s) : IsTopologicalBasis s := by
convert isTopologicalBasis_of_subbasis hsg
refine le_antisymm (fun t ht ↦ ⟨{t}, by simpa using ht⟩) ?_
rintro _ ⟨g, ⟨hg, hgs⟩, rfl⟩
lift g to Finset (Set α) using hg
exact hsi.finiteInter_mem g hgs
theorem isTopologicalBasis_of_subbasis_of_inter {r : Set (Set α)} (hsg : t = generateFrom r)
(hsi : ∀ ⦃s⦄, s ∈ r → ∀ ⦃t⦄, t ∈ r → s ∩ t ∈ r) : IsTopologicalBasis (insert univ r) :=
isTopologicalBasis_of_subbasis_of_finiteInter (by simpa using hsg) (FiniteInter.mk₂ hsi)
theorem IsTopologicalBasis.of_hasBasis_nhds {s : Set (Set α)}
(h_nhds : ∀ a, (𝓝 a).HasBasis (fun t ↦ t ∈ s ∧ a ∈ t) id) : IsTopologicalBasis s where
exists_subset_inter t₁ ht₁ t₂ ht₂ x hx := by
simpa only [and_assoc, (h_nhds x).mem_iff]
using (inter_mem ((h_nhds _).mem_of_mem ⟨ht₁, hx.1⟩) ((h_nhds _).mem_of_mem ⟨ht₂, hx.2⟩))
sUnion_eq := sUnion_eq_univ_iff.2 fun x ↦ (h_nhds x).ex_mem
eq_generateFrom := ext_nhds fun x ↦ by
simpa only [nhds_generateFrom, and_comm] using (h_nhds x).eq_biInf
/-- If a family of open sets `s` is such that every open neighbourhood contains some
member of `s`, then `s` is a topological basis. -/
theorem isTopologicalBasis_of_isOpen_of_nhds {s : Set (Set α)} (h_open : ∀ u ∈ s, IsOpen u)
(h_nhds : ∀ (a : α) (u : Set α), a ∈ u → IsOpen u → ∃ v ∈ s, a ∈ v ∧ v ⊆ u) :
IsTopologicalBasis s :=
.of_hasBasis_nhds <| fun a ↦
(nhds_basis_opens a).to_hasBasis' (by simpa [and_assoc] using h_nhds a)
fun _ ⟨hts, hat⟩ ↦ (h_open _ hts).mem_nhds hat
/-- A set `s` is in the neighbourhood of `a` iff there is some basis set `t`, which
contains `a` and is itself contained in `s`. -/
theorem IsTopologicalBasis.mem_nhds_iff {a : α} {s : Set α} {b : Set (Set α)}
(hb : IsTopologicalBasis b) : s ∈ 𝓝 a ↔ ∃ t ∈ b, a ∈ t ∧ t ⊆ s := by
change s ∈ (𝓝 a).sets ↔ ∃ t ∈ b, a ∈ t ∧ t ⊆ s
rw [hb.eq_generateFrom, nhds_generateFrom, biInf_sets_eq]
· simp [and_assoc, and_left_comm]
· rintro s ⟨hs₁, hs₂⟩ t ⟨ht₁, ht₂⟩
let ⟨u, hu₁, hu₂, hu₃⟩ := hb.1 _ hs₂ _ ht₂ _ ⟨hs₁, ht₁⟩
exact ⟨u, ⟨hu₂, hu₁⟩, le_principal_iff.2 (hu₃.trans inter_subset_left),
le_principal_iff.2 (hu₃.trans inter_subset_right)⟩
· rcases eq_univ_iff_forall.1 hb.sUnion_eq a with ⟨i, h1, h2⟩
exact ⟨i, h2, h1⟩
theorem IsTopologicalBasis.isOpen_iff {s : Set α} {b : Set (Set α)} (hb : IsTopologicalBasis b) :
IsOpen s ↔ ∀ a ∈ s, ∃ t ∈ b, a ∈ t ∧ t ⊆ s := by simp [isOpen_iff_mem_nhds, hb.mem_nhds_iff]
theorem IsTopologicalBasis.of_isOpen_of_subset {s s' : Set (Set α)} (h_open : ∀ u ∈ s', IsOpen u)
(hs : IsTopologicalBasis s) (hss' : s ⊆ s') : IsTopologicalBasis s' :=
isTopologicalBasis_of_isOpen_of_nhds h_open fun a _ ha u_open ↦
have ⟨t, hts, ht⟩ := hs.isOpen_iff.mp u_open a ha; ⟨t, hss' hts, ht⟩
theorem IsTopologicalBasis.nhds_hasBasis {b : Set (Set α)} (hb : IsTopologicalBasis b) {a : α} :
(𝓝 a).HasBasis (fun t : Set α => t ∈ b ∧ a ∈ t) fun t => t :=
⟨fun s => hb.mem_nhds_iff.trans <| by simp only [and_assoc]⟩
protected theorem IsTopologicalBasis.isOpen {s : Set α} {b : Set (Set α)}
(hb : IsTopologicalBasis b) (hs : s ∈ b) : IsOpen s := by
rw [hb.eq_generateFrom]
exact .basic s hs
theorem IsTopologicalBasis.insert_empty {s : Set (Set α)} (h : IsTopologicalBasis s) :
IsTopologicalBasis (insert ∅ s) :=
h.of_isOpen_of_subset (by rintro _ (rfl | hu); exacts [isOpen_empty, h.isOpen hu])
(subset_insert ..)
theorem IsTopologicalBasis.diff_empty {s : Set (Set α)} (h : IsTopologicalBasis s) :
IsTopologicalBasis (s \ {∅}) :=
isTopologicalBasis_of_isOpen_of_nhds (fun _ hu ↦ h.isOpen hu.1) fun a _ ha hu ↦
have ⟨t, hts, ht⟩ := h.isOpen_iff.mp hu a ha
⟨t, ⟨hts, ne_of_mem_of_not_mem' ht.1 <| not_mem_empty _⟩, ht⟩
protected theorem IsTopologicalBasis.mem_nhds {a : α} {s : Set α} {b : Set (Set α)}
(hb : IsTopologicalBasis b) (hs : s ∈ b) (ha : a ∈ s) : s ∈ 𝓝 a :=
(hb.isOpen hs).mem_nhds ha
theorem IsTopologicalBasis.exists_subset_of_mem_open {b : Set (Set α)} (hb : IsTopologicalBasis b)
{a : α} {u : Set α} (au : a ∈ u) (ou : IsOpen u) : ∃ v ∈ b, a ∈ v ∧ v ⊆ u :=
hb.mem_nhds_iff.1 <| IsOpen.mem_nhds ou au
/-- Any open set is the union of the basis sets contained in it. -/
theorem IsTopologicalBasis.open_eq_sUnion' {B : Set (Set α)} (hB : IsTopologicalBasis B) {u : Set α}
(ou : IsOpen u) : u = ⋃₀ { s ∈ B | s ⊆ u } :=
ext fun _a =>
⟨fun ha =>
let ⟨b, hb, ab, bu⟩ := hB.exists_subset_of_mem_open ha ou
⟨b, ⟨hb, bu⟩, ab⟩,
fun ⟨_b, ⟨_, bu⟩, ab⟩ => bu ab⟩
theorem IsTopologicalBasis.open_eq_sUnion {B : Set (Set α)} (hB : IsTopologicalBasis B) {u : Set α}
(ou : IsOpen u) : ∃ S ⊆ B, u = ⋃₀ S :=
⟨{ s ∈ B | s ⊆ u }, fun _ h => h.1, hB.open_eq_sUnion' ou⟩
theorem IsTopologicalBasis.open_iff_eq_sUnion {B : Set (Set α)} (hB : IsTopologicalBasis B)
{u : Set α} : IsOpen u ↔ ∃ S ⊆ B, u = ⋃₀ S :=
⟨hB.open_eq_sUnion, fun ⟨_S, hSB, hu⟩ => hu.symm ▸ isOpen_sUnion fun _s hs => hB.isOpen (hSB hs)⟩
theorem IsTopologicalBasis.open_eq_iUnion {B : Set (Set α)} (hB : IsTopologicalBasis B) {u : Set α}
(ou : IsOpen u) : ∃ (β : Type u) (f : β → Set α), (u = ⋃ i, f i) ∧ ∀ i, f i ∈ B :=
⟨↥({ s ∈ B | s ⊆ u }), (↑), by
rw [← sUnion_eq_iUnion]
apply hB.open_eq_sUnion' ou, fun s => And.left s.2⟩
lemma IsTopologicalBasis.subset_of_forall_subset {t : Set α} (hB : IsTopologicalBasis B)
(hs : IsOpen s) (h : ∀ U ∈ B, U ⊆ s → U ⊆ t) : s ⊆ t := by
rw [hB.open_eq_sUnion' hs]; simpa [sUnion_subset_iff]
lemma IsTopologicalBasis.eq_of_forall_subset_iff {t : Set α} (hB : IsTopologicalBasis B)
(hs : IsOpen s) (ht : IsOpen t) (h : ∀ U ∈ B, U ⊆ s ↔ U ⊆ t) : s = t := by
rw [hB.open_eq_sUnion' hs, hB.open_eq_sUnion' ht]
exact congr_arg _ (Set.ext fun U ↦ and_congr_right <| h _)
/-- A point `a` is in the closure of `s` iff all basis sets containing `a` intersect `s`. -/
theorem IsTopologicalBasis.mem_closure_iff {b : Set (Set α)} (hb : IsTopologicalBasis b) {s : Set α}
{a : α} : a ∈ closure s ↔ ∀ o ∈ b, a ∈ o → (o ∩ s).Nonempty :=
(mem_closure_iff_nhds_basis' hb.nhds_hasBasis).trans <| by simp only [and_imp]
/-- A set is dense iff it has non-trivial intersection with all basis sets. -/
theorem IsTopologicalBasis.dense_iff {b : Set (Set α)} (hb : IsTopologicalBasis b) {s : Set α} :
Dense s ↔ ∀ o ∈ b, Set.Nonempty o → (o ∩ s).Nonempty := by
simp only [Dense, hb.mem_closure_iff]
exact ⟨fun h o hb ⟨a, ha⟩ => h a o hb ha, fun h a o hb ha => h o hb ⟨a, ha⟩⟩
theorem IsTopologicalBasis.isOpenMap_iff {β} [TopologicalSpace β] {B : Set (Set α)}
(hB : IsTopologicalBasis B) {f : α → β} : IsOpenMap f ↔ ∀ s ∈ B, IsOpen (f '' s) := by
refine ⟨fun H o ho => H _ (hB.isOpen ho), fun hf o ho => ?_⟩
rw [hB.open_eq_sUnion' ho, sUnion_eq_iUnion, image_iUnion]
exact isOpen_iUnion fun s => hf s s.2.1
theorem IsTopologicalBasis.exists_nonempty_subset {B : Set (Set α)} (hb : IsTopologicalBasis B)
{u : Set α} (hu : u.Nonempty) (ou : IsOpen u) : ∃ v ∈ B, Set.Nonempty v ∧ v ⊆ u :=
let ⟨x, hx⟩ := hu
let ⟨v, vB, xv, vu⟩ := hb.exists_subset_of_mem_open hx ou
⟨v, vB, ⟨x, xv⟩, vu⟩
theorem isTopologicalBasis_opens : IsTopologicalBasis { U : Set α | IsOpen U } :=
isTopologicalBasis_of_isOpen_of_nhds (by tauto) (by tauto)
protected lemma IsTopologicalBasis.isInducing {β} [TopologicalSpace β] {f : α → β} {T : Set (Set β)}
(hf : IsInducing f) (h : IsTopologicalBasis T) : IsTopologicalBasis ((preimage f) '' T) :=
.of_hasBasis_nhds fun a ↦ by
convert (hf.basis_nhds (h.nhds_hasBasis (a := f a))).to_image_id with s
aesop
@[deprecated (since := "2024-10-28")]
alias IsTopologicalBasis.inducing := IsTopologicalBasis.isInducing
protected theorem IsTopologicalBasis.induced {α} [s : TopologicalSpace β] (f : α → β)
{T : Set (Set β)} (h : IsTopologicalBasis T) :
IsTopologicalBasis (t := induced f s) ((preimage f) '' T) :=
h.isInducing (t := induced f s) (.induced f)
protected theorem IsTopologicalBasis.inf {t₁ t₂ : TopologicalSpace β} {B₁ B₂ : Set (Set β)}
(h₁ : IsTopologicalBasis (t := t₁) B₁) (h₂ : IsTopologicalBasis (t := t₂) B₂) :
IsTopologicalBasis (t := t₁ ⊓ t₂) (image2 (· ∩ ·) B₁ B₂) := by
refine .of_hasBasis_nhds (t := ?_) fun a ↦ ?_
rw [nhds_inf (t₁ := t₁)]
convert ((h₁.nhds_hasBasis (t := t₁)).inf (h₂.nhds_hasBasis (t := t₂))).to_image_id
aesop
theorem IsTopologicalBasis.inf_induced {γ} [s : TopologicalSpace β] {B₁ : Set (Set α)}
{B₂ : Set (Set β)} (h₁ : IsTopologicalBasis B₁) (h₂ : IsTopologicalBasis B₂) (f₁ : γ → α)
(f₂ : γ → β) :
IsTopologicalBasis (t := induced f₁ t ⊓ induced f₂ s) (image2 (f₁ ⁻¹' · ∩ f₂ ⁻¹' ·) B₁ B₂) := by
simpa only [image2_image_left, image2_image_right] using (h₁.induced f₁).inf (h₂.induced f₂)
protected theorem IsTopologicalBasis.prod {β} [TopologicalSpace β] {B₁ : Set (Set α)}
{B₂ : Set (Set β)} (h₁ : IsTopologicalBasis B₁) (h₂ : IsTopologicalBasis B₂) :
IsTopologicalBasis (image2 (· ×ˢ ·) B₁ B₂) :=
h₁.inf_induced h₂ Prod.fst Prod.snd
theorem isTopologicalBasis_of_cover {ι} {U : ι → Set α} (Uo : ∀ i, IsOpen (U i))
(Uc : ⋃ i, U i = univ) {b : ∀ i, Set (Set (U i))} (hb : ∀ i, IsTopologicalBasis (b i)) :
IsTopologicalBasis (⋃ i : ι, image ((↑) : U i → α) '' b i) := by
refine isTopologicalBasis_of_isOpen_of_nhds (fun u hu => ?_) ?_
· simp only [mem_iUnion, mem_image] at hu
rcases hu with ⟨i, s, sb, rfl⟩
exact (Uo i).isOpenMap_subtype_val _ ((hb i).isOpen sb)
· intro a u ha uo
rcases iUnion_eq_univ_iff.1 Uc a with ⟨i, hi⟩
lift a to ↥(U i) using hi
rcases (hb i).exists_subset_of_mem_open ha (uo.preimage continuous_subtype_val) with
⟨v, hvb, hav, hvu⟩
exact ⟨(↑) '' v, mem_iUnion.2 ⟨i, mem_image_of_mem _ hvb⟩, mem_image_of_mem _ hav,
image_subset_iff.2 hvu⟩
protected theorem IsTopologicalBasis.continuous_iff {β : Type*} [TopologicalSpace β]
{B : Set (Set β)} (hB : IsTopologicalBasis B) {f : α → β} :
Continuous f ↔ ∀ s ∈ B, IsOpen (f ⁻¹' s) := by
rw [hB.eq_generateFrom, continuous_generateFrom_iff]
@[simp] lemma isTopologicalBasis_empty : IsTopologicalBasis (∅ : Set (Set α)) ↔ IsEmpty α where
mp h := by simpa using h.sUnion_eq.symm
mpr h := ⟨by simp, by simp [Set.univ_eq_empty_iff.2], Subsingleton.elim ..⟩
variable (α)
/-- A separable space is one with a countable dense subset, available through
`TopologicalSpace.exists_countable_dense`. If `α` is also known to be nonempty, then
`TopologicalSpace.denseSeq` provides a sequence `ℕ → α` with dense range, see
`TopologicalSpace.denseRange_denseSeq`.
If `α` is a uniform space with countably generated uniformity filter (e.g., an `EMetricSpace`), then
this condition is equivalent to `SecondCountableTopology α`. In this case the
latter should be used as a typeclass argument in theorems because Lean can automatically deduce
`TopologicalSpace.SeparableSpace` from `SecondCountableTopology` but it can't
deduce `SecondCountableTopology` from `TopologicalSpace.SeparableSpace`.
Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: the previous paragraph describes the state of the art in Lean 3.
We can have instance cycles in Lean 4 but we might want to
postpone adding them till after the port. -/
@[mk_iff] class SeparableSpace : Prop where
/-- There exists a countable dense set. -/
exists_countable_dense : ∃ s : Set α, s.Countable ∧ Dense s
theorem exists_countable_dense [SeparableSpace α] : ∃ s : Set α, s.Countable ∧ Dense s :=
SeparableSpace.exists_countable_dense
/-- A nonempty separable space admits a sequence with dense range. Instead of running `cases` on the
conclusion of this lemma, you might want to use `TopologicalSpace.denseSeq` and
`TopologicalSpace.denseRange_denseSeq`.
If `α` might be empty, then `TopologicalSpace.exists_countable_dense` is the main way to use
separability of `α`. -/
theorem exists_dense_seq [SeparableSpace α] [Nonempty α] : ∃ u : ℕ → α, DenseRange u := by
obtain ⟨s : Set α, hs, s_dense⟩ := exists_countable_dense α
obtain ⟨u, hu⟩ := Set.countable_iff_exists_subset_range.mp hs
exact ⟨u, s_dense.mono hu⟩
/-- A dense sequence in a non-empty separable topological space.
If `α` might be empty, then `TopologicalSpace.exists_countable_dense` is the main way to use
separability of `α`. -/
def denseSeq [SeparableSpace α] [Nonempty α] : ℕ → α :=
Classical.choose (exists_dense_seq α)
/-- The sequence `TopologicalSpace.denseSeq α` has dense range. -/
@[simp]
theorem denseRange_denseSeq [SeparableSpace α] [Nonempty α] : DenseRange (denseSeq α) :=
Classical.choose_spec (exists_dense_seq α)
variable {α}
instance (priority := 100) Countable.to_separableSpace [Countable α] : SeparableSpace α where
exists_countable_dense := ⟨Set.univ, Set.countable_univ, dense_univ⟩
/-- If `f` has a dense range and its domain is countable, then its codomain is a separable space.
See also `DenseRange.separableSpace`. -/
theorem SeparableSpace.of_denseRange {ι : Sort _} [Countable ι] (u : ι → α) (hu : DenseRange u) :
SeparableSpace α :=
⟨⟨range u, countable_range u, hu⟩⟩
alias _root_.DenseRange.separableSpace' := SeparableSpace.of_denseRange
/-- If `α` is a separable space and `f : α → β` is a continuous map with dense range, then `β` is
a separable space as well. E.g., the completion of a separable uniform space is separable. -/
protected theorem _root_.DenseRange.separableSpace [SeparableSpace α] [TopologicalSpace β]
{f : α → β} (h : DenseRange f) (h' : Continuous f) : SeparableSpace β :=
let ⟨s, s_cnt, s_dense⟩ := exists_countable_dense α
⟨⟨f '' s, Countable.image s_cnt f, h.dense_image h' s_dense⟩⟩
theorem _root_.Topology.IsQuotientMap.separableSpace [SeparableSpace α] [TopologicalSpace β]
{f : α → β} (hf : IsQuotientMap f) : SeparableSpace β :=
hf.surjective.denseRange.separableSpace hf.continuous
@[deprecated (since := "2024-10-22")]
alias _root_.QuotientMap.separableSpace := Topology.IsQuotientMap.separableSpace
/-- The product of two separable spaces is a separable space. -/
instance [TopologicalSpace β] [SeparableSpace α] [SeparableSpace β] : SeparableSpace (α × β) := by
rcases exists_countable_dense α with ⟨s, hsc, hsd⟩
rcases exists_countable_dense β with ⟨t, htc, htd⟩
exact ⟨⟨s ×ˢ t, hsc.prod htc, hsd.prod htd⟩⟩
/-- The product of a countable family of separable spaces is a separable space. -/
instance {ι : Type*} {X : ι → Type*} [∀ i, TopologicalSpace (X i)] [∀ i, SeparableSpace (X i)]
[Countable ι] : SeparableSpace (∀ i, X i) := by
choose t htc htd using (exists_countable_dense <| X ·)
haveI := fun i ↦ (htc i).to_subtype
nontriviality ∀ i, X i; inhabit ∀ i, X i
classical
set f : (Σ I : Finset ι, ∀ i : I, t i) → ∀ i, X i := fun ⟨I, g⟩ i ↦
if hi : i ∈ I then g ⟨i, hi⟩ else (default : ∀ i, X i) i
refine ⟨⟨range f, countable_range f, dense_iff_inter_open.2 fun U hU ⟨g, hg⟩ ↦ ?_⟩⟩
rcases isOpen_pi_iff.1 hU g hg with ⟨I, u, huo, huU⟩
have : ∀ i : I, ∃ y ∈ t i, y ∈ u i := fun i ↦
(htd i).exists_mem_open (huo i i.2).1 ⟨_, (huo i i.2).2⟩
choose y hyt hyu using this
lift y to ∀ i : I, t i using hyt
refine ⟨f ⟨I, y⟩, huU fun i (hi : i ∈ I) ↦ ?_, mem_range_self (f := f) ⟨I, y⟩⟩
simp only [f, dif_pos hi]
exact hyu ⟨i, _⟩
instance [SeparableSpace α] {r : α → α → Prop} : SeparableSpace (Quot r) :=
isQuotientMap_quot_mk.separableSpace
instance [SeparableSpace α] {s : Setoid α} : SeparableSpace (Quotient s) :=
isQuotientMap_quot_mk.separableSpace
/-- A topological space with discrete topology is separable iff it is countable. -/
theorem separableSpace_iff_countable [DiscreteTopology α] : SeparableSpace α ↔ Countable α := by
simp [separableSpace_iff, countable_univ_iff]
/-- In a separable space, a family of nonempty disjoint open sets is countable. -/
theorem _root_.Pairwise.countable_of_isOpen_disjoint [SeparableSpace α] {ι : Type*}
{s : ι → Set α} (hd : Pairwise (Disjoint on s)) (ho : ∀ i, IsOpen (s i))
(hne : ∀ i, (s i).Nonempty) : Countable ι := by
rcases exists_countable_dense α with ⟨u, u_countable, u_dense⟩
choose f hfu hfs using fun i ↦ u_dense.exists_mem_open (ho i) (hne i)
have f_inj : Injective f := fun i j hij ↦
hd.eq <| not_disjoint_iff.2 ⟨f i, hfs i, hij.symm ▸ hfs j⟩
have := u_countable.to_subtype
exact (f_inj.codRestrict hfu).countable
/-- In a separable space, a family of nonempty disjoint open sets is countable. -/
theorem _root_.Set.PairwiseDisjoint.countable_of_isOpen [SeparableSpace α] {ι : Type*}
{s : ι → Set α} {a : Set ι} (h : a.PairwiseDisjoint s) (ho : ∀ i ∈ a, IsOpen (s i))
(hne : ∀ i ∈ a, (s i).Nonempty) : a.Countable :=
(h.subtype _ _).countable_of_isOpen_disjoint (Subtype.forall.2 ho) (Subtype.forall.2 hne)
/-- In a separable space, a family of disjoint sets with nonempty interiors is countable. -/
theorem _root_.Set.PairwiseDisjoint.countable_of_nonempty_interior [SeparableSpace α] {ι : Type*}
{s : ι → Set α} {a : Set ι} (h : a.PairwiseDisjoint s)
(ha : ∀ i ∈ a, (interior (s i)).Nonempty) : a.Countable :=
(h.mono fun _ => interior_subset).countable_of_isOpen (fun _ _ => isOpen_interior) ha
/-- A set `s` in a topological space is separable if it is contained in the closure of a countable
set `c`. Beware that this definition does not require that `c` is contained in `s` (to express the
latter, use `TopologicalSpace.SeparableSpace s` or
`TopologicalSpace.IsSeparable (univ : Set s))`. In metric spaces, the two definitions are
equivalent, see `TopologicalSpace.IsSeparable.separableSpace`. -/
def IsSeparable (s : Set α) :=
∃ c : Set α, c.Countable ∧ s ⊆ closure c
theorem IsSeparable.mono {s u : Set α} (hs : IsSeparable s) (hu : u ⊆ s) : IsSeparable u := by
rcases hs with ⟨c, c_count, hs⟩
exact ⟨c, c_count, hu.trans hs⟩
theorem IsSeparable.iUnion {ι : Sort*} [Countable ι] {s : ι → Set α}
(hs : ∀ i, IsSeparable (s i)) : IsSeparable (⋃ i, s i) := by
choose c hc h'c using hs
refine ⟨⋃ i, c i, countable_iUnion hc, iUnion_subset_iff.2 fun i => ?_⟩
exact (h'c i).trans (closure_mono (subset_iUnion _ i))
@[simp]
theorem isSeparable_iUnion {ι : Sort*} [Countable ι] {s : ι → Set α} :
IsSeparable (⋃ i, s i) ↔ ∀ i, IsSeparable (s i) :=
⟨fun h i ↦ h.mono <| subset_iUnion s i, .iUnion⟩
@[simp]
theorem isSeparable_union {s t : Set α} : IsSeparable (s ∪ t) ↔ IsSeparable s ∧ IsSeparable t := by
simp [union_eq_iUnion, and_comm]
theorem IsSeparable.union {s u : Set α} (hs : IsSeparable s) (hu : IsSeparable u) :
IsSeparable (s ∪ u) :=
isSeparable_union.2 ⟨hs, hu⟩
@[simp]
theorem isSeparable_closure : IsSeparable (closure s) ↔ IsSeparable s := by
simp only [IsSeparable, isClosed_closure.closure_subset_iff]
protected alias ⟨_, IsSeparable.closure⟩ := isSeparable_closure
theorem _root_.Set.Countable.isSeparable {s : Set α} (hs : s.Countable) : IsSeparable s :=
⟨s, hs, subset_closure⟩
theorem _root_.Set.Finite.isSeparable {s : Set α} (hs : s.Finite) : IsSeparable s :=
hs.countable.isSeparable
theorem IsSeparable.univ_pi {ι : Type*} [Countable ι] {X : ι → Type*} {s : ∀ i, Set (X i)}
[∀ i, TopologicalSpace (X i)] (h : ∀ i, IsSeparable (s i)) :
IsSeparable (univ.pi s) := by
classical
rcases eq_empty_or_nonempty (univ.pi s) with he | ⟨f₀, -⟩
· rw [he]
exact countable_empty.isSeparable
· choose c c_count hc using h
haveI := fun i ↦ (c_count i).to_subtype
set g : (I : Finset ι) × ((i : I) → c i) → (i : ι) → X i := fun ⟨I, f⟩ i ↦
if hi : i ∈ I then f ⟨i, hi⟩ else f₀ i
refine ⟨range g, countable_range g, fun f hf ↦ mem_closure_iff.2 fun o ho hfo ↦ ?_⟩
rcases isOpen_pi_iff.1 ho f hfo with ⟨I, u, huo, hI⟩
rsuffices ⟨f, hf⟩ : ∃ f : (i : I) → c i, g ⟨I, f⟩ ∈ Set.pi I u
· exact ⟨g ⟨I, f⟩, hI hf, mem_range_self (f := g) ⟨I, f⟩⟩
suffices H : ∀ i ∈ I, (u i ∩ c i).Nonempty by
choose f hfu hfc using H
refine ⟨fun i ↦ ⟨f i i.2, hfc i i.2⟩, fun i (hi : i ∈ I) ↦ ?_⟩
simpa only [g, dif_pos hi] using hfu i hi
intro i hi
exact mem_closure_iff.1 (hc i <| hf _ trivial) _ (huo i hi).1 (huo i hi).2
lemma isSeparable_pi {ι : Type*} [Countable ι] {α : ι → Type*} {s : ∀ i, Set (α i)}
[∀ i, TopologicalSpace (α i)] (h : ∀ i, IsSeparable (s i)) :
IsSeparable {f : ∀ i, α i | ∀ i, f i ∈ s i} := by
simpa only [← mem_univ_pi] using IsSeparable.univ_pi h
lemma IsSeparable.prod {β : Type*} [TopologicalSpace β]
{s : Set α} {t : Set β} (hs : IsSeparable s) (ht : IsSeparable t) :
IsSeparable (s ×ˢ t) := by
rcases hs with ⟨cs, cs_count, hcs⟩
rcases ht with ⟨ct, ct_count, hct⟩
refine ⟨cs ×ˢ ct, cs_count.prod ct_count, ?_⟩
rw [closure_prod_eq]
gcongr
theorem IsSeparable.image {β : Type*} [TopologicalSpace β] {s : Set α} (hs : IsSeparable s)
{f : α → β} (hf : Continuous f) : IsSeparable (f '' s) := by
rcases hs with ⟨c, c_count, hc⟩
refine ⟨f '' c, c_count.image _, ?_⟩
rw [image_subset_iff]
exact hc.trans (closure_subset_preimage_closure_image hf)
theorem _root_.Dense.isSeparable_iff (hs : Dense s) :
IsSeparable s ↔ SeparableSpace α := by
simp_rw [IsSeparable, separableSpace_iff, dense_iff_closure_eq, ← univ_subset_iff,
← hs.closure_eq, isClosed_closure.closure_subset_iff]
theorem isSeparable_univ_iff : IsSeparable (univ : Set α) ↔ SeparableSpace α :=
dense_univ.isSeparable_iff
theorem isSeparable_range [TopologicalSpace β] [SeparableSpace α] {f : α → β} (hf : Continuous f) :
IsSeparable (range f) :=
image_univ (f := f) ▸ (isSeparable_univ_iff.2 ‹_›).image hf
theorem IsSeparable.of_subtype (s : Set α) [SeparableSpace s] : IsSeparable s := by
simpa using isSeparable_range (continuous_subtype_val (p := (· ∈ s)))
theorem IsSeparable.of_separableSpace [h : SeparableSpace α] (s : Set α) : IsSeparable s :=
IsSeparable.mono (isSeparable_univ_iff.2 h) (subset_univ _)
end TopologicalSpace
open TopologicalSpace
protected theorem IsTopologicalBasis.iInf {β : Type*} {ι : Type*} {t : ι → TopologicalSpace β}
{T : ι → Set (Set β)} (h_basis : ∀ i, IsTopologicalBasis (t := t i) (T i)) :
IsTopologicalBasis (t := ⨅ i, t i)
{ S | ∃ (U : ι → Set β) (F : Finset ι), (∀ i, i ∈ F → U i ∈ T i) ∧ S = ⋂ i ∈ F, U i } := by
let _ := ⨅ i, t i
refine isTopologicalBasis_of_isOpen_of_nhds ?_ ?_
· rintro - ⟨U, F, hU, rfl⟩
refine isOpen_biInter_finset fun i hi ↦
(h_basis i).isOpen (t := t i) (hU i hi) |>.mono (iInf_le _ _)
· intro a u ha hu
rcases (nhds_iInf (t := t) (a := a)).symm ▸ hasBasis_iInf'
(fun i ↦ (h_basis i).nhds_hasBasis (t := t i)) |>.mem_iff.1 (hu.mem_nhds ha)
with ⟨⟨F, U⟩, ⟨hF, hU⟩, hUu⟩
refine ⟨_, ⟨U, hF.toFinset, ?_, rfl⟩, ?_, ?_⟩ <;> simp only [Finite.mem_toFinset, mem_iInter]
· exact fun i hi ↦ (hU i hi).1
· exact fun i hi ↦ (hU i hi).2
· exact hUu
theorem IsTopologicalBasis.iInf_induced {β : Type*} {ι : Type*} {X : ι → Type*}
[t : Π i, TopologicalSpace (X i)] {T : Π i, Set (Set (X i))}
(cond : ∀ i, IsTopologicalBasis (T i)) (f : Π i, β → X i) :
IsTopologicalBasis (t := ⨅ i, induced (f i) (t i))
{ S | ∃ (U : ∀ i, Set (X i)) (F : Finset ι),
(∀ i, i ∈ F → U i ∈ T i) ∧ S = ⋂ (i) (_ : i ∈ F), f i ⁻¹' U i } := by
convert IsTopologicalBasis.iInf (fun i ↦ (cond i).induced (f i)) with S
constructor <;> rintro ⟨U, F, hUT, hSU⟩
· exact ⟨fun i ↦ (f i) ⁻¹' (U i), F, fun i hi ↦ mem_image_of_mem _ (hUT i hi), hSU⟩
· choose! U' hU' hUU' using hUT
exact ⟨U', F, hU', hSU ▸ (.symm <| iInter₂_congr hUU')⟩
theorem isTopologicalBasis_pi {ι : Type*} {X : ι → Type*} [∀ i, TopologicalSpace (X i)]
{T : ∀ i, Set (Set (X i))} (cond : ∀ i, IsTopologicalBasis (T i)) :
IsTopologicalBasis { S | ∃ (U : ∀ i, Set (X i)) (F : Finset ι),
(∀ i, i ∈ F → U i ∈ T i) ∧ S = (F : Set ι).pi U } := by
simpa only [Set.pi_def] using IsTopologicalBasis.iInf_induced cond eval
theorem isTopologicalBasis_singletons (α : Type*) [TopologicalSpace α] [DiscreteTopology α] :
IsTopologicalBasis { s | ∃ x : α, (s : Set α) = {x} } :=
isTopologicalBasis_of_isOpen_of_nhds (fun _ _ => isOpen_discrete _) fun x _ hx _ =>
⟨{x}, ⟨x, rfl⟩, mem_singleton x, singleton_subset_iff.2 hx⟩
theorem isTopologicalBasis_subtype
{α : Type*} [TopologicalSpace α] {B : Set (Set α)}
(h : TopologicalSpace.IsTopologicalBasis B) (p : α → Prop) :
IsTopologicalBasis (Set.preimage (Subtype.val (p := p)) '' B) :=
h.isInducing ⟨rfl⟩
section
variable {ι : Type*} {π : ι → Type*} [∀ i, TopologicalSpace (π i)]
lemma isOpenMap_eval (i : ι) : IsOpenMap (Function.eval i : (∀ i, π i) → π i) := by
classical
refine (isTopologicalBasis_pi fun _ ↦ isTopologicalBasis_opens).isOpenMap_iff.2 ?_
rintro _ ⟨U, s, hU, rfl⟩
obtain h | h := ((s : Set ι).pi U).eq_empty_or_nonempty
· simp [h]
by_cases hi : i ∈ s
· rw [eval_image_pi (mod_cast hi) h]
exact hU _ hi
· rw [eval_image_pi_of_not_mem (mod_cast hi), if_pos h]
exact isOpen_univ
end
theorem Dense.exists_countable_dense_subset {α : Type*} [TopologicalSpace α] {s : Set α}
[SeparableSpace s] (hs : Dense s) : ∃ t ⊆ s, t.Countable ∧ Dense t :=
let ⟨t, htc, htd⟩ := exists_countable_dense s
⟨(↑) '' t, Subtype.coe_image_subset s t, htc.image Subtype.val,
hs.denseRange_val.dense_image continuous_subtype_val htd⟩
/-- Let `s` be a dense set in a topological space `α` with partial order structure. If `s` is a
separable space (e.g., if `α` has a second countable topology), then there exists a countable
dense subset `t ⊆ s` such that `t` contains bottom/top element of `α` when they exist and belong
to `s`. For a dense subset containing neither bot nor top elements, see
`Dense.exists_countable_dense_subset_no_bot_top`. -/
theorem Dense.exists_countable_dense_subset_bot_top {α : Type*} [TopologicalSpace α]
[PartialOrder α] {s : Set α} [SeparableSpace s] (hs : Dense s) :
∃ t ⊆ s, t.Countable ∧ Dense t ∧ (∀ x, IsBot x → x ∈ s → x ∈ t) ∧
∀ x, IsTop x → x ∈ s → x ∈ t := by
rcases hs.exists_countable_dense_subset with ⟨t, hts, htc, htd⟩
refine ⟨(t ∪ ({ x | IsBot x } ∪ { x | IsTop x })) ∩ s, ?_, ?_, ?_, ?_, ?_⟩
exacts [inter_subset_right,
(htc.union ((countable_isBot α).union (countable_isTop α))).mono inter_subset_left,
htd.mono (subset_inter subset_union_left hts), fun x hx hxs => ⟨Or.inr <| Or.inl hx, hxs⟩,
fun x hx hxs => ⟨Or.inr <| Or.inr hx, hxs⟩]
instance separableSpace_univ {α : Type*} [TopologicalSpace α] [SeparableSpace α] :
SeparableSpace (univ : Set α) :=
(Equiv.Set.univ α).symm.surjective.denseRange.separableSpace (continuous_id.subtype_mk _)
/-- If `α` is a separable topological space with a partial order, then there exists a countable
dense set `s : Set α` that contains those of both bottom and top elements of `α` that actually
exist. For a dense set containing neither bot nor top elements, see
`exists_countable_dense_no_bot_top`. -/
theorem exists_countable_dense_bot_top (α : Type*) [TopologicalSpace α] [SeparableSpace α]
[PartialOrder α] :
∃ s : Set α, s.Countable ∧ Dense s ∧ (∀ x, IsBot x → x ∈ s) ∧ ∀ x, IsTop x → x ∈ s := by
simpa using dense_univ.exists_countable_dense_subset_bot_top
namespace TopologicalSpace
universe u
variable (α : Type u) [t : TopologicalSpace α]
/-- A first-countable space is one in which every point has a
countable neighborhood basis. -/
class _root_.FirstCountableTopology : Prop where
/-- The filter `𝓝 a` is countably generated for all points `a`. -/
nhds_generated_countable : ∀ a : α, (𝓝 a).IsCountablyGenerated
attribute [instance] FirstCountableTopology.nhds_generated_countable
/-- If `β` is a first-countable space, then its induced topology via `f` on `α` is also
first-countable. -/
theorem firstCountableTopology_induced (α β : Type*) [t : TopologicalSpace β]
[FirstCountableTopology β] (f : α → β) : @FirstCountableTopology α (t.induced f) :=
let _ := t.induced f
⟨fun x ↦ nhds_induced f x ▸ inferInstance⟩
variable {α}
instance Subtype.firstCountableTopology (s : Set α) [FirstCountableTopology α] :
FirstCountableTopology s :=
firstCountableTopology_induced s α (↑)
protected theorem _root_.Topology.IsInducing.firstCountableTopology {β : Type*}
[TopologicalSpace β] [FirstCountableTopology β] {f : α → β} (hf : IsInducing f) :
FirstCountableTopology α := by
rw [hf.1]
exact firstCountableTopology_induced α β f
@[deprecated (since := "2024-10-28")]
alias _root_.Inducing.firstCountableTopology := IsInducing.firstCountableTopology
protected theorem _root_.Topology.IsEmbedding.firstCountableTopology {β : Type*}
[TopologicalSpace β] [FirstCountableTopology β] {f : α → β} (hf : IsEmbedding f) :
FirstCountableTopology α :=
hf.1.firstCountableTopology
@[deprecated (since := "2024-10-26")]
alias _root_.Embedding.firstCountableTopology := IsEmbedding.firstCountableTopology
namespace FirstCountableTopology
/-- In a first-countable space, a cluster point `x` of a sequence
is the limit of some subsequence. -/
theorem tendsto_subseq [FirstCountableTopology α] {u : ℕ → α} {x : α}
(hx : MapClusterPt x atTop u) : ∃ ψ : ℕ → ℕ, StrictMono ψ ∧ Tendsto (u ∘ ψ) atTop (𝓝 x) :=
subseq_tendsto_of_neBot hx
end FirstCountableTopology
instance {β} [TopologicalSpace β] [FirstCountableTopology α] [FirstCountableTopology β] :
FirstCountableTopology (α × β) :=
⟨fun ⟨x, y⟩ => by rw [nhds_prod_eq]; infer_instance⟩
section Pi
instance {ι : Type*} {π : ι → Type*} [Countable ι] [∀ i, TopologicalSpace (π i)]
[∀ i, FirstCountableTopology (π i)] : FirstCountableTopology (∀ i, π i) :=
⟨fun f => by rw [nhds_pi]; infer_instance⟩
end Pi
instance isCountablyGenerated_nhdsWithin (x : α) [IsCountablyGenerated (𝓝 x)] (s : Set α) :
IsCountablyGenerated (𝓝[s] x) :=
Inf.isCountablyGenerated _ _
variable (α) in
/-- A second-countable space is one with a countable basis. -/
class _root_.SecondCountableTopology : Prop where
/-- There exists a countable set of sets that generates the topology. -/
is_open_generated_countable : ∃ b : Set (Set α), b.Countable ∧ t = TopologicalSpace.generateFrom b
protected theorem IsTopologicalBasis.secondCountableTopology {b : Set (Set α)}
(hb : IsTopologicalBasis b) (hc : b.Countable) : SecondCountableTopology α :=
⟨⟨b, hc, hb.eq_generateFrom⟩⟩
lemma SecondCountableTopology.mk' {α} {b : Set (Set α)} (hc : b.Countable) :
@SecondCountableTopology α (generateFrom b) :=
@SecondCountableTopology.mk α (generateFrom b) ⟨b, hc, rfl⟩
instance _root_.Finite.toSecondCountableTopology [Finite α] : SecondCountableTopology α where
is_open_generated_countable :=
⟨_, {U | IsOpen U}.to_countable, TopologicalSpace.isTopologicalBasis_opens.eq_generateFrom⟩
variable (α)
theorem exists_countable_basis [SecondCountableTopology α] :
∃ b : Set (Set α), b.Countable ∧ ∅ ∉ b ∧ IsTopologicalBasis b := by
obtain ⟨b, hb₁, hb₂⟩ := @SecondCountableTopology.is_open_generated_countable α _ _
refine ⟨_, ?_, not_mem_diff_of_mem ?_, (isTopologicalBasis_of_subbasis hb₂).diff_empty⟩
exacts [((countable_setOf_finite_subset hb₁).image _).mono diff_subset, rfl]
/-- A countable topological basis of `α`. -/
def countableBasis [SecondCountableTopology α] : Set (Set α) :=
(exists_countable_basis α).choose
theorem countable_countableBasis [SecondCountableTopology α] : (countableBasis α).Countable :=
(exists_countable_basis α).choose_spec.1
instance encodableCountableBasis [SecondCountableTopology α] : Encodable (countableBasis α) :=
(countable_countableBasis α).toEncodable
theorem empty_nmem_countableBasis [SecondCountableTopology α] : ∅ ∉ countableBasis α :=
(exists_countable_basis α).choose_spec.2.1
theorem isBasis_countableBasis [SecondCountableTopology α] :
IsTopologicalBasis (countableBasis α) :=
(exists_countable_basis α).choose_spec.2.2
theorem eq_generateFrom_countableBasis [SecondCountableTopology α] :
‹TopologicalSpace α› = generateFrom (countableBasis α) :=
(isBasis_countableBasis α).eq_generateFrom
variable {α}
theorem isOpen_of_mem_countableBasis [SecondCountableTopology α] {s : Set α}
(hs : s ∈ countableBasis α) : IsOpen s :=
(isBasis_countableBasis α).isOpen hs
theorem nonempty_of_mem_countableBasis [SecondCountableTopology α] {s : Set α}
(hs : s ∈ countableBasis α) : s.Nonempty :=
nonempty_iff_ne_empty.2 <| ne_of_mem_of_not_mem hs <| empty_nmem_countableBasis α
variable (α)
-- see Note [lower instance priority]
instance (priority := 100) SecondCountableTopology.to_firstCountableTopology
[SecondCountableTopology α] : FirstCountableTopology α :=
⟨fun _ => HasCountableBasis.isCountablyGenerated <|
⟨(isBasis_countableBasis α).nhds_hasBasis,
(countable_countableBasis α).mono inter_subset_left⟩⟩
/-- If `β` is a second-countable space, then its induced topology via
`f` on `α` is also second-countable. -/
theorem secondCountableTopology_induced (α β) [t : TopologicalSpace β] [SecondCountableTopology β]
(f : α → β) : @SecondCountableTopology α (t.induced f) := by
rcases @SecondCountableTopology.is_open_generated_countable β _ _ with ⟨b, hb, eq⟩
letI := t.induced f
refine { is_open_generated_countable := ⟨preimage f '' b, hb.image _, ?_⟩ }
rw [eq, induced_generateFrom_eq]
variable {α}
instance Subtype.secondCountableTopology (s : Set α) [SecondCountableTopology α] :
SecondCountableTopology s :=
secondCountableTopology_induced s α (↑)
lemma secondCountableTopology_iInf {α ι} [Countable ι] {t : ι → TopologicalSpace α}
(ht : ∀ i, @SecondCountableTopology α (t i)) : @SecondCountableTopology α (⨅ i, t i) := by
rw [funext fun i => @eq_generateFrom_countableBasis α (t i) (ht i), ← generateFrom_iUnion]
exact SecondCountableTopology.mk' <|
countable_iUnion fun i => @countable_countableBasis _ (t i) (ht i)
-- TODO: more fine grained instances for `FirstCountableTopology`, `SeparableSpace`, `T2Space`, ...
instance {β : Type*} [TopologicalSpace β] [SecondCountableTopology α] [SecondCountableTopology β] :
SecondCountableTopology (α × β) :=
((isBasis_countableBasis α).prod (isBasis_countableBasis β)).secondCountableTopology <|
(countable_countableBasis α).image2 (countable_countableBasis β) _
instance {ι : Type*} {π : ι → Type*} [Countable ι] [∀ a, TopologicalSpace (π a)]
[∀ a, SecondCountableTopology (π a)] : SecondCountableTopology (∀ a, π a) :=
secondCountableTopology_iInf fun _ => secondCountableTopology_induced _ _ _
-- see Note [lower instance priority]
instance (priority := 100) SecondCountableTopology.to_separableSpace [SecondCountableTopology α] :
SeparableSpace α := by
choose p hp using fun s : countableBasis α => nonempty_of_mem_countableBasis s.2
exact ⟨⟨range p, countable_range _, (isBasis_countableBasis α).dense_iff.2 fun o ho _ =>
⟨p ⟨o, ho⟩, hp ⟨o, _⟩, mem_range_self _⟩⟩⟩
/-- A countable open cover induces a second-countable topology if all open covers
are themselves second countable. -/
theorem secondCountableTopology_of_countable_cover {ι} [Countable ι] {U : ι → Set α}
[∀ i, SecondCountableTopology (U i)] (Uo : ∀ i, IsOpen (U i)) (hc : ⋃ i, U i = univ) :
SecondCountableTopology α :=
haveI : IsTopologicalBasis (⋃ i, image ((↑) : U i → α) '' countableBasis (U i)) :=
isTopologicalBasis_of_cover Uo hc fun i => isBasis_countableBasis (U i)
this.secondCountableTopology (countable_iUnion fun _ => (countable_countableBasis _).image _)
/-- In a second-countable space, an open set, given as a union of open sets,
is equal to the union of countably many of those sets.
In particular, any open covering of `α` has a countable subcover: α is a Lindelöf space. -/
theorem isOpen_iUnion_countable [SecondCountableTopology α] {ι} (s : ι → Set α)
(H : ∀ i, IsOpen (s i)) : ∃ T : Set ι, T.Countable ∧ ⋃ i ∈ T, s i = ⋃ i, s i := by
let B := { b ∈ countableBasis α | ∃ i, b ⊆ s i }
choose f hf using fun b : B => b.2.2
haveI : Countable B := ((countable_countableBasis α).mono (sep_subset _ _)).to_subtype
refine ⟨_, countable_range f, (iUnion₂_subset_iUnion _ _).antisymm (sUnion_subset ?_)⟩
rintro _ ⟨i, rfl⟩ x xs
rcases (isBasis_countableBasis α).exists_subset_of_mem_open xs (H _) with ⟨b, hb, xb, bs⟩
exact ⟨_, ⟨_, rfl⟩, _, ⟨⟨⟨_, hb, _, bs⟩, rfl⟩, rfl⟩, hf _ xb⟩
theorem isOpen_biUnion_countable [SecondCountableTopology α] {ι : Type*} (I : Set ι) (s : ι → Set α)
(H : ∀ i ∈ I, IsOpen (s i)) : ∃ T ⊆ I, T.Countable ∧ ⋃ i ∈ T, s i = ⋃ i ∈ I, s i := by
simp_rw [← Subtype.exists_set_subtype, biUnion_image]
rcases isOpen_iUnion_countable (fun i : I ↦ s i) fun i ↦ H i i.2 with ⟨T, hTc, hU⟩
exact ⟨T, hTc.image _, hU.trans <| iUnion_subtype ..⟩
theorem isOpen_sUnion_countable [SecondCountableTopology α] (S : Set (Set α))
(H : ∀ s ∈ S, IsOpen s) : ∃ T : Set (Set α), T.Countable ∧ T ⊆ S ∧ ⋃₀ T = ⋃₀ S := by
simpa only [and_left_comm, sUnion_eq_biUnion] using isOpen_biUnion_countable S id H
/-- In a topological space with second countable topology, if `f` is a function that sends each
point `x` to a neighborhood of `x`, then for some countable set `s`, the neighborhoods `f x`,
`x ∈ s`, cover the whole space. -/
theorem countable_cover_nhds [SecondCountableTopology α] {f : α → Set α} (hf : ∀ x, f x ∈ 𝓝 x) :
∃ s : Set α, s.Countable ∧ ⋃ x ∈ s, f x = univ := by
rcases isOpen_iUnion_countable (fun x => interior (f x)) fun x => isOpen_interior with
⟨s, hsc, hsU⟩
suffices ⋃ x ∈ s, interior (f x) = univ from
⟨s, hsc, flip eq_univ_of_subset this <| iUnion₂_mono fun _ _ => interior_subset⟩
simp only [hsU, eq_univ_iff_forall, mem_iUnion]
exact fun x => ⟨x, mem_interior_iff_mem_nhds.2 (hf x)⟩
theorem countable_cover_nhdsWithin [SecondCountableTopology α] {f : α → Set α} {s : Set α}
(hf : ∀ x ∈ s, f x ∈ 𝓝[s] x) : ∃ t ⊆ s, t.Countable ∧ s ⊆ ⋃ x ∈ t, f x := by
have : ∀ x : s, (↑) ⁻¹' f x ∈ 𝓝 x := fun x => preimage_coe_mem_nhds_subtype.2 (hf x x.2)
rcases countable_cover_nhds this with ⟨t, htc, htU⟩
refine ⟨(↑) '' t, Subtype.coe_image_subset _ _, htc.image _, fun x hx => ?_⟩
simp only [biUnion_image, eq_univ_iff_forall, ← preimage_iUnion, mem_preimage] at htU ⊢
exact htU ⟨x, hx⟩
section Sigma
variable {ι : Type*} {E : ι → Type*} [∀ i, TopologicalSpace (E i)]
/-- In a disjoint union space `Σ i, E i`, one can form a topological basis by taking the union of
topological bases on each of the parts of the space. -/
theorem IsTopologicalBasis.sigma {s : ∀ i : ι, Set (Set (E i))}
(hs : ∀ i, IsTopologicalBasis (s i)) :
IsTopologicalBasis (⋃ i : ι, (fun u => (Sigma.mk i '' u : Set (Σi, E i))) '' s i) := by
refine .of_hasBasis_nhds fun a ↦ ?_
rw [Sigma.nhds_eq]
convert (((hs a.1).nhds_hasBasis).map _).to_image_id
aesop
/-- A countable disjoint union of second countable spaces is second countable. -/
instance [Countable ι] [∀ i, SecondCountableTopology (E i)] :
SecondCountableTopology (Σi, E i) := by
let b := ⋃ i : ι, (fun u => (Sigma.mk i '' u : Set (Σi, E i))) '' countableBasis (E i)
have A : IsTopologicalBasis b := IsTopologicalBasis.sigma fun i => isBasis_countableBasis _
have B : b.Countable := countable_iUnion fun i => (countable_countableBasis _).image _
exact A.secondCountableTopology B
end Sigma
section Sum
variable {β : Type*} [TopologicalSpace β]
/-- In a sum space `α ⊕ β`, one can form a topological basis by taking the union of
topological bases on each of the two components. -/
theorem IsTopologicalBasis.sum {s : Set (Set α)} (hs : IsTopologicalBasis s) {t : Set (Set β)}
(ht : IsTopologicalBasis t) :
IsTopologicalBasis ((fun u => Sum.inl '' u) '' s ∪ (fun u => Sum.inr '' u) '' t) := by
apply isTopologicalBasis_of_isOpen_of_nhds
· rintro u (⟨w, hw, rfl⟩ | ⟨w, hw, rfl⟩)
· exact IsOpenEmbedding.inl.isOpenMap w (hs.isOpen hw)
· exact IsOpenEmbedding.inr.isOpenMap w (ht.isOpen hw)
· rintro (x | x) u hxu u_open
· obtain ⟨v, vs, xv, vu⟩ : ∃ v ∈ s, x ∈ v ∧ v ⊆ Sum.inl ⁻¹' u :=
hs.exists_subset_of_mem_open hxu (isOpen_sum_iff.1 u_open).1
exact ⟨Sum.inl '' v, mem_union_left _ (mem_image_of_mem _ vs), mem_image_of_mem _ xv,
image_subset_iff.2 vu⟩
· obtain ⟨v, vs, xv, vu⟩ : ∃ v ∈ t, x ∈ v ∧ v ⊆ Sum.inr ⁻¹' u :=
ht.exists_subset_of_mem_open hxu (isOpen_sum_iff.1 u_open).2
exact ⟨Sum.inr '' v, mem_union_right _ (mem_image_of_mem _ vs), mem_image_of_mem _ xv,
image_subset_iff.2 vu⟩
/-- A sum type of two second countable spaces is second countable. -/
instance [SecondCountableTopology α] [SecondCountableTopology β] :
SecondCountableTopology (α ⊕ β) := by
let b :=
(fun u => Sum.inl '' u) '' countableBasis α ∪ (fun u => Sum.inr '' u) '' countableBasis β
have A : IsTopologicalBasis b := (isBasis_countableBasis α).sum (isBasis_countableBasis β)
have B : b.Countable :=
(Countable.image (countable_countableBasis _) _).union
(Countable.image (countable_countableBasis _) _)
exact A.secondCountableTopology B
end Sum
section Quotient
variable {X : Type*} [TopologicalSpace X] {Y : Type*} [TopologicalSpace Y] {π : X → Y}
/-- The image of a topological basis under an open quotient map is a topological basis. -/
theorem IsTopologicalBasis.isQuotientMap {V : Set (Set X)} (hV : IsTopologicalBasis V)
(h' : IsQuotientMap π) (h : IsOpenMap π) : IsTopologicalBasis (Set.image π '' V) := by
apply isTopologicalBasis_of_isOpen_of_nhds
· rintro - ⟨U, U_in_V, rfl⟩
apply h U (hV.isOpen U_in_V)
· intro y U y_in_U U_open
obtain ⟨x, rfl⟩ := h'.surjective y
let W := π ⁻¹' U
have x_in_W : x ∈ W := y_in_U
have W_open : IsOpen W := U_open.preimage h'.continuous
obtain ⟨Z, Z_in_V, x_in_Z, Z_in_W⟩ := hV.exists_subset_of_mem_open x_in_W W_open
have πZ_in_U : π '' Z ⊆ U := (Set.image_subset _ Z_in_W).trans (image_preimage_subset π U)
exact ⟨π '' Z, ⟨Z, Z_in_V, rfl⟩, ⟨x, x_in_Z, rfl⟩, πZ_in_U⟩
@[deprecated (since := "2024-10-22")]
alias IsTopologicalBasis.quotientMap := IsTopologicalBasis.isQuotientMap
/-- A second countable space is mapped by an open quotient map to a second countable space. -/
theorem _root_.Topology.IsQuotientMap.secondCountableTopology [SecondCountableTopology X]
(h' : IsQuotientMap π) (h : IsOpenMap π) : SecondCountableTopology Y where
is_open_generated_countable := by
obtain ⟨V, V_countable, -, V_generates⟩ := exists_countable_basis X
exact ⟨Set.image π '' V, V_countable.image (Set.image π),
(V_generates.isQuotientMap h' h).eq_generateFrom⟩
@[deprecated (since := "2024-10-22")]
alias _root_.QuotientMap.secondCountableTopology := IsQuotientMap.secondCountableTopology
variable {S : Setoid X}
/-- The image of a topological basis "downstairs" in an open quotient is a topological basis. -/
theorem IsTopologicalBasis.quotient {V : Set (Set X)} (hV : IsTopologicalBasis V)
(h : IsOpenMap (Quotient.mk' : X → Quotient S)) :
IsTopologicalBasis (Set.image (Quotient.mk' : X → Quotient S) '' V) :=
hV.isQuotientMap isQuotientMap_quotient_mk' h
/-- An open quotient of a second countable space is second countable. -/
theorem Quotient.secondCountableTopology [SecondCountableTopology X]
(h : IsOpenMap (Quotient.mk' : X → Quotient S)) : SecondCountableTopology (Quotient S) :=
isQuotientMap_quotient_mk'.secondCountableTopology h
end Quotient
end TopologicalSpace
open TopologicalSpace
variable {α β : Type*} [TopologicalSpace α] {f : α → β}
protected theorem Topology.IsInducing.secondCountableTopology [TopologicalSpace β]
[SecondCountableTopology β] (hf : IsInducing f) : SecondCountableTopology α := by
rw [hf.1]
exact secondCountableTopology_induced α β f
@[deprecated (since := "2024-10-28")]
alias Inducing.secondCountableTopology := IsInducing.secondCountableTopology
protected theorem Topology.IsEmbedding.secondCountableTopology
[TopologicalSpace β] [SecondCountableTopology β]
(hf : IsEmbedding f) : SecondCountableTopology α :=
hf.1.secondCountableTopology
protected theorem Topology.IsEmbedding.separableSpace
[TopologicalSpace β] [SecondCountableTopology β] {f : α → β} (hf : IsEmbedding f) :
TopologicalSpace.SeparableSpace α := by
have := hf.secondCountableTopology
exact SecondCountableTopology.to_separableSpace
| Mathlib/Topology/Bases.lean | 992 | 1,004 | |
/-
Copyright (c) 2023 Joël Riou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joël Riou
-/
import Mathlib.Algebra.Homology.ShortComplex.PreservesHomology
import Mathlib.Algebra.Homology.ShortComplex.Abelian
import Mathlib.Algebra.Homology.ShortComplex.QuasiIso
import Mathlib.CategoryTheory.Abelian.Opposite
import Mathlib.CategoryTheory.Preadditive.AdditiveFunctor
import Mathlib.CategoryTheory.Preadditive.Injective.Basic
/-!
# Exact short complexes
When `S : ShortComplex C`, this file defines a structure
`S.Exact` which expresses the exactness of `S`, i.e. there
exists a homology data `h : S.HomologyData` such that
`h.left.H` is zero. When `[S.HasHomology]`, it is equivalent
to the assertion `IsZero S.homology`.
Almost by construction, this notion of exactness is self dual,
see `Exact.op` and `Exact.unop`.
-/
namespace CategoryTheory
open Category Limits ZeroObject Preadditive
variable {C D : Type*} [Category C] [Category D]
namespace ShortComplex
section
variable
[HasZeroMorphisms C] [HasZeroMorphisms D] (S : ShortComplex C) {S₁ S₂ : ShortComplex C}
/-- The assertion that the short complex `S : ShortComplex C` is exact. -/
structure Exact : Prop where
/-- the condition that there exists an homology data whose `left.H` field is zero -/
condition : ∃ (h : S.HomologyData), IsZero h.left.H
variable {S}
lemma Exact.hasHomology (h : S.Exact) : S.HasHomology :=
HasHomology.mk' h.condition.choose
lemma Exact.hasZeroObject (h : S.Exact) : HasZeroObject C :=
⟨h.condition.choose.left.H, h.condition.choose_spec⟩
variable (S)
lemma exact_iff_isZero_homology [S.HasHomology] :
S.Exact ↔ IsZero S.homology := by
constructor
· rintro ⟨⟨h', z⟩⟩
exact IsZero.of_iso z h'.left.homologyIso
· intro h
exact ⟨⟨_, h⟩⟩
variable {S}
lemma LeftHomologyData.exact_iff [S.HasHomology]
(h : S.LeftHomologyData) :
S.Exact ↔ IsZero h.H := by
rw [S.exact_iff_isZero_homology]
exact Iso.isZero_iff h.homologyIso
lemma RightHomologyData.exact_iff [S.HasHomology]
(h : S.RightHomologyData) :
S.Exact ↔ IsZero h.H := by
rw [S.exact_iff_isZero_homology]
exact Iso.isZero_iff h.homologyIso
variable (S)
lemma exact_iff_isZero_leftHomology [S.HasHomology] :
S.Exact ↔ IsZero S.leftHomology :=
LeftHomologyData.exact_iff _
lemma exact_iff_isZero_rightHomology [S.HasHomology] :
S.Exact ↔ IsZero S.rightHomology :=
RightHomologyData.exact_iff _
variable {S}
lemma HomologyData.exact_iff (h : S.HomologyData) :
S.Exact ↔ IsZero h.left.H := by
haveI := HasHomology.mk' h
exact LeftHomologyData.exact_iff h.left
lemma HomologyData.exact_iff' (h : S.HomologyData) :
S.Exact ↔ IsZero h.right.H := by
haveI := HasHomology.mk' h
exact RightHomologyData.exact_iff h.right
variable (S)
lemma exact_iff_homology_iso_zero [S.HasHomology] [HasZeroObject C] :
S.Exact ↔ Nonempty (S.homology ≅ 0) := by
rw [exact_iff_isZero_homology]
constructor
· intro h
exact ⟨h.isoZero⟩
· rintro ⟨e⟩
exact IsZero.of_iso (isZero_zero C) e
lemma exact_of_iso (e : S₁ ≅ S₂) (h : S₁.Exact) : S₂.Exact := by
obtain ⟨⟨h, z⟩⟩ := h
exact ⟨⟨HomologyData.ofIso e h, z⟩⟩
lemma exact_iff_of_iso (e : S₁ ≅ S₂) : S₁.Exact ↔ S₂.Exact :=
⟨exact_of_iso e, exact_of_iso e.symm⟩
lemma exact_and_mono_f_iff_of_iso (e : S₁ ≅ S₂) :
S₁.Exact ∧ Mono S₁.f ↔ S₂.Exact ∧ Mono S₂.f := by
have : Mono S₁.f ↔ Mono S₂.f :=
(MorphismProperty.monomorphisms C).arrow_mk_iso_iff
(Arrow.isoMk (ShortComplex.π₁.mapIso e) (ShortComplex.π₂.mapIso e) e.hom.comm₁₂)
rw [exact_iff_of_iso e, this]
lemma exact_and_epi_g_iff_of_iso (e : S₁ ≅ S₂) :
S₁.Exact ∧ Epi S₁.g ↔ S₂.Exact ∧ Epi S₂.g := by
have : Epi S₁.g ↔ Epi S₂.g :=
(MorphismProperty.epimorphisms C).arrow_mk_iso_iff
(Arrow.isoMk (ShortComplex.π₂.mapIso e) (ShortComplex.π₃.mapIso e) e.hom.comm₂₃)
rw [exact_iff_of_iso e, this]
lemma exact_of_isZero_X₂ (h : IsZero S.X₂) : S.Exact := by
rw [(HomologyData.ofZeros S (IsZero.eq_of_tgt h _ _) (IsZero.eq_of_src h _ _)).exact_iff]
exact h
lemma exact_iff_of_epi_of_isIso_of_mono (φ : S₁ ⟶ S₂) [Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] :
S₁.Exact ↔ S₂.Exact := by
constructor
· rintro ⟨h₁, z₁⟩
exact ⟨HomologyData.ofEpiOfIsIsoOfMono φ h₁, z₁⟩
· rintro ⟨h₂, z₂⟩
exact ⟨HomologyData.ofEpiOfIsIsoOfMono' φ h₂, z₂⟩
variable {S}
lemma HomologyData.exact_iff_i_p_zero (h : S.HomologyData) :
S.Exact ↔ h.left.i ≫ h.right.p = 0 := by
haveI := HasHomology.mk' h
rw [h.left.exact_iff, ← h.comm]
constructor
· intro z
rw [IsZero.eq_of_src z h.iso.hom 0, zero_comp, comp_zero]
· intro eq
simp only [IsZero.iff_id_eq_zero, ← cancel_mono h.iso.hom, id_comp, ← cancel_mono h.right.ι,
← cancel_epi h.left.π, eq, zero_comp, comp_zero]
variable (S)
lemma exact_iff_i_p_zero [S.HasHomology] (h₁ : S.LeftHomologyData)
(h₂ : S.RightHomologyData) :
S.Exact ↔ h₁.i ≫ h₂.p = 0 :=
(HomologyData.ofIsIsoLeftRightHomologyComparison' h₁ h₂).exact_iff_i_p_zero
lemma exact_iff_iCycles_pOpcycles_zero [S.HasHomology] :
S.Exact ↔ S.iCycles ≫ S.pOpcycles = 0 :=
S.exact_iff_i_p_zero _ _
lemma exact_iff_kernel_ι_comp_cokernel_π_zero [S.HasHomology]
[HasKernel S.g] [HasCokernel S.f] :
S.Exact ↔ kernel.ι S.g ≫ cokernel.π S.f = 0 := by
haveI := HasLeftHomology.hasCokernel S
haveI := HasRightHomology.hasKernel S
exact S.exact_iff_i_p_zero (LeftHomologyData.ofHasKernelOfHasCokernel S)
(RightHomologyData.ofHasCokernelOfHasKernel S)
variable {S}
lemma Exact.op (h : S.Exact) : S.op.Exact := by
obtain ⟨h, z⟩ := h
exact ⟨⟨h.op, (IsZero.of_iso z h.iso.symm).op⟩⟩
lemma Exact.unop {S : ShortComplex Cᵒᵖ} (h : S.Exact) : S.unop.Exact := by
obtain ⟨h, z⟩ := h
exact ⟨⟨h.unop, (IsZero.of_iso z h.iso.symm).unop⟩⟩
variable (S)
@[simp]
lemma exact_op_iff : S.op.Exact ↔ S.Exact :=
⟨Exact.unop, Exact.op⟩
@[simp]
lemma exact_unop_iff (S : ShortComplex Cᵒᵖ) : S.unop.Exact ↔ S.Exact :=
S.unop.exact_op_iff.symm
variable {S}
lemma LeftHomologyData.exact_map_iff (h : S.LeftHomologyData) (F : C ⥤ D)
[F.PreservesZeroMorphisms] [h.IsPreservedBy F] [(S.map F).HasHomology] :
(S.map F).Exact ↔ IsZero (F.obj h.H) :=
(h.map F).exact_iff
lemma RightHomologyData.exact_map_iff (h : S.RightHomologyData) (F : C ⥤ D)
[F.PreservesZeroMorphisms] [h.IsPreservedBy F] [(S.map F).HasHomology] :
(S.map F).Exact ↔ IsZero (F.obj h.H) :=
(h.map F).exact_iff
lemma Exact.map_of_preservesLeftHomologyOf (h : S.Exact) (F : C ⥤ D)
[F.PreservesZeroMorphisms] [F.PreservesLeftHomologyOf S]
[(S.map F).HasHomology] : (S.map F).Exact := by
have := h.hasHomology
rw [S.leftHomologyData.exact_iff, IsZero.iff_id_eq_zero] at h
rw [S.leftHomologyData.exact_map_iff F, IsZero.iff_id_eq_zero,
← F.map_id, h, F.map_zero]
lemma Exact.map_of_preservesRightHomologyOf (h : S.Exact) (F : C ⥤ D)
[F.PreservesZeroMorphisms] [F.PreservesRightHomologyOf S]
[(S.map F).HasHomology] : (S.map F).Exact := by
have : S.HasHomology := h.hasHomology
rw [S.rightHomologyData.exact_iff, IsZero.iff_id_eq_zero] at h
rw [S.rightHomologyData.exact_map_iff F, IsZero.iff_id_eq_zero,
← F.map_id, h, F.map_zero]
lemma Exact.map (h : S.Exact) (F : C ⥤ D)
[F.PreservesZeroMorphisms] [F.PreservesLeftHomologyOf S]
[F.PreservesRightHomologyOf S] : (S.map F).Exact := by
have := h.hasHomology
exact h.map_of_preservesLeftHomologyOf F
variable (S)
lemma exact_map_iff_of_faithful [S.HasHomology]
(F : C ⥤ D) [F.PreservesZeroMorphisms] [F.PreservesLeftHomologyOf S]
[F.PreservesRightHomologyOf S] [F.Faithful] :
(S.map F).Exact ↔ S.Exact := by
constructor
· intro h
rw [S.leftHomologyData.exact_iff, IsZero.iff_id_eq_zero]
rw [(S.leftHomologyData.map F).exact_iff, IsZero.iff_id_eq_zero,
LeftHomologyData.map_H] at h
apply F.map_injective
rw [F.map_id, F.map_zero, h]
· intro h
exact h.map F
variable {S}
@[reassoc]
lemma Exact.comp_eq_zero (h : S.Exact) {X Y : C} {a : X ⟶ S.X₂} (ha : a ≫ S.g = 0)
{b : S.X₂ ⟶ Y} (hb : S.f ≫ b = 0) : a ≫ b = 0 := by
have := h.hasHomology
have eq := h
rw [exact_iff_iCycles_pOpcycles_zero] at eq
rw [← S.liftCycles_i a ha, ← S.p_descOpcycles b hb, assoc, reassoc_of% eq,
zero_comp, comp_zero]
lemma Exact.isZero_of_both_zeros (ex : S.Exact) (hf : S.f = 0) (hg : S.g = 0) :
IsZero S.X₂ :=
(ShortComplex.HomologyData.ofZeros S hf hg).exact_iff.1 ex
end
section Preadditive
variable [Preadditive C] [Preadditive D] (S : ShortComplex C)
lemma exact_iff_mono [HasZeroObject C] (hf : S.f = 0) :
S.Exact ↔ Mono S.g := by
constructor
· intro h
have := h.hasHomology
simp only [exact_iff_isZero_homology] at h
have := S.isIso_pOpcycles hf
have := mono_of_isZero_kernel' _ S.homologyIsKernel h
rw [← S.p_fromOpcycles]
apply mono_comp
· intro
rw [(HomologyData.ofIsLimitKernelFork S hf _
(KernelFork.IsLimit.ofMonoOfIsZero (KernelFork.ofι (0 : 0 ⟶ S.X₂) zero_comp)
inferInstance (isZero_zero C))).exact_iff]
exact isZero_zero C
lemma exact_iff_epi [HasZeroObject C] (hg : S.g = 0) :
S.Exact ↔ Epi S.f := by
constructor
· intro h
have := h.hasHomology
simp only [exact_iff_isZero_homology] at h
haveI := S.isIso_iCycles hg
haveI : Epi S.toCycles := epi_of_isZero_cokernel' _ S.homologyIsCokernel h
rw [← S.toCycles_i]
apply epi_comp
· intro
rw [(HomologyData.ofIsColimitCokernelCofork S hg _
(CokernelCofork.IsColimit.ofEpiOfIsZero (CokernelCofork.ofπ (0 : S.X₂ ⟶ 0) comp_zero)
inferInstance (isZero_zero C))).exact_iff]
exact isZero_zero C
variable {S}
lemma Exact.epi_f' (hS : S.Exact) (h : LeftHomologyData S) : Epi h.f' :=
epi_of_isZero_cokernel' _ h.hπ (by
haveI := hS.hasHomology
dsimp
simpa only [← h.exact_iff] using hS)
lemma Exact.mono_g' (hS : S.Exact) (h : RightHomologyData S) : Mono h.g' :=
mono_of_isZero_kernel' _ h.hι (by
haveI := hS.hasHomology
dsimp
simpa only [← h.exact_iff] using hS)
lemma Exact.epi_toCycles (hS : S.Exact) [S.HasLeftHomology] : Epi S.toCycles :=
hS.epi_f' _
lemma Exact.mono_fromOpcycles (hS : S.Exact) [S.HasRightHomology] : Mono S.fromOpcycles :=
hS.mono_g' _
lemma LeftHomologyData.exact_iff_epi_f' [S.HasHomology] (h : LeftHomologyData S) :
S.Exact ↔ Epi h.f' := by
constructor
· intro hS
exact hS.epi_f' h
· intro
simp only [h.exact_iff, IsZero.iff_id_eq_zero, ← cancel_epi h.π, ← cancel_epi h.f',
comp_id, h.f'_π, comp_zero]
lemma RightHomologyData.exact_iff_mono_g' [S.HasHomology] (h : RightHomologyData S) :
S.Exact ↔ Mono h.g' := by
constructor
· intro hS
exact hS.mono_g' h
· intro
simp only [h.exact_iff, IsZero.iff_id_eq_zero, ← cancel_mono h.ι, ← cancel_mono h.g',
id_comp, h.ι_g', zero_comp]
/-- Given an exact short complex `S` and a limit kernel fork `kf` for `S.g`, this is the
left homology data for `S` with `K := kf.pt` and `H := 0`. -/
@[simps]
noncomputable def Exact.leftHomologyDataOfIsLimitKernelFork
(hS : S.Exact) [HasZeroObject C] (kf : KernelFork S.g) (hkf : IsLimit kf) :
S.LeftHomologyData where
K := kf.pt
H := 0
i := kf.ι
π := 0
wi := kf.condition
hi := IsLimit.ofIsoLimit hkf (Fork.ext (Iso.refl _) (by simp))
wπ := comp_zero
hπ := CokernelCofork.IsColimit.ofEpiOfIsZero _ (by
have := hS.hasHomology
refine ((MorphismProperty.epimorphisms C).arrow_mk_iso_iff ?_).1
hS.epi_toCycles
refine Arrow.isoMk (Iso.refl _)
(IsLimit.conePointUniqueUpToIso S.cyclesIsKernel hkf) ?_
apply Fork.IsLimit.hom_ext hkf
simp [IsLimit.conePointUniqueUpToIso]) (isZero_zero C)
/-- Given an exact short complex `S` and a colimit cokernel cofork `cc` for `S.f`, this is the
right homology data for `S` with `Q := cc.pt` and `H := 0`. -/
@[simps]
noncomputable def Exact.rightHomologyDataOfIsColimitCokernelCofork
(hS : S.Exact) [HasZeroObject C] (cc : CokernelCofork S.f) (hcc : IsColimit cc) :
S.RightHomologyData where
Q := cc.pt
H := 0
p := cc.π
ι := 0
wp := cc.condition
hp := IsColimit.ofIsoColimit hcc (Cofork.ext (Iso.refl _) (by simp))
wι := zero_comp
hι := KernelFork.IsLimit.ofMonoOfIsZero _ (by
have := hS.hasHomology
refine ((MorphismProperty.monomorphisms C).arrow_mk_iso_iff ?_).2
hS.mono_fromOpcycles
refine Arrow.isoMk (IsColimit.coconePointUniqueUpToIso hcc S.opcyclesIsCokernel)
(Iso.refl _) ?_
apply Cofork.IsColimit.hom_ext hcc
simp [IsColimit.coconePointUniqueUpToIso]) (isZero_zero C)
variable (S)
lemma exact_iff_epi_toCycles [S.HasHomology] : S.Exact ↔ Epi S.toCycles :=
S.leftHomologyData.exact_iff_epi_f'
lemma exact_iff_mono_fromOpcycles [S.HasHomology] : S.Exact ↔ Mono S.fromOpcycles :=
S.rightHomologyData.exact_iff_mono_g'
lemma exact_iff_epi_kernel_lift [S.HasHomology] [HasKernel S.g] :
S.Exact ↔ Epi (kernel.lift S.g S.f S.zero) := by
rw [exact_iff_epi_toCycles]
apply (MorphismProperty.epimorphisms C).arrow_mk_iso_iff
exact Arrow.isoMk (Iso.refl _) S.cyclesIsoKernel (by aesop_cat)
lemma exact_iff_mono_cokernel_desc [S.HasHomology] [HasCokernel S.f] :
S.Exact ↔ Mono (cokernel.desc S.f S.g S.zero) := by
rw [exact_iff_mono_fromOpcycles]
refine (MorphismProperty.monomorphisms C).arrow_mk_iso_iff (Iso.symm ?_)
exact Arrow.isoMk S.opcyclesIsoCokernel.symm (Iso.refl _) (by aesop_cat)
lemma QuasiIso.exact_iff {S₁ S₂ : ShortComplex C} (φ : S₁ ⟶ S₂)
[S₁.HasHomology] [S₂.HasHomology] [QuasiIso φ] : S₁.Exact ↔ S₂.Exact := by
simp only [exact_iff_isZero_homology]
exact Iso.isZero_iff (asIso (homologyMap φ))
lemma exact_of_f_is_kernel (hS : IsLimit (KernelFork.ofι S.f S.zero))
[S.HasHomology] : S.Exact := by
rw [exact_iff_epi_toCycles]
have : IsSplitEpi S.toCycles :=
⟨⟨{ section_ := hS.lift (KernelFork.ofι S.iCycles S.iCycles_g)
id := by
rw [← cancel_mono S.iCycles, assoc, toCycles_i, id_comp]
exact Fork.IsLimit.lift_ι hS }⟩⟩
infer_instance
lemma exact_of_g_is_cokernel (hS : IsColimit (CokernelCofork.ofπ S.g S.zero))
[S.HasHomology] : S.Exact := by
rw [exact_iff_mono_fromOpcycles]
have : IsSplitMono S.fromOpcycles :=
⟨⟨{ retraction := hS.desc (CokernelCofork.ofπ S.pOpcycles S.f_pOpcycles)
id := by
rw [← cancel_epi S.pOpcycles, p_fromOpcycles_assoc, comp_id]
exact Cofork.IsColimit.π_desc hS }⟩⟩
infer_instance
variable {S}
lemma Exact.mono_g (hS : S.Exact) (hf : S.f = 0) : Mono S.g := by
have := hS.hasHomology
have := hS.epi_toCycles
have : S.iCycles = 0 := by rw [← cancel_epi S.toCycles, comp_zero, toCycles_i, hf]
apply Preadditive.mono_of_cancel_zero
intro A x₂ hx₂
rw [← S.liftCycles_i x₂ hx₂, this, comp_zero]
lemma Exact.epi_f (hS : S.Exact) (hg : S.g = 0) : Epi S.f := by
have := hS.hasHomology
have := hS.mono_fromOpcycles
have : S.pOpcycles = 0 := by rw [← cancel_mono S.fromOpcycles, zero_comp, p_fromOpcycles, hg]
apply Preadditive.epi_of_cancel_zero
intro A x₂ hx₂
rw [← S.p_descOpcycles x₂ hx₂, this, zero_comp]
lemma Exact.mono_g_iff (hS : S.Exact) : Mono S.g ↔ S.f = 0 := by
constructor
· intro
rw [← cancel_mono S.g, zero, zero_comp]
· exact hS.mono_g
lemma Exact.epi_f_iff (hS : S.Exact) : Epi S.f ↔ S.g = 0 := by
constructor
· intro
rw [← cancel_epi S.f, zero, comp_zero]
· exact hS.epi_f
lemma Exact.isZero_X₂ (hS : S.Exact) (hf : S.f = 0) (hg : S.g = 0) : IsZero S.X₂ := by
have := hS.mono_g hf
rw [IsZero.iff_id_eq_zero, ← cancel_mono S.g, hg, comp_zero, comp_zero]
lemma Exact.isZero_X₂_iff (hS : S.Exact) : IsZero S.X₂ ↔ S.f = 0 ∧ S.g = 0 := by
constructor
· intro h
exact ⟨h.eq_of_tgt _ _, h.eq_of_src _ _⟩
· rintro ⟨hf, hg⟩
exact hS.isZero_X₂ hf hg
|
variable (S)
| Mathlib/Algebra/Homology/ShortComplex/Exact.lean | 465 | 467 |
/-
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.Order.Group.Finset
import Mathlib.Algebra.Polynomial.Derivative
import Mathlib.Algebra.Polynomial.Eval.SMul
import Mathlib.Algebra.Polynomial.Roots
import Mathlib.RingTheory.EuclideanDomain
import Mathlib.RingTheory.UniqueFactorizationDomain.NormalizedFactors
/-!
# Theory of univariate polynomials
This file starts looking like the ring theory of $R[X]$
-/
noncomputable section
open Polynomial
namespace Polynomial
universe u v w y z
variable {R : Type u} {S : Type v} {k : Type y} {A : Type z} {a b : R} {n : ℕ}
section CommRing
variable [CommRing R]
theorem rootMultiplicity_sub_one_le_derivative_rootMultiplicity_of_ne_zero
(p : R[X]) (t : R) (hnezero : derivative p ≠ 0) :
p.rootMultiplicity t - 1 ≤ p.derivative.rootMultiplicity t :=
(le_rootMultiplicity_iff hnezero).2 <|
pow_sub_one_dvd_derivative_of_pow_dvd (p.pow_rootMultiplicity_dvd t)
theorem derivative_rootMultiplicity_of_root_of_mem_nonZeroDivisors
{p : R[X]} {t : R} (hpt : Polynomial.IsRoot p t)
(hnzd : (p.rootMultiplicity t : R) ∈ nonZeroDivisors R) :
(derivative p).rootMultiplicity t = p.rootMultiplicity t - 1 := by
by_cases h : p = 0
· simp only [h, map_zero, rootMultiplicity_zero]
obtain ⟨g, hp, hndvd⟩ := p.exists_eq_pow_rootMultiplicity_mul_and_not_dvd h t
set m := p.rootMultiplicity t
have hm : m - 1 + 1 = m := Nat.sub_add_cancel <| (rootMultiplicity_pos h).2 hpt
have hndvd : ¬(X - C t) ^ m ∣ derivative p := by
rw [hp, derivative_mul, dvd_add_left (dvd_mul_right _ _),
derivative_X_sub_C_pow, ← hm, pow_succ, hm, mul_comm (C _), mul_assoc,
dvd_cancel_left_mem_nonZeroDivisors (monic_X_sub_C t |>.pow _ |>.mem_nonZeroDivisors)]
rw [dvd_iff_isRoot, IsRoot] at hndvd ⊢
rwa [eval_mul, eval_C, mul_left_mem_nonZeroDivisors_eq_zero_iff hnzd]
have hnezero : derivative p ≠ 0 := fun h ↦ hndvd (by rw [h]; exact dvd_zero _)
exact le_antisymm (by rwa [rootMultiplicity_le_iff hnezero, hm])
(rootMultiplicity_sub_one_le_derivative_rootMultiplicity_of_ne_zero _ t hnezero)
theorem isRoot_iterate_derivative_of_lt_rootMultiplicity {p : R[X]} {t : R} {n : ℕ}
(hn : n < p.rootMultiplicity t) : (derivative^[n] p).IsRoot t :=
dvd_iff_isRoot.mp <| (dvd_pow_self _ <| Nat.sub_ne_zero_of_lt hn).trans
(pow_sub_dvd_iterate_derivative_of_pow_dvd _ <| p.pow_rootMultiplicity_dvd t)
open Finset in
theorem eval_iterate_derivative_rootMultiplicity {p : R[X]} {t : R} :
(derivative^[p.rootMultiplicity t] p).eval t =
(p.rootMultiplicity t).factorial • (p /ₘ (X - C t) ^ p.rootMultiplicity t).eval t := by
set m := p.rootMultiplicity t with hm
conv_lhs => rw [← p.pow_mul_divByMonic_rootMultiplicity_eq t, ← hm]
rw [iterate_derivative_mul, eval_finset_sum, sum_eq_single_of_mem _ (mem_range.mpr m.succ_pos)]
· rw [m.choose_zero_right, one_smul, eval_mul, m.sub_zero, iterate_derivative_X_sub_pow_self,
eval_natCast, nsmul_eq_mul]; rfl
· intro b hb hb0
rw [iterate_derivative_X_sub_pow, eval_smul, eval_mul, eval_smul, eval_pow,
Nat.sub_sub_self (mem_range_succ_iff.mp hb), eval_sub, eval_X, eval_C, sub_self,
zero_pow hb0, smul_zero, zero_mul, smul_zero]
theorem lt_rootMultiplicity_of_isRoot_iterate_derivative_of_mem_nonZeroDivisors
{p : R[X]} {t : R} {n : ℕ} (h : p ≠ 0)
(hroot : ∀ m ≤ n, (derivative^[m] p).IsRoot t)
(hnzd : (n.factorial : R) ∈ nonZeroDivisors R) :
n < p.rootMultiplicity t := by
by_contra! h'
replace hroot := hroot _ h'
simp only [IsRoot, eval_iterate_derivative_rootMultiplicity] at hroot
obtain ⟨q, hq⟩ := Nat.cast_dvd_cast (α := R) <| Nat.factorial_dvd_factorial h'
rw [hq, mul_mem_nonZeroDivisors] at hnzd
rw [nsmul_eq_mul, mul_left_mem_nonZeroDivisors_eq_zero_iff hnzd.1] at hroot
exact eval_divByMonic_pow_rootMultiplicity_ne_zero t h hroot
theorem lt_rootMultiplicity_of_isRoot_iterate_derivative_of_mem_nonZeroDivisors'
{p : R[X]} {t : R} {n : ℕ} (h : p ≠ 0)
(hroot : ∀ m ≤ n, (derivative^[m] p).IsRoot t)
(hnzd : ∀ m ≤ n, m ≠ 0 → (m : R) ∈ nonZeroDivisors R) :
n < p.rootMultiplicity t := by
apply lt_rootMultiplicity_of_isRoot_iterate_derivative_of_mem_nonZeroDivisors h hroot
clear hroot
induction n with
| zero =>
simp only [Nat.factorial_zero, Nat.cast_one]
exact Submonoid.one_mem _
| succ n ih =>
rw [Nat.factorial_succ, Nat.cast_mul, mul_mem_nonZeroDivisors]
exact ⟨hnzd _ le_rfl n.succ_ne_zero, ih fun m h ↦ hnzd m (h.trans n.le_succ)⟩
theorem lt_rootMultiplicity_iff_isRoot_iterate_derivative_of_mem_nonZeroDivisors
{p : R[X]} {t : R} {n : ℕ} (h : p ≠ 0)
(hnzd : (n.factorial : R) ∈ nonZeroDivisors R) :
n < p.rootMultiplicity t ↔ ∀ m ≤ n, (derivative^[m] p).IsRoot t :=
⟨fun hn _ hm ↦ isRoot_iterate_derivative_of_lt_rootMultiplicity <| hm.trans_lt hn,
fun hr ↦ lt_rootMultiplicity_of_isRoot_iterate_derivative_of_mem_nonZeroDivisors h hr hnzd⟩
theorem lt_rootMultiplicity_iff_isRoot_iterate_derivative_of_mem_nonZeroDivisors'
{p : R[X]} {t : R} {n : ℕ} (h : p ≠ 0)
(hnzd : ∀ m ≤ n, m ≠ 0 → (m : R) ∈ nonZeroDivisors R) :
n < p.rootMultiplicity t ↔ ∀ m ≤ n, (derivative^[m] p).IsRoot t :=
⟨fun hn _ hm ↦ isRoot_iterate_derivative_of_lt_rootMultiplicity <| Nat.lt_of_le_of_lt hm hn,
fun hr ↦ lt_rootMultiplicity_of_isRoot_iterate_derivative_of_mem_nonZeroDivisors' h hr hnzd⟩
theorem one_lt_rootMultiplicity_iff_isRoot_iterate_derivative
{p : R[X]} {t : R} (h : p ≠ 0) :
1 < p.rootMultiplicity t ↔ ∀ m ≤ 1, (derivative^[m] p).IsRoot t :=
lt_rootMultiplicity_iff_isRoot_iterate_derivative_of_mem_nonZeroDivisors h
(by rw [Nat.factorial_one, Nat.cast_one]; exact Submonoid.one_mem _)
theorem one_lt_rootMultiplicity_iff_isRoot
{p : R[X]} {t : R} (h : p ≠ 0) :
1 < p.rootMultiplicity t ↔ p.IsRoot t ∧ (derivative p).IsRoot t := by
rw [one_lt_rootMultiplicity_iff_isRoot_iterate_derivative h]
refine ⟨fun h ↦ ⟨h 0 (by norm_num), h 1 (by norm_num)⟩, fun ⟨h0, h1⟩ m hm ↦ ?_⟩
obtain (_|_|m) := m
exacts [h0, h1, by omega]
end CommRing
section IsDomain
variable [CommRing R] [IsDomain R]
theorem one_lt_rootMultiplicity_iff_isRoot_gcd
[GCDMonoid R[X]] {p : R[X]} {t : R} (h : p ≠ 0) :
1 < p.rootMultiplicity t ↔ (gcd p (derivative p)).IsRoot t := by
simp_rw [one_lt_rootMultiplicity_iff_isRoot h, ← dvd_iff_isRoot, dvd_gcd_iff]
theorem derivative_rootMultiplicity_of_root [CharZero R] {p : R[X]} {t : R} (hpt : p.IsRoot t) :
p.derivative.rootMultiplicity t = p.rootMultiplicity t - 1 := by
by_cases h : p = 0
· rw [h, map_zero, rootMultiplicity_zero]
exact derivative_rootMultiplicity_of_root_of_mem_nonZeroDivisors hpt <|
mem_nonZeroDivisors_of_ne_zero <| Nat.cast_ne_zero.2 ((rootMultiplicity_pos h).2 hpt).ne'
theorem rootMultiplicity_sub_one_le_derivative_rootMultiplicity [CharZero R] (p : R[X]) (t : R) :
p.rootMultiplicity t - 1 ≤ p.derivative.rootMultiplicity t := by
by_cases h : p.IsRoot t
· exact (derivative_rootMultiplicity_of_root h).symm.le
· rw [rootMultiplicity_eq_zero h, zero_tsub]
exact zero_le _
theorem lt_rootMultiplicity_of_isRoot_iterate_derivative
[CharZero R] {p : R[X]} {t : R} {n : ℕ} (h : p ≠ 0)
(hroot : ∀ m ≤ n, (derivative^[m] p).IsRoot t) :
n < p.rootMultiplicity t :=
lt_rootMultiplicity_of_isRoot_iterate_derivative_of_mem_nonZeroDivisors h hroot <|
mem_nonZeroDivisors_of_ne_zero <| Nat.cast_ne_zero.2 <| Nat.factorial_ne_zero n
theorem lt_rootMultiplicity_iff_isRoot_iterate_derivative
[CharZero R] {p : R[X]} {t : R} {n : ℕ} (h : p ≠ 0) :
n < p.rootMultiplicity t ↔ ∀ m ≤ n, (derivative^[m] p).IsRoot t :=
⟨fun hn _ hm ↦ isRoot_iterate_derivative_of_lt_rootMultiplicity <| Nat.lt_of_le_of_lt hm hn,
fun hr ↦ lt_rootMultiplicity_of_isRoot_iterate_derivative h hr⟩
/-- A sufficient condition for the set of roots of a nonzero polynomial `f` to be a subset of the
set of roots of `g` is that `f` divides `f.derivative * g`. Over an algebraically closed field of
characteristic zero, this is also a necessary condition.
See `isRoot_of_isRoot_iff_dvd_derivative_mul` -/
theorem isRoot_of_isRoot_of_dvd_derivative_mul [CharZero R] {f g : R[X]} (hf0 : f ≠ 0)
(hfd : f ∣ f.derivative * g) {a : R} (haf : f.IsRoot a) : g.IsRoot a := by
rcases hfd with ⟨r, hr⟩
have hdf0 : derivative f ≠ 0 := by
contrapose! haf
rw [eq_C_of_derivative_eq_zero haf] at hf0 ⊢
exact not_isRoot_C _ _ <| C_ne_zero.mp hf0
by_contra hg
have hdfg0 : f.derivative * g ≠ 0 := mul_ne_zero hdf0 (by rintro rfl; simp at hg)
have hr' := congr_arg (rootMultiplicity a) hr
rw [rootMultiplicity_mul hdfg0, derivative_rootMultiplicity_of_root haf,
rootMultiplicity_eq_zero hg, add_zero, rootMultiplicity_mul (hr ▸ hdfg0), add_comm,
Nat.sub_eq_iff_eq_add (Nat.succ_le_iff.2 ((rootMultiplicity_pos hf0).2 haf))] at hr'
omega
section NormalizationMonoid
variable [NormalizationMonoid R]
instance instNormalizationMonoid : NormalizationMonoid R[X] where
normUnit p :=
⟨C ↑(normUnit p.leadingCoeff), C ↑(normUnit p.leadingCoeff)⁻¹, by
rw [← RingHom.map_mul, Units.mul_inv, C_1], by rw [← RingHom.map_mul, Units.inv_mul, C_1]⟩
normUnit_zero := Units.ext (by simp)
normUnit_mul hp0 hq0 :=
Units.ext
(by
dsimp
rw [Ne, ← leadingCoeff_eq_zero] at *
rw [leadingCoeff_mul, normUnit_mul hp0 hq0, Units.val_mul, C_mul])
normUnit_coe_units u :=
Units.ext
(by
dsimp
rw [← mul_one u⁻¹, Units.val_mul, Units.eq_inv_mul_iff_mul_eq]
rcases Polynomial.isUnit_iff.1 ⟨u, rfl⟩ with ⟨_, ⟨w, rfl⟩, h2⟩
rw [← h2, leadingCoeff_C, normUnit_coe_units, ← C_mul, Units.mul_inv, C_1]
rfl)
@[simp]
theorem coe_normUnit {p : R[X]} : (normUnit p : R[X]) = C ↑(normUnit p.leadingCoeff) := by
simp [normUnit]
@[simp]
theorem leadingCoeff_normalize (p : R[X]) :
leadingCoeff (normalize p) = normalize (leadingCoeff p) := by simp [normalize_apply]
theorem Monic.normalize_eq_self {p : R[X]} (hp : p.Monic) : normalize p = p := by
simp only [Polynomial.coe_normUnit, normalize_apply, hp.leadingCoeff, normUnit_one,
Units.val_one, Polynomial.C.map_one, mul_one]
theorem roots_normalize {p : R[X]} : (normalize p).roots = p.roots := by
rw [normalize_apply, mul_comm, coe_normUnit, roots_C_mul _ (normUnit (leadingCoeff p)).ne_zero]
theorem normUnit_X : normUnit (X : Polynomial R) = 1 := by
have := coe_normUnit (R := R) (p := X)
rwa [leadingCoeff_X, normUnit_one, Units.val_one, map_one, Units.val_eq_one] at this
theorem X_eq_normalize : (X : Polynomial R) = normalize X := by
simp only [normalize_apply, normUnit_X, Units.val_one, mul_one]
end NormalizationMonoid
end IsDomain
section DivisionRing
variable [DivisionRing R] {p q : R[X]}
theorem degree_pos_of_ne_zero_of_nonunit (hp0 : p ≠ 0) (hp : ¬IsUnit p) : 0 < degree p :=
lt_of_not_ge fun h => by
rw [eq_C_of_degree_le_zero h] at hp0 hp
exact hp (IsUnit.map C (IsUnit.mk0 (coeff p 0) (mt C_inj.2 (by simpa using hp0))))
@[simp]
protected theorem map_eq_zero [Semiring S] [Nontrivial S] (f : R →+* S) : p.map f = 0 ↔ p = 0 := by
simp only [Polynomial.ext_iff]
congr!
simp [map_eq_zero, coeff_map, coeff_zero]
theorem map_ne_zero [Semiring S] [Nontrivial S] {f : R →+* S} (hp : p ≠ 0) : p.map f ≠ 0 :=
mt (Polynomial.map_eq_zero f).1 hp
@[simp]
theorem degree_map [Semiring S] [Nontrivial S] (p : R[X]) (f : R →+* S) :
degree (p.map f) = degree p :=
p.degree_map_eq_of_injective f.injective
@[simp]
theorem natDegree_map [Semiring S] [Nontrivial S] (f : R →+* S) :
natDegree (p.map f) = natDegree p :=
natDegree_eq_of_degree_eq (degree_map _ f)
@[simp]
theorem leadingCoeff_map [Semiring S] [Nontrivial S] (f : R →+* S) :
leadingCoeff (p.map f) = f (leadingCoeff p) := by
simp only [← coeff_natDegree, coeff_map f, natDegree_map]
theorem monic_map_iff [Semiring S] [Nontrivial S] {f : R →+* S} {p : R[X]} :
(p.map f).Monic ↔ p.Monic := by
rw [Monic, leadingCoeff_map, ← f.map_one, Function.Injective.eq_iff f.injective, Monic]
end DivisionRing
section Field
variable [Field R] {p q : R[X]}
theorem isUnit_iff_degree_eq_zero : IsUnit p ↔ degree p = 0 :=
⟨degree_eq_zero_of_isUnit, fun h =>
have : degree p ≤ 0 := by simp [*, le_refl]
have hc : coeff p 0 ≠ 0 := fun hc => by
rw [eq_C_of_degree_le_zero this, hc] at h; simp only [map_zero] at h; contradiction
isUnit_iff_dvd_one.2
⟨C (coeff p 0)⁻¹, by
conv in p => rw [eq_C_of_degree_le_zero this]
rw [← C_mul, mul_inv_cancel₀ hc, C_1]⟩⟩
/-- Division of polynomials. See `Polynomial.divByMonic` for more details. -/
def div (p q : R[X]) :=
C (leadingCoeff q)⁻¹ * (p /ₘ (q * C (leadingCoeff q)⁻¹))
/-- Remainder of polynomial division. See `Polynomial.modByMonic` for more details. -/
def mod (p q : R[X]) :=
p %ₘ (q * C (leadingCoeff q)⁻¹)
private theorem quotient_mul_add_remainder_eq_aux (p q : R[X]) : q * div p q + mod p q = p := by
by_cases h : q = 0
· simp only [h, zero_mul, mod, modByMonic_zero, zero_add]
· conv =>
rhs
rw [← modByMonic_add_div p (monic_mul_leadingCoeff_inv h)]
rw [div, mod, add_comm, mul_assoc]
private theorem remainder_lt_aux (p : R[X]) (hq : q ≠ 0) : degree (mod p q) < degree q := by
rw [← degree_mul_leadingCoeff_inv q hq]
exact degree_modByMonic_lt p (monic_mul_leadingCoeff_inv hq)
instance : Div R[X] :=
⟨div⟩
instance : Mod R[X] :=
⟨mod⟩
theorem div_def : p / q = C (leadingCoeff q)⁻¹ * (p /ₘ (q * C (leadingCoeff q)⁻¹)) :=
rfl
theorem mod_def : p % q = p %ₘ (q * C (leadingCoeff q)⁻¹) := rfl
theorem modByMonic_eq_mod (p : R[X]) (hq : Monic q) : p %ₘ q = p % q :=
show p %ₘ q = p %ₘ (q * C (leadingCoeff q)⁻¹) by
simp only [Monic.def.1 hq, inv_one, mul_one, C_1]
theorem divByMonic_eq_div (p : R[X]) (hq : Monic q) : p /ₘ q = p / q :=
show p /ₘ q = C (leadingCoeff q)⁻¹ * (p /ₘ (q * C (leadingCoeff q)⁻¹)) by
simp only [Monic.def.1 hq, inv_one, C_1, one_mul, mul_one]
theorem mod_X_sub_C_eq_C_eval (p : R[X]) (a : R) : p % (X - C a) = C (p.eval a) :=
modByMonic_eq_mod p (monic_X_sub_C a) ▸ modByMonic_X_sub_C_eq_C_eval _ _
theorem mul_div_eq_iff_isRoot : (X - C a) * (p / (X - C a)) = p ↔ IsRoot p a :=
divByMonic_eq_div p (monic_X_sub_C a) ▸ mul_divByMonic_eq_iff_isRoot
instance instEuclideanDomain : EuclideanDomain R[X] :=
{ Polynomial.commRing,
Polynomial.nontrivial with
quotient := (· / ·)
quotient_zero := by simp [div_def]
remainder := (· % ·)
r := _
r_wellFounded := degree_lt_wf
quotient_mul_add_remainder_eq := quotient_mul_add_remainder_eq_aux
remainder_lt := fun _ _ hq => remainder_lt_aux _ hq
mul_left_not_lt := fun _ _ hq => not_lt_of_ge (degree_le_mul_left _ hq) }
theorem mod_eq_self_iff (hq0 : q ≠ 0) : p % q = p ↔ degree p < degree q :=
⟨fun h => h ▸ EuclideanDomain.mod_lt _ hq0, fun h => by
classical
have : ¬degree (q * C (leadingCoeff q)⁻¹) ≤ degree p :=
not_le_of_gt <| by rwa [degree_mul_leadingCoeff_inv q hq0]
rw [mod_def, modByMonic, dif_pos (monic_mul_leadingCoeff_inv hq0)]
unfold divModByMonicAux
dsimp
simp only [this, false_and, if_false]⟩
theorem div_eq_zero_iff (hq0 : q ≠ 0) : p / q = 0 ↔ degree p < degree q :=
⟨fun h => by
have := EuclideanDomain.div_add_mod p q
rwa [h, mul_zero, zero_add, mod_eq_self_iff hq0] at this,
fun h => by
have hlt : degree p < degree (q * C (leadingCoeff q)⁻¹) := by
rwa [degree_mul_leadingCoeff_inv q hq0]
have hm : Monic (q * C (leadingCoeff q)⁻¹) := monic_mul_leadingCoeff_inv hq0
rw [div_def, (divByMonic_eq_zero_iff hm).2 hlt, mul_zero]⟩
theorem degree_add_div (hq0 : q ≠ 0) (hpq : degree q ≤ degree p) :
degree q + degree (p / q) = degree p := by
have : degree (p % q) < degree (q * (p / q)) :=
calc
degree (p % q) < degree q := EuclideanDomain.mod_lt _ hq0
_ ≤ _ := degree_le_mul_left _ (mt (div_eq_zero_iff hq0).1 (not_lt_of_ge hpq))
conv_rhs =>
rw [← EuclideanDomain.div_add_mod p q, degree_add_eq_left_of_degree_lt this, degree_mul]
theorem degree_div_le (p q : R[X]) : degree (p / q) ≤ degree p := by
by_cases hq : q = 0
· simp [hq]
· rw [div_def, mul_comm, degree_mul_leadingCoeff_inv _ hq]; exact degree_divByMonic_le _ _
theorem degree_div_lt (hp : p ≠ 0) (hq : 0 < degree q) : degree (p / q) < degree p := by
have hq0 : q ≠ 0 := fun hq0 => by simp [hq0] at hq
rw [div_def, mul_comm, degree_mul_leadingCoeff_inv _ hq0]
exact degree_divByMonic_lt _ (monic_mul_leadingCoeff_inv hq0) hp
(by rw [degree_mul_leadingCoeff_inv _ hq0]; exact hq)
theorem isUnit_map [Field k] (f : R →+* k) : IsUnit (p.map f) ↔ IsUnit p := by
simp_rw [isUnit_iff_degree_eq_zero, degree_map]
theorem map_div [Field k] (f : R →+* k) : (p / q).map f = p.map f / q.map f := by
if hq0 : q = 0 then simp [hq0]
else
rw [div_def, div_def, Polynomial.map_mul, map_divByMonic f (monic_mul_leadingCoeff_inv hq0),
Polynomial.map_mul, map_C, leadingCoeff_map, map_inv₀]
theorem map_mod [Field k] (f : R →+* k) : (p % q).map f = p.map f % q.map f := by
by_cases hq0 : q = 0
· simp [hq0]
· rw [mod_def, mod_def, leadingCoeff_map f, ← map_inv₀ f, ← map_C f, ← Polynomial.map_mul f,
map_modByMonic f (monic_mul_leadingCoeff_inv hq0)]
lemma natDegree_mod_lt [Field k] (p : k[X]) {q : k[X]} (hq : q.natDegree ≠ 0) :
(p % q).natDegree < q.natDegree := by
have hq' : q.leadingCoeff ≠ 0 := by
rw [leadingCoeff_ne_zero]
contrapose! hq
simp [hq]
rw [mod_def]
refine (natDegree_modByMonic_lt p ?_ ?_).trans_le ?_
· refine monic_mul_C_of_leadingCoeff_mul_eq_one ?_
rw [mul_inv_eq_one₀ hq']
· contrapose! hq
rw [← natDegree_mul_C_eq_of_mul_eq_one ((inv_mul_eq_one₀ hq').mpr rfl)]
simp [hq]
· exact natDegree_mul_C_le q q.leadingCoeff⁻¹
section
open EuclideanDomain
theorem gcd_map [Field k] [DecidableEq R] [DecidableEq k] (f : R →+* k) :
gcd (p.map f) (q.map f) = (gcd p q).map f :=
GCD.induction p q (fun x => by simp_rw [Polynomial.map_zero, EuclideanDomain.gcd_zero_left])
fun x y _ ih => by rw [gcd_val, ← map_mod, ih, ← gcd_val]
end
theorem eval₂_gcd_eq_zero [CommSemiring k] [DecidableEq R]
{ϕ : R →+* k} {f g : R[X]} {α : k} (hf : f.eval₂ ϕ α = 0)
(hg : g.eval₂ ϕ α = 0) : (EuclideanDomain.gcd f g).eval₂ ϕ α = 0 := by
rw [EuclideanDomain.gcd_eq_gcd_ab f g, Polynomial.eval₂_add, Polynomial.eval₂_mul,
Polynomial.eval₂_mul, hf, hg, zero_mul, zero_mul, zero_add]
theorem eval_gcd_eq_zero [DecidableEq R] {f g : R[X]} {α : R}
(hf : f.eval α = 0) (hg : g.eval α = 0) : (EuclideanDomain.gcd f g).eval α = 0 :=
eval₂_gcd_eq_zero hf hg
theorem root_left_of_root_gcd [CommSemiring k] [DecidableEq R] {ϕ : R →+* k} {f g : R[X]} {α : k}
(hα : (EuclideanDomain.gcd f g).eval₂ ϕ α = 0) : f.eval₂ ϕ α = 0 := by
obtain ⟨p, hp⟩ := EuclideanDomain.gcd_dvd_left f g
rw [hp, Polynomial.eval₂_mul, hα, zero_mul]
theorem root_right_of_root_gcd [CommSemiring k] [DecidableEq R] {ϕ : R →+* k} {f g : R[X]} {α : k}
(hα : (EuclideanDomain.gcd f g).eval₂ ϕ α = 0) : g.eval₂ ϕ α = 0 := by
obtain ⟨p, hp⟩ := EuclideanDomain.gcd_dvd_right f g
rw [hp, Polynomial.eval₂_mul, hα, zero_mul]
theorem root_gcd_iff_root_left_right [CommSemiring k] [DecidableEq R]
{ϕ : R →+* k} {f g : R[X]} {α : k} :
(EuclideanDomain.gcd f g).eval₂ ϕ α = 0 ↔ f.eval₂ ϕ α = 0 ∧ g.eval₂ ϕ α = 0 :=
⟨fun h => ⟨root_left_of_root_gcd h, root_right_of_root_gcd h⟩, fun h => eval₂_gcd_eq_zero h.1 h.2⟩
theorem isRoot_gcd_iff_isRoot_left_right [DecidableEq R] {f g : R[X]} {α : R} :
(EuclideanDomain.gcd f g).IsRoot α ↔ f.IsRoot α ∧ g.IsRoot α :=
root_gcd_iff_root_left_right
theorem isCoprime_map [Field k] (f : R →+* k) : IsCoprime (p.map f) (q.map f) ↔ IsCoprime p q := by
classical
rw [← EuclideanDomain.gcd_isUnit_iff, ← EuclideanDomain.gcd_isUnit_iff, gcd_map, isUnit_map]
theorem mem_roots_map [CommRing k] [IsDomain k] {f : R →+* k} {x : k} (hp : p ≠ 0) :
x ∈ (p.map f).roots ↔ p.eval₂ f x = 0 := by
rw [mem_roots (map_ne_zero hp), IsRoot, Polynomial.eval_map]
theorem rootSet_monomial [CommRing S] [IsDomain S] [Algebra R S] {n : ℕ} (hn : n ≠ 0) {a : R}
(ha : a ≠ 0) : (monomial n a).rootSet S = {0} := by
classical
rw [rootSet, aroots_monomial ha,
Multiset.toFinset_nsmul _ _ hn, Multiset.toFinset_singleton, Finset.coe_singleton]
theorem rootSet_C_mul_X_pow [CommRing S] [IsDomain S] [Algebra R S] {n : ℕ} (hn : n ≠ 0) {a : R}
(ha : a ≠ 0) : rootSet (C a * X ^ n) S = {0} := by
rw [C_mul_X_pow_eq_monomial, rootSet_monomial hn ha]
| theorem rootSet_X_pow [CommRing S] [IsDomain S] [Algebra R S] {n : ℕ} (hn : n ≠ 0) :
(X ^ n : R[X]).rootSet S = {0} := by
rw [← one_mul (X ^ n : R[X]), ← C_1, rootSet_C_mul_X_pow hn]
| Mathlib/Algebra/Polynomial/FieldDivision.lean | 481 | 483 |
/-
Copyright (c) 2020 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel, Yury Kudryashov
-/
import Mathlib.Analysis.Calculus.FormalMultilinearSeries
import Mathlib.Analysis.SpecificLimits.Normed
import Mathlib.Logic.Equiv.Fin.Basic
import Mathlib.Tactic.Bound.Attribute
import Mathlib.Topology.Algebra.InfiniteSum.Module
/-!
# Analytic functions
A function is analytic in one dimension around `0` if it can be written as a converging power series
`Σ pₙ zⁿ`. This definition can be extended to any dimension (even in infinite dimension) by
requiring that `pₙ` is a continuous `n`-multilinear map. In general, `pₙ` is not unique (in two
dimensions, taking `p₂ (x, y) (x', y') = x y'` or `y x'` gives the same map when applied to a
vector `(x, y) (x, y)`). A way to guarantee uniqueness is to take a symmetric `pₙ`, but this is not
always possible in nonzero characteristic (in characteristic 2, the previous example has no
symmetric representative). Therefore, we do not insist on symmetry or uniqueness in the definition,
and we only require the existence of a converging series.
The general framework is important to say that the exponential map on bounded operators on a Banach
space is analytic, as well as the inverse on invertible operators.
## Main definitions
Let `p` be a formal multilinear series from `E` to `F`, i.e., `p n` is a multilinear map on `E^n`
for `n : ℕ`.
* `p.radius`: the largest `r : ℝ≥0∞` such that `‖p n‖ * r^n` grows subexponentially.
* `p.le_radius_of_bound`, `p.le_radius_of_bound_nnreal`, `p.le_radius_of_isBigO`: if `‖p n‖ * r ^ n`
is bounded above, then `r ≤ p.radius`;
* `p.isLittleO_of_lt_radius`, `p.norm_mul_pow_le_mul_pow_of_lt_radius`,
`p.isLittleO_one_of_lt_radius`,
`p.norm_mul_pow_le_of_lt_radius`, `p.nnnorm_mul_pow_le_of_lt_radius`: if `r < p.radius`, then
`‖p n‖ * r ^ n` tends to zero exponentially;
* `p.lt_radius_of_isBigO`: if `r ≠ 0` and `‖p n‖ * r ^ n = O(a ^ n)` for some `-1 < a < 1`, then
`r < p.radius`;
* `p.partialSum n x`: the sum `∑_{i = 0}^{n-1} pᵢ xⁱ`.
* `p.sum x`: the sum `∑'_{i = 0}^{∞} pᵢ xⁱ`.
Additionally, let `f` be a function from `E` to `F`.
* `HasFPowerSeriesOnBall f p x r`: on the ball of center `x` with radius `r`,
`f (x + y) = ∑'_n pₙ yⁿ`.
* `HasFPowerSeriesAt f p x`: on some ball of center `x` with positive radius, holds
`HasFPowerSeriesOnBall f p x r`.
* `AnalyticAt 𝕜 f x`: there exists a power series `p` such that holds `HasFPowerSeriesAt f p x`.
* `AnalyticOnNhd 𝕜 f s`: the function `f` is analytic at every point of `s`.
We also define versions of `HasFPowerSeriesOnBall`, `AnalyticAt`, and `AnalyticOnNhd` restricted to
a set, similar to `ContinuousWithinAt`. See `Mathlib.Analysis.Analytic.Within` for basic properties.
* `AnalyticWithinAt 𝕜 f s x` means a power series at `x` converges to `f` on `𝓝[s ∪ {x}] x`.
* `AnalyticOn 𝕜 f s t` means `∀ x ∈ t, AnalyticWithinAt 𝕜 f s x`.
We develop the basic properties of these notions, notably:
* If a function admits a power series, it is continuous (see
`HasFPowerSeriesOnBall.continuousOn` and `HasFPowerSeriesAt.continuousAt` and
`AnalyticAt.continuousAt`).
* In a complete space, the sum of a formal power series with positive radius is well defined on the
disk of convergence, see `FormalMultilinearSeries.hasFPowerSeriesOnBall`.
## Implementation details
We only introduce the radius of convergence of a power series, as `p.radius`.
For a power series in finitely many dimensions, there is a finer (directional, coordinate-dependent)
notion, describing the polydisk of convergence. This notion is more specific, and not necessary to
build the general theory. We do not define it here.
-/
noncomputable section
variable {𝕜 E F G : Type*}
open Topology NNReal Filter ENNReal Set Asymptotics
namespace FormalMultilinearSeries
variable [Semiring 𝕜] [AddCommMonoid E] [AddCommMonoid F] [Module 𝕜 E] [Module 𝕜 F]
variable [TopologicalSpace E] [TopologicalSpace F]
variable [ContinuousAdd E] [ContinuousAdd F]
variable [ContinuousConstSMul 𝕜 E] [ContinuousConstSMul 𝕜 F]
/-- Given a formal multilinear series `p` and a vector `x`, then `p.sum x` is the sum `Σ pₙ xⁿ`. A
priori, it only behaves well when `‖x‖ < p.radius`. -/
protected def sum (p : FormalMultilinearSeries 𝕜 E F) (x : E) : F :=
∑' n : ℕ, p n fun _ => x
/-- Given a formal multilinear series `p` and a vector `x`, then `p.partialSum n x` is the sum
`Σ pₖ xᵏ` for `k ∈ {0,..., n-1}`. -/
def partialSum (p : FormalMultilinearSeries 𝕜 E F) (n : ℕ) (x : E) : F :=
∑ k ∈ Finset.range n, p k fun _ : Fin k => x
/-- The partial sums of a formal multilinear series are continuous. -/
theorem partialSum_continuous (p : FormalMultilinearSeries 𝕜 E F) (n : ℕ) :
Continuous (p.partialSum n) := by
unfold partialSum
fun_prop
end FormalMultilinearSeries
/-! ### The radius of a formal multilinear series -/
variable [NontriviallyNormedField 𝕜] [NormedAddCommGroup E] [NormedSpace 𝕜 E] [NormedAddCommGroup F]
[NormedSpace 𝕜 F] [NormedAddCommGroup G] [NormedSpace 𝕜 G]
namespace FormalMultilinearSeries
variable (p : FormalMultilinearSeries 𝕜 E F) {r : ℝ≥0}
/-- The radius of a formal multilinear series is the largest `r` such that the sum `Σ ‖pₙ‖ ‖y‖ⁿ`
converges for all `‖y‖ < r`. This implies that `Σ pₙ yⁿ` converges for all `‖y‖ < r`, but these
definitions are *not* equivalent in general. -/
def radius (p : FormalMultilinearSeries 𝕜 E F) : ℝ≥0∞ :=
⨆ (r : ℝ≥0) (C : ℝ) (_ : ∀ n, ‖p n‖ * (r : ℝ) ^ n ≤ C), (r : ℝ≥0∞)
/-- If `‖pₙ‖ rⁿ` is bounded in `n`, then the radius of `p` is at least `r`. -/
theorem le_radius_of_bound (C : ℝ) {r : ℝ≥0} (h : ∀ n : ℕ, ‖p n‖ * (r : ℝ) ^ n ≤ C) :
(r : ℝ≥0∞) ≤ p.radius :=
le_iSup_of_le r <| le_iSup_of_le C <| le_iSup (fun _ => (r : ℝ≥0∞)) h
/-- If `‖pₙ‖ rⁿ` is bounded in `n`, then the radius of `p` is at least `r`. -/
theorem le_radius_of_bound_nnreal (C : ℝ≥0) {r : ℝ≥0} (h : ∀ n : ℕ, ‖p n‖₊ * r ^ n ≤ C) :
(r : ℝ≥0∞) ≤ p.radius :=
p.le_radius_of_bound C fun n => mod_cast h n
/-- If `‖pₙ‖ rⁿ = O(1)`, as `n → ∞`, then the radius of `p` is at least `r`. -/
theorem le_radius_of_isBigO (h : (fun n => ‖p n‖ * (r : ℝ) ^ n) =O[atTop] fun _ => (1 : ℝ)) :
↑r ≤ p.radius :=
Exists.elim (isBigO_one_nat_atTop_iff.1 h) fun C hC =>
p.le_radius_of_bound C fun n => (le_abs_self _).trans (hC n)
theorem le_radius_of_eventually_le (C) (h : ∀ᶠ n in atTop, ‖p n‖ * (r : ℝ) ^ n ≤ C) :
↑r ≤ p.radius :=
p.le_radius_of_isBigO <| IsBigO.of_bound C <| h.mono fun n hn => by simpa
theorem le_radius_of_summable_nnnorm (h : Summable fun n => ‖p n‖₊ * r ^ n) : ↑r ≤ p.radius :=
p.le_radius_of_bound_nnreal (∑' n, ‖p n‖₊ * r ^ n) fun _ => h.le_tsum' _
theorem le_radius_of_summable (h : Summable fun n => ‖p n‖ * (r : ℝ) ^ n) : ↑r ≤ p.radius :=
p.le_radius_of_summable_nnnorm <| by
simp only [← coe_nnnorm] at h
exact mod_cast h
theorem radius_eq_top_of_forall_nnreal_isBigO
(h : ∀ r : ℝ≥0, (fun n => ‖p n‖ * (r : ℝ) ^ n) =O[atTop] fun _ => (1 : ℝ)) : p.radius = ∞ :=
ENNReal.eq_top_of_forall_nnreal_le fun r => p.le_radius_of_isBigO (h r)
theorem radius_eq_top_of_eventually_eq_zero (h : ∀ᶠ n in atTop, p n = 0) : p.radius = ∞ :=
p.radius_eq_top_of_forall_nnreal_isBigO fun r =>
(isBigO_zero _ _).congr' (h.mono fun n hn => by simp [hn]) EventuallyEq.rfl
theorem radius_eq_top_of_forall_image_add_eq_zero (n : ℕ) (hn : ∀ m, p (m + n) = 0) :
p.radius = ∞ :=
p.radius_eq_top_of_eventually_eq_zero <|
mem_atTop_sets.2 ⟨n, fun _ hk => tsub_add_cancel_of_le hk ▸ hn _⟩
@[simp]
theorem constFormalMultilinearSeries_radius {v : F} :
(constFormalMultilinearSeries 𝕜 E v).radius = ⊤ :=
(constFormalMultilinearSeries 𝕜 E v).radius_eq_top_of_forall_image_add_eq_zero 1
(by simp [constFormalMultilinearSeries])
/-- `0` has infinite radius of convergence -/
@[simp] lemma zero_radius : (0 : FormalMultilinearSeries 𝕜 E F).radius = ∞ := by
rw [← constFormalMultilinearSeries_zero]
exact constFormalMultilinearSeries_radius
/-- For `r` strictly smaller than the radius of `p`, then `‖pₙ‖ rⁿ` tends to zero exponentially:
for some `0 < a < 1`, `‖p n‖ rⁿ = o(aⁿ)`. -/
theorem isLittleO_of_lt_radius (h : ↑r < p.radius) :
∃ a ∈ Ioo (0 : ℝ) 1, (fun n => ‖p n‖ * (r : ℝ) ^ n) =o[atTop] (a ^ ·) := by
have := (TFAE_exists_lt_isLittleO_pow (fun n => ‖p n‖ * (r : ℝ) ^ n) 1).out 1 4
rw [this]
-- Porting note: was
-- rw [(TFAE_exists_lt_isLittleO_pow (fun n => ‖p n‖ * (r : ℝ) ^ n) 1).out 1 4]
simp only [radius, lt_iSup_iff] at h
rcases h with ⟨t, C, hC, rt⟩
rw [ENNReal.coe_lt_coe, ← NNReal.coe_lt_coe] at rt
have : 0 < (t : ℝ) := r.coe_nonneg.trans_lt rt
rw [← div_lt_one this] at rt
refine ⟨_, rt, C, Or.inr zero_lt_one, fun n => ?_⟩
calc
|‖p n‖ * (r : ℝ) ^ n| = ‖p n‖ * (t : ℝ) ^ n * (r / t : ℝ) ^ n := by
field_simp [mul_right_comm, abs_mul]
_ ≤ C * (r / t : ℝ) ^ n := by gcongr; apply hC
/-- For `r` strictly smaller than the radius of `p`, then `‖pₙ‖ rⁿ = o(1)`. -/
theorem isLittleO_one_of_lt_radius (h : ↑r < p.radius) :
(fun n => ‖p n‖ * (r : ℝ) ^ n) =o[atTop] (fun _ => 1 : ℕ → ℝ) :=
let ⟨_, ha, hp⟩ := p.isLittleO_of_lt_radius h
hp.trans <| (isLittleO_pow_pow_of_lt_left ha.1.le ha.2).congr (fun _ => rfl) one_pow
/-- For `r` strictly smaller than the radius of `p`, then `‖pₙ‖ rⁿ` tends to zero exponentially:
for some `0 < a < 1` and `C > 0`, `‖p n‖ * r ^ n ≤ C * a ^ n`. -/
theorem norm_mul_pow_le_mul_pow_of_lt_radius (h : ↑r < p.radius) :
∃ a ∈ Ioo (0 : ℝ) 1, ∃ C > 0, ∀ n, ‖p n‖ * (r : ℝ) ^ n ≤ C * a ^ n := by
have := ((TFAE_exists_lt_isLittleO_pow (fun n => ‖p n‖ * (r : ℝ) ^ n) 1).out 1 5).mp
(p.isLittleO_of_lt_radius h)
rcases this with ⟨a, ha, C, hC, H⟩
exact ⟨a, ha, C, hC, fun n => (le_abs_self _).trans (H n)⟩
/-- If `r ≠ 0` and `‖pₙ‖ rⁿ = O(aⁿ)` for some `-1 < a < 1`, then `r < p.radius`. -/
theorem lt_radius_of_isBigO (h₀ : r ≠ 0) {a : ℝ} (ha : a ∈ Ioo (-1 : ℝ) 1)
(hp : (fun n => ‖p n‖ * (r : ℝ) ^ n) =O[atTop] (a ^ ·)) : ↑r < p.radius := by
have := ((TFAE_exists_lt_isLittleO_pow (fun n => ‖p n‖ * (r : ℝ) ^ n) 1).out 2 5)
rcases this.mp ⟨a, ha, hp⟩ with ⟨a, ha, C, hC, hp⟩
rw [← pos_iff_ne_zero, ← NNReal.coe_pos] at h₀
lift a to ℝ≥0 using ha.1.le
have : (r : ℝ) < r / a := by
simpa only [div_one] using (div_lt_div_iff_of_pos_left h₀ zero_lt_one ha.1).2 ha.2
norm_cast at this
rw [← ENNReal.coe_lt_coe] at this
refine this.trans_le (p.le_radius_of_bound C fun n => ?_)
rw [NNReal.coe_div, div_pow, ← mul_div_assoc, div_le_iff₀ (pow_pos ha.1 n)]
exact (le_abs_self _).trans (hp n)
/-- For `r` strictly smaller than the radius of `p`, then `‖pₙ‖ rⁿ` is bounded. -/
theorem norm_mul_pow_le_of_lt_radius (p : FormalMultilinearSeries 𝕜 E F) {r : ℝ≥0}
(h : (r : ℝ≥0∞) < p.radius) : ∃ C > 0, ∀ n, ‖p n‖ * (r : ℝ) ^ n ≤ C :=
let ⟨_, ha, C, hC, h⟩ := p.norm_mul_pow_le_mul_pow_of_lt_radius h
⟨C, hC, fun n => (h n).trans <| mul_le_of_le_one_right hC.lt.le (pow_le_one₀ ha.1.le ha.2.le)⟩
/-- For `r` strictly smaller than the radius of `p`, then `‖pₙ‖ rⁿ` is bounded. -/
theorem norm_le_div_pow_of_pos_of_lt_radius (p : FormalMultilinearSeries 𝕜 E F) {r : ℝ≥0}
(h0 : 0 < r) (h : (r : ℝ≥0∞) < p.radius) : ∃ C > 0, ∀ n, ‖p n‖ ≤ C / (r : ℝ) ^ n :=
let ⟨C, hC, hp⟩ := p.norm_mul_pow_le_of_lt_radius h
⟨C, hC, fun n => Iff.mpr (le_div_iff₀ (pow_pos h0 _)) (hp n)⟩
/-- For `r` strictly smaller than the radius of `p`, then `‖pₙ‖ rⁿ` is bounded. -/
theorem nnnorm_mul_pow_le_of_lt_radius (p : FormalMultilinearSeries 𝕜 E F) {r : ℝ≥0}
(h : (r : ℝ≥0∞) < p.radius) : ∃ C > 0, ∀ n, ‖p n‖₊ * r ^ n ≤ C :=
let ⟨C, hC, hp⟩ := p.norm_mul_pow_le_of_lt_radius h
⟨⟨C, hC.lt.le⟩, hC, mod_cast hp⟩
theorem le_radius_of_tendsto (p : FormalMultilinearSeries 𝕜 E F) {l : ℝ}
(h : Tendsto (fun n => ‖p n‖ * (r : ℝ) ^ n) atTop (𝓝 l)) : ↑r ≤ p.radius :=
p.le_radius_of_isBigO (h.isBigO_one _)
theorem le_radius_of_summable_norm (p : FormalMultilinearSeries 𝕜 E F)
(hs : Summable fun n => ‖p n‖ * (r : ℝ) ^ n) : ↑r ≤ p.radius :=
p.le_radius_of_tendsto hs.tendsto_atTop_zero
theorem not_summable_norm_of_radius_lt_nnnorm (p : FormalMultilinearSeries 𝕜 E F) {x : E}
(h : p.radius < ‖x‖₊) : ¬Summable fun n => ‖p n‖ * ‖x‖ ^ n :=
fun hs => not_le_of_lt h (p.le_radius_of_summable_norm hs)
theorem summable_norm_mul_pow (p : FormalMultilinearSeries 𝕜 E F) {r : ℝ≥0} (h : ↑r < p.radius) :
Summable fun n : ℕ => ‖p n‖ * (r : ℝ) ^ n := by
obtain ⟨a, ha : a ∈ Ioo (0 : ℝ) 1, C, - : 0 < C, hp⟩ := p.norm_mul_pow_le_mul_pow_of_lt_radius h
exact .of_nonneg_of_le (fun n => mul_nonneg (norm_nonneg _) (pow_nonneg r.coe_nonneg _))
hp ((summable_geometric_of_lt_one ha.1.le ha.2).mul_left _)
theorem summable_norm_apply (p : FormalMultilinearSeries 𝕜 E F) {x : E}
(hx : x ∈ EMetric.ball (0 : E) p.radius) : Summable fun n : ℕ => ‖p n fun _ => x‖ := by
rw [mem_emetric_ball_zero_iff] at hx
refine .of_nonneg_of_le
(fun _ ↦ norm_nonneg _) (fun n ↦ ((p n).le_opNorm _).trans_eq ?_) (p.summable_norm_mul_pow hx)
simp
theorem summable_nnnorm_mul_pow (p : FormalMultilinearSeries 𝕜 E F) {r : ℝ≥0} (h : ↑r < p.radius) :
Summable fun n : ℕ => ‖p n‖₊ * r ^ n := by
rw [← NNReal.summable_coe]
push_cast
exact p.summable_norm_mul_pow h
protected theorem summable [CompleteSpace F] (p : FormalMultilinearSeries 𝕜 E F) {x : E}
(hx : x ∈ EMetric.ball (0 : E) p.radius) : Summable fun n : ℕ => p n fun _ => x :=
(p.summable_norm_apply hx).of_norm
theorem radius_eq_top_of_summable_norm (p : FormalMultilinearSeries 𝕜 E F)
(hs : ∀ r : ℝ≥0, Summable fun n => ‖p n‖ * (r : ℝ) ^ n) : p.radius = ∞ :=
ENNReal.eq_top_of_forall_nnreal_le fun r => p.le_radius_of_summable_norm (hs r)
theorem radius_eq_top_iff_summable_norm (p : FormalMultilinearSeries 𝕜 E F) :
p.radius = ∞ ↔ ∀ r : ℝ≥0, Summable fun n => ‖p n‖ * (r : ℝ) ^ n := by
constructor
· intro h r
obtain ⟨a, ha : a ∈ Ioo (0 : ℝ) 1, C, - : 0 < C, hp⟩ := p.norm_mul_pow_le_mul_pow_of_lt_radius
(show (r : ℝ≥0∞) < p.radius from h.symm ▸ ENNReal.coe_lt_top)
refine .of_norm_bounded
(fun n ↦ (C : ℝ) * a ^ n) ((summable_geometric_of_lt_one ha.1.le ha.2).mul_left _) fun n ↦ ?_
specialize hp n
rwa [Real.norm_of_nonneg (mul_nonneg (norm_nonneg _) (pow_nonneg r.coe_nonneg n))]
· exact p.radius_eq_top_of_summable_norm
/-- If the radius of `p` is positive, then `‖pₙ‖` grows at most geometrically. -/
theorem le_mul_pow_of_radius_pos (p : FormalMultilinearSeries 𝕜 E F) (h : 0 < p.radius) :
∃ (C r : _) (_ : 0 < C) (_ : 0 < r), ∀ n, ‖p n‖ ≤ C * r ^ n := by
rcases ENNReal.lt_iff_exists_nnreal_btwn.1 h with ⟨r, r0, rlt⟩
have rpos : 0 < (r : ℝ) := by simp [ENNReal.coe_pos.1 r0]
rcases norm_le_div_pow_of_pos_of_lt_radius p rpos rlt with ⟨C, Cpos, hCp⟩
refine ⟨C, r⁻¹, Cpos, by simp only [inv_pos, rpos], fun n => ?_⟩
rw [inv_pow, ← div_eq_mul_inv]
exact hCp n
lemma radius_le_of_le {𝕜' E' F' : Type*}
[NontriviallyNormedField 𝕜'] [NormedAddCommGroup E'] [NormedSpace 𝕜' E']
[NormedAddCommGroup F'] [NormedSpace 𝕜' F']
{p : FormalMultilinearSeries 𝕜 E F} {q : FormalMultilinearSeries 𝕜' E' F'}
(h : ∀ n, ‖p n‖ ≤ ‖q n‖) : q.radius ≤ p.radius := by
apply le_of_forall_nnreal_lt (fun r hr ↦ ?_)
rcases norm_mul_pow_le_of_lt_radius _ hr with ⟨C, -, hC⟩
apply le_radius_of_bound _ C (fun n ↦ ?_)
apply le_trans _ (hC n)
gcongr
exact h n
/-- The radius of the sum of two formal series is at least the minimum of their two radii. -/
theorem min_radius_le_radius_add (p q : FormalMultilinearSeries 𝕜 E F) :
min p.radius q.radius ≤ (p + q).radius := by
refine ENNReal.le_of_forall_nnreal_lt fun r hr => ?_
rw [lt_min_iff] at hr
have := ((p.isLittleO_one_of_lt_radius hr.1).add (q.isLittleO_one_of_lt_radius hr.2)).isBigO
refine (p + q).le_radius_of_isBigO ((isBigO_of_le _ fun n => ?_).trans this)
rw [← add_mul, norm_mul, norm_mul, norm_norm]
exact mul_le_mul_of_nonneg_right ((norm_add_le _ _).trans (le_abs_self _)) (norm_nonneg _)
@[simp]
theorem radius_neg (p : FormalMultilinearSeries 𝕜 E F) : (-p).radius = p.radius := by
simp only [radius, neg_apply, norm_neg]
theorem radius_le_smul {p : FormalMultilinearSeries 𝕜 E F} {c : 𝕜} : p.radius ≤ (c • p).radius := by
simp only [radius, smul_apply]
refine iSup_mono fun r ↦ iSup_mono' fun C ↦ ⟨‖c‖ * C, iSup_mono' fun h ↦ ?_⟩
simp only [le_refl, exists_prop, and_true]
intro n
rw [norm_smul c (p n), mul_assoc]
gcongr
exact h n
theorem radius_smul_eq (p : FormalMultilinearSeries 𝕜 E F) {c : 𝕜} (hc : c ≠ 0) :
(c • p).radius = p.radius := by
apply eq_of_le_of_le _ radius_le_smul
exact radius_le_smul.trans_eq (congr_arg _ <| inv_smul_smul₀ hc p)
@[simp]
theorem radius_shift (p : FormalMultilinearSeries 𝕜 E F) : p.shift.radius = p.radius := by
simp only [radius, shift, Nat.succ_eq_add_one, ContinuousMultilinearMap.curryRight_norm]
congr
ext r
apply eq_of_le_of_le
· apply iSup_mono'
intro C
use ‖p 0‖ ⊔ (C * r)
apply iSup_mono'
intro h
simp only [le_refl, le_sup_iff, exists_prop, and_true]
intro n
rcases n with - | m
· simp
right
rw [pow_succ, ← mul_assoc]
apply mul_le_mul_of_nonneg_right (h m) zero_le_coe
· apply iSup_mono'
intro C
use ‖p 1‖ ⊔ C / r
apply iSup_mono'
intro h
simp only [le_refl, le_sup_iff, exists_prop, and_true]
intro n
cases eq_zero_or_pos r with
| inl hr =>
rw [hr]
cases n <;> simp
| inr hr =>
right
rw [← NNReal.coe_pos] at hr
specialize h (n + 1)
rw [le_div_iff₀ hr]
rwa [pow_succ, ← mul_assoc] at h
@[simp]
theorem radius_unshift (p : FormalMultilinearSeries 𝕜 E (E →L[𝕜] F)) (z : F) :
(p.unshift z).radius = p.radius := by
rw [← radius_shift, unshift_shift]
protected theorem hasSum [CompleteSpace F] (p : FormalMultilinearSeries 𝕜 E F) {x : E}
(hx : x ∈ EMetric.ball (0 : E) p.radius) : HasSum (fun n : ℕ => p n fun _ => x) (p.sum x) :=
(p.summable hx).hasSum
theorem radius_le_radius_continuousLinearMap_comp (p : FormalMultilinearSeries 𝕜 E F)
(f : F →L[𝕜] G) : p.radius ≤ (f.compFormalMultilinearSeries p).radius := by
refine ENNReal.le_of_forall_nnreal_lt fun r hr => ?_
apply le_radius_of_isBigO
apply (IsBigO.trans_isLittleO _ (p.isLittleO_one_of_lt_radius hr)).isBigO
refine IsBigO.mul (@IsBigOWith.isBigO _ _ _ _ _ ‖f‖ _ _ _ ?_) (isBigO_refl _ _)
refine IsBigOWith.of_bound (Eventually.of_forall fun n => ?_)
simpa only [norm_norm] using f.norm_compContinuousMultilinearMap_le (p n)
end FormalMultilinearSeries
/-! ### Expanding a function as a power series -/
section
variable {f g : E → F} {p pf : FormalMultilinearSeries 𝕜 E F} {s t : Set E} {x : E} {r r' : ℝ≥0∞}
/-- Given a function `f : E → F` and a formal multilinear series `p`, we say that `f` has `p` as
a power series on the ball of radius `r > 0` around `x` if `f (x + y) = ∑' pₙ yⁿ` for all `‖y‖ < r`.
-/
structure HasFPowerSeriesOnBall (f : E → F) (p : FormalMultilinearSeries 𝕜 E F) (x : E) (r : ℝ≥0∞) :
Prop where
r_le : r ≤ p.radius
r_pos : 0 < r
hasSum :
∀ {y}, y ∈ EMetric.ball (0 : E) r → HasSum (fun n : ℕ => p n fun _ : Fin n => y) (f (x + y))
/-- Analogue of `HasFPowerSeriesOnBall` where convergence is required only on a set `s`. We also
require convergence at `x` as the behavior of this notion is very bad otherwise. -/
structure HasFPowerSeriesWithinOnBall (f : E → F) (p : FormalMultilinearSeries 𝕜 E F) (s : Set E)
(x : E) (r : ℝ≥0∞) : Prop where
/-- `p` converges on `ball 0 r` -/
r_le : r ≤ p.radius
/-- The radius of convergence is positive -/
r_pos : 0 < r
/-- `p converges to f` within `s` -/
hasSum : ∀ {y}, x + y ∈ insert x s → y ∈ EMetric.ball (0 : E) r →
HasSum (fun n : ℕ => p n fun _ : Fin n => y) (f (x + y))
/-- Given a function `f : E → F` and a formal multilinear series `p`, we say that `f` has `p` as
a power series around `x` if `f (x + y) = ∑' pₙ yⁿ` for all `y` in a neighborhood of `0`. -/
def HasFPowerSeriesAt (f : E → F) (p : FormalMultilinearSeries 𝕜 E F) (x : E) :=
∃ r, HasFPowerSeriesOnBall f p x r
/-- Analogue of `HasFPowerSeriesAt` where convergence is required only on a set `s`. -/
def HasFPowerSeriesWithinAt (f : E → F) (p : FormalMultilinearSeries 𝕜 E F) (s : Set E) (x : E) :=
∃ r, HasFPowerSeriesWithinOnBall f p s x r
-- Teach the `bound` tactic that power series have positive radius
attribute [bound_forward] HasFPowerSeriesOnBall.r_pos HasFPowerSeriesWithinOnBall.r_pos
variable (𝕜)
/-- Given a function `f : E → F`, we say that `f` is analytic at `x` if it admits a convergent power
series expansion around `x`. -/
@[fun_prop]
def AnalyticAt (f : E → F) (x : E) :=
∃ p : FormalMultilinearSeries 𝕜 E F, HasFPowerSeriesAt f p x
/-- `f` is analytic within `s` at `x` if it has a power series at `x` that converges on `𝓝[s] x` -/
def AnalyticWithinAt (f : E → F) (s : Set E) (x : E) : Prop :=
∃ p : FormalMultilinearSeries 𝕜 E F, HasFPowerSeriesWithinAt f p s x
/-- Given a function `f : E → F`, we say that `f` is analytic on a set `s` if it is analytic around
every point of `s`. -/
def AnalyticOnNhd (f : E → F) (s : Set E) :=
∀ x, x ∈ s → AnalyticAt 𝕜 f x
/-- `f` is analytic within `s` if it is analytic within `s` at each point of `s`. Note that
this is weaker than `AnalyticOnNhd 𝕜 f s`, as `f` is allowed to be arbitrary outside `s`. -/
def AnalyticOn (f : E → F) (s : Set E) : Prop :=
∀ x ∈ s, AnalyticWithinAt 𝕜 f s x
/-!
### `HasFPowerSeriesOnBall` and `HasFPowerSeriesWithinOnBall`
-/
variable {𝕜}
theorem HasFPowerSeriesOnBall.hasFPowerSeriesAt (hf : HasFPowerSeriesOnBall f p x r) :
HasFPowerSeriesAt f p x :=
⟨r, hf⟩
theorem HasFPowerSeriesAt.analyticAt (hf : HasFPowerSeriesAt f p x) : AnalyticAt 𝕜 f x :=
⟨p, hf⟩
theorem HasFPowerSeriesOnBall.analyticAt (hf : HasFPowerSeriesOnBall f p x r) : AnalyticAt 𝕜 f x :=
hf.hasFPowerSeriesAt.analyticAt
theorem HasFPowerSeriesWithinOnBall.hasFPowerSeriesWithinAt
(hf : HasFPowerSeriesWithinOnBall f p s x r) : HasFPowerSeriesWithinAt f p s x :=
⟨r, hf⟩
theorem HasFPowerSeriesWithinAt.analyticWithinAt (hf : HasFPowerSeriesWithinAt f p s x) :
AnalyticWithinAt 𝕜 f s x := ⟨p, hf⟩
theorem HasFPowerSeriesWithinOnBall.analyticWithinAt (hf : HasFPowerSeriesWithinOnBall f p s x r) :
AnalyticWithinAt 𝕜 f s x :=
hf.hasFPowerSeriesWithinAt.analyticWithinAt
/-- If a function `f` has a power series `p` around `x`, then the function `z ↦ f (z - y)` has the
same power series around `x + y`. -/
theorem HasFPowerSeriesOnBall.comp_sub (hf : HasFPowerSeriesOnBall f p x r) (y : E) :
HasFPowerSeriesOnBall (fun z => f (z - y)) p (x + y) r :=
{ r_le := hf.r_le
r_pos := hf.r_pos
hasSum := fun {z} hz => by
convert hf.hasSum hz using 2
abel }
theorem HasFPowerSeriesWithinOnBall.hasSum_sub (hf : HasFPowerSeriesWithinOnBall f p s x r) {y : E}
(hy : y ∈ (insert x s) ∩ EMetric.ball x r) :
HasSum (fun n : ℕ => p n fun _ => y - x) (f y) := by
have : y - x ∈ EMetric.ball (0 : E) r := by simpa [edist_eq_enorm_sub] using hy.2
have := hf.hasSum (by simpa only [add_sub_cancel] using hy.1) this
simpa only [add_sub_cancel]
theorem HasFPowerSeriesOnBall.hasSum_sub (hf : HasFPowerSeriesOnBall f p x r) {y : E}
(hy : y ∈ EMetric.ball x r) : HasSum (fun n : ℕ => p n fun _ => y - x) (f y) := by
have : y - x ∈ EMetric.ball (0 : E) r := by simpa [edist_eq_enorm_sub] using hy
simpa only [add_sub_cancel] using hf.hasSum this
theorem HasFPowerSeriesOnBall.radius_pos (hf : HasFPowerSeriesOnBall f p x r) : 0 < p.radius :=
lt_of_lt_of_le hf.r_pos hf.r_le
theorem HasFPowerSeriesWithinOnBall.radius_pos (hf : HasFPowerSeriesWithinOnBall f p s x r) :
0 < p.radius :=
lt_of_lt_of_le hf.r_pos hf.r_le
theorem HasFPowerSeriesAt.radius_pos (hf : HasFPowerSeriesAt f p x) : 0 < p.radius :=
let ⟨_, hr⟩ := hf
hr.radius_pos
theorem HasFPowerSeriesWithinOnBall.of_le
(hf : HasFPowerSeriesWithinOnBall f p s x r) (r'_pos : 0 < r') (hr : r' ≤ r) :
HasFPowerSeriesWithinOnBall f p s x r' :=
⟨le_trans hr hf.1, r'_pos, fun hy h'y => hf.hasSum hy (EMetric.ball_subset_ball hr h'y)⟩
theorem HasFPowerSeriesOnBall.mono (hf : HasFPowerSeriesOnBall f p x r) (r'_pos : 0 < r')
(hr : r' ≤ r) : HasFPowerSeriesOnBall f p x r' :=
⟨le_trans hr hf.1, r'_pos, fun hy => hf.hasSum (EMetric.ball_subset_ball hr hy)⟩
lemma HasFPowerSeriesWithinOnBall.congr {f g : E → F} {p : FormalMultilinearSeries 𝕜 E F}
{s : Set E} {x : E} {r : ℝ≥0∞} (h : HasFPowerSeriesWithinOnBall f p s x r)
(h' : EqOn g f (s ∩ EMetric.ball x r)) (h'' : g x = f x) :
HasFPowerSeriesWithinOnBall g p s x r := by
refine ⟨h.r_le, h.r_pos, ?_⟩
intro y hy h'y
convert h.hasSum hy h'y using 1
simp only [mem_insert_iff, add_eq_left] at hy
rcases hy with rfl | hy
· simpa using h''
· apply h'
refine ⟨hy, ?_⟩
simpa [edist_eq_enorm_sub] using h'y
/-- Variant of `HasFPowerSeriesWithinOnBall.congr` in which one requests equality on `insert x s`
instead of separating `x` and `s`. -/
lemma HasFPowerSeriesWithinOnBall.congr' {f g : E → F} {p : FormalMultilinearSeries 𝕜 E F}
{s : Set E} {x : E} {r : ℝ≥0∞} (h : HasFPowerSeriesWithinOnBall f p s x r)
(h' : EqOn g f (insert x s ∩ EMetric.ball x r)) :
HasFPowerSeriesWithinOnBall g p s x r := by
refine ⟨h.r_le, h.r_pos, fun {y} hy h'y ↦ ?_⟩
convert h.hasSum hy h'y using 1
exact h' ⟨hy, by simpa [edist_eq_enorm_sub] using h'y⟩
lemma HasFPowerSeriesWithinAt.congr {f g : E → F} {p : FormalMultilinearSeries 𝕜 E F} {s : Set E}
{x : E} (h : HasFPowerSeriesWithinAt f p s x) (h' : g =ᶠ[𝓝[s] x] f) (h'' : g x = f x) :
HasFPowerSeriesWithinAt g p s x := by
rcases h with ⟨r, hr⟩
obtain ⟨ε, εpos, hε⟩ : ∃ ε > 0, EMetric.ball x ε ∩ s ⊆ {y | g y = f y} :=
EMetric.mem_nhdsWithin_iff.1 h'
let r' := min r ε
refine ⟨r', ?_⟩
have := hr.of_le (r' := r') (by simp [r', εpos, hr.r_pos]) (min_le_left _ _)
apply this.congr _ h''
intro z hz
exact hε ⟨EMetric.ball_subset_ball (min_le_right _ _) hz.2, hz.1⟩
theorem HasFPowerSeriesOnBall.congr (hf : HasFPowerSeriesOnBall f p x r)
(hg : EqOn f g (EMetric.ball x r)) : HasFPowerSeriesOnBall g p x r :=
{ r_le := hf.r_le
r_pos := hf.r_pos
hasSum := fun {y} hy => by
convert hf.hasSum hy using 1
apply hg.symm
simpa [edist_eq_enorm_sub] using hy }
theorem HasFPowerSeriesAt.congr (hf : HasFPowerSeriesAt f p x) (hg : f =ᶠ[𝓝 x] g) :
HasFPowerSeriesAt g p x := by
rcases hf with ⟨r₁, h₁⟩
rcases EMetric.mem_nhds_iff.mp hg with ⟨r₂, h₂pos, h₂⟩
exact ⟨min r₁ r₂,
(h₁.mono (lt_min h₁.r_pos h₂pos) inf_le_left).congr
fun y hy => h₂ (EMetric.ball_subset_ball inf_le_right hy)⟩
theorem HasFPowerSeriesWithinOnBall.unique (hf : HasFPowerSeriesWithinOnBall f p s x r)
(hg : HasFPowerSeriesWithinOnBall g p s x r) :
(insert x s ∩ EMetric.ball x r).EqOn f g := fun _ hy ↦
(hf.hasSum_sub hy).unique (hg.hasSum_sub hy)
theorem HasFPowerSeriesOnBall.unique (hf : HasFPowerSeriesOnBall f p x r)
(hg : HasFPowerSeriesOnBall g p x r) : (EMetric.ball x r).EqOn f g := fun _ hy ↦
(hf.hasSum_sub hy).unique (hg.hasSum_sub hy)
protected theorem HasFPowerSeriesWithinAt.eventually (hf : HasFPowerSeriesWithinAt f p s x) :
∀ᶠ r : ℝ≥0∞ in 𝓝[>] 0, HasFPowerSeriesWithinOnBall f p s x r :=
let ⟨_, hr⟩ := hf
mem_of_superset (Ioo_mem_nhdsGT hr.r_pos) fun _ hr' => hr.of_le hr'.1 hr'.2.le
protected theorem HasFPowerSeriesAt.eventually (hf : HasFPowerSeriesAt f p x) :
∀ᶠ r : ℝ≥0∞ in 𝓝[>] 0, HasFPowerSeriesOnBall f p x r :=
let ⟨_, hr⟩ := hf
mem_of_superset (Ioo_mem_nhdsGT hr.r_pos) fun _ hr' => hr.mono hr'.1 hr'.2.le
theorem HasFPowerSeriesOnBall.eventually_hasSum (hf : HasFPowerSeriesOnBall f p x r) :
∀ᶠ y in 𝓝 0, HasSum (fun n : ℕ => p n fun _ : Fin n => y) (f (x + y)) := by
filter_upwards [EMetric.ball_mem_nhds (0 : E) hf.r_pos] using fun _ => hf.hasSum
theorem HasFPowerSeriesAt.eventually_hasSum (hf : HasFPowerSeriesAt f p x) :
∀ᶠ y in 𝓝 0, HasSum (fun n : ℕ => p n fun _ : Fin n => y) (f (x + y)) :=
let ⟨_, hr⟩ := hf
hr.eventually_hasSum
theorem HasFPowerSeriesOnBall.eventually_hasSum_sub (hf : HasFPowerSeriesOnBall f p x r) :
∀ᶠ y in 𝓝 x, HasSum (fun n : ℕ => p n fun _ : Fin n => y - x) (f y) := by
filter_upwards [EMetric.ball_mem_nhds x hf.r_pos] with y using hf.hasSum_sub
theorem HasFPowerSeriesAt.eventually_hasSum_sub (hf : HasFPowerSeriesAt f p x) :
∀ᶠ y in 𝓝 x, HasSum (fun n : ℕ => p n fun _ : Fin n => y - x) (f y) :=
let ⟨_, hr⟩ := hf
hr.eventually_hasSum_sub
theorem HasFPowerSeriesOnBall.eventually_eq_zero
(hf : HasFPowerSeriesOnBall f (0 : FormalMultilinearSeries 𝕜 E F) x r) :
∀ᶠ z in 𝓝 x, f z = 0 := by
filter_upwards [hf.eventually_hasSum_sub] with z hz using hz.unique hasSum_zero
theorem HasFPowerSeriesAt.eventually_eq_zero
(hf : HasFPowerSeriesAt f (0 : FormalMultilinearSeries 𝕜 E F) x) : ∀ᶠ z in 𝓝 x, f z = 0 :=
let ⟨_, hr⟩ := hf
hr.eventually_eq_zero
@[simp] lemma hasFPowerSeriesWithinOnBall_univ :
HasFPowerSeriesWithinOnBall f p univ x r ↔ HasFPowerSeriesOnBall f p x r := by
constructor
· intro h
refine ⟨h.r_le, h.r_pos, fun {y} m ↦ h.hasSum (by simp) m⟩
· intro h
exact ⟨h.r_le, h.r_pos, fun {y} _ m => h.hasSum m⟩
@[simp] lemma hasFPowerSeriesWithinAt_univ :
HasFPowerSeriesWithinAt f p univ x ↔ HasFPowerSeriesAt f p x := by
simp only [HasFPowerSeriesWithinAt, hasFPowerSeriesWithinOnBall_univ, HasFPowerSeriesAt]
lemma HasFPowerSeriesWithinOnBall.mono (hf : HasFPowerSeriesWithinOnBall f p s x r) (h : t ⊆ s) :
HasFPowerSeriesWithinOnBall f p t x r where
r_le := hf.r_le
r_pos := hf.r_pos
hasSum hy h'y := hf.hasSum (insert_subset_insert h hy) h'y
lemma HasFPowerSeriesOnBall.hasFPowerSeriesWithinOnBall (hf : HasFPowerSeriesOnBall f p x r) :
HasFPowerSeriesWithinOnBall f p s x r := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
exact hf.mono (subset_univ _)
lemma HasFPowerSeriesWithinAt.mono (hf : HasFPowerSeriesWithinAt f p s x) (h : t ⊆ s) :
HasFPowerSeriesWithinAt f p t x := by
obtain ⟨r, hp⟩ := hf
exact ⟨r, hp.mono h⟩
lemma HasFPowerSeriesAt.hasFPowerSeriesWithinAt (hf : HasFPowerSeriesAt f p x) :
HasFPowerSeriesWithinAt f p s x := by
rw [← hasFPowerSeriesWithinAt_univ] at hf
apply hf.mono (subset_univ _)
theorem HasFPowerSeriesWithinAt.mono_of_mem_nhdsWithin
(h : HasFPowerSeriesWithinAt f p s x) (hst : s ∈ 𝓝[t] x) :
HasFPowerSeriesWithinAt f p t x := by
rcases h with ⟨r, hr⟩
rcases EMetric.mem_nhdsWithin_iff.1 hst with ⟨r', r'_pos, hr'⟩
refine ⟨min r r', ?_⟩
have Z := hr.of_le (by simp [r'_pos, hr.r_pos]) (min_le_left r r')
refine ⟨Z.r_le, Z.r_pos, fun {y} hy h'y ↦ ?_⟩
apply Z.hasSum ?_ h'y
simp only [mem_insert_iff, add_eq_left] at hy
rcases hy with rfl | hy
· simp
apply mem_insert_of_mem _ (hr' ?_)
simp only [EMetric.mem_ball, edist_eq_enorm_sub, sub_zero, lt_min_iff, mem_inter_iff,
add_sub_cancel_left, hy, and_true] at h'y ⊢
exact h'y.2
@[deprecated (since := "2024-10-31")]
alias HasFPowerSeriesWithinAt.mono_of_mem := HasFPowerSeriesWithinAt.mono_of_mem_nhdsWithin
@[simp] lemma hasFPowerSeriesWithinOnBall_insert_self :
HasFPowerSeriesWithinOnBall f p (insert x s) x r ↔ HasFPowerSeriesWithinOnBall f p s x r := by
refine ⟨fun h ↦ ?_, fun h ↦ ?_⟩ <;>
exact ⟨h.r_le, h.r_pos, fun {y} ↦ by simpa only [insert_idem] using h.hasSum (y := y)⟩
@[simp] theorem hasFPowerSeriesWithinAt_insert {y : E} :
HasFPowerSeriesWithinAt f p (insert y s) x ↔ HasFPowerSeriesWithinAt f p s x := by
rcases eq_or_ne x y with rfl | hy
· simp [HasFPowerSeriesWithinAt]
· refine ⟨fun h ↦ h.mono (subset_insert _ _), fun h ↦ ?_⟩
apply HasFPowerSeriesWithinAt.mono_of_mem_nhdsWithin h
rw [nhdsWithin_insert_of_ne hy]
exact self_mem_nhdsWithin
theorem HasFPowerSeriesWithinOnBall.coeff_zero (hf : HasFPowerSeriesWithinOnBall f pf s x r)
(v : Fin 0 → E) : pf 0 v = f x := by
have v_eq : v = fun i => 0 := Subsingleton.elim _ _
have zero_mem : (0 : E) ∈ EMetric.ball (0 : E) r := by simp [hf.r_pos]
have : ∀ i, i ≠ 0 → (pf i fun _ => 0) = 0 := by
intro i hi
have : 0 < i := pos_iff_ne_zero.2 hi
exact ContinuousMultilinearMap.map_coord_zero _ (⟨0, this⟩ : Fin i) rfl
have A := (hf.hasSum (by simp) zero_mem).unique (hasSum_single _ this)
simpa [v_eq] using A.symm
theorem HasFPowerSeriesOnBall.coeff_zero (hf : HasFPowerSeriesOnBall f pf x r)
(v : Fin 0 → E) : pf 0 v = f x := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
exact hf.coeff_zero v
theorem HasFPowerSeriesWithinAt.coeff_zero (hf : HasFPowerSeriesWithinAt f pf s x) (v : Fin 0 → E) :
pf 0 v = f x :=
let ⟨_, hrf⟩ := hf
hrf.coeff_zero v
theorem HasFPowerSeriesAt.coeff_zero (hf : HasFPowerSeriesAt f pf x) (v : Fin 0 → E) :
pf 0 v = f x :=
let ⟨_, hrf⟩ := hf
hrf.coeff_zero v
/-!
### Analytic functions
-/
@[simp] theorem analyticOn_empty : AnalyticOn 𝕜 f ∅ := by intro; simp
@[simp] theorem analyticOnNhd_empty : AnalyticOnNhd 𝕜 f ∅ := by intro; simp
@[simp] lemma analyticWithinAt_univ :
AnalyticWithinAt 𝕜 f univ x ↔ AnalyticAt 𝕜 f x := by
simp [AnalyticWithinAt, AnalyticAt]
@[simp] lemma analyticOn_univ {f : E → F} :
AnalyticOn 𝕜 f univ ↔ AnalyticOnNhd 𝕜 f univ := by
simp only [AnalyticOn, analyticWithinAt_univ, AnalyticOnNhd]
lemma AnalyticWithinAt.mono (hf : AnalyticWithinAt 𝕜 f s x) (h : t ⊆ s) :
AnalyticWithinAt 𝕜 f t x := by
obtain ⟨p, hp⟩ := hf
exact ⟨p, hp.mono h⟩
lemma AnalyticAt.analyticWithinAt (hf : AnalyticAt 𝕜 f x) : AnalyticWithinAt 𝕜 f s x := by
rw [← analyticWithinAt_univ] at hf
apply hf.mono (subset_univ _)
lemma AnalyticOnNhd.analyticOn (hf : AnalyticOnNhd 𝕜 f s) : AnalyticOn 𝕜 f s :=
fun x hx ↦ (hf x hx).analyticWithinAt
lemma AnalyticWithinAt.congr_of_eventuallyEq {f g : E → F} {s : Set E} {x : E}
(hf : AnalyticWithinAt 𝕜 f s x) (hs : g =ᶠ[𝓝[s] x] f) (hx : g x = f x) :
AnalyticWithinAt 𝕜 g s x := by
rcases hf with ⟨p, hp⟩
exact ⟨p, hp.congr hs hx⟩
lemma AnalyticWithinAt.congr_of_eventuallyEq_insert {f g : E → F} {s : Set E} {x : E}
(hf : AnalyticWithinAt 𝕜 f s x) (hs : g =ᶠ[𝓝[insert x s] x] f) :
AnalyticWithinAt 𝕜 g s x := by
apply hf.congr_of_eventuallyEq (nhdsWithin_mono x (subset_insert x s) hs)
apply mem_of_mem_nhdsWithin (mem_insert x s) hs
lemma AnalyticWithinAt.congr {f g : E → F} {s : Set E} {x : E}
(hf : AnalyticWithinAt 𝕜 f s x) (hs : EqOn g f s) (hx : g x = f x) :
AnalyticWithinAt 𝕜 g s x :=
hf.congr_of_eventuallyEq hs.eventuallyEq_nhdsWithin hx
lemma AnalyticOn.congr {f g : E → F} {s : Set E}
(hf : AnalyticOn 𝕜 f s) (hs : EqOn g f s) :
AnalyticOn 𝕜 g s :=
fun x m ↦ (hf x m).congr hs (hs m)
theorem AnalyticAt.congr (hf : AnalyticAt 𝕜 f x) (hg : f =ᶠ[𝓝 x] g) : AnalyticAt 𝕜 g x :=
let ⟨_, hpf⟩ := hf
(hpf.congr hg).analyticAt
theorem analyticAt_congr (h : f =ᶠ[𝓝 x] g) : AnalyticAt 𝕜 f x ↔ AnalyticAt 𝕜 g x :=
⟨fun hf ↦ hf.congr h, fun hg ↦ hg.congr h.symm⟩
theorem AnalyticOnNhd.mono {s t : Set E} (hf : AnalyticOnNhd 𝕜 f t) (hst : s ⊆ t) :
AnalyticOnNhd 𝕜 f s :=
fun z hz => hf z (hst hz)
theorem AnalyticOnNhd.congr' (hf : AnalyticOnNhd 𝕜 f s) (hg : f =ᶠ[𝓝ˢ s] g) :
AnalyticOnNhd 𝕜 g s :=
fun z hz => (hf z hz).congr (mem_nhdsSet_iff_forall.mp hg z hz)
theorem analyticOnNhd_congr' (h : f =ᶠ[𝓝ˢ s] g) : AnalyticOnNhd 𝕜 f s ↔ AnalyticOnNhd 𝕜 g s :=
⟨fun hf => hf.congr' h, fun hg => hg.congr' h.symm⟩
theorem AnalyticOnNhd.congr (hs : IsOpen s) (hf : AnalyticOnNhd 𝕜 f s) (hg : s.EqOn f g) :
AnalyticOnNhd 𝕜 g s :=
hf.congr' <| mem_nhdsSet_iff_forall.mpr
(fun _ hz => eventuallyEq_iff_exists_mem.mpr ⟨s, hs.mem_nhds hz, hg⟩)
theorem analyticOnNhd_congr (hs : IsOpen s) (h : s.EqOn f g) : AnalyticOnNhd 𝕜 f s ↔
AnalyticOnNhd 𝕜 g s := ⟨fun hf => hf.congr hs h, fun hg => hg.congr hs h.symm⟩
theorem AnalyticWithinAt.mono_of_mem_nhdsWithin
(h : AnalyticWithinAt 𝕜 f s x) (hst : s ∈ 𝓝[t] x) : AnalyticWithinAt 𝕜 f t x := by
rcases h with ⟨p, hp⟩
exact ⟨p, hp.mono_of_mem_nhdsWithin hst⟩
@[deprecated (since := "2024-10-31")]
alias AnalyticWithinAt.mono_of_mem := AnalyticWithinAt.mono_of_mem_nhdsWithin
lemma AnalyticOn.mono {f : E → F} {s t : Set E} (h : AnalyticOn 𝕜 f t)
(hs : s ⊆ t) : AnalyticOn 𝕜 f s :=
fun _ m ↦ (h _ (hs m)).mono hs
@[simp] theorem analyticWithinAt_insert {f : E → F} {s : Set E} {x y : E} :
AnalyticWithinAt 𝕜 f (insert y s) x ↔ AnalyticWithinAt 𝕜 f s x := by
simp [AnalyticWithinAt]
/-!
### Composition with linear maps
-/
/-- If a function `f` has a power series `p` on a ball within a set and `g` is linear,
then `g ∘ f` has the power series `g ∘ p` on the same ball. -/
theorem ContinuousLinearMap.comp_hasFPowerSeriesWithinOnBall (g : F →L[𝕜] G)
(h : HasFPowerSeriesWithinOnBall f p s x r) :
HasFPowerSeriesWithinOnBall (g ∘ f) (g.compFormalMultilinearSeries p) s x r where
r_le := h.r_le.trans (p.radius_le_radius_continuousLinearMap_comp _)
r_pos := h.r_pos
hasSum hy h'y := by
simpa only [ContinuousLinearMap.compFormalMultilinearSeries_apply,
ContinuousLinearMap.compContinuousMultilinearMap_coe, Function.comp_apply] using
g.hasSum (h.hasSum hy h'y)
/-- If a function `f` has a power series `p` on a ball and `g` is linear, then `g ∘ f` has the
power series `g ∘ p` on the same ball. -/
theorem ContinuousLinearMap.comp_hasFPowerSeriesOnBall (g : F →L[𝕜] G)
(h : HasFPowerSeriesOnBall f p x r) :
HasFPowerSeriesOnBall (g ∘ f) (g.compFormalMultilinearSeries p) x r := by
rw [← hasFPowerSeriesWithinOnBall_univ] at h ⊢
exact g.comp_hasFPowerSeriesWithinOnBall h
/-- If a function `f` is analytic on a set `s` and `g` is linear, then `g ∘ f` is analytic
on `s`. -/
theorem ContinuousLinearMap.comp_analyticOn (g : F →L[𝕜] G) (h : AnalyticOn 𝕜 f s) :
AnalyticOn 𝕜 (g ∘ f) s := by
rintro x hx
rcases h x hx with ⟨p, r, hp⟩
exact ⟨g.compFormalMultilinearSeries p, r, g.comp_hasFPowerSeriesWithinOnBall hp⟩
/-- If a function `f` is analytic on a set `s` and `g` is linear, then `g ∘ f` is analytic
on `s`. -/
theorem ContinuousLinearMap.comp_analyticOnNhd
{s : Set E} (g : F →L[𝕜] G) (h : AnalyticOnNhd 𝕜 f s) :
AnalyticOnNhd 𝕜 (g ∘ f) s := by
rintro x hx
rcases h x hx with ⟨p, r, hp⟩
exact ⟨g.compFormalMultilinearSeries p, r, g.comp_hasFPowerSeriesOnBall hp⟩
/-!
### Relation between analytic function and the partial sums of its power series
-/
theorem HasFPowerSeriesWithinOnBall.tendsto_partialSum
(hf : HasFPowerSeriesWithinOnBall f p s x r) {y : E} (hy : y ∈ EMetric.ball (0 : E) r)
(h'y : x + y ∈ insert x s) :
Tendsto (fun n => p.partialSum n y) atTop (𝓝 (f (x + y))) :=
(hf.hasSum h'y hy).tendsto_sum_nat
theorem HasFPowerSeriesOnBall.tendsto_partialSum
(hf : HasFPowerSeriesOnBall f p x r) {y : E} (hy : y ∈ EMetric.ball (0 : E) r) :
Tendsto (fun n => p.partialSum n y) atTop (𝓝 (f (x + y))) :=
(hf.hasSum hy).tendsto_sum_nat
theorem HasFPowerSeriesAt.tendsto_partialSum
(hf : HasFPowerSeriesAt f p x) :
∀ᶠ y in 𝓝 0, Tendsto (fun n => p.partialSum n y) atTop (𝓝 (f (x + y))) := by
rcases hf with ⟨r, hr⟩
filter_upwards [EMetric.ball_mem_nhds (0 : E) hr.r_pos] with y hy
exact hr.tendsto_partialSum hy
open Finset in
/-- If a function admits a power series expansion within a ball, then the partial sums
`p.partialSum n z` converge to `f (x + y)` as `n → ∞` and `z → y`. Note that `x + z` doesn't need
to belong to the set where the power series expansion holds. -/
theorem HasFPowerSeriesWithinOnBall.tendsto_partialSum_prod {y : E}
(hf : HasFPowerSeriesWithinOnBall f p s x r) (hy : y ∈ EMetric.ball (0 : E) r)
(h'y : x + y ∈ insert x s) :
Tendsto (fun (z : ℕ × E) ↦ p.partialSum z.1 z.2) (atTop ×ˢ 𝓝 y) (𝓝 (f (x + y))) := by
have A : Tendsto (fun (z : ℕ × E) ↦ p.partialSum z.1 y) (atTop ×ˢ 𝓝 y) (𝓝 (f (x + y))) := by
apply (hf.tendsto_partialSum hy h'y).comp tendsto_fst
suffices Tendsto (fun (z : ℕ × E) ↦ p.partialSum z.1 z.2 - p.partialSum z.1 y)
(atTop ×ˢ 𝓝 y) (𝓝 0) by simpa using A.add this
apply Metric.tendsto_nhds.2 (fun ε εpos ↦ ?_)
obtain ⟨r', yr', r'r⟩ : ∃ (r' : ℝ≥0), ‖y‖₊ < r' ∧ r' < r := by
simp [edist_zero_eq_enorm] at hy
simpa using ENNReal.lt_iff_exists_nnreal_btwn.1 hy
have yr'_2 : ‖y‖ < r' := by simpa [← coe_nnnorm] using yr'
have S : Summable fun n ↦ ‖p n‖ * ↑r' ^ n := p.summable_norm_mul_pow (r'r.trans_le hf.r_le)
obtain ⟨k, hk⟩ : ∃ k, ∑' (n : ℕ), ‖p (n + k)‖ * ↑r' ^ (n + k) < ε / 4 := by
have : Tendsto (fun k ↦ ∑' n, ‖p (n + k)‖ * ↑r' ^ (n + k)) atTop (𝓝 0) := by
apply _root_.tendsto_sum_nat_add (f := fun n ↦ ‖p n‖ * ↑r' ^ n)
exact ((tendsto_order.1 this).2 _ (by linarith)).exists
have A : ∀ᶠ (z : ℕ × E) in atTop ×ˢ 𝓝 y,
dist (p.partialSum k z.2) (p.partialSum k y) < ε / 4 := by
have : ContinuousAt (fun z ↦ p.partialSum k z) y := (p.partialSum_continuous k).continuousAt
exact tendsto_snd (Metric.tendsto_nhds.1 this.tendsto (ε / 4) (by linarith))
have B : ∀ᶠ (z : ℕ × E) in atTop ×ˢ 𝓝 y, ‖z.2‖₊ < r' := by
suffices ∀ᶠ (z : E) in 𝓝 y, ‖z‖₊ < r' from tendsto_snd this
have : Metric.ball 0 r' ∈ 𝓝 y := Metric.isOpen_ball.mem_nhds (by simpa using yr'_2)
filter_upwards [this] with a ha using by simpa [← coe_nnnorm] using ha
have C : ∀ᶠ (z : ℕ × E) in atTop ×ˢ 𝓝 y, k ≤ z.1 := tendsto_fst (Ici_mem_atTop _)
filter_upwards [A, B, C]
rintro ⟨n, z⟩ hz h'z hkn
simp only [dist_eq_norm, sub_zero] at hz ⊢
have I (w : E) (hw : ‖w‖₊ < r') : ‖∑ i ∈ Ico k n, p i (fun _ ↦ w)‖ ≤ ε / 4 := calc
‖∑ i ∈ Ico k n, p i (fun _ ↦ w)‖
_ = ‖∑ i ∈ range (n - k), p (i + k) (fun _ ↦ w)‖ := by
rw [sum_Ico_eq_sum_range]
congr with i
rw [add_comm k]
_ ≤ ∑ i ∈ range (n - k), ‖p (i + k) (fun _ ↦ w)‖ := norm_sum_le _ _
_ ≤ ∑ i ∈ range (n - k), ‖p (i + k)‖ * ‖w‖ ^ (i + k) := by
gcongr with i _hi; exact ((p (i + k)).le_opNorm _).trans_eq (by simp)
_ ≤ ∑ i ∈ range (n - k), ‖p (i + k)‖ * ↑r' ^ (i + k) := by
gcongr with i _hi; simpa [← coe_nnnorm] using hw.le
_ ≤ ∑' i, ‖p (i + k)‖ * ↑r' ^ (i + k) := by
apply Summable.sum_le_tsum _ (fun i _hi ↦ by positivity)
apply ((_root_.summable_nat_add_iff k).2 S)
_ ≤ ε / 4 := hk.le
calc
‖p.partialSum n z - p.partialSum n y‖
_ = ‖∑ i ∈ range n, p i (fun _ ↦ z) - ∑ i ∈ range n, p i (fun _ ↦ y)‖ := rfl
_ = ‖(∑ i ∈ range k, p i (fun _ ↦ z) + ∑ i ∈ Ico k n, p i (fun _ ↦ z))
- (∑ i ∈ range k, p i (fun _ ↦ y) + ∑ i ∈ Ico k n, p i (fun _ ↦ y))‖ := by
simp [sum_range_add_sum_Ico _ hkn]
_ = ‖(p.partialSum k z - p.partialSum k y) + (∑ i ∈ Ico k n, p i (fun _ ↦ z))
+ (- ∑ i ∈ Ico k n, p i (fun _ ↦ y))‖ := by
congr 1
simp only [FormalMultilinearSeries.partialSum]
abel
_ ≤ ‖p.partialSum k z - p.partialSum k y‖ + ‖∑ i ∈ Ico k n, p i (fun _ ↦ z)‖
+ ‖- ∑ i ∈ Ico k n, p i (fun _ ↦ y)‖ := norm_add₃_le
_ ≤ ε / 4 + ε / 4 + ε / 4 := by
gcongr
· exact I _ h'z
· simp only [norm_neg]; exact I _ yr'
_ < ε := by linarith
/-- If a function admits a power series on a ball, then the partial sums
`p.partialSum n z` converges to `f (x + y)` as `n → ∞` and `z → y`. -/
theorem HasFPowerSeriesOnBall.tendsto_partialSum_prod {y : E}
(hf : HasFPowerSeriesOnBall f p x r) (hy : y ∈ EMetric.ball (0 : E) r) :
Tendsto (fun (z : ℕ × E) ↦ p.partialSum z.1 z.2) (atTop ×ˢ 𝓝 y) (𝓝 (f (x + y))) :=
(hf.hasFPowerSeriesWithinOnBall (s := univ)).tendsto_partialSum_prod hy (by simp)
/-- If a function admits a power series expansion, then it is exponentially close to the partial
sums of this power series on strict subdisks of the disk of convergence.
This version provides an upper estimate that decreases both in `‖y‖` and `n`. See also
`HasFPowerSeriesWithinOnBall.uniform_geometric_approx` for a weaker version. -/
theorem HasFPowerSeriesWithinOnBall.uniform_geometric_approx' {r' : ℝ≥0}
(hf : HasFPowerSeriesWithinOnBall f p s x r) (h : (r' : ℝ≥0∞) < r) :
∃ a ∈ Ioo (0 : ℝ) 1, ∃ C > 0, ∀ y ∈ Metric.ball (0 : E) r', ∀ n, x + y ∈ insert x s →
‖f (x + y) - p.partialSum n y‖ ≤ C * (a * (‖y‖ / r')) ^ n := by
obtain ⟨a, ha, C, hC, hp⟩ : ∃ a ∈ Ioo (0 : ℝ) 1, ∃ C > 0, ∀ n, ‖p n‖ * (r' : ℝ) ^ n ≤ C * a ^ n :=
p.norm_mul_pow_le_mul_pow_of_lt_radius (h.trans_le hf.r_le)
refine ⟨a, ha, C / (1 - a), div_pos hC (sub_pos.2 ha.2), fun y hy n ys => ?_⟩
have yr' : ‖y‖ < r' := by
rw [ball_zero_eq] at hy
exact hy
have hr'0 : 0 < (r' : ℝ) := (norm_nonneg _).trans_lt yr'
have : y ∈ EMetric.ball (0 : E) r := by
refine mem_emetric_ball_zero_iff.2 (lt_trans ?_ h)
simpa [enorm] using yr'
rw [norm_sub_rev, ← mul_div_right_comm]
have ya : a * (‖y‖ / ↑r') ≤ a :=
mul_le_of_le_one_right ha.1.le (div_le_one_of_le₀ yr'.le r'.coe_nonneg)
suffices ‖p.partialSum n y - f (x + y)‖ ≤ C * (a * (‖y‖ / r')) ^ n / (1 - a * (‖y‖ / r')) by
refine this.trans ?_
have : 0 < a := ha.1
gcongr
apply_rules [sub_pos.2, ha.2]
apply norm_sub_le_of_geometric_bound_of_hasSum (ya.trans_lt ha.2) _ (hf.hasSum ys this)
intro n
calc
‖(p n) fun _ : Fin n => y‖
_ ≤ ‖p n‖ * ∏ _i : Fin n, ‖y‖ := ContinuousMultilinearMap.le_opNorm _ _
_ = ‖p n‖ * (r' : ℝ) ^ n * (‖y‖ / r') ^ n := by field_simp [mul_right_comm]
_ ≤ C * a ^ n * (‖y‖ / r') ^ n := by gcongr ?_ * _; apply hp
_ ≤ C * (a * (‖y‖ / r')) ^ n := by rw [mul_pow, mul_assoc]
/-- If a function admits a power series expansion, then it is exponentially close to the partial
sums of this power series on strict subdisks of the disk of convergence.
This version provides an upper estimate that decreases both in `‖y‖` and `n`. See also
`HasFPowerSeriesOnBall.uniform_geometric_approx` for a weaker version. -/
theorem HasFPowerSeriesOnBall.uniform_geometric_approx' {r' : ℝ≥0}
(hf : HasFPowerSeriesOnBall f p x r) (h : (r' : ℝ≥0∞) < r) :
∃ a ∈ Ioo (0 : ℝ) 1, ∃ C > 0, ∀ y ∈ Metric.ball (0 : E) r', ∀ n,
‖f (x + y) - p.partialSum n y‖ ≤ C * (a * (‖y‖ / r')) ^ n := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
simpa using hf.uniform_geometric_approx' h
/-- If a function admits a power series expansion within a set in a ball, then it is exponentially
close to the partial sums of this power series on strict subdisks of the disk of convergence. -/
theorem HasFPowerSeriesWithinOnBall.uniform_geometric_approx {r' : ℝ≥0}
(hf : HasFPowerSeriesWithinOnBall f p s x r) (h : (r' : ℝ≥0∞) < r) :
∃ a ∈ Ioo (0 : ℝ) 1,
∃ C > 0, ∀ y ∈ Metric.ball (0 : E) r', ∀ n, x + y ∈ insert x s →
‖f (x + y) - p.partialSum n y‖ ≤ C * a ^ n := by
obtain ⟨a, ha, C, hC, hp⟩ : ∃ a ∈ Ioo (0 : ℝ) 1, ∃ C > 0, ∀ y ∈ Metric.ball (0 : E) r', ∀ n,
x + y ∈ insert x s → ‖f (x + y) - p.partialSum n y‖ ≤ C * (a * (‖y‖ / r')) ^ n :=
hf.uniform_geometric_approx' h
refine ⟨a, ha, C, hC, fun y hy n ys => (hp y hy n ys).trans ?_⟩
have yr' : ‖y‖ < r' := by rwa [ball_zero_eq] at hy
have := ha.1.le -- needed to discharge a side goal on the next line
gcongr
exact mul_le_of_le_one_right ha.1.le (div_le_one_of_le₀ yr'.le r'.coe_nonneg)
/-- If a function admits a power series expansion, then it is exponentially close to the partial
sums of this power series on strict subdisks of the disk of convergence. -/
theorem HasFPowerSeriesOnBall.uniform_geometric_approx {r' : ℝ≥0}
(hf : HasFPowerSeriesOnBall f p x r) (h : (r' : ℝ≥0∞) < r) :
∃ a ∈ Ioo (0 : ℝ) 1,
∃ C > 0, ∀ y ∈ Metric.ball (0 : E) r', ∀ n,
‖f (x + y) - p.partialSum n y‖ ≤ C * a ^ n := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
simpa using hf.uniform_geometric_approx h
/-- Taylor formula for an analytic function within a set, `IsBigO` version. -/
theorem HasFPowerSeriesWithinAt.isBigO_sub_partialSum_pow
(hf : HasFPowerSeriesWithinAt f p s x) (n : ℕ) :
(fun y : E => f (x + y) - p.partialSum n y)
=O[𝓝[(x + ·)⁻¹' insert x s] 0] fun y => ‖y‖ ^ n := by
rcases hf with ⟨r, hf⟩
rcases ENNReal.lt_iff_exists_nnreal_btwn.1 hf.r_pos with ⟨r', r'0, h⟩
obtain ⟨a, -, C, -, hp⟩ : ∃ a ∈ Ioo (0 : ℝ) 1, ∃ C > 0, ∀ y ∈ Metric.ball (0 : E) r', ∀ n,
x + y ∈ insert x s → ‖f (x + y) - p.partialSum n y‖ ≤ C * (a * (‖y‖ / r')) ^ n :=
hf.uniform_geometric_approx' h
refine isBigO_iff.2 ⟨C * (a / r') ^ n, ?_⟩
replace r'0 : 0 < (r' : ℝ) := mod_cast r'0
filter_upwards [inter_mem_nhdsWithin _ (Metric.ball_mem_nhds (0 : E) r'0)] with y hy
simpa [mul_pow, mul_div_assoc, mul_assoc, div_mul_eq_mul_div, div_pow]
using hp y hy.2 n (by simpa using hy.1)
/-- Taylor formula for an analytic function, `IsBigO` version. -/
theorem HasFPowerSeriesAt.isBigO_sub_partialSum_pow
(hf : HasFPowerSeriesAt f p x) (n : ℕ) :
(fun y : E => f (x + y) - p.partialSum n y) =O[𝓝 0] fun y => ‖y‖ ^ n := by
rw [← hasFPowerSeriesWithinAt_univ] at hf
simpa using hf.isBigO_sub_partialSum_pow n
/-- If `f` has formal power series `∑ n, pₙ` in a set, within a ball of radius `r`, then
for `y, z` in any smaller ball, the norm of the difference `f y - f z - p 1 (fun _ ↦ y - z)` is
bounded above by `C * (max ‖y - x‖ ‖z - x‖) * ‖y - z‖`. This lemma formulates this property
using `IsBigO` and `Filter.principal` on `E × E`. -/
theorem HasFPowerSeriesWithinOnBall.isBigO_image_sub_image_sub_deriv_principal
(hf : HasFPowerSeriesWithinOnBall f p s x r) (hr : r' < r) :
(fun y : E × E => f y.1 - f y.2 - p 1 fun _ => y.1 - y.2)
=O[𝓟 (EMetric.ball (x, x) r' ∩ ((insert x s) ×ˢ (insert x s)))]
fun y => ‖y - (x, x)‖ * ‖y.1 - y.2‖ := by
lift r' to ℝ≥0 using ne_top_of_lt hr
rcases (zero_le r').eq_or_lt with (rfl | hr'0)
· simp only [ENNReal.coe_zero, EMetric.ball_zero, empty_inter, principal_empty, isBigO_bot]
obtain ⟨a, ha, C, hC : 0 < C, hp⟩ :
∃ a ∈ Ioo (0 : ℝ) 1, ∃ C > 0, ∀ n : ℕ, ‖p n‖ * (r' : ℝ) ^ n ≤ C * a ^ n :=
p.norm_mul_pow_le_mul_pow_of_lt_radius (hr.trans_le hf.r_le)
simp only [← le_div_iff₀ (pow_pos (NNReal.coe_pos.2 hr'0) _)] at hp
set L : E × E → ℝ := fun y =>
C * (a / r') ^ 2 * (‖y - (x, x)‖ * ‖y.1 - y.2‖) * (a / (1 - a) ^ 2 + 2 / (1 - a))
have hL : ∀ y ∈ EMetric.ball (x, x) r' ∩ ((insert x s) ×ˢ (insert x s)),
‖f y.1 - f y.2 - p 1 fun _ => y.1 - y.2‖ ≤ L y := by
intro y ⟨hy', ys⟩
have hy : y ∈ EMetric.ball x r ×ˢ EMetric.ball x r := by
rw [EMetric.ball_prod_same]
exact EMetric.ball_subset_ball hr.le hy'
set A : ℕ → F := fun n => (p n fun _ => y.1 - x) - p n fun _ => y.2 - x
have hA : HasSum (fun n => A (n + 2)) (f y.1 - f y.2 - p 1 fun _ => y.1 - y.2) := by
convert (hasSum_nat_add_iff' 2).2
((hf.hasSum_sub ⟨ys.1, hy.1⟩).sub (hf.hasSum_sub ⟨ys.2, hy.2⟩)) using 1
rw [Finset.sum_range_succ, Finset.sum_range_one, hf.coeff_zero, hf.coeff_zero, sub_self,
zero_add, ← Subsingleton.pi_single_eq (0 : Fin 1) (y.1 - x), Pi.single,
← Subsingleton.pi_single_eq (0 : Fin 1) (y.2 - x), Pi.single, ← (p 1).map_update_sub,
← Pi.single, Subsingleton.pi_single_eq, sub_sub_sub_cancel_right]
rw [EMetric.mem_ball, edist_eq_enorm_sub, enorm_lt_coe] at hy'
set B : ℕ → ℝ := fun n => C * (a / r') ^ 2 * (‖y - (x, x)‖ * ‖y.1 - y.2‖) * ((n + 2) * a ^ n)
have hAB : ∀ n, ‖A (n + 2)‖ ≤ B n := fun n =>
calc
‖A (n + 2)‖ ≤ ‖p (n + 2)‖ * ↑(n + 2) * ‖y - (x, x)‖ ^ (n + 1) * ‖y.1 - y.2‖ := by
simpa only [Fintype.card_fin, pi_norm_const, Prod.norm_def, Pi.sub_def,
Prod.fst_sub, Prod.snd_sub, sub_sub_sub_cancel_right] using
(p <| n + 2).norm_image_sub_le (fun _ => y.1 - x) fun _ => y.2 - x
_ = ‖p (n + 2)‖ * ‖y - (x, x)‖ ^ n * (↑(n + 2) * ‖y - (x, x)‖ * ‖y.1 - y.2‖) := by
rw [pow_succ ‖y - (x, x)‖]
ring
_ ≤ C * a ^ (n + 2) / r' ^ (n + 2)
* r' ^ n * (↑(n + 2) * ‖y - (x, x)‖ * ‖y.1 - y.2‖) := by
have : 0 < a := ha.1
gcongr
· apply hp
· apply hy'.le
_ = B n := by
field_simp [B, pow_succ]
simp only [mul_assoc, mul_comm, mul_left_comm]
have hBL : HasSum B (L y) := by
apply HasSum.mul_left
simp only [add_mul]
have : ‖a‖ < 1 := by simp only [Real.norm_eq_abs, abs_of_pos ha.1, ha.2]
rw [div_eq_mul_inv, div_eq_mul_inv]
exact (hasSum_coe_mul_geometric_of_norm_lt_one this).add
((hasSum_geometric_of_norm_lt_one this).mul_left 2)
exact hA.norm_le_of_bounded hBL hAB
suffices L =O[𝓟 (EMetric.ball (x, x) r' ∩ ((insert x s) ×ˢ (insert x s)))]
fun y => ‖y - (x, x)‖ * ‖y.1 - y.2‖ from
.trans (.of_norm_eventuallyLE (eventually_principal.2 hL)) this
simp_rw [L, mul_right_comm _ (_ * _)]
exact (isBigO_refl _ _).const_mul_left _
/-- If `f` has formal power series `∑ n, pₙ` on a ball of radius `r`, then for `y, z` in any smaller
ball, the norm of the difference `f y - f z - p 1 (fun _ ↦ y - z)` is bounded above by
`C * (max ‖y - x‖ ‖z - x‖) * ‖y - z‖`. This lemma formulates this property using `IsBigO` and
`Filter.principal` on `E × E`. -/
theorem HasFPowerSeriesOnBall.isBigO_image_sub_image_sub_deriv_principal
(hf : HasFPowerSeriesOnBall f p x r) (hr : r' < r) :
(fun y : E × E => f y.1 - f y.2 - p 1 fun _ => y.1 - y.2)
=O[𝓟 (EMetric.ball (x, x) r')] fun y => ‖y - (x, x)‖ * ‖y.1 - y.2‖ := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
simpa using hf.isBigO_image_sub_image_sub_deriv_principal hr
/-- If `f` has formal power series `∑ n, pₙ` within a set, on a ball of radius `r`, then for `y, z`
in any smaller ball, the norm of the difference `f y - f z - p 1 (fun _ ↦ y - z)` is bounded above
by `C * (max ‖y - x‖ ‖z - x‖) * ‖y - z‖`. -/
theorem HasFPowerSeriesWithinOnBall.image_sub_sub_deriv_le
(hf : HasFPowerSeriesWithinOnBall f p s x r) (hr : r' < r) :
∃ C, ∀ᵉ (y ∈ insert x s ∩ EMetric.ball x r') (z ∈ insert x s ∩ EMetric.ball x r'),
‖f y - f z - p 1 fun _ => y - z‖ ≤ C * max ‖y - x‖ ‖z - x‖ * ‖y - z‖ := by
have := hf.isBigO_image_sub_image_sub_deriv_principal hr
simp only [isBigO_principal, mem_inter_iff, EMetric.mem_ball, Prod.edist_eq, max_lt_iff, mem_prod,
norm_mul, Real.norm_eq_abs, abs_norm, and_imp, Prod.forall, mul_assoc] at this ⊢
rcases this with ⟨C, hC⟩
exact ⟨C, fun y ys hy z zs hz ↦ hC y z hy hz ys zs⟩
/-- If `f` has formal power series `∑ n, pₙ` on a ball of radius `r`, then for `y, z` in any smaller
ball, the norm of the difference `f y - f z - p 1 (fun _ ↦ y - z)` is bounded above by
`C * (max ‖y - x‖ ‖z - x‖) * ‖y - z‖`. -/
theorem HasFPowerSeriesOnBall.image_sub_sub_deriv_le
(hf : HasFPowerSeriesOnBall f p x r) (hr : r' < r) :
∃ C, ∀ᵉ (y ∈ EMetric.ball x r') (z ∈ EMetric.ball x r'),
‖f y - f z - p 1 fun _ => y - z‖ ≤ C * max ‖y - x‖ ‖z - x‖ * ‖y - z‖ := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
simpa only [mem_univ, insert_eq_of_mem, univ_inter] using hf.image_sub_sub_deriv_le hr
/-- If `f` has formal power series `∑ n, pₙ` at `x` within a set `s`, then
`f y - f z - p 1 (fun _ ↦ y - z) = O(‖(y, z) - (x, x)‖ * ‖y - z‖)` as `(y, z) → (x, x)`
within `s × s`. -/
theorem HasFPowerSeriesWithinAt.isBigO_image_sub_norm_mul_norm_sub
(hf : HasFPowerSeriesWithinAt f p s x) :
(fun y : E × E => f y.1 - f y.2 - p 1 fun _ => y.1 - y.2)
=O[𝓝[(insert x s) ×ˢ (insert x s)] (x, x)] fun y => ‖y - (x, x)‖ * ‖y.1 - y.2‖ := by
rcases hf with ⟨r, hf⟩
rcases ENNReal.lt_iff_exists_nnreal_btwn.1 hf.r_pos with ⟨r', r'0, h⟩
refine (hf.isBigO_image_sub_image_sub_deriv_principal h).mono ?_
rw [inter_comm]
exact le_principal_iff.2 (inter_mem_nhdsWithin _ (EMetric.ball_mem_nhds _ r'0))
/-- If `f` has formal power series `∑ n, pₙ` at `x`, then
`f y - f z - p 1 (fun _ ↦ y - z) = O(‖(y, z) - (x, x)‖ * ‖y - z‖)` as `(y, z) → (x, x)`.
In particular, `f` is strictly differentiable at `x`. -/
theorem HasFPowerSeriesAt.isBigO_image_sub_norm_mul_norm_sub (hf : HasFPowerSeriesAt f p x) :
(fun y : E × E => f y.1 - f y.2 - p 1 fun _ => y.1 - y.2) =O[𝓝 (x, x)] fun y =>
‖y - (x, x)‖ * ‖y.1 - y.2‖ := by
rw [← hasFPowerSeriesWithinAt_univ] at hf
simpa using hf.isBigO_image_sub_norm_mul_norm_sub
/-- If a function admits a power series expansion within a set at `x`, then it is the uniform limit
of the partial sums of this power series on strict subdisks of the disk of convergence, i.e.,
`f (x + y)` is the uniform limit of `p.partialSum n y` there. -/
theorem HasFPowerSeriesWithinOnBall.tendstoUniformlyOn {r' : ℝ≥0}
(hf : HasFPowerSeriesWithinOnBall f p s x r) (h : (r' : ℝ≥0∞) < r) :
TendstoUniformlyOn (fun n y => p.partialSum n y) (fun y => f (x + y)) atTop
((x + ·)⁻¹' (insert x s) ∩ Metric.ball (0 : E) r') := by
obtain ⟨a, ha, C, -, hp⟩ : ∃ a ∈ Ioo (0 : ℝ) 1, ∃ C > 0, ∀ y ∈ Metric.ball (0 : E) r', ∀ n,
x + y ∈ insert x s → ‖f (x + y) - p.partialSum n y‖ ≤ C * a ^ n := hf.uniform_geometric_approx h
refine Metric.tendstoUniformlyOn_iff.2 fun ε εpos => ?_
have L : Tendsto (fun n => (C : ℝ) * a ^ n) atTop (𝓝 ((C : ℝ) * 0)) :=
tendsto_const_nhds.mul (tendsto_pow_atTop_nhds_zero_of_lt_one ha.1.le ha.2)
rw [mul_zero] at L
refine (L.eventually (gt_mem_nhds εpos)).mono fun n hn y hy => ?_
rw [dist_eq_norm]
exact (hp y hy.2 n hy.1).trans_lt hn
/-- If a function admits a power series expansion at `x`, then it is the uniform limit of the
partial sums of this power series on strict subdisks of the disk of convergence, i.e., `f (x + y)`
is the uniform limit of `p.partialSum n y` there. -/
theorem HasFPowerSeriesOnBall.tendstoUniformlyOn {r' : ℝ≥0} (hf : HasFPowerSeriesOnBall f p x r)
(h : (r' : ℝ≥0∞) < r) :
TendstoUniformlyOn (fun n y => p.partialSum n y) (fun y => f (x + y)) atTop
(Metric.ball (0 : E) r') := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
simpa using hf.tendstoUniformlyOn h
/-- If a function admits a power series expansion within a set at `x`, then it is the locally
uniform limit of the partial sums of this power series on the disk of convergence, i.e., `f (x + y)`
is the locally uniform limit of `p.partialSum n y` there. -/
theorem HasFPowerSeriesWithinOnBall.tendstoLocallyUniformlyOn
(hf : HasFPowerSeriesWithinOnBall f p s x r) :
TendstoLocallyUniformlyOn (fun n y => p.partialSum n y) (fun y => f (x + y)) atTop
((x + ·)⁻¹' (insert x s) ∩ EMetric.ball (0 : E) r) := by
intro u hu y hy
rcases ENNReal.lt_iff_exists_nnreal_btwn.1 hy.2 with ⟨r', yr', hr'⟩
have : EMetric.ball (0 : E) r' ∈ 𝓝 y := IsOpen.mem_nhds EMetric.isOpen_ball yr'
refine ⟨(x + ·)⁻¹' (insert x s) ∩ EMetric.ball (0 : E) r', ?_, ?_⟩
· rw [nhdsWithin_inter_of_mem']
· exact inter_mem_nhdsWithin _ this
· apply mem_nhdsWithin_of_mem_nhds
apply Filter.mem_of_superset this (EMetric.ball_subset_ball hr'.le)
· simpa [Metric.emetric_ball_nnreal] using hf.tendstoUniformlyOn hr' u hu
/-- If a function admits a power series expansion at `x`, then it is the locally uniform limit of
the partial sums of this power series on the disk of convergence, i.e., `f (x + y)`
is the locally uniform limit of `p.partialSum n y` there. -/
theorem HasFPowerSeriesOnBall.tendstoLocallyUniformlyOn (hf : HasFPowerSeriesOnBall f p x r) :
TendstoLocallyUniformlyOn (fun n y => p.partialSum n y) (fun y => f (x + y)) atTop
(EMetric.ball (0 : E) r) := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
simpa using hf.tendstoLocallyUniformlyOn
/-- If a function admits a power series expansion within a set at `x`, then it is the uniform limit
of the partial sums of this power series on strict subdisks of the disk of convergence, i.e., `f y`
is the uniform limit of `p.partialSum n (y - x)` there. -/
theorem HasFPowerSeriesWithinOnBall.tendstoUniformlyOn' {r' : ℝ≥0}
(hf : HasFPowerSeriesWithinOnBall f p s x r) (h : (r' : ℝ≥0∞) < r) :
TendstoUniformlyOn (fun n y => p.partialSum n (y - x)) f atTop
(insert x s ∩ Metric.ball (x : E) r') := by
convert (hf.tendstoUniformlyOn h).comp fun y => y - x using 1
· simp [Function.comp_def]
· ext z
simp [dist_eq_norm]
/-- If a function admits a power series expansion at `x`, then it is the uniform limit of the
partial sums of this power series on strict subdisks of the disk of convergence, i.e., `f y`
is the uniform limit of `p.partialSum n (y - x)` there. -/
theorem HasFPowerSeriesOnBall.tendstoUniformlyOn' {r' : ℝ≥0} (hf : HasFPowerSeriesOnBall f p x r)
(h : (r' : ℝ≥0∞) < r) :
TendstoUniformlyOn (fun n y => p.partialSum n (y - x)) f atTop (Metric.ball (x : E) r') := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
simpa using hf.tendstoUniformlyOn' h
/-- If a function admits a power series expansion within a set at `x`, then it is the locally
uniform limit of the partial sums of this power series on the disk of convergence, i.e., `f y`
is the locally uniform limit of `p.partialSum n (y - x)` there. -/
theorem HasFPowerSeriesWithinOnBall.tendstoLocallyUniformlyOn'
(hf : HasFPowerSeriesWithinOnBall f p s x r) :
TendstoLocallyUniformlyOn (fun n y => p.partialSum n (y - x)) f atTop
(insert x s ∩ EMetric.ball (x : E) r) := by
have A : ContinuousOn (fun y : E => y - x) (insert x s ∩ EMetric.ball (x : E) r) :=
(continuous_id.sub continuous_const).continuousOn
convert hf.tendstoLocallyUniformlyOn.comp (fun y : E => y - x) _ A using 1
· ext z
simp
· intro z
simp [edist_zero_eq_enorm, edist_eq_enorm_sub]
/-- If a function admits a power series expansion at `x`, then it is the locally uniform limit of
the partial sums of this power series on the disk of convergence, i.e., `f y`
is the locally uniform limit of `p.partialSum n (y - x)` there. -/
theorem HasFPowerSeriesOnBall.tendstoLocallyUniformlyOn' (hf : HasFPowerSeriesOnBall f p x r) :
TendstoLocallyUniformlyOn (fun n y => p.partialSum n (y - x)) f atTop
(EMetric.ball (x : E) r) := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
simpa using hf.tendstoLocallyUniformlyOn'
/-- If a function admits a power series expansion within a set on a ball, then it is
continuous there. -/
protected theorem HasFPowerSeriesWithinOnBall.continuousOn
(hf : HasFPowerSeriesWithinOnBall f p s x r) :
ContinuousOn f (insert x s ∩ EMetric.ball x r) :=
hf.tendstoLocallyUniformlyOn'.continuousOn <|
Eventually.of_forall fun n =>
((p.partialSum_continuous n).comp (continuous_id.sub continuous_const)).continuousOn
/-- If a function admits a power series expansion on a ball, then it is continuous there. -/
protected theorem HasFPowerSeriesOnBall.continuousOn (hf : HasFPowerSeriesOnBall f p x r) :
ContinuousOn f (EMetric.ball x r) := by
rw [← hasFPowerSeriesWithinOnBall_univ] at hf
simpa using hf.continuousOn
protected theorem HasFPowerSeriesWithinOnBall.continuousWithinAt_insert
(hf : HasFPowerSeriesWithinOnBall f p s x r) :
ContinuousWithinAt f (insert x s) x := by
apply (hf.continuousOn.continuousWithinAt (x := x) (by simp [hf.r_pos])).mono_of_mem_nhdsWithin
exact inter_mem_nhdsWithin _ (EMetric.ball_mem_nhds x hf.r_pos)
protected theorem HasFPowerSeriesWithinOnBall.continuousWithinAt
(hf : HasFPowerSeriesWithinOnBall f p s x r) :
ContinuousWithinAt f s x :=
hf.continuousWithinAt_insert.mono (subset_insert x s)
protected theorem HasFPowerSeriesWithinAt.continuousWithinAt_insert
(hf : HasFPowerSeriesWithinAt f p s x) :
ContinuousWithinAt f (insert x s) x := by
rcases hf with ⟨r, hr⟩
apply hr.continuousWithinAt_insert
protected theorem HasFPowerSeriesWithinAt.continuousWithinAt
(hf : HasFPowerSeriesWithinAt f p s x) :
ContinuousWithinAt f s x :=
hf.continuousWithinAt_insert.mono (subset_insert x s)
protected theorem HasFPowerSeriesAt.continuousAt (hf : HasFPowerSeriesAt f p x) :
ContinuousAt f x :=
let ⟨_, hr⟩ := hf
hr.continuousOn.continuousAt (EMetric.ball_mem_nhds x hr.r_pos)
protected theorem AnalyticWithinAt.continuousWithinAt_insert (hf : AnalyticWithinAt 𝕜 f s x) :
ContinuousWithinAt f (insert x s) x :=
let ⟨_, hp⟩ := hf
hp.continuousWithinAt_insert
protected theorem AnalyticWithinAt.continuousWithinAt (hf : AnalyticWithinAt 𝕜 f s x) :
ContinuousWithinAt f s x :=
hf.continuousWithinAt_insert.mono (subset_insert x s)
@[fun_prop]
protected theorem AnalyticAt.continuousAt (hf : AnalyticAt 𝕜 f x) : ContinuousAt f x :=
let ⟨_, hp⟩ := hf
hp.continuousAt
protected theorem AnalyticAt.eventually_continuousAt (hf : AnalyticAt 𝕜 f x) :
∀ᶠ y in 𝓝 x, ContinuousAt f y := by
rcases hf with ⟨g, r, hg⟩
have : EMetric.ball x r ∈ 𝓝 x := EMetric.ball_mem_nhds _ hg.r_pos
filter_upwards [this] with y hy
apply hg.continuousOn.continuousAt
exact EMetric.isOpen_ball.mem_nhds hy
protected theorem AnalyticOnNhd.continuousOn {s : Set E} (hf : AnalyticOnNhd 𝕜 f s) :
ContinuousOn f s :=
fun x hx => (hf x hx).continuousAt.continuousWithinAt
protected lemma AnalyticOn.continuousOn {f : E → F} {s : Set E} (h : AnalyticOn 𝕜 f s) :
ContinuousOn f s :=
fun x m ↦ (h x m).continuousWithinAt
/-- Analytic everywhere implies continuous -/
theorem AnalyticOnNhd.continuous {f : E → F} (fa : AnalyticOnNhd 𝕜 f univ) : Continuous f := by
rw [continuous_iff_continuousOn_univ]; exact fa.continuousOn
/-- In a complete space, the sum of a converging power series `p` admits `p` as a power series.
This is not totally obvious as we need to check the convergence of the series. -/
protected theorem FormalMultilinearSeries.hasFPowerSeriesOnBall [CompleteSpace F]
(p : FormalMultilinearSeries 𝕜 E F) (h : 0 < p.radius) :
HasFPowerSeriesOnBall p.sum p 0 p.radius :=
{ r_le := le_rfl
r_pos := h
hasSum := fun hy => by
rw [zero_add]
exact p.hasSum hy }
theorem HasFPowerSeriesWithinOnBall.sum (h : HasFPowerSeriesWithinOnBall f p s x r) {y : E}
(h'y : x + y ∈ insert x s) (hy : y ∈ EMetric.ball (0 : E) r) : f (x + y) = p.sum y :=
(h.hasSum h'y hy).tsum_eq.symm
theorem HasFPowerSeriesOnBall.sum (h : HasFPowerSeriesOnBall f p x r) {y : E}
(hy : y ∈ EMetric.ball (0 : E) r) : f (x + y) = p.sum y :=
(h.hasSum hy).tsum_eq.symm
/-- The sum of a converging power series is continuous in its disk of convergence. -/
protected theorem FormalMultilinearSeries.continuousOn [CompleteSpace F] :
ContinuousOn p.sum (EMetric.ball 0 p.radius) := by
rcases (zero_le p.radius).eq_or_lt with h | h
· simp [← h, continuousOn_empty]
· exact (p.hasFPowerSeriesOnBall h).continuousOn
end
section
open FormalMultilinearSeries
variable {p : FormalMultilinearSeries 𝕜 𝕜 E} {f : 𝕜 → E} {z₀ : 𝕜}
/-- A function `f : 𝕜 → E` has `p` as power series expansion at a point `z₀` iff it is the sum of
`p` in a neighborhood of `z₀`. This makes some proofs easier by hiding the fact that
`HasFPowerSeriesAt` depends on `p.radius`. -/
theorem hasFPowerSeriesAt_iff :
HasFPowerSeriesAt f p z₀ ↔ ∀ᶠ z in 𝓝 0, HasSum (fun n => z ^ n • p.coeff n) (f (z₀ + z)) := by
refine ⟨fun ⟨r, _, r_pos, h⟩ =>
eventually_of_mem (EMetric.ball_mem_nhds 0 r_pos) fun _ => by simpa using h, ?_⟩
simp only [Metric.eventually_nhds_iff]
rintro ⟨r, r_pos, h⟩
refine ⟨p.radius ⊓ r.toNNReal, by simp, ?_, ?_⟩
| · simp only [r_pos.lt, lt_inf_iff, ENNReal.coe_pos, Real.toNNReal_pos, and_true]
obtain ⟨z, z_pos, le_z⟩ := NormedField.exists_norm_lt 𝕜 r_pos.lt
have : (‖z‖₊ : ENNReal) ≤ p.radius := by
simp only [dist_zero_right] at h
apply FormalMultilinearSeries.le_radius_of_tendsto
convert tendsto_norm.comp (h le_z).summable.tendsto_atTop_zero
| Mathlib/Analysis/Analytic/Basic.lean | 1,389 | 1,394 |
/-
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.NAry
import Mathlib.Data.Finset.Slice
import Mathlib.Data.Set.Sups
/-!
# Set family operations
This file defines a few binary operations on `Finset α` for use in set family combinatorics.
## Main declarations
* `Finset.sups s t`: Finset of elements of the form `a ⊔ b` where `a ∈ s`, `b ∈ t`.
* `Finset.infs s t`: Finset of elements of the form `a ⊓ b` where `a ∈ s`, `b ∈ t`.
* `Finset.disjSups s t`: Finset of elements of the form `a ⊔ b` where `a ∈ s`, `b ∈ t` and `a`
and `b` are disjoint.
* `Finset.diffs`: Finset of elements of the form `a \ b` where `a ∈ s`, `b ∈ t`.
* `Finset.compls`: Finset of elements of the form `aᶜ` where `a ∈ s`.
## Notation
We define the following notation in locale `FinsetFamily`:
* `s ⊻ t` for `Finset.sups`
* `s ⊼ t` for `Finset.infs`
* `s ○ t` for `Finset.disjSups s t`
* `s \\ t` for `Finset.diffs`
* `sᶜˢ` for `Finset.compls`
## References
[B. Bollobás, *Combinatorics*][bollobas1986]
-/
open Function
open SetFamily
variable {F α β : Type*}
namespace Finset
section Sups
variable [DecidableEq α] [DecidableEq β]
variable [SemilatticeSup α] [SemilatticeSup β] [FunLike F α β] [SupHomClass F α β]
variable (s s₁ s₂ t t₁ t₂ u v : Finset α)
/-- `s ⊻ t` is the finset of elements of the form `a ⊔ b` where `a ∈ s`, `b ∈ t`. -/
protected def hasSups : HasSups (Finset α) :=
⟨image₂ (· ⊔ ·)⟩
scoped[FinsetFamily] attribute [instance] Finset.hasSups
open FinsetFamily
variable {s t} {a b c : α}
@[simp]
theorem mem_sups : c ∈ s ⊻ t ↔ ∃ a ∈ s, ∃ b ∈ t, a ⊔ b = c := by simp [(· ⊻ ·)]
variable (s t)
@[simp, norm_cast]
theorem coe_sups : (↑(s ⊻ t) : Set α) = ↑s ⊻ ↑t :=
coe_image₂ _ _ _
theorem card_sups_le : #(s ⊻ t) ≤ #s * #t := card_image₂_le _ _ _
theorem card_sups_iff : #(s ⊻ t) = #s * #t ↔ (s ×ˢ t : Set (α × α)).InjOn fun x => x.1 ⊔ x.2 :=
card_image₂_iff
variable {s s₁ s₂ t t₁ t₂ u}
theorem sup_mem_sups : a ∈ s → b ∈ t → a ⊔ b ∈ s ⊻ t :=
mem_image₂_of_mem
theorem sups_subset : s₁ ⊆ s₂ → t₁ ⊆ t₂ → s₁ ⊻ t₁ ⊆ s₂ ⊻ t₂ :=
image₂_subset
theorem sups_subset_left : t₁ ⊆ t₂ → s ⊻ t₁ ⊆ s ⊻ t₂ :=
image₂_subset_left
theorem sups_subset_right : s₁ ⊆ s₂ → s₁ ⊻ t ⊆ s₂ ⊻ t :=
image₂_subset_right
lemma image_subset_sups_left : b ∈ t → s.image (· ⊔ b) ⊆ s ⊻ t := image_subset_image₂_left
lemma image_subset_sups_right : a ∈ s → t.image (a ⊔ ·) ⊆ s ⊻ t := image_subset_image₂_right
theorem forall_sups_iff {p : α → Prop} : (∀ c ∈ s ⊻ t, p c) ↔ ∀ a ∈ s, ∀ b ∈ t, p (a ⊔ b) :=
forall_mem_image₂
@[simp]
theorem sups_subset_iff : s ⊻ t ⊆ u ↔ ∀ a ∈ s, ∀ b ∈ t, a ⊔ b ∈ u :=
image₂_subset_iff
@[simp]
theorem sups_nonempty : (s ⊻ t).Nonempty ↔ s.Nonempty ∧ t.Nonempty :=
image₂_nonempty_iff
@[aesop safe apply (rule_sets := [finsetNonempty])]
protected theorem Nonempty.sups : s.Nonempty → t.Nonempty → (s ⊻ t).Nonempty :=
Nonempty.image₂
theorem Nonempty.of_sups_left : (s ⊻ t).Nonempty → s.Nonempty :=
Nonempty.of_image₂_left
theorem Nonempty.of_sups_right : (s ⊻ t).Nonempty → t.Nonempty :=
Nonempty.of_image₂_right
@[simp]
theorem empty_sups : ∅ ⊻ t = ∅ :=
image₂_empty_left
@[simp]
theorem sups_empty : s ⊻ ∅ = ∅ :=
image₂_empty_right
@[simp]
theorem sups_eq_empty : s ⊻ t = ∅ ↔ s = ∅ ∨ t = ∅ :=
image₂_eq_empty_iff
@[simp] lemma singleton_sups : {a} ⊻ t = t.image (a ⊔ ·) := image₂_singleton_left
@[simp] lemma sups_singleton : s ⊻ {b} = s.image (· ⊔ b) := image₂_singleton_right
theorem singleton_sups_singleton : ({a} ⊻ {b} : Finset α) = {a ⊔ b} :=
image₂_singleton
theorem sups_union_left : (s₁ ∪ s₂) ⊻ t = s₁ ⊻ t ∪ s₂ ⊻ t :=
image₂_union_left
theorem sups_union_right : s ⊻ (t₁ ∪ t₂) = s ⊻ t₁ ∪ s ⊻ t₂ :=
image₂_union_right
theorem sups_inter_subset_left : (s₁ ∩ s₂) ⊻ t ⊆ s₁ ⊻ t ∩ s₂ ⊻ t :=
image₂_inter_subset_left
theorem sups_inter_subset_right : s ⊻ (t₁ ∩ t₂) ⊆ s ⊻ t₁ ∩ s ⊻ t₂ :=
image₂_inter_subset_right
theorem subset_sups {s t : Set α} :
↑u ⊆ s ⊻ t → ∃ s' t' : Finset α, ↑s' ⊆ s ∧ ↑t' ⊆ t ∧ u ⊆ s' ⊻ t' :=
subset_set_image₂
lemma image_sups (f : F) (s t : Finset α) : image f (s ⊻ t) = image f s ⊻ image f t :=
image_image₂_distrib <| map_sup f
lemma map_sups (f : F) (hf) (s t : Finset α) :
map ⟨f, hf⟩ (s ⊻ t) = map ⟨f, hf⟩ s ⊻ map ⟨f, hf⟩ t := by
simpa [map_eq_image] using image_sups f s t
lemma subset_sups_self : s ⊆ s ⊻ s := fun _a ha ↦ mem_sups.2 ⟨_, ha, _, ha, sup_idem _⟩
lemma sups_subset_self : s ⊻ s ⊆ s ↔ SupClosed (s : Set α) := sups_subset_iff
@[simp] lemma sups_eq_self : s ⊻ s = s ↔ SupClosed (s : Set α) := by simp [← coe_inj]
@[simp] lemma univ_sups_univ [Fintype α] : (univ : Finset α) ⊻ univ = univ := by simp
lemma filter_sups_le [DecidableLE α] (s t : Finset α) (a : α) :
{b ∈ s ⊻ t | b ≤ a} = {b ∈ s | b ≤ a} ⊻ {b ∈ t | b ≤ a} := by
simp only [← coe_inj, coe_filter, coe_sups, ← mem_coe, Set.sep_sups_le]
variable (s t u)
lemma biUnion_image_sup_left : s.biUnion (fun a ↦ t.image (a ⊔ ·)) = s ⊻ t := biUnion_image_left
lemma biUnion_image_sup_right : t.biUnion (fun b ↦ s.image (· ⊔ b)) = s ⊻ t := biUnion_image_right
theorem image_sup_product (s t : Finset α) : (s ×ˢ t).image (uncurry (· ⊔ ·)) = s ⊻ t :=
image_uncurry_product _ _ _
theorem sups_assoc : s ⊻ t ⊻ u = s ⊻ (t ⊻ u) := image₂_assoc sup_assoc
theorem sups_comm : s ⊻ t = t ⊻ s := image₂_comm sup_comm
theorem sups_left_comm : s ⊻ (t ⊻ u) = t ⊻ (s ⊻ u) :=
image₂_left_comm sup_left_comm
theorem sups_right_comm : s ⊻ t ⊻ u = s ⊻ u ⊻ t :=
image₂_right_comm sup_right_comm
theorem sups_sups_sups_comm : s ⊻ t ⊻ (u ⊻ v) = s ⊻ u ⊻ (t ⊻ v) :=
image₂_image₂_image₂_comm sup_sup_sup_comm
end Sups
section Infs
variable [DecidableEq α] [DecidableEq β]
variable [SemilatticeInf α] [SemilatticeInf β] [FunLike F α β] [InfHomClass F α β]
variable (s s₁ s₂ t t₁ t₂ u v : Finset α)
/-- `s ⊼ t` is the finset of elements of the form `a ⊓ b` where `a ∈ s`, `b ∈ t`. -/
protected def hasInfs : HasInfs (Finset α) :=
⟨image₂ (· ⊓ ·)⟩
scoped[FinsetFamily] attribute [instance] Finset.hasInfs
open FinsetFamily
variable {s t} {a b c : α}
@[simp]
theorem mem_infs : c ∈ s ⊼ t ↔ ∃ a ∈ s, ∃ b ∈ t, a ⊓ b = c := by simp [(· ⊼ ·)]
variable (s t)
@[simp, norm_cast]
theorem coe_infs : (↑(s ⊼ t) : Set α) = ↑s ⊼ ↑t :=
coe_image₂ _ _ _
theorem card_infs_le : #(s ⊼ t) ≤ #s * #t := card_image₂_le _ _ _
theorem card_infs_iff : #(s ⊼ t) = #s * #t ↔ (s ×ˢ t : Set (α × α)).InjOn fun x => x.1 ⊓ x.2 :=
card_image₂_iff
variable {s s₁ s₂ t t₁ t₂ u}
theorem inf_mem_infs : a ∈ s → b ∈ t → a ⊓ b ∈ s ⊼ t :=
mem_image₂_of_mem
theorem infs_subset : s₁ ⊆ s₂ → t₁ ⊆ t₂ → s₁ ⊼ t₁ ⊆ s₂ ⊼ t₂ :=
image₂_subset
theorem infs_subset_left : t₁ ⊆ t₂ → s ⊼ t₁ ⊆ s ⊼ t₂ :=
image₂_subset_left
theorem infs_subset_right : s₁ ⊆ s₂ → s₁ ⊼ t ⊆ s₂ ⊼ t :=
image₂_subset_right
lemma image_subset_infs_left : b ∈ t → s.image (· ⊓ b) ⊆ s ⊼ t := image_subset_image₂_left
lemma image_subset_infs_right : a ∈ s → t.image (a ⊓ ·) ⊆ s ⊼ t := image_subset_image₂_right
theorem forall_infs_iff {p : α → Prop} : (∀ c ∈ s ⊼ t, p c) ↔ ∀ a ∈ s, ∀ b ∈ t, p (a ⊓ b) :=
forall_mem_image₂
@[simp]
theorem infs_subset_iff : s ⊼ t ⊆ u ↔ ∀ a ∈ s, ∀ b ∈ t, a ⊓ b ∈ u :=
image₂_subset_iff
@[simp]
theorem infs_nonempty : (s ⊼ t).Nonempty ↔ s.Nonempty ∧ t.Nonempty :=
image₂_nonempty_iff
@[aesop safe apply (rule_sets := [finsetNonempty])]
protected theorem Nonempty.infs : s.Nonempty → t.Nonempty → (s ⊼ t).Nonempty :=
Nonempty.image₂
theorem Nonempty.of_infs_left : (s ⊼ t).Nonempty → s.Nonempty :=
Nonempty.of_image₂_left
theorem Nonempty.of_infs_right : (s ⊼ t).Nonempty → t.Nonempty :=
Nonempty.of_image₂_right
@[simp]
theorem empty_infs : ∅ ⊼ t = ∅ :=
image₂_empty_left
@[simp]
theorem infs_empty : s ⊼ ∅ = ∅ :=
image₂_empty_right
@[simp]
theorem infs_eq_empty : s ⊼ t = ∅ ↔ s = ∅ ∨ t = ∅ :=
image₂_eq_empty_iff
@[simp] lemma singleton_infs : {a} ⊼ t = t.image (a ⊓ ·) := image₂_singleton_left
@[simp] lemma infs_singleton : s ⊼ {b} = s.image (· ⊓ b) := image₂_singleton_right
theorem singleton_infs_singleton : ({a} ⊼ {b} : Finset α) = {a ⊓ b} :=
image₂_singleton
theorem infs_union_left : (s₁ ∪ s₂) ⊼ t = s₁ ⊼ t ∪ s₂ ⊼ t :=
image₂_union_left
theorem infs_union_right : s ⊼ (t₁ ∪ t₂) = s ⊼ t₁ ∪ s ⊼ t₂ :=
image₂_union_right
theorem infs_inter_subset_left : (s₁ ∩ s₂) ⊼ t ⊆ s₁ ⊼ t ∩ s₂ ⊼ t :=
image₂_inter_subset_left
theorem infs_inter_subset_right : s ⊼ (t₁ ∩ t₂) ⊆ s ⊼ t₁ ∩ s ⊼ t₂ :=
image₂_inter_subset_right
theorem subset_infs {s t : Set α} :
↑u ⊆ s ⊼ t → ∃ s' t' : Finset α, ↑s' ⊆ s ∧ ↑t' ⊆ t ∧ u ⊆ s' ⊼ t' :=
subset_set_image₂
lemma image_infs (f : F) (s t : Finset α) : image f (s ⊼ t) = image f s ⊼ image f t :=
image_image₂_distrib <| map_inf f
lemma map_infs (f : F) (hf) (s t : Finset α) :
map ⟨f, hf⟩ (s ⊼ t) = map ⟨f, hf⟩ s ⊼ map ⟨f, hf⟩ t := by
simpa [map_eq_image] using image_infs f s t
lemma subset_infs_self : s ⊆ s ⊼ s := fun _a ha ↦ mem_infs.2 ⟨_, ha, _, ha, inf_idem _⟩
lemma infs_self_subset : s ⊼ s ⊆ s ↔ InfClosed (s : Set α) := infs_subset_iff
@[simp] lemma infs_self : s ⊼ s = s ↔ InfClosed (s : Set α) := by simp [← coe_inj]
@[simp] lemma univ_infs_univ [Fintype α] : (univ : Finset α) ⊼ univ = univ := by simp
lemma filter_infs_le [DecidableLE α] (s t : Finset α) (a : α) :
{b ∈ s ⊼ t | a ≤ b} = {b ∈ s | a ≤ b} ⊼ {b ∈ t | a ≤ b} := by
simp only [← coe_inj, coe_filter, coe_infs, ← mem_coe, Set.sep_infs_le]
variable (s t u)
lemma biUnion_image_inf_left : s.biUnion (fun a ↦ t.image (a ⊓ ·)) = s ⊼ t := biUnion_image_left
lemma biUnion_image_inf_right : t.biUnion (fun b ↦ s.image (· ⊓ b)) = s ⊼ t := biUnion_image_right
theorem image_inf_product (s t : Finset α) : (s ×ˢ t).image (uncurry (· ⊓ ·)) = s ⊼ t :=
image_uncurry_product _ _ _
theorem infs_assoc : s ⊼ t ⊼ u = s ⊼ (t ⊼ u) := image₂_assoc inf_assoc
theorem infs_comm : s ⊼ t = t ⊼ s := image₂_comm inf_comm
theorem infs_left_comm : s ⊼ (t ⊼ u) = t ⊼ (s ⊼ u) :=
image₂_left_comm inf_left_comm
theorem infs_right_comm : s ⊼ t ⊼ u = s ⊼ u ⊼ t :=
image₂_right_comm inf_right_comm
theorem infs_infs_infs_comm : s ⊼ t ⊼ (u ⊼ v) = s ⊼ u ⊼ (t ⊼ v) :=
image₂_image₂_image₂_comm inf_inf_inf_comm
end Infs
open FinsetFamily
section DistribLattice
variable [DecidableEq α]
variable [DistribLattice α] (s t u : Finset α)
theorem sups_infs_subset_left : s ⊻ t ⊼ u ⊆ (s ⊻ t) ⊼ (s ⊻ u) :=
image₂_distrib_subset_left sup_inf_left
theorem sups_infs_subset_right : t ⊼ u ⊻ s ⊆ (t ⊻ s) ⊼ (u ⊻ s) :=
image₂_distrib_subset_right sup_inf_right
theorem infs_sups_subset_left : s ⊼ (t ⊻ u) ⊆ s ⊼ t ⊻ s ⊼ u :=
image₂_distrib_subset_left inf_sup_left
theorem infs_sups_subset_right : (t ⊻ u) ⊼ s ⊆ t ⊼ s ⊻ u ⊼ s :=
image₂_distrib_subset_right inf_sup_right
end DistribLattice
section Finset
variable [DecidableEq α]
variable {𝒜 ℬ : Finset (Finset α)} {s t : Finset α}
@[simp] lemma powerset_union (s t : Finset α) : (s ∪ t).powerset = s.powerset ⊻ t.powerset := by
ext u
simp only [mem_sups, mem_powerset, le_eq_subset, sup_eq_union]
refine ⟨fun h ↦ ⟨_, inter_subset_left (s₂ := u), _, inter_subset_left (s₂ := u), ?_⟩, ?_⟩
· rwa [← union_inter_distrib_right, inter_eq_right]
· rintro ⟨v, hv, w, hw, rfl⟩
exact union_subset_union hv hw
@[simp] lemma powerset_inter (s t : Finset α) : (s ∩ t).powerset = s.powerset ⊼ t.powerset := by
ext u
simp only [mem_infs, mem_powerset, le_eq_subset, inf_eq_inter]
refine ⟨fun h ↦ ⟨_, inter_subset_left (s₂ := u), _, inter_subset_left (s₂ := u), ?_⟩, ?_⟩
· rwa [← inter_inter_distrib_right, inter_eq_right]
· rintro ⟨v, hv, w, hw, rfl⟩
exact inter_subset_inter hv hw
@[simp] lemma powerset_sups_powerset_self (s : Finset α) :
s.powerset ⊻ s.powerset = s.powerset := by simp [← powerset_union]
@[simp] lemma powerset_infs_powerset_self (s : Finset α) :
s.powerset ⊼ s.powerset = s.powerset := by simp [← powerset_inter]
lemma union_mem_sups : s ∈ 𝒜 → t ∈ ℬ → s ∪ t ∈ 𝒜 ⊻ ℬ := sup_mem_sups
lemma inter_mem_infs : s ∈ 𝒜 → t ∈ ℬ → s ∩ t ∈ 𝒜 ⊼ ℬ := inf_mem_infs
end Finset
section DisjSups
variable [DecidableEq α]
variable [SemilatticeSup α] [OrderBot α] [DecidableRel (α := α) Disjoint]
(s s₁ s₂ t t₁ t₂ u : Finset α)
/-- The finset of elements of the form `a ⊔ b` where `a ∈ s`, `b ∈ t` and `a` and `b` are disjoint.
-/
def disjSups : Finset α := {ab ∈ s ×ˢ t | Disjoint ab.1 ab.2}.image fun ab => ab.1 ⊔ ab.2
@[inherit_doc]
scoped[FinsetFamily] infixl:74 " ○ " => Finset.disjSups
open FinsetFamily
variable {s t u} {a b c : α}
@[simp]
theorem mem_disjSups : c ∈ s ○ t ↔ ∃ a ∈ s, ∃ b ∈ t, Disjoint a b ∧ a ⊔ b = c := by
simp [disjSups, and_assoc]
theorem disjSups_subset_sups : s ○ t ⊆ s ⊻ t := by
simp_rw [subset_iff, mem_sups, mem_disjSups]
exact fun c ⟨a, b, ha, hb, _, hc⟩ => ⟨a, b, ha, hb, hc⟩
variable (s t)
theorem card_disjSups_le : #(s ○ t) ≤ #s * #t :=
(card_le_card disjSups_subset_sups).trans <| card_sups_le _ _
variable {s s₁ s₂ t t₁ t₂}
theorem disjSups_subset (hs : s₁ ⊆ s₂) (ht : t₁ ⊆ t₂) : s₁ ○ t₁ ⊆ s₂ ○ t₂ :=
image_subset_image <| filter_subset_filter _ <| product_subset_product hs ht
theorem disjSups_subset_left (ht : t₁ ⊆ t₂) : s ○ t₁ ⊆ s ○ t₂ :=
disjSups_subset Subset.rfl ht
theorem disjSups_subset_right (hs : s₁ ⊆ s₂) : s₁ ○ t ⊆ s₂ ○ t :=
disjSups_subset hs Subset.rfl
theorem forall_disjSups_iff {p : α → Prop} :
(∀ c ∈ s ○ t, p c) ↔ ∀ a ∈ s, ∀ b ∈ t, Disjoint a b → p (a ⊔ b) := by
simp_rw [mem_disjSups]
refine ⟨fun h a ha b hb hab => h _ ⟨_, ha, _, hb, hab, rfl⟩, ?_⟩
rintro h _ ⟨a, ha, b, hb, hab, rfl⟩
exact h _ ha _ hb hab
@[simp]
theorem disjSups_subset_iff : s ○ t ⊆ u ↔ ∀ a ∈ s, ∀ b ∈ t, Disjoint a b → a ⊔ b ∈ u :=
forall_disjSups_iff
theorem Nonempty.of_disjSups_left : (s ○ t).Nonempty → s.Nonempty := by
simp_rw [Finset.Nonempty, mem_disjSups]
exact fun ⟨_, a, ha, _⟩ => ⟨a, ha⟩
theorem Nonempty.of_disjSups_right : (s ○ t).Nonempty → t.Nonempty := by
simp_rw [Finset.Nonempty, mem_disjSups]
exact fun ⟨_, _, _, b, hb, _⟩ => ⟨b, hb⟩
@[simp]
theorem disjSups_empty_left : ∅ ○ t = ∅ := by simp [disjSups]
@[simp]
theorem disjSups_empty_right : s ○ ∅ = ∅ := by simp [disjSups]
theorem disjSups_singleton : ({a} ○ {b} : Finset α) = if Disjoint a b then {a ⊔ b} else ∅ := by
split_ifs with h <;> simp [disjSups, filter_singleton, h]
theorem disjSups_union_left : (s₁ ∪ s₂) ○ t = s₁ ○ t ∪ s₂ ○ t := by
simp [disjSups, filter_union, image_union]
theorem disjSups_union_right : s ○ (t₁ ∪ t₂) = s ○ t₁ ∪ s ○ t₂ := by
simp [disjSups, filter_union, image_union]
theorem disjSups_inter_subset_left : (s₁ ∩ s₂) ○ t ⊆ s₁ ○ t ∩ s₂ ○ t := by
simpa only [disjSups, inter_product, filter_inter_distrib] using image_inter_subset _ _ _
theorem disjSups_inter_subset_right : s ○ (t₁ ∩ t₂) ⊆ s ○ t₁ ∩ s ○ t₂ := by
simpa only [disjSups, product_inter, filter_inter_distrib] using image_inter_subset _ _ _
variable (s t)
theorem disjSups_comm : s ○ t = t ○ s := by
aesop (add simp disjoint_comm, simp sup_comm)
instance : @Std.Commutative (Finset α) (· ○ ·) := ⟨disjSups_comm⟩
end DisjSups
open FinsetFamily
section DistribLattice
variable [DecidableEq α]
variable [DistribLattice α] [OrderBot α] [DecidableRel (α := α) Disjoint] (s t u v : Finset α)
theorem disjSups_assoc : ∀ s t u : Finset α, s ○ t ○ u = s ○ (t ○ u) := by
refine (associative_of_commutative_of_le inferInstance ?_).assoc
simp only [le_eq_subset, disjSups_subset_iff, mem_disjSups]
rintro s t u _ ⟨a, ha, b, hb, hab, rfl⟩ c hc habc
rw [disjoint_sup_left] at habc
exact ⟨a, ha, _, ⟨b, hb, c, hc, habc.2, rfl⟩, hab.sup_right habc.1, (sup_assoc ..).symm⟩
instance : @Std.Associative (Finset α) (· ○ ·) := ⟨disjSups_assoc⟩
theorem disjSups_left_comm : s ○ (t ○ u) = t ○ (s ○ u) := by
simp_rw [← disjSups_assoc, disjSups_comm s]
theorem disjSups_right_comm : s ○ t ○ u = s ○ u ○ t := by simp_rw [disjSups_assoc, disjSups_comm]
theorem disjSups_disjSups_disjSups_comm : s ○ t ○ (u ○ v) = s ○ u ○ (t ○ v) := by
simp_rw [← disjSups_assoc, disjSups_right_comm]
end DistribLattice
section Diffs
variable [DecidableEq α]
variable [GeneralizedBooleanAlgebra α] (s s₁ s₂ t t₁ t₂ u : Finset α)
/-- `s \\ t` is the finset of elements of the form `a \ b` where `a ∈ s`, `b ∈ t`. -/
def diffs : Finset α → Finset α → Finset α := image₂ (· \ ·)
@[inherit_doc]
scoped[FinsetFamily] infixl:74 " \\\\ " => Finset.diffs
-- This notation is meant to have higher precedence than `\` and `⊓`, but still within the
-- realm of other binary notation
open FinsetFamily
variable {s t} {a b c : α}
@[simp] lemma mem_diffs : c ∈ s \\ t ↔ ∃ a ∈ s, ∃ b ∈ t, a \ b = c := by simp [(· \\ ·)]
variable (s t)
@[simp, norm_cast] lemma coe_diffs : (↑(s \\ t) : Set α) = Set.image2 (· \ ·) s t :=
coe_image₂ _ _ _
lemma card_diffs_le : #(s \\ t) ≤ #s * #t := card_image₂_le _ _ _
lemma card_diffs_iff : #(s \\ t) = #s * #t ↔ (s ×ˢ t : Set (α × α)).InjOn fun x ↦ x.1 \ x.2 :=
card_image₂_iff
variable {s s₁ s₂ t t₁ t₂ u}
lemma sdiff_mem_diffs : a ∈ s → b ∈ t → a \ b ∈ s \\ t := mem_image₂_of_mem
lemma diffs_subset : s₁ ⊆ s₂ → t₁ ⊆ t₂ → s₁ \\ t₁ ⊆ s₂ \\ t₂ := image₂_subset
lemma diffs_subset_left : t₁ ⊆ t₂ → s \\ t₁ ⊆ s \\ t₂ := image₂_subset_left
lemma diffs_subset_right : s₁ ⊆ s₂ → s₁ \\ t ⊆ s₂ \\ t := image₂_subset_right
lemma image_subset_diffs_left : b ∈ t → s.image (· \ b) ⊆ s \\ t := image_subset_image₂_left
lemma image_subset_diffs_right : a ∈ s → t.image (a \ ·) ⊆ s \\ t := image_subset_image₂_right
lemma forall_mem_diffs {p : α → Prop} : (∀ c ∈ s \\ t, p c) ↔ ∀ a ∈ s, ∀ b ∈ t, p (a \ b) :=
forall_mem_image₂
@[simp] lemma diffs_subset_iff : s \\ t ⊆ u ↔ ∀ a ∈ s, ∀ b ∈ t, a \ b ∈ u := image₂_subset_iff
@[simp]
lemma diffs_nonempty : (s \\ t).Nonempty ↔ s.Nonempty ∧ t.Nonempty := image₂_nonempty_iff
@[aesop safe apply (rule_sets := [finsetNonempty])]
protected lemma Nonempty.diffs : s.Nonempty → t.Nonempty → (s \\ t).Nonempty := Nonempty.image₂
lemma Nonempty.of_diffs_left : (s \\ t).Nonempty → s.Nonempty := Nonempty.of_image₂_left
lemma Nonempty.of_diffs_right : (s \\ t).Nonempty → t.Nonempty := Nonempty.of_image₂_right
@[simp] lemma empty_diffs : ∅ \\ t = ∅ := image₂_empty_left
@[simp] lemma diffs_empty : s \\ ∅ = ∅ := image₂_empty_right
@[simp] lemma diffs_eq_empty : s \\ t = ∅ ↔ s = ∅ ∨ t = ∅ := image₂_eq_empty_iff
@[simp] lemma singleton_diffs : {a} \\ t = t.image (a \ ·) := image₂_singleton_left
@[simp] lemma diffs_singleton : s \\ {b} = s.image (· \ b) := image₂_singleton_right
lemma singleton_diffs_singleton : ({a} \\ {b} : Finset α) = {a \ b} := image₂_singleton
lemma diffs_union_left : (s₁ ∪ s₂) \\ t = s₁ \\ t ∪ s₂ \\ t := image₂_union_left
lemma diffs_union_right : s \\ (t₁ ∪ t₂) = s \\ t₁ ∪ s \\ t₂ := image₂_union_right
lemma diffs_inter_subset_left : (s₁ ∩ s₂) \\ t ⊆ s₁ \\ t ∩ s₂ \\ t := image₂_inter_subset_left
lemma diffs_inter_subset_right : s \\ (t₁ ∩ t₂) ⊆ s \\ t₁ ∩ s \\ t₂ := image₂_inter_subset_right
lemma subset_diffs {s t : Set α} :
↑u ⊆ Set.image2 (· \ ·) s t → ∃ s' t' : Finset α, ↑s' ⊆ s ∧ ↑t' ⊆ t ∧ u ⊆ s' \\ t' :=
subset_set_image₂
variable (s t u)
lemma biUnion_image_sdiff_left : s.biUnion (fun a ↦ t.image (a \ ·)) = s \\ t := biUnion_image_left
lemma biUnion_image_sdiff_right : t.biUnion (fun b ↦ s.image (· \ b)) = s \\ t :=
biUnion_image_right
lemma image_sdiff_product (s t : Finset α) : (s ×ˢ t).image (uncurry (· \ ·)) = s \\ t :=
image_uncurry_product _ _ _
lemma diffs_right_comm : s \\ t \\ u = s \\ u \\ t := image₂_right_comm sdiff_right_comm
end Diffs
section Compls
variable [BooleanAlgebra α] (s s₁ s₂ t : Finset α)
/-- `sᶜˢ` is the finset of elements of the form `aᶜ` where `a ∈ s`. -/
| def compls : Finset α → Finset α := map ⟨compl, compl_injective⟩
@[inherit_doc]
scoped[FinsetFamily] postfix:max "ᶜˢ" => Finset.compls
open FinsetFamily
| Mathlib/Data/Finset/Sups.lean | 590 | 595 |
/-
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.Nat.ModEq
import Mathlib.Data.Nat.Prime.Basic
import Mathlib.NumberTheory.Zsqrtd.Basic
/-!
# Pell's equation and Matiyasevic's theorem
This file solves Pell's equation, i.e. integer solutions to `x ^ 2 - d * y ^ 2 = 1`
*in the special case that `d = a ^ 2 - 1`*.
This is then applied to prove Matiyasevic's theorem that the power
function is Diophantine, which is the last key ingredient in the solution to Hilbert's tenth
problem. For the definition of Diophantine function, see `NumberTheory.Dioph`.
For results on Pell's equation for arbitrary (positive, non-square) `d`, see
`NumberTheory.Pell`.
## Main definition
* `pell` is a function assigning to a natural number `n` the `n`-th solution to Pell's equation
constructed recursively from the initial solution `(0, 1)`.
## Main statements
* `eq_pell` shows that every solution to Pell's equation is recursively obtained using `pell`
* `matiyasevic` shows that a certain system of Diophantine equations has a solution if and only if
the first variable is the `x`-component in a solution to Pell's equation - the key step towards
Hilbert's tenth problem in Davis' version of Matiyasevic's theorem.
* `eq_pow_of_pell` shows that the power function is Diophantine.
## Implementation notes
The proof of Matiyasevic's theorem doesn't follow Matiyasevic's original account of using Fibonacci
numbers but instead Davis' variant of using solutions to Pell's equation.
## References
* [M. Carneiro, _A Lean formalization of Matiyasevič's theorem_][carneiro2018matiyasevic]
* [M. Davis, _Hilbert's tenth problem is unsolvable_][MR317916]
## Tags
Pell's equation, Matiyasevic's theorem, Hilbert's tenth problem
-/
namespace Pell
open Nat
section
variable {d : ℤ}
/-- The property of being a solution to the Pell equation, expressed
as a property of elements of `ℤ√d`. -/
def IsPell : ℤ√d → Prop
| ⟨x, y⟩ => x * x - d * y * y = 1
theorem isPell_norm : ∀ {b : ℤ√d}, IsPell b ↔ b * star b = 1
| ⟨x, y⟩ => by simp [Zsqrtd.ext_iff, IsPell, mul_comm]; ring_nf
theorem isPell_iff_mem_unitary : ∀ {b : ℤ√d}, IsPell b ↔ b ∈ unitary (ℤ√d)
| ⟨x, y⟩ => by rw [unitary.mem_iff, isPell_norm, mul_comm (star _), and_self_iff]
theorem isPell_mul {b c : ℤ√d} (hb : IsPell b) (hc : IsPell c) : IsPell (b * c) :=
isPell_norm.2 (by simp [mul_comm, mul_left_comm c, mul_assoc,
star_mul, isPell_norm.1 hb, isPell_norm.1 hc])
theorem isPell_star : ∀ {b : ℤ√d}, IsPell b ↔ IsPell (star b)
| ⟨x, y⟩ => by simp [IsPell, Zsqrtd.star_mk]
end
section
variable {a : ℕ} (a1 : 1 < a)
private def d (_a1 : 1 < a) :=
a * a - 1
@[simp]
theorem d_pos : 0 < d a1 :=
tsub_pos_of_lt (mul_lt_mul a1 (le_of_lt a1) (by decide) (Nat.zero_le _) : 1 * 1 < a * a)
-- TODO(lint): Fix double namespace issue
/-- The Pell sequences, i.e. the sequence of integer solutions to `x ^ 2 - d * y ^ 2 = 1`, where
`d = a ^ 2 - 1`, defined together in mutual recursion. -/
--@[nolint dup_namespace]
def pell : ℕ → ℕ × ℕ
| 0 => (1, 0)
| n+1 => ((pell n).1 * a + d a1 * (pell n).2, (pell n).1 + (pell n).2 * a)
/-- The Pell `x` sequence. -/
def xn (n : ℕ) : ℕ :=
(pell a1 n).1
/-- The Pell `y` sequence. -/
def yn (n : ℕ) : ℕ :=
(pell a1 n).2
@[simp]
theorem pell_val (n : ℕ) : pell a1 n = (xn a1 n, yn a1 n) :=
show pell a1 n = ((pell a1 n).1, (pell a1 n).2) from
match pell a1 n with
| (_, _) => rfl
@[simp]
theorem xn_zero : xn a1 0 = 1 :=
rfl
@[simp]
theorem yn_zero : yn a1 0 = 0 :=
rfl
@[simp]
theorem xn_succ (n : ℕ) : xn a1 (n + 1) = xn a1 n * a + d a1 * yn a1 n :=
rfl
@[simp]
theorem yn_succ (n : ℕ) : yn a1 (n + 1) = xn a1 n + yn a1 n * a :=
rfl
theorem xn_one : xn a1 1 = a := by simp
theorem yn_one : yn a1 1 = 1 := by simp
/-- The Pell `x` sequence, considered as an integer sequence. -/
def xz (n : ℕ) : ℤ :=
xn a1 n
/-- The Pell `y` sequence, considered as an integer sequence. -/
def yz (n : ℕ) : ℤ :=
yn a1 n
section
/-- The element `a` such that `d = a ^ 2 - 1`, considered as an integer. -/
def az (a : ℕ) : ℤ :=
a
end
include a1 in
theorem asq_pos : 0 < a * a :=
le_trans (le_of_lt a1)
(by have := @Nat.mul_le_mul_left 1 a a (le_of_lt a1); rwa [mul_one] at this)
theorem dz_val : ↑(d a1) = az a * az a - 1 :=
have : 1 ≤ a * a := asq_pos a1
by rw [Pell.d, Int.ofNat_sub this]; rfl
@[simp]
theorem xz_succ (n : ℕ) : (xz a1 (n + 1)) = xz a1 n * az a + d a1 * yz a1 n :=
rfl
@[simp]
theorem yz_succ (n : ℕ) : yz a1 (n + 1) = xz a1 n + yz a1 n * az a :=
rfl
/-- The Pell sequence can also be viewed as an element of `ℤ√d` -/
def pellZd (n : ℕ) : ℤ√(d a1) :=
⟨xn a1 n, yn a1 n⟩
@[simp]
theorem pellZd_re (n : ℕ) : (pellZd a1 n).re = xn a1 n :=
rfl
@[simp]
theorem pellZd_im (n : ℕ) : (pellZd a1 n).im = yn a1 n :=
rfl
theorem isPell_nat {x y : ℕ} : IsPell (⟨x, y⟩ : ℤ√(d a1)) ↔ x * x - d a1 * y * y = 1 :=
⟨fun h =>
(Nat.cast_inj (R := ℤ)).1
(by rw [Int.ofNat_sub (Int.le_of_ofNat_le_ofNat <| Int.le.intro_sub _ h)]; exact h),
fun h =>
show ((x * x : ℕ) - (d a1 * y * y : ℕ) : ℤ) = 1 by
rw [← Int.ofNat_sub <| le_of_lt <| Nat.lt_of_sub_eq_succ h, h]; rfl⟩
@[simp]
theorem pellZd_succ (n : ℕ) : pellZd a1 (n + 1) = pellZd a1 n * ⟨a, 1⟩ := by ext <;> simp
theorem isPell_one : IsPell (⟨a, 1⟩ : ℤ√(d a1)) :=
show az a * az a - d a1 * 1 * 1 = 1 by simp [dz_val]
theorem isPell_pellZd : ∀ n : ℕ, IsPell (pellZd a1 n)
| 0 => rfl
| n + 1 => by
let o := isPell_one a1
simpa using Pell.isPell_mul (isPell_pellZd n) o
@[simp]
theorem pell_eqz (n : ℕ) : xz a1 n * xz a1 n - d a1 * yz a1 n * yz a1 n = 1 :=
isPell_pellZd a1 n
@[simp]
theorem pell_eq (n : ℕ) : xn a1 n * xn a1 n - d a1 * yn a1 n * yn a1 n = 1 :=
let pn := pell_eqz a1 n
have h : (↑(xn a1 n * xn a1 n) : ℤ) - ↑(d a1 * yn a1 n * yn a1 n) = 1 := by
repeat' rw [Int.natCast_mul]; exact pn
have hl : d a1 * yn a1 n * yn a1 n ≤ xn a1 n * xn a1 n :=
Nat.cast_le.1 <| Int.le.intro _ <| add_eq_of_eq_sub' <| Eq.symm h
(Nat.cast_inj (R := ℤ)).1 (by rw [Int.ofNat_sub hl]; exact h)
instance dnsq : Zsqrtd.Nonsquare (d a1) :=
⟨fun n h =>
have : n * n + 1 = a * a := by rw [← h]; exact Nat.succ_pred_eq_of_pos (asq_pos a1)
have na : n < a := Nat.mul_self_lt_mul_self_iff.1 (by rw [← this]; exact Nat.lt_succ_self _)
have : (n + 1) * (n + 1) ≤ n * n + 1 := by rw [this]; exact Nat.mul_self_le_mul_self na
have : n + n ≤ 0 :=
@Nat.le_of_add_le_add_right _ (n * n + 1) _ (by ring_nf at this ⊢; assumption)
Nat.ne_of_gt (d_pos a1) <| by
rwa [Nat.eq_zero_of_le_zero ((Nat.le_add_left _ _).trans this)] at h⟩
theorem xn_ge_a_pow : ∀ n : ℕ, a ^ n ≤ xn a1 n
| 0 => le_refl 1
| n + 1 => by
simp only [_root_.pow_succ, xn_succ]
exact le_trans (Nat.mul_le_mul_right _ (xn_ge_a_pow n)) (Nat.le_add_right _ _)
theorem n_lt_xn (n) : n < xn a1 n :=
lt_of_lt_of_le (Nat.lt_pow_self a1) (xn_ge_a_pow a1 n)
theorem x_pos (n) : 0 < xn a1 n :=
lt_of_le_of_lt (Nat.zero_le n) (n_lt_xn a1 n)
theorem eq_pell_lem : ∀ (n) (b : ℤ√(d a1)), 1 ≤ b → IsPell b →
b ≤ pellZd a1 n → ∃ n, b = pellZd a1 n
| 0, _ => fun h1 _ hl => ⟨0, @Zsqrtd.le_antisymm _ (dnsq a1) _ _ hl h1⟩
| n + 1, b => fun h1 hp h =>
have a1p : (0 : ℤ√(d a1)) ≤ ⟨a, 1⟩ := trivial
have am1p : (0 : ℤ√(d a1)) ≤ ⟨a, -1⟩ := show (_ : Nat) ≤ _ by simp; exact Nat.pred_le _
have a1m : (⟨a, 1⟩ * ⟨a, -1⟩ : ℤ√(d a1)) = 1 := isPell_norm.1 (isPell_one a1)
if ha : (⟨↑a, 1⟩ : ℤ√(d a1)) ≤ b then
let ⟨m, e⟩ :=
eq_pell_lem n (b * ⟨a, -1⟩) (by rw [← a1m]; exact mul_le_mul_of_nonneg_right ha am1p)
(isPell_mul hp (isPell_star.1 (isPell_one a1)))
(by
have t := mul_le_mul_of_nonneg_right h am1p
rwa [pellZd_succ, mul_assoc, a1m, mul_one] at t)
⟨m + 1, by
rw [show b = b * ⟨a, -1⟩ * ⟨a, 1⟩ by rw [mul_assoc, Eq.trans (mul_comm _ _) a1m]; simp,
pellZd_succ, e]⟩
else
suffices ¬1 < b from ⟨0, show b = 1 from (Or.resolve_left (lt_or_eq_of_le h1) this).symm⟩
fun h1l => by
obtain ⟨x, y⟩ := b
exact by
have bm : (_ * ⟨_, _⟩ : ℤ√d a1) = 1 := Pell.isPell_norm.1 hp
have y0l : (0 : ℤ√d a1) < ⟨x - x, y - -y⟩ :=
sub_lt_sub h1l fun hn : (1 : ℤ√d a1) ≤ ⟨x, -y⟩ => by
have t := mul_le_mul_of_nonneg_left hn (le_trans zero_le_one h1)
rw [bm, mul_one] at t
exact h1l t
have yl2 : (⟨_, _⟩ : ℤ√_) < ⟨_, _⟩ :=
show (⟨x, y⟩ - ⟨x, -y⟩ : ℤ√d a1) < ⟨a, 1⟩ - ⟨a, -1⟩ from
sub_lt_sub ha fun hn : (⟨x, -y⟩ : ℤ√d a1) ≤ ⟨a, -1⟩ => by
have t := mul_le_mul_of_nonneg_right
(mul_le_mul_of_nonneg_left hn (le_trans zero_le_one h1)) a1p
rw [bm, one_mul, mul_assoc, Eq.trans (mul_comm _ _) a1m, mul_one] at t
exact ha t
simp only [sub_self, sub_neg_eq_add] at y0l; simp only [Zsqrtd.neg_re, add_neg_cancel,
Zsqrtd.neg_im, neg_neg] at yl2
exact
match y, y0l, (yl2 : (⟨_, _⟩ : ℤ√_) < ⟨_, _⟩) with
| 0, y0l, _ => y0l (le_refl 0)
| (y + 1 : ℕ), _, yl2 =>
yl2
(Zsqrtd.le_of_le_le (by simp [sub_eq_add_neg])
(let t := Int.ofNat_le_ofNat_of_le (Nat.succ_pos y)
add_le_add t t))
| Int.negSucc _, y0l, _ => y0l trivial
theorem eq_pellZd (b : ℤ√(d a1)) (b1 : 1 ≤ b) (hp : IsPell b) : ∃ n, b = pellZd a1 n :=
let ⟨n, h⟩ := @Zsqrtd.le_arch (d a1) b
eq_pell_lem a1 n b b1 hp <|
h.trans <| by
rw [Zsqrtd.natCast_val]
exact
Zsqrtd.le_of_le_le (Int.ofNat_le_ofNat_of_le <| le_of_lt <| n_lt_xn _ _)
(Int.ofNat_zero_le _)
/-- Every solution to **Pell's equation** is recursively obtained from the initial solution
`(1,0)` using the recursion `pell`. -/
theorem eq_pell {x y : ℕ} (hp : x * x - d a1 * y * y = 1) : ∃ n, x = xn a1 n ∧ y = yn a1 n :=
have : (1 : ℤ√(d a1)) ≤ ⟨x, y⟩ :=
match x, hp with
| 0, (hp : 0 - _ = 1) => by rw [zero_tsub] at hp; contradiction
| x + 1, _hp =>
Zsqrtd.le_of_le_le (Int.ofNat_le_ofNat_of_le <| Nat.succ_pos x) (Int.ofNat_zero_le _)
let ⟨m, e⟩ := eq_pellZd a1 ⟨x, y⟩ this ((isPell_nat a1).2 hp)
⟨m,
match x, y, e with
| _, _, rfl => ⟨rfl, rfl⟩⟩
theorem pellZd_add (m) : ∀ n, pellZd a1 (m + n) = pellZd a1 m * pellZd a1 n
| 0 => (mul_one _).symm
| n + 1 => by rw [← add_assoc, pellZd_succ, pellZd_succ, pellZd_add _ n, ← mul_assoc]
theorem xn_add (m n) : xn a1 (m + n) = xn a1 m * xn a1 n + d a1 * yn a1 m * yn a1 n := by
injection pellZd_add a1 m n with h _
zify
rw [h]
simp [pellZd]
theorem yn_add (m n) : yn a1 (m + n) = xn a1 m * yn a1 n + yn a1 m * xn a1 n := by
injection pellZd_add a1 m n with _ h
zify
rw [h]
simp [pellZd]
theorem pellZd_sub {m n} (h : n ≤ m) : pellZd a1 (m - n) = pellZd a1 m * star (pellZd a1 n) := by
let t := pellZd_add a1 n (m - n)
rw [add_tsub_cancel_of_le h] at t
rw [t, mul_comm (pellZd _ n) _, mul_assoc, isPell_norm.1 (isPell_pellZd _ _), mul_one]
theorem xz_sub {m n} (h : n ≤ m) :
xz a1 (m - n) = xz a1 m * xz a1 n - d a1 * yz a1 m * yz a1 n := by
rw [sub_eq_add_neg, ← mul_neg]
exact congr_arg Zsqrtd.re (pellZd_sub a1 h)
theorem yz_sub {m n} (h : n ≤ m) : yz a1 (m - n) = xz a1 n * yz a1 m - xz a1 m * yz a1 n := by
rw [sub_eq_add_neg, ← mul_neg, mul_comm, add_comm]
exact congr_arg Zsqrtd.im (pellZd_sub a1 h)
theorem xy_coprime (n) : (xn a1 n).Coprime (yn a1 n) :=
Nat.coprime_of_dvd' fun k _ kx ky => by
let p := pell_eq a1 n
rw [← p]
exact Nat.dvd_sub (kx.mul_left _) (ky.mul_left _)
theorem strictMono_y : StrictMono (yn a1)
| _, 0, h => absurd h <| Nat.not_lt_zero _
| m, n + 1, h => by
have : yn a1 m ≤ yn a1 n :=
Or.elim (lt_or_eq_of_le <| Nat.le_of_succ_le_succ h) (fun hl => le_of_lt <| strictMono_y hl)
fun e => by rw [e]
simp only [yn_succ, gt_iff_lt]; refine lt_of_le_of_lt ?_ (Nat.lt_add_of_pos_left <| x_pos a1 n)
rw [← mul_one (yn a1 m)]
exact mul_le_mul this (le_of_lt a1) (Nat.zero_le _) (Nat.zero_le _)
theorem strictMono_x : StrictMono (xn a1)
| _, 0, h => absurd h <| Nat.not_lt_zero _
| m, n + 1, h => by
have : xn a1 m ≤ xn a1 n :=
Or.elim (lt_or_eq_of_le <| Nat.le_of_succ_le_succ h) (fun hl => le_of_lt <| strictMono_x hl)
fun e => by rw [e]
simp only [xn_succ, gt_iff_lt]
refine lt_of_lt_of_le (lt_of_le_of_lt this ?_) (Nat.le_add_right _ _)
have t := Nat.mul_lt_mul_of_pos_left a1 (x_pos a1 n)
rwa [mul_one] at t
theorem yn_ge_n : ∀ n, n ≤ yn a1 n
| 0 => Nat.zero_le _
| n + 1 =>
show n < yn a1 (n + 1) from lt_of_le_of_lt (yn_ge_n n) (strictMono_y a1 <| Nat.lt_succ_self n)
theorem y_mul_dvd (n) : ∀ k, yn a1 n ∣ yn a1 (n * k)
| 0 => dvd_zero _
| k + 1 => by
rw [Nat.mul_succ, yn_add]; exact dvd_add (dvd_mul_left _ _) ((y_mul_dvd _ k).mul_right _)
theorem y_dvd_iff (m n) : yn a1 m ∣ yn a1 n ↔ m ∣ n :=
⟨fun h =>
Nat.dvd_of_mod_eq_zero <|
(Nat.eq_zero_or_pos _).resolve_right fun hp => by
have co : Nat.Coprime (yn a1 m) (xn a1 (m * (n / m))) :=
Nat.Coprime.symm <| (xy_coprime a1 _).coprime_dvd_right (y_mul_dvd a1 m (n / m))
have m0 : 0 < m :=
m.eq_zero_or_pos.resolve_left fun e => by
rw [e, Nat.mod_zero] at hp;rw [e] at h
exact _root_.ne_of_lt (strictMono_y a1 hp) (eq_zero_of_zero_dvd h).symm
rw [← Nat.mod_add_div n m, yn_add] at h
exact
not_le_of_gt (strictMono_y _ <| Nat.mod_lt n m0)
(Nat.le_of_dvd (strictMono_y _ hp) <|
co.dvd_of_dvd_mul_right <|
(Nat.dvd_add_iff_right <| (y_mul_dvd _ _ _).mul_left _).2 h),
fun ⟨k, e⟩ => by rw [e]; apply y_mul_dvd⟩
theorem xy_modEq_yn (n) :
∀ k, xn a1 (n * k) ≡ xn a1 n ^ k [MOD yn a1 n ^ 2] ∧ yn a1 (n * k) ≡
k * xn a1 n ^ (k - 1) * yn a1 n [MOD yn a1 n ^ 3]
| 0 => by constructor <;> simpa using Nat.ModEq.refl _
| k + 1 => by
let ⟨hx, hy⟩ := xy_modEq_yn n k
have L : xn a1 (n * k) * xn a1 n + d a1 * yn a1 (n * k) * yn a1 n ≡
xn a1 n ^ k * xn a1 n + 0 [MOD yn a1 n ^ 2] :=
(hx.mul_right _).add <|
modEq_zero_iff_dvd.2 <| by
rw [_root_.pow_succ]
exact
mul_dvd_mul_right
(dvd_mul_of_dvd_right
(modEq_zero_iff_dvd.1 <|
(hy.of_dvd <| by simp [_root_.pow_succ]).trans <|
modEq_zero_iff_dvd.2 <| by simp)
_) _
have R : xn a1 (n * k) * yn a1 n + yn a1 (n * k) * xn a1 n ≡
xn a1 n ^ k * yn a1 n + k * xn a1 n ^ k * yn a1 n [MOD yn a1 n ^ 3] :=
ModEq.add
(by
rw [_root_.pow_succ]
exact hx.mul_right' _) <| by
have : k * xn a1 n ^ (k - 1) * yn a1 n * xn a1 n = k * xn a1 n ^ k * yn a1 n := by
rcases k with - | k <;> simp [_root_.pow_succ]; ring_nf
rw [← this]
exact hy.mul_right _
rw [add_tsub_cancel_right, Nat.mul_succ, xn_add, yn_add, pow_succ (xn _ n), Nat.succ_mul,
add_comm (k * xn _ n ^ k) (xn _ n ^ k), right_distrib]
exact ⟨L, R⟩
theorem ysq_dvd_yy (n) : yn a1 n * yn a1 n ∣ yn a1 (n * yn a1 n) :=
modEq_zero_iff_dvd.1 <|
((xy_modEq_yn a1 n (yn a1 n)).right.of_dvd <| by simp [_root_.pow_succ]).trans
(modEq_zero_iff_dvd.2 <| by simp [mul_dvd_mul_left, mul_assoc])
theorem dvd_of_ysq_dvd {n t} (h : yn a1 n * yn a1 n ∣ yn a1 t) : yn a1 n ∣ t :=
have nt : n ∣ t := (y_dvd_iff a1 n t).1 <| dvd_of_mul_left_dvd h
n.eq_zero_or_pos.elim (fun n0 => by rwa [n0] at nt ⊢) fun n0l : 0 < n => by
let ⟨k, ke⟩ := nt
have : yn a1 n ∣ k * xn a1 n ^ (k - 1) :=
Nat.dvd_of_mul_dvd_mul_right (strictMono_y a1 n0l) <|
modEq_zero_iff_dvd.1 <| by
have xm := (xy_modEq_yn a1 n k).right; rw [← ke] at xm
exact (xm.of_dvd <| by simp [_root_.pow_succ]).symm.trans h.modEq_zero_nat
rw [ke]
exact dvd_mul_of_dvd_right (((xy_coprime _ _).pow_left _).symm.dvd_of_dvd_mul_right this) _
theorem pellZd_succ_succ (n) :
pellZd a1 (n + 2) + pellZd a1 n = (2 * a : ℕ) * pellZd a1 (n + 1) := by
have : (1 : ℤ√(d a1)) + ⟨a, 1⟩ * ⟨a, 1⟩ = ⟨a, 1⟩ * (2 * a) := by
rw [Zsqrtd.natCast_val]
change (⟨_, _⟩ : ℤ√(d a1)) = ⟨_, _⟩
rw [dz_val]
dsimp [az]
ext <;> dsimp <;> ring_nf
simpa [mul_add, mul_comm, mul_left_comm, add_comm] using congr_arg (· * pellZd a1 n) this
theorem xy_succ_succ (n) :
xn a1 (n + 2) + xn a1 n =
2 * a * xn a1 (n + 1) ∧ yn a1 (n + 2) + yn a1 n = 2 * a * yn a1 (n + 1) := by
have := pellZd_succ_succ a1 n; unfold pellZd at this
rw [Zsqrtd.nsmul_val (2 * a : ℕ)] at this
injection this with h₁ h₂
constructor <;> apply Int.ofNat.inj <;> [simpa using h₁; simpa using h₂]
theorem xn_succ_succ (n) : xn a1 (n + 2) + xn a1 n = 2 * a * xn a1 (n + 1) :=
(xy_succ_succ a1 n).1
theorem yn_succ_succ (n) : yn a1 (n + 2) + yn a1 n = 2 * a * yn a1 (n + 1) :=
(xy_succ_succ a1 n).2
theorem xz_succ_succ (n) : xz a1 (n + 2) = (2 * a : ℕ) * xz a1 (n + 1) - xz a1 n :=
eq_sub_of_add_eq <| by delta xz; rw [← Int.natCast_add, ← Int.natCast_mul, xn_succ_succ]
theorem yz_succ_succ (n) : yz a1 (n + 2) = (2 * a : ℕ) * yz a1 (n + 1) - yz a1 n :=
eq_sub_of_add_eq <| by delta yz; rw [← Int.natCast_add, ← Int.natCast_mul, yn_succ_succ]
theorem yn_modEq_a_sub_one : ∀ n, yn a1 n ≡ n [MOD a - 1]
| 0 => by simp [Nat.ModEq.refl]
| 1 => by simp [Nat.ModEq.refl]
| n + 2 =>
(yn_modEq_a_sub_one n).add_right_cancel <| by
rw [yn_succ_succ, (by ring : n + 2 + n = 2 * (n + 1))]
exact ((modEq_sub a1.le).mul_left 2).mul (yn_modEq_a_sub_one (n + 1))
theorem yn_modEq_two : ∀ n, yn a1 n ≡ n [MOD 2]
| 0 => by rfl
| 1 => by simp; rfl
| n + 2 =>
(yn_modEq_two n).add_right_cancel <| by
rw [yn_succ_succ, mul_assoc, (by ring : n + 2 + n = 2 * (n + 1))]
exact (dvd_mul_right 2 _).modEq_zero_nat.trans (dvd_mul_right 2 _).zero_modEq_nat
section
theorem x_sub_y_dvd_pow_lem (y2 y1 y0 yn1 yn0 xn1 xn0 ay a2 : ℤ) :
(a2 * yn1 - yn0) * ay + y2 - (a2 * xn1 - xn0) =
y2 - a2 * y1 + y0 + a2 * (yn1 * ay + y1 - xn1) - (yn0 * ay + y0 - xn0) := by
ring
end
theorem x_sub_y_dvd_pow (y : ℕ) :
∀ n, (2 * a * y - y * y - 1 : ℤ) ∣ yz a1 n * (a - y) + ↑(y ^ n) - xz a1 n
| 0 => by simp [xz, yz, Int.ofNat_zero, Int.ofNat_one]
| 1 => by simp [xz, yz, Int.ofNat_zero, Int.ofNat_one]
| n + 2 => by
have : (2 * a * y - y * y - 1 : ℤ) ∣ ↑(y ^ (n + 2)) - ↑(2 * a) * ↑(y ^ (n + 1)) + ↑(y ^ n) :=
⟨-↑(y ^ n), by
simp [_root_.pow_succ, mul_add, Int.natCast_mul, show ((2 : ℕ) : ℤ) = 2 from rfl, mul_comm,
mul_left_comm]
ring⟩
rw [xz_succ_succ, yz_succ_succ, x_sub_y_dvd_pow_lem ↑(y ^ (n + 2)) ↑(y ^ (n + 1)) ↑(y ^ n)]
exact _root_.dvd_sub (dvd_add this <| (x_sub_y_dvd_pow _ (n + 1)).mul_left _)
(x_sub_y_dvd_pow _ n)
theorem xn_modEq_x2n_add_lem (n j) : xn a1 n ∣ d a1 * yn a1 n * (yn a1 n * xn a1 j) + xn a1 j := by
have h1 : d a1 * yn a1 n * (yn a1 n * xn a1 j) + xn a1 j =
(d a1 * yn a1 n * yn a1 n + 1) * xn a1 j := by
simp [add_mul, mul_assoc]
have h2 : d a1 * yn a1 n * yn a1 n + 1 = xn a1 n * xn a1 n := by
zify at *
apply add_eq_of_eq_sub' (Eq.symm (pell_eqz a1 n))
rw [h2] at h1; rw [h1, mul_assoc]; exact dvd_mul_right _ _
theorem xn_modEq_x2n_add (n j) : xn a1 (2 * n + j) + xn a1 j ≡ 0 [MOD xn a1 n] := by
rw [two_mul, add_assoc, xn_add, add_assoc, ← zero_add 0]
refine (dvd_mul_right (xn a1 n) (xn a1 (n + j))).modEq_zero_nat.add ?_
rw [yn_add, left_distrib, add_assoc, ← zero_add 0]
exact
((dvd_mul_right _ _).mul_left _).modEq_zero_nat.add (xn_modEq_x2n_add_lem _ _ _).modEq_zero_nat
theorem xn_modEq_x2n_sub_lem {n j} (h : j ≤ n) : xn a1 (2 * n - j) + xn a1 j ≡ 0 [MOD xn a1 n] := by
have h1 : xz a1 n ∣ d a1 * yz a1 n * yz a1 (n - j) + xz a1 j := by
rw [yz_sub _ h, mul_sub_left_distrib, sub_add_eq_add_sub]
exact
dvd_sub
(by
delta xz; delta yz
rw [mul_comm (xn _ _ : ℤ)]
exact mod_cast (xn_modEq_x2n_add_lem _ n j))
((dvd_mul_right _ _).mul_left _)
rw [two_mul, add_tsub_assoc_of_le h, xn_add, add_assoc, ← zero_add 0]
exact
(dvd_mul_right _ _).modEq_zero_nat.add
(Int.natCast_dvd_natCast.1 <| by simpa [xz, yz] using h1).modEq_zero_nat
theorem xn_modEq_x2n_sub {n j} (h : j ≤ 2 * n) : xn a1 (2 * n - j) + xn a1 j ≡ 0 [MOD xn a1 n] :=
(le_total j n).elim (xn_modEq_x2n_sub_lem a1) fun jn => by
have : 2 * n - j + j ≤ n + j := by
rw [tsub_add_cancel_of_le h, two_mul]; exact Nat.add_le_add_left jn _
let t := xn_modEq_x2n_sub_lem a1 (Nat.le_of_add_le_add_right this)
rwa [tsub_tsub_cancel_of_le h, add_comm] at t
theorem xn_modEq_x4n_add (n j) : xn a1 (4 * n + j) ≡ xn a1 j [MOD xn a1 n] :=
ModEq.add_right_cancel' (xn a1 (2 * n + j)) <| by
refine @ModEq.trans _ _ 0 _ ?_ (by rw [add_comm]; exact (xn_modEq_x2n_add _ _ _).symm)
rw [show 4 * n = 2 * n + 2 * n from right_distrib 2 2 n, add_assoc]
apply xn_modEq_x2n_add
theorem xn_modEq_x4n_sub {n j} (h : j ≤ 2 * n) : xn a1 (4 * n - j) ≡ xn a1 j [MOD xn a1 n] :=
have h' : j ≤ 2 * n := le_trans h (by rw [Nat.succ_mul])
ModEq.add_right_cancel' (xn a1 (2 * n - j)) <| by
refine @ModEq.trans _ _ 0 _ ?_ (by rw [add_comm]; exact (xn_modEq_x2n_sub _ h).symm)
rw [show 4 * n = 2 * n + 2 * n from right_distrib 2 2 n, add_tsub_assoc_of_le h']
apply xn_modEq_x2n_add
theorem eq_of_xn_modEq_lem1 {i n} : ∀ {j}, i < j → j < n → xn a1 i % xn a1 n < xn a1 j % xn a1 n
| 0, ij, _ => absurd ij (Nat.not_lt_zero _)
| j + 1, ij, jn => by
suffices xn a1 j % xn a1 n < xn a1 (j + 1) % xn a1 n from
(lt_or_eq_of_le (Nat.le_of_succ_le_succ ij)).elim
(fun h => lt_trans (eq_of_xn_modEq_lem1 h (le_of_lt jn)) this) fun h => by
rw [h]; exact this
rw [Nat.mod_eq_of_lt (strictMono_x _ (Nat.lt_of_succ_lt jn)),
Nat.mod_eq_of_lt (strictMono_x _ jn)]
exact strictMono_x _ (Nat.lt_succ_self _)
theorem eq_of_xn_modEq_lem2 {n} (h : 2 * xn a1 n = xn a1 (n + 1)) : a = 2 ∧ n = 0 := by
rw [xn_succ, mul_comm] at h
have : n = 0 :=
n.eq_zero_or_pos.resolve_right fun np =>
_root_.ne_of_lt
(lt_of_le_of_lt (Nat.mul_le_mul_left _ a1)
(Nat.lt_add_of_pos_right <| mul_pos (d_pos a1) (strictMono_y a1 np)))
h
cases this; simp at h; exact ⟨h.symm, rfl⟩
theorem eq_of_xn_modEq_lem3 {i n} (npos : 0 < n) :
∀ {j}, i < j → j ≤ 2 * n → j ≠ n → ¬(a = 2 ∧ n = 1 ∧ i = 0 ∧ j = 2) →
xn a1 i % xn a1 n < xn a1 j % xn a1 n
| 0, ij, _, _, _ => absurd ij (Nat.not_lt_zero _)
| j + 1, ij, j2n, jnn, ntriv =>
have lem2 : ∀ k > n, k ≤ 2 * n → (↑(xn a1 k % xn a1 n) : ℤ) =
xn a1 n - xn a1 (2 * n - k) := fun k kn k2n => by
let k2nl :=
lt_of_add_lt_add_right <|
show 2 * n - k + k < n + k by
rw [tsub_add_cancel_of_le]
· rw [two_mul]
exact add_lt_add_left kn n
exact k2n
have xle : xn a1 (2 * n - k) ≤ xn a1 n := le_of_lt <| strictMono_x a1 k2nl
suffices xn a1 k % xn a1 n = xn a1 n - xn a1 (2 * n - k) by rw [this, Int.ofNat_sub xle]
rw [← Nat.mod_eq_of_lt (Nat.sub_lt (x_pos a1 n) (x_pos a1 (2 * n - k)))]
apply ModEq.add_right_cancel' (xn a1 (2 * n - k))
rw [tsub_add_cancel_of_le xle]
have t := xn_modEq_x2n_sub_lem a1 k2nl.le
rw [tsub_tsub_cancel_of_le k2n] at t
exact t.trans dvd_rfl.zero_modEq_nat
(lt_trichotomy j n).elim (fun jn : j < n => eq_of_xn_modEq_lem1 _ ij (lt_of_le_of_ne jn jnn))
fun o =>
o.elim
(fun jn : j = n => by
cases jn
apply Int.lt_of_ofNat_lt_ofNat
rw [lem2 (n + 1) (Nat.lt_succ_self _) j2n,
show 2 * n - (n + 1) = n - 1 by
rw [two_mul, tsub_add_eq_tsub_tsub, add_tsub_cancel_right]]
refine lt_sub_left_of_add_lt (Int.ofNat_lt_ofNat_of_lt ?_)
rcases lt_or_eq_of_le <| Nat.le_of_succ_le_succ ij with lin | ein
· rw [Nat.mod_eq_of_lt (strictMono_x _ lin)]
have ll : xn a1 (n - 1) + xn a1 (n - 1) ≤ xn a1 n := by
rw [← two_mul, mul_comm,
show xn a1 n = xn a1 (n - 1 + 1) by rw [tsub_add_cancel_of_le (succ_le_of_lt npos)],
xn_succ]
exact le_trans (Nat.mul_le_mul_left _ a1) (Nat.le_add_right _ _)
have npm : (n - 1).succ = n := Nat.succ_pred_eq_of_pos npos
have il : i ≤ n - 1 := by
apply Nat.le_of_succ_le_succ
rw [npm]
exact lin
rcases lt_or_eq_of_le il with ill | ile
· exact lt_of_lt_of_le (Nat.add_lt_add_left (strictMono_x a1 ill) _) ll
· rw [ile]
apply lt_of_le_of_ne ll
rw [← two_mul]
exact fun e =>
ntriv <| by
let ⟨a2, s1⟩ :=
@eq_of_xn_modEq_lem2 _ a1 (n - 1)
(by rwa [tsub_add_cancel_of_le (succ_le_of_lt npos)])
have n1 : n = 1 := le_antisymm (tsub_eq_zero_iff_le.mp s1) npos
rw [ile, a2, n1]; exact ⟨rfl, rfl, rfl, rfl⟩
· rw [ein, Nat.mod_self, add_zero]
exact strictMono_x _ (Nat.pred_lt npos.ne'))
fun jn : j > n =>
have lem1 : j ≠ n → xn a1 j % xn a1 n < xn a1 (j + 1) % xn a1 n →
xn a1 i % xn a1 n < xn a1 (j + 1) % xn a1 n :=
fun jn s =>
(lt_or_eq_of_le (Nat.le_of_succ_le_succ ij)).elim
(fun h =>
lt_trans
(eq_of_xn_modEq_lem3 npos h (le_of_lt (Nat.lt_of_succ_le j2n)) jn
fun ⟨_, n1, _, j2⟩ => by
rw [n1, j2] at j2n; exact absurd j2n (by decide))
s)
fun h => by rw [h]; exact s
lem1 (_root_.ne_of_gt jn) <|
Int.lt_of_ofNat_lt_ofNat <| by
rw [lem2 j jn (le_of_lt j2n), lem2 (j + 1) (Nat.le_succ_of_le jn) j2n]
refine sub_lt_sub_left (Int.ofNat_lt_ofNat_of_lt <| strictMono_x _ ?_) _
rw [Nat.sub_succ]
exact Nat.pred_lt (_root_.ne_of_gt <| tsub_pos_of_lt j2n)
theorem eq_of_xn_modEq_le {i j n} (ij : i ≤ j) (j2n : j ≤ 2 * n)
(h : xn a1 i ≡ xn a1 j [MOD xn a1 n])
(ntriv : ¬(a = 2 ∧ n = 1 ∧ i = 0 ∧ j = 2)) : i = j :=
if npos : n = 0 then by simp_all
else
(lt_or_eq_of_le ij).resolve_left fun ij' =>
if jn : j = n then by
refine _root_.ne_of_gt ?_ h
rw [jn, Nat.mod_self]
have x0 : 0 < xn a1 0 % xn a1 n := by
rw [Nat.mod_eq_of_lt (strictMono_x a1 (Nat.pos_of_ne_zero npos))]
exact Nat.succ_pos _
| rcases i with - | i
· exact x0
rw [jn] at ij'
exact
x0.trans
(eq_of_xn_modEq_lem3 _ (Nat.pos_of_ne_zero npos) (Nat.succ_pos _) (le_trans ij j2n)
(_root_.ne_of_lt ij') fun ⟨_, n1, _, i2⟩ => by
rw [n1, i2] at ij'; exact absurd ij' (by decide))
else _root_.ne_of_lt (eq_of_xn_modEq_lem3 a1 (Nat.pos_of_ne_zero npos) ij' j2n jn ntriv) h
theorem eq_of_xn_modEq {i j n} (i2n : i ≤ 2 * n) (j2n : j ≤ 2 * n)
(h : xn a1 i ≡ xn a1 j [MOD xn a1 n])
(ntriv : a = 2 → n = 1 → (i = 0 → j ≠ 2) ∧ (i = 2 → j ≠ 0)) : i = j :=
(le_total i j).elim
(fun ij => eq_of_xn_modEq_le a1 ij j2n h fun ⟨a2, n1, i0, j2⟩ => (ntriv a2 n1).left i0 j2)
fun ij =>
(eq_of_xn_modEq_le a1 ij i2n h.symm fun ⟨a2, n1, j0, i2⟩ => (ntriv a2 n1).right i2 j0).symm
theorem eq_of_xn_modEq' {i j n} (ipos : 0 < i) (hin : i ≤ n) (j4n : j ≤ 4 * n)
(h : xn a1 j ≡ xn a1 i [MOD xn a1 n]) : j = i ∨ j + i = 4 * n :=
have i2n : i ≤ 2 * n := by apply le_trans hin; rw [two_mul]; apply Nat.le_add_left
(le_or_gt j (2 * n)).imp
(fun j2n : j ≤ 2 * n =>
eq_of_xn_modEq a1 j2n i2n h fun _ n1 =>
⟨fun _ i2 => by rw [n1, i2] at hin; exact absurd hin (by decide), fun _ i0 =>
_root_.ne_of_gt ipos i0⟩)
fun j2n : 2 * n < j =>
suffices i = 4 * n - j by rw [this, add_tsub_cancel_of_le j4n]
have j42n : 4 * n - j ≤ 2 * n := by omega
eq_of_xn_modEq a1 i2n j42n
(h.symm.trans <| by
let t := xn_modEq_x4n_sub a1 j42n
rwa [tsub_tsub_cancel_of_le j4n] at t)
(by omega)
theorem modEq_of_xn_modEq {i j n} (ipos : 0 < i) (hin : i ≤ n)
(h : xn a1 j ≡ xn a1 i [MOD xn a1 n]) :
j ≡ i [MOD 4 * n] ∨ j + i ≡ 0 [MOD 4 * n] :=
let j' := j % (4 * n)
have n4 : 0 < 4 * n := mul_pos (by decide) (ipos.trans_le hin)
have jl : j' < 4 * n := Nat.mod_lt _ n4
have jj : j ≡ j' [MOD 4 * n] := by delta ModEq; rw [Nat.mod_eq_of_lt jl]
have : ∀ j q, xn a1 (j + 4 * n * q) ≡ xn a1 j [MOD xn a1 n] := by
intro j q; induction q with
| zero => simp [ModEq.refl]
| succ q IH =>
rw [Nat.mul_succ, ← add_assoc, add_comm]
exact (xn_modEq_x4n_add _ _ _).trans IH
Or.imp (fun ji : j' = i => by rwa [← ji])
(fun ji : j' + i = 4 * n =>
(jj.add_right _).trans <| by
rw [ji]
exact dvd_rfl.modEq_zero_nat)
(eq_of_xn_modEq' a1 ipos hin jl.le <|
(h.symm.trans <| by
rw [← Nat.mod_add_div j (4 * n)]
exact this j' _).symm)
end
theorem xy_modEq_of_modEq {a b c} (a1 : 1 < a) (b1 : 1 < b) (h : a ≡ b [MOD c]) :
∀ n, xn a1 n ≡ xn b1 n [MOD c] ∧ yn a1 n ≡ yn b1 n [MOD c]
| 0 => by constructor <;> rfl
| 1 => by simpa using ⟨h, ModEq.refl 1⟩
| n + 2 =>
⟨(xy_modEq_of_modEq a1 b1 h n).left.add_right_cancel <| by
rw [xn_succ_succ a1, xn_succ_succ b1]
exact (h.mul_left _).mul (xy_modEq_of_modEq _ _ h (n + 1)).left,
(xy_modEq_of_modEq a1 b1 h n).right.add_right_cancel <| by
rw [yn_succ_succ a1, yn_succ_succ b1]
exact (h.mul_left _).mul (xy_modEq_of_modEq _ _ h (n + 1)).right⟩
theorem matiyasevic {a k x y} :
(∃ a1 : 1 < a, xn a1 k = x ∧ yn a1 k = y) ↔
1 < a ∧ k ≤ y ∧ (x = 1 ∧ y = 0 ∨
∃ u v s t b : ℕ,
| Mathlib/NumberTheory/PellMatiyasevic.lean | 666 | 741 |
/-
Copyright (c) 2021 Aaron Anderson. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Aaron Anderson, Gabin Kolly
-/
import Mathlib.Data.Fintype.Order
import Mathlib.Order.Closure
import Mathlib.ModelTheory.Semantics
import Mathlib.ModelTheory.Encoding
/-!
# First-Order Substructures
This file defines substructures of first-order structures in a similar manner to the various
substructures appearing in the algebra library.
## Main Definitions
- A `FirstOrder.Language.Substructure` is defined so that `L.Substructure M` is the type of all
substructures of the `L`-structure `M`.
- `FirstOrder.Language.Substructure.closure` is defined so that if `s : Set M`, `closure L s` is
the least substructure of `M` containing `s`.
- `FirstOrder.Language.Substructure.comap` is defined so that `s.comap f` is the preimage of the
substructure `s` under the homomorphism `f`, as a substructure.
- `FirstOrder.Language.Substructure.map` is defined so that `s.map f` is the image of the
substructure `s` under the homomorphism `f`, as a substructure.
- `FirstOrder.Language.Hom.range` is defined so that `f.range` is the range of the
homomorphism `f`, as a substructure.
- `FirstOrder.Language.Hom.domRestrict` and `FirstOrder.Language.Hom.codRestrict` restrict
the domain and codomain respectively of first-order homomorphisms to substructures.
- `FirstOrder.Language.Embedding.domRestrict` and `FirstOrder.Language.Embedding.codRestrict`
restrict the domain and codomain respectively of first-order embeddings to substructures.
- `FirstOrder.Language.Substructure.inclusion` is the inclusion embedding between substructures.
- `FirstOrder.Language.Substructure.PartialEquiv` is defined so that `PartialEquiv L M N` is
the type of equivalences between substructures of `M` and `N`.
## Main Results
- `L.Substructure M` forms a `CompleteLattice`.
-/
universe u v w
namespace FirstOrder
namespace Language
variable {L : Language.{u, v}} {M : Type w} {N P : Type*}
variable [L.Structure M] [L.Structure N] [L.Structure P]
open FirstOrder Cardinal
open Structure Cardinal
section ClosedUnder
open Set
variable {n : ℕ} (f : L.Functions n) (s : Set M)
/-- Indicates that a set in a given structure is a closed under a function symbol. -/
def ClosedUnder : Prop :=
∀ x : Fin n → M, (∀ i : Fin n, x i ∈ s) → funMap f x ∈ s
variable (L)
@[simp]
theorem closedUnder_univ : ClosedUnder f (univ : Set M) := fun _ _ => mem_univ _
variable {L f s} {t : Set M}
namespace ClosedUnder
theorem inter (hs : ClosedUnder f s) (ht : ClosedUnder f t) : ClosedUnder f (s ∩ t) := fun x h =>
mem_inter (hs x fun i => mem_of_mem_inter_left (h i)) (ht x fun i => mem_of_mem_inter_right (h i))
theorem inf (hs : ClosedUnder f s) (ht : ClosedUnder f t) : ClosedUnder f (s ⊓ t) :=
hs.inter ht
variable {S : Set (Set M)}
theorem sInf (hS : ∀ s, s ∈ S → ClosedUnder f s) : ClosedUnder f (sInf S) := fun x h s hs =>
hS s hs x fun i => h i s hs
end ClosedUnder
end ClosedUnder
variable (L) (M)
/-- A substructure of a structure `M` is a set closed under application of function symbols. -/
structure Substructure where
/-- The underlying set of this substructure -/
carrier : Set M
fun_mem : ∀ {n}, ∀ f : L.Functions n, ClosedUnder f carrier
variable {L} {M}
namespace Substructure
attribute [coe] Substructure.carrier
instance instSetLike : SetLike (L.Substructure M) M :=
⟨Substructure.carrier, fun p q h => by cases p; cases q; congr⟩
/-- See Note [custom simps projection] -/
def Simps.coe (S : L.Substructure M) : Set M :=
S
initialize_simps_projections Substructure (carrier → coe, as_prefix coe)
@[simp]
theorem mem_carrier {s : L.Substructure M} {x : M} : x ∈ s.carrier ↔ x ∈ s :=
Iff.rfl
/-- Two substructures are equal if they have the same elements. -/
@[ext]
theorem ext {S T : L.Substructure M} (h : ∀ x, x ∈ S ↔ x ∈ T) : S = T :=
SetLike.ext h
/-- Copy a substructure replacing `carrier` with a set that is equal to it. -/
protected def copy (S : L.Substructure M) (s : Set M) (hs : s = S) : L.Substructure M where
carrier := s
fun_mem _ f := hs.symm ▸ S.fun_mem _ f
end Substructure
variable {S : L.Substructure M}
theorem Term.realize_mem {α : Type*} (t : L.Term α) (xs : α → M) (h : ∀ a, xs a ∈ S) :
t.realize xs ∈ S := by
induction t with
| var a => exact h a
| func f ts ih => exact Substructure.fun_mem _ _ _ ih
namespace Substructure
@[simp]
theorem coe_copy {s : Set M} (hs : s = S) : (S.copy s hs : Set M) = s :=
rfl
theorem copy_eq {s : Set M} (hs : s = S) : S.copy s hs = S :=
SetLike.coe_injective hs
theorem constants_mem (c : L.Constants) : (c : M) ∈ S :=
mem_carrier.2 (S.fun_mem c _ finZeroElim)
/-- The substructure `M` of the structure `M`. -/
instance instTop : Top (L.Substructure M) :=
⟨{ carrier := Set.univ
fun_mem := fun {_} _ _ _ => Set.mem_univ _ }⟩
instance instInhabited : Inhabited (L.Substructure M) :=
⟨⊤⟩
@[simp]
theorem mem_top (x : M) : x ∈ (⊤ : L.Substructure M) :=
Set.mem_univ x
@[simp]
theorem coe_top : ((⊤ : L.Substructure M) : Set M) = Set.univ :=
rfl
/-- The inf of two substructures is their intersection. -/
instance instInf : Min (L.Substructure M) :=
⟨fun S₁ S₂ =>
{ carrier := (S₁ : Set M) ∩ (S₂ : Set M)
fun_mem := fun {_} f => (S₁.fun_mem f).inf (S₂.fun_mem f) }⟩
@[simp]
theorem coe_inf (p p' : L.Substructure M) :
((p ⊓ p' : L.Substructure M) : Set M) = (p : Set M) ∩ (p' : Set M) :=
rfl
@[simp]
theorem mem_inf {p p' : L.Substructure M} {x : M} : x ∈ p ⊓ p' ↔ x ∈ p ∧ x ∈ p' :=
Iff.rfl
instance instInfSet : InfSet (L.Substructure M) :=
⟨fun s =>
{ carrier := ⋂ t ∈ s, (t : Set M)
fun_mem := fun {n} f =>
ClosedUnder.sInf
(by
rintro _ ⟨t, rfl⟩
by_cases h : t ∈ s
· simpa [h] using t.fun_mem f
· simp [h]) }⟩
@[simp, norm_cast]
theorem coe_sInf (S : Set (L.Substructure M)) :
((sInf S : L.Substructure M) : Set M) = ⋂ s ∈ S, (s : Set M) :=
rfl
theorem mem_sInf {S : Set (L.Substructure M)} {x : M} : x ∈ sInf S ↔ ∀ p ∈ S, x ∈ p :=
Set.mem_iInter₂
theorem mem_iInf {ι : Sort*} {S : ι → L.Substructure M} {x : M} :
(x ∈ ⨅ i, S i) ↔ ∀ i, x ∈ S i := by simp only [iInf, mem_sInf, Set.forall_mem_range]
@[simp, norm_cast]
theorem coe_iInf {ι : Sort*} {S : ι → L.Substructure M} :
((⨅ i, S i : L.Substructure M) : Set M) = ⋂ i, (S i : Set M) := by
simp only [iInf, coe_sInf, Set.biInter_range]
/-- Substructures of a structure form a complete lattice. -/
instance instCompleteLattice : CompleteLattice (L.Substructure M) :=
{ completeLatticeOfInf (L.Substructure M) fun _ =>
IsGLB.of_image
(fun {S T : L.Substructure M} => show (S : Set M) ≤ T ↔ S ≤ T from SetLike.coe_subset_coe)
isGLB_biInf with
le := (· ≤ ·)
lt := (· < ·)
top := ⊤
le_top := fun _ x _ => mem_top x
inf := (· ⊓ ·)
sInf := InfSet.sInf
le_inf := fun _a _b _c ha hb _x hx => ⟨ha hx, hb hx⟩
inf_le_left := fun _ _ _ => And.left
inf_le_right := fun _ _ _ => And.right }
variable (L)
/-- The `L.Substructure` generated by a set. -/
def closure : LowerAdjoint ((↑) : L.Substructure M → Set M) :=
⟨fun s => sInf { S | s ⊆ S }, fun _ _ =>
⟨Set.Subset.trans fun _x hx => mem_sInf.2 fun _S hS => hS hx, fun h => sInf_le h⟩⟩
variable {L} {s : Set M}
theorem mem_closure {x : M} : x ∈ closure L s ↔ ∀ S : L.Substructure M, s ⊆ S → x ∈ S :=
mem_sInf
/-- The substructure generated by a set includes the set. -/
@[simp]
theorem subset_closure : s ⊆ closure L s :=
(closure L).le_closure s
theorem not_mem_of_not_mem_closure {P : M} (hP : P ∉ closure L s) : P ∉ s := fun h =>
hP (subset_closure h)
@[simp]
theorem closed (S : L.Substructure M) : (closure L).closed (S : Set M) :=
congr rfl ((closure L).eq_of_le Set.Subset.rfl fun _x xS => mem_closure.2 fun _T hT => hT xS)
open Set
/-- A substructure `S` includes `closure L s` if and only if it includes `s`. -/
@[simp]
theorem closure_le : closure L s ≤ S ↔ s ⊆ S :=
(closure L).closure_le_closed_iff_le s S.closed
/-- Substructure closure of a set is monotone in its argument: if `s ⊆ t`,
then `closure L s ≤ closure L t`. -/
@[gcongr]
theorem closure_mono ⦃s t : Set M⦄ (h : s ⊆ t) : closure L s ≤ closure L t :=
(closure L).monotone h
theorem closure_eq_of_le (h₁ : s ⊆ S) (h₂ : S ≤ closure L s) : closure L s = S :=
(closure L).eq_of_le h₁ h₂
theorem coe_closure_eq_range_term_realize :
(closure L s : Set M) = range (@Term.realize L _ _ _ ((↑) : s → M)) := by
let S : L.Substructure M := ⟨range (Term.realize (L := L) ((↑) : s → M)), fun {n} f x hx => by
simp only [mem_range] at *
refine ⟨func f fun i => Classical.choose (hx i), ?_⟩
simp only [Term.realize, fun i => Classical.choose_spec (hx i)]⟩
change _ = (S : Set M)
rw [← SetLike.ext'_iff]
refine closure_eq_of_le (fun x hx => ⟨var ⟨x, hx⟩, rfl⟩) (le_sInf fun S' hS' => ?_)
rintro _ ⟨t, rfl⟩
exact t.realize_mem _ fun i => hS' i.2
instance small_closure [Small.{u} s] : Small.{u} (closure L s) := by
rw [← SetLike.coe_sort_coe, Substructure.coe_closure_eq_range_term_realize]
exact small_range _
theorem mem_closure_iff_exists_term {x : M} :
x ∈ closure L s ↔ ∃ t : L.Term s, t.realize ((↑) : s → M) = x := by
rw [← SetLike.mem_coe, coe_closure_eq_range_term_realize, mem_range]
theorem lift_card_closure_le_card_term : Cardinal.lift.{max u w} #(closure L s) ≤ #(L.Term s) := by
rw [← SetLike.coe_sort_coe, coe_closure_eq_range_term_realize]
rw [← Cardinal.lift_id'.{w, max u w} #(L.Term s)]
exact Cardinal.mk_range_le_lift
theorem lift_card_closure_le :
Cardinal.lift.{u, w} #(closure L s) ≤
max ℵ₀ (Cardinal.lift.{u, w} #s + Cardinal.lift.{w, u} #(Σi, L.Functions i)) := by
rw [← lift_umax]
refine lift_card_closure_le_card_term.trans (Term.card_le.trans ?_)
rw [mk_sum, lift_umax.{w, u}]
lemma mem_closed_iff (s : Set M) :
s ∈ (closure L).closed ↔ ∀ {n}, ∀ f : L.Functions n, ClosedUnder f s := by
refine ⟨fun h n f => ?_, fun h => ?_⟩
· rw [← h]
exact Substructure.fun_mem _ _
· have h' : closure L s = ⟨s, h⟩ := closure_eq_of_le (refl _) subset_closure
exact congr_arg _ h'
variable (L)
lemma mem_closed_of_isRelational [L.IsRelational] (s : Set M) : s ∈ (closure L).closed :=
(mem_closed_iff s).2 isEmptyElim
@[simp]
lemma closure_eq_of_isRelational [L.IsRelational] (s : Set M) : closure L s = s :=
LowerAdjoint.closure_eq_self_of_mem_closed _ (mem_closed_of_isRelational L s)
@[simp]
lemma mem_closure_iff_of_isRelational [L.IsRelational] (s : Set M) (m : M) :
m ∈ closure L s ↔ m ∈ s := by
| rw [← SetLike.mem_coe, closure_eq_of_isRelational]
theorem _root_.Set.Countable.substructure_closure
| Mathlib/ModelTheory/Substructures.lean | 314 | 316 |
/-
Copyright (c) 2019 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Sébastien Gouëzel, Yury Kudryashov
-/
import Mathlib.Analysis.Calculus.FDeriv.Linear
import Mathlib.Analysis.Calculus.FDeriv.Comp
/-!
# Additive operations on derivatives
For detailed documentation of the Fréchet derivative,
see the module docstring of `Analysis/Calculus/FDeriv/Basic.lean`.
This file contains the usual formulas (and existence assertions) for the derivative of
* sum of finitely many functions
* multiplication of a function by a scalar constant
* negative of a function
* subtraction of two functions
-/
open Filter Asymptotics ContinuousLinearMap
noncomputable section
section
variable {𝕜 : Type*} [NontriviallyNormedField 𝕜]
variable {E : Type*} [NormedAddCommGroup E] [NormedSpace 𝕜 E]
variable {F : Type*} [NormedAddCommGroup F] [NormedSpace 𝕜 F]
variable {f g : E → F}
variable {f' g' : E →L[𝕜] F}
variable {x : E}
variable {s : Set E}
variable {L : Filter E}
section ConstSMul
variable {R : Type*} [Semiring R] [Module R F] [SMulCommClass 𝕜 R F] [ContinuousConstSMul R F]
/-! ### Derivative of a function multiplied by a constant -/
@[fun_prop]
theorem HasStrictFDerivAt.const_smul (h : HasStrictFDerivAt f f' x) (c : R) :
HasStrictFDerivAt (fun x => c • f x) (c • f') x :=
(c • (1 : F →L[𝕜] F)).hasStrictFDerivAt.comp x h
theorem HasFDerivAtFilter.const_smul (h : HasFDerivAtFilter f f' x L) (c : R) :
HasFDerivAtFilter (fun x => c • f x) (c • f') x L :=
(c • (1 : F →L[𝕜] F)).hasFDerivAtFilter.comp x h tendsto_map
@[fun_prop]
nonrec theorem HasFDerivWithinAt.const_smul (h : HasFDerivWithinAt f f' s x) (c : R) :
HasFDerivWithinAt (fun x => c • f x) (c • f') s x :=
h.const_smul c
@[fun_prop]
nonrec theorem HasFDerivAt.const_smul (h : HasFDerivAt f f' x) (c : R) :
HasFDerivAt (fun x => c • f x) (c • f') x :=
h.const_smul c
@[fun_prop]
theorem DifferentiableWithinAt.const_smul (h : DifferentiableWithinAt 𝕜 f s x) (c : R) :
DifferentiableWithinAt 𝕜 (fun y => c • f y) s x :=
(h.hasFDerivWithinAt.const_smul c).differentiableWithinAt
@[fun_prop]
theorem DifferentiableAt.const_smul (h : DifferentiableAt 𝕜 f x) (c : R) :
DifferentiableAt 𝕜 (fun y => c • f y) x :=
(h.hasFDerivAt.const_smul c).differentiableAt
@[fun_prop]
theorem DifferentiableOn.const_smul (h : DifferentiableOn 𝕜 f s) (c : R) :
DifferentiableOn 𝕜 (fun y => c • f y) s := fun x hx => (h x hx).const_smul c
@[fun_prop]
theorem Differentiable.const_smul (h : Differentiable 𝕜 f) (c : R) :
Differentiable 𝕜 fun y => c • f y := fun x => (h x).const_smul c
theorem fderivWithin_const_smul (hxs : UniqueDiffWithinAt 𝕜 s x)
(h : DifferentiableWithinAt 𝕜 f s x) (c : R) :
fderivWithin 𝕜 (fun y => c • f y) s x = c • fderivWithin 𝕜 f s x :=
(h.hasFDerivWithinAt.const_smul c).fderivWithin hxs
/-- Version of `fderivWithin_const_smul` written with `c • f` instead of `fun y ↦ c • f y`. -/
theorem fderivWithin_const_smul' (hxs : UniqueDiffWithinAt 𝕜 s x)
(h : DifferentiableWithinAt 𝕜 f s x) (c : R) :
fderivWithin 𝕜 (c • f) s x = c • fderivWithin 𝕜 f s x :=
fderivWithin_const_smul hxs h c
theorem fderiv_const_smul (h : DifferentiableAt 𝕜 f x) (c : R) :
fderiv 𝕜 (fun y => c • f y) x = c • fderiv 𝕜 f x :=
(h.hasFDerivAt.const_smul c).fderiv
/-- Version of `fderiv_const_smul` written with `c • f` instead of `fun y ↦ c • f y`. -/
theorem fderiv_const_smul' (h : DifferentiableAt 𝕜 f x) (c : R) :
fderiv 𝕜 (c • f) x = c • fderiv 𝕜 f x :=
(h.hasFDerivAt.const_smul c).fderiv
end ConstSMul
section Add
/-! ### Derivative of the sum of two functions -/
@[fun_prop]
nonrec theorem HasStrictFDerivAt.add (hf : HasStrictFDerivAt f f' x)
(hg : HasStrictFDerivAt g g' x) : HasStrictFDerivAt (fun y => f y + g y) (f' + g') x :=
.of_isLittleO <| (hf.isLittleO.add hg.isLittleO).congr_left fun y => by
simp only [LinearMap.sub_apply, LinearMap.add_apply, map_sub, map_add, add_apply]
abel
theorem HasFDerivAtFilter.add (hf : HasFDerivAtFilter f f' x L)
(hg : HasFDerivAtFilter g g' x L) : HasFDerivAtFilter (fun y => f y + g y) (f' + g') x L :=
.of_isLittleO <| (hf.isLittleO.add hg.isLittleO).congr_left fun _ => by
simp only [LinearMap.sub_apply, LinearMap.add_apply, map_sub, map_add, add_apply]
abel
@[fun_prop]
nonrec theorem HasFDerivWithinAt.add (hf : HasFDerivWithinAt f f' s x)
(hg : HasFDerivWithinAt g g' s x) : HasFDerivWithinAt (fun y => f y + g y) (f' + g') s x :=
hf.add hg
@[fun_prop]
nonrec theorem HasFDerivAt.add (hf : HasFDerivAt f f' x) (hg : HasFDerivAt g g' x) :
HasFDerivAt (fun x => f x + g x) (f' + g') x :=
hf.add hg
@[fun_prop]
theorem DifferentiableWithinAt.add (hf : DifferentiableWithinAt 𝕜 f s x)
(hg : DifferentiableWithinAt 𝕜 g s x) : DifferentiableWithinAt 𝕜 (fun y => f y + g y) s x :=
(hf.hasFDerivWithinAt.add hg.hasFDerivWithinAt).differentiableWithinAt
@[simp, fun_prop]
theorem DifferentiableAt.add (hf : DifferentiableAt 𝕜 f x) (hg : DifferentiableAt 𝕜 g x) :
DifferentiableAt 𝕜 (fun y => f y + g y) x :=
(hf.hasFDerivAt.add hg.hasFDerivAt).differentiableAt
@[fun_prop]
theorem DifferentiableOn.add (hf : DifferentiableOn 𝕜 f s) (hg : DifferentiableOn 𝕜 g s) :
DifferentiableOn 𝕜 (fun y => f y + g y) s := fun x hx => (hf x hx).add (hg x hx)
@[simp, fun_prop]
theorem Differentiable.add (hf : Differentiable 𝕜 f) (hg : Differentiable 𝕜 g) :
Differentiable 𝕜 fun y => f y + g y := fun x => (hf x).add (hg x)
theorem fderivWithin_add (hxs : UniqueDiffWithinAt 𝕜 s x) (hf : DifferentiableWithinAt 𝕜 f s x)
(hg : DifferentiableWithinAt 𝕜 g s x) :
fderivWithin 𝕜 (fun y => f y + g y) s x = fderivWithin 𝕜 f s x + fderivWithin 𝕜 g s x :=
(hf.hasFDerivWithinAt.add hg.hasFDerivWithinAt).fderivWithin hxs
/-- Version of `fderivWithin_add` where the function is written as `f + g` instead
of `fun y ↦ f y + g y`. -/
theorem fderivWithin_add' (hxs : UniqueDiffWithinAt 𝕜 s x) (hf : DifferentiableWithinAt 𝕜 f s x)
(hg : DifferentiableWithinAt 𝕜 g s x) :
fderivWithin 𝕜 (f + g) s x = fderivWithin 𝕜 f s x + fderivWithin 𝕜 g s x :=
fderivWithin_add hxs hf hg
theorem fderiv_add (hf : DifferentiableAt 𝕜 f x) (hg : DifferentiableAt 𝕜 g x) :
fderiv 𝕜 (fun y => f y + g y) x = fderiv 𝕜 f x + fderiv 𝕜 g x :=
(hf.hasFDerivAt.add hg.hasFDerivAt).fderiv
/-- Version of `fderiv_add` where the function is written as `f + g` instead
of `fun y ↦ f y + g y`. -/
theorem fderiv_add' (hf : DifferentiableAt 𝕜 f x) (hg : DifferentiableAt 𝕜 g x) :
fderiv 𝕜 (f + g) x = fderiv 𝕜 f x + fderiv 𝕜 g x :=
fderiv_add hf hg
@[simp]
theorem hasFDerivAtFilter_add_const_iff (c : F) :
HasFDerivAtFilter (f · + c) f' x L ↔ HasFDerivAtFilter f f' x L := by
simp [hasFDerivAtFilter_iff_isLittleOTVS]
alias ⟨_, HasFDerivAtFilter.add_const⟩ := hasFDerivAtFilter_add_const_iff
@[simp]
theorem hasStrictFDerivAt_add_const_iff (c : F) :
HasStrictFDerivAt (f · + c) f' x ↔ HasStrictFDerivAt f f' x := by
simp [hasStrictFDerivAt_iff_isLittleO]
@[fun_prop]
alias ⟨_, HasStrictFDerivAt.add_const⟩ := hasStrictFDerivAt_add_const_iff
@[simp]
theorem hasFDerivWithinAt_add_const_iff (c : F) :
HasFDerivWithinAt (f · + c) f' s x ↔ HasFDerivWithinAt f f' s x :=
hasFDerivAtFilter_add_const_iff c
@[fun_prop]
alias ⟨_, HasFDerivWithinAt.add_const⟩ := hasFDerivWithinAt_add_const_iff
@[simp]
theorem hasFDerivAt_add_const_iff (c : F) : HasFDerivAt (f · + c) f' x ↔ HasFDerivAt f f' x :=
hasFDerivAtFilter_add_const_iff c
@[fun_prop]
alias ⟨_, HasFDerivAt.add_const⟩ := hasFDerivAt_add_const_iff
@[simp]
theorem differentiableWithinAt_add_const_iff (c : F) :
DifferentiableWithinAt 𝕜 (fun y => f y + c) s x ↔ DifferentiableWithinAt 𝕜 f s x :=
exists_congr fun _ ↦ hasFDerivWithinAt_add_const_iff c
@[fun_prop]
alias ⟨_, DifferentiableWithinAt.add_const⟩ := differentiableWithinAt_add_const_iff
@[simp]
theorem differentiableAt_add_const_iff (c : F) :
DifferentiableAt 𝕜 (fun y => f y + c) x ↔ DifferentiableAt 𝕜 f x :=
exists_congr fun _ ↦ hasFDerivAt_add_const_iff c
@[fun_prop]
alias ⟨_, DifferentiableAt.add_const⟩ := differentiableAt_add_const_iff
@[simp]
theorem differentiableOn_add_const_iff (c : F) :
DifferentiableOn 𝕜 (fun y => f y + c) s ↔ DifferentiableOn 𝕜 f s :=
forall₂_congr fun _ _ ↦ differentiableWithinAt_add_const_iff c
@[fun_prop]
alias ⟨_, DifferentiableOn.add_const⟩ := differentiableOn_add_const_iff
@[simp]
theorem differentiable_add_const_iff (c : F) :
(Differentiable 𝕜 fun y => f y + c) ↔ Differentiable 𝕜 f :=
forall_congr' fun _ ↦ differentiableAt_add_const_iff c
@[fun_prop]
alias ⟨_, Differentiable.add_const⟩ := differentiable_add_const_iff
@[simp]
theorem fderivWithin_add_const (c : F) :
fderivWithin 𝕜 (fun y => f y + c) s x = fderivWithin 𝕜 f s x := by
classical simp [fderivWithin]
@[simp]
theorem fderiv_add_const (c : F) : fderiv 𝕜 (fun y => f y + c) x = fderiv 𝕜 f x := by
simp only [← fderivWithin_univ, fderivWithin_add_const]
@[simp]
theorem hasFDerivAtFilter_const_add_iff (c : F) :
HasFDerivAtFilter (c + f ·) f' x L ↔ HasFDerivAtFilter f f' x L := by
simpa only [add_comm] using hasFDerivAtFilter_add_const_iff c
alias ⟨_, HasFDerivAtFilter.const_add⟩ := hasFDerivAtFilter_const_add_iff
@[simp]
theorem hasStrictFDerivAt_const_add_iff (c : F) :
HasStrictFDerivAt (c + f ·) f' x ↔ HasStrictFDerivAt f f' x := by
simpa only [add_comm] using hasStrictFDerivAt_add_const_iff c
@[fun_prop]
alias ⟨_, HasStrictFDerivAt.const_add⟩ := hasStrictFDerivAt_const_add_iff
@[simp]
theorem hasFDerivWithinAt_const_add_iff (c : F) :
HasFDerivWithinAt (c + f ·) f' s x ↔ HasFDerivWithinAt f f' s x :=
hasFDerivAtFilter_const_add_iff c
@[fun_prop]
alias ⟨_, HasFDerivWithinAt.const_add⟩ := hasFDerivWithinAt_const_add_iff
@[simp]
theorem hasFDerivAt_const_add_iff (c : F) : HasFDerivAt (c + f ·) f' x ↔ HasFDerivAt f f' x :=
hasFDerivAtFilter_const_add_iff c
@[fun_prop]
alias ⟨_, HasFDerivAt.const_add⟩ := hasFDerivAt_const_add_iff
@[simp]
theorem differentiableWithinAt_const_add_iff (c : F) :
DifferentiableWithinAt 𝕜 (fun y => c + f y) s x ↔ DifferentiableWithinAt 𝕜 f s x :=
exists_congr fun _ ↦ hasFDerivWithinAt_const_add_iff c
@[fun_prop]
alias ⟨_, DifferentiableWithinAt.const_add⟩ := differentiableWithinAt_const_add_iff
@[simp]
theorem differentiableAt_const_add_iff (c : F) :
DifferentiableAt 𝕜 (fun y => c + f y) x ↔ DifferentiableAt 𝕜 f x :=
exists_congr fun _ ↦ hasFDerivAt_const_add_iff c
@[fun_prop]
alias ⟨_, DifferentiableAt.const_add⟩ := differentiableAt_const_add_iff
@[simp]
theorem differentiableOn_const_add_iff (c : F) :
DifferentiableOn 𝕜 (fun y => c + f y) s ↔ DifferentiableOn 𝕜 f s :=
forall₂_congr fun _ _ ↦ differentiableWithinAt_const_add_iff c
@[fun_prop]
alias ⟨_, DifferentiableOn.const_add⟩ := differentiableOn_const_add_iff
@[simp]
theorem differentiable_const_add_iff (c : F) :
(Differentiable 𝕜 fun y => c + f y) ↔ Differentiable 𝕜 f :=
forall_congr' fun _ ↦ differentiableAt_const_add_iff c
@[fun_prop]
alias ⟨_, Differentiable.const_add⟩ := differentiable_const_add_iff
@[simp]
theorem fderivWithin_const_add (c : F) :
fderivWithin 𝕜 (fun y => c + f y) s x = fderivWithin 𝕜 f s x := by
simpa only [add_comm] using fderivWithin_add_const c
@[simp]
theorem fderiv_const_add (c : F) : fderiv 𝕜 (fun y => c + f y) x = fderiv 𝕜 f x := by
simp only [add_comm c, fderiv_add_const]
end Add
section Sum
/-! ### Derivative of a finite sum of functions -/
variable {ι : Type*} {u : Finset ι} {A : ι → E → F} {A' : ι → E →L[𝕜] F}
@[fun_prop]
theorem HasStrictFDerivAt.sum (h : ∀ i ∈ u, HasStrictFDerivAt (A i) (A' i) x) :
HasStrictFDerivAt (fun y => ∑ i ∈ u, A i y) (∑ i ∈ u, A' i) x := by
simp only [hasStrictFDerivAt_iff_isLittleO] at *
convert IsLittleO.sum h
simp [Finset.sum_sub_distrib, ContinuousLinearMap.sum_apply]
theorem HasFDerivAtFilter.sum (h : ∀ i ∈ u, HasFDerivAtFilter (A i) (A' i) x L) :
HasFDerivAtFilter (fun y => ∑ i ∈ u, A i y) (∑ i ∈ u, A' i) x L := by
simp only [hasFDerivAtFilter_iff_isLittleO] at *
convert IsLittleO.sum h
simp [ContinuousLinearMap.sum_apply]
@[fun_prop]
theorem HasFDerivWithinAt.sum (h : ∀ i ∈ u, HasFDerivWithinAt (A i) (A' i) s x) :
HasFDerivWithinAt (fun y => ∑ i ∈ u, A i y) (∑ i ∈ u, A' i) s x :=
HasFDerivAtFilter.sum h
@[fun_prop]
theorem HasFDerivAt.sum (h : ∀ i ∈ u, HasFDerivAt (A i) (A' i) x) :
HasFDerivAt (fun y => ∑ i ∈ u, A i y) (∑ i ∈ u, A' i) x :=
HasFDerivAtFilter.sum h
@[fun_prop]
theorem DifferentiableWithinAt.sum (h : ∀ i ∈ u, DifferentiableWithinAt 𝕜 (A i) s x) :
DifferentiableWithinAt 𝕜 (fun y => ∑ i ∈ u, A i y) s x :=
HasFDerivWithinAt.differentiableWithinAt <|
HasFDerivWithinAt.sum fun i hi => (h i hi).hasFDerivWithinAt
@[simp, fun_prop]
theorem DifferentiableAt.sum (h : ∀ i ∈ u, DifferentiableAt 𝕜 (A i) x) :
DifferentiableAt 𝕜 (fun y => ∑ i ∈ u, A i y) x :=
HasFDerivAt.differentiableAt <| HasFDerivAt.sum fun i hi => (h i hi).hasFDerivAt
@[fun_prop]
theorem DifferentiableOn.sum (h : ∀ i ∈ u, DifferentiableOn 𝕜 (A i) s) :
DifferentiableOn 𝕜 (fun y => ∑ i ∈ u, A i y) s := fun x hx =>
DifferentiableWithinAt.sum fun i hi => h i hi x hx
@[simp, fun_prop]
theorem Differentiable.sum (h : ∀ i ∈ u, Differentiable 𝕜 (A i)) :
Differentiable 𝕜 fun y => ∑ i ∈ u, A i y := fun x => DifferentiableAt.sum fun i hi => h i hi x
theorem fderivWithin_sum (hxs : UniqueDiffWithinAt 𝕜 s x)
(h : ∀ i ∈ u, DifferentiableWithinAt 𝕜 (A i) s x) :
fderivWithin 𝕜 (fun y => ∑ i ∈ u, A i y) s x = ∑ i ∈ u, fderivWithin 𝕜 (A i) s x :=
(HasFDerivWithinAt.sum fun i hi => (h i hi).hasFDerivWithinAt).fderivWithin hxs
theorem fderiv_sum (h : ∀ i ∈ u, DifferentiableAt 𝕜 (A i) x) :
fderiv 𝕜 (fun y => ∑ i ∈ u, A i y) x = ∑ i ∈ u, fderiv 𝕜 (A i) x :=
(HasFDerivAt.sum fun i hi => (h i hi).hasFDerivAt).fderiv
end Sum
section Neg
/-! ### Derivative of the negative of a function -/
@[fun_prop]
theorem HasStrictFDerivAt.neg (h : HasStrictFDerivAt f f' x) :
HasStrictFDerivAt (fun x => -f x) (-f') x :=
(-1 : F →L[𝕜] F).hasStrictFDerivAt.comp x h
theorem HasFDerivAtFilter.neg (h : HasFDerivAtFilter f f' x L) :
HasFDerivAtFilter (fun x => -f x) (-f') x L :=
(-1 : F →L[𝕜] F).hasFDerivAtFilter.comp x h tendsto_map
@[fun_prop]
nonrec theorem HasFDerivWithinAt.neg (h : HasFDerivWithinAt f f' s x) :
HasFDerivWithinAt (fun x => -f x) (-f') s x :=
h.neg
@[fun_prop]
nonrec theorem HasFDerivAt.neg (h : HasFDerivAt f f' x) : HasFDerivAt (fun x => -f x) (-f') x :=
h.neg
@[fun_prop]
theorem DifferentiableWithinAt.neg (h : DifferentiableWithinAt 𝕜 f s x) :
DifferentiableWithinAt 𝕜 (fun y => -f y) s x :=
h.hasFDerivWithinAt.neg.differentiableWithinAt
@[simp]
theorem differentiableWithinAt_neg_iff :
DifferentiableWithinAt 𝕜 (fun y => -f y) s x ↔ DifferentiableWithinAt 𝕜 f s x :=
⟨fun h => by simpa only [neg_neg] using h.neg, fun h => h.neg⟩
@[fun_prop]
theorem DifferentiableAt.neg (h : DifferentiableAt 𝕜 f x) : DifferentiableAt 𝕜 (fun y => -f y) x :=
h.hasFDerivAt.neg.differentiableAt
@[simp]
theorem differentiableAt_neg_iff : DifferentiableAt 𝕜 (fun y => -f y) x ↔ DifferentiableAt 𝕜 f x :=
⟨fun h => by simpa only [neg_neg] using h.neg, fun h => h.neg⟩
@[fun_prop]
theorem DifferentiableOn.neg (h : DifferentiableOn 𝕜 f s) : DifferentiableOn 𝕜 (fun y => -f y) s :=
fun x hx => (h x hx).neg
@[simp]
theorem differentiableOn_neg_iff : DifferentiableOn 𝕜 (fun y => -f y) s ↔ DifferentiableOn 𝕜 f s :=
⟨fun h => by simpa only [neg_neg] using h.neg, fun h => h.neg⟩
@[fun_prop]
theorem Differentiable.neg (h : Differentiable 𝕜 f) : Differentiable 𝕜 fun y => -f y := fun x =>
(h x).neg
@[simp]
theorem differentiable_neg_iff : (Differentiable 𝕜 fun y => -f y) ↔ Differentiable 𝕜 f :=
⟨fun h => by simpa only [neg_neg] using h.neg, fun h => h.neg⟩
theorem fderivWithin_neg (hxs : UniqueDiffWithinAt 𝕜 s x) :
fderivWithin 𝕜 (fun y => -f y) s x = -fderivWithin 𝕜 f s x := by
classical
by_cases h : DifferentiableWithinAt 𝕜 f s x
· exact h.hasFDerivWithinAt.neg.fderivWithin hxs
· rw [fderivWithin_zero_of_not_differentiableWithinAt h,
fderivWithin_zero_of_not_differentiableWithinAt, neg_zero]
simpa
/-- Version of `fderivWithin_neg` where the function is written `-f` instead of `fun y ↦ - f y`. -/
theorem fderivWithin_neg' (hxs : UniqueDiffWithinAt 𝕜 s x) :
fderivWithin 𝕜 (-f) s x = -fderivWithin 𝕜 f s x :=
fderivWithin_neg hxs
@[simp]
theorem fderiv_neg : fderiv 𝕜 (fun y => -f y) x = -fderiv 𝕜 f x := by
simp only [← fderivWithin_univ, fderivWithin_neg uniqueDiffWithinAt_univ]
/-- Version of `fderiv_neg` where the function is written `-f` instead of `fun y ↦ - f y`. -/
theorem fderiv_neg' : fderiv 𝕜 (-f) x = -fderiv 𝕜 f x :=
fderiv_neg
end Neg
section Sub
/-! ### Derivative of the difference of two functions -/
@[fun_prop]
theorem HasStrictFDerivAt.sub (hf : HasStrictFDerivAt f f' x) (hg : HasStrictFDerivAt g g' x) :
HasStrictFDerivAt (fun x => f x - g x) (f' - g') x := by
simpa only [sub_eq_add_neg] using hf.add hg.neg
theorem HasFDerivAtFilter.sub (hf : HasFDerivAtFilter f f' x L) (hg : HasFDerivAtFilter g g' x L) :
HasFDerivAtFilter (fun x => f x - g x) (f' - g') x L := by
simpa only [sub_eq_add_neg] using hf.add hg.neg
@[fun_prop]
nonrec theorem HasFDerivWithinAt.sub (hf : HasFDerivWithinAt f f' s x)
(hg : HasFDerivWithinAt g g' s x) : HasFDerivWithinAt (fun x => f x - g x) (f' - g') s x :=
hf.sub hg
@[fun_prop]
| nonrec theorem HasFDerivAt.sub (hf : HasFDerivAt f f' x) (hg : HasFDerivAt g g' x) :
HasFDerivAt (fun x => f x - g x) (f' - g') x :=
hf.sub hg
@[fun_prop]
theorem DifferentiableWithinAt.sub (hf : DifferentiableWithinAt 𝕜 f s x)
(hg : DifferentiableWithinAt 𝕜 g s x) : DifferentiableWithinAt 𝕜 (fun y => f y - g y) s x :=
| Mathlib/Analysis/Calculus/FDeriv/Add.lean | 478 | 484 |
/-
Copyright (c) 2022 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel
-/
import Mathlib.MeasureTheory.Function.Jacobian
import Mathlib.MeasureTheory.Measure.Lebesgue.Complex
import Mathlib.Analysis.SpecialFunctions.Trigonometric.Deriv
/-!
# Polar coordinates
We define polar coordinates, as a partial homeomorphism in `ℝ^2` between `ℝ^2 - (-∞, 0]` and
`(0, +∞) × (-π, π)`. Its inverse is given by `(r, θ) ↦ (r cos θ, r sin θ)`.
It satisfies the following change of variables formula (see `integral_comp_polarCoord_symm`):
`∫ p in polarCoord.target, p.1 • f (polarCoord.symm p) = ∫ p, f p`
-/
noncomputable section Real
open Real Set MeasureTheory
open scoped ENNReal Real Topology
/-- The polar coordinates partial homeomorphism in `ℝ^2`, mapping `(r cos θ, r sin θ)` to `(r, θ)`.
It is a homeomorphism between `ℝ^2 - (-∞, 0]` and `(0, +∞) × (-π, π)`. -/
@[simps]
def polarCoord : PartialHomeomorph (ℝ × ℝ) (ℝ × ℝ) where
toFun q := (√(q.1 ^ 2 + q.2 ^ 2), Complex.arg (Complex.equivRealProd.symm q))
invFun p := (p.1 * cos p.2, p.1 * sin p.2)
source := {q | 0 < q.1} ∪ {q | q.2 ≠ 0}
target := Ioi (0 : ℝ) ×ˢ Ioo (-π) π
map_target' := by
rintro ⟨r, θ⟩ ⟨hr, hθ⟩
dsimp at hr hθ
rcases eq_or_ne θ 0 with (rfl | h'θ)
· simpa using hr
· right
simp at hr
simpa only [ne_of_gt hr, Ne, mem_setOf_eq, mul_eq_zero, false_or,
sin_eq_zero_iff_of_lt_of_lt hθ.1 hθ.2] using h'θ
map_source' := by
rintro ⟨x, y⟩ hxy
simp only [prodMk_mem_set_prod_eq, mem_Ioi, sqrt_pos, mem_Ioo, Complex.neg_pi_lt_arg,
true_and, Complex.arg_lt_pi_iff]
constructor
· rcases hxy with hxy | hxy
· dsimp at hxy; linarith [sq_pos_of_ne_zero hxy.ne', sq_nonneg y]
· linarith [sq_nonneg x, sq_pos_of_ne_zero hxy]
· rcases hxy with hxy | hxy
· exact Or.inl (le_of_lt hxy)
· exact Or.inr hxy
right_inv' := by
rintro ⟨r, θ⟩ ⟨hr, hθ⟩
ext <;> dsimp at hr hθ ⊢
· conv_rhs => rw [← sqrt_sq (le_of_lt hr), ← one_mul (r ^ 2), ← sin_sq_add_cos_sq θ]
congr 1
ring
· convert Complex.arg_mul_cos_add_sin_mul_I hr ⟨hθ.1, hθ.2.le⟩
simp only [Complex.equivRealProd_symm_apply, Complex.ofReal_mul, Complex.ofReal_cos,
Complex.ofReal_sin]
ring
left_inv' := by
rintro ⟨x, y⟩ _
have A : √(x ^ 2 + y ^ 2) = ‖x + y * Complex.I‖ := by
rw [Complex.norm_def, Complex.normSq_add_mul_I]
have Z := Complex.norm_mul_cos_add_sin_mul_I (x + y * Complex.I)
simp only [← Complex.ofReal_cos, ← Complex.ofReal_sin, mul_add, ← Complex.ofReal_mul, ←
mul_assoc] at Z
simp [A]
open_target := isOpen_Ioi.prod isOpen_Ioo
open_source :=
(isOpen_lt continuous_const continuous_fst).union
(isOpen_ne_fun continuous_snd continuous_const)
continuousOn_invFun := by fun_prop
continuousOn_toFun := by
refine .prodMk (by fun_prop) ?_
have A : MapsTo Complex.equivRealProd.symm ({q : ℝ × ℝ | 0 < q.1} ∪ {q : ℝ × ℝ | q.2 ≠ 0})
Complex.slitPlane := by
rintro ⟨x, y⟩ hxy; simpa only using hxy
refine ContinuousOn.comp (f := Complex.equivRealProd.symm)
(g := Complex.arg) (fun z hz => ?_) ?_ A
· exact (Complex.continuousAt_arg hz).continuousWithinAt
· exact Complex.equivRealProdCLM.symm.continuous.continuousOn
@[fun_prop]
theorem continuous_polarCoord_symm :
Continuous polarCoord.symm :=
.prodMk (by fun_prop) (by fun_prop)
/-- The derivative of `polarCoord.symm`, see `hasFDerivAt_polarCoord_symm`. -/
def fderivPolarCoordSymm (p : ℝ × ℝ) : ℝ × ℝ →L[ℝ] ℝ × ℝ :=
LinearMap.toContinuousLinearMap (Matrix.toLin (Basis.finTwoProd ℝ)
(Basis.finTwoProd ℝ) !![cos p.2, -p.1 * sin p.2; sin p.2, p.1 * cos p.2])
theorem hasFDerivAt_polarCoord_symm (p : ℝ × ℝ) :
HasFDerivAt polarCoord.symm (fderivPolarCoordSymm p) p := by
unfold fderivPolarCoordSymm
rw [Matrix.toLin_finTwoProd_toContinuousLinearMap]
convert HasFDerivAt.prodMk (𝕜 := ℝ)
(hasFDerivAt_fst.mul ((hasDerivAt_cos p.2).comp_hasFDerivAt p hasFDerivAt_snd))
(hasFDerivAt_fst.mul ((hasDerivAt_sin p.2).comp_hasFDerivAt p hasFDerivAt_snd)) using 2 <;>
simp [smul_smul, add_comm, neg_mul, smul_neg, neg_smul _ (ContinuousLinearMap.snd ℝ ℝ ℝ)]
theorem det_fderivPolarCoordSymm (p : ℝ × ℝ) :
(fderivPolarCoordSymm p).det = p.1 := by
conv_rhs => rw [← one_mul p.1, ← cos_sq_add_sin_sq p.2]
unfold fderivPolarCoordSymm
simp only [neg_mul, LinearMap.det_toContinuousLinearMap, LinearMap.det_toLin,
Matrix.det_fin_two_of, sub_neg_eq_add]
ring
-- Porting note: this instance is needed but not automatically synthesised
instance : Measure.IsAddHaarMeasure volume (G := ℝ × ℝ) :=
Measure.prod.instIsAddHaarMeasure _ _
theorem polarCoord_source_ae_eq_univ : polarCoord.source =ᵐ[volume] univ := by
have A : polarCoord.sourceᶜ ⊆ LinearMap.ker (LinearMap.snd ℝ ℝ ℝ) := by
intro x hx
simp only [polarCoord_source, compl_union, mem_inter_iff, mem_compl_iff, mem_setOf_eq, not_lt,
Classical.not_not] at hx
exact hx.2
have B : volume (LinearMap.ker (LinearMap.snd ℝ ℝ ℝ) : Set (ℝ × ℝ)) = 0 := by
| apply Measure.addHaar_submodule
rw [Ne, LinearMap.ker_eq_top]
intro h
have : (LinearMap.snd ℝ ℝ ℝ) (0, 1) = (0 : ℝ × ℝ →ₗ[ℝ] ℝ) (0, 1) := by rw [h]
simp at this
simp only [ae_eq_univ]
exact le_antisymm ((measure_mono A).trans (le_of_eq B)) bot_le
theorem integral_comp_polarCoord_symm {E : Type*} [NormedAddCommGroup E] [NormedSpace ℝ E]
(f : ℝ × ℝ → E) :
(∫ p in polarCoord.target, p.1 • f (polarCoord.symm p)) = ∫ p, f p := by
symm
calc
∫ p, f p = ∫ p in polarCoord.source, f p := by
rw [← setIntegral_univ]
apply setIntegral_congr_set
exact polarCoord_source_ae_eq_univ.symm
_ = ∫ p in polarCoord.target, |p.1| • f (polarCoord.symm p) := by
rw [← PartialHomeomorph.symm_target, integral_target_eq_integral_abs_det_fderiv_smul volume
(fun p _ ↦ hasFDerivAt_polarCoord_symm p), PartialHomeomorph.symm_source]
simp_rw [det_fderivPolarCoordSymm]
_ = ∫ p in polarCoord.target, p.1 • f (polarCoord.symm p) := by
apply setIntegral_congr_fun polarCoord.open_target.measurableSet fun x hx => ?_
rw [abs_of_pos hx.1]
theorem lintegral_comp_polarCoord_symm (f : ℝ × ℝ → ℝ≥0∞) :
| Mathlib/Analysis/SpecialFunctions/PolarCoord.lean | 126 | 151 |
/-
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, Simon Hudon, Mario Carneiro
-/
import Aesop
import Mathlib.Algebra.Group.Defs
import Mathlib.Data.Nat.Init
import Mathlib.Data.Int.Init
import Mathlib.Logic.Function.Iterate
import Mathlib.Tactic.SimpRw
import Mathlib.Tactic.SplitIfs
/-!
# Basic lemmas about semigroups, monoids, and groups
This file lists various basic lemmas about semigroups, monoids, and groups. Most proofs are
one-liners from the corresponding axioms. For the definitions of semigroups, monoids and groups, see
`Algebra/Group/Defs.lean`.
-/
assert_not_exists MonoidWithZero DenselyOrdered
open Function
variable {α β G M : Type*}
section ite
variable [Pow α β]
@[to_additive (attr := simp) dite_smul]
lemma pow_dite (p : Prop) [Decidable p] (a : α) (b : p → β) (c : ¬ p → β) :
a ^ (if h : p then b h else c h) = if h : p then a ^ b h else a ^ c h := by split_ifs <;> rfl
@[to_additive (attr := simp) smul_dite]
lemma dite_pow (p : Prop) [Decidable p] (a : p → α) (b : ¬ p → α) (c : β) :
(if h : p then a h else b h) ^ c = if h : p then a h ^ c else b h ^ c := by split_ifs <;> rfl
@[to_additive (attr := simp) ite_smul]
lemma pow_ite (p : Prop) [Decidable p] (a : α) (b c : β) :
a ^ (if p then b else c) = if p then a ^ b else a ^ c := pow_dite _ _ _ _
@[to_additive (attr := simp) smul_ite]
lemma ite_pow (p : Prop) [Decidable p] (a b : α) (c : β) :
(if p then a else b) ^ c = if p then a ^ c else b ^ c := dite_pow _ _ _ _
set_option linter.existingAttributeWarning false in
attribute [to_additive (attr := simp)] dite_smul smul_dite ite_smul smul_ite
end ite
section Semigroup
variable [Semigroup α]
@[to_additive]
instance Semigroup.to_isAssociative : Std.Associative (α := α) (· * ·) := ⟨mul_assoc⟩
/-- Composing two multiplications on the left by `y` then `x`
is equal to a multiplication on the left by `x * y`.
-/
@[to_additive (attr := simp) "Composing two additions on the left by `y` then `x`
is equal to an addition on the left by `x + y`."]
theorem comp_mul_left (x y : α) : (x * ·) ∘ (y * ·) = (x * y * ·) := by
ext z
simp [mul_assoc]
/-- Composing two multiplications on the right by `y` and `x`
is equal to a multiplication on the right by `y * x`.
-/
@[to_additive (attr := simp) "Composing two additions on the right by `y` and `x`
is equal to an addition on the right by `y + x`."]
theorem comp_mul_right (x y : α) : (· * x) ∘ (· * y) = (· * (y * x)) := by
ext z
simp [mul_assoc]
end Semigroup
@[to_additive]
instance CommMagma.to_isCommutative [CommMagma G] : Std.Commutative (α := G) (· * ·) := ⟨mul_comm⟩
section MulOneClass
variable [MulOneClass M]
@[to_additive]
theorem ite_mul_one {P : Prop} [Decidable P] {a b : M} :
ite P (a * b) 1 = ite P a 1 * ite P b 1 := by
by_cases h : P <;> simp [h]
@[to_additive]
theorem ite_one_mul {P : Prop} [Decidable P] {a b : M} :
ite P 1 (a * b) = ite P 1 a * ite P 1 b := by
by_cases h : P <;> simp [h]
@[to_additive]
theorem eq_one_iff_eq_one_of_mul_eq_one {a b : M} (h : a * b = 1) : a = 1 ↔ b = 1 := by
constructor <;> (rintro rfl; simpa using h)
@[to_additive]
theorem one_mul_eq_id : ((1 : M) * ·) = id :=
funext one_mul
@[to_additive]
theorem mul_one_eq_id : (· * (1 : M)) = id :=
funext mul_one
end MulOneClass
section CommSemigroup
variable [CommSemigroup G]
@[to_additive]
theorem mul_left_comm (a b c : G) : a * (b * c) = b * (a * c) := by
rw [← mul_assoc, mul_comm a, mul_assoc]
@[to_additive]
theorem mul_right_comm (a b c : G) : a * b * c = a * c * b := by
rw [mul_assoc, mul_comm b, mul_assoc]
@[to_additive]
theorem mul_mul_mul_comm (a b c d : G) : a * b * (c * d) = a * c * (b * d) := by
simp only [mul_left_comm, mul_assoc]
@[to_additive]
theorem mul_rotate (a b c : G) : a * b * c = b * c * a := by
simp only [mul_left_comm, mul_comm]
@[to_additive]
theorem mul_rotate' (a b c : G) : a * (b * c) = b * (c * a) := by
simp only [mul_left_comm, mul_comm]
end CommSemigroup
attribute [local simp] mul_assoc sub_eq_add_neg
section Monoid
variable [Monoid M] {a b : M} {m n : ℕ}
@[to_additive boole_nsmul]
lemma pow_boole (P : Prop) [Decidable P] (a : M) :
(a ^ if P then 1 else 0) = if P then a else 1 := by simp only [pow_ite, pow_one, pow_zero]
@[to_additive nsmul_add_sub_nsmul]
lemma pow_mul_pow_sub (a : M) (h : m ≤ n) : a ^ m * a ^ (n - m) = a ^ n := by
rw [← pow_add, Nat.add_comm, Nat.sub_add_cancel h]
@[to_additive sub_nsmul_nsmul_add]
lemma pow_sub_mul_pow (a : M) (h : m ≤ n) : a ^ (n - m) * a ^ m = a ^ n := by
rw [← pow_add, Nat.sub_add_cancel h]
@[to_additive sub_one_nsmul_add]
lemma mul_pow_sub_one (hn : n ≠ 0) (a : M) : a * a ^ (n - 1) = a ^ n := by
rw [← pow_succ', Nat.sub_add_cancel <| Nat.one_le_iff_ne_zero.2 hn]
@[to_additive add_sub_one_nsmul]
lemma pow_sub_one_mul (hn : n ≠ 0) (a : M) : a ^ (n - 1) * a = a ^ n := by
rw [← pow_succ, Nat.sub_add_cancel <| Nat.one_le_iff_ne_zero.2 hn]
/-- If `x ^ n = 1`, then `x ^ m` is the same as `x ^ (m % n)` -/
@[to_additive nsmul_eq_mod_nsmul "If `n • x = 0`, then `m • x` is the same as `(m % n) • x`"]
lemma pow_eq_pow_mod (m : ℕ) (ha : a ^ n = 1) : a ^ m = a ^ (m % n) := by
calc
a ^ m = a ^ (m % n + n * (m / n)) := by rw [Nat.mod_add_div]
_ = a ^ (m % n) := by simp [pow_add, pow_mul, ha]
@[to_additive] lemma pow_mul_pow_eq_one : ∀ n, a * b = 1 → a ^ n * b ^ n = 1
| 0, _ => by simp
| n + 1, h =>
calc
a ^ n.succ * b ^ n.succ = a ^ n * a * (b * b ^ n) := by rw [pow_succ, pow_succ']
_ = a ^ n * (a * b) * b ^ n := by simp only [mul_assoc]
_ = 1 := by simp [h, pow_mul_pow_eq_one]
@[to_additive (attr := simp)]
lemma mul_left_iterate (a : M) : ∀ n : ℕ, (a * ·)^[n] = (a ^ n * ·)
| 0 => by ext; simp
| n + 1 => by ext; simp [pow_succ, mul_left_iterate]
@[to_additive (attr := simp)]
lemma mul_right_iterate (a : M) : ∀ n : ℕ, (· * a)^[n] = (· * a ^ n)
| 0 => by ext; simp
| n + 1 => by ext; simp [pow_succ', mul_right_iterate]
@[to_additive]
lemma mul_left_iterate_apply_one (a : M) : (a * ·)^[n] 1 = a ^ n := by simp [mul_right_iterate]
@[to_additive]
lemma mul_right_iterate_apply_one (a : M) : (· * a)^[n] 1 = a ^ n := by simp [mul_right_iterate]
@[to_additive (attr := simp)]
lemma pow_iterate (k : ℕ) : ∀ n : ℕ, (fun x : M ↦ x ^ k)^[n] = (· ^ k ^ n)
| 0 => by ext; simp
| n + 1 => by ext; simp [pow_iterate, Nat.pow_succ', pow_mul]
end Monoid
section CommMonoid
variable [CommMonoid M] {x y z : M}
@[to_additive]
theorem inv_unique (hy : x * y = 1) (hz : x * z = 1) : y = z :=
left_inv_eq_right_inv (Trans.trans (mul_comm _ _) hy) hz
@[to_additive nsmul_add] lemma mul_pow (a b : M) : ∀ n, (a * b) ^ n = a ^ n * b ^ n
| 0 => by rw [pow_zero, pow_zero, pow_zero, one_mul]
| n + 1 => by rw [pow_succ', pow_succ', pow_succ', mul_pow, mul_mul_mul_comm]
end CommMonoid
section LeftCancelMonoid
variable [Monoid M] [IsLeftCancelMul M] {a b : M}
@[to_additive (attr := simp)]
theorem mul_eq_left : a * b = a ↔ b = 1 := calc
a * b = a ↔ a * b = a * 1 := by rw [mul_one]
_ ↔ b = 1 := mul_left_cancel_iff
@[deprecated (since := "2025-03-05")] alias mul_right_eq_self := mul_eq_left
@[deprecated (since := "2025-03-05")] alias add_right_eq_self := add_eq_left
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] mul_right_eq_self
@[to_additive (attr := simp)]
theorem left_eq_mul : a = a * b ↔ b = 1 :=
eq_comm.trans mul_eq_left
@[deprecated (since := "2025-03-05")] alias self_eq_mul_right := left_eq_mul
@[deprecated (since := "2025-03-05")] alias self_eq_add_right := left_eq_add
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] self_eq_mul_right
@[to_additive]
theorem mul_ne_left : a * b ≠ a ↔ b ≠ 1 := mul_eq_left.not
@[deprecated (since := "2025-03-05")] alias mul_right_ne_self := mul_ne_left
@[deprecated (since := "2025-03-05")] alias add_right_ne_self := add_ne_left
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] mul_right_ne_self
@[to_additive]
theorem left_ne_mul : a ≠ a * b ↔ b ≠ 1 := left_eq_mul.not
@[deprecated (since := "2025-03-05")] alias self_ne_mul_right := left_ne_mul
@[deprecated (since := "2025-03-05")] alias self_ne_add_right := left_ne_add
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] self_ne_mul_right
end LeftCancelMonoid
section RightCancelMonoid
variable [RightCancelMonoid M] {a b : M}
@[to_additive (attr := simp)]
theorem mul_eq_right : a * b = b ↔ a = 1 := calc
a * b = b ↔ a * b = 1 * b := by rw [one_mul]
_ ↔ a = 1 := mul_right_cancel_iff
@[deprecated (since := "2025-03-05")] alias mul_left_eq_self := mul_eq_right
@[deprecated (since := "2025-03-05")] alias add_left_eq_self := add_eq_right
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] mul_left_eq_self
@[to_additive (attr := simp)]
theorem right_eq_mul : b = a * b ↔ a = 1 :=
eq_comm.trans mul_eq_right
@[deprecated (since := "2025-03-05")] alias self_eq_mul_left := right_eq_mul
@[deprecated (since := "2025-03-05")] alias self_eq_add_left := right_eq_add
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] self_eq_mul_left
@[to_additive]
theorem mul_ne_right : a * b ≠ b ↔ a ≠ 1 := mul_eq_right.not
@[deprecated (since := "2025-03-05")] alias mul_left_ne_self := mul_ne_right
@[deprecated (since := "2025-03-05")] alias add_left_ne_self := add_ne_right
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] mul_left_ne_self
@[to_additive]
theorem right_ne_mul : b ≠ a * b ↔ a ≠ 1 := right_eq_mul.not
@[deprecated (since := "2025-03-05")] alias self_ne_mul_left := right_ne_mul
@[deprecated (since := "2025-03-05")] alias self_ne_add_left := right_ne_add
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] self_ne_mul_left
end RightCancelMonoid
section CancelCommMonoid
variable [CancelCommMonoid α] {a b c d : α}
@[to_additive] lemma eq_iff_eq_of_mul_eq_mul (h : a * b = c * d) : a = c ↔ b = d := by aesop
@[to_additive] lemma ne_iff_ne_of_mul_eq_mul (h : a * b = c * d) : a ≠ c ↔ b ≠ d := by aesop
end CancelCommMonoid
section InvolutiveInv
variable [InvolutiveInv G] {a b : G}
@[to_additive (attr := simp)]
theorem inv_involutive : Function.Involutive (Inv.inv : G → G) :=
inv_inv
@[to_additive (attr := simp)]
theorem inv_surjective : Function.Surjective (Inv.inv : G → G) :=
inv_involutive.surjective
@[to_additive]
theorem inv_injective : Function.Injective (Inv.inv : G → G) :=
inv_involutive.injective
@[to_additive (attr := simp)]
theorem inv_inj : a⁻¹ = b⁻¹ ↔ a = b :=
inv_injective.eq_iff
@[to_additive]
theorem inv_eq_iff_eq_inv : a⁻¹ = b ↔ a = b⁻¹ :=
⟨fun h => h ▸ (inv_inv a).symm, fun h => h.symm ▸ inv_inv b⟩
variable (G)
@[to_additive]
theorem inv_comp_inv : Inv.inv ∘ Inv.inv = @id G :=
inv_involutive.comp_self
@[to_additive]
theorem leftInverse_inv : LeftInverse (fun a : G ↦ a⁻¹) fun a ↦ a⁻¹ :=
inv_inv
@[to_additive]
theorem rightInverse_inv : RightInverse (fun a : G ↦ a⁻¹) fun a ↦ a⁻¹ :=
inv_inv
end InvolutiveInv
section DivInvMonoid
variable [DivInvMonoid G]
@[to_additive]
theorem mul_one_div (x y : G) : x * (1 / y) = x / y := by
rw [div_eq_mul_inv, one_mul, div_eq_mul_inv]
@[to_additive, field_simps] -- The attributes are out of order on purpose
theorem mul_div_assoc' (a b c : G) : a * (b / c) = a * b / c :=
(mul_div_assoc _ _ _).symm
@[to_additive]
theorem mul_div (a b c : G) : a * (b / c) = a * b / c := by simp only [mul_assoc, div_eq_mul_inv]
@[to_additive]
theorem div_eq_mul_one_div (a b : G) : a / b = a * (1 / b) := by rw [div_eq_mul_inv, one_div]
end DivInvMonoid
section DivInvOneMonoid
variable [DivInvOneMonoid G]
@[to_additive (attr := simp)]
theorem div_one (a : G) : a / 1 = a := by simp [div_eq_mul_inv]
@[to_additive]
theorem one_div_one : (1 : G) / 1 = 1 :=
div_one _
end DivInvOneMonoid
section DivisionMonoid
variable [DivisionMonoid α] {a b c d : α}
attribute [local simp] mul_assoc div_eq_mul_inv
@[to_additive]
theorem eq_inv_of_mul_eq_one_right (h : a * b = 1) : b = a⁻¹ :=
(inv_eq_of_mul_eq_one_right h).symm
@[to_additive]
theorem eq_one_div_of_mul_eq_one_left (h : b * a = 1) : b = 1 / a := by
rw [eq_inv_of_mul_eq_one_left h, one_div]
@[to_additive]
theorem eq_one_div_of_mul_eq_one_right (h : a * b = 1) : b = 1 / a := by
rw [eq_inv_of_mul_eq_one_right h, one_div]
@[to_additive]
theorem eq_of_div_eq_one (h : a / b = 1) : a = b :=
inv_injective <| inv_eq_of_mul_eq_one_right <| by rwa [← div_eq_mul_inv]
@[to_additive]
lemma eq_of_inv_mul_eq_one (h : a⁻¹ * b = 1) : a = b := by simpa using eq_inv_of_mul_eq_one_left h
@[to_additive]
lemma eq_of_mul_inv_eq_one (h : a * b⁻¹ = 1) : a = b := by simpa using eq_inv_of_mul_eq_one_left h
@[to_additive]
theorem div_ne_one_of_ne : a ≠ b → a / b ≠ 1 :=
mt eq_of_div_eq_one
variable (a b c)
@[to_additive]
theorem one_div_mul_one_div_rev : 1 / a * (1 / b) = 1 / (b * a) := by simp
@[to_additive]
theorem inv_div_left : a⁻¹ / b = (b * a)⁻¹ := by simp
@[to_additive (attr := simp)]
theorem inv_div : (a / b)⁻¹ = b / a := by simp
@[to_additive]
theorem one_div_div : 1 / (a / b) = b / a := by simp
@[to_additive]
theorem one_div_one_div : 1 / (1 / a) = a := by simp
@[to_additive]
theorem div_eq_div_iff_comm : a / b = c / d ↔ b / a = d / c :=
inv_inj.symm.trans <| by simp only [inv_div]
@[to_additive]
instance (priority := 100) DivisionMonoid.toDivInvOneMonoid : DivInvOneMonoid α :=
{ DivisionMonoid.toDivInvMonoid with
inv_one := by simpa only [one_div, inv_inv] using (inv_div (1 : α) 1).symm }
@[to_additive (attr := simp)]
lemma inv_pow (a : α) : ∀ n : ℕ, a⁻¹ ^ n = (a ^ n)⁻¹
| 0 => by rw [pow_zero, pow_zero, inv_one]
| n + 1 => by rw [pow_succ', pow_succ, inv_pow _ n, mul_inv_rev]
-- the attributes are intentionally out of order. `smul_zero` proves `zsmul_zero`.
@[to_additive zsmul_zero, simp]
lemma one_zpow : ∀ n : ℤ, (1 : α) ^ n = 1
| (n : ℕ) => by rw [zpow_natCast, one_pow]
| .negSucc n => by rw [zpow_negSucc, one_pow, inv_one]
@[to_additive (attr := simp) neg_zsmul]
lemma zpow_neg (a : α) : ∀ n : ℤ, a ^ (-n) = (a ^ n)⁻¹
| (_ + 1 : ℕ) => DivInvMonoid.zpow_neg' _ _
| 0 => by simp
| Int.negSucc n => by
rw [zpow_negSucc, inv_inv, ← zpow_natCast]
rfl
@[to_additive neg_one_zsmul_add]
lemma mul_zpow_neg_one (a b : α) : (a * b) ^ (-1 : ℤ) = b ^ (-1 : ℤ) * a ^ (-1 : ℤ) := by
simp only [zpow_neg, zpow_one, mul_inv_rev]
@[to_additive zsmul_neg]
lemma inv_zpow (a : α) : ∀ n : ℤ, a⁻¹ ^ n = (a ^ n)⁻¹
| (n : ℕ) => by rw [zpow_natCast, zpow_natCast, inv_pow]
| .negSucc n => by rw [zpow_negSucc, zpow_negSucc, inv_pow]
@[to_additive (attr := simp) zsmul_neg']
lemma inv_zpow' (a : α) (n : ℤ) : a⁻¹ ^ n = a ^ (-n) := by rw [inv_zpow, zpow_neg]
@[to_additive nsmul_zero_sub]
lemma one_div_pow (a : α) (n : ℕ) : (1 / a) ^ n = 1 / a ^ n := by simp only [one_div, inv_pow]
@[to_additive zsmul_zero_sub]
lemma one_div_zpow (a : α) (n : ℤ) : (1 / a) ^ n = 1 / a ^ n := by simp only [one_div, inv_zpow]
variable {a b c}
@[to_additive (attr := simp)]
theorem inv_eq_one : a⁻¹ = 1 ↔ a = 1 :=
inv_injective.eq_iff' inv_one
@[to_additive (attr := simp)]
theorem one_eq_inv : 1 = a⁻¹ ↔ a = 1 :=
eq_comm.trans inv_eq_one
@[to_additive]
theorem inv_ne_one : a⁻¹ ≠ 1 ↔ a ≠ 1 :=
inv_eq_one.not
@[to_additive]
theorem eq_of_one_div_eq_one_div (h : 1 / a = 1 / b) : a = b := by
rw [← one_div_one_div a, h, one_div_one_div]
-- Note that `mul_zsmul` and `zpow_mul` have the primes swapped
-- when additivised since their argument order,
-- and therefore the more "natural" choice of lemma, is reversed.
@[to_additive mul_zsmul'] lemma zpow_mul (a : α) : ∀ m n : ℤ, a ^ (m * n) = (a ^ m) ^ n
| (m : ℕ), (n : ℕ) => by
rw [zpow_natCast, zpow_natCast, ← pow_mul, ← zpow_natCast]
rfl
| (m : ℕ), .negSucc n => by
rw [zpow_natCast, zpow_negSucc, ← pow_mul, Int.ofNat_mul_negSucc, zpow_neg, inv_inj,
← zpow_natCast]
| .negSucc m, (n : ℕ) => by
rw [zpow_natCast, zpow_negSucc, ← inv_pow, ← pow_mul, Int.negSucc_mul_ofNat, zpow_neg, inv_pow,
inv_inj, ← zpow_natCast]
| .negSucc m, .negSucc n => by
rw [zpow_negSucc, zpow_negSucc, Int.negSucc_mul_negSucc, inv_pow, inv_inv, ← pow_mul, ←
zpow_natCast]
rfl
@[to_additive mul_zsmul]
lemma zpow_mul' (a : α) (m n : ℤ) : a ^ (m * n) = (a ^ n) ^ m := by rw [Int.mul_comm, zpow_mul]
@[to_additive]
theorem zpow_comm (a : α) (m n : ℤ) : (a ^ m) ^ n = (a ^ n) ^ m := by rw [← zpow_mul, zpow_mul']
variable (a b c)
@[to_additive, field_simps] -- The attributes are out of order on purpose
theorem div_div_eq_mul_div : a / (b / c) = a * c / b := by simp
@[to_additive (attr := simp)]
theorem div_inv_eq_mul : a / b⁻¹ = a * b := by simp
@[to_additive]
theorem div_mul_eq_div_div_swap : a / (b * c) = a / c / b := by
simp only [mul_assoc, mul_inv_rev, div_eq_mul_inv]
end DivisionMonoid
section DivisionCommMonoid
variable [DivisionCommMonoid α] (a b c d : α)
attribute [local simp] mul_assoc mul_comm mul_left_comm div_eq_mul_inv
@[to_additive neg_add]
theorem mul_inv : (a * b)⁻¹ = a⁻¹ * b⁻¹ := by simp
@[to_additive]
theorem inv_div' : (a / b)⁻¹ = a⁻¹ / b⁻¹ := by simp
@[to_additive]
theorem div_eq_inv_mul : a / b = b⁻¹ * a := by simp
@[to_additive]
theorem inv_mul_eq_div : a⁻¹ * b = b / a := by simp
@[to_additive] lemma inv_div_comm (a b : α) : a⁻¹ / b = b⁻¹ / a := by simp
@[to_additive]
theorem inv_mul' : (a * b)⁻¹ = a⁻¹ / b := by simp
@[to_additive]
theorem inv_div_inv : a⁻¹ / b⁻¹ = b / a := by simp
@[to_additive]
theorem inv_inv_div_inv : (a⁻¹ / b⁻¹)⁻¹ = a / b := by simp
@[to_additive]
theorem one_div_mul_one_div : 1 / a * (1 / b) = 1 / (a * b) := by simp
@[to_additive]
theorem div_right_comm : a / b / c = a / c / b := by simp
@[to_additive, field_simps]
theorem div_div : a / b / c = a / (b * c) := by simp
@[to_additive]
theorem div_mul : a / b * c = a / (b / c) := by simp
@[to_additive]
theorem mul_div_left_comm : a * (b / c) = b * (a / c) := by simp
@[to_additive]
theorem mul_div_right_comm : a * b / c = a / c * b := by simp
@[to_additive]
theorem div_mul_eq_div_div : a / (b * c) = a / b / c := by simp
@[to_additive, field_simps]
theorem div_mul_eq_mul_div : a / b * c = a * c / b := by simp
@[to_additive]
theorem one_div_mul_eq_div : 1 / a * b = b / a := by simp
@[to_additive]
theorem mul_comm_div : a / b * c = a * (c / b) := by simp
@[to_additive]
theorem div_mul_comm : a / b * c = c / b * a := by simp
@[to_additive]
theorem div_mul_eq_div_mul_one_div : a / (b * c) = a / b * (1 / c) := by simp
@[to_additive]
theorem div_div_div_eq : a / b / (c / d) = a * d / (b * c) := by simp
@[to_additive]
theorem div_div_div_comm : a / b / (c / d) = a / c / (b / d) := by simp
@[to_additive]
theorem div_mul_div_comm : a / b * (c / d) = a * c / (b * d) := by simp
@[to_additive]
theorem mul_div_mul_comm : a * b / (c * d) = a / c * (b / d) := by simp
@[to_additive zsmul_add] lemma mul_zpow : ∀ n : ℤ, (a * b) ^ n = a ^ n * b ^ n
| (n : ℕ) => by simp_rw [zpow_natCast, mul_pow]
| .negSucc n => by simp_rw [zpow_negSucc, ← inv_pow, mul_inv, mul_pow]
@[to_additive nsmul_sub]
lemma div_pow (a b : α) (n : ℕ) : (a / b) ^ n = a ^ n / b ^ n := by
simp only [div_eq_mul_inv, mul_pow, inv_pow]
@[to_additive zsmul_sub]
lemma div_zpow (a b : α) (n : ℤ) : (a / b) ^ n = a ^ n / b ^ n := by
simp only [div_eq_mul_inv, mul_zpow, inv_zpow]
attribute [field_simps] div_pow div_zpow
end DivisionCommMonoid
section Group
variable [Group G] {a b c d : G} {n : ℤ}
@[to_additive (attr := simp)]
theorem div_eq_inv_self : a / b = b⁻¹ ↔ a = 1 := by rw [div_eq_mul_inv, mul_eq_right]
@[to_additive]
theorem mul_left_surjective (a : G) : Surjective (a * ·) :=
fun x ↦ ⟨a⁻¹ * x, mul_inv_cancel_left a x⟩
@[to_additive]
theorem mul_right_surjective (a : G) : Function.Surjective fun x ↦ x * a := fun x ↦
⟨x * a⁻¹, inv_mul_cancel_right x a⟩
@[to_additive]
theorem eq_mul_inv_of_mul_eq (h : a * c = b) : a = b * c⁻¹ := by simp [h.symm]
@[to_additive]
theorem eq_inv_mul_of_mul_eq (h : b * a = c) : a = b⁻¹ * c := by simp [h.symm]
@[to_additive]
theorem inv_mul_eq_of_eq_mul (h : b = a * c) : a⁻¹ * b = c := by simp [h]
@[to_additive]
theorem mul_inv_eq_of_eq_mul (h : a = c * b) : a * b⁻¹ = c := by simp [h]
@[to_additive]
theorem eq_mul_of_mul_inv_eq (h : a * c⁻¹ = b) : a = b * c := by simp [h.symm]
@[to_additive]
theorem eq_mul_of_inv_mul_eq (h : b⁻¹ * a = c) : a = b * c := by simp [h.symm, mul_inv_cancel_left]
@[to_additive]
theorem mul_eq_of_eq_inv_mul (h : b = a⁻¹ * c) : a * b = c := by rw [h, mul_inv_cancel_left]
@[to_additive]
theorem mul_eq_of_eq_mul_inv (h : a = c * b⁻¹) : a * b = c := by simp [h]
@[to_additive]
theorem mul_eq_one_iff_eq_inv : a * b = 1 ↔ a = b⁻¹ :=
⟨eq_inv_of_mul_eq_one_left, fun h ↦ by rw [h, inv_mul_cancel]⟩
@[to_additive]
theorem mul_eq_one_iff_inv_eq : a * b = 1 ↔ a⁻¹ = b := by
rw [mul_eq_one_iff_eq_inv, inv_eq_iff_eq_inv]
/-- Variant of `mul_eq_one_iff_eq_inv` with swapped equality. -/
@[to_additive]
theorem mul_eq_one_iff_eq_inv' : a * b = 1 ↔ b = a⁻¹ := by
rw [mul_eq_one_iff_inv_eq, eq_comm]
/-- Variant of `mul_eq_one_iff_inv_eq` with swapped equality. -/
@[to_additive]
theorem mul_eq_one_iff_inv_eq' : a * b = 1 ↔ b⁻¹ = a := by
rw [mul_eq_one_iff_eq_inv, eq_comm]
@[to_additive]
theorem eq_inv_iff_mul_eq_one : a = b⁻¹ ↔ a * b = 1 :=
mul_eq_one_iff_eq_inv.symm
@[to_additive]
theorem inv_eq_iff_mul_eq_one : a⁻¹ = b ↔ a * b = 1 :=
mul_eq_one_iff_inv_eq.symm
@[to_additive]
theorem eq_mul_inv_iff_mul_eq : a = b * c⁻¹ ↔ a * c = b :=
⟨fun h ↦ by rw [h, inv_mul_cancel_right], fun h ↦ by rw [← h, mul_inv_cancel_right]⟩
@[to_additive]
theorem eq_inv_mul_iff_mul_eq : a = b⁻¹ * c ↔ b * a = c :=
⟨fun h ↦ by rw [h, mul_inv_cancel_left], fun h ↦ by rw [← h, inv_mul_cancel_left]⟩
@[to_additive]
theorem inv_mul_eq_iff_eq_mul : a⁻¹ * b = c ↔ b = a * c :=
⟨fun h ↦ by rw [← h, mul_inv_cancel_left], fun h ↦ by rw [h, inv_mul_cancel_left]⟩
@[to_additive]
theorem mul_inv_eq_iff_eq_mul : a * b⁻¹ = c ↔ a = c * b :=
⟨fun h ↦ by rw [← h, inv_mul_cancel_right], fun h ↦ by rw [h, mul_inv_cancel_right]⟩
@[to_additive]
theorem mul_inv_eq_one : a * b⁻¹ = 1 ↔ a = b := by rw [mul_eq_one_iff_eq_inv, inv_inv]
@[to_additive]
theorem inv_mul_eq_one : a⁻¹ * b = 1 ↔ a = b := by rw [mul_eq_one_iff_eq_inv, inv_inj]
@[to_additive (attr := simp)]
theorem conj_eq_one_iff : a * b * a⁻¹ = 1 ↔ b = 1 := by
rw [mul_inv_eq_one, mul_eq_left]
@[to_additive]
theorem div_left_injective : Function.Injective fun a ↦ a / b := by
-- FIXME this could be by `simpa`, but it fails. This is probably a bug in `simpa`.
simp only [div_eq_mul_inv]
exact fun a a' h ↦ mul_left_injective b⁻¹ h
@[to_additive]
theorem div_right_injective : Function.Injective fun a ↦ b / a := by
-- FIXME see above
simp only [div_eq_mul_inv]
exact fun a a' h ↦ inv_injective (mul_right_injective b h)
@[to_additive (attr := simp)]
lemma div_mul_cancel_right (a b : G) : a / (b * a) = b⁻¹ := by rw [← inv_div, mul_div_cancel_right]
@[to_additive (attr := simp)]
theorem mul_div_mul_right_eq_div (a b c : G) : a * c / (b * c) = a / b := by
rw [div_mul_eq_div_div_swap]; simp only [mul_left_inj, eq_self_iff_true, mul_div_cancel_right]
@[to_additive eq_sub_of_add_eq]
theorem eq_div_of_mul_eq' (h : a * c = b) : a = b / c := by simp [← h]
@[to_additive sub_eq_of_eq_add]
theorem div_eq_of_eq_mul'' (h : a = c * b) : a / b = c := by simp [h]
@[to_additive]
theorem eq_mul_of_div_eq (h : a / c = b) : a = b * c := by simp [← h]
@[to_additive]
theorem mul_eq_of_eq_div (h : a = c / b) : a * b = c := by simp [h]
@[to_additive (attr := simp)]
theorem div_right_inj : a / b = a / c ↔ b = c :=
div_right_injective.eq_iff
@[to_additive (attr := simp)]
theorem div_left_inj : b / a = c / a ↔ b = c := by
rw [div_eq_mul_inv, div_eq_mul_inv]
exact mul_left_inj _
@[to_additive (attr := simp)]
theorem div_mul_div_cancel (a b c : G) : a / b * (b / c) = a / c := by
rw [← mul_div_assoc, div_mul_cancel]
@[to_additive (attr := simp)]
theorem div_div_div_cancel_right (a b c : G) : a / c / (b / c) = a / b := by
rw [← inv_div c b, div_inv_eq_mul, div_mul_div_cancel]
@[to_additive]
theorem div_eq_one : a / b = 1 ↔ a = b :=
⟨eq_of_div_eq_one, fun h ↦ by rw [h, div_self']⟩
alias ⟨_, div_eq_one_of_eq⟩ := div_eq_one
alias ⟨_, sub_eq_zero_of_eq⟩ := sub_eq_zero
@[to_additive]
theorem div_ne_one : a / b ≠ 1 ↔ a ≠ b :=
not_congr div_eq_one
@[to_additive (attr := simp)]
theorem div_eq_self : a / b = a ↔ b = 1 := by rw [div_eq_mul_inv, mul_eq_left, inv_eq_one]
@[to_additive eq_sub_iff_add_eq]
theorem eq_div_iff_mul_eq' : a = b / c ↔ a * c = b := by rw [div_eq_mul_inv, eq_mul_inv_iff_mul_eq]
@[to_additive]
theorem div_eq_iff_eq_mul : a / b = c ↔ a = c * b := by rw [div_eq_mul_inv, mul_inv_eq_iff_eq_mul]
@[to_additive]
theorem eq_iff_eq_of_div_eq_div (H : a / b = c / d) : a = b ↔ c = d := by
rw [← div_eq_one, H, div_eq_one]
@[to_additive]
theorem leftInverse_div_mul_left (c : G) : Function.LeftInverse (fun x ↦ x / c) fun x ↦ x * c :=
fun x ↦ mul_div_cancel_right x c
@[to_additive]
theorem leftInverse_mul_left_div (c : G) : Function.LeftInverse (fun x ↦ x * c) fun x ↦ x / c :=
fun x ↦ div_mul_cancel x c
@[to_additive]
theorem leftInverse_mul_right_inv_mul (c : G) :
Function.LeftInverse (fun x ↦ c * x) fun x ↦ c⁻¹ * x :=
fun x ↦ mul_inv_cancel_left c x
@[to_additive]
theorem leftInverse_inv_mul_mul_right (c : G) :
Function.LeftInverse (fun x ↦ c⁻¹ * x) fun x ↦ c * x :=
fun x ↦ inv_mul_cancel_left c x
@[to_additive (attr := simp) natAbs_nsmul_eq_zero]
lemma pow_natAbs_eq_one : a ^ n.natAbs = 1 ↔ a ^ n = 1 := by cases n <;> simp
@[to_additive sub_nsmul]
lemma pow_sub (a : G) {m n : ℕ} (h : n ≤ m) : a ^ (m - n) = a ^ m * (a ^ n)⁻¹ :=
eq_mul_inv_of_mul_eq <| by rw [← pow_add, Nat.sub_add_cancel h]
@[to_additive sub_nsmul_neg]
theorem inv_pow_sub (a : G) {m n : ℕ} (h : n ≤ m) : a⁻¹ ^ (m - n) = (a ^ m)⁻¹ * a ^ n := by
rw [pow_sub a⁻¹ h, inv_pow, inv_pow, inv_inv]
@[to_additive add_one_zsmul]
lemma zpow_add_one (a : G) : ∀ n : ℤ, a ^ (n + 1) = a ^ n * a
| (n : ℕ) => by simp only [← Int.natCast_succ, zpow_natCast, pow_succ]
| -1 => by simp [Int.add_left_neg]
| .negSucc (n + 1) => by
rw [zpow_negSucc, pow_succ', mul_inv_rev, inv_mul_cancel_right]
rw [Int.negSucc_eq, Int.neg_add, Int.neg_add_cancel_right]
exact zpow_negSucc _ _
@[to_additive sub_one_zsmul]
lemma zpow_sub_one (a : G) (n : ℤ) : a ^ (n - 1) = a ^ n * a⁻¹ :=
calc
a ^ (n - 1) = a ^ (n - 1) * a * a⁻¹ := (mul_inv_cancel_right _ _).symm
_ = a ^ n * a⁻¹ := by rw [← zpow_add_one, Int.sub_add_cancel]
@[to_additive add_zsmul]
lemma zpow_add (a : G) (m n : ℤ) : a ^ (m + n) = a ^ m * a ^ n := by
induction n with
| hz => simp
| hp n ihn => simp only [← Int.add_assoc, zpow_add_one, ihn, mul_assoc]
| hn n ihn => rw [zpow_sub_one, ← mul_assoc, ← ihn, ← zpow_sub_one, Int.add_sub_assoc]
@[to_additive one_add_zsmul]
lemma zpow_one_add (a : G) (n : ℤ) : a ^ (1 + n) = a * a ^ n := by rw [zpow_add, zpow_one]
@[to_additive add_zsmul_self]
lemma mul_self_zpow (a : G) (n : ℤ) : a * a ^ n = a ^ (n + 1) := by
rw [Int.add_comm, zpow_add, zpow_one]
@[to_additive add_self_zsmul]
lemma mul_zpow_self (a : G) (n : ℤ) : a ^ n * a = a ^ (n + 1) := (zpow_add_one ..).symm
@[to_additive sub_zsmul] lemma zpow_sub (a : G) (m n : ℤ) : a ^ (m - n) = a ^ m * (a ^ n)⁻¹ := by
rw [Int.sub_eq_add_neg, zpow_add, zpow_neg]
@[to_additive natCast_sub_natCast_zsmul]
lemma zpow_natCast_sub_natCast (a : G) (m n : ℕ) : a ^ (m - n : ℤ) = a ^ m / a ^ n := by
simpa [div_eq_mul_inv] using zpow_sub a m n
@[to_additive natCast_sub_one_zsmul]
lemma zpow_natCast_sub_one (a : G) (n : ℕ) : a ^ (n - 1 : ℤ) = a ^ n / a := by
simpa [div_eq_mul_inv] using zpow_sub a n 1
@[to_additive one_sub_natCast_zsmul]
lemma zpow_one_sub_natCast (a : G) (n : ℕ) : a ^ (1 - n : ℤ) = a / a ^ n := by
simpa [div_eq_mul_inv] using zpow_sub a 1 n
@[to_additive] lemma zpow_mul_comm (a : G) (m n : ℤ) : a ^ m * a ^ n = a ^ n * a ^ m := by
rw [← zpow_add, Int.add_comm, zpow_add]
theorem zpow_eq_zpow_emod {x : G} (m : ℤ) {n : ℤ} (h : x ^ n = 1) :
x ^ m = x ^ (m % n) :=
calc
x ^ m = x ^ (m % n + n * (m / n)) := by rw [Int.emod_add_ediv]
_ = x ^ (m % n) := by simp [zpow_add, zpow_mul, h]
theorem zpow_eq_zpow_emod' {x : G} (m : ℤ) {n : ℕ} (h : x ^ n = 1) :
x ^ m = x ^ (m % (n : ℤ)) := zpow_eq_zpow_emod m (by simpa)
@[to_additive (attr := simp)]
lemma zpow_iterate (k : ℤ) : ∀ n : ℕ, (fun x : G ↦ x ^ k)^[n] = (· ^ k ^ n)
| 0 => by ext; simp [Int.pow_zero]
| n + 1 => by ext; simp [zpow_iterate, Int.pow_succ', zpow_mul]
/-- To show a property of all powers of `g` it suffices to show it is closed under multiplication
by `g` and `g⁻¹` on the left. For subgroups generated by more than one element, see
`Subgroup.closure_induction_left`. -/
@[to_additive "To show a property of all multiples of `g` it suffices to show it is closed under
addition by `g` and `-g` on the left. For additive subgroups generated by more than one element, see
`AddSubgroup.closure_induction_left`."]
lemma zpow_induction_left {g : G} {P : G → Prop} (h_one : P (1 : G))
(h_mul : ∀ a, P a → P (g * a)) (h_inv : ∀ a, P a → P (g⁻¹ * a)) (n : ℤ) : P (g ^ n) := by
induction n with
| hz => rwa [zpow_zero]
| hp n ih =>
rw [Int.add_comm, zpow_add, zpow_one]
exact h_mul _ ih
| hn n ih =>
rw [Int.sub_eq_add_neg, Int.add_comm, zpow_add, zpow_neg_one]
exact h_inv _ ih
/-- To show a property of all powers of `g` it suffices to show it is closed under multiplication
by `g` and `g⁻¹` on the right. For subgroups generated by more than one element, see
`Subgroup.closure_induction_right`. -/
@[to_additive "To show a property of all multiples of `g` it suffices to show it is closed under
addition by `g` and `-g` on the right. For additive subgroups generated by more than one element,
see `AddSubgroup.closure_induction_right`."]
lemma zpow_induction_right {g : G} {P : G → Prop} (h_one : P (1 : G))
(h_mul : ∀ a, P a → P (a * g)) (h_inv : ∀ a, P a → P (a * g⁻¹)) (n : ℤ) : P (g ^ n) := by
induction n with
| hz => rwa [zpow_zero]
| hp n ih =>
rw [zpow_add_one]
exact h_mul _ ih
| hn n ih =>
rw [zpow_sub_one]
exact h_inv _ ih
end Group
section CommGroup
variable [CommGroup G] {a b c d : G}
attribute [local simp] mul_assoc mul_comm mul_left_comm div_eq_mul_inv
@[to_additive]
theorem div_eq_of_eq_mul' {a b c : G} (h : a = b * c) : a / b = c := by
rw [h, div_eq_mul_inv, mul_comm, inv_mul_cancel_left]
@[to_additive (attr := simp)]
theorem mul_div_mul_left_eq_div (a b c : G) : c * a / (c * b) = a / b := by
rw [div_eq_mul_inv, mul_inv_rev, mul_comm b⁻¹ c⁻¹, mul_comm c a, mul_assoc, ← mul_assoc c,
mul_inv_cancel, one_mul, div_eq_mul_inv]
@[to_additive eq_sub_of_add_eq']
theorem eq_div_of_mul_eq'' (h : c * a = b) : a = b / c := by simp [h.symm]
@[to_additive]
theorem eq_mul_of_div_eq' (h : a / b = c) : a = b * c := by simp [h.symm]
@[to_additive]
theorem mul_eq_of_eq_div' (h : b = c / a) : a * b = c := by
rw [h, div_eq_mul_inv, mul_comm c, mul_inv_cancel_left]
@[to_additive sub_sub_self]
theorem div_div_self' (a b : G) : a / (a / b) = b := by simp
@[to_additive]
theorem div_eq_div_mul_div (a b c : G) : a / b = c / b * (a / c) := by simp [mul_left_comm c]
@[to_additive (attr := simp)]
theorem div_div_cancel (a b : G) : a / (a / b) = b :=
div_div_self' a b
@[to_additive (attr := simp)]
theorem div_div_cancel_left (a b : G) : a / b / a = b⁻¹ := by simp
@[to_additive eq_sub_iff_add_eq']
theorem eq_div_iff_mul_eq'' : a = b / c ↔ c * a = b := by rw [eq_div_iff_mul_eq', mul_comm]
@[to_additive]
theorem div_eq_iff_eq_mul' : a / b = c ↔ a = b * c := by rw [div_eq_iff_eq_mul, mul_comm]
@[to_additive (attr := simp)]
theorem mul_div_cancel_left (a b : G) : a * b / a = b := by rw [div_eq_inv_mul, inv_mul_cancel_left]
@[to_additive (attr := simp)]
theorem mul_div_cancel (a b : G) : a * (b / a) = b := by
rw [← mul_div_assoc, mul_div_cancel_left]
@[to_additive (attr := simp)]
theorem div_mul_cancel_left (a b : G) : a / (a * b) = b⁻¹ := by rw [← inv_div, mul_div_cancel_left]
-- This lemma is in the `simp` set under the name `mul_inv_cancel_comm_assoc`,
-- along with the additive version `add_neg_cancel_comm_assoc`,
-- defined in `Algebra.Group.Commute`
@[to_additive]
theorem mul_mul_inv_cancel'_right (a b : G) : a * (b * a⁻¹) = b := by
rw [← div_eq_mul_inv, mul_div_cancel a b]
@[to_additive (attr := simp)]
theorem mul_mul_div_cancel (a b c : G) : a * c * (b / c) = a * b := by
rw [mul_assoc, mul_div_cancel]
@[to_additive (attr := simp)]
theorem div_mul_mul_cancel (a b c : G) : a / c * (b * c) = a * b := by
rw [mul_left_comm, div_mul_cancel, mul_comm]
@[to_additive (attr := simp)]
theorem div_mul_div_cancel' (a b c : G) : a / b * (c / a) = c / b := by
rw [mul_comm]; apply div_mul_div_cancel
@[to_additive (attr := simp)]
theorem mul_div_div_cancel (a b c : G) : a * b / (a / c) = b * c := by
rw [← div_mul, mul_div_cancel_left]
@[to_additive (attr := simp)]
theorem div_div_div_cancel_left (a b c : G) : c / a / (c / b) = b / a := by
rw [← inv_div b c, div_inv_eq_mul, mul_comm, div_mul_div_cancel]
@[to_additive]
theorem div_eq_div_iff_mul_eq_mul : a / b = c / d ↔ a * d = c * b := by
rw [div_eq_iff_eq_mul, div_mul_eq_mul_div, eq_comm, div_eq_iff_eq_mul']
simp only [mul_comm, eq_comm]
@[to_additive]
theorem div_eq_div_iff_div_eq_div : a / b = c / d ↔ a / c = b / d := by
rw [div_eq_iff_eq_mul, div_mul_eq_mul_div, div_eq_iff_eq_mul', mul_div_assoc]
end CommGroup
section multiplicative
variable [Monoid β] (p r : α → α → Prop) [IsTotal α r] (f : α → α → β)
@[to_additive additive_of_symmetric_of_isTotal]
lemma multiplicative_of_symmetric_of_isTotal
(hsymm : Symmetric p) (hf_swap : ∀ {a b}, p a b → f a b * f b a = 1)
(hmul : ∀ {a b c}, r a b → r b c → p a b → p b c → p a c → f a c = f a b * f b c)
{a b c : α} (pab : p a b) (pbc : p b c) (pac : p a c) : f a c = f a b * f b c := by
have hmul' : ∀ {b c}, r b c → p a b → p b c → p a c → f a c = f a b * f b c := by
intros b c rbc pab pbc pac
obtain rab | rba := total_of r a b
· exact hmul rab rbc pab pbc pac
rw [← one_mul (f a c), ← hf_swap pab, mul_assoc]
obtain rac | rca := total_of r a c
· rw [hmul rba rac (hsymm pab) pac pbc]
· rw [hmul rbc rca pbc (hsymm pac) (hsymm pab), mul_assoc, hf_swap (hsymm pac), mul_one]
obtain rbc | rcb := total_of r b c
· exact hmul' rbc pab pbc pac
· rw [hmul' rcb pac (hsymm pbc) pab, mul_assoc, hf_swap (hsymm pbc), mul_one]
/-- If a binary function from a type equipped with a total relation `r` to a monoid is
anti-symmetric (i.e. satisfies `f a b * f b a = 1`), in order to show it is multiplicative
(i.e. satisfies `f a c = f a b * f b c`), we may assume `r a b` and `r b c` are satisfied.
We allow restricting to a subset specified by a predicate `p`. -/
@[to_additive additive_of_isTotal "If a binary function from a type equipped with a total relation
`r` to an additive monoid is anti-symmetric (i.e. satisfies `f a b + f b a = 0`), in order to show
it is additive (i.e. satisfies `f a c = f a b + f b c`), we may assume `r a b` and `r b c` are
satisfied. We allow restricting to a subset specified by a predicate `p`."]
theorem multiplicative_of_isTotal (p : α → Prop) (hswap : ∀ {a b}, p a → p b → f a b * f b a = 1)
(hmul : ∀ {a b c}, r a b → r b c → p a → p b → p c → f a c = f a b * f b c) {a b c : α}
(pa : p a) (pb : p b) (pc : p c) : f a c = f a b * f b c := by
apply multiplicative_of_symmetric_of_isTotal (fun a b => p a ∧ p b) r f fun _ _ => And.symm
· simp_rw [and_imp]; exact @hswap
· exact fun rab rbc pab _pbc pac => hmul rab rbc pab.1 pab.2 pac.2
exacts [⟨pa, pb⟩, ⟨pb, pc⟩, ⟨pa, pc⟩]
end multiplicative
/-- An auxiliary lemma that can be used to prove `⇑(f ^ n) = ⇑f^[n]`. -/
@[to_additive]
lemma hom_coe_pow {F : Type*} [Monoid F] (c : F → M → M) (h1 : c 1 = id)
(hmul : ∀ f g, c (f * g) = c f ∘ c g) (f : F) : ∀ n, c (f ^ n) = (c f)^[n]
| 0 => by
rw [pow_zero, h1]
rfl
| n + 1 => by rw [pow_succ, iterate_succ, hmul, hom_coe_pow c h1 hmul f n]
| Mathlib/Algebra/Group/Basic.lean | 1,104 | 1,105 | |
/-
Copyright (c) 2020 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.Geometry.Manifold.ContMDiff.Constructions
import Mathlib.Analysis.NormedSpace.OperatorNorm.Prod
/-! ## Equivalence of smoothness with the basic definition for functions between vector spaces
* `contMDiff_iff_contDiff`: for functions between vector spaces,
manifold-smoothness is equivalent to usual smoothness.
* `ContinuousLinearMap.contMDiff`: continuous linear maps between normed spaces are smooth
* `smooth_smul`: multiplication by scalars is a smooth operation
-/
open Set ChartedSpace
open scoped Topology Manifold
variable {𝕜 : Type*} [NontriviallyNormedField 𝕜]
-- declare a charted space `M` over the pair `(E, H)`.
{E : Type*}
[NormedAddCommGroup E] [NormedSpace 𝕜 E] {H : Type*} [TopologicalSpace H]
{I : ModelWithCorners 𝕜 E H} {M : Type*} [TopologicalSpace M] [ChartedSpace H M]
-- declare normed spaces `E'`, `F`, `F'`, `F₁`, `F₂`, `F₃`, `F₄`.
{E' : Type*} [NormedAddCommGroup E'] [NormedSpace 𝕜 E']
{F : Type*} [NormedAddCommGroup F] [NormedSpace 𝕜 F]
{F' : Type*} [NormedAddCommGroup F'] [NormedSpace 𝕜 F']
{F₁ : Type*} [NormedAddCommGroup F₁] [NormedSpace 𝕜 F₁] {F₂ : Type*} [NormedAddCommGroup F₂]
[NormedSpace 𝕜 F₂] {F₃ : Type*} [NormedAddCommGroup F₃] [NormedSpace 𝕜 F₃] {F₄ : Type*}
[NormedAddCommGroup F₄] [NormedSpace 𝕜 F₄]
-- declare functions, sets, points and smoothness indices
{s : Set M} {x : M} {n : WithTop ℕ∞}
section Module
theorem contMDiffWithinAt_iff_contDiffWithinAt {f : E → E'} {s : Set E} {x : E} :
ContMDiffWithinAt 𝓘(𝕜, E) 𝓘(𝕜, E') n f s x ↔ ContDiffWithinAt 𝕜 n f s x := by
simp +contextual only [ContMDiffWithinAt, liftPropWithinAt_iff',
ContDiffWithinAtProp, iff_def, mfld_simps]
exact ContDiffWithinAt.continuousWithinAt
alias ⟨ContMDiffWithinAt.contDiffWithinAt, ContDiffWithinAt.contMDiffWithinAt⟩ :=
contMDiffWithinAt_iff_contDiffWithinAt
theorem contMDiffAt_iff_contDiffAt {f : E → E'} {x : E} :
ContMDiffAt 𝓘(𝕜, E) 𝓘(𝕜, E') n f x ↔ ContDiffAt 𝕜 n f x := by
rw [← contMDiffWithinAt_univ, contMDiffWithinAt_iff_contDiffWithinAt, contDiffWithinAt_univ]
| alias ⟨ContMDiffAt.contDiffAt, ContDiffAt.contMDiffAt⟩ := contMDiffAt_iff_contDiffAt
theorem contMDiffOn_iff_contDiffOn {f : E → E'} {s : Set E} :
ContMDiffOn 𝓘(𝕜, E) 𝓘(𝕜, E') n f s ↔ ContDiffOn 𝕜 n f s :=
forall_congr' <| by simp [contMDiffWithinAt_iff_contDiffWithinAt]
| Mathlib/Geometry/Manifold/ContMDiff/NormedSpace.lean | 51 | 55 |
/-
Copyright (c) 2018 Guy Leroy. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sangwoo Jo (aka Jason), Guy Leroy, Johannes Hölzl, Mario Carneiro
-/
import Mathlib.Algebra.GroupWithZero.Semiconj
import Mathlib.Algebra.Group.Commute.Units
import Mathlib.Data.Nat.GCD.Basic
import Mathlib.Data.Set.Operations
import Mathlib.Order.Basic
import Mathlib.Order.Bounds.Defs
import Mathlib.Algebra.Group.Int.Defs
import Mathlib.Data.Int.Basic
/-!
# Extended GCD and divisibility over ℤ
## Main definitions
* Given `x y : ℕ`, `xgcd x y` computes the pair of integers `(a, b)` such that
`gcd x y = x * a + y * b`. `gcdA x y` and `gcdB x y` are defined to be `a` and `b`,
respectively.
## Main statements
* `gcd_eq_gcd_ab`: Bézout's lemma, given `x y : ℕ`, `gcd x y = x * gcdA x y + y * gcdB x y`.
## Tags
Bézout's lemma, Bezout's lemma
-/
/-! ### Extended Euclidean algorithm -/
namespace Nat
/-- Helper function for the extended GCD algorithm (`Nat.xgcd`). -/
def xgcdAux : ℕ → ℤ → ℤ → ℕ → ℤ → ℤ → ℕ × ℤ × ℤ
| 0, _, _, r', s', t' => (r', s', t')
| succ k, s, t, r', s', t' =>
let q := r' / succ k
xgcdAux (r' % succ k) (s' - q * s) (t' - q * t) (succ k) s t
termination_by k => k
decreasing_by exact mod_lt _ <| (succ_pos _).gt
@[simp]
theorem xgcd_zero_left {s t r' s' t'} : xgcdAux 0 s t r' s' t' = (r', s', t') := by simp [xgcdAux]
theorem xgcdAux_rec {r s t r' s' t'} (h : 0 < r) :
xgcdAux r s t r' s' t' = xgcdAux (r' % r) (s' - r' / r * s) (t' - r' / r * t) r s t := by
obtain ⟨r, rfl⟩ := Nat.exists_eq_succ_of_ne_zero h.ne'
simp [xgcdAux]
/-- Use the extended GCD algorithm to generate the `a` and `b` values
satisfying `gcd x y = x * a + y * b`. -/
def xgcd (x y : ℕ) : ℤ × ℤ :=
(xgcdAux x 1 0 y 0 1).2
/-- The extended GCD `a` value in the equation `gcd x y = x * a + y * b`. -/
def gcdA (x y : ℕ) : ℤ :=
(xgcd x y).1
/-- The extended GCD `b` value in the equation `gcd x y = x * a + y * b`. -/
def gcdB (x y : ℕ) : ℤ :=
(xgcd x y).2
@[simp]
theorem gcdA_zero_left {s : ℕ} : gcdA 0 s = 0 := by
unfold gcdA
rw [xgcd, xgcd_zero_left]
@[simp]
theorem gcdB_zero_left {s : ℕ} : gcdB 0 s = 1 := by
unfold gcdB
rw [xgcd, xgcd_zero_left]
@[simp]
theorem gcdA_zero_right {s : ℕ} (h : s ≠ 0) : gcdA s 0 = 1 := by
unfold gcdA xgcd
obtain ⟨s, rfl⟩ := Nat.exists_eq_succ_of_ne_zero h
rw [xgcdAux]
simp
@[simp]
theorem gcdB_zero_right {s : ℕ} (h : s ≠ 0) : gcdB s 0 = 0 := by
unfold gcdB xgcd
obtain ⟨s, rfl⟩ := Nat.exists_eq_succ_of_ne_zero h
rw [xgcdAux]
simp
@[simp]
theorem xgcdAux_fst (x y) : ∀ s t s' t', (xgcdAux x s t y s' t').1 = gcd x y :=
gcd.induction x y (by simp) fun x y h IH s t s' t' => by
simp only [h, xgcdAux_rec, IH]
rw [← gcd_rec]
theorem xgcdAux_val (x y) : xgcdAux x 1 0 y 0 1 = (gcd x y, xgcd x y) := by
rw [xgcd, ← xgcdAux_fst x y 1 0 0 1]
theorem xgcd_val (x y) : xgcd x y = (gcdA x y, gcdB x y) := by
unfold gcdA gcdB; cases xgcd x y; rfl
section
variable (x y : ℕ)
private def P : ℕ × ℤ × ℤ → Prop
| (r, s, t) => (r : ℤ) = x * s + y * t
theorem xgcdAux_P {r r'} :
∀ {s t s' t'}, P x y (r, s, t) → P x y (r', s', t') → P x y (xgcdAux r s t r' s' t') := by
induction r, r' using gcd.induction with
| H0 => simp
| H1 a b h IH =>
intro s t s' t' p p'
rw [xgcdAux_rec h]; refine IH ?_ p; dsimp [P] at *
rw [Int.emod_def]; generalize (b / a : ℤ) = k
rw [p, p', Int.mul_sub, sub_add_eq_add_sub, Int.mul_sub, Int.add_mul, mul_comm k t,
mul_comm k s, ← mul_assoc, ← mul_assoc, add_comm (x * s * k), ← add_sub_assoc, sub_sub]
/-- **Bézout's lemma**: given `x y : ℕ`, `gcd x y = x * a + y * b`, where `a = gcd_a x y` and
`b = gcd_b x y` are computed by the extended Euclidean algorithm.
-/
theorem gcd_eq_gcd_ab : (gcd x y : ℤ) = x * gcdA x y + y * gcdB x y := by
have := @xgcdAux_P x y x y 1 0 0 1 (by simp [P]) (by simp [P])
rwa [xgcdAux_val, xgcd_val] at this
end
theorem exists_mul_emod_eq_gcd {k n : ℕ} (hk : gcd n k < k) : ∃ m, n * m % k = gcd n k := by
have hk' := Int.ofNat_ne_zero.2 (ne_of_gt (lt_of_le_of_lt (zero_le (gcd n k)) hk))
have key := congr_arg (fun (m : ℤ) => (m % k).toNat) (gcd_eq_gcd_ab n k)
simp only at key
rw [Int.add_mul_emod_self_left, ← Int.natCast_mod, Int.toNat_natCast, mod_eq_of_lt hk] at key
refine ⟨(n.gcdA k % k).toNat, Eq.trans (Int.ofNat.inj ?_) key.symm⟩
rw [Int.ofNat_eq_coe, Int.natCast_mod, Int.natCast_mul,
Int.toNat_of_nonneg (Int.emod_nonneg _ hk'), Int.ofNat_eq_coe,
Int.toNat_of_nonneg (Int.emod_nonneg _ hk'), Int.mul_emod, Int.emod_emod, ← Int.mul_emod]
theorem exists_mul_emod_eq_one_of_coprime {k n : ℕ} (hkn : Coprime n k) (hk : 1 < k) :
∃ m, n * m % k = 1 :=
Exists.recOn (exists_mul_emod_eq_gcd (lt_of_le_of_lt (le_of_eq hkn) hk)) fun m hm ↦
⟨m, hm.trans hkn⟩
end Nat
/-! ### Divisibility over ℤ -/
namespace Int
theorem gcd_def (i j : ℤ) : gcd i j = Nat.gcd i.natAbs j.natAbs := rfl
@[simp, norm_cast] protected lemma gcd_natCast_natCast (m n : ℕ) : gcd ↑m ↑n = m.gcd n := rfl
/-- The extended GCD `a` value in the equation `gcd x y = x * a + y * b`. -/
def gcdA : ℤ → ℤ → ℤ
| ofNat m, n => m.gcdA n.natAbs
| -[m+1], n => -m.succ.gcdA n.natAbs
/-- The extended GCD `b` value in the equation `gcd x y = x * a + y * b`. -/
def gcdB : ℤ → ℤ → ℤ
| m, ofNat n => m.natAbs.gcdB n
| m, -[n+1] => -m.natAbs.gcdB n.succ
/-- **Bézout's lemma** -/
theorem gcd_eq_gcd_ab : ∀ x y : ℤ, (gcd x y : ℤ) = x * gcdA x y + y * gcdB x y
| (m : ℕ), (n : ℕ) => Nat.gcd_eq_gcd_ab _ _
| (m : ℕ), -[n+1] =>
show (_ : ℤ) = _ + -(n + 1) * -_ by rw [Int.neg_mul_neg]; apply Nat.gcd_eq_gcd_ab
| -[m+1], (n : ℕ) =>
show (_ : ℤ) = -(m + 1) * -_ + _ by rw [Int.neg_mul_neg]; apply Nat.gcd_eq_gcd_ab
| -[m+1], -[n+1] =>
show (_ : ℤ) = -(m + 1) * -_ + -(n + 1) * -_ by
rw [Int.neg_mul_neg, Int.neg_mul_neg]
apply Nat.gcd_eq_gcd_ab
theorem lcm_def (i j : ℤ) : lcm i j = Nat.lcm (natAbs i) (natAbs j) :=
rfl
protected theorem coe_nat_lcm (m n : ℕ) : Int.lcm ↑m ↑n = Nat.lcm m n :=
rfl
theorem dvd_coe_gcd {i j k : ℤ} (h1 : k ∣ i) (h2 : k ∣ j) : k ∣ gcd i j :=
natAbs_dvd.1 <|
natCast_dvd_natCast.2 <| Nat.dvd_gcd (natAbs_dvd_natAbs.2 h1) (natAbs_dvd_natAbs.2 h2)
@[deprecated (since := "2025-04-27")] alias dvd_gcd := dvd_coe_gcd
theorem gcd_mul_lcm (i j : ℤ) : gcd i j * lcm i j = natAbs (i * j) := by
rw [Int.gcd, Int.lcm, Nat.gcd_mul_lcm, natAbs_mul]
theorem gcd_comm (i j : ℤ) : gcd i j = gcd j i :=
Nat.gcd_comm _ _
theorem gcd_assoc (i j k : ℤ) : gcd (gcd i j) k = gcd i (gcd j k) :=
Nat.gcd_assoc _ _ _
@[simp]
theorem gcd_self (i : ℤ) : gcd i i = natAbs i := by simp [gcd]
@[simp]
theorem gcd_zero_left (i : ℤ) : gcd 0 i = natAbs i := by simp [gcd]
@[simp]
theorem gcd_zero_right (i : ℤ) : gcd i 0 = natAbs i := by simp [gcd]
theorem gcd_mul_left (i j k : ℤ) : gcd (i * j) (i * k) = natAbs i * gcd j k := by
rw [Int.gcd, Int.gcd, natAbs_mul, natAbs_mul]
apply Nat.gcd_mul_left
theorem gcd_mul_right (i j k : ℤ) : gcd (i * j) (k * j) = gcd i k * natAbs j := by
rw [Int.gcd, Int.gcd, natAbs_mul, natAbs_mul]
apply Nat.gcd_mul_right
theorem gcd_pos_of_ne_zero_left {i : ℤ} (j : ℤ) (hi : i ≠ 0) : 0 < gcd i j :=
Nat.gcd_pos_of_pos_left _ <| natAbs_pos.2 hi
theorem gcd_pos_of_ne_zero_right (i : ℤ) {j : ℤ} (hj : j ≠ 0) : 0 < gcd i j :=
Nat.gcd_pos_of_pos_right _ <| natAbs_pos.2 hj
theorem gcd_eq_zero_iff {i j : ℤ} : gcd i j = 0 ↔ i = 0 ∧ j = 0 := by
rw [gcd, Nat.gcd_eq_zero_iff, natAbs_eq_zero, natAbs_eq_zero]
theorem gcd_pos_iff {i j : ℤ} : 0 < gcd i j ↔ i ≠ 0 ∨ j ≠ 0 :=
Nat.pos_iff_ne_zero.trans <| gcd_eq_zero_iff.not.trans not_and_or
theorem gcd_div {i j k : ℤ} (H1 : k ∣ i) (H2 : k ∣ j) :
gcd (i / k) (j / k) = gcd i j / natAbs k := by
rw [gcd, natAbs_ediv_of_dvd i k H1, natAbs_ediv_of_dvd j k H2]
exact Nat.gcd_div (natAbs_dvd_natAbs.mpr H1) (natAbs_dvd_natAbs.mpr H2)
theorem gcd_div_gcd_div_gcd {i j : ℤ} (H : 0 < gcd i j) : gcd (i / gcd i j) (j / gcd i j) = 1 := by
rw [gcd_div gcd_dvd_left gcd_dvd_right, natAbs_ofNat, Nat.div_self H]
theorem gcd_dvd_gcd_of_dvd_left {i k : ℤ} (j : ℤ) (H : i ∣ k) : gcd i j ∣ gcd k j :=
Int.natCast_dvd_natCast.1 <| dvd_coe_gcd (gcd_dvd_left.trans H) gcd_dvd_right
theorem gcd_dvd_gcd_of_dvd_right {i k : ℤ} (j : ℤ) (H : i ∣ k) : gcd j i ∣ gcd j k :=
Int.natCast_dvd_natCast.1 <| dvd_coe_gcd gcd_dvd_left (gcd_dvd_right.trans H)
theorem gcd_dvd_gcd_mul_left (i j k : ℤ) : gcd i j ∣ gcd (k * i) j :=
gcd_dvd_gcd_of_dvd_left _ (dvd_mul_left _ _)
theorem gcd_dvd_gcd_mul_right (i j k : ℤ) : gcd i j ∣ gcd (i * k) j :=
gcd_dvd_gcd_of_dvd_left _ (dvd_mul_right _ _)
theorem gcd_dvd_gcd_mul_left_right (i j k : ℤ) : gcd i j ∣ gcd i (k * j) :=
gcd_dvd_gcd_of_dvd_right _ (dvd_mul_left _ _)
theorem gcd_dvd_gcd_mul_right_right (i j k : ℤ) : gcd i j ∣ gcd i (j * k) :=
gcd_dvd_gcd_of_dvd_right _ (dvd_mul_right _ _)
/-- If `gcd a (m * n) = 1`, then `gcd a m = 1`. -/
theorem gcd_eq_one_of_gcd_mul_right_eq_one_left {a : ℤ} {m n : ℕ} (h : a.gcd (m * n) = 1) :
a.gcd m = 1 :=
Nat.dvd_one.mp <| h ▸ gcd_dvd_gcd_mul_right_right a m n
/-- If `gcd a (m * n) = 1`, then `gcd a n = 1`. -/
theorem gcd_eq_one_of_gcd_mul_right_eq_one_right {a : ℤ} {m n : ℕ} (h : a.gcd (m * n) = 1) :
a.gcd n = 1 :=
Nat.dvd_one.mp <| h ▸ gcd_dvd_gcd_mul_left_right a n m
theorem gcd_eq_left {i j : ℤ} (H : i ∣ j) : gcd i j = natAbs i :=
Nat.dvd_antisymm (Nat.gcd_dvd_left _ _) (Nat.dvd_gcd dvd_rfl (natAbs_dvd_natAbs.mpr H))
theorem gcd_eq_right {i j : ℤ} (H : j ∣ i) : gcd i j = natAbs j := by rw [gcd_comm, gcd_eq_left H]
theorem ne_zero_of_gcd {x y : ℤ} (hc : gcd x y ≠ 0) : x ≠ 0 ∨ y ≠ 0 := by
contrapose! hc
rw [hc.left, hc.right, gcd_zero_right, natAbs_zero]
theorem exists_gcd_one {m n : ℤ} (H : 0 < gcd m n) :
∃ m' n' : ℤ, gcd m' n' = 1 ∧ m = m' * gcd m n ∧ n = n' * gcd m n :=
⟨_, _, gcd_div_gcd_div_gcd H, (Int.ediv_mul_cancel gcd_dvd_left).symm,
(Int.ediv_mul_cancel gcd_dvd_right).symm⟩
theorem exists_gcd_one' {m n : ℤ} (H : 0 < gcd m n) :
∃ (g : ℕ) (m' n' : ℤ), 0 < g ∧ gcd m' n' = 1 ∧ m = m' * g ∧ n = n' * g :=
let ⟨m', n', h⟩ := exists_gcd_one H
⟨_, m', n', H, h⟩
theorem pow_dvd_pow_iff {m n : ℤ} {k : ℕ} (k0 : k ≠ 0) : m ^ k ∣ n ^ k ↔ m ∣ n := by
refine ⟨fun h => ?_, fun h => pow_dvd_pow_of_dvd h _⟩
rwa [← natAbs_dvd_natAbs, ← Nat.pow_dvd_pow_iff k0, ← Int.natAbs_pow, ← Int.natAbs_pow,
natAbs_dvd_natAbs]
theorem gcd_dvd_iff {a b : ℤ} {n : ℕ} : gcd a b ∣ n ↔ ∃ x y : ℤ, ↑n = a * x + b * y := by
constructor
· intro h
rw [← Nat.mul_div_cancel' h, Int.ofNat_mul, gcd_eq_gcd_ab, Int.add_mul, mul_assoc, mul_assoc]
exact ⟨_, _, rfl⟩
· rintro ⟨x, y, h⟩
rw [← Int.natCast_dvd_natCast, h]
exact Int.dvd_add (dvd_mul_of_dvd_left gcd_dvd_left _) (dvd_mul_of_dvd_left gcd_dvd_right y)
theorem gcd_greatest {a b d : ℤ} (hd_pos : 0 ≤ d) (hda : d ∣ a) (hdb : d ∣ b)
(hd : ∀ e : ℤ, e ∣ a → e ∣ b → e ∣ d) : d = gcd a b :=
dvd_antisymm hd_pos (ofNat_zero_le (gcd a b)) (dvd_coe_gcd hda hdb)
(hd _ gcd_dvd_left gcd_dvd_right)
/-- Euclid's lemma: if `a ∣ b * c` and `gcd a c = 1` then `a ∣ b`.
Compare with `IsCoprime.dvd_of_dvd_mul_left` and
`UniqueFactorizationMonoid.dvd_of_dvd_mul_left_of_no_prime_factors` -/
theorem dvd_of_dvd_mul_left_of_gcd_one {a b c : ℤ} (habc : a ∣ b * c) (hab : gcd a c = 1) :
a ∣ b := by
have := gcd_eq_gcd_ab a c
simp only [hab, Int.ofNat_zero, Int.ofNat_succ, zero_add] at this
have : b * a * gcdA a c + b * c * gcdB a c = b := by simp [mul_assoc, ← Int.mul_add, ← this]
rw [← this]
exact Int.dvd_add (dvd_mul_of_dvd_left (dvd_mul_left a b) _) (dvd_mul_of_dvd_left habc _)
/-- Euclid's lemma: if `a ∣ b * c` and `gcd a b = 1` then `a ∣ c`.
Compare with `IsCoprime.dvd_of_dvd_mul_right` and
`UniqueFactorizationMonoid.dvd_of_dvd_mul_right_of_no_prime_factors` -/
theorem dvd_of_dvd_mul_right_of_gcd_one {a b c : ℤ} (habc : a ∣ b * c) (hab : gcd a b = 1) :
a ∣ c := by
rw [mul_comm] at habc
exact dvd_of_dvd_mul_left_of_gcd_one habc hab
/-- For nonzero integers `a` and `b`, `gcd a b` is the smallest positive natural number that can be
written in the form `a * x + b * y` for some pair of integers `x` and `y` -/
theorem gcd_least_linear {a b : ℤ} (ha : a ≠ 0) :
IsLeast { n : ℕ | 0 < n ∧ ∃ x y : ℤ, ↑n = a * x + b * y } (a.gcd b) := by
simp_rw [← gcd_dvd_iff]
constructor
· simpa [and_true, dvd_refl, Set.mem_setOf_eq] using gcd_pos_of_ne_zero_left b ha
· simp only [lowerBounds, and_imp, Set.mem_setOf_eq]
exact fun n hn_pos hn => Nat.le_of_dvd hn_pos hn
/-! ### lcm -/
theorem lcm_comm (i j : ℤ) : lcm i j = lcm j i := by
rw [Int.lcm, Int.lcm]
exact Nat.lcm_comm _ _
theorem lcm_assoc (i j k : ℤ) : lcm (lcm i j) k = lcm i (lcm j k) := by
rw [Int.lcm, Int.lcm, Int.lcm, Int.lcm, natAbs_ofNat, natAbs_ofNat]
apply Nat.lcm_assoc
@[simp]
theorem lcm_zero_left (i : ℤ) : lcm 0 i = 0 := by
rw [Int.lcm]
apply Nat.lcm_zero_left
@[simp]
theorem lcm_zero_right (i : ℤ) : lcm i 0 = 0 := by
rw [Int.lcm]
apply Nat.lcm_zero_right
@[simp]
theorem lcm_one_left (i : ℤ) : lcm 1 i = natAbs i := by
rw [Int.lcm]
apply Nat.lcm_one_left
@[simp]
theorem lcm_one_right (i : ℤ) : lcm i 1 = natAbs i := by
rw [Int.lcm]
apply Nat.lcm_one_right
theorem coe_lcm_dvd {i j k : ℤ} : i ∣ k → j ∣ k → (lcm i j : ℤ) ∣ k := by
rw [Int.lcm]
intro hi hj
exact natCast_dvd.mpr (Nat.lcm_dvd (natAbs_dvd_natAbs.mpr hi) (natAbs_dvd_natAbs.mpr hj))
@[deprecated (since := "2025-04-27")] alias lcm_dvd := coe_lcm_dvd
theorem lcm_mul_left {m n k : ℤ} : (m * n).lcm (m * k) = natAbs m * n.lcm k := by
simp_rw [Int.lcm, natAbs_mul, Nat.lcm_mul_left]
theorem lcm_mul_right {m n k : ℤ} : (m * n).lcm (k * n) = m.lcm k * natAbs n := by
simp_rw [Int.lcm, natAbs_mul, Nat.lcm_mul_right]
end Int
@[to_additive gcd_nsmul_eq_zero]
theorem pow_gcd_eq_one {M : Type*} [Monoid M] (x : M) {m n : ℕ} (hm : x ^ m = 1) (hn : x ^ n = 1) :
x ^ m.gcd n = 1 := by
rcases m with (rfl | m); · simp [hn]
obtain ⟨y, rfl⟩ := IsUnit.of_pow_eq_one hm m.succ_ne_zero
rw [← Units.val_pow_eq_pow_val, ← Units.val_one (α := M), ← zpow_natCast, ← Units.ext_iff] at *
rw [Nat.gcd_eq_gcd_ab, zpow_add, zpow_mul, zpow_mul, hn, hm, one_zpow, one_zpow, one_mul]
variable {α : Type*}
section GroupWithZero
variable [GroupWithZero α] {a b : α} {m n : ℕ}
protected lemma Commute.pow_eq_pow_iff_of_coprime (hab : Commute a b) (hmn : m.Coprime n) :
a ^ m = b ^ n ↔ ∃ c, a = c ^ n ∧ b = c ^ m := by
refine ⟨fun h ↦ ?_, by rintro ⟨c, rfl, rfl⟩; rw [← pow_mul, ← pow_mul']⟩
by_cases m = 0; · aesop
by_cases n = 0; · aesop
by_cases hb : b = 0; · exact ⟨0, by aesop⟩
by_cases ha : a = 0; · exact ⟨0, by have := h.symm; aesop⟩
refine ⟨a ^ Nat.gcdB m n * b ^ Nat.gcdA m n, ?_, ?_⟩ <;>
· refine (pow_one _).symm.trans ?_
conv_lhs => rw [← zpow_natCast, ← hmn, Nat.gcd_eq_gcd_ab]
simp only [zpow_add₀ ha, zpow_add₀ hb, ← zpow_natCast, (hab.zpow_zpow₀ _ _).mul_zpow,
← zpow_mul, mul_comm (Nat.gcdB m n), mul_comm (Nat.gcdA m n)]
simp only [zpow_mul, zpow_natCast, h]
exact ((Commute.pow_pow (by aesop) _ _).zpow_zpow₀ _ _).symm
end GroupWithZero
section CommGroupWithZero
variable [CommGroupWithZero α] {a b : α} {m n : ℕ}
lemma pow_eq_pow_iff_of_coprime (hmn : m.Coprime n) : a ^ m = b ^ n ↔ ∃ c, a = c ^ n ∧ b = c ^ m :=
| (Commute.all _ _).pow_eq_pow_iff_of_coprime hmn
lemma pow_mem_range_pow_of_coprime (hmn : m.Coprime n) (a : α) :
| Mathlib/Data/Int/GCD.lean | 412 | 414 |
/-
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
| Mathlib/Data/Set/Image.lean | 53 | 55 |
/-
Copyright (c) 2022 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov
-/
import Mathlib.Data.Nat.Lattice
import Mathlib.Data.NNReal.Basic
import Mathlib.Topology.Metrizable.Basic
/-!
# Metrizable uniform spaces
In this file we prove that a uniform space with countably generated uniformity filter is
pseudometrizable: there exists a `PseudoMetricSpace` structure that generates the same uniformity.
The proof follows [Sergey Melikhov, Metrizable uniform spaces][melikhov2011].
## Main definitions
* `PseudoMetricSpace.ofPreNNDist`: given a function `d : X → X → ℝ≥0` such that `d x x = 0` and
`d x y = d y x` for all `x y : X`, constructs the maximal pseudo metric space structure such that
`NNDist x y ≤ d x y` for all `x y : X`.
* `UniformSpace.pseudoMetricSpace`: given a uniform space `X` with countably generated `𝓤 X`,
constructs a `PseudoMetricSpace X` instance that is compatible with the uniform space structure.
* `UniformSpace.metricSpace`: given a T₀ uniform space `X` with countably generated `𝓤 X`,
constructs a `MetricSpace X` instance that is compatible with the uniform space structure.
## Main statements
* `UniformSpace.metrizable_uniformity`: if `X` is a uniform space with countably generated `𝓤 X`,
then there exists a `PseudoMetricSpace` structure that is compatible with this `UniformSpace`
structure. Use `UniformSpace.pseudoMetricSpace` or `UniformSpace.metricSpace` instead.
* `UniformSpace.pseudoMetrizableSpace`: a uniform space with countably generated `𝓤 X` is pseudo
metrizable.
* `UniformSpace.metrizableSpace`: a T₀ uniform space with countably generated `𝓤 X` is
metrizable. This is not an instance to avoid loops.
## Tags
metrizable space, uniform space
-/
open Set Function Metric List Filter
open NNReal Filter Uniformity
variable {X : Type*}
namespace PseudoMetricSpace
/-- The maximal pseudo metric space structure on `X` such that `dist x y ≤ d x y` for all `x y`,
where `d : X → X → ℝ≥0` is a function such that `d x x = 0` and `d x y = d y x` for all `x`, `y`. -/
noncomputable def ofPreNNDist (d : X → X → ℝ≥0) (dist_self : ∀ x, d x x = 0)
(dist_comm : ∀ x y, d x y = d y x) : PseudoMetricSpace X where
dist x y := ↑(⨅ l : List X, ((x::l).zipWith d (l ++ [y])).sum : ℝ≥0)
dist_self x := NNReal.coe_eq_zero.2 <|
nonpos_iff_eq_zero.1 <| (ciInf_le (OrderBot.bddBelow _) []).trans_eq <| by simp [dist_self]
dist_comm x y :=
NNReal.coe_inj.2 <| by
refine reverse_surjective.iInf_congr _ fun l ↦ ?_
rw [← sum_reverse, reverse_zipWith, reverse_append, reverse_reverse,
reverse_singleton, singleton_append, reverse_cons, reverse_reverse,
zipWith_comm_of_comm dist_comm]
simp only [length, length_append]
dist_triangle x y z := by
rw [← NNReal.coe_add, NNReal.coe_le_coe]
refine NNReal.le_iInf_add_iInf fun lxy lyz ↦ ?_
calc
⨅ l, (zipWith d (x::l) (l ++ [z])).sum ≤
(zipWith d (x::lxy ++ y::lyz) ((lxy ++ y::lyz) ++ [z])).sum :=
ciInf_le (OrderBot.bddBelow _) (lxy ++ y::lyz)
_ = (zipWith d (x::lxy) (lxy ++ [y])).sum + (zipWith d (y::lyz) (lyz ++ [z])).sum := by
rw [← sum_append, ← zipWith_append, cons_append, ← @singleton_append _ y, append_assoc,
append_assoc, append_assoc]
rw [length_cons, length_append, length_singleton]
theorem dist_ofPreNNDist (d : X → X → ℝ≥0) (dist_self : ∀ x, d x x = 0)
(dist_comm : ∀ x y, d x y = d y x) (x y : X) :
@dist X (@PseudoMetricSpace.toDist X (PseudoMetricSpace.ofPreNNDist d dist_self dist_comm)) x
y =
↑(⨅ l : List X, ((x::l).zipWith d (l ++ [y])).sum : ℝ≥0) :=
rfl
theorem dist_ofPreNNDist_le (d : X → X → ℝ≥0) (dist_self : ∀ x, d x x = 0)
(dist_comm : ∀ x y, d x y = d y x) (x y : X) :
@dist X (@PseudoMetricSpace.toDist X (PseudoMetricSpace.ofPreNNDist d dist_self dist_comm)) x
y ≤
d x y :=
NNReal.coe_le_coe.2 <| (ciInf_le (OrderBot.bddBelow _) []).trans_eq <| by simp
/-- Consider a function `d : X → X → ℝ≥0` such that `d x x = 0` and `d x y = d y x` for all `x`,
`y`. Let `dist` be the largest pseudometric distance such that `dist x y ≤ d x y`, see
`PseudoMetricSpace.ofPreNNDist`. Suppose that `d` satisfies the following triangle-like
inequality: `d x₁ x₄ ≤ 2 * max (d x₁ x₂, d x₂ x₃, d x₃ x₄)`. Then `d x y ≤ 2 * dist x y` for all
`x`, `y`. -/
theorem le_two_mul_dist_ofPreNNDist (d : X → X → ℝ≥0) (dist_self : ∀ x, d x x = 0)
(dist_comm : ∀ x y, d x y = d y x)
(hd : ∀ x₁ x₂ x₃ x₄, d x₁ x₄ ≤ 2 * max (d x₁ x₂) (max (d x₂ x₃) (d x₃ x₄))) (x y : X) :
↑(d x y) ≤ 2 * @dist X
(@PseudoMetricSpace.toDist X (PseudoMetricSpace.ofPreNNDist d dist_self dist_comm)) x y := by
/- We need to show that `d x y` is at most twice the sum `L` of `d xᵢ xᵢ₊₁` over a path
`x₀=x, ..., xₙ=y`. We prove it by induction on the length `n` of the sequence. Find an edge that
splits the path into two parts of almost equal length: both `d x₀ x₁ + ... + d xₖ₋₁ xₖ` and
`d xₖ₊₁ xₖ₊₂ + ... + d xₙ₋₁ xₙ` are less than or equal to `L / 2`.
Then `d x₀ xₖ ≤ L`, `d xₖ xₖ₊₁ ≤ L`, and `d xₖ₊₁ xₙ ≤ L`, thus `d x₀ xₙ ≤ 2 * L`. -/
rw [dist_ofPreNNDist, ← NNReal.coe_two, ← NNReal.coe_mul, NNReal.mul_iInf, NNReal.coe_le_coe]
refine le_ciInf fun l => ?_
have hd₀_trans : Transitive fun x y => d x y = 0 := by
intro a b c hab hbc
rw [← nonpos_iff_eq_zero]
simpa only [nonpos_iff_eq_zero, hab, hbc, dist_self c, max_self, mul_zero] using hd a b c c
haveI : IsTrans X fun x y => d x y = 0 := ⟨hd₀_trans⟩
suffices ∀ n, length l = n → d x y ≤ 2 * (zipWith d (x :: l) (l ++ [y])).sum by exact this _ rfl
intro n hn
induction n using Nat.strong_induction_on generalizing x y l with | h n ihn =>
simp only at ihn
subst n
set L := zipWith d (x::l) (l ++ [y])
have hL_len : length L = length l + 1 := by simp [L]
rcases eq_or_ne (d x y) 0 with hd₀ | hd₀
· simp only [hd₀, zero_le]
rsuffices ⟨z, z', hxz, hzz', hz'y⟩ : ∃ z z' : X, d x z ≤ L.sum ∧ d z z' ≤ L.sum ∧ d z' y ≤ L.sum
· exact (hd x z z' y).trans (mul_le_mul_left' (max_le hxz (max_le hzz' hz'y)) _)
set s : Set ℕ := { m : ℕ | 2 * (take m L).sum ≤ L.sum }
have hs₀ : 0 ∈ s := by simp [s]
have hsne : s.Nonempty := ⟨0, hs₀⟩
obtain ⟨M, hMl, hMs⟩ : ∃ M ≤ length l, IsGreatest s M := by
have hs_ub : length l ∈ upperBounds s := by
intro m hm
rw [← not_lt, Nat.lt_iff_add_one_le, ← hL_len]
intro hLm
rw [mem_setOf_eq, take_of_length_le hLm, two_mul, add_le_iff_nonpos_left, nonpos_iff_eq_zero,
sum_eq_zero_iff, ← forall_iff_forall_mem, forall_zipWith,
← chain_append_singleton_iff_forall₂]
at hm <;>
[skip; simp]
exact hd₀ (hm.rel (mem_append.2 <| Or.inr <| mem_singleton_self _))
have hs_bdd : BddAbove s := ⟨length l, hs_ub⟩
exact ⟨sSup s, csSup_le hsne hs_ub, ⟨Nat.sSup_mem hsne hs_bdd, fun k => le_csSup hs_bdd⟩⟩
have hM_lt : M < length L := by rwa [hL_len, Nat.lt_succ_iff]
have hM_ltx : M < length (x::l) := lt_length_left_of_zipWith hM_lt
have hM_lty : M < length (l ++ [y]) := lt_length_right_of_zipWith hM_lt
refine ⟨(x::l)[M], (l ++ [y])[M], ?_, ?_, ?_⟩
· cases M with
| zero =>
simp [dist_self, List.get]
| succ M =>
rw [Nat.succ_le_iff] at hMl
have hMl' : length (take M l) = M := length_take.trans (min_eq_left hMl.le)
refine (ihn _ hMl _ _ _ hMl').trans ?_
convert hMs.1.out
rw [take_zipWith, take, take_succ, getElem?_append_left hMl, getElem?_eq_getElem hMl,
← Option.coe_def, Option.toList_some, take_append_of_le_length hMl.le, getElem_cons_succ]
· exact single_le_sum (fun x _ => zero_le x) _ (mem_iff_get.2 ⟨⟨M, hM_lt⟩, getElem_zipWith⟩)
· rcases hMl.eq_or_lt with (rfl | hMl)
· simp only [getElem_append_right le_rfl, sub_self, getElem_singleton, dist_self, zero_le]
rw [getElem_append_left hMl]
have hlen : length (drop (M + 1) l) = length l - (M + 1) := length_drop
have hlen_lt : length l - (M + 1) < length l := Nat.sub_lt_of_pos_le M.succ_pos hMl
refine (ihn _ hlen_lt _ y _ hlen).trans ?_
rw [cons_getElem_drop_succ]
have hMs' : L.sum ≤ 2 * (L.take (M + 1)).sum :=
not_lt.1 fun h => (hMs.2 h.le).not_lt M.lt_succ_self
rw [← sum_take_add_sum_drop L (M + 1), two_mul, add_le_add_iff_left, ← add_le_add_iff_right,
sum_take_add_sum_drop, ← two_mul] at hMs'
convert hMs'
rwa [drop_zipWith, drop, drop_append_of_le_length]
end PseudoMetricSpace
/-- If `X` is a uniform space with countably generated uniformity filter, there exists a
`PseudoMetricSpace` structure compatible with the `UniformSpace` structure. Use
`UniformSpace.pseudoMetricSpace` or `UniformSpace.metricSpace` instead. -/
protected theorem UniformSpace.metrizable_uniformity (X : Type*) [UniformSpace X]
[IsCountablyGenerated (𝓤 X)] : ∃ I : PseudoMetricSpace X, I.toUniformSpace = ‹_› := by
classical
/- Choose a fast decreasing antitone basis `U : ℕ → set (X × X)` of the uniformity filter `𝓤 X`.
Define `d x y : ℝ≥0` to be `(1 / 2) ^ n`, where `n` is the minimal index of `U n` that
separates `x` and `y`: `(x, y) ∉ U n`, or `0` if `x` is not separated from `y`. This function
satisfies the assumptions of `PseudoMetricSpace.ofPreNNDist` and
`PseudoMetricSpace.le_two_mul_dist_ofPreNNDist`, hence the distance given by the former pseudo
metric space structure is Lipschitz equivalent to the `d`. Thus the uniformities generated by
`d` and `dist` are equal. Since the former uniformity is equal to `𝓤 X`, the latter is equal to
`𝓤 X` as well. -/
obtain ⟨U, hU_symm, hU_comp, hB⟩ :
∃ U : ℕ → Set (X × X),
(∀ n, IsSymmetricRel (U n)) ∧
(∀ ⦃m n⦄, m < n → U n ○ (U n ○ U n) ⊆ U m) ∧ (𝓤 X).HasAntitoneBasis U := by
rcases UniformSpace.has_seq_basis X with ⟨V, hB, hV_symm⟩
rcases hB.subbasis_with_rel fun m =>
hB.tendsto_smallSets.eventually
(eventually_uniformity_iterate_comp_subset (hB.mem m) 2) with
⟨φ, -, hφ_comp, hφB⟩
exact ⟨V ∘ φ, fun n => hV_symm _, hφ_comp, hφB⟩
set d : X → X → ℝ≥0 := fun x y => if h : ∃ n, (x, y) ∉ U n then (1 / 2) ^ Nat.find h else 0
have hd₀ : ∀ {x y}, d x y = 0 ↔ Inseparable x y := by
intro x y
refine Iff.trans ?_ hB.inseparable_iff_uniformity.symm
simp only [d, true_imp_iff]
split_ifs with h
· rw [← not_forall] at h
simp [h, pow_eq_zero_iff']
· simpa only [not_exists, Classical.not_not, eq_self_iff_true, true_iff] using h
have hd_symm : ∀ x y, d x y = d y x := by
intro x y
simp only [d, @IsSymmetricRel.mk_mem_comm _ _ (hU_symm _) x y]
have hr : (1 / 2 : ℝ≥0) ∈ Ioo (0 : ℝ≥0) 1 := ⟨half_pos one_pos, NNReal.half_lt_self one_ne_zero⟩
letI I := PseudoMetricSpace.ofPreNNDist d (fun x => hd₀.2 rfl) hd_symm
have hdist_le : ∀ x y, dist x y ≤ d x y := PseudoMetricSpace.dist_ofPreNNDist_le _ _ _
have hle_d : ∀ {x y : X} {n : ℕ}, (1 / 2) ^ n ≤ d x y ↔ (x, y) ∉ U n := by
intro x y n
dsimp only [d]
split_ifs with h
· rw [(pow_right_strictAnti₀ hr.1 hr.2).le_iff_le, Nat.find_le_iff]
exact ⟨fun ⟨m, hmn, hm⟩ hn => hm (hB.antitone hmn hn), fun h => ⟨n, le_rfl, h⟩⟩
· push_neg at h
simp only [h, not_true, (pow_pos hr.1 _).not_le]
have hd_le : ∀ x y, ↑(d x y) ≤ 2 * dist x y := by
refine PseudoMetricSpace.le_two_mul_dist_ofPreNNDist _ _ _ fun x₁ x₂ x₃ x₄ => ?_
by_cases H : ∃ n, (x₁, x₄) ∉ U n
· refine (dif_pos H).trans_le ?_
rw [← div_le_iff₀' zero_lt_two, ← mul_one_div (_ ^ _), ← pow_succ]
simp only [le_max_iff, hle_d, ← not_and_or]
rintro ⟨h₁₂, h₂₃, h₃₄⟩
refine Nat.find_spec H (hU_comp (lt_add_one <| Nat.find H) ?_)
exact ⟨x₂, h₁₂, x₃, h₂₃, h₃₄⟩
· exact (dif_neg H).trans_le (zero_le _)
-- Porting note: without the next line, `uniformity_basis_dist_pow` ends up introducing some
-- `Subtype.val` applications instead of `NNReal.toReal`.
rw [mem_Ioo, ← NNReal.coe_lt_coe, ← NNReal.coe_lt_coe] at hr
refine ⟨I, UniformSpace.ext <| (uniformity_basis_dist_pow hr.1 hr.2).ext hB.toHasBasis ?_ ?_⟩
· refine fun n hn => ⟨n, hn, fun x hx => (hdist_le _ _).trans_lt ?_⟩
rwa [← NNReal.coe_pow, NNReal.coe_lt_coe, ← not_le, hle_d, Classical.not_not]
· refine fun n _ => ⟨n + 1, trivial, fun x hx => ?_⟩
rw [mem_setOf_eq] at hx
contrapose! hx
refine le_trans ?_ ((div_le_iff₀' zero_lt_two).2 (hd_le x.1 x.2))
rwa [← NNReal.coe_two, ← NNReal.coe_div, ← NNReal.coe_pow, NNReal.coe_le_coe, pow_succ,
mul_one_div, div_le_iff₀ zero_lt_two, div_mul_cancel₀ _ two_ne_zero, hle_d]
/-- A `PseudoMetricSpace` instance compatible with a given `UniformSpace` structure. -/
protected noncomputable def UniformSpace.pseudoMetricSpace (X : Type*) [UniformSpace X]
[IsCountablyGenerated (𝓤 X)] : PseudoMetricSpace X :=
(UniformSpace.metrizable_uniformity X).choose.replaceUniformity <|
congr_arg _ (UniformSpace.metrizable_uniformity X).choose_spec.symm
/-- A `MetricSpace` instance compatible with a given `UniformSpace` structure. -/
protected noncomputable def UniformSpace.metricSpace (X : Type*) [UniformSpace X]
[IsCountablyGenerated (𝓤 X)] [T0Space X] : MetricSpace X :=
@MetricSpace.ofT0PseudoMetricSpace X (UniformSpace.pseudoMetricSpace X) _
/-- A uniform space with countably generated `𝓤 X` is pseudo metrizable. -/
instance (priority := 100) UniformSpace.pseudoMetrizableSpace [UniformSpace X]
[IsCountablyGenerated (𝓤 X)] : TopologicalSpace.PseudoMetrizableSpace X := by
letI := UniformSpace.pseudoMetricSpace X
infer_instance
/-- A T₀ uniform space with countably generated `𝓤 X` is metrizable. This is not an instance to
avoid loops. -/
theorem UniformSpace.metrizableSpace [UniformSpace X] [IsCountablyGenerated (𝓤 X)] [T0Space X] :
TopologicalSpace.MetrizableSpace X := by
letI := UniformSpace.metricSpace X
infer_instance
/-- A totally bounded set is separable in countably generated uniform spaces. This can be obtained
from the more general `EMetric.subset_countable_closure_of_almost_dense_set`. -/
lemma TotallyBounded.isSeparable [UniformSpace X] [i : IsCountablyGenerated (𝓤 X)]
{s : Set X} (h : TotallyBounded s) : TopologicalSpace.IsSeparable s := by
letI := (UniformSpace.pseudoMetricSpace (X := X)).toPseudoEMetricSpace
rw [EMetric.totallyBounded_iff] at h
have h' : ∀ ε > 0, ∃ t, Set.Countable t ∧ s ⊆ ⋃ y ∈ t, EMetric.closedBall y ε := by
| intro ε hε
obtain ⟨t, ht⟩ := h ε hε
refine ⟨t, ht.1.countable, subset_trans ht.2 ?_⟩
gcongr
| Mathlib/Topology/Metrizable/Uniformity.lean | 276 | 279 |
/-
Copyright (c) 2021 Yourong Zang. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yourong Zang, Yury Kudryashov
-/
import Mathlib.Data.Fintype.Option
import Mathlib.Topology.Homeomorph.Lemmas
import Mathlib.Topology.Sets.Opens
/-!
# The OnePoint Compactification
We construct the OnePoint compactification (the one-point compactification) of an arbitrary
topological space `X` and prove some properties inherited from `X`.
## Main definitions
* `OnePoint`: the OnePoint compactification, we use coercion for the canonical embedding
`X → OnePoint X`; when `X` is already compact, the compactification adds an isolated point
to the space.
* `OnePoint.infty`: the extra point
## Main results
* The topological structure of `OnePoint X`
* The connectedness of `OnePoint X` for a noncompact, preconnected `X`
* `OnePoint X` is `T₀` for a T₀ space `X`
* `OnePoint X` is `T₁` for a T₁ space `X`
* `OnePoint X` is normal if `X` is a locally compact Hausdorff space
## Tags
one-point compactification, Alexandroff compactification, compactness
-/
open Set Filter Topology
/-!
### Definition and basic properties
In this section we define `OnePoint X` to be the disjoint union of `X` and `∞`, implemented as
`Option X`. Then we restate some lemmas about `Option X` for `OnePoint X`.
-/
variable {X Y : Type*}
/-- The OnePoint extension of an arbitrary topological space `X` -/
def OnePoint (X : Type*) :=
Option X
/-- The repr uses the notation from the `OnePoint` locale. -/
instance [Repr X] : Repr (OnePoint X) :=
⟨fun o _ =>
match o with
| none => "∞"
| some a => "↑" ++ repr a⟩
namespace OnePoint
/-- The point at infinity -/
@[match_pattern] def infty : OnePoint X := none
@[inherit_doc]
scoped notation "∞" => OnePoint.infty
/-- Coercion from `X` to `OnePoint X`. -/
@[coe, match_pattern] def some : X → OnePoint X := Option.some
@[simp]
lemma some_eq_iff (x₁ x₂ : X) : (some x₁ = some x₂) ↔ (x₁ = x₂) := by
rw [iff_eq_eq]
exact Option.some.injEq x₁ x₂
instance : CoeTC X (OnePoint X) := ⟨some⟩
instance : Inhabited (OnePoint X) := ⟨∞⟩
protected lemma «forall» {p : OnePoint X → Prop} :
(∀ (x : OnePoint X), p x) ↔ p ∞ ∧ ∀ (x : X), p x :=
Option.forall
protected lemma «exists» {p : OnePoint X → Prop} :
(∃ x, p x) ↔ p ∞ ∨ ∃ (x : X), p x :=
Option.exists
instance [Fintype X] : Fintype (OnePoint X) :=
inferInstanceAs (Fintype (Option X))
instance infinite [Infinite X] : Infinite (OnePoint X) :=
inferInstanceAs (Infinite (Option X))
theorem coe_injective : Function.Injective ((↑) : X → OnePoint X) :=
Option.some_injective X
@[norm_cast]
theorem coe_eq_coe {x y : X} : (x : OnePoint X) = y ↔ x = y :=
coe_injective.eq_iff
@[simp]
theorem coe_ne_infty (x : X) : (x : OnePoint X) ≠ ∞ :=
nofun
@[simp]
theorem infty_ne_coe (x : X) : ∞ ≠ (x : OnePoint X) :=
nofun
/-- Recursor for `OnePoint` using the preferred forms `∞` and `↑x`. -/
@[elab_as_elim, induction_eliminator, cases_eliminator]
protected def rec {C : OnePoint X → Sort*} (infty : C ∞) (coe : ∀ x : X, C x) :
∀ z : OnePoint X, C z
| ∞ => infty
| (x : X) => coe x
/-- An elimination principle for `OnePoint`. -/
@[inline] protected def elim : OnePoint X → Y → (X → Y) → Y := Option.elim
@[simp] theorem elim_infty (y : Y) (f : X → Y) : ∞.elim y f = y := rfl
@[simp] theorem elim_some (y : Y) (f : X → Y) (x : X) : (some x).elim y f = f x := rfl
theorem isCompl_range_coe_infty : IsCompl (range ((↑) : X → OnePoint X)) {∞} :=
isCompl_range_some_none X
theorem range_coe_union_infty : range ((↑) : X → OnePoint X) ∪ {∞} = univ :=
range_some_union_none X
@[simp]
theorem insert_infty_range_coe : insert ∞ (range (@some X)) = univ :=
insert_none_range_some _
@[simp]
theorem range_coe_inter_infty : range ((↑) : X → OnePoint X) ∩ {∞} = ∅ :=
range_some_inter_none X
@[simp]
theorem compl_range_coe : (range ((↑) : X → OnePoint X))ᶜ = {∞} :=
compl_range_some X
theorem compl_infty : ({∞}ᶜ : Set (OnePoint X)) = range ((↑) : X → OnePoint X) :=
(@isCompl_range_coe_infty X).symm.compl_eq
theorem compl_image_coe (s : Set X) : ((↑) '' s : Set (OnePoint X))ᶜ = (↑) '' sᶜ ∪ {∞} := by
rw [coe_injective.compl_image_eq, compl_range_coe]
theorem ne_infty_iff_exists {x : OnePoint X} : x ≠ ∞ ↔ ∃ y : X, (y : OnePoint X) = x := by
induction x using OnePoint.rec <;> simp
instance canLift : CanLift (OnePoint X) X (↑) fun x => x ≠ ∞ :=
WithTop.canLift
theorem not_mem_range_coe_iff {x : OnePoint X} : x ∉ range some ↔ x = ∞ := by
rw [← mem_compl_iff, compl_range_coe, mem_singleton_iff]
theorem infty_not_mem_range_coe : ∞ ∉ range ((↑) : X → OnePoint X) :=
not_mem_range_coe_iff.2 rfl
theorem infty_not_mem_image_coe {s : Set X} : ∞ ∉ ((↑) : X → OnePoint X) '' s :=
not_mem_subset (image_subset_range _ _) infty_not_mem_range_coe
@[simp]
theorem coe_preimage_infty : ((↑) : X → OnePoint X) ⁻¹' {∞} = ∅ := by
ext
simp
/-- Extend a map `f : X → Y` to a map `OnePoint X → OnePoint Y`
by sending infinity to infinity. -/
protected def map (f : X → Y) : OnePoint X → OnePoint Y :=
Option.map f
@[simp] theorem map_infty (f : X → Y) : OnePoint.map f ∞ = ∞ := rfl
@[simp] theorem map_some (f : X → Y) (x : X) : (x : OnePoint X).map f = f x := rfl
@[simp] theorem map_id : OnePoint.map (id : X → X) = id := Option.map_id
theorem map_comp {Z : Type*} (f : Y → Z) (g : X → Y) :
OnePoint.map (f ∘ g) = OnePoint.map f ∘ OnePoint.map g :=
(Option.map_comp_map _ _).symm
/-!
### Topological space structure on `OnePoint X`
We define a topological space structure on `OnePoint X` so that `s` is open if and only if
* `(↑) ⁻¹' s` is open in `X`;
* if `∞ ∈ s`, then `((↑) ⁻¹' s)ᶜ` is compact.
Then we reformulate this definition in a few different ways, and prove that
`(↑) : X → OnePoint X` is an open embedding. If `X` is not a compact space, then we also prove
that `(↑)` has dense range, so it is a dense embedding.
-/
variable [TopologicalSpace X]
instance : TopologicalSpace (OnePoint X) where
IsOpen s := (∞ ∈ s → IsCompact (((↑) : X → OnePoint X) ⁻¹' s)ᶜ) ∧
IsOpen (((↑) : X → OnePoint X) ⁻¹' s)
isOpen_univ := by simp
isOpen_inter s t := by
rintro ⟨hms, hs⟩ ⟨hmt, ht⟩
refine ⟨?_, hs.inter ht⟩
rintro ⟨hms', hmt'⟩
simpa [compl_inter] using (hms hms').union (hmt hmt')
isOpen_sUnion S ho := by
suffices IsOpen ((↑) ⁻¹' ⋃₀ S : Set X) by
refine ⟨?_, this⟩
rintro ⟨s, hsS : s ∈ S, hs : ∞ ∈ s⟩
refine IsCompact.of_isClosed_subset ((ho s hsS).1 hs) this.isClosed_compl ?_
exact compl_subset_compl.mpr (preimage_mono <| subset_sUnion_of_mem hsS)
rw [preimage_sUnion]
exact isOpen_biUnion fun s hs => (ho s hs).2
variable {s : Set (OnePoint X)}
theorem isOpen_def :
IsOpen s ↔ (∞ ∈ s → IsCompact ((↑) ⁻¹' s : Set X)ᶜ) ∧ IsOpen ((↑) ⁻¹' s : Set X) :=
Iff.rfl
theorem isOpen_iff_of_mem' (h : ∞ ∈ s) :
IsOpen s ↔ IsCompact ((↑) ⁻¹' s : Set X)ᶜ ∧ IsOpen ((↑) ⁻¹' s : Set X) := by
simp [isOpen_def, h]
theorem isOpen_iff_of_mem (h : ∞ ∈ s) :
IsOpen s ↔ IsClosed ((↑) ⁻¹' s : Set X)ᶜ ∧ IsCompact ((↑) ⁻¹' s : Set X)ᶜ := by
simp only [isOpen_iff_of_mem' h, isClosed_compl_iff, and_comm]
theorem isOpen_iff_of_not_mem (h : ∞ ∉ s) : IsOpen s ↔ IsOpen ((↑) ⁻¹' s : Set X) := by
simp [isOpen_def, h]
theorem isClosed_iff_of_mem (h : ∞ ∈ s) : IsClosed s ↔ IsClosed ((↑) ⁻¹' s : Set X) := by
have : ∞ ∉ sᶜ := fun H => H h
rw [← isOpen_compl_iff, isOpen_iff_of_not_mem this, ← isOpen_compl_iff, preimage_compl]
theorem isClosed_iff_of_not_mem (h : ∞ ∉ s) :
IsClosed s ↔ IsClosed ((↑) ⁻¹' s : Set X) ∧ IsCompact ((↑) ⁻¹' s : Set X) := by
rw [← isOpen_compl_iff, isOpen_iff_of_mem (mem_compl h), ← preimage_compl, compl_compl]
|
@[simp]
theorem isOpen_image_coe {s : Set X} : IsOpen ((↑) '' s : Set (OnePoint X)) ↔ IsOpen s := by
| Mathlib/Topology/Compactification/OnePoint.lean | 238 | 240 |
/-
Copyright (c) 2022 Amelia Livingston. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Amelia Livingston
-/
import Mathlib.Algebra.Category.ModuleCat.Projective
import Mathlib.AlgebraicTopology.ExtraDegeneracy
import Mathlib.CategoryTheory.Abelian.Ext
import Mathlib.GroupTheory.GroupAction.Ring
import Mathlib.RepresentationTheory.Rep
import Mathlib.RingTheory.TensorProduct.Free
import Mathlib.CategoryTheory.Functor.ReflectsIso.Balanced
/-!
# The structure of the `k[G]`-module `k[Gⁿ]`
This file contains facts about an important `k[G]`-module structure on `k[Gⁿ]`, where `k` is a
commutative ring and `G` is a group. The module structure arises from the representation
`G →* End(k[Gⁿ])` induced by the diagonal action of `G` on `Gⁿ.`
In particular, we define an isomorphism of `k`-linear `G`-representations between `k[Gⁿ⁺¹]` and
`k[G] ⊗ₖ k[Gⁿ]` (on which `G` acts by `ρ(g₁)(g₂ ⊗ x) = (g₁ * g₂) ⊗ x`).
This allows us to define a `k[G]`-basis on `k[Gⁿ⁺¹]`, by mapping the natural `k[G]`-basis of
`k[G] ⊗ₖ k[Gⁿ]` along the isomorphism.
We then define the standard resolution of `k` as a trivial representation, by
taking the alternating face map complex associated to an appropriate simplicial `k`-linear
`G`-representation. This simplicial object is the `Rep.linearization` of the simplicial `G`-set
given by the universal cover of the classifying space of `G`, `EG`. We prove this simplicial
`G`-set `EG` is isomorphic to the Čech nerve of the natural arrow of `G`-sets `G ⟶ {pt}`.
We then use this isomorphism to deduce that as a complex of `k`-modules, the standard resolution
of `k` as a trivial `G`-representation is homotopy equivalent to the complex with `k` at 0 and 0
elsewhere.
Putting this material together allows us to define `groupCohomology.projectiveResolution`, the
standard projective resolution of `k` as a trivial `k`-linear `G`-representation.
## Main definitions
* `groupCohomology.resolution.actionDiagonalSucc`
* `groupCohomology.resolution.diagonalSucc`
* `groupCohomology.resolution.ofMulActionBasis`
* `classifyingSpaceUniversalCover`
* `groupCohomology.resolution.forget₂ToModuleCatHomotopyEquiv`
* `groupCohomology.projectiveResolution`
## Implementation notes
We express `k[G]`-module structures on a module `k`-module `V` using the `Representation`
definition. We avoid using instances `Module (G →₀ k) V` so that we do not run into possible
scalar action diamonds.
We also use the category theory library to bundle the type `k[Gⁿ]` - or more generally `k[H]` when
`H` has `G`-action - and the representation together, as a term of type `Rep k G`, and call it
`Rep.ofMulAction k G H.` This enables us to express the fact that certain maps are
`G`-equivariant by constructing morphisms in the category `Rep k G`, i.e., representations of `G`
over `k`.
-/
/- Porting note: most altered proofs in this file involved changing `simp` to `rw` or `erw`, so
https://github.com/leanprover-community/mathlib4/issues/5026 and
https://github.com/leanprover-community/mathlib4/issues/5164 are relevant. -/
suppress_compilation
noncomputable section
universe u v w
variable {k G : Type u} [CommRing k] {n : ℕ}
open CategoryTheory Finsupp
local notation "Gⁿ" => Fin n → G
set_option quotPrecheck false
local notation "Gⁿ⁺¹" => Fin (n + 1) → G
namespace groupCohomology.resolution
open Finsupp hiding lift
open MonoidalCategory
open Fin (partialProd)
section Basis
variable (k G n) [Group G]
section Action
open Action
/-- An isomorphism of `G`-sets `Gⁿ⁺¹ ≅ G × Gⁿ`, where `G` acts by left multiplication on `Gⁿ⁺¹` and
`G` but trivially on `Gⁿ`. The map sends `(g₀, ..., gₙ) ↦ (g₀, (g₀⁻¹g₁, g₁⁻¹g₂, ..., gₙ₋₁⁻¹gₙ))`,
and the inverse is `(g₀, (g₁, ..., gₙ)) ↦ (g₀, g₀g₁, g₀g₁g₂, ..., g₀g₁...gₙ).` -/
def actionDiagonalSucc (G : Type u) [Group G] :
∀ n : ℕ, diagonal G (n + 1) ≅ leftRegular G ⊗ Action.mk (Fin n → G) 1
| 0 =>
diagonalOneIsoLeftRegular G ≪≫
(ρ_ _).symm ≪≫ tensorIso (Iso.refl _) (tensorUnitIso (Equiv.ofUnique PUnit _).toIso)
| n + 1 =>
diagonalSucc _ _ ≪≫
tensorIso (Iso.refl _) (actionDiagonalSucc G n) ≪≫
leftRegularTensorIso _ _ ≪≫
tensorIso (Iso.refl _)
(mkIso (Fin.insertNthEquiv (fun _ => G) 0).toIso fun _ => rfl)
theorem actionDiagonalSucc_hom_apply {G : Type u} [Group G] {n : ℕ} (f : Fin (n + 1) → G) :
(actionDiagonalSucc G n).hom.hom f = (f 0, fun i => (f (Fin.castSucc i))⁻¹ * f i.succ) := by
induction n with
| zero => exact Prod.ext rfl (funext fun x => Fin.elim0 x)
| succ n hn =>
refine Prod.ext rfl (funext fun x => ?_)
/- Porting note (https://github.com/leanprover-community/mathlib4/issues/11039): broken proof was
· dsimp only [actionDiagonalSucc]
simp only [Iso.trans_hom, comp_hom, types_comp_apply, diagonalSucc_hom_hom,
leftRegularTensorIso_hom_hom, tensorIso_hom, mkIso_hom_hom, Equiv.toIso_hom,
Action.tensorHom, Equiv.piFinSuccAbove_symm_apply, tensor_apply, types_id_apply,
tensor_rho, MonoidHom.one_apply, End.one_def, hn fun j : Fin (n + 1) => f j.succ,
Fin.insertNth_zero']
refine' Fin.cases (Fin.cons_zero _ _) (fun i => _) x
· simp only [Fin.cons_succ, mul_left_inj, inv_inj, Fin.castSucc_fin_succ] -/
dsimp [actionDiagonalSucc]
erw [hn (fun (j : Fin (n + 1)) => f j.succ)]
exact Fin.cases rfl (fun i => rfl) x
theorem actionDiagonalSucc_inv_apply {G : Type u} [Group G] {n : ℕ} (g : G) (f : Fin n → G) :
(actionDiagonalSucc G n).inv.hom (g, f) = (g • Fin.partialProd f : Fin (n + 1) → G) := by
revert g
induction n with
| zero =>
intro g
funext (x : Fin 1)
simp only [Subsingleton.elim x 0, Pi.smul_apply, Fin.partialProd_zero, smul_eq_mul, mul_one]
rfl
| succ n hn =>
intro g
/- Porting note (https://github.com/leanprover-community/mathlib4/issues/11039): broken proof was
ext
dsimp only [actionDiagonalSucc]
simp only [Iso.trans_inv, comp_hom, hn, diagonalSucc_inv_hom, types_comp_apply, tensorIso_inv,
Iso.refl_inv, Action.tensorHom, id_hom, tensor_apply, types_id_apply,
leftRegularTensorIso_inv_hom, tensor_ρ, leftRegular_ρ_apply, Pi.smul_apply, smul_eq_mul]
refine' Fin.cases _ _ x
· simp only [Fin.cons_zero, Fin.partialProd_zero, mul_one]
· intro i
simpa only [Fin.cons_succ, Pi.smul_apply, smul_eq_mul, Fin.partialProd_succ', mul_assoc] -/
funext x
dsimp [actionDiagonalSucc]
erw [hn, Fin.consEquiv_apply]
refine Fin.cases ?_ (fun i => ?_) x
· simp only [Fin.insertNth_zero, Fin.cons_zero, Fin.partialProd_zero, mul_one]
· simp only [Fin.cons_succ, Pi.smul_apply, smul_eq_mul, Fin.partialProd_succ', ← mul_assoc]
rfl
end Action
section Rep
open Rep
/-- An isomorphism of `k`-linear representations of `G` from `k[Gⁿ⁺¹]` to `k[G] ⊗ₖ k[Gⁿ]` (on
which `G` acts by `ρ(g₁)(g₂ ⊗ x) = (g₁ * g₂) ⊗ x`) sending `(g₀, ..., gₙ)` to
`g₀ ⊗ (g₀⁻¹g₁, g₁⁻¹g₂, ..., gₙ₋₁⁻¹gₙ)`. The inverse sends `g₀ ⊗ (g₁, ..., gₙ)` to
`(g₀, g₀g₁, ..., g₀g₁...gₙ)`. -/
def diagonalSucc (n : ℕ) :
diagonal k G (n + 1) ≅ leftRegular k G ⊗ trivial k G ((Fin n → G) →₀ k) :=
(linearization k G).mapIso (actionDiagonalSucc G n) ≪≫
(Functor.Monoidal.μIso (linearization k G) _ _).symm ≪≫
tensorIso (Iso.refl _) (linearizationTrivialIso k G (Fin n → G))
variable {k G n}
theorem diagonalSucc_hom_single (f : Gⁿ⁺¹) (a : k) :
(diagonalSucc k G n).hom.hom (single f a) =
single (f 0) 1 ⊗ₜ single (fun i => (f (Fin.castSucc i))⁻¹ * f i.succ) a := by
dsimp [diagonalSucc]
erw [lmapDomain_apply, mapDomain_single, LinearEquiv.coe_toLinearMap, finsuppTensorFinsupp',
LinearEquiv.trans_symm, LinearEquiv.trans_apply, lcongr_symm, Equiv.refl_symm]
erw [lcongr_single]
rw [TensorProduct.lid_symm_apply, actionDiagonalSucc_hom_apply, finsuppTensorFinsupp_symm_single]
rfl
theorem diagonalSucc_inv_single_single (g : G) (f : Gⁿ) (a b : k) :
(diagonalSucc k G n).inv.hom (Finsupp.single g a ⊗ₜ Finsupp.single f b) =
single (g • partialProd f) (a * b) := by
/- Porting note (https://github.com/leanprover-community/mathlib4/issues/11039): broken proof was
dsimp only [diagonalSucc]
simp only [Iso.trans_inv, Iso.symm_inv, Iso.refl_inv, tensorIso_inv, Action.tensorHom,
Action.comp_hom, ModuleCat.comp_def, LinearMap.comp_apply, asIso_hom, Functor.mapIso_inv,
ModuleCat.MonoidalCategory.hom_apply, linearizationTrivialIso_inv_hom_apply,
linearization_μ_hom, Action.id_hom ((linearization k G).obj _), actionDiagonalSucc_inv_apply,
ModuleCat.id_apply, LinearEquiv.coe_toLinearMap,
finsuppTensorFinsupp'_single_tmul_single k (Action.leftRegular G).V,
linearization_map_hom_single (actionDiagonalSucc G n).inv (g, f) (a * b)] -/
change mapDomain (actionDiagonalSucc G n).inv.hom
(lcongr (Equiv.refl (G × (Fin n → G))) (TensorProduct.lid k k)
(finsuppTensorFinsupp k k k k G (Fin n → G) (single g a ⊗ₜ[k] single f b)))
= single (g • partialProd f) (a * b)
rw [finsuppTensorFinsupp_single, lcongr_single, mapDomain_single, Equiv.refl_apply,
actionDiagonalSucc_inv_apply]
rfl
theorem diagonalSucc_inv_single_left (g : G) (f : Gⁿ →₀ k) (r : k) :
(diagonalSucc k G n).inv.hom (Finsupp.single g r ⊗ₜ f) =
Finsupp.lift (Gⁿ⁺¹ →₀ k) k Gⁿ (fun f => single (g • partialProd f) r) f := by
refine f.induction ?_ ?_
· simp only [TensorProduct.tmul_zero, map_zero]
· intro a b x _ _ hx
-- `simp` doesn't pick up on `diagonalSucc_inv_single_single` unless it has parentheses.
simp only [lift_apply, smul_single', mul_one, TensorProduct.tmul_add, map_add,
(diagonalSucc_inv_single_single), hx, Finsupp.sum_single_index, mul_comm b,
zero_mul, single_zero]
theorem diagonalSucc_inv_single_right (g : G →₀ k) (f : Gⁿ) (r : k) :
(diagonalSucc k G n).inv.hom (g ⊗ₜ Finsupp.single f r) =
Finsupp.lift _ k G (fun a => single (a • partialProd f) r) g := by
refine g.induction ?_ ?_
· simp only [TensorProduct.zero_tmul, map_zero]
· intro a b x _ _ hx
-- `simp` doesn't pick up on `diagonalSucc_inv_single_single` unless it has parentheses.
simp only [lift_apply, smul_single', map_add, hx, (diagonalSucc_inv_single_single),
TensorProduct.add_tmul, Finsupp.sum_single_index, zero_mul, single_zero]
end Rep
open scoped TensorProduct
open Representation
/-- The `k[G]`-linear isomorphism `k[G] ⊗ₖ k[Gⁿ] ≃ k[Gⁿ⁺¹]`, where the `k[G]`-module structure on
the lefthand side is `TensorProduct.leftModule`, whilst that of the righthand side comes from
`Representation.asModule`. Allows us to use `Algebra.TensorProduct.basis` to get a `k[G]`-basis
of the righthand side. -/
def ofMulActionBasisAux :
MonoidAlgebra k G ⊗[k] ((Fin n → G) →₀ k) ≃ₗ[MonoidAlgebra k G]
(ofMulAction k G (Fin (n + 1) → G)).asModule :=
haveI e := (Rep.equivalenceModuleMonoidAlgebra.1.mapIso (diagonalSucc k G n).symm).toLinearEquiv
{ e with
map_smul' := fun r x => by
rw [RingHom.id_apply, LinearEquiv.toFun_eq_coe, ← LinearEquiv.map_smul e]
congr 1
/- Porting note (https://github.com/leanprover-community/mathlib4/issues/11039): broken proof was
refine' x.induction_on _ (fun x y => _) fun y z hy hz => _
· simp only [smul_zero]
· simp only [TensorProduct.smul_tmul']
show (r * x) ⊗ₜ y = _
rw [← ofMulAction_self_smul_eq_mul, smul_tprod_one_asModule]
· rw [smul_add, hz, hy, smul_add] -/
show _ = Representation.asAlgebraHom (tensorObj (Rep.leftRegular k G)
(Rep.trivial k G ((Fin n → G) →₀ k))).ρ r _
refine x.induction_on ?_ (fun x y => ?_) fun y z hy hz => ?_
· rw [smul_zero, map_zero]
· rw [TensorProduct.smul_tmul', smul_eq_mul, ← ofMulAction_self_smul_eq_mul]
exact (smul_tprod_one_asModule (Representation.ofMulAction k G G) r x y).symm
· rw [smul_add, hz, hy, map_add] }
/-- A `k[G]`-basis of `k[Gⁿ⁺¹]`, coming from the `k[G]`-linear isomorphism
`k[G] ⊗ₖ k[Gⁿ] ≃ k[Gⁿ⁺¹].` -/
def ofMulActionBasis :
Basis (Fin n → G) (MonoidAlgebra k G) (ofMulAction k G (Fin (n + 1) → G)).asModule :=
Basis.map
(Algebra.TensorProduct.basis (MonoidAlgebra k G)
(Finsupp.basisSingleOne : Basis (Fin n → G) k ((Fin n → G) →₀ k)))
(ofMulActionBasisAux k G n)
theorem ofMulAction_free :
Module.Free (MonoidAlgebra k G) (ofMulAction k G (Fin (n + 1) → G)).asModule :=
Module.Free.of_basis (ofMulActionBasis k G n)
end Basis
end groupCohomology.resolution
namespace Rep
variable (n) [Group G] (A : Rep k G)
open groupCohomology.resolution
/-- Given a `k`-linear `G`-representation `A`, the set of representation morphisms
`Hom(k[Gⁿ⁺¹], A)` is `k`-linearly isomorphic to the set of functions `Gⁿ → A`. -/
noncomputable def diagonalHomEquiv :
(Rep.diagonal k G (n + 1) ⟶ A) ≃ₗ[k] (Fin n → G) → A :=
Linear.homCongr k
((diagonalSucc k G n).trans ((Representation.ofMulAction k G G).repOfTprodIso 1))
(Iso.refl _) ≪≫ₗ
(Rep.MonoidalClosed.linearHomEquivComm _ _ _ ≪≫ₗ Rep.leftRegularHomEquiv _) ≪≫ₗ
(Finsupp.llift A k k (Fin n → G)).symm
variable {n A}
/-- Given a `k`-linear `G`-representation `A`, `diagonalHomEquiv` is a `k`-linear isomorphism of
the set of representation morphisms `Hom(k[Gⁿ⁺¹], A)` with `Fun(Gⁿ, A)`. This lemma says that this
sends a morphism of representations `f : k[Gⁿ⁺¹] ⟶ A` to the function
`(g₁, ..., gₙ) ↦ f(1, g₁, g₁g₂, ..., g₁g₂...gₙ).` -/
theorem diagonalHomEquiv_apply (f : Rep.diagonal k G (n + 1) ⟶ A) (x : Fin n → G) :
diagonalHomEquiv n A f x = f.hom (Finsupp.single (Fin.partialProd x) 1) := by
/- Porting note (https://github.com/leanprover-community/mathlib4/issues/11039): broken proof was
unfold diagonalHomEquiv
simpa only [LinearEquiv.trans_apply, Rep.leftRegularHomEquiv_apply,
MonoidalClosed.linearHomEquivComm_hom, Finsupp.llift_symm_apply, TensorProduct.curry_apply,
Linear.homCongr_apply, Iso.refl_hom, Iso.trans_inv, Action.comp_hom, ModuleCat.comp_def,
LinearMap.comp_apply, Representation.repOfTprodIso_inv_apply,
diagonalSucc_inv_single_single (1 : G) x, one_smul, one_mul] -/
change f.hom ((diagonalSucc k G n).inv.hom (Finsupp.single 1 1 ⊗ₜ[k] Finsupp.single x 1)) = _
rw [diagonalSucc_inv_single_single, one_smul, one_mul]
/-- Given a `k`-linear `G`-representation `A`, `diagonalHomEquiv` is a `k`-linear isomorphism of
the set of representation morphisms `Hom(k[Gⁿ⁺¹], A)` with `Fun(Gⁿ, A)`. This lemma says that the
inverse map sends a function `f : Gⁿ → A` to the representation morphism sending
`(g₀, ... gₙ) ↦ ρ(g₀)(f(g₀⁻¹g₁, g₁⁻¹g₂, ..., gₙ₋₁⁻¹gₙ))`, where `ρ` is the representation attached
to `A`. -/
theorem diagonalHomEquiv_symm_apply (f : (Fin n → G) → A) (x : Fin (n + 1) → G) :
((diagonalHomEquiv n A).symm f).hom (Finsupp.single x 1) =
A.ρ (x 0) (f fun i : Fin n => (x (Fin.castSucc i))⁻¹ * x i.succ) := by
unfold diagonalHomEquiv
/- Porting note (https://github.com/leanprover-community/mathlib4/issues/11039): broken proof was
simp only [LinearEquiv.trans_symm, LinearEquiv.symm_symm, LinearEquiv.trans_apply,
Rep.leftRegularHomEquiv_symm_apply, Linear.homCongr_symm_apply, Action.comp_hom, Iso.refl_inv,
Category.comp_id, Rep.MonoidalClosed.linearHomEquivComm_symm_hom, Iso.trans_hom,
ModuleCat.comp_def, LinearMap.comp_apply, Representation.repOfTprodIso_apply,
diagonalSucc_hom_single x (1 : k), TensorProduct.uncurry_apply, Rep.leftRegularHom_hom,
Finsupp.lift_apply, ihom_obj_ρ_def, Rep.ihom_obj_ρ_apply, Finsupp.sum_single_index, zero_smul,
one_smul, Rep.of_ρ, Rep.Action_ρ_eq_ρ, Rep.trivial_def (x 0)⁻¹, Finsupp.llift_apply A k k] -/
simp only [LinearEquiv.trans_symm, LinearEquiv.symm_symm, LinearEquiv.trans_apply,
leftRegularHomEquiv_symm_apply, Linear.homCongr_symm_apply, Iso.trans_hom, Iso.refl_inv,
Category.comp_id, Action.comp_hom, MonoidalClosed.linearHomEquivComm_symm_hom,
ModuleCat.hom_comp, LinearMap.comp_apply]
rw [diagonalSucc_hom_single]
-- The prototype linter that checks if `erw` could be replaced with `rw` would time out
-- if it replaces the next `erw`s with `rw`s. So we focus down on the relevant part.
conv_lhs =>
erw [TensorProduct.uncurry_apply, Finsupp.lift_apply, Finsupp.sum_single_index]
· simp only [one_smul]
erw [Representation.linHom_apply]
simp only [LinearMap.comp_apply, MonoidHom.one_apply, Module.End.one_apply]
erw [Finsupp.llift_apply]
rw [Finsupp.lift_apply]
erw [Finsupp.sum_single_index]
· rw [one_smul]
· rw [zero_smul]
· rw [zero_smul]
/-- Auxiliary lemma for defining group cohomology, used to show that the isomorphism
`diagonalHomEquiv` commutes with the differentials in two complexes which compute
group cohomology. -/
theorem diagonalHomEquiv_symm_partialProd_succ (f : (Fin n → G) → A) (g : Fin (n + 1) → G)
(a : Fin (n + 1)) :
((diagonalHomEquiv n A).symm f).hom (Finsupp.single (Fin.partialProd g ∘ a.succ.succAbove) 1)
= f (Fin.contractNth a (· * ·) g) := by
simp only [diagonalHomEquiv_symm_apply, Function.comp_apply, Fin.succ_succAbove_zero,
Fin.partialProd_zero, map_one, Fin.succ_succAbove_succ, Module.End.one_apply,
Fin.partialProd_succ]
congr
ext
rw [← Fin.partialProd_succ, Fin.inv_partialProd_mul_eq_contractNth]
end Rep
variable (G)
/-- The simplicial `G`-set sending `[n]` to `Gⁿ⁺¹` equipped with the diagonal action of `G`. -/
def classifyingSpaceUniversalCover [Monoid G] :
SimplicialObject (Action (Type u) G) where
obj n := Action.ofMulAction G (Fin (n.unop.len + 1) → G)
map f :=
{ hom := fun x => x ∘ f.unop.toOrderHom
comm := fun _ => rfl }
map_id _ := rfl
map_comp _ _ := rfl
namespace classifyingSpaceUniversalCover
open CategoryTheory CategoryTheory.Limits
variable [Monoid G]
/-- When the category is `G`-Set, `cechNerveTerminalFrom` of `G` with the left regular action is
isomorphic to `EG`, the universal cover of the classifying space of `G` as a simplicial `G`-set. -/
def cechNerveTerminalFromIso :
cechNerveTerminalFrom (Action.ofMulAction G G) ≅ classifyingSpaceUniversalCover G :=
NatIso.ofComponents (fun _ => limit.isoLimitCone (Action.ofMulActionLimitCone _ _)) fun f => by
refine IsLimit.hom_ext (Action.ofMulActionLimitCone.{u, 0} G fun _ => G).2 fun j => ?_
dsimp only [cechNerveTerminalFrom, Pi.lift]
rw [Category.assoc, limit.isoLimitCone_hom_π, limit.lift_π, Category.assoc]
exact (limit.isoLimitCone_hom_π _ _).symm
/-- As a simplicial set, `cechNerveTerminalFrom` of a monoid `G` is isomorphic to the universal
cover of the classifying space of `G` as a simplicial set. -/
def cechNerveTerminalFromIsoCompForget :
cechNerveTerminalFrom G ≅ classifyingSpaceUniversalCover G ⋙ forget _ :=
NatIso.ofComponents (fun _ => Types.productIso _) fun _ =>
Matrix.ext fun _ _ => Types.Limit.lift_π_apply (Discrete.functor fun _ ↦ G) _ _ _
variable (k)
open AlgebraicTopology SimplicialObject.Augmented SimplicialObject CategoryTheory.Arrow
/-- The universal cover of the classifying space of `G` as a simplicial set, augmented by the map
from `Fin 1 → G` to the terminal object in `Type u`. -/
def compForgetAugmented : SimplicialObject.Augmented (Type u) :=
SimplicialObject.augment (classifyingSpaceUniversalCover G ⋙ forget _) (terminal _)
(terminal.from _) fun _ _ _ => Subsingleton.elim _ _
/-- The augmented Čech nerve of the map from `Fin 1 → G` to the terminal object in `Type u` has an
extra degeneracy. -/
def extraDegeneracyAugmentedCechNerve :
ExtraDegeneracy (Arrow.mk <| terminal.from G).augmentedCechNerve :=
AugmentedCechNerve.extraDegeneracy (Arrow.mk <| terminal.from G)
⟨fun _ => (1 : G),
@Subsingleton.elim _ (@Unique.instSubsingleton _ (Limits.uniqueToTerminal _)) _ _⟩
/-- The universal cover of the classifying space of `G` as a simplicial set, augmented by the map
from `Fin 1 → G` to the terminal object in `Type u`, has an extra degeneracy. -/
def extraDegeneracyCompForgetAugmented : ExtraDegeneracy (compForgetAugmented G) := by
refine
ExtraDegeneracy.ofIso (?_ : (Arrow.mk <| terminal.from G).augmentedCechNerve ≅ _)
(extraDegeneracyAugmentedCechNerve G)
exact
Comma.isoMk (CechNerveTerminalFrom.iso G ≪≫ cechNerveTerminalFromIsoCompForget G)
(Iso.refl _) (by ext : 1; exact IsTerminal.hom_ext terminalIsTerminal _ _)
/-- The free functor `Type u ⥤ ModuleCat.{u} k` applied to the universal cover of the classifying
space of `G` as a simplicial set, augmented by the map from `Fin 1 → G` to the terminal object
in `Type u`. -/
def compForgetAugmented.toModule : SimplicialObject.Augmented (ModuleCat.{u} k) :=
((SimplicialObject.Augmented.whiskering _ _).obj (ModuleCat.free k)).obj (compForgetAugmented G)
/-- If we augment the universal cover of the classifying space of `G` as a simplicial set by the
map from `Fin 1 → G` to the terminal object in `Type u`, then apply the free functor
`Type u ⥤ ModuleCat.{u} k`, the resulting augmented simplicial `k`-module has an extra
degeneracy. -/
def extraDegeneracyCompForgetAugmentedToModule :
ExtraDegeneracy (compForgetAugmented.toModule k G) :=
ExtraDegeneracy.map (extraDegeneracyCompForgetAugmented G) (ModuleCat.free k)
end classifyingSpaceUniversalCover
variable (k)
/-- The standard resolution of `k` as a trivial representation, defined as the alternating
face map complex of a simplicial `k`-linear `G`-representation. -/
def groupCohomology.resolution [Monoid G] :=
(AlgebraicTopology.alternatingFaceMapComplex (Rep k G)).obj
(classifyingSpaceUniversalCover G ⋙ Rep.linearization k G)
namespace groupCohomology.resolution
open classifyingSpaceUniversalCover AlgebraicTopology CategoryTheory CategoryTheory.Limits
variable [Monoid G]
/-- The `k`-linear map underlying the differential in the standard resolution of `k` as a trivial
`k`-linear `G`-representation. It sends `(g₀, ..., gₙ) ↦ ∑ (-1)ⁱ • (g₀, ..., ĝᵢ, ..., gₙ)`. -/
def d (G : Type u) (n : ℕ) : ((Fin (n + 1) → G) →₀ k) →ₗ[k] (Fin n → G) →₀ k :=
Finsupp.lift ((Fin n → G) →₀ k) k (Fin (n + 1) → G) fun g =>
(@Finset.univ (Fin (n + 1)) _).sum fun p =>
Finsupp.single (g ∘ p.succAbove) ((-1 : k) ^ (p : ℕ))
variable {k G}
@[simp]
theorem d_of {G : Type u} {n : ℕ} (c : Fin (n + 1) → G) :
d k G n (Finsupp.single c 1) =
Finset.univ.sum fun p : Fin (n + 1) =>
Finsupp.single (c ∘ p.succAbove) ((-1 : k) ^ (p : ℕ)) := by
simp [d]
variable (k G)
/-- The `n`th object of the standard resolution of `k` is definitionally isomorphic to `k[Gⁿ⁺¹]`
equipped with the representation induced by the diagonal action of `G`. -/
def xIso (n : ℕ) : (groupCohomology.resolution k G).X n ≅ Rep.ofMulAction k G (Fin (n + 1) → G) :=
Iso.refl _
instance x_projective (G : Type u) [Group G] (n : ℕ) :
Projective ((groupCohomology.resolution k G).X n) :=
Rep.equivalenceModuleMonoidAlgebra.toAdjunction.projective_of_map_projective _ <|
@ModuleCat.projective_of_free.{u} _ _
(ModuleCat.of (MonoidAlgebra k G) (Representation.ofMulAction k G (Fin (n + 1) → G)).asModule)
_ (ofMulActionBasis k G n)
/-- Simpler expression for the differential in the standard resolution of `k` as a
`G`-representation. It sends `(g₀, ..., gₙ₊₁) ↦ ∑ (-1)ⁱ • (g₀, ..., ĝᵢ, ..., gₙ₊₁)`. -/
theorem d_eq (n : ℕ) : ((groupCohomology.resolution k G).d (n + 1) n).hom =
ModuleCat.ofHom (d k G (n + 1)) := by
ext : 1
refine Finsupp.lhom_ext' fun x => LinearMap.ext_ring ?_
dsimp [groupCohomology.resolution]
/- Porting note (https://github.com/leanprover-community/mathlib4/issues/11039): broken proof was
simpa [← @intCast_smul k, simplicial_object.δ] -/
simp_rw [alternatingFaceMapComplex_obj_d, AlternatingFaceMapComplex.objD, SimplicialObject.δ,
Functor.comp_map, ← Int.cast_smul_eq_zsmul k ((-1) ^ _ : ℤ), Int.cast_pow, Int.cast_neg,
Int.cast_one, Action.sum_hom, Action.smul_hom, Rep.linearization_map_hom]
rw [ModuleCat.hom_sum, LinearMap.coeFn_sum, Fintype.sum_apply]
erw [d_of (k := k) x]
/- Porting note: want to rewrite `LinearMap.smul_apply` but simp/simp_rw won't do it; I need erw,
so using Finset.sum_congr to get rid of the binder -/
refine Finset.sum_congr rfl fun _ _ => ?_
simp only [ModuleCat.hom_smul, SimplexCategory.len_mk, ModuleCat.hom_ofHom]
erw [LinearMap.smul_apply]
rw [Finsupp.lmapDomain_apply, Finsupp.mapDomain_single, Finsupp.smul_single', mul_one]
rfl
section Exactness
/-- The standard resolution of `k` as a trivial representation as a complex of `k`-modules. -/
def forget₂ToModuleCat :=
((forget₂ (Rep k G) (ModuleCat.{u} k)).mapHomologicalComplex _).obj
(groupCohomology.resolution k G)
/-- If we apply the free functor `Type u ⥤ ModuleCat.{u} k` to the universal cover of the
classifying space of `G` as a simplicial set, then take the alternating face map complex, the result
is isomorphic to the standard resolution of the trivial `G`-representation `k` as a complex of
`k`-modules. -/
def compForgetAugmentedIso :
AlternatingFaceMapComplex.obj
(SimplicialObject.Augmented.drop.obj (compForgetAugmented.toModule k G)) ≅
groupCohomology.resolution.forget₂ToModuleCat k G :=
eqToIso
(Functor.congr_obj (map_alternatingFaceMapComplex (forget₂ (Rep k G) (ModuleCat.{u} k))).symm
(classifyingSpaceUniversalCover G ⋙ Rep.linearization k G))
/-- As a complex of `k`-modules, the standard resolution of the trivial `G`-representation `k` is
homotopy equivalent to the complex which is `k` at 0 and 0 elsewhere. -/
def forget₂ToModuleCatHomotopyEquiv :
HomotopyEquiv (groupCohomology.resolution.forget₂ToModuleCat k G)
| ((ChainComplex.single₀ (ModuleCat k)).obj ((forget₂ (Rep k G) _).obj <| Rep.trivial k G k)) :=
(HomotopyEquiv.ofIso (compForgetAugmentedIso k G).symm).trans <|
(SimplicialObject.Augmented.ExtraDegeneracy.homotopyEquiv
(extraDegeneracyCompForgetAugmentedToModule k G)).trans
(HomotopyEquiv.ofIso <|
| Mathlib/RepresentationTheory/GroupCohomology/Resolution.lean | 531 | 535 |
/-
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.Data.Set.Piecewise
import Mathlib.Logic.Equiv.Defs
import Mathlib.Tactic.Core
import Mathlib.Tactic.Attr.Core
/-!
# Partial equivalences
This files defines equivalences between subsets of given types.
An element `e` of `PartialEquiv α β` is made of two maps `e.toFun` and `e.invFun` respectively
from α to β and from β to α (just like equivs), which are inverse to each other on the subsets
`e.source` and `e.target` of respectively α and β.
They are designed in particular to define charts on manifolds.
The main functionality is `e.trans f`, which composes the two partial equivalences by restricting
the source and target to the maximal set where the composition makes sense.
As for equivs, we register a coercion to functions and use it in our simp normal form: we write
`e x` and `e.symm y` instead of `e.toFun x` and `e.invFun y`.
## Main definitions
* `Equiv.toPartialEquiv`: associating a partial equiv to an equiv, with source = target = univ
* `PartialEquiv.symm`: the inverse of a partial equivalence
* `PartialEquiv.trans`: the composition of two partial equivalences
* `PartialEquiv.refl`: the identity partial equivalence
* `PartialEquiv.ofSet`: the identity on a set `s`
* `EqOnSource`: equivalence relation describing the "right" notion of equality for partial
equivalences (see below in implementation notes)
## Implementation notes
There are at least three possible implementations of partial equivalences:
* equivs on subtypes
* pairs of functions taking values in `Option α` and `Option β`, equal to none where the partial
equivalence is not defined
* pairs of functions defined everywhere, keeping the source and target as additional data
Each of these implementations has pros and cons.
* When dealing with subtypes, one still need to define additional API for composition and
restriction of domains. Checking that one always belongs to the right subtype makes things very
tedious, and leads quickly to DTT hell (as the subtype `u ∩ v` is not the "same" as `v ∩ u`, for
instance).
* With option-valued functions, the composition is very neat (it is just the usual composition, and
the domain is restricted automatically). These are implemented in `PEquiv.lean`. For manifolds,
where one wants to discuss thoroughly the smoothness of the maps, this creates however a lot of
overhead as one would need to extend all classes of smoothness to option-valued maps.
* The `PartialEquiv` version as explained above is easier to use for manifolds. The drawback is that
there is extra useless data (the values of `toFun` and `invFun` outside of `source` and `target`).
In particular, the equality notion between partial equivs is not "the right one", i.e., coinciding
source and target and equality there. Moreover, there are no partial equivs in this sense between
an empty type and a nonempty type. Since empty types are not that useful, and since one almost never
needs to talk about equal partial equivs, this is not an issue in practice.
Still, we introduce an equivalence relation `EqOnSource` that captures this right notion of
equality, and show that many properties are invariant under this equivalence relation.
### 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 Lean Meta Elab Tactic
/-! Implementation of the `mfld_set_tac` tactic for working with the domains of partially-defined
functions (`PartialEquiv`, `PartialHomeomorph`, etc).
This is in a separate file from `Mathlib.Logic.Equiv.MfldSimpsAttr` because attributes need a new
file to become functional.
-/
/-- Common `@[simps]` configuration options used for manifold-related declarations. -/
def mfld_cfg : Simps.Config where
attrs := [`mfld_simps]
fullyApplied := false
namespace Tactic.MfldSetTac
/-- A very basic tactic to show that sets showing up in manifolds coincide or are included
in one another. -/
elab (name := mfldSetTac) "mfld_set_tac" : tactic => withMainContext do
let g ← getMainGoal
let goalTy := (← instantiateMVars (← g.getDecl).type).getAppFnArgs
match goalTy with
| (``Eq, #[_ty, _e₁, _e₂]) =>
evalTactic (← `(tactic| (
apply Set.ext; intro my_y
constructor <;>
· intro h_my_y
try simp only [*, mfld_simps] at h_my_y
try simp only [*, mfld_simps])))
| (``Subset, #[_ty, _inst, _e₁, _e₂]) =>
evalTactic (← `(tactic| (
intro my_y h_my_y
try simp only [*, mfld_simps] at h_my_y
try simp only [*, mfld_simps])))
| _ => throwError "goal should be an equality or an inclusion"
attribute [mfld_simps] and_true eq_self_iff_true Function.comp_apply
end Tactic.MfldSetTac
open Function Set
variable {α : Type*} {β : Type*} {γ : Type*} {δ : Type*}
/-- Local equivalence between subsets `source` and `target` of `α` and `β` respectively. The
(global) maps `toFun : α → β` and `invFun : β → α` map `source` to `target` and conversely, and are
inverse to each other there. The values of `toFun` outside of `source` and of `invFun` outside of
`target` are irrelevant. -/
structure PartialEquiv (α : Type*) (β : Type*) where
/-- The global function which has a partial inverse. Its value outside of the `source` subset is
irrelevant. -/
toFun : α → β
/-- The partial inverse to `toFun`. Its value outside of the `target` subset is irrelevant. -/
invFun : β → α
/-- The domain of the partial equivalence. -/
source : Set α
/-- The codomain of the partial equivalence. -/
target : Set β
/-- The proposition that elements of `source` are mapped to elements of `target`. -/
map_source' : ∀ ⦃x⦄, x ∈ source → toFun x ∈ target
/-- The proposition that elements of `target` are mapped to elements of `source`. -/
map_target' : ∀ ⦃x⦄, x ∈ target → invFun x ∈ source
/-- The proposition that `invFun` is a left-inverse of `toFun` on `source`. -/
left_inv' : ∀ ⦃x⦄, x ∈ source → invFun (toFun x) = x
/-- The proposition that `invFun` is a right-inverse of `toFun` on `target`. -/
right_inv' : ∀ ⦃x⦄, x ∈ target → toFun (invFun x) = x
attribute [coe] PartialEquiv.toFun
namespace PartialEquiv
variable (e : PartialEquiv α β) (e' : PartialEquiv β γ)
instance [Inhabited α] [Inhabited β] : Inhabited (PartialEquiv α β) :=
⟨⟨const α default, const β default, ∅, ∅, mapsTo_empty _ _, mapsTo_empty _ _, eqOn_empty _ _,
eqOn_empty _ _⟩⟩
/-- The inverse of a partial equivalence -/
@[symm]
protected def symm : PartialEquiv β α where
toFun := e.invFun
invFun := e.toFun
source := e.target
target := e.source
map_source' := e.map_target'
map_target' := e.map_source'
left_inv' := e.right_inv'
right_inv' := e.left_inv'
instance : CoeFun (PartialEquiv α β) fun _ => α → β :=
⟨PartialEquiv.toFun⟩
/-- See Note [custom simps projection] -/
def Simps.symm_apply (e : PartialEquiv α β) : β → α :=
e.symm
initialize_simps_projections PartialEquiv (toFun → apply, invFun → symm_apply)
theorem coe_mk (f : α → β) (g s t ml mr il ir) :
(PartialEquiv.mk f g s t ml mr il ir : α → β) = f := rfl
@[simp, mfld_simps]
theorem coe_symm_mk (f : α → β) (g s t ml mr il ir) :
((PartialEquiv.mk f g s t ml mr il ir).symm : β → α) = g :=
rfl
@[simp, mfld_simps]
theorem invFun_as_coe : e.invFun = e.symm :=
rfl
@[simp, mfld_simps]
theorem map_source {x : α} (h : x ∈ e.source) : e x ∈ e.target :=
e.map_source' h
/-- Variant of `e.map_source` and `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 : β} (h : x ∈ e.target) : e.symm x ∈ e.source :=
e.map_target' h
@[simp, mfld_simps]
theorem left_inv {x : α} (h : x ∈ e.source) : e.symm (e x) = x :=
e.left_inv' h
@[simp, mfld_simps]
theorem right_inv {x : β} (h : x ∈ e.target) : e (e.symm x) = x :=
e.right_inv' h
theorem eq_symm_apply {x : α} {y : β} (hx : x ∈ e.source) (hy : y ∈ e.target) :
x = e.symm y ↔ e x = y :=
⟨fun h => by rw [← e.right_inv hy, h], fun h => by rw [← e.left_inv hx, h]⟩
protected theorem mapsTo : MapsTo e e.source e.target := fun _ => e.map_source
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
/-- Interpret an `Equiv` as a `PartialEquiv` by restricting it to `s` in the domain
and to `t` in the codomain. -/
@[simps -fullyApplied]
def _root_.Equiv.toPartialEquivOfImageEq (e : α ≃ β) (s : Set α) (t : Set β) (h : e '' s = t) :
PartialEquiv α β where
toFun := e
invFun := e.symm
source := s
target := t
map_source' _ hx := h ▸ mem_image_of_mem _ hx
map_target' x hx := by
subst t
rcases hx with ⟨x, hx, rfl⟩
rwa [e.symm_apply_apply]
left_inv' x _ := e.symm_apply_apply x
right_inv' x _ := e.apply_symm_apply x
/-- Associate a `PartialEquiv` to an `Equiv`. -/
@[simps! (config := mfld_cfg)]
def _root_.Equiv.toPartialEquiv (e : α ≃ β) : PartialEquiv α β :=
e.toPartialEquivOfImageEq univ univ <| by rw [image_univ, e.surjective.range_eq]
instance inhabitedOfEmpty [IsEmpty α] [IsEmpty β] : Inhabited (PartialEquiv α β) :=
⟨((Equiv.equivEmpty α).trans (Equiv.equivEmpty β).symm).toPartialEquiv⟩
/-- Create a copy of a `PartialEquiv` providing better definitional equalities. -/
@[simps -fullyApplied]
def copy (e : PartialEquiv α β) (f : α → β) (hf : ⇑e = f) (g : β → α) (hg : ⇑e.symm = g) (s : Set α)
(hs : e.source = s) (t : Set β) (ht : e.target = t) :
PartialEquiv α β where
toFun := f
invFun := g
source := s
target := t
map_source' _ := ht ▸ hs ▸ hf ▸ e.map_source
map_target' _ := hs ▸ ht ▸ hg ▸ e.map_target
left_inv' _ := hs ▸ hf ▸ hg ▸ e.left_inv
right_inv' _ := ht ▸ hf ▸ hg ▸ e.right_inv
theorem copy_eq (e : PartialEquiv α β) (f : α → β) (hf : ⇑e = f) (g : β → α) (hg : ⇑e.symm = g)
(s : Set α) (hs : e.source = s) (t : Set β) (ht : e.target = t) :
e.copy f hf g hg s hs t ht = e := by
substs f g s t
cases e
rfl
/-- Associate to a `PartialEquiv` an `Equiv` between the source and the target. -/
protected def toEquiv : e.source ≃ e.target where
toFun x := ⟨e x, e.map_source x.mem⟩
invFun y := ⟨e.symm y, e.map_target y.mem⟩
left_inv := fun ⟨_, hx⟩ => Subtype.eq <| e.left_inv hx
right_inv := fun ⟨_, hy⟩ => Subtype.eq <| e.right_inv hy
@[simp, mfld_simps]
theorem symm_source : e.symm.source = e.target :=
rfl
@[simp, mfld_simps]
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 (PartialEquiv.symm : PartialEquiv α β → PartialEquiv β α) :=
Function.bijective_iff_has_inverse.mpr ⟨_, symm_symm, symm_symm⟩
theorem image_source_eq_target : e '' e.source = e.target :=
e.bijOn.image_eq
theorem forall_mem_target {p : β → Prop} : (∀ y ∈ e.target, p y) ↔ ∀ x ∈ e.source, p (e x) := by
rw [← image_source_eq_target, forall_mem_image]
theorem exists_mem_target {p : β → Prop} : (∃ y ∈ e.target, p y) ↔ ∃ x ∈ e.source, p (e x) := by
rw [← image_source_eq_target, exists_mem_image]
/-- We say that `t : Set β` is an image of `s : Set α` under a partial equivalence if
any of the following equivalent conditions hold:
* `e '' (e.source ∩ s) = e.target ∩ t`;
* `e.source ∩ e ⁻¹ t = e.source ∩ s`;
* `∀ x ∈ e.source, e x ∈ t ↔ x ∈ s` (this one is used in the definition).
-/
def IsImage (s : Set α) (t : Set β) : Prop :=
∀ ⦃x⦄, x ∈ e.source → (e x ∈ t ↔ x ∈ s)
namespace IsImage
variable {e} {s : Set α} {t : Set β} {x : α}
theorem apply_mem_iff (h : e.IsImage s t) (hx : x ∈ e.source) : e x ∈ t ↔ x ∈ s :=
h hx
theorem symm_apply_mem_iff (h : e.IsImage s t) : ∀ ⦃y⦄, y ∈ e.target → (e.symm y ∈ s ↔ y ∈ t) :=
e.forall_mem_target.mpr fun x hx => by rw [e.left_inv hx, h hx]
protected theorem symm (h : e.IsImage s t) : e.symm.IsImage t s :=
h.symm_apply_mem_iff
@[simp]
theorem symm_iff : e.symm.IsImage t s ↔ e.IsImage s t :=
⟨fun h => h.symm, fun h => h.symm⟩
protected theorem mapsTo (h : e.IsImage s t) : MapsTo e (e.source ∩ s) (e.target ∩ t) :=
fun _ hx => ⟨e.mapsTo hx.1, (h hx.1).2 hx.2⟩
theorem symm_mapsTo (h : e.IsImage s t) : MapsTo e.symm (e.target ∩ t) (e.source ∩ s) :=
h.symm.mapsTo
/-- Restrict a `PartialEquiv` to a pair of corresponding sets. -/
@[simps -fullyApplied]
def restr (h : e.IsImage s t) : PartialEquiv α β where
toFun := e
invFun := e.symm
source := e.source ∩ s
target := e.target ∩ t
map_source' := h.mapsTo
map_target' := h.symm_mapsTo
left_inv' := e.leftInvOn.mono inter_subset_left
right_inv' := e.rightInvOn.mono inter_subset_left
theorem image_eq (h : e.IsImage s t) : e '' (e.source ∩ s) = e.target ∩ t :=
h.restr.image_source_eq_target
theorem symm_image_eq (h : e.IsImage s t) : e.symm '' (e.target ∩ t) = e.source ∩ s :=
h.symm.image_eq
theorem iff_preimage_eq : e.IsImage s t ↔ e.source ∩ e ⁻¹' t = e.source ∩ s := by
simp only [IsImage, Set.ext_iff, mem_inter_iff, mem_preimage, and_congr_right_iff]
alias ⟨preimage_eq, of_preimage_eq⟩ := iff_preimage_eq
theorem iff_symm_preimage_eq : e.IsImage s t ↔ e.target ∩ e.symm ⁻¹' s = e.target ∩ t :=
symm_iff.symm.trans iff_preimage_eq
alias ⟨symm_preimage_eq, of_symm_preimage_eq⟩ := iff_symm_preimage_eq
theorem of_image_eq (h : e '' (e.source ∩ s) = e.target ∩ t) : e.IsImage s t :=
of_symm_preimage_eq <| Eq.trans (of_symm_preimage_eq rfl).image_eq.symm h
theorem of_symm_image_eq (h : e.symm '' (e.target ∩ t) = e.source ∩ s) : e.IsImage s t :=
of_preimage_eq <| Eq.trans (iff_preimage_eq.2 rfl).symm_image_eq.symm h
protected theorem compl (h : e.IsImage s t) : e.IsImage sᶜ tᶜ := fun _ hx => not_congr (h hx)
protected theorem inter {s' t'} (h : e.IsImage s t) (h' : e.IsImage s' t') :
e.IsImage (s ∩ s') (t ∩ t') := fun _ hx => and_congr (h hx) (h' hx)
protected theorem union {s' t'} (h : e.IsImage s t) (h' : e.IsImage s' t') :
e.IsImage (s ∪ s') (t ∪ t') := fun _ hx => or_congr (h hx) (h' hx)
protected theorem diff {s' t'} (h : e.IsImage s t) (h' : e.IsImage s' t') :
e.IsImage (s \ s') (t \ t') :=
h.inter h'.compl
theorem leftInvOn_piecewise {e' : PartialEquiv α β} [∀ i, Decidable (i ∈ s)]
[∀ i, Decidable (i ∈ t)] (h : e.IsImage s t) (h' : e'.IsImage s t) :
LeftInvOn (t.piecewise e.symm e'.symm) (s.piecewise e e') (s.ite e.source e'.source) := by
rintro x (⟨he, hs⟩ | ⟨he, hs : x ∉ s⟩)
· rw [piecewise_eq_of_mem _ _ _ hs, piecewise_eq_of_mem _ _ _ ((h he).2 hs), e.left_inv he]
· rw [piecewise_eq_of_not_mem _ _ _ hs, piecewise_eq_of_not_mem _ _ _ ((h'.compl he).2 hs),
e'.left_inv he]
theorem inter_eq_of_inter_eq_of_eqOn {e' : PartialEquiv α β} (h : e.IsImage s t)
(h' : e'.IsImage s t) (hs : e.source ∩ s = e'.source ∩ s) (heq : EqOn e e' (e.source ∩ s)) :
e.target ∩ t = e'.target ∩ t := by rw [← h.image_eq, ← h'.image_eq, ← hs, heq.image_eq]
theorem symm_eq_on_of_inter_eq_of_eqOn {e' : PartialEquiv α β} (h : e.IsImage s t)
(hs : e.source ∩ s = e'.source ∩ s) (heq : EqOn e e' (e.source ∩ s)) :
EqOn e.symm e'.symm (e.target ∩ t) := by
rw [← h.image_eq]
rintro y ⟨x, hx, rfl⟩
have hx' := hx; rw [hs] at hx'
rw [e.left_inv hx.1, heq hx, e'.left_inv hx'.1]
end IsImage
theorem isImage_source_target : e.IsImage e.source e.target := fun x hx => by simp [hx]
theorem isImage_source_target_of_disjoint (e' : PartialEquiv α β) (hs : Disjoint e.source e'.source)
(ht : Disjoint e.target e'.target) : e.IsImage e'.source e'.target :=
IsImage.of_image_eq <| by rw [hs.inter_eq, ht.inter_eq, image_empty]
theorem image_source_inter_eq' (s : Set α) : e '' (e.source ∩ s) = e.target ∩ e.symm ⁻¹' s := by
rw [inter_comm, e.leftInvOn.image_inter', image_source_eq_target, inter_comm]
theorem image_source_inter_eq (s : Set α) :
e '' (e.source ∩ s) = e.target ∩ e.symm ⁻¹' (e.source ∩ s) := by
rw [inter_comm, e.leftInvOn.image_inter, image_source_eq_target, inter_comm]
theorem image_eq_target_inter_inv_preimage {s : Set α} (h : s ⊆ e.source) :
e '' s = e.target ∩ e.symm ⁻¹' s := by
rw [← e.image_source_inter_eq', inter_eq_self_of_subset_right h]
theorem symm_image_eq_source_inter_preimage {s : Set β} (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 β) :
e.symm '' (e.target ∩ s) = e.source ∩ e ⁻¹' (e.target ∩ s) :=
e.symm.image_source_inter_eq _
theorem symm_image_target_inter_eq' (s : Set β) : e.symm '' (e.target ∩ s) = e.source ∩ e ⁻¹' s :=
e.symm.image_source_inter_eq' _
theorem source_inter_preimage_inv_preimage (s : Set α) :
e.source ∩ e ⁻¹' (e.symm ⁻¹' s) = e.source ∩ s :=
Set.ext fun x => and_congr_right_iff.2 fun hx =>
by simp only [mem_preimage, e.left_inv hx]
theorem source_inter_preimage_target_inter (s : Set β) :
e.source ∩ e ⁻¹' (e.target ∩ s) = e.source ∩ e ⁻¹' s :=
ext fun _ => ⟨fun hx => ⟨hx.1, hx.2.2⟩, fun hx => ⟨hx.1, e.map_source hx.1, hx.2⟩⟩
theorem target_inter_inv_preimage_preimage (s : Set β) :
e.target ∩ e.symm ⁻¹' (e ⁻¹' s) = e.target ∩ s :=
e.symm.source_inter_preimage_inv_preimage _
theorem symm_image_image_of_subset_source {s : Set α} (h : s ⊆ e.source) : e.symm '' (e '' s) = s :=
(e.leftInvOn.mono h).image_image
theorem image_symm_image_of_subset_target {s : Set β} (h : s ⊆ e.target) : e '' (e.symm '' s) = s :=
e.symm.symm_image_image_of_subset_source h
theorem source_subset_preimage_target : e.source ⊆ e ⁻¹' e.target :=
e.mapsTo
theorem symm_image_target_eq_source : e.symm '' e.target = e.source :=
e.symm.image_source_eq_target
theorem target_subset_preimage_source : e.target ⊆ e.symm ⁻¹' e.source :=
e.symm_mapsTo
/-- Two partial equivs that have the same `source`, same `toFun` and same `invFun`, coincide. -/
@[ext]
protected theorem ext {e e' : PartialEquiv α β} (h : ∀ x, e x = e' x)
(hsymm : ∀ x, e.symm x = e'.symm x) (hs : e.source = e'.source) : e = e' := by
have A : (e : α → β) = e' := by
ext x
exact h x
have B : (e.symm : β → α) = e'.symm := by
ext x
exact hsymm x
have I : e '' e.source = e.target := e.image_source_eq_target
have I' : e' '' e'.source = e'.target := e'.image_source_eq_target
rw [A, hs, I'] at I
cases e; cases e'
simp_all
/-- Restricting a partial equivalence to `e.source ∩ s` -/
protected def restr (s : Set α) : PartialEquiv α β :=
(@IsImage.of_symm_preimage_eq α β e s (e.symm ⁻¹' s) rfl).restr
@[simp, mfld_simps]
theorem restr_coe (s : Set α) : (e.restr s : α → β) = e :=
rfl
@[simp, mfld_simps]
theorem restr_coe_symm (s : Set α) : ((e.restr s).symm : β → α) = e.symm :=
rfl
@[simp, mfld_simps]
theorem restr_source (s : Set α) : (e.restr s).source = e.source ∩ s :=
rfl
theorem source_restr_subset_source (s : Set α) : (e.restr s).source ⊆ e.source := inter_subset_left
@[simp, mfld_simps]
theorem restr_target (s : Set α) : (e.restr s).target = e.target ∩ e.symm ⁻¹' s :=
rfl
theorem restr_eq_of_source_subset {e : PartialEquiv α β} {s : Set α} (h : e.source ⊆ s) :
e.restr s = e :=
PartialEquiv.ext (fun _ => rfl) (fun _ => rfl) (by simp [inter_eq_self_of_subset_left h])
@[simp, mfld_simps]
theorem restr_univ {e : PartialEquiv α β} : e.restr univ = e :=
restr_eq_of_source_subset (subset_univ _)
/-- The identity partial equiv -/
protected def refl (α : Type*) : PartialEquiv α α :=
(Equiv.refl α).toPartialEquiv
@[simp, mfld_simps]
theorem refl_source : (PartialEquiv.refl α).source = univ :=
rfl
@[simp, mfld_simps]
theorem refl_target : (PartialEquiv.refl α).target = univ :=
rfl
@[simp, mfld_simps]
theorem refl_coe : (PartialEquiv.refl α : α → α) = id :=
rfl
@[simp, mfld_simps]
theorem refl_symm : (PartialEquiv.refl α).symm = PartialEquiv.refl α :=
rfl
@[mfld_simps]
theorem refl_restr_source (s : Set α) : ((PartialEquiv.refl α).restr s).source = s := by simp
@[mfld_simps]
theorem refl_restr_target (s : Set α) : ((PartialEquiv.refl α).restr s).target = s := by simp
/-- The identity partial equivalence on a set `s` -/
def ofSet (s : Set α) : PartialEquiv α α where
toFun := id
invFun := id
source := s
target := s
map_source' _ hx := hx
map_target' _ hx := hx
left_inv' _ _ := rfl
right_inv' _ _ := rfl
@[simp, mfld_simps]
theorem ofSet_source (s : Set α) : (PartialEquiv.ofSet s).source = s :=
rfl
@[simp, mfld_simps]
theorem ofSet_target (s : Set α) : (PartialEquiv.ofSet s).target = s :=
rfl
@[simp, mfld_simps]
theorem ofSet_coe (s : Set α) : (PartialEquiv.ofSet s : α → α) = id :=
rfl
@[simp, mfld_simps]
theorem ofSet_symm (s : Set α) : (PartialEquiv.ofSet s).symm = PartialEquiv.ofSet s :=
rfl
/-- `Function.const` as a `PartialEquiv`.
It consists of two constant maps in opposite directions. -/
@[simps]
def single (a : α) (b : β) : PartialEquiv α β where
toFun := Function.const α b
invFun := Function.const β a
source := {a}
target := {b}
map_source' _ _ := rfl
map_target' _ _ := rfl
left_inv' a' ha' := by rw [eq_of_mem_singleton ha', const_apply]
right_inv' b' hb' := by rw [eq_of_mem_singleton hb', const_apply]
/-- Composing two partial equivs if the target of the first coincides with the source of the
second. -/
@[simps]
protected def trans' (e' : PartialEquiv β γ) (h : e.target = e'.source) : PartialEquiv α γ where
toFun := e' ∘ e
invFun := e.symm ∘ e'.symm
source := e.source
target := e'.target
map_source' x hx := by simp [← h, hx]
map_target' y hy := by simp [h, hy]
left_inv' x hx := by simp [hx, ← h]
right_inv' y hy := by simp [hy, h]
/-- Composing two partial equivs, by restricting to the maximal domain where their composition
is well defined.
Within the `Manifold` namespace, there is the notation `e ≫ f` for this.
-/
@[trans]
protected def trans : PartialEquiv α γ :=
PartialEquiv.trans' (e.symm.restr e'.source).symm (e'.restr e.target) (inter_comm _ _)
@[simp, mfld_simps]
theorem coe_trans : (e.trans e' : α → γ) = e' ∘ e :=
rfl
@[simp, mfld_simps]
theorem coe_trans_symm : ((e.trans e').symm : γ → α) = e.symm ∘ e'.symm :=
rfl
theorem trans_apply {x : α} : (e.trans e') x = e' (e x) :=
rfl
theorem trans_symm_eq_symm_trans_symm : (e.trans e').symm = e'.symm.trans e.symm := by
cases e; cases e'; rfl
@[simp, mfld_simps]
theorem trans_source : (e.trans e').source = e.source ∩ e ⁻¹' e'.source :=
rfl
theorem trans_source' : (e.trans e').source = e.source ∩ e ⁻¹' (e.target ∩ e'.source) := by
mfld_set_tac
theorem trans_source'' : (e.trans e').source = e.symm '' (e.target ∩ e'.source) := by
rw [e.trans_source', e.symm_image_target_inter_eq]
theorem image_trans_source : e '' (e.trans e').source = e.target ∩ e'.source :=
(e.symm.restr e'.source).symm.image_source_eq_target
@[simp, mfld_simps]
theorem trans_target : (e.trans e').target = e'.target ∩ e'.symm ⁻¹' e.target :=
rfl
theorem trans_target' : (e.trans e').target = e'.target ∩ e'.symm ⁻¹' (e'.source ∩ e.target) :=
trans_source' e'.symm e.symm
theorem trans_target'' : (e.trans e').target = e' '' (e'.source ∩ e.target) :=
trans_source'' e'.symm e.symm
theorem inv_image_trans_target : e'.symm '' (e.trans e').target = e'.source ∩ e.target :=
image_trans_source e'.symm e.symm
theorem trans_assoc (e'' : PartialEquiv γ δ) : (e.trans e').trans e'' = e.trans (e'.trans e'') :=
PartialEquiv.ext (fun _ => rfl) (fun _ => rfl)
(by simp [trans_source, @preimage_comp α β γ, inter_assoc])
@[simp, mfld_simps]
theorem trans_refl : e.trans (PartialEquiv.refl β) = e :=
PartialEquiv.ext (fun _ => rfl) (fun _ => rfl) (by simp [trans_source])
@[simp, mfld_simps]
theorem refl_trans : (PartialEquiv.refl α).trans e = e :=
PartialEquiv.ext (fun _ => rfl) (fun _ => rfl) (by simp [trans_source, preimage_id])
theorem trans_ofSet (s : Set β) : e.trans (ofSet s) = e.restr (e ⁻¹' s) :=
PartialEquiv.ext (fun _ => rfl) (fun _ => rfl) rfl
theorem trans_refl_restr (s : Set β) :
e.trans ((PartialEquiv.refl β).restr s) = e.restr (e ⁻¹' s) :=
PartialEquiv.ext (fun _ => rfl) (fun _ => rfl) (by simp [trans_source])
theorem trans_refl_restr' (s : Set β) :
e.trans ((PartialEquiv.refl β).restr s) = e.restr (e.source ∩ e ⁻¹' s) :=
PartialEquiv.ext (fun _ => rfl) (fun _ => rfl) <| by
simp only [trans_source, restr_source, refl_source, univ_inter]
rw [← inter_assoc, inter_self]
theorem restr_trans (s : Set α) : (e.restr s).trans e' = (e.trans e').restr s :=
PartialEquiv.ext (fun _ => rfl) (fun _ => rfl) <| by
simp [trans_source, inter_comm, inter_assoc]
/-- A lemma commonly useful when `e` and `e'` are charts of a manifold. -/
theorem mem_symm_trans_source {e' : PartialEquiv α γ} {x : α} (he : x ∈ e.source)
(he' : x ∈ e'.source) : e x ∈ (e.symm.trans e').source :=
⟨e.mapsTo he, by rwa [mem_preimage, PartialEquiv.symm_symm, e.left_inv he]⟩
/-- `EqOnSource e e'` means that `e` and `e'` have the same source, and coincide there. Then `e`
and `e'` should really be considered the same partial equiv. -/
def EqOnSource (e e' : PartialEquiv α β) : Prop :=
e.source = e'.source ∧ e.source.EqOn e e'
/-- `EqOnSource` is an equivalence relation. This instance provides the `≈` notation between two
`PartialEquiv`s. -/
instance eqOnSourceSetoid : Setoid (PartialEquiv α β) where
r := EqOnSource
iseqv := by constructor <;> simp only [Equivalence, EqOnSource, EqOn] <;> aesop
theorem eqOnSource_refl : e ≈ e :=
Setoid.refl _
/-- Two equivalent partial equivs have the same source. -/
theorem EqOnSource.source_eq {e e' : PartialEquiv α β} (h : e ≈ e') : e.source = e'.source :=
h.1
/-- Two equivalent partial equivs coincide on the source. -/
theorem EqOnSource.eqOn {e e' : PartialEquiv α β} (h : e ≈ e') : e.source.EqOn e e' :=
h.2
/-- Two equivalent partial equivs have the same target. -/
theorem EqOnSource.target_eq {e e' : PartialEquiv α β} (h : e ≈ e') : e.target = e'.target := by
simp only [← image_source_eq_target, ← source_eq h, h.2.image_eq]
/-- If two partial equivs are equivalent, so are their inverses. -/
theorem EqOnSource.symm' {e e' : PartialEquiv α β} (h : e ≈ e') : e.symm ≈ e'.symm := by
refine ⟨target_eq h, eqOn_of_leftInvOn_of_rightInvOn e.leftInvOn ?_ ?_⟩ <;>
simp only [symm_source, target_eq h, source_eq h, e'.symm_mapsTo]
exact e'.rightInvOn.congr_right e'.symm_mapsTo (source_eq h ▸ h.eqOn.symm)
/-- Two equivalent partial equivs have coinciding inverses on the target. -/
theorem EqOnSource.symm_eqOn {e e' : PartialEquiv α β} (h : e ≈ e') :
EqOn e.symm e'.symm e.target :=
-- Porting note: `h.symm'` dot notation doesn't work anymore because `h` is not recognised as
-- `PartialEquiv.EqOnSource` for some reason.
eqOn (symm' h)
/-- Composition of partial equivs respects equivalence. -/
theorem EqOnSource.trans' {e e' : PartialEquiv α β} {f f' : PartialEquiv β γ} (he : e ≈ e')
(hf : f ≈ f') : e.trans f ≈ e'.trans f' := by
constructor
· rw [trans_source'', trans_source'', ← target_eq he, ← hf.1]
exact (he.symm'.eqOn.mono inter_subset_left).image_eq
· intro x hx
rw [trans_source] at hx
simp [Function.comp_apply, PartialEquiv.coe_trans, (he.2 hx.1).symm, hf.2 hx.2]
/-- Restriction of partial equivs respects equivalence. -/
theorem EqOnSource.restr {e e' : PartialEquiv α β} (he : e ≈ e') (s : Set α) :
e.restr s ≈ e'.restr s := by
constructor
· simp [he.1]
· intro x hx
simp only [mem_inter_iff, restr_source] at hx
exact he.2 hx.1
/-- Preimages are respected by equivalence. -/
theorem EqOnSource.source_inter_preimage_eq {e e' : PartialEquiv α β} (he : e ≈ e') (s : Set β) :
e.source ∩ e ⁻¹' s = e'.source ∩ e' ⁻¹' s := by rw [he.eqOn.inter_preimage_eq, source_eq he]
/-- Composition of a partial equivalence and its inverse is equivalent to
the restriction of the identity to the source. -/
theorem self_trans_symm : e.trans e.symm ≈ ofSet e.source := by
have A : (e.trans e.symm).source = e.source := by mfld_set_tac
refine ⟨by rw [A, ofSet_source], fun x hx => ?_⟩
rw [A] at hx
simp only [hx, mfld_simps]
/-- Composition of the inverse of a partial equivalence and this partial equivalence is equivalent
to the restriction of the identity to the target. -/
theorem symm_trans_self : e.symm.trans e ≈ ofSet e.target :=
self_trans_symm e.symm
/-- Two equivalent partial equivs are equal when the source and target are `univ`. -/
theorem eq_of_eqOnSource_univ (e e' : PartialEquiv α β) (h : e ≈ e') (s : e.source = univ)
(t : e.target = univ) : e = e' := by
refine PartialEquiv.ext (fun x => ?_) (fun x => ?_) h.1
· apply h.2
rw [s]
exact mem_univ _
· apply h.symm'.2
rw [symm_source, t]
exact mem_univ _
section Prod
/-- The product of two partial equivalences, as a partial equivalence on the product. -/
def prod (e : PartialEquiv α β) (e' : PartialEquiv γ δ) : PartialEquiv (α × γ) (β × δ) where
source := e.source ×ˢ e'.source
target := e.target ×ˢ e'.target
toFun p := (e p.1, e' p.2)
invFun p := (e.symm p.1, e'.symm p.2)
map_source' p hp := by simp_all
map_target' p hp := by simp_all
left_inv' p hp := by simp_all
right_inv' p hp := by simp_all
@[simp, mfld_simps]
theorem prod_source (e : PartialEquiv α β) (e' : PartialEquiv γ δ) :
(e.prod e').source = e.source ×ˢ e'.source :=
rfl
@[simp, mfld_simps]
theorem prod_target (e : PartialEquiv α β) (e' : PartialEquiv γ δ) :
(e.prod e').target = e.target ×ˢ e'.target :=
rfl
@[simp, mfld_simps]
theorem prod_coe (e : PartialEquiv α β) (e' : PartialEquiv γ δ) :
(e.prod e' : α × γ → β × δ) = fun p => (e p.1, e' p.2) :=
rfl
theorem prod_coe_symm (e : PartialEquiv α β) (e' : PartialEquiv γ δ) :
((e.prod e').symm : β × δ → α × γ) = fun p => (e.symm p.1, e'.symm p.2) :=
rfl
@[simp, mfld_simps]
theorem prod_symm (e : PartialEquiv α β) (e' : PartialEquiv γ δ) :
(e.prod e').symm = e.symm.prod e'.symm := by
ext x <;> simp [prod_coe_symm]
@[simp, mfld_simps]
theorem refl_prod_refl :
(PartialEquiv.refl α).prod (PartialEquiv.refl β) = PartialEquiv.refl (α × β) := by
ext ⟨x, y⟩ <;> simp
@[simp, mfld_simps]
theorem prod_trans {η : Type*} {ε : Type*} (e : PartialEquiv α β) (f : PartialEquiv β γ)
(e' : PartialEquiv δ η) (f' : PartialEquiv η ε) :
(e.prod e').trans (f.prod f') = (e.trans f).prod (e'.trans f') := by
ext ⟨x, y⟩ <;> simp [Set.ext_iff]; tauto
end Prod
/-- Combine two `PartialEquiv`s using `Set.piecewise`. The source of the new `PartialEquiv` is
`s.ite e.source e'.source = e.source ∩ s ∪ e'.source \ s`, and similarly for target. The function
sends `e.source ∩ s` to `e.target ∩ t` using `e` and `e'.source \ s` to `e'.target \ t` using `e'`,
and similarly for the inverse function. The definition assumes `e.isImage s t` and
`e'.isImage s t`. -/
@[simps -fullyApplied]
def piecewise (e e' : PartialEquiv α β) (s : Set α) (t : Set β) [∀ x, Decidable (x ∈ s)]
[∀ y, Decidable (y ∈ t)] (H : e.IsImage s t) (H' : e'.IsImage s t) :
PartialEquiv α β where
toFun := s.piecewise e e'
invFun := t.piecewise e.symm e'.symm
source := s.ite e.source e'.source
target := t.ite e.target e'.target
map_source' := H.mapsTo.piecewise_ite H'.compl.mapsTo
map_target' := H.symm.mapsTo.piecewise_ite H'.symm.compl.mapsTo
left_inv' := H.leftInvOn_piecewise H'
right_inv' := H.symm.leftInvOn_piecewise H'.symm
theorem symm_piecewise (e e' : PartialEquiv α β) {s : Set α} {t : Set β} [∀ x, Decidable (x ∈ s)]
[∀ y, Decidable (y ∈ t)] (H : e.IsImage s t) (H' : e'.IsImage s t) :
(e.piecewise e' s t H H').symm = e.symm.piecewise e'.symm t s H.symm H'.symm :=
rfl
/-- Combine two `PartialEquiv`s with disjoint sources and disjoint targets. We reuse
`PartialEquiv.piecewise`, then override `source` and `target` to ensure better definitional
equalities. -/
@[simps! -fullyApplied]
def disjointUnion (e e' : PartialEquiv α β) (hs : Disjoint e.source e'.source)
(ht : Disjoint e.target e'.target) [∀ x, Decidable (x ∈ e.source)]
[∀ y, Decidable (y ∈ e.target)] : PartialEquiv α β :=
(e.piecewise e' e.source e.target e.isImage_source_target <|
e'.isImage_source_target_of_disjoint _ hs.symm ht.symm).copy
_ rfl _ rfl (e.source ∪ e'.source) (ite_left _ _) (e.target ∪ e'.target) (ite_left _ _)
theorem disjointUnion_eq_piecewise (e e' : PartialEquiv α β) (hs : Disjoint e.source e'.source)
(ht : Disjoint e.target e'.target) [∀ x, Decidable (x ∈ e.source)]
[∀ y, Decidable (y ∈ e.target)] :
e.disjointUnion e' hs ht =
e.piecewise e' e.source e.target e.isImage_source_target
(e'.isImage_source_target_of_disjoint _ hs.symm ht.symm) :=
copy_eq ..
section Pi
variable {ι : Type*} {αi βi γi : ι → Type*}
/-- The product of a family of partial equivalences, as a partial equivalence on the pi type. -/
@[simps (config := mfld_cfg) apply source target]
protected def pi (ei : ∀ i, PartialEquiv (αi i) (βi i)) : PartialEquiv (∀ i, αi i) (∀ i, βi i) where
toFun := Pi.map fun i ↦ ei i
| invFun := Pi.map fun i ↦ (ei i).symm
source := pi univ fun i => (ei i).source
target := pi univ fun i => (ei i).target
map_source' _ hf i hi := (ei i).map_source (hf i hi)
map_target' _ hf i hi := (ei i).map_target (hf i hi)
left_inv' _ hf := funext fun i => (ei i).left_inv (hf i trivial)
right_inv' _ hf := funext fun i => (ei i).right_inv (hf i trivial)
| Mathlib/Logic/Equiv/PartialEquiv.lean | 851 | 857 |
/-
Copyright (c) 2021 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov, Alistair Tucker, Wen Yang
-/
import Mathlib.Order.Interval.Set.Image
import Mathlib.Order.CompleteLatticeIntervals
import Mathlib.Topology.Order.DenselyOrdered
import Mathlib.Topology.Order.Monotone
import Mathlib.Topology.Connected.TotallyDisconnected
/-!
# Intermediate Value Theorem
In this file we prove the Intermediate Value Theorem: if `f : α → β` is a function defined on a
connected set `s` that takes both values `≤ a` and values `≥ a` on `s`, then it is equal to `a` at
some point of `s`. We also prove that intervals in a dense conditionally complete order are
preconnected and any preconnected set is an interval. Then we specialize IVT to functions continuous
on intervals.
## Main results
* `IsPreconnected_I??` : all intervals `I??` are preconnected,
* `IsPreconnected.intermediate_value`, `intermediate_value_univ` : Intermediate Value Theorem for
connected sets and connected spaces, respectively;
* `intermediate_value_Icc`, `intermediate_value_Icc'`: Intermediate Value Theorem for functions
on closed intervals.
### Miscellaneous facts
* `IsClosed.Icc_subset_of_forall_mem_nhdsWithin` : “Continuous induction” principle;
if `s ∩ [a, b]` is closed, `a ∈ s`, and for each `x ∈ [a, b) ∩ s` some of its right neighborhoods
is included `s`, then `[a, b] ⊆ s`.
* `IsClosed.Icc_subset_of_forall_exists_gt`, `IsClosed.mem_of_ge_of_forall_exists_gt` : two
other versions of the “continuous induction” principle.
* `ContinuousOn.StrictMonoOn_of_InjOn_Ioo` :
Every continuous injective `f : (a, b) → δ` is strictly monotone
or antitone (increasing or decreasing).
## Tags
intermediate value theorem, connected space, connected set
-/
open Filter OrderDual TopologicalSpace Function Set
open scoped Topology Filter Interval
universe u v
/-!
### Intermediate value theorem on a (pre)connected space
In this section we prove the following theorem (see `IsPreconnected.intermediate_value₂`): if `f`
and `g` are two functions continuous on a preconnected set `s`, `f a ≤ g a` at some `a ∈ s` and
`g b ≤ f b` at some `b ∈ s`, then `f c = g c` at some `c ∈ s`. We prove several versions of this
statement, including the classical IVT that corresponds to a constant function `g`.
-/
section
variable {X : Type u} {α : Type v} [TopologicalSpace X] [LinearOrder α] [TopologicalSpace α]
[OrderClosedTopology α]
/-- Intermediate value theorem for two functions: if `f` and `g` are two continuous functions
on a preconnected space and `f a ≤ g a` and `g b ≤ f b`, then for some `x` we have `f x = g x`. -/
theorem intermediate_value_univ₂ [PreconnectedSpace X] {a b : X} {f g : X → α} (hf : Continuous f)
(hg : Continuous g) (ha : f a ≤ g a) (hb : g b ≤ f b) : ∃ x, f x = g x := by
obtain ⟨x, _, hfg, hgf⟩ : (univ ∩ { x | f x ≤ g x ∧ g x ≤ f x }).Nonempty :=
isPreconnected_closed_iff.1 PreconnectedSpace.isPreconnected_univ _ _ (isClosed_le hf hg)
(isClosed_le hg hf) (fun _ _ => le_total _ _) ⟨a, trivial, ha⟩ ⟨b, trivial, hb⟩
exact ⟨x, le_antisymm hfg hgf⟩
theorem intermediate_value_univ₂_eventually₁ [PreconnectedSpace X] {a : X} {l : Filter X} [NeBot l]
{f g : X → α} (hf : Continuous f) (hg : Continuous g) (ha : f a ≤ g a) (he : g ≤ᶠ[l] f) :
∃ x, f x = g x :=
let ⟨_, h⟩ := he.exists; intermediate_value_univ₂ hf hg ha h
theorem intermediate_value_univ₂_eventually₂ [PreconnectedSpace X] {l₁ l₂ : Filter X} [NeBot l₁]
[NeBot l₂] {f g : X → α} (hf : Continuous f) (hg : Continuous g) (he₁ : f ≤ᶠ[l₁] g)
(he₂ : g ≤ᶠ[l₂] f) : ∃ x, f x = g x :=
let ⟨_, h₁⟩ := he₁.exists
let ⟨_, h₂⟩ := he₂.exists
intermediate_value_univ₂ hf hg h₁ h₂
/-- Intermediate value theorem for two functions: if `f` and `g` are two functions continuous
on a preconnected set `s` and for some `a b ∈ s` we have `f a ≤ g a` and `g b ≤ f b`,
then for some `x ∈ s` we have `f x = g x`. -/
theorem IsPreconnected.intermediate_value₂ {s : Set X} (hs : IsPreconnected s) {a b : X}
(ha : a ∈ s) (hb : b ∈ s) {f g : X → α} (hf : ContinuousOn f s) (hg : ContinuousOn g s)
(ha' : f a ≤ g a) (hb' : g b ≤ f b) : ∃ x ∈ s, f x = g x :=
let ⟨x, hx⟩ :=
@intermediate_value_univ₂ s α _ _ _ _ (Subtype.preconnectedSpace hs) ⟨a, ha⟩ ⟨b, hb⟩ _ _
(continuousOn_iff_continuous_restrict.1 hf) (continuousOn_iff_continuous_restrict.1 hg) ha'
hb'
⟨x, x.2, hx⟩
theorem IsPreconnected.intermediate_value₂_eventually₁ {s : Set X} (hs : IsPreconnected s) {a : X}
{l : Filter X} (ha : a ∈ s) [NeBot l] (hl : l ≤ 𝓟 s) {f g : X → α} (hf : ContinuousOn f s)
(hg : ContinuousOn g s) (ha' : f a ≤ g a) (he : g ≤ᶠ[l] f) : ∃ x ∈ s, f x = g x := by
rw [continuousOn_iff_continuous_restrict] at hf hg
obtain ⟨b, h⟩ :=
@intermediate_value_univ₂_eventually₁ _ _ _ _ _ _ (Subtype.preconnectedSpace hs) ⟨a, ha⟩ _
(comap_coe_neBot_of_le_principal hl) _ _ hf hg ha' (he.comap _)
exact ⟨b, b.prop, h⟩
theorem IsPreconnected.intermediate_value₂_eventually₂ {s : Set X} (hs : IsPreconnected s)
{l₁ l₂ : Filter X} [NeBot l₁] [NeBot l₂] (hl₁ : l₁ ≤ 𝓟 s) (hl₂ : l₂ ≤ 𝓟 s) {f g : X → α}
(hf : ContinuousOn f s) (hg : ContinuousOn g s) (he₁ : f ≤ᶠ[l₁] g) (he₂ : g ≤ᶠ[l₂] f) :
∃ x ∈ s, f x = g x := by
rw [continuousOn_iff_continuous_restrict] at hf hg
obtain ⟨b, h⟩ :=
@intermediate_value_univ₂_eventually₂ _ _ _ _ _ _ (Subtype.preconnectedSpace hs) _ _
(comap_coe_neBot_of_le_principal hl₁) (comap_coe_neBot_of_le_principal hl₂) _ _ hf hg
(he₁.comap _) (he₂.comap _)
exact ⟨b, b.prop, h⟩
/-- **Intermediate Value Theorem** for continuous functions on connected sets. -/
theorem IsPreconnected.intermediate_value {s : Set X} (hs : IsPreconnected s) {a b : X} (ha : a ∈ s)
(hb : b ∈ s) {f : X → α} (hf : ContinuousOn f s) : Icc (f a) (f b) ⊆ f '' s := fun _x hx =>
hs.intermediate_value₂ ha hb hf continuousOn_const hx.1 hx.2
theorem IsPreconnected.intermediate_value_Ico {s : Set X} (hs : IsPreconnected s) {a : X}
{l : Filter X} (ha : a ∈ s) [NeBot l] (hl : l ≤ 𝓟 s) {f : X → α} (hf : ContinuousOn f s) {v : α}
(ht : Tendsto f l (𝓝 v)) : Ico (f a) v ⊆ f '' s := fun _ h =>
hs.intermediate_value₂_eventually₁ ha hl hf continuousOn_const h.1 (ht.eventually_const_le h.2)
theorem IsPreconnected.intermediate_value_Ioc {s : Set X} (hs : IsPreconnected s) {a : X}
{l : Filter X} (ha : a ∈ s) [NeBot l] (hl : l ≤ 𝓟 s) {f : X → α} (hf : ContinuousOn f s) {v : α}
(ht : Tendsto f l (𝓝 v)) : Ioc v (f a) ⊆ f '' s := fun _ h =>
(hs.intermediate_value₂_eventually₁ ha hl continuousOn_const hf h.2
(ht.eventually_le_const h.1)).imp fun _ h => h.imp_right Eq.symm
theorem IsPreconnected.intermediate_value_Ioo {s : Set X} (hs : IsPreconnected s) {l₁ l₂ : Filter X}
[NeBot l₁] [NeBot l₂] (hl₁ : l₁ ≤ 𝓟 s) (hl₂ : l₂ ≤ 𝓟 s) {f : X → α} (hf : ContinuousOn f s)
{v₁ v₂ : α} (ht₁ : Tendsto f l₁ (𝓝 v₁)) (ht₂ : Tendsto f l₂ (𝓝 v₂)) :
Ioo v₁ v₂ ⊆ f '' s := fun _ h =>
hs.intermediate_value₂_eventually₂ hl₁ hl₂ hf continuousOn_const
(ht₁.eventually_le_const h.1) (ht₂.eventually_const_le h.2)
theorem IsPreconnected.intermediate_value_Ici {s : Set X} (hs : IsPreconnected s) {a : X}
{l : Filter X} (ha : a ∈ s) [NeBot l] (hl : l ≤ 𝓟 s) {f : X → α} (hf : ContinuousOn f s)
(ht : Tendsto f l atTop) : Ici (f a) ⊆ f '' s := fun y h =>
hs.intermediate_value₂_eventually₁ ha hl hf continuousOn_const h (tendsto_atTop.1 ht y)
theorem IsPreconnected.intermediate_value_Iic {s : Set X} (hs : IsPreconnected s) {a : X}
{l : Filter X} (ha : a ∈ s) [NeBot l] (hl : l ≤ 𝓟 s) {f : X → α} (hf : ContinuousOn f s)
(ht : Tendsto f l atBot) : Iic (f a) ⊆ f '' s := fun y h =>
(hs.intermediate_value₂_eventually₁ ha hl continuousOn_const hf h (tendsto_atBot.1 ht y)).imp
fun _ h => h.imp_right Eq.symm
theorem IsPreconnected.intermediate_value_Ioi {s : Set X} (hs : IsPreconnected s) {l₁ l₂ : Filter X}
[NeBot l₁] [NeBot l₂] (hl₁ : l₁ ≤ 𝓟 s) (hl₂ : l₂ ≤ 𝓟 s) {f : X → α} (hf : ContinuousOn f s)
{v : α} (ht₁ : Tendsto f l₁ (𝓝 v)) (ht₂ : Tendsto f l₂ atTop) : Ioi v ⊆ f '' s := fun y h =>
hs.intermediate_value₂_eventually₂ hl₁ hl₂ hf continuousOn_const
(ht₁.eventually_le_const h) (ht₂.eventually_ge_atTop y)
theorem IsPreconnected.intermediate_value_Iio {s : Set X} (hs : IsPreconnected s) {l₁ l₂ : Filter X}
[NeBot l₁] [NeBot l₂] (hl₁ : l₁ ≤ 𝓟 s) (hl₂ : l₂ ≤ 𝓟 s) {f : X → α} (hf : ContinuousOn f s)
{v : α} (ht₁ : Tendsto f l₁ atBot) (ht₂ : Tendsto f l₂ (𝓝 v)) : Iio v ⊆ f '' s := fun y h =>
hs.intermediate_value₂_eventually₂ hl₁ hl₂ hf continuousOn_const (ht₁.eventually_le_atBot y)
(ht₂.eventually_const_le h)
theorem IsPreconnected.intermediate_value_Iii {s : Set X} (hs : IsPreconnected s) {l₁ l₂ : Filter X}
[NeBot l₁] [NeBot l₂] (hl₁ : l₁ ≤ 𝓟 s) (hl₂ : l₂ ≤ 𝓟 s) {f : X → α} (hf : ContinuousOn f s)
(ht₁ : Tendsto f l₁ atBot) (ht₂ : Tendsto f l₂ atTop) : univ ⊆ f '' s := fun y _ =>
hs.intermediate_value₂_eventually₂ hl₁ hl₂ hf continuousOn_const (ht₁.eventually_le_atBot y)
(ht₂.eventually_ge_atTop y)
/-- **Intermediate Value Theorem** for continuous functions on connected spaces. -/
theorem intermediate_value_univ [PreconnectedSpace X] (a b : X) {f : X → α} (hf : Continuous f) :
Icc (f a) (f b) ⊆ range f := fun _ hx => intermediate_value_univ₂ hf continuous_const hx.1 hx.2
/-- **Intermediate Value Theorem** for continuous functions on connected spaces. -/
theorem mem_range_of_exists_le_of_exists_ge [PreconnectedSpace X] {c : α} {f : X → α}
(hf : Continuous f) (h₁ : ∃ a, f a ≤ c) (h₂ : ∃ b, c ≤ f b) : c ∈ range f :=
let ⟨a, ha⟩ := h₁; let ⟨b, hb⟩ := h₂; intermediate_value_univ a b hf ⟨ha, hb⟩
/-!
### (Pre)connected sets in a linear order
In this section we prove the following results:
* `IsPreconnected.ordConnected`: any preconnected set `s` in a linear order is `OrdConnected`,
i.e. `a ∈ s` and `b ∈ s` imply `Icc a b ⊆ s`;
* `IsPreconnected.mem_intervals`: any preconnected set `s` in a conditionally complete linear order
is one of the intervals `Set.Icc`, `set.`Ico`, `set.Ioc`, `set.Ioo`, ``Set.Ici`, `Set.Iic`,
`Set.Ioi`, `Set.Iio`; note that this is false for non-complete orders: e.g., in `ℝ \ {0}`, the set
of positive numbers cannot be represented as `Set.Ioi _`.
-/
/-- If a preconnected set contains endpoints of an interval, then it includes the whole interval. -/
theorem IsPreconnected.Icc_subset {s : Set α} (hs : IsPreconnected s) {a b : α} (ha : a ∈ s)
(hb : b ∈ s) : Icc a b ⊆ s := by
simpa only [image_id] using hs.intermediate_value ha hb continuousOn_id
theorem IsPreconnected.ordConnected {s : Set α} (h : IsPreconnected s) : OrdConnected s :=
⟨fun _ hx _ hy => h.Icc_subset hx hy⟩
/-- If a preconnected set contains endpoints of an interval, then it includes the whole interval. -/
theorem IsConnected.Icc_subset {s : Set α} (hs : IsConnected s) {a b : α} (ha : a ∈ s)
(hb : b ∈ s) : Icc a b ⊆ s :=
hs.2.Icc_subset ha hb
/-- If preconnected set in a linear order space is unbounded below and above, then it is the whole
space. -/
theorem IsPreconnected.eq_univ_of_unbounded {s : Set α} (hs : IsPreconnected s) (hb : ¬BddBelow s)
(ha : ¬BddAbove s) : s = univ := by
refine eq_univ_of_forall fun x => ?_
obtain ⟨y, ys, hy⟩ : ∃ y ∈ s, y < x := not_bddBelow_iff.1 hb x
obtain ⟨z, zs, hz⟩ : ∃ z ∈ s, x < z := not_bddAbove_iff.1 ha x
exact hs.Icc_subset ys zs ⟨le_of_lt hy, le_of_lt hz⟩
end
variable {α : Type u} [ConditionallyCompleteLinearOrder α] [TopologicalSpace α] [OrderTopology α]
/-- A bounded connected subset of a conditionally complete linear order includes the open interval
`(Inf s, Sup s)`. -/
theorem IsConnected.Ioo_csInf_csSup_subset {s : Set α} (hs : IsConnected s) (hb : BddBelow s)
(ha : BddAbove s) : Ioo (sInf s) (sSup s) ⊆ s := fun _x hx =>
let ⟨_y, ys, hy⟩ := (isGLB_lt_iff (isGLB_csInf hs.nonempty hb)).1 hx.1
let ⟨_z, zs, hz⟩ := (lt_isLUB_iff (isLUB_csSup hs.nonempty ha)).1 hx.2
hs.Icc_subset ys zs ⟨hy.le, hz.le⟩
theorem eq_Icc_csInf_csSup_of_connected_bdd_closed {s : Set α} (hc : IsConnected s)
(hb : BddBelow s) (ha : BddAbove s) (hcl : IsClosed s) : s = Icc (sInf s) (sSup s) :=
(subset_Icc_csInf_csSup hb ha).antisymm <|
hc.Icc_subset (hcl.csInf_mem hc.nonempty hb) (hcl.csSup_mem hc.nonempty ha)
theorem IsPreconnected.Ioi_csInf_subset {s : Set α} (hs : IsPreconnected s) (hb : BddBelow s)
(ha : ¬BddAbove s) : Ioi (sInf s) ⊆ s := fun x hx =>
have sne : s.Nonempty := nonempty_of_not_bddAbove ha
let ⟨_y, ys, hy⟩ : ∃ y ∈ s, y < x := (isGLB_lt_iff (isGLB_csInf sne hb)).1 hx
let ⟨_z, zs, hz⟩ : ∃ z ∈ s, x < z := not_bddAbove_iff.1 ha x
hs.Icc_subset ys zs ⟨hy.le, hz.le⟩
theorem IsPreconnected.Iio_csSup_subset {s : Set α} (hs : IsPreconnected s) (hb : ¬BddBelow s)
(ha : BddAbove s) : Iio (sSup s) ⊆ s :=
IsPreconnected.Ioi_csInf_subset (α := αᵒᵈ) hs ha hb
/-- A preconnected set in a conditionally complete linear order is either one of the intervals
`[Inf s, Sup s]`, `[Inf s, Sup s)`, `(Inf s, Sup s]`, `(Inf s, Sup s)`, `[Inf s, +∞)`,
`(Inf s, +∞)`, `(-∞, Sup s]`, `(-∞, Sup s)`, `(-∞, +∞)`, or `∅`. The converse statement requires
`α` to be densely ordered. -/
theorem IsPreconnected.mem_intervals {s : Set α} (hs : IsPreconnected s) :
s ∈
({Icc (sInf s) (sSup s), Ico (sInf s) (sSup s), Ioc (sInf s) (sSup s), Ioo (sInf s) (sSup s),
Ici (sInf s), Ioi (sInf s), Iic (sSup s), Iio (sSup s), univ, ∅} : Set (Set α)) := by
rcases s.eq_empty_or_nonempty with (rfl | hne)
· apply_rules [Or.inr, mem_singleton]
have hs' : IsConnected s := ⟨hne, hs⟩
by_cases hb : BddBelow s <;> by_cases ha : BddAbove s
· refine mem_of_subset_of_mem ?_ <| mem_Icc_Ico_Ioc_Ioo_of_subset_of_subset
(hs'.Ioo_csInf_csSup_subset hb ha) (subset_Icc_csInf_csSup hb ha)
simp only [insert_subset_iff, mem_insert_iff, mem_singleton_iff, true_or, or_true,
singleton_subset_iff, and_self]
· refine Or.inr <| Or.inr <| Or.inr <| Or.inr ?_
rcases mem_Ici_Ioi_of_subset_of_subset (hs.Ioi_csInf_subset hb ha) fun x hx ↦
csInf_le hb hx with hs | hs
· exact Or.inl hs
· exact Or.inr (Or.inl hs)
· iterate 6 apply Or.inr
rcases mem_Iic_Iio_of_subset_of_subset (hs.Iio_csSup_subset hb ha) fun x hx ↦
le_csSup ha hx with hs | hs
· exact Or.inl hs
· exact Or.inr (Or.inl hs)
· iterate 8 apply Or.inr
exact Or.inl (hs.eq_univ_of_unbounded hb ha)
/-- A preconnected set is either one of the intervals `Icc`, `Ico`, `Ioc`, `Ioo`, `Ici`, `Ioi`,
`Iic`, `Iio`, or `univ`, or `∅`. The converse statement requires `α` to be densely ordered. Though
one can represent `∅` as `(Inf ∅, Inf ∅)`, we include it into the list of possible cases to improve
readability. -/
theorem setOf_isPreconnected_subset_of_ordered :
{ s : Set α | IsPreconnected s } ⊆
-- bounded intervals
(range (uncurry Icc) ∪ range (uncurry Ico) ∪ range (uncurry Ioc) ∪ range (uncurry Ioo)) ∪
-- unbounded intervals and `univ`
(range Ici ∪ range Ioi ∪ range Iic ∪ range Iio ∪ {univ, ∅}) := by
intro s hs
rcases hs.mem_intervals with (hs | hs | hs | hs | hs | hs | hs | hs | hs | hs) <;> rw [hs] <;>
simp only [union_insert, union_singleton, mem_insert_iff, mem_union, mem_range, Prod.exists,
uncurry_apply_pair, exists_apply_eq_apply, true_or, or_true, exists_apply_eq_apply2]
/-!
### Intervals are connected
In this section we prove that a closed interval (hence, any `OrdConnected` set) in a dense
conditionally complete linear order is preconnected.
-/
/-- A "continuous induction principle" for a closed interval: if a set `s` meets `[a, b]`
on a closed subset, contains `a`, and the set `s ∩ [a, b)` has no maximal point, then `b ∈ s`. -/
theorem IsClosed.mem_of_ge_of_forall_exists_gt {a b : α} {s : Set α} (hs : IsClosed (s ∩ Icc a b))
(ha : a ∈ s) (hab : a ≤ b) (hgt : ∀ x ∈ s ∩ Ico a b, (s ∩ Ioc x b).Nonempty) : b ∈ s := by
let S := s ∩ Icc a b
replace ha : a ∈ S := ⟨ha, left_mem_Icc.2 hab⟩
have Sbd : BddAbove S := ⟨b, fun z hz => hz.2.2⟩
let c := sSup (s ∩ Icc a b)
have c_mem : c ∈ S := hs.csSup_mem ⟨_, ha⟩ Sbd
have c_le : c ≤ b := csSup_le ⟨_, ha⟩ fun x hx => hx.2.2
rcases eq_or_lt_of_le c_le with hc | hc
· exact hc ▸ c_mem.1
exfalso
rcases hgt c ⟨c_mem.1, c_mem.2.1, hc⟩ with ⟨x, xs, cx, xb⟩
exact not_lt_of_le (le_csSup Sbd ⟨xs, le_trans (le_csSup Sbd ha) (le_of_lt cx), xb⟩) cx
/-- A "continuous induction principle" for a closed interval: if a set `s` meets `[a, b]`
on a closed subset, contains `a`, and for any `a ≤ x < y ≤ b`, `x ∈ s`, the set `s ∩ (x, y]`
is not empty, then `[a, b] ⊆ s`. -/
theorem IsClosed.Icc_subset_of_forall_exists_gt {a b : α} {s : Set α} (hs : IsClosed (s ∩ Icc a b))
(ha : a ∈ s) (hgt : ∀ x ∈ s ∩ Ico a b, ∀ y ∈ Ioi x, (s ∩ Ioc x y).Nonempty) : Icc a b ⊆ s := by
intro y hy
have : IsClosed (s ∩ Icc a y) := by
suffices s ∩ Icc a y = s ∩ Icc a b ∩ Icc a y by
rw [this]
exact IsClosed.inter hs isClosed_Icc
rw [inter_assoc]
congr
exact (inter_eq_self_of_subset_right <| Icc_subset_Icc_right hy.2).symm
exact
IsClosed.mem_of_ge_of_forall_exists_gt this ha hy.1 fun x hx =>
hgt x ⟨hx.1, Ico_subset_Ico_right hy.2 hx.2⟩ y hx.2.2
variable [DenselyOrdered α] {a b : α}
/-- A "continuous induction principle" for a closed interval: if a set `s` meets `[a, b]`
on a closed subset, contains `a`, and for any `x ∈ s ∩ [a, b)` the set `s` includes some open
neighborhood of `x` within `(x, +∞)`, then `[a, b] ⊆ s`. -/
theorem IsClosed.Icc_subset_of_forall_mem_nhdsWithin {a b : α} {s : Set α}
(hs : IsClosed (s ∩ Icc a b)) (ha : a ∈ s) (hgt : ∀ x ∈ s ∩ Ico a b, s ∈ 𝓝[>] x) :
Icc a b ⊆ s := by
apply hs.Icc_subset_of_forall_exists_gt ha
rintro x ⟨hxs, hxab⟩ y hyxb
have : s ∩ Ioc x y ∈ 𝓝[>] x := inter_mem (hgt x ⟨hxs, hxab⟩) (Ioc_mem_nhdsGT hyxb)
exact (nhdsGT_neBot_of_exists_gt ⟨b, hxab.2⟩).nonempty_of_mem this
theorem isPreconnected_Icc_aux (x y : α) (s t : Set α) (hxy : x ≤ y) (hs : IsClosed s)
(ht : IsClosed t) (hab : Icc a b ⊆ s ∪ t) (hx : x ∈ Icc a b ∩ s) (hy : y ∈ Icc a b ∩ t) :
(Icc a b ∩ (s ∩ t)).Nonempty := by
have xyab : Icc x y ⊆ Icc a b := Icc_subset_Icc hx.1.1 hy.1.2
by_contra hst
suffices Icc x y ⊆ s from
hst ⟨y, xyab <| right_mem_Icc.2 hxy, this <| right_mem_Icc.2 hxy, hy.2⟩
apply (IsClosed.inter hs isClosed_Icc).Icc_subset_of_forall_mem_nhdsWithin hx.2
rintro z ⟨zs, hz⟩
have zt : z ∈ tᶜ := fun zt => hst ⟨z, xyab <| Ico_subset_Icc_self hz, zs, zt⟩
have : tᶜ ∩ Ioc z y ∈ 𝓝[>] z := by
rw [← nhdsWithin_Ioc_eq_nhdsGT hz.2]
exact mem_nhdsWithin.2 ⟨tᶜ, ht.isOpen_compl, zt, Subset.rfl⟩
apply mem_of_superset this
have : Ioc z y ⊆ s ∪ t := fun w hw => hab (xyab ⟨le_trans hz.1 (le_of_lt hw.1), hw.2⟩)
exact fun w ⟨wt, wzy⟩ => (this wzy).elim id fun h => (wt h).elim
/-- A closed interval in a densely ordered conditionally complete linear order is preconnected. -/
theorem isPreconnected_Icc : IsPreconnected (Icc a b) :=
isPreconnected_closed_iff.2
(by
rintro s t hs ht hab ⟨x, hx⟩ ⟨y, hy⟩
-- This used to use `wlog`, but it was causing timeouts.
rcases le_total x y with h | h
· exact isPreconnected_Icc_aux x y s t h hs ht hab hx hy
· rw [inter_comm s t]
rw [union_comm s t] at hab
exact isPreconnected_Icc_aux y x t s h ht hs hab hy hx)
theorem isPreconnected_uIcc : IsPreconnected ([[a, b]]) :=
isPreconnected_Icc
theorem Set.OrdConnected.isPreconnected {s : Set α} (h : s.OrdConnected) : IsPreconnected s :=
isPreconnected_of_forall_pair fun x hx y hy =>
⟨[[x, y]], h.uIcc_subset hx hy, left_mem_uIcc, right_mem_uIcc, isPreconnected_uIcc⟩
theorem isPreconnected_iff_ordConnected {s : Set α} : IsPreconnected s ↔ OrdConnected s :=
⟨IsPreconnected.ordConnected, Set.OrdConnected.isPreconnected⟩
theorem isPreconnected_Ici : IsPreconnected (Ici a) :=
ordConnected_Ici.isPreconnected
theorem isPreconnected_Iic : IsPreconnected (Iic a) :=
ordConnected_Iic.isPreconnected
theorem isPreconnected_Iio : IsPreconnected (Iio a) :=
ordConnected_Iio.isPreconnected
theorem isPreconnected_Ioi : IsPreconnected (Ioi a) :=
ordConnected_Ioi.isPreconnected
theorem isPreconnected_Ioo : IsPreconnected (Ioo a b) :=
ordConnected_Ioo.isPreconnected
theorem isPreconnected_Ioc : IsPreconnected (Ioc a b) :=
ordConnected_Ioc.isPreconnected
theorem isPreconnected_Ico : IsPreconnected (Ico a b) :=
ordConnected_Ico.isPreconnected
theorem isConnected_Ici : IsConnected (Ici a) :=
⟨nonempty_Ici, isPreconnected_Ici⟩
theorem isConnected_Iic : IsConnected (Iic a) :=
⟨nonempty_Iic, isPreconnected_Iic⟩
theorem isConnected_Ioi [NoMaxOrder α] : IsConnected (Ioi a) :=
⟨nonempty_Ioi, isPreconnected_Ioi⟩
theorem isConnected_Iio [NoMinOrder α] : IsConnected (Iio a) :=
⟨nonempty_Iio, isPreconnected_Iio⟩
theorem isConnected_Icc (h : a ≤ b) : IsConnected (Icc a b) :=
⟨nonempty_Icc.2 h, isPreconnected_Icc⟩
theorem isConnected_Ioo (h : a < b) : IsConnected (Ioo a b) :=
⟨nonempty_Ioo.2 h, isPreconnected_Ioo⟩
theorem isConnected_Ioc (h : a < b) : IsConnected (Ioc a b) :=
⟨nonempty_Ioc.2 h, isPreconnected_Ioc⟩
theorem isConnected_Ico (h : a < b) : IsConnected (Ico a b) :=
⟨nonempty_Ico.2 h, isPreconnected_Ico⟩
instance (priority := 100) ordered_connected_space : PreconnectedSpace α :=
⟨ordConnected_univ.isPreconnected⟩
/-- In a dense conditionally complete linear order, the set of preconnected sets is exactly
the set of the intervals `Icc`, `Ico`, `Ioc`, `Ioo`, `Ici`, `Ioi`, `Iic`, `Iio`, `(-∞, +∞)`,
or `∅`. Though one can represent `∅` as `(sInf s, sInf s)`, we include it into the list of
possible cases to improve readability. -/
theorem setOf_isPreconnected_eq_of_ordered :
{ s : Set α | IsPreconnected s } =
-- bounded intervals
range (uncurry Icc) ∪ range (uncurry Ico) ∪ range (uncurry Ioc) ∪ range (uncurry Ioo) ∪
-- unbounded intervals and `univ`
(range Ici ∪ range Ioi ∪ range Iic ∪ range Iio ∪ {univ, ∅}) := by
refine Subset.antisymm setOf_isPreconnected_subset_of_ordered ?_
simp only [subset_def, forall_mem_range, uncurry, or_imp, forall_and, mem_union,
mem_setOf_eq, insert_eq, mem_singleton_iff, forall_eq, forall_true_iff, and_true,
isPreconnected_Icc, isPreconnected_Ico, isPreconnected_Ioc, isPreconnected_Ioo,
isPreconnected_Ioi, isPreconnected_Iio, isPreconnected_Ici, isPreconnected_Iic,
isPreconnected_univ, isPreconnected_empty]
/-- This lemmas characterizes when a subset `s` of a densely ordered conditionally complete linear
order is totally disconnected with respect to the order topology: between any two distinct points
of `s` must lie a point not in `s`. -/
lemma isTotallyDisconnected_iff_lt {s : Set α} :
IsTotallyDisconnected s ↔ ∀ x ∈ s, ∀ y ∈ s, x < y → ∃ z ∉ s, z ∈ Ioo x y := by
simp only [IsTotallyDisconnected, isPreconnected_iff_ordConnected, ← not_nontrivial_iff,
nontrivial_iff_exists_lt, not_exists, not_and]
refine ⟨fun h x hx y hy hxy ↦ ?_, fun h t hts ht x hx y hy hxy ↦ ?_⟩
· simp_rw [← not_ordConnected_inter_Icc_iff hx hy]
exact fun hs ↦ h _ inter_subset_left hs _ ⟨hx, le_rfl, hxy.le⟩ _ ⟨hy, hxy.le, le_rfl⟩ hxy
· obtain ⟨z, h1z, h2z⟩ := h x (hts hx) y (hts hy) hxy
exact h1z <| hts <| ht.1 hx hy ⟨h2z.1.le, h2z.2.le⟩
/-!
### Intermediate Value Theorem on an interval
In this section we prove several versions of the Intermediate Value Theorem for a function
continuous on an interval.
-/
variable {δ : Type*} [LinearOrder δ] [TopologicalSpace δ] [OrderClosedTopology δ]
/-- **Intermediate Value Theorem** for continuous functions on closed intervals, case
`f a ≤ t ≤ f b`. -/
theorem intermediate_value_Icc {a b : α} (hab : a ≤ b) {f : α → δ} (hf : ContinuousOn f (Icc a b)) :
Icc (f a) (f b) ⊆ f '' Icc a b :=
isPreconnected_Icc.intermediate_value (left_mem_Icc.2 hab) (right_mem_Icc.2 hab) hf
/-- **Intermediate Value Theorem** for continuous functions on closed intervals, case
`f a ≥ t ≥ f b`. -/
theorem intermediate_value_Icc' {a b : α} (hab : a ≤ b) {f : α → δ}
(hf : ContinuousOn f (Icc a b)) : Icc (f b) (f a) ⊆ f '' Icc a b :=
isPreconnected_Icc.intermediate_value (right_mem_Icc.2 hab) (left_mem_Icc.2 hab) hf
/-- **Intermediate Value Theorem** for continuous functions on closed intervals, unordered case. -/
theorem intermediate_value_uIcc {a b : α} {f : α → δ} (hf : ContinuousOn f [[a, b]]) :
[[f a, f b]] ⊆ f '' uIcc a b := by
cases le_total (f a) (f b) <;> simp [*, isPreconnected_uIcc.intermediate_value]
/-- If `f : α → α` is continuous on `[[a, b]]`, `a ≤ f a`, and `f b ≤ b`,
then `f` has a fixed point on `[[a, b]]`. -/
theorem exists_mem_uIcc_isFixedPt {a b : α} {f : α → α} (hf : ContinuousOn f (uIcc a b))
(ha : a ≤ f a) (hb : f b ≤ b) : ∃ c ∈ [[a, b]], IsFixedPt f c :=
isPreconnected_uIcc.intermediate_value₂ right_mem_uIcc left_mem_uIcc hf continuousOn_id hb ha
/-- If `f : α → α` is continuous on `[a, b]`, `a ≤ b`, `a ≤ f a`, and `f b ≤ b`,
then `f` has a fixed point on `[a, b]`.
In particular, if `[a, b]` is forward-invariant under `f`,
then `f` has a fixed point on `[a, b]`, see `exists_mem_Icc_isFixedPt_of_mapsTo`. -/
theorem exists_mem_Icc_isFixedPt {a b : α} {f : α → α} (hf : ContinuousOn f (Icc a b))
(hle : a ≤ b) (ha : a ≤ f a) (hb : f b ≤ b) : ∃ c ∈ Icc a b, IsFixedPt f c :=
isPreconnected_Icc.intermediate_value₂
(right_mem_Icc.2 hle) (left_mem_Icc.2 hle) hf continuousOn_id hb ha
/-- If a closed interval is forward-invariant under a continuous map `f : α → α`,
then this map has a fixed point on this interval. -/
theorem exists_mem_Icc_isFixedPt_of_mapsTo {a b : α} {f : α → α} (hf : ContinuousOn f (Icc a b))
(hle : a ≤ b) (hmaps : MapsTo f (Icc a b) (Icc a b)) : ∃ c ∈ Icc a b, IsFixedPt f c :=
exists_mem_Icc_isFixedPt hf hle (hmaps <| left_mem_Icc.2 hle).1 (hmaps <| right_mem_Icc.2 hle).2
theorem intermediate_value_Ico {a b : α} (hab : a ≤ b) {f : α → δ} (hf : ContinuousOn f (Icc a b)) :
Ico (f a) (f b) ⊆ f '' Ico a b :=
Or.elim (eq_or_lt_of_le hab) (fun he _ h => absurd h.2 (not_lt_of_le (he ▸ h.1))) fun hlt =>
@IsPreconnected.intermediate_value_Ico _ _ _ _ _ _ _ isPreconnected_Ico _ _ ⟨refl a, hlt⟩
(right_nhdsWithin_Ico_neBot hlt) inf_le_right _ (hf.mono Ico_subset_Icc_self) _
((hf.continuousWithinAt ⟨hab, refl b⟩).mono Ico_subset_Icc_self)
theorem intermediate_value_Ico' {a b : α} (hab : a ≤ b) {f : α → δ}
(hf : ContinuousOn f (Icc a b)) : Ioc (f b) (f a) ⊆ f '' Ico a b :=
Or.elim (eq_or_lt_of_le hab) (fun he _ h => absurd h.1 (not_lt_of_le (he ▸ h.2))) fun hlt =>
@IsPreconnected.intermediate_value_Ioc _ _ _ _ _ _ _ isPreconnected_Ico _ _ ⟨refl a, hlt⟩
(right_nhdsWithin_Ico_neBot hlt) inf_le_right _ (hf.mono Ico_subset_Icc_self) _
((hf.continuousWithinAt ⟨hab, refl b⟩).mono Ico_subset_Icc_self)
theorem intermediate_value_Ioc {a b : α} (hab : a ≤ b) {f : α → δ} (hf : ContinuousOn f (Icc a b)) :
Ioc (f a) (f b) ⊆ f '' Ioc a b :=
Or.elim (eq_or_lt_of_le hab) (fun he _ h => absurd h.2 (not_le_of_lt (he ▸ h.1))) fun hlt =>
@IsPreconnected.intermediate_value_Ioc _ _ _ _ _ _ _ isPreconnected_Ioc _ _ ⟨hlt, refl b⟩
(left_nhdsWithin_Ioc_neBot hlt) inf_le_right _ (hf.mono Ioc_subset_Icc_self) _
((hf.continuousWithinAt ⟨refl a, hab⟩).mono Ioc_subset_Icc_self)
theorem intermediate_value_Ioc' {a b : α} (hab : a ≤ b) {f : α → δ}
(hf : ContinuousOn f (Icc a b)) : Ico (f b) (f a) ⊆ f '' Ioc a b :=
Or.elim (eq_or_lt_of_le hab) (fun he _ h => absurd h.1 (not_le_of_lt (he ▸ h.2))) fun hlt =>
@IsPreconnected.intermediate_value_Ico _ _ _ _ _ _ _ isPreconnected_Ioc _ _ ⟨hlt, refl b⟩
(left_nhdsWithin_Ioc_neBot hlt) inf_le_right _ (hf.mono Ioc_subset_Icc_self) _
((hf.continuousWithinAt ⟨refl a, hab⟩).mono Ioc_subset_Icc_self)
theorem intermediate_value_Ioo {a b : α} (hab : a ≤ b) {f : α → δ} (hf : ContinuousOn f (Icc a b)) :
Ioo (f a) (f b) ⊆ f '' Ioo a b :=
Or.elim (eq_or_lt_of_le hab) (fun he _ h => absurd h.2 (not_lt_of_lt (he ▸ h.1))) fun hlt =>
@IsPreconnected.intermediate_value_Ioo _ _ _ _ _ _ _ isPreconnected_Ioo _ _
(left_nhdsWithin_Ioo_neBot hlt) (right_nhdsWithin_Ioo_neBot hlt) inf_le_right inf_le_right _
(hf.mono Ioo_subset_Icc_self) _ _
((hf.continuousWithinAt ⟨refl a, hab⟩).mono Ioo_subset_Icc_self)
((hf.continuousWithinAt ⟨hab, refl b⟩).mono Ioo_subset_Icc_self)
theorem intermediate_value_Ioo' {a b : α} (hab : a ≤ b) {f : α → δ}
(hf : ContinuousOn f (Icc a b)) : Ioo (f b) (f a) ⊆ f '' Ioo a b :=
Or.elim (eq_or_lt_of_le hab) (fun he _ h => absurd h.1 (not_lt_of_lt (he ▸ h.2))) fun hlt =>
@IsPreconnected.intermediate_value_Ioo _ _ _ _ _ _ _ isPreconnected_Ioo _ _
(right_nhdsWithin_Ioo_neBot hlt) (left_nhdsWithin_Ioo_neBot hlt) inf_le_right inf_le_right _
(hf.mono Ioo_subset_Icc_self) _ _
((hf.continuousWithinAt ⟨hab, refl b⟩).mono Ioo_subset_Icc_self)
((hf.continuousWithinAt ⟨refl a, hab⟩).mono Ioo_subset_Icc_self)
/-- **Intermediate value theorem**: if `f` is continuous on an order-connected set `s` and `a`,
`b` are two points of this set, then `f` sends `s` to a superset of `Icc (f x) (f y)`. -/
theorem ContinuousOn.surjOn_Icc {s : Set α} [hs : OrdConnected s] {f : α → δ}
(hf : ContinuousOn f s) {a b : α} (ha : a ∈ s) (hb : b ∈ s) : SurjOn f s (Icc (f a) (f b)) :=
hs.isPreconnected.intermediate_value ha hb hf
/-- **Intermediate value theorem**: if `f` is continuous on an order-connected set `s` and `a`,
`b` are two points of this set, then `f` sends `s` to a superset of `[f x, f y]`. -/
theorem ContinuousOn.surjOn_uIcc {s : Set α} [hs : OrdConnected s] {f : α → δ}
(hf : ContinuousOn f s) {a b : α} (ha : a ∈ s) (hb : b ∈ s) :
SurjOn f s (uIcc (f a) (f b)) := by
rcases le_total (f a) (f b) with hab | hab <;> simp [hf.surjOn_Icc, *]
/-- A continuous function which tendsto `Filter.atTop` along `Filter.atTop` and to `atBot` along
`at_bot` is surjective. -/
theorem Continuous.surjective {f : α → δ} (hf : Continuous f) (h_top : Tendsto f atTop atTop)
(h_bot : Tendsto f atBot atBot) : Function.Surjective f := fun p =>
mem_range_of_exists_le_of_exists_ge hf (h_bot.eventually (eventually_le_atBot p)).exists
(h_top.eventually (eventually_ge_atTop p)).exists
/-- A continuous function which tendsto `Filter.atBot` along `Filter.atTop` and to `Filter.atTop`
along `atBot` is surjective. -/
theorem Continuous.surjective' {f : α → δ} (hf : Continuous f) (h_top : Tendsto f atBot atTop)
(h_bot : Tendsto f atTop atBot) : Function.Surjective f :=
Continuous.surjective (α := αᵒᵈ) hf h_top h_bot
/-- If a function `f : α → β` is continuous on a nonempty interval `s`, its restriction to `s`
tends to `at_bot : Filter β` along `at_bot : Filter ↥s` and tends to `Filter.atTop : Filter β` along
`Filter.atTop : Filter ↥s`, then the restriction of `f` to `s` is surjective. We formulate the
conclusion as `Function.surjOn f s Set.univ`. -/
theorem ContinuousOn.surjOn_of_tendsto {f : α → δ} {s : Set α} [OrdConnected s] (hs : s.Nonempty)
(hf : ContinuousOn f s) (hbot : Tendsto (fun x : s => f x) atBot atBot)
(htop : Tendsto (fun x : s => f x) atTop atTop) : SurjOn f s univ :=
haveI := Classical.inhabited_of_nonempty hs.to_subtype
surjOn_iff_surjective.2 <| hf.restrict.surjective htop hbot
/-- If a function `f : α → β` is continuous on a nonempty interval `s`, its restriction to `s`
tends to `Filter.atTop : Filter β` along `Filter.atBot : Filter ↥s` and tends to
`Filter.atBot : Filter β` along `Filter.atTop : Filter ↥s`, then the restriction of `f` to `s` is
surjective. We formulate the conclusion as `Function.surjOn f s Set.univ`. -/
theorem ContinuousOn.surjOn_of_tendsto' {f : α → δ} {s : Set α} [OrdConnected s] (hs : s.Nonempty)
(hf : ContinuousOn f s) (hbot : Tendsto (fun x : s => f x) atBot atTop)
(htop : Tendsto (fun x : s => f x) atTop atBot) : SurjOn f s univ :=
ContinuousOn.surjOn_of_tendsto (δ := δᵒᵈ) hs hf hbot htop
theorem Continuous.strictMono_of_inj_boundedOrder [BoundedOrder α] {f : α → δ}
(hf_c : Continuous f) (hf : f ⊥ ≤ f ⊤) (hf_i : Injective f) : StrictMono f := by
intro a b hab
by_contra! h
have H : f b < f a := lt_of_le_of_ne h <| hf_i.ne hab.ne'
by_cases ha : f a ≤ f ⊥
· obtain ⟨u, hu⟩ := intermediate_value_Ioc le_top hf_c.continuousOn ⟨H.trans_le ha, hf⟩
have : u = ⊥ := hf_i hu.2
aesop
· by_cases hb : f ⊥ < f b
· obtain ⟨u, hu⟩ := intermediate_value_Ioo bot_le hf_c.continuousOn ⟨hb, H⟩
rw [hf_i hu.2] at hu
exact (hab.trans hu.1.2).false
· push_neg at ha hb
replace hb : f b < f ⊥ := lt_of_le_of_ne hb <| hf_i.ne (lt_of_lt_of_le' hab bot_le).ne'
obtain ⟨u, hu⟩ := intermediate_value_Ioo' hab.le hf_c.continuousOn ⟨hb, ha⟩
have : u = ⊥ := hf_i hu.2
aesop
theorem Continuous.strictAnti_of_inj_boundedOrder [BoundedOrder α] {f : α → δ}
(hf_c : Continuous f) (hf : f ⊤ ≤ f ⊥) (hf_i : Injective f) : StrictAnti f :=
hf_c.strictMono_of_inj_boundedOrder (δ := δᵒᵈ) hf hf_i
theorem Continuous.strictMono_of_inj_boundedOrder' [BoundedOrder α] {f : α → δ}
(hf_c : Continuous f) (hf_i : Injective f) : StrictMono f ∨ StrictAnti f :=
(le_total (f ⊥) (f ⊤)).imp
(hf_c.strictMono_of_inj_boundedOrder · hf_i)
(hf_c.strictAnti_of_inj_boundedOrder · hf_i)
/-- Suppose `α` is equipped with a conditionally complete linear dense order and `f : α → δ` is
continuous and injective. Then `f` is strictly monotone (increasing) if
it is strictly monotone (increasing) on some closed interval `[a, b]`. -/
theorem Continuous.strictMonoOn_of_inj_rigidity {f : α → δ}
(hf_c : Continuous f) (hf_i : Injective f) {a b : α} (hab : a < b)
(hf_mono : StrictMonoOn f (Icc a b)) : StrictMono f := by
intro x y hxy
let s := min a x
let t := max b y
have hsa : s ≤ a := min_le_left a x
have hbt : b ≤ t := le_max_left b y
have hf_mono_st : StrictMonoOn f (Icc s t) ∨ StrictAntiOn f (Icc s t) := by
have : Fact (s ≤ t) := ⟨hsa.trans <| hbt.trans' hab.le⟩
have := Continuous.strictMono_of_inj_boundedOrder' (f := Set.restrict (Icc s t) f)
hf_c.continuousOn.restrict hf_i.injOn.injective
exact this.imp strictMono_restrict.mp strictAntiOn_iff_strictAnti.mpr
have (h : StrictAntiOn f (Icc s t)) : False := by
have : Icc a b ⊆ Icc s t := Icc_subset_Icc hsa hbt
replace : StrictAntiOn f (Icc a b) := StrictAntiOn.mono h this
replace : IsAntichain (· ≤ ·) (Icc a b) :=
IsAntichain.of_strictMonoOn_antitoneOn hf_mono this.antitoneOn
exact this.not_lt (left_mem_Icc.mpr (le_of_lt hab)) (right_mem_Icc.mpr (le_of_lt hab)) hab
replace hf_mono_st : StrictMonoOn f (Icc s t) := hf_mono_st.resolve_right this
have hsx : s ≤ x := min_le_right a x
have hyt : y ≤ t := le_max_right b y
replace : Icc x y ⊆ Icc s t := Icc_subset_Icc hsx hyt
replace : StrictMonoOn f (Icc x y) := StrictMonoOn.mono hf_mono_st this
exact this (left_mem_Icc.mpr (le_of_lt hxy)) (right_mem_Icc.mpr (le_of_lt hxy)) hxy
/-- Suppose `f : [a, b] → δ` is
continuous and injective. Then `f` is strictly monotone (increasing) if `f(a) ≤ f(b)`. -/
theorem ContinuousOn.strictMonoOn_of_injOn_Icc {a b : α} {f : α → δ}
(hab : a ≤ b) (hfab : f a ≤ f b)
(hf_c : ContinuousOn f (Icc a b)) (hf_i : InjOn f (Icc a b)) :
StrictMonoOn f (Icc a b) := by
have : Fact (a ≤ b) := ⟨hab⟩
refine StrictMono.of_restrict ?_
set g : Icc a b → δ := Set.restrict (Icc a b) f
have hgab : g ⊥ ≤ g ⊤ := by aesop
exact Continuous.strictMono_of_inj_boundedOrder (f := g) hf_c.restrict hgab hf_i.injective
/-- Suppose `f : [a, b] → δ` is
continuous and injective. Then `f` is strictly antitone (decreasing) if `f(b) ≤ f(a)`. -/
theorem ContinuousOn.strictAntiOn_of_injOn_Icc {a b : α} {f : α → δ}
(hab : a ≤ b) (hfab : f b ≤ f a)
(hf_c : ContinuousOn f (Icc a b)) (hf_i : InjOn f (Icc a b)) :
StrictAntiOn f (Icc a b) := ContinuousOn.strictMonoOn_of_injOn_Icc (δ := δᵒᵈ) hab hfab hf_c hf_i
/-- Suppose `f : [a, b] → δ` is continuous and injective. Then `f` is strictly monotone
or antitone (increasing or decreasing). -/
theorem ContinuousOn.strictMonoOn_of_injOn_Icc' {a b : α} {f : α → δ} (hab : a ≤ b)
(hf_c : ContinuousOn f (Icc a b)) (hf_i : InjOn f (Icc a b)) :
StrictMonoOn f (Icc a b) ∨ StrictAntiOn f (Icc a b) :=
(le_total (f a) (f b)).imp
(ContinuousOn.strictMonoOn_of_injOn_Icc hab · hf_c hf_i)
(ContinuousOn.strictAntiOn_of_injOn_Icc hab · hf_c hf_i)
/-- Suppose `α` is equipped with a conditionally complete linear dense order and `f : α → δ` is
continuous and injective. Then `f` is strictly monotone or antitone (increasing or decreasing). -/
theorem Continuous.strictMono_of_inj {f : α → δ}
(hf_c : Continuous f) (hf_i : Injective f) : StrictMono f ∨ StrictAnti f := by
have H {c d : α} (hcd : c < d) : StrictMono f ∨ StrictAnti f :=
(hf_c.continuousOn.strictMonoOn_of_injOn_Icc' hcd.le hf_i.injOn).imp
(hf_c.strictMonoOn_of_inj_rigidity hf_i hcd)
(hf_c.strictMonoOn_of_inj_rigidity (δ := δᵒᵈ) hf_i hcd)
by_cases hn : Nonempty α
· let a : α := Classical.choice ‹_›
by_cases h : ∃ b : α, a ≠ b
· choose b hb using h
by_cases hab : a < b
· exact H hab
· push_neg at hab
have : b < a := by exact Ne.lt_of_le (id (Ne.symm hb)) hab
exact H this
· push_neg at h
haveI : Subsingleton α := ⟨fun c d => Trans.trans (h c).symm (h d)⟩
exact Or.inl <| Subsingleton.strictMono f
· aesop
/-- Every continuous injective `f : (a, b) → δ` is strictly monotone
or antitone (increasing or decreasing). -/
theorem ContinuousOn.strictMonoOn_of_injOn_Ioo {a b : α} {f : α → δ} (hab : a < b)
(hf_c : ContinuousOn f (Ioo a b)) (hf_i : InjOn f (Ioo a b)) :
StrictMonoOn f (Ioo a b) ∨ StrictAntiOn f (Ioo a b) := by
haveI : Inhabited (Ioo a b) := Classical.inhabited_of_nonempty (nonempty_Ioo_subtype hab)
let g : Ioo a b → δ := Set.restrict (Ioo a b) f
| have : StrictMono g ∨ StrictAnti g :=
Continuous.strictMono_of_inj hf_c.restrict hf_i.injective
exact this.imp strictMono_restrict.mp strictAntiOn_iff_strictAnti.mpr
| Mathlib/Topology/Order/IntermediateValue.lean | 715 | 723 |
/-
Copyright (c) 2020 Kyle Miller. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kyle Miller
-/
import Mathlib.Algebra.Group.Action.Pi
import Mathlib.Data.Finset.Prod
import Mathlib.Data.SetLike.Basic
import Mathlib.Data.Sym.Basic
import Mathlib.Data.Sym.Sym2.Init
/-!
# The symmetric square
This file defines the symmetric square, which is `α × α` modulo
swapping. This is also known as the type of unordered pairs.
More generally, the symmetric square is the second symmetric power
(see `Data.Sym.Basic`). The equivalence is `Sym2.equivSym`.
From the point of view that an unordered pair is equivalent to a
multiset of cardinality two (see `Sym2.equivMultiset`), there is a
`Mem` instance `Sym2.Mem`, which is a `Prop`-valued membership
test. Given `h : a ∈ z` for `z : Sym2 α`, then `Mem.other h` is the other
element of the pair, defined using `Classical.choice`. If `α` has
decidable equality, then `h.other'` computably gives the other element.
The universal property of `Sym2` is provided as `Sym2.lift`, which
states that functions from `Sym2 α` are equivalent to symmetric
two-argument functions from `α`.
Recall that an undirected graph (allowing self loops, but no multiple
edges) is equivalent to a symmetric relation on the vertex type `α`.
Given a symmetric relation on `α`, the corresponding edge set is
constructed by `Sym2.fromRel` which is a special case of `Sym2.lift`.
## Notation
The element `Sym2.mk (a, b)` can be written as `s(a, b)` for short.
## Tags
symmetric square, unordered pairs, symmetric powers
-/
assert_not_exists MonoidWithZero
open List (Vector)
open Finset Function Sym
universe u
variable {α β γ : Type*}
namespace Sym2
/-- This is the relation capturing the notion of pairs equivalent up to permutations. -/
@[aesop (rule_sets := [Sym2]) [safe [constructors, cases], norm]]
inductive Rel (α : Type u) : α × α → α × α → Prop
| refl (x y : α) : Rel _ (x, y) (x, y)
| swap (x y : α) : Rel _ (x, y) (y, x)
attribute [refl] Rel.refl
@[symm]
theorem Rel.symm {x y : α × α} : Rel α x y → Rel α y x := by aesop (rule_sets := [Sym2])
@[trans]
theorem Rel.trans {x y z : α × α} (a : Rel α x y) (b : Rel α y z) : Rel α x z := by
aesop (rule_sets := [Sym2])
theorem Rel.is_equivalence : Equivalence (Rel α) :=
{ refl := fun (x, y) ↦ Rel.refl x y, symm := Rel.symm, trans := Rel.trans }
/-- One can use `attribute [local instance] Sym2.Rel.setoid` to temporarily
make `Quotient` functionality work for `α × α`. -/
def Rel.setoid (α : Type u) : Setoid (α × α) :=
⟨Rel α, Rel.is_equivalence⟩
@[simp]
theorem rel_iff' {p q : α × α} : Rel α p q ↔ p = q ∨ p = q.swap := by
aesop (rule_sets := [Sym2])
theorem rel_iff {x y z w : α} : Rel α (x, y) (z, w) ↔ x = z ∧ y = w ∨ x = w ∧ y = z := by
simp
end Sym2
/-- `Sym2 α` is the symmetric square of `α`, which, in other words, is the
type of unordered pairs.
It is equivalent in a natural way to multisets of cardinality 2 (see
`Sym2.equivMultiset`).
-/
abbrev Sym2 (α : Type u) := Quot (Sym2.Rel α)
/-- Constructor for `Sym2`. This is the quotient map `α × α → Sym2 α`. -/
protected abbrev Sym2.mk {α : Type*} (p : α × α) : Sym2 α := Quot.mk (Sym2.Rel α) p
/-- `s(x, y)` is an unordered pair,
which is to say a pair modulo the action of the symmetric group.
It is equal to `Sym2.mk (x, y)`. -/
notation3 "s(" x ", " y ")" => Sym2.mk (x, y)
namespace Sym2
protected theorem sound {p p' : α × α} (h : Sym2.Rel α p p') : Sym2.mk p = Sym2.mk p' :=
Quot.sound h
protected theorem exact {p p' : α × α} (h : Sym2.mk p = Sym2.mk p') : Sym2.Rel α p p' :=
Quotient.exact (s := Sym2.Rel.setoid α) h
@[simp]
protected theorem eq {p p' : α × α} : Sym2.mk p = Sym2.mk p' ↔ Sym2.Rel α p p' :=
Quotient.eq' (s₁ := Sym2.Rel.setoid α)
@[elab_as_elim, cases_eliminator, induction_eliminator]
protected theorem ind {f : Sym2 α → Prop} (h : ∀ x y, f s(x, y)) : ∀ i, f i :=
Quot.ind <| Prod.rec <| h
@[elab_as_elim]
protected theorem inductionOn {f : Sym2 α → Prop} (i : Sym2 α) (hf : ∀ x y, f s(x, y)) : f i :=
i.ind hf
@[elab_as_elim]
protected theorem inductionOn₂ {f : Sym2 α → Sym2 β → Prop} (i : Sym2 α) (j : Sym2 β)
(hf : ∀ a₁ a₂ b₁ b₂, f s(a₁, a₂) s(b₁, b₂)) : f i j :=
Quot.induction_on₂ i j <| by
intro ⟨a₁, a₂⟩ ⟨b₁, b₂⟩
exact hf _ _ _ _
/-- Dependent recursion principal for `Sym2`. See `Quot.rec`. -/
@[elab_as_elim]
protected def rec {motive : Sym2 α → Sort*}
(f : (p : α × α) → motive (Sym2.mk p))
(h : (p q : α × α) → (h : Sym2.Rel α p q) → Eq.ndrec (f p) (Sym2.sound h) = f q)
(z : Sym2 α) : motive z :=
Quot.rec f h z
/-- Dependent recursion principal for `Sym2` when the target is a `Subsingleton` type.
See `Quot.recOnSubsingleton`. -/
@[elab_as_elim]
protected abbrev recOnSubsingleton {motive : Sym2 α → Sort*}
[(p : α × α) → Subsingleton (motive (Sym2.mk p))]
(z : Sym2 α) (f : (p : α × α) → motive (Sym2.mk p)) : motive z :=
Quot.recOnSubsingleton z f
protected theorem «exists» {α : Sort _} {f : Sym2 α → Prop} :
(∃ x : Sym2 α, f x) ↔ ∃ x y, f s(x, y) :=
Quot.mk_surjective.exists.trans Prod.exists
protected theorem «forall» {α : Sort _} {f : Sym2 α → Prop} :
(∀ x : Sym2 α, f x) ↔ ∀ x y, f s(x, y) :=
Quot.mk_surjective.forall.trans Prod.forall
theorem eq_swap {a b : α} : s(a, b) = s(b, a) := Quot.sound (Rel.swap _ _)
@[simp]
theorem mk_prod_swap_eq {p : α × α} : Sym2.mk p.swap = Sym2.mk p := by
cases p
exact eq_swap
theorem congr_right {a b c : α} : s(a, b) = s(a, c) ↔ b = c := by
simp +contextual
theorem congr_left {a b c : α} : s(b, a) = s(c, a) ↔ b = c := by
simp +contextual
theorem eq_iff {x y z w : α} : s(x, y) = s(z, w) ↔ x = z ∧ y = w ∨ x = w ∧ y = z := by
simp
theorem mk_eq_mk_iff {p q : α × α} : Sym2.mk p = Sym2.mk q ↔ p = q ∨ p = q.swap := by
cases p
cases q
simp only [eq_iff, Prod.mk_inj, Prod.swap_prod_mk]
/-- The universal property of `Sym2`; symmetric functions of two arguments are equivalent to
functions from `Sym2`. Note that when `β` is `Prop`, it can sometimes be more convenient to use
`Sym2.fromRel` instead. -/
def lift : { f : α → α → β // ∀ a₁ a₂, f a₁ a₂ = f a₂ a₁ } ≃ (Sym2 α → β) where
toFun f :=
Quot.lift (uncurry ↑f) <| by
rintro _ _ ⟨⟩
exacts [rfl, f.prop _ _]
invFun F := ⟨curry (F ∘ Sym2.mk), fun _ _ => congr_arg F eq_swap⟩
left_inv _ := Subtype.ext rfl
right_inv _ := funext <| Sym2.ind fun _ _ => rfl
@[simp]
theorem lift_mk (f : { f : α → α → β // ∀ a₁ a₂, f a₁ a₂ = f a₂ a₁ }) (a₁ a₂ : α) :
lift f s(a₁, a₂) = (f : α → α → β) a₁ a₂ :=
rfl
@[simp]
theorem coe_lift_symm_apply (F : Sym2 α → β) (a₁ a₂ : α) :
(lift.symm F : α → α → β) a₁ a₂ = F s(a₁, a₂) :=
rfl
/-- A two-argument version of `Sym2.lift`. -/
def lift₂ :
{ f : α → α → β → β → γ //
∀ a₁ a₂ b₁ b₂, f a₁ a₂ b₁ b₂ = f a₂ a₁ b₁ b₂ ∧ f a₁ a₂ b₁ b₂ = f a₁ a₂ b₂ b₁ } ≃
(Sym2 α → Sym2 β → γ) where
toFun f :=
Quotient.lift₂ (s₁ := Sym2.Rel.setoid α) (s₂ := Sym2.Rel.setoid β)
(fun (a : α × α) (b : β × β) => f.1 a.1 a.2 b.1 b.2)
(by
rintro _ _ _ _ ⟨⟩ ⟨⟩
exacts [rfl, (f.2 _ _ _ _).2, (f.2 _ _ _ _).1, (f.2 _ _ _ _).1.trans (f.2 _ _ _ _).2])
invFun F :=
⟨fun a₁ a₂ b₁ b₂ => F s(a₁, a₂) s(b₁, b₂), fun a₁ a₂ b₁ b₂ => by
constructor
exacts [congr_arg₂ F eq_swap rfl, congr_arg₂ F rfl eq_swap]⟩
left_inv _ := Subtype.ext rfl
right_inv _ := funext₂ fun a b => Sym2.inductionOn₂ a b fun _ _ _ _ => rfl
@[simp]
theorem lift₂_mk
(f :
{ f : α → α → β → β → γ //
∀ a₁ a₂ b₁ b₂, f a₁ a₂ b₁ b₂ = f a₂ a₁ b₁ b₂ ∧ f a₁ a₂ b₁ b₂ = f a₁ a₂ b₂ b₁ })
(a₁ a₂ : α) (b₁ b₂ : β) : lift₂ f s(a₁, a₂) s(b₁, b₂) = (f : α → α → β → β → γ) a₁ a₂ b₁ b₂ :=
rfl
@[simp]
theorem coe_lift₂_symm_apply (F : Sym2 α → Sym2 β → γ) (a₁ a₂ : α) (b₁ b₂ : β) :
(lift₂.symm F : α → α → β → β → γ) a₁ a₂ b₁ b₂ = F s(a₁, a₂) s(b₁, b₂) :=
rfl
/-- The functor `Sym2` is functorial, and this function constructs the induced maps.
-/
def map (f : α → β) : Sym2 α → Sym2 β :=
Quot.map (Prod.map f f)
(by intro _ _ h; cases h <;> constructor)
@[simp]
theorem map_id : map (@id α) = id := by
ext ⟨⟨x, y⟩⟩
rfl
theorem map_comp {g : β → γ} {f : α → β} : Sym2.map (g ∘ f) = Sym2.map g ∘ Sym2.map f := by
ext ⟨⟨x, y⟩⟩
rfl
theorem map_map {g : β → γ} {f : α → β} (x : Sym2 α) : map g (map f x) = map (g ∘ f) x := by
induction x; aesop
@[simp]
theorem map_pair_eq (f : α → β) (x y : α) : map f s(x, y) = s(f x, f y) :=
rfl
theorem map.injective {f : α → β} (hinj : Injective f) : Injective (map f) := by
intro z z'
refine Sym2.inductionOn₂ z z' (fun x y x' y' => ?_)
simp [hinj.eq_iff]
/-- `mk a` as an embedding. This is the symmetric version of `Function.Embedding.sectL`. -/
@[simps]
def mkEmbedding (a : α) : α ↪ Sym2 α where
toFun b := s(a, b)
inj' b₁ b₁ h := by
simp only [Sym2.eq, Sym2.rel_iff', Prod.mk.injEq, true_and, Prod.swap_prod_mk] at h
obtain rfl | ⟨rfl, rfl⟩ := h <;> rfl
/-- `Sym2.map` as an embedding. -/
@[simps]
def _root_.Function.Embedding.sym2Map (f : α ↪ β) : Sym2 α ↪ Sym2 β where
toFun := map f
inj' := map.injective f.injective
lemma lift_comp_map {g : γ → α} (f : {f : α → α → β // ∀ a₁ a₂, f a₁ a₂ = f a₂ a₁}) :
lift f ∘ map g = lift ⟨fun (c₁ c₂ : γ) => f.val (g c₁) (g c₂), fun _ _ => f.prop _ _⟩ :=
lift.symm_apply_eq.mp rfl
lemma lift_map_apply {g : γ → α} (f : {f : α → α → β // ∀ a₁ a₂, f a₁ a₂ = f a₂ a₁}) (p : Sym2 γ) :
lift f (map g p) = lift ⟨fun (c₁ c₂ : γ) => f.val (g c₁) (g c₂), fun _ _ => f.prop _ _⟩ p := by
conv_rhs => rw [← lift_comp_map, comp_apply]
section Membership
/-! ### Membership and set coercion -/
/-- This is a predicate that determines whether a given term is a member of a term of the
symmetric square. From this point of view, the symmetric square is the subtype of
cardinality-two multisets on `α`.
-/
protected def Mem (x : α) (z : Sym2 α) : Prop :=
∃ y : α, z = s(x, y)
@[aesop norm (rule_sets := [Sym2])]
theorem mem_iff' {a b c : α} : Sym2.Mem a s(b, c) ↔ a = b ∨ a = c :=
{ mp := by
rintro ⟨_, h⟩
rw [eq_iff] at h
aesop
mpr := by
rintro (rfl | rfl)
· exact ⟨_, rfl⟩
rw [eq_swap]
exact ⟨_, rfl⟩ }
instance : SetLike (Sym2 α) α where
coe z := { x | z.Mem x }
coe_injective' z z' h := by
simp only [Set.ext_iff, Set.mem_setOf_eq] at h
obtain ⟨x, y⟩ := z
obtain ⟨x', y'⟩ := z'
have hx := h x; have hy := h y; have hx' := h x'; have hy' := h y'
simp only [mem_iff', eq_self_iff_true] at hx hy hx' hy'
aesop
@[simp]
theorem mem_iff_mem {x : α} {z : Sym2 α} : Sym2.Mem x z ↔ x ∈ z :=
Iff.rfl
theorem mem_iff_exists {x : α} {z : Sym2 α} : x ∈ z ↔ ∃ y : α, z = s(x, y) :=
Iff.rfl
@[ext]
theorem ext {p q : Sym2 α} (h : ∀ x, x ∈ p ↔ x ∈ q) : p = q :=
SetLike.ext h
theorem mem_mk_left (x y : α) : x ∈ s(x, y) :=
⟨y, rfl⟩
theorem mem_mk_right (x y : α) : y ∈ s(x, y) :=
eq_swap ▸ mem_mk_left y x
@[simp, aesop norm (rule_sets := [Sym2])]
theorem mem_iff {a b c : α} : a ∈ s(b, c) ↔ a = b ∨ a = c :=
mem_iff'
theorem out_fst_mem (e : Sym2 α) : e.out.1 ∈ e :=
⟨e.out.2, by rw [Sym2.mk, e.out_eq]⟩
theorem out_snd_mem (e : Sym2 α) : e.out.2 ∈ e :=
⟨e.out.1, by rw [eq_swap, Sym2.mk, e.out_eq]⟩
theorem ball {p : α → Prop} {a b : α} : (∀ c ∈ s(a, b), p c) ↔ p a ∧ p b := by
refine ⟨fun h => ⟨h _ <| mem_mk_left _ _, h _ <| mem_mk_right _ _⟩, fun h c hc => ?_⟩
obtain rfl | rfl := Sym2.mem_iff.1 hc
· exact h.1
· exact h.2
/-- Given an element of the unordered pair, give the other element using `Classical.choose`.
See also `Mem.other'` for the computable version.
-/
noncomputable def Mem.other {a : α} {z : Sym2 α} (h : a ∈ z) : α :=
Classical.choose h
@[simp]
theorem other_spec {a : α} {z : Sym2 α} (h : a ∈ z) : s(a, Mem.other h) = z := by
erw [← Classical.choose_spec h]
theorem other_mem {a : α} {z : Sym2 α} (h : a ∈ z) : Mem.other h ∈ z := by
convert mem_mk_right a <| Mem.other h
rw [other_spec h]
theorem mem_and_mem_iff {x y : α} {z : Sym2 α} (hne : x ≠ y) : x ∈ z ∧ y ∈ z ↔ z = s(x, y) := by
constructor
· cases z
rw [mem_iff, mem_iff]
aesop
· rintro rfl
simp
theorem eq_of_ne_mem {x y : α} {z z' : Sym2 α} (h : x ≠ y) (h1 : x ∈ z) (h2 : y ∈ z) (h3 : x ∈ z')
(h4 : y ∈ z') : z = z' :=
((mem_and_mem_iff h).mp ⟨h1, h2⟩).trans ((mem_and_mem_iff h).mp ⟨h3, h4⟩).symm
instance Mem.decidable [DecidableEq α] (x : α) (z : Sym2 α) : Decidable (x ∈ z) :=
z.recOnSubsingleton fun ⟨_, _⟩ => decidable_of_iff' _ mem_iff
end Membership
@[simp]
theorem mem_map {f : α → β} {b : β} {z : Sym2 α} : b ∈ Sym2.map f z ↔ ∃ a, a ∈ z ∧ f a = b := by
cases z
simp only [map_pair_eq, mem_iff, exists_eq_or_imp, exists_eq_left]
aesop
@[congr]
theorem map_congr {f g : α → β} {s : Sym2 α} (h : ∀ x ∈ s, f x = g x) : map f s = map g s := by
ext y
simp only [mem_map]
constructor <;>
· rintro ⟨w, hw, rfl⟩
exact ⟨w, hw, by simp [hw, h]⟩
/-- Note: `Sym2.map_id` will not simplify `Sym2.map id z` due to `Sym2.map_congr`. -/
@[simp]
theorem map_id' : (map fun x : α => x) = id :=
map_id
/--
Partial map. If `f : ∀ a, p a → β` is a partial function defined on `a : α` satisfying `p`,
then `pmap f s h` is essentially the same as `map f s` but is defined only when all members of `s`
satisfy `p`, using the proof to apply `f`.
-/
def pmap {P : α → Prop} (f : ∀ a, P a → β) (s : Sym2 α) : (∀ a ∈ s, P a) → Sym2 β :=
let g (p : α × α) (H : ∀ a ∈ Sym2.mk p, P a) : Sym2 β :=
s(f p.1 (H p.1 <| mem_mk_left _ _), f p.2 (H p.2 <| mem_mk_right _ _))
Quot.recOn s g fun p q hpq => funext fun Hq => by
rw [rel_iff'] at hpq
have Hp : ∀ a ∈ Sym2.mk p, P a := fun a hmem =>
Hq a (Sym2.mk_eq_mk_iff.2 hpq ▸ hmem : a ∈ Sym2.mk q)
have h : ∀ {s₂ e H}, Eq.ndrec (motive := fun s => (∀ a ∈ s, P a) → Sym2 β) (g p) (b := s₂) e H =
g p Hp := by
rintro s₂ rfl _
rfl
refine h.trans (Quot.sound ?_)
rw [rel_iff', Prod.mk.injEq, Prod.swap_prod_mk]
apply hpq.imp <;> rintro rfl <;> simp
theorem forall_mem_pair {P : α → Prop} {a b : α} : (∀ x ∈ s(a, b), P x) ↔ P a ∧ P b := by
simp only [mem_iff, forall_eq_or_imp, forall_eq]
lemma pair_eq_pmap {P : α → Prop} (f : ∀ a, P a → β) (a b : α) (h : P a) (h' : P b) :
s(f a h, f b h') = pmap f s(a, b) (forall_mem_pair.mpr ⟨h, h'⟩) := rfl
lemma pmap_pair {P : α → Prop} (f : ∀ a, P a → β) (a b : α) (h : ∀ x ∈ s(a, b), P x) :
pmap f s(a, b) h = s(f a (h a (mem_mk_left a b)), f b (h b (mem_mk_right a b))) := rfl
@[simp]
lemma mem_pmap_iff {P : α → Prop} (f : ∀ a, P a → β) (z : Sym2 α) (h : ∀ a ∈ z, P a) (b : β) :
b ∈ z.pmap f h ↔ ∃ (a : α) (ha : a ∈ z), b = f a (h a ha) := by
obtain ⟨x, y⟩ := z
rw [pmap_pair f x y h]
aesop
lemma pmap_eq_map {P : α → Prop} (f : α → β) (z : Sym2 α) (h : ∀ a ∈ z, P a) :
z.pmap (fun a _ => f a) h = z.map f := by
cases z; rfl
lemma map_pmap {Q : β → Prop} (f : α → β) (g : ∀ b, Q b → γ) (z : Sym2 α) (h : ∀ b ∈ z.map f, Q b):
(z.map f).pmap g h =
z.pmap (fun a ha => g (f a) (h (f a) (mem_map.mpr ⟨a, ha, rfl⟩))) (fun _ ha => ha) := by
cases z; rfl
lemma pmap_map {P : α → Prop} {Q : β → Prop} (f : ∀ a, P a → β) (g : β → γ)
(z : Sym2 α) (h : ∀ a ∈ z, P a) (h' : ∀ b ∈ z.pmap f h, Q b) :
(z.pmap f h).map g = z.pmap (fun a ha => g (f a (h a ha))) (fun _ ha ↦ ha) := by
cases z; rfl
lemma pmap_pmap {P : α → Prop} {Q : β → Prop} (f : ∀ a, P a → β) (g : ∀ b, Q b → γ)
(z : Sym2 α) (h : ∀ a ∈ z, P a) (h' : ∀ b ∈ z.pmap f h, Q b) :
(z.pmap f h).pmap g h' = z.pmap (fun a ha => g (f a (h a ha))
(h' _ ((mem_pmap_iff f z h _).mpr ⟨a, ha, rfl⟩))) (fun _ ha ↦ ha) := by
cases z; rfl
@[simp]
lemma pmap_subtype_map_subtypeVal {P : α → Prop} (s : Sym2 α) (h : ∀ a ∈ s, P a) :
(s.pmap Subtype.mk h).map Subtype.val = s := by
cases s; rfl
/--
"Attach" a proof `P a` that holds for all the elements of `s` to produce a new Sym2 object
with the same elements but in the type `{x // P x}`.
-/
def attachWith {P : α → Prop} (s : Sym2 α) (h : ∀ a ∈ s, P a) : Sym2 {a // P a} :=
pmap Subtype.mk s h
@[simp]
lemma attachWith_map_subtypeVal {s : Sym2 α} {P : α → Prop} (h : ∀ a ∈ s, P a) :
(s.attachWith h).map Subtype.val = s := by
cases s; rfl
/-! ### Diagonal -/
variable {e : Sym2 α} {f : α → β}
/-- A type `α` is naturally included in the diagonal of `α × α`, and this function gives the image
of this diagonal in `Sym2 α`.
-/
def diag (x : α) : Sym2 α := s(x, x)
theorem diag_injective : Function.Injective (Sym2.diag : α → Sym2 α) := fun x y h => by
cases Sym2.exact h <;> rfl
/-- A predicate for testing whether an element of `Sym2 α` is on the diagonal.
-/
def IsDiag : Sym2 α → Prop :=
lift ⟨Eq, fun _ _ => propext eq_comm⟩
theorem mk_isDiag_iff {x y : α} : IsDiag s(x, y) ↔ x = y :=
Iff.rfl
@[simp]
theorem isDiag_iff_proj_eq (z : α × α) : IsDiag (Sym2.mk z) ↔ z.1 = z.2 :=
Prod.recOn z fun _ _ => mk_isDiag_iff
protected lemma IsDiag.map : e.IsDiag → (e.map f).IsDiag := Sym2.ind (fun _ _ ↦ congr_arg f) e
lemma isDiag_map (hf : Injective f) : (e.map f).IsDiag ↔ e.IsDiag :=
Sym2.ind (fun _ _ ↦ hf.eq_iff) e
@[simp]
theorem diag_isDiag (a : α) : IsDiag (diag a) :=
Eq.refl a
theorem IsDiag.mem_range_diag {z : Sym2 α} : IsDiag z → z ∈ Set.range (@diag α) := by
obtain ⟨x, y⟩ := z
rintro (rfl : x = y)
exact ⟨_, rfl⟩
theorem isDiag_iff_mem_range_diag (z : Sym2 α) : IsDiag z ↔ z ∈ Set.range (@diag α) :=
⟨IsDiag.mem_range_diag, fun ⟨i, hi⟩ => hi ▸ diag_isDiag i⟩
instance IsDiag.decidablePred (α : Type u) [DecidableEq α] : DecidablePred (@IsDiag α) :=
fun z => z.recOnSubsingleton fun a => decidable_of_iff' _ (isDiag_iff_proj_eq a)
theorem other_ne {a : α} {z : Sym2 α} (hd : ¬IsDiag z) (h : a ∈ z) : Mem.other h ≠ a := by
contrapose! hd
have h' := Sym2.other_spec h
rw [hd] at h'
rw [← h']
simp
section Relations
/-! ### Declarations about symmetric relations -/
variable {r : α → α → Prop}
/-- Symmetric relations define a set on `Sym2 α` by taking all those pairs
of elements that are related.
-/
def fromRel (sym : Symmetric r) : Set (Sym2 α) :=
setOf (lift ⟨r, fun _ _ => propext ⟨(sym ·), (sym ·)⟩⟩)
@[simp]
theorem fromRel_proj_prop {sym : Symmetric r} {z : α × α} : Sym2.mk z ∈ fromRel sym ↔ r z.1 z.2 :=
Iff.rfl
theorem fromRel_prop {sym : Symmetric r} {a b : α} : s(a, b) ∈ fromRel sym ↔ r a b :=
Iff.rfl
theorem fromRel_bot : fromRel (fun (_ _ : α) z => z : Symmetric ⊥) = ∅ := by
apply Set.eq_empty_of_forall_not_mem fun e => _
apply Sym2.ind
simp [-Set.bot_eq_empty, Prop.bot_eq_false]
theorem fromRel_top : fromRel (fun (_ _ : α) z => z : Symmetric ⊤) = Set.univ := by
apply Set.eq_univ_of_forall fun e => _
apply Sym2.ind
simp [-Set.top_eq_univ, Prop.top_eq_true]
theorem fromRel_ne : fromRel (fun (_ _ : α) z => z.symm : Symmetric Ne) = {z | ¬IsDiag z} := by
ext z; exact z.ind (by simp)
theorem fromRel_irreflexive {sym : Symmetric r} :
Irreflexive r ↔ ∀ {z}, z ∈ fromRel sym → ¬IsDiag z :=
{ mp := by intro h; apply Sym2.ind; aesop
mpr := fun h _ hr => h (fromRel_prop.mpr hr) rfl }
theorem mem_fromRel_irrefl_other_ne {sym : Symmetric r} (irrefl : Irreflexive r) {a : α}
{z : Sym2 α} (hz : z ∈ fromRel sym) (h : a ∈ z) : Mem.other h ≠ a :=
other_ne (fromRel_irreflexive.mp irrefl hz) h
instance fromRel.decidablePred (sym : Symmetric r) [h : DecidableRel r] :
DecidablePred (· ∈ Sym2.fromRel sym) := fun z => z.recOnSubsingleton fun _ => h _ _
lemma fromRel_relationMap {r : α → α → Prop} (hr : Symmetric r) (f : α → β) :
fromRel (Relation.map_symmetric hr f) = Sym2.map f '' Sym2.fromRel hr := by
ext ⟨a, b⟩
simp only [fromRel_proj_prop, Relation.Map, Set.mem_image, Sym2.exists, map_pair_eq, Sym2.eq,
rel_iff', Prod.mk.injEq, Prod.swap_prod_mk, and_or_left, exists_or, iff_self_or,
forall_exists_index, and_imp]
exact fun c d hcd hc hd ↦ ⟨d, c, hr hcd, hd, hc⟩
/-- The inverse to `Sym2.fromRel`. Given a set on `Sym2 α`, give a symmetric relation on `α`
(see `Sym2.toRel_symmetric`). -/
def ToRel (s : Set (Sym2 α)) (x y : α) : Prop :=
s(x, y) ∈ s
@[simp]
theorem toRel_prop (s : Set (Sym2 α)) (x y : α) : ToRel s x y ↔ s(x, y) ∈ s :=
Iff.rfl
theorem toRel_symmetric (s : Set (Sym2 α)) : Symmetric (ToRel s) := fun x y => by simp [eq_swap]
theorem toRel_fromRel (sym : Symmetric r) : ToRel (fromRel sym) = r :=
rfl
theorem fromRel_toRel (s : Set (Sym2 α)) : fromRel (toRel_symmetric s) = s :=
Set.ext fun z => Sym2.ind (fun _ _ => Iff.rfl) z
end Relations
section SymEquiv
/-! ### Equivalence to the second symmetric power -/
attribute [local instance] List.Vector.Perm.isSetoid
private def fromVector : List.Vector α 2 → α × α
| ⟨[a, b], _⟩ => (a, b)
private theorem perm_card_two_iff {a₁ b₁ a₂ b₂ : α} :
[a₁, b₁].Perm [a₂, b₂] ↔ a₁ = a₂ ∧ b₁ = b₂ ∨ a₁ = b₂ ∧ b₁ = a₂ :=
{ mp := by
simp only [← Multiset.coe_eq_coe, ← Multiset.cons_coe, Multiset.coe_nil, Multiset.cons_zero,
Multiset.cons_eq_cons, Multiset.singleton_inj, ne_eq, Multiset.singleton_eq_cons_iff,
exists_eq_right_right, and_true]
tauto
mpr := fun
| .inl ⟨h₁, h₂⟩ | .inr ⟨h₁, h₂⟩ => by
rw [h₁, h₂]
first | done | apply List.Perm.swap'; rfl }
/-- The symmetric square is equivalent to length-2 vectors up to permutations. -/
def sym2EquivSym' : Equiv (Sym2 α) (Sym' α 2) where
toFun :=
Quot.map (fun x : α × α => ⟨[x.1, x.2], rfl⟩)
(by
rintro _ _ ⟨_⟩
· constructor; apply List.Perm.refl
apply List.Perm.swap'
rfl)
invFun :=
Quot.map fromVector
(by
rintro ⟨x, hx⟩ ⟨y, hy⟩ h
rcases x with - | ⟨_, x⟩; · simp at hx
rcases x with - | ⟨_, x⟩; · simp at hx
rcases x with - | ⟨_, x⟩; swap
· exfalso
simp at hx
rcases y with - | ⟨_, y⟩; · simp at hy
rcases y with - | ⟨_, y⟩; · simp at hy
rcases y with - | ⟨_, y⟩; swap
· exfalso
simp at hy
rcases perm_card_two_iff.mp h with (⟨rfl, rfl⟩ | ⟨rfl, rfl⟩)
· constructor
apply Sym2.Rel.swap)
left_inv := by apply Sym2.ind; aesop (add norm unfold [Sym2.fromVector])
right_inv x := by
refine x.recOnSubsingleton fun x => ?_
obtain ⟨x, hx⟩ := x
obtain - | ⟨-, x⟩ := x
· simp at hx
rcases x with - | ⟨_, x⟩
· simp at hx
rcases x with - | ⟨_, x⟩
swap
· exfalso
simp at hx
rfl
/-- The symmetric square is equivalent to the second symmetric power. -/
def equivSym (α : Type*) : Sym2 α ≃ Sym α 2 :=
Equiv.trans sym2EquivSym' symEquivSym'.symm
/-- The symmetric square is equivalent to multisets of cardinality
two. (This is currently a synonym for `equivSym`, but it's provided
in case the definition for `Sym` changes.) -/
def equivMultiset (α : Type*) : Sym2 α ≃ { s : Multiset α // Multiset.card s = 2 } :=
equivSym α
end SymEquiv
section Decidable
/-- Given `[DecidableEq α]` and `[Fintype α]`, the following instance gives `Fintype (Sym2 α)`.
-/
instance instDecidableRel [DecidableEq α] : DecidableRel (Rel α) :=
fun _ _ => decidable_of_iff' _ rel_iff
section
attribute [local instance] Sym2.Rel.setoid
instance instDecidableRel' [DecidableEq α] : DecidableRel (HasEquiv.Equiv (α := α × α)) :=
instDecidableRel
end
instance [DecidableEq α] : DecidableEq (Sym2 α) :=
inferInstanceAs <| DecidableEq (Quotient (Sym2.Rel.setoid α))
/-! ### The other element of an element of the symmetric square -/
/--
A function that gives the other element of a pair given one of the elements. Used in `Mem.other'`.
-/
@[aesop norm unfold (rule_sets := [Sym2])]
private def pairOther [DecidableEq α] (a : α) (z : α × α) : α :=
if a = z.1 then z.2 else z.1
|
/-- Get the other element of the unordered pair using the decidable equality.
This is the computable version of `Mem.other`. -/
| Mathlib/Data/Sym/Sym2.lean | 694 | 697 |
/-
Copyright (c) 2023 Dagur Asgeirsson. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Dagur Asgeirsson
-/
import Mathlib.CategoryTheory.EffectiveEpi.Comp
import Mathlib.Data.Fintype.EquivFin
/-!
# Functors preserving effective epimorphisms
This file concerns functors which preserve and/or reflect effective epimorphisms and effective
epimorphic families.
## TODO
- Find nice sufficient conditions in terms of preserving/reflecting (co)limits, to preserve/reflect
effective epis, similar to `CategoryTheory.preserves_epi_of_preservesColimit`.
-/
universe u
namespace CategoryTheory
open Limits
variable {C : Type*} [Category C]
noncomputable section Equivalence
variable {D : Type*} [Category D] (e : C ≌ D) {B : C}
variable {α : Type*} (X : α → C) (π : (a : α) → (X a ⟶ B))
| theorem effectiveEpiFamilyStructOfEquivalence_aux {W : D} (ε : (a : α) → e.functor.obj (X a) ⟶ W)
(h : ∀ {Z : D} (a₁ a₂ : α) (g₁ : Z ⟶ e.functor.obj (X a₁)) (g₂ : Z ⟶ e.functor.obj (X a₂)),
g₁ ≫ e.functor.map (π a₁) = g₂ ≫ e.functor.map (π a₂) → g₁ ≫ ε a₁ = g₂ ≫ ε a₂)
{Z : C} (a₁ a₂ : α) (g₁ : Z ⟶ X a₁) (g₂ : Z ⟶ X a₂) (hg : g₁ ≫ π a₁ = g₂ ≫ π a₂) :
g₁ ≫ (fun a ↦ e.unit.app (X a) ≫ e.inverse.map (ε a)) a₁ =
g₂ ≫ (fun a ↦ e.unit.app (X a) ≫ e.inverse.map (ε a)) a₂ := by
have := h a₁ a₂ (e.functor.map g₁) (e.functor.map g₂)
simp only [← Functor.map_comp, hg] at this
simpa using congrArg e.inverse.map (this (by trivial))
| Mathlib/CategoryTheory/EffectiveEpi/Preserves.lean | 34 | 42 |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Floris van Doorn, Violeta Hernández Palacios
-/
import Mathlib.Algebra.GroupWithZero.Divisibility
import Mathlib.Data.Nat.SuccPred
import Mathlib.Order.SuccPred.InitialSeg
import Mathlib.SetTheory.Ordinal.Basic
/-!
# Ordinal arithmetic
Ordinals have an addition (corresponding to disjoint union) that turns them into an additive
monoid, and a multiplication (corresponding to the lexicographic order on the product) that turns
them into a monoid. One can also define correspondingly a subtraction, a division, a successor
function, a power function and a logarithm function.
We also define limit ordinals and prove the basic induction principle on ordinals separating
successor ordinals and limit ordinals, in `limitRecOn`.
## Main definitions and results
* `o₁ + o₂` is the order on the disjoint union of `o₁` and `o₂` obtained by declaring that
every element of `o₁` is smaller than every element of `o₂`.
* `o₁ - o₂` is the unique ordinal `o` such that `o₂ + o = o₁`, when `o₂ ≤ o₁`.
* `o₁ * o₂` is the lexicographic order on `o₂ × o₁`.
* `o₁ / o₂` is the ordinal `o` such that `o₁ = o₂ * o + o'` with `o' < o₂`. We also define the
divisibility predicate, and a modulo operation.
* `Order.succ o = o + 1` is the successor of `o`.
* `pred o` if the predecessor of `o`. If `o` is not a successor, we set `pred o = o`.
We discuss the properties of casts of natural numbers of and of `ω` with respect to these
operations.
Some properties of the operations are also used to discuss general tools on ordinals:
* `IsLimit o`: an ordinal is a limit ordinal if it is neither `0` nor a successor.
* `limitRecOn` is the main induction principle of ordinals: if one can prove a property by
induction at successor ordinals and at limit ordinals, then it holds for all ordinals.
* `IsNormal`: a function `f : Ordinal → Ordinal` satisfies `IsNormal` if it is strictly increasing
and order-continuous, i.e., the image `f o` of a limit ordinal `o` is the sup of `f a` for
`a < o`.
Various other basic arithmetic results are given in `Principal.lean` instead.
-/
assert_not_exists Field Module
noncomputable section
open Function Cardinal Set Equiv Order
open scoped Ordinal
universe u v w
namespace Ordinal
variable {α β γ : Type*} {r : α → α → Prop} {s : β → β → Prop} {t : γ → γ → Prop}
/-! ### Further properties of addition on ordinals -/
@[simp]
theorem lift_add (a b : Ordinal.{v}) : lift.{u} (a + b) = lift.{u} a + lift.{u} b :=
Quotient.inductionOn₂ a b fun ⟨_α, _r, _⟩ ⟨_β, _s, _⟩ =>
Quotient.sound
⟨(RelIso.preimage Equiv.ulift _).trans
(RelIso.sumLexCongr (RelIso.preimage Equiv.ulift _) (RelIso.preimage Equiv.ulift _)).symm⟩
@[simp]
theorem lift_succ (a : Ordinal.{v}) : lift.{u} (succ a) = succ (lift.{u} a) := by
rw [← add_one_eq_succ, lift_add, lift_one]
rfl
instance instAddLeftReflectLE :
AddLeftReflectLE Ordinal.{u} where
elim c a b := by
refine inductionOn₃ a b c fun α r _ β s _ γ t _ ⟨f⟩ ↦ ?_
have H₁ a : f (Sum.inl a) = Sum.inl a := by
simpa using ((InitialSeg.leAdd t r).trans f).eq (InitialSeg.leAdd t s) a
have H₂ a : ∃ b, f (Sum.inr a) = Sum.inr b := by
generalize hx : f (Sum.inr a) = x
obtain x | x := x
· rw [← H₁, f.inj] at hx
contradiction
· exact ⟨x, rfl⟩
choose g hg using H₂
refine (RelEmbedding.ofMonotone g fun _ _ h ↦ ?_).ordinal_type_le
rwa [← @Sum.lex_inr_inr _ t _ s, ← hg, ← hg, f.map_rel_iff, Sum.lex_inr_inr]
instance : IsLeftCancelAdd Ordinal where
add_left_cancel a b c h := by simpa only [le_antisymm_iff, add_le_add_iff_left] using h
@[deprecated add_left_cancel_iff (since := "2024-12-11")]
protected theorem add_left_cancel (a) {b c : Ordinal} : a + b = a + c ↔ b = c :=
add_left_cancel_iff
private theorem add_lt_add_iff_left' (a) {b c : Ordinal} : a + b < a + c ↔ b < c := by
rw [← not_le, ← not_le, add_le_add_iff_left]
instance instAddLeftStrictMono : AddLeftStrictMono Ordinal.{u} :=
⟨fun a _b _c ↦ (add_lt_add_iff_left' a).2⟩
instance instAddLeftReflectLT : AddLeftReflectLT Ordinal.{u} :=
⟨fun a _b _c ↦ (add_lt_add_iff_left' a).1⟩
instance instAddRightReflectLT : AddRightReflectLT Ordinal.{u} :=
⟨fun _a _b _c ↦ lt_imp_lt_of_le_imp_le fun h => add_le_add_right h _⟩
theorem add_le_add_iff_right {a b : Ordinal} : ∀ n : ℕ, a + n ≤ b + n ↔ a ≤ b
| 0 => by simp
| n + 1 => by
simp only [natCast_succ, add_succ, add_succ, succ_le_succ_iff, add_le_add_iff_right]
theorem add_right_cancel {a b : Ordinal} (n : ℕ) : a + n = b + n ↔ a = b := by
simp only [le_antisymm_iff, add_le_add_iff_right]
theorem add_eq_zero_iff {a b : Ordinal} : a + b = 0 ↔ a = 0 ∧ b = 0 :=
inductionOn₂ a b fun α r _ β s _ => by
simp_rw [← type_sum_lex, type_eq_zero_iff_isEmpty]
exact isEmpty_sum
theorem left_eq_zero_of_add_eq_zero {a b : Ordinal} (h : a + b = 0) : a = 0 :=
(add_eq_zero_iff.1 h).1
theorem right_eq_zero_of_add_eq_zero {a b : Ordinal} (h : a + b = 0) : b = 0 :=
(add_eq_zero_iff.1 h).2
/-! ### The predecessor of an ordinal -/
open Classical in
/-- The ordinal predecessor of `o` is `o'` if `o = succ o'`,
and `o` otherwise. -/
def pred (o : Ordinal) : Ordinal :=
if h : ∃ a, o = succ a then Classical.choose h else o
@[simp]
theorem pred_succ (o) : pred (succ o) = o := by
have h : ∃ a, succ o = succ a := ⟨_, rfl⟩
simpa only [pred, dif_pos h] using (succ_injective <| Classical.choose_spec h).symm
theorem pred_le_self (o) : pred o ≤ o := by
classical
exact if h : ∃ a, o = succ a then by
let ⟨a, e⟩ := h
rw [e, pred_succ]; exact le_succ a
else by rw [pred, dif_neg h]
theorem pred_eq_iff_not_succ {o} : pred o = o ↔ ¬∃ a, o = succ a :=
⟨fun e ⟨a, e'⟩ => by rw [e', pred_succ] at e; exact (lt_succ a).ne e, fun h => dif_neg h⟩
theorem pred_eq_iff_not_succ' {o} : pred o = o ↔ ∀ a, o ≠ succ a := by
simpa using pred_eq_iff_not_succ
theorem pred_lt_iff_is_succ {o} : pred o < o ↔ ∃ a, o = succ a :=
Iff.trans (by simp only [le_antisymm_iff, pred_le_self, true_and, not_le])
(iff_not_comm.1 pred_eq_iff_not_succ).symm
@[simp]
theorem pred_zero : pred 0 = 0 :=
pred_eq_iff_not_succ'.2 fun a => (succ_ne_zero a).symm
theorem succ_pred_iff_is_succ {o} : succ (pred o) = o ↔ ∃ a, o = succ a :=
⟨fun e => ⟨_, e.symm⟩, fun ⟨a, e⟩ => by simp only [e, pred_succ]⟩
theorem succ_lt_of_not_succ {o b : Ordinal} (h : ¬∃ a, o = succ a) : succ b < o ↔ b < o :=
⟨(lt_succ b).trans, fun l => lt_of_le_of_ne (succ_le_of_lt l) fun e => h ⟨_, e.symm⟩⟩
theorem lt_pred {a b} : a < pred b ↔ succ a < b := by
classical
exact if h : ∃ a, b = succ a then by
let ⟨c, e⟩ := h
rw [e, pred_succ, succ_lt_succ_iff]
else by simp only [pred, dif_neg h, succ_lt_of_not_succ h]
theorem pred_le {a b} : pred a ≤ b ↔ a ≤ succ b :=
le_iff_le_iff_lt_iff_lt.2 lt_pred
@[simp]
theorem lift_is_succ {o : Ordinal.{v}} : (∃ a, lift.{u} o = succ a) ↔ ∃ a, o = succ a :=
⟨fun ⟨a, h⟩ =>
let ⟨b, e⟩ := mem_range_lift_of_le <| show a ≤ lift.{u} o from le_of_lt <| h.symm ▸ lt_succ a
⟨b, (lift_inj.{u,v}).1 <| by rw [h, ← e, lift_succ]⟩,
fun ⟨a, h⟩ => ⟨lift.{u} a, by simp only [h, lift_succ]⟩⟩
@[simp]
theorem lift_pred (o : Ordinal.{v}) : lift.{u} (pred o) = pred (lift.{u} o) := by
classical
exact if h : ∃ a, o = succ a then by obtain ⟨a, e⟩ := h; simp only [e, pred_succ, lift_succ]
else by rw [pred_eq_iff_not_succ.2 h, pred_eq_iff_not_succ.2 (mt lift_is_succ.1 h)]
/-! ### Limit ordinals -/
/-- A limit ordinal is an ordinal which is not zero and not a successor.
TODO: deprecate this in favor of `Order.IsSuccLimit`. -/
def IsLimit (o : Ordinal) : Prop :=
IsSuccLimit o
theorem isLimit_iff {o} : IsLimit o ↔ o ≠ 0 ∧ IsSuccPrelimit o := by
simp [IsLimit, IsSuccLimit]
theorem IsLimit.isSuccPrelimit {o} (h : IsLimit o) : IsSuccPrelimit o :=
IsSuccLimit.isSuccPrelimit h
theorem IsLimit.succ_lt {o a : Ordinal} (h : IsLimit o) : a < o → succ a < o :=
IsSuccLimit.succ_lt h
theorem isSuccPrelimit_zero : IsSuccPrelimit (0 : Ordinal) := isSuccPrelimit_bot
theorem not_zero_isLimit : ¬IsLimit 0 :=
not_isSuccLimit_bot
theorem not_succ_isLimit (o) : ¬IsLimit (succ o) :=
not_isSuccLimit_succ o
theorem not_succ_of_isLimit {o} (h : IsLimit o) : ¬∃ a, o = succ a
| ⟨a, e⟩ => not_succ_isLimit a (e ▸ h)
theorem succ_lt_of_isLimit {o a : Ordinal} (h : IsLimit o) : succ a < o ↔ a < o :=
IsSuccLimit.succ_lt_iff h
theorem le_succ_of_isLimit {o} (h : IsLimit o) {a} : o ≤ succ a ↔ o ≤ a :=
le_iff_le_iff_lt_iff_lt.2 <| succ_lt_of_isLimit h
theorem limit_le {o} (h : IsLimit o) {a} : o ≤ a ↔ ∀ x < o, x ≤ a :=
⟨fun h _x l => l.le.trans h, fun H =>
(le_succ_of_isLimit h).1 <| le_of_not_lt fun hn => not_lt_of_le (H _ hn) (lt_succ a)⟩
theorem lt_limit {o} (h : IsLimit o) {a} : a < o ↔ ∃ x < o, a < x := by
-- Porting note: `bex_def` is required.
simpa only [not_forall₂, not_le, bex_def] using not_congr (@limit_le _ h a)
@[simp]
theorem lift_isLimit (o : Ordinal.{v}) : IsLimit (lift.{u,v} o) ↔ IsLimit o :=
liftInitialSeg.isSuccLimit_apply_iff
theorem IsLimit.pos {o : Ordinal} (h : IsLimit o) : 0 < o :=
IsSuccLimit.bot_lt h
theorem IsLimit.ne_zero {o : Ordinal} (h : IsLimit o) : o ≠ 0 :=
h.pos.ne'
theorem IsLimit.one_lt {o : Ordinal} (h : IsLimit o) : 1 < o := by
simpa only [succ_zero] using h.succ_lt h.pos
theorem IsLimit.nat_lt {o : Ordinal} (h : IsLimit o) : ∀ n : ℕ, (n : Ordinal) < o
| 0 => h.pos
| n + 1 => h.succ_lt (IsLimit.nat_lt h n)
theorem zero_or_succ_or_limit (o : Ordinal) : o = 0 ∨ (∃ a, o = succ a) ∨ IsLimit o := by
simpa [eq_comm] using isMin_or_mem_range_succ_or_isSuccLimit o
theorem isLimit_of_not_succ_of_ne_zero {o : Ordinal} (h : ¬∃ a, o = succ a) (h' : o ≠ 0) :
IsLimit o := ((zero_or_succ_or_limit o).resolve_left h').resolve_left h
-- TODO: this is an iff with `IsSuccPrelimit`
theorem IsLimit.sSup_Iio {o : Ordinal} (h : IsLimit o) : sSup (Iio o) = o := by
apply (csSup_le' (fun a ha ↦ le_of_lt ha)).antisymm
apply le_of_forall_lt
intro a ha
exact (lt_succ a).trans_le (le_csSup bddAbove_Iio (h.succ_lt ha))
theorem IsLimit.iSup_Iio {o : Ordinal} (h : IsLimit o) : ⨆ a : Iio o, a.1 = o := by
rw [← sSup_eq_iSup', h.sSup_Iio]
/-- Main induction principle of ordinals: if one can prove a property by
induction at successor ordinals and at limit ordinals, then it holds for all ordinals. -/
@[elab_as_elim]
def limitRecOn {motive : Ordinal → Sort*} (o : Ordinal)
(zero : motive 0) (succ : ∀ o, motive o → motive (succ o))
(isLimit : ∀ o, IsLimit o → (∀ o' < o, motive o') → motive o) : motive o := by
refine SuccOrder.limitRecOn o (fun a ha ↦ ?_) (fun a _ ↦ succ a) isLimit
convert zero
simpa using ha
@[simp]
theorem limitRecOn_zero {motive} (H₁ H₂ H₃) : @limitRecOn motive 0 H₁ H₂ H₃ = H₁ :=
SuccOrder.limitRecOn_isMin _ _ _ isMin_bot
@[simp]
theorem limitRecOn_succ {motive} (o H₁ H₂ H₃) :
@limitRecOn motive (succ o) H₁ H₂ H₃ = H₂ o (@limitRecOn motive o H₁ H₂ H₃) :=
SuccOrder.limitRecOn_succ ..
@[simp]
theorem limitRecOn_limit {motive} (o H₁ H₂ H₃ h) :
@limitRecOn motive o H₁ H₂ H₃ = H₃ o h fun x _h => @limitRecOn motive x H₁ H₂ H₃ :=
SuccOrder.limitRecOn_of_isSuccLimit ..
/-- Bounded recursion on ordinals. Similar to `limitRecOn`, with the assumption `o < l`
added to all cases. The final term's domain is the ordinals below `l`. -/
@[elab_as_elim]
def boundedLimitRecOn {l : Ordinal} (lLim : l.IsLimit) {motive : Iio l → Sort*} (o : Iio l)
(zero : motive ⟨0, lLim.pos⟩)
(succ : (o : Iio l) → motive o → motive ⟨succ o, lLim.succ_lt o.2⟩)
(isLimit : (o : Iio l) → IsLimit o → (Π o' < o, motive o') → motive o) : motive o :=
limitRecOn (motive := fun p ↦ (h : p < l) → motive ⟨p, h⟩) o.1 (fun _ ↦ zero)
(fun o ih h ↦ succ ⟨o, _⟩ <| ih <| (lt_succ o).trans h)
(fun _o ho ih _ ↦ isLimit _ ho fun _o' h ↦ ih _ h _) o.2
@[simp]
theorem boundedLimitRec_zero {l} (lLim : l.IsLimit) {motive} (H₁ H₂ H₃) :
@boundedLimitRecOn l lLim motive ⟨0, lLim.pos⟩ H₁ H₂ H₃ = H₁ := by
rw [boundedLimitRecOn, limitRecOn_zero]
@[simp]
theorem boundedLimitRec_succ {l} (lLim : l.IsLimit) {motive} (o H₁ H₂ H₃) :
@boundedLimitRecOn l lLim motive ⟨succ o.1, lLim.succ_lt o.2⟩ H₁ H₂ H₃ = H₂ o
(@boundedLimitRecOn l lLim motive o H₁ H₂ H₃) := by
rw [boundedLimitRecOn, limitRecOn_succ]
rfl
theorem boundedLimitRec_limit {l} (lLim : l.IsLimit) {motive} (o H₁ H₂ H₃ oLim) :
@boundedLimitRecOn l lLim motive o H₁ H₂ H₃ = H₃ o oLim (fun x _ ↦
@boundedLimitRecOn l lLim motive x H₁ H₂ H₃) := by
rw [boundedLimitRecOn, limitRecOn_limit]
rfl
instance orderTopToTypeSucc (o : Ordinal) : OrderTop (succ o).toType :=
@OrderTop.mk _ _ (Top.mk _) le_enum_succ
theorem enum_succ_eq_top {o : Ordinal} :
enum (α := (succ o).toType) (· < ·) ⟨o, type_toType _ ▸ lt_succ o⟩ = ⊤ :=
rfl
theorem has_succ_of_type_succ_lt {α} {r : α → α → Prop} [wo : IsWellOrder α r]
(h : ∀ a < type r, succ a < type r) (x : α) : ∃ y, r x y := by
use enum r ⟨succ (typein r x), h _ (typein_lt_type r x)⟩
convert enum_lt_enum.mpr _
· rw [enum_typein]
· rw [Subtype.mk_lt_mk, lt_succ_iff]
theorem toType_noMax_of_succ_lt {o : Ordinal} (ho : ∀ a < o, succ a < o) : NoMaxOrder o.toType :=
⟨has_succ_of_type_succ_lt (type_toType _ ▸ ho)⟩
theorem bounded_singleton {r : α → α → Prop} [IsWellOrder α r] (hr : (type r).IsLimit) (x) :
Bounded r {x} := by
refine ⟨enum r ⟨succ (typein r x), hr.succ_lt (typein_lt_type r x)⟩, ?_⟩
intro b hb
rw [mem_singleton_iff.1 hb]
nth_rw 1 [← enum_typein r x]
rw [@enum_lt_enum _ r, Subtype.mk_lt_mk]
apply lt_succ
@[simp]
theorem typein_ordinal (o : Ordinal.{u}) :
@typein Ordinal (· < ·) _ o = Ordinal.lift.{u + 1} o := by
refine Quotient.inductionOn o ?_
rintro ⟨α, r, wo⟩; apply Quotient.sound
constructor; refine ((RelIso.preimage Equiv.ulift r).trans (enum r).symm).symm
theorem mk_Iio_ordinal (o : Ordinal.{u}) :
#(Iio o) = Cardinal.lift.{u + 1} o.card := by
rw [lift_card, ← typein_ordinal]
rfl
/-! ### Normal ordinal functions -/
/-- A normal ordinal function is a strictly increasing function which is
order-continuous, i.e., the image `f o` of a limit ordinal `o` is the sup of `f a` for
`a < o`. -/
def IsNormal (f : Ordinal → Ordinal) : Prop :=
(∀ o, f o < f (succ o)) ∧ ∀ o, IsLimit o → ∀ a, f o ≤ a ↔ ∀ b < o, f b ≤ a
theorem IsNormal.limit_le {f} (H : IsNormal f) :
∀ {o}, IsLimit o → ∀ {a}, f o ≤ a ↔ ∀ b < o, f b ≤ a :=
@H.2
theorem IsNormal.limit_lt {f} (H : IsNormal f) {o} (h : IsLimit o) {a} :
a < f o ↔ ∃ b < o, a < f b :=
not_iff_not.1 <| by simpa only [exists_prop, not_exists, not_and, not_lt] using H.2 _ h a
theorem IsNormal.strictMono {f} (H : IsNormal f) : StrictMono f := fun a b =>
limitRecOn b (Not.elim (not_lt_of_le <| Ordinal.zero_le _))
(fun _b IH h =>
(lt_or_eq_of_le (le_of_lt_succ h)).elim (fun h => (IH h).trans (H.1 _)) fun e => e ▸ H.1 _)
fun _b l _IH h => lt_of_lt_of_le (H.1 a) ((H.2 _ l _).1 le_rfl _ (l.succ_lt h))
theorem IsNormal.monotone {f} (H : IsNormal f) : Monotone f :=
H.strictMono.monotone
theorem isNormal_iff_strictMono_limit (f : Ordinal → Ordinal) :
IsNormal f ↔ StrictMono f ∧ ∀ o, IsLimit o → ∀ a, (∀ b < o, f b ≤ a) → f o ≤ a :=
⟨fun hf => ⟨hf.strictMono, fun a ha c => (hf.2 a ha c).2⟩, fun ⟨hs, hl⟩ =>
⟨fun a => hs (lt_succ a), fun a ha c =>
⟨fun hac _b hba => ((hs hba).trans_le hac).le, hl a ha c⟩⟩⟩
theorem IsNormal.lt_iff {f} (H : IsNormal f) {a b} : f a < f b ↔ a < b :=
StrictMono.lt_iff_lt <| H.strictMono
theorem IsNormal.le_iff {f} (H : IsNormal f) {a b} : f a ≤ f b ↔ a ≤ b :=
le_iff_le_iff_lt_iff_lt.2 H.lt_iff
theorem IsNormal.inj {f} (H : IsNormal f) {a b} : f a = f b ↔ a = b := by
simp only [le_antisymm_iff, H.le_iff]
theorem IsNormal.id_le {f} (H : IsNormal f) : id ≤ f :=
H.strictMono.id_le
theorem IsNormal.le_apply {f} (H : IsNormal f) {a} : a ≤ f a :=
H.strictMono.le_apply
theorem IsNormal.le_iff_eq {f} (H : IsNormal f) {a} : f a ≤ a ↔ f a = a :=
H.le_apply.le_iff_eq
theorem IsNormal.le_set {f o} (H : IsNormal f) (p : Set Ordinal) (p0 : p.Nonempty) (b)
(H₂ : ∀ o, b ≤ o ↔ ∀ a ∈ p, a ≤ o) : f b ≤ o ↔ ∀ a ∈ p, f a ≤ o :=
⟨fun h _ pa => (H.le_iff.2 ((H₂ _).1 le_rfl _ pa)).trans h, fun h => by
induction b using limitRecOn with
| zero =>
obtain ⟨x, px⟩ := p0
have := Ordinal.le_zero.1 ((H₂ _).1 (Ordinal.zero_le _) _ px)
rw [this] at px
exact h _ px
| succ S _ =>
rcases not_forall₂.1 (mt (H₂ S).2 <| (lt_succ S).not_le) with ⟨a, h₁, h₂⟩
exact (H.le_iff.2 <| succ_le_of_lt <| not_le.1 h₂).trans (h _ h₁)
| isLimit S L _ =>
refine (H.2 _ L _).2 fun a h' => ?_
rcases not_forall₂.1 (mt (H₂ a).2 h'.not_le) with ⟨b, h₁, h₂⟩
exact (H.le_iff.2 <| (not_le.1 h₂).le).trans (h _ h₁)⟩
theorem IsNormal.le_set' {f o} (H : IsNormal f) (p : Set α) (p0 : p.Nonempty) (g : α → Ordinal) (b)
(H₂ : ∀ o, b ≤ o ↔ ∀ a ∈ p, g a ≤ o) : f b ≤ o ↔ ∀ a ∈ p, f (g a) ≤ o := by
simpa [H₂] using H.le_set (g '' p) (p0.image g) b
theorem IsNormal.refl : IsNormal id :=
⟨lt_succ, fun _o l _a => Ordinal.limit_le l⟩
theorem IsNormal.trans {f g} (H₁ : IsNormal f) (H₂ : IsNormal g) : IsNormal (f ∘ g) :=
⟨fun _x => H₁.lt_iff.2 (H₂.1 _), fun o l _a =>
H₁.le_set' (· < o) ⟨0, l.pos⟩ g _ fun _c => H₂.2 _ l _⟩
theorem IsNormal.isLimit {f} (H : IsNormal f) {o} (ho : IsLimit o) : IsLimit (f o) := by
rw [isLimit_iff, isSuccPrelimit_iff_succ_lt]
use (H.lt_iff.2 ho.pos).ne_bot
intro a ha
obtain ⟨b, hb, hab⟩ := (H.limit_lt ho).1 ha
rw [← succ_le_iff] at hab
apply hab.trans_lt
rwa [H.lt_iff]
theorem add_le_of_limit {a b c : Ordinal} (h : IsLimit b) :
a + b ≤ c ↔ ∀ b' < b, a + b' ≤ c :=
⟨fun h _ l => (add_le_add_left l.le _).trans h, fun H =>
le_of_not_lt <| by
-- Porting note: `induction` tactics are required because of the parser bug.
induction a using inductionOn with
| H α r =>
induction b using inductionOn with
| H β s =>
intro l
suffices ∀ x : β, Sum.Lex r s (Sum.inr x) (enum _ ⟨_, l⟩) by
-- Porting note: `revert` & `intro` is required because `cases'` doesn't replace
-- `enum _ _ l` in `this`.
revert this; rcases enum _ ⟨_, l⟩ with x | x <;> intro this
· cases this (enum s ⟨0, h.pos⟩)
· exact irrefl _ (this _)
intro x
rw [← typein_lt_typein (Sum.Lex r s), typein_enum]
have := H _ (h.succ_lt (typein_lt_type s x))
rw [add_succ, succ_le_iff] at this
refine
(RelEmbedding.ofMonotone (fun a => ?_) fun a b => ?_).ordinal_type_le.trans_lt this
· rcases a with ⟨a | b, h⟩
· exact Sum.inl a
· exact Sum.inr ⟨b, by cases h; assumption⟩
· rcases a with ⟨a | a, h₁⟩ <;> rcases b with ⟨b | b, h₂⟩ <;> cases h₁ <;> cases h₂ <;>
rintro ⟨⟩ <;> constructor <;> assumption⟩
theorem isNormal_add_right (a : Ordinal) : IsNormal (a + ·) :=
⟨fun b => (add_lt_add_iff_left a).2 (lt_succ b), fun _b l _c => add_le_of_limit l⟩
theorem isLimit_add (a) {b} : IsLimit b → IsLimit (a + b) :=
(isNormal_add_right a).isLimit
alias IsLimit.add := isLimit_add
/-! ### Subtraction on ordinals -/
/-- The set in the definition of subtraction is nonempty. -/
private theorem sub_nonempty {a b : Ordinal} : { o | a ≤ b + o }.Nonempty :=
⟨a, le_add_left _ _⟩
/-- `a - b` is the unique ordinal satisfying `b + (a - b) = a` when `b ≤ a`. -/
instance sub : Sub Ordinal :=
⟨fun a b => sInf { o | a ≤ b + o }⟩
theorem le_add_sub (a b : Ordinal) : a ≤ b + (a - b) :=
csInf_mem sub_nonempty
theorem sub_le {a b c : Ordinal} : a - b ≤ c ↔ a ≤ b + c :=
⟨fun h => (le_add_sub a b).trans (add_le_add_left h _), fun h => csInf_le' h⟩
theorem lt_sub {a b c : Ordinal} : a < b - c ↔ c + a < b :=
lt_iff_lt_of_le_iff_le sub_le
theorem add_sub_cancel (a b : Ordinal) : a + b - a = b :=
le_antisymm (sub_le.2 <| le_rfl) ((add_le_add_iff_left a).1 <| le_add_sub _ _)
theorem sub_eq_of_add_eq {a b c : Ordinal} (h : a + b = c) : c - a = b :=
h ▸ add_sub_cancel _ _
theorem sub_le_self (a b : Ordinal) : a - b ≤ a :=
sub_le.2 <| le_add_left _ _
protected theorem add_sub_cancel_of_le {a b : Ordinal} (h : b ≤ a) : b + (a - b) = a :=
(le_add_sub a b).antisymm'
(by
rcases zero_or_succ_or_limit (a - b) with (e | ⟨c, e⟩ | l)
· simp only [e, add_zero, h]
· rw [e, add_succ, succ_le_iff, ← lt_sub, e]
exact lt_succ c
· exact (add_le_of_limit l).2 fun c l => (lt_sub.1 l).le)
theorem le_sub_of_le {a b c : Ordinal} (h : b ≤ a) : c ≤ a - b ↔ b + c ≤ a := by
rw [← add_le_add_iff_left b, Ordinal.add_sub_cancel_of_le h]
theorem sub_lt_of_le {a b c : Ordinal} (h : b ≤ a) : a - b < c ↔ a < b + c :=
lt_iff_lt_of_le_iff_le (le_sub_of_le h)
instance existsAddOfLE : ExistsAddOfLE Ordinal :=
⟨fun h => ⟨_, (Ordinal.add_sub_cancel_of_le h).symm⟩⟩
@[simp]
theorem sub_zero (a : Ordinal) : a - 0 = a := by simpa only [zero_add] using add_sub_cancel 0 a
@[simp]
theorem zero_sub (a : Ordinal) : 0 - a = 0 := by rw [← Ordinal.le_zero]; apply sub_le_self
@[simp]
theorem sub_self (a : Ordinal) : a - a = 0 := by simpa only [add_zero] using add_sub_cancel a 0
protected theorem sub_eq_zero_iff_le {a b : Ordinal} : a - b = 0 ↔ a ≤ b :=
⟨fun h => by simpa only [h, add_zero] using le_add_sub a b, fun h => by
rwa [← Ordinal.le_zero, sub_le, add_zero]⟩
protected theorem sub_ne_zero_iff_lt {a b : Ordinal} : a - b ≠ 0 ↔ b < a := by
simpa using Ordinal.sub_eq_zero_iff_le.not
theorem sub_sub (a b c : Ordinal) : a - b - c = a - (b + c) :=
eq_of_forall_ge_iff fun d => by rw [sub_le, sub_le, sub_le, add_assoc]
@[simp]
theorem add_sub_add_cancel (a b c : Ordinal) : a + b - (a + c) = b - c := by
rw [← sub_sub, add_sub_cancel]
theorem le_sub_of_add_le {a b c : Ordinal} (h : b + c ≤ a) : c ≤ a - b := by
rw [← add_le_add_iff_left b]
exact h.trans (le_add_sub a b)
theorem sub_lt_of_lt_add {a b c : Ordinal} (h : a < b + c) (hc : 0 < c) : a - b < c := by
obtain hab | hba := lt_or_le a b
· rwa [Ordinal.sub_eq_zero_iff_le.2 hab.le]
· rwa [sub_lt_of_le hba]
theorem lt_add_iff {a b c : Ordinal} (hc : c ≠ 0) : a < b + c ↔ ∃ d < c, a ≤ b + d := by
use fun h ↦ ⟨_, sub_lt_of_lt_add h hc.bot_lt, le_add_sub a b⟩
rintro ⟨d, hd, ha⟩
exact ha.trans_lt (add_lt_add_left hd b)
theorem add_le_iff {a b c : Ordinal} (hb : b ≠ 0) : a + b ≤ c ↔ ∀ d < b, a + d < c := by
simpa using (lt_add_iff hb).not
@[deprecated add_le_iff (since := "2024-12-08")]
theorem add_le_of_forall_add_lt {a b c : Ordinal} (hb : 0 < b) (h : ∀ d < b, a + d < c) :
a + b ≤ c :=
(add_le_iff hb.ne').2 h
theorem isLimit_sub {a b} (ha : IsLimit a) (h : b < a) : IsLimit (a - b) := by
rw [isLimit_iff, Ordinal.sub_ne_zero_iff_lt, isSuccPrelimit_iff_succ_lt]
refine ⟨h, fun c hc ↦ ?_⟩
rw [lt_sub] at hc ⊢
rw [add_succ]
exact ha.succ_lt hc
/-! ### Multiplication of ordinals -/
/-- The multiplication of ordinals `o₁` and `o₂` is the (well founded) lexicographic order on
`o₂ × o₁`. -/
instance monoid : Monoid Ordinal.{u} where
mul a b :=
Quotient.liftOn₂ a b
(fun ⟨α, r, _⟩ ⟨β, s, _⟩ => ⟦⟨β × α, Prod.Lex s r, inferInstance⟩⟧ :
WellOrder → WellOrder → Ordinal)
fun ⟨_, _, _⟩ _ _ _ ⟨f⟩ ⟨g⟩ => Quot.sound ⟨RelIso.prodLexCongr g f⟩
one := 1
mul_assoc a b c :=
Quotient.inductionOn₃ a b c fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ =>
Eq.symm <|
Quotient.sound
⟨⟨prodAssoc _ _ _, @fun a b => by
rcases a with ⟨⟨a₁, a₂⟩, a₃⟩
rcases b with ⟨⟨b₁, b₂⟩, b₃⟩
simp [Prod.lex_def, and_or_left, or_assoc, and_assoc]⟩⟩
mul_one a :=
inductionOn a fun α r _ =>
Quotient.sound
⟨⟨punitProd _, @fun a b => by
rcases a with ⟨⟨⟨⟩⟩, a⟩; rcases b with ⟨⟨⟨⟩⟩, b⟩
simp only [Prod.lex_def, EmptyRelation, false_or]
simp only [eq_self_iff_true, true_and]
rfl⟩⟩
one_mul a :=
inductionOn a fun α r _ =>
Quotient.sound
⟨⟨prodPUnit _, @fun a b => by
rcases a with ⟨a, ⟨⟨⟩⟩⟩; rcases b with ⟨b, ⟨⟨⟩⟩⟩
simp only [Prod.lex_def, EmptyRelation, and_false, or_false]
rfl⟩⟩
@[simp]
theorem type_prod_lex {α β : Type u} (r : α → α → Prop) (s : β → β → Prop) [IsWellOrder α r]
[IsWellOrder β s] : type (Prod.Lex s r) = type r * type s :=
rfl
private theorem mul_eq_zero' {a b : Ordinal} : a * b = 0 ↔ a = 0 ∨ b = 0 :=
inductionOn a fun α _ _ =>
inductionOn b fun β _ _ => by
simp_rw [← type_prod_lex, type_eq_zero_iff_isEmpty]
rw [or_comm]
exact isEmpty_prod
instance monoidWithZero : MonoidWithZero Ordinal :=
{ Ordinal.monoid with
zero := 0
mul_zero := fun _a => mul_eq_zero'.2 <| Or.inr rfl
zero_mul := fun _a => mul_eq_zero'.2 <| Or.inl rfl }
instance noZeroDivisors : NoZeroDivisors Ordinal :=
⟨fun {_ _} => mul_eq_zero'.1⟩
@[simp]
theorem lift_mul (a b : Ordinal.{v}) : lift.{u} (a * b) = lift.{u} a * lift.{u} b :=
Quotient.inductionOn₂ a b fun ⟨_α, _r, _⟩ ⟨_β, _s, _⟩ =>
Quotient.sound
⟨(RelIso.preimage Equiv.ulift _).trans
(RelIso.prodLexCongr (RelIso.preimage Equiv.ulift _)
(RelIso.preimage Equiv.ulift _)).symm⟩
@[simp]
theorem card_mul (a b) : card (a * b) = card a * card b :=
Quotient.inductionOn₂ a b fun ⟨α, _r, _⟩ ⟨β, _s, _⟩ => mul_comm #β #α
instance leftDistribClass : LeftDistribClass Ordinal.{u} :=
⟨fun a b c =>
Quotient.inductionOn₃ a b c fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ =>
Quotient.sound
⟨⟨sumProdDistrib _ _ _, by
rintro ⟨a₁ | a₁, a₂⟩ ⟨b₁ | b₁, b₂⟩ <;>
simp only [Prod.lex_def, Sum.lex_inl_inl, Sum.Lex.sep, Sum.lex_inr_inl, Sum.lex_inr_inr,
sumProdDistrib_apply_left, sumProdDistrib_apply_right, reduceCtorEq] <;>
-- Porting note: `Sum.inr.inj_iff` is required.
simp only [Sum.inl.inj_iff, Sum.inr.inj_iff, true_or, false_and, false_or]⟩⟩⟩
theorem mul_succ (a b : Ordinal) : a * succ b = a * b + a :=
mul_add_one a b
instance mulLeftMono : MulLeftMono Ordinal.{u} :=
⟨fun c a b =>
Quotient.inductionOn₃ a b c fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ ⟨f⟩ => by
refine
(RelEmbedding.ofMonotone (fun a : α × γ => (f a.1, a.2)) fun a b h => ?_).ordinal_type_le
obtain ⟨-, -, h'⟩ | ⟨-, h'⟩ := h
· exact Prod.Lex.left _ _ (f.toRelEmbedding.map_rel_iff.2 h')
· exact Prod.Lex.right _ h'⟩
instance mulRightMono : MulRightMono Ordinal.{u} :=
⟨fun c a b =>
Quotient.inductionOn₃ a b c fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ ⟨f⟩ => by
refine
(RelEmbedding.ofMonotone (fun a : γ × α => (a.1, f a.2)) fun a b h => ?_).ordinal_type_le
obtain ⟨-, -, h'⟩ | ⟨-, h'⟩ := h
· exact Prod.Lex.left _ _ h'
· exact Prod.Lex.right _ (f.toRelEmbedding.map_rel_iff.2 h')⟩
theorem le_mul_left (a : Ordinal) {b : Ordinal} (hb : 0 < b) : a ≤ a * b := by
convert mul_le_mul_left' (one_le_iff_pos.2 hb) a
rw [mul_one a]
theorem le_mul_right (a : Ordinal) {b : Ordinal} (hb : 0 < b) : a ≤ b * a := by
convert mul_le_mul_right' (one_le_iff_pos.2 hb) a
rw [one_mul a]
private theorem mul_le_of_limit_aux {α β r s} [IsWellOrder α r] [IsWellOrder β s] {c}
(h : IsLimit (type s)) (H : ∀ b' < type s, type r * b' ≤ c) (l : c < type r * type s) :
False := by
suffices ∀ a b, Prod.Lex s r (b, a) (enum _ ⟨_, l⟩) by
obtain ⟨b, a⟩ := enum _ ⟨_, l⟩
exact irrefl _ (this _ _)
intro a b
rw [← typein_lt_typein (Prod.Lex s r), typein_enum]
have := H _ (h.succ_lt (typein_lt_type s b))
rw [mul_succ] at this
have := ((add_lt_add_iff_left _).2 (typein_lt_type _ a)).trans_le this
refine (RelEmbedding.ofMonotone (fun a => ?_) fun a b => ?_).ordinal_type_le.trans_lt this
· rcases a with ⟨⟨b', a'⟩, h⟩
by_cases e : b = b'
· refine Sum.inr ⟨a', ?_⟩
subst e
obtain ⟨-, -, h⟩ | ⟨-, h⟩ := h
· exact (irrefl _ h).elim
· exact h
· refine Sum.inl (⟨b', ?_⟩, a')
obtain ⟨-, -, h⟩ | ⟨e, h⟩ := h
· exact h
· exact (e rfl).elim
· rcases a with ⟨⟨b₁, a₁⟩, h₁⟩
rcases b with ⟨⟨b₂, a₂⟩, h₂⟩
intro h
by_cases e₁ : b = b₁ <;> by_cases e₂ : b = b₂
· substs b₁ b₂
simpa only [subrel_val, Prod.lex_def, @irrefl _ s _ b, true_and, false_or,
eq_self_iff_true, dif_pos, Sum.lex_inr_inr] using h
· subst b₁
simp only [subrel_val, Prod.lex_def, e₂, Prod.lex_def, dif_pos, subrel_val, eq_self_iff_true,
or_false, dif_neg, not_false_iff, Sum.lex_inr_inl, false_and] at h ⊢
obtain ⟨-, -, h₂_h⟩ | e₂ := h₂ <;> [exact asymm h h₂_h; exact e₂ rfl]
· simp [e₂, dif_neg e₁, show b₂ ≠ b₁ from e₂ ▸ e₁]
· simpa only [dif_neg e₁, dif_neg e₂, Prod.lex_def, subrel_val, Subtype.mk_eq_mk,
Sum.lex_inl_inl] using h
theorem mul_le_of_limit {a b c : Ordinal} (h : IsLimit b) : a * b ≤ c ↔ ∀ b' < b, a * b' ≤ c :=
⟨fun h _ l => (mul_le_mul_left' l.le _).trans h, fun H =>
-- Porting note: `induction` tactics are required because of the parser bug.
le_of_not_lt <| by
induction a using inductionOn with
| H α r =>
induction b using inductionOn with
| H β s =>
exact mul_le_of_limit_aux h H⟩
theorem isNormal_mul_right {a : Ordinal} (h : 0 < a) : IsNormal (a * ·) :=
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/12129): additional beta reduction needed
⟨fun b => by
beta_reduce
rw [mul_succ]
simpa only [add_zero] using (add_lt_add_iff_left (a * b)).2 h,
fun _ l _ => mul_le_of_limit l⟩
theorem lt_mul_of_limit {a b c : Ordinal} (h : IsLimit c) : a < b * c ↔ ∃ c' < c, a < b * c' := by
-- Porting note: `bex_def` is required.
simpa only [not_forall₂, not_le, bex_def] using not_congr (@mul_le_of_limit b c a h)
theorem mul_lt_mul_iff_left {a b c : Ordinal} (a0 : 0 < a) : a * b < a * c ↔ b < c :=
(isNormal_mul_right a0).lt_iff
theorem mul_le_mul_iff_left {a b c : Ordinal} (a0 : 0 < a) : a * b ≤ a * c ↔ b ≤ c :=
(isNormal_mul_right a0).le_iff
theorem mul_lt_mul_of_pos_left {a b c : Ordinal} (h : a < b) (c0 : 0 < c) : c * a < c * b :=
(mul_lt_mul_iff_left c0).2 h
theorem mul_pos {a b : Ordinal} (h₁ : 0 < a) (h₂ : 0 < b) : 0 < a * b := by
simpa only [mul_zero] using mul_lt_mul_of_pos_left h₂ h₁
theorem mul_ne_zero {a b : Ordinal} : a ≠ 0 → b ≠ 0 → a * b ≠ 0 := by
simpa only [Ordinal.pos_iff_ne_zero] using mul_pos
theorem le_of_mul_le_mul_left {a b c : Ordinal} (h : c * a ≤ c * b) (h0 : 0 < c) : a ≤ b :=
le_imp_le_of_lt_imp_lt (fun h' => mul_lt_mul_of_pos_left h' h0) h
theorem mul_right_inj {a b c : Ordinal} (a0 : 0 < a) : a * b = a * c ↔ b = c :=
(isNormal_mul_right a0).inj
theorem isLimit_mul {a b : Ordinal} (a0 : 0 < a) : IsLimit b → IsLimit (a * b) :=
(isNormal_mul_right a0).isLimit
theorem isLimit_mul_left {a b : Ordinal} (l : IsLimit a) (b0 : 0 < b) : IsLimit (a * b) := by
rcases zero_or_succ_or_limit b with (rfl | ⟨b, rfl⟩ | lb)
· exact b0.false.elim
· rw [mul_succ]
exact isLimit_add _ l
· exact isLimit_mul l.pos lb
theorem smul_eq_mul : ∀ (n : ℕ) (a : Ordinal), n • a = a * n
| 0, a => by rw [zero_nsmul, Nat.cast_zero, mul_zero]
| n + 1, a => by rw [succ_nsmul, Nat.cast_add, mul_add, Nat.cast_one, mul_one, smul_eq_mul n]
private theorem add_mul_limit_aux {a b c : Ordinal} (ba : b + a = a) (l : IsLimit c)
(IH : ∀ c' < c, (a + b) * succ c' = a * succ c' + b) : (a + b) * c = a * c :=
le_antisymm
((mul_le_of_limit l).2 fun c' h => by
apply (mul_le_mul_left' (le_succ c') _).trans
rw [IH _ h]
apply (add_le_add_left _ _).trans
· rw [← mul_succ]
exact mul_le_mul_left' (succ_le_of_lt <| l.succ_lt h) _
· rw [← ba]
exact le_add_right _ _)
(mul_le_mul_right' (le_add_right _ _) _)
theorem add_mul_succ {a b : Ordinal} (c) (ba : b + a = a) : (a + b) * succ c = a * succ c + b := by
induction c using limitRecOn with
| zero => simp only [succ_zero, mul_one]
| succ c IH =>
rw [mul_succ, IH, ← add_assoc, add_assoc _ b, ba, ← mul_succ]
| isLimit c l IH =>
rw [mul_succ, add_mul_limit_aux ba l IH, mul_succ, add_assoc]
theorem add_mul_limit {a b c : Ordinal} (ba : b + a = a) (l : IsLimit c) : (a + b) * c = a * c :=
add_mul_limit_aux ba l fun c' _ => add_mul_succ c' ba
/-! ### Division on ordinals -/
/-- The set in the definition of division is nonempty. -/
private theorem div_nonempty {a b : Ordinal} (h : b ≠ 0) : { o | a < b * succ o }.Nonempty :=
⟨a, (succ_le_iff (a := a) (b := b * succ a)).1 <| by
simpa only [succ_zero, one_mul] using
mul_le_mul_right' (succ_le_of_lt (Ordinal.pos_iff_ne_zero.2 h)) (succ a)⟩
/-- `a / b` is the unique ordinal `o` satisfying `a = b * o + o'` with `o' < b`. -/
instance div : Div Ordinal :=
⟨fun a b => if b = 0 then 0 else sInf { o | a < b * succ o }⟩
@[simp]
theorem div_zero (a : Ordinal) : a / 0 = 0 :=
dif_pos rfl
private theorem div_def (a) {b : Ordinal} (h : b ≠ 0) : a / b = sInf { o | a < b * succ o } :=
dif_neg h
theorem lt_mul_succ_div (a) {b : Ordinal} (h : b ≠ 0) : a < b * succ (a / b) := by
rw [div_def a h]; exact csInf_mem (div_nonempty h)
theorem lt_mul_div_add (a) {b : Ordinal} (h : b ≠ 0) : a < b * (a / b) + b := by
simpa only [mul_succ] using lt_mul_succ_div a h
theorem div_le {a b c : Ordinal} (b0 : b ≠ 0) : a / b ≤ c ↔ a < b * succ c :=
⟨fun h => (lt_mul_succ_div a b0).trans_le (mul_le_mul_left' (succ_le_succ_iff.2 h) _), fun h => by
rw [div_def a b0]; exact csInf_le' h⟩
theorem lt_div {a b c : Ordinal} (h : c ≠ 0) : a < b / c ↔ c * succ a ≤ b := by
rw [← not_le, div_le h, not_lt]
theorem div_pos {b c : Ordinal} (h : c ≠ 0) : 0 < b / c ↔ c ≤ b := by simp [lt_div h]
theorem le_div {a b c : Ordinal} (c0 : c ≠ 0) : a ≤ b / c ↔ c * a ≤ b := by
induction a using limitRecOn with
| zero => simp only [mul_zero, Ordinal.zero_le]
| succ _ _ => rw [succ_le_iff, lt_div c0]
| isLimit _ h₁ h₂ =>
revert h₁ h₂
simp +contextual only [mul_le_of_limit, limit_le, forall_true_iff]
theorem div_lt {a b c : Ordinal} (b0 : b ≠ 0) : a / b < c ↔ a < b * c :=
lt_iff_lt_of_le_iff_le <| le_div b0
theorem div_le_of_le_mul {a b c : Ordinal} (h : a ≤ b * c) : a / b ≤ c :=
if b0 : b = 0 then by simp only [b0, div_zero, Ordinal.zero_le]
else
(div_le b0).2 <| h.trans_lt <| mul_lt_mul_of_pos_left (lt_succ c) (Ordinal.pos_iff_ne_zero.2 b0)
theorem mul_lt_of_lt_div {a b c : Ordinal} : a < b / c → c * a < b :=
lt_imp_lt_of_le_imp_le div_le_of_le_mul
@[simp]
theorem zero_div (a : Ordinal) : 0 / a = 0 :=
Ordinal.le_zero.1 <| div_le_of_le_mul <| Ordinal.zero_le _
theorem mul_div_le (a b : Ordinal) : b * (a / b) ≤ a :=
if b0 : b = 0 then by simp only [b0, zero_mul, Ordinal.zero_le] else (le_div b0).1 le_rfl
theorem div_le_left {a b : Ordinal} (h : a ≤ b) (c : Ordinal) : a / c ≤ b / c := by
obtain rfl | hc := eq_or_ne c 0
· rw [div_zero, div_zero]
· rw [le_div hc]
exact (mul_div_le a c).trans h
theorem mul_add_div (a) {b : Ordinal} (b0 : b ≠ 0) (c) : (b * a + c) / b = a + c / b := by
apply le_antisymm
· apply (div_le b0).2
rw [mul_succ, mul_add, add_assoc, add_lt_add_iff_left]
apply lt_mul_div_add _ b0
· rw [le_div b0, mul_add, add_le_add_iff_left]
apply mul_div_le
theorem div_eq_zero_of_lt {a b : Ordinal} (h : a < b) : a / b = 0 := by
rw [← Ordinal.le_zero, div_le <| Ordinal.pos_iff_ne_zero.1 <| (Ordinal.zero_le _).trans_lt h]
simpa only [succ_zero, mul_one] using h
@[simp]
theorem mul_div_cancel (a) {b : Ordinal} (b0 : b ≠ 0) : b * a / b = a := by
simpa only [add_zero, zero_div] using mul_add_div a b0 0
theorem mul_add_div_mul {a c : Ordinal} (hc : c < a) (b d : Ordinal) :
(a * b + c) / (a * d) = b / d := by
have ha : a ≠ 0 := ((Ordinal.zero_le c).trans_lt hc).ne'
obtain rfl | hd := eq_or_ne d 0
· rw [mul_zero, div_zero, div_zero]
· have H := mul_ne_zero ha hd
apply le_antisymm
· rw [← lt_succ_iff, div_lt H, mul_assoc]
· apply (add_lt_add_left hc _).trans_le
rw [← mul_succ]
apply mul_le_mul_left'
rw [succ_le_iff]
exact lt_mul_succ_div b hd
· rw [le_div H, mul_assoc]
exact (mul_le_mul_left' (mul_div_le b d) a).trans (le_add_right _ c)
theorem mul_div_mul_cancel {a : Ordinal} (ha : a ≠ 0) (b c) : a * b / (a * c) = b / c := by
convert mul_add_div_mul (Ordinal.pos_iff_ne_zero.2 ha) b c using 1
rw [add_zero]
@[simp]
theorem div_one (a : Ordinal) : a / 1 = a := by
simpa only [one_mul] using mul_div_cancel a Ordinal.one_ne_zero
@[simp]
theorem div_self {a : Ordinal} (h : a ≠ 0) : a / a = 1 := by
simpa only [mul_one] using mul_div_cancel 1 h
theorem mul_sub (a b c : Ordinal) : a * (b - c) = a * b - a * c :=
if a0 : a = 0 then by simp only [a0, zero_mul, sub_self]
else
eq_of_forall_ge_iff fun d => by rw [sub_le, ← le_div a0, sub_le, ← le_div a0, mul_add_div _ a0]
theorem isLimit_add_iff {a b} : IsLimit (a + b) ↔ IsLimit b ∨ b = 0 ∧ IsLimit a := by
constructor <;> intro h
· by_cases h' : b = 0
· rw [h', add_zero] at h
right
exact ⟨h', h⟩
left
rw [← add_sub_cancel a b]
apply isLimit_sub h
suffices a + 0 < a + b by simpa only [add_zero] using this
rwa [add_lt_add_iff_left, Ordinal.pos_iff_ne_zero]
rcases h with (h | ⟨rfl, h⟩)
· exact isLimit_add a h
· simpa only [add_zero]
theorem dvd_add_iff : ∀ {a b c : Ordinal}, a ∣ b → (a ∣ b + c ↔ a ∣ c)
| a, _, c, ⟨b, rfl⟩ =>
⟨fun ⟨d, e⟩ => ⟨d - b, by rw [mul_sub, ← e, add_sub_cancel]⟩, fun ⟨d, e⟩ => by
rw [e, ← mul_add]
apply dvd_mul_right⟩
theorem div_mul_cancel : ∀ {a b : Ordinal}, a ≠ 0 → a ∣ b → a * (b / a) = b
| a, _, a0, ⟨b, rfl⟩ => by rw [mul_div_cancel _ a0]
theorem le_of_dvd : ∀ {a b : Ordinal}, b ≠ 0 → a ∣ b → a ≤ b
-- Porting note: `⟨b, rfl⟩ => by` → `⟨b, e⟩ => by subst e`
| a, _, b0, ⟨b, e⟩ => by
subst e
-- Porting note: `Ne` is required.
simpa only [mul_one] using
mul_le_mul_left'
(one_le_iff_ne_zero.2 fun h : b = 0 => by
simp only [h, mul_zero, Ne, not_true_eq_false] at b0) a
theorem dvd_antisymm {a b : Ordinal} (h₁ : a ∣ b) (h₂ : b ∣ a) : a = b :=
if a0 : a = 0 then by subst a; exact (eq_zero_of_zero_dvd h₁).symm
else
if b0 : b = 0 then by subst b; exact eq_zero_of_zero_dvd h₂
else (le_of_dvd b0 h₁).antisymm (le_of_dvd a0 h₂)
instance isAntisymm : IsAntisymm Ordinal (· ∣ ·) :=
⟨@dvd_antisymm⟩
/-- `a % b` is the unique ordinal `o'` satisfying
`a = b * o + o'` with `o' < b`. -/
instance mod : Mod Ordinal :=
⟨fun a b => a - b * (a / b)⟩
theorem mod_def (a b : Ordinal) : a % b = a - b * (a / b) :=
rfl
theorem mod_le (a b : Ordinal) : a % b ≤ a :=
sub_le_self a _
@[simp]
theorem mod_zero (a : Ordinal) : a % 0 = a := by simp only [mod_def, div_zero, zero_mul, sub_zero]
theorem mod_eq_of_lt {a b : Ordinal} (h : a < b) : a % b = a := by
simp only [mod_def, div_eq_zero_of_lt h, mul_zero, sub_zero]
@[simp]
theorem zero_mod (b : Ordinal) : 0 % b = 0 := by simp only [mod_def, zero_div, mul_zero, sub_self]
theorem div_add_mod (a b : Ordinal) : b * (a / b) + a % b = a :=
Ordinal.add_sub_cancel_of_le <| mul_div_le _ _
theorem mod_lt (a) {b : Ordinal} (h : b ≠ 0) : a % b < b :=
(add_lt_add_iff_left (b * (a / b))).1 <| by rw [div_add_mod]; exact lt_mul_div_add a h
@[simp]
theorem mod_self (a : Ordinal) : a % a = 0 :=
if a0 : a = 0 then by simp only [a0, zero_mod]
else by simp only [mod_def, div_self a0, mul_one, sub_self]
@[simp]
theorem mod_one (a : Ordinal) : a % 1 = 0 := by simp only [mod_def, div_one, one_mul, sub_self]
theorem dvd_of_mod_eq_zero {a b : Ordinal} (H : a % b = 0) : b ∣ a :=
⟨a / b, by simpa [H] using (div_add_mod a b).symm⟩
theorem mod_eq_zero_of_dvd {a b : Ordinal} (H : b ∣ a) : a % b = 0 := by
rcases H with ⟨c, rfl⟩
rcases eq_or_ne b 0 with (rfl | hb)
· simp
· simp [mod_def, hb]
theorem dvd_iff_mod_eq_zero {a b : Ordinal} : b ∣ a ↔ a % b = 0 :=
⟨mod_eq_zero_of_dvd, dvd_of_mod_eq_zero⟩
@[simp]
theorem mul_add_mod_self (x y z : Ordinal) : (x * y + z) % x = z % x := by
rcases eq_or_ne x 0 with rfl | hx
· simp
· rwa [mod_def, mul_add_div, mul_add, ← sub_sub, add_sub_cancel, mod_def]
@[simp]
theorem mul_mod (x y : Ordinal) : x * y % x = 0 := by
simpa using mul_add_mod_self x y 0
theorem mul_add_mod_mul {w x : Ordinal} (hw : w < x) (y z : Ordinal) :
(x * y + w) % (x * z) = x * (y % z) + w := by
rw [mod_def, mul_add_div_mul hw]
apply sub_eq_of_add_eq
rw [← add_assoc, mul_assoc, ← mul_add, div_add_mod]
theorem mul_mod_mul (x y z : Ordinal) : (x * y) % (x * z) = x * (y % z) := by
obtain rfl | hx := Ordinal.eq_zero_or_pos x
· simp
· convert mul_add_mod_mul hx y z using 1 <;>
rw [add_zero]
theorem mod_mod_of_dvd (a : Ordinal) {b c : Ordinal} (h : c ∣ b) : a % b % c = a % c := by
nth_rw 2 [← div_add_mod a b]
rcases h with ⟨d, rfl⟩
rw [mul_assoc, mul_add_mod_self]
@[simp]
theorem mod_mod (a b : Ordinal) : a % b % b = a % b :=
mod_mod_of_dvd a dvd_rfl
/-! ### Casting naturals into ordinals, compatibility with operations -/
instance instCharZero : CharZero Ordinal := by
refine ⟨fun a b h ↦ ?_⟩
rwa [← Cardinal.ord_nat, ← Cardinal.ord_nat, Cardinal.ord_inj, Nat.cast_inj] at h
@[simp]
theorem one_add_natCast (m : ℕ) : 1 + (m : Ordinal) = succ m := by
rw [← Nat.cast_one, ← Nat.cast_add, add_comm]
rfl
@[simp]
theorem one_add_ofNat (m : ℕ) [m.AtLeastTwo] :
1 + (ofNat(m) : Ordinal) = Order.succ (OfNat.ofNat m : Ordinal) :=
one_add_natCast m
@[simp, norm_cast]
theorem natCast_mul (m : ℕ) : ∀ n : ℕ, ((m * n : ℕ) : Ordinal) = m * n
| 0 => by simp
| n + 1 => by rw [Nat.mul_succ, Nat.cast_add, natCast_mul m n, Nat.cast_succ, mul_add_one]
@[simp, norm_cast]
theorem natCast_sub (m n : ℕ) : ((m - n : ℕ) : Ordinal) = m - n := by
rcases le_total m n with h | h
· rw [tsub_eq_zero_iff_le.2 h, Ordinal.sub_eq_zero_iff_le.2 (Nat.cast_le.2 h), Nat.cast_zero]
· rw [← add_left_cancel_iff (a := ↑n), ← Nat.cast_add, add_tsub_cancel_of_le h,
Ordinal.add_sub_cancel_of_le (Nat.cast_le.2 h)]
@[simp, norm_cast]
theorem natCast_div (m n : ℕ) : ((m / n : ℕ) : Ordinal) = m / n := by
rcases eq_or_ne n 0 with (rfl | hn)
· simp
· have hn' : (n : Ordinal) ≠ 0 := Nat.cast_ne_zero.2 hn
apply le_antisymm
· rw [le_div hn', ← natCast_mul, Nat.cast_le, mul_comm]
apply Nat.div_mul_le_self
· rw [div_le hn', ← add_one_eq_succ, ← Nat.cast_succ, ← natCast_mul, Nat.cast_lt, mul_comm,
← Nat.div_lt_iff_lt_mul (Nat.pos_of_ne_zero hn)]
apply Nat.lt_succ_self
@[simp, norm_cast]
theorem natCast_mod (m n : ℕ) : ((m % n : ℕ) : Ordinal) = m % n := by
rw [← add_left_cancel_iff, div_add_mod, ← natCast_div, ← natCast_mul, ← Nat.cast_add,
Nat.div_add_mod]
@[simp]
theorem lift_natCast : ∀ n : ℕ, lift.{u, v} n = n
| 0 => by simp
| n + 1 => by simp [lift_natCast n]
@[simp]
theorem lift_ofNat (n : ℕ) [n.AtLeastTwo] :
lift.{u, v} ofNat(n) = OfNat.ofNat n :=
lift_natCast n
theorem lt_omega0 {o : Ordinal} : o < ω ↔ ∃ n : ℕ, o = n := by
simp_rw [← Cardinal.ord_aleph0, Cardinal.lt_ord, lt_aleph0, card_eq_nat]
theorem nat_lt_omega0 (n : ℕ) : ↑n < ω :=
lt_omega0.2 ⟨_, rfl⟩
theorem eq_nat_or_omega0_le (o : Ordinal) : (∃ n : ℕ, o = n) ∨ ω ≤ o := by
obtain ho | ho := lt_or_le o ω
· exact Or.inl <| lt_omega0.1 ho
· exact Or.inr ho
theorem omega0_pos : 0 < ω :=
nat_lt_omega0 0
theorem omega0_ne_zero : ω ≠ 0 :=
omega0_pos.ne'
theorem one_lt_omega0 : 1 < ω := by simpa only [Nat.cast_one] using nat_lt_omega0 1
theorem isLimit_omega0 : IsLimit ω := by
rw [isLimit_iff, isSuccPrelimit_iff_succ_lt]
refine ⟨omega0_ne_zero, fun o h => ?_⟩
obtain ⟨n, rfl⟩ := lt_omega0.1 h
exact nat_lt_omega0 (n + 1)
theorem omega0_le {o : Ordinal} : ω ≤ o ↔ ∀ n : ℕ, ↑n ≤ o :=
⟨fun h n => (nat_lt_omega0 _).le.trans h, fun H =>
le_of_forall_lt fun a h => by
let ⟨n, e⟩ := lt_omega0.1 h
rw [e, ← succ_le_iff]; exact H (n + 1)⟩
theorem nat_lt_limit {o} (h : IsLimit o) : ∀ n : ℕ, ↑n < o
| 0 => h.pos
| n + 1 => h.succ_lt (nat_lt_limit h n)
theorem omega0_le_of_isLimit {o} (h : IsLimit o) : ω ≤ o :=
omega0_le.2 fun n => le_of_lt <| nat_lt_limit h n
theorem natCast_add_omega0 (n : ℕ) : n + ω = ω := by
refine le_antisymm (le_of_forall_lt fun a ha ↦ ?_) (le_add_left _ _)
obtain ⟨b, hb', hb⟩ := (lt_add_iff omega0_ne_zero).1 ha
obtain ⟨m, rfl⟩ := lt_omega0.1 hb'
apply hb.trans_lt
exact_mod_cast nat_lt_omega0 (n + m)
theorem one_add_omega0 : 1 + ω = ω :=
mod_cast natCast_add_omega0 1
theorem add_omega0 {a : Ordinal} (h : a < ω) : a + ω = ω := by
obtain ⟨n, rfl⟩ := lt_omega0.1 h
exact natCast_add_omega0 n
@[simp]
theorem natCast_add_of_omega0_le {o} (h : ω ≤ o) (n : ℕ) : n + o = o := by
rw [← Ordinal.add_sub_cancel_of_le h, ← add_assoc, natCast_add_omega0]
@[simp]
theorem one_add_of_omega0_le {o} (h : ω ≤ o) : 1 + o = o :=
mod_cast natCast_add_of_omega0_le h 1
open Ordinal
theorem isLimit_iff_omega0_dvd {a : Ordinal} : IsLimit a ↔ a ≠ 0 ∧ ω ∣ a := by
refine ⟨fun l => ⟨l.ne_zero, ⟨a / ω, le_antisymm ?_ (mul_div_le _ _)⟩⟩, fun h => ?_⟩
· refine (limit_le l).2 fun x hx => le_of_lt ?_
rw [← div_lt omega0_ne_zero, ← succ_le_iff, le_div omega0_ne_zero, mul_succ,
add_le_of_limit isLimit_omega0]
intro b hb
rcases lt_omega0.1 hb with ⟨n, rfl⟩
exact
(add_le_add_right (mul_div_le _ _) _).trans
(lt_sub.1 <| nat_lt_limit (isLimit_sub l hx) _).le
· rcases h with ⟨a0, b, rfl⟩
refine isLimit_mul_left isLimit_omega0 (Ordinal.pos_iff_ne_zero.2 <| mt ?_ a0)
intro e
simp only [e, mul_zero]
@[simp]
theorem natCast_mod_omega0 (n : ℕ) : n % ω = n :=
mod_eq_of_lt (nat_lt_omega0 n)
end Ordinal
namespace Cardinal
open Ordinal
@[simp]
theorem add_one_of_aleph0_le {c} (h : ℵ₀ ≤ c) : c + 1 = c := by
rw [add_comm, ← card_ord c, ← card_one, ← card_add, one_add_of_omega0_le]
rwa [← ord_aleph0, ord_le_ord]
theorem isLimit_ord {c} (co : ℵ₀ ≤ c) : (ord c).IsLimit := by
rw [isLimit_iff, isSuccPrelimit_iff_succ_lt]
refine ⟨fun h => aleph0_ne_zero ?_, fun a => lt_imp_lt_of_le_imp_le fun h => ?_⟩
· rw [← Ordinal.le_zero, ord_le] at h
simpa only [card_zero, nonpos_iff_eq_zero] using co.trans h
· rw [ord_le] at h ⊢
rwa [← @add_one_of_aleph0_le (card a), ← card_succ]
rw [← ord_le, ← le_succ_of_isLimit, ord_le]
· exact co.trans h
· rw [ord_aleph0]
exact Ordinal.isLimit_omega0
theorem noMaxOrder {c} (h : ℵ₀ ≤ c) : NoMaxOrder c.ord.toType :=
toType_noMax_of_succ_lt fun _ ↦ (isLimit_ord h).succ_lt
end Cardinal
| Mathlib/SetTheory/Ordinal/Arithmetic.lean | 2,386 | 2,395 | |
/-
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.Basic
/-!
# Tagged partitions
A tagged (pre)partition is a (pre)partition `π` enriched with a tagged point for each box of
`π`. For simplicity we require that the function `BoxIntegral.TaggedPrepartition.tag` is defined
on all boxes `J : Box ι` but use its values only on boxes of the partition. Given
`π : BoxIntegral.TaggedPrepartition I`, we require that each `BoxIntegral.TaggedPrepartition π J`
belongs to `BoxIntegral.Box.Icc I`. If for every `J ∈ π`, `π.tag J` belongs to `J.Icc`, then `π` is
called a *Henstock* partition. We do not include this assumption into the definition of a tagged
(pre)partition because McShane integral is defined as a limit along tagged partitions without this
requirement.
## Tags
rectangular box, box partition
-/
noncomputable section
open Finset Function ENNReal NNReal Set
namespace BoxIntegral
variable {ι : Type*}
/-- A tagged prepartition is a prepartition enriched with a tagged point for each box of the
prepartition. For simplicity we require that `tag` is defined for all boxes in `ι → ℝ` but
we will use only the values of `tag` on the boxes of the partition. -/
structure TaggedPrepartition (I : Box ι) extends Prepartition I where
/-- Choice of tagged point of each box in this prepartition:
we extend this to a total function, on all boxes in `ι → ℝ`. -/
tag : Box ι → ι → ℝ
/-- Each tagged point belongs to `I` -/
tag_mem_Icc : ∀ J, tag J ∈ Box.Icc I
namespace TaggedPrepartition
variable {I J J₁ J₂ : Box ι} (π : TaggedPrepartition I) {x : ι → ℝ}
instance : Membership (Box ι) (TaggedPrepartition I) :=
⟨fun π J => J ∈ π.boxes⟩
@[simp]
theorem mem_toPrepartition {π : TaggedPrepartition I} : J ∈ π.toPrepartition ↔ J ∈ π := Iff.rfl
@[simp]
theorem mem_mk (π : Prepartition I) (f h) : J ∈ mk π f h ↔ J ∈ π := Iff.rfl
/-- Union of all boxes of a tagged prepartition. -/
def iUnion : Set (ι → ℝ) :=
π.toPrepartition.iUnion
theorem iUnion_def : π.iUnion = ⋃ J ∈ π, ↑J := rfl
@[simp]
theorem iUnion_mk (π : Prepartition I) (f h) : (mk π f h).iUnion = π.iUnion := rfl
@[simp]
theorem iUnion_toPrepartition : π.toPrepartition.iUnion = π.iUnion := rfl
-- Porting note: Previous proof was `:= Set.mem_iUnion₂`
@[simp]
theorem mem_iUnion : x ∈ π.iUnion ↔ ∃ J ∈ π, x ∈ J := by
convert Set.mem_iUnion₂
rw [Box.mem_coe, mem_toPrepartition, exists_prop]
theorem subset_iUnion (h : J ∈ π) : ↑J ⊆ π.iUnion :=
subset_biUnion_of_mem h
theorem iUnion_subset : π.iUnion ⊆ I :=
iUnion₂_subset π.le_of_mem'
/-- A tagged prepartition is a partition if it covers the whole box. -/
def IsPartition :=
π.toPrepartition.IsPartition
theorem isPartition_iff_iUnion_eq : IsPartition π ↔ π.iUnion = I :=
Prepartition.isPartition_iff_iUnion_eq
/-- The tagged partition made of boxes of `π` that satisfy predicate `p`. -/
@[simps! -fullyApplied]
def filter (p : Box ι → Prop) : TaggedPrepartition I :=
⟨π.1.filter p, π.2, π.3⟩
@[simp]
theorem mem_filter {p : Box ι → Prop} : J ∈ π.filter p ↔ J ∈ π ∧ p J := by
classical exact Finset.mem_filter
@[simp]
theorem iUnion_filter_not (π : TaggedPrepartition I) (p : Box ι → Prop) :
(π.filter fun J => ¬p J).iUnion = π.iUnion \ (π.filter p).iUnion :=
π.toPrepartition.iUnion_filter_not p
end TaggedPrepartition
namespace Prepartition
variable {I J : Box ι}
/-- Given a partition `π` of `I : BoxIntegral.Box ι` and a collection of tagged partitions
`πi J` of all boxes `J ∈ π`, returns the tagged partition of `I` into all the boxes of `πi J`
with tags coming from `(πi J).tag`. -/
def biUnionTagged (π : Prepartition I) (πi : ∀ J : Box ι, TaggedPrepartition J) :
TaggedPrepartition I where
toPrepartition := π.biUnion fun J => (πi J).toPrepartition
tag J := (πi (π.biUnionIndex (fun J => (πi J).toPrepartition) J)).tag J
tag_mem_Icc _ := Box.le_iff_Icc.1 (π.biUnionIndex_le _ _) ((πi _).tag_mem_Icc _)
@[simp]
theorem mem_biUnionTagged (π : Prepartition I) {πi : ∀ J, TaggedPrepartition J} :
J ∈ π.biUnionTagged πi ↔ ∃ J' ∈ π, J ∈ πi J' :=
π.mem_biUnion
theorem tag_biUnionTagged (π : Prepartition I) {πi : ∀ J, TaggedPrepartition J} (hJ : J ∈ π) {J'}
(hJ' : J' ∈ πi J) : (π.biUnionTagged πi).tag J' = (πi J).tag J' := by
rw [← π.biUnionIndex_of_mem (πi := fun J => (πi J).toPrepartition) hJ hJ']
rfl
@[simp]
theorem iUnion_biUnionTagged (π : Prepartition I) (πi : ∀ J, TaggedPrepartition J) :
(π.biUnionTagged πi).iUnion = ⋃ J ∈ π, (πi J).iUnion :=
iUnion_biUnion _ _
theorem forall_biUnionTagged (p : (ι → ℝ) → Box ι → Prop) (π : Prepartition I)
(πi : ∀ J, TaggedPrepartition J) :
(∀ J ∈ π.biUnionTagged πi, p ((π.biUnionTagged πi).tag J) J) ↔
∀ J ∈ π, ∀ J' ∈ πi J, p ((πi J).tag J') J' := by
simp only [mem_biUnionTagged]
refine ⟨fun H J hJ J' hJ' => ?_, fun H J' ⟨J, hJ, hJ'⟩ => ?_⟩
· rw [← π.tag_biUnionTagged hJ hJ']
exact H J' ⟨J, hJ, hJ'⟩
· rw [π.tag_biUnionTagged hJ hJ']
exact H J hJ J' hJ'
theorem IsPartition.biUnionTagged {π : Prepartition I} (h : IsPartition π)
{πi : ∀ J, TaggedPrepartition J} (hi : ∀ J ∈ π, (πi J).IsPartition) :
(π.biUnionTagged πi).IsPartition :=
h.biUnion hi
end Prepartition
namespace TaggedPrepartition
variable {I J : Box ι} {π π₁ π₂ : TaggedPrepartition I} {x : ι → ℝ}
/-- Given a tagged partition `π` of `I` and a (not tagged) partition `πi J hJ` of each `J ∈ π`,
returns the tagged partition of `I` into all the boxes of all `πi J hJ`. The tag of a box `J`
is defined to be the `π.tag` of the box of the partition `π` that includes `J`.
Note that usually the result is not a Henstock partition. -/
@[simps -fullyApplied tag]
def biUnionPrepartition (π : TaggedPrepartition I) (πi : ∀ J : Box ι, Prepartition J) :
TaggedPrepartition I where
toPrepartition := π.toPrepartition.biUnion πi
tag J := π.tag (π.toPrepartition.biUnionIndex πi J)
tag_mem_Icc _ := π.tag_mem_Icc _
theorem IsPartition.biUnionPrepartition {π : TaggedPrepartition I} (h : IsPartition π)
{πi : ∀ J, Prepartition J} (hi : ∀ J ∈ π, (πi J).IsPartition) :
(π.biUnionPrepartition πi).IsPartition :=
h.biUnion hi
/-- Given two partitions `π₁` and `π₁`, one of them tagged and the other is not, returns the tagged
partition with `toPrepartition = π₁.toPrepartition ⊓ π₂` and tags coming from `π₁`.
Note that usually the result is not a Henstock partition. -/
def infPrepartition (π : TaggedPrepartition I) (π' : Prepartition I) : TaggedPrepartition I :=
π.biUnionPrepartition fun J => π'.restrict J
@[simp]
theorem infPrepartition_toPrepartition (π : TaggedPrepartition I) (π' : Prepartition I) :
(π.infPrepartition π').toPrepartition = π.toPrepartition ⊓ π' := rfl
theorem mem_infPrepartition_comm :
J ∈ π₁.infPrepartition π₂.toPrepartition ↔ J ∈ π₂.infPrepartition π₁.toPrepartition := by
simp only [← mem_toPrepartition, infPrepartition_toPrepartition, inf_comm]
theorem IsPartition.infPrepartition (h₁ : π₁.IsPartition) {π₂ : Prepartition I}
(h₂ : π₂.IsPartition) : (π₁.infPrepartition π₂).IsPartition :=
h₁.inf h₂
open Metric
/-- A tagged partition is said to be a Henstock partition if for each `J ∈ π`, the tag of `J`
belongs to `J.Icc`. -/
def IsHenstock (π : TaggedPrepartition I) : Prop :=
∀ J ∈ π, π.tag J ∈ Box.Icc J
@[simp]
theorem isHenstock_biUnionTagged {π : Prepartition I} {πi : ∀ J, TaggedPrepartition J} :
IsHenstock (π.biUnionTagged πi) ↔ ∀ J ∈ π, (πi J).IsHenstock :=
π.forall_biUnionTagged (fun x J => x ∈ Box.Icc J) πi
/-- In a Henstock prepartition, there are at most `2 ^ Fintype.card ι` boxes with a given tag. -/
theorem IsHenstock.card_filter_tag_eq_le [Fintype ι] (h : π.IsHenstock) (x : ι → ℝ) :
#{J ∈ π.boxes | π.tag J = x} ≤ 2 ^ Fintype.card ι := by
classical
calc
#{J ∈ π.boxes | π.tag J = x} ≤ #{J ∈ π.boxes | x ∈ Box.Icc J} := by
refine Finset.card_le_card fun J hJ => ?_
rw [Finset.mem_filter] at hJ ⊢; rcases hJ with ⟨hJ, rfl⟩
exact ⟨hJ, h J hJ⟩
_ ≤ 2 ^ Fintype.card ι := π.toPrepartition.card_filter_mem_Icc_le x
/-- A tagged partition `π` is subordinate to `r : (ι → ℝ) → ℝ` if each box `J ∈ π` is included in
the closed ball with center `π.tag J` and radius `r (π.tag J)`. -/
def IsSubordinate [Fintype ι] (π : TaggedPrepartition I) (r : (ι → ℝ) → Ioi (0 : ℝ)) : Prop :=
∀ J ∈ π, Box.Icc J ⊆ closedBall (π.tag J) (r <| π.tag J)
variable {r r₁ r₂ : (ι → ℝ) → Ioi (0 : ℝ)}
@[simp]
theorem isSubordinate_biUnionTagged [Fintype ι] {π : Prepartition I}
{πi : ∀ J, TaggedPrepartition J} :
IsSubordinate (π.biUnionTagged πi) r ↔ ∀ J ∈ π, (πi J).IsSubordinate r :=
π.forall_biUnionTagged (fun x J => Box.Icc J ⊆ closedBall x (r x)) πi
theorem IsSubordinate.biUnionPrepartition [Fintype ι] (h : IsSubordinate π r)
(πi : ∀ J, Prepartition J) : IsSubordinate (π.biUnionPrepartition πi) r :=
fun _ hJ => Subset.trans (Box.le_iff_Icc.1 <| π.toPrepartition.le_biUnionIndex hJ) <|
h _ <| π.toPrepartition.biUnionIndex_mem hJ
theorem IsSubordinate.infPrepartition [Fintype ι] (h : IsSubordinate π r) (π' : Prepartition I) :
IsSubordinate (π.infPrepartition π') r :=
h.biUnionPrepartition _
theorem IsSubordinate.mono' [Fintype ι] {π : TaggedPrepartition I} (hr₁ : π.IsSubordinate r₁)
(h : ∀ J ∈ π, r₁ (π.tag J) ≤ r₂ (π.tag J)) : π.IsSubordinate r₂ :=
fun _ hJ _ hx => closedBall_subset_closedBall (h _ hJ) (hr₁ _ hJ hx)
theorem IsSubordinate.mono [Fintype ι] {π : TaggedPrepartition I} (hr₁ : π.IsSubordinate r₁)
(h : ∀ x ∈ Box.Icc I, r₁ x ≤ r₂ x) : π.IsSubordinate r₂ :=
hr₁.mono' fun J _ => h _ <| π.tag_mem_Icc J
theorem IsSubordinate.diam_le [Fintype ι] {π : TaggedPrepartition I} (h : π.IsSubordinate r)
(hJ : J ∈ π.boxes) : diam (Box.Icc J) ≤ 2 * r (π.tag J) :=
calc
diam (Box.Icc J) ≤ diam (closedBall (π.tag J) (r <| π.tag J)) :=
diam_mono (h J hJ) isBounded_closedBall
_ ≤ 2 * r (π.tag J) := diam_closedBall (le_of_lt (r _).2)
/-- Tagged prepartition with single box and prescribed tag. -/
@[simps! -fullyApplied]
def single (I J : Box ι) (hJ : J ≤ I) (x : ι → ℝ) (h : x ∈ Box.Icc I) : TaggedPrepartition I :=
⟨Prepartition.single I J hJ, fun _ => x, fun _ => h⟩
@[simp]
theorem mem_single {J'} (hJ : J ≤ I) (h : x ∈ Box.Icc I) : J' ∈ single I J hJ x h ↔ J' = J :=
Finset.mem_singleton
instance (I : Box ι) : Inhabited (TaggedPrepartition I) :=
⟨single I I le_rfl I.upper I.upper_mem_Icc⟩
theorem isPartition_single_iff (hJ : J ≤ I) (h : x ∈ Box.Icc I) :
(single I J hJ x h).IsPartition ↔ J = I :=
Prepartition.isPartition_single_iff hJ
theorem isPartition_single (h : x ∈ Box.Icc I) : (single I I le_rfl x h).IsPartition :=
Prepartition.isPartitionTop I
theorem forall_mem_single (p : (ι → ℝ) → Box ι → Prop) (hJ : J ≤ I) (h : x ∈ Box.Icc I) :
(∀ J' ∈ single I J hJ x h, p ((single I J hJ x h).tag J') J') ↔ p x J := by simp
@[simp]
theorem isHenstock_single_iff (hJ : J ≤ I) (h : x ∈ Box.Icc I) :
IsHenstock (single I J hJ x h) ↔ x ∈ Box.Icc J :=
forall_mem_single (fun x J => x ∈ Box.Icc J) hJ h
theorem isHenstock_single (h : x ∈ Box.Icc I) : IsHenstock (single I I le_rfl x h) :=
(isHenstock_single_iff (le_refl I) h).2 h
@[simp]
theorem isSubordinate_single [Fintype ι] (hJ : J ≤ I) (h : x ∈ Box.Icc I) :
IsSubordinate (single I J hJ x h) r ↔ Box.Icc J ⊆ closedBall x (r x) :=
forall_mem_single (fun x J => Box.Icc J ⊆ closedBall x (r x)) hJ h
@[simp]
theorem iUnion_single (hJ : J ≤ I) (h : x ∈ Box.Icc I) : (single I J hJ x h).iUnion = J :=
Prepartition.iUnion_single hJ
open scoped Classical in
/-- Union of two tagged prepartitions with disjoint unions of boxes. -/
def disjUnion (π₁ π₂ : TaggedPrepartition I) (h : Disjoint π₁.iUnion π₂.iUnion) :
TaggedPrepartition I where
toPrepartition := π₁.toPrepartition.disjUnion π₂.toPrepartition h
tag := π₁.boxes.piecewise π₁.tag π₂.tag
tag_mem_Icc J := by
dsimp only [Finset.piecewise]
split_ifs
exacts [π₁.tag_mem_Icc J, π₂.tag_mem_Icc J]
open scoped Classical in
@[simp]
theorem disjUnion_boxes (h : Disjoint π₁.iUnion π₂.iUnion) :
(π₁.disjUnion π₂ h).boxes = π₁.boxes ∪ π₂.boxes := rfl
@[simp]
theorem mem_disjUnion (h : Disjoint π₁.iUnion π₂.iUnion) :
J ∈ π₁.disjUnion π₂ h ↔ J ∈ π₁ ∨ J ∈ π₂ := by
classical exact Finset.mem_union
@[simp]
theorem iUnion_disjUnion (h : Disjoint π₁.iUnion π₂.iUnion) :
(π₁.disjUnion π₂ h).iUnion = π₁.iUnion ∪ π₂.iUnion :=
Prepartition.iUnion_disjUnion h
theorem disjUnion_tag_of_mem_left (h : Disjoint π₁.iUnion π₂.iUnion) (hJ : J ∈ π₁) :
(π₁.disjUnion π₂ h).tag J = π₁.tag J :=
dif_pos hJ
theorem disjUnion_tag_of_mem_right (h : Disjoint π₁.iUnion π₂.iUnion) (hJ : J ∈ π₂) :
(π₁.disjUnion π₂ h).tag J = π₂.tag J :=
dif_neg fun h₁ => h.le_bot ⟨π₁.subset_iUnion h₁ J.upper_mem, π₂.subset_iUnion hJ J.upper_mem⟩
theorem IsSubordinate.disjUnion [Fintype ι] (h₁ : IsSubordinate π₁ r) (h₂ : IsSubordinate π₂ r)
(h : Disjoint π₁.iUnion π₂.iUnion) : IsSubordinate (π₁.disjUnion π₂ h) r := by
classical
refine fun J hJ => (Finset.mem_union.1 hJ).elim (fun hJ => ?_) fun hJ => ?_
· rw [disjUnion_tag_of_mem_left _ hJ]
exact h₁ _ hJ
· rw [disjUnion_tag_of_mem_right _ hJ]
exact h₂ _ hJ
theorem IsHenstock.disjUnion (h₁ : IsHenstock π₁) (h₂ : IsHenstock π₂)
(h : Disjoint π₁.iUnion π₂.iUnion) : IsHenstock (π₁.disjUnion π₂ h) := by
classical
refine fun J hJ => (Finset.mem_union.1 hJ).elim (fun hJ => ?_) fun hJ => ?_
· rw [disjUnion_tag_of_mem_left _ hJ]
exact h₁ _ hJ
· rw [disjUnion_tag_of_mem_right _ hJ]
exact h₂ _ hJ
/-- If `I ≤ J`, then every tagged prepartition of `I` is a tagged prepartition of `J`. -/
def embedBox (I J : Box ι) (h : I ≤ J) : TaggedPrepartition I ↪ TaggedPrepartition J where
toFun π :=
{ π with
le_of_mem' := fun J' hJ' => (π.le_of_mem' J' hJ').trans h
tag_mem_Icc := fun J => Box.le_iff_Icc.1 h (π.tag_mem_Icc J) }
inj' := by
rintro ⟨⟨b₁, h₁le, h₁d⟩, t₁, ht₁⟩ ⟨⟨b₂, h₂le, h₂d⟩, t₂, ht₂⟩ H
simpa using H
section Distortion
variable [Fintype ι] (π)
open Finset
/-- The distortion of a tagged prepartition is the maximum of distortions of its boxes. -/
def distortion : ℝ≥0 :=
π.toPrepartition.distortion
theorem distortion_le_of_mem (h : J ∈ π) : J.distortion ≤ π.distortion :=
le_sup h
theorem distortion_le_iff {c : ℝ≥0} : π.distortion ≤ c ↔ ∀ J ∈ π, Box.distortion J ≤ c :=
Finset.sup_le_iff
@[simp]
theorem _root_.BoxIntegral.Prepartition.distortion_biUnionTagged (π : Prepartition I)
(πi : ∀ J, TaggedPrepartition J) :
(π.biUnionTagged πi).distortion = π.boxes.sup fun J => (πi J).distortion := by
classical exact sup_biUnion _ _
@[simp]
theorem distortion_biUnionPrepartition (π : TaggedPrepartition I) (πi : ∀ J, Prepartition J) :
(π.biUnionPrepartition πi).distortion = π.boxes.sup fun J => (πi J).distortion := by
classical exact sup_biUnion _ _
@[simp]
theorem distortion_disjUnion (h : Disjoint π₁.iUnion π₂.iUnion) :
(π₁.disjUnion π₂ h).distortion = max π₁.distortion π₂.distortion := by
classical exact sup_union
theorem distortion_of_const {c} (h₁ : π.boxes.Nonempty) (h₂ : ∀ J ∈ π, Box.distortion J = c) :
| π.distortion = c :=
(sup_congr rfl h₂).trans (sup_const h₁ _)
@[simp]
theorem distortion_single (hJ : J ≤ I) (h : x ∈ Box.Icc I) :
distortion (single I J hJ x h) = J.distortion :=
sup_singleton
| Mathlib/Analysis/BoxIntegral/Partition/Tagged.lean | 384 | 390 |
/-
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') :=
| Mathlib/Data/Finset/NAry.lean | 404 | 409 |
/-
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.Complex.Log
/-! # Power function on `ℂ`
We construct the power functions `x ^ y`, where `x` and `y` are complex numbers.
-/
open Real Topology Filter ComplexConjugate Finset Set
namespace Complex
/-- The complex power function `x ^ y`, given by `x ^ y = exp(y log x)` (where `log` is the
principal determination of the logarithm), unless `x = 0` where one sets `0 ^ 0 = 1` and
`0 ^ y = 0` for `y ≠ 0`. -/
noncomputable def cpow (x y : ℂ) : ℂ :=
if x = 0 then if y = 0 then 1 else 0 else exp (log x * y)
noncomputable instance : Pow ℂ ℂ :=
⟨cpow⟩
@[simp]
theorem cpow_eq_pow (x y : ℂ) : cpow x y = x ^ y :=
rfl
theorem cpow_def (x y : ℂ) : x ^ y = if x = 0 then if y = 0 then 1 else 0 else exp (log x * y) :=
rfl
theorem cpow_def_of_ne_zero {x : ℂ} (hx : x ≠ 0) (y : ℂ) : x ^ y = exp (log x * y) :=
if_neg hx
@[simp]
theorem cpow_zero (x : ℂ) : x ^ (0 : ℂ) = 1 := by simp [cpow_def]
@[simp]
theorem cpow_eq_zero_iff (x y : ℂ) : x ^ y = 0 ↔ x = 0 ∧ y ≠ 0 := by
simp only [cpow_def]
split_ifs <;> simp [*, exp_ne_zero]
theorem cpow_ne_zero_iff {x y : ℂ} :
x ^ y ≠ 0 ↔ x ≠ 0 ∨ y = 0 := by
rw [ne_eq, cpow_eq_zero_iff, not_and_or, ne_eq, not_not]
theorem cpow_ne_zero_iff_of_exponent_ne_zero {x y : ℂ} (hy : y ≠ 0) :
x ^ y ≠ 0 ↔ x ≠ 0 := by simp [hy]
@[simp]
theorem zero_cpow {x : ℂ} (h : x ≠ 0) : (0 : ℂ) ^ x = 0 := by simp [cpow_def, *]
theorem zero_cpow_eq_iff {x : ℂ} {a : ℂ} : (0 : ℂ) ^ x = a ↔ x ≠ 0 ∧ a = 0 ∨ x = 0 ∧ a = 1 := by
constructor
· intro hyp
simp only [cpow_def, eq_self_iff_true, if_true] at hyp
by_cases h : x = 0
· subst h
simp only [if_true, eq_self_iff_true] at hyp
right
exact ⟨rfl, hyp.symm⟩
· rw [if_neg h] at hyp
left
exact ⟨h, hyp.symm⟩
· rintro (⟨h, rfl⟩ | ⟨rfl, rfl⟩)
· exact zero_cpow h
· exact cpow_zero _
theorem eq_zero_cpow_iff {x : ℂ} {a : ℂ} : a = (0 : ℂ) ^ x ↔ x ≠ 0 ∧ a = 0 ∨ x = 0 ∧ a = 1 := by
rw [← zero_cpow_eq_iff, eq_comm]
@[simp]
theorem cpow_one (x : ℂ) : x ^ (1 : ℂ) = x :=
if hx : x = 0 then by simp [hx, cpow_def]
else by rw [cpow_def, if_neg (one_ne_zero : (1 : ℂ) ≠ 0), if_neg hx, mul_one, exp_log hx]
@[simp]
theorem one_cpow (x : ℂ) : (1 : ℂ) ^ x = 1 := by
rw [cpow_def]
split_ifs <;> simp_all [one_ne_zero]
theorem cpow_add {x : ℂ} (y z : ℂ) (hx : x ≠ 0) : x ^ (y + z) = x ^ y * x ^ z := by
simp only [cpow_def, ite_mul, boole_mul, mul_ite, mul_boole]
simp_all [exp_add, mul_add]
theorem cpow_mul {x y : ℂ} (z : ℂ) (h₁ : -π < (log x * y).im) (h₂ : (log x * y).im ≤ π) :
x ^ (y * z) = (x ^ y) ^ z := by
simp only [cpow_def]
split_ifs <;> simp_all [exp_ne_zero, log_exp h₁ h₂, mul_assoc]
theorem cpow_neg (x y : ℂ) : x ^ (-y) = (x ^ y)⁻¹ := by
simp only [cpow_def, neg_eq_zero, mul_neg]
split_ifs <;> simp [exp_neg]
theorem cpow_sub {x : ℂ} (y z : ℂ) (hx : x ≠ 0) : x ^ (y - z) = x ^ y / x ^ z := by
rw [sub_eq_add_neg, cpow_add _ _ hx, cpow_neg, div_eq_mul_inv]
theorem cpow_neg_one (x : ℂ) : x ^ (-1 : ℂ) = x⁻¹ := by simpa using cpow_neg x 1
/-- See also `Complex.cpow_int_mul'`. -/
lemma cpow_int_mul (x : ℂ) (n : ℤ) (y : ℂ) : x ^ (n * y) = (x ^ y) ^ n := by
rcases eq_or_ne x 0 with rfl | hx
· rcases eq_or_ne n 0 with rfl | hn
· simp
· rcases eq_or_ne y 0 with rfl | hy <;> simp [*, zero_zpow]
· rw [cpow_def_of_ne_zero hx, cpow_def_of_ne_zero hx, mul_left_comm, exp_int_mul]
lemma cpow_mul_int (x y : ℂ) (n : ℤ) : x ^ (y * n) = (x ^ y) ^ n := by rw [mul_comm, cpow_int_mul]
lemma cpow_nat_mul (x : ℂ) (n : ℕ) (y : ℂ) : x ^ (n * y) = (x ^ y) ^ n :=
mod_cast cpow_int_mul x n y
lemma cpow_ofNat_mul (x : ℂ) (n : ℕ) [n.AtLeastTwo] (y : ℂ) :
x ^ (ofNat(n) * y) = (x ^ y) ^ ofNat(n) :=
cpow_nat_mul x n y
lemma cpow_mul_nat (x y : ℂ) (n : ℕ) : x ^ (y * n) = (x ^ y) ^ n := by
rw [mul_comm, cpow_nat_mul]
lemma cpow_mul_ofNat (x y : ℂ) (n : ℕ) [n.AtLeastTwo] :
x ^ (y * ofNat(n)) = (x ^ y) ^ ofNat(n) :=
cpow_mul_nat x y n
@[simp, norm_cast]
theorem cpow_natCast (x : ℂ) (n : ℕ) : x ^ (n : ℂ) = x ^ n := by simpa using cpow_nat_mul x n 1
@[simp]
lemma cpow_ofNat (x : ℂ) (n : ℕ) [n.AtLeastTwo] :
x ^ (ofNat(n) : ℂ) = x ^ ofNat(n) :=
cpow_natCast x n
theorem cpow_two (x : ℂ) : x ^ (2 : ℂ) = x ^ (2 : ℕ) := cpow_ofNat x 2
@[simp, norm_cast]
theorem cpow_intCast (x : ℂ) (n : ℤ) : x ^ (n : ℂ) = x ^ n := by simpa using cpow_int_mul x n 1
@[simp]
theorem cpow_nat_inv_pow (x : ℂ) {n : ℕ} (hn : n ≠ 0) : (x ^ (n⁻¹ : ℂ)) ^ n = x := by
rw [← cpow_nat_mul, mul_inv_cancel₀, cpow_one]
assumption_mod_cast
@[simp]
lemma cpow_ofNat_inv_pow (x : ℂ) (n : ℕ) [n.AtLeastTwo] :
(x ^ ((ofNat(n) : ℂ)⁻¹)) ^ (ofNat(n) : ℕ) = x :=
cpow_nat_inv_pow _ (NeZero.ne n)
/-- A version of `Complex.cpow_int_mul` with RHS that matches `Complex.cpow_mul`.
The assumptions on the arguments are needed
because the equality fails, e.g., for `x = -I`, `n = 2`, `y = 1/2`. -/
lemma cpow_int_mul' {x : ℂ} {n : ℤ} (hlt : -π < n * x.arg) (hle : n * x.arg ≤ π) (y : ℂ) :
x ^ (n * y) = (x ^ n) ^ y := by
rw [mul_comm] at hlt hle
rw [cpow_mul, cpow_intCast] <;> simpa [log_im]
/-- A version of `Complex.cpow_nat_mul` with RHS that matches `Complex.cpow_mul`.
The assumptions on the arguments are needed
because the equality fails, e.g., for `x = -I`, `n = 2`, `y = 1/2`. -/
lemma cpow_nat_mul' {x : ℂ} {n : ℕ} (hlt : -π < n * x.arg) (hle : n * x.arg ≤ π) (y : ℂ) :
x ^ (n * y) = (x ^ n) ^ y :=
cpow_int_mul' hlt hle y
lemma cpow_ofNat_mul' {x : ℂ} {n : ℕ} [n.AtLeastTwo] (hlt : -π < OfNat.ofNat n * x.arg)
(hle : OfNat.ofNat n * x.arg ≤ π) (y : ℂ) :
x ^ (OfNat.ofNat n * y) = (x ^ ofNat(n)) ^ y :=
cpow_nat_mul' hlt hle y
lemma pow_cpow_nat_inv {x : ℂ} {n : ℕ} (h₀ : n ≠ 0) (hlt : -(π / n) < x.arg) (hle : x.arg ≤ π / n) :
(x ^ n) ^ (n⁻¹ : ℂ) = x := by
rw [← cpow_nat_mul', mul_inv_cancel₀ (Nat.cast_ne_zero.2 h₀), cpow_one]
· rwa [← div_lt_iff₀' (Nat.cast_pos.2 h₀.bot_lt), neg_div]
· rwa [← le_div_iff₀' (Nat.cast_pos.2 h₀.bot_lt)]
lemma pow_cpow_ofNat_inv {x : ℂ} {n : ℕ} [n.AtLeastTwo] (hlt : -(π / OfNat.ofNat n) < x.arg)
(hle : x.arg ≤ π / OfNat.ofNat n) :
(x ^ ofNat(n)) ^ ((OfNat.ofNat n : ℂ)⁻¹) = x :=
pow_cpow_nat_inv (NeZero.ne n) hlt hle
/-- See also `Complex.pow_cpow_ofNat_inv` for a version that also works for `x * I`, `0 ≤ x`. -/
lemma sq_cpow_two_inv {x : ℂ} (hx : 0 < x.re) : (x ^ (2 : ℕ)) ^ (2⁻¹ : ℂ) = x :=
pow_cpow_ofNat_inv (neg_pi_div_two_lt_arg_iff.2 <| .inl hx)
(arg_le_pi_div_two_iff.2 <| .inl hx.le)
theorem mul_cpow_ofReal_nonneg {a b : ℝ} (ha : 0 ≤ a) (hb : 0 ≤ b) (r : ℂ) :
((a : ℂ) * (b : ℂ)) ^ r = (a : ℂ) ^ r * (b : ℂ) ^ r := by
rcases eq_or_ne r 0 with (rfl | hr)
· simp only [cpow_zero, mul_one]
rcases eq_or_lt_of_le ha with (rfl | ha')
· rw [ofReal_zero, zero_mul, zero_cpow hr, zero_mul]
rcases eq_or_lt_of_le hb with (rfl | hb')
· rw [ofReal_zero, mul_zero, zero_cpow hr, mul_zero]
have ha'' : (a : ℂ) ≠ 0 := ofReal_ne_zero.mpr ha'.ne'
have hb'' : (b : ℂ) ≠ 0 := ofReal_ne_zero.mpr hb'.ne'
rw [cpow_def_of_ne_zero (mul_ne_zero ha'' hb''), log_ofReal_mul ha' hb'', ofReal_log ha,
add_mul, exp_add, ← cpow_def_of_ne_zero ha'', ← cpow_def_of_ne_zero hb'']
lemma natCast_mul_natCast_cpow (m n : ℕ) (s : ℂ) : (m * n : ℂ) ^ s = m ^ s * n ^ s :=
ofReal_natCast m ▸ ofReal_natCast n ▸ mul_cpow_ofReal_nonneg m.cast_nonneg n.cast_nonneg s
lemma natCast_cpow_natCast_mul (n m : ℕ) (z : ℂ) : (n : ℂ) ^ (m * z) = ((n : ℂ) ^ m) ^ z := by
refine cpow_nat_mul' (x := n) (n := m) ?_ ?_ z
· simp only [natCast_arg, mul_zero, Left.neg_neg_iff, pi_pos]
· simp only [natCast_arg, mul_zero, pi_pos.le]
theorem inv_cpow_eq_ite (x : ℂ) (n : ℂ) :
x⁻¹ ^ n = if x.arg = π then conj (x ^ conj n)⁻¹ else (x ^ n)⁻¹ := by
simp_rw [Complex.cpow_def, log_inv_eq_ite, inv_eq_zero, map_eq_zero, ite_mul, neg_mul,
RCLike.conj_inv, apply_ite conj, apply_ite exp, apply_ite Inv.inv, map_zero, map_one, exp_neg,
inv_one, inv_zero, ← exp_conj, map_mul, conj_conj]
split_ifs with hx hn ha ha <;> rfl
theorem inv_cpow (x : ℂ) (n : ℂ) (hx : x.arg ≠ π) : x⁻¹ ^ n = (x ^ n)⁻¹ := by
rw [inv_cpow_eq_ite, if_neg hx]
/-- `Complex.inv_cpow_eq_ite` with the `ite` on the other side. -/
theorem inv_cpow_eq_ite' (x : ℂ) (n : ℂ) :
(x ^ n)⁻¹ = if x.arg = π then conj (x⁻¹ ^ conj n) else x⁻¹ ^ n := by
rw [inv_cpow_eq_ite, apply_ite conj, conj_conj, conj_conj]
split_ifs with h
· rfl
· rw [inv_cpow _ _ h]
theorem conj_cpow_eq_ite (x : ℂ) (n : ℂ) :
conj x ^ n = if x.arg = π then x ^ n else conj (x ^ conj n) := by
simp_rw [cpow_def, map_eq_zero, apply_ite conj, map_one, map_zero, ← exp_conj, map_mul, conj_conj,
log_conj_eq_ite]
split_ifs with hcx hn hx <;> rfl
theorem conj_cpow (x : ℂ) (n : ℂ) (hx : x.arg ≠ π) : conj x ^ n = conj (x ^ conj n) := by
rw [conj_cpow_eq_ite, if_neg hx]
| theorem cpow_conj (x : ℂ) (n : ℂ) (hx : x.arg ≠ π) : x ^ conj n = conj (conj x ^ n) := by
rw [conj_cpow _ _ hx, conj_conj]
lemma natCast_add_one_cpow_ne_zero (n : ℕ) (z : ℂ) : (n + 1 : ℂ) ^ z ≠ 0 :=
mt (cpow_eq_zero_iff ..).mp fun H ↦ by norm_cast at H; exact H.1
| Mathlib/Analysis/SpecialFunctions/Pow/Complex.lean | 235 | 240 |
/-
Copyright (c) 2021 Oliver Nash. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Oliver Nash
-/
import Mathlib.Order.Atoms
import Mathlib.Order.OrderIsoNat
import Mathlib.Order.RelIso.Set
import Mathlib.Order.SupClosed
import Mathlib.Order.SupIndep
import Mathlib.Order.Zorn
import Mathlib.Data.Finset.Order
import Mathlib.Order.Interval.Set.OrderIso
import Mathlib.Data.Finite.Set
import Mathlib.Tactic.TFAE
/-!
# Compactness properties for complete lattices
For complete lattices, there are numerous equivalent ways to express the fact that the relation `>`
is well-founded. In this file we define three especially-useful characterisations and provide
proofs that they are indeed equivalent to well-foundedness.
## Main definitions
* `CompleteLattice.IsSupClosedCompact`
* `CompleteLattice.IsSupFiniteCompact`
* `CompleteLattice.IsCompactElement`
* `IsCompactlyGenerated`
## Main results
The main result is that the following four conditions are equivalent for a complete lattice:
* `well_founded (>)`
* `CompleteLattice.IsSupClosedCompact`
* `CompleteLattice.IsSupFiniteCompact`
* `∀ k, CompleteLattice.IsCompactElement k`
This is demonstrated by means of the following four lemmas:
* `CompleteLattice.WellFounded.isSupFiniteCompact`
* `CompleteLattice.IsSupFiniteCompact.isSupClosedCompact`
* `CompleteLattice.IsSupClosedCompact.wellFounded`
* `CompleteLattice.isSupFiniteCompact_iff_all_elements_compact`
We also show well-founded lattices are compactly generated
(`CompleteLattice.isCompactlyGenerated_of_wellFounded`).
## References
- [G. Călugăreanu, *Lattice Concepts of Module Theory*][calugareanu]
## Tags
complete lattice, well-founded, compact
-/
open Set
variable {ι : Sort*} {α : Type*} [CompleteLattice α] {f : ι → α}
namespace CompleteLattice
variable (α)
/-- A compactness property for a complete lattice is that any `sup`-closed non-empty subset
contains its `sSup`. -/
def IsSupClosedCompact : Prop :=
∀ (s : Set α) (_ : s.Nonempty), SupClosed s → sSup s ∈ s
/-- A compactness property for a complete lattice is that any subset has a finite subset with the
same `sSup`. -/
def IsSupFiniteCompact : Prop :=
∀ s : Set α, ∃ t : Finset α, ↑t ⊆ s ∧ sSup s = t.sup id
/-- An element `k` of a complete lattice is said to be compact if any set with `sSup`
above `k` has a finite subset with `sSup` above `k`. Such an element is also called
"finite" or "S-compact". -/
def IsCompactElement {α : Type*} [CompleteLattice α] (k : α) :=
∀ s : Set α, k ≤ sSup s → ∃ t : Finset α, ↑t ⊆ s ∧ k ≤ t.sup id
theorem isCompactElement_iff.{u} {α : Type u} [CompleteLattice α] (k : α) :
CompleteLattice.IsCompactElement k ↔
∀ (ι : Type u) (s : ι → α), k ≤ iSup s → ∃ t : Finset ι, k ≤ t.sup s := by
classical
constructor
· intro H ι s hs
obtain ⟨t, ht, ht'⟩ := H (Set.range s) hs
have : ∀ x : t, ∃ i, s i = x := fun x => ht x.prop
choose f hf using this
refine ⟨Finset.univ.image f, ht'.trans ?_⟩
rw [Finset.sup_le_iff]
intro b hb
rw [← show s (f ⟨b, hb⟩) = id b from hf _]
exact Finset.le_sup (Finset.mem_image_of_mem f <| Finset.mem_univ (Subtype.mk b hb))
· intro H s hs
obtain ⟨t, ht⟩ :=
H s Subtype.val
(by
delta iSup
rwa [Subtype.range_coe])
refine ⟨t.image Subtype.val, by simp, ht.trans ?_⟩
rw [Finset.sup_le_iff]
exact fun x hx => @Finset.le_sup _ _ _ _ _ id _ (Finset.mem_image_of_mem Subtype.val hx)
/-- An element `k` is compact if and only if any directed set with `sSup` above
`k` already got above `k` at some point in the set. -/
theorem isCompactElement_iff_le_of_directed_sSup_le (k : α) :
IsCompactElement k ↔
∀ s : Set α, s.Nonempty → DirectedOn (· ≤ ·) s → k ≤ sSup s → ∃ x : α, x ∈ s ∧ k ≤ x := by
classical
constructor
· intro hk s hne hdir hsup
obtain ⟨t, ht⟩ := hk s hsup
-- certainly every element of t is below something in s, since ↑t ⊆ s.
have t_below_s : ∀ x ∈ t, ∃ y ∈ s, x ≤ y := fun x hxt => ⟨x, ht.left hxt, le_rfl⟩
obtain ⟨x, ⟨hxs, hsupx⟩⟩ := Finset.sup_le_of_le_directed s hne hdir t t_below_s
exact ⟨x, ⟨hxs, le_trans ht.right hsupx⟩⟩
· intro hk s hsup
-- Consider the set of finite joins of elements of the (plain) set s.
let S : Set α := { x | ∃ t : Finset α, ↑t ⊆ s ∧ x = t.sup id }
-- S is directed, nonempty, and still has sup above k.
have dir_US : DirectedOn (· ≤ ·) S := by
rintro x ⟨c, hc⟩ y ⟨d, hd⟩
use x ⊔ y
constructor
· use c ∪ d
constructor
· simp only [hc.left, hd.left, Set.union_subset_iff, Finset.coe_union, and_self_iff]
· simp only [hc.right, hd.right, Finset.sup_union]
simp only [and_self_iff, le_sup_left, le_sup_right]
have sup_S : sSup s ≤ sSup S := by
apply sSup_le_sSup
intro x hx
use {x}
simpa only [and_true, id, Finset.coe_singleton, eq_self_iff_true,
Finset.sup_singleton, Set.singleton_subset_iff]
have Sne : S.Nonempty := by
suffices ⊥ ∈ S from Set.nonempty_of_mem this
use ∅
simp only [Set.empty_subset, Finset.coe_empty, Finset.sup_empty, eq_self_iff_true,
and_self_iff]
-- Now apply the defn of compact and finish.
obtain ⟨j, ⟨hjS, hjk⟩⟩ := hk S Sne dir_US (le_trans hsup sup_S)
obtain ⟨t, ⟨htS, htsup⟩⟩ := hjS
use t
exact ⟨htS, by rwa [← htsup]⟩
theorem IsCompactElement.exists_finset_of_le_iSup {k : α} (hk : IsCompactElement k) {ι : Type*}
(f : ι → α) (h : k ≤ ⨆ i, f i) : ∃ s : Finset ι, k ≤ ⨆ i ∈ s, f i := by
classical
let g : Finset ι → α := fun s => ⨆ i ∈ s, f i
have h1 : DirectedOn (· ≤ ·) (Set.range g) := by
rintro - ⟨s, rfl⟩ - ⟨t, rfl⟩
exact
⟨g (s ∪ t), ⟨s ∪ t, rfl⟩, iSup_le_iSup_of_subset Finset.subset_union_left,
iSup_le_iSup_of_subset Finset.subset_union_right⟩
have h2 : k ≤ sSup (Set.range g) :=
h.trans
(iSup_le fun i =>
le_sSup_of_le ⟨{i}, rfl⟩
(le_iSup_of_le i (le_iSup_of_le (Finset.mem_singleton_self i) le_rfl)))
obtain ⟨-, ⟨s, rfl⟩, hs⟩ :=
(isCompactElement_iff_le_of_directed_sSup_le α k).mp hk (Set.range g) (Set.range_nonempty g)
h1 h2
exact ⟨s, hs⟩
/-- A compact element `k` has the property that any directed set lying strictly below `k` has
its `sSup` strictly below `k`. -/
theorem IsCompactElement.directed_sSup_lt_of_lt {α : Type*} [CompleteLattice α] {k : α}
(hk : IsCompactElement k) {s : Set α} (hemp : s.Nonempty) (hdir : DirectedOn (· ≤ ·) s)
(hbelow : ∀ x ∈ s, x < k) : sSup s < k := by
rw [isCompactElement_iff_le_of_directed_sSup_le] at hk
by_contra h
have sSup' : sSup s ≤ k := sSup_le s k fun s hs => (hbelow s hs).le
replace sSup : sSup s = k := eq_iff_le_not_lt.mpr ⟨sSup', h⟩
obtain ⟨x, hxs, hkx⟩ := hk s hemp hdir sSup.symm.le
obtain hxk := hbelow x hxs
exact hxk.ne (hxk.le.antisymm hkx)
theorem isCompactElement_finsetSup {α β : Type*} [CompleteLattice α] {f : β → α} (s : Finset β)
(h : ∀ x ∈ s, IsCompactElement (f x)) : IsCompactElement (s.sup f) := by
classical
rw [isCompactElement_iff_le_of_directed_sSup_le]
intro d hemp hdir hsup
rw [← Function.id_comp f]
rw [← Finset.sup_image]
apply Finset.sup_le_of_le_directed d hemp hdir
rintro x hx
obtain ⟨p, ⟨hps, rfl⟩⟩ := Finset.mem_image.mp hx
specialize h p hps
rw [isCompactElement_iff_le_of_directed_sSup_le] at h
specialize h d hemp hdir (le_trans (Finset.le_sup hps) hsup)
simpa only [exists_prop]
theorem WellFoundedGT.isSupFiniteCompact [WellFoundedGT α] :
IsSupFiniteCompact α := fun s => by
let S := { x | ∃ t : Finset α, ↑t ⊆ s ∧ t.sup id = x }
obtain ⟨m, ⟨t, ⟨ht₁, rfl⟩⟩, hm⟩ := wellFounded_gt.has_min S ⟨⊥, ∅, by simp⟩
refine ⟨t, ht₁, (sSup_le _ _ fun y hy => ?_).antisymm ?_⟩
· classical
rw [eq_of_le_of_not_lt (Finset.sup_mono (t.subset_insert y))
(hm _ ⟨insert y t, by simp [Set.insert_subset_iff, hy, ht₁]⟩)]
simp
· rw [Finset.sup_id_eq_sSup]
exact sSup_le_sSup ht₁
theorem IsSupFiniteCompact.isSupClosedCompact (h : IsSupFiniteCompact α) :
IsSupClosedCompact α := by
intro s hne hsc; obtain ⟨t, ht₁, ht₂⟩ := h s; clear h
rcases t.eq_empty_or_nonempty with h | h
· subst h
rw [Finset.sup_empty] at ht₂
rw [ht₂]
simp [eq_singleton_bot_of_sSup_eq_bot_of_nonempty ht₂ hne]
· rw [ht₂]
exact hsc.finsetSup_mem h ht₁
theorem IsSupClosedCompact.wellFoundedGT (h : IsSupClosedCompact α) :
WellFoundedGT α where
wf := by
refine RelEmbedding.wellFounded_iff_no_descending_seq.mpr ⟨fun a => ?_⟩
suffices sSup (Set.range a) ∈ Set.range a by
obtain ⟨n, hn⟩ := Set.mem_range.mp this
have h' : sSup (Set.range a) < a (n + 1) := by
change _ > _
simp [← hn, a.map_rel_iff]
apply lt_irrefl (a (n + 1))
apply lt_of_le_of_lt _ h'
apply le_sSup
apply Set.mem_range_self
apply h (Set.range a)
· use a 37
apply Set.mem_range_self
· rintro x ⟨m, hm⟩ y ⟨n, hn⟩
use m ⊔ n
rw [← hm, ← hn]
apply RelHomClass.map_sup a
theorem isSupFiniteCompact_iff_all_elements_compact :
IsSupFiniteCompact α ↔ ∀ k : α, IsCompactElement k := by
refine ⟨fun h k s hs => ?_, fun h s => ?_⟩
· obtain ⟨t, ⟨hts, htsup⟩⟩ := h s
use t, hts
rwa [← htsup]
· obtain ⟨t, ⟨hts, htsup⟩⟩ := h (sSup s) s (by rfl)
have : sSup s = t.sup id := by
suffices t.sup id ≤ sSup s by apply le_antisymm <;> assumption
simp only [id, Finset.sup_le_iff]
intro x hx
exact le_sSup _ _ (hts hx)
exact ⟨t, hts, this⟩
open List in
theorem wellFoundedGT_characterisations : List.TFAE
[WellFoundedGT α, IsSupFiniteCompact α, IsSupClosedCompact α, ∀ k : α, IsCompactElement k] := by
tfae_have 1 → 2 := @WellFoundedGT.isSupFiniteCompact α _
tfae_have 2 → 3 := IsSupFiniteCompact.isSupClosedCompact α
tfae_have 3 → 1 := IsSupClosedCompact.wellFoundedGT α
tfae_have 2 ↔ 4 := isSupFiniteCompact_iff_all_elements_compact α
tfae_finish
theorem wellFoundedGT_iff_isSupFiniteCompact :
WellFoundedGT α ↔ IsSupFiniteCompact α :=
(wellFoundedGT_characterisations α).out 0 1
theorem isSupFiniteCompact_iff_isSupClosedCompact : IsSupFiniteCompact α ↔ IsSupClosedCompact α :=
(wellFoundedGT_characterisations α).out 1 2
theorem isSupClosedCompact_iff_wellFoundedGT :
IsSupClosedCompact α ↔ WellFoundedGT α :=
(wellFoundedGT_characterisations α).out 2 0
alias ⟨_, IsSupFiniteCompact.wellFoundedGT⟩ := wellFoundedGT_iff_isSupFiniteCompact
alias ⟨_, IsSupClosedCompact.isSupFiniteCompact⟩ := isSupFiniteCompact_iff_isSupClosedCompact
alias ⟨_, WellFoundedGT.isSupClosedCompact⟩ := isSupClosedCompact_iff_wellFoundedGT
end CompleteLattice
theorem WellFoundedGT.finite_of_sSupIndep [WellFoundedGT α] {s : Set α}
(hs : sSupIndep s) : s.Finite := by
classical
refine Set.not_infinite.mp fun contra => ?_
obtain ⟨t, ht₁, ht₂⟩ := CompleteLattice.WellFoundedGT.isSupFiniteCompact α s
replace contra : ∃ x : α, x ∈ s ∧ x ≠ ⊥ ∧ x ∉ t := by
have : (s \ (insert ⊥ t : Finset α)).Infinite := contra.diff (Finset.finite_toSet _)
obtain ⟨x, hx₁, hx₂⟩ := this.nonempty
exact ⟨x, hx₁, by simpa [not_or] using hx₂⟩
obtain ⟨x, hx₀, hx₁, hx₂⟩ := contra
replace hs : x ⊓ sSup s = ⊥ := by
have := hs.mono (by simp [ht₁, hx₀, -Set.union_singleton] : ↑t ∪ {x} ≤ s) (by simp : x ∈ _)
simpa [Disjoint, hx₂, ← t.sup_id_eq_sSup, ← ht₂] using this.eq_bot
apply hx₁
rw [← hs, eq_comm, inf_eq_left]
exact le_sSup hx₀
@[deprecated (since := "2024-11-24")]
alias CompleteLattice.WellFoundedGT.finite_of_setIndependent := WellFoundedGT.finite_of_sSupIndep
theorem WellFoundedGT.finite_ne_bot_of_iSupIndep [WellFoundedGT α]
{ι : Type*} {t : ι → α} (ht : iSupIndep t) : Set.Finite {i | t i ≠ ⊥} := by
refine Finite.of_finite_image (Finite.subset ?_ (image_subset_range t _)) ht.injOn
exact WellFoundedGT.finite_of_sSupIndep ht.sSupIndep_range
@[deprecated (since := "2024-11-24")]
alias CompleteLattice.WellFoundedGT.finite_ne_bot_of_independent :=
WellFoundedGT.finite_ne_bot_of_iSupIndep
theorem WellFoundedGT.finite_of_iSupIndep [WellFoundedGT α] {ι : Type*}
{t : ι → α} (ht : iSupIndep t) (h_ne_bot : ∀ i, t i ≠ ⊥) : Finite ι :=
haveI := (WellFoundedGT.finite_of_sSupIndep ht.sSupIndep_range).to_subtype
Finite.of_injective_finite_range (ht.injective h_ne_bot)
@[deprecated (since := "2024-11-24")]
alias CompleteLattice.WellFoundedGT.finite_of_independent := WellFoundedGT.finite_of_iSupIndep
theorem WellFoundedLT.finite_of_sSupIndep [WellFoundedLT α] {s : Set α}
(hs : sSupIndep s) : s.Finite := by
by_contra inf
let e := (Infinite.diff inf <| finite_singleton ⊥).to_subtype.natEmbedding
let a n := ⨆ i ≥ n, (e i).1
have sup_le n : (e n).1 ⊔ a (n + 1) ≤ a n := sup_le_iff.mpr ⟨le_iSup₂_of_le n le_rfl le_rfl,
iSup₂_le fun i hi ↦ le_iSup₂_of_le i (n.le_succ.trans hi) le_rfl⟩
have lt n : a (n + 1) < a n := (Disjoint.right_lt_sup_of_left_ne_bot
((hs (e n).2.1).mono_right <| iSup₂_le fun i hi ↦ le_sSup ?_) (e n).2.2).trans_le (sup_le n)
· exact (RelEmbedding.natGT a lt).not_wellFounded_of_decreasing_seq wellFounded_lt
exact ⟨(e i).2.1, fun h ↦ n.lt_succ_self.not_le <| hi.trans_eq <| e.2 <| Subtype.val_injective h⟩
@[deprecated (since := "2024-11-24")]
alias CompleteLattice.WellFoundedLT.finite_of_setIndependent := WellFoundedLT.finite_of_sSupIndep
theorem WellFoundedLT.finite_ne_bot_of_iSupIndep [WellFoundedLT α]
{ι : Type*} {t : ι → α} (ht : iSupIndep t) : Set.Finite {i | t i ≠ ⊥} := by
refine Finite.of_finite_image (Finite.subset ?_ (image_subset_range t _)) ht.injOn
exact WellFoundedLT.finite_of_sSupIndep ht.sSupIndep_range
@[deprecated (since := "2024-11-24")]
alias CompleteLattice.WellFoundedLT.finite_ne_bot_of_independent :=
WellFoundedLT.finite_ne_bot_of_iSupIndep
theorem WellFoundedLT.finite_of_iSupIndep [WellFoundedLT α] {ι : Type*}
{t : ι → α} (ht : iSupIndep t) (h_ne_bot : ∀ i, t i ≠ ⊥) : Finite ι :=
haveI := (WellFoundedLT.finite_of_sSupIndep ht.sSupIndep_range).to_subtype
Finite.of_injective_finite_range (ht.injective h_ne_bot)
@[deprecated (since := "2024-11-24")]
alias CompleteLattice.WellFoundedLT.finite_of_independent := WellFoundedLT.finite_of_iSupIndep
/-- A complete lattice is said to be compactly generated if any
element is the `sSup` of compact elements. -/
class IsCompactlyGenerated (α : Type*) [CompleteLattice α] : Prop where
/-- In a compactly generated complete lattice,
every element is the `sSup` of some set of compact elements. -/
exists_sSup_eq : ∀ x : α, ∃ s : Set α, (∀ x ∈ s, CompleteLattice.IsCompactElement x) ∧ sSup s = x
section
variable [IsCompactlyGenerated α] {a : α} {s : Set α}
@[simp]
theorem sSup_compact_le_eq (b) :
sSup { c : α | CompleteLattice.IsCompactElement c ∧ c ≤ b } = b := by
rcases IsCompactlyGenerated.exists_sSup_eq b with ⟨s, hs, rfl⟩
exact le_antisymm (sSup_le fun c hc => hc.2) (sSup_le_sSup fun c cs => ⟨hs c cs, le_sSup cs⟩)
@[simp]
theorem sSup_compact_eq_top : sSup { a : α | CompleteLattice.IsCompactElement a } = ⊤ := by
refine Eq.trans (congr rfl (Set.ext fun x => ?_)) (sSup_compact_le_eq ⊤)
exact (and_iff_left le_top).symm
theorem le_iff_compact_le_imp {a b : α} :
a ≤ b ↔ ∀ c : α, CompleteLattice.IsCompactElement c → c ≤ a → c ≤ b :=
⟨fun ab _ _ ca => le_trans ca ab, fun h => by
rw [← sSup_compact_le_eq a, ← sSup_compact_le_eq b]
exact sSup_le_sSup fun c hc => ⟨hc.1, h c hc.1 hc.2⟩⟩
/-- This property is sometimes referred to as `α` being upper continuous. -/
theorem DirectedOn.inf_sSup_eq (h : DirectedOn (· ≤ ·) s) : a ⊓ sSup s = ⨆ b ∈ s, a ⊓ b :=
le_antisymm
(by
rw [le_iff_compact_le_imp]
by_cases hs : s.Nonempty
· intro c hc hcinf
rw [le_inf_iff] at hcinf
rw [CompleteLattice.isCompactElement_iff_le_of_directed_sSup_le] at hc
rcases hc s hs h hcinf.2 with ⟨d, ds, cd⟩
refine (le_inf hcinf.1 cd).trans (le_trans ?_ (le_iSup₂ d ds))
rfl
· rw [Set.not_nonempty_iff_eq_empty] at hs
simp [hs])
iSup_inf_le_inf_sSup
/-- This property is sometimes referred to as `α` being upper continuous. -/
protected theorem DirectedOn.sSup_inf_eq (h : DirectedOn (· ≤ ·) s) :
sSup s ⊓ a = ⨆ b ∈ s, b ⊓ a := by
simp_rw [inf_comm _ a, h.inf_sSup_eq]
protected theorem Directed.inf_iSup_eq (h : Directed (· ≤ ·) f) :
(a ⊓ ⨆ i, f i) = ⨆ i, a ⊓ f i := by
rw [iSup, h.directedOn_range.inf_sSup_eq, iSup_range]
protected theorem Directed.iSup_inf_eq (h : Directed (· ≤ ·) f) :
(⨆ i, f i) ⊓ a = ⨆ i, f i ⊓ a := by
rw [iSup, h.directedOn_range.sSup_inf_eq, iSup_range]
protected theorem DirectedOn.disjoint_sSup_right (h : DirectedOn (· ≤ ·) s) :
Disjoint a (sSup s) ↔ ∀ ⦃b⦄, b ∈ s → Disjoint a b := by
simp_rw [disjoint_iff, h.inf_sSup_eq, iSup_eq_bot]
protected theorem DirectedOn.disjoint_sSup_left (h : DirectedOn (· ≤ ·) s) :
Disjoint (sSup s) a ↔ ∀ ⦃b⦄, b ∈ s → Disjoint b a := by
simp_rw [disjoint_iff, h.sSup_inf_eq, iSup_eq_bot]
protected theorem Directed.disjoint_iSup_right (h : Directed (· ≤ ·) f) :
Disjoint a (⨆ i, f i) ↔ ∀ i, Disjoint a (f i) := by
simp_rw [disjoint_iff, h.inf_iSup_eq, iSup_eq_bot]
protected theorem Directed.disjoint_iSup_left (h : Directed (· ≤ ·) f) :
Disjoint (⨆ i, f i) a ↔ ∀ i, Disjoint (f i) a := by
simp_rw [disjoint_iff, h.iSup_inf_eq, iSup_eq_bot]
|
/-- This property is equivalent to `α` being upper continuous. -/
theorem inf_sSup_eq_iSup_inf_sup_finset :
a ⊓ sSup s = ⨆ (t : Finset α) (_ : ↑t ⊆ s), a ⊓ t.sup id :=
le_antisymm
(by
rw [le_iff_compact_le_imp]
intro c hc hcinf
rw [le_inf_iff] at hcinf
rcases hc s hcinf.2 with ⟨t, ht1, ht2⟩
refine (le_inf hcinf.1 ht2).trans (le_trans ?_ (le_iSup₂ t ht1))
rfl)
| Mathlib/Order/CompactlyGenerated/Basic.lean | 420 | 431 |
/-
Copyright (c) 2018 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Kenny Lau, Johan Commelin, Mario Carneiro, Kevin Buzzard,
Amelia Livingston, Yury Kudryashov
-/
import Mathlib.Algebra.BigOperators.Group.Multiset.Defs
import Mathlib.Algebra.FreeMonoid.Basic
import Mathlib.Algebra.Group.Idempotent
import Mathlib.Algebra.Group.Nat.Hom
import Mathlib.Algebra.Group.Submonoid.MulOpposite
import Mathlib.Algebra.Group.Submonoid.Operations
import Mathlib.Data.Fintype.EquivFin
import Mathlib.Data.Int.Basic
/-!
# Submonoids: membership criteria
In this file we prove various facts about membership in a submonoid:
* `pow_mem`, `nsmul_mem`: if `x ∈ S` where `S` is a multiplicative (resp., additive) submonoid and
`n` is a natural number, then `x^n` (resp., `n • x`) belongs to `S`;
* `mem_iSup_of_directed`, `coe_iSup_of_directed`, `mem_sSup_of_directedOn`,
`coe_sSup_of_directedOn`: the supremum of a directed collection of submonoid is their union.
* `sup_eq_range`, `mem_sup`: supremum of two submonoids `S`, `T` of a commutative monoid is the set
of products;
* `closure_singleton_eq`, `mem_closure_singleton`, `mem_closure_pair`: the multiplicative (resp.,
additive) closure of `{x}` consists of powers (resp., natural multiples) of `x`, and a similar
result holds for the closure of `{x, y}`.
## Tags
submonoid, submonoids
-/
assert_not_exists MonoidWithZero
variable {M A B : Type*}
section Assoc
variable [Monoid M] [SetLike B M] [SubmonoidClass B M] {S : B}
end Assoc
section NonAssoc
variable [MulOneClass M]
open Set
namespace Submonoid
-- TODO: this section can be generalized to `[SubmonoidClass B M] [CompleteLattice B]`
-- such that `CompleteLattice.LE` coincides with `SetLike.LE`
@[to_additive]
theorem mem_iSup_of_directed {ι} [hι : Nonempty ι] {S : ι → Submonoid M} (hS : Directed (· ≤ ·) S)
{x : M} : (x ∈ ⨆ i, S i) ↔ ∃ i, x ∈ S i := by
refine ⟨?_, fun ⟨i, hi⟩ ↦ le_iSup S i hi⟩
suffices x ∈ closure (⋃ i, (S i : Set M)) → ∃ i, x ∈ S i by
simpa only [closure_iUnion, closure_eq (S _)] using this
refine closure_induction (fun _ ↦ mem_iUnion.1) ?_ ?_
· exact hι.elim fun i ↦ ⟨i, (S i).one_mem⟩
· rintro x y - - ⟨i, hi⟩ ⟨j, hj⟩
rcases hS i j with ⟨k, hki, hkj⟩
exact ⟨k, (S k).mul_mem (hki hi) (hkj hj)⟩
@[to_additive]
theorem coe_iSup_of_directed {ι} [Nonempty ι] {S : ι → Submonoid M} (hS : Directed (· ≤ ·) S) :
((⨆ i, S i : Submonoid M) : Set M) = ⋃ i, S i :=
Set.ext fun x ↦ by simp [mem_iSup_of_directed hS]
@[to_additive]
theorem mem_sSup_of_directedOn {S : Set (Submonoid M)} (Sne : S.Nonempty)
(hS : DirectedOn (· ≤ ·) S) {x : M} : x ∈ sSup S ↔ ∃ s ∈ S, x ∈ s := by
haveI : Nonempty S := Sne.to_subtype
simp [sSup_eq_iSup', mem_iSup_of_directed hS.directed_val, SetCoe.exists, Subtype.coe_mk]
@[to_additive]
theorem coe_sSup_of_directedOn {S : Set (Submonoid M)} (Sne : S.Nonempty)
(hS : DirectedOn (· ≤ ·) S) : (↑(sSup S) : Set M) = ⋃ s ∈ S, ↑s :=
Set.ext fun x => by simp [mem_sSup_of_directedOn Sne hS]
@[to_additive]
theorem mem_sup_left {S T : Submonoid M} : ∀ {x : M}, x ∈ S → x ∈ S ⊔ T := by
rw [← SetLike.le_def]
exact le_sup_left
@[to_additive]
theorem mem_sup_right {S T : Submonoid M} : ∀ {x : M}, x ∈ T → x ∈ S ⊔ T := by
rw [← SetLike.le_def]
exact le_sup_right
@[to_additive]
theorem mul_mem_sup {S T : Submonoid M} {x y : M} (hx : x ∈ S) (hy : y ∈ T) : x * y ∈ S ⊔ T :=
(S ⊔ T).mul_mem (mem_sup_left hx) (mem_sup_right hy)
@[to_additive]
theorem mem_iSup_of_mem {ι : Sort*} {S : ι → Submonoid M} (i : ι) :
∀ {x : M}, x ∈ S i → x ∈ iSup S := by
rw [← SetLike.le_def]
exact le_iSup _ _
@[to_additive]
theorem mem_sSup_of_mem {S : Set (Submonoid M)} {s : Submonoid M} (hs : s ∈ S) :
∀ {x : M}, x ∈ s → x ∈ sSup S := by
rw [← SetLike.le_def]
exact le_sSup hs
/-- An induction principle for elements of `⨆ i, S i`.
If `C` holds for `1` and all elements of `S i` for all `i`, and is preserved under multiplication,
then it holds for all elements of the supremum of `S`. -/
@[to_additive (attr := elab_as_elim)
" An induction principle for elements of `⨆ i, S i`.
If `C` holds for `0` and all elements of `S i` for all `i`, and is preserved under addition,
then it holds for all elements of the supremum of `S`. "]
theorem iSup_induction {ι : Sort*} (S : ι → Submonoid M) {motive : M → Prop} {x : M}
(hx : x ∈ ⨆ i, S i) (mem : ∀ (i), ∀ x ∈ S i, motive x) (one : motive 1)
(mul : ∀ x y, motive x → motive y → motive (x * y)) : motive x := by
rw [iSup_eq_closure] at hx
refine closure_induction (fun x hx => ?_) one (fun _ _ _ _ ↦ mul _ _) hx
obtain ⟨i, hi⟩ := Set.mem_iUnion.mp hx
exact mem _ _ hi
/-- A dependent version of `Submonoid.iSup_induction`. -/
@[to_additive (attr := elab_as_elim) "A dependent version of `AddSubmonoid.iSup_induction`. "]
theorem iSup_induction' {ι : Sort*} (S : ι → Submonoid M) {motive : ∀ x, (x ∈ ⨆ i, S i) → Prop}
(mem : ∀ (i), ∀ (x) (hxS : x ∈ S i), motive x (mem_iSup_of_mem i hxS))
(one : motive 1 (one_mem _))
(mul : ∀ x y hx hy, motive x hx → motive y hy → motive (x * y) (mul_mem ‹_› ‹_›)) {x : M}
(hx : x ∈ ⨆ i, S i) : motive x hx := by
refine Exists.elim (?_ : ∃ Hx, motive x Hx) fun (hx : x ∈ ⨆ i, S i) (hc : motive x hx) => hc
refine @iSup_induction _ _ ι S (fun m => ∃ hm, motive m hm) _ hx (fun i x hx => ?_) ?_
fun x y => ?_
· exact ⟨_, mem _ _ hx⟩
· exact ⟨_, one⟩
· rintro ⟨_, Cx⟩ ⟨_, Cy⟩
exact ⟨_, mul _ _ _ _ Cx Cy⟩
end Submonoid
end NonAssoc
namespace FreeMonoid
variable {α : Type*}
open Submonoid
@[to_additive]
theorem closure_range_of : closure (Set.range <| @of α) = ⊤ :=
eq_top_iff.2 fun x _ =>
FreeMonoid.recOn x (one_mem _) fun _x _xs hxs =>
mul_mem (subset_closure <| Set.mem_range_self _) hxs
end FreeMonoid
namespace Submonoid
variable [Monoid M] {a : M}
open MonoidHom
theorem closure_singleton_eq (x : M) : closure ({x} : Set M) = mrange (powersHom M x) :=
closure_eq_of_le (Set.singleton_subset_iff.2 ⟨Multiplicative.ofAdd 1, pow_one x⟩) fun _ ⟨_, hn⟩ =>
hn ▸ pow_mem (subset_closure <| Set.mem_singleton _) _
/-- The submonoid generated by an element of a monoid equals the set of natural number powers of
the element. -/
theorem mem_closure_singleton {x y : M} : y ∈ closure ({x} : Set M) ↔ ∃ n : ℕ, x ^ n = y := by
rw [closure_singleton_eq, mem_mrange]; rfl
theorem mem_closure_singleton_self {y : M} : y ∈ closure ({y} : Set M) :=
mem_closure_singleton.2 ⟨1, pow_one y⟩
theorem closure_singleton_one : closure ({1} : Set M) = ⊥ := by
simp [eq_bot_iff_forall, mem_closure_singleton]
section Submonoid
variable {S : Submonoid M} [Fintype S]
open Fintype
/- curly brackets `{}` are used here instead of instance brackets `[]` because
the instance in a goal is often not the same as the one inferred by type class inference. -/
@[to_additive]
theorem card_bot {_ : Fintype (⊥ : Submonoid M)} : card (⊥ : Submonoid M) = 1 :=
card_eq_one_iff.2
⟨⟨(1 : M), Set.mem_singleton 1⟩, fun ⟨_y, hy⟩ => Subtype.eq <| mem_bot.1 hy⟩
@[to_additive]
theorem eq_bot_of_card_le (h : card S ≤ 1) : S = ⊥ :=
let _ := card_le_one_iff_subsingleton.mp h
eq_bot_of_subsingleton S
@[to_additive]
theorem eq_bot_of_card_eq (h : card S = 1) : S = ⊥ :=
S.eq_bot_of_card_le (le_of_eq h)
@[to_additive card_le_one_iff_eq_bot]
theorem card_le_one_iff_eq_bot : card S ≤ 1 ↔ S = ⊥ :=
⟨fun h =>
(eq_bot_iff_forall _).2 fun x hx => by
simpa [Subtype.ext_iff] using card_le_one_iff.1 h ⟨x, hx⟩ 1,
fun h => by simp [h]⟩
@[to_additive]
lemma eq_bot_iff_card : S = ⊥ ↔ card S = 1 :=
⟨by rintro rfl; exact card_bot, eq_bot_of_card_eq⟩
end Submonoid
@[to_additive]
theorem _root_.FreeMonoid.mrange_lift {α} (f : α → M) :
mrange (FreeMonoid.lift f) = closure (Set.range f) := by
rw [mrange_eq_map, ← FreeMonoid.closure_range_of, map_mclosure, ← Set.range_comp,
FreeMonoid.lift_comp_of]
@[to_additive]
theorem closure_eq_mrange (s : Set M) : closure s = mrange (FreeMonoid.lift ((↑) : s → M)) := by
rw [FreeMonoid.mrange_lift, Subtype.range_coe]
@[to_additive]
theorem closure_eq_image_prod (s : Set M) :
(closure s : Set M) = List.prod '' { l : List M | ∀ x ∈ l, x ∈ s } := by
rw [closure_eq_mrange, coe_mrange, ← Set.range_list_map_coe, ← Set.range_comp]
exact congrArg _ (funext <| FreeMonoid.lift_apply _)
@[to_additive]
theorem exists_list_of_mem_closure {s : Set M} {x : M} (hx : x ∈ closure s) :
∃ l : List M, (∀ y ∈ l, y ∈ s) ∧ l.prod = x := by
rwa [← SetLike.mem_coe, closure_eq_image_prod, Set.mem_image] at hx
@[to_additive]
theorem exists_multiset_of_mem_closure {M : Type*} [CommMonoid M] {s : Set M} {x : M}
(hx : x ∈ closure s) : ∃ l : Multiset M, (∀ y ∈ l, y ∈ s) ∧ l.prod = x := by
obtain ⟨l, h1, h2⟩ := exists_list_of_mem_closure hx
exact ⟨l, h1, (Multiset.prod_coe l).trans h2⟩
@[to_additive (attr := elab_as_elim)]
theorem closure_induction_left {s : Set M} {p : (m : M) → m ∈ closure s → Prop}
(one : p 1 (one_mem _))
(mul_left : ∀ x (hx : x ∈ s), ∀ (y) hy, p y hy → p (x * y) (mul_mem (subset_closure hx) hy))
{x : M} (h : x ∈ closure s) :
p x h := by
simp_rw [closure_eq_mrange] at h
obtain ⟨l, rfl⟩ := h
induction l using FreeMonoid.inductionOn' with
| one => exact one
| mul_of x y ih =>
simp only [map_mul, FreeMonoid.lift_eval_of]
refine mul_left _ x.prop (FreeMonoid.lift Subtype.val y) _ (ih ?_)
simp only [closure_eq_mrange, mem_mrange, exists_apply_eq_apply]
@[to_additive (attr := elab_as_elim)]
theorem induction_of_closure_eq_top_left {s : Set M} {p : M → Prop} (hs : closure s = ⊤) (x : M)
(one : p 1) (mul : ∀ x ∈ s, ∀ (y), p y → p (x * y)) : p x := by
have : x ∈ closure s := by simp [hs]
induction this using closure_induction_left with
| one => exact one
| mul_left x hx y _ ih => exact mul x hx y ih
@[to_additive (attr := elab_as_elim)]
theorem closure_induction_right {s : Set M} {p : (m : M) → m ∈ closure s → Prop}
| (one : p 1 (one_mem _))
(mul_right : ∀ x hx, ∀ (y) (hy : y ∈ s), p x hx → p (x * y) (mul_mem hx (subset_closure hy)))
{x : M} (h : x ∈ closure s) : p x h :=
closure_induction_left (s := MulOpposite.unop ⁻¹' s)
| Mathlib/Algebra/Group/Submonoid/Membership.lean | 262 | 265 |
/-
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.Algebra.Group.TypeTags.Hom
import Mathlib.Algebra.Ring.Hom.Basic
import Mathlib.Algebra.Ring.Int.Defs
import Mathlib.Algebra.Ring.Parity
/-!
# Cast of integers (additional theorems)
This file proves additional properties about the *canonical* homomorphism from
the integers into an additive group with a one (`Int.cast`),
particularly results involving algebraic homomorphisms or the order structure on `ℤ`
which were not available in the import dependencies of `Data.Int.Cast.Basic`.
## Main declarations
* `castAddHom`: `cast` bundled as an `AddMonoidHom`.
* `castRingHom`: `cast` bundled as a `RingHom`.
-/
assert_not_exists RelIso OrderedCommMonoid Field
open Additive Function Multiplicative Nat
variable {F ι α β : Type*}
namespace Int
/-- Coercion `ℕ → ℤ` as a `RingHom`. -/
def ofNatHom : ℕ →+* ℤ :=
Nat.castRingHom ℤ
section cast
@[simp, norm_cast]
theorem cast_ite [IntCast α] (P : Prop) [Decidable P] (m n : ℤ) :
((ite P m n : ℤ) : α) = ite P (m : α) (n : α) :=
apply_ite _ _ _ _
/-- `coe : ℤ → α` as an `AddMonoidHom`. -/
def castAddHom (α : Type*) [AddGroupWithOne α] : ℤ →+ α where
toFun := Int.cast
map_zero' := cast_zero
map_add' := cast_add
section AddGroupWithOne
variable [AddGroupWithOne α]
@[simp] lemma coe_castAddHom : ⇑(castAddHom α) = fun x : ℤ => (x : α) := rfl
lemma _root_.Even.intCast {n : ℤ} (h : Even n) : Even (n : α) := h.map (castAddHom α)
variable [CharZero α] {m n : ℤ}
@[simp] lemma cast_eq_zero : (n : α) = 0 ↔ n = 0 where
mp h := by
cases n
· erw [Int.cast_natCast] at h
exact congr_arg _ (Nat.cast_eq_zero.1 h)
· rw [cast_negSucc, neg_eq_zero, Nat.cast_eq_zero] at h
contradiction
mpr h := by rw [h, cast_zero]
@[simp, norm_cast]
lemma cast_inj : (m : α) = n ↔ m = n := by rw [← sub_eq_zero, ← cast_sub, cast_eq_zero, sub_eq_zero]
lemma cast_injective : Injective (Int.cast : ℤ → α) := fun _ _ ↦ cast_inj.1
lemma cast_ne_zero : (n : α) ≠ 0 ↔ n ≠ 0 := not_congr cast_eq_zero
@[simp] lemma cast_eq_one : (n : α) = 1 ↔ n = 1 := by rw [← cast_one, cast_inj]
lemma cast_ne_one : (n : α) ≠ 1 ↔ n ≠ 1 := cast_eq_one.not
end AddGroupWithOne
section NonAssocRing
variable [NonAssocRing α]
variable (α) in
/-- `coe : ℤ → α` as a `RingHom`. -/
def castRingHom : ℤ →+* α where
toFun := Int.cast
map_zero' := cast_zero
map_add' := cast_add
map_one' := cast_one
map_mul' := cast_mul
@[simp] lemma coe_castRingHom : ⇑(castRingHom α) = fun x : ℤ ↦ (x : α) := rfl
lemma cast_commute : ∀ (n : ℤ) (a : α), Commute ↑n a
| (n : ℕ), x => by simpa using n.cast_commute x
| -[n+1], x => by
simpa only [cast_negSucc, Commute.neg_left_iff, Commute.neg_right_iff] using
(n + 1).cast_commute (-x)
lemma cast_comm (n : ℤ) (x : α) : n * x = x * n := (cast_commute ..).eq
lemma commute_cast (a : α) (n : ℤ) : Commute a n := (cast_commute ..).symm
@[simp] lemma _root_.zsmul_eq_mul (a : α) : ∀ n : ℤ, n • a = n * a
| (n : ℕ) => by rw [natCast_zsmul, nsmul_eq_mul, Int.cast_natCast]
| -[n+1] => by simp [Nat.cast_succ, neg_add_rev, Int.cast_negSucc, add_mul]
lemma _root_.zsmul_eq_mul' (a : α) (n : ℤ) : n • a = a * n := by
rw [zsmul_eq_mul, (n.cast_commute a).eq]
end NonAssocRing
section Ring
variable [Ring α] {n : ℤ}
lemma _root_.Odd.intCast (hn : Odd n) : Odd (n : α) := hn.map (castRingHom α)
end Ring
theorem cast_dvd_cast [Ring α] (m n : ℤ) (h : m ∣ n) : (m : α) ∣ (n : α) :=
| RingHom.map_dvd (Int.castRingHom α) h
end cast
| Mathlib/Data/Int/Cast/Lemmas.lean | 122 | 124 |
/-
Copyright (c) 2022 Joël Riou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joël Riou
-/
import Mathlib.CategoryTheory.Idempotents.Basic
import Mathlib.CategoryTheory.Preadditive.AdditiveFunctor
import Mathlib.CategoryTheory.Equivalence
/-!
# The Karoubi envelope of a category
In this file, we define the Karoubi envelope `Karoubi C` of a category `C`.
## Main constructions and definitions
- `Karoubi C` is the Karoubi envelope of a category `C`: it is an idempotent
complete category. It is also preadditive when `C` is preadditive.
- `toKaroubi C : C ⥤ Karoubi C` is a fully faithful functor, which is an equivalence
(`toKaroubiIsEquivalence`) when `C` is idempotent complete.
-/
noncomputable section
open CategoryTheory.Category CategoryTheory.Preadditive CategoryTheory.Limits
namespace CategoryTheory
variable (C : Type*) [Category C]
namespace Idempotents
/-- In a preadditive category `C`, when an object `X` decomposes as `X ≅ P ⨿ Q`, one may
consider `P` as a direct factor of `X` and up to unique isomorphism, it is determined by the
obvious idempotent `X ⟶ P ⟶ X` which is the projection onto `P` with kernel `Q`. More generally,
one may define a formal direct factor of an object `X : C` : it consists of an idempotent
`p : X ⟶ X` which is thought as the "formal image" of `p`. The type `Karoubi C` shall be the
type of the objects of the karoubi envelope of `C`. It makes sense for any category `C`. -/
structure Karoubi where
/-- an object of the underlying category -/
X : C
/-- an endomorphism of the object -/
p : X ⟶ X
/-- the condition that the given endomorphism is an idempotent -/
idem : p ≫ p = p := by aesop_cat
namespace Karoubi
variable {C}
attribute [reassoc (attr := simp)] idem
@[ext (iff := false)]
theorem ext {P Q : Karoubi C} (h_X : P.X = Q.X) (h_p : P.p ≫ eqToHom h_X = eqToHom h_X ≫ Q.p) :
P = Q := by
cases P
cases Q
dsimp at h_X h_p
subst h_X
simpa only [mk.injEq, heq_eq_eq, true_and, eqToHom_refl, comp_id, id_comp] using h_p
/-- A morphism `P ⟶ Q` in the category `Karoubi C` is a morphism in the underlying category
`C` which satisfies a relation, which in the preadditive case, expresses that it induces a
map between the corresponding "formal direct factors" and that it vanishes on the complement
formal direct factor. -/
@[ext]
structure Hom (P Q : Karoubi C) where
/-- a morphism between the underlying objects -/
f : P.X ⟶ Q.X
/-- compatibility of the given morphism with the given idempotents -/
comm : f = P.p ≫ f ≫ Q.p := by aesop_cat
instance [Preadditive C] (P Q : Karoubi C) : Inhabited (Hom P Q) :=
⟨⟨0, by rw [zero_comp, comp_zero]⟩⟩
@[reassoc (attr := simp)]
theorem p_comp {P Q : Karoubi C} (f : Hom P Q) : P.p ≫ f.f = f.f := by rw [f.comm, ← assoc, P.idem]
@[reassoc (attr := simp)]
theorem comp_p {P Q : Karoubi C} (f : Hom P Q) : f.f ≫ Q.p = f.f := by
rw [f.comm, assoc, assoc, Q.idem]
@[reassoc]
theorem p_comm {P Q : Karoubi C} (f : Hom P Q) : P.p ≫ f.f = f.f ≫ Q.p := by rw [p_comp, comp_p]
theorem comp_proof {P Q R : Karoubi C} (g : Hom Q R) (f : Hom P Q) :
f.f ≫ g.f = P.p ≫ (f.f ≫ g.f) ≫ R.p := by rw [assoc, comp_p, ← assoc, p_comp]
/-- The category structure on the karoubi envelope of a category. -/
instance : Category (Karoubi C) where
Hom := Karoubi.Hom
id P := ⟨P.p, by repeat' rw [P.idem]⟩
comp f g := ⟨f.f ≫ g.f, Karoubi.comp_proof g f⟩
@[simp]
theorem hom_ext_iff {P Q : Karoubi C} {f g : P ⟶ Q} : f = g ↔ f.f = g.f := by
constructor
· intro h
rw [h]
· apply Hom.ext
@[ext]
theorem hom_ext {P Q : Karoubi C} (f g : P ⟶ Q) (h : f.f = g.f) : f = g := by
simpa [hom_ext_iff] using h
@[simp]
theorem comp_f {P Q R : Karoubi C} (f : P ⟶ Q) (g : Q ⟶ R) : (f ≫ g).f = f.f ≫ g.f := rfl
@[simp]
theorem id_f {P : Karoubi C} : Hom.f (𝟙 P) = P.p := rfl
/-- It is possible to coerce an object of `C` into an object of `Karoubi C`.
See also the functor `toKaroubi`. -/
instance coe : CoeTC C (Karoubi C) :=
⟨fun X => ⟨X, 𝟙 X, by rw [comp_id]⟩⟩
theorem coe_X (X : C) : (X : Karoubi C).X = X := by simp
@[simp]
theorem coe_p (X : C) : (X : Karoubi C).p = 𝟙 X := rfl
@[simp]
theorem eqToHom_f {P Q : Karoubi C} (h : P = Q) :
Karoubi.Hom.f (eqToHom h) = P.p ≫ eqToHom (congr_arg Karoubi.X h) := by
subst h
simp only [eqToHom_refl, Karoubi.id_f, comp_id]
end Karoubi
/-- The obvious fully faithful functor `toKaroubi` sends an object `X : C` to the obvious
formal direct factor of `X` given by `𝟙 X`. -/
@[simps]
def toKaroubi : C ⥤ Karoubi C where
obj X := ⟨X, 𝟙 X, by rw [comp_id]⟩
map f := ⟨f, by simp only [comp_id, id_comp]⟩
instance : (toKaroubi C).Full where map_surjective f := ⟨f.f, rfl⟩
instance : (toKaroubi C).Faithful where
map_injective := fun h => congr_arg Karoubi.Hom.f h
variable {C}
@[simps add]
instance instAdd [Preadditive C] {P Q : Karoubi C} : Add (P ⟶ Q) where
add f g := ⟨f.f + g.f, by rw [add_comp, comp_add, ← f.comm, ← g.comm]⟩
@[simps neg]
instance instNeg [Preadditive C] {P Q : Karoubi C} : Neg (P ⟶ Q) where
neg f := ⟨-f.f, by simpa only [neg_comp, comp_neg, neg_inj] using f.comm⟩
@[simps zero]
instance instZero [Preadditive C] {P Q : Karoubi C} : Zero (P ⟶ Q) where
zero := ⟨0, by simp only [comp_zero, zero_comp]⟩
instance instAddCommGroupHom [Preadditive C] {P Q : Karoubi C} : AddCommGroup (P ⟶ Q) where
zero_add f := by
ext
apply zero_add
add_zero f := by
ext
apply add_zero
add_assoc f g h' := by
ext
apply add_assoc
add_comm f g := by
ext
apply add_comm
neg_add_cancel f := by
ext
apply neg_add_cancel
zsmul := zsmulRec
nsmul := nsmulRec
namespace Karoubi
theorem hom_eq_zero_iff [Preadditive C] {P Q : Karoubi C} {f : P ⟶ Q} : f = 0 ↔ f.f = 0 :=
hom_ext_iff
/-- The map sending `f : P ⟶ Q` to `f.f : P.X ⟶ Q.X` is additive. -/
@[simps]
def inclusionHom [Preadditive C] (P Q : Karoubi C) : AddMonoidHom (P ⟶ Q) (P.X ⟶ Q.X) where
toFun f := f.f
map_zero' := rfl
map_add' _ _ := rfl
@[simp]
theorem sum_hom [Preadditive C] {P Q : Karoubi C} {α : Type*} (s : Finset α) (f : α → (P ⟶ Q)) :
(∑ x ∈ s, f x).f = ∑ x ∈ s, (f x).f :=
map_sum (inclusionHom P Q) f s
end Karoubi
/-- The category `Karoubi C` is preadditive if `C` is. -/
instance [Preadditive C] : Preadditive (Karoubi C) where
homGroup P Q := by infer_instance
instance [Preadditive C] : Functor.Additive (toKaroubi C) where
open Karoubi
variable (C)
instance : IsIdempotentComplete (Karoubi C) := by
refine ⟨?_⟩
intro P p hp
simp only [hom_ext_iff, comp_f] at hp
use ⟨P.X, p.f, hp⟩
use ⟨p.f, by rw [comp_p p, hp]⟩
use ⟨p.f, by rw [hp, p_comp p]⟩
simp [hp]
instance [IsIdempotentComplete C] : (toKaroubi C).EssSurj :=
⟨fun P => by
rcases IsIdempotentComplete.idempotents_split P.X P.p P.idem with ⟨Y, i, e, ⟨h₁, h₂⟩⟩
use Y
exact
Nonempty.intro
{ hom := ⟨i, by erw [id_comp, ← h₂, ← assoc, h₁, id_comp]⟩
inv := ⟨e, by erw [comp_id, ← h₂, assoc, h₁, comp_id]⟩ }⟩
/-- If `C` is idempotent complete, the functor `toKaroubi : C ⥤ Karoubi C` is an equivalence. -/
instance toKaroubi_isEquivalence [IsIdempotentComplete C] : (toKaroubi C).IsEquivalence where
/-- The equivalence `C ≅ Karoubi C` when `C` is idempotent complete. -/
def toKaroubiEquivalence [IsIdempotentComplete C] : C ≌ Karoubi C :=
(toKaroubi C).asEquivalence
instance toKaroubiEquivalence_functor_additive [Preadditive C] [IsIdempotentComplete C] :
(toKaroubiEquivalence C).functor.Additive :=
(inferInstance : (toKaroubi C).Additive)
namespace Karoubi
variable {C}
/-- The split mono which appears in the factorisation `decompId P`. -/
@[simps]
def decompId_i (P : Karoubi C) : P ⟶ P.X :=
⟨P.p, by rw [coe_p, comp_id, P.idem]⟩
/-- The split epi which appears in the factorisation `decompId P`. -/
@[simps]
def decompId_p (P : Karoubi C) : (P.X : Karoubi C) ⟶ P :=
⟨P.p, by rw [coe_p, id_comp, P.idem]⟩
/-- The formal direct factor of `P.X` given by the idempotent `P.p` in the category `C`
is actually a direct factor in the category `Karoubi C`. -/
@[reassoc]
theorem decompId (P : Karoubi C) : 𝟙 P = decompId_i P ≫ decompId_p P := by
ext
simp only [comp_f, id_f, P.idem, decompId_i, decompId_p]
theorem decomp_p (P : Karoubi C) : (toKaroubi C).map P.p = decompId_p P ≫ decompId_i P := by
ext
simp only [comp_f, decompId_p_f, decompId_i_f, P.idem, toKaroubi_map_f]
theorem decompId_i_toKaroubi (X : C) : decompId_i ((toKaroubi C).obj X) = 𝟙 _ := by
rfl
theorem decompId_p_toKaroubi (X : C) : decompId_p ((toKaroubi C).obj X) = 𝟙 _ := by
rfl
theorem decompId_i_naturality {P Q : Karoubi C} (f : P ⟶ Q) :
f ≫ decompId_i Q = decompId_i P ≫ (by exact Hom.mk f.f (by simp)) := by
simp
theorem decompId_p_naturality {P Q : Karoubi C} (f : P ⟶ Q) :
decompId_p P ≫ f = (by exact Hom.mk f.f (by simp)) ≫ decompId_p Q := by
simp
@[simp]
theorem zsmul_hom [Preadditive C] {P Q : Karoubi C} (n : ℤ) (f : P ⟶ Q) : (n • f).f = n • f.f :=
map_zsmul (inclusionHom P Q) n f
end Karoubi
end Idempotents
end CategoryTheory
| Mathlib/CategoryTheory/Idempotents/Karoubi.lean | 295 | 296 | |
/-
Copyright (c) 2018 Johan Commelin. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johan Commelin, Simon Hudon
-/
import Batteries.Data.List.Lemmas
import Mathlib.Tactic.TypeStar
/-!
# The Following Are Equivalent
This file allows to state that all propositions in a list are equivalent. It is used by
`Mathlib.Tactic.Tfae`.
`TFAE l` means `∀ x ∈ l, ∀ y ∈ l, x ↔ y`. This is equivalent to `Pairwise (↔) l`.
-/
namespace List
/-- TFAE: The Following (propositions) Are Equivalent.
The `tfae_have` and `tfae_finish` tactics can be useful in proofs with `TFAE` goals.
-/
def TFAE (l : List Prop) : Prop :=
∀ x ∈ l, ∀ y ∈ l, x ↔ y
theorem tfae_nil : TFAE [] :=
forall_mem_nil _
@[simp]
theorem tfae_singleton (p) : TFAE [p] := by simp [TFAE, -eq_iff_iff]
theorem tfae_cons_of_mem {a b} {l : List Prop} (h : b ∈ l) : TFAE (a :: l) ↔ (a ↔ b) ∧ TFAE l :=
⟨fun H => ⟨H a (by simp) b (Mem.tail a h),
fun _ hp _ hq => H _ (Mem.tail a hp) _ (Mem.tail a hq)⟩,
by
rintro ⟨ab, H⟩ p (_ | ⟨_, hp⟩) q (_ | ⟨_, hq⟩)
· rfl
· exact ab.trans (H _ h _ hq)
| · exact (ab.trans (H _ h _ hp)).symm
· exact H _ hp _ hq⟩
theorem tfae_cons_cons {a b} {l : List Prop} : TFAE (a :: b :: l) ↔ (a ↔ b) ∧ TFAE (b :: l) :=
tfae_cons_of_mem (Mem.head _)
@[simp]
theorem tfae_cons_self {a} {l : List Prop} : TFAE (a :: a :: l) ↔ TFAE (a :: l) := by
simp [tfae_cons_cons]
| Mathlib/Data/List/TFAE.lean | 40 | 48 |
/-
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⟩⟩
/-- Given a predicate `p` on ZFC sets. `Hereditarily p x` means that `x` has property `p` and the
members of `x` are all `Hereditarily p`. -/
def Hereditarily (p : ZFSet → Prop) (x : ZFSet) : Prop :=
p x ∧ ∀ y ∈ x, Hereditarily p y
termination_by x
section Hereditarily
variable {p : ZFSet.{u} → Prop} {x y : ZFSet.{u}}
theorem hereditarily_iff : Hereditarily p x ↔ p x ∧ ∀ y ∈ x, Hereditarily p y := by
rw [← Hereditarily]
alias ⟨Hereditarily.def, _⟩ := hereditarily_iff
theorem Hereditarily.self (h : x.Hereditarily p) : p x :=
h.def.1
theorem Hereditarily.mem (h : x.Hereditarily p) (hy : y ∈ x) : y.Hereditarily p :=
h.def.2 _ hy
theorem Hereditarily.empty : Hereditarily p x → p ∅ := by
apply @ZFSet.inductionOn _ x
intro y IH h
rcases ZFSet.eq_empty_or_nonempty y with (rfl | ⟨a, ha⟩)
· exact h.self
· exact IH a ha (h.mem ha)
end Hereditarily
end ZFSet
| Mathlib/SetTheory/ZFC/Basic.lean | 1,777 | 1,780 | |
/-
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 | 3,277 | 3,286 | |
/-
Copyright (c) 2020 Bhavik Mehta. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Bhavik Mehta, Edward Ayers
-/
import Mathlib.CategoryTheory.Limits.Shapes.Pullback.HasPullback
import Mathlib.Data.Set.BooleanAlgebra
/-!
# Theory of sieves
- For an object `X` of a category `C`, a `Sieve X` is a set of morphisms to `X`
which is closed under left-composition.
- The complete lattice structure on sieves is given, as well as the Galois insertion
given by downward-closing.
- A `Sieve X` (functorially) induces a presheaf on `C` together with a monomorphism to
the yoneda embedding of `X`.
## Tags
sieve, pullback
-/
universe v₁ v₂ v₃ u₁ u₂ u₃
namespace CategoryTheory
open Category Limits
variable {C : Type u₁} [Category.{v₁} C] {D : Type u₂} [Category.{v₂} D] (F : C ⥤ D)
variable {X Y Z : C} (f : Y ⟶ X)
/-- A set of arrows all with codomain `X`. -/
def Presieve (X : C) :=
∀ ⦃Y⦄, Set (Y ⟶ X)-- deriving CompleteLattice
instance : CompleteLattice (Presieve X) := by
dsimp [Presieve]
infer_instance
namespace Presieve
noncomputable instance : Inhabited (Presieve X) :=
⟨⊤⟩
/-- The full subcategory of the over category `C/X` consisting of arrows which belong to a
presieve on `X`. -/
abbrev category {X : C} (P : Presieve X) :=
ObjectProperty.FullSubcategory fun f : Over X => P f.hom
/-- Construct an object of `P.category`. -/
abbrev categoryMk {X : C} (P : Presieve X) {Y : C} (f : Y ⟶ X) (hf : P f) : P.category :=
⟨Over.mk f, hf⟩
/-- Given a sieve `S` on `X : C`, its associated diagram `S.diagram` is defined to be
the natural functor from the full subcategory of the over category `C/X` consisting
of arrows in `S` to `C`. -/
abbrev diagram (S : Presieve X) : S.category ⥤ C :=
ObjectProperty.ι _ ⋙ Over.forget X
/-- Given a sieve `S` on `X : C`, its associated cocone `S.cocone` is defined to be
the natural cocone over the diagram defined above with cocone point `X`. -/
abbrev cocone (S : Presieve X) : Cocone S.diagram :=
(Over.forgetCocone X).whisker (ObjectProperty.ι _)
/-- Given a set of arrows `S` all with codomain `X`, and a set of arrows with codomain `Y` for each
`f : Y ⟶ X` in `S`, produce a set of arrows with codomain `X`:
`{ g ≫ f | (f : Y ⟶ X) ∈ S, (g : Z ⟶ Y) ∈ R f }`.
-/
def bind (S : Presieve X) (R : ∀ ⦃Y⦄ ⦃f : Y ⟶ X⦄, S f → Presieve Y) : Presieve X := fun Z h =>
∃ (Y : C) (g : Z ⟶ Y) (f : Y ⟶ X) (H : S f), R H g ∧ g ≫ f = h
/-- Structure which contains the data and properties for a morphism `h` satisfying
`Presieve.bind S R h`. -/
structure BindStruct (S : Presieve X) (R : ∀ ⦃Y⦄ ⦃f : Y ⟶ X⦄, S f → Presieve Y)
{Z : C} (h : Z ⟶ X) where
/-- the intermediate object -/
Y : C
/-- a morphism in the family of presieves `R` -/
g : Z ⟶ Y
/-- a morphism in the presieve `S` -/
f : Y ⟶ X
hf : S f
hg : R hf g
fac : g ≫ f = h
attribute [reassoc (attr := simp)] BindStruct.fac
/-- If a morphism `h` satisfies `Presieve.bind S R h`, this is a choice of a structure
in `BindStruct S R h`. -/
noncomputable def bind.bindStruct {S : Presieve X} {R : ∀ ⦃Y⦄ ⦃f : Y ⟶ X⦄, S f → Presieve Y}
{Z : C} {h : Z ⟶ X} (H : bind S R h) : BindStruct S R h :=
Nonempty.some (by
obtain ⟨Y, g, f, hf, hg, fac⟩ := H
exact ⟨{ hf := hf, hg := hg, fac := fac, .. }⟩)
lemma BindStruct.bind {S : Presieve X} {R : ∀ ⦃Y⦄ ⦃f : Y ⟶ X⦄, S f → Presieve Y}
{Z : C} {h : Z ⟶ X} (b : BindStruct S R h) : bind S R h :=
⟨b.Y, b.g, b.f, b.hf, b.hg, b.fac⟩
@[simp]
theorem bind_comp {S : Presieve X} {R : ∀ ⦃Y : C⦄ ⦃f : Y ⟶ X⦄, S f → Presieve Y} {g : Z ⟶ Y}
(h₁ : S f) (h₂ : R h₁ g) : bind S R (g ≫ f) :=
⟨_, _, _, h₁, h₂, rfl⟩
-- Porting note: it seems the definition of `Presieve` must be unfolded in order to define
-- this inductive type, it was thus renamed `singleton'`
-- Note we can't make this into `HasSingleton` because of the out-param.
/-- The singleton presieve. -/
inductive singleton' : ⦃Y : C⦄ → (Y ⟶ X) → Prop
| mk : singleton' f
/-- The singleton presieve. -/
def singleton : Presieve X := singleton' f
lemma singleton.mk {f : Y ⟶ X} : singleton f f := singleton'.mk
@[simp]
theorem singleton_eq_iff_domain (f g : Y ⟶ X) : singleton f g ↔ f = g := by
constructor
· rintro ⟨a, rfl⟩
rfl
· rintro rfl
apply singleton.mk
theorem singleton_self : singleton f f :=
singleton.mk
/-- Pullback a set of arrows with given codomain along a fixed map, by taking the pullback in the
category.
This is not the same as the arrow set of `Sieve.pullback`, but there is a relation between them
in `pullbackArrows_comm`.
-/
inductive pullbackArrows [HasPullbacks C] (R : Presieve X) : Presieve Y
| mk (Z : C) (h : Z ⟶ X) : R h → pullbackArrows _ (pullback.snd h f)
theorem pullback_singleton [HasPullbacks C] (g : Z ⟶ X) :
pullbackArrows f (singleton g) = singleton (pullback.snd g f) := by
funext W
ext h
constructor
· rintro ⟨W, _, _, _⟩
exact singleton.mk
· rintro ⟨_⟩
exact pullbackArrows.mk Z g singleton.mk
/-- Construct the presieve given by the family of arrows indexed by `ι`. -/
inductive ofArrows {ι : Type*} (Y : ι → C) (f : ∀ i, Y i ⟶ X) : Presieve X
| mk (i : ι) : ofArrows _ _ (f i)
theorem ofArrows_pUnit : (ofArrows _ fun _ : PUnit => f) = singleton f := by
funext Y
ext g
constructor
· rintro ⟨_⟩
apply singleton.mk
· rintro ⟨_⟩
exact ofArrows.mk PUnit.unit
theorem ofArrows_pullback [HasPullbacks C] {ι : Type*} (Z : ι → C) (g : ∀ i : ι, Z i ⟶ X) :
(ofArrows (fun i => pullback (g i) f) fun _ => pullback.snd _ _) =
pullbackArrows f (ofArrows Z g) := by
funext T
ext h
constructor
· rintro ⟨hk⟩
exact pullbackArrows.mk _ _ (ofArrows.mk hk)
· rintro ⟨W, k, ⟨_⟩⟩
apply ofArrows.mk
theorem ofArrows_bind {ι : Type*} (Z : ι → C) (g : ∀ i : ι, Z i ⟶ X)
(j : ∀ ⦃Y⦄ (f : Y ⟶ X), ofArrows Z g f → Type*) (W : ∀ ⦃Y⦄ (f : Y ⟶ X) (H), j f H → C)
(k : ∀ ⦃Y⦄ (f : Y ⟶ X) (H i), W f H i ⟶ Y) :
((ofArrows Z g).bind fun _ f H => ofArrows (W f H) (k f H)) =
ofArrows (fun i : Σi, j _ (ofArrows.mk i) => W (g i.1) _ i.2) fun ij =>
k (g ij.1) _ ij.2 ≫ g ij.1 := by
funext Y
ext f
constructor
· rintro ⟨_, _, _, ⟨i⟩, ⟨i'⟩, rfl⟩
exact ofArrows.mk (Sigma.mk _ _)
· rintro ⟨i⟩
exact bind_comp _ (ofArrows.mk _) (ofArrows.mk _)
theorem ofArrows_surj {ι : Type*} {Y : ι → C} (f : ∀ i, Y i ⟶ X) {Z : C} (g : Z ⟶ X)
(hg : ofArrows Y f g) : ∃ (i : ι) (h : Y i = Z),
g = eqToHom h.symm ≫ f i := by
obtain ⟨i⟩ := hg
exact ⟨i, rfl, by simp only [eqToHom_refl, id_comp]⟩
/-- Given a presieve on `F(X)`, we can define a presieve on `X` by taking the preimage via `F`. -/
def functorPullback (R : Presieve (F.obj X)) : Presieve X := fun _ f => R (F.map f)
@[simp]
theorem functorPullback_mem (R : Presieve (F.obj X)) {Y} (f : Y ⟶ X) :
R.functorPullback F f ↔ R (F.map f) :=
Iff.rfl
@[simp]
theorem functorPullback_id (R : Presieve X) : R.functorPullback (𝟭 _) = R :=
rfl
/-- Given a presieve `R` on `X`, the predicate `R.hasPullbacks` means that for all arrows `f` and
`g` in `R`, the pullback of `f` and `g` exists. -/
class hasPullbacks (R : Presieve X) : Prop where
/-- For all arrows `f` and `g` in `R`, the pullback of `f` and `g` exists. -/
has_pullbacks : ∀ {Y Z} {f : Y ⟶ X} (_ : R f) {g : Z ⟶ X} (_ : R g), HasPullback f g
instance (R : Presieve X) [HasPullbacks C] : R.hasPullbacks := ⟨fun _ _ ↦ inferInstance⟩
instance {α : Type v₂} {X : α → C} {B : C} (π : (a : α) → X a ⟶ B)
[(Presieve.ofArrows X π).hasPullbacks] (a b : α) : HasPullback (π a) (π b) :=
Presieve.hasPullbacks.has_pullbacks (Presieve.ofArrows.mk _) (Presieve.ofArrows.mk _)
section FunctorPushforward
variable {E : Type u₃} [Category.{v₃} E] (G : D ⥤ E)
/-- Given a presieve on `X`, we can define a presieve on `F(X)` (which is actually a sieve)
by taking the sieve generated by the image via `F`.
-/
def functorPushforward (S : Presieve X) : Presieve (F.obj X) := fun Y f =>
∃ (Z : C) (g : Z ⟶ X) (h : Y ⟶ F.obj Z), S g ∧ f = h ≫ F.map g
/-- An auxiliary definition in order to fix the choice of the preimages between various definitions.
-/
structure FunctorPushforwardStructure (S : Presieve X) {Y} (f : Y ⟶ F.obj X) where
/-- an object in the source category -/
preobj : C
/-- a map in the source category which has to be in the presieve -/
premap : preobj ⟶ X
/-- the morphism which appear in the factorisation -/
lift : Y ⟶ F.obj preobj
/-- the condition that `premap` is in the presieve -/
cover : S premap
/-- the factorisation of the morphism -/
fac : f = lift ≫ F.map premap
/-- The fixed choice of a preimage. -/
noncomputable def getFunctorPushforwardStructure {F : C ⥤ D} {S : Presieve X} {Y : D}
{f : Y ⟶ F.obj X} (h : S.functorPushforward F f) : FunctorPushforwardStructure F S f := by
choose Z f' g h₁ h using h
exact ⟨Z, f', g, h₁, h⟩
theorem functorPushforward_comp (R : Presieve X) :
R.functorPushforward (F ⋙ G) = (R.functorPushforward F).functorPushforward G := by
funext x
ext f
constructor
· rintro ⟨X, f₁, g₁, h₁, rfl⟩
exact ⟨F.obj X, F.map f₁, g₁, ⟨X, f₁, 𝟙 _, h₁, by simp⟩, rfl⟩
· rintro ⟨X, f₁, g₁, ⟨X', f₂, g₂, h₁, rfl⟩, rfl⟩
exact ⟨X', f₂, g₁ ≫ G.map g₂, h₁, by simp⟩
theorem image_mem_functorPushforward (R : Presieve X) {f : Y ⟶ X} (h : R f) :
R.functorPushforward F (F.map f) :=
⟨Y, f, 𝟙 _, h, by simp⟩
end FunctorPushforward
end Presieve
/--
For an object `X` of a category `C`, a `Sieve X` is a set of morphisms to `X` which is closed under
left-composition.
-/
structure Sieve {C : Type u₁} [Category.{v₁} C] (X : C) where
/-- the underlying presieve -/
arrows : Presieve X
/-- stability by precomposition -/
downward_closed : ∀ {Y Z f} (_ : arrows f) (g : Z ⟶ Y), arrows (g ≫ f)
namespace Sieve
instance : CoeFun (Sieve X) fun _ => Presieve X :=
⟨Sieve.arrows⟩
initialize_simps_projections Sieve (arrows → apply)
variable {S R : Sieve X}
attribute [simp] downward_closed
theorem arrows_ext : ∀ {R S : Sieve X}, R.arrows = S.arrows → R = S := by
rintro ⟨_, _⟩ ⟨_, _⟩ rfl
rfl
@[ext]
protected theorem ext {R S : Sieve X} (h : ∀ ⦃Y⦄ (f : Y ⟶ X), R f ↔ S f) : R = S :=
arrows_ext <| funext fun _ => funext fun f => propext <| h f
open Lattice
/-- The supremum of a collection of sieves: the union of them all. -/
protected def sup (𝒮 : Set (Sieve X)) : Sieve X where
arrows _ := { f | ∃ S ∈ 𝒮, Sieve.arrows S f }
downward_closed {_ _ f} hf _ := by
obtain ⟨S, hS, hf⟩ := hf
exact ⟨S, hS, S.downward_closed hf _⟩
/-- The infimum of a collection of sieves: the intersection of them all. -/
protected def inf (𝒮 : Set (Sieve X)) : Sieve X where
arrows _ := { f | ∀ S ∈ 𝒮, Sieve.arrows S f }
downward_closed {_ _ _} hf g S H := S.downward_closed (hf S H) g
/-- The union of two sieves is a sieve. -/
protected def union (S R : Sieve X) : Sieve X where
arrows _ f := S f ∨ R f
downward_closed := by rintro _ _ _ (h | h) g <;> simp [h]
/-- The intersection of two sieves is a sieve. -/
protected def inter (S R : Sieve X) : Sieve X where
arrows _ f := S f ∧ R f
downward_closed := by
rintro _ _ _ ⟨h₁, h₂⟩ g
simp [h₁, h₂]
/-- Sieves on an object `X` form a complete lattice.
We generate this directly rather than using the galois insertion for nicer definitional properties.
-/
instance : CompleteLattice (Sieve X) where
le S R := ∀ ⦃Y⦄ (f : Y ⟶ X), S f → R f
le_refl _ _ _ := id
le_trans _ _ _ S₁₂ S₂₃ _ _ h := S₂₃ _ (S₁₂ _ h)
le_antisymm _ _ p q := Sieve.ext fun _ _ => ⟨p _, q _⟩
top :=
{ arrows := fun _ => Set.univ
downward_closed := fun _ _ => ⟨⟩ }
bot :=
{ arrows := fun _ => ∅
downward_closed := False.elim }
sup := Sieve.union
inf := Sieve.inter
sSup := Sieve.sup
sInf := Sieve.inf
le_sSup _ S hS _ _ hf := ⟨S, hS, hf⟩
sSup_le := fun _ _ ha _ _ ⟨b, hb, hf⟩ => (ha b hb) _ hf
sInf_le _ _ hS _ _ h := h _ hS
le_sInf _ _ hS _ _ hf _ hR := hS _ hR _ hf
le_sup_left _ _ _ _ := Or.inl
le_sup_right _ _ _ _ := Or.inr
sup_le _ _ _ h₁ h₂ _ f := by--ℰ S hS Y f := by
rintro (hf | hf)
· exact h₁ _ hf
· exact h₂ _ hf
inf_le_left _ _ _ _ := And.left
inf_le_right _ _ _ _ := And.right
le_inf _ _ _ p q _ _ z := ⟨p _ z, q _ z⟩
le_top _ _ _ _ := trivial
bot_le _ _ _ := False.elim
/-- The maximal sieve always exists. -/
instance sieveInhabited : Inhabited (Sieve X) :=
⟨⊤⟩
@[simp]
theorem sInf_apply {Ss : Set (Sieve X)} {Y} (f : Y ⟶ X) :
sInf Ss f ↔ ∀ (S : Sieve X) (_ : S ∈ Ss), S f :=
Iff.rfl
@[simp]
theorem sSup_apply {Ss : Set (Sieve X)} {Y} (f : Y ⟶ X) :
sSup Ss f ↔ ∃ (S : Sieve X) (_ : S ∈ Ss), S f := by
simp [sSup, Sieve.sup, setOf]
@[simp]
theorem inter_apply {R S : Sieve X} {Y} (f : Y ⟶ X) : (R ⊓ S) f ↔ R f ∧ S f :=
Iff.rfl
@[simp]
theorem union_apply {R S : Sieve X} {Y} (f : Y ⟶ X) : (R ⊔ S) f ↔ R f ∨ S f :=
Iff.rfl
@[simp]
theorem top_apply (f : Y ⟶ X) : (⊤ : Sieve X) f :=
trivial
/-- Generate the smallest sieve containing the given set of arrows. -/
@[simps]
def generate (R : Presieve X) : Sieve X where
arrows Z f := ∃ (Y : _) (h : Z ⟶ Y) (g : Y ⟶ X), R g ∧ h ≫ g = f
downward_closed := by
rintro Y Z _ ⟨W, g, f, hf, rfl⟩ h
exact ⟨_, h ≫ g, _, hf, by simp⟩
/-- Given a presieve on `X`, and a sieve on each domain of an arrow in the presieve, we can bind to
produce a sieve on `X`.
-/
@[simps]
def bind (S : Presieve X) (R : ∀ ⦃Y⦄ ⦃f : Y ⟶ X⦄, S f → Sieve Y) : Sieve X where
arrows := S.bind fun _ _ h => R h
downward_closed := by
rintro Y Z f ⟨W, f, h, hh, hf, rfl⟩ g
exact ⟨_, g ≫ f, _, hh, by simp [hf]⟩
/-- Structure which contains the data and properties for a morphism `h` satisfying
`Sieve.bind S R h`. -/
abbrev BindStruct (S : Presieve X) (R : ∀ ⦃Y⦄ ⦃f : Y ⟶ X⦄, S f → Sieve Y)
{Z : C} (h : Z ⟶ X) :=
Presieve.BindStruct S (fun _ _ hf ↦ R hf) h
open Order Lattice
theorem generate_le_iff (R : Presieve X) (S : Sieve X) : generate R ≤ S ↔ R ≤ S :=
⟨fun H _ _ hg => H _ ⟨_, 𝟙 _, _, hg, id_comp _⟩, fun ss Y f => by
rintro ⟨Z, f, g, hg, rfl⟩
exact S.downward_closed (ss Z hg) f⟩
/-- Show that there is a galois insertion (generate, set_over). -/
def giGenerate : GaloisInsertion (generate : Presieve X → Sieve X) arrows where
gc := generate_le_iff
choice 𝒢 _ := generate 𝒢
choice_eq _ _ := rfl
le_l_u _ _ _ hf := ⟨_, 𝟙 _, _, hf, id_comp _⟩
theorem le_generate (R : Presieve X) : R ≤ generate R :=
giGenerate.gc.le_u_l R
@[simp]
theorem generate_sieve (S : Sieve X) : generate S = S :=
giGenerate.l_u_eq S
/-- If the identity arrow is in a sieve, the sieve is maximal. -/
theorem id_mem_iff_eq_top : S (𝟙 X) ↔ S = ⊤ :=
⟨fun h => top_unique fun Y f _ => by simpa using downward_closed _ h f, fun h => h.symm ▸ trivial⟩
/-- If an arrow set contains a split epi, it generates the maximal sieve. -/
theorem generate_of_contains_isSplitEpi {R : Presieve X} (f : Y ⟶ X) [IsSplitEpi f] (hf : R f) :
generate R = ⊤ := by
rw [← id_mem_iff_eq_top]
exact ⟨_, section_ f, f, hf, by simp⟩
@[simp]
theorem generate_of_singleton_isSplitEpi (f : Y ⟶ X) [IsSplitEpi f] :
generate (Presieve.singleton f) = ⊤ :=
generate_of_contains_isSplitEpi f (Presieve.singleton_self _)
@[simp]
theorem generate_top : generate (⊤ : Presieve X) = ⊤ :=
generate_of_contains_isSplitEpi (𝟙 _) ⟨⟩
@[simp]
lemma comp_mem_iff (i : X ⟶ Y) (f : Y ⟶ Z) [IsIso i] (S : Sieve Z) :
S (i ≫ f) ↔ S f := by
refine ⟨fun H ↦ ?_, fun H ↦ S.downward_closed H _⟩
convert S.downward_closed H (inv i)
simp
section
variable {I : Type*} {X : C} (Y : I → C) (f : ∀ i, Y i ⟶ X)
/-- The sieve of `X` generated by family of morphisms `Y i ⟶ X`. -/
abbrev ofArrows : Sieve X := generate (Presieve.ofArrows Y f)
lemma ofArrows_mk (i : I) : ofArrows Y f (f i) :=
⟨_, 𝟙 _, _, ⟨i⟩, by simp⟩
lemma mem_ofArrows_iff {W : C} (g : W ⟶ X) :
ofArrows Y f g ↔ ∃ (i : I) (a : W ⟶ Y i), g = a ≫ f i := by
constructor
· rintro ⟨T, a, b, ⟨i⟩, rfl⟩
exact ⟨i, a, rfl⟩
· rintro ⟨i, a, rfl⟩
apply downward_closed _ (ofArrows_mk Y f i)
variable {Y f} {W : C} {g : W ⟶ X} (hg : ofArrows Y f g)
include hg in
lemma ofArrows.exists : ∃ (i : I) (h : W ⟶ Y i), g = h ≫ f i := by
obtain ⟨_, h, _, ⟨i⟩, rfl⟩ := hg
exact ⟨i, h, rfl⟩
/-- When `hg : Sieve.ofArrows Y f g`, this is a choice of `i` such that `g`
factors through `f i`. -/
noncomputable def ofArrows.i : I := (ofArrows.exists hg).choose
/-- When `hg : Sieve.ofArrows Y f g`, this is a morphism `h : W ⟶ Y (i hg)` such
that `h ≫ f (i hg) = g`. -/
noncomputable def ofArrows.h : W ⟶ Y (i hg) := (ofArrows.exists hg).choose_spec.choose
@[reassoc (attr := simp)]
lemma ofArrows.fac : h hg ≫ f (i hg) = g :=
(ofArrows.exists hg).choose_spec.choose_spec.symm
end
/-- The sieve generated by two morphisms. -/
abbrev ofTwoArrows {U V X : C} (i : U ⟶ X) (j : V ⟶ X) : Sieve X :=
Sieve.ofArrows (Y := pairFunction U V) (fun k ↦ WalkingPair.casesOn k i j)
/-- The sieve of `X : C` that is generated by a family of objects `Y : I → C`:
it consists of morphisms to `X` which factor through at least one of the `Y i`. -/
def ofObjects {I : Type*} (Y : I → C) (X : C) : Sieve X where
arrows Z _ := ∃ (i : I), Nonempty (Z ⟶ Y i)
downward_closed := by
rintro Z₁ Z₂ p ⟨i, ⟨f⟩⟩ g
exact ⟨i, ⟨g ≫ f⟩⟩
lemma mem_ofObjects_iff {I : Type*} (Y : I → C) {Z X : C} (g : Z ⟶ X) :
ofObjects Y X g ↔ ∃ (i : I), Nonempty (Z ⟶ Y i) := by rfl
lemma ofArrows_le_ofObjects
{I : Type*} (Y : I → C) {X : C} (f : ∀ i, Y i ⟶ X) :
Sieve.ofArrows Y f ≤ Sieve.ofObjects Y X := by
intro W g hg
rw [mem_ofArrows_iff] at hg
obtain ⟨i, a, rfl⟩ := hg
exact ⟨i, ⟨a⟩⟩
lemma ofArrows_eq_ofObjects {X : C} (hX : IsTerminal X)
{I : Type*} (Y : I → C) (f : ∀ i, Y i ⟶ X) :
ofArrows Y f = ofObjects Y X := by
refine le_antisymm (ofArrows_le_ofObjects Y f) (fun W g => ?_)
rw [mem_ofArrows_iff, mem_ofObjects_iff]
rintro ⟨i, ⟨h⟩⟩
exact ⟨i, h, hX.hom_ext _ _⟩
/-- Given a morphism `h : Y ⟶ X`, send a sieve S on X to a sieve on Y
as the inverse image of S with `_ ≫ h`.
That is, `Sieve.pullback S h := (≫ h) '⁻¹ S`. -/
@[simps]
def pullback (h : Y ⟶ X) (S : Sieve X) : Sieve Y where
arrows _ sl := S (sl ≫ h)
downward_closed g := by simp [g]
@[simp]
theorem pullback_id : S.pullback (𝟙 _) = S := by simp [Sieve.ext_iff]
@[simp]
theorem pullback_top {f : Y ⟶ X} : (⊤ : Sieve X).pullback f = ⊤ :=
top_unique fun _ _ => id
theorem pullback_comp {f : Y ⟶ X} {g : Z ⟶ Y} (S : Sieve X) :
S.pullback (g ≫ f) = (S.pullback f).pullback g := by simp [Sieve.ext_iff]
@[simp]
theorem pullback_inter {f : Y ⟶ X} (S R : Sieve X) :
(S ⊓ R).pullback f = S.pullback f ⊓ R.pullback f := by simp [Sieve.ext_iff]
theorem mem_iff_pullback_eq_top (f : Y ⟶ X) : S f ↔ S.pullback f = ⊤ := by
rw [← id_mem_iff_eq_top, pullback_apply, id_comp]
@[deprecated (since := "2025-02-28")]
alias pullback_eq_top_iff_mem := mem_iff_pullback_eq_top
theorem pullback_eq_top_of_mem (S : Sieve X) {f : Y ⟶ X} : S f → S.pullback f = ⊤ :=
(mem_iff_pullback_eq_top f).1
lemma pullback_ofObjects_eq_top
{I : Type*} (Y : I → C) {X : C} {i : I} (g : X ⟶ Y i) :
ofObjects Y X = ⊤ := by
ext Z h
simp only [top_apply, iff_true]
rw [mem_ofObjects_iff ]
exact ⟨i, ⟨h ≫ g⟩⟩
/-- Push a sieve `R` on `Y` forward along an arrow `f : Y ⟶ X`: `gf : Z ⟶ X` is in the sieve if `gf`
factors through some `g : Z ⟶ Y` which is in `R`.
-/
@[simps]
def pushforward (f : Y ⟶ X) (R : Sieve Y) : Sieve X where
arrows _ gf := ∃ g, g ≫ f = gf ∧ R g
downward_closed := fun ⟨j, k, z⟩ h => ⟨h ≫ j, by simp [k], by simp [z]⟩
theorem pushforward_apply_comp {R : Sieve Y} {Z : C} {g : Z ⟶ Y} (hg : R g) (f : Y ⟶ X) :
R.pushforward f (g ≫ f) :=
⟨g, rfl, hg⟩
theorem pushforward_comp {f : Y ⟶ X} {g : Z ⟶ Y} (R : Sieve Z) :
R.pushforward (g ≫ f) = (R.pushforward g).pushforward f :=
Sieve.ext fun W h =>
⟨fun ⟨f₁, hq, hf₁⟩ => ⟨f₁ ≫ g, by simpa, f₁, rfl, hf₁⟩, fun ⟨y, hy, z, hR, hz⟩ =>
⟨z, by rw [← Category.assoc, hR]; tauto⟩⟩
theorem galoisConnection (f : Y ⟶ X) : GaloisConnection (Sieve.pushforward f) (Sieve.pullback f) :=
fun _ _ => ⟨fun hR _ g hg => hR _ ⟨g, rfl, hg⟩, fun hS _ _ ⟨h, hg, hh⟩ => hg ▸ hS h hh⟩
theorem pullback_monotone (f : Y ⟶ X) : Monotone (Sieve.pullback f) :=
(galoisConnection f).monotone_u
theorem pushforward_monotone (f : Y ⟶ X) : Monotone (Sieve.pushforward f) :=
(galoisConnection f).monotone_l
theorem le_pushforward_pullback (f : Y ⟶ X) (R : Sieve Y) : R ≤ (R.pushforward f).pullback f :=
(galoisConnection f).le_u_l _
theorem pullback_pushforward_le (f : Y ⟶ X) (R : Sieve X) : (R.pullback f).pushforward f ≤ R :=
(galoisConnection f).l_u_le _
theorem pushforward_union {f : Y ⟶ X} (S R : Sieve Y) :
(S ⊔ R).pushforward f = S.pushforward f ⊔ R.pushforward f :=
(galoisConnection f).l_sup
theorem pushforward_le_bind_of_mem (S : Presieve X) (R : ∀ ⦃Y : C⦄ ⦃f : Y ⟶ X⦄, S f → Sieve Y)
(f : Y ⟶ X) (h : S f) : (R h).pushforward f ≤ bind S R := by
rintro Z _ ⟨g, rfl, hg⟩
exact ⟨_, g, f, h, hg, rfl⟩
theorem le_pullback_bind (S : Presieve X) (R : ∀ ⦃Y : C⦄ ⦃f : Y ⟶ X⦄, S f → Sieve Y) (f : Y ⟶ X)
(h : S f) : R h ≤ (bind S R).pullback f := by
rw [← galoisConnection f]
apply pushforward_le_bind_of_mem
/-- If `f` is a monomorphism, the pushforward-pullback adjunction on sieves is coreflective. -/
def galoisCoinsertionOfMono (f : Y ⟶ X) [Mono f] :
GaloisCoinsertion (Sieve.pushforward f) (Sieve.pullback f) := by
apply (galoisConnection f).toGaloisCoinsertion
rintro S Z g ⟨g₁, hf, hg₁⟩
rw [cancel_mono f] at hf
rwa [← hf]
/-- If `f` is a split epi, the pushforward-pullback adjunction on sieves is reflective. -/
def galoisInsertionOfIsSplitEpi (f : Y ⟶ X) [IsSplitEpi f] :
GaloisInsertion (Sieve.pushforward f) (Sieve.pullback f) := by
apply (galoisConnection f).toGaloisInsertion
intro S Z g hg
exact ⟨g ≫ section_ f, by simpa⟩
theorem pullbackArrows_comm [HasPullbacks C] {X Y : C} (f : Y ⟶ X) (R : Presieve X) :
Sieve.generate (R.pullbackArrows f) = (Sieve.generate R).pullback f := by
ext W g
constructor
· rintro ⟨_, h, k, ⟨W, g, hg⟩, rfl⟩
rw [Sieve.pullback_apply, assoc, ← pullback.condition, ← assoc]
exact Sieve.downward_closed _ (by exact Sieve.le_generate R W hg) (h ≫ pullback.fst g f)
· rintro ⟨W, h, k, hk, comm⟩
exact ⟨_, _, _, Presieve.pullbackArrows.mk _ _ hk, pullback.lift_snd _ _ comm⟩
section Functor
variable {E : Type u₃} [Category.{v₃} E] (G : D ⥤ E)
/--
If `R` is a sieve, then the `CategoryTheory.Presieve.functorPullback` of `R` is actually a sieve.
-/
@[simps]
def functorPullback (R : Sieve (F.obj X)) : Sieve X where
arrows := Presieve.functorPullback F R
downward_closed := by
intro _ _ f hf g
unfold Presieve.functorPullback
rw [F.map_comp]
exact R.downward_closed hf (F.map g)
@[simp]
theorem functorPullback_arrows (R : Sieve (F.obj X)) :
(R.functorPullback F).arrows = R.arrows.functorPullback F :=
rfl
@[simp]
theorem functorPullback_id (R : Sieve X) : R.functorPullback (𝟭 _) = R := by
ext
rfl
theorem functorPullback_comp (R : Sieve ((F ⋙ G).obj X)) :
R.functorPullback (F ⋙ G) = (R.functorPullback G).functorPullback F := by
ext
rfl
theorem functorPushforward_extend_eq {R : Presieve X} :
(generate R).arrows.functorPushforward F = R.functorPushforward F := by
funext Y
ext f
constructor
· rintro ⟨X', g, f', ⟨X'', g', f'', h₁, rfl⟩, rfl⟩
exact ⟨X'', f'', f' ≫ F.map g', h₁, by simp⟩
· rintro ⟨X', g, f', h₁, h₂⟩
exact ⟨X', g, f', le_generate R _ h₁, h₂⟩
| /-- The sieve generated by the image of `R` under `F`. -/
@[simps]
def functorPushforward (R : Sieve X) : Sieve (F.obj X) where
arrows := R.arrows.functorPushforward F
| Mathlib/CategoryTheory/Sites/Sieves.lean | 672 | 675 |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl
-/
import Mathlib.Algebra.Order.Archimedean.Basic
import Mathlib.Algebra.Order.BigOperators.Ring.Finset
import Mathlib.Topology.Algebra.InfiniteSum.NatInt
import Mathlib.Topology.Algebra.Order.Field
import Mathlib.Topology.Order.MonotoneConvergence
/-!
# Infinite sum or product in an order
This file provides lemmas about the interaction of infinite sums and products and order operations.
-/
open Finset Filter Function
variable {ι κ α : Type*}
section Preorder
variable [Preorder α] [CommMonoid α] [TopologicalSpace α] {a c : α} {f : ι → α}
@[to_additive]
lemma hasProd_le_of_prod_le [ClosedIicTopology α]
(hf : HasProd f a) (h : ∀ s, ∏ i ∈ s, f i ≤ c) : a ≤ c :=
le_of_tendsto' hf h
@[to_additive]
theorem le_hasProd_of_le_prod [ClosedIciTopology α]
(hf : HasProd f a) (h : ∀ s, c ≤ ∏ i ∈ s, f i) : c ≤ a :=
ge_of_tendsto' hf h
@[to_additive]
protected theorem Multipliable.tprod_le_of_prod_range_le [ClosedIicTopology α] {f : ℕ → α}
(hf : Multipliable f) (h : ∀ n, ∏ i ∈ range n, f i ≤ c) : ∏' n, f n ≤ c :=
le_of_tendsto' hf.hasProd.tendsto_prod_nat h
@[deprecated (since := "2025-04-12")] alias tsum_le_of_sum_range_le :=
Summable.tsum_le_of_sum_range_le
@[to_additive existing, deprecated (since := "2025-04-12")] alias tprod_le_of_prod_range_le :=
Multipliable.tprod_le_of_prod_range_le
end Preorder
section OrderedCommMonoid
variable [CommMonoid α] [PartialOrder α] [IsOrderedMonoid α]
[TopologicalSpace α] [OrderClosedTopology α] {f g : ι → α}
{a a₁ a₂ : α}
@[to_additive]
theorem hasProd_le (h : ∀ i, f i ≤ g i) (hf : HasProd f a₁) (hg : HasProd g a₂) : a₁ ≤ a₂ :=
le_of_tendsto_of_tendsto' hf hg fun _ ↦ prod_le_prod' fun i _ ↦ h i
@[to_additive]
theorem hasProd_mono (hf : HasProd f a₁) (hg : HasProd g a₂) (h : f ≤ g) : a₁ ≤ a₂ :=
hasProd_le h hf hg
@[to_additive]
theorem hasProd_le_inj {g : κ → α} (e : ι → κ) (he : Injective e)
(hs : ∀ c, c ∉ Set.range e → 1 ≤ g c) (h : ∀ i, f i ≤ g (e i)) (hf : HasProd f a₁)
(hg : HasProd g a₂) : a₁ ≤ a₂ := by
rw [← hasProd_extend_one he] at hf
refine hasProd_le (fun c ↦ ?_) hf hg
obtain ⟨i, rfl⟩ | h := em (c ∈ Set.range e)
· rw [he.extend_apply]
exact h _
· rw [extend_apply' _ _ _ h]
exact hs _ h
@[to_additive]
protected theorem Multipliable.tprod_le_tprod_of_inj {g : κ → α} (e : ι → κ) (he : Injective e)
(hs : ∀ c, c ∉ Set.range e → 1 ≤ g c) (h : ∀ i, f i ≤ g (e i)) (hf : Multipliable f)
(hg : Multipliable g) : tprod f ≤ tprod g :=
hasProd_le_inj _ he hs h hf.hasProd hg.hasProd
@[deprecated (since := "2025-04-12")] alias tsum_le_tsum_of_inj := Summable.tsum_le_tsum_of_inj
@[to_additive existing, deprecated (since := "2025-04-12")] alias tprod_le_tprod_of_inj :=
Multipliable.tprod_le_tprod_of_inj
@[to_additive]
protected lemma Multipliable.tprod_subtype_le {κ γ : Type*} [CommGroup γ] [PartialOrder γ]
[IsOrderedMonoid γ] [UniformSpace γ] [IsUniformGroup γ] [OrderClosedTopology γ]
[CompleteSpace γ] (f : κ → γ) (β : Set κ) (h : ∀ a : κ, 1 ≤ f a) (hf : Multipliable f) :
(∏' (b : β), f b) ≤ (∏' (a : κ), f a) := by
apply Multipliable.tprod_le_tprod_of_inj _
(Subtype.coe_injective)
(by simp only [Subtype.range_coe_subtype, Set.setOf_mem_eq, h, implies_true])
(by simp only [le_refl, Subtype.forall, implies_true])
(by apply hf.subtype)
apply hf
@[deprecated (since := "2025-04-12")] alias tsum_subtype_le := Summable.tsum_subtype_le
@[to_additive existing, deprecated (since := "2025-04-12")] alias tprod_subtype_le :=
Multipliable.tprod_subtype_le
@[to_additive]
theorem prod_le_hasProd (s : Finset ι) (hs : ∀ i, i ∉ s → 1 ≤ f i) (hf : HasProd f a) :
∏ i ∈ s, f i ≤ a :=
ge_of_tendsto hf (eventually_atTop.2
⟨s, fun _t hst ↦ prod_le_prod_of_subset_of_one_le' hst fun i _ hbs ↦ hs i hbs⟩)
@[to_additive]
theorem isLUB_hasProd (h : ∀ i, 1 ≤ f i) (hf : HasProd f a) :
IsLUB (Set.range fun s ↦ ∏ i ∈ s, f i) a := by
| classical
exact isLUB_of_tendsto_atTop (Finset.prod_mono_set_of_one_le' h) hf
@[to_additive]
| Mathlib/Topology/Algebra/InfiniteSum/Order.lean | 109 | 112 |
/-
Copyright (c) 2024 Joël Riou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joël Riou, Kim Morrison
-/
import Mathlib.CategoryTheory.GradedObject.Unitor
import Mathlib.Data.Fintype.Prod
/-!
# The monoidal category structures on graded objects
Assuming that `C` is a monoidal category and that `I` is an additive monoid,
we introduce a partially defined tensor product on the category `GradedObject I C`:
given `X₁` and `X₂` two objects in `GradedObject I C`, we define
`GradedObject.Monoidal.tensorObj X₁ X₂` under the assumption `HasTensor X₁ X₂`
that the coproduct of `X₁ i ⊗ X₂ j` for `i + j = n` exists for any `n : I`.
Under suitable assumptions about the existence of coproducts and the
preservation of certain coproducts by the tensor products in `C`, we
obtain a monoidal category structure on `GradedObject I C`.
In particular, if `C` has finite coproducts to which the tensor
product commutes, we obtain a monoidal category structure on `GradedObject ℕ C`.
-/
universe u
namespace CategoryTheory
open Limits MonoidalCategory Category
variable {I : Type u} [AddMonoid I] {C : Type*} [Category C] [MonoidalCategory C]
namespace GradedObject
/-- The tensor product of two graded objects `X₁` and `X₂` exists if for any `n`,
the coproduct of the objects `X₁ i ⊗ X₂ j` for `i + j = n` exists. -/
abbrev HasTensor (X₁ X₂ : GradedObject I C) : Prop :=
HasMap (((mapBifunctor (curriedTensor C) I I).obj X₁).obj X₂) (fun ⟨i, j⟩ => i + j)
lemma hasTensor_of_iso {X₁ X₂ Y₁ Y₂ : GradedObject I C}
(e₁ : X₁ ≅ Y₁) (e₂ : X₂ ≅ Y₂) [HasTensor X₁ X₂] :
HasTensor Y₁ Y₂ := by
let e : ((mapBifunctor (curriedTensor C) I I).obj X₁).obj X₂ ≅
((mapBifunctor (curriedTensor C) I I).obj Y₁).obj Y₂ := isoMk _ _
(fun ⟨i, j⟩ ↦ (eval i).mapIso e₁ ⊗ (eval j).mapIso e₂)
exact hasMap_of_iso e _
namespace Monoidal
/-- The tensor product of two graded objects. -/
noncomputable abbrev tensorObj (X₁ X₂ : GradedObject I C) [HasTensor X₁ X₂] :
GradedObject I C :=
mapBifunctorMapObj (curriedTensor C) (fun ⟨i, j⟩ => i + j) X₁ X₂
section
variable (X₁ X₂ : GradedObject I C) [HasTensor X₁ X₂]
/-- The inclusion of a summand in a tensor product of two graded objects. -/
noncomputable def ιTensorObj (i₁ i₂ i₁₂ : I) (h : i₁ + i₂ = i₁₂) :
X₁ i₁ ⊗ X₂ i₂ ⟶ tensorObj X₁ X₂ i₁₂ :=
ιMapBifunctorMapObj (curriedTensor C) _ _ _ _ _ _ h
variable {X₁ X₂}
@[ext]
lemma tensorObj_ext {A : C} {j : I} (f g : tensorObj X₁ X₂ j ⟶ A)
(h : ∀ (i₁ i₂ : I) (hi : i₁ + i₂ = j),
ιTensorObj X₁ X₂ i₁ i₂ j hi ≫ f = ιTensorObj X₁ X₂ i₁ i₂ j hi ≫ g) : f = g := by
apply mapObj_ext
rintro ⟨i₁, i₂⟩ hi
exact h i₁ i₂ hi
/-- Constructor for morphisms from a tensor product of two graded objects. -/
noncomputable def tensorObjDesc {A : C} {k : I}
(f : ∀ (i₁ i₂ : I) (_ : i₁ + i₂ = k), X₁ i₁ ⊗ X₂ i₂ ⟶ A) : tensorObj X₁ X₂ k ⟶ A :=
mapBifunctorMapObjDesc f
| @[reassoc (attr := simp)]
lemma ι_tensorObjDesc {A : C} {k : I}
(f : ∀ (i₁ i₂ : I) (_ : i₁ + i₂ = k), X₁ i₁ ⊗ X₂ i₂ ⟶ A) (i₁ i₂ : I) (hi : i₁ + i₂ = k) :
ιTensorObj X₁ X₂ i₁ i₂ k hi ≫ tensorObjDesc f = f i₁ i₂ hi := by
apply ι_mapBifunctorMapObjDesc
end
| Mathlib/CategoryTheory/GradedObject/Monoidal.lean | 80 | 86 |
/-
Copyright (c) 2022 Tian Chen. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Tian Chen, Mantas Bakšys
-/
import Mathlib.Algebra.GeomSum
import Mathlib.Algebra.Order.Ring.Basic
import Mathlib.Algebra.Ring.Int.Parity
import Mathlib.Data.Nat.Choose.Sum
import Mathlib.Data.Nat.Prime.Int
import Mathlib.NumberTheory.Padics.PadicVal.Defs
import Mathlib.RingTheory.Ideal.Quotient.Defs
import Mathlib.RingTheory.Ideal.Span
/-!
# Multiplicity in Number Theory
This file contains results in number theory relating to multiplicity.
## Main statements
* `multiplicity.Int.pow_sub_pow` is the lifting the exponent lemma for odd primes.
We also prove several variations of the lemma.
## References
* [Wikipedia, *Lifting-the-exponent lemma*]
(https://en.wikipedia.org/wiki/Lifting-the-exponent_lemma)
-/
open Ideal Ideal.Quotient Finset
variable {R : Type*} {n : ℕ}
section CommRing
variable [CommRing R] {a b x y : R}
theorem dvd_geom_sum₂_iff_of_dvd_sub {x y p : R} (h : p ∣ x - y) :
(p ∣ ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) ↔ p ∣ n * y ^ (n - 1) := by
rw [← mem_span_singleton, ← Ideal.Quotient.eq] at h
simp only [← mem_span_singleton, ← eq_zero_iff_mem, RingHom.map_geom_sum₂, h, geom_sum₂_self,
map_mul, map_pow, map_natCast]
theorem dvd_geom_sum₂_iff_of_dvd_sub' {x y p : R} (h : p ∣ x - y) :
(p ∣ ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) ↔ p ∣ n * x ^ (n - 1) := by
rw [geom_sum₂_comm, dvd_geom_sum₂_iff_of_dvd_sub]; simpa using h.neg_right
theorem dvd_geom_sum₂_self {x y : R} (h : ↑n ∣ x - y) :
↑n ∣ ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) :=
(dvd_geom_sum₂_iff_of_dvd_sub h).mpr (dvd_mul_right _ _)
theorem sq_dvd_add_pow_sub_sub (p x : R) (n : ℕ) :
p ^ 2 ∣ (x + p) ^ n - x ^ (n - 1) * p * n - x ^ n := by
rcases n with - | n
· simp only [pow_zero, Nat.cast_zero, sub_zero, sub_self, dvd_zero, mul_zero]
· simp only [Nat.succ_sub_succ_eq_sub, tsub_zero, Nat.cast_succ, add_pow, Finset.sum_range_succ,
Nat.choose_self, Nat.succ_sub _, tsub_self, pow_one, Nat.choose_succ_self_right, pow_zero,
mul_one, Nat.cast_zero, zero_add, Nat.succ_eq_add_one, add_tsub_cancel_left]
suffices p ^ 2 ∣ ∑ i ∈ range n, x ^ i * p ^ (n + 1 - i) * ↑((n + 1).choose i) by
convert this; abel
apply Finset.dvd_sum
intro y hy
calc
p ^ 2 ∣ p ^ (n + 1 - y) :=
pow_dvd_pow p (le_tsub_of_add_le_left (by linarith [Finset.mem_range.mp hy]))
_ ∣ x ^ y * p ^ (n + 1 - y) * ↑((n + 1).choose y) :=
dvd_mul_of_dvd_left (dvd_mul_left _ _) _
theorem not_dvd_geom_sum₂ {p : R} (hp : Prime p) (hxy : p ∣ x - y) (hx : ¬p ∣ x) (hn : ¬p ∣ n) :
¬p ∣ ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) := fun h =>
hx <|
hp.dvd_of_dvd_pow <| (hp.dvd_or_dvd <| (dvd_geom_sum₂_iff_of_dvd_sub' hxy).mp h).resolve_left hn
variable {p : ℕ} (a b)
theorem odd_sq_dvd_geom_sum₂_sub (hp : Odd p) :
(p : R) ^ 2 ∣ (∑ i ∈ range p, (a + p * b) ^ i * a ^ (p - 1 - i)) - p * a ^ (p - 1) := by
have h1 : ∀ (i : ℕ),
(p : R) ^ 2 ∣ (a + ↑p * b) ^ i - (a ^ (i - 1) * (↑p * b) * i + a ^ i) := by
intro i
calc
↑p ^ 2 ∣ (↑p * b) ^ 2 := by simp only [mul_pow, dvd_mul_right]
_ ∣ (a + ↑p * b) ^ i - (a ^ (i - 1) * (↑p * b) * ↑i + a ^ i) := by
simp only [sq_dvd_add_pow_sub_sub (↑p * b) a i, ← sub_sub]
simp_rw [← mem_span_singleton, ← Ideal.Quotient.eq] at *
let s : R := (p : R)^2
calc
(Ideal.Quotient.mk (span {s})) (∑ i ∈ range p, (a + (p : R) * b) ^ i * a ^ (p - 1 - i)) =
∑ i ∈ Finset.range p,
mk (span {s}) ((a ^ (i - 1) * (↑p * b) * ↑i + a ^ i) * a ^ (p - 1 - i)) := by
simp_rw [s, RingHom.map_geom_sum₂, ← map_pow, h1, ← map_mul]
_ =
mk (span {s})
(∑ x ∈ Finset.range p, a ^ (x - 1) * (a ^ (p - 1 - x) * (↑p * (b * ↑x)))) +
mk (span {s}) (∑ x ∈ Finset.range p, a ^ (x + (p - 1 - x))) := by
ring_nf
simp_rw [← map_sum, sum_add_distrib, map_add]
_ =
mk (span {s})
(∑ x ∈ Finset.range p, a ^ (x - 1) * (a ^ (p - 1 - x) * (↑p * (b * ↑x)))) +
mk (span {s}) (∑ _x ∈ Finset.range p, a ^ (p - 1)) := by
rw [add_right_inj]
have : ∀ (x : ℕ), (hx : x ∈ range p) → a ^ (x + (p - 1 - x)) = a ^ (p - 1) := by
intro x hx
rw [← Nat.add_sub_assoc _ x, Nat.add_sub_cancel_left]
exact Nat.le_sub_one_of_lt (Finset.mem_range.mp hx)
rw [Finset.sum_congr rfl this]
_ =
mk (span {s})
(∑ x ∈ Finset.range p, a ^ (x - 1) * (a ^ (p - 1 - x) * (↑p * (b * ↑x)))) +
mk (span {s}) (↑p * a ^ (p - 1)) := by
simp only [add_right_inj, Finset.sum_const, Finset.card_range, nsmul_eq_mul]
_ =
mk (span {s}) (↑p * b * ∑ x ∈ Finset.range p, a ^ (p - 2) * x) +
mk (span {s}) (↑p * a ^ (p - 1)) := by
simp only [Finset.mul_sum, ← mul_assoc, ← pow_add]
rw [Finset.sum_congr rfl]
rintro (⟨⟩ | ⟨x⟩) hx
· rw [Nat.cast_zero, mul_zero, mul_zero]
· have : x.succ - 1 + (p - 1 - x.succ) = p - 2 := by
rw [← Nat.add_sub_assoc (Nat.le_sub_one_of_lt (Finset.mem_range.mp hx))]
exact congr_arg Nat.pred (Nat.add_sub_cancel_left _ _)
rw [this]
ring1
_ = mk (span {s}) (↑p * a ^ (p - 1)) := by
have : Finset.sum (range p) (fun (x : ℕ) ↦ (x : R)) =
((Finset.sum (range p) (fun (x : ℕ) ↦ (x : ℕ)))) := by simp only [Nat.cast_sum]
simp only [add_eq_right, ← Finset.mul_sum, this]
norm_cast
simp only [Finset.sum_range_id]
norm_cast
simp only [Nat.cast_mul, map_mul,
Nat.mul_div_assoc p (even_iff_two_dvd.mp (Nat.Odd.sub_odd hp odd_one))]
ring_nf
rw [mul_assoc, mul_assoc]
refine mul_eq_zero_of_left ?_ _
refine Ideal.Quotient.eq_zero_iff_mem.mpr ?_
simp [s, mem_span_singleton]
section IntegralDomain
variable [IsDomain R]
theorem emultiplicity_pow_sub_pow_of_prime {p : R} (hp : Prime p) {x y : R}
(hxy : p ∣ x - y) (hx : ¬p ∣ x) {n : ℕ} (hn : ¬p ∣ n) :
emultiplicity p (x ^ n - y ^ n) = emultiplicity p (x - y) := by
rw [← geom_sum₂_mul, emultiplicity_mul hp,
emultiplicity_eq_zero.2 (not_dvd_geom_sum₂ hp hxy hx hn), zero_add]
@[deprecated (since := "2024-11-30")]
alias multiplicity.pow_sub_pow_of_prime := emultiplicity_pow_sub_pow_of_prime
variable (hp : Prime (p : R)) (hp1 : Odd p) (hxy : ↑p ∣ x - y) (hx : ¬↑p ∣ x)
include hp hp1 hxy hx
theorem emultiplicity_geom_sum₂_eq_one :
emultiplicity (↑p) (∑ i ∈ range p, x ^ i * y ^ (p - 1 - i)) = 1 := by
rw [← Nat.cast_one]
refine emultiplicity_eq_coe.2 ⟨?_, ?_⟩
· rw [pow_one]
exact dvd_geom_sum₂_self hxy
rw [dvd_iff_dvd_of_dvd_sub hxy] at hx
obtain ⟨k, hk⟩ := hxy
rw [one_add_one_eq_two, eq_add_of_sub_eq' hk]
refine mt (dvd_iff_dvd_of_dvd_sub (@odd_sq_dvd_geom_sum₂_sub _ _ y k _ hp1)).mp ?_
rw [pow_two, mul_dvd_mul_iff_left hp.ne_zero]
exact mt hp.dvd_of_dvd_pow hx
@[deprecated (since := "2024-11-30")]
alias multiplicity.geom_sum₂_eq_one := emultiplicity_geom_sum₂_eq_one
theorem emultiplicity_pow_prime_sub_pow_prime :
emultiplicity (↑p) (x ^ p - y ^ p) = emultiplicity (↑p) (x - y) + 1 := by
rw [← geom_sum₂_mul, emultiplicity_mul hp, emultiplicity_geom_sum₂_eq_one hp hp1 hxy hx, add_comm]
@[deprecated (since := "2024-11-30")]
alias multiplicity.pow_prime_sub_pow_prime := emultiplicity_pow_prime_sub_pow_prime
theorem emultiplicity_pow_prime_pow_sub_pow_prime_pow (a : ℕ) :
emultiplicity (↑p) (x ^ p ^ a - y ^ p ^ a) = emultiplicity (↑p) (x - y) + a := by
induction a with
| zero => rw [Nat.cast_zero, add_zero, pow_zero, pow_one, pow_one]
| succ a h_ind =>
rw [Nat.cast_add, Nat.cast_one, ← add_assoc, ← h_ind, pow_succ, pow_mul, pow_mul]
apply emultiplicity_pow_prime_sub_pow_prime hp hp1
· rw [← geom_sum₂_mul]
exact dvd_mul_of_dvd_right hxy _
· exact fun h => hx (hp.dvd_of_dvd_pow h)
@[deprecated (since := "2024-11-30")]
alias multiplicity.pow_prime_pow_sub_pow_prime_pow := emultiplicity_pow_prime_pow_sub_pow_prime_pow
end IntegralDomain
section LiftingTheExponent
variable (hp : Nat.Prime p) (hp1 : Odd p)
include hp hp1
/-- **Lifting the exponent lemma** for odd primes. -/
theorem Int.emultiplicity_pow_sub_pow {x y : ℤ} (hxy : ↑p ∣ x - y) (hx : ¬↑p ∣ x) (n : ℕ) :
emultiplicity (↑p) (x ^ n - y ^ n) = emultiplicity (↑p) (x - y) + emultiplicity p n := by
rcases n with - | n
· simp only [emultiplicity_zero, add_top, pow_zero, sub_self]
have h : FiniteMultiplicity _ _ := Nat.finiteMultiplicity_iff.mpr ⟨hp.ne_one, n.succ_pos⟩
simp only [Nat.succ_eq_add_one] at h
rcases emultiplicity_eq_coe.mp h.emultiplicity_eq_multiplicity with ⟨⟨k, hk⟩, hpn⟩
conv_lhs => rw [hk, pow_mul, pow_mul]
rw [Nat.prime_iff_prime_int] at hp
rw [emultiplicity_pow_sub_pow_of_prime hp,
emultiplicity_pow_prime_pow_sub_pow_prime_pow hp hp1 hxy hx, h.emultiplicity_eq_multiplicity]
· rw [← geom_sum₂_mul]
exact dvd_mul_of_dvd_right hxy _
· exact fun h => hx (hp.dvd_of_dvd_pow h)
· rw [Int.natCast_dvd_natCast]
rintro ⟨c, rfl⟩
refine hpn ⟨c, ?_⟩
rwa [pow_succ, mul_assoc]
@[deprecated (since := "2024-11-30")]
alias multiplicity.Int.pow_sub_pow := Int.emultiplicity_pow_sub_pow
theorem Int.emultiplicity_pow_add_pow {x y : ℤ} (hxy : ↑p ∣ x + y) (hx : ¬↑p ∣ x)
{n : ℕ} (hn : Odd n) :
emultiplicity (↑p) (x ^ n + y ^ n) = emultiplicity (↑p) (x + y) + emultiplicity p n := by
rw [← sub_neg_eq_add] at hxy
rw [← sub_neg_eq_add, ← sub_neg_eq_add, ← Odd.neg_pow hn]
exact Int.emultiplicity_pow_sub_pow hp hp1 hxy hx n
@[deprecated (since := "2024-11-30")]
alias multiplicity.Int.pow_add_pow := Int.emultiplicity_pow_add_pow
theorem Nat.emultiplicity_pow_sub_pow {x y : ℕ} (hxy : p ∣ x - y) (hx : ¬p ∣ x) (n : ℕ) :
emultiplicity p (x ^ n - y ^ n) = emultiplicity p (x - y) + emultiplicity p n := by
obtain hyx | hyx := le_total y x
· iterate 2 rw [← Int.natCast_emultiplicity]
rw [Int.ofNat_sub (Nat.pow_le_pow_left hyx n)]
rw [← Int.natCast_dvd_natCast] at hxy hx
rw [Int.natCast_sub hyx] at *
push_cast at *
exact Int.emultiplicity_pow_sub_pow hp hp1 hxy hx n
· simp only [Nat.sub_eq_zero_iff_le.mpr (Nat.pow_le_pow_left hyx n), emultiplicity_zero,
Nat.sub_eq_zero_iff_le.mpr hyx, top_add]
@[deprecated (since := "2024-11-30")]
alias multiplicity.Nat.pow_sub_pow := Nat.emultiplicity_pow_sub_pow
theorem Nat.emultiplicity_pow_add_pow {x y : ℕ} (hxy : p ∣ x + y) (hx : ¬p ∣ x)
{n : ℕ} (hn : Odd n) :
emultiplicity p (x ^ n + y ^ n) = emultiplicity p (x + y) + emultiplicity p n := by
iterate 2 rw [← Int.natCast_emultiplicity]
rw [← Int.natCast_dvd_natCast] at hxy hx
push_cast at *
exact Int.emultiplicity_pow_add_pow hp hp1 hxy hx hn
@[deprecated (since := "2024-11-30")]
alias multiplicity.Nat.pow_add_pow := Nat.emultiplicity_pow_add_pow
end LiftingTheExponent
end CommRing
theorem pow_two_pow_sub_pow_two_pow [CommRing R] {x y : R} (n : ℕ) :
x ^ 2 ^ n - y ^ 2 ^ n = (∏ i ∈ Finset.range n, (x ^ 2 ^ i + y ^ 2 ^ i)) * (x - y) := by
induction n with
| zero => simp only [pow_zero, pow_one, range_zero, prod_empty, one_mul]
| succ d hd =>
suffices x ^ 2 ^ d.succ - y ^ 2 ^ d.succ = (x ^ 2 ^ d + y ^ 2 ^ d) * (x ^ 2 ^ d - y ^ 2 ^ d) by
rw [this, hd, Finset.prod_range_succ, ← mul_assoc, mul_comm (x ^ 2 ^ d + y ^ 2 ^ d)]
rw [Nat.succ_eq_add_one]
ring
theorem Int.sq_mod_four_eq_one_of_odd {x : ℤ} : Odd x → x ^ 2 % 4 = 1 := by
intro hx
unfold Odd at hx
rcases hx with ⟨_, rfl⟩
ring_nf
rw [add_assoc, ← add_mul, Int.add_mul_emod_self_right]
decide
theorem Int.two_pow_two_pow_add_two_pow_two_pow {x y : ℤ} (hx : ¬2 ∣ x) (hxy : 4 ∣ x - y) (i : ℕ) :
emultiplicity 2 (x ^ 2 ^ i + y ^ 2 ^ i) = ↑(1 : ℕ) := by
have hx_odd : Odd x := by rwa [← Int.not_even_iff_odd, even_iff_two_dvd]
have hxy_even : Even (x - y) := even_iff_two_dvd.mpr (dvd_trans (by decide) hxy)
have hy_odd : Odd y := by simpa using hx_odd.sub_even hxy_even
refine emultiplicity_eq_coe.mpr ⟨?_, ?_⟩
· rw [pow_one, ← even_iff_two_dvd]
exact hx_odd.pow.add_odd hy_odd.pow
rcases i with - | i
· intro hxy'
have : 2 * 2 ∣ 2 * x := by
have := dvd_add hxy hxy'
norm_num at *
rw [two_mul]
exact this
have : 2 ∣ x := (mul_dvd_mul_iff_left (by norm_num)).mp this
contradiction
suffices ∀ x : ℤ, Odd x → x ^ 2 ^ (i + 1) % 4 = 1 by
rw [show (2 ^ (1 + 1) : ℤ) = 4 by norm_num, Int.dvd_iff_emod_eq_zero, Int.add_emod,
this _ hx_odd, this _ hy_odd]
decide
intro x hx
rw [pow_succ', mul_comm, pow_mul, Int.sq_mod_four_eq_one_of_odd hx.pow]
theorem Int.two_pow_two_pow_sub_pow_two_pow {x y : ℤ} (n : ℕ) (hxy : 4 ∣ x - y) (hx : ¬2 ∣ x) :
emultiplicity 2 (x ^ 2 ^ n - y ^ 2 ^ n) = emultiplicity 2 (x - y) + n := by
simp only [pow_two_pow_sub_pow_two_pow n, emultiplicity_mul Int.prime_two,
Finset.emultiplicity_prod Int.prime_two, add_comm, Nat.cast_one, Finset.sum_const,
Finset.card_range, nsmul_one, Int.two_pow_two_pow_add_two_pow_two_pow hx hxy]
theorem Int.two_pow_sub_pow' {x y : ℤ} (n : ℕ) (hxy : 4 ∣ x - y) (hx : ¬2 ∣ x) :
emultiplicity 2 (x ^ n - y ^ n) = emultiplicity 2 (x - y) + emultiplicity (2 : ℤ) n := by
have hx_odd : Odd x := by rwa [← Int.not_even_iff_odd, even_iff_two_dvd]
have hxy_even : Even (x - y) := even_iff_two_dvd.mpr (dvd_trans (by decide) hxy)
have hy_odd : Odd y := by simpa using hx_odd.sub_even hxy_even
rcases n with - | n
· simp only [pow_zero, sub_self, emultiplicity_zero, Int.ofNat_zero, add_top]
have h : FiniteMultiplicity 2 n.succ := Nat.finiteMultiplicity_iff.mpr ⟨by norm_num, n.succ_pos⟩
simp only [Nat.succ_eq_add_one] at h
rcases emultiplicity_eq_coe.mp h.emultiplicity_eq_multiplicity with ⟨⟨k, hk⟩, hpn⟩
rw [hk, pow_mul, pow_mul, emultiplicity_pow_sub_pow_of_prime,
Int.two_pow_two_pow_sub_pow_two_pow _ hxy hx, ← hk]
· norm_cast
rw [h.emultiplicity_eq_multiplicity]
· exact Int.prime_two
· simpa only [even_iff_two_dvd] using hx_odd.pow.sub_odd hy_odd.pow
· simpa only [even_iff_two_dvd, ← Int.not_even_iff_odd] using hx_odd.pow
norm_cast
contrapose! hpn
rw [pow_succ]
conv_rhs => rw [hk]
exact mul_dvd_mul_left _ hpn
/-- **Lifting the exponent lemma** for `p = 2` -/
theorem Int.two_pow_sub_pow {x y : ℤ} {n : ℕ} (hxy : 2 ∣ x - y) (hx : ¬2 ∣ x) (hn : Even n) :
emultiplicity 2 (x ^ n - y ^ n) + 1 =
emultiplicity 2 (x + y) + emultiplicity 2 (x - y) + emultiplicity (2 : ℤ) n := by
have hy : Odd y := by
rw [← even_iff_two_dvd, Int.not_even_iff_odd] at hx
replace hxy := (@even_neg _ _ (x - y)).mpr (even_iff_two_dvd.mpr hxy)
convert Even.add_odd hxy hx
abel
obtain ⟨d, hd⟩ := hn
subst hd
simp only [← two_mul, pow_mul]
have hxy4 : 4 ∣ x ^ 2 - y ^ 2 := by
rw [Int.dvd_iff_emod_eq_zero, Int.sub_emod, Int.sq_mod_four_eq_one_of_odd _,
Int.sq_mod_four_eq_one_of_odd hy]
· norm_num
· simp only [← Int.not_even_iff_odd, even_iff_two_dvd, hx, not_false_iff]
rw [Int.two_pow_sub_pow' d hxy4 _, sq_sub_sq, ← Int.ofNat_mul_out,
emultiplicity_mul Int.prime_two, emultiplicity_mul Int.prime_two]
· suffices emultiplicity (2 : ℤ) ↑(2 : ℕ) = 1 by rw [this, add_comm 1, ← add_assoc]
norm_cast
rw [FiniteMultiplicity.emultiplicity_self]
rw [Nat.finiteMultiplicity_iff]
decide
· rw [← even_iff_two_dvd, Int.not_even_iff_odd]
apply Odd.pow
simp only [← Int.not_even_iff_odd, even_iff_two_dvd, hx, not_false_iff]
theorem Nat.two_pow_sub_pow {x y : ℕ} (hxy : 2 ∣ x - y) (hx : ¬2 ∣ x) {n : ℕ} (hn : Even n) :
emultiplicity 2 (x ^ n - y ^ n) + 1 =
emultiplicity 2 (x + y) + emultiplicity 2 (x - y) + emultiplicity 2 n := by
obtain hyx | hyx := le_total y x
· iterate 3 rw [← Int.natCast_emultiplicity]
simp only [Int.ofNat_sub hyx, Int.ofNat_sub (pow_le_pow_left' hyx _), Int.natCast_add,
Int.natCast_pow]
rw [← Int.natCast_dvd_natCast] at hx
rw [← Int.natCast_dvd_natCast, Int.ofNat_sub hyx] at hxy
convert Int.two_pow_sub_pow hxy hx hn using 2
rw [← Int.natCast_emultiplicity]
rfl
· simp only [Nat.sub_eq_zero_iff_le.mpr hyx,
Nat.sub_eq_zero_iff_le.mpr (pow_le_pow_left' hyx n), emultiplicity_zero,
top_add, add_top]
namespace padicValNat
variable {x y : ℕ}
theorem pow_two_sub_pow (hyx : y < x) (hxy : 2 ∣ x - y) (hx : ¬2 ∣ x) {n : ℕ} (hn : n ≠ 0)
(hneven : Even n) :
padicValNat 2 (x ^ n - y ^ n) + 1 =
padicValNat 2 (x + y) + padicValNat 2 (x - y) + padicValNat 2 n := by
simp only [← Nat.cast_inj (R := ℕ∞), Nat.cast_add]
iterate 4 rw [padicValNat_eq_emultiplicity]
· exact Nat.two_pow_sub_pow hxy hx hneven
· exact hn.bot_lt
· exact Nat.sub_pos_of_lt hyx
· omega
· simp only [tsub_pos_iff_lt, Nat.pow_lt_pow_left hyx hn]
|
variable {p : ℕ} [hp : Fact p.Prime] (hp1 : Odd p)
include hp hp1
theorem pow_sub_pow (hyx : y < x) (hxy : p ∣ x - y) (hx : ¬p ∣ x) {n : ℕ} (hn : n ≠ 0) :
padicValNat p (x ^ n - y ^ n) = padicValNat p (x - y) + padicValNat p n := by
rw [← Nat.cast_inj (R := ℕ∞), Nat.cast_add]
iterate 3 rw [padicValNat_eq_emultiplicity]
| Mathlib/NumberTheory/Multiplicity.lean | 395 | 402 |
/-
Copyright (c) 2019 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Sébastien Gouëzel, Yury Kudryashov
-/
import Mathlib.Analysis.Calculus.FDeriv.Linear
import Mathlib.Analysis.Calculus.FDeriv.Comp
/-!
# Additive operations on derivatives
For detailed documentation of the Fréchet derivative,
see the module docstring of `Analysis/Calculus/FDeriv/Basic.lean`.
This file contains the usual formulas (and existence assertions) for the derivative of
* sum of finitely many functions
* multiplication of a function by a scalar constant
* negative of a function
* subtraction of two functions
-/
open Filter Asymptotics ContinuousLinearMap
noncomputable section
section
variable {𝕜 : Type*} [NontriviallyNormedField 𝕜]
variable {E : Type*} [NormedAddCommGroup E] [NormedSpace 𝕜 E]
variable {F : Type*} [NormedAddCommGroup F] [NormedSpace 𝕜 F]
variable {f g : E → F}
variable {f' g' : E →L[𝕜] F}
variable {x : E}
variable {s : Set E}
variable {L : Filter E}
section ConstSMul
variable {R : Type*} [Semiring R] [Module R F] [SMulCommClass 𝕜 R F] [ContinuousConstSMul R F]
/-! ### Derivative of a function multiplied by a constant -/
@[fun_prop]
theorem HasStrictFDerivAt.const_smul (h : HasStrictFDerivAt f f' x) (c : R) :
HasStrictFDerivAt (fun x => c • f x) (c • f') x :=
(c • (1 : F →L[𝕜] F)).hasStrictFDerivAt.comp x h
theorem HasFDerivAtFilter.const_smul (h : HasFDerivAtFilter f f' x L) (c : R) :
HasFDerivAtFilter (fun x => c • f x) (c • f') x L :=
(c • (1 : F →L[𝕜] F)).hasFDerivAtFilter.comp x h tendsto_map
@[fun_prop]
nonrec theorem HasFDerivWithinAt.const_smul (h : HasFDerivWithinAt f f' s x) (c : R) :
HasFDerivWithinAt (fun x => c • f x) (c • f') s x :=
h.const_smul c
@[fun_prop]
nonrec theorem HasFDerivAt.const_smul (h : HasFDerivAt f f' x) (c : R) :
HasFDerivAt (fun x => c • f x) (c • f') x :=
h.const_smul c
@[fun_prop]
theorem DifferentiableWithinAt.const_smul (h : DifferentiableWithinAt 𝕜 f s x) (c : R) :
DifferentiableWithinAt 𝕜 (fun y => c • f y) s x :=
(h.hasFDerivWithinAt.const_smul c).differentiableWithinAt
@[fun_prop]
theorem DifferentiableAt.const_smul (h : DifferentiableAt 𝕜 f x) (c : R) :
DifferentiableAt 𝕜 (fun y => c • f y) x :=
(h.hasFDerivAt.const_smul c).differentiableAt
@[fun_prop]
theorem DifferentiableOn.const_smul (h : DifferentiableOn 𝕜 f s) (c : R) :
DifferentiableOn 𝕜 (fun y => c • f y) s := fun x hx => (h x hx).const_smul c
@[fun_prop]
theorem Differentiable.const_smul (h : Differentiable 𝕜 f) (c : R) :
Differentiable 𝕜 fun y => c • f y := fun x => (h x).const_smul c
theorem fderivWithin_const_smul (hxs : UniqueDiffWithinAt 𝕜 s x)
(h : DifferentiableWithinAt 𝕜 f s x) (c : R) :
fderivWithin 𝕜 (fun y => c • f y) s x = c • fderivWithin 𝕜 f s x :=
(h.hasFDerivWithinAt.const_smul c).fderivWithin hxs
/-- Version of `fderivWithin_const_smul` written with `c • f` instead of `fun y ↦ c • f y`. -/
theorem fderivWithin_const_smul' (hxs : UniqueDiffWithinAt 𝕜 s x)
(h : DifferentiableWithinAt 𝕜 f s x) (c : R) :
fderivWithin 𝕜 (c • f) s x = c • fderivWithin 𝕜 f s x :=
fderivWithin_const_smul hxs h c
theorem fderiv_const_smul (h : DifferentiableAt 𝕜 f x) (c : R) :
fderiv 𝕜 (fun y => c • f y) x = c • fderiv 𝕜 f x :=
(h.hasFDerivAt.const_smul c).fderiv
/-- Version of `fderiv_const_smul` written with `c • f` instead of `fun y ↦ c • f y`. -/
theorem fderiv_const_smul' (h : DifferentiableAt 𝕜 f x) (c : R) :
fderiv 𝕜 (c • f) x = c • fderiv 𝕜 f x :=
(h.hasFDerivAt.const_smul c).fderiv
end ConstSMul
section Add
/-! ### Derivative of the sum of two functions -/
@[fun_prop]
nonrec theorem HasStrictFDerivAt.add (hf : HasStrictFDerivAt f f' x)
(hg : HasStrictFDerivAt g g' x) : HasStrictFDerivAt (fun y => f y + g y) (f' + g') x :=
.of_isLittleO <| (hf.isLittleO.add hg.isLittleO).congr_left fun y => by
simp only [LinearMap.sub_apply, LinearMap.add_apply, map_sub, map_add, add_apply]
abel
theorem HasFDerivAtFilter.add (hf : HasFDerivAtFilter f f' x L)
(hg : HasFDerivAtFilter g g' x L) : HasFDerivAtFilter (fun y => f y + g y) (f' + g') x L :=
.of_isLittleO <| (hf.isLittleO.add hg.isLittleO).congr_left fun _ => by
simp only [LinearMap.sub_apply, LinearMap.add_apply, map_sub, map_add, add_apply]
abel
@[fun_prop]
nonrec theorem HasFDerivWithinAt.add (hf : HasFDerivWithinAt f f' s x)
(hg : HasFDerivWithinAt g g' s x) : HasFDerivWithinAt (fun y => f y + g y) (f' + g') s x :=
hf.add hg
@[fun_prop]
nonrec theorem HasFDerivAt.add (hf : HasFDerivAt f f' x) (hg : HasFDerivAt g g' x) :
HasFDerivAt (fun x => f x + g x) (f' + g') x :=
hf.add hg
@[fun_prop]
theorem DifferentiableWithinAt.add (hf : DifferentiableWithinAt 𝕜 f s x)
(hg : DifferentiableWithinAt 𝕜 g s x) : DifferentiableWithinAt 𝕜 (fun y => f y + g y) s x :=
(hf.hasFDerivWithinAt.add hg.hasFDerivWithinAt).differentiableWithinAt
@[simp, fun_prop]
theorem DifferentiableAt.add (hf : DifferentiableAt 𝕜 f x) (hg : DifferentiableAt 𝕜 g x) :
DifferentiableAt 𝕜 (fun y => f y + g y) x :=
(hf.hasFDerivAt.add hg.hasFDerivAt).differentiableAt
@[fun_prop]
theorem DifferentiableOn.add (hf : DifferentiableOn 𝕜 f s) (hg : DifferentiableOn 𝕜 g s) :
DifferentiableOn 𝕜 (fun y => f y + g y) s := fun x hx => (hf x hx).add (hg x hx)
@[simp, fun_prop]
theorem Differentiable.add (hf : Differentiable 𝕜 f) (hg : Differentiable 𝕜 g) :
Differentiable 𝕜 fun y => f y + g y := fun x => (hf x).add (hg x)
theorem fderivWithin_add (hxs : UniqueDiffWithinAt 𝕜 s x) (hf : DifferentiableWithinAt 𝕜 f s x)
(hg : DifferentiableWithinAt 𝕜 g s x) :
fderivWithin 𝕜 (fun y => f y + g y) s x = fderivWithin 𝕜 f s x + fderivWithin 𝕜 g s x :=
(hf.hasFDerivWithinAt.add hg.hasFDerivWithinAt).fderivWithin hxs
/-- Version of `fderivWithin_add` where the function is written as `f + g` instead
of `fun y ↦ f y + g y`. -/
theorem fderivWithin_add' (hxs : UniqueDiffWithinAt 𝕜 s x) (hf : DifferentiableWithinAt 𝕜 f s x)
(hg : DifferentiableWithinAt 𝕜 g s x) :
fderivWithin 𝕜 (f + g) s x = fderivWithin 𝕜 f s x + fderivWithin 𝕜 g s x :=
fderivWithin_add hxs hf hg
theorem fderiv_add (hf : DifferentiableAt 𝕜 f x) (hg : DifferentiableAt 𝕜 g x) :
fderiv 𝕜 (fun y => f y + g y) x = fderiv 𝕜 f x + fderiv 𝕜 g x :=
(hf.hasFDerivAt.add hg.hasFDerivAt).fderiv
/-- Version of `fderiv_add` where the function is written as `f + g` instead
of `fun y ↦ f y + g y`. -/
theorem fderiv_add' (hf : DifferentiableAt 𝕜 f x) (hg : DifferentiableAt 𝕜 g x) :
fderiv 𝕜 (f + g) x = fderiv 𝕜 f x + fderiv 𝕜 g x :=
fderiv_add hf hg
@[simp]
theorem hasFDerivAtFilter_add_const_iff (c : F) :
HasFDerivAtFilter (f · + c) f' x L ↔ HasFDerivAtFilter f f' x L := by
simp [hasFDerivAtFilter_iff_isLittleOTVS]
alias ⟨_, HasFDerivAtFilter.add_const⟩ := hasFDerivAtFilter_add_const_iff
@[simp]
theorem hasStrictFDerivAt_add_const_iff (c : F) :
HasStrictFDerivAt (f · + c) f' x ↔ HasStrictFDerivAt f f' x := by
simp [hasStrictFDerivAt_iff_isLittleO]
@[fun_prop]
alias ⟨_, HasStrictFDerivAt.add_const⟩ := hasStrictFDerivAt_add_const_iff
@[simp]
theorem hasFDerivWithinAt_add_const_iff (c : F) :
HasFDerivWithinAt (f · + c) f' s x ↔ HasFDerivWithinAt f f' s x :=
hasFDerivAtFilter_add_const_iff c
@[fun_prop]
alias ⟨_, HasFDerivWithinAt.add_const⟩ := hasFDerivWithinAt_add_const_iff
@[simp]
theorem hasFDerivAt_add_const_iff (c : F) : HasFDerivAt (f · + c) f' x ↔ HasFDerivAt f f' x :=
hasFDerivAtFilter_add_const_iff c
@[fun_prop]
alias ⟨_, HasFDerivAt.add_const⟩ := hasFDerivAt_add_const_iff
@[simp]
theorem differentiableWithinAt_add_const_iff (c : F) :
DifferentiableWithinAt 𝕜 (fun y => f y + c) s x ↔ DifferentiableWithinAt 𝕜 f s x :=
exists_congr fun _ ↦ hasFDerivWithinAt_add_const_iff c
@[fun_prop]
alias ⟨_, DifferentiableWithinAt.add_const⟩ := differentiableWithinAt_add_const_iff
@[simp]
theorem differentiableAt_add_const_iff (c : F) :
DifferentiableAt 𝕜 (fun y => f y + c) x ↔ DifferentiableAt 𝕜 f x :=
exists_congr fun _ ↦ hasFDerivAt_add_const_iff c
@[fun_prop]
alias ⟨_, DifferentiableAt.add_const⟩ := differentiableAt_add_const_iff
@[simp]
theorem differentiableOn_add_const_iff (c : F) :
DifferentiableOn 𝕜 (fun y => f y + c) s ↔ DifferentiableOn 𝕜 f s :=
forall₂_congr fun _ _ ↦ differentiableWithinAt_add_const_iff c
@[fun_prop]
alias ⟨_, DifferentiableOn.add_const⟩ := differentiableOn_add_const_iff
@[simp]
theorem differentiable_add_const_iff (c : F) :
(Differentiable 𝕜 fun y => f y + c) ↔ Differentiable 𝕜 f :=
forall_congr' fun _ ↦ differentiableAt_add_const_iff c
@[fun_prop]
alias ⟨_, Differentiable.add_const⟩ := differentiable_add_const_iff
@[simp]
theorem fderivWithin_add_const (c : F) :
fderivWithin 𝕜 (fun y => f y + c) s x = fderivWithin 𝕜 f s x := by
classical simp [fderivWithin]
@[simp]
theorem fderiv_add_const (c : F) : fderiv 𝕜 (fun y => f y + c) x = fderiv 𝕜 f x := by
simp only [← fderivWithin_univ, fderivWithin_add_const]
@[simp]
theorem hasFDerivAtFilter_const_add_iff (c : F) :
HasFDerivAtFilter (c + f ·) f' x L ↔ HasFDerivAtFilter f f' x L := by
simpa only [add_comm] using hasFDerivAtFilter_add_const_iff c
alias ⟨_, HasFDerivAtFilter.const_add⟩ := hasFDerivAtFilter_const_add_iff
@[simp]
theorem hasStrictFDerivAt_const_add_iff (c : F) :
HasStrictFDerivAt (c + f ·) f' x ↔ HasStrictFDerivAt f f' x := by
simpa only [add_comm] using hasStrictFDerivAt_add_const_iff c
|
@[fun_prop]
| Mathlib/Analysis/Calculus/FDeriv/Add.lean | 254 | 255 |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Mario Carneiro, Yury Kudryashov
-/
import Mathlib.Topology.Order.LeftRight
import Mathlib.Topology.Separation.Hausdorff
/-!
# Order-closed topologies
In this file we introduce 3 typeclass mixins that relate topology and order structures:
- `ClosedIicTopology` says that all the intervals $(-∞, a]$ (formally, `Set.Iic a`)
are closed sets;
- `ClosedIciTopology` says that all the intervals $[a, +∞)$ (formally, `Set.Ici a`)
are closed sets;
- `OrderClosedTopology` says that the set of points `(x, y)` such that `x ≤ y`
is closed in the product topology.
The last predicate implies the first two.
We prove many basic properties of such topologies.
## Main statements
This file contains the proofs of the following facts.
For exact requirements
(`OrderClosedTopology` vs `ClosedIciTopology` vs `ClosedIicTopology,
`Preorder` vs `PartialOrder` vs `LinearOrder` etc)
see their statements.
### Open / closed sets
* `isOpen_lt` : if `f` and `g` are continuous functions, then `{x | f x < g x}` is open;
* `isOpen_Iio`, `isOpen_Ioi`, `isOpen_Ioo` : open intervals are open;
* `isClosed_le` : if `f` and `g` are continuous functions, then `{x | f x ≤ g x}` is closed;
* `isClosed_Iic`, `isClosed_Ici`, `isClosed_Icc` : closed intervals are closed;
* `frontier_le_subset_eq`, `frontier_lt_subset_eq` : frontiers of both `{x | f x ≤ g x}`
and `{x | f x < g x}` are included by `{x | f x = g x}`;
### Convergence and inequalities
* `le_of_tendsto_of_tendsto` : if `f` converges to `a`, `g` converges to `b`, and eventually
`f x ≤ g x`, then `a ≤ b`
* `le_of_tendsto`, `ge_of_tendsto` : if `f` converges to `a` and eventually `f x ≤ b`
(resp., `b ≤ f x`), then `a ≤ b` (resp., `b ≤ a`); we also provide primed versions
that assume the inequalities to hold for all `x`.
### Min, max, `sSup` and `sInf`
* `Continuous.min`, `Continuous.max`: pointwise `min`/`max` of two continuous functions is
continuous.
* `Tendsto.min`, `Tendsto.max` : if `f` tends to `a` and `g` tends to `b`, then their pointwise
`min`/`max` tend to `min a b` and `max a b`, respectively.
-/
open Set Filter
open OrderDual (toDual)
open scoped Topology
universe u v w
variable {α : Type u} {β : Type v} {γ : Type w}
/-- If `α` is a topological space and a preorder, `ClosedIicTopology α` means that `Iic a` is
closed for all `a : α`. -/
class ClosedIicTopology (α : Type*) [TopologicalSpace α] [Preorder α] : Prop where
/-- For any `a`, the set `(-∞, a]` is closed. -/
isClosed_Iic (a : α) : IsClosed (Iic a)
/-- If `α` is a topological space and a preorder, `ClosedIciTopology α` means that `Ici a` is
closed for all `a : α`. -/
class ClosedIciTopology (α : Type*) [TopologicalSpace α] [Preorder α] : Prop where
/-- For any `a`, the set `[a, +∞)` is closed. -/
isClosed_Ici (a : α) : IsClosed (Ici a)
/-- A topology on a set which is both a topological space and a preorder is _order-closed_ if the
set of points `(x, y)` with `x ≤ y` is closed in the product space. We introduce this as a mixin.
This property is satisfied for the order topology on a linear order, but it can be satisfied more
generally, and suffices to derive many interesting properties relating order and topology. -/
class OrderClosedTopology (α : Type*) [TopologicalSpace α] [Preorder α] : Prop where
/-- The set `{ (x, y) | x ≤ y }` is a closed set. -/
isClosed_le' : IsClosed { p : α × α | p.1 ≤ p.2 }
instance [TopologicalSpace α] [h : FirstCountableTopology α] : FirstCountableTopology αᵒᵈ := h
instance [TopologicalSpace α] [h : SecondCountableTopology α] : SecondCountableTopology αᵒᵈ := h
theorem Dense.orderDual [TopologicalSpace α] {s : Set α} (hs : Dense s) :
Dense (OrderDual.ofDual ⁻¹' s) :=
hs
section General
variable [TopologicalSpace α] [Preorder α] {s : Set α}
protected lemma BddAbove.of_closure : BddAbove (closure s) → BddAbove s :=
BddAbove.mono subset_closure
protected lemma BddBelow.of_closure : BddBelow (closure s) → BddBelow s :=
BddBelow.mono subset_closure
end General
section ClosedIicTopology
section Preorder
variable [TopologicalSpace α] [Preorder α] [ClosedIicTopology α] {f : β → α} {a b : α} {s : Set α}
theorem isClosed_Iic : IsClosed (Iic a) :=
ClosedIicTopology.isClosed_Iic a
instance : ClosedIciTopology αᵒᵈ where
isClosed_Ici _ := isClosed_Iic (α := α)
@[simp]
theorem closure_Iic (a : α) : closure (Iic a) = Iic a :=
isClosed_Iic.closure_eq
theorem le_of_tendsto_of_frequently {x : Filter β} (lim : Tendsto f x (𝓝 a))
(h : ∃ᶠ c in x, f c ≤ b) : a ≤ b :=
isClosed_Iic.mem_of_frequently_of_tendsto h lim
theorem le_of_tendsto {x : Filter β} [NeBot x] (lim : Tendsto f x (𝓝 a))
(h : ∀ᶠ c in x, f c ≤ b) : a ≤ b :=
isClosed_Iic.mem_of_tendsto lim h
theorem le_of_tendsto' {x : Filter β} [NeBot x] (lim : Tendsto f x (𝓝 a))
(h : ∀ c, f c ≤ b) : a ≤ b :=
le_of_tendsto lim (Eventually.of_forall h)
@[simp] lemma upperBounds_closure (s : Set α) : upperBounds (closure s : Set α) = upperBounds s :=
ext fun a ↦ by simp_rw [mem_upperBounds_iff_subset_Iic, isClosed_Iic.closure_subset_iff]
@[simp] lemma bddAbove_closure : BddAbove (closure s) ↔ BddAbove s := by
simp_rw [BddAbove, upperBounds_closure]
protected alias ⟨_, BddAbove.closure⟩ := bddAbove_closure
@[simp]
theorem disjoint_nhds_atBot_iff : Disjoint (𝓝 a) atBot ↔ ¬IsBot a := by
constructor
· intro hd hbot
rw [hbot.atBot_eq, disjoint_principal_right] at hd
exact mem_of_mem_nhds hd le_rfl
· simp only [IsBot, not_forall]
rintro ⟨b, hb⟩
refine disjoint_of_disjoint_of_mem disjoint_compl_left ?_ (Iic_mem_atBot b)
exact isClosed_Iic.isOpen_compl.mem_nhds hb
theorem IsLUB.range_of_tendsto {F : Filter β} [F.NeBot] (hle : ∀ i, f i ≤ a)
(hlim : Tendsto f F (𝓝 a)) : IsLUB (range f) a :=
⟨forall_mem_range.mpr hle, fun _c hc ↦ le_of_tendsto' hlim fun i ↦ hc <| mem_range_self i⟩
end Preorder
section NoBotOrder
variable [Preorder α] [NoBotOrder α] [TopologicalSpace α] [ClosedIicTopology α] {a : α}
{l : Filter β} [NeBot l] {f : β → α}
theorem disjoint_nhds_atBot (a : α) : Disjoint (𝓝 a) atBot := by simp
@[simp]
theorem inf_nhds_atBot (a : α) : 𝓝 a ⊓ atBot = ⊥ := (disjoint_nhds_atBot a).eq_bot
theorem not_tendsto_nhds_of_tendsto_atBot (hf : Tendsto f l atBot) (a : α) : ¬Tendsto f l (𝓝 a) :=
hf.not_tendsto (disjoint_nhds_atBot a).symm
theorem not_tendsto_atBot_of_tendsto_nhds (hf : Tendsto f l (𝓝 a)) : ¬Tendsto f l atBot :=
hf.not_tendsto (disjoint_nhds_atBot a)
end NoBotOrder
theorem iSup_eq_of_forall_le_of_tendsto {ι : Type*} {F : Filter ι} [Filter.NeBot F]
[ConditionallyCompleteLattice α] [TopologicalSpace α] [ClosedIicTopology α]
{a : α} {f : ι → α} (hle : ∀ i, f i ≤ a) (hlim : Filter.Tendsto f F (𝓝 a)) :
⨆ i, f i = a :=
have := F.nonempty_of_neBot
(IsLUB.range_of_tendsto hle hlim).ciSup_eq
theorem iUnion_Iic_eq_Iio_of_lt_of_tendsto {ι : Type*} {F : Filter ι} [F.NeBot]
[ConditionallyCompleteLinearOrder α] [TopologicalSpace α] [ClosedIicTopology α]
{a : α} {f : ι → α} (hlt : ∀ i, f i < a) (hlim : Tendsto f F (𝓝 a)) :
⋃ i : ι, Iic (f i) = Iio a := by
have obs : a ∉ range f := by
rw [mem_range]
rintro ⟨i, rfl⟩
exact (hlt i).false
rw [← biUnion_range, (IsLUB.range_of_tendsto (le_of_lt <| hlt ·) hlim).biUnion_Iic_eq_Iio obs]
section LinearOrder
| variable [TopologicalSpace α] [LinearOrder α] [ClosedIicTopology α] [TopologicalSpace β]
{a b c : α} {f : α → β}
| Mathlib/Topology/Order/OrderClosed.lean | 193 | 195 |
/-
Copyright (c) 2024 Johan Commelin. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johan Commelin
-/
import Mathlib.Algebra.MvPolynomial.Monad
import Mathlib.LinearAlgebra.Charpoly.ToMatrix
import Mathlib.LinearAlgebra.FreeModule.StrongRankCondition
import Mathlib.LinearAlgebra.Matrix.Charpoly.Univ
import Mathlib.RingTheory.TensorProduct.Finite
import Mathlib.RingTheory.TensorProduct.Free
/-!
# Characteristic polynomials of linear families of endomorphisms
The coefficients of the characteristic polynomials of a linear family of endomorphisms
are homogeneous polynomials in the parameters.
This result is used in Lie theory
to establish the existence of regular elements and Cartan subalgebras,
and ultimately a well-defined notion of rank for Lie algebras.
In this file we prove this result about characteristic polynomials.
Let `L` and `M` be modules over a nontrivial commutative ring `R`,
and let `φ : L →ₗ[R] Module.End R M` be a linear map.
Let `b` be a basis of `L`, indexed by `ι`.
Then we define a multivariate polynomial with variables indexed by `ι`
that evaluates on elements `x` of `L` to the characteristic polynomial of `φ x`.
## Main declarations
* `Matrix.toMvPolynomial M i`: the family of multivariate polynomials that evaluates on `c : n → R`
to the dot product of the `i`-th row of `M` with `c`.
`Matrix.toMvPolynomial M i` is the sum of the monomials `C (M i j) * X j`.
* `LinearMap.toMvPolynomial b₁ b₂ f`: a version of `Matrix.toMvPolynomial` for linear maps `f`
with respect to bases `b₁` and `b₂` of the domain and codomain.
* `LinearMap.polyCharpoly`: the multivariate polynomial that evaluates on elements `x` of `L`
to the characteristic polynomial of `φ x`.
* `LinearMap.polyCharpoly_map_eq_charpoly`: the evaluation of `polyCharpoly` on elements `x` of `L`
is the characteristic polynomial of `φ x`.
* `LinearMap.polyCharpoly_coeff_isHomogeneous`: the coefficients of `polyCharpoly`
are homogeneous polynomials in the parameters.
* `LinearMap.nilRank`: the smallest index at which `polyCharpoly` has a non-zero coefficient,
which is independent of the choice of basis for `L`.
* `LinearMap.IsNilRegular`: an element `x` of `L` is *nil-regular* with respect to `φ`
if the `n`-th coefficient of the characteristic polynomial of `φ x` is non-zero,
where `n` denotes the nil-rank of `φ`.
## Implementation details
We show that `LinearMap.polyCharpoly` does not depend on the choice of basis of the target module.
This is done via `LinearMap.polyCharpoly_eq_polyCharpolyAux`
and `LinearMap.polyCharpolyAux_basisIndep`.
The latter is proven by considering
the base change of the `R`-linear map `φ : L →ₗ[R] End R M`
to the multivariate polynomial ring `MvPolynomial ι R`,
and showing that `polyCharpolyAux φ` is equal to the characteristic polynomial of this base change.
The proof concludes because characteristic polynomials are independent of the chosen basis.
## References
* [barnes1967]: "On Cartan subalgebras of Lie algebras" by D.W. Barnes.
-/
open scoped Matrix
namespace Matrix
variable {m n o R S : Type*}
variable [Fintype n] [Fintype o] [CommSemiring R] [CommSemiring S]
open MvPolynomial
/-- Let `M` be an `(m × n)`-matrix over `R`.
Then `Matrix.toMvPolynomial M` is the family (indexed by `i : m`)
of multivariate polynomials in `n` variables over `R` that evaluates on `c : n → R`
to the dot product of the `i`-th row of `M` with `c`:
`Matrix.toMvPolynomial M i` is the sum of the monomials `C (M i j) * X j`. -/
noncomputable
def toMvPolynomial (M : Matrix m n R) (i : m) : MvPolynomial n R :=
∑ j, monomial (.single j 1) (M i j)
lemma toMvPolynomial_eval_eq_apply (M : Matrix m n R) (i : m) (c : n → R) :
eval c (M.toMvPolynomial i) = (M *ᵥ c) i := by
simp only [toMvPolynomial, map_sum, eval_monomial, pow_zero, Finsupp.prod_single_index, pow_one,
mulVec, dotProduct]
lemma toMvPolynomial_map (f : R →+* S) (M : Matrix m n R) (i : m) :
(M.map f).toMvPolynomial i = MvPolynomial.map f (M.toMvPolynomial i) := by
simp only [toMvPolynomial, map_apply, map_sum, map_monomial]
lemma toMvPolynomial_isHomogeneous (M : Matrix m n R) (i : m) :
(M.toMvPolynomial i).IsHomogeneous 1 := by
apply MvPolynomial.IsHomogeneous.sum
rintro j -
apply MvPolynomial.isHomogeneous_monomial _ _
simp [Finsupp.degree, Finsupp.support_single_ne_zero _ one_ne_zero, Finset.sum_singleton,
Finsupp.single_eq_same]
lemma toMvPolynomial_totalDegree_le (M : Matrix m n R) (i : m) :
(M.toMvPolynomial i).totalDegree ≤ 1 := by
apply (toMvPolynomial_isHomogeneous _ _).totalDegree_le
@[simp]
lemma toMvPolynomial_constantCoeff (M : Matrix m n R) (i : m) :
constantCoeff (M.toMvPolynomial i) = 0 := by
simp only [toMvPolynomial, ← C_mul_X_eq_monomial, map_sum, map_mul, constantCoeff_X,
mul_zero, Finset.sum_const_zero]
@[simp]
lemma toMvPolynomial_zero : (0 : Matrix m n R).toMvPolynomial = 0 := by
ext; simp only [toMvPolynomial, zero_apply, map_zero, Finset.sum_const_zero, Pi.zero_apply]
@[simp]
lemma toMvPolynomial_one [DecidableEq n] : (1 : Matrix n n R).toMvPolynomial = X := by
ext i : 1
rw [toMvPolynomial, Finset.sum_eq_single i]
· simp only [one_apply_eq, ← C_mul_X_eq_monomial, C_1, one_mul]
· rintro j - hj
simp only [one_apply_ne hj.symm, map_zero]
· intro h
exact (h (Finset.mem_univ _)).elim
lemma toMvPolynomial_add (M N : Matrix m n R) :
(M + N).toMvPolynomial = M.toMvPolynomial + N.toMvPolynomial := by
ext i : 1
simp only [toMvPolynomial, add_apply, map_add, Finset.sum_add_distrib, Pi.add_apply]
lemma toMvPolynomial_mul (M : Matrix m n R) (N : Matrix n o R) (i : m) :
(M * N).toMvPolynomial i = bind₁ N.toMvPolynomial (M.toMvPolynomial i) := by
simp only [toMvPolynomial, mul_apply, map_sum, Finset.sum_comm (γ := o), bind₁, aeval,
AlgHom.coe_mk, coe_eval₂Hom, eval₂_monomial, algebraMap_apply, Algebra.id.map_eq_id,
RingHom.id_apply, C_apply, pow_zero, Finsupp.prod_single_index, pow_one, Finset.mul_sum,
monomial_mul, zero_add]
end Matrix
namespace LinearMap
open MvPolynomial
section
variable {R M₁ M₂ ι₁ ι₂ : Type*}
variable [CommRing R] [AddCommGroup M₁] [AddCommGroup M₂]
variable [Module R M₁] [Module R M₂]
variable [Fintype ι₁] [Finite ι₂]
variable [DecidableEq ι₁]
variable (b₁ : Basis ι₁ R M₁) (b₂ : Basis ι₂ R M₂)
/-- Let `f : M₁ →ₗ[R] M₂` be an `R`-linear map
between modules `M₁` and `M₂` with bases `b₁` and `b₂` respectively.
Then `LinearMap.toMvPolynomial b₁ b₂ f` is the family of multivariate polynomials over `R`
that evaluates on an element `x` of `M₁` (represented on the basis `b₁`)
to the element `f x` of `M₂` (represented on the basis `b₂`). -/
noncomputable
def toMvPolynomial (f : M₁ →ₗ[R] M₂) (i : ι₂) :
MvPolynomial ι₁ R :=
(toMatrix b₁ b₂ f).toMvPolynomial i
lemma toMvPolynomial_eval_eq_apply (f : M₁ →ₗ[R] M₂) (i : ι₂) (c : ι₁ →₀ R) :
eval c (f.toMvPolynomial b₁ b₂ i) = b₂.repr (f (b₁.repr.symm c)) i := by
rw [toMvPolynomial, Matrix.toMvPolynomial_eval_eq_apply,
← LinearMap.toMatrix_mulVec_repr b₁ b₂, LinearEquiv.apply_symm_apply]
open Algebra.TensorProduct in
lemma toMvPolynomial_baseChange (f : M₁ →ₗ[R] M₂) (i : ι₂) (A : Type*) [CommRing A] [Algebra R A] :
(f.baseChange A).toMvPolynomial (basis A b₁) (basis A b₂) i =
MvPolynomial.map (algebraMap R A) (f.toMvPolynomial b₁ b₂ i) := by
simp only [toMvPolynomial, toMatrix_baseChange, Matrix.toMvPolynomial_map]
lemma toMvPolynomial_isHomogeneous (f : M₁ →ₗ[R] M₂) (i : ι₂) :
(f.toMvPolynomial b₁ b₂ i).IsHomogeneous 1 :=
Matrix.toMvPolynomial_isHomogeneous _ _
lemma toMvPolynomial_totalDegree_le (f : M₁ →ₗ[R] M₂) (i : ι₂) :
(f.toMvPolynomial b₁ b₂ i).totalDegree ≤ 1 :=
Matrix.toMvPolynomial_totalDegree_le _ _
@[simp]
lemma toMvPolynomial_constantCoeff (f : M₁ →ₗ[R] M₂) (i : ι₂) :
constantCoeff (f.toMvPolynomial b₁ b₂ i) = 0 :=
Matrix.toMvPolynomial_constantCoeff _ _
@[simp]
lemma toMvPolynomial_zero : (0 : M₁ →ₗ[R] M₂).toMvPolynomial b₁ b₂ = 0 := by
unfold toMvPolynomial; simp only [map_zero, Matrix.toMvPolynomial_zero]
@[simp]
lemma toMvPolynomial_id : (id : M₁ →ₗ[R] M₁).toMvPolynomial b₁ b₁ = X := by
unfold toMvPolynomial; simp only [toMatrix_id, Matrix.toMvPolynomial_one]
lemma toMvPolynomial_add (f g : M₁ →ₗ[R] M₂) :
(f + g).toMvPolynomial b₁ b₂ = f.toMvPolynomial b₁ b₂ + g.toMvPolynomial b₁ b₂ := by
unfold toMvPolynomial; simp only [map_add, Matrix.toMvPolynomial_add]
end
variable {R M₁ M₂ M₃ ι₁ ι₂ ι₃ : Type*}
variable [CommRing R] [AddCommGroup M₁] [AddCommGroup M₂] [AddCommGroup M₃]
variable [Module R M₁] [Module R M₂] [Module R M₃]
variable [Fintype ι₁] [Fintype ι₂] [Finite ι₃]
variable [DecidableEq ι₁] [DecidableEq ι₂]
variable (b₁ : Basis ι₁ R M₁) (b₂ : Basis ι₂ R M₂) (b₃ : Basis ι₃ R M₃)
lemma toMvPolynomial_comp (g : M₂ →ₗ[R] M₃) (f : M₁ →ₗ[R] M₂) (i : ι₃) :
(g ∘ₗ f).toMvPolynomial b₁ b₃ i =
bind₁ (f.toMvPolynomial b₁ b₂) (g.toMvPolynomial b₂ b₃ i) := by
simp only [toMvPolynomial, toMatrix_comp b₁ b₂ b₃, Matrix.toMvPolynomial_mul]
rfl
end LinearMap
variable {R L M n ι ι' ιM : Type*}
variable [CommRing R] [AddCommGroup L] [Module R L] [AddCommGroup M] [Module R M]
variable (φ : L →ₗ[R] Module.End R M)
variable [Fintype ι] [Fintype ι'] [Fintype ιM] [DecidableEq ι] [DecidableEq ι']
namespace LinearMap
section aux
variable [DecidableEq ιM] (b : Basis ι R L) (bₘ : Basis ιM R M)
open Matrix
/-- (Implementation detail, see `LinearMap.polyCharpoly`.)
Let `L` and `M` be finite free modules over `R`,
and let `φ : L →ₗ[R] Module.End R M` be a linear map.
Let `b` be a basis of `L` and `bₘ` a basis of `M`.
Then `LinearMap.polyCharpolyAux φ b bₘ` is the polynomial that evaluates on elements `x` of `L`
to the characteristic polynomial of `φ x` acting on `M`.
This definition does not depend on the choice of `bₘ`
(see `LinearMap.polyCharpolyAux_basisIndep`). -/
noncomputable
def polyCharpolyAux : Polynomial (MvPolynomial ι R) :=
(charpoly.univ R ιM).map <| MvPolynomial.bind₁ (φ.toMvPolynomial b bₘ.end)
open Algebra.TensorProduct MvPolynomial in
lemma polyCharpolyAux_baseChange (A : Type*) [CommRing A] [Algebra R A] :
polyCharpolyAux (tensorProduct _ _ _ _ ∘ₗ φ.baseChange A) (basis A b) (basis A bₘ) =
(polyCharpolyAux φ b bₘ).map (MvPolynomial.map (algebraMap R A)) := by
simp only [polyCharpolyAux]
rw [← charpoly.univ_map_map _ (algebraMap R A)]
simp only [Polynomial.map_map]
congr 1
apply ringHom_ext
· intro r
simp only [RingHom.coe_comp, RingHom.coe_coe, Function.comp_apply, map_C, bind₁_C_right]
· rintro ij
simp only [RingHom.coe_comp, RingHom.coe_coe, Function.comp_apply, map_X, bind₁_X_right]
classical
rw [toMvPolynomial_comp _ (basis A (Basis.end bₘ)), ← toMvPolynomial_baseChange]
suffices toMvPolynomial (M₂ := (Module.End A (TensorProduct R A M)))
(basis A bₘ.end) (basis A bₘ).end (tensorProduct R A M M) ij = X ij by
rw [this, bind₁_X_right]
simp only [toMvPolynomial, Matrix.toMvPolynomial]
suffices ∀ kl,
(toMatrix (basis A bₘ.end) (basis A bₘ).end) (tensorProduct R A M M) ij kl =
if kl = ij then 1 else 0 by
rw [Finset.sum_eq_single ij]
· rw [this, if_pos rfl, X]
· rintro kl - H
rw [this, if_neg H, map_zero]
· intro h
exact (h (Finset.mem_univ _)).elim
intro kl
rw [toMatrix_apply, tensorProduct, TensorProduct.AlgebraTensorModule.lift_apply,
basis_apply, TensorProduct.lift.tmul, coe_restrictScalars]
dsimp only [coe_mk, AddHom.coe_mk, smul_apply, baseChangeHom_apply]
rw [one_smul, Basis.baseChange_end, Basis.repr_self_apply]
open LinearMap in
lemma polyCharpolyAux_map_eq_toMatrix_charpoly (x : L) :
(polyCharpolyAux φ b bₘ).map (MvPolynomial.eval (b.repr x)) =
(toMatrix bₘ bₘ (φ x)).charpoly := by
rw [polyCharpolyAux, Polynomial.map_map, ← MvPolynomial.eval₂Hom_C_eq_bind₁,
MvPolynomial.comp_eval₂Hom, charpoly.univ_map_eval₂Hom]
congr
ext
rw [of_apply, Function.curry_apply, toMvPolynomial_eval_eq_apply, LinearEquiv.symm_apply_apply]
rfl
open LinearMap in
lemma polyCharpolyAux_eval_eq_toMatrix_charpoly_coeff (x : L) (i : ℕ) :
MvPolynomial.eval (b.repr x) ((polyCharpolyAux φ b bₘ).coeff i) =
(toMatrix bₘ bₘ (φ x)).charpoly.coeff i := by
simp [← polyCharpolyAux_map_eq_toMatrix_charpoly φ b bₘ x]
@[simp]
lemma polyCharpolyAux_map_eq_charpoly [Module.Finite R M] [Module.Free R M]
(x : L) :
(polyCharpolyAux φ b bₘ).map (MvPolynomial.eval (b.repr x)) = (φ x).charpoly := by
nontriviality R
rw [polyCharpolyAux_map_eq_toMatrix_charpoly, LinearMap.charpoly_toMatrix]
@[simp]
lemma polyCharpolyAux_coeff_eval [Module.Finite R M] [Module.Free R M] (x : L) (i : ℕ) :
MvPolynomial.eval (b.repr x) ((polyCharpolyAux φ b bₘ).coeff i) = (φ x).charpoly.coeff i := by
nontriviality R
rw [← polyCharpolyAux_map_eq_charpoly φ b bₘ x, Polynomial.coeff_map]
lemma polyCharpolyAux_map_eval [Module.Finite R M] [Module.Free R M]
(x : ι → R) :
(polyCharpolyAux φ b bₘ).map (MvPolynomial.eval x) =
(φ (b.repr.symm (Finsupp.equivFunOnFinite.symm x))).charpoly := by
simp only [← polyCharpolyAux_map_eq_charpoly φ b bₘ, LinearEquiv.apply_symm_apply,
Finsupp.equivFunOnFinite, Equiv.coe_fn_symm_mk, Finsupp.coe_mk]
open Algebra.TensorProduct TensorProduct in
lemma polyCharpolyAux_map_aeval
(A : Type*) [CommRing A] [Algebra R A] [Module.Finite A (A ⊗[R] M)] [Module.Free A (A ⊗[R] M)]
(x : ι → A) :
(polyCharpolyAux φ b bₘ).map (MvPolynomial.aeval x).toRingHom =
LinearMap.charpoly ((tensorProduct R A M M).comp (baseChange A φ)
((basis A b).repr.symm (Finsupp.equivFunOnFinite.symm x))) := by
rw [← polyCharpolyAux_map_eval (tensorProduct R A M M ∘ₗ baseChange A φ) _ (basis A bₘ),
polyCharpolyAux_baseChange, Polynomial.map_map]
congr
exact DFunLike.ext _ _ fun f ↦ (MvPolynomial.eval_map (algebraMap R A) x f).symm
open Algebra.TensorProduct MvPolynomial in
/-- `LinearMap.polyCharpolyAux` is independent of the choice of basis of the target module.
Proof strategy:
1. Rewrite `polyCharpolyAux` as the (honest, ordinary) characteristic polynomial
of the basechange of `φ` to the multivariate polynomial ring `MvPolynomial ι R`.
2. Use that the characteristic polynomial of a linear map is independent of the choice of basis.
This independence result is used transitively via
`LinearMap.polyCharpolyAux_map_aeval` and `LinearMap.polyCharpolyAux_map_eq_charpoly`. -/
lemma polyCharpolyAux_basisIndep {ιM' : Type*} [Fintype ιM'] [DecidableEq ιM']
(bₘ' : Basis ιM' R M) :
polyCharpolyAux φ b bₘ = polyCharpolyAux φ b bₘ' := by
let f : Polynomial (MvPolynomial ι R) → Polynomial (MvPolynomial ι R) :=
Polynomial.map (MvPolynomial.aeval X).toRingHom
have hf : Function.Injective f := by
simp only [f, aeval_X_left, AlgHom.toRingHom_eq_coe, AlgHom.id_toRingHom, Polynomial.map_id]
exact Polynomial.map_injective (RingHom.id _) Function.injective_id
apply hf
let _h1 : Module.Finite (MvPolynomial ι R) (TensorProduct R (MvPolynomial ι R) M) :=
Module.Finite.of_basis (basis (MvPolynomial ι R) bₘ)
let _h2 : Module.Free (MvPolynomial ι R) (TensorProduct R (MvPolynomial ι R) M) :=
Module.Free.of_basis (basis (MvPolynomial ι R) bₘ)
simp only [f, polyCharpolyAux_map_aeval, polyCharpolyAux_map_aeval]
end aux
open Module Matrix
variable [Module.Free R M] [Module.Finite R M] (b : Basis ι R L)
/-- Let `L` and `M` be finite free modules over `R`,
and let `φ : L →ₗ[R] Module.End R M` be a linear family of endomorphisms.
Let `b` be a basis of `L` and `bₘ` a basis of `M`.
Then `LinearMap.polyCharpoly φ b` is the polynomial that evaluates on elements `x` of `L`
to the characteristic polynomial of `φ x` acting on `M`. -/
noncomputable
def polyCharpoly : Polynomial (MvPolynomial ι R) :=
φ.polyCharpolyAux b (Module.Free.chooseBasis R M)
lemma polyCharpoly_eq_of_basis [DecidableEq ιM] (bₘ : Basis ιM R M) :
polyCharpoly φ b =
(charpoly.univ R ιM).map (MvPolynomial.bind₁ (φ.toMvPolynomial b bₘ.end)) := by
rw [polyCharpoly, φ.polyCharpolyAux_basisIndep b (Module.Free.chooseBasis R M) bₘ,
polyCharpolyAux]
lemma polyCharpoly_monic : (polyCharpoly φ b).Monic :=
(charpoly.univ_monic R _).map _
lemma polyCharpoly_ne_zero [Nontrivial R] : (polyCharpoly φ b) ≠ 0 :=
(polyCharpoly_monic _ _).ne_zero
@[simp]
lemma polyCharpoly_natDegree [Nontrivial R] :
(polyCharpoly φ b).natDegree = finrank R M := by
rw [polyCharpoly, polyCharpolyAux, (charpoly.univ_monic _ _).natDegree_map,
charpoly.univ_natDegree, finrank_eq_card_chooseBasisIndex]
lemma polyCharpoly_coeff_isHomogeneous (i j : ℕ) (hij : i + j = finrank R M) [Nontrivial R] :
((polyCharpoly φ b).coeff i).IsHomogeneous j := by
rw [finrank_eq_card_chooseBasisIndex] at hij
| rw [polyCharpoly, polyCharpolyAux, Polynomial.coeff_map, ← one_mul j]
apply (charpoly.univ_coeff_isHomogeneous _ _ _ _ hij).eval₂
· exact fun r ↦ MvPolynomial.isHomogeneous_C _ _
· exact LinearMap.toMvPolynomial_isHomogeneous _ _ _
open Algebra.TensorProduct MvPolynomial in
lemma polyCharpoly_baseChange (A : Type*) [CommRing A] [Algebra R A] :
| Mathlib/Algebra/Module/LinearMap/Polynomial.lean | 384 | 390 |
/-
Copyright (c) 2022 Joël Riou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joël Riou
-/
import Mathlib.AlgebraicTopology.SimplicialObject.Split
import Mathlib.AlgebraicTopology.DoldKan.PInfty
/-!
# Construction of the inverse functor of the Dold-Kan equivalence
In this file, we construct the functor `Γ₀ : ChainComplex C ℕ ⥤ SimplicialObject C`
which shall be the inverse functor of the Dold-Kan equivalence in the case of abelian categories,
and more generally pseudoabelian categories.
By definition, when `K` is a chain_complex, `Γ₀.obj K` is a simplicial object which
sends `Δ : SimplexCategoryᵒᵖ` to a certain coproduct indexed by the set
`Splitting.IndexSet Δ` whose elements consists of epimorphisms `e : Δ.unop ⟶ Δ'.unop`
(with `Δ' : SimplexCategoryᵒᵖ`); the summand attached to such an `e` is `K.X Δ'.unop.len`.
By construction, `Γ₀.obj K` is a split simplicial object whose splitting is `Γ₀.splitting K`.
We also construct `Γ₂ : Karoubi (ChainComplex C ℕ) ⥤ Karoubi (SimplicialObject C)`
which shall be an equivalence for any additive category `C`.
(See `Equivalence.lean` for the general strategy of proof of the Dold-Kan equivalence.)
-/
noncomputable section
open CategoryTheory CategoryTheory.Category CategoryTheory.Limits SimplexCategory
SimplicialObject Opposite CategoryTheory.Idempotents Simplicial DoldKan
namespace AlgebraicTopology
namespace DoldKan
variable {C : Type*} [Category C] [Preadditive C] (K K' : ChainComplex C ℕ) (f : K ⟶ K')
{Δ Δ' Δ'' : SimplexCategory}
/-- `Isδ₀ i` is a simple condition used to check whether a monomorphism `i` in
`SimplexCategory` identifies to the coface map `δ 0`. -/
@[nolint unusedArguments]
def Isδ₀ {Δ Δ' : SimplexCategory} (i : Δ' ⟶ Δ) [Mono i] : Prop :=
Δ.len = Δ'.len + 1 ∧ i.toOrderHom 0 ≠ 0
namespace Isδ₀
theorem iff {j : ℕ} {i : Fin (j + 2)} : Isδ₀ (SimplexCategory.δ i) ↔ i = 0 := by
constructor
· rintro ⟨_, h₂⟩
by_contra h
exact h₂ (Fin.succAbove_ne_zero_zero h)
· rintro rfl
exact ⟨rfl, by dsimp; exact Fin.succ_ne_zero (0 : Fin (j + 1))⟩
theorem eq_δ₀ {n : ℕ} {i : ⦋n⦌ ⟶ ⦋n + 1⦌} [Mono i] (hi : Isδ₀ i) :
i = SimplexCategory.δ 0 := by
obtain ⟨j, rfl⟩ := SimplexCategory.eq_δ_of_mono i
rw [iff] at hi
rw [hi]
end Isδ₀
namespace Γ₀
namespace Obj
/-- In the definition of `(Γ₀.obj K).obj Δ` as a direct sum indexed by `A : Splitting.IndexSet Δ`,
the summand `summand K Δ A` is `K.X A.1.len`. -/
def summand (Δ : SimplexCategoryᵒᵖ) (A : Splitting.IndexSet Δ) : C :=
K.X A.1.unop.len
/-- The functor `Γ₀` sends a chain complex `K` to the simplicial object which
sends `Δ` to the direct sum of the objects `summand K Δ A` for all `A : Splitting.IndexSet Δ` -/
def obj₂ (K : ChainComplex C ℕ) (Δ : SimplexCategoryᵒᵖ) [HasFiniteCoproducts C] : C :=
∐ fun A : Splitting.IndexSet Δ => summand K Δ A
namespace Termwise
/-- A monomorphism `i : Δ' ⟶ Δ` induces a morphism `K.X Δ.len ⟶ K.X Δ'.len` which
is the identity if `Δ = Δ'`, the differential on the complex `K` if `i = δ 0`, and
zero otherwise. -/
def mapMono (K : ChainComplex C ℕ) {Δ' Δ : SimplexCategory} (i : Δ' ⟶ Δ) [Mono i] :
K.X Δ.len ⟶ K.X Δ'.len := by
by_cases Δ = Δ'
· exact eqToHom (by congr)
· by_cases Isδ₀ i
· exact K.d Δ.len Δ'.len
· exact 0
variable (Δ) in
theorem mapMono_id : mapMono K (𝟙 Δ) = 𝟙 _ := by
unfold mapMono
simp only [eq_self_iff_true, eqToHom_refl, dite_eq_ite, if_true]
theorem mapMono_δ₀' (i : Δ' ⟶ Δ) [Mono i] (hi : Isδ₀ i) : mapMono K i = K.d Δ.len Δ'.len := by
unfold mapMono
suffices Δ ≠ Δ' by
simp only [dif_neg this, dif_pos hi]
rintro rfl
simpa only [left_eq_add, Nat.one_ne_zero] using hi.1
@[simp]
theorem mapMono_δ₀ {n : ℕ} : mapMono K (δ (0 : Fin (n + 2))) = K.d (n + 1) n :=
mapMono_δ₀' K _ (by rw [Isδ₀.iff])
theorem mapMono_eq_zero (i : Δ' ⟶ Δ) [Mono i] (h₁ : Δ ≠ Δ') (h₂ : ¬Isδ₀ i) : mapMono K i = 0 := by
unfold mapMono
rw [Ne] at h₁
split_ifs
rfl
variable {K K'}
@[reassoc (attr := simp)]
theorem mapMono_naturality (i : Δ ⟶ Δ') [Mono i] :
mapMono K i ≫ f.f Δ.len = f.f Δ'.len ≫ mapMono K' i := by
unfold mapMono
split_ifs with h
· subst h
simp only [id_comp, eqToHom_refl, comp_id]
· rw [HomologicalComplex.Hom.comm]
· rw [zero_comp, comp_zero]
variable (K)
@[reassoc (attr := simp)]
theorem mapMono_comp (i' : Δ'' ⟶ Δ') (i : Δ' ⟶ Δ) [Mono i'] [Mono i] :
mapMono K i ≫ mapMono K i' = mapMono K (i' ≫ i) := by
-- case where i : Δ' ⟶ Δ is the identity
by_cases h₁ : Δ = Δ'
· subst h₁
simp only [SimplexCategory.eq_id_of_mono i, comp_id, id_comp, mapMono_id K, eqToHom_refl]
-- case where i' : Δ'' ⟶ Δ' is the identity
by_cases h₂ : Δ' = Δ''
· subst h₂
simp only [SimplexCategory.eq_id_of_mono i', comp_id, id_comp, mapMono_id K, eqToHom_refl]
-- then the RHS is always zero
obtain ⟨k, hk⟩ := Nat.exists_eq_add_of_lt (len_lt_of_mono i h₁)
obtain ⟨k', hk'⟩ := Nat.exists_eq_add_of_lt (len_lt_of_mono i' h₂)
have eq : Δ.len = Δ''.len + (k + k' + 2) := by omega
rw [mapMono_eq_zero K (i' ≫ i) _ _]; rotate_left
· by_contra h
simp only [left_eq_add, h, add_eq_zero, and_false, reduceCtorEq] at eq
· by_contra h
simp only [h.1, add_right_inj] at eq
omega
-- in all cases, the LHS is also zero, either by definition, or because d ≫ d = 0
by_cases h₃ : Isδ₀ i
· by_cases h₄ : Isδ₀ i'
· rw [mapMono_δ₀' K i h₃, mapMono_δ₀' K i' h₄, HomologicalComplex.d_comp_d]
· simp only [mapMono_eq_zero K i' h₂ h₄, comp_zero]
· simp only [mapMono_eq_zero K i h₁ h₃, zero_comp]
end Termwise
variable [HasFiniteCoproducts C]
/-- The simplicial morphism on the simplicial object `Γ₀.obj K` induced by
a morphism `Δ' → Δ` in `SimplexCategory` is defined on each summand
associated to an `A : Splitting.IndexSet Δ` in terms of the epi-mono factorisation
of `θ ≫ A.e`. -/
def map (K : ChainComplex C ℕ) {Δ' Δ : SimplexCategoryᵒᵖ} (θ : Δ ⟶ Δ') : obj₂ K Δ ⟶ obj₂ K Δ' :=
Sigma.desc fun A =>
Termwise.mapMono K (image.ι (θ.unop ≫ A.e)) ≫ Sigma.ι (summand K Δ') (A.pull θ)
@[reassoc]
theorem map_on_summand₀ {Δ Δ' : SimplexCategoryᵒᵖ} (A : Splitting.IndexSet Δ) {θ : Δ ⟶ Δ'}
{Δ'' : SimplexCategory} {e : Δ'.unop ⟶ Δ''} {i : Δ'' ⟶ A.1.unop} [Epi e] [Mono i]
(fac : e ≫ i = θ.unop ≫ A.e) :
Sigma.ι (summand K Δ) A ≫ map K θ =
Termwise.mapMono K i ≫ Sigma.ι (summand K Δ') (Splitting.IndexSet.mk e) := by
simp only [map, colimit.ι_desc, Cofan.mk_ι_app]
have h := SimplexCategory.image_eq fac
subst h
congr
· exact SimplexCategory.image_ι_eq fac
· dsimp only [SimplicialObject.Splitting.IndexSet.pull]
congr
exact SimplexCategory.factorThruImage_eq fac
@[reassoc]
theorem map_on_summand₀' {Δ Δ' : SimplexCategoryᵒᵖ} (A : Splitting.IndexSet Δ) (θ : Δ ⟶ Δ') :
Sigma.ι (summand K Δ) A ≫ map K θ =
Termwise.mapMono K (image.ι (θ.unop ≫ A.e)) ≫ Sigma.ι (summand K _) (A.pull θ) :=
map_on_summand₀ K A (A.fac_pull θ)
end Obj
variable [HasFiniteCoproducts C]
/-- The functor `Γ₀ : ChainComplex C ℕ ⥤ SimplicialObject C`, on objects. -/
@[simps]
def obj (K : ChainComplex C ℕ) : SimplicialObject C where
obj Δ := Obj.obj₂ K Δ
map θ := Obj.map K θ
map_id Δ := colimit.hom_ext (fun ⟨A⟩ => by
dsimp
have fac : A.e ≫ 𝟙 A.1.unop = (𝟙 Δ).unop ≫ A.e := by rw [unop_id, comp_id, id_comp]
rw [Obj.map_on_summand₀ K A fac, Obj.Termwise.mapMono_id, id_comp]
dsimp only [Obj.obj₂]
rw [comp_id]
rfl)
map_comp {Δ'' Δ' Δ} θ' θ := colimit.hom_ext (fun ⟨A⟩ => by
have fac : θ.unop ≫ θ'.unop ≫ A.e = (θ' ≫ θ).unop ≫ A.e := by rw [unop_comp, assoc]
rw [← image.fac (θ'.unop ≫ A.e), ← assoc, ←
image.fac (θ.unop ≫ factorThruImage (θ'.unop ≫ A.e)), assoc] at fac
simp only [Obj.map_on_summand₀'_assoc K A θ', Obj.map_on_summand₀' K _ θ,
Obj.Termwise.mapMono_comp_assoc, Obj.map_on_summand₀ K A fac]
rfl)
/-- By construction, the simplicial `Γ₀.obj K` is equipped with a splitting. -/
def splitting (K : ChainComplex C ℕ) : SimplicialObject.Splitting (Γ₀.obj K) where
N n := K.X n
ι n := Sigma.ι (Γ₀.Obj.summand K (op ⦋n⦌)) (Splitting.IndexSet.id (op ⦋n⦌))
isColimit' Δ := IsColimit.ofIsoColimit (colimit.isColimit _) (Cofan.ext (Iso.refl _) (by
intro A
dsimp [Splitting.cofan']
rw [comp_id, Γ₀.Obj.map_on_summand₀ K (SimplicialObject.Splitting.IndexSet.id A.1)
(show A.e ≫ 𝟙 _ = A.e.op.unop ≫ 𝟙 _ by rfl), Γ₀.Obj.Termwise.mapMono_id]
dsimp
rw [id_comp]
rfl))
@[reassoc]
theorem Obj.map_on_summand {Δ Δ' : SimplexCategoryᵒᵖ} (A : Splitting.IndexSet Δ) (θ : Δ ⟶ Δ')
{Δ'' : SimplexCategory} {e : Δ'.unop ⟶ Δ''} {i : Δ'' ⟶ A.1.unop} [Epi e] [Mono i]
(fac : e ≫ i = θ.unop ≫ A.e) :
((Γ₀.splitting K).cofan Δ).inj A ≫ (Γ₀.obj K).map θ =
Γ₀.Obj.Termwise.mapMono K i ≫ ((Γ₀.splitting K).cofan Δ').inj (Splitting.IndexSet.mk e) := by
dsimp [Splitting.cofan]
change (_ ≫ (Γ₀.obj K).map A.e.op) ≫ (Γ₀.obj K).map θ = _
rw [assoc, ← Functor.map_comp]
dsimp [splitting]
rw [Γ₀.Obj.map_on_summand₀ K (Splitting.IndexSet.id A.1)
(show e ≫ i = ((Splitting.IndexSet.e A).op ≫ θ).unop ≫ 𝟙 _ by rw [comp_id, fac]; rfl)]
dsimp only [Splitting.IndexSet.id_fst, Splitting.IndexSet.mk, op_unop, Splitting.IndexSet.e]
rw [Γ₀.Obj.map_on_summand₀ K (Splitting.IndexSet.id (op Δ''))
(show e ≫ 𝟙 Δ'' = e.op.unop ≫ 𝟙 _ by simp), Termwise.mapMono_id]
dsimp only [Splitting.IndexSet.id_fst]
rw [id_comp]
rfl
@[reassoc]
theorem Obj.map_on_summand' {Δ Δ' : SimplexCategoryᵒᵖ} (A : Splitting.IndexSet Δ) (θ : Δ ⟶ Δ') :
((splitting K).cofan Δ).inj A ≫ (obj K).map θ =
Obj.Termwise.mapMono K (image.ι (θ.unop ≫ A.e)) ≫
((splitting K).cofan Δ').inj (A.pull θ) := by
apply Obj.map_on_summand
apply image.fac
@[reassoc]
theorem Obj.mapMono_on_summand_id {Δ Δ' : SimplexCategory} (i : Δ' ⟶ Δ) [Mono i] :
((splitting K).cofan _).inj (Splitting.IndexSet.id (op Δ)) ≫ (obj K).map i.op =
Obj.Termwise.mapMono K i ≫ ((splitting K).cofan _).inj (Splitting.IndexSet.id (op Δ')) :=
Obj.map_on_summand K (Splitting.IndexSet.id (op Δ)) i.op (rfl : 𝟙 _ ≫ i = i ≫ 𝟙 _)
@[reassoc]
theorem Obj.map_epi_on_summand_id {Δ Δ' : SimplexCategory} (e : Δ' ⟶ Δ) [Epi e] :
((Γ₀.splitting K).cofan _).inj (Splitting.IndexSet.id (op Δ)) ≫ (Γ₀.obj K).map e.op =
((Γ₀.splitting K).cofan _).inj (Splitting.IndexSet.mk e) := by
simpa only [Γ₀.Obj.map_on_summand K (Splitting.IndexSet.id (op Δ)) e.op
(rfl : e ≫ 𝟙 Δ = e ≫ 𝟙 Δ),
Γ₀.Obj.Termwise.mapMono_id] using id_comp _
/-- The functor `Γ₀ : ChainComplex C ℕ ⥤ SimplicialObject C`, on morphisms. -/
@[simps]
def map {K K' : ChainComplex C ℕ} (f : K ⟶ K') : obj K ⟶ obj K' where
app Δ := (Γ₀.splitting K).desc Δ fun A => f.f A.1.unop.len ≫
((Γ₀.splitting K').cofan _).inj A
naturality {Δ' Δ} θ := by
apply (Γ₀.splitting K).hom_ext'
intro A
simp only [(splitting K).ι_desc_assoc, Obj.map_on_summand'_assoc K _ θ, (splitting K).ι_desc,
assoc, Obj.map_on_summand' K' _ θ]
apply Obj.Termwise.mapMono_naturality_assoc
end Γ₀
variable [HasFiniteCoproducts C]
/-- The functor `Γ₀' : ChainComplex C ℕ ⥤ SimplicialObject.Split C`
that induces `Γ₀ : ChainComplex C ℕ ⥤ SimplicialObject C`, which
shall be the inverse functor of the Dold-Kan equivalence for
abelian or pseudo-abelian categories. -/
@[simps]
def Γ₀' : ChainComplex C ℕ ⥤ SimplicialObject.Split C where
obj K := SimplicialObject.Split.mk' (Γ₀.splitting K)
map {K K'} f :=
{ F := Γ₀.map f
f := f.f
comm := fun n => by
dsimp
simp only [← Splitting.cofan_inj_id, (Γ₀.splitting K).ι_desc]
rfl }
/-- The functor `Γ₀ : ChainComplex C ℕ ⥤ SimplicialObject C`, which is
the inverse functor of the Dold-Kan equivalence when `C` is an abelian
category, or more generally a pseudoabelian category. -/
@[simps!]
def Γ₀ : ChainComplex C ℕ ⥤ SimplicialObject C :=
Γ₀' ⋙ Split.forget _
/-- The extension of `Γ₀ : ChainComplex C ℕ ⥤ SimplicialObject C`
on the idempotent completions. It shall be an equivalence of categories
for any additive category `C`. -/
@[simps!]
def Γ₂ : Karoubi (ChainComplex C ℕ) ⥤ Karoubi (SimplicialObject C) :=
(CategoryTheory.Idempotents.functorExtension₂ _ _).obj Γ₀
theorem HigherFacesVanish.on_Γ₀_summand_id (K : ChainComplex C ℕ) (n : ℕ) :
@HigherFacesVanish C _ _ (Γ₀.obj K) _ n (n + 1)
(((Γ₀.splitting K).cofan _).inj (Splitting.IndexSet.id (op ⦋n + 1⦌))) := by
intro j _
have eq := Γ₀.Obj.mapMono_on_summand_id K (SimplexCategory.δ j.succ)
rw [Γ₀.Obj.Termwise.mapMono_eq_zero K, zero_comp] at eq; rotate_left
· intro h
exact (Nat.succ_ne_self n) (congr_arg SimplexCategory.len h)
· exact fun h => Fin.succ_ne_zero j (by simpa only [Isδ₀.iff] using h)
exact eq
@[reassoc (attr := simp)]
theorem PInfty_on_Γ₀_splitting_summand_eq_self (K : ChainComplex C ℕ) {n : ℕ} :
((Γ₀.splitting K).cofan _).inj (Splitting.IndexSet.id (op ⦋n⦌)) ≫
(PInfty : K[Γ₀.obj K] ⟶ _).f n =
((Γ₀.splitting K).cofan _).inj (Splitting.IndexSet.id (op ⦋n⦌)) := by
rw [PInfty_f]
rcases n with _|n
· simpa only [P_f_0_eq] using comp_id _
· exact (HigherFacesVanish.on_Γ₀_summand_id K n).comp_P_eq_self
end DoldKan
end AlgebraicTopology
| Mathlib/AlgebraicTopology/DoldKan/FunctorGamma.lean | 339 | 348 | |
/-
Copyright (c) 2022 Heather Macbeth. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Heather Macbeth
-/
import Mathlib.Analysis.InnerProductSpace.Dual
import Mathlib.Analysis.InnerProductSpace.Orientation
import Mathlib.Data.Complex.FiniteDimensional
import Mathlib.Data.Complex.Orientation
import Mathlib.Tactic.LinearCombination
/-!
# Oriented two-dimensional real inner product spaces
This file defines constructions specific to the geometry of an oriented two-dimensional real inner
product space `E`.
## Main declarations
* `Orientation.areaForm`: an antisymmetric bilinear form `E →ₗ[ℝ] E →ₗ[ℝ] ℝ` (usual notation `ω`).
Morally, when `ω` is evaluated on two vectors, it gives the oriented area of the parallelogram
they span. (But mathlib does not yet have a construction of oriented area, and in fact the
construction of oriented area should pass through `ω`.)
* `Orientation.rightAngleRotation`: an isometric automorphism `E ≃ₗᵢ[ℝ] E` (usual notation `J`).
This automorphism squares to -1. In a later file, rotations (`Orientation.rotation`) are defined,
in such a way that this automorphism is equal to rotation by 90 degrees.
* `Orientation.basisRightAngleRotation`: for a nonzero vector `x` in `E`, the basis `![x, J x]`
for `E`.
* `Orientation.kahler`: a complex-valued real-bilinear map `E →ₗ[ℝ] E →ₗ[ℝ] ℂ`. Its real part is the
inner product and its imaginary part is `Orientation.areaForm`. For vectors `x` and `y` in `E`,
the complex number `o.kahler x y` has modulus `‖x‖ * ‖y‖`. In a later file, oriented angles
(`Orientation.oangle`) are defined, in such a way that the argument of `o.kahler x y` is the
oriented angle from `x` to `y`.
## Main results
* `Orientation.rightAngleRotation_rightAngleRotation`: the identity `J (J x) = - x`
* `Orientation.nonneg_inner_and_areaForm_eq_zero_iff_sameRay`: `x`, `y` are in the same ray, if
and only if `0 ≤ ⟪x, y⟫` and `ω x y = 0`
* `Orientation.kahler_mul`: the identity `o.kahler x a * o.kahler a y = ‖a‖ ^ 2 * o.kahler x y`
* `Complex.areaForm`, `Complex.rightAngleRotation`, `Complex.kahler`: the concrete
interpretations of `areaForm`, `rightAngleRotation`, `kahler` for the oriented real inner
product space `ℂ`
* `Orientation.areaForm_map_complex`, `Orientation.rightAngleRotation_map_complex`,
`Orientation.kahler_map_complex`: given an orientation-preserving isometry from `E` to `ℂ`,
expressions for `areaForm`, `rightAngleRotation`, `kahler` as the pullback of their concrete
interpretations on `ℂ`
## Implementation notes
Notation `ω` for `Orientation.areaForm` and `J` for `Orientation.rightAngleRotation` should be
defined locally in each file which uses them, since otherwise one would need a more cumbersome
notation which mentions the orientation explicitly (something like `ω[o]`). Write
```
local notation "ω" => o.areaForm
local notation "J" => o.rightAngleRotation
```
-/
noncomputable section
open scoped RealInnerProductSpace ComplexConjugate
open Module
lemma FiniteDimensional.of_fact_finrank_eq_two {K V : Type*} [DivisionRing K]
[AddCommGroup V] [Module K V] [Fact (finrank K V = 2)] : FiniteDimensional K V :=
.of_fact_finrank_eq_succ 1
attribute [local instance] FiniteDimensional.of_fact_finrank_eq_two
variable {E : Type*} [NormedAddCommGroup E] [InnerProductSpace ℝ E] [Fact (finrank ℝ E = 2)]
(o : Orientation ℝ E (Fin 2))
namespace Orientation
/-- An antisymmetric bilinear form on an oriented real inner product space of dimension 2 (usual
notation `ω`). When evaluated on two vectors, it gives the oriented area of the parallelogram they
span. -/
irreducible_def areaForm : E →ₗ[ℝ] E →ₗ[ℝ] ℝ := by
let z : E [⋀^Fin 0]→ₗ[ℝ] ℝ ≃ₗ[ℝ] ℝ :=
AlternatingMap.constLinearEquivOfIsEmpty.symm
let y : E [⋀^Fin 1]→ₗ[ℝ] ℝ →ₗ[ℝ] E →ₗ[ℝ] ℝ :=
LinearMap.llcomp ℝ E (E [⋀^Fin 0]→ₗ[ℝ] ℝ) ℝ z ∘ₗ AlternatingMap.curryLeftLinearMap
exact y ∘ₗ AlternatingMap.curryLeftLinearMap (R' := ℝ) o.volumeForm
local notation "ω" => o.areaForm
theorem areaForm_to_volumeForm (x y : E) : ω x y = o.volumeForm ![x, y] := by simp [areaForm]
@[simp]
theorem areaForm_apply_self (x : E) : ω x x = 0 := by
rw [areaForm_to_volumeForm]
refine o.volumeForm.map_eq_zero_of_eq ![x, x] ?_ (?_ : (0 : Fin 2) ≠ 1)
· simp
· norm_num
theorem areaForm_swap (x y : E) : ω x y = -ω y x := by
simp only [areaForm_to_volumeForm]
convert o.volumeForm.map_swap ![y, x] (_ : (0 : Fin 2) ≠ 1)
· ext i
fin_cases i <;> rfl
· norm_num
@[simp]
theorem areaForm_neg_orientation : (-o).areaForm = -o.areaForm := by
ext x y
simp [areaForm_to_volumeForm]
/-- Continuous linear map version of `Orientation.areaForm`, useful for calculus. -/
def areaForm' : E →L[ℝ] E →L[ℝ] ℝ :=
LinearMap.toContinuousLinearMap
(↑(LinearMap.toContinuousLinearMap : (E →ₗ[ℝ] ℝ) ≃ₗ[ℝ] E →L[ℝ] ℝ) ∘ₗ o.areaForm)
@[simp]
theorem areaForm'_apply (x : E) :
o.areaForm' x = LinearMap.toContinuousLinearMap (o.areaForm x) :=
rfl
theorem abs_areaForm_le (x y : E) : |ω x y| ≤ ‖x‖ * ‖y‖ := by
simpa [areaForm_to_volumeForm, Fin.prod_univ_succ] using o.abs_volumeForm_apply_le ![x, y]
theorem areaForm_le (x y : E) : ω x y ≤ ‖x‖ * ‖y‖ := by
simpa [areaForm_to_volumeForm, Fin.prod_univ_succ] using o.volumeForm_apply_le ![x, y]
theorem abs_areaForm_of_orthogonal {x y : E} (h : ⟪x, y⟫ = 0) : |ω x y| = ‖x‖ * ‖y‖ := by
rw [o.areaForm_to_volumeForm, o.abs_volumeForm_apply_of_pairwise_orthogonal]
· simp [Fin.prod_univ_succ]
intro i j hij
fin_cases i <;> fin_cases j
· simp_all
· simpa using h
· simpa [real_inner_comm] using h
· simp_all
theorem areaForm_map {F : Type*} [NormedAddCommGroup F] [InnerProductSpace ℝ F]
[hF : Fact (finrank ℝ F = 2)] (φ : E ≃ₗᵢ[ℝ] F) (x y : F) :
(Orientation.map (Fin 2) φ.toLinearEquiv o).areaForm x y =
o.areaForm (φ.symm x) (φ.symm y) := by
have : φ.symm ∘ ![x, y] = ![φ.symm x, φ.symm y] := by
ext i
fin_cases i <;> rfl
simp [areaForm_to_volumeForm, volumeForm_map, this]
/-- The area form is invariant under pullback by a positively-oriented isometric automorphism. -/
theorem areaForm_comp_linearIsometryEquiv (φ : E ≃ₗᵢ[ℝ] E)
(hφ : 0 < LinearMap.det (φ.toLinearEquiv : E →ₗ[ℝ] E)) (x y : E) :
o.areaForm (φ x) (φ y) = o.areaForm x y := by
convert o.areaForm_map φ (φ x) (φ y)
· symm
rwa [← o.map_eq_iff_det_pos φ.toLinearEquiv] at hφ
rw [@Fact.out (finrank ℝ E = 2), Fintype.card_fin]
· simp
· simp
/-- Auxiliary construction for `Orientation.rightAngleRotation`, rotation by 90 degrees in an
oriented real inner product space of dimension 2. -/
irreducible_def rightAngleRotationAux₁ : E →ₗ[ℝ] E :=
let to_dual : E ≃ₗ[ℝ] E →ₗ[ℝ] ℝ :=
(InnerProductSpace.toDual ℝ E).toLinearEquiv ≪≫ₗ LinearMap.toContinuousLinearMap.symm
↑to_dual.symm ∘ₗ ω
@[simp]
theorem inner_rightAngleRotationAux₁_left (x y : E) : ⟪o.rightAngleRotationAux₁ x, y⟫ = ω x y := by
simp only [rightAngleRotationAux₁, LinearEquiv.trans_symm, LinearIsometryEquiv.toLinearEquiv_symm,
LinearMap.coe_comp, LinearEquiv.coe_coe, Function.comp_apply, LinearEquiv.trans_apply,
LinearIsometryEquiv.coe_toLinearEquiv]
rw [InnerProductSpace.toDual_symm_apply]
norm_cast
@[simp]
theorem inner_rightAngleRotationAux₁_right (x y : E) :
⟪x, o.rightAngleRotationAux₁ y⟫ = -ω x y := by
rw [real_inner_comm]
simp [o.areaForm_swap y x]
/-- Auxiliary construction for `Orientation.rightAngleRotation`, rotation by 90 degrees in an
oriented real inner product space of dimension 2. -/
def rightAngleRotationAux₂ : E →ₗᵢ[ℝ] E :=
{ o.rightAngleRotationAux₁ with
norm_map' := fun x => by
refine le_antisymm ?_ ?_
· rcases eq_or_lt_of_le (norm_nonneg (o.rightAngleRotationAux₁ x)) with h | h
· rw [← h]
positivity
refine le_of_mul_le_mul_right ?_ h
rw [← real_inner_self_eq_norm_mul_norm, o.inner_rightAngleRotationAux₁_left]
exact o.areaForm_le x (o.rightAngleRotationAux₁ x)
· let K : Submodule ℝ E := ℝ ∙ x
have : Nontrivial Kᗮ := by
apply nontrivial_of_finrank_pos (R := ℝ)
have : finrank ℝ K ≤ Finset.card {x} := by
rw [← Set.toFinset_singleton]
exact finrank_span_le_card ({x} : Set E)
have : Finset.card {x} = 1 := Finset.card_singleton x
have : finrank ℝ K + finrank ℝ Kᗮ = finrank ℝ E := K.finrank_add_finrank_orthogonal
have : finrank ℝ E = 2 := Fact.out
omega
obtain ⟨w, hw₀⟩ : ∃ w : Kᗮ, w ≠ 0 := exists_ne 0
have hw' : ⟪x, (w : E)⟫ = 0 := Submodule.mem_orthogonal_singleton_iff_inner_right.mp w.2
have hw : (w : E) ≠ 0 := fun h => hw₀ (Submodule.coe_eq_zero.mp h)
refine le_of_mul_le_mul_right ?_ (by rwa [norm_pos_iff] : 0 < ‖(w : E)‖)
rw [← o.abs_areaForm_of_orthogonal hw']
rw [← o.inner_rightAngleRotationAux₁_left x w]
exact abs_real_inner_le_norm (o.rightAngleRotationAux₁ x) w }
@[simp]
theorem rightAngleRotationAux₁_rightAngleRotationAux₁ (x : E) :
o.rightAngleRotationAux₁ (o.rightAngleRotationAux₁ x) = -x := by
apply ext_inner_left ℝ
intro y
have : ⟪o.rightAngleRotationAux₁ y, o.rightAngleRotationAux₁ x⟫ = ⟪y, x⟫ :=
LinearIsometry.inner_map_map o.rightAngleRotationAux₂ y x
rw [o.inner_rightAngleRotationAux₁_right, ← o.inner_rightAngleRotationAux₁_left, this,
inner_neg_right]
/-- An isometric automorphism of an oriented real inner product space of dimension 2 (usual notation
`J`). This automorphism squares to -1. We will define rotations in such a way that this
automorphism is equal to rotation by 90 degrees. -/
irreducible_def rightAngleRotation : E ≃ₗᵢ[ℝ] E :=
LinearIsometryEquiv.ofLinearIsometry o.rightAngleRotationAux₂ (-o.rightAngleRotationAux₁)
(by ext; simp [rightAngleRotationAux₂]) (by ext; simp [rightAngleRotationAux₂])
local notation "J" => o.rightAngleRotation
@[simp]
theorem inner_rightAngleRotation_left (x y : E) : ⟪J x, y⟫ = ω x y := by
rw [rightAngleRotation]
exact o.inner_rightAngleRotationAux₁_left x y
@[simp]
theorem inner_rightAngleRotation_right (x y : E) : ⟪x, J y⟫ = -ω x y := by
rw [rightAngleRotation]
exact o.inner_rightAngleRotationAux₁_right x y
@[simp]
theorem rightAngleRotation_rightAngleRotation (x : E) : J (J x) = -x := by
rw [rightAngleRotation]
exact o.rightAngleRotationAux₁_rightAngleRotationAux₁ x
@[simp]
theorem rightAngleRotation_symm :
LinearIsometryEquiv.symm J = LinearIsometryEquiv.trans J (LinearIsometryEquiv.neg ℝ) := by
rw [rightAngleRotation]
exact LinearIsometryEquiv.toLinearIsometry_injective rfl
theorem inner_rightAngleRotation_self (x : E) : ⟪J x, x⟫ = 0 := by simp
theorem inner_rightAngleRotation_swap (x y : E) : ⟪x, J y⟫ = -⟪J x, y⟫ := by simp
theorem inner_rightAngleRotation_swap' (x y : E) : ⟪J x, y⟫ = -⟪x, J y⟫ := by
simp [o.inner_rightAngleRotation_swap x y]
theorem inner_comp_rightAngleRotation (x y : E) : ⟪J x, J y⟫ = ⟪x, y⟫ :=
LinearIsometryEquiv.inner_map_map J x y
@[simp]
theorem areaForm_rightAngleRotation_left (x y : E) : ω (J x) y = -⟪x, y⟫ := by
rw [← o.inner_comp_rightAngleRotation, o.inner_rightAngleRotation_right, neg_neg]
@[simp]
theorem areaForm_rightAngleRotation_right (x y : E) : ω x (J y) = ⟪x, y⟫ := by
rw [← o.inner_rightAngleRotation_left, o.inner_comp_rightAngleRotation]
theorem areaForm_comp_rightAngleRotation (x y : E) : ω (J x) (J y) = ω x y := by simp
@[simp]
theorem rightAngleRotation_trans_rightAngleRotation :
LinearIsometryEquiv.trans J J = LinearIsometryEquiv.neg ℝ := by ext; simp
theorem rightAngleRotation_neg_orientation (x : E) :
(-o).rightAngleRotation x = -o.rightAngleRotation x := by
apply ext_inner_right ℝ
intro y
rw [inner_rightAngleRotation_left]
simp
@[simp]
theorem rightAngleRotation_trans_neg_orientation :
(-o).rightAngleRotation = o.rightAngleRotation.trans (LinearIsometryEquiv.neg ℝ) :=
LinearIsometryEquiv.ext <| o.rightAngleRotation_neg_orientation
theorem rightAngleRotation_map {F : Type*} [NormedAddCommGroup F] [InnerProductSpace ℝ F]
[hF : Fact (finrank ℝ F = 2)] (φ : E ≃ₗᵢ[ℝ] F) (x : F) :
(Orientation.map (Fin 2) φ.toLinearEquiv o).rightAngleRotation x =
φ (o.rightAngleRotation (φ.symm x)) := by
apply ext_inner_right ℝ
intro y
rw [inner_rightAngleRotation_left]
trans ⟪J (φ.symm x), φ.symm y⟫
· simp [o.areaForm_map]
trans ⟪φ (J (φ.symm x)), φ (φ.symm y)⟫
· rw [φ.inner_map_map]
· simp
/-- `J` commutes with any positively-oriented isometric automorphism. -/
theorem linearIsometryEquiv_comp_rightAngleRotation (φ : E ≃ₗᵢ[ℝ] E)
(hφ : 0 < LinearMap.det (φ.toLinearEquiv : E →ₗ[ℝ] E)) (x : E) : φ (J x) = J (φ x) := by
convert (o.rightAngleRotation_map φ (φ x)).symm
· simp
· symm
rwa [← o.map_eq_iff_det_pos φ.toLinearEquiv] at hφ
rw [@Fact.out (finrank ℝ E = 2), Fintype.card_fin]
theorem rightAngleRotation_map' {F : Type*} [NormedAddCommGroup F] [InnerProductSpace ℝ F]
[Fact (finrank ℝ F = 2)] (φ : E ≃ₗᵢ[ℝ] F) :
(Orientation.map (Fin 2) φ.toLinearEquiv o).rightAngleRotation =
(φ.symm.trans o.rightAngleRotation).trans φ :=
LinearIsometryEquiv.ext <| o.rightAngleRotation_map φ
| /-- `J` commutes with any positively-oriented isometric automorphism. -/
theorem linearIsometryEquiv_comp_rightAngleRotation' (φ : E ≃ₗᵢ[ℝ] E)
(hφ : 0 < LinearMap.det (φ.toLinearEquiv : E →ₗ[ℝ] E)) :
LinearIsometryEquiv.trans J φ = φ.trans J :=
LinearIsometryEquiv.ext <| o.linearIsometryEquiv_comp_rightAngleRotation φ hφ
| Mathlib/Analysis/InnerProductSpace/TwoDim.lean | 321 | 326 |
/-
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)) :
| Mathlib/Data/Finset/NAry.lean | 208 | 212 |
/-
Copyright (c) 2023 Rémy Degenne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Rémy Degenne
-/
import Mathlib.Probability.Kernel.Disintegration.Unique
import Mathlib.Probability.Notation
/-!
# Regular conditional probability distribution
We define the regular conditional probability distribution of `Y : α → Ω` given `X : α → β`, where
`Ω` is a standard Borel space. This is a `Kernel β Ω` such that for almost all `a`, `condDistrib`
evaluated at `X a` and a measurable set `s` is equal to the conditional expectation
`μ⟦Y ⁻¹' s | mβ.comap X⟧` evaluated at `a`.
`μ⟦Y ⁻¹' s | mβ.comap X⟧` maps a measurable set `s` to a function `α → ℝ≥0∞`, and for all `s` that
map is unique up to a `μ`-null set. For all `a`, the map from sets to `ℝ≥0∞` that we obtain that way
verifies some of the properties of a measure, but in general the fact that the `μ`-null set depends
on `s` can prevent us from finding versions of the conditional expectation that combine into a true
measure. The standard Borel space assumption on `Ω` allows us to do so.
The case `Y = X = id` is developed in more detail in `Probability/Kernel/Condexp.lean`: here `X` is
understood as a map from `Ω` with a sub-σ-algebra `m` to `Ω` with its default σ-algebra and the
conditional distribution defines a kernel associated with the conditional expectation with respect
to `m`.
## Main definitions
* `condDistrib Y X μ`: regular conditional probability distribution of `Y : α → Ω` given
`X : α → β`, where `Ω` is a standard Borel space.
## Main statements
* `condDistrib_ae_eq_condExp`: for almost all `a`, `condDistrib` evaluated at `X a` and a
measurable set `s` is equal to the conditional expectation `μ⟦Y ⁻¹' s | mβ.comap X⟧ a`.
* `condExp_prod_ae_eq_integral_condDistrib`: the conditional expectation
`μ[(fun a => f (X a, Y a)) | X; mβ]` is almost everywhere equal to the integral
`∫ y, f (X a, y) ∂(condDistrib Y X μ (X a))`.
-/
open MeasureTheory Set Filter TopologicalSpace
open scoped ENNReal MeasureTheory ProbabilityTheory
namespace ProbabilityTheory
variable {α β Ω F : Type*} [MeasurableSpace Ω] [StandardBorelSpace Ω]
[Nonempty Ω] [NormedAddCommGroup F] {mα : MeasurableSpace α} {μ : Measure α} [IsFiniteMeasure μ]
{X : α → β} {Y : α → Ω}
/-- **Regular conditional probability distribution**: kernel associated with the conditional
expectation of `Y` given `X`.
For almost all `a`, `condDistrib Y X μ` evaluated at `X a` and a measurable set `s` is equal to
the conditional expectation `μ⟦Y ⁻¹' s | mβ.comap X⟧ a`. It also satisfies the equality
`μ[(fun a => f (X a, Y a)) | mβ.comap X] =ᵐ[μ] fun a => ∫ y, f (X a, y) ∂(condDistrib Y X μ (X a))`
for all integrable functions `f`. -/
noncomputable irreducible_def condDistrib {_ : MeasurableSpace α} [MeasurableSpace β] (Y : α → Ω)
(X : α → β) (μ : Measure α) [IsFiniteMeasure μ] : Kernel β Ω :=
(μ.map fun a => (X a, Y a)).condKernel
instance [MeasurableSpace β] : IsMarkovKernel (condDistrib Y X μ) := by
rw [condDistrib]; infer_instance
variable {mβ : MeasurableSpace β} {s : Set Ω} {t : Set β} {f : β × Ω → F}
/-- If the singleton `{x}` has non-zero mass for `μ.map X`, then for all `s : Set Ω`,
`condDistrib Y X μ x s = (μ.map X {x})⁻¹ * μ.map (fun a => (X a, Y a)) ({x} ×ˢ s)` . -/
lemma condDistrib_apply_of_ne_zero [MeasurableSingletonClass β]
(hY : Measurable Y) (x : β) (hX : μ.map X {x} ≠ 0) (s : Set Ω) :
condDistrib Y X μ x s = (μ.map X {x})⁻¹ * μ.map (fun a => (X a, Y a)) ({x} ×ˢ s) := by
rw [condDistrib, Measure.condKernel_apply_of_ne_zero _ s]
· rw [Measure.fst_map_prodMk hY]
· rwa [Measure.fst_map_prodMk hY]
lemma compProd_map_condDistrib (hY : AEMeasurable Y μ) :
(μ.map X) ⊗ₘ condDistrib Y X μ = μ.map fun a ↦ (X a, Y a) := by
rw [condDistrib, ← Measure.fst_map_prodMk₀ hY, Measure.disintegrate]
section Measurability
theorem measurable_condDistrib (hs : MeasurableSet s) :
Measurable[mβ.comap X] fun a => condDistrib Y X μ (X a) s :=
(Kernel.measurable_coe _ hs).comp (Measurable.of_comap_le le_rfl)
theorem _root_.MeasureTheory.AEStronglyMeasurable.ae_integrable_condDistrib_map_iff
(hY : AEMeasurable Y μ) (hf : AEStronglyMeasurable f (μ.map fun a => (X a, Y a))) :
(∀ᵐ a ∂μ.map X, Integrable (fun ω => f (a, ω)) (condDistrib Y X μ a)) ∧
Integrable (fun a => ∫ ω, ‖f (a, ω)‖ ∂condDistrib Y X μ a) (μ.map X) ↔
Integrable f (μ.map fun a => (X a, Y a)) := by
rw [condDistrib, ← hf.ae_integrable_condKernel_iff, Measure.fst_map_prodMk₀ hY]
variable [NormedSpace ℝ F]
theorem _root_.MeasureTheory.StronglyMeasurable.integral_condDistrib (hf : StronglyMeasurable f) :
StronglyMeasurable (fun x ↦ ∫ y, f (x, y) ∂condDistrib Y X μ x) := by
rw [condDistrib]; exact hf.integral_kernel_prod_right'
theorem _root_.MeasureTheory.AEStronglyMeasurable.integral_condDistrib_map
(hY : AEMeasurable Y μ) (hf : AEStronglyMeasurable f (μ.map fun a => (X a, Y a))) :
AEStronglyMeasurable (fun x => ∫ y, f (x, y) ∂condDistrib Y X μ x) (μ.map X) := by
rw [← Measure.fst_map_prodMk₀ hY, condDistrib]; exact hf.integral_condKernel
theorem _root_.MeasureTheory.AEStronglyMeasurable.integral_condDistrib (hX : AEMeasurable X μ)
(hY : AEMeasurable Y μ) (hf : AEStronglyMeasurable f (μ.map fun a => (X a, Y a))) :
AEStronglyMeasurable (fun a => ∫ y, f (X a, y) ∂condDistrib Y X μ (X a)) μ :=
(hf.integral_condDistrib_map hY).comp_aemeasurable hX
theorem stronglyMeasurable_integral_condDistrib (hf : StronglyMeasurable f) :
StronglyMeasurable[mβ.comap X] (fun a ↦ ∫ y, f (X a, y) ∂condDistrib Y X μ (X a)) :=
(hf.integral_condDistrib).comp_measurable <| Measurable.of_comap_le le_rfl
theorem aestronglyMeasurable_integral_condDistrib (hX : AEMeasurable X μ) (hY : AEMeasurable Y μ)
(hf : AEStronglyMeasurable f (μ.map fun a => (X a, Y a))) :
AEStronglyMeasurable[mβ.comap X] (fun a => ∫ y, f (X a, y) ∂condDistrib Y X μ (X a)) μ :=
(hf.integral_condDistrib_map hY).comp_ae_measurable' hX
@[deprecated (since := "2025-01-24")]
alias aestronglyMeasurable'_integral_condDistrib := aestronglyMeasurable_integral_condDistrib
end Measurability
/-- `condDistrib` is a.e. uniquely defined as the kernel satisfying the defining property of
`condKernel`. -/
theorem condDistrib_ae_eq_of_measure_eq_compProd (hX : Measurable X) (hY : Measurable Y)
(κ : Kernel β Ω) [IsFiniteKernel κ] (hκ : μ.map (fun x => (X x, Y x)) = μ.map X ⊗ₘ κ) :
∀ᵐ x ∂μ.map X, κ x = condDistrib Y X μ x := by
have heq : μ.map X = (μ.map (fun x ↦ (X x, Y x))).fst := by
ext s hs
rw [Measure.map_apply hX hs, Measure.fst_apply hs, Measure.map_apply]
exacts [rfl, Measurable.prod hX hY, measurable_fst hs]
rw [heq, condDistrib]
refine eq_condKernel_of_measure_eq_compProd _ ?_
convert hκ
exact heq.symm
section Integrability
theorem integrable_toReal_condDistrib (hX : AEMeasurable X μ) (hs : MeasurableSet s) :
Integrable (fun a => (condDistrib Y X μ (X a)).real s) μ := by
refine integrable_toReal_of_lintegral_ne_top ?_ ?_
· exact Measurable.comp_aemeasurable (Kernel.measurable_coe _ hs) hX
· refine ne_of_lt ?_
calc
∫⁻ a, condDistrib Y X μ (X a) s ∂μ ≤ ∫⁻ _, 1 ∂μ := lintegral_mono fun a => prob_le_one
_ = μ univ := lintegral_one
_ < ∞ := measure_lt_top _ _
theorem _root_.MeasureTheory.Integrable.condDistrib_ae_map
(hY : AEMeasurable Y μ) (hf_int : Integrable f (μ.map fun a => (X a, Y a))) :
∀ᵐ b ∂μ.map X, Integrable (fun ω => f (b, ω)) (condDistrib Y X μ b) := by
rw [condDistrib, ← Measure.fst_map_prodMk₀ (X := X) hY]; exact hf_int.condKernel_ae
theorem _root_.MeasureTheory.Integrable.condDistrib_ae (hX : AEMeasurable X μ)
(hY : AEMeasurable Y μ) (hf_int : Integrable f (μ.map fun a => (X a, Y a))) :
∀ᵐ a ∂μ, Integrable (fun ω => f (X a, ω)) (condDistrib Y X μ (X a)) :=
ae_of_ae_map hX (hf_int.condDistrib_ae_map hY)
theorem _root_.MeasureTheory.Integrable.integral_norm_condDistrib_map
(hY : AEMeasurable Y μ) (hf_int : Integrable f (μ.map fun a => (X a, Y a))) :
Integrable (fun x => ∫ y, ‖f (x, y)‖ ∂condDistrib Y X μ x) (μ.map X) := by
rw [condDistrib, ← Measure.fst_map_prodMk₀ (X := X) hY]; exact hf_int.integral_norm_condKernel
theorem _root_.MeasureTheory.Integrable.integral_norm_condDistrib (hX : AEMeasurable X μ)
(hY : AEMeasurable Y μ) (hf_int : Integrable f (μ.map fun a => (X a, Y a))) :
Integrable (fun a => ∫ y, ‖f (X a, y)‖ ∂condDistrib Y X μ (X a)) μ :=
(hf_int.integral_norm_condDistrib_map hY).comp_aemeasurable hX
variable [NormedSpace ℝ F]
theorem _root_.MeasureTheory.Integrable.norm_integral_condDistrib_map
(hY : AEMeasurable Y μ) (hf_int : Integrable f (μ.map fun a => (X a, Y a))) :
Integrable (fun x => ‖∫ y, f (x, y) ∂condDistrib Y X μ x‖) (μ.map X) := by
rw [condDistrib, ← Measure.fst_map_prodMk₀ (X := X) hY]; exact hf_int.norm_integral_condKernel
theorem _root_.MeasureTheory.Integrable.norm_integral_condDistrib (hX : AEMeasurable X μ)
(hY : AEMeasurable Y μ) (hf_int : Integrable f (μ.map fun a => (X a, Y a))) :
Integrable (fun a => ‖∫ y, f (X a, y) ∂condDistrib Y X μ (X a)‖) μ :=
(hf_int.norm_integral_condDistrib_map hY).comp_aemeasurable hX
theorem _root_.MeasureTheory.Integrable.integral_condDistrib_map
(hY : AEMeasurable Y μ) (hf_int : Integrable f (μ.map fun a => (X a, Y a))) :
Integrable (fun x => ∫ y, f (x, y) ∂condDistrib Y X μ x) (μ.map X) :=
(integrable_norm_iff (hf_int.1.integral_condDistrib_map hY)).mp
(hf_int.norm_integral_condDistrib_map hY)
theorem _root_.MeasureTheory.Integrable.integral_condDistrib (hX : AEMeasurable X μ)
(hY : AEMeasurable Y μ) (hf_int : Integrable f (μ.map fun a => (X a, Y a))) :
Integrable (fun a => ∫ y, f (X a, y) ∂condDistrib Y X μ (X a)) μ :=
(hf_int.integral_condDistrib_map hY).comp_aemeasurable hX
end Integrability
theorem setLIntegral_preimage_condDistrib (hX : Measurable X) (hY : AEMeasurable Y μ)
(hs : MeasurableSet s) (ht : MeasurableSet t) :
∫⁻ a in X ⁻¹' t, condDistrib Y X μ (X a) s ∂μ = μ (X ⁻¹' t ∩ Y ⁻¹' s) := by
-- Porting note: need to massage the LHS integrand into the form accepted by `lintegral_comp`
-- (`rw` does not see that the two forms are defeq)
conv_lhs => arg 2; change (fun a => ((condDistrib Y X μ) a) s) ∘ X
rw [lintegral_comp (Kernel.measurable_coe _ hs) hX, condDistrib, ← Measure.restrict_map hX ht, ←
Measure.fst_map_prodMk₀ hY, Measure.setLIntegral_condKernel_eq_measure_prod ht hs,
Measure.map_apply_of_aemeasurable (hX.aemeasurable.prodMk hY) (ht.prod hs), mk_preimage_prod]
theorem setLIntegral_condDistrib_of_measurableSet (hX : Measurable X) (hY : AEMeasurable Y μ)
(hs : MeasurableSet s) {t : Set α} (ht : MeasurableSet[mβ.comap X] t) :
∫⁻ a in t, condDistrib Y X μ (X a) s ∂μ = μ (t ∩ Y ⁻¹' s) := by
obtain ⟨t', ht', rfl⟩ := ht
rw [setLIntegral_preimage_condDistrib hX hY hs ht']
/-- For almost every `a : α`, the `condDistrib Y X μ` kernel applied to `X a` and a measurable set
`s` is equal to the conditional expectation of the indicator of `Y ⁻¹' s`. -/
theorem condDistrib_ae_eq_condExp (hX : Measurable X) (hY : Measurable Y) (hs : MeasurableSet s) :
(fun a => (condDistrib Y X μ (X a)).real s) =ᵐ[μ] μ⟦Y ⁻¹' s|mβ.comap X⟧ := by
refine ae_eq_condExp_of_forall_setIntegral_eq hX.comap_le ?_ ?_ ?_ ?_
· exact (integrable_const _).indicator (hY hs)
· exact fun t _ _ => (integrable_toReal_condDistrib hX.aemeasurable hs).integrableOn
· intro t ht _
simp_rw [measureReal_def]
rw [integral_toReal ((measurable_condDistrib hs).mono hX.comap_le le_rfl).aemeasurable
(Eventually.of_forall fun ω => measure_lt_top (condDistrib Y X μ (X ω)) _),
integral_indicator_const _ (hY hs), measureReal_restrict_apply (hY hs), smul_eq_mul, mul_one,
inter_comm, setLIntegral_condDistrib_of_measurableSet hX hY.aemeasurable hs ht,
measureReal_def]
· exact (measurable_condDistrib hs).ennreal_toReal.aestronglyMeasurable
@[deprecated (since := "2025-01-21")] alias condDistrib_ae_eq_condexp := condDistrib_ae_eq_condExp
/-- The conditional expectation of a function `f` of the product `(X, Y)` is almost everywhere equal
to the integral of `y ↦ f(X, y)` against the `condDistrib` kernel. -/
theorem condExp_prod_ae_eq_integral_condDistrib' [NormedSpace ℝ F] [CompleteSpace F]
(hX : Measurable X) (hY : AEMeasurable Y μ)
(hf_int : Integrable f (μ.map fun a => (X a, Y a))) :
μ[fun a => f (X a, Y a)|mβ.comap X] =ᵐ[μ] fun a => ∫ y, f (X a,y) ∂condDistrib Y X μ (X a) := by
have hf_int' : Integrable (fun a => f (X a, Y a)) μ :=
(integrable_map_measure hf_int.1 (hX.aemeasurable.prodMk hY)).mp hf_int
refine (ae_eq_condExp_of_forall_setIntegral_eq hX.comap_le hf_int' (fun s _ _ => ?_) ?_ ?_).symm
· exact (hf_int.integral_condDistrib hX.aemeasurable hY).integrableOn
| · rintro s ⟨t, ht, rfl⟩ _
change ∫ a in X ⁻¹' t, ((fun x' => ∫ y, f (x', y) ∂(condDistrib Y X μ) x') ∘ X) a ∂μ =
∫ a in X ⁻¹' t, f (X a, Y a) ∂μ
simp only [Function.comp_apply]
rw [← integral_map hX.aemeasurable (f := fun x' => ∫ y, f (x', y) ∂(condDistrib Y X μ) x')]
swap
· rw [← Measure.restrict_map hX ht]
exact (hf_int.1.integral_condDistrib_map hY).restrict
rw [← Measure.restrict_map hX ht, ← Measure.fst_map_prodMk₀ hY, condDistrib,
Measure.setIntegral_condKernel_univ_right ht hf_int.integrableOn,
setIntegral_map (ht.prod MeasurableSet.univ) hf_int.1 (hX.aemeasurable.prodMk hY),
mk_preimage_prod, preimage_univ, inter_univ]
· exact aestronglyMeasurable_integral_condDistrib hX.aemeasurable hY hf_int.1
@[deprecated (since := "2025-01-21")]
alias condexp_prod_ae_eq_integral_condDistrib' := condExp_prod_ae_eq_integral_condDistrib'
/-- The conditional expectation of a function `f` of the product `(X, Y)` is almost everywhere equal
to the integral of `y ↦ f(X, y)` against the `condDistrib` kernel. -/
theorem condExp_prod_ae_eq_integral_condDistrib₀ [NormedSpace ℝ F] [CompleteSpace F]
(hX : Measurable X) (hY : AEMeasurable Y μ)
| Mathlib/Probability/Kernel/CondDistrib.lean | 240 | 260 |
/-
Copyright (c) 2021 Yaël Dillies. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies
-/
import Mathlib.Order.ConditionallyCompleteLattice.Basic
import Mathlib.Order.Cover
import Mathlib.Order.Iterate
/-!
# Successor and predecessor
This file defines successor and predecessor orders. `succ a`, the successor of an element `a : α` is
the least element greater than `a`. `pred a` is the greatest element less than `a`. Typical examples
include `ℕ`, `ℤ`, `ℕ+`, `Fin n`, but also `ENat`, the lexicographic order of a successor/predecessor
order...
## Typeclasses
* `SuccOrder`: Order equipped with a sensible successor function.
* `PredOrder`: Order equipped with a sensible predecessor function.
## Implementation notes
Maximal elements don't have a sensible successor. Thus the naïve typeclass
```lean
class NaiveSuccOrder (α : Type*) [Preorder α] where
(succ : α → α)
(succ_le_iff : ∀ {a b}, succ a ≤ b ↔ a < b)
(lt_succ_iff : ∀ {a b}, a < succ b ↔ a ≤ b)
```
can't apply to an `OrderTop` because plugging in `a = b = ⊤` into either of `succ_le_iff` and
`lt_succ_iff` yields `⊤ < ⊤` (or more generally `m < m` for a maximal element `m`).
The solution taken here is to remove the implications `≤ → <` and instead require that `a < succ a`
for all non maximal elements (enforced by the combination of `le_succ` and the contrapositive of
`max_of_succ_le`).
The stricter condition of every element having a sensible successor can be obtained through the
combination of `SuccOrder α` and `NoMaxOrder α`.
-/
open Function OrderDual Set
variable {α β : Type*}
/-- Order equipped with a sensible successor function. -/
@[ext]
class SuccOrder (α : Type*) [Preorder α] where
/-- Successor function -/
succ : α → α
/-- Proof of basic ordering with respect to `succ` -/
le_succ : ∀ a, a ≤ succ a
/-- Proof of interaction between `succ` and maximal element -/
max_of_succ_le {a} : succ a ≤ a → IsMax a
/-- Proof that `succ a` is the least element greater than `a` -/
succ_le_of_lt {a b} : a < b → succ a ≤ b
/-- Order equipped with a sensible predecessor function. -/
@[ext]
class PredOrder (α : Type*) [Preorder α] where
/-- Predecessor function -/
pred : α → α
/-- Proof of basic ordering with respect to `pred` -/
pred_le : ∀ a, pred a ≤ a
/-- Proof of interaction between `pred` and minimal element -/
min_of_le_pred {a} : a ≤ pred a → IsMin a
/-- Proof that `pred b` is the greatest element less than `b` -/
le_pred_of_lt {a b} : a < b → a ≤ pred b
instance [Preorder α] [SuccOrder α] :
PredOrder αᵒᵈ where
pred := toDual ∘ SuccOrder.succ ∘ ofDual
pred_le := by
simp only [comp, OrderDual.forall, ofDual_toDual, toDual_le_toDual,
SuccOrder.le_succ, implies_true]
min_of_le_pred h := by apply SuccOrder.max_of_succ_le h
le_pred_of_lt := by intro a b h; exact SuccOrder.succ_le_of_lt h
instance [Preorder α] [PredOrder α] :
SuccOrder αᵒᵈ where
succ := toDual ∘ PredOrder.pred ∘ ofDual
le_succ := by
simp only [comp, OrderDual.forall, ofDual_toDual, toDual_le_toDual,
PredOrder.pred_le, implies_true]
max_of_succ_le h := by apply PredOrder.min_of_le_pred h
succ_le_of_lt := by intro a b h; exact PredOrder.le_pred_of_lt h
section Preorder
variable [Preorder α]
/-- A constructor for `SuccOrder α` usable when `α` has no maximal element. -/
def SuccOrder.ofSuccLeIff (succ : α → α) (hsucc_le_iff : ∀ {a b}, succ a ≤ b ↔ a < b) :
SuccOrder α :=
{ succ
le_succ := fun _ => (hsucc_le_iff.1 le_rfl).le
max_of_succ_le := fun ha => (lt_irrefl _ <| hsucc_le_iff.1 ha).elim
succ_le_of_lt := fun h => hsucc_le_iff.2 h }
/-- A constructor for `PredOrder α` usable when `α` has no minimal element. -/
def PredOrder.ofLePredIff (pred : α → α) (hle_pred_iff : ∀ {a b}, a ≤ pred b ↔ a < b) :
PredOrder α :=
{ pred
pred_le := fun _ => (hle_pred_iff.1 le_rfl).le
min_of_le_pred := fun ha => (lt_irrefl _ <| hle_pred_iff.1 ha).elim
le_pred_of_lt := fun h => hle_pred_iff.2 h }
end Preorder
section LinearOrder
variable [LinearOrder α]
/-- A constructor for `SuccOrder α` for `α` a linear order. -/
@[simps]
def SuccOrder.ofCore (succ : α → α) (hn : ∀ {a}, ¬IsMax a → ∀ b, a < b ↔ succ a ≤ b)
(hm : ∀ a, IsMax a → succ a = a) : SuccOrder α :=
{ succ
succ_le_of_lt := fun {a b} =>
by_cases (fun h hab => (hm a h).symm ▸ hab.le) fun h => (hn h b).mp
le_succ := fun a =>
by_cases (fun h => (hm a h).symm.le) fun h => le_of_lt <| by simpa using (hn h a).not
max_of_succ_le := fun {a} => not_imp_not.mp fun h => by simpa using (hn h a).not }
/-- A constructor for `PredOrder α` for `α` a linear order. -/
@[simps]
def PredOrder.ofCore (pred : α → α)
(hn : ∀ {a}, ¬IsMin a → ∀ b, b ≤ pred a ↔ b < a) (hm : ∀ a, IsMin a → pred a = a) :
PredOrder α :=
{ pred
le_pred_of_lt := fun {a b} =>
by_cases (fun h hab => (hm b h).symm ▸ hab.le) fun h => (hn h a).mpr
pred_le := fun a =>
by_cases (fun h => (hm a h).le) fun h => le_of_lt <| by simpa using (hn h a).not
min_of_le_pred := fun {a} => not_imp_not.mp fun h => by simpa using (hn h a).not }
variable (α)
open Classical in
/-- A well-order is a `SuccOrder`. -/
noncomputable def SuccOrder.ofLinearWellFoundedLT [WellFoundedLT α] : SuccOrder α :=
ofCore (fun a ↦ if h : (Ioi a).Nonempty then wellFounded_lt.min _ h else a)
(fun ha _ ↦ by
rw [not_isMax_iff] at ha
simp_rw [Set.Nonempty, mem_Ioi, dif_pos ha]
exact ⟨(wellFounded_lt.min_le · ha), lt_of_lt_of_le (wellFounded_lt.min_mem _ ha)⟩)
fun _ ha ↦ dif_neg (not_not_intro ha <| not_isMax_iff.mpr ·)
/-- A linear order with well-founded greater-than relation is a `PredOrder`. -/
noncomputable def PredOrder.ofLinearWellFoundedGT (α) [LinearOrder α] [WellFoundedGT α] :
PredOrder α := letI := SuccOrder.ofLinearWellFoundedLT αᵒᵈ; inferInstanceAs (PredOrder αᵒᵈᵒᵈ)
end LinearOrder
/-! ### Successor order -/
namespace Order
section Preorder
variable [Preorder α] [SuccOrder α] {a b : α}
/-- The successor of an element. If `a` is not maximal, then `succ a` is the least element greater
than `a`. If `a` is maximal, then `succ a = a`. -/
def succ : α → α :=
SuccOrder.succ
theorem le_succ : ∀ a : α, a ≤ succ a :=
SuccOrder.le_succ
theorem max_of_succ_le {a : α} : succ a ≤ a → IsMax a :=
SuccOrder.max_of_succ_le
theorem succ_le_of_lt {a b : α} : a < b → succ a ≤ b :=
SuccOrder.succ_le_of_lt
alias _root_.LT.lt.succ_le := succ_le_of_lt
@[simp]
theorem succ_le_iff_isMax : succ a ≤ a ↔ IsMax a :=
⟨max_of_succ_le, fun h => h <| le_succ _⟩
alias ⟨_root_.IsMax.of_succ_le, _root_.IsMax.succ_le⟩ := succ_le_iff_isMax
@[simp]
theorem lt_succ_iff_not_isMax : a < succ a ↔ ¬IsMax a :=
⟨not_isMax_of_lt, fun ha => (le_succ a).lt_of_not_le fun h => ha <| max_of_succ_le h⟩
alias ⟨_, lt_succ_of_not_isMax⟩ := lt_succ_iff_not_isMax
theorem wcovBy_succ (a : α) : a ⩿ succ a :=
⟨le_succ a, fun _ hb => (succ_le_of_lt hb).not_lt⟩
theorem covBy_succ_of_not_isMax (h : ¬IsMax a) : a ⋖ succ a :=
(wcovBy_succ a).covBy_of_lt <| lt_succ_of_not_isMax h
theorem lt_succ_of_le_of_not_isMax (hab : b ≤ a) (ha : ¬IsMax a) : b < succ a :=
hab.trans_lt <| lt_succ_of_not_isMax ha
theorem succ_le_iff_of_not_isMax (ha : ¬IsMax a) : succ a ≤ b ↔ a < b :=
⟨(lt_succ_of_not_isMax ha).trans_le, succ_le_of_lt⟩
lemma succ_lt_succ_of_not_isMax (h : a < b) (hb : ¬ IsMax b) : succ a < succ b :=
lt_succ_of_le_of_not_isMax (succ_le_of_lt h) hb
@[simp, mono, gcongr]
theorem succ_le_succ (h : a ≤ b) : succ a ≤ succ b := by
by_cases hb : IsMax b
· by_cases hba : b ≤ a
· exact (hb <| hba.trans <| le_succ _).trans (le_succ _)
· exact succ_le_of_lt ((h.lt_of_not_le hba).trans_le <| le_succ b)
· rw [succ_le_iff_of_not_isMax fun ha => hb <| ha.mono h]
apply lt_succ_of_le_of_not_isMax h hb
theorem succ_mono : Monotone (succ : α → α) := fun _ _ => succ_le_succ
/-- See also `Order.succ_eq_of_covBy`. -/
lemma le_succ_of_wcovBy (h : a ⩿ b) : b ≤ succ a := by
obtain hab | ⟨-, hba⟩ := h.covBy_or_le_and_le
· by_contra hba
exact h.2 (lt_succ_of_not_isMax hab.lt.not_isMax) <| hab.lt.succ_le.lt_of_not_le hba
· exact hba.trans (le_succ _)
alias _root_.WCovBy.le_succ := le_succ_of_wcovBy
theorem le_succ_iterate (k : ℕ) (x : α) : x ≤ succ^[k] x :=
id_le_iterate_of_id_le le_succ _ _
theorem isMax_iterate_succ_of_eq_of_lt {n m : ℕ} (h_eq : succ^[n] a = succ^[m] a)
(h_lt : n < m) : IsMax (succ^[n] a) := by
refine max_of_succ_le (le_trans ?_ h_eq.symm.le)
rw [← iterate_succ_apply' succ]
have h_le : n + 1 ≤ m := Nat.succ_le_of_lt h_lt
exact Monotone.monotone_iterate_of_le_map succ_mono (le_succ a) h_le
theorem isMax_iterate_succ_of_eq_of_ne {n m : ℕ} (h_eq : succ^[n] a = succ^[m] a)
(h_ne : n ≠ m) : IsMax (succ^[n] a) := by
rcases le_total n m with h | h
· exact isMax_iterate_succ_of_eq_of_lt h_eq (lt_of_le_of_ne h h_ne)
· rw [h_eq]
exact isMax_iterate_succ_of_eq_of_lt h_eq.symm (lt_of_le_of_ne h h_ne.symm)
theorem Iic_subset_Iio_succ_of_not_isMax (ha : ¬IsMax a) : Iic a ⊆ Iio (succ a) :=
fun _ => (lt_succ_of_le_of_not_isMax · ha)
theorem Ici_succ_of_not_isMax (ha : ¬IsMax a) : Ici (succ a) = Ioi a :=
Set.ext fun _ => succ_le_iff_of_not_isMax ha
theorem Icc_subset_Ico_succ_right_of_not_isMax (hb : ¬IsMax b) : Icc a b ⊆ Ico a (succ b) := by
rw [← Ici_inter_Iio, ← Ici_inter_Iic]
gcongr
intro _ h
apply lt_succ_of_le_of_not_isMax h hb
theorem Ioc_subset_Ioo_succ_right_of_not_isMax (hb : ¬IsMax b) : Ioc a b ⊆ Ioo a (succ b) := by
rw [← Ioi_inter_Iio, ← Ioi_inter_Iic]
gcongr
intro _ h
apply Iic_subset_Iio_succ_of_not_isMax hb h
theorem Icc_succ_left_of_not_isMax (ha : ¬IsMax a) : Icc (succ a) b = Ioc a b := by
rw [← Ici_inter_Iic, Ici_succ_of_not_isMax ha, Ioi_inter_Iic]
theorem Ico_succ_left_of_not_isMax (ha : ¬IsMax a) : Ico (succ a) b = Ioo a b := by
rw [← Ici_inter_Iio, Ici_succ_of_not_isMax ha, Ioi_inter_Iio]
section NoMaxOrder
variable [NoMaxOrder α]
theorem lt_succ (a : α) : a < succ a :=
lt_succ_of_not_isMax <| not_isMax a
@[simp]
theorem lt_succ_of_le : a ≤ b → a < succ b :=
(lt_succ_of_le_of_not_isMax · <| not_isMax b)
@[simp]
theorem succ_le_iff : succ a ≤ b ↔ a < b :=
succ_le_iff_of_not_isMax <| not_isMax a
@[gcongr] theorem succ_lt_succ (hab : a < b) : succ a < succ b := by simp [hab]
theorem succ_strictMono : StrictMono (succ : α → α) := fun _ _ => succ_lt_succ
theorem covBy_succ (a : α) : a ⋖ succ a :=
covBy_succ_of_not_isMax <| not_isMax a
theorem Iic_subset_Iio_succ (a : α) : Iic a ⊆ Iio (succ a) := by simp
@[simp]
theorem Ici_succ (a : α) : Ici (succ a) = Ioi a :=
Ici_succ_of_not_isMax <| not_isMax _
@[simp]
theorem Icc_subset_Ico_succ_right (a b : α) : Icc a b ⊆ Ico a (succ b) :=
Icc_subset_Ico_succ_right_of_not_isMax <| not_isMax _
@[simp]
theorem Ioc_subset_Ioo_succ_right (a b : α) : Ioc a b ⊆ Ioo a (succ b) :=
Ioc_subset_Ioo_succ_right_of_not_isMax <| not_isMax _
@[simp]
theorem Icc_succ_left (a b : α) : Icc (succ a) b = Ioc a b :=
Icc_succ_left_of_not_isMax <| not_isMax _
@[simp]
theorem Ico_succ_left (a b : α) : Ico (succ a) b = Ioo a b :=
Ico_succ_left_of_not_isMax <| not_isMax _
end NoMaxOrder
end Preorder
section PartialOrder
variable [PartialOrder α] [SuccOrder α] {a b : α}
@[simp]
theorem succ_eq_iff_isMax : succ a = a ↔ IsMax a :=
⟨fun h => max_of_succ_le h.le, fun h => h.eq_of_ge <| le_succ _⟩
alias ⟨_, _root_.IsMax.succ_eq⟩ := succ_eq_iff_isMax
lemma le_iff_eq_or_succ_le : a ≤ b ↔ a = b ∨ succ a ≤ b := by
by_cases ha : IsMax a
· simpa [ha.succ_eq] using le_of_eq
· rw [succ_le_iff_of_not_isMax ha, le_iff_eq_or_lt]
theorem le_le_succ_iff : a ≤ b ∧ b ≤ succ a ↔ b = a ∨ b = succ a := by
refine
⟨fun h =>
or_iff_not_imp_left.2 fun hba : b ≠ a =>
h.2.antisymm (succ_le_of_lt <| h.1.lt_of_ne <| hba.symm),
| ?_⟩
rintro (rfl | rfl)
| Mathlib/Order/SuccPred/Basic.lean | 335 | 336 |
/-
Copyright (c) 2020 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov, Patrick Massot, Sébastien Gouëzel
-/
import Mathlib.MeasureTheory.Integral.IntervalIntegral.Basic
import Mathlib.MeasureTheory.Integral.IntervalIntegral.FundThmCalculus
import Mathlib.MeasureTheory.Integral.IntervalIntegral.IntegrationByParts
deprecated_module (since := "2025-04-13")
| Mathlib/MeasureTheory/Integral/IntervalIntegral.lean | 1,058 | 1,061 | |
/-
Copyright (c) 2021 Vladimir Goryachev. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies, Vladimir Goryachev, Kyle Miller, Kim Morrison, Eric Rodriguez
-/
import Mathlib.Data.List.GetD
import Mathlib.Data.Nat.Count
import Mathlib.Data.Nat.SuccPred
import Mathlib.Order.Interval.Set.Monotone
import Mathlib.Order.OrderIsoNat
import Mathlib.Order.WellFounded
import Mathlib.Order.OmegaCompletePartialOrder
import Mathlib.Data.Finset.Sort
/-!
# The `n`th Number Satisfying a Predicate
This file defines a function for "what is the `n`th number that satisfies a given predicate `p`",
and provides lemmas that deal with this function and its connection to `Nat.count`.
## Main definitions
* `Nat.nth p n`: The `n`-th natural `k` (zero-indexed) such that `p k`. If there is no
such natural (that is, `p` is true for at most `n` naturals), then `Nat.nth p n = 0`.
## Main results
* `Nat.nth_eq_orderEmbOfFin`: For a finitely-often true `p`, gives the cardinality of the set of
numbers satisfying `p` above particular values of `nth p`
* `Nat.gc_count_nth`: Establishes a Galois connection between `Nat.nth p` and `Nat.count p`.
* `Nat.nth_eq_orderIsoOfNat`: For an infinitely-often true predicate, `nth` agrees with the
order-isomorphism of the subtype to the natural numbers.
There has been some discussion on the subject of whether both of `nth` and
`Nat.Subtype.orderIsoOfNat` should exist. See discussion
[here](https://github.com/leanprover-community/mathlib/pull/9457#pullrequestreview-767221180).
Future work should address how lemmas that use these should be written.
-/
open Finset
namespace Nat
variable (p : ℕ → Prop)
/-- Find the `n`-th natural number satisfying `p` (indexed from `0`, so `nth p 0` is the first
natural number satisfying `p`), or `0` if there is no such number. See also
`Subtype.orderIsoOfNat` for the order isomorphism with ℕ when `p` is infinitely often true. -/
noncomputable def nth (p : ℕ → Prop) (n : ℕ) : ℕ := by
classical exact
if h : Set.Finite (setOf p) then (h.toFinset.sort (· ≤ ·)).getD n 0
else @Nat.Subtype.orderIsoOfNat (setOf p) (Set.Infinite.to_subtype h) n
variable {p}
/-!
### Lemmas about `Nat.nth` on a finite set
-/
theorem nth_of_card_le (hf : (setOf p).Finite) {n : ℕ} (hn : #hf.toFinset ≤ n) :
nth p n = 0 := by rw [nth, dif_pos hf, List.getD_eq_default]; rwa [Finset.length_sort]
theorem nth_eq_getD_sort (h : (setOf p).Finite) (n : ℕ) :
nth p n = (h.toFinset.sort (· ≤ ·)).getD n 0 :=
dif_pos h
theorem nth_eq_orderEmbOfFin (hf : (setOf p).Finite) {n : ℕ} (hn : n < #hf.toFinset) :
nth p n = hf.toFinset.orderEmbOfFin rfl ⟨n, hn⟩ := by
rw [nth_eq_getD_sort hf, Finset.orderEmbOfFin_apply, List.getD_eq_getElem, Fin.getElem_fin]
theorem nth_strictMonoOn (hf : (setOf p).Finite) :
StrictMonoOn (nth p) (Set.Iio #hf.toFinset) := by
rintro m (hm : m < _) n (hn : n < _) h
simp only [nth_eq_orderEmbOfFin, *]
exact OrderEmbedding.strictMono _ h
theorem nth_lt_nth_of_lt_card (hf : (setOf p).Finite) {m n : ℕ} (h : m < n)
(hn : n < #hf.toFinset) : nth p m < nth p n :=
nth_strictMonoOn hf (h.trans hn) hn h
theorem nth_le_nth_of_lt_card (hf : (setOf p).Finite) {m n : ℕ} (h : m ≤ n)
(hn : n < #hf.toFinset) : nth p m ≤ nth p n :=
(nth_strictMonoOn hf).monotoneOn (h.trans_lt hn) hn h
theorem lt_of_nth_lt_nth_of_lt_card (hf : (setOf p).Finite) {m n : ℕ} (h : nth p m < nth p n)
(hm : m < #hf.toFinset) : m < n :=
not_le.1 fun hle => h.not_le <| nth_le_nth_of_lt_card hf hle hm
theorem le_of_nth_le_nth_of_lt_card (hf : (setOf p).Finite) {m n : ℕ} (h : nth p m ≤ nth p n)
(hm : m < #hf.toFinset) : m ≤ n :=
not_lt.1 fun hlt => h.not_lt <| nth_lt_nth_of_lt_card hf hlt hm
theorem nth_injOn (hf : (setOf p).Finite) : (Set.Iio #hf.toFinset).InjOn (nth p) :=
(nth_strictMonoOn hf).injOn
theorem range_nth_of_finite (hf : (setOf p).Finite) : Set.range (nth p) = insert 0 (setOf p) := by
simpa only [← List.getD_eq_getElem?_getD, ← nth_eq_getD_sort hf, mem_sort,
Set.Finite.mem_toFinset] using Set.range_list_getD (hf.toFinset.sort (· ≤ ·)) 0
@[simp]
theorem image_nth_Iio_card (hf : (setOf p).Finite) : nth p '' Set.Iio #hf.toFinset = setOf p :=
calc
nth p '' Set.Iio #hf.toFinset = Set.range (hf.toFinset.orderEmbOfFin rfl) := by
ext x
simp only [Set.mem_image, Set.mem_range, Fin.exists_iff, ← nth_eq_orderEmbOfFin hf,
Set.mem_Iio, exists_prop]
_ = setOf p := by rw [range_orderEmbOfFin, Set.Finite.coe_toFinset]
theorem nth_mem_of_lt_card {n : ℕ} (hf : (setOf p).Finite) (hlt : n < #hf.toFinset) :
p (nth p n) :=
(image_nth_Iio_card hf).subset <| Set.mem_image_of_mem _ hlt
theorem exists_lt_card_finite_nth_eq (hf : (setOf p).Finite) {x} (h : p x) :
∃ n, n < #hf.toFinset ∧ nth p n = x := by
rwa [← @Set.mem_setOf_eq _ _ p, ← image_nth_Iio_card hf] at h
/-!
### Lemmas about `Nat.nth` on an infinite set
-/
/-- When `s` is an infinite set, `nth` agrees with `Nat.Subtype.orderIsoOfNat`. -/
theorem nth_apply_eq_orderIsoOfNat (hf : (setOf p).Infinite) (n : ℕ) :
nth p n = @Nat.Subtype.orderIsoOfNat (setOf p) hf.to_subtype n := by rw [nth, dif_neg hf]
/-- When `s` is an infinite set, `nth` agrees with `Nat.Subtype.orderIsoOfNat`. -/
theorem nth_eq_orderIsoOfNat (hf : (setOf p).Infinite) :
nth p = (↑) ∘ @Nat.Subtype.orderIsoOfNat (setOf p) hf.to_subtype :=
funext <| nth_apply_eq_orderIsoOfNat hf
theorem nth_strictMono (hf : (setOf p).Infinite) : StrictMono (nth p) := by
rw [nth_eq_orderIsoOfNat hf]
exact (Subtype.strictMono_coe _).comp (OrderIso.strictMono _)
theorem nth_injective (hf : (setOf p).Infinite) : Function.Injective (nth p) :=
(nth_strictMono hf).injective
theorem nth_monotone (hf : (setOf p).Infinite) : Monotone (nth p) :=
(nth_strictMono hf).monotone
theorem nth_lt_nth (hf : (setOf p).Infinite) {k n} : nth p k < nth p n ↔ k < n :=
(nth_strictMono hf).lt_iff_lt
theorem nth_le_nth (hf : (setOf p).Infinite) {k n} : nth p k ≤ nth p n ↔ k ≤ n :=
(nth_strictMono hf).le_iff_le
theorem range_nth_of_infinite (hf : (setOf p).Infinite) : Set.range (nth p) = setOf p := by
rw [nth_eq_orderIsoOfNat hf]
haveI := hf.to_subtype
classical exact Nat.Subtype.coe_comp_ofNat_range
theorem nth_mem_of_infinite (hf : (setOf p).Infinite) (n : ℕ) : p (nth p n) :=
Set.range_subset_iff.1 (range_nth_of_infinite hf).le n
/-!
### Lemmas that work for finite and infinite sets
-/
theorem exists_lt_card_nth_eq {x} (h : p x) :
∃ n, (∀ hf : (setOf p).Finite, n < #hf.toFinset) ∧ nth p n = x := by
refine (setOf p).finite_or_infinite.elim (fun hf => ?_) fun hf => ?_
· rcases exists_lt_card_finite_nth_eq hf h with ⟨n, hn, hx⟩
exact ⟨n, fun _ => hn, hx⟩
· rw [← @Set.mem_setOf_eq _ _ p, ← range_nth_of_infinite hf] at h
rcases h with ⟨n, hx⟩
exact ⟨n, fun hf' => absurd hf' hf, hx⟩
theorem subset_range_nth : setOf p ⊆ Set.range (nth p) := fun x (hx : p x) =>
let ⟨n, _, hn⟩ := exists_lt_card_nth_eq hx
⟨n, hn⟩
theorem range_nth_subset : Set.range (nth p) ⊆ insert 0 (setOf p) :=
(setOf p).finite_or_infinite.elim (fun h => (range_nth_of_finite h).subset) fun h =>
(range_nth_of_infinite h).trans_subset (Set.subset_insert _ _)
theorem nth_mem (n : ℕ) (h : ∀ hf : (setOf p).Finite, n < #hf.toFinset) : p (nth p n) :=
(setOf p).finite_or_infinite.elim (fun hf => nth_mem_of_lt_card hf (h hf)) fun h =>
nth_mem_of_infinite h n
theorem nth_lt_nth' {m n : ℕ} (hlt : m < n) (h : ∀ hf : (setOf p).Finite, n < #hf.toFinset) :
nth p m < nth p n :=
(setOf p).finite_or_infinite.elim (fun hf => nth_lt_nth_of_lt_card hf hlt (h _)) fun hf =>
(nth_lt_nth hf).2 hlt
theorem nth_le_nth' {m n : ℕ} (hle : m ≤ n) (h : ∀ hf : (setOf p).Finite, n < #hf.toFinset) :
nth p m ≤ nth p n :=
(setOf p).finite_or_infinite.elim (fun hf => nth_le_nth_of_lt_card hf hle (h _)) fun hf =>
(nth_le_nth hf).2 hle
theorem le_nth {n : ℕ} (h : ∀ hf : (setOf p).Finite, n < #hf.toFinset) : n ≤ nth p n :=
(setOf p).finite_or_infinite.elim
(fun hf => ((nth_strictMonoOn hf).mono <| Set.Iic_subset_Iio.2 (h _)).Iic_id_le _ le_rfl)
fun hf => (nth_strictMono hf).id_le _
theorem isLeast_nth {n} (h : ∀ hf : (setOf p).Finite, n < #hf.toFinset) :
IsLeast {i | p i ∧ ∀ k < n, nth p k < i} (nth p n) :=
⟨⟨nth_mem n h, fun _k hk => nth_lt_nth' hk h⟩, fun _x hx =>
let ⟨k, hk, hkx⟩ := exists_lt_card_nth_eq hx.1
(lt_or_le k n).elim (fun hlt => absurd hkx (hx.2 _ hlt).ne) fun hle => hkx ▸ nth_le_nth' hle hk⟩
theorem isLeast_nth_of_lt_card {n : ℕ} (hf : (setOf p).Finite) (hn : n < #hf.toFinset) :
IsLeast {i | p i ∧ ∀ k < n, nth p k < i} (nth p n) :=
isLeast_nth fun _ => hn
theorem isLeast_nth_of_infinite (hf : (setOf p).Infinite) (n : ℕ) :
IsLeast {i | p i ∧ ∀ k < n, nth p k < i} (nth p n) :=
isLeast_nth fun h => absurd h hf
/-- An alternative recursive definition of `Nat.nth`: `Nat.nth s n` is the infimum of `x ∈ s` such
that `Nat.nth s k < x` for all `k < n`, if this set is nonempty. We do not assume that the set is
nonempty because we use the same "garbage value" `0` both for `sInf` on `ℕ` and for `Nat.nth s n`
for `n ≥ #s`. -/
theorem nth_eq_sInf (p : ℕ → Prop) (n : ℕ) : nth p n = sInf {x | p x ∧ ∀ k < n, nth p k < x} := by
by_cases hn : ∀ hf : (setOf p).Finite, n < #hf.toFinset
· exact (isLeast_nth hn).csInf_eq.symm
· push_neg at hn
rcases hn with ⟨hf, hn⟩
rw [nth_of_card_le _ hn]
refine ((congr_arg sInf <| Set.eq_empty_of_forall_not_mem fun k hk => ?_).trans sInf_empty).symm
rcases exists_lt_card_nth_eq hk.1 with ⟨k, hlt, rfl⟩
exact (hk.2 _ ((hlt hf).trans_le hn)).false
theorem nth_zero : nth p 0 = sInf (setOf p) := by rw [nth_eq_sInf]; simp
@[simp]
theorem nth_zero_of_zero (h : p 0) : nth p 0 = 0 := by simp [nth_zero, h]
theorem nth_zero_of_exists [DecidablePred p] (h : ∃ n, p n) : nth p 0 = Nat.find h := by
rw [nth_zero]; convert Nat.sInf_def h
theorem nth_eq_zero {n} :
nth p n = 0 ↔ p 0 ∧ n = 0 ∨ ∃ hf : (setOf p).Finite, #hf.toFinset ≤ n := by
refine ⟨fun h => ?_, ?_⟩
· simp only [or_iff_not_imp_right, not_exists, not_le]
exact fun hn => ⟨h ▸ nth_mem _ hn, nonpos_iff_eq_zero.1 <| h ▸ le_nth hn⟩
· rintro (⟨h₀, rfl⟩ | ⟨hf, hle⟩)
exacts [nth_zero_of_zero h₀, nth_of_card_le hf hle]
lemma lt_card_toFinset_of_nth_ne_zero {n : ℕ} (h : nth p n ≠ 0) (hf : (setOf p).Finite) :
n < #hf.toFinset := by
simp only [ne_eq, nth_eq_zero, not_or, not_exists, not_le] at h
exact h.2 hf
lemma nth_mem_of_ne_zero {n : ℕ} (h : nth p n ≠ 0) : p (Nat.nth p n) :=
nth_mem n (lt_card_toFinset_of_nth_ne_zero h)
theorem nth_eq_zero_mono (h₀ : ¬p 0) {a b : ℕ} (hab : a ≤ b) (ha : nth p a = 0) : nth p b = 0 := by
simp only [nth_eq_zero, h₀, false_and, false_or] at ha ⊢
exact ha.imp fun hf hle => hle.trans hab
lemma nth_ne_zero_anti (h₀ : ¬p 0) {a b : ℕ} (hab : a ≤ b) (hb : nth p b ≠ 0) : nth p a ≠ 0 :=
mt (nth_eq_zero_mono h₀ hab) hb
theorem le_nth_of_lt_nth_succ {k a : ℕ} (h : a < nth p (k + 1)) (ha : p a) : a ≤ nth p k := by
rcases (setOf p).finite_or_infinite with hf | hf
· rcases exists_lt_card_finite_nth_eq hf ha with ⟨n, hn, rfl⟩
rcases lt_or_le (k + 1) #hf.toFinset with hk | hk
· rwa [(nth_strictMonoOn hf).lt_iff_lt hn hk, Nat.lt_succ_iff,
← (nth_strictMonoOn hf).le_iff_le hn (k.lt_succ_self.trans hk)] at h
· rw [nth_of_card_le _ hk] at h
exact absurd h (zero_le _).not_lt
· rcases subset_range_nth ha with ⟨n, rfl⟩
rwa [nth_lt_nth hf, Nat.lt_succ_iff, ← nth_le_nth hf] at h
lemma nth_mem_anti {a b : ℕ} (hab : a ≤ b) (h : p (nth p b)) : p (nth p a) := by
by_cases h' : ∀ hf : (setOf p).Finite, a < #hf.toFinset
· exact nth_mem a h'
· simp only [not_forall, not_lt] at h'
have h'b : ∃ hf : (setOf p).Finite, #hf.toFinset ≤ b := by
rcases h' with ⟨hf, ha⟩
exact ⟨hf, ha.trans hab⟩
have ha0 : nth p a = 0 := by simp [nth_eq_zero, h']
have hb0 : nth p b = 0 := by simp [nth_eq_zero, h'b]
rw [ha0]
rwa [hb0] at h
|
lemma nth_comp_of_strictMono {n : ℕ} {f : ℕ → ℕ} (hf : StrictMono f)
(h0 : ∀ k, p k → k ∈ Set.range f) (h : ∀ hfi : (setOf p).Finite, n < hfi.toFinset.card) :
| Mathlib/Data/Nat/Nth.lean | 278 | 280 |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Yury Kudryashov
-/
import Mathlib.MeasureTheory.Group.Arithmetic
import Mathlib.Topology.GDelta.UniformSpace
import Mathlib.Topology.Instances.EReal.Lemmas
import Mathlib.Topology.Instances.Rat
/-!
# Borel (measurable) space
## Main definitions
* `borel α` : the least `σ`-algebra that contains all open sets;
* `class BorelSpace` : a space with `TopologicalSpace` and `MeasurableSpace` structures
such that `‹MeasurableSpace α› = borel α`;
* `class OpensMeasurableSpace` : a space with `TopologicalSpace` and `MeasurableSpace`
structures such that all open sets are measurable; equivalently, `borel α ≤ ‹MeasurableSpace α›`.
* `BorelSpace` instances on `Empty`, `Unit`, `Bool`, `Nat`, `Int`, `Rat`;
* `MeasurableSpace` and `BorelSpace` instances on `ℝ`, `ℝ≥0`, `ℝ≥0∞`.
## Main statements
* `IsOpen.measurableSet`, `IsClosed.measurableSet`: open and closed sets are measurable;
* `Continuous.measurable` : a continuous function is measurable;
* `Continuous.measurable2` : if `f : α → β` and `g : α → γ` are measurable and `op : β × γ → δ`
is continuous, then `fun x => op (f x, g y)` is measurable;
* `Measurable.add` etc : dot notation for arithmetic operations on `Measurable` predicates,
and similarly for `dist` and `edist`;
* `AEMeasurable.add` : similar dot notation for almost everywhere measurable functions;
-/
noncomputable section
open Filter MeasureTheory Set Topology
open scoped NNReal ENNReal MeasureTheory
universe u v w x y
variable {α β γ γ₂ δ : Type*} {ι : Sort y} {s t u : Set α}
open MeasurableSpace TopologicalSpace
/-- `MeasurableSpace` structure generated by `TopologicalSpace`. -/
def borel (α : Type u) [TopologicalSpace α] : MeasurableSpace α :=
generateFrom { s : Set α | IsOpen s }
theorem borel_anti : Antitone (@borel α) := fun _ _ h =>
MeasurableSpace.generateFrom_le fun _ hs => .basic _ (h _ hs)
theorem borel_eq_top_of_discrete [TopologicalSpace α] [DiscreteTopology α] : borel α = ⊤ :=
top_le_iff.1 fun s _ => GenerateMeasurable.basic s (isOpen_discrete s)
theorem borel_eq_generateFrom_of_subbasis {s : Set (Set α)} [t : TopologicalSpace α]
[SecondCountableTopology α] (hs : t = .generateFrom s) : borel α = .generateFrom s :=
le_antisymm
(generateFrom_le fun u (hu : t.IsOpen u) => by
rw [hs] at hu
induction hu with
| | basic u hu => exact GenerateMeasurable.basic u hu
| univ => exact @MeasurableSet.univ α (generateFrom s)
| inter s₁ s₂ _ _ hs₁ hs₂ => exact @MeasurableSet.inter α (generateFrom s) _ _ hs₁ hs₂
| sUnion f hf ih =>
rcases isOpen_sUnion_countable f (by rwa [hs]) with ⟨v, hv, vf, vu⟩
rw [← vu]
exact @MeasurableSet.sUnion α (generateFrom s) _ hv fun x xv => ih _ (vf xv))
| Mathlib/MeasureTheory/Constructions/BorelSpace/Basic.lean | 63 | 69 |
/-
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
/-- Every ordinal has a fundamental sequence. -/
theorem exists_fundamental_sequence (a : Ordinal.{u}) :
∃ f, IsFundamentalSequence a a.cof.ord f := by
suffices h : ∃ o f, IsFundamentalSequence a o f by
rcases h with ⟨o, f, hf⟩
exact ⟨_, hf.ord_cof⟩
rcases exists_lsub_cof a with ⟨ι, f, hf, hι⟩
rcases ord_eq ι with ⟨r, wo, hr⟩
haveI := wo
let r' := Subrel r fun i ↦ ∀ j, r j i → f j < f i
let hrr' : r' ↪r r := Subrel.relEmbedding _ _
haveI := hrr'.isWellOrder
refine
⟨_, _, hrr'.ordinal_type_le.trans ?_, @fun i j _ h _ => (enum r' ⟨j, h⟩).prop _ ?_,
le_antisymm (blsub_le fun i hi => lsub_le_iff.1 hf.le _) ?_⟩
· rw [← hι, hr]
· change r (hrr'.1 _) (hrr'.1 _)
rwa [hrr'.2, @enum_lt_enum _ r']
· rw [← hf, lsub_le_iff]
intro i
suffices h : ∃ i' hi', f i ≤ bfamilyOfFamily' r' (fun i => f i) i' hi' by
rcases h with ⟨i', hi', hfg⟩
exact hfg.trans_lt (lt_blsub _ _ _)
by_cases h : ∀ j, r j i → f j < f i
· refine ⟨typein r' ⟨i, h⟩, typein_lt_type _ _, ?_⟩
rw [bfamilyOfFamily'_typein]
· push_neg at h
obtain ⟨hji, hij⟩ := wo.wf.min_mem _ h
refine ⟨typein r' ⟨_, fun k hkj => lt_of_lt_of_le ?_ hij⟩, typein_lt_type _ _, ?_⟩
· by_contra! H
exact (wo.wf.not_lt_min _ h ⟨IsTrans.trans _ _ _ hkj hji, H⟩) hkj
· rwa [bfamilyOfFamily'_typein]
@[simp]
theorem cof_cof (a : Ordinal.{u}) : cof (cof a).ord = cof a := by
obtain ⟨f, hf⟩ := exists_fundamental_sequence a
obtain ⟨g, hg⟩ := exists_fundamental_sequence a.cof.ord
exact ord_injective (hf.trans hg).cof_eq.symm
protected theorem IsNormal.isFundamentalSequence {f : Ordinal.{u} → Ordinal.{u}} (hf : IsNormal f)
{a o} (ha : IsLimit a) {g} (hg : IsFundamentalSequence a o g) :
IsFundamentalSequence (f a) o fun b hb => f (g b hb) := by
refine ⟨?_, @fun i j _ _ h => hf.strictMono (hg.2.1 _ _ h), ?_⟩
· rcases exists_lsub_cof (f a) with ⟨ι, f', hf', hι⟩
rw [← hg.cof_eq, ord_le_ord, ← hι]
suffices (lsub.{u, u} fun i => sInf { b : Ordinal | f' i ≤ f b }) = a by
rw [← this]
apply cof_lsub_le
have H : ∀ i, ∃ b < a, f' i ≤ f b := fun i => by
have := lt_lsub.{u, u} f' i
rw [hf', ← IsNormal.blsub_eq.{u, u} hf ha, lt_blsub_iff] at this
simpa using this
refine (lsub_le fun i => ?_).antisymm (le_of_forall_lt fun b hb => ?_)
· rcases H i with ⟨b, hb, hb'⟩
exact lt_of_le_of_lt (csInf_le' hb') hb
· have := hf.strictMono hb
rw [← hf', lt_lsub_iff] at this
obtain ⟨i, hi⟩ := this
rcases H i with ⟨b, _, hb⟩
exact
((le_csInf_iff'' ⟨b, by exact hb⟩).2 fun c hc =>
hf.strictMono.le_iff_le.1 (hi.trans hc)).trans_lt (lt_lsub _ i)
· rw [@blsub_comp.{u, u, u} a _ (fun b _ => f b) (@fun i j _ _ h => hf.strictMono.monotone h) g
hg.2.2]
exact IsNormal.blsub_eq.{u, u} hf ha
theorem IsNormal.cof_eq {f} (hf : IsNormal f) {a} (ha : IsLimit a) : cof (f a) = cof a :=
let ⟨_, hg⟩ := exists_fundamental_sequence a
ord_injective (hf.isFundamentalSequence ha hg).cof_eq
theorem IsNormal.cof_le {f} (hf : IsNormal f) (a) : cof a ≤ cof (f a) := by
rcases zero_or_succ_or_limit a with (rfl | ⟨b, rfl⟩ | ha)
· rw [cof_zero]
exact zero_le _
· rw [cof_succ, Cardinal.one_le_iff_ne_zero, cof_ne_zero, ← Ordinal.pos_iff_ne_zero]
exact (Ordinal.zero_le (f b)).trans_lt (hf.1 b)
· rw [hf.cof_eq ha]
@[simp]
theorem cof_add (a b : Ordinal) : b ≠ 0 → cof (a + b) = cof b := fun h => by
rcases zero_or_succ_or_limit b with (rfl | ⟨c, rfl⟩ | hb)
· contradiction
· rw [add_succ, cof_succ, cof_succ]
· exact (isNormal_add_right a).cof_eq hb
theorem aleph0_le_cof {o} : ℵ₀ ≤ cof o ↔ IsLimit o := by
rcases zero_or_succ_or_limit o with (rfl | ⟨o, rfl⟩ | l)
· simp [not_zero_isLimit, Cardinal.aleph0_ne_zero]
· simp [not_succ_isLimit, Cardinal.one_lt_aleph0]
· simp only [l, iff_true]
refine le_of_not_lt fun h => ?_
obtain ⟨n, e⟩ := Cardinal.lt_aleph0.1 h
have := cof_cof o
rw [e, ord_nat] at this
cases n
· simp at e
simp [e, not_zero_isLimit] at l
· rw [natCast_succ, cof_succ] at this
rw [← this, cof_eq_one_iff_is_succ] at e
rcases e with ⟨a, rfl⟩
exact not_succ_isLimit _ l
@[simp]
theorem cof_preOmega {o : Ordinal} (ho : IsSuccPrelimit o) : (preOmega o).cof = o.cof := by
by_cases h : IsMin o
· simp [h.eq_bot]
· exact isNormal_preOmega.cof_eq ⟨h, ho⟩
@[simp]
theorem cof_omega {o : Ordinal} (ho : o.IsLimit) : (ω_ o).cof = o.cof :=
isNormal_omega.cof_eq ho
@[simp]
theorem cof_omega0 : cof ω = ℵ₀ :=
(aleph0_le_cof.2 isLimit_omega0).antisymm' <| by
rw [← card_omega0]
apply cof_le_card
theorem cof_eq' (r : α → α → Prop) [IsWellOrder α r] (h : IsLimit (type r)) :
∃ S : Set α, (∀ a, ∃ b ∈ S, r a b) ∧ #S = cof (type r) :=
let ⟨S, H, e⟩ := cof_eq r
⟨S, fun a =>
let a' := enum r ⟨_, h.succ_lt (typein_lt_type r a)⟩
let ⟨b, h, ab⟩ := H a'
⟨b, h,
(IsOrderConnected.conn a b a' <|
(typein_lt_typein r).1
(by
rw [typein_enum]
exact lt_succ (typein _ _))).resolve_right
ab⟩,
e⟩
@[simp]
theorem cof_univ : cof univ.{u, v} = Cardinal.univ.{u, v} :=
le_antisymm (cof_le_card _)
(by
refine le_of_forall_lt fun c h => ?_
rcases lt_univ'.1 h with ⟨c, rfl⟩
rcases @cof_eq Ordinal.{u} (· < ·) _ with ⟨S, H, Se⟩
rw [univ, ← lift_cof, ← Cardinal.lift_lift.{u+1, v, u}, Cardinal.lift_lt, ← Se]
refine lt_of_not_ge fun h => ?_
obtain ⟨a, e⟩ := Cardinal.mem_range_lift_of_le h
refine Quotient.inductionOn a (fun α e => ?_) e
obtain ⟨f⟩ := Quotient.exact e
have f := Equiv.ulift.symm.trans f
let g a := (f a).1
let o := succ (iSup g)
rcases H o with ⟨b, h, l⟩
refine l (lt_succ_iff.2 ?_)
rw [← show g (f.symm ⟨b, h⟩) = b by simp [g]]
apply Ordinal.le_iSup)
end Ordinal
namespace Cardinal
open Ordinal
/-! ### Results on sets -/
theorem mk_bounded_subset {α : Type*} (h : ∀ x < #α, 2 ^ x < #α) {r : α → α → Prop}
[IsWellOrder α r] (hr : (#α).ord = type r) : #{ s : Set α // Bounded r s } = #α := by
rcases eq_or_ne #α 0 with (ha | ha)
· rw [ha]
haveI := mk_eq_zero_iff.1 ha
rw [mk_eq_zero_iff]
constructor
rintro ⟨s, hs⟩
exact (not_unbounded_iff s).2 hs (unbounded_of_isEmpty s)
have h' : IsStrongLimit #α := ⟨ha, @h⟩
have ha := h'.aleph0_le
apply le_antisymm
· have : { s : Set α | Bounded r s } = ⋃ i, 𝒫{ j | r j i } := setOf_exists _
rw [← coe_setOf, this]
refine mk_iUnion_le_sum_mk.trans ((sum_le_iSup (fun i => #(𝒫{ j | r j i }))).trans
((mul_le_max_of_aleph0_le_left ha).trans ?_))
rw [max_eq_left]
apply ciSup_le' _
intro i
rw [mk_powerset]
apply (h'.two_power_lt _).le
rw [coe_setOf, card_typein, ← lt_ord, hr]
apply typein_lt_type
· refine @mk_le_of_injective α _ (fun x => Subtype.mk {x} ?_) ?_
· apply bounded_singleton
rw [← hr]
apply isLimit_ord ha
· intro a b hab
simpa [singleton_eq_singleton_iff] using hab
theorem mk_subset_mk_lt_cof {α : Type*} (h : ∀ x < #α, 2 ^ x < #α) :
#{ s : Set α // #s < cof (#α).ord } = #α := by
rcases eq_or_ne #α 0 with (ha | ha)
· simp [ha]
have h' : IsStrongLimit #α := ⟨ha, @h⟩
rcases ord_eq α with ⟨r, wo, hr⟩
haveI := wo
apply le_antisymm
· conv_rhs => rw [← mk_bounded_subset h hr]
apply mk_le_mk_of_subset
intro s hs
rw [hr] at hs
exact lt_cof_type hs
· refine @mk_le_of_injective α _ (fun x => Subtype.mk {x} ?_) ?_
· rw [mk_singleton]
exact one_lt_aleph0.trans_le (aleph0_le_cof.2 (isLimit_ord h'.aleph0_le))
· intro a b hab
simpa [singleton_eq_singleton_iff] using hab
/-- If the union of s is unbounded and s is smaller than the cofinality,
then s has an unbounded member -/
theorem unbounded_of_unbounded_sUnion (r : α → α → Prop) [wo : IsWellOrder α r] {s : Set (Set α)}
(h₁ : Unbounded r <| ⋃₀ s) (h₂ : #s < Order.cof (swap rᶜ)) : ∃ x ∈ s, Unbounded r x := by
by_contra! h
simp_rw [not_unbounded_iff] at h
let f : s → α := fun x : s => wo.wf.sup x (h x.1 x.2)
refine h₂.not_le (le_trans (csInf_le' ⟨range f, fun x => ?_, rfl⟩) mk_range_le)
rcases h₁ x with ⟨y, ⟨c, hc, hy⟩, hxy⟩
exact ⟨f ⟨c, hc⟩, mem_range_self _, fun hxz => hxy (Trans.trans (wo.wf.lt_sup _ hy) hxz)⟩
/-- If the union of s is unbounded and s is smaller than the cofinality,
then s has an unbounded member -/
theorem unbounded_of_unbounded_iUnion {α β : Type u} (r : α → α → Prop) [wo : IsWellOrder α r]
(s : β → Set α) (h₁ : Unbounded r <| ⋃ x, s x) (h₂ : #β < Order.cof (swap rᶜ)) :
∃ x : β, Unbounded r (s x) := by
rw [← sUnion_range] at h₁
rcases unbounded_of_unbounded_sUnion r h₁ (mk_range_le.trans_lt h₂) with ⟨_, ⟨x, rfl⟩, u⟩
exact ⟨x, u⟩
/-! ### Consequences of König's lemma -/
theorem lt_power_cof {c : Cardinal.{u}} : ℵ₀ ≤ c → c < c ^ c.ord.cof :=
Cardinal.inductionOn c fun α h => by
rcases ord_eq α with ⟨r, wo, re⟩
have := isLimit_ord h
rw [re] at this ⊢
rcases cof_eq' r this with ⟨S, H, Se⟩
have := sum_lt_prod (fun a : S => #{ x // r x a }) (fun _ => #α) fun i => ?_
· simp only [Cardinal.prod_const, Cardinal.lift_id, ← Se, ← mk_sigma, power_def] at this ⊢
refine lt_of_le_of_lt ?_ this
refine ⟨Embedding.ofSurjective ?_ ?_⟩
· exact fun x => x.2.1
· exact fun a =>
let ⟨b, h, ab⟩ := H a
⟨⟨⟨_, h⟩, _, ab⟩, rfl⟩
· have := typein_lt_type r i
rwa [← re, lt_ord] at this
theorem lt_cof_power {a b : Cardinal} (ha : ℵ₀ ≤ a) (b1 : 1 < b) : a < (b ^ a).ord.cof := by
have b0 : b ≠ 0 := (zero_lt_one.trans b1).ne'
apply lt_imp_lt_of_le_imp_le (power_le_power_left <| power_ne_zero a b0)
rw [← power_mul, mul_eq_self ha]
exact lt_power_cof (ha.trans <| (cantor' _ b1).le)
end Cardinal
| Mathlib/SetTheory/Cardinal/Cofinality.lean | 802 | 814 | |
/-
Copyright (c) 2020 Joseph Myers. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joseph Myers, Sébastien Gouëzel, Heather Macbeth
-/
import Mathlib.Analysis.InnerProductSpace.Projection
import Mathlib.Analysis.Normed.Lp.PiLp
import Mathlib.LinearAlgebra.FiniteDimensional.Lemmas
import Mathlib.LinearAlgebra.UnitaryGroup
import Mathlib.Util.Superscript
/-!
# `L²` inner product space structure on finite products of inner product spaces
The `L²` norm on a finite product of inner product spaces is compatible with an inner product
$$
\langle x, y\rangle = \sum \langle x_i, y_i \rangle.
$$
This is recorded in this file as an inner product space instance on `PiLp 2`.
This file develops the notion of a finite dimensional Hilbert space over `𝕜 = ℂ, ℝ`, referred to as
`E`. We define an `OrthonormalBasis 𝕜 ι E` as a linear isometric equivalence
between `E` and `EuclideanSpace 𝕜 ι`. Then `stdOrthonormalBasis` shows that such an equivalence
always exists if `E` is finite dimensional. We provide language for converting between a basis
that is orthonormal and an orthonormal basis (e.g. `Basis.toOrthonormalBasis`). We show that
orthonormal bases for each summand in a direct sum of spaces can be combined into an orthonormal
basis for the whole sum in `DirectSum.IsInternal.subordinateOrthonormalBasis`. In
the last section, various properties of matrices are explored.
## Main definitions
- `EuclideanSpace 𝕜 n`: defined to be `PiLp 2 (n → 𝕜)` for any `Fintype n`, i.e., the space
from functions to `n` to `𝕜` with the `L²` norm. We register several instances on it (notably
that it is a finite-dimensional inner product space), and provide a `!ₚ[]` notation (for numeric
subscripts like `₂`) for the case when the indexing type is `Fin n`.
- `OrthonormalBasis 𝕜 ι`: defined to be an isometry to Euclidean space from a given
finite-dimensional inner product space, `E ≃ₗᵢ[𝕜] EuclideanSpace 𝕜 ι`.
- `Basis.toOrthonormalBasis`: constructs an `OrthonormalBasis` for a finite-dimensional
Euclidean space from a `Basis` which is `Orthonormal`.
- `Orthonormal.exists_orthonormalBasis_extension`: provides an existential result of an
`OrthonormalBasis` extending a given orthonormal set
- `exists_orthonormalBasis`: provides an orthonormal basis on a finite dimensional vector space
- `stdOrthonormalBasis`: provides an arbitrarily-chosen `OrthonormalBasis` of a given finite
dimensional inner product space
For consequences in infinite dimension (Hilbert bases, etc.), see the file
`Analysis.InnerProductSpace.L2Space`.
-/
open Real Set Filter RCLike Submodule Function Uniformity Topology NNReal ENNReal
ComplexConjugate DirectSum
noncomputable section
variable {ι ι' 𝕜 : Type*} [RCLike 𝕜]
variable {E : Type*} [NormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable {F : Type*} [NormedAddCommGroup F] [InnerProductSpace ℝ F]
variable {F' : Type*} [NormedAddCommGroup F'] [InnerProductSpace ℝ F']
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-
If `ι` is a finite type and each space `f i`, `i : ι`, is an inner product space,
then `Π i, f i` is an inner product space as well. Since `Π i, f i` is endowed with the sup norm,
we use instead `PiLp 2 f` for the product space, which is endowed with the `L^2` norm.
-/
instance PiLp.innerProductSpace {ι : Type*} [Fintype ι] (f : ι → Type*)
[∀ i, NormedAddCommGroup (f i)] [∀ i, InnerProductSpace 𝕜 (f i)] :
InnerProductSpace 𝕜 (PiLp 2 f) where
inner x y := ∑ i, inner (x i) (y i)
norm_sq_eq_re_inner x := by
simp only [PiLp.norm_sq_eq_of_L2, map_sum, ← norm_sq_eq_re_inner, one_div]
conj_inner_symm := by
intro x y
unfold inner
rw [map_sum]
apply Finset.sum_congr rfl
rintro z -
apply inner_conj_symm
add_left x y z :=
show (∑ i, inner (x i + y i) (z i)) = (∑ i, inner (x i) (z i)) + ∑ i, inner (y i) (z i) by
simp only [inner_add_left, Finset.sum_add_distrib]
smul_left x y r :=
show (∑ i : ι, inner (r • x i) (y i)) = conj r * ∑ i, inner (x i) (y i) by
simp only [Finset.mul_sum, inner_smul_left]
@[simp]
theorem PiLp.inner_apply {ι : Type*} [Fintype ι] {f : ι → Type*} [∀ i, NormedAddCommGroup (f i)]
[∀ i, InnerProductSpace 𝕜 (f i)] (x y : PiLp 2 f) : ⟪x, y⟫ = ∑ i, ⟪x i, y i⟫ :=
rfl
/-- The standard real/complex Euclidean space, functions on a finite type. For an `n`-dimensional
space use `EuclideanSpace 𝕜 (Fin n)`.
For the case when `n = Fin _`, there is `!₂[x, y, ...]` notation for building elements of this type,
analogous to `![x, y, ...]` notation. -/
abbrev EuclideanSpace (𝕜 : Type*) (n : Type*) : Type _ :=
PiLp 2 fun _ : n => 𝕜
section Notation
open Lean Meta Elab Term Macro TSyntax PrettyPrinter.Delaborator SubExpr
open Mathlib.Tactic (subscriptTerm)
/-- Notation for vectors in Lp space. `!₂[x, y, ...]` is a shorthand for
`(WithLp.equiv 2 _ _).symm ![x, y, ...]`, of type `EuclideanSpace _ (Fin _)`.
This also works for other subscripts. -/
syntax (name := PiLp.vecNotation) "!" noWs subscriptTerm noWs "[" term,* "]" : term
macro_rules | `(!$p:subscript[$e:term,*]) => do
-- override the `Fin n.succ` to a literal
let n := e.getElems.size
`((WithLp.equiv $p <| ∀ _ : Fin $(quote n), _).symm ![$e,*])
/-- Unexpander for the `!₂[x, y, ...]` notation. -/
@[app_delab DFunLike.coe]
def EuclideanSpace.delabVecNotation : Delab :=
whenNotPPOption getPPExplicit <| whenPPOption getPPNotation <| withOverApp 6 do
-- check that the `(WithLp.equiv _ _).symm` is present
let p : Term ← withAppFn <| withAppArg do
let_expr Equiv.symm _ _ e := ← getExpr | failure
let_expr WithLp.equiv _ _ := e | failure
withNaryArg 2 <| withNaryArg 0 <| delab
-- to be conservative, only allow subscripts which are numerals
guard <| p matches `($_:num)
let `(![$elems,*]) := ← withAppArg delab | failure
`(!$p[$elems,*])
end Notation
theorem EuclideanSpace.nnnorm_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x : EuclideanSpace 𝕜 n) : ‖x‖₊ = NNReal.sqrt (∑ i, ‖x i‖₊ ^ 2) :=
PiLp.nnnorm_eq_of_L2 x
theorem EuclideanSpace.norm_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x : EuclideanSpace 𝕜 n) : ‖x‖ = √(∑ i, ‖x i‖ ^ 2) := by
simpa only [Real.coe_sqrt, NNReal.coe_sum] using congr_arg ((↑) : ℝ≥0 → ℝ) x.nnnorm_eq
theorem EuclideanSpace.dist_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x y : EuclideanSpace 𝕜 n) : dist x y = √(∑ i, dist (x i) (y i) ^ 2) :=
PiLp.dist_eq_of_L2 x y
theorem EuclideanSpace.nndist_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x y : EuclideanSpace 𝕜 n) : nndist x y = NNReal.sqrt (∑ i, nndist (x i) (y i) ^ 2) :=
PiLp.nndist_eq_of_L2 x y
theorem EuclideanSpace.edist_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x y : EuclideanSpace 𝕜 n) : edist x y = (∑ i, edist (x i) (y i) ^ 2) ^ (1 / 2 : ℝ) :=
PiLp.edist_eq_of_L2 x y
theorem EuclideanSpace.ball_zero_eq {n : Type*} [Fintype n] (r : ℝ) (hr : 0 ≤ r) :
Metric.ball (0 : EuclideanSpace ℝ n) r = {x | ∑ i, x i ^ 2 < r ^ 2} := by
ext x
have : (0 : ℝ) ≤ ∑ i, x i ^ 2 := Finset.sum_nonneg fun _ _ => sq_nonneg _
simp_rw [mem_setOf, mem_ball_zero_iff, norm_eq, norm_eq_abs, sq_abs, sqrt_lt this hr]
theorem EuclideanSpace.closedBall_zero_eq {n : Type*} [Fintype n] (r : ℝ) (hr : 0 ≤ r) :
Metric.closedBall (0 : EuclideanSpace ℝ n) r = {x | ∑ i, x i ^ 2 ≤ r ^ 2} := by
ext
simp_rw [mem_setOf, mem_closedBall_zero_iff, norm_eq, norm_eq_abs, sq_abs, sqrt_le_left hr]
theorem EuclideanSpace.sphere_zero_eq {n : Type*} [Fintype n] (r : ℝ) (hr : 0 ≤ r) :
Metric.sphere (0 : EuclideanSpace ℝ n) r = {x | ∑ i, x i ^ 2 = r ^ 2} := by
ext x
have : (0 : ℝ) ≤ ∑ i, x i ^ 2 := Finset.sum_nonneg fun _ _ => sq_nonneg _
simp_rw [mem_setOf, mem_sphere_zero_iff_norm, norm_eq, norm_eq_abs, sq_abs,
Real.sqrt_eq_iff_eq_sq this hr]
section
variable [Fintype ι]
@[simp]
theorem finrank_euclideanSpace :
Module.finrank 𝕜 (EuclideanSpace 𝕜 ι) = Fintype.card ι := by
simp [EuclideanSpace, PiLp, WithLp]
theorem finrank_euclideanSpace_fin {n : ℕ} :
Module.finrank 𝕜 (EuclideanSpace 𝕜 (Fin n)) = n := by simp
theorem EuclideanSpace.inner_eq_star_dotProduct (x y : EuclideanSpace 𝕜 ι) :
⟪x, y⟫ = dotProduct (WithLp.equiv _ _ y) (star <| WithLp.equiv _ _ x) :=
rfl
theorem EuclideanSpace.inner_piLp_equiv_symm (x y : ι → 𝕜) :
⟪(WithLp.equiv 2 _).symm x, (WithLp.equiv 2 _).symm y⟫ = dotProduct y (star x) :=
rfl
/-- A finite, mutually orthogonal family of subspaces of `E`, which span `E`, induce an isometry
from `E` to `PiLp 2` of the subspaces equipped with the `L2` inner product. -/
def DirectSum.IsInternal.isometryL2OfOrthogonalFamily [DecidableEq ι] {V : ι → Submodule 𝕜 E}
(hV : DirectSum.IsInternal V)
(hV' : OrthogonalFamily 𝕜 (fun i => V i) fun i => (V i).subtypeₗᵢ) :
E ≃ₗᵢ[𝕜] PiLp 2 fun i => V i := by
let e₁ := DirectSum.linearEquivFunOnFintype 𝕜 ι fun i => V i
let e₂ := LinearEquiv.ofBijective (DirectSum.coeLinearMap V) hV
refine LinearEquiv.isometryOfInner (e₂.symm.trans e₁) ?_
suffices ∀ (v w : PiLp 2 fun i => V i), ⟪v, w⟫ = ⟪e₂ (e₁.symm v), e₂ (e₁.symm w)⟫ by
intro v₀ w₀
convert this (e₁ (e₂.symm v₀)) (e₁ (e₂.symm w₀)) <;>
simp only [LinearEquiv.symm_apply_apply, LinearEquiv.apply_symm_apply]
intro v w
trans ⟪∑ i, (V i).subtypeₗᵢ (v i), ∑ i, (V i).subtypeₗᵢ (w i)⟫
· simp only [sum_inner, hV'.inner_right_fintype, PiLp.inner_apply]
· congr <;> simp
@[simp]
theorem DirectSum.IsInternal.isometryL2OfOrthogonalFamily_symm_apply [DecidableEq ι]
{V : ι → Submodule 𝕜 E} (hV : DirectSum.IsInternal V)
(hV' : OrthogonalFamily 𝕜 (fun i => V i) fun i => (V i).subtypeₗᵢ) (w : PiLp 2 fun i => V i) :
(hV.isometryL2OfOrthogonalFamily hV').symm w = ∑ i, (w i : E) := by
classical
let e₁ := DirectSum.linearEquivFunOnFintype 𝕜 ι fun i => V i
let e₂ := LinearEquiv.ofBijective (DirectSum.coeLinearMap V) hV
suffices ∀ v : ⨁ i, V i, e₂ v = ∑ i, e₁ v i by exact this (e₁.symm w)
intro v
simp [e₁, e₂, DirectSum.coeLinearMap, DirectSum.toModule, DFinsupp.lsum,
DFinsupp.sumAddHom_apply]
end
variable (ι 𝕜)
/-- A shorthand for `PiLp.continuousLinearEquiv`. -/
abbrev EuclideanSpace.equiv : EuclideanSpace 𝕜 ι ≃L[𝕜] ι → 𝕜 :=
PiLp.continuousLinearEquiv 2 𝕜 _
variable {ι 𝕜}
/-- The projection on the `i`-th coordinate of `EuclideanSpace 𝕜 ι`, as a linear map. -/
abbrev EuclideanSpace.projₗ (i : ι) : EuclideanSpace 𝕜 ι →ₗ[𝕜] 𝕜 := PiLp.projₗ _ _ i
/-- The projection on the `i`-th coordinate of `EuclideanSpace 𝕜 ι`, as a continuous linear map. -/
abbrev EuclideanSpace.proj (i : ι) : EuclideanSpace 𝕜 ι →L[𝕜] 𝕜 := PiLp.proj _ _ i
section DecEq
variable [DecidableEq ι]
-- TODO : This should be generalized to `PiLp`.
/-- The vector given in euclidean space by being `a : 𝕜` at coordinate `i : ι` and `0 : 𝕜` at
all other coordinates. -/
def EuclideanSpace.single (i : ι) (a : 𝕜) : EuclideanSpace 𝕜 ι :=
(WithLp.equiv _ _).symm (Pi.single i a)
@[simp]
theorem WithLp.equiv_single (i : ι) (a : 𝕜) :
WithLp.equiv _ _ (EuclideanSpace.single i a) = Pi.single i a :=
rfl
@[simp]
theorem WithLp.equiv_symm_single (i : ι) (a : 𝕜) :
(WithLp.equiv _ _).symm (Pi.single i a) = EuclideanSpace.single i a :=
rfl
@[simp]
theorem EuclideanSpace.single_apply (i : ι) (a : 𝕜) (j : ι) :
(EuclideanSpace.single i a) j = ite (j = i) a 0 := by
rw [EuclideanSpace.single, WithLp.equiv_symm_pi_apply, ← Pi.single_apply i a j]
variable [Fintype ι]
theorem EuclideanSpace.inner_single_left (i : ι) (a : 𝕜) (v : EuclideanSpace 𝕜 ι) :
⟪EuclideanSpace.single i (a : 𝕜), v⟫ = conj a * v i := by simp [apply_ite conj, mul_comm]
theorem EuclideanSpace.inner_single_right (i : ι) (a : 𝕜) (v : EuclideanSpace 𝕜 ι) :
⟪v, EuclideanSpace.single i (a : 𝕜)⟫ = a * conj (v i) := by simp [apply_ite conj]
@[simp]
theorem EuclideanSpace.norm_single (i : ι) (a : 𝕜) :
‖EuclideanSpace.single i (a : 𝕜)‖ = ‖a‖ :=
PiLp.norm_equiv_symm_single 2 (fun _ => 𝕜) i a
@[simp]
theorem EuclideanSpace.nnnorm_single (i : ι) (a : 𝕜) :
‖EuclideanSpace.single i (a : 𝕜)‖₊ = ‖a‖₊ :=
PiLp.nnnorm_equiv_symm_single 2 (fun _ => 𝕜) i a
@[simp]
theorem EuclideanSpace.dist_single_same (i : ι) (a b : 𝕜) :
dist (EuclideanSpace.single i (a : 𝕜)) (EuclideanSpace.single i (b : 𝕜)) = dist a b :=
PiLp.dist_equiv_symm_single_same 2 (fun _ => 𝕜) i a b
@[simp]
theorem EuclideanSpace.nndist_single_same (i : ι) (a b : 𝕜) :
nndist (EuclideanSpace.single i (a : 𝕜)) (EuclideanSpace.single i (b : 𝕜)) = nndist a b :=
PiLp.nndist_equiv_symm_single_same 2 (fun _ => 𝕜) i a b
@[simp]
theorem EuclideanSpace.edist_single_same (i : ι) (a b : 𝕜) :
edist (EuclideanSpace.single i (a : 𝕜)) (EuclideanSpace.single i (b : 𝕜)) = edist a b :=
PiLp.edist_equiv_symm_single_same 2 (fun _ => 𝕜) i a b
/-- `EuclideanSpace.single` forms an orthonormal family. -/
theorem EuclideanSpace.orthonormal_single :
Orthonormal 𝕜 fun i : ι => EuclideanSpace.single i (1 : 𝕜) := by
simp_rw [orthonormal_iff_ite, EuclideanSpace.inner_single_left, map_one, one_mul,
EuclideanSpace.single_apply]
intros
trivial
theorem EuclideanSpace.piLpCongrLeft_single
{ι' : Type*} [Fintype ι'] [DecidableEq ι'] (e : ι' ≃ ι) (i' : ι') (v : 𝕜) :
LinearIsometryEquiv.piLpCongrLeft 2 𝕜 𝕜 e (EuclideanSpace.single i' v) =
EuclideanSpace.single (e i') v :=
LinearIsometryEquiv.piLpCongrLeft_single e i' _
end DecEq
variable (ι 𝕜 E)
variable [Fintype ι]
/-- An orthonormal basis on E is an identification of `E` with its dimensional-matching
`EuclideanSpace 𝕜 ι`. -/
structure OrthonormalBasis where ofRepr ::
/-- Linear isometry between `E` and `EuclideanSpace 𝕜 ι` representing the orthonormal basis. -/
repr : E ≃ₗᵢ[𝕜] EuclideanSpace 𝕜 ι
variable {ι 𝕜 E}
namespace OrthonormalBasis
theorem repr_injective :
Injective (repr : OrthonormalBasis ι 𝕜 E → E ≃ₗᵢ[𝕜] EuclideanSpace 𝕜 ι) := fun f g h => by
cases f
cases g
congr
/-- `b i` is the `i`th basis vector. -/
instance instFunLike : FunLike (OrthonormalBasis ι 𝕜 E) ι E where
coe b i := by classical exact b.repr.symm (EuclideanSpace.single i (1 : 𝕜))
coe_injective' b b' h := repr_injective <| LinearIsometryEquiv.toLinearEquiv_injective <|
LinearEquiv.symm_bijective.injective <| LinearEquiv.toLinearMap_injective <| by
classical
rw [← LinearMap.cancel_right (WithLp.linearEquiv 2 𝕜 (_ → 𝕜)).symm.surjective]
simp only [LinearIsometryEquiv.toLinearEquiv_symm]
refine LinearMap.pi_ext fun i k => ?_
have : k = k • (1 : 𝕜) := by rw [smul_eq_mul, mul_one]
rw [this, Pi.single_smul]
replace h := congr_fun h i
simp only [LinearEquiv.comp_coe, map_smul, LinearEquiv.coe_coe,
LinearEquiv.trans_apply, WithLp.linearEquiv_symm_apply, WithLp.equiv_symm_single,
LinearIsometryEquiv.coe_toLinearEquiv] at h ⊢
rw [h]
@[simp]
theorem coe_ofRepr [DecidableEq ι] (e : E ≃ₗᵢ[𝕜] EuclideanSpace 𝕜 ι) :
⇑(OrthonormalBasis.ofRepr e) = fun i => e.symm (EuclideanSpace.single i (1 : 𝕜)) := by
dsimp only [DFunLike.coe]
funext
congr!
@[simp]
protected theorem repr_symm_single [DecidableEq ι] (b : OrthonormalBasis ι 𝕜 E) (i : ι) :
b.repr.symm (EuclideanSpace.single i (1 : 𝕜)) = b i := by
dsimp only [DFunLike.coe]
congr!
@[simp]
protected theorem repr_self [DecidableEq ι] (b : OrthonormalBasis ι 𝕜 E) (i : ι) :
b.repr (b i) = EuclideanSpace.single i (1 : 𝕜) := by
rw [← b.repr_symm_single i, LinearIsometryEquiv.apply_symm_apply]
protected theorem repr_apply_apply (b : OrthonormalBasis ι 𝕜 E) (v : E) (i : ι) :
b.repr v i = ⟪b i, v⟫ := by
classical
rw [← b.repr.inner_map_map (b i) v, b.repr_self i, EuclideanSpace.inner_single_left]
simp only [one_mul, eq_self_iff_true, map_one]
@[simp]
protected theorem orthonormal (b : OrthonormalBasis ι 𝕜 E) : Orthonormal 𝕜 b := by
classical
rw [orthonormal_iff_ite]
intro i j
rw [← b.repr.inner_map_map (b i) (b j), b.repr_self i, b.repr_self j,
EuclideanSpace.inner_single_left, EuclideanSpace.single_apply, map_one, one_mul]
@[simp]
lemma norm_eq_one (b : OrthonormalBasis ι 𝕜 E) (i : ι) :
‖b i‖ = 1 := b.orthonormal.norm_eq_one i
@[simp]
lemma nnnorm_eq_one (b : OrthonormalBasis ι 𝕜 E) (i : ι) :
‖b i‖₊ = 1 := b.orthonormal.nnnorm_eq_one i
@[simp]
lemma enorm_eq_one (b : OrthonormalBasis ι 𝕜 E) (i : ι) :
‖b i‖ₑ = 1 := b.orthonormal.enorm_eq_one i
@[simp]
lemma inner_eq_zero (b : OrthonormalBasis ι 𝕜 E) {i j : ι} (hij : i ≠ j) :
⟪b i, b j⟫ = 0 := b.orthonormal.inner_eq_zero hij
/-- The `Basis ι 𝕜 E` underlying the `OrthonormalBasis` -/
protected def toBasis (b : OrthonormalBasis ι 𝕜 E) : Basis ι 𝕜 E :=
Basis.ofEquivFun b.repr.toLinearEquiv
@[simp]
protected theorem coe_toBasis (b : OrthonormalBasis ι 𝕜 E) : (⇑b.toBasis : ι → E) = ⇑b := rfl
@[simp]
protected theorem coe_toBasis_repr (b : OrthonormalBasis ι 𝕜 E) :
b.toBasis.equivFun = b.repr.toLinearEquiv :=
Basis.equivFun_ofEquivFun _
@[simp]
protected theorem coe_toBasis_repr_apply (b : OrthonormalBasis ι 𝕜 E) (x : E) (i : ι) :
b.toBasis.repr x i = b.repr x i := by
rw [← Basis.equivFun_apply, OrthonormalBasis.coe_toBasis_repr]
-- This used to be `rw`, but we need `erw` after https://github.com/leanprover/lean4/pull/2644
erw [LinearIsometryEquiv.coe_toLinearEquiv]
protected theorem sum_repr (b : OrthonormalBasis ι 𝕜 E) (x : E) : ∑ i, b.repr x i • b i = x := by
simp_rw [← b.coe_toBasis_repr_apply, ← b.coe_toBasis]
exact b.toBasis.sum_repr x
open scoped InnerProductSpace in
protected theorem sum_repr' (b : OrthonormalBasis ι 𝕜 E) (x : E) : ∑ i, ⟪b i, x⟫_𝕜 • b i = x := by
nth_rw 2 [← (b.sum_repr x)]
simp_rw [b.repr_apply_apply x]
protected theorem sum_repr_symm (b : OrthonormalBasis ι 𝕜 E) (v : EuclideanSpace 𝕜 ι) :
∑ i, v i • b i = b.repr.symm v := by simpa using (b.toBasis.equivFun_symm_apply v).symm
protected theorem sum_inner_mul_inner (b : OrthonormalBasis ι 𝕜 E) (x y : E) :
∑ i, ⟪x, b i⟫ * ⟪b i, y⟫ = ⟪x, y⟫ := by
have := congr_arg (innerSL 𝕜 x) (b.sum_repr y)
rw [map_sum] at this
convert this
rw [map_smul, b.repr_apply_apply, mul_comm]
simp
lemma sum_sq_norm_inner (b : OrthonormalBasis ι 𝕜 E) (x : E) :
∑ i, ‖⟪b i, x⟫‖ ^ 2 = ‖x‖ ^ 2 := by
rw [@norm_eq_sqrt_re_inner 𝕜, ← OrthonormalBasis.sum_inner_mul_inner b x x, map_sum]
simp_rw [inner_mul_symm_re_eq_norm, norm_mul, ← inner_conj_symm x, starRingEnd_apply,
| norm_star, ← pow_two]
rw [Real.sq_sqrt]
exact Fintype.sum_nonneg fun _ ↦ by positivity
| Mathlib/Analysis/InnerProductSpace/PiL2.lean | 443 | 445 |
/-
Copyright (c) 2017 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Tim Baumann, Stephen Morgan, Kim Morrison, Floris van Doorn
-/
import Mathlib.CategoryTheory.Functor.Category
import Mathlib.CategoryTheory.Iso
/-!
# Natural isomorphisms
For the most part, natural isomorphisms are just another sort of isomorphism.
We provide some special support for extracting components:
* if `α : F ≅ G`, then `a.app X : F.obj X ≅ G.obj X`,
and building natural isomorphisms from components:
*
```
NatIso.ofComponents
(app : ∀ X : C, F.obj X ≅ G.obj X)
(naturality : ∀ {X Y : C} (f : X ⟶ Y), F.map f ≫ (app Y).hom = (app X).hom ≫ G.map f) :
F ≅ G
```
only needing to check naturality in one direction.
## Implementation
Note that `NatIso` is a namespace without a corresponding definition;
we put some declarations that are specifically about natural isomorphisms in the `Iso`
namespace so that they are available using dot notation.
-/
open CategoryTheory
-- declare the `v`'s first; see `CategoryTheory.Category` for an explanation
universe v₁ v₂ v₃ v₄ u₁ u₂ u₃ u₄
namespace CategoryTheory
open NatTrans
variable {C : Type u₁} [Category.{v₁} C] {D : Type u₂} [Category.{v₂} D] {E : Type u₃}
[Category.{v₃} E] {E' : Type u₄} [Category.{v₄} E']
namespace Iso
/-- The application of a natural isomorphism to an object. We put this definition in a different
namespace, so that we can use `α.app` -/
@[simps]
def app {F G : C ⥤ D} (α : F ≅ G) (X : C) :
F.obj X ≅ G.obj X where
hom := α.hom.app X
inv := α.inv.app X
hom_inv_id := by rw [← comp_app, Iso.hom_inv_id]; rfl
inv_hom_id := by rw [← comp_app, Iso.inv_hom_id]; rfl
@[reassoc (attr := simp)]
theorem hom_inv_id_app {F G : C ⥤ D} (α : F ≅ G) (X : C) :
α.hom.app X ≫ α.inv.app X = 𝟙 (F.obj X) :=
congr_fun (congr_arg NatTrans.app α.hom_inv_id) X
@[reassoc (attr := simp)]
theorem inv_hom_id_app {F G : C ⥤ D} (α : F ≅ G) (X : C) :
α.inv.app X ≫ α.hom.app X = 𝟙 (G.obj X) :=
congr_fun (congr_arg NatTrans.app α.inv_hom_id) X
@[reassoc (attr := simp)]
lemma hom_inv_id_app_app {F G : C ⥤ D ⥤ E} (e : F ≅ G) (X₁ : C) (X₂ : D) :
(e.hom.app X₁).app X₂ ≫ (e.inv.app X₁).app X₂ = 𝟙 _ := by
rw [← NatTrans.comp_app, Iso.hom_inv_id_app, NatTrans.id_app]
@[reassoc (attr := simp)]
lemma inv_hom_id_app_app {F G : C ⥤ D ⥤ E} (e : F ≅ G) (X₁ : C) (X₂ : D) :
(e.inv.app X₁).app X₂ ≫ (e.hom.app X₁).app X₂ = 𝟙 _ := by
rw [← NatTrans.comp_app, Iso.inv_hom_id_app, NatTrans.id_app]
@[reassoc (attr := simp)]
lemma hom_inv_id_app_app_app {F G : C ⥤ D ⥤ E ⥤ E'} (e : F ≅ G)
(X₁ : C) (X₂ : D) (X₃ : E) :
((e.hom.app X₁).app X₂).app X₃ ≫ ((e.inv.app X₁).app X₂).app X₃ = 𝟙 _ := by
rw [← NatTrans.comp_app, ← NatTrans.comp_app, Iso.hom_inv_id_app,
NatTrans.id_app, NatTrans.id_app]
@[reassoc (attr := simp)]
lemma inv_hom_id_app_app_app {F G : C ⥤ D ⥤ E ⥤ E'} (e : F ≅ G)
(X₁ : C) (X₂ : D) (X₃ : E) :
((e.inv.app X₁).app X₂).app X₃ ≫ ((e.hom.app X₁).app X₂).app X₃ = 𝟙 _ := by
rw [← NatTrans.comp_app, ← NatTrans.comp_app, Iso.inv_hom_id_app,
NatTrans.id_app, NatTrans.id_app]
end Iso
namespace NatIso
open CategoryTheory.Category CategoryTheory.Functor
@[simp]
theorem trans_app {F G H : C ⥤ D} (α : F ≅ G) (β : G ≅ H) (X : C) :
(α ≪≫ β).app X = α.app X ≪≫ β.app X :=
rfl
@[deprecated Iso.app_hom (since := "2025-03-11")]
theorem app_hom {F G : C ⥤ D} (α : F ≅ G) (X : C) : (α.app X).hom = α.hom.app X :=
rfl
@[deprecated Iso.app_hom (since := "2025-03-11")]
theorem app_inv {F G : C ⥤ D} (α : F ≅ G) (X : C) : (α.app X).inv = α.inv.app X :=
rfl
variable {F G : C ⥤ D}
instance hom_app_isIso (α : F ≅ G) (X : C) : IsIso (α.hom.app X) :=
⟨⟨α.inv.app X,
⟨by rw [← comp_app, Iso.hom_inv_id, ← id_app], by rw [← comp_app, Iso.inv_hom_id, ← id_app]⟩⟩⟩
instance inv_app_isIso (α : F ≅ G) (X : C) : IsIso (α.inv.app X) :=
⟨⟨α.hom.app X,
⟨by rw [← comp_app, Iso.inv_hom_id, ← id_app], by rw [← comp_app, Iso.hom_inv_id, ← id_app]⟩⟩⟩
section
/-!
Unfortunately we need a separate set of cancellation lemmas for components of natural isomorphisms,
because the `simp` normal form is `α.hom.app X`, rather than `α.app.hom X`.
(With the latter, the morphism would be visibly part of an isomorphism, so general lemmas about
isomorphisms would apply.)
In the future, we should consider a redesign that changes this simp norm form,
but for now it breaks too many proofs.
-/
variable (α : F ≅ G)
@[simp]
theorem cancel_natIso_hom_left {X : C} {Z : D} (g g' : G.obj X ⟶ Z) :
α.hom.app X ≫ g = α.hom.app X ≫ g' ↔ g = g' := by simp only [cancel_epi, refl]
@[simp]
theorem cancel_natIso_inv_left {X : C} {Z : D} (g g' : F.obj X ⟶ Z) :
α.inv.app X ≫ g = α.inv.app X ≫ g' ↔ g = g' := by simp only [cancel_epi, refl]
@[simp]
| theorem cancel_natIso_hom_right {X : D} {Y : C} (f f' : X ⟶ F.obj Y) :
f ≫ α.hom.app Y = f' ≫ α.hom.app Y ↔ f = f' := by simp only [cancel_mono, refl]
@[simp]
| Mathlib/CategoryTheory/NatIso.lean | 146 | 149 |
/-
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.Complex.Log
/-! # Power function on `ℂ`
We construct the power functions `x ^ y`, where `x` and `y` are complex numbers.
-/
open Real Topology Filter ComplexConjugate Finset Set
namespace Complex
/-- The complex power function `x ^ y`, given by `x ^ y = exp(y log x)` (where `log` is the
principal determination of the logarithm), unless `x = 0` where one sets `0 ^ 0 = 1` and
`0 ^ y = 0` for `y ≠ 0`. -/
noncomputable def cpow (x y : ℂ) : ℂ :=
if x = 0 then if y = 0 then 1 else 0 else exp (log x * y)
noncomputable instance : Pow ℂ ℂ :=
⟨cpow⟩
@[simp]
theorem cpow_eq_pow (x y : ℂ) : cpow x y = x ^ y :=
rfl
theorem cpow_def (x y : ℂ) : x ^ y = if x = 0 then if y = 0 then 1 else 0 else exp (log x * y) :=
rfl
theorem cpow_def_of_ne_zero {x : ℂ} (hx : x ≠ 0) (y : ℂ) : x ^ y = exp (log x * y) :=
if_neg hx
@[simp]
theorem cpow_zero (x : ℂ) : x ^ (0 : ℂ) = 1 := by simp [cpow_def]
@[simp]
theorem cpow_eq_zero_iff (x y : ℂ) : x ^ y = 0 ↔ x = 0 ∧ y ≠ 0 := by
simp only [cpow_def]
split_ifs <;> simp [*, exp_ne_zero]
theorem cpow_ne_zero_iff {x y : ℂ} :
x ^ y ≠ 0 ↔ x ≠ 0 ∨ y = 0 := by
rw [ne_eq, cpow_eq_zero_iff, not_and_or, ne_eq, not_not]
theorem cpow_ne_zero_iff_of_exponent_ne_zero {x y : ℂ} (hy : y ≠ 0) :
x ^ y ≠ 0 ↔ x ≠ 0 := by simp [hy]
@[simp]
theorem zero_cpow {x : ℂ} (h : x ≠ 0) : (0 : ℂ) ^ x = 0 := by simp [cpow_def, *]
theorem zero_cpow_eq_iff {x : ℂ} {a : ℂ} : (0 : ℂ) ^ x = a ↔ x ≠ 0 ∧ a = 0 ∨ x = 0 ∧ a = 1 := by
constructor
· intro hyp
simp only [cpow_def, eq_self_iff_true, if_true] at hyp
by_cases h : x = 0
· subst h
simp only [if_true, eq_self_iff_true] at hyp
right
exact ⟨rfl, hyp.symm⟩
· rw [if_neg h] at hyp
left
exact ⟨h, hyp.symm⟩
· rintro (⟨h, rfl⟩ | ⟨rfl, rfl⟩)
· exact zero_cpow h
· exact cpow_zero _
theorem eq_zero_cpow_iff {x : ℂ} {a : ℂ} : a = (0 : ℂ) ^ x ↔ x ≠ 0 ∧ a = 0 ∨ x = 0 ∧ a = 1 := by
rw [← zero_cpow_eq_iff, eq_comm]
@[simp]
theorem cpow_one (x : ℂ) : x ^ (1 : ℂ) = x :=
if hx : x = 0 then by simp [hx, cpow_def]
else by rw [cpow_def, if_neg (one_ne_zero : (1 : ℂ) ≠ 0), if_neg hx, mul_one, exp_log hx]
@[simp]
theorem one_cpow (x : ℂ) : (1 : ℂ) ^ x = 1 := by
rw [cpow_def]
split_ifs <;> simp_all [one_ne_zero]
theorem cpow_add {x : ℂ} (y z : ℂ) (hx : x ≠ 0) : x ^ (y + z) = x ^ y * x ^ z := by
simp only [cpow_def, ite_mul, boole_mul, mul_ite, mul_boole]
simp_all [exp_add, mul_add]
theorem cpow_mul {x y : ℂ} (z : ℂ) (h₁ : -π < (log x * y).im) (h₂ : (log x * y).im ≤ π) :
x ^ (y * z) = (x ^ y) ^ z := by
simp only [cpow_def]
split_ifs <;> simp_all [exp_ne_zero, log_exp h₁ h₂, mul_assoc]
theorem cpow_neg (x y : ℂ) : x ^ (-y) = (x ^ y)⁻¹ := by
simp only [cpow_def, neg_eq_zero, mul_neg]
split_ifs <;> simp [exp_neg]
theorem cpow_sub {x : ℂ} (y z : ℂ) (hx : x ≠ 0) : x ^ (y - z) = x ^ y / x ^ z := by
rw [sub_eq_add_neg, cpow_add _ _ hx, cpow_neg, div_eq_mul_inv]
theorem cpow_neg_one (x : ℂ) : x ^ (-1 : ℂ) = x⁻¹ := by simpa using cpow_neg x 1
/-- See also `Complex.cpow_int_mul'`. -/
lemma cpow_int_mul (x : ℂ) (n : ℤ) (y : ℂ) : x ^ (n * y) = (x ^ y) ^ n := by
rcases eq_or_ne x 0 with rfl | hx
· rcases eq_or_ne n 0 with rfl | hn
· simp
| · rcases eq_or_ne y 0 with rfl | hy <;> simp [*, zero_zpow]
· rw [cpow_def_of_ne_zero hx, cpow_def_of_ne_zero hx, mul_left_comm, exp_int_mul]
| Mathlib/Analysis/SpecialFunctions/Pow/Complex.lean | 107 | 108 |
/-
Copyright (c) 2020 Aaron Anderson. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Aaron Anderson
-/
import Mathlib.FieldTheory.SplittingField.Construction
import Mathlib.RingTheory.Localization.Integral
import Mathlib.RingTheory.IntegralClosure.IntegrallyClosed
import Mathlib.RingTheory.Polynomial.Content
/-!
# Gauss's Lemma
Gauss's Lemma is one of a few results pertaining to irreducibility of primitive polynomials.
## Main Results
- `IsIntegrallyClosed.eq_map_mul_C_of_dvd`: if `R` is integrally closed, `K = Frac(R)` and
`g : K[X]` divides a monic polynomial with coefficients in `R`, then `g * (C g.leadingCoeff⁻¹)`
has coefficients in `R`
- `Polynomial.Monic.irreducible_iff_irreducible_map_fraction_map`:
A monic polynomial over an integrally closed domain is irreducible iff it is irreducible in a
fraction field
- `isIntegrallyClosed_iff'`:
Integrally closed domains are precisely the domains for in which Gauss's lemma holds
for monic polynomials
- `Polynomial.IsPrimitive.irreducible_iff_irreducible_map_fraction_map`:
A primitive polynomial over a GCD domain is irreducible iff it is irreducible in a fraction field
- `Polynomial.IsPrimitive.Int.irreducible_iff_irreducible_map_cast`:
A primitive polynomial over `ℤ` is irreducible iff it is irreducible over `ℚ`.
- `Polynomial.IsPrimitive.dvd_iff_fraction_map_dvd_fraction_map`:
Two primitive polynomials over a GCD domain divide each other iff they do in a fraction field.
- `Polynomial.IsPrimitive.Int.dvd_iff_map_cast_dvd_map_cast`:
Two primitive polynomials over `ℤ` divide each other if they do in `ℚ`.
-/
open scoped nonZeroDivisors Polynomial
variable {R : Type*} [CommRing R]
section IsIntegrallyClosed
open Polynomial
open integralClosure
open IsIntegrallyClosed
variable (K : Type*) [Field K] [Algebra R K]
theorem integralClosure.mem_lifts_of_monic_of_dvd_map {f : R[X]} (hf : f.Monic) {g : K[X]}
(hg : g.Monic) (hd : g ∣ f.map (algebraMap R K)) :
g ∈ lifts (algebraMap (integralClosure R K) K) := by
have := mem_lift_of_splits_of_roots_mem_range (integralClosure R g.SplittingField)
((splits_id_iff_splits _).2 <| SplittingField.splits g) (hg.map _) fun a ha =>
(SetLike.ext_iff.mp (integralClosure R g.SplittingField).range_algebraMap _).mpr <|
roots_mem_integralClosure hf ?_
· rw [lifts_iff_coeff_lifts, ← RingHom.coe_range, Subalgebra.range_algebraMap] at this
refine (lifts_iff_coeff_lifts _).2 fun n => ?_
rw [← RingHom.coe_range, Subalgebra.range_algebraMap]
obtain ⟨p, hp, he⟩ := SetLike.mem_coe.mp (this n); use p, hp
rw [IsScalarTower.algebraMap_eq R K, coeff_map, ← eval₂_map, eval₂_at_apply] at he
rw [eval₂_eq_eval_map]; apply (injective_iff_map_eq_zero _).1 _ _ he
apply RingHom.injective
rw [aroots_def, IsScalarTower.algebraMap_eq R K _, ← map_map]
refine Multiset.mem_of_le (roots.le_of_dvd ((hf.map _).map _).ne_zero ?_) ha
exact map_dvd (algebraMap K g.SplittingField) hd
variable [IsFractionRing R K]
/-- If `K = Frac(R)` and `g : K[X]` divides a monic polynomial with coefficients in `R`, then
`g * (C g.leadingCoeff⁻¹)` has coefficients in `R` -/
theorem IsIntegrallyClosed.eq_map_mul_C_of_dvd [IsIntegrallyClosed R] {f : R[X]} (hf : f.Monic)
{g : K[X]} (hg : g ∣ f.map (algebraMap R K)) :
∃ g' : R[X], g'.map (algebraMap R K) * (C <| leadingCoeff g) = g := by
have g_ne_0 : g ≠ 0 := ne_zero_of_dvd_ne_zero (Monic.ne_zero <| hf.map (algebraMap R K)) hg
suffices lem : ∃ g' : R[X], g'.map (algebraMap R K) = g * C g.leadingCoeff⁻¹ by
obtain ⟨g', hg'⟩ := lem
use g'
rw [hg', mul_assoc, ← C_mul, inv_mul_cancel₀ (leadingCoeff_ne_zero.mpr g_ne_0), C_1, mul_one]
have g_mul_dvd : g * C g.leadingCoeff⁻¹ ∣ f.map (algebraMap R K) := by
rwa [Associated.dvd_iff_dvd_left (show Associated (g * C g.leadingCoeff⁻¹) g from _)]
rw [associated_mul_isUnit_left_iff]
exact isUnit_C.mpr (inv_ne_zero <| leadingCoeff_ne_zero.mpr g_ne_0).isUnit
let algeq :=
(Subalgebra.equivOfEq _ _ <| integralClosure_eq_bot R _).trans
(Algebra.botEquivOfInjective <| IsFractionRing.injective R <| K)
have :
(algebraMap R _).comp algeq.toAlgHom.toRingHom = (integralClosure R _).toSubring.subtype := by
ext x; (conv_rhs => rw [← algeq.symm_apply_apply x]); rfl
have H :=
(mem_lifts _).1
(integralClosure.mem_lifts_of_monic_of_dvd_map K hf (monic_mul_leadingCoeff_inv g_ne_0)
g_mul_dvd)
refine ⟨map algeq.toAlgHom.toRingHom ?_, ?_⟩
· use! Classical.choose H
· rw [map_map, this]
exact Classical.choose_spec H
end IsIntegrallyClosed
namespace Polynomial
section
variable {S : Type*} [CommRing S] [IsDomain S]
variable {φ : R →+* S} (hinj : Function.Injective φ) {f : R[X]} (hf : f.IsPrimitive)
include hinj hf
theorem IsPrimitive.isUnit_iff_isUnit_map_of_injective : IsUnit f ↔ IsUnit (map φ f) := by
refine ⟨(mapRingHom φ).isUnit_map, fun h => ?_⟩
rcases isUnit_iff.1 h with ⟨_, ⟨u, rfl⟩, hu⟩
have hdeg := degree_C u.ne_zero
rw [hu, degree_map_eq_of_injective hinj] at hdeg
rw [eq_C_of_degree_eq_zero hdeg] at hf ⊢
exact isUnit_C.mpr (isPrimitive_iff_isUnit_of_C_dvd.mp hf (f.coeff 0) dvd_rfl)
theorem IsPrimitive.irreducible_of_irreducible_map_of_injective (h_irr : Irreducible (map φ f)) :
Irreducible f := by
refine
⟨fun h => h_irr.not_isUnit (IsUnit.map (mapRingHom φ) h), fun a b h =>
(h_irr.isUnit_or_isUnit <| by rw [h, Polynomial.map_mul]).imp ?_ ?_⟩
all_goals apply ((isPrimitive_of_dvd hf _).isUnit_iff_isUnit_map_of_injective hinj).mpr
exacts [Dvd.intro _ h.symm, Dvd.intro_left _ h.symm]
end
section FractionMap
variable {K : Type*} [Field K] [Algebra R K] [IsFractionRing R K]
theorem IsPrimitive.isUnit_iff_isUnit_map {p : R[X]} (hp : p.IsPrimitive) :
IsUnit p ↔ IsUnit (p.map (algebraMap R K)) :=
hp.isUnit_iff_isUnit_map_of_injective (IsFractionRing.injective _ _)
section IsIntegrallyClosed
open IsIntegrallyClosed
/-- **Gauss's Lemma** for integrally closed domains states that a monic polynomial is irreducible
iff it is irreducible in the fraction field. -/
theorem Monic.irreducible_iff_irreducible_map_fraction_map [IsIntegrallyClosed R] {p : R[X]}
(h : p.Monic) : Irreducible p ↔ Irreducible (p.map <| algebraMap R K) := by
/- The ← direction follows from `IsPrimitive.irreducible_of_irreducible_map_of_injective`.
For the → direction, it is enough to show that if `(p.map <| algebraMap R K) = a * b` and
`a` is not a unit then `b` is a unit -/
refine
⟨fun hp =>
irreducible_iff.mpr
⟨hp.not_isUnit.imp h.isPrimitive.isUnit_iff_isUnit_map.mpr, fun a b H =>
or_iff_not_imp_left.mpr fun hₐ => ?_⟩,
fun hp =>
h.isPrimitive.irreducible_of_irreducible_map_of_injective (IsFractionRing.injective R K) hp⟩
obtain ⟨a', ha⟩ := eq_map_mul_C_of_dvd K h (dvd_of_mul_right_eq b H.symm)
obtain ⟨b', hb⟩ := eq_map_mul_C_of_dvd K h (dvd_of_mul_left_eq a H.symm)
have : a.leadingCoeff * b.leadingCoeff = 1 := by
rw [← leadingCoeff_mul, ← H, Monic.leadingCoeff (h.map <| algebraMap R K)]
rw [← ha, ← hb, mul_comm _ (C b.leadingCoeff), mul_assoc, ← mul_assoc (C a.leadingCoeff), ←
C_mul, this, C_1, one_mul, ← Polynomial.map_mul] at H
rw [← hb, ← Polynomial.coe_mapRingHom]
refine
IsUnit.mul (IsUnit.map _ (Or.resolve_left (hp.isUnit_or_isUnit ?_) (show ¬IsUnit a' from ?_)))
(isUnit_iff_exists_inv'.mpr
-- Porting note(https://github.com/leanprover-community/mathlib4/issues/5073): was `rwa`
(Exists.intro (C a.leadingCoeff) <| by rw [← C_mul, this, C_1]))
· exact Polynomial.map_injective _ (IsFractionRing.injective R K) H
· by_contra h_contra
refine hₐ ?_
rw [← ha, ← Polynomial.coe_mapRingHom]
exact
IsUnit.mul (IsUnit.map _ h_contra)
(isUnit_iff_exists_inv.mpr
-- Porting note(https://github.com/leanprover-community/mathlib4/issues/5073): was `rwa`
(Exists.intro (C b.leadingCoeff) <| by rw [← C_mul, this, C_1]))
/-- Integrally closed domains are precisely the domains for in which Gauss's lemma holds
for monic polynomials -/
theorem isIntegrallyClosed_iff' [IsDomain R] :
IsIntegrallyClosed R ↔
∀ p : R[X], p.Monic → (Irreducible p ↔ Irreducible (p.map <| algebraMap R K)) := by
constructor
· intro hR p hp; exact Monic.irreducible_iff_irreducible_map_fraction_map hp
· intro H
refine
(isIntegrallyClosed_iff K).mpr fun {x} hx =>
RingHom.mem_range.mp <| minpoly.mem_range_of_degree_eq_one R x ?_
rw [← Monic.degree_map (minpoly.monic hx) (algebraMap R K)]
apply
degree_eq_one_of_irreducible_of_root ((H _ <| minpoly.monic hx).mp (minpoly.irreducible hx))
rw [IsRoot, eval_map, ← aeval_def, minpoly.aeval R x]
theorem Monic.dvd_of_fraction_map_dvd_fraction_map [IsIntegrallyClosed R] {p q : R[X]}
(hp : p.Monic) (hq : q.Monic)
(h : q.map (algebraMap R K) ∣ p.map (algebraMap R K)) : q ∣ p := by
obtain ⟨r, hr⟩ := h
obtain ⟨d', hr'⟩ := IsIntegrallyClosed.eq_map_mul_C_of_dvd K hp (dvd_of_mul_left_eq _ hr.symm)
rw [Monic.leadingCoeff, C_1, mul_one] at hr'
· rw [← hr', ← Polynomial.map_mul] at hr
exact dvd_of_mul_right_eq _ (Polynomial.map_injective _ (IsFractionRing.injective R K) hr.symm)
· exact Monic.of_mul_monic_left (hq.map (algebraMap R K)) (by simpa [← hr] using hp.map _)
theorem Monic.dvd_iff_fraction_map_dvd_fraction_map [IsIntegrallyClosed R] {p q : R[X]}
| (hp : p.Monic) (hq : q.Monic) : q.map (algebraMap R K) ∣ p.map (algebraMap R K) ↔ q ∣ p :=
⟨fun h => hp.dvd_of_fraction_map_dvd_fraction_map hq h, fun ⟨a, b⟩ =>
⟨a.map (algebraMap R K), b.symm ▸ Polynomial.map_mul (algebraMap R K)⟩⟩
end IsIntegrallyClosed
open IsLocalization
section NormalizedGCDMonoid
| Mathlib/RingTheory/Polynomial/GaussLemma.lean | 204 | 212 |
/-
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.Tactic.Ring
import Mathlib.Data.PNat.Prime
/-!
# Euclidean algorithm for ℕ
This file sets up a version of the Euclidean algorithm that only works with natural numbers.
Given `0 < a, b`, it computes the unique `(w, x, y, z, d)` such that the following identities hold:
* `a = (w + x) d`
* `b = (y + z) d`
* `w * z = x * y + 1`
`d` is then the gcd of `a` and `b`, and `a' := a / d = w + x` and `b' := b / d = y + z` are coprime.
This story is closely related to the structure of SL₂(ℕ) (as a free monoid on two generators) and
the theory of continued fractions.
## Main declarations
* `XgcdType`: Helper type in defining the gcd. Encapsulates `(wp, x, y, zp, ap, bp)`. where `wp`
`zp`, `ap`, `bp` are the variables getting changed through the algorithm.
* `IsSpecial`: States `wp * zp = x * y + 1`
* `IsReduced`: States `ap = a ∧ bp = b`
## Notes
See `Nat.Xgcd` for a very similar algorithm allowing values in `ℤ`.
-/
open Nat
namespace PNat
/-- A term of `XgcdType` is a system of six naturals. They should
be thought of as representing the matrix
[[w, x], [y, z]] = [[wp + 1, x], [y, zp + 1]]
together with the vector [a, b] = [ap + 1, bp + 1].
-/
structure XgcdType where
/-- `wp` is a variable which changes through the algorithm. -/
wp : ℕ
/-- `x` satisfies `a / d = w + x` at the final step. -/
x : ℕ
/-- `y` satisfies `b / d = z + y` at the final step. -/
y : ℕ
/-- `zp` is a variable which changes through the algorithm. -/
zp : ℕ
/-- `ap` is a variable which changes through the algorithm. -/
ap : ℕ
/-- `bp` is a variable which changes through the algorithm. -/
bp : ℕ
deriving Inhabited
namespace XgcdType
variable (u : XgcdType)
instance : SizeOf XgcdType :=
⟨fun u => u.bp⟩
/-- The `Repr` instance converts terms to strings in a way that
reflects the matrix/vector interpretation as above. -/
instance : Repr XgcdType where
reprPrec
| g, _ => s!"[[[{repr (g.wp + 1)}, {repr g.x}], \
[{repr g.y}, {repr (g.zp + 1)}]], \
[{repr (g.ap + 1)}, {repr (g.bp + 1)}]]"
/-- Another `mk` using ℕ and ℕ+ -/
def mk' (w : ℕ+) (x : ℕ) (y : ℕ) (z : ℕ+) (a : ℕ+) (b : ℕ+) : XgcdType :=
mk w.val.pred x y z.val.pred a.val.pred b.val.pred
/-- `w = wp + 1` -/
def w : ℕ+ :=
succPNat u.wp
/-- `z = zp + 1` -/
def z : ℕ+ :=
succPNat u.zp
/-- `a = ap + 1` -/
def a : ℕ+ :=
succPNat u.ap
/-- `b = bp + 1` -/
def b : ℕ+ :=
succPNat u.bp
/-- `r = a % b`: remainder -/
def r : ℕ :=
(u.ap + 1) % (u.bp + 1)
/-- `q = ap / bp`: quotient -/
def q : ℕ :=
(u.ap + 1) / (u.bp + 1)
/-- `qp = q - 1` -/
def qp : ℕ :=
u.q - 1
/-- The map `v` gives the product of the matrix
[[w, x], [y, z]] = [[wp + 1, x], [y, zp + 1]]
and the vector [a, b] = [ap + 1, bp + 1]. The map
`vp` gives [sp, tp] such that v = [sp + 1, tp + 1].
-/
def vp : ℕ × ℕ :=
⟨u.wp + u.x + u.ap + u.wp * u.ap + u.x * u.bp, u.y + u.zp + u.bp + u.y * u.ap + u.zp * u.bp⟩
/-- `v = [sp + 1, tp + 1]`, check `vp` -/
def v : ℕ × ℕ :=
⟨u.w * u.a + u.x * u.b, u.y * u.a + u.z * u.b⟩
/-- `succ₂ [t.1, t.2] = [t.1.succ, t.2.succ]` -/
def succ₂ (t : ℕ × ℕ) : ℕ × ℕ :=
⟨t.1.succ, t.2.succ⟩
theorem v_eq_succ_vp : u.v = succ₂ u.vp := by
ext <;> dsimp [v, vp, w, z, a, b, succ₂] <;> ring_nf
/-- `IsSpecial` holds if the matrix has determinant one. -/
def IsSpecial : Prop :=
u.wp + u.zp + u.wp * u.zp = u.x * u.y
/-- `IsSpecial'` is an alternative of `IsSpecial`. -/
def IsSpecial' : Prop :=
u.w * u.z = succPNat (u.x * u.y)
theorem isSpecial_iff : u.IsSpecial ↔ u.IsSpecial' := by
dsimp [IsSpecial, IsSpecial']
let ⟨wp, x, y, zp, ap, bp⟩ := u
constructor <;> intro h <;> simp only [w, succPNat, succ_eq_add_one, z] at * <;>
simp only [← coe_inj, mul_coe, mk_coe] at *
· simp_all [← h]; ring
· simp [Nat.mul_add, Nat.add_mul, ← Nat.add_assoc] at h; rw [← h]; ring
/-- `IsReduced` holds if the two entries in the vector are the
same. The reduction algorithm will produce a system with this
property, whose product vector is the same as for the original
system. -/
def IsReduced : Prop :=
u.ap = u.bp
/-- `IsReduced'` is an alternative of `IsReduced`. -/
def IsReduced' : Prop :=
u.a = u.b
theorem isReduced_iff : u.IsReduced ↔ u.IsReduced' :=
succPNat_inj.symm
/-- `flip` flips the placement of variables during the algorithm. -/
def flip : XgcdType where
wp := u.zp
x := u.y
y := u.x
zp := u.wp
ap := u.bp
bp := u.ap
@[simp]
theorem flip_w : (flip u).w = u.z :=
rfl
@[simp]
theorem flip_x : (flip u).x = u.y :=
rfl
@[simp]
theorem flip_y : (flip u).y = u.x :=
rfl
@[simp]
theorem flip_z : (flip u).z = u.w :=
rfl
@[simp]
theorem flip_a : (flip u).a = u.b :=
rfl
@[simp]
theorem flip_b : (flip u).b = u.a :=
rfl
theorem flip_isReduced : (flip u).IsReduced ↔ u.IsReduced := by
dsimp [IsReduced, flip]
constructor <;> intro h <;> exact h.symm
theorem flip_isSpecial : (flip u).IsSpecial ↔ u.IsSpecial := by
dsimp [IsSpecial, flip]
rw [mul_comm u.x, mul_comm u.zp, add_comm u.zp]
theorem flip_v : (flip u).v = u.v.swap := by
dsimp [v]
ext
· simp only
ring
· simp only
ring
/-- Properties of division with remainder for a / b. -/
theorem rq_eq : u.r + (u.bp + 1) * u.q = u.ap + 1 :=
Nat.mod_add_div (u.ap + 1) (u.bp + 1)
theorem qp_eq (hr : u.r = 0) : u.q = u.qp + 1 := by
by_cases hq : u.q = 0
· let h := u.rq_eq
rw [hr, hq, mul_zero, add_zero] at h
cases h
· exact (Nat.succ_pred_eq_of_pos (Nat.pos_of_ne_zero hq)).symm
/-- The following function provides the starting point for
our algorithm. We will apply an iterative reduction process
to it, which will produce a system satisfying IsReduced.
The gcd can be read off from this final system.
-/
def start (a b : ℕ+) : XgcdType :=
⟨0, 0, 0, 0, a - 1, b - 1⟩
theorem start_isSpecial (a b : ℕ+) : (start a b).IsSpecial := by
dsimp [start, IsSpecial]
theorem start_v (a b : ℕ+) : (start a b).v = ⟨a, b⟩ := by
dsimp [start, v, XgcdType.a, XgcdType.b, w, z]
rw [one_mul, one_mul, zero_mul, zero_mul]
have := a.pos
have := b.pos
congr <;> omega
/-- `finish` happens when the reducing process ends. -/
def finish : XgcdType :=
XgcdType.mk u.wp ((u.wp + 1) * u.qp + u.x) u.y (u.y * u.qp + u.zp) u.bp u.bp
theorem finish_isReduced : u.finish.IsReduced := by
dsimp [IsReduced]
rfl
theorem finish_isSpecial (hs : u.IsSpecial) : u.finish.IsSpecial := by
dsimp [IsSpecial, finish] at hs ⊢
rw [add_mul _ _ u.y, add_comm _ (u.x * u.y), ← hs]
ring
theorem finish_v (hr : u.r = 0) : u.finish.v = u.v := by
let ha : u.r + u.b * u.q = u.a := u.rq_eq
rw [hr, zero_add] at ha
ext
· change (u.wp + 1) * u.b + ((u.wp + 1) * u.qp + u.x) * u.b = u.w * u.a + u.x * u.b
have : u.wp + 1 = u.w := rfl
rw [this, ← ha, u.qp_eq hr]
ring
· change u.y * u.b + (u.y * u.qp + u.z) * u.b = u.y * u.a + u.z * u.b
rw [← ha, u.qp_eq hr]
ring
| /-- This is the main reduction step, which is used when u.r ≠ 0, or
equivalently b does not divide a. -/
| Mathlib/Data/PNat/Xgcd.lean | 258 | 259 |
/-
Copyright (c) 2018 Kenny Lau. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kenny Lau, Patrick Massot, Yury Kudryashov
-/
import Mathlib.Topology.Connected.Clopen
/-!
# Totally disconnected and totally separated topological spaces
## Main definitions
We define the following properties for sets in a topological space:
* `IsTotallyDisconnected`: all of its connected components are singletons.
* `IsTotallySeparated`: any two points can be separated by two disjoint opens that cover the set.
For both of these definitions, we also have a class stating that the whole space
satisfies that property: `TotallyDisconnectedSpace`, `TotallySeparatedSpace`.
-/
open Function Set Topology
universe u v
variable {α : Type u} {β : Type v} {ι : Type*} {π : ι → Type*} [TopologicalSpace α]
{s t u v : Set α}
section TotallyDisconnected
/-- A set `s` is called totally disconnected if every subset `t ⊆ s` which is preconnected is
a subsingleton, ie either empty or a singleton. -/
def IsTotallyDisconnected (s : Set α) : Prop :=
∀ t, t ⊆ s → IsPreconnected t → t.Subsingleton
theorem isTotallyDisconnected_empty : IsTotallyDisconnected (∅ : Set α) := fun _ ht _ _ x_in _ _ =>
(ht x_in).elim
theorem isTotallyDisconnected_singleton {x} : IsTotallyDisconnected ({x} : Set α) := fun _ ht _ =>
subsingleton_singleton.anti ht
/-- A space is totally disconnected if all of its connected components are singletons. -/
@[mk_iff]
class TotallyDisconnectedSpace (α : Type u) [TopologicalSpace α] : Prop where
/-- The universal set `Set.univ` in a totally disconnected space is totally disconnected. -/
isTotallyDisconnected_univ : IsTotallyDisconnected (univ : Set α)
theorem IsPreconnected.subsingleton [TotallyDisconnectedSpace α] {s : Set α}
(h : IsPreconnected s) : s.Subsingleton :=
TotallyDisconnectedSpace.isTotallyDisconnected_univ s (subset_univ s) h
instance Pi.totallyDisconnectedSpace {α : Type*} {β : α → Type*}
[∀ a, TopologicalSpace (β a)] [∀ a, TotallyDisconnectedSpace (β a)] :
TotallyDisconnectedSpace (∀ a : α, β a) :=
⟨fun t _ h2 =>
have this : ∀ a, IsPreconnected ((fun x : ∀ a, β a => x a) '' t) := fun a =>
h2.image (fun x => x a) (continuous_apply a).continuousOn
fun x x_in y y_in => funext fun a => (this a).subsingleton ⟨x, x_in, rfl⟩ ⟨y, y_in, rfl⟩⟩
instance Prod.totallyDisconnectedSpace [TopologicalSpace β] [TotallyDisconnectedSpace α]
[TotallyDisconnectedSpace β] : TotallyDisconnectedSpace (α × β) :=
⟨fun t _ h2 =>
have H1 : IsPreconnected (Prod.fst '' t) := h2.image Prod.fst continuous_fst.continuousOn
have H2 : IsPreconnected (Prod.snd '' t) := h2.image Prod.snd continuous_snd.continuousOn
fun x hx y hy =>
Prod.ext (H1.subsingleton ⟨x, hx, rfl⟩ ⟨y, hy, rfl⟩)
(H2.subsingleton ⟨x, hx, rfl⟩ ⟨y, hy, rfl⟩)⟩
instance [TopologicalSpace β] [TotallyDisconnectedSpace α] [TotallyDisconnectedSpace β] :
TotallyDisconnectedSpace (α ⊕ β) := by
refine ⟨fun s _ hs => ?_⟩
obtain ⟨t, ht, rfl⟩ | ⟨t, ht, rfl⟩ := Sum.isPreconnected_iff.1 hs
· exact ht.subsingleton.image _
· exact ht.subsingleton.image _
instance [∀ i, TopologicalSpace (π i)] [∀ i, TotallyDisconnectedSpace (π i)] :
TotallyDisconnectedSpace (Σi, π i) := by
refine ⟨fun s _ hs => ?_⟩
obtain rfl | h := s.eq_empty_or_nonempty
· exact subsingleton_empty
· obtain ⟨a, t, ht, rfl⟩ := Sigma.isConnected_iff.1 ⟨h, hs⟩
exact ht.isPreconnected.subsingleton.image _
/-- A space is totally disconnected iff its connected components are subsingletons. -/
theorem totallyDisconnectedSpace_iff_connectedComponent_subsingleton :
TotallyDisconnectedSpace α ↔ ∀ x : α, (connectedComponent x).Subsingleton := by
constructor
· intro h x
apply h.1
· exact subset_univ _
exact isPreconnected_connectedComponent
intro h; constructor
intro s s_sub hs
rcases eq_empty_or_nonempty s with (rfl | ⟨x, x_in⟩)
· exact subsingleton_empty
· exact (h x).anti (hs.subset_connectedComponent x_in)
/-- A space is totally disconnected iff its connected components are singletons. -/
theorem totallyDisconnectedSpace_iff_connectedComponent_singleton :
TotallyDisconnectedSpace α ↔ ∀ x : α, connectedComponent x = {x} := by
rw [totallyDisconnectedSpace_iff_connectedComponent_subsingleton]
refine forall_congr' fun x => ?_
rw [subsingleton_iff_singleton]
exact mem_connectedComponent
@[simp] theorem connectedComponent_eq_singleton [TotallyDisconnectedSpace α] (x : α) :
connectedComponent x = {x} :=
totallyDisconnectedSpace_iff_connectedComponent_singleton.1 ‹_› x
|
/-- The image of a connected component in a totally disconnected space is a singleton. -/
@[simp]
theorem Continuous.image_connectedComponent_eq_singleton {β : Type*} [TopologicalSpace β]
[TotallyDisconnectedSpace β] {f : α → β} (h : Continuous f) (a : α) :
f '' connectedComponent a = {f a} :=
(Set.subsingleton_iff_singleton <| mem_image_of_mem f mem_connectedComponent).mp
(isPreconnected_connectedComponent.image f h.continuousOn).subsingleton
theorem isTotallyDisconnected_of_totallyDisconnectedSpace [TotallyDisconnectedSpace α] (s : Set α) :
IsTotallyDisconnected s := fun t _ ht =>
TotallyDisconnectedSpace.isTotallyDisconnected_univ _ t.subset_univ ht
| Mathlib/Topology/Connected/TotallyDisconnected.lean | 108 | 119 |
/-
Copyright (c) 2020 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel, Sophie Morel, Yury Kudryashov
-/
import Mathlib.Analysis.NormedSpace.OperatorNorm.NormedSpace
import Mathlib.Logic.Embedding.Basic
import Mathlib.Data.Fintype.CardEmbedding
import Mathlib.Topology.Algebra.Module.Multilinear.Topology
/-!
# Operator norm on the space of continuous multilinear maps
When `f` is a continuous multilinear map in finitely many variables, we define its norm `‖f‖` as the
smallest number such that `‖f m‖ ≤ ‖f‖ * ∏ i, ‖m i‖` for all `m`.
We show that it is indeed a norm, and prove its basic properties.
## Main results
Let `f` be a multilinear map in finitely many variables.
* `exists_bound_of_continuous` asserts that, if `f` is continuous, then there exists `C > 0`
with `‖f m‖ ≤ C * ∏ i, ‖m i‖` for all `m`.
* `continuous_of_bound`, conversely, asserts that this bound implies continuity.
* `mkContinuous` constructs the associated continuous multilinear map.
Let `f` be a continuous multilinear map in finitely many variables.
* `‖f‖` is its norm, i.e., the smallest number such that `‖f m‖ ≤ ‖f‖ * ∏ i, ‖m i‖` for
all `m`.
* `le_opNorm f m` asserts the fundamental inequality `‖f m‖ ≤ ‖f‖ * ∏ i, ‖m i‖`.
* `norm_image_sub_le f m₁ m₂` gives a control of the difference `f m₁ - f m₂` in terms of
`‖f‖` and `‖m₁ - m₂‖`.
## Implementation notes
We mostly follow the API (and the proofs) of `OperatorNorm.lean`, with the additional complexity
that we should deal with multilinear maps in several variables.
From the mathematical point of view, all the results follow from the results on operator norm in
one variable, by applying them to one variable after the other through currying. However, this
is only well defined when there is an order on the variables (for instance on `Fin n`) although
the final result is independent of the order. While everything could be done following this
approach, it turns out that direct proofs are easier and more efficient.
-/
suppress_compilation
noncomputable section
open scoped NNReal Topology Uniformity
open Finset Metric Function Filter
/-!
### Type variables
We use the following type variables in this file:
* `𝕜` : a `NontriviallyNormedField`;
* `ι`, `ι'` : finite index types with decidable equality;
* `E`, `E₁` : families of normed vector spaces over `𝕜` indexed by `i : ι`;
* `E'` : a family of normed vector spaces over `𝕜` indexed by `i' : ι'`;
* `Ei` : a family of normed vector spaces over `𝕜` indexed by `i : Fin (Nat.succ n)`;
* `G`, `G'` : normed vector spaces over `𝕜`.
-/
universe u v v' wE wE₁ wE' wG wG'
section continuous_eval
variable {𝕜 ι : Type*} {E : ι → Type*} {F : Type*}
[NormedField 𝕜] [Finite ι] [∀ i, SeminormedAddCommGroup (E i)] [∀ i, NormedSpace 𝕜 (E i)]
[TopologicalSpace F] [AddCommGroup F] [IsTopologicalAddGroup F] [Module 𝕜 F]
instance ContinuousMultilinearMap.instContinuousEval :
ContinuousEval (ContinuousMultilinearMap 𝕜 E F) (Π i, E i) F where
continuous_eval := by
cases nonempty_fintype ι
let _ := IsTopologicalAddGroup.toUniformSpace F
have := isUniformAddGroup_of_addCommGroup (G := F)
refine (UniformOnFun.continuousOn_eval₂ fun m ↦ ?_).comp_continuous
(isEmbedding_toUniformOnFun.continuous.prodMap continuous_id) fun (f, x) ↦ f.cont.continuousAt
exact ⟨ball m 1, NormedSpace.isVonNBounded_of_isBounded _ isBounded_ball,
ball_mem_nhds _ one_pos⟩
namespace ContinuousLinearMap
variable {G : Type*} [AddCommGroup G] [TopologicalSpace G] [Module 𝕜 G] [ContinuousConstSMul 𝕜 F]
lemma continuous_uncurry_of_multilinear (f : G →L[𝕜] ContinuousMultilinearMap 𝕜 E F) :
Continuous (fun (p : G × (Π i, E i)) ↦ f p.1 p.2) := by
fun_prop
lemma continuousOn_uncurry_of_multilinear (f : G →L[𝕜] ContinuousMultilinearMap 𝕜 E F) {s} :
ContinuousOn (fun (p : G × (Π i, E i)) ↦ f p.1 p.2) s :=
f.continuous_uncurry_of_multilinear.continuousOn
lemma continuousAt_uncurry_of_multilinear (f : G →L[𝕜] ContinuousMultilinearMap 𝕜 E F) {x} :
ContinuousAt (fun (p : G × (Π i, E i)) ↦ f p.1 p.2) x :=
f.continuous_uncurry_of_multilinear.continuousAt
lemma continuousWithinAt_uncurry_of_multilinear (f : G →L[𝕜] ContinuousMultilinearMap 𝕜 E F) {s x} :
ContinuousWithinAt (fun (p : G × (Π i, E i)) ↦ f p.1 p.2) s x :=
f.continuous_uncurry_of_multilinear.continuousWithinAt
end ContinuousLinearMap
end continuous_eval
section Seminorm
variable {𝕜 : Type u} {ι : Type v} {ι' : Type v'} {E : ι → Type wE} {E₁ : ι → Type wE₁}
{E' : ι' → Type wE'} {G : Type wG} {G' : Type wG'}
[Fintype ι'] [NontriviallyNormedField 𝕜] [∀ i, SeminormedAddCommGroup (E i)]
[∀ i, NormedSpace 𝕜 (E i)] [∀ i, SeminormedAddCommGroup (E₁ i)] [∀ i, NormedSpace 𝕜 (E₁ i)]
[SeminormedAddCommGroup G] [NormedSpace 𝕜 G] [SeminormedAddCommGroup G'] [NormedSpace 𝕜 G']
/-!
### Continuity properties of multilinear maps
We relate continuity of multilinear maps to the inequality `‖f m‖ ≤ C * ∏ i, ‖m i‖`, in
both directions. Along the way, we prove useful bounds on the difference `‖f m₁ - f m₂‖`.
-/
namespace MultilinearMap
/-- If `f` is a continuous multilinear map on `E`
and `m` is an element of `∀ i, E i` such that one of the `m i` has norm `0`,
then `f m` has norm `0`.
Note that we cannot drop the continuity assumption because `f (m : Unit → E) = f (m ())`,
where the domain has zero norm and the codomain has a nonzero norm
does not satisfy this condition. -/
lemma norm_map_coord_zero (f : MultilinearMap 𝕜 E G) (hf : Continuous f)
{m : ∀ i, E i} {i : ι} (hi : ‖m i‖ = 0) : ‖f m‖ = 0 := by
classical
rw [← inseparable_zero_iff_norm] at hi ⊢
have : Inseparable (update m i 0) m := inseparable_pi.2 <|
(forall_update_iff m fun i a ↦ Inseparable a (m i)).2 ⟨hi.symm, fun _ _ ↦ rfl⟩
simpa only [map_update_zero] using this.symm.map hf
variable [Fintype ι]
/-- If a multilinear map in finitely many variables on seminormed spaces
sends vectors with a component of norm zero to vectors of norm zero
and satisfies the inequality `‖f m‖ ≤ C * ∏ i, ‖m i‖` on a shell `ε i / ‖c i‖ < ‖m i‖ < ε i`
for some positive numbers `ε i` and elements `c i : 𝕜`, `1 < ‖c i‖`,
then it satisfies this inequality for all `m`.
The first assumption is automatically satisfied on normed spaces, see `bound_of_shell` below.
For seminormed spaces, it follows from continuity of `f`, see next lemma,
see `bound_of_shell_of_continuous` below. -/
theorem bound_of_shell_of_norm_map_coord_zero (f : MultilinearMap 𝕜 E G)
(hf₀ : ∀ {m i}, ‖m i‖ = 0 → ‖f m‖ = 0)
{ε : ι → ℝ} {C : ℝ} (hε : ∀ i, 0 < ε i) {c : ι → 𝕜} (hc : ∀ i, 1 < ‖c i‖)
(hf : ∀ m : ∀ i, E i, (∀ i, ε i / ‖c i‖ ≤ ‖m i‖) → (∀ i, ‖m i‖ < ε i) → ‖f m‖ ≤ C * ∏ i, ‖m i‖)
(m : ∀ i, E i) : ‖f m‖ ≤ C * ∏ i, ‖m i‖ := by
rcases em (∃ i, ‖m i‖ = 0) with (⟨i, hi⟩ | hm)
· rw [hf₀ hi, prod_eq_zero (mem_univ i) hi, mul_zero]
push_neg at hm
choose δ hδ0 hδm_lt hle_δm _ using fun i => rescale_to_shell_semi_normed (hc i) (hε i) (hm i)
have hδ0 : 0 < ∏ i, ‖δ i‖ := prod_pos fun i _ => norm_pos_iff.2 (hδ0 i)
simpa [map_smul_univ, norm_smul, prod_mul_distrib, mul_left_comm C, mul_le_mul_left hδ0] using
hf (fun i => δ i • m i) hle_δm hδm_lt
/-- If a continuous multilinear map in finitely many variables on normed spaces satisfies
the inequality `‖f m‖ ≤ C * ∏ i, ‖m i‖` on a shell `ε i / ‖c i‖ < ‖m i‖ < ε i` for some positive
numbers `ε i` and elements `c i : 𝕜`, `1 < ‖c i‖`, then it satisfies this inequality for all `m`. -/
theorem bound_of_shell_of_continuous (f : MultilinearMap 𝕜 E G) (hfc : Continuous f)
{ε : ι → ℝ} {C : ℝ} (hε : ∀ i, 0 < ε i) {c : ι → 𝕜} (hc : ∀ i, 1 < ‖c i‖)
(hf : ∀ m : ∀ i, E i, (∀ i, ε i / ‖c i‖ ≤ ‖m i‖) → (∀ i, ‖m i‖ < ε i) → ‖f m‖ ≤ C * ∏ i, ‖m i‖)
(m : ∀ i, E i) : ‖f m‖ ≤ C * ∏ i, ‖m i‖ :=
bound_of_shell_of_norm_map_coord_zero f (norm_map_coord_zero f hfc) hε hc hf m
/-- If a multilinear map in finitely many variables on normed spaces is continuous, then it
satisfies the inequality `‖f m‖ ≤ C * ∏ i, ‖m i‖`, for some `C` which can be chosen to be
positive. -/
theorem exists_bound_of_continuous (f : MultilinearMap 𝕜 E G) (hf : Continuous f) :
∃ C : ℝ, 0 < C ∧ ∀ m, ‖f m‖ ≤ C * ∏ i, ‖m i‖ := by
cases isEmpty_or_nonempty ι
· refine ⟨‖f 0‖ + 1, add_pos_of_nonneg_of_pos (norm_nonneg _) zero_lt_one, fun m => ?_⟩
obtain rfl : m = 0 := funext (IsEmpty.elim ‹_›)
simp [univ_eq_empty, zero_le_one]
obtain ⟨ε : ℝ, ε0 : 0 < ε, hε : ∀ m : ∀ i, E i, ‖m - 0‖ < ε → ‖f m - f 0‖ < 1⟩ :=
NormedAddCommGroup.tendsto_nhds_nhds.1 (hf.tendsto 0) 1 zero_lt_one
simp only [sub_zero, f.map_zero] at hε
rcases NormedField.exists_one_lt_norm 𝕜 with ⟨c, hc⟩
have : 0 < (‖c‖ / ε) ^ Fintype.card ι := pow_pos (div_pos (zero_lt_one.trans hc) ε0) _
refine ⟨_, this, ?_⟩
refine f.bound_of_shell_of_continuous hf (fun _ => ε0) (fun _ => hc) fun m hcm hm => ?_
refine (hε m ((pi_norm_lt_iff ε0).2 hm)).le.trans ?_
rw [← div_le_iff₀' this, one_div, ← inv_pow, inv_div, Fintype.card, ← prod_const]
exact prod_le_prod (fun _ _ => div_nonneg ε0.le (norm_nonneg _)) fun i _ => hcm i
/-- If a multilinear map `f` satisfies a boundedness property around `0`,
one can deduce a bound on `f m₁ - f m₂` using the multilinearity.
Here, we give a precise but hard to use version.
See `norm_image_sub_le_of_bound` for a less precise but more usable version.
The bound reads
`‖f m - f m'‖ ≤
C * ‖m 1 - m' 1‖ * max ‖m 2‖ ‖m' 2‖ * max ‖m 3‖ ‖m' 3‖ * ... * max ‖m n‖ ‖m' n‖ + ...`,
where the other terms in the sum are the same products where `1` is replaced by any `i`. -/
theorem norm_image_sub_le_of_bound' [DecidableEq ι] (f : MultilinearMap 𝕜 E G) {C : ℝ} (hC : 0 ≤ C)
(H : ∀ m, ‖f m‖ ≤ C * ∏ i, ‖m i‖) (m₁ m₂ : ∀ i, E i) :
‖f m₁ - f m₂‖ ≤ C * ∑ i, ∏ j, if j = i then ‖m₁ i - m₂ i‖ else max ‖m₁ j‖ ‖m₂ j‖ := by
have A :
∀ s : Finset ι,
‖f m₁ - f (s.piecewise m₂ m₁)‖ ≤
C * ∑ i ∈ s, ∏ j, if j = i then ‖m₁ i - m₂ i‖ else max ‖m₁ j‖ ‖m₂ j‖ := by
intro s
induction' s using Finset.induction with i s his Hrec
· simp
have I :
‖f (s.piecewise m₂ m₁) - f ((insert i s).piecewise m₂ m₁)‖ ≤
C * ∏ j, if j = i then ‖m₁ i - m₂ i‖ else max ‖m₁ j‖ ‖m₂ j‖ := by
have A : (insert i s).piecewise m₂ m₁ = Function.update (s.piecewise m₂ m₁) i (m₂ i) :=
s.piecewise_insert _ _ _
have B : s.piecewise m₂ m₁ = Function.update (s.piecewise m₂ m₁) i (m₁ i) := by
simp [eq_update_iff, his]
rw [B, A, ← f.map_update_sub]
apply le_trans (H _)
gcongr with j
by_cases h : j = i
· rw [h]
simp
· by_cases h' : j ∈ s <;> simp [h', h, le_refl]
calc
‖f m₁ - f ((insert i s).piecewise m₂ m₁)‖ ≤
‖f m₁ - f (s.piecewise m₂ m₁)‖ +
‖f (s.piecewise m₂ m₁) - f ((insert i s).piecewise m₂ m₁)‖ := by
rw [← dist_eq_norm, ← dist_eq_norm, ← dist_eq_norm]
exact dist_triangle _ _ _
_ ≤ (C * ∑ i ∈ s, ∏ j, if j = i then ‖m₁ i - m₂ i‖ else max ‖m₁ j‖ ‖m₂ j‖) +
C * ∏ j, if j = i then ‖m₁ i - m₂ i‖ else max ‖m₁ j‖ ‖m₂ j‖ :=
(add_le_add Hrec I)
_ = C * ∑ i ∈ insert i s, ∏ j, if j = i then ‖m₁ i - m₂ i‖ else max ‖m₁ j‖ ‖m₂ j‖ := by
simp [his, add_comm, left_distrib]
convert A univ
simp
/-- If `f` satisfies a boundedness property around `0`, one can deduce a bound on `f m₁ - f m₂`
using the multilinearity. Here, we give a usable but not very precise version. See
`norm_image_sub_le_of_bound'` for a more precise but less usable version. The bound is
`‖f m - f m'‖ ≤ C * card ι * ‖m - m'‖ * (max ‖m‖ ‖m'‖) ^ (card ι - 1)`. -/
theorem norm_image_sub_le_of_bound (f : MultilinearMap 𝕜 E G)
{C : ℝ} (hC : 0 ≤ C) (H : ∀ m, ‖f m‖ ≤ C * ∏ i, ‖m i‖) (m₁ m₂ : ∀ i, E i) :
‖f m₁ - f m₂‖ ≤ C * Fintype.card ι * max ‖m₁‖ ‖m₂‖ ^ (Fintype.card ι - 1) * ‖m₁ - m₂‖ := by
classical
have A :
∀ i : ι,
∏ j, (if j = i then ‖m₁ i - m₂ i‖ else max ‖m₁ j‖ ‖m₂ j‖) ≤
‖m₁ - m₂‖ * max ‖m₁‖ ‖m₂‖ ^ (Fintype.card ι - 1) := by
intro i
calc
∏ j, (if j = i then ‖m₁ i - m₂ i‖ else max ‖m₁ j‖ ‖m₂ j‖) ≤
∏ j : ι, Function.update (fun _ => max ‖m₁‖ ‖m₂‖) i ‖m₁ - m₂‖ j := by
apply Finset.prod_le_prod
· intro j _
by_cases h : j = i <;> simp [h, norm_nonneg]
· intro j _
by_cases h : j = i
· rw [h]
simp only [ite_true, Function.update_self]
exact norm_le_pi_norm (m₁ - m₂) i
· simp [h, - le_sup_iff, - sup_le_iff, sup_le_sup, norm_le_pi_norm]
_ = ‖m₁ - m₂‖ * max ‖m₁‖ ‖m₂‖ ^ (Fintype.card ι - 1) := by
rw [prod_update_of_mem (Finset.mem_univ _)]
simp [card_univ_diff]
calc
‖f m₁ - f m₂‖ ≤ C * ∑ i, ∏ j, if j = i then ‖m₁ i - m₂ i‖ else max ‖m₁ j‖ ‖m₂ j‖ :=
f.norm_image_sub_le_of_bound' hC H m₁ m₂
_ ≤ C * ∑ _i, ‖m₁ - m₂‖ * max ‖m₁‖ ‖m₂‖ ^ (Fintype.card ι - 1) := by gcongr; apply A
_ = C * Fintype.card ι * max ‖m₁‖ ‖m₂‖ ^ (Fintype.card ι - 1) * ‖m₁ - m₂‖ := by
rw [sum_const, card_univ, nsmul_eq_mul]
ring
/-- If a multilinear map satisfies an inequality `‖f m‖ ≤ C * ∏ i, ‖m i‖`, then it is
continuous. -/
theorem continuous_of_bound (f : MultilinearMap 𝕜 E G) (C : ℝ) (H : ∀ m, ‖f m‖ ≤ C * ∏ i, ‖m i‖) :
Continuous f := by
let D := max C 1
have D_pos : 0 ≤ D := le_trans zero_le_one (le_max_right _ _)
replace H (m) : ‖f m‖ ≤ D * ∏ i, ‖m i‖ :=
(H m).trans (mul_le_mul_of_nonneg_right (le_max_left _ _) <| by positivity)
refine continuous_iff_continuousAt.2 fun m => ?_
refine
continuousAt_of_locally_lipschitz zero_lt_one
(D * Fintype.card ι * (‖m‖ + 1) ^ (Fintype.card ι - 1)) fun m' h' => ?_
rw [dist_eq_norm, dist_eq_norm]
have : max ‖m'‖ ‖m‖ ≤ ‖m‖ + 1 := by
simp [zero_le_one, norm_le_of_mem_closedBall (le_of_lt h')]
calc
‖f m' - f m‖ ≤ D * Fintype.card ι * max ‖m'‖ ‖m‖ ^ (Fintype.card ι - 1) * ‖m' - m‖ :=
f.norm_image_sub_le_of_bound D_pos H m' m
_ ≤ D * Fintype.card ι * (‖m‖ + 1) ^ (Fintype.card ι - 1) * ‖m' - m‖ := by gcongr
/-- Constructing a continuous multilinear map from a multilinear map satisfying a boundedness
condition. -/
def mkContinuous (f : MultilinearMap 𝕜 E G) (C : ℝ) (H : ∀ m, ‖f m‖ ≤ C * ∏ i, ‖m i‖) :
ContinuousMultilinearMap 𝕜 E G :=
{ f with cont := f.continuous_of_bound C H }
@[simp]
theorem coe_mkContinuous (f : MultilinearMap 𝕜 E G) (C : ℝ) (H : ∀ m, ‖f m‖ ≤ C * ∏ i, ‖m i‖) :
⇑(f.mkContinuous C H) = f :=
rfl
/-- Given a multilinear map in `n` variables, if one restricts it to `k` variables putting `z` on
the other coordinates, then the resulting restricted function satisfies an inequality
`‖f.restr v‖ ≤ C * ‖z‖^(n-k) * Π ‖v i‖` if the original function satisfies `‖f v‖ ≤ C * Π ‖v i‖`. -/
theorem restr_norm_le {k n : ℕ} (f : MultilinearMap 𝕜 (fun _ : Fin n => G) G')
(s : Finset (Fin n)) (hk : #s = k) (z : G) {C : ℝ} (H : ∀ m, ‖f m‖ ≤ C * ∏ i, ‖m i‖)
(v : Fin k → G) : ‖f.restr s hk z v‖ ≤ C * ‖z‖ ^ (n - k) * ∏ i, ‖v i‖ := by
rw [mul_right_comm, mul_assoc]
convert H _ using 2
simp only [apply_dite norm, Fintype.prod_dite, prod_const ‖z‖, Finset.card_univ,
Fintype.card_of_subtype sᶜ fun _ => mem_compl, card_compl, Fintype.card_fin, hk, mk_coe, ←
(s.orderIsoOfFin hk).symm.bijective.prod_comp fun x => ‖v x‖]
convert rfl
end MultilinearMap
/-!
### Continuous multilinear maps
We define the norm `‖f‖` of a continuous multilinear map `f` in finitely many variables as the
smallest number such that `‖f m‖ ≤ ‖f‖ * ∏ i, ‖m i‖` for all `m`. We show that this
defines a normed space structure on `ContinuousMultilinearMap 𝕜 E G`.
-/
namespace ContinuousMultilinearMap
variable [Fintype ι]
theorem bound (f : ContinuousMultilinearMap 𝕜 E G) :
∃ C : ℝ, 0 < C ∧ ∀ m, ‖f m‖ ≤ C * ∏ i, ‖m i‖ :=
f.toMultilinearMap.exists_bound_of_continuous f.2
open Real
/-- The operator norm of a continuous multilinear map is the inf of all its bounds. -/
def opNorm (f : ContinuousMultilinearMap 𝕜 E G) : ℝ :=
sInf { c | 0 ≤ (c : ℝ) ∧ ∀ m, ‖f m‖ ≤ c * ∏ i, ‖m i‖ }
instance hasOpNorm : Norm (ContinuousMultilinearMap 𝕜 E G) :=
⟨opNorm⟩
/-- An alias of `ContinuousMultilinearMap.hasOpNorm` with non-dependent types to help typeclass
search. -/
instance hasOpNorm' : Norm (ContinuousMultilinearMap 𝕜 (fun _ : ι => G) G') :=
ContinuousMultilinearMap.hasOpNorm
theorem norm_def (f : ContinuousMultilinearMap 𝕜 E G) :
‖f‖ = sInf { c | 0 ≤ (c : ℝ) ∧ ∀ m, ‖f m‖ ≤ c * ∏ i, ‖m i‖ } :=
rfl
-- So that invocations of `le_csInf` make sense: we show that the set of
-- bounds is nonempty and bounded below.
theorem bounds_nonempty {f : ContinuousMultilinearMap 𝕜 E G} :
∃ c, c ∈ { c | 0 ≤ c ∧ ∀ m, ‖f m‖ ≤ c * ∏ i, ‖m i‖ } :=
let ⟨M, hMp, hMb⟩ := f.bound
⟨M, le_of_lt hMp, hMb⟩
theorem bounds_bddBelow {f : ContinuousMultilinearMap 𝕜 E G} :
BddBelow { c | 0 ≤ c ∧ ∀ m, ‖f m‖ ≤ c * ∏ i, ‖m i‖ } :=
⟨0, fun _ ⟨hn, _⟩ => hn⟩
theorem isLeast_opNorm (f : ContinuousMultilinearMap 𝕜 E G) :
IsLeast {c : ℝ | 0 ≤ c ∧ ∀ m, ‖f m‖ ≤ c * ∏ i, ‖m i‖} ‖f‖ := by
refine IsClosed.isLeast_csInf ?_ bounds_nonempty bounds_bddBelow
simp only [Set.setOf_and, Set.setOf_forall]
exact isClosed_Ici.inter (isClosed_iInter fun m ↦
isClosed_le continuous_const (continuous_id.mul continuous_const))
theorem opNorm_nonneg (f : ContinuousMultilinearMap 𝕜 E G) : 0 ≤ ‖f‖ :=
Real.sInf_nonneg fun _ ⟨hx, _⟩ => hx
/-- The fundamental property of the operator norm of a continuous multilinear map:
`‖f m‖` is bounded by `‖f‖` times the product of the `‖m i‖`. -/
theorem le_opNorm (f : ContinuousMultilinearMap 𝕜 E G) (m : ∀ i, E i) :
‖f m‖ ≤ ‖f‖ * ∏ i, ‖m i‖ :=
f.isLeast_opNorm.1.2 m
theorem le_mul_prod_of_opNorm_le_of_le {f : ContinuousMultilinearMap 𝕜 E G}
{m : ∀ i, E i} {C : ℝ} {b : ι → ℝ} (hC : ‖f‖ ≤ C) (hm : ∀ i, ‖m i‖ ≤ b i) :
‖f m‖ ≤ C * ∏ i, b i :=
(f.le_opNorm m).trans <| by gcongr; exacts [f.opNorm_nonneg.trans hC, hm _]
@[deprecated (since := "2024-11-27")]
alias le_mul_prod_of_le_opNorm_of_le := le_mul_prod_of_opNorm_le_of_le
theorem le_opNorm_mul_prod_of_le (f : ContinuousMultilinearMap 𝕜 E G)
{m : ∀ i, E i} {b : ι → ℝ} (hm : ∀ i, ‖m i‖ ≤ b i) : ‖f m‖ ≤ ‖f‖ * ∏ i, b i :=
le_mul_prod_of_opNorm_le_of_le le_rfl hm
theorem le_opNorm_mul_pow_card_of_le (f : ContinuousMultilinearMap 𝕜 E G) {m b} (hm : ‖m‖ ≤ b) :
‖f m‖ ≤ ‖f‖ * b ^ Fintype.card ι := by
simpa only [prod_const] using f.le_opNorm_mul_prod_of_le fun i => (norm_le_pi_norm m i).trans hm
theorem le_opNorm_mul_pow_of_le {n : ℕ} {Ei : Fin n → Type*} [∀ i, SeminormedAddCommGroup (Ei i)]
[∀ i, NormedSpace 𝕜 (Ei i)] (f : ContinuousMultilinearMap 𝕜 Ei G) {m : ∀ i, Ei i} {b : ℝ}
(hm : ‖m‖ ≤ b) : ‖f m‖ ≤ ‖f‖ * b ^ n := by
simpa only [Fintype.card_fin] using f.le_opNorm_mul_pow_card_of_le hm
theorem le_of_opNorm_le {f : ContinuousMultilinearMap 𝕜 E G} {C : ℝ} (h : ‖f‖ ≤ C) (m : ∀ i, E i) :
‖f m‖ ≤ C * ∏ i, ‖m i‖ :=
le_mul_prod_of_opNorm_le_of_le h fun _ ↦ le_rfl
theorem ratio_le_opNorm (f : ContinuousMultilinearMap 𝕜 E G) (m : ∀ i, E i) :
(‖f m‖ / ∏ i, ‖m i‖) ≤ ‖f‖ :=
div_le_of_le_mul₀ (by positivity) (opNorm_nonneg _) (f.le_opNorm m)
/-- The image of the unit ball under a continuous multilinear map is bounded. -/
theorem unit_le_opNorm (f : ContinuousMultilinearMap 𝕜 E G) {m : ∀ i, E i} (h : ‖m‖ ≤ 1) :
‖f m‖ ≤ ‖f‖ :=
(le_opNorm_mul_pow_card_of_le f h).trans <| by simp
/-- If one controls the norm of every `f x`, then one controls the norm of `f`. -/
theorem opNorm_le_bound {f : ContinuousMultilinearMap 𝕜 E G}
{M : ℝ} (hMp : 0 ≤ M) (hM : ∀ m, ‖f m‖ ≤ M * ∏ i, ‖m i‖) : ‖f‖ ≤ M :=
csInf_le bounds_bddBelow ⟨hMp, hM⟩
theorem opNorm_le_iff {f : ContinuousMultilinearMap 𝕜 E G} {C : ℝ} (hC : 0 ≤ C) :
‖f‖ ≤ C ↔ ∀ m, ‖f m‖ ≤ C * ∏ i, ‖m i‖ :=
⟨fun h _ ↦ le_of_opNorm_le h _, opNorm_le_bound hC⟩
/-- The operator norm satisfies the triangle inequality. -/
theorem opNorm_add_le (f g : ContinuousMultilinearMap 𝕜 E G) : ‖f + g‖ ≤ ‖f‖ + ‖g‖ :=
opNorm_le_bound (add_nonneg (opNorm_nonneg f) (opNorm_nonneg g)) fun x => by
rw [add_mul]
exact norm_add_le_of_le (le_opNorm _ _) (le_opNorm _ _)
theorem opNorm_zero : ‖(0 : ContinuousMultilinearMap 𝕜 E G)‖ = 0 :=
(opNorm_nonneg _).antisymm' <| opNorm_le_bound le_rfl fun m => by simp
section
variable {𝕜' : Type*} [NormedField 𝕜'] [NormedSpace 𝕜' G] [SMulCommClass 𝕜 𝕜' G]
theorem opNorm_smul_le (c : 𝕜') (f : ContinuousMultilinearMap 𝕜 E G) : ‖c • f‖ ≤ ‖c‖ * ‖f‖ :=
(c • f).opNorm_le_bound (mul_nonneg (norm_nonneg _) (opNorm_nonneg _)) fun m ↦ by
rw [smul_apply, norm_smul, mul_assoc]
exact mul_le_mul_of_nonneg_left (le_opNorm _ _) (norm_nonneg _)
variable (𝕜 E G) in
/-- Operator seminorm on the space of continuous multilinear maps, as `Seminorm`.
We use this seminorm
to define a `SeminormedAddCommGroup` structure on `ContinuousMultilinearMap 𝕜 E G`,
but we have to override the projection `UniformSpace`
so that it is definitionally equal to the one coming from the topologies on `E` and `G`. -/
protected def seminorm : Seminorm 𝕜 (ContinuousMultilinearMap 𝕜 E G) :=
.ofSMulLE norm opNorm_zero opNorm_add_le fun c f ↦ f.opNorm_smul_le c
private lemma uniformity_eq_seminorm :
𝓤 (ContinuousMultilinearMap 𝕜 E G) = ⨅ r > 0, 𝓟 {f | ‖f.1 - f.2‖ < r} := by
refine (ContinuousMultilinearMap.seminorm 𝕜 E G).uniformity_eq_of_hasBasis
(ContinuousMultilinearMap.hasBasis_nhds_zero_of_basis Metric.nhds_basis_closedBall)
?_ fun (s, r) ⟨hs, hr⟩ ↦ ?_
· rcases NormedField.exists_lt_norm 𝕜 1 with ⟨c, hc⟩
have hc₀ : 0 < ‖c‖ := one_pos.trans hc
simp only [hasBasis_nhds_zero.mem_iff, Prod.exists]
use 1, closedBall 0 ‖c‖, closedBall 0 1
suffices ∀ f : ContinuousMultilinearMap 𝕜 E G, (∀ x, ‖x‖ ≤ ‖c‖ → ‖f x‖ ≤ 1) → ‖f‖ ≤ 1 by
simpa [NormedSpace.isVonNBounded_closedBall, closedBall_mem_nhds, Set.subset_def, Set.MapsTo]
intro f hf
refine opNorm_le_bound (by positivity) <|
f.1.bound_of_shell_of_continuous f.2 (fun _ ↦ hc₀) (fun _ ↦ hc) fun x hcx hx ↦ ?_
calc
‖f x‖ ≤ 1 := hf _ <| (pi_norm_le_iff_of_nonneg (norm_nonneg c)).2 fun i ↦ (hx i).le
_ = ∏ i : ι, 1 := by simp
_ ≤ ∏ i, ‖x i‖ := Finset.prod_le_prod (fun _ _ ↦ zero_le_one) fun i _ ↦ by
simpa only [div_self hc₀.ne'] using hcx i
_ = 1 * ∏ i, ‖x i‖ := (one_mul _).symm
· rcases (NormedSpace.isVonNBounded_iff' _).1 hs with ⟨ε, hε⟩
rcases exists_pos_mul_lt hr (ε ^ Fintype.card ι) with ⟨δ, hδ₀, hδ⟩
refine ⟨δ, hδ₀, fun f hf x hx ↦ ?_⟩
simp only [Seminorm.mem_ball_zero, mem_closedBall_zero_iff] at hf ⊢
replace hf : ‖f‖ ≤ δ := hf.le
replace hx : ‖x‖ ≤ ε := hε x hx
calc
‖f x‖ ≤ ‖f‖ * ε ^ Fintype.card ι := le_opNorm_mul_pow_card_of_le f hx
_ ≤ δ * ε ^ Fintype.card ι := by have := (norm_nonneg x).trans hx; gcongr
_ ≤ r := (mul_comm _ _).trans_le hδ.le
instance instPseudoMetricSpace : PseudoMetricSpace (ContinuousMultilinearMap 𝕜 E G) :=
.replaceUniformity
(ContinuousMultilinearMap.seminorm 𝕜 E G).toSeminormedAddCommGroup.toPseudoMetricSpace
uniformity_eq_seminorm
/-- Continuous multilinear maps themselves form a seminormed space with respect to
the operator norm. -/
instance seminormedAddCommGroup :
SeminormedAddCommGroup (ContinuousMultilinearMap 𝕜 E G) := ⟨fun _ _ ↦ rfl⟩
/-- An alias of `ContinuousMultilinearMap.seminormedAddCommGroup` with non-dependent types to help
typeclass search. -/
instance seminormedAddCommGroup' :
SeminormedAddCommGroup (ContinuousMultilinearMap 𝕜 (fun _ : ι => G) G') :=
ContinuousMultilinearMap.seminormedAddCommGroup
instance normedSpace : NormedSpace 𝕜' (ContinuousMultilinearMap 𝕜 E G) :=
⟨fun c f => f.opNorm_smul_le c⟩
/-- An alias of `ContinuousMultilinearMap.normedSpace` with non-dependent types to help typeclass
search. -/
instance normedSpace' : NormedSpace 𝕜' (ContinuousMultilinearMap 𝕜 (fun _ : ι => G') G) :=
ContinuousMultilinearMap.normedSpace
@[deprecated norm_neg (since := "2024-11-24")]
theorem opNorm_neg (f : ContinuousMultilinearMap 𝕜 E G) : ‖-f‖ = ‖f‖ := norm_neg f
/-- The fundamental property of the operator norm of a continuous multilinear map:
`‖f m‖` is bounded by `‖f‖` times the product of the `‖m i‖`, `nnnorm` version. -/
theorem le_opNNNorm (f : ContinuousMultilinearMap 𝕜 E G) (m : ∀ i, E i) :
‖f m‖₊ ≤ ‖f‖₊ * ∏ i, ‖m i‖₊ :=
NNReal.coe_le_coe.1 <| by
push_cast
exact f.le_opNorm m
theorem le_of_opNNNorm_le (f : ContinuousMultilinearMap 𝕜 E G)
{C : ℝ≥0} (h : ‖f‖₊ ≤ C) (m : ∀ i, E i) : ‖f m‖₊ ≤ C * ∏ i, ‖m i‖₊ :=
(f.le_opNNNorm m).trans <| mul_le_mul' h le_rfl
theorem opNNNorm_le_iff {f : ContinuousMultilinearMap 𝕜 E G} {C : ℝ≥0} :
‖f‖₊ ≤ C ↔ ∀ m, ‖f m‖₊ ≤ C * ∏ i, ‖m i‖₊ := by
simp only [← NNReal.coe_le_coe]; simp [opNorm_le_iff C.coe_nonneg, NNReal.coe_prod]
theorem isLeast_opNNNorm (f : ContinuousMultilinearMap 𝕜 E G) :
IsLeast {C : ℝ≥0 | ∀ m, ‖f m‖₊ ≤ C * ∏ i, ‖m i‖₊} ‖f‖₊ := by
simpa only [← opNNNorm_le_iff] using isLeast_Ici
theorem opNNNorm_prod (f : ContinuousMultilinearMap 𝕜 E G) (g : ContinuousMultilinearMap 𝕜 E G') :
‖f.prod g‖₊ = max ‖f‖₊ ‖g‖₊ :=
eq_of_forall_ge_iff fun _ ↦ by
simp only [opNNNorm_le_iff, prod_apply, Prod.nnnorm_def, max_le_iff, forall_and]
theorem opNorm_prod (f : ContinuousMultilinearMap 𝕜 E G) (g : ContinuousMultilinearMap 𝕜 E G') :
‖f.prod g‖ = max ‖f‖ ‖g‖ :=
congr_arg NNReal.toReal (opNNNorm_prod f g)
theorem opNNNorm_pi
[∀ i', SeminormedAddCommGroup (E' i')] [∀ i', NormedSpace 𝕜 (E' i')]
(f : ∀ i', ContinuousMultilinearMap 𝕜 E (E' i')) : ‖pi f‖₊ = ‖f‖₊ :=
eq_of_forall_ge_iff fun _ ↦ by simpa [opNNNorm_le_iff, pi_nnnorm_le_iff] using forall_swap
theorem opNorm_pi {ι' : Type v'} [Fintype ι'] {E' : ι' → Type wE'}
[∀ i', SeminormedAddCommGroup (E' i')] [∀ i', NormedSpace 𝕜 (E' i')]
(f : ∀ i', ContinuousMultilinearMap 𝕜 E (E' i')) :
‖pi f‖ = ‖f‖ :=
congr_arg NNReal.toReal (opNNNorm_pi f)
section
@[simp]
| theorem norm_ofSubsingleton [Subsingleton ι] (i : ι) (f : G →L[𝕜] G') :
‖ofSubsingleton 𝕜 G G' i f‖ = ‖f‖ := by
letI : Unique ι := uniqueOfSubsingleton i
simp [norm_def, ContinuousLinearMap.norm_def, (Equiv.funUnique _ _).symm.surjective.forall]
| Mathlib/Analysis/NormedSpace/Multilinear/Basic.lean | 555 | 558 |
/-
Copyright (c) 2019 Reid Barton. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel
-/
import Mathlib.Topology.Constructions
/-!
# Neighborhoods and continuity relative to a subset
This file develops API on the relative versions
* `nhdsWithin` of `nhds`
* `ContinuousOn` of `Continuous`
* `ContinuousWithinAt` of `ContinuousAt`
related to continuity, which are defined in previous definition files.
Their basic properties studied in this file include the relationships between
these restricted notions and the corresponding notions for the subtype
equipped with the subspace topology.
## Notation
* `𝓝 x`: the filter of neighborhoods of a point `x`;
* `𝓟 s`: the principal filter of a set `s`;
* `𝓝[s] x`: the filter `nhdsWithin x s` of neighborhoods of a point `x` within a set `s`.
-/
open Set Filter Function Topology Filter
variable {α β γ δ : Type*}
variable [TopologicalSpace α]
/-!
## Properties of the neighborhood-within filter
-/
@[simp]
theorem nhds_bind_nhdsWithin {a : α} {s : Set α} : ((𝓝 a).bind fun x => 𝓝[s] x) = 𝓝[s] a :=
bind_inf_principal.trans <| congr_arg₂ _ nhds_bind_nhds rfl
@[simp]
theorem eventually_nhds_nhdsWithin {a : α} {s : Set α} {p : α → Prop} :
(∀ᶠ y in 𝓝 a, ∀ᶠ x in 𝓝[s] y, p x) ↔ ∀ᶠ x in 𝓝[s] a, p x :=
Filter.ext_iff.1 nhds_bind_nhdsWithin { x | p x }
theorem eventually_nhdsWithin_iff {a : α} {s : Set α} {p : α → Prop} :
(∀ᶠ x in 𝓝[s] a, p x) ↔ ∀ᶠ x in 𝓝 a, x ∈ s → p x :=
eventually_inf_principal
theorem frequently_nhdsWithin_iff {z : α} {s : Set α} {p : α → Prop} :
(∃ᶠ x in 𝓝[s] z, p x) ↔ ∃ᶠ x in 𝓝 z, p x ∧ x ∈ s :=
frequently_inf_principal.trans <| by simp only [and_comm]
theorem mem_closure_ne_iff_frequently_within {z : α} {s : Set α} :
z ∈ closure (s \ {z}) ↔ ∃ᶠ x in 𝓝[≠] z, x ∈ s := by
simp [mem_closure_iff_frequently, frequently_nhdsWithin_iff]
@[simp]
theorem eventually_eventually_nhdsWithin {a : α} {s : Set α} {p : α → Prop} :
(∀ᶠ y in 𝓝[s] a, ∀ᶠ x in 𝓝[s] y, p x) ↔ ∀ᶠ x in 𝓝[s] a, p x := by
refine ⟨fun h => ?_, fun h => (eventually_nhds_nhdsWithin.2 h).filter_mono inf_le_left⟩
simp only [eventually_nhdsWithin_iff] at h ⊢
exact h.mono fun x hx hxs => (hx hxs).self_of_nhds hxs
@[simp]
theorem eventually_mem_nhdsWithin_iff {x : α} {s t : Set α} :
(∀ᶠ x' in 𝓝[s] x, t ∈ 𝓝[s] x') ↔ t ∈ 𝓝[s] x :=
eventually_eventually_nhdsWithin
theorem nhdsWithin_eq (a : α) (s : Set α) :
𝓝[s] a = ⨅ t ∈ { t : Set α | a ∈ t ∧ IsOpen t }, 𝓟 (t ∩ s) :=
((nhds_basis_opens a).inf_principal s).eq_biInf
@[simp] lemma nhdsWithin_univ (a : α) : 𝓝[Set.univ] a = 𝓝 a := by
rw [nhdsWithin, principal_univ, inf_top_eq]
theorem nhdsWithin_hasBasis {ι : Sort*} {p : ι → Prop} {s : ι → Set α} {a : α}
(h : (𝓝 a).HasBasis p s) (t : Set α) : (𝓝[t] a).HasBasis p fun i => s i ∩ t :=
h.inf_principal t
theorem nhdsWithin_basis_open (a : α) (t : Set α) :
(𝓝[t] a).HasBasis (fun u => a ∈ u ∧ IsOpen u) fun u => u ∩ t :=
nhdsWithin_hasBasis (nhds_basis_opens a) t
theorem mem_nhdsWithin {t : Set α} {a : α} {s : Set α} :
t ∈ 𝓝[s] a ↔ ∃ u, IsOpen u ∧ a ∈ u ∧ u ∩ s ⊆ t := by
simpa only [and_assoc, and_left_comm] using (nhdsWithin_basis_open a s).mem_iff
theorem mem_nhdsWithin_iff_exists_mem_nhds_inter {t : Set α} {a : α} {s : Set α} :
t ∈ 𝓝[s] a ↔ ∃ u ∈ 𝓝 a, u ∩ s ⊆ t :=
(nhdsWithin_hasBasis (𝓝 a).basis_sets s).mem_iff
theorem diff_mem_nhdsWithin_compl {x : α} {s : Set α} (hs : s ∈ 𝓝 x) (t : Set α) :
s \ t ∈ 𝓝[tᶜ] x :=
diff_mem_inf_principal_compl hs t
theorem diff_mem_nhdsWithin_diff {x : α} {s t : Set α} (hs : s ∈ 𝓝[t] x) (t' : Set α) :
s \ t' ∈ 𝓝[t \ t'] x := by
rw [nhdsWithin, diff_eq, diff_eq, ← inf_principal, ← inf_assoc]
exact inter_mem_inf hs (mem_principal_self _)
theorem nhds_of_nhdsWithin_of_nhds {s t : Set α} {a : α} (h1 : s ∈ 𝓝 a) (h2 : t ∈ 𝓝[s] a) :
t ∈ 𝓝 a := by
rcases mem_nhdsWithin_iff_exists_mem_nhds_inter.mp h2 with ⟨_, Hw, hw⟩
exact (𝓝 a).sets_of_superset ((𝓝 a).inter_sets Hw h1) hw
theorem mem_nhdsWithin_iff_eventually {s t : Set α} {x : α} :
t ∈ 𝓝[s] x ↔ ∀ᶠ y in 𝓝 x, y ∈ s → y ∈ t :=
eventually_inf_principal
theorem mem_nhdsWithin_iff_eventuallyEq {s t : Set α} {x : α} :
t ∈ 𝓝[s] x ↔ s =ᶠ[𝓝 x] (s ∩ t : Set α) := by
simp_rw [mem_nhdsWithin_iff_eventually, eventuallyEq_set, mem_inter_iff, iff_self_and]
theorem nhdsWithin_eq_iff_eventuallyEq {s t : Set α} {x : α} : 𝓝[s] x = 𝓝[t] x ↔ s =ᶠ[𝓝 x] t :=
set_eventuallyEq_iff_inf_principal.symm
theorem nhdsWithin_le_iff {s t : Set α} {x : α} : 𝓝[s] x ≤ 𝓝[t] x ↔ t ∈ 𝓝[s] x :=
set_eventuallyLE_iff_inf_principal_le.symm.trans set_eventuallyLE_iff_mem_inf_principal
theorem preimage_nhdsWithin_coinduced' {π : α → β} {s : Set β} {t : Set α} {a : α} (h : a ∈ t)
(hs : s ∈ @nhds β (.coinduced (fun x : t => π x) inferInstance) (π a)) :
π ⁻¹' s ∈ 𝓝[t] a := by
lift a to t using h
replace hs : (fun x : t => π x) ⁻¹' s ∈ 𝓝 a := preimage_nhds_coinduced hs
rwa [← map_nhds_subtype_val, mem_map]
theorem mem_nhdsWithin_of_mem_nhds {s t : Set α} {a : α} (h : s ∈ 𝓝 a) : s ∈ 𝓝[t] a :=
mem_inf_of_left h
theorem self_mem_nhdsWithin {a : α} {s : Set α} : s ∈ 𝓝[s] a :=
mem_inf_of_right (mem_principal_self s)
theorem eventually_mem_nhdsWithin {a : α} {s : Set α} : ∀ᶠ x in 𝓝[s] a, x ∈ s :=
self_mem_nhdsWithin
theorem inter_mem_nhdsWithin (s : Set α) {t : Set α} {a : α} (h : t ∈ 𝓝 a) : s ∩ t ∈ 𝓝[s] a :=
inter_mem self_mem_nhdsWithin (mem_inf_of_left h)
theorem pure_le_nhdsWithin {a : α} {s : Set α} (ha : a ∈ s) : pure a ≤ 𝓝[s] a :=
le_inf (pure_le_nhds a) (le_principal_iff.2 ha)
theorem mem_of_mem_nhdsWithin {a : α} {s t : Set α} (ha : a ∈ s) (ht : t ∈ 𝓝[s] a) : a ∈ t :=
pure_le_nhdsWithin ha ht
theorem Filter.Eventually.self_of_nhdsWithin {p : α → Prop} {s : Set α} {x : α}
(h : ∀ᶠ y in 𝓝[s] x, p y) (hx : x ∈ s) : p x :=
mem_of_mem_nhdsWithin hx h
theorem tendsto_const_nhdsWithin {l : Filter β} {s : Set α} {a : α} (ha : a ∈ s) :
Tendsto (fun _ : β => a) l (𝓝[s] a) :=
tendsto_const_pure.mono_right <| pure_le_nhdsWithin ha
theorem nhdsWithin_restrict'' {a : α} (s : Set α) {t : Set α} (h : t ∈ 𝓝[s] a) :
𝓝[s] a = 𝓝[s ∩ t] a :=
le_antisymm (le_inf inf_le_left (le_principal_iff.mpr (inter_mem self_mem_nhdsWithin h)))
(inf_le_inf_left _ (principal_mono.mpr Set.inter_subset_left))
theorem nhdsWithin_restrict' {a : α} (s : Set α) {t : Set α} (h : t ∈ 𝓝 a) : 𝓝[s] a = 𝓝[s ∩ t] a :=
nhdsWithin_restrict'' s <| mem_inf_of_left h
theorem nhdsWithin_restrict {a : α} (s : Set α) {t : Set α} (h₀ : a ∈ t) (h₁ : IsOpen t) :
𝓝[s] a = 𝓝[s ∩ t] a :=
nhdsWithin_restrict' s (IsOpen.mem_nhds h₁ h₀)
theorem nhdsWithin_le_of_mem {a : α} {s t : Set α} (h : s ∈ 𝓝[t] a) : 𝓝[t] a ≤ 𝓝[s] a :=
nhdsWithin_le_iff.mpr h
theorem nhdsWithin_le_nhds {a : α} {s : Set α} : 𝓝[s] a ≤ 𝓝 a := by
rw [← nhdsWithin_univ]
apply nhdsWithin_le_of_mem
exact univ_mem
theorem nhdsWithin_eq_nhdsWithin' {a : α} {s t u : Set α} (hs : s ∈ 𝓝 a) (h₂ : t ∩ s = u ∩ s) :
𝓝[t] a = 𝓝[u] a := by rw [nhdsWithin_restrict' t hs, nhdsWithin_restrict' u hs, h₂]
theorem nhdsWithin_eq_nhdsWithin {a : α} {s t u : Set α} (h₀ : a ∈ s) (h₁ : IsOpen s)
(h₂ : t ∩ s = u ∩ s) : 𝓝[t] a = 𝓝[u] a := by
rw [nhdsWithin_restrict t h₀ h₁, nhdsWithin_restrict u h₀ h₁, h₂]
@[simp] theorem nhdsWithin_eq_nhds {a : α} {s : Set α} : 𝓝[s] a = 𝓝 a ↔ s ∈ 𝓝 a :=
inf_eq_left.trans le_principal_iff
theorem IsOpen.nhdsWithin_eq {a : α} {s : Set α} (h : IsOpen s) (ha : a ∈ s) : 𝓝[s] a = 𝓝 a :=
nhdsWithin_eq_nhds.2 <| h.mem_nhds ha
theorem preimage_nhds_within_coinduced {π : α → β} {s : Set β} {t : Set α} {a : α} (h : a ∈ t)
(ht : IsOpen t)
(hs : s ∈ @nhds β (.coinduced (fun x : t => π x) inferInstance) (π a)) :
π ⁻¹' s ∈ 𝓝 a := by
rw [← ht.nhdsWithin_eq h]
exact preimage_nhdsWithin_coinduced' h hs
@[simp]
theorem nhdsWithin_empty (a : α) : 𝓝[∅] a = ⊥ := by rw [nhdsWithin, principal_empty, inf_bot_eq]
theorem nhdsWithin_union (a : α) (s t : Set α) : 𝓝[s ∪ t] a = 𝓝[s] a ⊔ 𝓝[t] a := by
delta nhdsWithin
rw [← inf_sup_left, sup_principal]
theorem nhds_eq_nhdsWithin_sup_nhdsWithin (b : α) {I₁ I₂ : Set α} (hI : Set.univ = I₁ ∪ I₂) :
nhds b = nhdsWithin b I₁ ⊔ nhdsWithin b I₂ := by
rw [← nhdsWithin_univ b, hI, nhdsWithin_union]
/-- If `L` and `R` are neighborhoods of `b` within sets whose union is `Set.univ`, then
`L ∪ R` is a neighborhood of `b`. -/
theorem union_mem_nhds_of_mem_nhdsWithin {b : α}
{I₁ I₂ : Set α} (h : Set.univ = I₁ ∪ I₂)
{L : Set α} (hL : L ∈ nhdsWithin b I₁)
{R : Set α} (hR : R ∈ nhdsWithin b I₂) : L ∪ R ∈ nhds b := by
rw [← nhdsWithin_univ b, h, nhdsWithin_union]
exact ⟨mem_of_superset hL (by simp), mem_of_superset hR (by simp)⟩
/-- Writing a punctured neighborhood filter as a sup of left and right filters. -/
lemma punctured_nhds_eq_nhdsWithin_sup_nhdsWithin [LinearOrder α] {x : α} :
𝓝[≠] x = 𝓝[<] x ⊔ 𝓝[>] x := by
rw [← Iio_union_Ioi, nhdsWithin_union]
/-- Obtain a "predictably-sided" neighborhood of `b` from two one-sided neighborhoods. -/
theorem nhds_of_Ici_Iic [LinearOrder α] {b : α}
{L : Set α} (hL : L ∈ 𝓝[≤] b)
{R : Set α} (hR : R ∈ 𝓝[≥] b) : L ∩ Iic b ∪ R ∩ Ici b ∈ 𝓝 b :=
union_mem_nhds_of_mem_nhdsWithin Iic_union_Ici.symm
(inter_mem hL self_mem_nhdsWithin) (inter_mem hR self_mem_nhdsWithin)
theorem nhdsWithin_biUnion {ι} {I : Set ι} (hI : I.Finite) (s : ι → Set α) (a : α) :
𝓝[⋃ i ∈ I, s i] a = ⨆ i ∈ I, 𝓝[s i] a := by
induction I, hI using Set.Finite.induction_on with
| empty => simp
| insert _ _ hT => simp only [hT, nhdsWithin_union, iSup_insert, biUnion_insert]
theorem nhdsWithin_sUnion {S : Set (Set α)} (hS : S.Finite) (a : α) :
𝓝[⋃₀ S] a = ⨆ s ∈ S, 𝓝[s] a := by
rw [sUnion_eq_biUnion, nhdsWithin_biUnion hS]
theorem nhdsWithin_iUnion {ι} [Finite ι] (s : ι → Set α) (a : α) :
𝓝[⋃ i, s i] a = ⨆ i, 𝓝[s i] a := by
rw [← sUnion_range, nhdsWithin_sUnion (finite_range s), iSup_range]
theorem nhdsWithin_inter (a : α) (s t : Set α) : 𝓝[s ∩ t] a = 𝓝[s] a ⊓ 𝓝[t] a := by
delta nhdsWithin
rw [inf_left_comm, inf_assoc, inf_principal, ← inf_assoc, inf_idem]
theorem nhdsWithin_inter' (a : α) (s t : Set α) : 𝓝[s ∩ t] a = 𝓝[s] a ⊓ 𝓟 t := by
delta nhdsWithin
rw [← inf_principal, inf_assoc]
theorem nhdsWithin_inter_of_mem {a : α} {s t : Set α} (h : s ∈ 𝓝[t] a) : 𝓝[s ∩ t] a = 𝓝[t] a := by
rw [nhdsWithin_inter, inf_eq_right]
exact nhdsWithin_le_of_mem h
theorem nhdsWithin_inter_of_mem' {a : α} {s t : Set α} (h : t ∈ 𝓝[s] a) : 𝓝[s ∩ t] a = 𝓝[s] a := by
rw [inter_comm, nhdsWithin_inter_of_mem h]
@[simp]
theorem nhdsWithin_singleton (a : α) : 𝓝[{a}] a = pure a := by
rw [nhdsWithin, principal_singleton, inf_eq_right.2 (pure_le_nhds a)]
@[simp]
theorem nhdsWithin_insert (a : α) (s : Set α) : 𝓝[insert a s] a = pure a ⊔ 𝓝[s] a := by
rw [← singleton_union, nhdsWithin_union, nhdsWithin_singleton]
theorem mem_nhdsWithin_insert {a : α} {s t : Set α} : t ∈ 𝓝[insert a s] a ↔ a ∈ t ∧ t ∈ 𝓝[s] a := by
simp
theorem insert_mem_nhdsWithin_insert {a : α} {s t : Set α} (h : t ∈ 𝓝[s] a) :
insert a t ∈ 𝓝[insert a s] a := by simp [mem_of_superset h]
theorem insert_mem_nhds_iff {a : α} {s : Set α} : insert a s ∈ 𝓝 a ↔ s ∈ 𝓝[≠] a := by
simp only [nhdsWithin, mem_inf_principal, mem_compl_iff, mem_singleton_iff, or_iff_not_imp_left,
insert_def]
@[simp]
theorem nhdsNE_sup_pure (a : α) : 𝓝[≠] a ⊔ pure a = 𝓝 a := by
rw [← nhdsWithin_singleton, ← nhdsWithin_union, compl_union_self, nhdsWithin_univ]
@[deprecated (since := "2025-03-02")]
alias nhdsWithin_compl_singleton_sup_pure := nhdsNE_sup_pure
@[simp]
theorem pure_sup_nhdsNE (a : α) : pure a ⊔ 𝓝[≠] a = 𝓝 a := by rw [← sup_comm, nhdsNE_sup_pure]
theorem nhdsWithin_prod [TopologicalSpace β]
{s u : Set α} {t v : Set β} {a : α} {b : β} (hu : u ∈ 𝓝[s] a) (hv : v ∈ 𝓝[t] b) :
u ×ˢ v ∈ 𝓝[s ×ˢ t] (a, b) := by
rw [nhdsWithin_prod_eq]
exact prod_mem_prod hu hv
lemma Filter.EventuallyEq.mem_interior {x : α} {s t : Set α} (hst : s =ᶠ[𝓝 x] t)
(h : x ∈ interior s) : x ∈ interior t := by
rw [← nhdsWithin_eq_iff_eventuallyEq] at hst
simpa [mem_interior_iff_mem_nhds, ← nhdsWithin_eq_nhds, hst] using h
lemma Filter.EventuallyEq.mem_interior_iff {x : α} {s t : Set α} (hst : s =ᶠ[𝓝 x] t) :
x ∈ interior s ↔ x ∈ interior t :=
⟨fun h ↦ hst.mem_interior h, fun h ↦ hst.symm.mem_interior h⟩
@[deprecated (since := "2024-11-11")]
alias EventuallyEq.mem_interior_iff := Filter.EventuallyEq.mem_interior_iff
section Pi
variable {ι : Type*} {π : ι → Type*} [∀ i, TopologicalSpace (π i)]
theorem nhdsWithin_pi_eq' {I : Set ι} (hI : I.Finite) (s : ∀ i, Set (π i)) (x : ∀ i, π i) :
𝓝[pi I s] x = ⨅ i, comap (fun x => x i) (𝓝 (x i) ⊓ ⨅ (_ : i ∈ I), 𝓟 (s i)) := by
simp only [nhdsWithin, nhds_pi, Filter.pi, comap_inf, comap_iInf, pi_def, comap_principal, ←
iInf_principal_finite hI, ← iInf_inf_eq]
theorem nhdsWithin_pi_eq {I : Set ι} (hI : I.Finite) (s : ∀ i, Set (π i)) (x : ∀ i, π i) :
𝓝[pi I s] x =
(⨅ i ∈ I, comap (fun x => x i) (𝓝[s i] x i)) ⊓
⨅ (i) (_ : i ∉ I), comap (fun x => x i) (𝓝 (x i)) := by
simp only [nhdsWithin, nhds_pi, Filter.pi, pi_def, ← iInf_principal_finite hI, comap_inf,
comap_principal, eval]
rw [iInf_split _ fun i => i ∈ I, inf_right_comm]
simp only [iInf_inf_eq]
theorem nhdsWithin_pi_univ_eq [Finite ι] (s : ∀ i, Set (π i)) (x : ∀ i, π i) :
𝓝[pi univ s] x = ⨅ i, comap (fun x => x i) (𝓝[s i] x i) := by
simpa [nhdsWithin] using nhdsWithin_pi_eq finite_univ s x
theorem nhdsWithin_pi_eq_bot {I : Set ι} {s : ∀ i, Set (π i)} {x : ∀ i, π i} :
𝓝[pi I s] x = ⊥ ↔ ∃ i ∈ I, 𝓝[s i] x i = ⊥ := by
simp only [nhdsWithin, nhds_pi, pi_inf_principal_pi_eq_bot]
theorem nhdsWithin_pi_neBot {I : Set ι} {s : ∀ i, Set (π i)} {x : ∀ i, π i} :
(𝓝[pi I s] x).NeBot ↔ ∀ i ∈ I, (𝓝[s i] x i).NeBot := by
simp [neBot_iff, nhdsWithin_pi_eq_bot]
instance instNeBotNhdsWithinUnivPi {s : ∀ i, Set (π i)} {x : ∀ i, π i}
[∀ i, (𝓝[s i] x i).NeBot] : (𝓝[pi univ s] x).NeBot := by
simpa [nhdsWithin_pi_neBot]
instance Pi.instNeBotNhdsWithinIio [Nonempty ι] [∀ i, Preorder (π i)] {x : ∀ i, π i}
[∀ i, (𝓝[<] x i).NeBot] : (𝓝[<] x).NeBot :=
have : (𝓝[pi univ fun i ↦ Iio (x i)] x).NeBot := inferInstance
this.mono <| nhdsWithin_mono _ fun _y hy ↦ lt_of_strongLT fun i ↦ hy i trivial
instance Pi.instNeBotNhdsWithinIoi [Nonempty ι] [∀ i, Preorder (π i)] {x : ∀ i, π i}
[∀ i, (𝓝[>] x i).NeBot] : (𝓝[>] x).NeBot :=
Pi.instNeBotNhdsWithinIio (π := fun i ↦ (π i)ᵒᵈ) (x := fun i ↦ OrderDual.toDual (x i))
end Pi
theorem Filter.Tendsto.piecewise_nhdsWithin {f g : α → β} {t : Set α} [∀ x, Decidable (x ∈ t)]
{a : α} {s : Set α} {l : Filter β} (h₀ : Tendsto f (𝓝[s ∩ t] a) l)
(h₁ : Tendsto g (𝓝[s ∩ tᶜ] a) l) : Tendsto (piecewise t f g) (𝓝[s] a) l := by
apply Tendsto.piecewise <;> rwa [← nhdsWithin_inter']
theorem Filter.Tendsto.if_nhdsWithin {f g : α → β} {p : α → Prop} [DecidablePred p] {a : α}
{s : Set α} {l : Filter β} (h₀ : Tendsto f (𝓝[s ∩ { x | p x }] a) l)
(h₁ : Tendsto g (𝓝[s ∩ { x | ¬p x }] a) l) :
Tendsto (fun x => if p x then f x else g x) (𝓝[s] a) l :=
h₀.piecewise_nhdsWithin h₁
theorem map_nhdsWithin (f : α → β) (a : α) (s : Set α) :
map f (𝓝[s] a) = ⨅ t ∈ { t : Set α | a ∈ t ∧ IsOpen t }, 𝓟 (f '' (t ∩ s)) :=
((nhdsWithin_basis_open a s).map f).eq_biInf
theorem tendsto_nhdsWithin_mono_left {f : α → β} {a : α} {s t : Set α} {l : Filter β} (hst : s ⊆ t)
(h : Tendsto f (𝓝[t] a) l) : Tendsto f (𝓝[s] a) l :=
h.mono_left <| nhdsWithin_mono a hst
theorem tendsto_nhdsWithin_mono_right {f : β → α} {l : Filter β} {a : α} {s t : Set α} (hst : s ⊆ t)
(h : Tendsto f l (𝓝[s] a)) : Tendsto f l (𝓝[t] a) :=
h.mono_right (nhdsWithin_mono a hst)
theorem tendsto_nhdsWithin_of_tendsto_nhds {f : α → β} {a : α} {s : Set α} {l : Filter β}
(h : Tendsto f (𝓝 a) l) : Tendsto f (𝓝[s] a) l :=
h.mono_left inf_le_left
theorem eventually_mem_of_tendsto_nhdsWithin {f : β → α} {a : α} {s : Set α} {l : Filter β}
(h : Tendsto f l (𝓝[s] a)) : ∀ᶠ i in l, f i ∈ s := by
simp_rw [nhdsWithin_eq, tendsto_iInf, mem_setOf_eq, tendsto_principal, mem_inter_iff,
eventually_and] at h
exact (h univ ⟨mem_univ a, isOpen_univ⟩).2
theorem tendsto_nhds_of_tendsto_nhdsWithin {f : β → α} {a : α} {s : Set α} {l : Filter β}
(h : Tendsto f l (𝓝[s] a)) : Tendsto f l (𝓝 a) :=
h.mono_right nhdsWithin_le_nhds
theorem nhdsWithin_neBot_of_mem {s : Set α} {x : α} (hx : x ∈ s) : NeBot (𝓝[s] x) :=
mem_closure_iff_nhdsWithin_neBot.1 <| subset_closure hx
theorem IsClosed.mem_of_nhdsWithin_neBot {s : Set α} (hs : IsClosed s) {x : α}
(hx : NeBot <| 𝓝[s] x) : x ∈ s :=
hs.closure_eq ▸ mem_closure_iff_nhdsWithin_neBot.2 hx
theorem DenseRange.nhdsWithin_neBot {ι : Type*} {f : ι → α} (h : DenseRange f) (x : α) :
NeBot (𝓝[range f] x) :=
mem_closure_iff_clusterPt.1 (h x)
theorem mem_closure_pi {ι : Type*} {α : ι → Type*} [∀ i, TopologicalSpace (α i)] {I : Set ι}
{s : ∀ i, Set (α i)} {x : ∀ i, α i} : x ∈ closure (pi I s) ↔ ∀ i ∈ I, x i ∈ closure (s i) := by
simp only [mem_closure_iff_nhdsWithin_neBot, nhdsWithin_pi_neBot]
theorem closure_pi_set {ι : Type*} {α : ι → Type*} [∀ i, TopologicalSpace (α i)] (I : Set ι)
(s : ∀ i, Set (α i)) : closure (pi I s) = pi I fun i => closure (s i) :=
Set.ext fun _ => mem_closure_pi
theorem dense_pi {ι : Type*} {α : ι → Type*} [∀ i, TopologicalSpace (α i)] {s : ∀ i, Set (α i)}
(I : Set ι) (hs : ∀ i ∈ I, Dense (s i)) : Dense (pi I s) := by
simp only [dense_iff_closure_eq, closure_pi_set, pi_congr rfl fun i hi => (hs i hi).closure_eq,
pi_univ]
theorem DenseRange.piMap {ι : Type*} {X Y : ι → Type*} [∀ i, TopologicalSpace (Y i)]
{f : (i : ι) → (X i) → (Y i)} (hf : ∀ i, DenseRange (f i)):
DenseRange (Pi.map f) := by
rw [DenseRange, Set.range_piMap]
exact dense_pi Set.univ (fun i _ => hf i)
theorem eventuallyEq_nhdsWithin_iff {f g : α → β} {s : Set α} {a : α} :
f =ᶠ[𝓝[s] a] g ↔ ∀ᶠ x in 𝓝 a, x ∈ s → f x = g x :=
mem_inf_principal
/-- Two functions agree on a neighborhood of `x` if they agree at `x` and in a punctured
neighborhood. -/
theorem eventuallyEq_nhds_of_eventuallyEq_nhdsNE {f g : α → β} {a : α} (h₁ : f =ᶠ[𝓝[≠] a] g)
(h₂ : f a = g a) :
f =ᶠ[𝓝 a] g := by
filter_upwards [eventually_nhdsWithin_iff.1 h₁]
intro x hx
by_cases h₂x : x = a
· simp [h₂x, h₂]
· tauto
theorem eventuallyEq_nhdsWithin_of_eqOn {f g : α → β} {s : Set α} {a : α} (h : EqOn f g s) :
f =ᶠ[𝓝[s] a] g :=
mem_inf_of_right h
theorem Set.EqOn.eventuallyEq_nhdsWithin {f g : α → β} {s : Set α} {a : α} (h : EqOn f g s) :
f =ᶠ[𝓝[s] a] g :=
eventuallyEq_nhdsWithin_of_eqOn h
theorem tendsto_nhdsWithin_congr {f g : α → β} {s : Set α} {a : α} {l : Filter β}
(hfg : ∀ x ∈ s, f x = g x) (hf : Tendsto f (𝓝[s] a) l) : Tendsto g (𝓝[s] a) l :=
(tendsto_congr' <| eventuallyEq_nhdsWithin_of_eqOn hfg).1 hf
theorem eventually_nhdsWithin_of_forall {s : Set α} {a : α} {p : α → Prop} (h : ∀ x ∈ s, p x) :
∀ᶠ x in 𝓝[s] a, p x :=
mem_inf_of_right h
theorem tendsto_nhdsWithin_of_tendsto_nhds_of_eventually_within {a : α} {l : Filter β} {s : Set α}
(f : β → α) (h1 : Tendsto f l (𝓝 a)) (h2 : ∀ᶠ x in l, f x ∈ s) : Tendsto f l (𝓝[s] a) :=
tendsto_inf.2 ⟨h1, tendsto_principal.2 h2⟩
theorem tendsto_nhdsWithin_iff {a : α} {l : Filter β} {s : Set α} {f : β → α} :
Tendsto f l (𝓝[s] a) ↔ Tendsto f l (𝓝 a) ∧ ∀ᶠ n in l, f n ∈ s :=
⟨fun h => ⟨tendsto_nhds_of_tendsto_nhdsWithin h, eventually_mem_of_tendsto_nhdsWithin h⟩, fun h =>
tendsto_nhdsWithin_of_tendsto_nhds_of_eventually_within _ h.1 h.2⟩
@[simp]
theorem tendsto_nhdsWithin_range {a : α} {l : Filter β} {f : β → α} :
Tendsto f l (𝓝[range f] a) ↔ Tendsto f l (𝓝 a) :=
⟨fun h => h.mono_right inf_le_left, fun h =>
tendsto_inf.2 ⟨h, tendsto_principal.2 <| Eventually.of_forall mem_range_self⟩⟩
theorem Filter.EventuallyEq.eq_of_nhdsWithin {s : Set α} {f g : α → β} {a : α} (h : f =ᶠ[𝓝[s] a] g)
(hmem : a ∈ s) : f a = g a :=
h.self_of_nhdsWithin hmem
theorem eventually_nhdsWithin_of_eventually_nhds {s : Set α}
{a : α} {p : α → Prop} (h : ∀ᶠ x in 𝓝 a, p x) : ∀ᶠ x in 𝓝[s] a, p x :=
mem_nhdsWithin_of_mem_nhds h
lemma Set.MapsTo.preimage_mem_nhdsWithin {f : α → β} {s : Set α} {t : Set β} {x : α}
(hst : MapsTo f s t) : f ⁻¹' t ∈ 𝓝[s] x :=
Filter.mem_of_superset self_mem_nhdsWithin hst
/-!
### `nhdsWithin` and subtypes
-/
theorem mem_nhdsWithin_subtype {s : Set α} {a : { x // x ∈ s }} {t u : Set { x // x ∈ s }} :
t ∈ 𝓝[u] a ↔ t ∈ comap ((↑) : s → α) (𝓝[(↑) '' u] a) := by
rw [nhdsWithin, nhds_subtype, principal_subtype, ← comap_inf, ← nhdsWithin]
theorem nhdsWithin_subtype (s : Set α) (a : { x // x ∈ s }) (t : Set { x // x ∈ s }) :
𝓝[t] a = comap ((↑) : s → α) (𝓝[(↑) '' t] a) :=
Filter.ext fun _ => mem_nhdsWithin_subtype
theorem nhdsWithin_eq_map_subtype_coe {s : Set α} {a : α} (h : a ∈ s) :
𝓝[s] a = map ((↑) : s → α) (𝓝 ⟨a, h⟩) :=
(map_nhds_subtype_val ⟨a, h⟩).symm
theorem mem_nhds_subtype_iff_nhdsWithin {s : Set α} {a : s} {t : Set s} :
t ∈ 𝓝 a ↔ (↑) '' t ∈ 𝓝[s] (a : α) := by
rw [← map_nhds_subtype_val, image_mem_map_iff Subtype.val_injective]
theorem preimage_coe_mem_nhds_subtype {s t : Set α} {a : s} : (↑) ⁻¹' t ∈ 𝓝 a ↔ t ∈ 𝓝[s] ↑a := by
rw [← map_nhds_subtype_val, mem_map]
theorem eventually_nhds_subtype_iff (s : Set α) (a : s) (P : α → Prop) :
(∀ᶠ x : s in 𝓝 a, P x) ↔ ∀ᶠ x in 𝓝[s] a, P x :=
preimage_coe_mem_nhds_subtype
theorem frequently_nhds_subtype_iff (s : Set α) (a : s) (P : α → Prop) :
(∃ᶠ x : s in 𝓝 a, P x) ↔ ∃ᶠ x in 𝓝[s] a, P x :=
eventually_nhds_subtype_iff s a (¬ P ·) |>.not
theorem tendsto_nhdsWithin_iff_subtype {s : Set α} {a : α} (h : a ∈ s) (f : α → β) (l : Filter β) :
Tendsto f (𝓝[s] a) l ↔ Tendsto (s.restrict f) (𝓝 ⟨a, h⟩) l := by
rw [nhdsWithin_eq_map_subtype_coe h, tendsto_map'_iff]; rfl
/-!
## Local continuity properties of functions
-/
variable [TopologicalSpace β] [TopologicalSpace γ] [TopologicalSpace δ]
{f g : α → β} {s s' s₁ t : Set α} {x : α}
/-!
### `ContinuousWithinAt`
-/
/-- If a function is continuous within `s` at `x`, then it tends to `f x` within `s` by definition.
We register this fact for use with the dot notation, especially to use `Filter.Tendsto.comp` as
`ContinuousWithinAt.comp` will have a different meaning. -/
theorem ContinuousWithinAt.tendsto (h : ContinuousWithinAt f s x) :
Tendsto f (𝓝[s] x) (𝓝 (f x)) :=
h
theorem continuousWithinAt_univ (f : α → β) (x : α) :
ContinuousWithinAt f Set.univ x ↔ ContinuousAt f x := by
rw [ContinuousAt, ContinuousWithinAt, nhdsWithin_univ]
theorem continuous_iff_continuousOn_univ {f : α → β} : Continuous f ↔ ContinuousOn f univ := by
simp [continuous_iff_continuousAt, ContinuousOn, ContinuousAt, ContinuousWithinAt,
nhdsWithin_univ]
theorem continuousWithinAt_iff_continuousAt_restrict (f : α → β) {x : α} {s : Set α} (h : x ∈ s) :
ContinuousWithinAt f s x ↔ ContinuousAt (s.restrict f) ⟨x, h⟩ :=
| tendsto_nhdsWithin_iff_subtype h f _
theorem ContinuousWithinAt.tendsto_nhdsWithin {t : Set β}
| Mathlib/Topology/ContinuousOn.lean | 538 | 540 |
/-
Copyright (c) 2017 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Jeremy Avigad, Simon Hudon
-/
import Batteries.WF
import Mathlib.Data.Part
import Mathlib.Data.Rel
import Mathlib.Tactic.GeneralizeProofs
/-!
# Partial functions
This file defines partial functions. Partial functions are like functions, except they can also be
"undefined" on some inputs. We define them as functions `α → Part β`.
## Definitions
* `PFun α β`: Type of partial functions from `α` to `β`. Defined as `α → Part β` and denoted
`α →. β`.
* `PFun.Dom`: Domain of a partial function. Set of values on which it is defined. Not to be confused
with the domain of a function `α → β`, which is a type (`α` presently).
* `PFun.fn`: Evaluation of a partial function. Takes in an element and a proof it belongs to the
partial function's `Dom`.
* `PFun.asSubtype`: Returns a partial function as a function from its `Dom`.
* `PFun.toSubtype`: Restricts the codomain of a function to a subtype.
* `PFun.evalOpt`: Returns a partial function with a decidable `Dom` as a function `a → Option β`.
* `PFun.lift`: Turns a function into a partial function.
* `PFun.id`: The identity as a partial function.
* `PFun.comp`: Composition of partial functions.
* `PFun.restrict`: Restriction of a partial function to a smaller `Dom`.
* `PFun.res`: Turns a function into a partial function with a prescribed domain.
* `PFun.fix` : First return map of a partial function `f : α →. β ⊕ α`.
* `PFun.fix_induction`: A recursion principle for `PFun.fix`.
### Partial functions as relations
Partial functions can be considered as relations, so we specialize some `Rel` definitions to `PFun`:
* `PFun.image`: Image of a set under a partial function.
* `PFun.ran`: Range of a partial function.
* `PFun.preimage`: Preimage of a set under a partial function.
* `PFun.core`: Core of a set under a partial function.
* `PFun.graph`: Graph of a partial function `a →. β`as a `Set (α × β)`.
* `PFun.graph'`: Graph of a partial function `a →. β`as a `Rel α β`.
### `PFun α` as a monad
Monad operations:
* `PFun.pure`: The monad `pure` function, the constant `x` function.
* `PFun.bind`: The monad `bind` function, pointwise `Part.bind`
* `PFun.map`: The monad `map` function, pointwise `Part.map`.
-/
-- Pending rename in core.
alias WellFounded.fixF_eq := WellFounded.fixFEq
open Function
/-- `PFun α β`, or `α →. β`, is the type of partial functions from
`α` to `β`. It is defined as `α → Part β`. -/
def PFun (α β : Type*) :=
α → Part β
/-- `α →. β` is notation for the type `PFun α β` of partial functions from `α` to `β`. -/
infixr:25 " →. " => PFun
namespace PFun
variable {α β γ δ ε ι : Type*}
instance inhabited : Inhabited (α →. β) :=
⟨fun _ => Part.none⟩
/-- The domain of a partial function -/
def Dom (f : α →. β) : Set α :=
{ a | (f a).Dom }
@[simp]
theorem mem_dom (f : α →. β) (x : α) : x ∈ Dom f ↔ ∃ y, y ∈ f x := by simp [Dom, Part.dom_iff_mem]
@[simp]
theorem dom_mk (p : α → Prop) (f : ∀ a, p a → β) : (PFun.Dom fun x => ⟨p x, f x⟩) = { x | p x } :=
rfl
theorem dom_eq (f : α →. β) : Dom f = { x | ∃ y, y ∈ f x } :=
Set.ext (mem_dom f)
/-- Evaluate a partial function -/
def fn (f : α →. β) (a : α) : Dom f a → β :=
(f a).get
@[simp]
theorem fn_apply (f : α →. β) (a : α) : f.fn a = (f a).get :=
rfl
/-- Evaluate a partial function to return an `Option` -/
def evalOpt (f : α →. β) [D : DecidablePred (· ∈ Dom f)] (x : α) : Option β :=
@Part.toOption _ _ (D x)
/-- Partial function extensionality -/
theorem ext' {f g : α →. β} (H1 : ∀ a, a ∈ Dom f ↔ a ∈ Dom g) (H2 : ∀ a p q, f.fn a p = g.fn a q) :
f = g :=
funext fun a => Part.ext' (H1 a) (H2 a)
@[ext]
theorem ext {f g : α →. β} (H : ∀ a b, b ∈ f a ↔ b ∈ g a) : f = g :=
funext fun a => Part.ext (H a)
/-- Turns a partial function into a function out of its domain. -/
def asSubtype (f : α →. β) (s : f.Dom) : β :=
f.fn s s.2
/-- The type of partial functions `α →. β` is equivalent to
the type of pairs `(p : α → Prop, f : Subtype p → β)`. -/
def equivSubtype : (α →. β) ≃ Σp : α → Prop, Subtype p → β :=
⟨fun f => ⟨fun a => (f a).Dom, asSubtype f⟩, fun f x => ⟨f.1 x, fun h => f.2 ⟨x, h⟩⟩, fun _ =>
funext fun _ => Part.eta _, fun ⟨p, f⟩ => by dsimp; congr⟩
theorem asSubtype_eq_of_mem {f : α →. β} {x : α} {y : β} (fxy : y ∈ f x) (domx : x ∈ f.Dom) :
f.asSubtype ⟨x, domx⟩ = y :=
Part.mem_unique (Part.get_mem _) fxy
/-- Turn a total function into a partial function. -/
@[coe]
protected def lift (f : α → β) : α →. β := fun a => Part.some (f a)
instance coe : Coe (α → β) (α →. β) :=
⟨PFun.lift⟩
@[simp]
theorem coe_val (f : α → β) (a : α) : (f : α →. β) a = Part.some (f a) :=
rfl
@[simp]
theorem dom_coe (f : α → β) : (f : α →. β).Dom = Set.univ :=
rfl
theorem lift_injective : Injective (PFun.lift : (α → β) → α →. β) := fun _ _ h =>
funext fun a => Part.some_injective <| congr_fun h a
/-- Graph of a partial function `f` as the set of pairs `(x, f x)` where `x` is in the domain of
`f`. -/
def graph (f : α →. β) : Set (α × β) :=
{ p | p.2 ∈ f p.1 }
/-- Graph of a partial function as a relation. `x` and `y` are related iff `f x` is defined and
"equals" `y`. -/
def graph' (f : α →. β) : Rel α β := fun x y => y ∈ f x
/-- The range of a partial function is the set of values
`f x` where `x` is in the domain of `f`. -/
def ran (f : α →. β) : Set β :=
{ b | ∃ a, b ∈ f a }
/-- Restrict a partial function to a smaller domain. -/
def restrict (f : α →. β) {p : Set α} (H : p ⊆ f.Dom) : α →. β := fun x =>
(f x).restrict (x ∈ p) (@H x)
@[simp]
theorem mem_restrict {f : α →. β} {s : Set α} (h : s ⊆ f.Dom) (a : α) (b : β) :
b ∈ f.restrict h a ↔ a ∈ s ∧ b ∈ f a := by simp [restrict]
/-- Turns a function into a partial function with a prescribed domain. -/
def res (f : α → β) (s : Set α) : α →. β :=
(PFun.lift f).restrict s.subset_univ
theorem mem_res (f : α → β) (s : Set α) (a : α) (b : β) : b ∈ res f s a ↔ a ∈ s ∧ f a = b := by
simp [res, @eq_comm _ b]
theorem res_univ (f : α → β) : PFun.res f Set.univ = f :=
rfl
theorem dom_iff_graph (f : α →. β) (x : α) : x ∈ f.Dom ↔ ∃ y, (x, y) ∈ f.graph :=
Part.dom_iff_mem
theorem lift_graph {f : α → β} {a b} : (a, b) ∈ (f : α →. β).graph ↔ f a = b :=
show (∃ _ : True, f a = b) ↔ f a = b by simp
/-- The monad `pure` function, the total constant `x` function -/
protected def pure (x : β) : α →. β := fun _ => Part.some x
/-- The monad `bind` function, pointwise `Part.bind` -/
def bind (f : α →. β) (g : β → α →. γ) : α →. γ := fun a => (f a).bind fun b => g b a
@[simp]
theorem bind_apply (f : α →. β) (g : β → α →. γ) (a : α) : f.bind g a = (f a).bind fun b => g b a :=
rfl
/-- The monad `map` function, pointwise `Part.map` -/
def map (f : β → γ) (g : α →. β) : α →. γ := fun a => (g a).map f
instance monad : Monad (PFun α) where
pure := PFun.pure
bind := PFun.bind
map := PFun.map
instance lawfulMonad : LawfulMonad (PFun α) := LawfulMonad.mk'
(bind_pure_comp := fun _ _ => funext fun _ => Part.bind_some_eq_map _ _)
(id_map := fun f => by funext a; dsimp [Functor.map, PFun.map]; cases f a; rfl)
(pure_bind := fun x f => funext fun _ => Part.bind_some _ (f x))
(bind_assoc := fun f g k => funext fun a => (f a).bind_assoc (fun b => g b a) fun b => k b a)
theorem pure_defined (p : Set α) (x : β) : p ⊆ (@PFun.pure α _ x).Dom :=
p.subset_univ
theorem bind_defined {α β γ} (p : Set α) {f : α →. β} {g : β → α →. γ} (H1 : p ⊆ f.Dom)
(H2 : ∀ x, p ⊆ (g x).Dom) : p ⊆ (f >>= g).Dom := fun a ha =>
(⟨H1 ha, H2 _ ha⟩ : (f >>= g).Dom a)
/-- First return map. Transforms a partial function `f : α →. β ⊕ α` into the partial function
`α →. β` which sends `a : α` to the first value in `β` it hits by iterating `f`, if such a value
exists. By abusing notation to illustrate, either `f a` is in the `β` part of `β ⊕ α` (in which
case `f.fix a` returns `f a`), or it is undefined (in which case `f.fix a` is undefined as well), or
it is in the `α` part of `β ⊕ α` (in which case we repeat the procedure, so `f.fix a` will return
`f.fix (f a)`). -/
def fix (f : α →. β ⊕ α) : α →. β := fun a =>
Part.assert (Acc (fun x y => Sum.inr x ∈ f y) a) fun h =>
WellFounded.fixF
(fun a IH =>
Part.assert (f a).Dom fun hf =>
match e : (f a).get hf with
| Sum.inl b => Part.some b
| Sum.inr a' => IH a' ⟨hf, e⟩)
a h
theorem dom_of_mem_fix {f : α →. β ⊕ α} {a : α} {b : β} (h : b ∈ f.fix a) : (f a).Dom := by
let ⟨h₁, h₂⟩ := Part.mem_assert_iff.1 h
rw [WellFounded.fixF_eq] at h₂; exact h₂.fst.fst
theorem mem_fix_iff {f : α →. β ⊕ α} {a : α} {b : β} :
b ∈ f.fix a ↔ Sum.inl b ∈ f a ∨ ∃ a', Sum.inr a' ∈ f a ∧ b ∈ f.fix a' :=
⟨fun h => by
let ⟨h₁, h₂⟩ := Part.mem_assert_iff.1 h
rw [WellFounded.fixF_eq] at h₂
simp only [Part.mem_assert_iff] at h₂
obtain ⟨h₂, h₃⟩ := h₂
split at h₃
next e => simp only [Part.mem_some_iff] at h₃; subst b; exact Or.inl ⟨h₂, e⟩
next e => exact Or.inr ⟨_, ⟨_, e⟩, Part.mem_assert _ h₃⟩,
fun h => by
simp only [fix, Part.mem_assert_iff]
rcases h with (⟨h₁, h₂⟩ | ⟨a', h, h₃⟩)
· refine ⟨⟨_, fun y h' => ?_⟩, ?_⟩
· injection Part.mem_unique ⟨h₁, h₂⟩ h'
· rw [WellFounded.fixF_eq]
-- Porting note: used to be simp [h₁, h₂]
apply Part.mem_assert h₁
split
next e =>
injection h₂.symm.trans e with h; simp [h]
next e =>
injection h₂.symm.trans e
· simp only [fix, Part.mem_assert_iff] at h₃
obtain ⟨h₃, h₄⟩ := h₃
refine ⟨⟨_, fun y h' => ?_⟩, ?_⟩
· injection Part.mem_unique h h' with e
exact e ▸ h₃
· obtain ⟨h₁, h₂⟩ := h
rw [WellFounded.fixF_eq]
-- Porting note: used to be simp [h₁, h₂, h₄]
apply Part.mem_assert h₁
split
next e =>
injection h₂.symm.trans e
next e =>
injection h₂.symm.trans e; subst a'; exact h₄⟩
/-- If advancing one step from `a` leads to `b : β`, then `f.fix a = b` -/
theorem fix_stop {f : α →. β ⊕ α} {b : β} {a : α} (hb : Sum.inl b ∈ f a) : b ∈ f.fix a := by
rw [PFun.mem_fix_iff]
exact Or.inl hb
/-- If advancing one step from `a` on `f` leads to `a' : α`, then `f.fix a = f.fix a'` -/
theorem fix_fwd_eq {f : α →. β ⊕ α} {a a' : α} (ha' : Sum.inr a' ∈ f a) : f.fix a = f.fix a' := by
ext b; constructor
· intro h
obtain h' | ⟨a, h', e'⟩ := mem_fix_iff.1 h <;> cases Part.mem_unique ha' h'
exact e'
· intro h
rw [PFun.mem_fix_iff]
exact Or.inr ⟨a', ha', h⟩
theorem fix_fwd {f : α →. β ⊕ α} {b : β} {a a' : α} (hb : b ∈ f.fix a) (ha' : Sum.inr a' ∈ f a) :
b ∈ f.fix a' := by rwa [← fix_fwd_eq ha']
/-- A recursion principle for `PFun.fix`. -/
@[elab_as_elim]
def fixInduction {C : α → Sort*} {f : α →. β ⊕ α} {b : β} {a : α} (h : b ∈ f.fix a)
(H : ∀ a', b ∈ f.fix a' → (∀ a'', Sum.inr a'' ∈ f a' → C a'') → C a') : C a := by
have h₂ := (Part.mem_assert_iff.1 h).snd
generalize_proofs at h₂
clear h
induction ‹Acc _ _› with | intro a ha IH => _
have h : b ∈ f.fix a := Part.mem_assert_iff.2 ⟨⟨a, ha⟩, h₂⟩
exact H a h fun a' fa' => IH a' fa' (Part.mem_assert_iff.1 (fix_fwd h fa')).snd
theorem fixInduction_spec {C : α → Sort*} {f : α →. β ⊕ α} {b : β} {a : α} (h : b ∈ f.fix a)
(H : ∀ a', b ∈ f.fix a' → (∀ a'', Sum.inr a'' ∈ f a' → C a'') → C a') :
@fixInduction _ _ C _ _ _ h H = H a h fun _ h' => fixInduction (fix_fwd h h') H := by
unfold fixInduction
generalize_proofs
induction ‹Acc _ _›
rfl
/-- Another induction lemma for `b ∈ f.fix a` which allows one to prove a predicate `P` holds for
`a` given that `f a` inherits `P` from `a` and `P` holds for preimages of `b`.
-/
@[elab_as_elim]
def fixInduction' {C : α → Sort*} {f : α →. β ⊕ α} {b : β} {a : α}
(h : b ∈ f.fix a) (hbase : ∀ a_final : α, Sum.inl b ∈ f a_final → C a_final)
(hind : ∀ a₀ a₁ : α, b ∈ f.fix a₁ → Sum.inr a₁ ∈ f a₀ → C a₁ → C a₀) : C a := by
refine fixInduction h fun a' h ih => ?_
rcases e : (f a').get (dom_of_mem_fix h) with b' | a'' <;> replace e : _ ∈ f a' := ⟨_, e⟩
· apply hbase
convert e
exact Part.mem_unique h (fix_stop e)
· exact hind _ _ (fix_fwd h e) e (ih _ e)
theorem fixInduction'_stop {C : α → Sort*} {f : α →. β ⊕ α} {b : β} {a : α} (h : b ∈ f.fix a)
(fa : Sum.inl b ∈ f a) (hbase : ∀ a_final : α, Sum.inl b ∈ f a_final → C a_final)
(hind : ∀ a₀ a₁ : α, b ∈ f.fix a₁ → Sum.inr a₁ ∈ f a₀ → C a₁ → C a₀) :
@fixInduction' _ _ C _ _ _ h hbase hind = hbase a fa := by
unfold fixInduction'
rw [fixInduction_spec]
-- Porting note: the explicit motive required because `simp` does not apply `Part.get_eq_of_mem`
refine Eq.rec (motive := fun x e ↦
Sum.casesOn x ?_ ?_ (Eq.trans (Part.get_eq_of_mem fa (dom_of_mem_fix h)) e) = hbase a fa) ?_
(Part.get_eq_of_mem fa (dom_of_mem_fix h)).symm
simp
theorem fixInduction'_fwd {C : α → Sort*} {f : α →. β ⊕ α} {b : β} {a a' : α} (h : b ∈ f.fix a)
(h' : b ∈ f.fix a') (fa : Sum.inr a' ∈ f a)
(hbase : ∀ a_final : α, Sum.inl b ∈ f a_final → C a_final)
(hind : ∀ a₀ a₁ : α, b ∈ f.fix a₁ → Sum.inr a₁ ∈ f a₀ → C a₁ → C a₀) :
@fixInduction' _ _ C _ _ _ h hbase hind = hind a a' h' fa (fixInduction' h' hbase hind) := by
unfold fixInduction'
rw [fixInduction_spec]
-- Porting note: the explicit motive required because `simp` does not apply `Part.get_eq_of_mem`
refine Eq.rec (motive := fun x e =>
Sum.casesOn (motive := fun y => (f a).get (dom_of_mem_fix h) = y → C a) x ?_ ?_
(Eq.trans (Part.get_eq_of_mem fa (dom_of_mem_fix h)) e) = _) ?_
(Part.get_eq_of_mem fa (dom_of_mem_fix h)).symm
simp
variable (f : α →. β)
/-- Image of a set under a partial function. -/
def image (s : Set α) : Set β :=
f.graph'.image s
theorem image_def (s : Set α) : f.image s = { y | ∃ x ∈ s, y ∈ f x } :=
rfl
theorem mem_image (y : β) (s : Set α) : y ∈ f.image s ↔ ∃ x ∈ s, y ∈ f x :=
Iff.rfl
theorem image_mono {s t : Set α} (h : s ⊆ t) : f.image s ⊆ f.image t :=
Rel.image_mono _ h
theorem image_inter (s t : Set α) : f.image (s ∩ t) ⊆ f.image s ∩ f.image t :=
Rel.image_inter _ s t
theorem image_union (s t : Set α) : f.image (s ∪ t) = f.image s ∪ f.image t :=
Rel.image_union _ s t
/-- Preimage of a set under a partial function. -/
def preimage (s : Set β) : Set α :=
Rel.image (fun x y => x ∈ f y) s
theorem Preimage_def (s : Set β) : f.preimage s = { x | ∃ y ∈ s, y ∈ f x } :=
rfl
@[simp]
theorem mem_preimage (s : Set β) (x : α) : x ∈ f.preimage s ↔ ∃ y ∈ s, y ∈ f x :=
Iff.rfl
theorem preimage_subset_dom (s : Set β) : f.preimage s ⊆ f.Dom := fun _ ⟨y, _, fxy⟩ =>
Part.dom_iff_mem.mpr ⟨y, fxy⟩
theorem preimage_mono {s t : Set β} (h : s ⊆ t) : f.preimage s ⊆ f.preimage t :=
Rel.preimage_mono _ h
theorem preimage_inter (s t : Set β) : f.preimage (s ∩ t) ⊆ f.preimage s ∩ f.preimage t :=
Rel.preimage_inter _ s t
theorem preimage_union (s t : Set β) : f.preimage (s ∪ t) = f.preimage s ∪ f.preimage t :=
Rel.preimage_union _ s t
theorem preimage_univ : f.preimage Set.univ = f.Dom := by ext; simp [mem_preimage, mem_dom]
theorem coe_preimage (f : α → β) (s : Set β) : (f : α →. β).preimage s = f ⁻¹' s := by ext; simp
/-- Core of a set `s : Set β` with respect to a partial function `f : α →. β`. Set of all `a : α`
such that `f a ∈ s`, if `f a` is defined. -/
def core (s : Set β) : Set α :=
f.graph'.core s
theorem core_def (s : Set β) : f.core s = { x | ∀ y, y ∈ f x → y ∈ s } :=
rfl
@[simp]
theorem mem_core (x : α) (s : Set β) : x ∈ f.core s ↔ ∀ y, y ∈ f x → y ∈ s :=
Iff.rfl
theorem compl_dom_subset_core (s : Set β) : f.Domᶜ ⊆ f.core s := fun x hx y fxy =>
absurd ((mem_dom f x).mpr ⟨y, fxy⟩) hx
theorem core_mono {s t : Set β} (h : s ⊆ t) : f.core s ⊆ f.core t :=
Rel.core_mono _ h
theorem core_inter (s t : Set β) : f.core (s ∩ t) = f.core s ∩ f.core t :=
Rel.core_inter _ s t
theorem mem_core_res (f : α → β) (s : Set α) (t : Set β) (x : α) :
x ∈ (res f s).core t ↔ x ∈ s → f x ∈ t := by simp [mem_core, mem_res]
theorem core_res (f : α → β) (s : Set α) (t : Set β) : (res f s).core t = sᶜ ∪ f ⁻¹' t := by
ext x
rw [mem_core_res]
by_cases h : x ∈ s <;> simp [h]
theorem core_restrict (f : α → β) (s : Set β) : (f : α →. β).core s = s.preimage f := by
ext x; simp [core_def]
theorem preimage_subset_core (f : α →. β) (s : Set β) : f.preimage s ⊆ f.core s :=
fun _ ⟨y, ys, fxy⟩ y' fxy' =>
have : y = y' := Part.mem_unique fxy fxy'
this ▸ ys
theorem preimage_eq (f : α →. β) (s : Set β) : f.preimage s = f.core s ∩ f.Dom :=
Set.eq_of_subset_of_subset (Set.subset_inter (f.preimage_subset_core s) (f.preimage_subset_dom s))
fun x ⟨xcore, xdom⟩ =>
let y := (f x).get xdom
have ys : y ∈ s := xcore _ (Part.get_mem _)
show x ∈ f.preimage s from ⟨(f x).get xdom, ys, Part.get_mem _⟩
theorem core_eq (f : α →. β) (s : Set β) : f.core s = f.preimage s ∪ f.Domᶜ := by
rw [preimage_eq, Set.inter_union_distrib_right, Set.union_comm (Dom f), Set.compl_union_self,
Set.inter_univ, Set.union_eq_self_of_subset_right (f.compl_dom_subset_core s)]
theorem preimage_asSubtype (f : α →. β) (s : Set β) :
f.asSubtype ⁻¹' s = Subtype.val ⁻¹' f.preimage s := by
ext x
simp only [Set.mem_preimage, Set.mem_setOf_eq, PFun.asSubtype, PFun.mem_preimage]
show f.fn x.val _ ∈ s ↔ ∃ y ∈ s, y ∈ f x.val
exact
Iff.intro (fun h => ⟨_, h, Part.get_mem _⟩) fun ⟨y, ys, fxy⟩ =>
have : f.fn x.val x.property ∈ f x.val := Part.get_mem _
Part.mem_unique fxy this ▸ ys
/-- Turns a function into a partial function to a subtype. -/
def toSubtype (p : β → Prop) (f : α → β) : α →. Subtype p := fun a => ⟨p (f a), Subtype.mk _⟩
@[simp]
theorem dom_toSubtype (p : β → Prop) (f : α → β) : (toSubtype p f).Dom = { a | p (f a) } :=
rfl
@[simp]
theorem toSubtype_apply (p : β → Prop) (f : α → β) (a : α) :
toSubtype p f a = ⟨p (f a), Subtype.mk _⟩ :=
rfl
theorem dom_toSubtype_apply_iff {p : β → Prop} {f : α → β} {a : α} :
(toSubtype p f a).Dom ↔ p (f a) :=
Iff.rfl
theorem mem_toSubtype_iff {p : β → Prop} {f : α → β} {a : α} {b : Subtype p} :
b ∈ toSubtype p f a ↔ ↑b = f a := by
rw [toSubtype_apply, Part.mem_mk_iff, exists_subtype_mk_eq_iff, eq_comm]
/-- The identity as a partial function -/
protected def id (α : Type*) : α →. α :=
Part.some
@[simp, norm_cast]
theorem coe_id (α : Type*) : ((id : α → α) : α →. α) = PFun.id α :=
rfl
@[simp]
theorem id_apply (a : α) : PFun.id α a = Part.some a :=
rfl
/-- Composition of partial functions as a partial function. -/
def comp (f : β →. γ) (g : α →. β) : α →. γ := fun a => (g a).bind f
@[simp]
theorem comp_apply (f : β →. γ) (g : α →. β) (a : α) : f.comp g a = (g a).bind f :=
rfl
@[simp]
theorem id_comp (f : α →. β) : (PFun.id β).comp f = f :=
ext fun _ _ => by simp
@[simp]
theorem comp_id (f : α →. β) : f.comp (PFun.id α) = f :=
ext fun _ _ => by simp
@[simp]
theorem dom_comp (f : β →. γ) (g : α →. β) : (f.comp g).Dom = g.preimage f.Dom := by
ext
simp_rw [mem_preimage, mem_dom, comp_apply, Part.mem_bind_iff, ← exists_and_right]
rw [exists_comm]
simp_rw [and_comm]
@[simp]
theorem preimage_comp (f : β →. γ) (g : α →. β) (s : Set γ) :
(f.comp g).preimage s = g.preimage (f.preimage s) := by
ext
simp_rw [mem_preimage, comp_apply, Part.mem_bind_iff, ← exists_and_right, ← exists_and_left]
rw [exists_comm]
simp_rw [and_assoc, and_comm]
@[simp]
theorem Part.bind_comp (f : β →. γ) (g : α →. β) (a : Part α) :
a.bind (f.comp g) = (a.bind g).bind f := by
ext c
simp_rw [Part.mem_bind_iff, comp_apply, Part.mem_bind_iff, ← exists_and_right, ← exists_and_left]
rw [exists_comm]
simp_rw [and_assoc]
@[simp]
theorem comp_assoc (f : γ →. δ) (g : β →. γ) (h : α →. β) : (f.comp g).comp h = f.comp (g.comp h) :=
ext fun _ _ => by simp only [comp_apply, Part.bind_comp]
-- This can't be `simp`
theorem coe_comp (g : β → γ) (f : α → β) : ((g ∘ f : α → γ) : α →. γ) = (g : β →. γ).comp f :=
ext fun _ _ => by simp only [coe_val, comp_apply, Function.comp, Part.bind_some]
/-- Product of partial functions. -/
def prodLift (f : α →. β) (g : α →. γ) : α →. β × γ := fun x =>
⟨(f x).Dom ∧ (g x).Dom, fun h => ((f x).get h.1, (g x).get h.2)⟩
@[simp]
theorem dom_prodLift (f : α →. β) (g : α →. γ) :
(f.prodLift g).Dom = { x | (f x).Dom ∧ (g x).Dom } :=
rfl
theorem get_prodLift (f : α →. β) (g : α →. γ) (x : α) (h) :
(f.prodLift g x).get h = ((f x).get h.1, (g x).get h.2) :=
rfl
@[simp]
theorem prodLift_apply (f : α →. β) (g : α →. γ) (x : α) :
f.prodLift g x = ⟨(f x).Dom ∧ (g x).Dom, fun h => ((f x).get h.1, (g x).get h.2)⟩ :=
rfl
theorem mem_prodLift {f : α →. β} {g : α →. γ} {x : α} {y : β × γ} :
y ∈ f.prodLift g x ↔ y.1 ∈ f x ∧ y.2 ∈ g x := by
trans ∃ hp hq, (f x).get hp = y.1 ∧ (g x).get hq = y.2
· simp only [prodLift, Part.mem_mk_iff, And.exists, Prod.ext_iff]
· simp only [exists_and_left, exists_and_right, Membership.mem, Part.Mem]
/-- Product of partial functions. -/
def prodMap (f : α →. γ) (g : β →. δ) : α × β →. γ × δ := fun x =>
⟨(f x.1).Dom ∧ (g x.2).Dom, fun h => ((f x.1).get h.1, (g x.2).get h.2)⟩
@[simp]
theorem dom_prodMap (f : α →. γ) (g : β →. δ) :
(f.prodMap g).Dom = { x | (f x.1).Dom ∧ (g x.2).Dom } :=
rfl
theorem get_prodMap (f : α →. γ) (g : β →. δ) (x : α × β) (h) :
(f.prodMap g x).get h = ((f x.1).get h.1, (g x.2).get h.2) :=
rfl
@[simp]
theorem prodMap_apply (f : α →. γ) (g : β →. δ) (x : α × β) :
f.prodMap g x = ⟨(f x.1).Dom ∧ (g x.2).Dom, fun h => ((f x.1).get h.1, (g x.2).get h.2)⟩ :=
rfl
theorem mem_prodMap {f : α →. γ} {g : β →. δ} {x : α × β} {y : γ × δ} :
y ∈ f.prodMap g x ↔ y.1 ∈ f x.1 ∧ y.2 ∈ g x.2 := by
trans ∃ hp hq, (f x.1).get hp = y.1 ∧ (g x.2).get hq = y.2
· simp only [prodMap, Part.mem_mk_iff, And.exists, Prod.ext_iff]
· simp only [exists_and_left, exists_and_right, Membership.mem, Part.Mem]
@[simp]
theorem prodLift_fst_comp_snd_comp (f : α →. γ) (g : β →. δ) :
prodLift (f.comp ((Prod.fst : α × β → α) : α × β →. α))
(g.comp ((Prod.snd : α × β → β) : α × β →. β)) =
prodMap f g := by
aesop
@[simp]
theorem prodMap_id_id : (PFun.id α).prodMap (PFun.id β) = PFun.id _ := by
aesop
@[simp]
theorem prodMap_comp_comp (f₁ : α →. β) (f₂ : β →. γ) (g₁ : δ →. ε) (g₂ : ε →. ι) :
(f₂.comp f₁).prodMap (g₂.comp g₁) = (f₂.prodMap g₂).comp (f₁.prodMap g₁) :=
-- `aesop` can prove this but takes over a second, so we do it manually
ext <| fun ⟨_, _⟩ ⟨_, _⟩ ↦
⟨fun ⟨⟨⟨h1l1, h1l2⟩, ⟨h1r1, h1r2⟩⟩, h2⟩ ↦ ⟨⟨⟨h1l1, h1r1⟩, ⟨h1l2, h1r2⟩⟩, h2⟩,
fun ⟨⟨⟨h1l1, h1r1⟩, ⟨h1l2, h1r2⟩⟩, h2⟩ ↦ ⟨⟨⟨h1l1, h1l2⟩, ⟨h1r1, h1r2⟩⟩, h2⟩⟩
end PFun
| Mathlib/Data/PFun.lean | 677 | 681 | |
/-
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.
| Mathlib/MeasureTheory/SetSemiring.lean | 71 | 75 |
/-
Copyright (c) 2024 Newell Jensen. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Newell Jensen, Mitchell Lee, Óscar Álvarez
-/
import Mathlib.Algebra.Group.Subgroup.Pointwise
import Mathlib.Algebra.Ring.Int.Parity
import Mathlib.GroupTheory.Coxeter.Matrix
import Mathlib.GroupTheory.PresentedGroup
import Mathlib.Tactic.NormNum.DivMod
import Mathlib.Tactic.Ring
import Mathlib.Tactic.Use
/-!
# Coxeter groups and Coxeter systems
This file defines Coxeter groups and Coxeter systems.
Let `B` be a (possibly infinite) type, and let $M = (M_{i,i'})_{i, i' \in B}$ be a matrix
of natural numbers. Further assume that $M$ is a *Coxeter matrix* (`CoxeterMatrix`); that is, $M$ is
symmetric and $M_{i,i'} = 1$ if and only if $i = i'$. The *Coxeter group* associated to $M$
(`CoxeterMatrix.group`) has the presentation
$$\langle \{s_i\}_{i \in B} \vert \{(s_i s_{i'})^{M_{i, i'}}\}_{i, i' \in B} \rangle.$$
The elements $s_i$ are called the *simple reflections* (`CoxeterMatrix.simple`) of the Coxeter
group. Note that every simple reflection is an involution.
A *Coxeter system* (`CoxeterSystem`) is a group $W$, together with an isomorphism between $W$ and
the Coxeter group associated to some Coxeter matrix $M$. By abuse of language, we also say that $W$
is a Coxeter group (`IsCoxeterGroup`), and we may speak of the simple reflections $s_i \in W$
(`CoxeterSystem.simple`). We state all of our results about Coxeter groups in terms of Coxeter
systems where possible.
Let $W$ be a group equipped with a Coxeter system. For all monoids $G$ and all functions
$f \colon B \to G$ whose values satisfy the Coxeter relations, we may lift $f$ to a multiplicative
homomorphism $W \to G$ (`CoxeterSystem.lift`) in a unique way.
A *word* is a sequence of elements of $B$. The word $(i_1, \ldots, i_\ell)$ has a corresponding
product $s_{i_1} \cdots s_{i_\ell} \in W$ (`CoxeterSystem.wordProd`). Every element of $W$ is the
product of some word (`CoxeterSystem.wordProd_surjective`). The words that alternate between two
elements of $B$ (`CoxeterSystem.alternatingWord`) are particularly important.
## Implementation details
Much of the literature on Coxeter groups conflates the set $S = \{s_i : i \in B\} \subseteq W$ of
simple reflections with the set $B$ that indexes the simple reflections. This is usually permissible
because the simple reflections $s_i$ of any Coxeter group are all distinct (a nontrivial fact that
we do not prove in this file). In contrast, we try not to refer to the set $S$ of simple
reflections unless necessary; instead, we state our results in terms of $B$ wherever possible.
## Main definitions
* `CoxeterMatrix.Group`
* `CoxeterSystem`
* `IsCoxeterGroup`
* `CoxeterSystem.simple` : If `cs` is a Coxeter system on the group `W`, then `cs.simple i` is the
simple reflection of `W` at the index `i`.
* `CoxeterSystem.lift` : Extend a function `f : B → G` to a monoid homomorphism `f' : W → G`
satisfying `f' (cs.simple i) = f i` for all `i`.
* `CoxeterSystem.wordProd`
* `CoxeterSystem.alternatingWord`
## References
* [N. Bourbaki, *Lie Groups and Lie Algebras, Chapters 4--6*](bourbaki1968) chapter IV
pages 4--5, 13--15
* [J. Baez, *Coxeter and Dynkin Diagrams*](https://math.ucr.edu/home/baez/twf_dynkin.pdf)
## TODO
* The simple reflections of a Coxeter system are distinct.
* Introduce some ways to actually construct some Coxeter groups. For example, given a Coxeter matrix
$M : B \times B \to \mathbb{N}$, a real vector space $V$, a basis $\{\alpha_i : i \in B\}$
and a bilinear form $\langle \cdot, \cdot \rangle \colon V \times V \to \mathbb{R}$ satisfying
$$\langle \alpha_i, \alpha_{i'}\rangle = - \cos(\pi / M_{i,i'}),$$ one can form the subgroup of
$GL(V)$ generated by the reflections in the $\alpha_i$, and it is a Coxeter group. We can use this
to combinatorially describe the Coxeter groups of type $A$, $B$, $D$, and $I$.
* State and prove Matsumoto's theorem.
* Classify the finite Coxeter groups.
## Tags
coxeter system, coxeter group
-/
open Function Set List
/-! ### Coxeter groups -/
namespace CoxeterMatrix
variable {B B' : Type*} (M : CoxeterMatrix B) (e : B ≃ B')
/-- The Coxeter relation associated to a Coxeter matrix $M$ and two indices $i, i' \in B$.
That is, the relation $(s_i s_{i'})^{M_{i, i'}}$, considered as an element of the free group
on $\{s_i\}_{i \in B}$.
If $M_{i, i'} = 0$, then this is the identity, indicating that there is no relation between
$s_i$ and $s_{i'}$. -/
def relation (i i' : B) : FreeGroup B := (FreeGroup.of i * FreeGroup.of i') ^ M i i'
/-- The set of all Coxeter relations associated to the Coxeter matrix $M$. -/
def relationsSet : Set (FreeGroup B) := range <| uncurry M.relation
/-- The Coxeter group associated to a Coxeter matrix $M$; that is, the group
$$\langle \{s_i\}_{i \in B} \vert \{(s_i s_{i'})^{M_{i, i'}}\}_{i, i' \in B} \rangle.$$ -/
protected def Group : Type _ := PresentedGroup M.relationsSet
instance : Group M.Group := QuotientGroup.Quotient.group _
/-- The simple reflection of the Coxeter group `M.group` at the index `i`. -/
def simple (i : B) : M.Group := PresentedGroup.of i
theorem reindex_relationsSet :
(M.reindex e).relationsSet =
FreeGroup.freeGroupCongr e '' M.relationsSet := let M' := M.reindex e; calc
Set.range (uncurry M'.relation)
_ = Set.range (uncurry M'.relation ∘ Prod.map e e) := by simp [Set.range_comp]
_ = Set.range (FreeGroup.freeGroupCongr e ∘ uncurry M.relation) := by
apply congrArg Set.range
ext ⟨i, i'⟩
simp [relation, reindex_apply, M']
_ = _ := by simp [Set.range_comp, relationsSet]
/-- The isomorphism between the Coxeter group associated to the reindexed matrix `M.reindex e` and
the Coxeter group associated to `M`. -/
def reindexGroupEquiv : (M.reindex e).Group ≃* M.Group :=
.symm <| QuotientGroup.congr
(Subgroup.normalClosure M.relationsSet)
(Subgroup.normalClosure (M.reindex e).relationsSet)
(FreeGroup.freeGroupCongr e)
(by
rw [reindex_relationsSet,
Subgroup.map_normalClosure _ _ (by simpa using (FreeGroup.freeGroupCongr e).surjective),
MonoidHom.coe_coe])
theorem reindexGroupEquiv_apply_simple (i : B') :
(M.reindexGroupEquiv e) ((M.reindex e).simple i) = M.simple (e.symm i) := rfl
theorem reindexGroupEquiv_symm_apply_simple (i : B) :
(M.reindexGroupEquiv e).symm (M.simple i) = (M.reindex e).simple (e i) := rfl
end CoxeterMatrix
/-! ### Coxeter systems -/
section
variable {B : Type*} (M : CoxeterMatrix B)
/-- A Coxeter system `CoxeterSystem M W` is a structure recording the isomorphism between
a group `W` and the Coxeter group associated to a Coxeter matrix `M`. -/
@[ext]
structure CoxeterSystem (W : Type*) [Group W] where
/-- The isomorphism between `W` and the Coxeter group associated to `M`. -/
mulEquiv : W ≃* M.Group
/-- A group is a Coxeter group if it admits a Coxeter system for some Coxeter matrix `M`. -/
class IsCoxeterGroup.{u} (W : Type u) [Group W] : Prop where
nonempty_system : ∃ B : Type u, ∃ M : CoxeterMatrix B, Nonempty (CoxeterSystem M W)
/-- The canonical Coxeter system on the Coxeter group associated to `M`. -/
def CoxeterMatrix.toCoxeterSystem : CoxeterSystem M M.Group := ⟨.refl _⟩
end
namespace CoxeterSystem
open CoxeterMatrix
variable {B B' : Type*} (e : B ≃ B')
variable {W H : Type*} [Group W] [Group H]
variable {M : CoxeterMatrix B} (cs : CoxeterSystem M W)
/-- Reindex a Coxeter system through a bijection of the indexing sets. -/
@[simps]
protected def reindex (e : B ≃ B') : CoxeterSystem (M.reindex e) W :=
⟨cs.mulEquiv.trans (M.reindexGroupEquiv e).symm⟩
/-- Push a Coxeter system through a group isomorphism. -/
@[simps]
protected def map (e : W ≃* H) : CoxeterSystem M H := ⟨e.symm.trans cs.mulEquiv⟩
/-! ### Simple reflections -/
/-- The simple reflection of `W` at the index `i`. -/
def simple (i : B) : W := cs.mulEquiv.symm (PresentedGroup.of i)
@[simp]
theorem _root_.CoxeterMatrix.toCoxeterSystem_simple (M : CoxeterMatrix B) :
M.toCoxeterSystem.simple = M.simple := rfl
@[simp] theorem reindex_simple (i' : B') : (cs.reindex e).simple i' = cs.simple (e.symm i') := rfl
@[simp] theorem map_simple (e : W ≃* H) (i : B) : (cs.map e).simple i = e (cs.simple i) := rfl
local prefix:100 "s" => cs.simple
@[simp]
theorem simple_mul_simple_self (i : B) : s i * s i = 1 := by
have : (FreeGroup.of i) * (FreeGroup.of i) ∈ M.relationsSet := ⟨(i, i), by simp [relation]⟩
have : (PresentedGroup.mk _ (FreeGroup.of i * FreeGroup.of i) : M.Group) = 1 :=
(QuotientGroup.eq_one_iff _).mpr (Subgroup.subset_normalClosure this)
unfold simple
rw [← map_mul, PresentedGroup.of, map_mul]
exact map_mul_eq_one cs.mulEquiv.symm this
@[simp]
theorem simple_mul_simple_cancel_right {w : W} (i : B) : w * s i * s i = w := by
simp [mul_assoc]
@[simp]
theorem simple_mul_simple_cancel_left {w : W} (i : B) : s i * (s i * w) = w := by
simp [← mul_assoc]
@[simp] theorem simple_sq (i : B) : s i ^ 2 = 1 := pow_two (s i) ▸ cs.simple_mul_simple_self i
@[simp]
theorem inv_simple (i : B) : (s i)⁻¹ = s i :=
(eq_inv_of_mul_eq_one_right (cs.simple_mul_simple_self i)).symm
@[simp]
theorem simple_mul_simple_pow (i i' : B) : (s i * s i') ^ M i i' = 1 := by
have : (FreeGroup.of i * FreeGroup.of i') ^ M i i' ∈ M.relationsSet := ⟨(i, i'), rfl⟩
have : (PresentedGroup.mk _ ((FreeGroup.of i * FreeGroup.of i') ^ M i i') : M.Group) = 1 :=
(QuotientGroup.eq_one_iff _).mpr (Subgroup.subset_normalClosure this)
unfold simple
rw [← map_mul, ← map_pow]
exact (MulEquiv.map_eq_one_iff cs.mulEquiv.symm).mpr this
@[simp] theorem simple_mul_simple_pow' (i i' : B) : (s i' * s i) ^ M i i' = 1 :=
M.symmetric i' i ▸ cs.simple_mul_simple_pow i' i
/-- The simple reflections of `W` generate `W` as a group. -/
theorem subgroup_closure_range_simple : Subgroup.closure (range cs.simple) = ⊤ := by
have : cs.simple = cs.mulEquiv.symm ∘ PresentedGroup.of := rfl
rw [this, Set.range_comp, ← MulEquiv.coe_toMonoidHom, ← MonoidHom.map_closure,
PresentedGroup.closure_range_of, ← MonoidHom.range_eq_map]
exact MonoidHom.range_eq_top.2 (MulEquiv.surjective _)
/-- The simple reflections of `W` generate `W` as a monoid. -/
theorem submonoid_closure_range_simple : Submonoid.closure (range cs.simple) = ⊤ := by
have : range cs.simple = range cs.simple ∪ (range cs.simple)⁻¹ := by
simp_rw [inv_range, inv_simple, union_self]
rw [this, ← Subgroup.closure_toSubmonoid, subgroup_closure_range_simple, Subgroup.top_toSubmonoid]
/-! ### Induction principles for Coxeter systems -/
/-- If `p : W → Prop` holds for all simple reflections, it holds for the identity, and it is
preserved under multiplication, then it holds for all elements of `W`. -/
theorem simple_induction {p : W → Prop} (w : W) (simple : ∀ i : B, p (s i)) (one : p 1)
(mul : ∀ w w' : W, p w → p w' → p (w * w')) : p w := by
have := cs.submonoid_closure_range_simple.symm ▸ Submonoid.mem_top w
exact Submonoid.closure_induction (fun x ⟨i, hi⟩ ↦ hi ▸ simple i) one (fun _ _ _ _ ↦ mul _ _)
this
/-- If `p : W → Prop` holds for the identity and it is preserved under multiplying on the left
by a simple reflection, then it holds for all elements of `W`. -/
theorem simple_induction_left {p : W → Prop} (w : W) (one : p 1)
(mul_simple_left : ∀ (w : W) (i : B), p w → p (s i * w)) : p w := by
let p' : (w : W) → w ∈ Submonoid.closure (Set.range cs.simple) → Prop :=
fun w _ ↦ p w
have := cs.submonoid_closure_range_simple.symm ▸ Submonoid.mem_top w
apply Submonoid.closure_induction_left (p := p')
· exact one
· rintro _ ⟨i, rfl⟩ y _
exact mul_simple_left y i
· exact this
/-- If `p : W → Prop` holds for the identity and it is preserved under multiplying on the right
by a simple reflection, then it holds for all elements of `W`. -/
theorem simple_induction_right {p : W → Prop} (w : W) (one : p 1)
(mul_simple_right : ∀ (w : W) (i : B), p w → p (w * s i)) : p w := by
let p' : ((w : W) → w ∈ Submonoid.closure (Set.range cs.simple) → Prop) :=
fun w _ ↦ p w
have := cs.submonoid_closure_range_simple.symm ▸ Submonoid.mem_top w
apply Submonoid.closure_induction_right (p := p')
· exact one
· rintro x _ _ ⟨i, rfl⟩
exact mul_simple_right x i
· exact this
/-! ### Homomorphisms from a Coxeter group -/
/-- If two homomorphisms with domain `W` agree on all simple reflections, then they are equal. -/
theorem ext_simple {G : Type*} [MulOneClass G] {φ₁ φ₂ : W →* G} (h : ∀ i : B, φ₁ (s i) = φ₂ (s i)) :
φ₁ = φ₂ :=
MonoidHom.eq_of_eqOn_denseM cs.submonoid_closure_range_simple (fun _ ⟨i, hi⟩ ↦ hi ▸ h i)
/-- The proposition that the values of the function `f : B → G` satisfy the Coxeter relations
corresponding to the matrix `M`. -/
def _root_.CoxeterMatrix.IsLiftable {G : Type*} [Monoid G] (M : CoxeterMatrix B) (f : B → G) :
Prop := ∀ i i', (f i * f i') ^ M i i' = 1
private theorem relations_liftable {G : Type*} [Group G] {f : B → G} (hf : IsLiftable M f)
(r : FreeGroup B) (hr : r ∈ M.relationsSet) : (FreeGroup.lift f) r = 1 := by
rcases hr with ⟨⟨i, i'⟩, rfl⟩
rw [uncurry, relation, map_pow, map_mul, FreeGroup.lift.of, FreeGroup.lift.of]
exact hf i i'
private def groupLift {G : Type*} [Group G] {f : B → G} (hf : IsLiftable M f) : W →* G :=
(PresentedGroup.toGroup (relations_liftable hf)).comp cs.mulEquiv.toMonoidHom
private def restrictUnit {G : Type*} [Monoid G] {f : B → G} (hf : IsLiftable M f) (i : B) :
Gˣ where
val := f i
inv := f i
val_inv := pow_one (f i * f i) ▸ M.diagonal i ▸ hf i i
inv_val := pow_one (f i * f i) ▸ M.diagonal i ▸ hf i i
private theorem toMonoidHom_apply_symm_apply (a : PresentedGroup (M.relationsSet)) :
(MulEquiv.toMonoidHom cs.mulEquiv : W →* PresentedGroup (M.relationsSet))
((MulEquiv.symm cs.mulEquiv) a) = a := calc
_ = cs.mulEquiv ((MulEquiv.symm cs.mulEquiv) a) := by rfl
_ = _ := by rw [MulEquiv.apply_symm_apply]
/-- The universal mapping property of Coxeter systems. For any monoid `G`,
functions `f : B → G` whose values satisfy the Coxeter relations are equivalent to
monoid homomorphisms `f' : W → G`. -/
def lift {G : Type*} [Monoid G] : {f : B → G // IsLiftable M f} ≃ (W →* G) where
toFun f := MonoidHom.comp (Units.coeHom G) (cs.groupLift
(show ∀ i i', ((restrictUnit f.property) i * (restrictUnit f.property) i') ^ M i i' = 1 from
fun i i' ↦ Units.ext (f.property i i')))
invFun ι := ⟨ι ∘ cs.simple, fun i i' ↦ by
rw [comp_apply, comp_apply, ← map_mul, ← map_pow, simple_mul_simple_pow, map_one]⟩
left_inv f := by
ext i
simp only [MonoidHom.comp_apply, comp_apply, mem_setOf_eq, groupLift, simple]
rw [← MonoidHom.toFun_eq_coe, toMonoidHom_apply_symm_apply, PresentedGroup.toGroup.of,
OneHom.toFun_eq_coe, MonoidHom.toOneHom_coe, Units.coeHom_apply, restrictUnit]
right_inv ι := by
apply cs.ext_simple
intro i
dsimp only
rw [groupLift, simple, MonoidHom.comp_apply, MonoidHom.comp_apply, toMonoidHom_apply_symm_apply,
PresentedGroup.toGroup.of, CoxeterSystem.restrictUnit, Units.coeHom_apply]
simp only [comp_apply, simple]
@[simp]
theorem lift_apply_simple {G : Type*} [Monoid G] {f : B → G} (hf : IsLiftable M f) (i : B) :
cs.lift ⟨f, hf⟩ (s i) = f i := congrFun (congrArg Subtype.val (cs.lift.left_inv ⟨f, hf⟩)) i
/-- If two Coxeter systems on the same group `W` have the same Coxeter matrix `M : Matrix B B ℕ`
and the same simple reflection map `B → W`, then they are identical. -/
theorem simple_determines_coxeterSystem :
Injective (simple : CoxeterSystem M W → B → W) := by
intro cs1 cs2 h
apply CoxeterSystem.ext
apply MulEquiv.toMonoidHom_injective
apply cs1.ext_simple
intro i
nth_rw 2 [h]
simp [simple]
/-! ### Words -/
/-- The product of the simple reflections of `W` corresponding to the indices in `ω`. -/
def wordProd (ω : List B) : W := prod (map cs.simple ω)
local prefix:100 "π" => cs.wordProd
@[simp] theorem wordProd_nil : π [] = 1 := by simp [wordProd]
theorem wordProd_cons (i : B) (ω : List B) : π (i :: ω) = s i * π ω := by simp [wordProd]
@[simp] theorem wordProd_singleton (i : B) : π ([i]) = s i := by simp [wordProd]
theorem wordProd_concat (i : B) (ω : List B) : π (ω.concat i) = π ω * s i := by simp [wordProd]
theorem wordProd_append (ω ω' : List B) : π (ω ++ ω') = π ω * π ω' := by simp [wordProd]
|
@[simp] theorem wordProd_reverse (ω : List B) : π (reverse ω) = (π ω)⁻¹ := by
induction' ω with x ω' ih
· simp
· simpa [wordProd_cons, wordProd_append] using ih
theorem wordProd_surjective : Surjective cs.wordProd := by
intro w
| Mathlib/GroupTheory/Coxeter/Basic.lean | 371 | 378 |
/-
Copyright (c) 2022 Paul Reichert. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Paul Reichert
-/
import Mathlib.LinearAlgebra.AffineSpace.AffineSubspace.Basic
/-!
# Affine map restrictions
This file defines restrictions of affine maps.
## Main definitions
* The domain and codomain of an affine map can be restricted using
`AffineMap.restrict`.
## Main theorems
* The associated linear map of the restriction is the restriction of the
linear map associated to the original affine map.
* The restriction is injective if the original map is injective.
* The restriction in surjective if the codomain is the image of the domain.
-/
variable {k V₁ P₁ V₂ P₂ : Type*} [Ring k] [AddCommGroup V₁] [AddCommGroup V₂] [Module k V₁]
[Module k V₂] [AddTorsor V₁ P₁] [AddTorsor V₂ P₂]
-- not an instance because it loops with `Nonempty`
theorem AffineSubspace.nonempty_map {E : AffineSubspace k P₁} [Ene : Nonempty E] {φ : P₁ →ᵃ[k] P₂} :
Nonempty (E.map φ) := by
obtain ⟨x, hx⟩ := id Ene
exact ⟨⟨φ x, AffineSubspace.mem_map.mpr ⟨x, hx, rfl⟩⟩⟩
attribute [local instance] AffineSubspace.nonempty_map AffineSubspace.toAddTorsor
/-- Restrict domain and codomain of an affine map to the given subspaces. -/
def AffineMap.restrict (φ : P₁ →ᵃ[k] P₂) {E : AffineSubspace k P₁} {F : AffineSubspace k P₂}
[Nonempty E] [Nonempty F] (hEF : E.map φ ≤ F) : E →ᵃ[k] F := by
refine ⟨?_, ?_, ?_⟩
· exact fun x => ⟨φ x, hEF <| AffineSubspace.mem_map.mpr ⟨x, x.property, rfl⟩⟩
· refine φ.linear.restrict (?_ : E.direction ≤ F.direction.comap φ.linear)
rw [← Submodule.map_le_iff_le_comap, ← AffineSubspace.map_direction]
exact AffineSubspace.direction_le hEF
· intro p v
simp only [Subtype.ext_iff, Subtype.coe_mk, AffineSubspace.coe_vadd]
apply AffineMap.map_vadd
theorem AffineMap.restrict.coe_apply (φ : P₁ →ᵃ[k] P₂) {E : AffineSubspace k P₁}
{F : AffineSubspace k P₂} [Nonempty E] [Nonempty F] (hEF : E.map φ ≤ F) (x : E) :
↑(φ.restrict hEF x) = φ x :=
rfl
theorem AffineMap.restrict.linear_aux {φ : P₁ →ᵃ[k] P₂} {E : AffineSubspace k P₁}
{F : AffineSubspace k P₂} (hEF : E.map φ ≤ F) : E.direction ≤ F.direction.comap φ.linear := by
rw [← Submodule.map_le_iff_le_comap, ← AffineSubspace.map_direction]
exact AffineSubspace.direction_le hEF
theorem AffineMap.restrict.linear (φ : P₁ →ᵃ[k] P₂) {E : AffineSubspace k P₁}
| {F : AffineSubspace k P₂} [Nonempty E] [Nonempty F] (hEF : E.map φ ≤ F) :
(φ.restrict hEF).linear = φ.linear.restrict (AffineMap.restrict.linear_aux hEF) :=
rfl
| Mathlib/LinearAlgebra/AffineSpace/Restrict.lean | 61 | 64 |
/-
Copyright (c) 2022 Yaël Dillies. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies, Yury Kudryashov
-/
import Mathlib.Analysis.Normed.Module.Convex
import Mathlib.Analysis.Normed.Module.Ray
import Mathlib.Analysis.NormedSpace.Pointwise
/-!
# Strictly convex spaces
This file defines strictly convex spaces. A normed space is strictly convex if all closed balls are
strictly convex. This does **not** mean that the norm is strictly convex (in fact, it never is).
## Main definitions
`StrictConvexSpace`: a typeclass saying that a given normed space over a normed linear ordered
field (e.g., `ℝ` or `ℚ`) is strictly convex. The definition requires strict convexity of a closed
ball of positive radius with center at the origin; strict convexity of any other closed ball follows
from this assumption.
## Main results
In a strictly convex space, we prove
- `strictConvex_closedBall`: a closed ball is strictly convex.
- `combo_mem_ball_of_ne`, `openSegment_subset_ball_of_ne`, `norm_combo_lt_of_ne`:
a nontrivial convex combination of two points in a closed ball belong to the corresponding open
ball;
- `norm_add_lt_of_not_sameRay`, `sameRay_iff_norm_add`, `dist_add_dist_eq_iff`:
the triangle inequality `dist x y + dist y z ≤ dist x z` is a strict inequality unless `y` belongs
to the segment `[x -[ℝ] z]`.
- `Isometry.affineIsometryOfStrictConvexSpace`: an isometry of `NormedAddTorsor`s for real
normed spaces, strictly convex in the case of the codomain, is an affine isometry.
We also provide several lemmas that can be used as alternative constructors for `StrictConvex ℝ E`:
- `StrictConvexSpace.of_strictConvex_unitClosedBall`: if `closed_ball (0 : E) 1` is strictly
convex, then `E` is a strictly convex space;
- `StrictConvexSpace.of_norm_add`: if `‖x + y‖ = ‖x‖ + ‖y‖` implies `SameRay ℝ x y` for all
nonzero `x y : E`, then `E` is a strictly convex space.
## Implementation notes
While the definition is formulated for any normed linear ordered field, most of the lemmas are
formulated only for the case `𝕜 = ℝ`.
## Tags
convex, strictly convex
-/
open Convex Pointwise Set Metric
/-- A *strictly convex space* is a normed space where the closed balls are strictly convex. We only
require balls of positive radius with center at the origin to be strictly convex in the definition,
then prove that any closed ball is strictly convex in `strictConvex_closedBall` below.
See also `StrictConvexSpace.of_strictConvex_unitClosedBall`. -/
@[mk_iff]
class StrictConvexSpace (𝕜 E : Type*) [NormedField 𝕜] [PartialOrder 𝕜]
[NormedAddCommGroup E] [NormedSpace 𝕜 E] : Prop where
strictConvex_closedBall : ∀ r : ℝ, 0 < r → StrictConvex 𝕜 (closedBall (0 : E) r)
variable (𝕜 : Type*) {E : Type*} [NormedField 𝕜] [PartialOrder 𝕜]
[NormedAddCommGroup E] [NormedSpace 𝕜 E]
/-- A closed ball in a strictly convex space is strictly convex. -/
theorem strictConvex_closedBall [StrictConvexSpace 𝕜 E] (x : E) (r : ℝ) :
StrictConvex 𝕜 (closedBall x r) := by
rcases le_or_lt r 0 with hr | hr
· exact (subsingleton_closedBall x hr).strictConvex
rw [← vadd_closedBall_zero]
exact (StrictConvexSpace.strictConvex_closedBall r hr).vadd _
variable [NormedSpace ℝ E]
/-- A real normed vector space is strictly convex provided that the unit ball is strictly convex. -/
theorem StrictConvexSpace.of_strictConvex_unitClosedBall [LinearMap.CompatibleSMul E E 𝕜 ℝ]
(h : StrictConvex 𝕜 (closedBall (0 : E) 1)) : StrictConvexSpace 𝕜 E :=
⟨fun r hr => by simpa only [smul_unitClosedBall_of_nonneg hr.le] using h.smul r⟩
@[deprecated (since := "2024-12-01")]
alias StrictConvexSpace.of_strictConvex_closed_unit_ball :=
StrictConvexSpace.of_strictConvex_unitClosedBall
/-- Strict convexity is equivalent to `‖a • x + b • y‖ < 1` for all `x` and `y` of norm at most `1`
and all strictly positive `a` and `b` such that `a + b = 1`. This lemma shows that it suffices to
check this for points of norm one and some `a`, `b` such that `a + b = 1`. -/
theorem StrictConvexSpace.of_norm_combo_lt_one
(h : ∀ x y : E, ‖x‖ = 1 → ‖y‖ = 1 → x ≠ y → ∃ a b : ℝ, a + b = 1 ∧ ‖a • x + b • y‖ < 1) :
StrictConvexSpace ℝ E := by
refine
StrictConvexSpace.of_strictConvex_unitClosedBall ℝ
((convex_closedBall _ _).strictConvex' fun x hx y hy hne => ?_)
rw [interior_closedBall (0 : E) one_ne_zero, closedBall_diff_ball,
mem_sphere_zero_iff_norm] at hx hy
rcases h x y hx hy hne with ⟨a, b, hab, hlt⟩
use b
rwa [AffineMap.lineMap_apply_module, interior_closedBall (0 : E) one_ne_zero, mem_ball_zero_iff,
sub_eq_iff_eq_add.2 hab.symm]
theorem StrictConvexSpace.of_norm_combo_ne_one
(h :
∀ x y : E,
‖x‖ = 1 → ‖y‖ = 1 → x ≠ y → ∃ a b : ℝ, 0 ≤ a ∧ 0 ≤ b ∧ a + b = 1 ∧ ‖a • x + b • y‖ ≠ 1) :
StrictConvexSpace ℝ E := by
refine StrictConvexSpace.of_strictConvex_unitClosedBall ℝ
((convex_closedBall _ _).strictConvex ?_)
simp only [interior_closedBall _ one_ne_zero, closedBall_diff_ball, Set.Pairwise,
frontier_closedBall _ one_ne_zero, mem_sphere_zero_iff_norm]
intro x hx y hy hne
rcases h x y hx hy hne with ⟨a, b, ha, hb, hab, hne'⟩
exact ⟨_, ⟨a, b, ha, hb, hab, rfl⟩, mt mem_sphere_zero_iff_norm.1 hne'⟩
theorem StrictConvexSpace.of_norm_add_ne_two
(h : ∀ ⦃x y : E⦄, ‖x‖ = 1 → ‖y‖ = 1 → x ≠ y → ‖x + y‖ ≠ 2) : StrictConvexSpace ℝ E := by
refine
StrictConvexSpace.of_norm_combo_ne_one fun x y hx hy hne =>
⟨1 / 2, 1 / 2, one_half_pos.le, one_half_pos.le, add_halves _, ?_⟩
| rw [← smul_add, norm_smul, Real.norm_of_nonneg one_half_pos.le, one_div, ← div_eq_inv_mul, Ne,
div_eq_one_iff_eq (two_ne_zero' ℝ)]
exact h hx hy hne
theorem StrictConvexSpace.of_pairwise_sphere_norm_ne_two
(h : (sphere (0 : E) 1).Pairwise fun x y => ‖x + y‖ ≠ 2) : StrictConvexSpace ℝ E :=
StrictConvexSpace.of_norm_add_ne_two fun _ _ hx hy =>
h (mem_sphere_zero_iff_norm.2 hx) (mem_sphere_zero_iff_norm.2 hy)
| Mathlib/Analysis/Convex/StrictConvexSpace.lean | 123 | 130 |
/-
Copyright (c) 2022 Eric Rodriguez. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Eric Rodriguez, Eric Wieser
-/
import Mathlib.Data.List.Chain
/-!
# Destuttering of Lists
This file proves theorems about `List.destutter` (in `Data.List.Defs`), which greedily removes all
non-related items that are adjacent in a list, e.g. `[2, 2, 3, 3, 2].destutter (≠) = [2, 3, 2]`.
Note that we make no guarantees of being the longest sublist with this property; e.g.,
`[123, 1, 2, 5, 543, 1000].destutter (<) = [123, 543, 1000]`, but a longer ascending chain could be
`[1, 2, 5, 543, 1000]`.
## Main statements
* `List.destutter_sublist`: `l.destutter` is a sublist of `l`.
* `List.destutter_is_chain'`: `l.destutter` satisfies `Chain' R`.
* Analogies of these theorems for `List.destutter'`, which is the `destutter` equivalent of `Chain`.
## Tags
adjacent, chain, duplicates, remove, list, stutter, destutter
-/
open Function
variable {α β : Type*} (l l₁ l₂ : List α) (R : α → α → Prop) [DecidableRel R] {a b : α}
variable {R₂ : β → β → Prop} [DecidableRel R₂]
namespace List
@[simp]
theorem destutter'_nil : destutter' R a [] = [a] :=
rfl
theorem destutter'_cons :
(b :: l).destutter' R a = if R a b then a :: destutter' R b l else destutter' R a l :=
rfl
variable {R}
@[simp]
theorem destutter'_cons_pos (h : R b a) : (a :: l).destutter' R b = b :: l.destutter' R a := by
rw [destutter', if_pos h]
@[simp]
theorem destutter'_cons_neg (h : ¬R b a) : (a :: l).destutter' R b = l.destutter' R b := by
rw [destutter', if_neg h]
variable (R)
@[simp]
theorem destutter'_singleton : [b].destutter' R a = if R a b then [a, b] else [a] := by
split_ifs with h <;> simp! [h]
theorem destutter'_sublist (a) : l.destutter' R a <+ a :: l := by
induction' l with b l hl generalizing a
· simp
rw [destutter']
split_ifs
· exact Sublist.cons₂ a (hl b)
· exact (hl a).trans ((l.sublist_cons_self b).cons_cons a)
theorem mem_destutter' (a) : a ∈ l.destutter' R a := by
induction' l with b l hl
· simp
rw [destutter']
split_ifs
· simp
· assumption
theorem destutter'_is_chain : ∀ l : List α, ∀ {a b}, R a b → (l.destutter' R b).Chain R a
| [], _, _, h => chain_singleton.mpr h
| c :: l, a, b, h => by
rw [destutter']
split_ifs with hbc
· rw [chain_cons]
exact ⟨h, destutter'_is_chain l hbc⟩
· exact destutter'_is_chain l h
theorem destutter'_is_chain' (a) : (l.destutter' R a).Chain' R := by
induction' l with b l hl generalizing a
· simp
rw [destutter']
split_ifs with h
· exact destutter'_is_chain R l h
· exact hl a
theorem destutter'_of_chain (h : l.Chain R a) : l.destutter' R a = a :: l := by
induction' l with b l hb generalizing a
· simp
obtain ⟨h, hc⟩ := chain_cons.mp h
rw [l.destutter'_cons_pos h, hb hc]
@[simp]
theorem destutter'_eq_self_iff (a) : l.destutter' R a = a :: l ↔ l.Chain R a :=
⟨fun h => by
suffices Chain' R (a::l) by
assumption
rw [← h]
exact l.destutter'_is_chain' R a, destutter'_of_chain _ _⟩
theorem destutter'_ne_nil : l.destutter' R a ≠ [] :=
ne_nil_of_mem <| l.mem_destutter' R a
@[simp]
theorem destutter_nil : ([] : List α).destutter R = [] :=
rfl
theorem destutter_cons' : (a :: l).destutter R = destutter' R a l :=
rfl
theorem destutter_cons_cons :
(a :: b :: l).destutter R = if R a b then a :: destutter' R b l else destutter' R a l :=
rfl
@[simp]
theorem destutter_singleton : destutter R [a] = [a] :=
rfl
@[simp]
theorem destutter_pair : destutter R [a, b] = if R a b then [a, b] else [a] :=
destutter_cons_cons _ R
theorem destutter_sublist : ∀ l : List α, l.destutter R <+ l
| [] => Sublist.slnil
| h :: l => l.destutter'_sublist R h
theorem destutter_is_chain' : ∀ l : List α, (l.destutter R).Chain' R
| [] => List.chain'_nil
| h :: l => l.destutter'_is_chain' R h
theorem destutter_of_chain' : ∀ l : List α, l.Chain' R → l.destutter R = l
| [], _ => rfl
| _ :: l, h => l.destutter'_of_chain _ h
@[simp]
theorem destutter_eq_self_iff : ∀ l : List α, l.destutter R = l ↔ l.Chain' R
| [] => by simp
| a :: l => l.destutter'_eq_self_iff R a
theorem destutter_idem : (l.destutter R).destutter R = l.destutter R :=
destutter_of_chain' R _ <| l.destutter_is_chain' R
@[simp]
theorem destutter_eq_nil : ∀ {l : List α}, destutter R l = [] ↔ l = []
| [] => Iff.rfl
| _ :: l => ⟨fun h => absurd h <| l.destutter'_ne_nil R, fun h => nomatch h⟩
variable {R}
/-- For a relation-preserving map, `destutter` commutes with `map`. -/
theorem map_destutter {f : α → β} : ∀ {l : List α}, (∀ a ∈ l, ∀ b ∈ l, R a b ↔ R₂ (f a) (f b)) →
(l.destutter R).map f = (l.map f).destutter R₂
| [], hl => by simp
| [a], hl => by simp
| | a :: b :: l, hl => by
have := hl a (by simp) b (by simp)
simp_rw [map_cons, destutter_cons_cons, ← this]
| Mathlib/Data/List/Destutter.lean | 161 | 163 |
/-
Copyright (c) 2015 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Robert Y. Lewis, Yury Kudryashov
-/
import Mathlib.Algebra.Order.Monoid.Unbundled.Basic
import Mathlib.Algebra.Order.Monoid.Unbundled.OrderDual
import Mathlib.Tactic.Lift
import Mathlib.Tactic.Monotonicity.Attr
/-!
# Lemmas about the interaction of power operations with order in terms of `CovariantClass`
-/
open Function
variable {β G M : Type*}
section Monoid
variable [Monoid M]
section Preorder
variable [Preorder M]
namespace Left
variable [MulLeftMono M] {a : M}
| @[to_additive Left.nsmul_nonneg]
theorem one_le_pow_of_le (ha : 1 ≤ a) : ∀ n : ℕ, 1 ≤ a ^ n
| 0 => by simp
| k + 1 => by
rw [pow_succ]
exact one_le_mul (one_le_pow_of_le ha k) ha
| Mathlib/Algebra/Order/Monoid/Unbundled/Pow.lean | 31 | 36 |
/-
Copyright (c) 2018 Kenny Lau. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kenny Lau, Chris Hughes, Mario Carneiro
-/
import Mathlib.Algebra.Field.IsField
import Mathlib.Data.Fin.VecNotation
import Mathlib.Data.Nat.Choose.Sum
import Mathlib.LinearAlgebra.Finsupp.LinearCombination
import Mathlib.RingTheory.Ideal.Maximal
import Mathlib.Tactic.FinCases
/-!
# Ideals over a ring
This file contains an assortment of definitions and results for `Ideal R`,
the type of (left) ideals over a ring `R`.
Note that over commutative rings, left ideals and two-sided ideals are equivalent.
## Implementation notes
`Ideal R` is implemented using `Submodule R R`, where `•` is interpreted as `*`.
## TODO
Support right ideals, and two-sided ideals over non-commutative rings.
-/
variable {ι α β F : Type*}
open Set Function
open Pointwise
section Semiring
namespace Ideal
variable {α : ι → Type*} [Π i, Semiring (α i)] (I : Π i, Ideal (α i))
section Pi
/-- `Πᵢ Iᵢ` as an ideal of `Πᵢ Rᵢ`. -/
def pi : Ideal (Π i, α i) where
carrier := { x | ∀ i, x i ∈ I i }
zero_mem' i := (I i).zero_mem
add_mem' ha hb i := (I i).add_mem (ha i) (hb i)
smul_mem' a _b hb i := (I i).mul_mem_left (a i) (hb i)
theorem mem_pi (x : Π i, α i) : x ∈ pi I ↔ ∀ i, x i ∈ I i :=
Iff.rfl
instance (priority := low) [∀ i, (I i).IsTwoSided] : (pi I).IsTwoSided :=
⟨fun _b hb i ↦ mul_mem_right _ _ (hb i)⟩
end Pi
section Commute
variable {α : Type*} [Semiring α] (I : Ideal α) {a b : α}
theorem add_pow_mem_of_pow_mem_of_le_of_commute {m n k : ℕ}
(ha : a ^ m ∈ I) (hb : b ^ n ∈ I) (hk : m + n ≤ k + 1)
(hab : Commute a b) :
(a + b) ^ k ∈ I := by
simp_rw [hab.add_pow, ← Nat.cast_comm]
apply I.sum_mem
intro c _
apply mul_mem_left
by_cases h : m ≤ c
· rw [hab.pow_pow]
exact I.mul_mem_left _ (I.pow_mem_of_pow_mem ha h)
· refine I.mul_mem_left _ (I.pow_mem_of_pow_mem hb ?_)
omega
theorem add_pow_add_pred_mem_of_pow_mem_of_commute {m n : ℕ}
(ha : a ^ m ∈ I) (hb : b ^ n ∈ I) (hab : Commute a b) :
(a + b) ^ (m + n - 1) ∈ I :=
I.add_pow_mem_of_pow_mem_of_le_of_commute ha hb (by rw [← Nat.sub_le_iff_le_add]) hab
end Commute
end Ideal
end Semiring
section CommSemiring
variable {a b : α}
-- A separate namespace definition is needed because the variables were historically in a different
-- order.
namespace Ideal
variable [CommSemiring α] (I : Ideal α)
theorem add_pow_mem_of_pow_mem_of_le {m n k : ℕ}
(ha : a ^ m ∈ I) (hb : b ^ n ∈ I) (hk : m + n ≤ k + 1) :
(a + b) ^ k ∈ I :=
I.add_pow_mem_of_pow_mem_of_le_of_commute ha hb hk (Commute.all ..)
theorem add_pow_add_pred_mem_of_pow_mem {m n : ℕ}
(ha : a ^ m ∈ I) (hb : b ^ n ∈ I) :
(a + b) ^ (m + n - 1) ∈ I :=
I.add_pow_add_pred_mem_of_pow_mem_of_commute ha hb (Commute.all ..)
theorem pow_multiset_sum_mem_span_pow [DecidableEq α] (s : Multiset α) (n : ℕ) :
s.sum ^ (Multiset.card s * n + 1) ∈
span ((s.map fun (x : α) ↦ x ^ (n + 1)).toFinset : Set α) := by
induction' s using Multiset.induction_on with a s hs
· simp
simp only [Finset.coe_insert, Multiset.map_cons, Multiset.toFinset_cons, Multiset.sum_cons,
Multiset.card_cons, add_pow]
refine Submodule.sum_mem _ ?_
intro c _hc
rw [mem_span_insert]
by_cases h : n + 1 ≤ c
· refine ⟨a ^ (c - (n + 1)) * s.sum ^ ((Multiset.card s + 1) * n + 1 - c) *
((Multiset.card s + 1) * n + 1).choose c, 0, Submodule.zero_mem _, ?_⟩
rw [mul_comm _ (a ^ (n + 1))]
simp_rw [← mul_assoc]
rw [← pow_add, add_zero, add_tsub_cancel_of_le h]
· use 0
simp_rw [zero_mul, zero_add]
refine ⟨_, ?_, rfl⟩
replace h : c ≤ n := Nat.lt_succ_iff.mp (not_le.mp h)
have : (Multiset.card s + 1) * n + 1 - c = Multiset.card s * n + 1 + (n - c) := by
rw [add_mul, one_mul, add_assoc, add_comm n 1, ← add_assoc, add_tsub_assoc_of_le h]
rw [this, pow_add]
simp_rw [mul_assoc, mul_comm (s.sum ^ (Multiset.card s * n + 1)), ← mul_assoc]
exact mul_mem_left _ _ hs
theorem sum_pow_mem_span_pow {ι} (s : Finset ι) (f : ι → α) (n : ℕ) :
(∑ i ∈ s, f i) ^ (s.card * n + 1) ∈ span ((fun i => f i ^ (n + 1)) '' s) := by
classical
simpa only [Multiset.card_map, Multiset.map_map, comp_apply, Multiset.toFinset_map,
Finset.coe_image, Finset.val_toFinset] using pow_multiset_sum_mem_span_pow (s.1.map f) n
theorem span_pow_eq_top (s : Set α) (hs : span s = ⊤) (n : ℕ) :
span ((fun (x : α) => x ^ n) '' s) = ⊤ := by
rw [eq_top_iff_one]
rcases n with - | n
· obtain rfl | ⟨x, hx⟩ := eq_empty_or_nonempty s
· rw [Set.image_empty, hs]
trivial
· exact subset_span ⟨_, hx, pow_zero _⟩
rw [eq_top_iff_one, span, Finsupp.mem_span_iff_linearCombination] at hs
rcases hs with ⟨f, hf⟩
have hf : (f.support.sum fun a => f a * a) = 1 := hf -- Porting note: was `change ... at hf`
have := sum_pow_mem_span_pow f.support (fun a => f a * a) n
rw [hf, one_pow] at this
refine span_le.mpr ?_ this
rintro _ hx
simp_rw [Set.mem_image] at hx
rcases hx with ⟨x, _, rfl⟩
have : span ({(x : α) ^ (n + 1)} : Set α) ≤ span ((fun x : α => x ^ (n + 1)) '' s) := by
rw [span_le, Set.singleton_subset_iff]
exact subset_span ⟨x, x.prop, rfl⟩
refine this ?_
rw [mul_pow, mem_span_singleton]
exact ⟨f x ^ (n + 1), mul_comm _ _⟩
theorem span_range_pow_eq_top (s : Set α) (hs : span s = ⊤) (n : s → ℕ) :
span (Set.range fun x ↦ x.1 ^ n x) = ⊤ := by
have ⟨t, hts, mem⟩ := Submodule.mem_span_finite_of_mem_span ((eq_top_iff_one _).mp hs)
refine top_unique ((span_pow_eq_top _ ((eq_top_iff_one _).mpr mem) <|
t.attach.sup fun x ↦ n ⟨x, hts x.2⟩).ge.trans <| span_le.mpr ?_)
rintro _ ⟨x, hxt, rfl⟩
rw [← Nat.sub_add_cancel (Finset.le_sup <| t.mem_attach ⟨x, hxt⟩)]
simp_rw [pow_add]
exact mul_mem_left _ _ (subset_span ⟨_, rfl⟩)
theorem prod_mem {ι : Type*} {f : ι → α} {s : Finset ι}
(I : Ideal α) {i : ι} (hi : i ∈ s) (hfi : f i ∈ I) :
∏ i ∈ s, f i ∈ I := by
classical
rw [Finset.prod_eq_prod_diff_singleton_mul hi]
exact Ideal.mul_mem_left _ _ hfi
end Ideal
end CommSemiring
section DivisionSemiring
variable {K : Type*} [DivisionSemiring K] (I : Ideal K)
namespace Ideal
variable (K) in
/-- A bijection between (left) ideals of a division ring and `{0, 1}`, sending `⊥` to `0`
and `⊤` to `1`. -/
def equivFinTwo [DecidableEq (Ideal K)] : Ideal K ≃ Fin 2 where
toFun := fun I ↦ if I = ⊥ then 0 else 1
invFun := ![⊥, ⊤]
left_inv := fun I ↦ by rcases eq_bot_or_top I with rfl | rfl <;> simp
right_inv := fun i ↦ by fin_cases i <;> simp
instance : Finite (Ideal K) := let _i := Classical.decEq (Ideal K); ⟨equivFinTwo K⟩
/-- Ideals of a `DivisionSemiring` are a simple order. Thanks to the way abbreviations work,
this automatically gives an `IsSimpleModule K` instance. -/
instance isSimpleOrder : IsSimpleOrder (Ideal K) :=
⟨eq_bot_or_top⟩
end Ideal
end DivisionSemiring
-- TODO: consider moving the lemmas below out of the `Ring` namespace since they are
-- about `CommSemiring`s.
namespace Ring
variable {R : Type*} [CommSemiring R]
theorem exists_not_isUnit_of_not_isField [Nontrivial R] (hf : ¬IsField R) :
∃ (x : R) (_hx : x ≠ (0 : R)), ¬IsUnit x := by
have : ¬_ := fun h => hf ⟨exists_pair_ne R, mul_comm, h⟩
simp_rw [isUnit_iff_exists_inv]
push_neg at this ⊢
obtain ⟨x, hx, not_unit⟩ := this
exact ⟨x, hx, not_unit⟩
theorem not_isField_iff_exists_ideal_bot_lt_and_lt_top [Nontrivial R] :
¬IsField R ↔ ∃ I : Ideal R, ⊥ < I ∧ I < ⊤ := by
constructor
· intro h
obtain ⟨x, nz, nu⟩ := exists_not_isUnit_of_not_isField h
use Ideal.span {x}
rw [bot_lt_iff_ne_bot, lt_top_iff_ne_top]
exact ⟨mt Ideal.span_singleton_eq_bot.mp nz, mt Ideal.span_singleton_eq_top.mp nu⟩
· rintro ⟨I, bot_lt, lt_top⟩ hf
obtain ⟨x, mem, ne_zero⟩ := SetLike.exists_of_lt bot_lt
rw [Submodule.mem_bot] at ne_zero
obtain ⟨y, hy⟩ := hf.mul_inv_cancel ne_zero
rw [lt_top_iff_ne_top, Ne, Ideal.eq_top_iff_one, ← hy] at lt_top
exact lt_top (I.mul_mem_right _ mem)
theorem not_isField_iff_exists_prime [Nontrivial R] :
¬IsField R ↔ ∃ p : Ideal R, p ≠ ⊥ ∧ p.IsPrime :=
not_isField_iff_exists_ideal_bot_lt_and_lt_top.trans
⟨fun ⟨I, bot_lt, lt_top⟩ =>
let ⟨p, hp, le_p⟩ := I.exists_le_maximal (lt_top_iff_ne_top.mp lt_top)
⟨p, bot_lt_iff_ne_bot.mp (lt_of_lt_of_le bot_lt le_p), hp.isPrime⟩,
fun ⟨p, ne_bot, Prime⟩ => ⟨p, bot_lt_iff_ne_bot.mpr ne_bot, lt_top_iff_ne_top.mpr Prime.1⟩⟩
/-- Also see `Ideal.isSimpleOrder` for the forward direction as an instance when `R` is a
division (semi)ring.
This result actually holds for all division semirings, but we lack the predicate to state it. -/
theorem isField_iff_isSimpleOrder_ideal : IsField R ↔ IsSimpleOrder (Ideal R) := by
cases subsingleton_or_nontrivial R
· exact
⟨fun h => (not_isField_of_subsingleton _ h).elim, fun h =>
(false_of_nontrivial_of_subsingleton <| Ideal R).elim⟩
rw [← not_iff_not, Ring.not_isField_iff_exists_ideal_bot_lt_and_lt_top, ← not_iff_not]
push_neg
simp_rw [lt_top_iff_ne_top, bot_lt_iff_ne_bot, ← or_iff_not_imp_left, not_ne_iff]
exact ⟨fun h => ⟨h⟩, fun h => h.2⟩
/-- When a ring is not a field, the maximal ideals are nontrivial. -/
theorem ne_bot_of_isMaximal_of_not_isField [Nontrivial R] {M : Ideal R} (max : M.IsMaximal)
(not_field : ¬IsField R) : M ≠ ⊥ := by
rintro h
rw [h] at max
rcases max with ⟨⟨_h1, h2⟩⟩
obtain ⟨I, hIbot, hItop⟩ := not_isField_iff_exists_ideal_bot_lt_and_lt_top.mp not_field
exact ne_of_lt hItop (h2 I hIbot)
end Ring
namespace Ideal
variable {R : Type*} [CommSemiring R] [Nontrivial R]
theorem bot_lt_of_maximal (M : Ideal R) [hm : M.IsMaximal] (non_field : ¬IsField R) : ⊥ < M := by
rcases Ring.not_isField_iff_exists_ideal_bot_lt_and_lt_top.1 non_field with ⟨I, Ibot, Itop⟩
constructor; · simp
intro mle
apply lt_irrefl (⊤ : Ideal R)
have : M = ⊥ := eq_bot_iff.mpr mle
rw [← this] at Ibot
rwa [hm.1.2 I Ibot] at Itop
end Ideal
| Mathlib/RingTheory/Ideal/Basic.lean | 603 | 606 | |
/-
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.Computability.Partrec
import Mathlib.Data.Option.Basic
/-!
# Gödel Numbering for Partial Recursive Functions.
This file defines `Nat.Partrec.Code`, an inductive datatype describing code for partial
recursive functions on ℕ. It defines an encoding for these codes, and proves that the constructors
are primitive recursive with respect to the encoding.
It also defines the evaluation of these codes as partial functions using `PFun`, and proves that a
function is partially recursive (as defined by `Nat.Partrec`) if and only if it is the evaluation
of some code.
## Main Definitions
* `Nat.Partrec.Code`: Inductive datatype for partial recursive codes.
* `Nat.Partrec.Code.encodeCode`: A (computable) encoding of codes as natural numbers.
* `Nat.Partrec.Code.ofNatCode`: The inverse of this encoding.
* `Nat.Partrec.Code.eval`: The interpretation of a `Nat.Partrec.Code` as a partial function.
## Main Results
* `Nat.Partrec.Code.rec_prim`: Recursion on `Nat.Partrec.Code` is primitive recursive.
* `Nat.Partrec.Code.rec_computable`: Recursion on `Nat.Partrec.Code` is computable.
* `Nat.Partrec.Code.smn`: The $S_n^m$ theorem.
* `Nat.Partrec.Code.exists_code`: Partial recursiveness is equivalent to being the eval of a code.
* `Nat.Partrec.Code.evaln_prim`: `evaln` is primitive recursive.
* `Nat.Partrec.Code.fixed_point`: Roger's fixed point theorem.
* `Nat.Partrec.Code.fixed_point₂`: Kleene's second recursion theorem.
## References
* [Mario Carneiro, *Formalizing computability theory via partial recursive functions*][carneiro2019]
-/
open Encodable Denumerable
namespace Nat.Partrec
theorem rfind' {f} (hf : Nat.Partrec f) :
Nat.Partrec
(Nat.unpaired fun a m =>
(Nat.rfind fun n => (fun m => m = 0) <$> f (Nat.pair a (n + m))).map (· + m)) :=
Partrec₂.unpaired'.2 <| by
refine
Partrec.map
((@Partrec₂.unpaired' fun a b : ℕ =>
Nat.rfind fun n => (fun m => m = 0) <$> f (Nat.pair a (n + b))).1
?_)
(Primrec.nat_add.comp Primrec.snd <| Primrec.snd.comp Primrec.fst).to_comp.to₂
have : Nat.Partrec (fun a => Nat.rfind (fun n => (fun m => decide (m = 0)) <$>
Nat.unpaired (fun a b => f (Nat.pair (Nat.unpair a).1 (b + (Nat.unpair a).2)))
(Nat.pair a n))) :=
rfind
(Partrec₂.unpaired'.2
((Partrec.nat_iff.2 hf).comp
(Primrec₂.pair.comp (Primrec.fst.comp <| Primrec.unpair.comp Primrec.fst)
(Primrec.nat_add.comp Primrec.snd
(Primrec.snd.comp <| Primrec.unpair.comp Primrec.fst))).to_comp))
simpa
/-- Code for partial recursive functions from ℕ to ℕ.
See `Nat.Partrec.Code.eval` for the interpretation of these constructors.
-/
inductive Code : Type
| zero : Code
| succ : Code
| left : Code
| right : Code
| pair : Code → Code → Code
| comp : Code → Code → Code
| prec : Code → Code → Code
| rfind' : Code → Code
compile_inductive% Code
end Nat.Partrec
namespace Nat.Partrec.Code
instance instInhabited : Inhabited Code :=
⟨zero⟩
/-- Returns a code for the constant function outputting a particular natural. -/
protected def const : ℕ → Code
| 0 => zero
| n + 1 => comp succ (Code.const n)
theorem const_inj : ∀ {n₁ n₂}, Nat.Partrec.Code.const n₁ = Nat.Partrec.Code.const n₂ → n₁ = n₂
| 0, 0, _ => by simp
| n₁ + 1, n₂ + 1, h => by
dsimp [Nat.Partrec.Code.const] at h
injection h with h₁ h₂
simp only [const_inj h₂]
/-- A code for the identity function. -/
protected def id : Code :=
pair left right
/-- Given a code `c` taking a pair as input, returns a code using `n` as the first argument to `c`.
-/
def curry (c : Code) (n : ℕ) : Code :=
comp c (pair (Code.const n) Code.id)
/-- An encoding of a `Nat.Partrec.Code` as a ℕ. -/
def encodeCode : Code → ℕ
| zero => 0
| succ => 1
| left => 2
| right => 3
| pair cf cg => 2 * (2 * Nat.pair (encodeCode cf) (encodeCode cg)) + 4
| comp cf cg => 2 * (2 * Nat.pair (encodeCode cf) (encodeCode cg) + 1) + 4
| prec cf cg => (2 * (2 * Nat.pair (encodeCode cf) (encodeCode cg)) + 1) + 4
| rfind' cf => (2 * (2 * encodeCode cf + 1) + 1) + 4
/--
A decoder for `Nat.Partrec.Code.encodeCode`, taking any ℕ to the `Nat.Partrec.Code` it represents.
-/
def ofNatCode : ℕ → Code
| 0 => zero
| 1 => succ
| 2 => left
| 3 => right
| n + 4 =>
let m := n.div2.div2
have hm : m < n + 4 := by
simp only [m, div2_val]
exact
lt_of_le_of_lt (le_trans (Nat.div_le_self _ _) (Nat.div_le_self _ _))
(Nat.succ_le_succ (Nat.le_add_right _ _))
have _m1 : m.unpair.1 < n + 4 := lt_of_le_of_lt m.unpair_left_le hm
have _m2 : m.unpair.2 < n + 4 := lt_of_le_of_lt m.unpair_right_le hm
match n.bodd, n.div2.bodd with
| false, false => pair (ofNatCode m.unpair.1) (ofNatCode m.unpair.2)
| false, true => comp (ofNatCode m.unpair.1) (ofNatCode m.unpair.2)
| true , false => prec (ofNatCode m.unpair.1) (ofNatCode m.unpair.2)
| true , true => rfind' (ofNatCode m)
/-- Proof that `Nat.Partrec.Code.ofNatCode` is the inverse of `Nat.Partrec.Code.encodeCode` -/
private theorem encode_ofNatCode : ∀ n, encodeCode (ofNatCode n) = n
| 0 => by simp [ofNatCode, encodeCode]
| 1 => by simp [ofNatCode, encodeCode]
| 2 => by simp [ofNatCode, encodeCode]
| 3 => by simp [ofNatCode, encodeCode]
| n + 4 => by
let m := n.div2.div2
have hm : m < n + 4 := by
simp only [m, div2_val]
exact
lt_of_le_of_lt (le_trans (Nat.div_le_self _ _) (Nat.div_le_self _ _))
(Nat.succ_le_succ (Nat.le_add_right _ _))
have _m1 : m.unpair.1 < n + 4 := lt_of_le_of_lt m.unpair_left_le hm
have _m2 : m.unpair.2 < n + 4 := lt_of_le_of_lt m.unpair_right_le hm
have IH := encode_ofNatCode m
have IH1 := encode_ofNatCode m.unpair.1
have IH2 := encode_ofNatCode m.unpair.2
conv_rhs => rw [← Nat.bit_decomp n, ← Nat.bit_decomp n.div2]
simp only [ofNatCode.eq_5]
cases n.bodd <;> cases n.div2.bodd <;>
simp [m, encodeCode, ofNatCode, IH, IH1, IH2, Nat.bit_val]
instance instDenumerable : Denumerable Code :=
mk'
⟨encodeCode, ofNatCode, fun c => by
induction c <;> simp [encodeCode, ofNatCode, Nat.div2_val, *],
encode_ofNatCode⟩
theorem encodeCode_eq : encode = encodeCode :=
rfl
theorem ofNatCode_eq : ofNat Code = ofNatCode :=
rfl
theorem encode_lt_pair (cf cg) :
encode cf < encode (pair cf cg) ∧ encode cg < encode (pair cf cg) := by
simp only [encodeCode_eq, encodeCode]
have := Nat.mul_le_mul_right (Nat.pair cf.encodeCode cg.encodeCode) (by decide : 1 ≤ 2 * 2)
rw [one_mul, mul_assoc] at this
have := lt_of_le_of_lt this (lt_add_of_pos_right _ (by decide : 0 < 4))
exact ⟨lt_of_le_of_lt (Nat.left_le_pair _ _) this, lt_of_le_of_lt (Nat.right_le_pair _ _) this⟩
theorem encode_lt_comp (cf cg) :
encode cf < encode (comp cf cg) ∧ encode cg < encode (comp cf cg) := by
have : encode (pair cf cg) < encode (comp cf cg) := by simp [encodeCode_eq, encodeCode]
exact (encode_lt_pair cf cg).imp (fun h => lt_trans h this) fun h => lt_trans h this
theorem encode_lt_prec (cf cg) :
encode cf < encode (prec cf cg) ∧ encode cg < encode (prec cf cg) := by
have : encode (pair cf cg) < encode (prec cf cg) := by simp [encodeCode_eq, encodeCode]
exact (encode_lt_pair cf cg).imp (fun h => lt_trans h this) fun h => lt_trans h this
theorem encode_lt_rfind' (cf) : encode cf < encode (rfind' cf) := by
simp only [encodeCode_eq, encodeCode]
omega
end Nat.Partrec.Code
section
open Primrec
namespace Nat.Partrec.Code
theorem pair_prim : Primrec₂ pair :=
Primrec₂.ofNat_iff.2 <|
Primrec₂.encode_iff.1 <|
nat_add.comp
(nat_double.comp <|
nat_double.comp <|
Primrec₂.natPair.comp (encode_iff.2 <| (Primrec.ofNat Code).comp fst)
(encode_iff.2 <| (Primrec.ofNat Code).comp snd))
(Primrec₂.const 4)
theorem comp_prim : Primrec₂ comp :=
Primrec₂.ofNat_iff.2 <|
Primrec₂.encode_iff.1 <|
nat_add.comp
(nat_double.comp <|
nat_double_succ.comp <|
Primrec₂.natPair.comp (encode_iff.2 <| (Primrec.ofNat Code).comp fst)
(encode_iff.2 <| (Primrec.ofNat Code).comp snd))
(Primrec₂.const 4)
theorem prec_prim : Primrec₂ prec :=
Primrec₂.ofNat_iff.2 <|
Primrec₂.encode_iff.1 <|
nat_add.comp
(nat_double_succ.comp <|
nat_double.comp <|
Primrec₂.natPair.comp (encode_iff.2 <| (Primrec.ofNat Code).comp fst)
(encode_iff.2 <| (Primrec.ofNat Code).comp snd))
(Primrec₂.const 4)
theorem rfind_prim : Primrec rfind' :=
ofNat_iff.2 <|
encode_iff.1 <|
nat_add.comp
(nat_double_succ.comp <| nat_double_succ.comp <|
encode_iff.2 <| Primrec.ofNat Code)
(const 4)
theorem rec_prim' {α σ} [Primcodable α] [Primcodable σ] {c : α → Code} (hc : Primrec c) {z : α → σ}
(hz : Primrec z) {s : α → σ} (hs : Primrec s) {l : α → σ} (hl : Primrec l) {r : α → σ}
(hr : Primrec r) {pr : α → Code × Code × σ × σ → σ} (hpr : Primrec₂ pr)
{co : α → Code × Code × σ × σ → σ} (hco : Primrec₂ co) {pc : α → Code × Code × σ × σ → σ}
(hpc : Primrec₂ pc) {rf : α → Code × σ → σ} (hrf : Primrec₂ rf) :
let PR (a) cf cg hf hg := pr a (cf, cg, hf, hg)
let CO (a) cf cg hf hg := co a (cf, cg, hf, hg)
let PC (a) cf cg hf hg := pc a (cf, cg, hf, hg)
let RF (a) cf hf := rf a (cf, hf)
let F (a : α) (c : Code) : σ :=
Nat.Partrec.Code.recOn c (z a) (s a) (l a) (r a) (PR a) (CO a) (PC a) (RF a)
Primrec (fun a => F a (c a) : α → σ) := by
intros _ _ _ _ F
let G₁ : (α × List σ) × ℕ × ℕ → Option σ := fun p =>
letI a := p.1.1; letI IH := p.1.2; letI n := p.2.1; letI m := p.2.2
IH[m]?.bind fun s =>
IH[m.unpair.1]?.bind fun s₁ =>
IH[m.unpair.2]?.map fun s₂ =>
cond n.bodd
(cond n.div2.bodd (rf a (ofNat Code m, s))
(pc a (ofNat Code m.unpair.1, ofNat Code m.unpair.2, s₁, s₂)))
(cond n.div2.bodd (co a (ofNat Code m.unpair.1, ofNat Code m.unpair.2, s₁, s₂))
(pr a (ofNat Code m.unpair.1, ofNat Code m.unpair.2, s₁, s₂)))
have : Primrec G₁ :=
option_bind (list_getElem?.comp (snd.comp fst) (snd.comp snd)) <| .mk <|
option_bind ((list_getElem?.comp (snd.comp fst)
(fst.comp <| Primrec.unpair.comp (snd.comp snd))).comp fst) <| .mk <|
option_map ((list_getElem?.comp (snd.comp fst)
(snd.comp <| Primrec.unpair.comp (snd.comp snd))).comp <| fst.comp fst) <| .mk <|
have a := fst.comp (fst.comp <| fst.comp <| fst.comp fst)
have n := fst.comp (snd.comp <| fst.comp <| fst.comp fst)
have m := snd.comp (snd.comp <| fst.comp <| fst.comp fst)
have m₁ := fst.comp (Primrec.unpair.comp m)
have m₂ := snd.comp (Primrec.unpair.comp m)
have s := snd.comp (fst.comp fst)
have s₁ := snd.comp fst
have s₂ := snd
(nat_bodd.comp n).cond
((nat_bodd.comp <| nat_div2.comp n).cond
(hrf.comp a (((Primrec.ofNat Code).comp m).pair s))
(hpc.comp a (((Primrec.ofNat Code).comp m₁).pair <|
((Primrec.ofNat Code).comp m₂).pair <| s₁.pair s₂)))
(Primrec.cond (nat_bodd.comp <| nat_div2.comp n)
(hco.comp a (((Primrec.ofNat Code).comp m₁).pair <|
((Primrec.ofNat Code).comp m₂).pair <| s₁.pair s₂))
(hpr.comp a (((Primrec.ofNat Code).comp m₁).pair <|
((Primrec.ofNat Code).comp m₂).pair <| s₁.pair s₂)))
let G : α → List σ → Option σ := fun a IH =>
IH.length.casesOn (some (z a)) fun n =>
n.casesOn (some (s a)) fun n =>
n.casesOn (some (l a)) fun n =>
n.casesOn (some (r a)) fun n =>
G₁ ((a, IH), n, n.div2.div2)
have : Primrec₂ G := .mk <|
nat_casesOn (list_length.comp snd) (option_some_iff.2 (hz.comp fst)) <| .mk <|
nat_casesOn snd (option_some_iff.2 (hs.comp (fst.comp fst))) <| .mk <|
nat_casesOn snd (option_some_iff.2 (hl.comp (fst.comp <| fst.comp fst))) <| .mk <|
nat_casesOn snd (option_some_iff.2 (hr.comp (fst.comp <| fst.comp <| fst.comp fst))) <| .mk <|
this.comp <|
((fst.pair snd).comp <| fst.comp <| fst.comp <| fst.comp <| fst).pair <|
snd.pair <| nat_div2.comp <| nat_div2.comp snd
refine (nat_strong_rec (fun a n => F a (ofNat Code n)) this.to₂ fun a n => ?_)
|>.comp .id (encode_iff.2 hc) |>.of_eq fun a => by simp
iterate 4 rcases n with - | n; · simp [ofNatCode_eq, ofNatCode]; rfl
simp only [G]; rw [List.length_map, List.length_range]
let m := n.div2.div2
show G₁ ((a, (List.range (n + 4)).map fun n => F a (ofNat Code n)), n, m)
= some (F a (ofNat Code (n + 4)))
have hm : m < n + 4 := by
simp only [m, div2_val]
exact lt_of_le_of_lt
(le_trans (Nat.div_le_self ..) (Nat.div_le_self ..))
(Nat.succ_le_succ (Nat.le_add_right ..))
have m1 : m.unpair.1 < n + 4 := lt_of_le_of_lt m.unpair_left_le hm
have m2 : m.unpair.2 < n + 4 := lt_of_le_of_lt m.unpair_right_le hm
simp [G₁, m, List.getElem?_map, List.getElem?_range, hm, m1, m2]
rw [show ofNat Code (n + 4) = ofNatCode (n + 4) from rfl]
simp [ofNatCode]
cases n.bodd <;> cases n.div2.bodd <;> rfl
/-- Recursion on `Nat.Partrec.Code` is primitive recursive. -/
theorem rec_prim {α σ} [Primcodable α] [Primcodable σ] {c : α → Code} (hc : Primrec c) {z : α → σ}
(hz : Primrec z) {s : α → σ} (hs : Primrec s) {l : α → σ} (hl : Primrec l) {r : α → σ}
(hr : Primrec r) {pr : α → Code → Code → σ → σ → σ}
(hpr : Primrec fun a : α × Code × Code × σ × σ => pr a.1 a.2.1 a.2.2.1 a.2.2.2.1 a.2.2.2.2)
{co : α → Code → Code → σ → σ → σ}
(hco : Primrec fun a : α × Code × Code × σ × σ => co a.1 a.2.1 a.2.2.1 a.2.2.2.1 a.2.2.2.2)
{pc : α → Code → Code → σ → σ → σ}
(hpc : Primrec fun a : α × Code × Code × σ × σ => pc a.1 a.2.1 a.2.2.1 a.2.2.2.1 a.2.2.2.2)
{rf : α → Code → σ → σ} (hrf : Primrec fun a : α × Code × σ => rf a.1 a.2.1 a.2.2) :
let F (a : α) (c : Code) : σ :=
Nat.Partrec.Code.recOn c (z a) (s a) (l a) (r a) (pr a) (co a) (pc a) (rf a)
Primrec fun a => F a (c a) :=
rec_prim' hc hz hs hl hr
(pr := fun a b => pr a b.1 b.2.1 b.2.2.1 b.2.2.2) (.mk hpr)
(co := fun a b => co a b.1 b.2.1 b.2.2.1 b.2.2.2) (.mk hco)
(pc := fun a b => pc a b.1 b.2.1 b.2.2.1 b.2.2.2) (.mk hpc)
(rf := fun a b => rf a b.1 b.2) (.mk hrf)
end Nat.Partrec.Code
end
namespace Nat.Partrec.Code
section
open Computable
/-- Recursion on `Nat.Partrec.Code` is computable. -/
theorem rec_computable {α σ} [Primcodable α] [Primcodable σ] {c : α → Code} (hc : Computable c)
{z : α → σ} (hz : Computable z) {s : α → σ} (hs : Computable s) {l : α → σ} (hl : Computable l)
{r : α → σ} (hr : Computable r) {pr : α → Code × Code × σ × σ → σ} (hpr : Computable₂ pr)
{co : α → Code × Code × σ × σ → σ} (hco : Computable₂ co) {pc : α → Code × Code × σ × σ → σ}
(hpc : Computable₂ pc) {rf : α → Code × σ → σ} (hrf : Computable₂ rf) :
let PR (a) cf cg hf hg := pr a (cf, cg, hf, hg)
let CO (a) cf cg hf hg := co a (cf, cg, hf, hg)
let PC (a) cf cg hf hg := pc a (cf, cg, hf, hg)
let RF (a) cf hf := rf a (cf, hf)
let F (a : α) (c : Code) : σ :=
Nat.Partrec.Code.recOn c (z a) (s a) (l a) (r a) (PR a) (CO a) (PC a) (RF a)
Computable fun a => F a (c a) := by
-- TODO(Mario): less copy-paste from previous proof
intros _ _ _ _ F
let G₁ : (α × List σ) × ℕ × ℕ → Option σ := fun p =>
letI a := p.1.1; letI IH := p.1.2; letI n := p.2.1; letI m := p.2.2
IH[m]?.bind fun s =>
IH[m.unpair.1]?.bind fun s₁ =>
IH[m.unpair.2]?.map fun s₂ =>
cond n.bodd
(cond n.div2.bodd (rf a (ofNat Code m, s))
(pc a (ofNat Code m.unpair.1, ofNat Code m.unpair.2, s₁, s₂)))
(cond n.div2.bodd (co a (ofNat Code m.unpair.1, ofNat Code m.unpair.2, s₁, s₂))
(pr a (ofNat Code m.unpair.1, ofNat Code m.unpair.2, s₁, s₂)))
have : Computable G₁ := by
refine option_bind (list_getElem?.comp (snd.comp fst) (snd.comp snd)) <| .mk ?_
refine option_bind ((list_getElem?.comp (snd.comp fst)
(fst.comp <| Computable.unpair.comp (snd.comp snd))).comp fst) <| .mk ?_
refine option_map ((list_getElem?.comp (snd.comp fst)
(snd.comp <| Computable.unpair.comp (snd.comp snd))).comp <| fst.comp fst) <| .mk ?_
exact
have a := fst.comp (fst.comp <| fst.comp <| fst.comp fst)
have n := fst.comp (snd.comp <| fst.comp <| fst.comp fst)
have m := snd.comp (snd.comp <| fst.comp <| fst.comp fst)
have m₁ := fst.comp (Computable.unpair.comp m)
have m₂ := snd.comp (Computable.unpair.comp m)
have s := snd.comp (fst.comp fst)
have s₁ := snd.comp fst
have s₂ := snd
(nat_bodd.comp n).cond
((nat_bodd.comp <| nat_div2.comp n).cond
(hrf.comp a (((Computable.ofNat Code).comp m).pair s))
(hpc.comp a (((Computable.ofNat Code).comp m₁).pair <|
((Computable.ofNat Code).comp m₂).pair <| s₁.pair s₂)))
(Computable.cond (nat_bodd.comp <| nat_div2.comp n)
(hco.comp a (((Computable.ofNat Code).comp m₁).pair <|
((Computable.ofNat Code).comp m₂).pair <| s₁.pair s₂))
(hpr.comp a (((Computable.ofNat Code).comp m₁).pair <|
((Computable.ofNat Code).comp m₂).pair <| s₁.pair s₂)))
let G : α → List σ → Option σ := fun a IH =>
IH.length.casesOn (some (z a)) fun n =>
n.casesOn (some (s a)) fun n =>
n.casesOn (some (l a)) fun n =>
n.casesOn (some (r a)) fun n =>
G₁ ((a, IH), n, n.div2.div2)
have : Computable₂ G := .mk <|
nat_casesOn (list_length.comp snd) (option_some_iff.2 (hz.comp fst)) <| .mk <|
nat_casesOn snd (option_some_iff.2 (hs.comp (fst.comp fst))) <| .mk <|
nat_casesOn snd (option_some_iff.2 (hl.comp (fst.comp <| fst.comp fst))) <| .mk <|
nat_casesOn snd (option_some_iff.2 (hr.comp (fst.comp <| fst.comp <| fst.comp fst))) <| .mk <|
this.comp <|
((fst.pair snd).comp <| fst.comp <| fst.comp <| fst.comp <| fst).pair <|
snd.pair <| nat_div2.comp <| nat_div2.comp snd
refine (nat_strong_rec (fun a n => F a (ofNat Code n)) this.to₂ fun a n => ?_)
|>.comp .id (encode_iff.2 hc) |>.of_eq fun a => by simp
iterate 4 rcases n with - | n; · simp [ofNatCode_eq, ofNatCode]; rfl
simp only [G]; rw [List.length_map, List.length_range]
let m := n.div2.div2
show G₁ ((a, (List.range (n + 4)).map fun n => F a (ofNat Code n)), n, m)
= some (F a (ofNat Code (n + 4)))
have hm : m < n + 4 := by
simp only [m, div2_val]
exact lt_of_le_of_lt
(le_trans (Nat.div_le_self ..) (Nat.div_le_self ..))
(Nat.succ_le_succ (Nat.le_add_right ..))
have m1 : m.unpair.1 < n + 4 := lt_of_le_of_lt m.unpair_left_le hm
have m2 : m.unpair.2 < n + 4 := lt_of_le_of_lt m.unpair_right_le hm
simp [G₁, m, List.getElem?_map, List.getElem?_range, hm, m1, m2]
rw [show ofNat Code (n + 4) = ofNatCode (n + 4) from rfl]
simp [ofNatCode]
cases n.bodd <;> cases n.div2.bodd <;> rfl
end
/-- The interpretation of a `Nat.Partrec.Code` as a partial function.
* `Nat.Partrec.Code.zero`: The constant zero function.
* `Nat.Partrec.Code.succ`: The successor function.
* `Nat.Partrec.Code.left`: Left unpairing of a pair of ℕ (encoded by `Nat.pair`)
* `Nat.Partrec.Code.right`: Right unpairing of a pair of ℕ (encoded by `Nat.pair`)
* `Nat.Partrec.Code.pair`: Pairs the outputs of argument codes using `Nat.pair`.
* `Nat.Partrec.Code.comp`: Composition of two argument codes.
* `Nat.Partrec.Code.prec`: Primitive recursion. Given an argument of the form `Nat.pair a n`:
* If `n = 0`, returns `eval cf a`.
* If `n = succ k`, returns `eval cg (pair a (pair k (eval (prec cf cg) (pair a k))))`
* `Nat.Partrec.Code.rfind'`: Minimization. For `f` an argument of the form `Nat.pair a m`,
`rfind' f m` returns the least `a` such that `f a m = 0`, if one exists and `f b m` terminates
for `b < a`
-/
def eval : Code → ℕ →. ℕ
| zero => pure 0
| succ => Nat.succ
| left => ↑fun n : ℕ => n.unpair.1
| right => ↑fun n : ℕ => n.unpair.2
| pair cf cg => fun n => Nat.pair <$> eval cf n <*> eval cg n
| comp cf cg => fun n => eval cg n >>= eval cf
| prec cf cg =>
Nat.unpaired fun a n =>
n.rec (eval cf a) fun y IH => do
let i ← IH
eval cg (Nat.pair a (Nat.pair y i))
| rfind' cf =>
Nat.unpaired fun a m =>
(Nat.rfind fun n => (fun m => m = 0) <$> eval cf (Nat.pair a (n + m))).map (· + m)
/-- Helper lemma for the evaluation of `prec` in the base case. -/
@[simp]
theorem eval_prec_zero (cf cg : Code) (a : ℕ) : eval (prec cf cg) (Nat.pair a 0) = eval cf a := by
rw [eval, Nat.unpaired, Nat.unpair_pair]
simp (config := { Lean.Meta.Simp.neutralConfig with proj := true }) only []
rw [Nat.rec_zero]
/-- Helper lemma for the evaluation of `prec` in the recursive case. -/
theorem eval_prec_succ (cf cg : Code) (a k : ℕ) :
eval (prec cf cg) (Nat.pair a (Nat.succ k)) =
do {let ih ← eval (prec cf cg) (Nat.pair a k); eval cg (Nat.pair a (Nat.pair k ih))} := by
rw [eval, Nat.unpaired, Part.bind_eq_bind, Nat.unpair_pair]
simp
instance : Membership (ℕ →. ℕ) Code :=
⟨fun c f => eval c = f⟩
@[simp]
theorem eval_const : ∀ n m, eval (Code.const n) m = Part.some n
| 0, _ => rfl
| n + 1, m => by simp! [eval_const n m]
@[simp]
theorem eval_id (n) : eval Code.id n = Part.some n := by simp! [Seq.seq, Code.id]
@[simp]
theorem eval_curry (c n x) : eval (curry c n) x = eval c (Nat.pair n x) := by simp! [Seq.seq, curry]
theorem const_prim : Primrec Code.const :=
(_root_.Primrec.id.nat_iterate (_root_.Primrec.const zero)
(comp_prim.comp (_root_.Primrec.const succ) Primrec.snd).to₂).of_eq
fun n => by simp; induction n <;>
simp [*, Code.const, Function.iterate_succ', -Function.iterate_succ]
theorem curry_prim : Primrec₂ curry :=
comp_prim.comp Primrec.fst <| pair_prim.comp (const_prim.comp Primrec.snd)
(_root_.Primrec.const Code.id)
theorem curry_inj {c₁ c₂ n₁ n₂} (h : curry c₁ n₁ = curry c₂ n₂) : c₁ = c₂ ∧ n₁ = n₂ :=
⟨by injection h, by
injection h with h₁ h₂
injection h₂ with h₃ h₄
exact const_inj h₃⟩
/--
The $S_n^m$ theorem: There is a computable function, namely `Nat.Partrec.Code.curry`, that takes a
program and a ℕ `n`, and returns a new program using `n` as the first argument.
-/
theorem smn :
∃ f : Code → ℕ → Code, Computable₂ f ∧ ∀ c n x, eval (f c n) x = eval c (Nat.pair n x) :=
⟨curry, Primrec₂.to_comp curry_prim, eval_curry⟩
/-- A function is partial recursive if and only if there is a code implementing it. Therefore,
`eval` is a **universal partial recursive function**. -/
theorem exists_code {f : ℕ →. ℕ} : Nat.Partrec f ↔ ∃ c : Code, eval c = f := by
refine ⟨fun h => ?_, ?_⟩
· induction h with
| zero => exact ⟨zero, rfl⟩
| succ => exact ⟨succ, rfl⟩
| left => exact ⟨left, rfl⟩
| right => exact ⟨right, rfl⟩
| pair pf pg hf hg =>
rcases hf with ⟨cf, rfl⟩; rcases hg with ⟨cg, rfl⟩
exact ⟨pair cf cg, rfl⟩
| comp pf pg hf hg =>
rcases hf with ⟨cf, rfl⟩; rcases hg with ⟨cg, rfl⟩
exact ⟨comp cf cg, rfl⟩
| prec pf pg hf hg =>
rcases hf with ⟨cf, rfl⟩; rcases hg with ⟨cg, rfl⟩
exact ⟨prec cf cg, rfl⟩
| rfind pf hf =>
rcases hf with ⟨cf, rfl⟩
refine ⟨comp (rfind' cf) (pair Code.id zero), ?_⟩
simp [eval, Seq.seq, pure, PFun.pure, Part.map_id']
· rintro ⟨c, rfl⟩
induction c with
| zero => exact Nat.Partrec.zero
| succ => exact Nat.Partrec.succ
| left => exact Nat.Partrec.left
| right => exact Nat.Partrec.right
| pair cf cg pf pg => exact pf.pair pg
| comp cf cg pf pg => exact pf.comp pg
| prec cf cg pf pg => exact pf.prec pg
| rfind' cf pf => exact pf.rfind'
/-- A modified evaluation for the code which returns an `Option ℕ` instead of a `Part ℕ`. To avoid
undecidability, `evaln` takes a parameter `k` and fails if it encounters a number ≥ k in the course
of its execution. Other than this, the semantics are the same as in `Nat.Partrec.Code.eval`.
-/
def evaln : ℕ → Code → ℕ → Option ℕ
| 0, _ => fun _ => Option.none
| k + 1, zero => fun n => do
guard (n ≤ k)
return 0
| k + 1, succ => fun n => do
guard (n ≤ k)
return (Nat.succ n)
| k + 1, left => fun n => do
guard (n ≤ k)
return n.unpair.1
| k + 1, right => fun n => do
guard (n ≤ k)
pure n.unpair.2
| k + 1, pair cf cg => fun n => do
guard (n ≤ k)
Nat.pair <$> evaln (k + 1) cf n <*> evaln (k + 1) cg n
| k + 1, comp cf cg => fun n => do
guard (n ≤ k)
let x ← evaln (k + 1) cg n
evaln (k + 1) cf x
| k + 1, prec cf cg => fun n => do
guard (n ≤ k)
n.unpaired fun a n =>
n.casesOn (evaln (k + 1) cf a) fun y => do
let i ← evaln k (prec cf cg) (Nat.pair a y)
evaln (k + 1) cg (Nat.pair a (Nat.pair y i))
| k + 1, rfind' cf => fun n => do
guard (n ≤ k)
n.unpaired fun a m => do
let x ← evaln (k + 1) cf (Nat.pair a m)
if x = 0 then
pure m
else
evaln k (rfind' cf) (Nat.pair a (m + 1))
theorem evaln_bound : ∀ {k c n x}, x ∈ evaln k c n → n < k
| 0, c, n, x, h => by simp [evaln] at h
| k + 1, c, n, x, h => by
suffices ∀ {o : Option ℕ}, x ∈ do { guard (n ≤ k); o } → n < k + 1 by
cases c <;> rw [evaln] at h <;> exact this h
simpa [Option.bind_eq_some_iff] using Nat.lt_succ_of_le
theorem evaln_mono : ∀ {k₁ k₂ c n x}, k₁ ≤ k₂ → x ∈ evaln k₁ c n → x ∈ evaln k₂ c n
| 0, k₂, c, n, x, _, h => by simp [evaln] at h
| k + 1, k₂ + 1, c, n, x, hl, h => by
have hl' := Nat.le_of_succ_le_succ hl
have :
∀ {k k₂ n x : ℕ} {o₁ o₂ : Option ℕ},
k ≤ k₂ → (x ∈ o₁ → x ∈ o₂) →
x ∈ do { guard (n ≤ k); o₁ } → x ∈ do { guard (n ≤ k₂); o₂ } := by
simp only [Option.mem_def, bind, Option.bind_eq_some_iff, Option.guard_eq_some',
exists_and_left, exists_const, and_imp]
introv h h₁ h₂ h₃
exact ⟨le_trans h₂ h, h₁ h₃⟩
simp? at h ⊢ says simp only [Option.mem_def] at h ⊢
induction c generalizing x n <;> rw [evaln] at h ⊢ <;> refine this hl' (fun h => ?_) h
iterate 4 exact h
case pair cf cg hf hg _ =>
simp? [Seq.seq, Option.bind_eq_some_iff] at h ⊢ says
simp only [Seq.seq, Option.map_eq_map, Option.mem_def, Option.bind_eq_some_iff,
Option.map_eq_some', exists_exists_and_eq_and] at h ⊢
exact h.imp fun a => And.imp (hf _ _) <| Exists.imp fun b => And.imp_left (hg _ _)
case comp cf cg hf hg _ =>
simp? [Bind.bind, Option.bind_eq_some_iff] at h ⊢ says
simp only [bind, Option.mem_def, Option.bind_eq_some_iff] at h ⊢
exact h.imp fun a => And.imp (hg _ _) (hf _ _)
case prec cf cg hf hg _ =>
revert h
simp only [unpaired, bind, Option.mem_def]
induction n.unpair.2 <;> simp [Option.bind_eq_some_iff]
· apply hf
· exact fun y h₁ h₂ => ⟨y, evaln_mono hl' h₁, hg _ _ h₂⟩
case rfind' cf hf _ =>
simp? [Bind.bind, Option.bind_eq_some_iff] at h ⊢ says
simp only [unpaired, bind, pair_unpair, Option.pure_def, Option.mem_def,
Option.bind_eq_some_iff] at h ⊢
refine h.imp fun x => And.imp (hf _ _) ?_
by_cases x0 : x = 0 <;> simp [x0]
exact evaln_mono hl'
theorem evaln_sound : ∀ {k c n x}, x ∈ evaln k c n → x ∈ eval c n
| 0, _, n, x, h => by simp [evaln] at h
| | k + 1, c, n, x, h => by
induction c generalizing x n <;> simp [eval, evaln, Option.bind_eq_some_iff, Seq.seq] at h ⊢ <;>
obtain ⟨_, h⟩ := h
iterate 4 simpa [pure, PFun.pure, eq_comm] using h
case pair cf cg hf hg _ =>
rcases h with ⟨y, ef, z, eg, rfl⟩
| Mathlib/Computability/PartrecCode.lean | 642 | 647 |
/-
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.Typeclasses.Finite
import Mathlib.MeasureTheory.Measure.Typeclasses.NoAtoms
import Mathlib.MeasureTheory.Measure.Typeclasses.Probability
import Mathlib.MeasureTheory.Measure.Typeclasses.SFinite
deprecated_module (since := "2025-04-13")
| Mathlib/MeasureTheory/Measure/Typeclasses.lean | 951 | 954 | |
/-
Copyright (c) 2016 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Leonardo de Moura, Mario Carneiro
-/
import Mathlib.Algebra.Order.GroupWithZero.Synonym
import Mathlib.Algebra.Order.Ring.Canonical
import Mathlib.Algebra.Ring.Hom.Defs
import Mathlib.Algebra.Order.Monoid.WithTop
/-! # Structures involving `*` and `0` on `WithTop` and `WithBot`
The main results of this section are `WithTop.instOrderedCommSemiring` and
`WithBot.instOrderedCommSemiring`.
-/
variable {α : Type*}
namespace WithTop
variable [DecidableEq α]
section MulZeroClass
variable [MulZeroClass α] {a b : WithTop α}
instance instMulZeroClass : MulZeroClass (WithTop α) where
zero := 0
mul
| (a : α), (b : α) => ↑(a * b)
| (a : α), ⊤ => if a = 0 then 0 else ⊤
| ⊤, (b : α) => if b = 0 then 0 else ⊤
| ⊤, ⊤ => ⊤
mul_zero
| (a : α) => congr_arg some <| mul_zero _
| ⊤ => if_pos rfl
zero_mul
| (b : α) => congr_arg some <| zero_mul _
| ⊤ => if_pos rfl
@[simp, norm_cast] lemma coe_mul (a b : α) : (↑(a * b) : WithTop α) = a * b := rfl
lemma mul_top' : ∀ (a : WithTop α), a * ⊤ = if a = 0 then 0 else ⊤
| (a : α) => if_congr coe_eq_zero.symm rfl rfl
| ⊤ => (if_neg top_ne_zero).symm
@[simp] lemma mul_top (h : a ≠ 0) : a * ⊤ = ⊤ := by rw [mul_top', if_neg h]
lemma top_mul' : ∀ (b : WithTop α), ⊤ * b = if b = 0 then 0 else ⊤
| (b : α) => if_congr coe_eq_zero.symm rfl rfl
| ⊤ => (if_neg top_ne_zero).symm
@[simp] lemma top_mul (hb : b ≠ 0) : ⊤ * b = ⊤ := by rw [top_mul', if_neg hb]
@[simp] lemma top_mul_top : (⊤ * ⊤ : WithTop α) = ⊤ := rfl
lemma mul_def (a b : WithTop α) :
a * b = if a = 0 ∨ b = 0 then 0 else WithTop.map₂ (· * ·) a b := by
cases a <;> cases b <;> aesop
lemma mul_eq_top_iff : a * b = ⊤ ↔ a ≠ 0 ∧ b = ⊤ ∨ a = ⊤ ∧ b ≠ 0 := by rw [mul_def]; aesop
lemma mul_coe_eq_bind {b : α} (hb : b ≠ 0) : ∀ a, (a * b : WithTop α) = a.bind fun a ↦ ↑(a * b)
| ⊤ => by simp [top_mul, hb]; rfl
| (a : α) => rfl
lemma coe_mul_eq_bind {a : α} (ha : a ≠ 0) : ∀ b, (a * b : WithTop α) = b.bind fun b ↦ ↑(a * b)
| ⊤ => by simp [top_mul, ha]; rfl
| (b : α) => rfl
@[simp]
lemma untopD_zero_mul (a b : WithTop α) : (a * b).untopD 0 = a.untopD 0 * b.untopD 0 := by
by_cases ha : a = 0; · rw [ha, zero_mul, ← coe_zero, untopD_coe, zero_mul]
by_cases hb : b = 0; · rw [hb, mul_zero, ← coe_zero, untopD_coe, mul_zero]
induction a; · rw [top_mul hb, untopD_top, zero_mul]
induction b; · rw [mul_top ha, untopD_top, mul_zero]
rw [← coe_mul, untopD_coe, untopD_coe, untopD_coe]
@[deprecated (since := "2025-02-06")]
alias untop'_zero_mul := untopD_zero_mul
theorem mul_ne_top {a b : WithTop α} (ha : a ≠ ⊤) (hb : b ≠ ⊤) : a * b ≠ ⊤ := by
simp [mul_eq_top_iff, *]
theorem mul_lt_top [LT α] {a b : WithTop α} (ha : a < ⊤) (hb : b < ⊤) : a * b < ⊤ := by
rw [WithTop.lt_top_iff_ne_top] at *
exact mul_ne_top ha hb
instance instNoZeroDivisors [NoZeroDivisors α] : NoZeroDivisors (WithTop α) := by
refine ⟨fun h₁ => Decidable.byContradiction fun h₂ => ?_⟩
| rw [mul_def, if_neg h₂] at h₁
rcases Option.mem_map₂_iff.1 h₁ with ⟨a, b, (rfl : _ = _), (rfl : _ = _), hab⟩
exact h₂ ((eq_zero_or_eq_zero_of_mul_eq_zero hab).imp (congr_arg some) (congr_arg some))
| Mathlib/Algebra/Order/Ring/WithTop.lean | 89 | 91 |
/-
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.Algebra.Category.ModuleCat.Presheaf.Colimits
import Mathlib.Algebra.Category.ModuleCat.Sheaf.Colimits
/-!
# Free sheaves of modules
In this file, we construct the functor
`SheafOfModules.freeFunctor : Type u ⥤ SheafOfModules.{u} R` which sends
a type `I` to the coproduct of copies indexed by `I` of `unit R`.
## TODO
* In case the category `C` has a terminal object `X`, promote `freeHomEquiv`
into an adjunction between `freeFunctor` and the evaluation functor at `X`.
(Alternatively, assuming specific universe parameters, we could show that
`freeHomEquiv` is a left adjoint to `SheafOfModules.sectionsFunctor`.)
-/
universe u v' u'
open CategoryTheory Limits
variable {C : Type u'} [Category.{v'} C] {J : GrothendieckTopology C} {R : Sheaf J RingCat.{u}}
[HasWeakSheafify J AddCommGrp.{u}] [J.WEqualsLocallyBijective AddCommGrp.{u}]
[J.HasSheafCompose (forget₂ RingCat.{u} AddCommGrp.{u})]
namespace SheafOfModules
/-- The free sheaf of modules on a certain type `I`. -/
noncomputable def free (I : Type u) : SheafOfModules.{u} R := ∐ (fun (_ : I) ↦ unit R)
/-- The data of a morphism `free I ⟶ M` from a free sheaf of modules is
equivalent to the data of a family `I → M.sections` of sections of `M`. -/
noncomputable def freeHomEquiv (M : SheafOfModules.{u} R) {I : Type u} :
(free I ⟶ M) ≃ (I → M.sections) where
toFun f i := M.unitHomEquiv (Sigma.ι (fun (_ : I) ↦ unit R) i ≫ f)
invFun s := Sigma.desc (fun i ↦ M.unitHomEquiv.symm (s i))
left_inv s := Sigma.hom_ext _ _ (by simp)
right_inv f := by ext1 i; simp
lemma freeHomEquiv_comp_apply {M N : SheafOfModules.{u} R} {I : Type u}
(f : free I ⟶ M) (p : M ⟶ N) (i : I) :
N.freeHomEquiv (f ≫ p) i = sectionsMap p (M.freeHomEquiv f i) := rfl
lemma freeHomEquiv_symm_comp {M N : SheafOfModules.{u} R} {I : Type u} (s : I → M.sections)
(p : M ⟶ N) :
M.freeHomEquiv.symm s ≫ p = N.freeHomEquiv.symm (fun i ↦ sectionsMap p (s i)) :=
N.freeHomEquiv.injective (by ext; simp [freeHomEquiv_comp_apply])
/-- The tautological section of `free I : SheafOfModules R` corresponding to `i : I`. -/
noncomputable abbrev freeSection {I : Type u} (i : I) : (free (R := R) I).sections :=
(free (R := R) I).freeHomEquiv (𝟙 (free I)) i
section
variable {I J : Type u} (f : I → J)
/-- The morphism of presheaves of `R`-modules `free I ⟶ free J` induced by
a map `f : I → J`. -/
noncomputable def freeMap : free (R := R) I ⟶ free J :=
(freeHomEquiv _).symm (fun i ↦ freeSection (f i))
| @[simp]
lemma freeHomEquiv_freeMap :
(freeHomEquiv _ (freeMap (R := R) f)) = freeSection.comp f :=
(freeHomEquiv _).symm.injective (by simp; rfl)
| Mathlib/Algebra/Category/ModuleCat/Sheaf/Free.lean | 68 | 71 |
/-
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.Algebra.Order.Pi
import Mathlib.MeasureTheory.Constructions.BorelSpace.Order
/-!
# Simple functions
A function `f` from a measurable space to any type is called *simple*, if every preimage `f ⁻¹' {x}`
is measurable, and the range is finite. In this file, we define simple functions and establish their
basic properties; and we construct a sequence of simple functions approximating an arbitrary Borel
measurable function `f : α → ℝ≥0∞`.
The theorem `Measurable.ennreal_induction` shows that in order to prove something for an arbitrary
measurable function into `ℝ≥0∞`, it is sufficient to show that the property holds for (multiples of)
characteristic functions and is closed under addition and supremum of increasing sequences of
functions.
-/
noncomputable section
open Set hiding restrict restrict_apply
open Filter ENNReal
open Function (support)
open Topology NNReal ENNReal MeasureTheory
namespace MeasureTheory
variable {α β γ δ : Type*}
/-- A function `f` from a measurable space to any type is called *simple*,
if every preimage `f ⁻¹' {x}` is measurable, and the range is finite. This structure bundles
a function with these properties. -/
structure SimpleFunc.{u, v} (α : Type u) [MeasurableSpace α] (β : Type v) where
/-- The underlying function -/
toFun : α → β
measurableSet_fiber' : ∀ x, MeasurableSet (toFun ⁻¹' {x})
finite_range' : (Set.range toFun).Finite
local infixr:25 " →ₛ " => SimpleFunc
namespace SimpleFunc
section Measurable
variable [MeasurableSpace α]
instance instFunLike : FunLike (α →ₛ β) α β where
coe := toFun
coe_injective' | ⟨_, _, _⟩, ⟨_, _, _⟩, rfl => rfl
theorem coe_injective ⦃f g : α →ₛ β⦄ (H : (f : α → β) = g) : f = g := DFunLike.ext' H
@[ext]
theorem ext {f g : α →ₛ β} (H : ∀ a, f a = g a) : f = g := DFunLike.ext _ _ H
theorem finite_range (f : α →ₛ β) : (Set.range f).Finite :=
f.finite_range'
theorem measurableSet_fiber (f : α →ₛ β) (x : β) : MeasurableSet (f ⁻¹' {x}) :=
f.measurableSet_fiber' x
@[simp] theorem coe_mk (f : α → β) (h h') : ⇑(mk f h h') = f := rfl
theorem apply_mk (f : α → β) (h h') (x : α) : SimpleFunc.mk f h h' x = f x :=
rfl
/-- Simple function defined on a finite type. -/
def ofFinite [Finite α] [MeasurableSingletonClass α] (f : α → β) : α →ₛ β where
toFun := f
measurableSet_fiber' x := (toFinite (f ⁻¹' {x})).measurableSet
finite_range' := Set.finite_range f
/-- Simple function defined on the empty type. -/
def ofIsEmpty [IsEmpty α] : α →ₛ β := ofFinite isEmptyElim
/-- Range of a simple function `α →ₛ β` as a `Finset β`. -/
protected def range (f : α →ₛ β) : Finset β :=
f.finite_range.toFinset
@[simp]
theorem mem_range {f : α →ₛ β} {b} : b ∈ f.range ↔ b ∈ range f :=
Finite.mem_toFinset _
theorem mem_range_self (f : α →ₛ β) (x : α) : f x ∈ f.range :=
mem_range.2 ⟨x, rfl⟩
@[simp]
theorem coe_range (f : α →ₛ β) : (↑f.range : Set β) = Set.range f :=
f.finite_range.coe_toFinset
theorem mem_range_of_measure_ne_zero {f : α →ₛ β} {x : β} {μ : Measure α} (H : μ (f ⁻¹' {x}) ≠ 0) :
x ∈ f.range :=
let ⟨a, ha⟩ := nonempty_of_measure_ne_zero H
mem_range.2 ⟨a, ha⟩
theorem forall_mem_range {f : α →ₛ β} {p : β → Prop} : (∀ y ∈ f.range, p y) ↔ ∀ x, p (f x) := by
simp only [mem_range, Set.forall_mem_range]
theorem exists_range_iff {f : α →ₛ β} {p : β → Prop} : (∃ y ∈ f.range, p y) ↔ ∃ x, p (f x) := by
simpa only [mem_range, exists_prop] using Set.exists_range_iff
theorem preimage_eq_empty_iff (f : α →ₛ β) (b : β) : f ⁻¹' {b} = ∅ ↔ b ∉ f.range :=
preimage_singleton_eq_empty.trans <| not_congr mem_range.symm
theorem exists_forall_le [Nonempty β] [Preorder β] [IsDirected β (· ≤ ·)] (f : α →ₛ β) :
∃ C, ∀ x, f x ≤ C :=
f.range.exists_le.imp fun _ => forall_mem_range.1
/-- Constant function as a `SimpleFunc`. -/
def const (α) {β} [MeasurableSpace α] (b : β) : α →ₛ β :=
⟨fun _ => b, fun _ => MeasurableSet.const _, finite_range_const⟩
instance instInhabited [Inhabited β] : Inhabited (α →ₛ β) :=
⟨const _ default⟩
theorem const_apply (a : α) (b : β) : (const α b) a = b :=
rfl
@[simp]
theorem coe_const (b : β) : ⇑(const α b) = Function.const α b :=
rfl
@[simp]
theorem range_const (α) [MeasurableSpace α] [Nonempty α] (b : β) : (const α b).range = {b} :=
Finset.coe_injective <| by simp +unfoldPartialApp [Function.const]
theorem range_const_subset (α) [MeasurableSpace α] (b : β) : (const α b).range ⊆ {b} :=
Finset.coe_subset.1 <| by simp
theorem simpleFunc_bot {α} (f : @SimpleFunc α ⊥ β) [Nonempty β] : ∃ c, ∀ x, f x = c := by
have hf_meas := @SimpleFunc.measurableSet_fiber α _ ⊥ f
simp_rw [MeasurableSpace.measurableSet_bot_iff] at hf_meas
exact (exists_eq_const_of_preimage_singleton hf_meas).imp fun c hc ↦ congr_fun hc
theorem simpleFunc_bot' {α} [Nonempty β] (f : @SimpleFunc α ⊥ β) :
∃ c, f = @SimpleFunc.const α _ ⊥ c :=
letI : MeasurableSpace α := ⊥; (simpleFunc_bot f).imp fun _ ↦ ext
theorem measurableSet_cut (r : α → β → Prop) (f : α →ₛ β) (h : ∀ b, MeasurableSet { a | r a b }) :
MeasurableSet { a | r a (f a) } := by
have : { a | r a (f a) } = ⋃ b ∈ range f, { a | r a b } ∩ f ⁻¹' {b} := by
ext a
suffices r a (f a) ↔ ∃ i, r a (f i) ∧ f a = f i by simpa
exact ⟨fun h => ⟨a, ⟨h, rfl⟩⟩, fun ⟨a', ⟨h', e⟩⟩ => e.symm ▸ h'⟩
rw [this]
exact
MeasurableSet.biUnion f.finite_range.countable fun b _ =>
MeasurableSet.inter (h b) (f.measurableSet_fiber _)
@[measurability]
theorem measurableSet_preimage (f : α →ₛ β) (s) : MeasurableSet (f ⁻¹' s) :=
measurableSet_cut (fun _ b => b ∈ s) f fun b => MeasurableSet.const (b ∈ s)
/-- A simple function is measurable -/
@[measurability, fun_prop]
protected theorem measurable [MeasurableSpace β] (f : α →ₛ β) : Measurable f := fun s _ =>
measurableSet_preimage f s
@[measurability]
protected theorem aemeasurable [MeasurableSpace β] {μ : Measure α} (f : α →ₛ β) :
AEMeasurable f μ :=
f.measurable.aemeasurable
protected theorem sum_measure_preimage_singleton (f : α →ₛ β) {μ : Measure α} (s : Finset β) :
(∑ y ∈ s, μ (f ⁻¹' {y})) = μ (f ⁻¹' ↑s) :=
sum_measure_preimage_singleton _ fun _ _ => f.measurableSet_fiber _
theorem sum_range_measure_preimage_singleton (f : α →ₛ β) (μ : Measure α) :
(∑ y ∈ f.range, μ (f ⁻¹' {y})) = μ univ := by
rw [f.sum_measure_preimage_singleton, coe_range, preimage_range]
open scoped Classical in
/-- If-then-else as a `SimpleFunc`. -/
def piecewise (s : Set α) (hs : MeasurableSet s) (f g : α →ₛ β) : α →ₛ β :=
⟨s.piecewise f g, fun _ =>
letI : MeasurableSpace β := ⊤
f.measurable.piecewise hs g.measurable trivial,
(f.finite_range.union g.finite_range).subset range_ite_subset⟩
open scoped Classical in
@[simp]
theorem coe_piecewise {s : Set α} (hs : MeasurableSet s) (f g : α →ₛ β) :
⇑(piecewise s hs f g) = s.piecewise f g :=
rfl
open scoped Classical in
theorem piecewise_apply {s : Set α} (hs : MeasurableSet s) (f g : α →ₛ β) (a) :
piecewise s hs f g a = if a ∈ s then f a else g a :=
rfl
open scoped Classical in
@[simp]
theorem piecewise_compl {s : Set α} (hs : MeasurableSet sᶜ) (f g : α →ₛ β) :
piecewise sᶜ hs f g = piecewise s hs.of_compl g f :=
coe_injective <| by simp [hs]
@[simp]
theorem piecewise_univ (f g : α →ₛ β) : piecewise univ MeasurableSet.univ f g = f :=
coe_injective <| by simp
@[simp]
theorem piecewise_empty (f g : α →ₛ β) : piecewise ∅ MeasurableSet.empty f g = g :=
coe_injective <| by simp
open scoped Classical in
@[simp]
theorem piecewise_same (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) :
piecewise s hs f f = f :=
coe_injective <| Set.piecewise_same _ _
theorem support_indicator [Zero β] {s : Set α} (hs : MeasurableSet s) (f : α →ₛ β) :
Function.support (f.piecewise s hs (SimpleFunc.const α 0)) = s ∩ Function.support f :=
Set.support_indicator
open scoped Classical in
theorem range_indicator {s : Set α} (hs : MeasurableSet s) (hs_nonempty : s.Nonempty)
(hs_ne_univ : s ≠ univ) (x y : β) :
(piecewise s hs (const α x) (const α y)).range = {x, y} := by
simp only [← Finset.coe_inj, coe_range, coe_piecewise, range_piecewise, coe_const,
Finset.coe_insert, Finset.coe_singleton, hs_nonempty.image_const,
(nonempty_compl.2 hs_ne_univ).image_const, singleton_union, Function.const]
theorem measurable_bind [MeasurableSpace γ] (f : α →ₛ β) (g : β → α → γ)
(hg : ∀ b, Measurable (g b)) : Measurable fun a => g (f a) a := fun s hs =>
f.measurableSet_cut (fun a b => g b a ∈ s) fun b => hg b hs
/-- If `f : α →ₛ β` is a simple function and `g : β → α →ₛ γ` is a family of simple functions,
then `f.bind g` binds the first argument of `g` to `f`. In other words, `f.bind g a = g (f a) a`. -/
def bind (f : α →ₛ β) (g : β → α →ₛ γ) : α →ₛ γ :=
⟨fun a => g (f a) a, fun c =>
f.measurableSet_cut (fun a b => g b a = c) fun b => (g b).measurableSet_preimage {c},
(f.finite_range.biUnion fun b _ => (g b).finite_range).subset <| by
rintro _ ⟨a, rfl⟩; simp⟩
@[simp]
theorem bind_apply (f : α →ₛ β) (g : β → α →ₛ γ) (a) : f.bind g a = g (f a) a :=
rfl
/-- Given a function `g : β → γ` and a simple function `f : α →ₛ β`, `f.map g` return the simple
function `g ∘ f : α →ₛ γ` -/
def map (g : β → γ) (f : α →ₛ β) : α →ₛ γ :=
bind f (const α ∘ g)
theorem map_apply (g : β → γ) (f : α →ₛ β) (a) : f.map g a = g (f a) :=
rfl
theorem map_map (g : β → γ) (h : γ → δ) (f : α →ₛ β) : (f.map g).map h = f.map (h ∘ g) :=
rfl
@[simp]
theorem coe_map (g : β → γ) (f : α →ₛ β) : (f.map g : α → γ) = g ∘ f :=
rfl
@[simp]
theorem range_map [DecidableEq γ] (g : β → γ) (f : α →ₛ β) : (f.map g).range = f.range.image g :=
Finset.coe_injective <| by simp only [coe_range, coe_map, Finset.coe_image, range_comp]
@[simp]
theorem map_const (g : β → γ) (b : β) : (const α b).map g = const α (g b) :=
rfl
open scoped Classical in
theorem map_preimage (f : α →ₛ β) (g : β → γ) (s : Set γ) :
f.map g ⁻¹' s = f ⁻¹' ↑{b ∈ f.range | g b ∈ s} := by
simp only [coe_range, sep_mem_eq, coe_map, Finset.coe_filter,
← mem_preimage, inter_comm, preimage_inter_range, ← Finset.mem_coe]
exact preimage_comp
open scoped Classical in
theorem map_preimage_singleton (f : α →ₛ β) (g : β → γ) (c : γ) :
f.map g ⁻¹' {c} = f ⁻¹' ↑{b ∈ f.range | g b = c} :=
map_preimage _ _ _
/-- Composition of a `SimpleFun` and a measurable function is a `SimpleFunc`. -/
def comp [MeasurableSpace β] (f : β →ₛ γ) (g : α → β) (hgm : Measurable g) : α →ₛ γ where
toFun := f ∘ g
finite_range' := f.finite_range.subset <| Set.range_comp_subset_range _ _
measurableSet_fiber' z := hgm (f.measurableSet_fiber z)
@[simp]
theorem coe_comp [MeasurableSpace β] (f : β →ₛ γ) {g : α → β} (hgm : Measurable g) :
⇑(f.comp g hgm) = f ∘ g :=
rfl
theorem range_comp_subset_range [MeasurableSpace β] (f : β →ₛ γ) {g : α → β} (hgm : Measurable g) :
(f.comp g hgm).range ⊆ f.range :=
Finset.coe_subset.1 <| by simp only [coe_range, coe_comp, Set.range_comp_subset_range]
/-- Extend a `SimpleFunc` along a measurable embedding: `f₁.extend g hg f₂` is the function
`F : β →ₛ γ` such that `F ∘ g = f₁` and `F y = f₂ y` whenever `y ∉ range g`. -/
def extend [MeasurableSpace β] (f₁ : α →ₛ γ) (g : α → β) (hg : MeasurableEmbedding g)
(f₂ : β →ₛ γ) : β →ₛ γ where
toFun := Function.extend g f₁ f₂
finite_range' :=
(f₁.finite_range.union <| f₂.finite_range.subset (image_subset_range _ _)).subset
(range_extend_subset _ _ _)
measurableSet_fiber' := by
letI : MeasurableSpace γ := ⊤; haveI : MeasurableSingletonClass γ := ⟨fun _ => trivial⟩
exact fun x => hg.measurable_extend f₁.measurable f₂.measurable (measurableSet_singleton _)
@[simp]
theorem extend_apply [MeasurableSpace β] (f₁ : α →ₛ γ) {g : α → β} (hg : MeasurableEmbedding g)
(f₂ : β →ₛ γ) (x : α) : (f₁.extend g hg f₂) (g x) = f₁ x :=
hg.injective.extend_apply _ _ _
@[simp]
theorem extend_apply' [MeasurableSpace β] (f₁ : α →ₛ γ) {g : α → β} (hg : MeasurableEmbedding g)
(f₂ : β →ₛ γ) {y : β} (h : ¬∃ x, g x = y) : (f₁.extend g hg f₂) y = f₂ y :=
Function.extend_apply' _ _ _ h
@[simp]
theorem extend_comp_eq' [MeasurableSpace β] (f₁ : α →ₛ γ) {g : α → β} (hg : MeasurableEmbedding g)
(f₂ : β →ₛ γ) : f₁.extend g hg f₂ ∘ g = f₁ :=
funext fun _ => extend_apply _ _ _ _
@[simp]
theorem extend_comp_eq [MeasurableSpace β] (f₁ : α →ₛ γ) {g : α → β} (hg : MeasurableEmbedding g)
(f₂ : β →ₛ γ) : (f₁.extend g hg f₂).comp g hg.measurable = f₁ :=
coe_injective <| extend_comp_eq' _ hg _
/-- If `f` is a simple function taking values in `β → γ` and `g` is another simple function
with the same domain and codomain `β`, then `f.seq g = f a (g a)`. -/
def seq (f : α →ₛ β → γ) (g : α →ₛ β) : α →ₛ γ :=
f.bind fun f => g.map f
@[simp]
theorem seq_apply (f : α →ₛ β → γ) (g : α →ₛ β) (a : α) : f.seq g a = f a (g a) :=
rfl
/-- Combine two simple functions `f : α →ₛ β` and `g : α →ₛ β`
into `fun a => (f a, g a)`. -/
def pair (f : α →ₛ β) (g : α →ₛ γ) : α →ₛ β × γ :=
(f.map Prod.mk).seq g
@[simp]
theorem pair_apply (f : α →ₛ β) (g : α →ₛ γ) (a) : pair f g a = (f a, g a) :=
rfl
theorem pair_preimage (f : α →ₛ β) (g : α →ₛ γ) (s : Set β) (t : Set γ) :
pair f g ⁻¹' s ×ˢ t = f ⁻¹' s ∩ g ⁻¹' t :=
rfl
-- A special form of `pair_preimage`
theorem pair_preimage_singleton (f : α →ₛ β) (g : α →ₛ γ) (b : β) (c : γ) :
pair f g ⁻¹' {(b, c)} = f ⁻¹' {b} ∩ g ⁻¹' {c} := by
rw [← singleton_prod_singleton]
exact pair_preimage _ _ _ _
@[simp] theorem map_fst_pair (f : α →ₛ β) (g : α →ₛ γ) : (f.pair g).map Prod.fst = f := rfl
@[simp] theorem map_snd_pair (f : α →ₛ β) (g : α →ₛ γ) : (f.pair g).map Prod.snd = g := rfl
@[simp]
theorem bind_const (f : α →ₛ β) : f.bind (const α) = f := by ext; simp
@[to_additive]
instance instOne [One β] : One (α →ₛ β) :=
⟨const α 1⟩
@[to_additive]
instance instMul [Mul β] : Mul (α →ₛ β) :=
⟨fun f g => (f.map (· * ·)).seq g⟩
@[to_additive]
instance instDiv [Div β] : Div (α →ₛ β) :=
⟨fun f g => (f.map (· / ·)).seq g⟩
@[to_additive]
instance instInv [Inv β] : Inv (α →ₛ β) :=
⟨fun f => f.map Inv.inv⟩
instance instSup [Max β] : Max (α →ₛ β) :=
⟨fun f g => (f.map (· ⊔ ·)).seq g⟩
instance instInf [Min β] : Min (α →ₛ β) :=
⟨fun f g => (f.map (· ⊓ ·)).seq g⟩
instance instLE [LE β] : LE (α →ₛ β) :=
⟨fun f g => ∀ a, f a ≤ g a⟩
@[to_additive (attr := simp)]
theorem const_one [One β] : const α (1 : β) = 1 :=
rfl
@[to_additive (attr := simp, norm_cast)]
theorem coe_one [One β] : ⇑(1 : α →ₛ β) = 1 :=
rfl
@[to_additive (attr := simp, norm_cast)]
theorem coe_mul [Mul β] (f g : α →ₛ β) : ⇑(f * g) = ⇑f * ⇑g :=
rfl
@[to_additive (attr := simp, norm_cast)]
theorem coe_inv [Inv β] (f : α →ₛ β) : ⇑(f⁻¹) = (⇑f)⁻¹ :=
rfl
@[to_additive (attr := simp, norm_cast)]
theorem coe_div [Div β] (f g : α →ₛ β) : ⇑(f / g) = ⇑f / ⇑g :=
rfl
@[simp, norm_cast]
theorem coe_le [LE β] {f g : α →ₛ β} : (f : α → β) ≤ g ↔ f ≤ g :=
Iff.rfl
@[simp, norm_cast]
theorem coe_sup [Max β] (f g : α →ₛ β) : ⇑(f ⊔ g) = ⇑f ⊔ ⇑g :=
rfl
@[simp, norm_cast]
theorem coe_inf [Min β] (f g : α →ₛ β) : ⇑(f ⊓ g) = ⇑f ⊓ ⇑g :=
rfl
@[to_additive]
theorem mul_apply [Mul β] (f g : α →ₛ β) (a : α) : (f * g) a = f a * g a :=
rfl
@[to_additive]
theorem div_apply [Div β] (f g : α →ₛ β) (x : α) : (f / g) x = f x / g x :=
rfl
@[to_additive]
theorem inv_apply [Inv β] (f : α →ₛ β) (x : α) : f⁻¹ x = (f x)⁻¹ :=
rfl
theorem sup_apply [Max β] (f g : α →ₛ β) (a : α) : (f ⊔ g) a = f a ⊔ g a :=
rfl
theorem inf_apply [Min β] (f g : α →ₛ β) (a : α) : (f ⊓ g) a = f a ⊓ g a :=
rfl
@[to_additive (attr := simp)]
theorem range_one [Nonempty α] [One β] : (1 : α →ₛ β).range = {1} :=
Finset.ext fun x => by simp [eq_comm]
@[simp]
theorem range_eq_empty_of_isEmpty {β} [hα : IsEmpty α] (f : α →ₛ β) : f.range = ∅ := by
rw [← Finset.not_nonempty_iff_eq_empty]
by_contra h
obtain ⟨y, hy_mem⟩ := h
rw [SimpleFunc.mem_range, Set.mem_range] at hy_mem
obtain ⟨x, hxy⟩ := hy_mem
rw [isEmpty_iff] at hα
exact hα x
theorem eq_zero_of_mem_range_zero [Zero β] : ∀ {y : β}, y ∈ (0 : α →ₛ β).range → y = 0 :=
@(forall_mem_range.2 fun _ => rfl)
@[to_additive]
theorem mul_eq_map₂ [Mul β] (f g : α →ₛ β) : f * g = (pair f g).map fun p : β × β => p.1 * p.2 :=
rfl
theorem sup_eq_map₂ [Max β] (f g : α →ₛ β) : f ⊔ g = (pair f g).map fun p : β × β => p.1 ⊔ p.2 :=
rfl
@[to_additive]
theorem const_mul_eq_map [Mul β] (f : α →ₛ β) (b : β) : const α b * f = f.map fun a => b * a :=
rfl
@[to_additive]
theorem map_mul [Mul β] [Mul γ] {g : β → γ} (hg : ∀ x y, g (x * y) = g x * g y) (f₁ f₂ : α →ₛ β) :
(f₁ * f₂).map g = f₁.map g * f₂.map g :=
ext fun _ => hg _ _
variable {K : Type*}
@[to_additive]
instance instSMul [SMul K β] : SMul K (α →ₛ β) :=
⟨fun k f => f.map (k • ·)⟩
@[to_additive (attr := simp)]
theorem coe_smul [SMul K β] (c : K) (f : α →ₛ β) : ⇑(c • f) = c • ⇑f :=
rfl
@[to_additive (attr := simp)]
theorem smul_apply [SMul K β] (k : K) (f : α →ₛ β) (a : α) : (k • f) a = k • f a :=
rfl
instance hasNatSMul [AddMonoid β] : SMul ℕ (α →ₛ β) := inferInstance
@[to_additive existing hasNatSMul]
instance hasNatPow [Monoid β] : Pow (α →ₛ β) ℕ :=
⟨fun f n => f.map (· ^ n)⟩
@[simp]
theorem coe_pow [Monoid β] (f : α →ₛ β) (n : ℕ) : ⇑(f ^ n) = (⇑f) ^ n :=
rfl
theorem pow_apply [Monoid β] (n : ℕ) (f : α →ₛ β) (a : α) : (f ^ n) a = f a ^ n :=
rfl
instance hasIntPow [DivInvMonoid β] : Pow (α →ₛ β) ℤ :=
⟨fun f n => f.map (· ^ n)⟩
@[simp]
theorem coe_zpow [DivInvMonoid β] (f : α →ₛ β) (z : ℤ) : ⇑(f ^ z) = (⇑f) ^ z :=
rfl
theorem zpow_apply [DivInvMonoid β] (z : ℤ) (f : α →ₛ β) (a : α) : (f ^ z) a = f a ^ z :=
rfl
-- TODO: work out how to generate these instances with `to_additive`, which gets confused by the
-- argument order swap between `coe_smul` and `coe_pow`.
section Additive
instance instAddMonoid [AddMonoid β] : AddMonoid (α →ₛ β) :=
Function.Injective.addMonoid (fun f => show α → β from f) coe_injective coe_zero coe_add
fun _ _ => coe_smul _ _
instance instAddCommMonoid [AddCommMonoid β] : AddCommMonoid (α →ₛ β) :=
Function.Injective.addCommMonoid (fun f => show α → β from f) coe_injective coe_zero coe_add
fun _ _ => coe_smul _ _
instance instAddGroup [AddGroup β] : AddGroup (α →ₛ β) :=
Function.Injective.addGroup (fun f => show α → β from f) coe_injective coe_zero coe_add coe_neg
coe_sub (fun _ _ => coe_smul _ _) fun _ _ => coe_smul _ _
instance instAddCommGroup [AddCommGroup β] : AddCommGroup (α →ₛ β) :=
Function.Injective.addCommGroup (fun f => show α → β from f) coe_injective coe_zero coe_add
coe_neg coe_sub (fun _ _ => coe_smul _ _) fun _ _ => coe_smul _ _
end Additive
@[to_additive existing]
instance instMonoid [Monoid β] : Monoid (α →ₛ β) :=
Function.Injective.monoid (fun f => show α → β from f) coe_injective coe_one coe_mul coe_pow
@[to_additive existing]
instance instCommMonoid [CommMonoid β] : CommMonoid (α →ₛ β) :=
Function.Injective.commMonoid (fun f => show α → β from f) coe_injective coe_one coe_mul coe_pow
@[to_additive existing]
instance instGroup [Group β] : Group (α →ₛ β) :=
Function.Injective.group (fun f => show α → β from f) coe_injective coe_one coe_mul coe_inv
coe_div coe_pow coe_zpow
@[to_additive existing]
instance instCommGroup [CommGroup β] : CommGroup (α →ₛ β) :=
Function.Injective.commGroup (fun f => show α → β from f) coe_injective coe_one coe_mul coe_inv
coe_div coe_pow coe_zpow
instance instModule [Semiring K] [AddCommMonoid β] [Module K β] : Module K (α →ₛ β) :=
Function.Injective.module K ⟨⟨fun f => show α → β from f, coe_zero⟩, coe_add⟩
coe_injective coe_smul
theorem smul_eq_map [SMul K β] (k : K) (f : α →ₛ β) : k • f = f.map (k • ·) :=
rfl
section Preorder
variable [Preorder β] {s : Set α} {f f₁ f₂ g g₁ g₂ : α →ₛ β} {hs : MeasurableSet s}
instance instPreorder : Preorder (α →ₛ β) := Preorder.lift (⇑)
@[norm_cast] lemma coe_le_coe : ⇑f ≤ g ↔ f ≤ g := .rfl
@[simp, norm_cast] lemma coe_lt_coe : ⇑f < g ↔ f < g := .rfl
@[simp] lemma mk_le_mk {f g : α → β} {hf hg hf' hg'} : mk f hf hf' ≤ mk g hg hg' ↔ f ≤ g := Iff.rfl
@[simp] lemma mk_lt_mk {f g : α → β} {hf hg hf' hg'} : mk f hf hf' < mk g hg hg' ↔ f < g := Iff.rfl
@[gcongr] protected alias ⟨_, GCongr.mk_le_mk⟩ := mk_le_mk
@[gcongr] protected alias ⟨_, GCongr.mk_lt_mk⟩ := mk_lt_mk
@[gcongr] protected alias ⟨_, GCongr.coe_le_coe⟩ := coe_le_coe
@[gcongr] protected alias ⟨_, GCongr.coe_lt_coe⟩ := coe_lt_coe
open scoped Classical in
@[gcongr]
lemma piecewise_mono (hf : ∀ a ∈ s, f₁ a ≤ f₂ a) (hg : ∀ a ∉ s, g₁ a ≤ g₂ a) :
piecewise s hs f₁ g₁ ≤ piecewise s hs f₂ g₂ := Set.piecewise_mono hf hg
end Preorder
instance instPartialOrder [PartialOrder β] : PartialOrder (α →ₛ β) :=
{ SimpleFunc.instPreorder with
le_antisymm := fun _f _g hfg hgf => ext fun a => le_antisymm (hfg a) (hgf a) }
instance instOrderBot [LE β] [OrderBot β] : OrderBot (α →ₛ β) where
bot := const α ⊥
bot_le _ _ := bot_le
instance instOrderTop [LE β] [OrderTop β] : OrderTop (α →ₛ β) where
top := const α ⊤
le_top _ _ := le_top
@[to_additive]
instance [CommMonoid β] [PartialOrder β] [IsOrderedMonoid β] :
IsOrderedMonoid (α →ₛ β) where
mul_le_mul_left _ _ h _ _ := mul_le_mul_left' (h _) _
instance instSemilatticeInf [SemilatticeInf β] : SemilatticeInf (α →ₛ β) :=
{ SimpleFunc.instPartialOrder with
inf := (· ⊓ ·)
inf_le_left := fun _ _ _ => inf_le_left
inf_le_right := fun _ _ _ => inf_le_right
le_inf := fun _f _g _h hfh hgh a => le_inf (hfh a) (hgh a) }
instance instSemilatticeSup [SemilatticeSup β] : SemilatticeSup (α →ₛ β) :=
{ SimpleFunc.instPartialOrder with
sup := (· ⊔ ·)
le_sup_left := fun _ _ _ => le_sup_left
le_sup_right := fun _ _ _ => le_sup_right
sup_le := fun _f _g _h hfh hgh a => sup_le (hfh a) (hgh a) }
instance instLattice [Lattice β] : Lattice (α →ₛ β) :=
{ SimpleFunc.instSemilatticeSup, SimpleFunc.instSemilatticeInf with }
instance instBoundedOrder [LE β] [BoundedOrder β] : BoundedOrder (α →ₛ β) :=
{ SimpleFunc.instOrderBot, SimpleFunc.instOrderTop with }
theorem finset_sup_apply [SemilatticeSup β] [OrderBot β] {f : γ → α →ₛ β} (s : Finset γ) (a : α) :
s.sup f a = s.sup fun c => f c a := by
classical
refine Finset.induction_on s rfl ?_
intro a s _ ih
rw [Finset.sup_insert, Finset.sup_insert, sup_apply, ih]
section Restrict
variable [Zero β]
open scoped Classical in
/-- Restrict a simple function `f : α →ₛ β` to a set `s`. If `s` is measurable,
then `f.restrict s a = if a ∈ s then f a else 0`, otherwise `f.restrict s = const α 0`. -/
def restrict (f : α →ₛ β) (s : Set α) : α →ₛ β :=
if hs : MeasurableSet s then piecewise s hs f 0 else 0
theorem restrict_of_not_measurable {f : α →ₛ β} {s : Set α} (hs : ¬MeasurableSet s) :
restrict f s = 0 :=
dif_neg hs
@[simp]
theorem coe_restrict (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) :
⇑(restrict f s) = indicator s f := by
classical
rw [restrict, dif_pos hs, coe_piecewise, coe_zero, piecewise_eq_indicator]
@[simp]
theorem restrict_univ (f : α →ₛ β) : restrict f univ = f := by simp [restrict]
@[simp]
theorem restrict_empty (f : α →ₛ β) : restrict f ∅ = 0 := by simp [restrict]
open scoped Classical in
theorem map_restrict_of_zero [Zero γ] {g : β → γ} (hg : g 0 = 0) (f : α →ₛ β) (s : Set α) :
(f.restrict s).map g = (f.map g).restrict s :=
ext fun x =>
if hs : MeasurableSet s then by simp [hs, Set.indicator_comp_of_zero hg]
else by simp [restrict_of_not_measurable hs, hg]
theorem map_coe_ennreal_restrict (f : α →ₛ ℝ≥0) (s : Set α) :
(f.restrict s).map ((↑) : ℝ≥0 → ℝ≥0∞) = (f.map (↑)).restrict s :=
map_restrict_of_zero ENNReal.coe_zero _ _
theorem map_coe_nnreal_restrict (f : α →ₛ ℝ≥0) (s : Set α) :
(f.restrict s).map ((↑) : ℝ≥0 → ℝ) = (f.map (↑)).restrict s :=
map_restrict_of_zero NNReal.coe_zero _ _
theorem restrict_apply (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) (a) :
restrict f s a = indicator s f a := by simp only [f.coe_restrict hs]
theorem restrict_preimage (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) {t : Set β}
(ht : (0 : β) ∉ t) : restrict f s ⁻¹' t = s ∩ f ⁻¹' t := by
simp [hs, indicator_preimage_of_not_mem _ _ ht, inter_comm]
theorem restrict_preimage_singleton (f : α →ₛ β) {s : Set α} (hs : MeasurableSet s) {r : β}
(hr : r ≠ 0) : restrict f s ⁻¹' {r} = s ∩ f ⁻¹' {r} :=
f.restrict_preimage hs hr.symm
theorem mem_restrict_range {r : β} {s : Set α} {f : α →ₛ β} (hs : MeasurableSet s) :
r ∈ (restrict f s).range ↔ r = 0 ∧ s ≠ univ ∨ r ∈ f '' s := by
rw [← Finset.mem_coe, coe_range, coe_restrict _ hs, mem_range_indicator]
open scoped Classical in
theorem mem_image_of_mem_range_restrict {r : β} {s : Set α} {f : α →ₛ β}
(hr : r ∈ (restrict f s).range) (h0 : r ≠ 0) : r ∈ f '' s :=
if hs : MeasurableSet s then by simpa [mem_restrict_range hs, h0, -mem_range] using hr
else by
rw [restrict_of_not_measurable hs] at hr
exact (h0 <| eq_zero_of_mem_range_zero hr).elim
open scoped Classical in
@[gcongr, mono]
theorem restrict_mono [Preorder β] (s : Set α) {f g : α →ₛ β} (H : f ≤ g) :
f.restrict s ≤ g.restrict s :=
if hs : MeasurableSet s then fun x => by
simp only [coe_restrict _ hs, indicator_le_indicator (H x)]
else by simp only [restrict_of_not_measurable hs, le_refl]
end Restrict
section Approx
section
variable [SemilatticeSup β] [OrderBot β] [Zero β]
/-- Fix a sequence `i : ℕ → β`. Given a function `α → β`, its `n`-th approximation
by simple functions is defined so that in case `β = ℝ≥0∞` it sends each `a` to the supremum
of the set `{i k | k ≤ n ∧ i k ≤ f a}`, see `approx_apply` and `iSup_approx_apply` for details. -/
def approx (i : ℕ → β) (f : α → β) (n : ℕ) : α →ₛ β :=
(Finset.range n).sup fun k => restrict (const α (i k)) { a : α | i k ≤ f a }
open scoped Classical in
theorem approx_apply [TopologicalSpace β] [OrderClosedTopology β] [MeasurableSpace β]
[OpensMeasurableSpace β] {i : ℕ → β} {f : α → β} {n : ℕ} (a : α) (hf : Measurable f) :
(approx i f n : α →ₛ β) a = (Finset.range n).sup fun k => if i k ≤ f a then i k else 0 := by
dsimp only [approx]
rw [finset_sup_apply]
congr
funext k
rw [restrict_apply]
· simp only [coe_const, mem_setOf_eq, indicator_apply, Function.const_apply]
· exact hf measurableSet_Ici
theorem monotone_approx (i : ℕ → β) (f : α → β) : Monotone (approx i f) := fun _ _ h =>
Finset.sup_mono <| Finset.range_subset.2 h
theorem approx_comp [TopologicalSpace β] [OrderClosedTopology β] [MeasurableSpace β]
[OpensMeasurableSpace β] [MeasurableSpace γ] {i : ℕ → β} {f : γ → β} {g : α → γ} {n : ℕ} (a : α)
(hf : Measurable f) (hg : Measurable g) :
(approx i (f ∘ g) n : α →ₛ β) a = (approx i f n : γ →ₛ β) (g a) := by
rw [approx_apply _ hf, approx_apply _ (hf.comp hg), Function.comp_apply]
end
theorem iSup_approx_apply [TopologicalSpace β] [CompleteLattice β] [OrderClosedTopology β] [Zero β]
[MeasurableSpace β] [OpensMeasurableSpace β] (i : ℕ → β) (f : α → β) (a : α) (hf : Measurable f)
(h_zero : (0 : β) = ⊥) : ⨆ n, (approx i f n : α →ₛ β) a = ⨆ (k) (_ : i k ≤ f a), i k := by
refine le_antisymm (iSup_le fun n => ?_) (iSup_le fun k => iSup_le fun hk => ?_)
· rw [approx_apply a hf, h_zero]
refine Finset.sup_le fun k _ => ?_
split_ifs with h
· exact le_iSup_of_le k (le_iSup (fun _ : i k ≤ f a => i k) h)
· exact bot_le
· refine le_iSup_of_le (k + 1) ?_
rw [approx_apply a hf]
have : k ∈ Finset.range (k + 1) := Finset.mem_range.2 (Nat.lt_succ_self _)
refine le_trans (le_of_eq ?_) (Finset.le_sup this)
rw [if_pos hk]
end Approx
section EApprox
variable {f : α → ℝ≥0∞}
/-- A sequence of `ℝ≥0∞`s such that its range is the set of non-negative rational numbers. -/
def ennrealRatEmbed (n : ℕ) : ℝ≥0∞ :=
ENNReal.ofReal ((Encodable.decode (α := ℚ) n).getD (0 : ℚ))
theorem ennrealRatEmbed_encode (q : ℚ) :
ennrealRatEmbed (Encodable.encode q) = Real.toNNReal q := by
rw [ennrealRatEmbed, Encodable.encodek]; rfl
/-- Approximate a function `α → ℝ≥0∞` by a sequence of simple functions. -/
def eapprox : (α → ℝ≥0∞) → ℕ → α →ₛ ℝ≥0∞ :=
approx ennrealRatEmbed
theorem eapprox_lt_top (f : α → ℝ≥0∞) (n : ℕ) (a : α) : eapprox f n a < ∞ := by
simp only [eapprox, approx, finset_sup_apply, Finset.mem_range, ENNReal.bot_eq_zero, restrict]
rw [Finset.sup_lt_iff (α := ℝ≥0∞) WithTop.top_pos]
intro b _
split_ifs
· simp only [coe_zero, coe_piecewise, piecewise_eq_indicator, coe_const]
calc
{ a : α | ennrealRatEmbed b ≤ f a }.indicator (fun _ => ennrealRatEmbed b) a ≤
ennrealRatEmbed b :=
indicator_le_self _ _ a
_ < ⊤ := ENNReal.coe_lt_top
· exact WithTop.top_pos
@[mono]
theorem monotone_eapprox (f : α → ℝ≥0∞) : Monotone (eapprox f) :=
monotone_approx _ f
@[gcongr]
lemma eapprox_mono {m n : ℕ} (hmn : m ≤ n) : eapprox f m ≤ eapprox f n := monotone_eapprox _ hmn
lemma iSup_eapprox_apply (hf : Measurable f) (a : α) : ⨆ n, (eapprox f n : α →ₛ ℝ≥0∞) a = f a := by
rw [eapprox, iSup_approx_apply ennrealRatEmbed f a hf rfl]
refine le_antisymm (iSup_le fun i => iSup_le fun hi => hi) (le_of_not_gt ?_)
intro h
rcases ENNReal.lt_iff_exists_rat_btwn.1 h with ⟨q, _, lt_q, q_lt⟩
have :
(Real.toNNReal q : ℝ≥0∞) ≤ ⨆ (k : ℕ) (_ : ennrealRatEmbed k ≤ f a), ennrealRatEmbed k := by
refine le_iSup_of_le (Encodable.encode q) ?_
rw [ennrealRatEmbed_encode q]
exact le_iSup_of_le (le_of_lt q_lt) le_rfl
exact lt_irrefl _ (lt_of_le_of_lt this lt_q)
lemma iSup_coe_eapprox (hf : Measurable f) : ⨆ n, ⇑(eapprox f n) = f := by
simpa [funext_iff] using iSup_eapprox_apply hf
theorem eapprox_comp [MeasurableSpace γ] {f : γ → ℝ≥0∞} {g : α → γ} {n : ℕ} (hf : Measurable f)
(hg : Measurable g) : (eapprox (f ∘ g) n : α → ℝ≥0∞) = (eapprox f n : γ →ₛ ℝ≥0∞) ∘ g :=
funext fun a => approx_comp a hf hg
lemma tendsto_eapprox {f : α → ℝ≥0∞} (hf_meas : Measurable f) (a : α) :
Tendsto (fun n ↦ eapprox f n a) atTop (𝓝 (f a)) := by
nth_rw 2 [← iSup_coe_eapprox hf_meas]
rw [iSup_apply]
exact tendsto_atTop_iSup fun _ _ hnm ↦ monotone_eapprox f hnm a
/-- Approximate a function `α → ℝ≥0∞` by a series of simple functions taking their values
in `ℝ≥0`. -/
def eapproxDiff (f : α → ℝ≥0∞) : ℕ → α →ₛ ℝ≥0
| 0 => (eapprox f 0).map ENNReal.toNNReal
| n + 1 => (eapprox f (n + 1) - eapprox f n).map ENNReal.toNNReal
theorem sum_eapproxDiff (f : α → ℝ≥0∞) (n : ℕ) (a : α) :
(∑ k ∈ Finset.range (n + 1), (eapproxDiff f k a : ℝ≥0∞)) = eapprox f n a := by
induction' n with n IH
· simp only [Nat.zero_add, Finset.sum_singleton, Finset.range_one]
rfl
· rw [Finset.sum_range_succ, IH, eapproxDiff, coe_map, Function.comp_apply,
coe_sub, Pi.sub_apply, ENNReal.coe_toNNReal,
add_tsub_cancel_of_le (monotone_eapprox f (Nat.le_succ _) _)]
apply (lt_of_le_of_lt _ (eapprox_lt_top f (n + 1) a)).ne
rw [tsub_le_iff_right]
exact le_self_add
theorem tsum_eapproxDiff (f : α → ℝ≥0∞) (hf : Measurable f) (a : α) :
(∑' n, (eapproxDiff f n a : ℝ≥0∞)) = f a := by
simp_rw [ENNReal.tsum_eq_iSup_nat' (tendsto_add_atTop_nat 1), sum_eapproxDiff,
iSup_eapprox_apply hf a]
end EApprox
end Measurable
section Measure
variable {m : MeasurableSpace α} {μ ν : Measure α}
/-- Integral of a simple function whose codomain is `ℝ≥0∞`. -/
def lintegral {_m : MeasurableSpace α} (f : α →ₛ ℝ≥0∞) (μ : Measure α) : ℝ≥0∞ :=
∑ x ∈ f.range, x * μ (f ⁻¹' {x})
theorem lintegral_eq_of_subset (f : α →ₛ ℝ≥0∞) {s : Finset ℝ≥0∞}
(hs : ∀ x, f x ≠ 0 → μ (f ⁻¹' {f x}) ≠ 0 → f x ∈ s) :
f.lintegral μ = ∑ x ∈ s, x * μ (f ⁻¹' {x}) := by
refine Finset.sum_bij_ne_zero (fun r _ _ => r) ?_ ?_ ?_ ?_
· simpa only [forall_mem_range, mul_ne_zero_iff, and_imp]
· intros
assumption
· intro b _ hb
refine ⟨b, ?_, hb, rfl⟩
rw [mem_range, ← preimage_singleton_nonempty]
exact nonempty_of_measure_ne_zero (mul_ne_zero_iff.1 hb).2
· intros
rfl
theorem lintegral_eq_of_subset' (f : α →ₛ ℝ≥0∞) {s : Finset ℝ≥0∞} (hs : f.range \ {0} ⊆ s) :
f.lintegral μ = ∑ x ∈ s, x * μ (f ⁻¹' {x}) :=
f.lintegral_eq_of_subset fun x hfx _ =>
hs <| Finset.mem_sdiff.2 ⟨f.mem_range_self x, mt Finset.mem_singleton.1 hfx⟩
/-- Calculate the integral of `(g ∘ f)`, where `g : β → ℝ≥0∞` and `f : α →ₛ β`. -/
theorem map_lintegral (g : β → ℝ≥0∞) (f : α →ₛ β) :
(f.map g).lintegral μ = ∑ x ∈ f.range, g x * μ (f ⁻¹' {x}) := by
simp only [lintegral, range_map]
refine Finset.sum_image' _ fun b hb => ?_
rcases mem_range.1 hb with ⟨a, rfl⟩
rw [map_preimage_singleton, ← f.sum_measure_preimage_singleton, Finset.mul_sum]
refine Finset.sum_congr ?_ ?_
· congr
· intro x
simp only [Finset.mem_filter]
rintro ⟨_, h⟩
rw [h]
theorem add_lintegral (f g : α →ₛ ℝ≥0∞) : (f + g).lintegral μ = f.lintegral μ + g.lintegral μ :=
calc
(f + g).lintegral μ =
∑ x ∈ (pair f g).range, (x.1 * μ (pair f g ⁻¹' {x}) + x.2 * μ (pair f g ⁻¹' {x})) := by
rw [add_eq_map₂, map_lintegral]; exact Finset.sum_congr rfl fun a _ => add_mul _ _ _
_ = (∑ x ∈ (pair f g).range, x.1 * μ (pair f g ⁻¹' {x})) +
∑ x ∈ (pair f g).range, x.2 * μ (pair f g ⁻¹' {x}) := by
rw [Finset.sum_add_distrib]
_ = ((pair f g).map Prod.fst).lintegral μ + ((pair f g).map Prod.snd).lintegral μ := by
rw [map_lintegral, map_lintegral]
_ = lintegral f μ + lintegral g μ := rfl
theorem const_mul_lintegral (f : α →ₛ ℝ≥0∞) (x : ℝ≥0∞) :
(const α x * f).lintegral μ = x * f.lintegral μ :=
calc
(f.map fun a => x * a).lintegral μ = ∑ r ∈ f.range, x * r * μ (f ⁻¹' {r}) := map_lintegral _ _
_ = x * ∑ r ∈ f.range, r * μ (f ⁻¹' {r}) := by simp_rw [Finset.mul_sum, mul_assoc]
/-- Integral of a simple function `α →ₛ ℝ≥0∞` as a bilinear map. -/
def lintegralₗ {m : MeasurableSpace α} : (α →ₛ ℝ≥0∞) →ₗ[ℝ≥0∞] Measure α →ₗ[ℝ≥0∞] ℝ≥0∞ where
toFun f :=
{ toFun := lintegral f
map_add' := by simp [lintegral, mul_add, Finset.sum_add_distrib]
map_smul' := fun c μ => by
simp [lintegral, mul_left_comm _ c, Finset.mul_sum, Measure.smul_apply c] }
map_add' f g := LinearMap.ext fun _ => add_lintegral f g
map_smul' c f := LinearMap.ext fun _ => const_mul_lintegral f c
@[simp]
theorem zero_lintegral : (0 : α →ₛ ℝ≥0∞).lintegral μ = 0 :=
LinearMap.ext_iff.1 lintegralₗ.map_zero μ
theorem lintegral_add {ν} (f : α →ₛ ℝ≥0∞) : f.lintegral (μ + ν) = f.lintegral μ + f.lintegral ν :=
(lintegralₗ f).map_add μ ν
theorem lintegral_smul {R : Type*} [SMul R ℝ≥0∞] [IsScalarTower R ℝ≥0∞ ℝ≥0∞]
(f : α →ₛ ℝ≥0∞) (c : R) : f.lintegral (c • μ) = c • f.lintegral μ := by
simpa only [smul_one_smul] using (lintegralₗ f).map_smul (c • 1) μ
@[simp]
theorem lintegral_zero [MeasurableSpace α] (f : α →ₛ ℝ≥0∞) : f.lintegral 0 = 0 :=
(lintegralₗ f).map_zero
theorem lintegral_finset_sum {ι} (f : α →ₛ ℝ≥0∞) (μ : ι → Measure α) (s : Finset ι) :
f.lintegral (∑ i ∈ s, μ i) = ∑ i ∈ s, f.lintegral (μ i) :=
map_sum (lintegralₗ f) ..
theorem lintegral_sum {m : MeasurableSpace α} {ι} (f : α →ₛ ℝ≥0∞) (μ : ι → Measure α) :
f.lintegral (Measure.sum μ) = ∑' i, f.lintegral (μ i) := by
simp only [lintegral, Measure.sum_apply, f.measurableSet_preimage, ← Finset.tsum_subtype, ←
ENNReal.tsum_mul_left]
apply ENNReal.tsum_comm
open scoped Classical in
theorem restrict_lintegral (f : α →ₛ ℝ≥0∞) {s : Set α} (hs : MeasurableSet s) :
(restrict f s).lintegral μ = ∑ r ∈ f.range, r * μ (f ⁻¹' {r} ∩ s) :=
calc
(restrict f s).lintegral μ = ∑ r ∈ f.range, r * μ (restrict f s ⁻¹' {r}) :=
lintegral_eq_of_subset _ fun x hx =>
if hxs : x ∈ s then fun _ => by
simp only [f.restrict_apply hs, indicator_of_mem hxs, mem_range_self]
else False.elim <| hx <| by simp [*]
_ = ∑ r ∈ f.range, r * μ (f ⁻¹' {r} ∩ s) :=
Finset.sum_congr rfl <|
forall_mem_range.2 fun b =>
if hb : f b = 0 then by simp only [hb, zero_mul]
else by rw [restrict_preimage_singleton _ hs hb, inter_comm]
theorem lintegral_restrict {m : MeasurableSpace α} (f : α →ₛ ℝ≥0∞) (s : Set α) (μ : Measure α) :
f.lintegral (μ.restrict s) = ∑ y ∈ f.range, y * μ (f ⁻¹' {y} ∩ s) := by
simp only [lintegral, Measure.restrict_apply, f.measurableSet_preimage]
theorem restrict_lintegral_eq_lintegral_restrict (f : α →ₛ ℝ≥0∞) {s : Set α}
(hs : MeasurableSet s) : (restrict f s).lintegral μ = f.lintegral (μ.restrict s) := by
rw [f.restrict_lintegral hs, lintegral_restrict]
theorem lintegral_restrict_iUnion_of_directed {ι : Type*} [Countable ι]
(f : α →ₛ ℝ≥0∞) {s : ι → Set α} (hd : Directed (· ⊆ ·) s) (μ : Measure α) :
f.lintegral (μ.restrict (⋃ i, s i)) = ⨆ i, f.lintegral (μ.restrict (s i)) := by
simp only [lintegral, Measure.restrict_iUnion_apply_eq_iSup hd (measurableSet_preimage ..),
ENNReal.mul_iSup]
refine finsetSum_iSup fun i j ↦ (hd i j).imp fun k ⟨hik, hjk⟩ ↦ fun a ↦ ?_
-- TODO https://github.com/leanprover-community/mathlib4/pull/14739 make `gcongr` close this goal
constructor <;> · gcongr; refine Measure.restrict_mono ?_ le_rfl _; assumption
theorem const_lintegral (c : ℝ≥0∞) : (const α c).lintegral μ = c * μ univ := by
rw [lintegral]
cases isEmpty_or_nonempty α
· simp [μ.eq_zero_of_isEmpty]
· simp only [range_const, coe_const, Finset.sum_singleton]
unfold Function.const; rw [preimage_const_of_mem (mem_singleton c)]
theorem const_lintegral_restrict (c : ℝ≥0∞) (s : Set α) :
(const α c).lintegral (μ.restrict s) = c * μ s := by
rw [const_lintegral, Measure.restrict_apply MeasurableSet.univ, univ_inter]
theorem restrict_const_lintegral (c : ℝ≥0∞) {s : Set α} (hs : MeasurableSet s) :
((const α c).restrict s).lintegral μ = c * μ s := by
rw [restrict_lintegral_eq_lintegral_restrict _ hs, const_lintegral_restrict]
@[gcongr]
theorem lintegral_mono_fun {f g : α →ₛ ℝ≥0∞} (h : f ≤ g) : f.lintegral μ ≤ g.lintegral μ := by
refine Monotone.of_left_le_map_sup (f := (lintegral · μ)) (fun f g ↦ ?_) h
calc
f.lintegral μ = ((pair f g).map Prod.fst).lintegral μ := by rw [map_fst_pair]
_ ≤ ((pair f g).map fun p ↦ p.1 ⊔ p.2).lintegral μ := by
simp only [map_lintegral]
gcongr
exact le_sup_left
theorem le_sup_lintegral (f g : α →ₛ ℝ≥0∞) : f.lintegral μ ⊔ g.lintegral μ ≤ (f ⊔ g).lintegral μ :=
Monotone.le_map_sup (fun _ _ ↦ lintegral_mono_fun) f g
@[gcongr]
theorem lintegral_mono_measure {f : α →ₛ ℝ≥0∞} (h : μ ≤ ν) : f.lintegral μ ≤ f.lintegral ν := by
simp only [lintegral]
gcongr
apply h
/-- `SimpleFunc.lintegral` is monotone both in function and in measure. -/
@[mono, gcongr]
theorem lintegral_mono {f g : α →ₛ ℝ≥0∞} (hfg : f ≤ g) (hμν : μ ≤ ν) :
f.lintegral μ ≤ g.lintegral ν :=
(lintegral_mono_fun hfg).trans (lintegral_mono_measure hμν)
/-- `SimpleFunc.lintegral` depends only on the measures of `f ⁻¹' {y}`. -/
theorem lintegral_eq_of_measure_preimage [MeasurableSpace β] {f : α →ₛ ℝ≥0∞} {g : β →ₛ ℝ≥0∞}
{ν : Measure β} (H : ∀ y, μ (f ⁻¹' {y}) = ν (g ⁻¹' {y})) : f.lintegral μ = g.lintegral ν := by
simp only [lintegral, ← H]
apply lintegral_eq_of_subset
simp only [H]
intros
exact mem_range_of_measure_ne_zero ‹_›
/-- If two simple functions are equal a.e., then their `lintegral`s are equal. -/
theorem lintegral_congr {f g : α →ₛ ℝ≥0∞} (h : f =ᵐ[μ] g) : f.lintegral μ = g.lintegral μ :=
lintegral_eq_of_measure_preimage fun y =>
measure_congr <| Eventually.set_eq <| h.mono fun x hx => by simp [hx]
theorem lintegral_map' {β} [MeasurableSpace β] {μ' : Measure β} (f : α →ₛ ℝ≥0∞) (g : β →ₛ ℝ≥0∞)
(m' : α → β) (eq : ∀ a, f a = g (m' a)) (h : ∀ s, MeasurableSet s → μ' s = μ (m' ⁻¹' s)) :
f.lintegral μ = g.lintegral μ' :=
lintegral_eq_of_measure_preimage fun y => by
simp only [preimage, eq]
exact (h (g ⁻¹' {y}) (g.measurableSet_preimage _)).symm
theorem lintegral_map {β} [MeasurableSpace β] (g : β →ₛ ℝ≥0∞) {f : α → β} (hf : Measurable f) :
g.lintegral (Measure.map f μ) = (g.comp f hf).lintegral μ :=
Eq.symm <| lintegral_map' _ _ f (fun _ => rfl) fun _s hs => Measure.map_apply hf hs
end Measure
section FinMeasSupp
open Finset Function
open scoped Classical in
theorem support_eq [MeasurableSpace α] [Zero β] (f : α →ₛ β) :
support f = ⋃ y ∈ {y ∈ f.range | y ≠ 0}, f ⁻¹' {y} :=
Set.ext fun x => by
simp only [mem_support, Set.mem_preimage, mem_filter, mem_range_self, true_and, exists_prop,
mem_iUnion, Set.mem_range, mem_singleton_iff, exists_eq_right']
variable {m : MeasurableSpace α} [Zero β] [Zero γ] {μ : Measure α} {f : α →ₛ β}
theorem measurableSet_support [MeasurableSpace α] (f : α →ₛ β) : MeasurableSet (support f) := by
rw [f.support_eq]
exact Finset.measurableSet_biUnion _ fun y _ => measurableSet_fiber _ _
lemma measure_support_lt_top (f : α →ₛ β) (hf : ∀ y, y ≠ 0 → μ (f ⁻¹' {y}) < ∞) :
μ (support f) < ∞ := by
classical
rw [support_eq]
refine (measure_biUnion_finset_le _ _).trans_lt (ENNReal.sum_lt_top.mpr fun y hy => ?_)
rw [Finset.mem_filter] at hy
exact hf y hy.2
/-- A `SimpleFunc` has finite measure support if it is equal to `0` outside of a set of finite
measure. -/
protected def FinMeasSupp {_m : MeasurableSpace α} (f : α →ₛ β) (μ : Measure α) : Prop :=
f =ᶠ[μ.cofinite] 0
theorem finMeasSupp_iff_support : f.FinMeasSupp μ ↔ μ (support f) < ∞ :=
Iff.rfl
theorem finMeasSupp_iff : f.FinMeasSupp μ ↔ ∀ y, y ≠ 0 → μ (f ⁻¹' {y}) < ∞ := by
classical
constructor
· refine fun h y hy => lt_of_le_of_lt (measure_mono ?_) h
exact fun x hx (H : f x = 0) => hy <| H ▸ Eq.symm hx
· intro H
rw [finMeasSupp_iff_support, support_eq]
exact measure_biUnion_lt_top (finite_toSet _) fun y hy ↦ H y (mem_filter.1 hy).2
namespace FinMeasSupp
theorem meas_preimage_singleton_ne_zero (h : f.FinMeasSupp μ) {y : β} (hy : y ≠ 0) :
μ (f ⁻¹' {y}) < ∞ :=
finMeasSupp_iff.1 h y hy
protected theorem map {g : β → γ} (hf : f.FinMeasSupp μ) (hg : g 0 = 0) : (f.map g).FinMeasSupp μ :=
flip lt_of_le_of_lt hf (measure_mono <| support_comp_subset hg f)
theorem of_map {g : β → γ} (h : (f.map g).FinMeasSupp μ) (hg : ∀ b, g b = 0 → b = 0) :
f.FinMeasSupp μ :=
flip lt_of_le_of_lt h <| measure_mono <| support_subset_comp @(hg) _
theorem map_iff {g : β → γ} (hg : ∀ {b}, g b = 0 ↔ b = 0) :
(f.map g).FinMeasSupp μ ↔ f.FinMeasSupp μ :=
⟨fun h => h.of_map fun _ => hg.1, fun h => h.map <| hg.2 rfl⟩
protected theorem pair {g : α →ₛ γ} (hf : f.FinMeasSupp μ) (hg : g.FinMeasSupp μ) :
(pair f g).FinMeasSupp μ :=
calc
μ (support <| pair f g) = μ (support f ∪ support g) := congr_arg μ <| support_prod_mk f g
_ ≤ μ (support f) + μ (support g) := measure_union_le _ _
_ < _ := add_lt_top.2 ⟨hf, hg⟩
protected theorem map₂ [Zero δ] (hf : f.FinMeasSupp μ) {g : α →ₛ γ} (hg : g.FinMeasSupp μ)
{op : β → γ → δ} (H : op 0 0 = 0) : ((pair f g).map (Function.uncurry op)).FinMeasSupp μ :=
(hf.pair hg).map H
protected theorem add {β} [AddZeroClass β] {f g : α →ₛ β} (hf : f.FinMeasSupp μ)
(hg : g.FinMeasSupp μ) : (f + g).FinMeasSupp μ := by
rw [add_eq_map₂]
exact hf.map₂ hg (zero_add 0)
protected theorem mul {β} [MulZeroClass β] {f g : α →ₛ β} (hf : f.FinMeasSupp μ)
(hg : g.FinMeasSupp μ) : (f * g).FinMeasSupp μ := by
rw [mul_eq_map₂]
exact hf.map₂ hg (zero_mul 0)
theorem lintegral_lt_top {f : α →ₛ ℝ≥0∞} (hm : f.FinMeasSupp μ) (hf : ∀ᵐ a ∂μ, f a ≠ ∞) :
f.lintegral μ < ∞ := by
refine sum_lt_top.2 fun a ha => ?_
rcases eq_or_ne a ∞ with (rfl | ha)
· simp only [ae_iff, Ne, Classical.not_not] at hf
simp [Set.preimage, hf]
· by_cases ha0 : a = 0
· subst a
simp
· exact mul_lt_top ha.lt_top (finMeasSupp_iff.1 hm _ ha0)
theorem of_lintegral_ne_top {f : α →ₛ ℝ≥0∞} (h : f.lintegral μ ≠ ∞) : f.FinMeasSupp μ := by
refine finMeasSupp_iff.2 fun b hb => ?_
rw [f.lintegral_eq_of_subset' (Finset.subset_insert b _)] at h
refine ENNReal.lt_top_of_mul_ne_top_right ?_ hb
exact (lt_top_of_sum_ne_top h (Finset.mem_insert_self _ _)).ne
theorem iff_lintegral_lt_top {f : α →ₛ ℝ≥0∞} (hf : ∀ᵐ a ∂μ, f a ≠ ∞) :
f.FinMeasSupp μ ↔ f.lintegral μ < ∞ :=
⟨fun h => h.lintegral_lt_top hf, fun h => of_lintegral_ne_top h.ne⟩
end FinMeasSupp
lemma measure_support_lt_top_of_lintegral_ne_top {f : α →ₛ ℝ≥0∞} (hf : f.lintegral μ ≠ ∞) :
μ (support f) < ∞ := by
refine measure_support_lt_top f ?_
rw [← finMeasSupp_iff]
exact FinMeasSupp.of_lintegral_ne_top hf
end FinMeasSupp
/-- To prove something for an arbitrary simple function, it suffices to show
that the property holds for (multiples of) characteristic functions and is closed under
addition (of functions with disjoint support).
It is possible to make the hypotheses in `h_add` a bit stronger, and such conditions can be added
once we need them (for example it is only necessary to consider the case where `g` is a multiple
of a characteristic function, and that this multiple doesn't appear in the image of `f`).
To use in an induction proof, the syntax is `induction f using SimpleFunc.induction with`. -/
@[elab_as_elim]
protected theorem induction {α γ} [MeasurableSpace α] [AddZeroClass γ]
{motive : SimpleFunc α γ → Prop}
(const : ∀ (c) {s} (hs : MeasurableSet s),
motive (SimpleFunc.piecewise s hs (SimpleFunc.const _ c) (SimpleFunc.const _ 0)))
(add : ∀ ⦃f g : SimpleFunc α γ⦄,
Disjoint (support f) (support g) → motive f → motive g → motive (f + g))
(f : SimpleFunc α γ) : motive f := by
classical
generalize h : f.range \ {0} = s
rw [← Finset.coe_inj, Finset.coe_sdiff, Finset.coe_singleton, SimpleFunc.coe_range] at h
induction s using Finset.induction generalizing f with
| empty =>
| rw [Finset.coe_empty, diff_eq_empty, range_subset_singleton] at h
convert const 0 MeasurableSet.univ
ext x
simp [h]
| insert x s hxs ih =>
| Mathlib/MeasureTheory/Function/SimpleFunc.lean | 1,162 | 1,166 |
/-
Copyright (c) 2020 Rémy Degenne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Rémy Degenne, Eric Wieser
-/
import Mathlib.Data.ENNReal.Holder
import Mathlib.MeasureTheory.Function.LpSeminorm.Basic
import Mathlib.MeasureTheory.Integral.MeanInequalities
import Mathlib.Tactic.Finiteness
/-!
# Compare Lp seminorms for different values of `p`
In this file we compare `MeasureTheory.eLpNorm'` and `MeasureTheory.eLpNorm` for different
exponents.
-/
open Filter ENNReal
open scoped Topology
namespace MeasureTheory
section SameSpace
variable {α ε ε' : Type*} {m : MeasurableSpace α} {μ : Measure α} {f : α → ε}
[TopologicalSpace ε] [ContinuousENorm ε]
[TopologicalSpace ε'] [ENormedAddMonoid ε']
theorem eLpNorm'_le_eLpNorm'_mul_rpow_measure_univ {p q : ℝ} (hp0_lt : 0 < p) (hpq : p ≤ q)
(hf : AEStronglyMeasurable f μ) :
eLpNorm' f p μ ≤ eLpNorm' f q μ * μ Set.univ ^ (1 / p - 1 / q) := by
have hq0_lt : 0 < q := lt_of_lt_of_le hp0_lt hpq
by_cases hpq_eq : p = q
· rw [hpq_eq, sub_self, ENNReal.rpow_zero, mul_one]
have hpq : p < q := lt_of_le_of_ne hpq hpq_eq
let g := fun _ : α => (1 : ℝ≥0∞)
have h_rw : (∫⁻ a, ‖f a‖ₑ ^ p ∂μ) = ∫⁻ a, (‖f a‖ₑ * g a) ^ p ∂μ :=
lintegral_congr fun a => by simp [g]
repeat' rw [eLpNorm'_eq_lintegral_enorm]
rw [h_rw]
let r := p * q / (q - p)
have hpqr : 1 / p = 1 / q + 1 / r := by field_simp [r, hp0_lt.ne', hq0_lt.ne']
calc
(∫⁻ a : α, (‖f a‖ₑ * g a) ^ p ∂μ) ^ (1 / p) ≤
(∫⁻ a : α, ‖f a‖ₑ ^ q ∂μ) ^ (1 / q) * (∫⁻ a : α, g a ^ r ∂μ) ^ (1 / r) :=
ENNReal.lintegral_Lp_mul_le_Lq_mul_Lr hp0_lt hpq hpqr μ hf.enorm aemeasurable_const
_ = (∫⁻ a : α, ‖f a‖ₑ ^ q ∂μ) ^ (1 / q) * μ Set.univ ^ (1 / p - 1 / q) := by
rw [hpqr]; simp [r, g]
theorem eLpNorm'_le_eLpNormEssSup_mul_rpow_measure_univ {q : ℝ} (hq_pos : 0 < q) :
eLpNorm' f q μ ≤ eLpNormEssSup f μ * μ Set.univ ^ (1 / q) := by
have h_le : (∫⁻ a : α, ‖f a‖ₑ ^ q ∂μ) ≤ ∫⁻ _ : α, eLpNormEssSup f μ ^ q ∂μ := by
refine lintegral_mono_ae ?_
have h_nnnorm_le_eLpNorm_ess_sup := enorm_ae_le_eLpNormEssSup f μ
exact h_nnnorm_le_eLpNorm_ess_sup.mono fun x hx => by gcongr
rw [eLpNorm', ← ENNReal.rpow_one (eLpNormEssSup f μ)]
nth_rw 2 [← mul_inv_cancel₀ (ne_of_lt hq_pos).symm]
rw [ENNReal.rpow_mul, one_div, ← ENNReal.mul_rpow_of_nonneg _ _ (by simp [hq_pos.le] : 0 ≤ q⁻¹)]
gcongr
rwa [lintegral_const] at h_le
theorem eLpNorm_le_eLpNorm_mul_rpow_measure_univ {p q : ℝ≥0∞} (hpq : p ≤ q)
(hf : AEStronglyMeasurable f μ) :
eLpNorm f p μ ≤ eLpNorm f q μ * μ Set.univ ^ (1 / p.toReal - 1 / q.toReal) := by
by_cases hp0 : p = 0
· simp [hp0, zero_le]
rw [← Ne] at hp0
have hp0_lt : 0 < p := lt_of_le_of_ne (zero_le _) hp0.symm
have hq0_lt : 0 < q := lt_of_lt_of_le hp0_lt hpq
by_cases hq_top : q = ∞
· simp only [hq_top, _root_.div_zero, one_div, ENNReal.toReal_top, sub_zero, eLpNorm_exponent_top,
GroupWithZero.inv_zero]
by_cases hp_top : p = ∞
· simp only [hp_top, ENNReal.rpow_zero, mul_one, ENNReal.toReal_top, sub_zero,
GroupWithZero.inv_zero, eLpNorm_exponent_top]
exact le_rfl
rw [eLpNorm_eq_eLpNorm' hp0 hp_top]
have hp_pos : 0 < p.toReal := ENNReal.toReal_pos hp0_lt.ne' hp_top
refine (eLpNorm'_le_eLpNormEssSup_mul_rpow_measure_univ hp_pos).trans (le_of_eq ?_)
congr
exact one_div _
have hp_lt_top : p < ∞ := hpq.trans_lt (lt_top_iff_ne_top.mpr hq_top)
have hp_pos : 0 < p.toReal := ENNReal.toReal_pos hp0_lt.ne' hp_lt_top.ne
rw [eLpNorm_eq_eLpNorm' hp0_lt.ne.symm hp_lt_top.ne, eLpNorm_eq_eLpNorm' hq0_lt.ne.symm hq_top]
have hpq_real : p.toReal ≤ q.toReal := ENNReal.toReal_mono hq_top hpq
exact eLpNorm'_le_eLpNorm'_mul_rpow_measure_univ hp_pos hpq_real hf
theorem eLpNorm'_le_eLpNorm'_of_exponent_le {p q : ℝ} (hp0_lt : 0 < p)
(hpq : p ≤ q) (μ : Measure α) [IsProbabilityMeasure μ] (hf : AEStronglyMeasurable f μ) :
eLpNorm' f p μ ≤ eLpNorm' f q μ := by
have h_le_μ := eLpNorm'_le_eLpNorm'_mul_rpow_measure_univ hp0_lt hpq hf
rwa [measure_univ, ENNReal.one_rpow, mul_one] at h_le_μ
theorem eLpNorm'_le_eLpNormEssSup {q : ℝ} (hq_pos : 0 < q) [IsProbabilityMeasure μ] :
eLpNorm' f q μ ≤ eLpNormEssSup f μ :=
(eLpNorm'_le_eLpNormEssSup_mul_rpow_measure_univ hq_pos).trans_eq (by simp [measure_univ])
theorem eLpNorm_le_eLpNorm_of_exponent_le {p q : ℝ≥0∞} (hpq : p ≤ q) [IsProbabilityMeasure μ]
(hf : AEStronglyMeasurable f μ) : eLpNorm f p μ ≤ eLpNorm f q μ :=
(eLpNorm_le_eLpNorm_mul_rpow_measure_univ hpq hf).trans (le_of_eq (by simp [measure_univ]))
theorem eLpNorm'_lt_top_of_eLpNorm'_lt_top_of_exponent_le {p q : ℝ} [IsFiniteMeasure μ]
(hf : AEStronglyMeasurable f μ) (hfq_lt_top : eLpNorm' f q μ < ∞) (hp_nonneg : 0 ≤ p)
(hpq : p ≤ q) : eLpNorm' f p μ < ∞ := by
rcases le_or_lt p 0 with hp_nonpos | hp_pos
· rw [le_antisymm hp_nonpos hp_nonneg]
simp
have hq_pos : 0 < q := lt_of_lt_of_le hp_pos hpq
calc
eLpNorm' f p μ ≤ eLpNorm' f q μ * μ Set.univ ^ (1 / p - 1 / q) :=
eLpNorm'_le_eLpNorm'_mul_rpow_measure_univ hp_pos hpq hf
_ < ∞ := by
rw [ENNReal.mul_lt_top_iff]
refine Or.inl ⟨hfq_lt_top, ENNReal.rpow_lt_top_of_nonneg ?_ (measure_ne_top μ Set.univ)⟩
rwa [le_sub_comm, sub_zero, one_div, one_div, inv_le_inv₀ hq_pos hp_pos]
theorem MemLp.mono_exponent {p q : ℝ≥0∞} [IsFiniteMeasure μ] (hfq : MemLp f q μ)
(hpq : p ≤ q) : MemLp f p μ := by
obtain ⟨hfq_m, hfq_lt_top⟩ := hfq
by_cases hp0 : p = 0
· rwa [hp0, memLp_zero_iff_aestronglyMeasurable]
rw [← Ne] at hp0
refine ⟨hfq_m, ?_⟩
by_cases hp_top : p = ∞
· have hq_top : q = ∞ := by rwa [hp_top, top_le_iff] at hpq
rw [hp_top]
rwa [hq_top] at hfq_lt_top
have hp_pos : 0 < p.toReal := ENNReal.toReal_pos hp0 hp_top
by_cases hq_top : q = ∞
· rw [eLpNorm_eq_eLpNorm' hp0 hp_top]
rw [hq_top, eLpNorm_exponent_top] at hfq_lt_top
refine lt_of_le_of_lt (eLpNorm'_le_eLpNormEssSup_mul_rpow_measure_univ hp_pos) ?_
refine ENNReal.mul_lt_top hfq_lt_top ?_
exact ENNReal.rpow_lt_top_of_nonneg (by simp [hp_pos.le]) (measure_ne_top μ Set.univ)
have hq0 : q ≠ 0 := by
by_contra hq_eq_zero
have hp_eq_zero : p = 0 := le_antisymm (by rwa [hq_eq_zero] at hpq) (zero_le _)
rw [hp_eq_zero, ENNReal.toReal_zero] at hp_pos
exact (lt_irrefl _) hp_pos
have hpq_real : p.toReal ≤ q.toReal := ENNReal.toReal_mono hq_top hpq
rw [eLpNorm_eq_eLpNorm' hp0 hp_top]
rw [eLpNorm_eq_eLpNorm' hq0 hq_top] at hfq_lt_top
exact eLpNorm'_lt_top_of_eLpNorm'_lt_top_of_exponent_le hfq_m hfq_lt_top hp_pos.le hpq_real
@[deprecated (since := "2025-02-21")]
alias Memℒp.mono_exponent := MemLp.mono_exponent
@[deprecated (since := "2025-01-07")] alias MemLp.memℒp_of_exponent_le := MemLp.mono_exponent
/-- If a function is supported on a finite-measure set and belongs to `ℒ^p`, then it belongs to
`ℒ^q` for any `q ≤ p`. -/
lemma MemLp.mono_exponent_of_measure_support_ne_top {p q : ℝ≥0∞} {f : α → ε'} (hfq : MemLp f q μ)
{s : Set α} (hf : ∀ x, x ∉ s → f x = 0) (hs : μ s ≠ ∞) (hpq : p ≤ q) : MemLp f p μ := by
have : (toMeasurable μ s).indicator f = f := by
apply Set.indicator_eq_self.2
apply Function.support_subset_iff'.2 fun x hx ↦ hf x ?_
contrapose! hx
exact subset_toMeasurable μ s hx
rw [← this, memLp_indicator_iff_restrict (measurableSet_toMeasurable μ s)] at hfq ⊢
have : Fact (μ (toMeasurable μ s) < ∞) := ⟨by simpa [lt_top_iff_ne_top] using hs⟩
exact hfq.mono_exponent hpq
@[deprecated (since := "2025-02-21")]
alias Memℒp.mono_exponent_of_measure_support_ne_top := MemLp.mono_exponent_of_measure_support_ne_top
@[deprecated (since := "2025-01-07")]
alias MemLp.memℒp_of_exponent_le_of_measure_support_ne_top :=
MemLp.mono_exponent_of_measure_support_ne_top
end SameSpace
section Bilinear
variable {α E F G : Type*} {m : MeasurableSpace α}
[NormedAddCommGroup E] [NormedAddCommGroup F] [NormedAddCommGroup G] {μ : Measure α}
{f : α → E} {g : α → F}
open NNReal
theorem eLpNorm_le_eLpNorm_top_mul_eLpNorm (p : ℝ≥0∞) (f : α → E) {g : α → F}
(hg : AEStronglyMeasurable g μ) (b : E → F → G) (c : ℝ≥0)
(h : ∀ᵐ x ∂μ, ‖b (f x) (g x)‖₊ ≤ c * ‖f x‖₊ * ‖g x‖₊) :
eLpNorm (fun x => b (f x) (g x)) p μ ≤ c * eLpNorm f ∞ μ * eLpNorm g p μ := by
calc
eLpNorm (fun x => b (f x) (g x)) p μ ≤ eLpNorm (fun x => (c : ℝ) • ‖f x‖ * ‖g x‖) p μ :=
eLpNorm_mono_ae_real h
_ ≤ c * eLpNorm f ∞ μ * eLpNorm g p μ := ?_
simp only [smul_mul_assoc, ← Pi.smul_def, eLpNorm_const_smul]
rw [Real.enorm_eq_ofReal c.coe_nonneg, ENNReal.ofReal_coe_nnreal, mul_assoc]
gcongr
obtain (rfl | rfl | hp) := ENNReal.trichotomy p
· simp
· rw [← eLpNorm_norm f, ← eLpNorm_norm g]
simp_rw [eLpNorm_exponent_top, eLpNormEssSup_eq_essSup_enorm, enorm_mul, enorm_norm]
exact ENNReal.essSup_mul_le (‖f ·‖ₑ) (‖g ·‖ₑ)
obtain ⟨hp₁, hp₂⟩ := ENNReal.toReal_pos_iff.mp hp
simp_rw [eLpNorm_eq_lintegral_rpow_enorm hp₁.ne' hp₂.ne, eLpNorm_exponent_top, eLpNormEssSup,
one_div, ENNReal.rpow_inv_le_iff hp, enorm_mul, enorm_norm]
rw [ENNReal.mul_rpow_of_nonneg (hz := hp.le), ENNReal.rpow_inv_rpow hp.ne',
← lintegral_const_mul'' _ (by fun_prop)]
simp only [← ENNReal.mul_rpow_of_nonneg (hz := hp.le)]
apply lintegral_mono_ae
filter_upwards [h, enorm_ae_le_eLpNormEssSup f μ] with x hb hf
refine ENNReal.rpow_le_rpow ?_ hp.le
gcongr
exact hf
theorem eLpNorm_le_eLpNorm_mul_eLpNorm_top (p : ℝ≥0∞) {f : α → E} (hf : AEStronglyMeasurable f μ)
(g : α → F) (b : E → F → G) (c : ℝ≥0)
(h : ∀ᵐ x ∂μ, ‖b (f x) (g x)‖₊ ≤ c * ‖f x‖₊ * ‖g x‖₊) :
eLpNorm (fun x => b (f x) (g x)) p μ ≤ c * eLpNorm f p μ * eLpNorm g ∞ μ :=
calc
eLpNorm (fun x ↦ b (f x) (g x)) p μ ≤ c * eLpNorm g ∞ μ * eLpNorm f p μ :=
eLpNorm_le_eLpNorm_top_mul_eLpNorm p g hf (flip b) c <| by
convert h using 3 with x
simp only [mul_assoc, mul_comm ‖f x‖₊]
_ = c * eLpNorm f p μ * eLpNorm g ∞ μ := by
simp only [mul_assoc]; rw [mul_comm (eLpNorm _ _ _)]
theorem eLpNorm'_le_eLpNorm'_mul_eLpNorm' {p q r : ℝ} (hf : AEStronglyMeasurable f μ)
(hg : AEStronglyMeasurable g μ) (b : E → F → G) (c : ℝ≥0)
(h : ∀ᵐ x ∂μ, ‖b (f x) (g x)‖₊ ≤ c * ‖f x‖₊ * ‖g x‖₊) (hro_lt : 0 < r) (hrp : r < p)
(hpqr : 1 / r = 1 / p + 1 / q) :
eLpNorm' (fun x => b (f x) (g x)) r μ ≤ c * eLpNorm' f p μ * eLpNorm' g q μ := by
calc
eLpNorm' (fun x => b (f x) (g x)) r μ
≤ eLpNorm' (fun x ↦ (c : ℝ) • ‖f x‖ * ‖g x‖) r μ := by
simp only [eLpNorm']
refine (ENNReal.rpow_le_rpow_iff <| one_div_pos.mpr hro_lt).mpr <|
lintegral_mono_ae <| h.mono fun a ha ↦ (ENNReal.rpow_le_rpow_iff hro_lt).mpr <| ?_
simp only [enorm_eq_nnnorm, ENNReal.coe_le_coe, ← NNReal.coe_le_coe]
simpa [Real.nnnorm_of_nonneg (by positivity)] using ha
_ ≤ c * eLpNorm' f p μ * eLpNorm' g q μ := by
simp only [smul_mul_assoc, ← Pi.smul_def, eLpNorm'_const_smul _ hro_lt]
rw [Real.enorm_eq_ofReal c.coe_nonneg, ENNReal.ofReal_coe_nnreal, mul_assoc]
gcongr
simpa only [eLpNorm', enorm_mul, enorm_norm] using
ENNReal.lintegral_Lp_mul_le_Lq_mul_Lr hro_lt hrp hpqr μ hf.enorm hg.enorm
/-- Hölder's inequality, as an inequality on the `ℒp` seminorm of an elementwise operation
`fun x => b (f x) (g x)`. -/
theorem eLpNorm_le_eLpNorm_mul_eLpNorm_of_nnnorm {p q r : ℝ≥0∞}
(hf : AEStronglyMeasurable f μ) (hg : AEStronglyMeasurable g μ) (b : E → F → G) (c : ℝ≥0)
(h : ∀ᵐ x ∂μ, ‖b (f x) (g x)‖₊ ≤ c * ‖f x‖₊ * ‖g x‖₊) [hpqr : HolderTriple p q r] :
eLpNorm (fun x => b (f x) (g x)) r μ ≤ c * eLpNorm f p μ * eLpNorm g q μ := by
have hpqr := hpqr.one_div_eq
obtain (rfl | rfl | hp) := ENNReal.trichotomy p
· simp_all
· have : r = q := by simpa using hpqr
exact this ▸ eLpNorm_le_eLpNorm_top_mul_eLpNorm r f hg b c h
obtain (rfl | rfl | hq) := ENNReal.trichotomy q
· simp_all
· have : r = p := by simpa using hpqr
exact this ▸ eLpNorm_le_eLpNorm_mul_eLpNorm_top p hf g b c h
obtain ⟨hp₁, hp₂⟩ := ENNReal.toReal_pos_iff.mp hp
obtain ⟨hq₁, hq₂⟩ := ENNReal.toReal_pos_iff.mp hq
have hpqr' : 1 / r.toReal = 1 / p.toReal + 1 / q.toReal := by
have := congr(ENNReal.toReal $(hpqr))
rw [ENNReal.toReal_add (by simpa using hp₁.ne') (by simpa using hq₁.ne')] at this
simpa
have hr : 0 < r.toReal := one_div_pos.mp <| by rw [hpqr']; positivity
obtain ⟨hr₁, hr₂⟩ := ENNReal.toReal_pos_iff.mp hr
have hrp : r.toReal < p.toReal := lt_of_one_div_lt_one_div hp <|
hpqr' ▸ lt_add_of_pos_right _ (by positivity)
rw [eLpNorm_eq_eLpNorm', eLpNorm_eq_eLpNorm', eLpNorm_eq_eLpNorm']
· exact eLpNorm'_le_eLpNorm'_mul_eLpNorm' hf hg b c h hr hrp hpqr'
all_goals first | positivity | finiteness
/-- Hölder's inequality, as an inequality on the `ℒp` seminorm of an elementwise operation
`fun x => b (f x) (g x)`. -/
theorem eLpNorm_le_eLpNorm_mul_eLpNorm'_of_norm {p q r : ℝ≥0∞} (hf : AEStronglyMeasurable f μ)
(hg : AEStronglyMeasurable g μ) (b : E → F → G) (c : ℝ≥0)
(h : ∀ᵐ x ∂μ, ‖b (f x) (g x)‖ ≤ c * ‖f x‖ * ‖g x‖) [hpqr : HolderTriple p q r] :
eLpNorm (fun x => b (f x) (g x)) r μ ≤ c * eLpNorm f p μ * eLpNorm g q μ :=
eLpNorm_le_eLpNorm_mul_eLpNorm_of_nnnorm hf hg b c h
open NNReal in
theorem MemLp.of_bilin {p q r : ℝ≥0∞} {f : α → E} {g : α → F} (b : E → F → G) (c : ℝ≥0)
(hf : MemLp f p μ) (hg : MemLp g q μ)
(h : AEStronglyMeasurable (fun x ↦ b (f x) (g x)) μ)
(hb : ∀ᵐ (x : α) ∂μ, ‖b (f x) (g x)‖₊ ≤ c * ‖f x‖₊ * ‖g x‖₊)
[hpqr : HolderTriple p q r] :
MemLp (fun x ↦ b (f x) (g x)) r μ := by
refine ⟨h, ?_⟩
apply (eLpNorm_le_eLpNorm_mul_eLpNorm_of_nnnorm hf.1 hg.1 b c hb (hpqr := hpqr)).trans_lt
have := hf.2
have := hg.2
finiteness
@[deprecated (since := "2025-02-21")]
alias Memℒp.of_bilin := MemLp.of_bilin
end Bilinear
section IsBoundedSMul
variable {𝕜 α E F : Type*} {m : MeasurableSpace α} {μ : Measure α} [NormedRing 𝕜]
[NormedAddCommGroup E] [MulActionWithZero 𝕜 E] [IsBoundedSMul 𝕜 E]
[NormedAddCommGroup F] [MulActionWithZero 𝕜 F] [IsBoundedSMul 𝕜 F] {f : α → E}
theorem eLpNorm_smul_le_eLpNorm_top_mul_eLpNorm (p : ℝ≥0∞) (hf : AEStronglyMeasurable f μ)
(φ : α → 𝕜) : eLpNorm (φ • f) p μ ≤ eLpNorm φ ∞ μ * eLpNorm f p μ := by
simpa using (eLpNorm_le_eLpNorm_top_mul_eLpNorm p φ hf (· • ·) 1
(.of_forall fun _ => by simpa using nnnorm_smul_le _ _) :)
theorem eLpNorm_smul_le_eLpNorm_mul_eLpNorm_top (p : ℝ≥0∞) (f : α → E) {φ : α → 𝕜}
(hφ : AEStronglyMeasurable φ μ) : eLpNorm (φ • f) p μ ≤ eLpNorm φ p μ * eLpNorm f ∞ μ := by
simpa using (eLpNorm_le_eLpNorm_mul_eLpNorm_top p hφ f (· • ·) 1
(.of_forall fun _ => by simpa using nnnorm_smul_le _ _) :)
theorem eLpNorm'_smul_le_mul_eLpNorm' {p q r : ℝ} {f : α → E} (hf : AEStronglyMeasurable f μ)
{φ : α → 𝕜} (hφ : AEStronglyMeasurable φ μ) (hp0_lt : 0 < p) (hpq : p < q)
(hpqr : 1 / p = 1 / q + 1 / r) : eLpNorm' (φ • f) p μ ≤ eLpNorm' φ q μ * eLpNorm' f r μ := by
simpa using eLpNorm'_le_eLpNorm'_mul_eLpNorm' hφ hf (· • ·) 1
(.of_forall fun _ => by simpa using nnnorm_smul_le _ _)
hp0_lt hpq hpqr
/-- Hölder's inequality, as an inequality on the `ℒp` seminorm of a scalar product `φ • f`. -/
theorem eLpNorm_smul_le_mul_eLpNorm {p q r : ℝ≥0∞} {f : α → E} (hf : AEStronglyMeasurable f μ)
{φ : α → 𝕜} (hφ : AEStronglyMeasurable φ μ) [hpqr : HolderTriple p q r] :
eLpNorm (φ • f) r μ ≤ eLpNorm φ p μ * eLpNorm f q μ := by
simpa using (eLpNorm_le_eLpNorm_mul_eLpNorm_of_nnnorm hφ hf (· • ·) 1
(.of_forall fun _ => by simpa using nnnorm_smul_le _ _) : _)
|
theorem MemLp.smul {p q r : ℝ≥0∞} {f : α → E} {φ : α → 𝕜} (hf : MemLp f q μ) (hφ : MemLp φ p μ)
[hpqr : HolderTriple p q r] : MemLp (φ • f) r μ :=
⟨hφ.1.smul hf.1,
| Mathlib/MeasureTheory/Function/LpSeminorm/CompareExp.lean | 324 | 327 |
/-
Copyright (c) 2020 Rémy Degenne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Rémy Degenne, Eric Wieser
-/
import Mathlib.Data.ENNReal.Holder
import Mathlib.MeasureTheory.Function.LpSeminorm.Basic
import Mathlib.MeasureTheory.Integral.MeanInequalities
import Mathlib.Tactic.Finiteness
/-!
# Compare Lp seminorms for different values of `p`
In this file we compare `MeasureTheory.eLpNorm'` and `MeasureTheory.eLpNorm` for different
exponents.
-/
open Filter ENNReal
open scoped Topology
namespace MeasureTheory
section SameSpace
variable {α ε ε' : Type*} {m : MeasurableSpace α} {μ : Measure α} {f : α → ε}
[TopologicalSpace ε] [ContinuousENorm ε]
[TopologicalSpace ε'] [ENormedAddMonoid ε']
theorem eLpNorm'_le_eLpNorm'_mul_rpow_measure_univ {p q : ℝ} (hp0_lt : 0 < p) (hpq : p ≤ q)
(hf : AEStronglyMeasurable f μ) :
eLpNorm' f p μ ≤ eLpNorm' f q μ * μ Set.univ ^ (1 / p - 1 / q) := by
have hq0_lt : 0 < q := lt_of_lt_of_le hp0_lt hpq
by_cases hpq_eq : p = q
· rw [hpq_eq, sub_self, ENNReal.rpow_zero, mul_one]
have hpq : p < q := lt_of_le_of_ne hpq hpq_eq
let g := fun _ : α => (1 : ℝ≥0∞)
have h_rw : (∫⁻ a, ‖f a‖ₑ ^ p ∂μ) = ∫⁻ a, (‖f a‖ₑ * g a) ^ p ∂μ :=
lintegral_congr fun a => by simp [g]
repeat' rw [eLpNorm'_eq_lintegral_enorm]
rw [h_rw]
let r := p * q / (q - p)
have hpqr : 1 / p = 1 / q + 1 / r := by field_simp [r, hp0_lt.ne', hq0_lt.ne']
calc
(∫⁻ a : α, (‖f a‖ₑ * g a) ^ p ∂μ) ^ (1 / p) ≤
(∫⁻ a : α, ‖f a‖ₑ ^ q ∂μ) ^ (1 / q) * (∫⁻ a : α, g a ^ r ∂μ) ^ (1 / r) :=
ENNReal.lintegral_Lp_mul_le_Lq_mul_Lr hp0_lt hpq hpqr μ hf.enorm aemeasurable_const
_ = (∫⁻ a : α, ‖f a‖ₑ ^ q ∂μ) ^ (1 / q) * μ Set.univ ^ (1 / p - 1 / q) := by
rw [hpqr]; simp [r, g]
theorem eLpNorm'_le_eLpNormEssSup_mul_rpow_measure_univ {q : ℝ} (hq_pos : 0 < q) :
eLpNorm' f q μ ≤ eLpNormEssSup f μ * μ Set.univ ^ (1 / q) := by
have h_le : (∫⁻ a : α, ‖f a‖ₑ ^ q ∂μ) ≤ ∫⁻ _ : α, eLpNormEssSup f μ ^ q ∂μ := by
refine lintegral_mono_ae ?_
have h_nnnorm_le_eLpNorm_ess_sup := enorm_ae_le_eLpNormEssSup f μ
exact h_nnnorm_le_eLpNorm_ess_sup.mono fun x hx => by gcongr
rw [eLpNorm', ← ENNReal.rpow_one (eLpNormEssSup f μ)]
nth_rw 2 [← mul_inv_cancel₀ (ne_of_lt hq_pos).symm]
rw [ENNReal.rpow_mul, one_div, ← ENNReal.mul_rpow_of_nonneg _ _ (by simp [hq_pos.le] : 0 ≤ q⁻¹)]
gcongr
rwa [lintegral_const] at h_le
theorem eLpNorm_le_eLpNorm_mul_rpow_measure_univ {p q : ℝ≥0∞} (hpq : p ≤ q)
(hf : AEStronglyMeasurable f μ) :
eLpNorm f p μ ≤ eLpNorm f q μ * μ Set.univ ^ (1 / p.toReal - 1 / q.toReal) := by
by_cases hp0 : p = 0
· simp [hp0, zero_le]
rw [← Ne] at hp0
have hp0_lt : 0 < p := lt_of_le_of_ne (zero_le _) hp0.symm
have hq0_lt : 0 < q := lt_of_lt_of_le hp0_lt hpq
by_cases hq_top : q = ∞
· simp only [hq_top, _root_.div_zero, one_div, ENNReal.toReal_top, sub_zero, eLpNorm_exponent_top,
GroupWithZero.inv_zero]
by_cases hp_top : p = ∞
· simp only [hp_top, ENNReal.rpow_zero, mul_one, ENNReal.toReal_top, sub_zero,
GroupWithZero.inv_zero, eLpNorm_exponent_top]
exact le_rfl
rw [eLpNorm_eq_eLpNorm' hp0 hp_top]
have hp_pos : 0 < p.toReal := ENNReal.toReal_pos hp0_lt.ne' hp_top
refine (eLpNorm'_le_eLpNormEssSup_mul_rpow_measure_univ hp_pos).trans (le_of_eq ?_)
congr
exact one_div _
have hp_lt_top : p < ∞ := hpq.trans_lt (lt_top_iff_ne_top.mpr hq_top)
have hp_pos : 0 < p.toReal := ENNReal.toReal_pos hp0_lt.ne' hp_lt_top.ne
rw [eLpNorm_eq_eLpNorm' hp0_lt.ne.symm hp_lt_top.ne, eLpNorm_eq_eLpNorm' hq0_lt.ne.symm hq_top]
have hpq_real : p.toReal ≤ q.toReal := ENNReal.toReal_mono hq_top hpq
exact eLpNorm'_le_eLpNorm'_mul_rpow_measure_univ hp_pos hpq_real hf
theorem eLpNorm'_le_eLpNorm'_of_exponent_le {p q : ℝ} (hp0_lt : 0 < p)
(hpq : p ≤ q) (μ : Measure α) [IsProbabilityMeasure μ] (hf : AEStronglyMeasurable f μ) :
eLpNorm' f p μ ≤ eLpNorm' f q μ := by
have h_le_μ := eLpNorm'_le_eLpNorm'_mul_rpow_measure_univ hp0_lt hpq hf
rwa [measure_univ, ENNReal.one_rpow, mul_one] at h_le_μ
theorem eLpNorm'_le_eLpNormEssSup {q : ℝ} (hq_pos : 0 < q) [IsProbabilityMeasure μ] :
eLpNorm' f q μ ≤ eLpNormEssSup f μ :=
(eLpNorm'_le_eLpNormEssSup_mul_rpow_measure_univ hq_pos).trans_eq (by simp [measure_univ])
theorem eLpNorm_le_eLpNorm_of_exponent_le {p q : ℝ≥0∞} (hpq : p ≤ q) [IsProbabilityMeasure μ]
(hf : AEStronglyMeasurable f μ) : eLpNorm f p μ ≤ eLpNorm f q μ :=
(eLpNorm_le_eLpNorm_mul_rpow_measure_univ hpq hf).trans (le_of_eq (by simp [measure_univ]))
theorem eLpNorm'_lt_top_of_eLpNorm'_lt_top_of_exponent_le {p q : ℝ} [IsFiniteMeasure μ]
(hf : AEStronglyMeasurable f μ) (hfq_lt_top : eLpNorm' f q μ < ∞) (hp_nonneg : 0 ≤ p)
(hpq : p ≤ q) : eLpNorm' f p μ < ∞ := by
| rcases le_or_lt p 0 with hp_nonpos | hp_pos
· rw [le_antisymm hp_nonpos hp_nonneg]
simp
have hq_pos : 0 < q := lt_of_lt_of_le hp_pos hpq
calc
eLpNorm' f p μ ≤ eLpNorm' f q μ * μ Set.univ ^ (1 / p - 1 / q) :=
eLpNorm'_le_eLpNorm'_mul_rpow_measure_univ hp_pos hpq hf
_ < ∞ := by
rw [ENNReal.mul_lt_top_iff]
refine Or.inl ⟨hfq_lt_top, ENNReal.rpow_lt_top_of_nonneg ?_ (measure_ne_top μ Set.univ)⟩
rwa [le_sub_comm, sub_zero, one_div, one_div, inv_le_inv₀ hq_pos hp_pos]
theorem MemLp.mono_exponent {p q : ℝ≥0∞} [IsFiniteMeasure μ] (hfq : MemLp f q μ)
(hpq : p ≤ q) : MemLp f p μ := by
| Mathlib/MeasureTheory/Function/LpSeminorm/CompareExp.lean | 105 | 118 |
/-
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, Jeremy Avigad
-/
import Mathlib.Data.Set.Finite.Basic
import Mathlib.Data.Set.Finite.Range
import Mathlib.Data.Set.Lattice
import Mathlib.Topology.Defs.Filter
/-!
# Openness and closedness of a set
This file provides lemmas relating to the predicates `IsOpen` and `IsClosed` of a set endowed with
a topology.
## Implementation notes
Topology in mathlib heavily uses filters (even more than in Bourbaki). See explanations in
<https://leanprover-community.github.io/theories/topology.html>.
## References
* [N. Bourbaki, *General Topology*][bourbaki1966]
* [I. M. James, *Topologies and Uniformities*][james1999]
## Tags
topological space
-/
open Set Filter Topology
universe u v
/-- A constructor for topologies by specifying the closed sets,
and showing that they satisfy the appropriate conditions. -/
def TopologicalSpace.ofClosed {X : Type u} (T : Set (Set X)) (empty_mem : ∅ ∈ T)
(sInter_mem : ∀ A, A ⊆ T → ⋂₀ A ∈ T)
(union_mem : ∀ A, A ∈ T → ∀ B, B ∈ T → A ∪ B ∈ T) : TopologicalSpace X where
IsOpen X := Xᶜ ∈ T
isOpen_univ := by simp [empty_mem]
isOpen_inter s t hs ht := by simpa only [compl_inter] using union_mem sᶜ hs tᶜ ht
isOpen_sUnion s hs := by
simp only [Set.compl_sUnion]
exact sInter_mem (compl '' s) fun z ⟨y, hy, hz⟩ => hz ▸ hs y hy
section TopologicalSpace
variable {X : Type u} {ι : Sort v} {α : Type*} {x : X} {s s₁ s₂ t : Set X} {p p₁ p₂ : X → Prop}
lemma isOpen_mk {p h₁ h₂ h₃} : IsOpen[⟨p, h₁, h₂, h₃⟩] s ↔ p s := Iff.rfl
@[ext (iff := false)]
protected theorem TopologicalSpace.ext :
∀ {f g : TopologicalSpace X}, IsOpen[f] = IsOpen[g] → f = g
| ⟨_, _, _, _⟩, ⟨_, _, _, _⟩, rfl => rfl
protected theorem TopologicalSpace.ext_iff {t t' : TopologicalSpace X} :
t = t' ↔ ∀ s, IsOpen[t] s ↔ IsOpen[t'] s :=
⟨fun h _ => h ▸ Iff.rfl, fun h => by ext; exact h _⟩
theorem isOpen_fold {t : TopologicalSpace X} : t.IsOpen s = IsOpen[t] s :=
rfl
variable [TopologicalSpace X]
theorem isOpen_iUnion {f : ι → Set X} (h : ∀ i, IsOpen (f i)) : IsOpen (⋃ i, f i) :=
isOpen_sUnion (forall_mem_range.2 h)
theorem isOpen_biUnion {s : Set α} {f : α → Set X} (h : ∀ i ∈ s, IsOpen (f i)) :
IsOpen (⋃ i ∈ s, f i) :=
isOpen_iUnion fun i => isOpen_iUnion fun hi => h i hi
theorem IsOpen.union (h₁ : IsOpen s₁) (h₂ : IsOpen s₂) : IsOpen (s₁ ∪ s₂) := by
rw [union_eq_iUnion]; exact isOpen_iUnion (Bool.forall_bool.2 ⟨h₂, h₁⟩)
lemma isOpen_iff_of_cover {f : α → Set X} (ho : ∀ i, IsOpen (f i)) (hU : (⋃ i, f i) = univ) :
IsOpen s ↔ ∀ i, IsOpen (f i ∩ s) := by
refine ⟨fun h i ↦ (ho i).inter h, fun h ↦ ?_⟩
rw [← s.inter_univ, inter_comm, ← hU, iUnion_inter]
exact isOpen_iUnion fun i ↦ h i
@[simp] theorem isOpen_empty : IsOpen (∅ : Set X) := by
rw [← sUnion_empty]; exact isOpen_sUnion fun a => False.elim
theorem Set.Finite.isOpen_sInter {s : Set (Set X)} (hs : s.Finite) (h : ∀ t ∈ s, IsOpen t) :
IsOpen (⋂₀ s) := by
induction s, hs using Set.Finite.induction_on with
| empty => rw [sInter_empty]; exact isOpen_univ
| insert _ _ ih =>
simp only [sInter_insert, forall_mem_insert] at h ⊢
exact h.1.inter (ih h.2)
theorem Set.Finite.isOpen_biInter {s : Set α} {f : α → Set X} (hs : s.Finite)
(h : ∀ i ∈ s, IsOpen (f i)) :
IsOpen (⋂ i ∈ s, f i) :=
sInter_image f s ▸ (hs.image _).isOpen_sInter (forall_mem_image.2 h)
theorem isOpen_iInter_of_finite [Finite ι] {s : ι → Set X} (h : ∀ i, IsOpen (s i)) :
IsOpen (⋂ i, s i) :=
(finite_range _).isOpen_sInter (forall_mem_range.2 h)
theorem isOpen_biInter_finset {s : Finset α} {f : α → Set X} (h : ∀ i ∈ s, IsOpen (f i)) :
IsOpen (⋂ i ∈ s, f i) :=
s.finite_toSet.isOpen_biInter h
@[simp]
theorem isOpen_const {p : Prop} : IsOpen { _x : X | p } := by by_cases p <;> simp [*]
theorem IsOpen.and : IsOpen { x | p₁ x } → IsOpen { x | p₂ x } → IsOpen { x | p₁ x ∧ p₂ x } :=
IsOpen.inter
@[simp] theorem isOpen_compl_iff : IsOpen sᶜ ↔ IsClosed s :=
⟨fun h => ⟨h⟩, fun h => h.isOpen_compl⟩
theorem TopologicalSpace.ext_iff_isClosed {X} {t₁ t₂ : TopologicalSpace X} :
t₁ = t₂ ↔ ∀ s, IsClosed[t₁] s ↔ IsClosed[t₂] s := by
rw [TopologicalSpace.ext_iff, compl_surjective.forall]
simp only [@isOpen_compl_iff _ _ t₁, @isOpen_compl_iff _ _ t₂]
alias ⟨_, TopologicalSpace.ext_isClosed⟩ := TopologicalSpace.ext_iff_isClosed
theorem isClosed_const {p : Prop} : IsClosed { _x : X | p } := ⟨isOpen_const (p := ¬p)⟩
@[simp] theorem isClosed_empty : IsClosed (∅ : Set X) := isClosed_const
@[simp] theorem isClosed_univ : IsClosed (univ : Set X) := isClosed_const
lemma IsOpen.isLocallyClosed (hs : IsOpen s) : IsLocallyClosed s :=
⟨_, _, hs, isClosed_univ, (inter_univ _).symm⟩
lemma IsClosed.isLocallyClosed (hs : IsClosed s) : IsLocallyClosed s :=
⟨_, _, isOpen_univ, hs, (univ_inter _).symm⟩
theorem IsClosed.union : IsClosed s₁ → IsClosed s₂ → IsClosed (s₁ ∪ s₂) := by
simpa only [← isOpen_compl_iff, compl_union] using IsOpen.inter
theorem isClosed_sInter {s : Set (Set X)} : (∀ t ∈ s, IsClosed t) → IsClosed (⋂₀ s) := by
simpa only [← isOpen_compl_iff, compl_sInter, sUnion_image] using isOpen_biUnion
theorem isClosed_iInter {f : ι → Set X} (h : ∀ i, IsClosed (f i)) : IsClosed (⋂ i, f i) :=
isClosed_sInter <| forall_mem_range.2 h
theorem isClosed_biInter {s : Set α} {f : α → Set X} (h : ∀ i ∈ s, IsClosed (f i)) :
IsClosed (⋂ i ∈ s, f i) :=
isClosed_iInter fun i => isClosed_iInter <| h i
@[simp]
theorem isClosed_compl_iff {s : Set X} : IsClosed sᶜ ↔ IsOpen s := by
rw [← isOpen_compl_iff, compl_compl]
alias ⟨_, IsOpen.isClosed_compl⟩ := isClosed_compl_iff
theorem IsOpen.sdiff (h₁ : IsOpen s) (h₂ : IsClosed t) : IsOpen (s \ t) :=
IsOpen.inter h₁ h₂.isOpen_compl
theorem IsClosed.inter (h₁ : IsClosed s₁) (h₂ : IsClosed s₂) : IsClosed (s₁ ∩ s₂) := by
rw [← isOpen_compl_iff] at *
rw [compl_inter]
exact IsOpen.union h₁ h₂
theorem IsClosed.sdiff (h₁ : IsClosed s) (h₂ : IsOpen t) : IsClosed (s \ t) :=
IsClosed.inter h₁ (isClosed_compl_iff.mpr h₂)
theorem Set.Finite.isClosed_biUnion {s : Set α} {f : α → Set X} (hs : s.Finite)
(h : ∀ i ∈ s, IsClosed (f i)) :
IsClosed (⋃ i ∈ s, f i) := by
simp only [← isOpen_compl_iff, compl_iUnion] at *
exact hs.isOpen_biInter h
lemma isClosed_biUnion_finset {s : Finset α} {f : α → Set X} (h : ∀ i ∈ s, IsClosed (f i)) :
IsClosed (⋃ i ∈ s, f i) :=
s.finite_toSet.isClosed_biUnion h
theorem isClosed_iUnion_of_finite [Finite ι] {s : ι → Set X} (h : ∀ i, IsClosed (s i)) :
IsClosed (⋃ i, s i) := by
simp only [← isOpen_compl_iff, compl_iUnion] at *
exact isOpen_iInter_of_finite h
theorem isClosed_imp {p q : X → Prop} (hp : IsOpen { x | p x }) (hq : IsClosed { x | q x }) :
IsClosed { x | p x → q x } := by
simpa only [imp_iff_not_or] using hp.isClosed_compl.union hq
theorem IsClosed.not : IsClosed { a | p a } → IsOpen { a | ¬p a } :=
isOpen_compl_iff.mpr
/-!
### Limits of filters in topological spaces
In this section we define functions that return a limit of a filter (or of a function along a
filter), if it exists, and a random point otherwise. These functions are rarely used in Mathlib,
most of the theorems are written using `Filter.Tendsto`. One of the reasons is that
`Filter.limUnder f g = x` is not equivalent to `Filter.Tendsto g f (𝓝 x)` unless the codomain is a
Hausdorff space and `g` has a limit along `f`.
-/
section lim
/-- If a filter `f` is majorated by some `𝓝 x`, then it is majorated by `𝓝 (Filter.lim f)`. We
formulate this lemma with a `[Nonempty X]` argument of `lim` derived from `h` to make it useful for
types without a `[Nonempty X]` instance. Because of the built-in proof irrelevance, Lean will unify
this instance with any other instance. -/
theorem le_nhds_lim {f : Filter X} (h : ∃ x, f ≤ 𝓝 x) : f ≤ 𝓝 (@lim _ _ (nonempty_of_exists h) f) :=
Classical.epsilon_spec h
/-- If `g` tends to some `𝓝 x` along `f`, then it tends to `𝓝 (Filter.limUnder f g)`. We formulate
| this lemma with a `[Nonempty X]` argument of `lim` derived from `h` to make it useful for types
without a `[Nonempty X]` instance. Because of the built-in proof irrelevance, Lean will unify this
instance with any other instance. -/
theorem tendsto_nhds_limUnder {f : Filter α} {g : α → X} (h : ∃ x, Tendsto g f (𝓝 x)) :
| Mathlib/Topology/Basic.lean | 208 | 211 |
/-
Copyright (c) 2021 Johan Commelin. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johan Commelin
-/
import Mathlib.Algebra.Group.Indicator
import Mathlib.Tactic.FinCases
import Mathlib.Topology.Connected.LocallyConnected
import Mathlib.Topology.Sets.Closeds
/-!
# Locally constant functions
This file sets up the theory of locally constant function from a topological space to a type.
## Main definitions and constructions
* `IsLocallyConstant f` : a map `f : X → Y` where `X` is a topological space is locally
constant if every set in `Y` has an open preimage.
* `LocallyConstant X Y` : the type of locally constant maps from `X` to `Y`
* `LocallyConstant.map` : push-forward of locally constant maps
* `LocallyConstant.comap` : pull-back of locally constant maps
-/
variable {X Y Z α : Type*} [TopologicalSpace X]
open Set Filter
open scoped Topology
/-- A function between topological spaces is locally constant if the preimage of any set is open. -/
def IsLocallyConstant (f : X → Y) : Prop :=
∀ s : Set Y, IsOpen (f ⁻¹' s)
namespace IsLocallyConstant
open List in
protected theorem tfae (f : X → Y) :
TFAE [IsLocallyConstant f,
∀ x, ∀ᶠ x' in 𝓝 x, f x' = f x,
∀ x, IsOpen { x' | f x' = f x },
∀ y, IsOpen (f ⁻¹' {y}),
∀ x, ∃ U : Set X, IsOpen U ∧ x ∈ U ∧ ∀ x' ∈ U, f x' = f x] := by
tfae_have 1 → 4 := fun h y => h {y}
tfae_have 4 → 3 := fun h x => h (f x)
tfae_have 3 → 2 := fun h x => IsOpen.mem_nhds (h x) rfl
tfae_have 2 → 5
| h, x => by
rcases mem_nhds_iff.1 (h x) with ⟨U, eq, hU, hx⟩
exact ⟨U, hU, hx, eq⟩
tfae_have 5 → 1
| h, s => by
refine isOpen_iff_forall_mem_open.2 fun x hx ↦ ?_
rcases h x with ⟨U, hU, hxU, eq⟩
exact ⟨U, fun x' hx' => mem_preimage.2 <| (eq x' hx').symm ▸ hx, hU, hxU⟩
tfae_finish
@[nontriviality]
theorem of_discrete [DiscreteTopology X] (f : X → Y) : IsLocallyConstant f := fun _ =>
isOpen_discrete _
theorem isOpen_fiber {f : X → Y} (hf : IsLocallyConstant f) (y : Y) : IsOpen { x | f x = y } :=
hf {y}
theorem isClosed_fiber {f : X → Y} (hf : IsLocallyConstant f) (y : Y) : IsClosed { x | f x = y } :=
⟨hf {y}ᶜ⟩
theorem isClopen_fiber {f : X → Y} (hf : IsLocallyConstant f) (y : Y) : IsClopen { x | f x = y } :=
⟨isClosed_fiber hf _, isOpen_fiber hf _⟩
theorem iff_exists_open (f : X → Y) :
IsLocallyConstant f ↔ ∀ x, ∃ U : Set X, IsOpen U ∧ x ∈ U ∧ ∀ x' ∈ U, f x' = f x :=
(IsLocallyConstant.tfae f).out 0 4
theorem iff_eventually_eq (f : X → Y) : IsLocallyConstant f ↔ ∀ x, ∀ᶠ y in 𝓝 x, f y = f x :=
(IsLocallyConstant.tfae f).out 0 1
theorem exists_open {f : X → Y} (hf : IsLocallyConstant f) (x : X) :
∃ U : Set X, IsOpen U ∧ x ∈ U ∧ ∀ x' ∈ U, f x' = f x :=
(iff_exists_open f).1 hf x
protected theorem eventually_eq {f : X → Y} (hf : IsLocallyConstant f) (x : X) :
∀ᶠ y in 𝓝 x, f y = f x :=
(iff_eventually_eq f).1 hf x
theorem iff_isOpen_fiber_apply {f : X → Y} : IsLocallyConstant f ↔ ∀ x, IsOpen (f ⁻¹' {f x}) :=
(IsLocallyConstant.tfae f).out 0 2
theorem iff_isOpen_fiber {f : X → Y} : IsLocallyConstant f ↔ ∀ y, IsOpen (f ⁻¹' {y}) :=
(IsLocallyConstant.tfae f).out 0 3
protected theorem continuous [TopologicalSpace Y] {f : X → Y} (hf : IsLocallyConstant f) :
Continuous f :=
⟨fun _ _ => hf _⟩
theorem iff_continuous {_ : TopologicalSpace Y} [DiscreteTopology Y] (f : X → Y) :
IsLocallyConstant f ↔ Continuous f :=
⟨IsLocallyConstant.continuous, fun h s => h.isOpen_preimage s (isOpen_discrete _)⟩
theorem of_constant (f : X → Y) (h : ∀ x y, f x = f y) : IsLocallyConstant f :=
(iff_eventually_eq f).2 fun _ => Eventually.of_forall fun _ => h _ _
protected theorem const (y : Y) : IsLocallyConstant (Function.const X y) :=
of_constant _ fun _ _ => rfl
protected theorem comp {f : X → Y} (hf : IsLocallyConstant f) (g : Y → Z) :
IsLocallyConstant (g ∘ f) := fun s => by
rw [Set.preimage_comp]
exact hf _
theorem prodMk {Y'} {f : X → Y} {f' : X → Y'} (hf : IsLocallyConstant f)
(hf' : IsLocallyConstant f') : IsLocallyConstant fun x => (f x, f' x) :=
(iff_eventually_eq _).2 fun x =>
(hf.eventually_eq x).mp <| (hf'.eventually_eq x).mono fun _ hf' hf => Prod.ext hf hf'
@[deprecated (since := "2025-03-10")]
alias prod_mk := prodMk
theorem comp₂ {Y₁ Y₂ Z : Type*} {f : X → Y₁} {g : X → Y₂} (hf : IsLocallyConstant f)
(hg : IsLocallyConstant g) (h : Y₁ → Y₂ → Z) : IsLocallyConstant fun x => h (f x) (g x) :=
(hf.prodMk hg).comp fun x : Y₁ × Y₂ => h x.1 x.2
theorem comp_continuous [TopologicalSpace Y] {g : Y → Z} {f : X → Y} (hg : IsLocallyConstant g)
(hf : Continuous f) : IsLocallyConstant (g ∘ f) := fun s => by
rw [Set.preimage_comp]
exact hf.isOpen_preimage _ (hg _)
/-- A locally constant function is constant on any preconnected set. -/
theorem apply_eq_of_isPreconnected {f : X → Y} (hf : IsLocallyConstant f) {s : Set X}
(hs : IsPreconnected s) {x y : X} (hx : x ∈ s) (hy : y ∈ s) : f x = f y := by
let U := f ⁻¹' {f y}
suffices x ∉ Uᶜ from Classical.not_not.1 this
intro hxV
specialize hs U Uᶜ (hf {f y}) (hf {f y}ᶜ) _ ⟨y, ⟨hy, rfl⟩⟩ ⟨x, ⟨hx, hxV⟩⟩
· simp only [union_compl_self, subset_univ]
· simp only [inter_empty, Set.not_nonempty_empty, inter_compl_self] at hs
theorem apply_eq_of_preconnectedSpace [PreconnectedSpace X] {f : X → Y} (hf : IsLocallyConstant f)
(x y : X) : f x = f y :=
hf.apply_eq_of_isPreconnected isPreconnected_univ trivial trivial
theorem eq_const [PreconnectedSpace X] {f : X → Y} (hf : IsLocallyConstant f) (x : X) :
f = Function.const X (f x) :=
funext fun y => hf.apply_eq_of_preconnectedSpace y x
theorem exists_eq_const [PreconnectedSpace X] [Nonempty Y] {f : X → Y} (hf : IsLocallyConstant f) :
∃ y, f = Function.const X y := by
rcases isEmpty_or_nonempty X with h | h
· exact ⟨Classical.arbitrary Y, funext <| h.elim⟩
· exact ⟨f (Classical.arbitrary X), hf.eq_const _⟩
theorem iff_is_const [PreconnectedSpace X] {f : X → Y} : IsLocallyConstant f ↔ ∀ x y, f x = f y :=
⟨fun h _ _ => h.apply_eq_of_isPreconnected isPreconnected_univ trivial trivial, of_constant _⟩
theorem range_finite [CompactSpace X] {f : X → Y} (hf : IsLocallyConstant f) :
(Set.range f).Finite := by
letI : TopologicalSpace Y := ⊥; haveI := discreteTopology_bot Y
exact (isCompact_range hf.continuous).finite_of_discrete
@[to_additive]
theorem one [One Y] : IsLocallyConstant (1 : X → Y) := IsLocallyConstant.const 1
@[to_additive]
theorem inv [Inv Y] ⦃f : X → Y⦄ (hf : IsLocallyConstant f) : IsLocallyConstant f⁻¹ :=
hf.comp fun x => x⁻¹
@[to_additive]
theorem mul [Mul Y] ⦃f g : X → Y⦄ (hf : IsLocallyConstant f) (hg : IsLocallyConstant g) :
IsLocallyConstant (f * g) :=
hf.comp₂ hg (· * ·)
@[to_additive]
theorem div [Div Y] ⦃f g : X → Y⦄ (hf : IsLocallyConstant f) (hg : IsLocallyConstant g) :
IsLocallyConstant (f / g) :=
hf.comp₂ hg (· / ·)
/-- If a composition of a function `f` followed by an injection `g` is locally
constant, then the locally constant property descends to `f`. -/
theorem desc {α β : Type*} (f : X → α) (g : α → β) (h : IsLocallyConstant (g ∘ f))
(inj : Function.Injective g) : IsLocallyConstant f := fun s => by
rw [← preimage_image_eq s inj, preimage_preimage]
| exact h (g '' s)
theorem of_constant_on_connected_components [LocallyConnectedSpace X] {f : X → Y}
(h : ∀ x, ∀ y ∈ connectedComponent x, f y = f x) : IsLocallyConstant f :=
| Mathlib/Topology/LocallyConstant/Basic.lean | 181 | 184 |
/-
Copyright (c) 2021 Yourong Zang. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yourong Zang
-/
import Mathlib.Analysis.Calculus.Conformal.NormedSpace
import Mathlib.Analysis.InnerProductSpace.ConformalLinearMap
/-!
# Conformal maps between inner product spaces
A function between inner product spaces which has a derivative at `x`
is conformal at `x` iff the derivative preserves inner products up to a scalar multiple.
-/
noncomputable section
variable {E F : Type*}
variable [NormedAddCommGroup E] [NormedAddCommGroup F]
variable [InnerProductSpace ℝ E] [InnerProductSpace ℝ F]
open RealInnerProductSpace
/-- A real differentiable map `f` is conformal at point `x` if and only if its
differential `fderiv ℝ f x` at that point scales every inner product by a positive scalar. -/
theorem conformalAt_iff' {f : E → F} {x : E} : ConformalAt f x ↔
∃ c : ℝ, 0 < c ∧ ∀ u v : E, ⟪fderiv ℝ f x u, fderiv ℝ f x v⟫ = c * ⟪u, v⟫ := by
| rw [conformalAt_iff_isConformalMap_fderiv, isConformalMap_iff]
/-- A real differentiable map `f` is conformal at point `x` if and only if its
| Mathlib/Analysis/Calculus/Conformal/InnerProduct.lean | 29 | 31 |
/-
Copyright (c) 2020 Thomas Browning, Patrick Lutz. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Thomas Browning, Patrick Lutz
-/
import Mathlib.Data.Fintype.Pigeonhole
import Mathlib.FieldTheory.IsAlgClosed.Basic
import Mathlib.FieldTheory.SplittingField.Construction
import Mathlib.RingTheory.IntegralDomain
import Mathlib.RingTheory.Polynomial.UniqueFactorization
/-!
# Primitive Element Theorem
In this file we prove the primitive element theorem.
## Main results
- `Field.exists_primitive_element`: a finite separable extension `E / F` has a primitive element,
i.e. there is an `α : E` such that `F⟮α⟯ = (⊤ : Subalgebra F E)`.
- `Field.exists_primitive_element_iff_finite_intermediateField`: a finite extension `E / F` has a
primitive element if and only if there exist only finitely many intermediate fields between `E`
and `F`.
## Implementation notes
In declaration names, `primitive_element` abbreviates `adjoin_simple_eq_top`:
it stands for the statement `F⟮α⟯ = (⊤ : Subalgebra F E)`. We did not add an extra
declaration `IsPrimitiveElement F α := F⟮α⟯ = (⊤ : Subalgebra F E)` because this
requires more unfolding without much obvious benefit.
## Tags
primitive element, separable field extension, separable extension, intermediate field, adjoin,
exists_adjoin_simple_eq_top
-/
noncomputable section
open Module Polynomial IntermediateField
namespace Field
section PrimitiveElementFinite
variable (F : Type*) [Field F] (E : Type*) [Field E] [Algebra F E]
/-! ### Primitive element theorem for finite fields -/
/-- **Primitive element theorem** assuming E is finite. -/
@[stacks 09HY "second part"]
theorem exists_primitive_element_of_finite_top [Finite E] : ∃ α : E, F⟮α⟯ = ⊤ := by
obtain ⟨α, hα⟩ := @IsCyclic.exists_generator Eˣ _ _
use α
rw [eq_top_iff]
rintro x -
by_cases hx : x = 0
· rw [hx]
exact F⟮α.val⟯.zero_mem
· obtain ⟨n, hn⟩ := Set.mem_range.mp (hα (Units.mk0 x hx))
rw [show x = α ^ n by norm_cast; rw [hn, Units.val_mk0]]
exact zpow_mem (mem_adjoin_simple_self F (E := E) ↑α) n
/-- Primitive element theorem for finite dimensional extension of a finite field. -/
theorem exists_primitive_element_of_finite_bot [Finite F] [FiniteDimensional F E] :
∃ α : E, F⟮α⟯ = ⊤ :=
haveI : Finite E := Module.finite_of_finite F
exists_primitive_element_of_finite_top F E
end PrimitiveElementFinite
/-! ### Primitive element theorem for infinite fields -/
section PrimitiveElementInf
variable {F : Type*} [Field F] [Infinite F] {E : Type*} [Field E] (ϕ : F →+* E) (α β : E)
theorem primitive_element_inf_aux_exists_c (f g : F[X]) :
∃ c : F, ∀ α' ∈ (f.map ϕ).roots, ∀ β' ∈ (g.map ϕ).roots, -(α' - α) / (β' - β) ≠ ϕ c := by
classical
let sf := (f.map ϕ).roots
let sg := (g.map ϕ).roots
classical
let s := (sf.bind fun α' => sg.map fun β' => -(α' - α) / (β' - β)).toFinset
let s' := s.preimage ϕ fun x _ y _ h => ϕ.injective h
obtain ⟨c, hc⟩ := Infinite.exists_not_mem_finset s'
simp_rw [s', s, Finset.mem_preimage, Multiset.mem_toFinset, Multiset.mem_bind, Multiset.mem_map]
at hc
push_neg at hc
exact ⟨c, hc⟩
variable (F)
variable [Algebra F E]
/-- This is the heart of the proof of the primitive element theorem. It shows that if `F` is
infinite and `α` and `β` are separable over `F` then `F⟮α, β⟯` is generated by a single element. -/
theorem primitive_element_inf_aux [Algebra.IsSeparable F E] : ∃ γ : E, F⟮α, β⟯ = F⟮γ⟯ := by
classical
| have hα := Algebra.IsSeparable.isIntegral F α
have hβ := Algebra.IsSeparable.isIntegral F β
let f := minpoly F α
let g := minpoly F β
let ιFE := algebraMap F E
let ιEE' := algebraMap E (SplittingField (g.map ιFE))
obtain ⟨c, hc⟩ := primitive_element_inf_aux_exists_c (ιEE'.comp ιFE) (ιEE' α) (ιEE' β) f g
let γ := α + c • β
suffices β_in_Fγ : β ∈ F⟮γ⟯ by
use γ
apply le_antisymm
· rw [adjoin_le_iff]
have α_in_Fγ : α ∈ F⟮γ⟯ := by
rw [← add_sub_cancel_right α (c • β)]
exact F⟮γ⟯.sub_mem (mem_adjoin_simple_self F γ) (F⟮γ⟯.toSubalgebra.smul_mem β_in_Fγ c)
rintro x (rfl | rfl) <;> assumption
· rw [adjoin_simple_le_iff]
have α_in_Fαβ : α ∈ F⟮α, β⟯ := subset_adjoin F {α, β} (Set.mem_insert α {β})
have β_in_Fαβ : β ∈ F⟮α, β⟯ := subset_adjoin F {α, β} (Set.mem_insert_of_mem α rfl)
exact F⟮α, β⟯.add_mem α_in_Fαβ (F⟮α, β⟯.smul_mem β_in_Fαβ)
classical
let p := EuclideanDomain.gcd ((f.map (algebraMap F F⟮γ⟯)).comp
(C (AdjoinSimple.gen F γ) - (C ↑c : F⟮γ⟯[X]) * X)) (g.map (algebraMap F F⟮γ⟯))
let h := EuclideanDomain.gcd ((f.map ιFE).comp (C γ - C (ιFE c) * X)) (g.map ιFE)
have map_g_ne_zero : g.map ιFE ≠ 0 := map_ne_zero (minpoly.ne_zero hβ)
have h_ne_zero : h ≠ 0 :=
mt EuclideanDomain.gcd_eq_zero_iff.mp (not_and.mpr fun _ => map_g_ne_zero)
suffices p_linear : p.map (algebraMap F⟮γ⟯ E) = C h.leadingCoeff * (X - C β) by
have finale : β = algebraMap F⟮γ⟯ E (-p.coeff 0 / p.coeff 1) := by
simp [map_div₀, RingHom.map_neg, ← coeff_map, ← coeff_map, p_linear,
mul_sub, coeff_C, mul_div_cancel_left₀ β (mt leadingCoeff_eq_zero.mp h_ne_zero)]
rw [finale]
exact Subtype.mem (-p.coeff 0 / p.coeff 1)
have h_sep : h.Separable := separable_gcd_right _ (Algebra.IsSeparable.isSeparable F β).map
have h_root : h.eval β = 0 := by
apply eval_gcd_eq_zero
· rw [eval_comp, eval_sub, eval_mul, eval_C, eval_C, eval_X, eval_map, ← aeval_def, ←
Algebra.smul_def, add_sub_cancel_right, minpoly.aeval]
· rw [eval_map, ← aeval_def, minpoly.aeval]
have h_splits : Splits ιEE' h :=
splits_of_splits_gcd_right ιEE' map_g_ne_zero (SplittingField.splits _)
have h_roots : ∀ x ∈ (h.map ιEE').roots, x = ιEE' β := by
intro x hx
rw [mem_roots_map h_ne_zero] at hx
specialize hc (ιEE' γ - ιEE' (ιFE c) * x) (by
have f_root := root_left_of_root_gcd hx
rw [eval₂_comp, eval₂_sub, eval₂_mul, eval₂_C, eval₂_C, eval₂_X, eval₂_map] at f_root
exact (mem_roots_map (minpoly.ne_zero hα)).mpr f_root)
specialize hc x (by
rw [mem_roots_map (minpoly.ne_zero hβ), ← eval₂_map]
exact root_right_of_root_gcd hx)
by_contra a
apply hc
apply (div_eq_iff (sub_ne_zero.mpr a)).mpr
simp only [γ, Algebra.smul_def, RingHom.map_add, RingHom.map_mul, RingHom.comp_apply]
ring
rw [← eq_X_sub_C_of_separable_of_root_eq h_sep h_root h_splits h_roots]
trans EuclideanDomain.gcd (?_ : E[X]) (?_ : E[X])
· dsimp only [γ]
convert (gcd_map (algebraMap F⟮γ⟯ E)).symm
· simp only [map_comp, Polynomial.map_map, ← IsScalarTower.algebraMap_eq, Polynomial.map_sub,
map_C, AdjoinSimple.algebraMap_gen, map_add, Polynomial.map_mul, map_X]
congr
-- If `F` is infinite and `E/F` has only finitely many intermediate fields, then for any
-- `α` and `β` in `E`, `F⟮α, β⟯` is generated by a single element.
-- Marked as private since it's a special case of
-- `exists_primitive_element_of_finite_intermediateField`.
private theorem primitive_element_inf_aux_of_finite_intermediateField
[Finite (IntermediateField F E)] : ∃ γ : E, F⟮α, β⟯ = F⟮γ⟯ := by
| Mathlib/FieldTheory/PrimitiveElement.lean | 103 | 172 |
/-
Copyright (c) 2022 Eric Rodriguez. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Eric Rodriguez
-/
import Mathlib.Algebra.GroupWithZero.Units.Lemmas
import Mathlib.Algebra.Order.BigOperators.Group.Finset
import Mathlib.Algebra.Order.Ring.Cast
import Mathlib.Data.Fintype.BigOperators
import Mathlib.Tactic.DeriveFintype
/-!
# Sign function
This file defines the sign function for types with zero and a decidable less-than relation, and
proves some basic theorems about it.
-/
-- Don't generate unnecessary `sizeOf_spec` lemmas which the `simpNF` linter will complain about.
set_option genSizeOfSpec false in
/-- The type of signs. -/
inductive SignType
| zero
| neg
| pos
deriving DecidableEq, Inhabited, Fintype
namespace SignType
instance : Zero SignType :=
⟨zero⟩
instance : One SignType :=
⟨pos⟩
instance : Neg SignType :=
⟨fun s =>
match s with
| neg => pos
| zero => zero
| pos => neg⟩
@[simp]
theorem zero_eq_zero : zero = 0 :=
rfl
@[simp]
theorem neg_eq_neg_one : neg = -1 :=
rfl
@[simp]
theorem pos_eq_one : pos = 1 :=
rfl
instance : Mul SignType :=
⟨fun x y =>
match x with
| neg => -y
| zero => zero
| pos => y⟩
/-- The less-than-or-equal relation on signs. -/
protected inductive LE : SignType → SignType → Prop
| of_neg (a) : SignType.LE neg a
| zero : SignType.LE zero zero
| of_pos (a) : SignType.LE a pos
instance : LE SignType :=
⟨SignType.LE⟩
instance LE.decidableRel : DecidableRel SignType.LE := fun a b => by
cases a <;> cases b <;> first | exact isTrue (by constructor)| exact isFalse (by rintro ⟨_⟩)
instance decidableEq : DecidableEq SignType := fun a b => by
cases a <;> cases b <;> first | exact isTrue (by constructor)| exact isFalse (by rintro ⟨_⟩)
private lemma mul_comm : ∀ (a b : SignType), a * b = b * a := by rintro ⟨⟩ ⟨⟩ <;> rfl
private lemma mul_assoc : ∀ (a b c : SignType), (a * b) * c = a * (b * c) := by
rintro ⟨⟩ ⟨⟩ ⟨⟩ <;> rfl
/- We can define a `Field` instance on `SignType`, but it's not mathematically sensible,
so we only define the `CommGroupWithZero`. -/
instance : CommGroupWithZero SignType where
zero := 0
one := 1
mul := (· * ·)
inv := id
mul_zero a := by cases a <;> rfl
zero_mul a := by cases a <;> rfl
mul_one a := by cases a <;> rfl
one_mul a := by cases a <;> rfl
mul_inv_cancel a ha := by cases a <;> trivial
mul_comm := mul_comm
mul_assoc := mul_assoc
exists_pair_ne := ⟨0, 1, by rintro ⟨_⟩⟩
inv_zero := rfl
private lemma le_antisymm (a b : SignType) (_ : a ≤ b) (_ : b ≤ a) : a = b := by
cases a <;> cases b <;> trivial
private lemma le_trans (a b c : SignType) (_ : a ≤ b) (_ : b ≤ c) : a ≤ c := by
cases a <;> cases b <;> cases c <;> tauto
instance : LinearOrder SignType where
le := (· ≤ ·)
le_refl a := by cases a <;> constructor
le_total a b := by cases a <;> cases b <;> first | left; constructor | right; constructor
le_antisymm := le_antisymm
le_trans := le_trans
toDecidableLE := LE.decidableRel
| toDecidableEq := SignType.decidableEq
| Mathlib/Data/Sign.lean | 111 | 112 |
/-
Copyright (c) 2021 Adam Topaz. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Calle Sönne, Adam Topaz
-/
import Mathlib.Data.Setoid.Partition
import Mathlib.Topology.LocallyConstant.Basic
import Mathlib.Topology.Separation.Regular
import Mathlib.Topology.Connected.TotallyDisconnected
/-!
# Discrete quotients of a topological space.
This file defines the type of discrete quotients of a topological space,
denoted `DiscreteQuotient X`. To avoid quantifying over types, we model such
quotients as setoids whose equivalence classes are clopen.
## Definitions
1. `DiscreteQuotient X` is the type of discrete quotients of `X`.
It is endowed with a coercion to `Type`, which is defined as the
quotient associated to the setoid in question, and each such quotient
is endowed with the discrete topology.
2. Given `S : DiscreteQuotient X`, the projection `X → S` is denoted
`S.proj`.
3. When `X` is compact and `S : DiscreteQuotient X`, the space `S` is
endowed with a `Fintype` instance.
## Order structure
The type `DiscreteQuotient X` is endowed with an instance of a `SemilatticeInf` with `OrderTop`.
The partial ordering `A ≤ B` mathematically means that `B.proj` factors through `A.proj`.
The top element `⊤` is the trivial quotient, meaning that every element of `X` is collapsed
to a point. Given `h : A ≤ B`, the map `A → B` is `DiscreteQuotient.ofLE h`.
Whenever `X` is a locally connected space, the type `DiscreteQuotient X` is also endowed with an
instance of an `OrderBot`, where the bot element `⊥` is given by the `connectedComponentSetoid`,
i.e., `x ~ y` means that `x` and `y` belong to the same connected component. In particular, if `X`
is a discrete topological space, then `x ~ y` is equivalent (propositionally, not definitionally) to
`x = y`.
Given `f : C(X, Y)`, we define a predicate `DiscreteQuotient.LEComap f A B` for
`A : DiscreteQuotient X` and `B : DiscreteQuotient Y`, asserting that `f` descends to `A → B`. If
`cond : DiscreteQuotient.LEComap h A B`, the function `A → B` is obtained by
`DiscreteQuotient.map f cond`.
## Theorems
The two main results proved in this file are:
1. `DiscreteQuotient.eq_of_forall_proj_eq` which states that when `X` is compact, T₂, and totally
disconnected, any two elements of `X` are equal if their projections in `Q` agree for all
`Q : DiscreteQuotient X`.
2. `DiscreteQuotient.exists_of_compat` which states that when `X` is compact, then any
system of elements of `Q` as `Q : DiscreteQuotient X` varies, which is compatible with
respect to `DiscreteQuotient.ofLE`, must arise from some element of `X`.
## Remarks
The constructions in this file will be used to show that any profinite space is a limit
of finite discrete spaces.
-/
open Set Function TopologicalSpace Topology
variable {α X Y Z : Type*} [TopologicalSpace X] [TopologicalSpace Y] [TopologicalSpace Z]
/-- The type of discrete quotients of a topological space. -/
@[ext]
structure DiscreteQuotient (X : Type*) [TopologicalSpace X] extends Setoid X where
/-- For every point `x`, the set `{ y | Rel x y }` is an open set. -/
protected isOpen_setOf_rel : ∀ x, IsOpen (setOf (toSetoid x))
namespace DiscreteQuotient
variable (S : DiscreteQuotient X)
lemma toSetoid_injective : Function.Injective (@toSetoid X _)
| ⟨_, _⟩, ⟨_, _⟩, _ => by congr
/-- Construct a discrete quotient from a clopen set. -/
def ofIsClopen {A : Set X} (h : IsClopen A) : DiscreteQuotient X where
toSetoid := ⟨fun x y => x ∈ A ↔ y ∈ A, fun _ => Iff.rfl, Iff.symm, Iff.trans⟩
isOpen_setOf_rel x := by by_cases hx : x ∈ A <;> simp [hx, h.1, h.2, ← compl_setOf]
theorem refl : ∀ x, S.toSetoid x x := S.refl'
theorem symm (x y : X) : S.toSetoid x y → S.toSetoid y x := S.symm'
theorem trans (x y z : X) : S.toSetoid x y → S.toSetoid y z → S.toSetoid x z := S.trans'
/-- The setoid whose quotient yields the discrete quotient. -/
add_decl_doc toSetoid
instance : CoeSort (DiscreteQuotient X) (Type _) :=
⟨fun S => Quotient S.toSetoid⟩
instance : TopologicalSpace S :=
inferInstanceAs (TopologicalSpace (Quotient S.toSetoid))
/-- The projection from `X` to the given discrete quotient. -/
def proj : X → S := Quotient.mk''
theorem fiber_eq (x : X) : S.proj ⁻¹' {S.proj x} = setOf (S.toSetoid x) :=
Set.ext fun _ => eq_comm.trans Quotient.eq''
theorem proj_surjective : Function.Surjective S.proj :=
Quotient.mk''_surjective
theorem proj_isQuotientMap : IsQuotientMap S.proj :=
isQuotientMap_quot_mk
@[deprecated (since := "2024-10-22")]
alias proj_quotientMap := proj_isQuotientMap
theorem proj_continuous : Continuous S.proj :=
S.proj_isQuotientMap.continuous
instance : DiscreteTopology S :=
singletons_open_iff_discrete.1 <| S.proj_surjective.forall.2 fun x => by
rw [← S.proj_isQuotientMap.isOpen_preimage, fiber_eq]
exact S.isOpen_setOf_rel _
theorem proj_isLocallyConstant : IsLocallyConstant S.proj :=
(IsLocallyConstant.iff_continuous S.proj).2 S.proj_continuous
theorem isClopen_preimage (A : Set S) : IsClopen (S.proj ⁻¹' A) :=
(isClopen_discrete A).preimage S.proj_continuous
theorem isOpen_preimage (A : Set S) : IsOpen (S.proj ⁻¹' A) :=
(S.isClopen_preimage A).2
theorem isClosed_preimage (A : Set S) : IsClosed (S.proj ⁻¹' A) :=
(S.isClopen_preimage A).1
theorem isClopen_setOf_rel (x : X) : IsClopen (setOf (S.toSetoid x)) := by
rw [← fiber_eq]
apply isClopen_preimage
instance : Min (DiscreteQuotient X) :=
⟨fun S₁ S₂ => ⟨S₁.1 ⊓ S₂.1, fun x => (S₁.2 x).inter (S₂.2 x)⟩⟩
instance : SemilatticeInf (DiscreteQuotient X) :=
Injective.semilatticeInf toSetoid toSetoid_injective fun _ _ => rfl
instance : OrderTop (DiscreteQuotient X) where
top := ⟨⊤, fun _ => isOpen_univ⟩
le_top a := by tauto
instance : Inhabited (DiscreteQuotient X) := ⟨⊤⟩
instance inhabitedQuotient [Inhabited X] : Inhabited S := ⟨S.proj default⟩
-- TODO: add instances about `Nonempty (Quot _)`/`Nonempty (Quotient _)`
instance [Nonempty X] : Nonempty S := Nonempty.map S.proj ‹_›
/-- The quotient by `⊤ : DiscreteQuotient X` is a `Subsingleton`. -/
instance : Subsingleton (⊤ : DiscreteQuotient X) where
allEq := by rintro ⟨_⟩ ⟨_⟩; exact Quotient.sound trivial
section Comap
variable (g : C(Y, Z)) (f : C(X, Y))
/-- Comap a discrete quotient along a continuous map. -/
def comap (S : DiscreteQuotient Y) : DiscreteQuotient X where
toSetoid := Setoid.comap f S.1
isOpen_setOf_rel _ := (S.2 _).preimage f.continuous
@[simp]
theorem comap_id : S.comap (ContinuousMap.id X) = S := rfl
@[simp]
theorem comap_comp (S : DiscreteQuotient Z) : S.comap (g.comp f) = (S.comap g).comap f :=
rfl
@[mono]
theorem comap_mono {A B : DiscreteQuotient Y} (h : A ≤ B) : A.comap f ≤ B.comap f := by tauto
end Comap
section OfLE
variable {A B C : DiscreteQuotient X}
/-- The map induced by a refinement of a discrete quotient. -/
def ofLE (h : A ≤ B) : A → B :=
Quotient.map' id h
@[simp]
theorem ofLE_refl : ofLE (le_refl A) = id := by
ext ⟨⟩
rfl
theorem ofLE_refl_apply (a : A) : ofLE (le_refl A) a = a := by simp
@[simp]
theorem ofLE_ofLE (h₁ : A ≤ B) (h₂ : B ≤ C) (x : A) :
ofLE h₂ (ofLE h₁ x) = ofLE (h₁.trans h₂) x := by
rcases x with ⟨⟩
rfl
@[simp]
theorem ofLE_comp_ofLE (h₁ : A ≤ B) (h₂ : B ≤ C) : ofLE h₂ ∘ ofLE h₁ = ofLE (le_trans h₁ h₂) :=
funext <| ofLE_ofLE _ _
theorem ofLE_continuous (h : A ≤ B) : Continuous (ofLE h) :=
continuous_of_discreteTopology
@[simp]
theorem ofLE_proj (h : A ≤ B) (x : X) : ofLE h (A.proj x) = B.proj x :=
Quotient.sound' (B.refl _)
@[simp]
theorem ofLE_comp_proj (h : A ≤ B) : ofLE h ∘ A.proj = B.proj :=
funext <| ofLE_proj _
end OfLE
/-- When `X` is a locally connected space, there is an `OrderBot` instance on
`DiscreteQuotient X`. The bottom element is given by `connectedComponentSetoid X`
-/
instance [LocallyConnectedSpace X] : OrderBot (DiscreteQuotient X) where
bot :=
{ toSetoid := connectedComponentSetoid X
isOpen_setOf_rel := fun x => by
convert isOpen_connectedComponent (x := x)
ext y
simpa only [connectedComponentSetoid, ← connectedComponent_eq_iff_mem] using eq_comm }
bot_le S := fun x y (h : connectedComponent x = connectedComponent y) =>
(S.isClopen_setOf_rel x).connectedComponent_subset (S.refl _) <| h.symm ▸ mem_connectedComponent
@[simp]
theorem proj_bot_eq [LocallyConnectedSpace X] {x y : X} :
proj ⊥ x = proj ⊥ y ↔ connectedComponent x = connectedComponent y :=
Quotient.eq''
theorem proj_bot_inj [DiscreteTopology X] {x y : X} : proj ⊥ x = proj ⊥ y ↔ x = y := by simp
theorem proj_bot_injective [DiscreteTopology X] : Injective (⊥ : DiscreteQuotient X).proj :=
fun _ _ => proj_bot_inj.1
theorem proj_bot_bijective [DiscreteTopology X] : Bijective (⊥ : DiscreteQuotient X).proj :=
⟨proj_bot_injective, proj_surjective _⟩
section Map
variable (f : C(X, Y)) (A A' : DiscreteQuotient X) (B B' : DiscreteQuotient Y)
/-- Given `f : C(X, Y)`, `DiscreteQuotient.LEComap f A B` is defined as
`A ≤ B.comap f`. Mathematically this means that `f` descends to a morphism `A → B`. -/
def LEComap : Prop :=
A ≤ B.comap f
theorem leComap_id : LEComap (.id X) A A := le_rfl
variable {A A' B B'} {f} {g : C(Y, Z)} {C : DiscreteQuotient Z}
@[simp]
theorem leComap_id_iff : LEComap (ContinuousMap.id X) A A' ↔ A ≤ A' :=
Iff.rfl
theorem LEComap.comp : LEComap g B C → LEComap f A B → LEComap (g.comp f) A C := by tauto
@[mono]
theorem LEComap.mono (h : LEComap f A B) (hA : A' ≤ A) (hB : B ≤ B') : LEComap f A' B' :=
hA.trans <| h.trans <| comap_mono _ hB
/-- Map a discrete quotient along a continuous map. -/
def map (f : C(X, Y)) (cond : LEComap f A B) : A → B := Quotient.map' f cond
theorem map_continuous (cond : LEComap f A B) : Continuous (map f cond) :=
continuous_of_discreteTopology
@[simp]
theorem map_comp_proj (cond : LEComap f A B) : map f cond ∘ A.proj = B.proj ∘ f :=
rfl
@[simp]
theorem map_proj (cond : LEComap f A B) (x : X) : map f cond (A.proj x) = B.proj (f x) :=
rfl
@[simp]
theorem map_id : map _ (leComap_id A) = id := by ext ⟨⟩; rfl
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: figure out why `simpNF` says this is a bad `@[simp]` lemma
-- See https://github.com/leanprover-community/batteries/issues/365
theorem map_comp (h1 : LEComap g B C) (h2 : LEComap f A B) :
map (g.comp f) (h1.comp h2) = map g h1 ∘ map f h2 := by
ext ⟨⟩
rfl
@[simp]
theorem ofLE_map (cond : LEComap f A B) (h : B ≤ B') (a : A) :
ofLE h (map f cond a) = map f (cond.mono le_rfl h) a := by
rcases a with ⟨⟩
rfl
@[simp]
theorem ofLE_comp_map (cond : LEComap f A B) (h : B ≤ B') :
ofLE h ∘ map f cond = map f (cond.mono le_rfl h) :=
funext <| ofLE_map cond h
@[simp]
theorem map_ofLE (cond : LEComap f A B) (h : A' ≤ A) (c : A') :
map f cond (ofLE h c) = map f (cond.mono h le_rfl) c := by
rcases c with ⟨⟩
rfl
@[simp]
theorem map_comp_ofLE (cond : LEComap f A B) (h : A' ≤ A) :
map f cond ∘ ofLE h = map f (cond.mono h le_rfl) :=
funext <| map_ofLE cond h
end Map
theorem eq_of_forall_proj_eq [T2Space X] [CompactSpace X] [disc : TotallyDisconnectedSpace X]
{x y : X} (h : ∀ Q : DiscreteQuotient X, Q.proj x = Q.proj y) : x = y := by
rw [← mem_singleton_iff, ← connectedComponent_eq_singleton, connectedComponent_eq_iInter_isClopen,
mem_iInter]
rintro ⟨U, hU1, hU2⟩
exact (Quotient.exact' (h (ofIsClopen hU1))).mpr hU2
theorem fiber_subset_ofLE {A B : DiscreteQuotient X} (h : A ≤ B) (a : A) :
A.proj ⁻¹' {a} ⊆ B.proj ⁻¹' {ofLE h a} := by
rcases A.proj_surjective a with ⟨a, rfl⟩
rw [fiber_eq, ofLE_proj, fiber_eq]
exact fun _ h' => h h'
theorem exists_of_compat [CompactSpace X] (Qs : (Q : DiscreteQuotient X) → Q)
(compat : ∀ (A B : DiscreteQuotient X) (h : A ≤ B), ofLE h (Qs _) = Qs _) :
∃ x : X, ∀ Q : DiscreteQuotient X, Q.proj x = Qs _ := by
have H₁ : ∀ Q₁ Q₂, Q₁ ≤ Q₂ → proj Q₁ ⁻¹' {Qs Q₁} ⊆ proj Q₂ ⁻¹' {Qs Q₂} := fun _ _ h => by
rw [← compat _ _ h]
exact fiber_subset_ofLE _ _
obtain ⟨x, hx⟩ : Set.Nonempty (⋂ Q, proj Q ⁻¹' {Qs Q}) :=
IsCompact.nonempty_iInter_of_directed_nonempty_isCompact_isClosed
(fun Q : DiscreteQuotient X => Q.proj ⁻¹' {Qs _}) (directed_of_isDirected_ge H₁)
(fun Q => (singleton_nonempty _).preimage Q.proj_surjective)
(fun Q => (Q.isClosed_preimage {Qs _}).isCompact) fun Q => Q.isClosed_preimage _
exact ⟨x, mem_iInter.1 hx⟩
/-- If `X` is a compact space, then any discrete quotient of `X` is finite. -/
instance [CompactSpace X] : Finite S := by
have : CompactSpace S := Quotient.compactSpace
rwa [← isCompact_univ_iff, isCompact_iff_finite, finite_univ_iff] at this
|
variable (X)
open Classical in
| Mathlib/Topology/DiscreteQuotient.lean | 348 | 351 |
/-
Copyright (c) 2022 Jujian Zhang. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jujian Zhang, Kim Morrison, Joël Riou
-/
import Mathlib.Algebra.Homology.Additive
import Mathlib.CategoryTheory.Abelian.Injective.Resolution
/-!
# Right-derived functors
We define the right-derived functors `F.rightDerived n : C ⥤ D` for any additive functor `F`
out of a category with injective resolutions.
We first define a functor
`F.rightDerivedToHomotopyCategory : C ⥤ HomotopyCategory D (ComplexShape.up ℕ)` which is
`injectiveResolutions C ⋙ F.mapHomotopyCategory _`. We show that if `X : C` and
`I : InjectiveResolution X`, then `F.rightDerivedToHomotopyCategory.obj X` identifies
to the image in the homotopy category of the functor `F` applied objectwise to `I.cocomplex`
(this isomorphism is `I.isoRightDerivedToHomotopyCategoryObj F`).
Then, the right-derived functors `F.rightDerived n : C ⥤ D` are obtained by composing
`F.rightDerivedToHomotopyCategory` with the homology functors on the homotopy category.
Similarly we define natural transformations between right-derived functors coming from
natural transformations between the original additive functors,
and show how to compute the components.
## Main results
* `Functor.isZero_rightDerived_obj_injective_succ`: injective objects have no higher
right derived functor.
* `NatTrans.rightDerived`: the natural isomorphism between right derived functors
induced by natural transformation.
* `Functor.toRightDerivedZero`: the natural transformation `F ⟶ F.rightDerived 0`,
which is an isomorphism when `F` is left exact (i.e. preserves finite limits),
see also `Functor.rightDerivedZeroIsoSelf`.
## TODO
* refactor `Functor.rightDerived` (and `Functor.leftDerived`) when the necessary
material enters mathlib: derived categories, injective/projective derivability
structures, existence of derived functors from derivability structures.
Eventually, we shall get a right derived functor
`F.rightDerivedFunctorPlus : DerivedCategory.Plus C ⥤ DerivedCategory.Plus D`,
and `F.rightDerived` shall be redefined using `F.rightDerivedFunctorPlus`.
-/
universe v u
namespace CategoryTheory
open Category Limits
variable {C : Type u} [Category.{v} C] {D : Type*} [Category D]
[Abelian C] [HasInjectiveResolutions C] [Abelian D]
/-- When `F : C ⥤ D` is an additive functor, this is
the functor `C ⥤ HomotopyCategory D (ComplexShape.up ℕ)` which
sends `X : C` to `F` applied to an injective resolution of `X`. -/
noncomputable def Functor.rightDerivedToHomotopyCategory (F : C ⥤ D) [F.Additive] :
C ⥤ HomotopyCategory D (ComplexShape.up ℕ) :=
injectiveResolutions C ⋙ F.mapHomotopyCategory _
/-- If `I : InjectiveResolution Z` and `F : C ⥤ D` is an additive functor, this is
an isomorphism between `F.rightDerivedToHomotopyCategory.obj X` and the complex
obtained by applying `F` to `I.cocomplex`. -/
noncomputable def InjectiveResolution.isoRightDerivedToHomotopyCategoryObj {X : C}
(I : InjectiveResolution X) (F : C ⥤ D) [F.Additive] :
F.rightDerivedToHomotopyCategory.obj X ≅
(F.mapHomologicalComplex _ ⋙ HomotopyCategory.quotient _ _).obj I.cocomplex :=
(F.mapHomotopyCategory _).mapIso I.iso ≪≫
(F.mapHomotopyCategoryFactors _).app I.cocomplex
@[reassoc]
lemma InjectiveResolution.isoRightDerivedToHomotopyCategoryObj_hom_naturality
{X Y : C} (f : X ⟶ Y) (I : InjectiveResolution X) (J : InjectiveResolution Y)
(φ : I.cocomplex ⟶ J.cocomplex) (comm : I.ι.f 0 ≫ φ.f 0 = f ≫ J.ι.f 0)
(F : C ⥤ D) [F.Additive] :
F.rightDerivedToHomotopyCategory.map f ≫ (J.isoRightDerivedToHomotopyCategoryObj F).hom =
(I.isoRightDerivedToHomotopyCategoryObj F).hom ≫
(F.mapHomologicalComplex _ ⋙ HomotopyCategory.quotient _ _).map φ := by
dsimp [Functor.rightDerivedToHomotopyCategory, isoRightDerivedToHomotopyCategoryObj]
rw [← Functor.map_comp_assoc, iso_hom_naturality f I J φ comm, Functor.map_comp,
assoc, assoc]
erw [(F.mapHomotopyCategoryFactors (ComplexShape.up ℕ)).hom.naturality]
rfl
@[reassoc]
lemma InjectiveResolution.isoRightDerivedToHomotopyCategoryObj_inv_naturality
{X Y : C} (f : X ⟶ Y) (I : InjectiveResolution X) (J : InjectiveResolution Y)
(φ : I.cocomplex ⟶ J.cocomplex) (comm : I.ι.f 0 ≫ φ.f 0 = f ≫ J.ι.f 0)
(F : C ⥤ D) [F.Additive] :
(I.isoRightDerivedToHomotopyCategoryObj F).inv ≫ F.rightDerivedToHomotopyCategory.map f =
(F.mapHomologicalComplex _ ⋙ HomotopyCategory.quotient _ _).map φ ≫
(J.isoRightDerivedToHomotopyCategoryObj F).inv := by
rw [← cancel_epi (I.isoRightDerivedToHomotopyCategoryObj F).hom, Iso.hom_inv_id_assoc]
dsimp
rw [← isoRightDerivedToHomotopyCategoryObj_hom_naturality_assoc f I J φ comm F,
Iso.hom_inv_id, comp_id]
/-- The right derived functors of an additive functor. -/
noncomputable def Functor.rightDerived (F : C ⥤ D) [F.Additive] (n : ℕ) : C ⥤ D :=
F.rightDerivedToHomotopyCategory ⋙ HomotopyCategory.homologyFunctor D _ n
/-- We can compute a right derived functor using a chosen injective resolution. -/
noncomputable def InjectiveResolution.isoRightDerivedObj {X : C} (I : InjectiveResolution X)
(F : C ⥤ D) [F.Additive] (n : ℕ) :
(F.rightDerived n).obj X ≅
(HomologicalComplex.homologyFunctor D _ n).obj
((F.mapHomologicalComplex _).obj I.cocomplex) :=
(HomotopyCategory.homologyFunctor D _ n).mapIso
(I.isoRightDerivedToHomotopyCategoryObj F) ≪≫
(HomotopyCategory.homologyFunctorFactors D (ComplexShape.up ℕ) n).app _
@[reassoc]
lemma InjectiveResolution.isoRightDerivedObj_hom_naturality
{X Y : C} (f : X ⟶ Y) (I : InjectiveResolution X) (J : InjectiveResolution Y)
(φ : I.cocomplex ⟶ J.cocomplex) (comm : I.ι.f 0 ≫ φ.f 0 = f ≫ J.ι.f 0)
(F : C ⥤ D) [F.Additive] (n : ℕ) :
(F.rightDerived n).map f ≫ (J.isoRightDerivedObj F n).hom =
(I.isoRightDerivedObj F n).hom ≫
(F.mapHomologicalComplex _ ⋙ HomologicalComplex.homologyFunctor _ _ n).map φ := by
dsimp [isoRightDerivedObj, Functor.rightDerived]
rw [assoc, ← Functor.map_comp_assoc,
InjectiveResolution.isoRightDerivedToHomotopyCategoryObj_hom_naturality f I J φ comm F,
Functor.map_comp, assoc]
erw [(HomotopyCategory.homologyFunctorFactors D (ComplexShape.up ℕ) n).hom.naturality]
rfl
@[reassoc]
lemma InjectiveResolution.isoRightDerivedObj_inv_naturality
{X Y : C} (f : X ⟶ Y) (I : InjectiveResolution X) (J : InjectiveResolution Y)
(φ : I.cocomplex ⟶ J.cocomplex) (comm : I.ι.f 0 ≫ φ.f 0 = f ≫ J.ι.f 0)
(F : C ⥤ D) [F.Additive] (n : ℕ) :
(I.isoRightDerivedObj F n).inv ≫ (F.rightDerived n).map f =
(F.mapHomologicalComplex _ ⋙ HomologicalComplex.homologyFunctor _ _ n).map φ ≫
(J.isoRightDerivedObj F n).inv := by
rw [← cancel_mono (J.isoRightDerivedObj F n).hom, assoc, assoc,
InjectiveResolution.isoRightDerivedObj_hom_naturality f I J φ comm F n,
Iso.inv_hom_id_assoc, Iso.inv_hom_id, comp_id]
/-- The higher derived functors vanish on injective objects. -/
lemma Functor.isZero_rightDerived_obj_injective_succ
(F : C ⥤ D) [F.Additive] (n : ℕ) (X : C) [Injective X] :
IsZero ((F.rightDerived (n+1)).obj X) := by
refine IsZero.of_iso ?_ ((InjectiveResolution.self X).isoRightDerivedObj F (n + 1))
erw [← HomologicalComplex.exactAt_iff_isZero_homology]
exact ShortComplex.exact_of_isZero_X₂ _ (F.map_isZero (by apply isZero_zero))
/-- We can compute a right derived functor on a morphism using a descent of that morphism
to a cochain map between chosen injective resolutions.
-/
theorem Functor.rightDerived_map_eq (F : C ⥤ D) [F.Additive] (n : ℕ) {X Y : C} (f : X ⟶ Y)
{P : InjectiveResolution X} {Q : InjectiveResolution Y} (g : P.cocomplex ⟶ Q.cocomplex)
(w : P.ι ≫ g = (CochainComplex.single₀ C).map f ≫ Q.ι) :
(F.rightDerived n).map f =
(P.isoRightDerivedObj F n).hom ≫
(F.mapHomologicalComplex _ ⋙ HomologicalComplex.homologyFunctor _ _ n).map g ≫
(Q.isoRightDerivedObj F n).inv := by
rw [← cancel_mono (Q.isoRightDerivedObj F n).hom,
InjectiveResolution.isoRightDerivedObj_hom_naturality f P Q g _ F n,
assoc, assoc, Iso.inv_hom_id, comp_id]
rw [← HomologicalComplex.comp_f, w, HomologicalComplex.comp_f,
CochainComplex.single₀_map_f_zero]
/-- The natural transformation
`F.rightDerivedToHomotopyCategory ⟶ G.rightDerivedToHomotopyCategory` induced by
a natural transformation `F ⟶ G` between additive functors. -/
noncomputable def NatTrans.rightDerivedToHomotopyCategory
{F G : C ⥤ D} [F.Additive] [G.Additive] (α : F ⟶ G) :
F.rightDerivedToHomotopyCategory ⟶ G.rightDerivedToHomotopyCategory :=
whiskerLeft _ (NatTrans.mapHomotopyCategory α (ComplexShape.up ℕ))
lemma InjectiveResolution.rightDerivedToHomotopyCategory_app_eq
{F G : C ⥤ D} [F.Additive] [G.Additive] (α : F ⟶ G) {X : C} (P : InjectiveResolution X) :
(NatTrans.rightDerivedToHomotopyCategory α).app X =
(P.isoRightDerivedToHomotopyCategoryObj F).hom ≫
(HomotopyCategory.quotient _ _).map
((NatTrans.mapHomologicalComplex α _).app P.cocomplex) ≫
(P.isoRightDerivedToHomotopyCategoryObj G).inv := by
rw [← cancel_mono (P.isoRightDerivedToHomotopyCategoryObj G).hom, assoc, assoc,
Iso.inv_hom_id, comp_id]
dsimp [isoRightDerivedToHomotopyCategoryObj, Functor.mapHomotopyCategoryFactors,
NatTrans.rightDerivedToHomotopyCategory]
rw [assoc]
erw [id_comp, comp_id]
obtain ⟨β, hβ⟩ := (HomotopyCategory.quotient _ _).map_surjective (iso P).hom
rw [← hβ]
dsimp
simp only [← Functor.map_comp, NatTrans.mapHomologicalComplex_naturality]
rfl
@[simp]
lemma NatTrans.rightDerivedToHomotopyCategory_id (F : C ⥤ D) [F.Additive] :
NatTrans.rightDerivedToHomotopyCategory (𝟙 F) = 𝟙 _ := rfl
@[simp, reassoc]
lemma NatTrans.rightDerivedToHomotopyCategory_comp {F G H : C ⥤ D} (α : F ⟶ G) (β : G ⟶ H)
[F.Additive] [G.Additive] [H.Additive] :
NatTrans.rightDerivedToHomotopyCategory (α ≫ β) =
NatTrans.rightDerivedToHomotopyCategory α ≫
NatTrans.rightDerivedToHomotopyCategory β := rfl
/-- The natural transformation between right-derived functors
induced by a natural transformation. -/
noncomputable def NatTrans.rightDerived
{F G : C ⥤ D} [F.Additive] [G.Additive] (α : F ⟶ G) (n : ℕ) :
F.rightDerived n ⟶ G.rightDerived n :=
whiskerRight (NatTrans.rightDerivedToHomotopyCategory α) _
@[simp]
theorem NatTrans.rightDerived_id (F : C ⥤ D) [F.Additive] (n : ℕ) :
NatTrans.rightDerived (𝟙 F) n = 𝟙 (F.rightDerived n) := by
dsimp only [rightDerived]
simp only [rightDerivedToHomotopyCategory_id, whiskerRight_id']
rfl
@[simp, reassoc]
theorem NatTrans.rightDerived_comp {F G H : C ⥤ D} [F.Additive] [G.Additive] [H.Additive]
(α : F ⟶ G) (β : G ⟶ H) (n : ℕ) :
NatTrans.rightDerived (α ≫ β) n = NatTrans.rightDerived α n ≫ NatTrans.rightDerived β n := by
simp [NatTrans.rightDerived]
namespace InjectiveResolution
/-- A component of the natural transformation between right-derived functors can be computed
using a chosen injective resolution. -/
lemma rightDerived_app_eq
{F G : C ⥤ D} [F.Additive] [G.Additive] (α : F ⟶ G) {X : C} (P : InjectiveResolution X)
(n : ℕ) : (NatTrans.rightDerived α n).app X =
(P.isoRightDerivedObj F n).hom ≫
(HomologicalComplex.homologyFunctor D (ComplexShape.up ℕ) n).map
((NatTrans.mapHomologicalComplex α _).app P.cocomplex) ≫
(P.isoRightDerivedObj G n).inv := by
dsimp [NatTrans.rightDerived, isoRightDerivedObj]
rw [InjectiveResolution.rightDerivedToHomotopyCategory_app_eq α P,
Functor.map_comp, Functor.map_comp, assoc]
erw [← (HomotopyCategory.homologyFunctorFactors D (ComplexShape.up ℕ) n).hom.naturality_assoc
((NatTrans.mapHomologicalComplex α (ComplexShape.up ℕ)).app P.cocomplex)]
simp only [Functor.comp_map, Iso.hom_inv_id_app_assoc]
/-- If `P : InjectiveResolution X` and `F` is an additive functor, this is
the canonical morphism from `F.obj X` to the cycles in degree `0` of
`(F.mapHomologicalComplex _).obj P.cocomplex`. -/
noncomputable def toRightDerivedZero' {X : C}
(P : InjectiveResolution X) (F : C ⥤ D) [F.Additive] :
F.obj X ⟶ ((F.mapHomologicalComplex _).obj P.cocomplex).cycles 0 :=
HomologicalComplex.liftCycles _ (F.map (P.ι.f 0)) 1 (by simp) (by
dsimp
rw [← F.map_comp, HomologicalComplex.Hom.comm, HomologicalComplex.single_obj_d,
zero_comp, F.map_zero])
@[reassoc (attr := simp)]
lemma toRightDerivedZero'_comp_iCycles {C} [Category C] [Abelian C] {X : C}
(P : InjectiveResolution X) (F : C ⥤ D) [F.Additive] :
P.toRightDerivedZero' F ≫
HomologicalComplex.iCycles _ _ = F.map (P.ι.f 0) := by
simp [toRightDerivedZero']
@[reassoc]
lemma toRightDerivedZero'_naturality {C} [Category C] [Abelian C] {X Y : C} (f : X ⟶ Y)
(P : InjectiveResolution X) (Q : InjectiveResolution Y)
(φ : P.cocomplex ⟶ Q.cocomplex) (comm : P.ι.f 0 ≫ φ.f 0 = f ≫ Q.ι.f 0)
(F : C ⥤ D) [F.Additive] :
F.map f ≫ Q.toRightDerivedZero' F =
P.toRightDerivedZero' F ≫
HomologicalComplex.cyclesMap ((F.mapHomologicalComplex _).map φ) 0 := by
simp only [← cancel_mono (HomologicalComplex.iCycles _ _),
Functor.mapHomologicalComplex_obj_X, assoc, toRightDerivedZero'_comp_iCycles,
CochainComplex.single₀_obj_zero, HomologicalComplex.cyclesMap_i,
Functor.mapHomologicalComplex_map_f, toRightDerivedZero'_comp_iCycles_assoc,
← F.map_comp, comm]
instance (F : C ⥤ D) [F.Additive] (X : C) [Injective X] :
IsIso ((InjectiveResolution.self X).toRightDerivedZero' F) := by
dsimp [InjectiveResolution.toRightDerivedZero']
rw [CochainComplex.isIso_liftCycles_iff]
refine ⟨ShortComplex.Splitting.exact ?_, inferInstance⟩
exact
{ r := 𝟙 _
s := 0
s_g := (F.map_isZero (isZero_zero _)).eq_of_src _ _ }
end InjectiveResolution
/-- The natural transformation `F ⟶ F.rightDerived 0`. -/
noncomputable def Functor.toRightDerivedZero (F : C ⥤ D) [F.Additive] :
F ⟶ F.rightDerived 0 where
app X := (injectiveResolution X).toRightDerivedZero' F ≫
(CochainComplex.isoHomologyπ₀ _).hom ≫
(HomotopyCategory.homologyFunctorFactors D (ComplexShape.up ℕ) 0).inv.app _
naturality {X Y} f := by
dsimp [rightDerived]
rw [assoc, assoc, InjectiveResolution.toRightDerivedZero'_naturality_assoc f
(injectiveResolution X) (injectiveResolution Y)
(InjectiveResolution.desc f _ _) (by simp),
← HomologicalComplex.homologyπ_naturality_assoc]
erw [← NatTrans.naturality]
rfl
lemma InjectiveResolution.toRightDerivedZero_eq
{X : C} (I : InjectiveResolution X) (F : C ⥤ D) [F.Additive] :
F.toRightDerivedZero.app X = I.toRightDerivedZero' F ≫
(CochainComplex.isoHomologyπ₀ _).hom ≫ (I.isoRightDerivedObj F 0).inv := by
dsimp [Functor.toRightDerivedZero, isoRightDerivedObj]
have h₁ := InjectiveResolution.toRightDerivedZero'_naturality
(𝟙 X) (injectiveResolution X) I (desc (𝟙 X) _ _) (by simp) F
simp only [Functor.map_id, id_comp] at h₁
| have h₂ : (I.isoRightDerivedToHomotopyCategoryObj F).hom =
(F.mapHomologicalComplex _ ⋙ HomotopyCategory.quotient _ _).map (desc (𝟙 X) _ _) :=
comp_id _
rw [← cancel_mono ((HomotopyCategory.homologyFunctor _ _ 0).map
(I.isoRightDerivedToHomotopyCategoryObj F).hom),
assoc, assoc, assoc, assoc, assoc, ← Functor.map_comp,
Iso.inv_hom_id, Functor.map_id, comp_id,
reassoc_of% h₁, h₂, ← HomologicalComplex.homologyπ_naturality_assoc]
erw [← NatTrans.naturality]
rfl
instance (F : C ⥤ D) [F.Additive] (X : C) [Injective X] :
IsIso (F.toRightDerivedZero.app X) := by
rw [(InjectiveResolution.self X).toRightDerivedZero_eq F]
infer_instance
section
| Mathlib/CategoryTheory/Abelian/RightDerived.lean | 310 | 327 |
/-
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 | 2,033 | 2,036 | |
/-
Copyright (c) 2021 Patrick Massot. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Patrick Massot
-/
import Mathlib.Analysis.Normed.Group.Hom
import Mathlib.Analysis.SpecificLimits.Normed
/-! # Extending a backward bound on a normed group homomorphism from a dense set
Possible TODO (from the PR's review, https://github.com/leanprover-community/mathlib/pull/8498):
"This feels a lot like the second step in the proof of the Banach open mapping theorem
(`exists_preimage_norm_le`) ... wonder if it would be possible to refactor it using one of [the
lemmas in this file]."
-/
open Filter Finset
open Topology
variable {G : Type*} [NormedAddCommGroup G] [CompleteSpace G]
variable {H : Type*} [NormedAddCommGroup H]
/-- Given `f : NormedAddGroupHom G H` for some complete `G` and a subgroup `K` of `H`, if every
element `x` of `K` has a preimage under `f` whose norm is at most `C*‖x‖` then the same holds for
elements of the (topological) closure of `K` with constant `C+ε` instead of `C`, for any
positive `ε`.
-/
theorem controlled_closure_of_complete {f : NormedAddGroupHom G H} {K : AddSubgroup H} {C ε : ℝ}
(hC : 0 < C) (hε : 0 < ε) (hyp : f.SurjectiveOnWith K C) :
| f.SurjectiveOnWith K.topologicalClosure (C + ε) := by
rintro (h : H) (h_in : h ∈ K.topologicalClosure)
-- We first get rid of the easy case where `h = 0`.
by_cases hyp_h : h = 0
· rw [hyp_h]
use 0
simp
/- The desired preimage will be constructed as the sum of a series. Convergence of
the series will be guaranteed by completeness of `G`. We first write `h` as the sum
of a sequence `v` of elements of `K` which starts close to `h` and then quickly goes to zero.
The sequence `b` below quantifies this. -/
set b : ℕ → ℝ := fun i => (1 / 2) ^ i * (ε * ‖h‖ / 2) / C
have b_pos (i) : 0 < b i := by field_simp [b, hC, hyp_h]
obtain
⟨v : ℕ → H, lim_v : Tendsto (fun n : ℕ => ∑ k ∈ range (n + 1), v k) atTop (𝓝 h), v_in :
∀ n, v n ∈ K, hv₀ : ‖v 0 - h‖ < b 0, hv : ∀ n > 0, ‖v n‖ < b n⟩ :=
controlled_sum_of_mem_closure h_in b_pos
/- The controlled surjectivity assumption on `f` allows to build preimages `u n` for all
elements `v n` of the `v` sequence. -/
have : ∀ n, ∃ m' : G, f m' = v n ∧ ‖m'‖ ≤ C * ‖v n‖ := fun n : ℕ => hyp (v n) (v_in n)
choose u hu hnorm_u using this
/- The desired series `s` is then obtained by summing `u`. We then check our choice of
`b` ensures `s` is Cauchy. -/
set s : ℕ → G := fun n => ∑ k ∈ range (n + 1), u k
have : CauchySeq s := by
apply NormedAddCommGroup.cauchy_series_of_le_geometric'' (by norm_num) one_half_lt_one
· rintro n (hn : n ≥ 1)
calc
‖u n‖ ≤ C * ‖v n‖ := hnorm_u n
_ ≤ C * b n := by gcongr; exact (hv _ <| Nat.succ_le_iff.mp hn).le
_ = (1 / 2) ^ n * (ε * ‖h‖ / 2) := by simp [b, mul_div_cancel₀ _ hC.ne.symm]
_ = ε * ‖h‖ / 2 * (1 / 2) ^ n := mul_comm _ _
-- We now show that the limit `g` of `s` is the desired preimage.
obtain ⟨g : G, hg⟩ := cauchySeq_tendsto_of_complete this
refine ⟨g, ?_, ?_⟩
· -- We indeed get a preimage. First note:
have : f ∘ s = fun n => ∑ k ∈ range (n + 1), v k := by
ext n
simp [s, map_sum, hu]
/- In the above equality, the left-hand-side converges to `f g` by continuity of `f` and
definition of `g` while the right-hand-side converges to `h` by construction of `v` so
`g` is indeed a preimage of `h`. -/
rw [← this] at lim_v
exact tendsto_nhds_unique ((f.continuous.tendsto g).comp hg) lim_v
· -- Then we need to estimate the norm of `g`, using our careful choice of `b`.
suffices ∀ n, ‖s n‖ ≤ (C + ε) * ‖h‖ from
le_of_tendsto' (continuous_norm.continuousAt.tendsto.comp hg) this
intro n
have hnorm₀ : ‖u 0‖ ≤ C * b 0 + C * ‖h‖ := by
have :=
calc
‖v 0‖ ≤ ‖h‖ + ‖v 0 - h‖ := norm_le_insert' _ _
_ ≤ ‖h‖ + b 0 := by gcongr
calc
‖u 0‖ ≤ C * ‖v 0‖ := hnorm_u 0
_ ≤ C * (‖h‖ + b 0) := by gcongr
_ = C * b 0 + C * ‖h‖ := by rw [add_comm, mul_add]
have : (∑ k ∈ range (n + 1), C * b k) ≤ ε * ‖h‖ :=
calc (∑ k ∈ range (n + 1), C * b k)
_ = (∑ k ∈ range (n + 1), (1 / 2 : ℝ) ^ k) * (ε * ‖h‖ / 2) := by
simp only [b, mul_div_cancel₀ _ hC.ne.symm, ← sum_mul]
_ ≤ 2 * (ε * ‖h‖ / 2) := by gcongr; apply sum_geometric_two_le
_ = ε * ‖h‖ := mul_div_cancel₀ _ two_ne_zero
calc
‖s n‖ ≤ ∑ k ∈ range (n + 1), ‖u k‖ := norm_sum_le _ _
_ = (∑ k ∈ range n, ‖u (k + 1)‖) + ‖u 0‖ := sum_range_succ' _ _
_ ≤ (∑ k ∈ range n, C * ‖v (k + 1)‖) + ‖u 0‖ := by gcongr; apply hnorm_u
_ ≤ (∑ k ∈ range n, C * b (k + 1)) + (C * b 0 + C * ‖h‖) := by
gcongr with k; exact (hv _ k.succ_pos).le
_ = (∑ k ∈ range (n + 1), C * b k) + C * ‖h‖ := by rw [← add_assoc, sum_range_succ']
_ ≤ (C + ε) * ‖h‖ := by
rw [add_comm, add_mul]
apply add_le_add_left this
/-- Given `f : NormedAddGroupHom G H` for some complete `G`, if every element `x` of the image of
| Mathlib/Analysis/Normed/Group/ControlledClosure.lean | 32 | 106 |
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