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/-
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.Normed.Group.Completion
/-!
# Completion of normed group homs
Given two (semi) normed groups `G` and `H` and a normed group hom `f : NormedAddGroupHom G H`,
we build and study a normed group hom
`f.completion : NormedAddGroupHom (completion G) (completion H)` such that the diagram
```
f
G -----------> H
| |
| |
| |
V V
completion G -----------> completion H
f.completion
```
commutes. The map itself comes from the general theory of completion of uniform spaces, but here
we want a normed group hom, study its operator norm and kernel.
The vertical maps in the above diagrams are also normed group homs constructed in this file.
## Main definitions and results:
* `NormedAddGroupHom.completion`: see the discussion above.
* `NormedAddCommGroup.toCompl : NormedAddGroupHom G (completion G)`: the canonical map from
`G` to its completion, as a normed group hom
* `NormedAddGroupHom.completion_toCompl`: the above diagram indeed commutes.
* `NormedAddGroupHom.norm_completion`: `‖f.completion‖ = ‖f‖`
* `NormedAddGroupHom.ker_le_ker_completion`: the kernel of `f.completion` contains the image of
the kernel of `f`.
* `NormedAddGroupHom.ker_completion`: the kernel of `f.completion` is the closure of the image of
the kernel of `f` under an assumption that `f` is quantitatively surjective onto its image.
* `NormedAddGroupHom.extension` : if `H` is complete, the extension of
`f : NormedAddGroupHom G H` to a `NormedAddGroupHom (completion G) H`.
-/
noncomputable section
open Set NormedAddGroupHom UniformSpace
section Completion
variable {G : Type*} [SeminormedAddCommGroup G] {H : Type*} [SeminormedAddCommGroup H]
{K : Type*} [SeminormedAddCommGroup K]
/-- The normed group hom induced between completions. -/
def NormedAddGroupHom.completion (f : NormedAddGroupHom G H) :
NormedAddGroupHom (Completion G) (Completion H) :=
.ofLipschitz (f.toAddMonoidHom.completion f.continuous) f.lipschitz.completion_map
theorem NormedAddGroupHom.completion_def (f : NormedAddGroupHom G H) (x : Completion G) :
f.completion x = Completion.map f x :=
rfl
@[simp]
theorem NormedAddGroupHom.completion_coe_to_fun (f : NormedAddGroupHom G H) :
(f.completion : Completion G → Completion H) = Completion.map f := rfl
theorem NormedAddGroupHom.completion_coe (f : NormedAddGroupHom G H) (g : G) :
f.completion g = f g :=
Completion.map_coe f.uniformContinuous _
@[simp]
theorem NormedAddGroupHom.completion_coe' (f : NormedAddGroupHom G H) (g : G) :
Completion.map f g = f g :=
f.completion_coe g
/-- Completion of normed group homs as a normed group hom. -/
@[simps]
def normedAddGroupHomCompletionHom :
NormedAddGroupHom G H →+ NormedAddGroupHom (Completion G) (Completion H) where
toFun := NormedAddGroupHom.completion
map_zero' := toAddMonoidHom_injective AddMonoidHom.completion_zero
map_add' f g := toAddMonoidHom_injective <|
f.toAddMonoidHom.completion_add g.toAddMonoidHom f.continuous g.continuous
@[simp]
theorem NormedAddGroupHom.completion_id :
(NormedAddGroupHom.id G).completion = NormedAddGroupHom.id (Completion G) := by
ext x
rw [NormedAddGroupHom.completion_def, NormedAddGroupHom.coe_id, Completion.map_id]
rfl
theorem NormedAddGroupHom.completion_comp (f : NormedAddGroupHom G H) (g : NormedAddGroupHom H K) :
g.completion.comp f.completion = (g.comp f).completion := by
ext x
rw [NormedAddGroupHom.coe_comp, NormedAddGroupHom.completion_def,
NormedAddGroupHom.completion_coe_to_fun, NormedAddGroupHom.completion_coe_to_fun,
Completion.map_comp g.uniformContinuous f.uniformContinuous]
rfl
theorem NormedAddGroupHom.completion_neg (f : NormedAddGroupHom G H) :
(-f).completion = -f.completion :=
| map_neg (normedAddGroupHomCompletionHom : NormedAddGroupHom G H →+ _) f
theorem NormedAddGroupHom.completion_add (f g : NormedAddGroupHom G H) :
(f + g).completion = f.completion + g.completion :=
normedAddGroupHomCompletionHom.map_add f g
theorem NormedAddGroupHom.completion_sub (f g : NormedAddGroupHom G H) :
| Mathlib/Analysis/Normed/Group/HomCompletion.lean | 107 | 113 |
/-
Copyright (c) 2020 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Floris van Doorn, Yury Kudryashov
-/
import Mathlib.Topology.Instances.NNReal.Lemmas
import Mathlib.Topology.Order.MonotoneContinuity
/-!
# Square root of a real number
In this file we define
* `NNReal.sqrt` to be the square root of a nonnegative real number.
* `Real.sqrt` to be the square root of a real number, defined to be zero on negative numbers.
Then we prove some basic properties of these functions.
## Implementation notes
We define `NNReal.sqrt` as the noncomputable inverse to the function `x ↦ x * x`. We use general
theory of inverses of strictly monotone functions to prove that `NNReal.sqrt x` exists. As a side
effect, `NNReal.sqrt` is a bundled `OrderIso`, so for `NNReal` numbers we get continuity as well as
theorems like `NNReal.sqrt x ≤ y ↔ x ≤ y * y` for free.
Then we define `Real.sqrt x` to be `NNReal.sqrt (Real.toNNReal x)`.
## Tags
square root
-/
open Set Filter
open scoped Filter NNReal Topology
namespace NNReal
variable {x y : ℝ≥0}
/-- Square root of a nonnegative real number. -/
-- Porting note (kmill): `pp_nodot` has no effect here
-- unless RFC https://github.com/leanprover/lean4/issues/6178 leads to dot notation pp for CoeFun
@[pp_nodot]
noncomputable def sqrt : ℝ≥0 ≃o ℝ≥0 :=
OrderIso.symm <| powOrderIso 2 two_ne_zero
@[simp] lemma sq_sqrt (x : ℝ≥0) : sqrt x ^ 2 = x := sqrt.symm_apply_apply _
@[simp] lemma sqrt_sq (x : ℝ≥0) : sqrt (x ^ 2) = x := sqrt.apply_symm_apply _
@[simp] lemma mul_self_sqrt (x : ℝ≥0) : sqrt x * sqrt x = x := by rw [← sq, sq_sqrt]
@[simp] lemma sqrt_mul_self (x : ℝ≥0) : sqrt (x * x) = x := by rw [← sq, sqrt_sq]
lemma sqrt_le_sqrt : sqrt x ≤ sqrt y ↔ x ≤ y := sqrt.le_iff_le
lemma sqrt_lt_sqrt : sqrt x < sqrt y ↔ x < y := sqrt.lt_iff_lt
lemma sqrt_eq_iff_eq_sq : sqrt x = y ↔ x = y ^ 2 := sqrt.toEquiv.apply_eq_iff_eq_symm_apply
lemma sqrt_le_iff_le_sq : sqrt x ≤ y ↔ x ≤ y ^ 2 := sqrt.to_galoisConnection _ _
lemma le_sqrt_iff_sq_le : x ≤ sqrt y ↔ x ^ 2 ≤ y := (sqrt.symm.to_galoisConnection _ _).symm
@[simp] lemma sqrt_eq_zero : sqrt x = 0 ↔ x = 0 := by simp [sqrt_eq_iff_eq_sq]
@[simp] lemma sqrt_eq_one : sqrt x = 1 ↔ x = 1 := by simp [sqrt_eq_iff_eq_sq]
@[simp] lemma sqrt_zero : sqrt 0 = 0 := by simp
@[simp] lemma sqrt_one : sqrt 1 = 1 := by simp
@[simp] lemma sqrt_le_one : sqrt x ≤ 1 ↔ x ≤ 1 := by rw [← sqrt_one, sqrt_le_sqrt, sqrt_one]
@[simp] lemma one_le_sqrt : 1 ≤ sqrt x ↔ 1 ≤ x := by rw [← sqrt_one, sqrt_le_sqrt, sqrt_one]
theorem sqrt_mul (x y : ℝ≥0) : sqrt (x * y) = sqrt x * sqrt y := by
rw [sqrt_eq_iff_eq_sq, mul_pow, sq_sqrt, sq_sqrt]
/-- `NNReal.sqrt` as a `MonoidWithZeroHom`. -/
noncomputable def sqrtHom : ℝ≥0 →*₀ ℝ≥0 :=
⟨⟨sqrt, sqrt_zero⟩, sqrt_one, sqrt_mul⟩
theorem sqrt_inv (x : ℝ≥0) : sqrt x⁻¹ = (sqrt x)⁻¹ :=
map_inv₀ sqrtHom x
theorem sqrt_div (x y : ℝ≥0) : sqrt (x / y) = sqrt x / sqrt y :=
map_div₀ sqrtHom x y
@[continuity, fun_prop]
theorem continuous_sqrt : Continuous sqrt := sqrt.continuous
@[simp] theorem sqrt_pos : 0 < sqrt x ↔ 0 < x := by simp [pos_iff_ne_zero]
alias ⟨_, sqrt_pos_of_pos⟩ := sqrt_pos
attribute [bound] sqrt_pos_of_pos
end NNReal
namespace Real
/-- The square root of a real number. This returns 0 for negative inputs.
This has notation `√x`. Note that `√x⁻¹` is parsed as `√(x⁻¹)`. -/
noncomputable def sqrt (x : ℝ) : ℝ :=
NNReal.sqrt (Real.toNNReal x)
-- TODO: replace this with a typeclass
@[inherit_doc]
prefix:max "√" => Real.sqrt
variable {x y : ℝ}
@[simp, norm_cast]
theorem coe_sqrt {x : ℝ≥0} : (NNReal.sqrt x : ℝ) = √(x : ℝ) := by
rw [Real.sqrt, Real.toNNReal_coe]
@[continuity]
theorem continuous_sqrt : Continuous (√· : ℝ → ℝ) :=
NNReal.continuous_coe.comp <| NNReal.continuous_sqrt.comp continuous_real_toNNReal
theorem sqrt_eq_zero_of_nonpos (h : x ≤ 0) : sqrt x = 0 := by simp [sqrt, Real.toNNReal_eq_zero.2 h]
@[simp] theorem sqrt_nonneg (x : ℝ) : 0 ≤ √x := NNReal.coe_nonneg _
@[simp]
theorem mul_self_sqrt (h : 0 ≤ x) : √x * √x = x := by
rw [Real.sqrt, ← NNReal.coe_mul, NNReal.mul_self_sqrt, Real.coe_toNNReal _ h]
@[simp]
theorem sqrt_mul_self (h : 0 ≤ x) : √(x * x) = x :=
(mul_self_inj_of_nonneg (sqrt_nonneg _) h).1 (mul_self_sqrt (mul_self_nonneg _))
theorem sqrt_eq_cases : √x = y ↔ y * y = x ∧ 0 ≤ y ∨ x < 0 ∧ y = 0 := by
constructor
· rintro rfl
rcases le_or_lt 0 x with hle | hlt
· exact Or.inl ⟨mul_self_sqrt hle, sqrt_nonneg x⟩
· exact Or.inr ⟨hlt, sqrt_eq_zero_of_nonpos hlt.le⟩
· rintro (⟨rfl, hy⟩ | ⟨hx, rfl⟩)
exacts [sqrt_mul_self hy, sqrt_eq_zero_of_nonpos hx.le]
theorem sqrt_eq_iff_mul_self_eq (hx : 0 ≤ x) (hy : 0 ≤ y) : √x = y ↔ x = y * y :=
⟨fun h => by rw [← h, mul_self_sqrt hx], fun h => by rw [h, sqrt_mul_self hy]⟩
theorem sqrt_eq_iff_mul_self_eq_of_pos (h : 0 < y) : √x = y ↔ y * y = x := by
simp [sqrt_eq_cases, h.ne', h.le]
@[simp]
theorem sqrt_eq_one : √x = 1 ↔ x = 1 :=
calc
√x = 1 ↔ 1 * 1 = x := sqrt_eq_iff_mul_self_eq_of_pos zero_lt_one
_ ↔ x = 1 := by rw [eq_comm, mul_one]
@[simp]
theorem sq_sqrt (h : 0 ≤ x) : √x ^ 2 = x := by rw [sq, mul_self_sqrt h]
| Mathlib/Data/Real/Sqrt.lean | 158 | 158 | |
/-
Copyright (c) 2014 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro
-/
import Mathlib.Algebra.Divisibility.Hom
import Mathlib.Algebra.Group.Even
import Mathlib.Algebra.Group.Nat.Hom
import Mathlib.Algebra.Ring.Hom.Defs
import Mathlib.Algebra.Ring.Nat
/-!
# Cast of natural numbers (additional theorems)
This file proves additional properties about the *canonical* homomorphism from
the natural numbers into an additive monoid with a one (`Nat.cast`).
## Main declarations
* `castAddMonoidHom`: `cast` bundled as an `AddMonoidHom`.
* `castRingHom`: `cast` bundled as a `RingHom`.
-/
assert_not_exists OrderedCommGroup Commute.zero_right Commute.add_right abs_eq_max_neg
NeZero.natCast_ne
-- TODO: `MulOpposite.op_natCast` was not intended to be imported
-- assert_not_exists MulOpposite.op_natCast
open Additive Multiplicative
variable {α β : Type*}
namespace Nat
/-- `Nat.cast : ℕ → α` as an `AddMonoidHom`. -/
def castAddMonoidHom (α : Type*) [AddMonoidWithOne α] :
ℕ →+ α where
toFun := Nat.cast
map_add' := cast_add
map_zero' := cast_zero
@[simp]
theorem coe_castAddMonoidHom [AddMonoidWithOne α] : (castAddMonoidHom α : ℕ → α) = Nat.cast :=
rfl
lemma _root_.Even.natCast [AddMonoidWithOne α] {n : ℕ} (hn : Even n) : Even (n : α) :=
hn.map <| Nat.castAddMonoidHom α
section NonAssocSemiring
variable [NonAssocSemiring α]
@[simp, norm_cast] lemma cast_mul (m n : ℕ) : ((m * n : ℕ) : α) = m * n := by
induction n <;> simp [mul_succ, mul_add, *]
variable (α) in
/-- `Nat.cast : ℕ → α` as a `RingHom` -/
def castRingHom : ℕ →+* α :=
{ castAddMonoidHom α with toFun := Nat.cast, map_one' := cast_one, map_mul' := cast_mul }
@[simp, norm_cast] lemma coe_castRingHom : (castRingHom α : ℕ → α) = Nat.cast := rfl
lemma _root_.nsmul_eq_mul' (a : α) (n : ℕ) : n • a = a * n := by
induction n with
| zero => rw [zero_nsmul, Nat.cast_zero, mul_zero]
| succ n ih => rw [succ_nsmul, ih, Nat.cast_succ, mul_add, mul_one]
@[simp] lemma _root_.nsmul_eq_mul (n : ℕ) (a : α) : n • a = n * a := by
induction n with
| zero => rw [zero_nsmul, Nat.cast_zero, zero_mul]
| succ n ih => rw [succ_nsmul, ih, Nat.cast_succ, add_mul, one_mul]
end NonAssocSemiring
section Semiring
variable [Semiring α] {m n : ℕ}
@[simp, norm_cast]
lemma cast_pow (m : ℕ) : ∀ n : ℕ, ↑(m ^ n) = (m ^ n : α)
| 0 => by simp
| n + 1 => by rw [_root_.pow_succ', _root_.pow_succ', cast_mul, cast_pow m n]
lemma cast_dvd_cast (h : m ∣ n) : (m : α) ∣ (n : α) := map_dvd (Nat.castRingHom α) h
alias _root_.Dvd.dvd.natCast := cast_dvd_cast
end Semiring
end Nat
section AddMonoidHomClass
variable {A B F : Type*} [AddMonoidWithOne B] [FunLike F ℕ A] [AddMonoidWithOne A]
-- these versions are primed so that the `RingHomClass` versions aren't
theorem eq_natCast' [AddMonoidHomClass F ℕ A] (f : F) (h1 : f 1 = 1) : ∀ n : ℕ, f n = n
| 0 => by simp
| n + 1 => by rw [map_add, h1, eq_natCast' f h1 n, Nat.cast_add_one]
theorem map_natCast' {A} [AddMonoidWithOne A] [FunLike F A B] [AddMonoidHomClass F A B]
(f : F) (h : f 1 = 1) :
∀ n : ℕ, f n = n :=
eq_natCast' ((f : A →+ B).comp <| Nat.castAddMonoidHom _) (by simpa)
theorem map_ofNat' {A} [AddMonoidWithOne A] [FunLike F A B] [AddMonoidHomClass F A B]
(f : F) (h : f 1 = 1) (n : ℕ) [n.AtLeastTwo] : f (OfNat.ofNat n) = OfNat.ofNat n :=
map_natCast' f h n
end AddMonoidHomClass
section MonoidWithZeroHomClass
variable {A F : Type*} [MulZeroOneClass A] [FunLike F ℕ A]
/-- If two `MonoidWithZeroHom`s agree on the positive naturals they are equal. -/
theorem ext_nat'' [ZeroHomClass F ℕ A] (f g : F) (h_pos : ∀ {n : ℕ}, 0 < n → f n = g n) :
f = g := by
apply DFunLike.ext
rintro (_ | n)
· simp
· exact h_pos n.succ_pos
@[ext]
theorem MonoidWithZeroHom.ext_nat {f g : ℕ →*₀ A} : (∀ {n : ℕ}, 0 < n → f n = g n) → f = g :=
ext_nat'' f g
end MonoidWithZeroHomClass
section RingHomClass
variable {R S F : Type*} [NonAssocSemiring R] [NonAssocSemiring S]
@[simp]
theorem eq_natCast [FunLike F ℕ R] [RingHomClass F ℕ R] (f : F) : ∀ n, f n = n :=
eq_natCast' f <| map_one f
@[simp]
theorem map_natCast [FunLike F R S] [RingHomClass F R S] (f : F) : ∀ n : ℕ, f (n : R) = n :=
map_natCast' f <| map_one f
/-- This lemma is not marked `@[simp]` lemma because its `#discr_tree_key` (for the LHS) would just
be `DFunLike.coe _ _`, due to the `ofNat` that https://github.com/leanprover/lean4/issues/2867
forces us to include, and therefore it would negatively impact performance.
If that issue is resolved, this can be marked `@[simp]`. -/
theorem map_ofNat [FunLike F R S] [RingHomClass F R S] (f : F) (n : ℕ) [Nat.AtLeastTwo n] :
(f ofNat(n) : S) = OfNat.ofNat n :=
map_natCast f n
theorem ext_nat [FunLike F ℕ R] [RingHomClass F ℕ R] (f g : F) : f = g :=
ext_nat' f g <| by simp
theorem NeZero.nat_of_neZero {R S} [NonAssocSemiring R] [NonAssocSemiring S]
{F} [FunLike F R S] [RingHomClass F R S] (f : F)
{n : ℕ} [hn : NeZero (n : S)] : NeZero (n : R) :=
.of_map (f := f) (neZero := by simp only [map_natCast, hn])
end RingHomClass
namespace RingHom
/-- This is primed to match `eq_intCast'`. -/
theorem eq_natCast' {R} [NonAssocSemiring R] (f : ℕ →+* R) : f = Nat.castRingHom R :=
RingHom.ext <| eq_natCast f
end RingHom
@[simp, norm_cast]
theorem Nat.cast_id (n : ℕ) : n.cast = n :=
rfl
@[simp]
theorem Nat.castRingHom_nat : Nat.castRingHom ℕ = RingHom.id ℕ :=
rfl
/-- We don't use `RingHomClass` here, since that might cause type-class slowdown for
`Subsingleton`. -/
instance Nat.uniqueRingHom {R : Type*} [NonAssocSemiring R] : Unique (ℕ →+* R) where
default := Nat.castRingHom R
uniq := RingHom.eq_natCast'
namespace Pi
variable {π : α → Type*}
section NatCast
variable [∀ a, NatCast (π a)]
instance instNatCast : NatCast (∀ a, π a) where natCast n _ := n
@[simp]
theorem natCast_apply (n : ℕ) (a : α) : (n : ∀ a, π a) a = n :=
rfl
theorem natCast_def (n : ℕ) : (n : ∀ a, π a) = fun _ ↦ ↑n :=
| rfl
| Mathlib/Data/Nat/Cast/Basic.lean | 194 | 195 |
/-
Copyright (c) 2021 Rémy Degenne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Rémy Degenne, Kexing Ying
-/
import Mathlib.Probability.Notation
import Mathlib.Probability.Process.Stopping
/-!
# Martingales
A family of functions `f : ι → Ω → E` is a martingale with respect to a filtration `ℱ` if every
`f i` is integrable, `f` is adapted with respect to `ℱ` and for all `i ≤ j`,
`μ[f j | ℱ i] =ᵐ[μ] f i`. On the other hand, `f : ι → Ω → E` is said to be a supermartingale
with respect to the filtration `ℱ` if `f i` is integrable, `f` is adapted with resepct to `ℱ`
and for all `i ≤ j`, `μ[f j | ℱ i] ≤ᵐ[μ] f i`. Finally, `f : ι → Ω → E` is said to be a
submartingale with respect to the filtration `ℱ` if `f i` is integrable, `f` is adapted with
resepct to `ℱ` and for all `i ≤ j`, `f i ≤ᵐ[μ] μ[f j | ℱ i]`.
The definitions of filtration and adapted can be found in `Probability.Process.Stopping`.
### Definitions
* `MeasureTheory.Martingale f ℱ μ`: `f` is a martingale with respect to filtration `ℱ` and
measure `μ`.
* `MeasureTheory.Supermartingale f ℱ μ`: `f` is a supermartingale with respect to
filtration `ℱ` and measure `μ`.
* `MeasureTheory.Submartingale f ℱ μ`: `f` is a submartingale with respect to filtration `ℱ` and
measure `μ`.
### Results
* `MeasureTheory.martingale_condExp f ℱ μ`: the sequence `fun i => μ[f | ℱ i, ℱ.le i])` is a
martingale with respect to `ℱ` and `μ`.
-/
open TopologicalSpace Filter
open scoped NNReal ENNReal MeasureTheory ProbabilityTheory
namespace MeasureTheory
variable {Ω E ι : Type*} [Preorder ι] {m0 : MeasurableSpace Ω} {μ : Measure Ω}
[NormedAddCommGroup E] [NormedSpace ℝ E] [CompleteSpace E] {f g : ι → Ω → E} {ℱ : Filtration ι m0}
/-- A family of functions `f : ι → Ω → E` is a martingale with respect to a filtration `ℱ` if `f`
is adapted with respect to `ℱ` and for all `i ≤ j`, `μ[f j | ℱ i] =ᵐ[μ] f i`. -/
def Martingale (f : ι → Ω → E) (ℱ : Filtration ι m0) (μ : Measure Ω) : Prop :=
Adapted ℱ f ∧ ∀ i j, i ≤ j → μ[f j|ℱ i] =ᵐ[μ] f i
/-- A family of integrable functions `f : ι → Ω → E` is a supermartingale with respect to a
filtration `ℱ` if `f` is adapted with respect to `ℱ` and for all `i ≤ j`,
`μ[f j | ℱ.le i] ≤ᵐ[μ] f i`. -/
def Supermartingale [LE E] (f : ι → Ω → E) (ℱ : Filtration ι m0) (μ : Measure Ω) : Prop :=
Adapted ℱ f ∧ (∀ i j, i ≤ j → μ[f j|ℱ i] ≤ᵐ[μ] f i) ∧ ∀ i, Integrable (f i) μ
/-- A family of integrable functions `f : ι → Ω → E` is a submartingale with respect to a
filtration `ℱ` if `f` is adapted with respect to `ℱ` and for all `i ≤ j`,
`f i ≤ᵐ[μ] μ[f j | ℱ.le i]`. -/
def Submartingale [LE E] (f : ι → Ω → E) (ℱ : Filtration ι m0) (μ : Measure Ω) : Prop :=
Adapted ℱ f ∧ (∀ i j, i ≤ j → f i ≤ᵐ[μ] μ[f j|ℱ i]) ∧ ∀ i, Integrable (f i) μ
theorem martingale_const (ℱ : Filtration ι m0) (μ : Measure Ω) [IsFiniteMeasure μ] (x : E) :
Martingale (fun _ _ => x) ℱ μ :=
⟨adapted_const ℱ _, fun i j _ => by rw [condExp_const (ℱ.le _)]⟩
theorem martingale_const_fun [OrderBot ι] (ℱ : Filtration ι m0) (μ : Measure Ω) [IsFiniteMeasure μ]
{f : Ω → E} (hf : StronglyMeasurable[ℱ ⊥] f) (hfint : Integrable f μ) :
Martingale (fun _ => f) ℱ μ := by
refine ⟨fun i => hf.mono <| ℱ.mono bot_le, fun i j _ => ?_⟩
rw [condExp_of_stronglyMeasurable (ℱ.le _) (hf.mono <| ℱ.mono bot_le) hfint]
variable (E) in
theorem martingale_zero (ℱ : Filtration ι m0) (μ : Measure Ω) : Martingale (0 : ι → Ω → E) ℱ μ :=
⟨adapted_zero E ℱ, fun i j _ => by rw [Pi.zero_apply, condExp_zero]; simp⟩
namespace Martingale
protected theorem adapted (hf : Martingale f ℱ μ) : Adapted ℱ f :=
hf.1
protected theorem stronglyMeasurable (hf : Martingale f ℱ μ) (i : ι) :
StronglyMeasurable[ℱ i] (f i) :=
hf.adapted i
theorem condExp_ae_eq (hf : Martingale f ℱ μ) {i j : ι} (hij : i ≤ j) : μ[f j|ℱ i] =ᵐ[μ] f i :=
hf.2 i j hij
@[deprecated (since := "2025-01-21")] alias condexp_ae_eq := condExp_ae_eq
protected theorem integrable (hf : Martingale f ℱ μ) (i : ι) : Integrable (f i) μ :=
integrable_condExp.congr (hf.condExp_ae_eq (le_refl i))
theorem setIntegral_eq [SigmaFiniteFiltration μ ℱ] (hf : Martingale f ℱ μ) {i j : ι} (hij : i ≤ j)
{s : Set Ω} (hs : MeasurableSet[ℱ i] s) : ∫ ω in s, f i ω ∂μ = ∫ ω in s, f j ω ∂μ := by
rw [← setIntegral_condExp (ℱ.le i) (hf.integrable j) hs]
refine setIntegral_congr_ae (ℱ.le i s hs) ?_
filter_upwards [hf.2 i j hij] with _ heq _ using heq.symm
theorem add (hf : Martingale f ℱ μ) (hg : Martingale g ℱ μ) : Martingale (f + g) ℱ μ := by
refine ⟨hf.adapted.add hg.adapted, fun i j hij => ?_⟩
exact (condExp_add (hf.integrable j) (hg.integrable j) _).trans
((hf.2 i j hij).add (hg.2 i j hij))
theorem neg (hf : Martingale f ℱ μ) : Martingale (-f) ℱ μ :=
⟨hf.adapted.neg, fun i j hij => (condExp_neg ..).trans (hf.2 i j hij).neg⟩
theorem sub (hf : Martingale f ℱ μ) (hg : Martingale g ℱ μ) : Martingale (f - g) ℱ μ := by
rw [sub_eq_add_neg]; exact hf.add hg.neg
theorem smul (c : ℝ) (hf : Martingale f ℱ μ) : Martingale (c • f) ℱ μ := by
refine ⟨hf.adapted.smul c, fun i j hij => ?_⟩
refine (condExp_smul ..).trans ((hf.2 i j hij).mono fun x hx => ?_)
simp only [Pi.smul_apply, hx]
theorem supermartingale [Preorder E] (hf : Martingale f ℱ μ) : Supermartingale f ℱ μ :=
⟨hf.1, fun i j hij => (hf.2 i j hij).le, fun i => hf.integrable i⟩
theorem submartingale [Preorder E] (hf : Martingale f ℱ μ) : Submartingale f ℱ μ :=
⟨hf.1, fun i j hij => (hf.2 i j hij).symm.le, fun i => hf.integrable i⟩
end Martingale
theorem martingale_iff [PartialOrder E] :
Martingale f ℱ μ ↔ Supermartingale f ℱ μ ∧ Submartingale f ℱ μ :=
⟨fun hf => ⟨hf.supermartingale, hf.submartingale⟩, fun ⟨hf₁, hf₂⟩ =>
⟨hf₁.1, fun i j hij => (hf₁.2.1 i j hij).antisymm (hf₂.2.1 i j hij)⟩⟩
theorem martingale_condExp (f : Ω → E) (ℱ : Filtration ι m0) (μ : Measure Ω)
[SigmaFiniteFiltration μ ℱ] : Martingale (fun i => μ[f|ℱ i]) ℱ μ :=
⟨fun _ => stronglyMeasurable_condExp, fun _ j hij => condExp_condExp_of_le (ℱ.mono hij) (ℱ.le j)⟩
@[deprecated (since := "2025-01-21")] alias martingale_condexp := martingale_condExp
namespace Supermartingale
protected theorem adapted [LE E] (hf : Supermartingale f ℱ μ) : Adapted ℱ f :=
hf.1
protected theorem stronglyMeasurable [LE E] (hf : Supermartingale f ℱ μ) (i : ι) :
StronglyMeasurable[ℱ i] (f i) :=
hf.adapted i
protected theorem integrable [LE E] (hf : Supermartingale f ℱ μ) (i : ι) : Integrable (f i) μ :=
hf.2.2 i
theorem condExp_ae_le [LE E] (hf : Supermartingale f ℱ μ) {i j : ι} (hij : i ≤ j) :
μ[f j|ℱ i] ≤ᵐ[μ] f i :=
hf.2.1 i j hij
@[deprecated (since := "2025-01-21")] alias condexp_ae_le := condExp_ae_le
theorem setIntegral_le [SigmaFiniteFiltration μ ℱ] {f : ι → Ω → ℝ} (hf : Supermartingale f ℱ μ)
{i j : ι} (hij : i ≤ j) {s : Set Ω} (hs : MeasurableSet[ℱ i] s) :
∫ ω in s, f j ω ∂μ ≤ ∫ ω in s, f i ω ∂μ := by
rw [← setIntegral_condExp (ℱ.le i) (hf.integrable j) hs]
refine setIntegral_mono_ae integrable_condExp.integrableOn (hf.integrable i).integrableOn ?_
filter_upwards [hf.2.1 i j hij] with _ heq using heq
theorem add [Preorder E] [AddLeftMono E] (hf : Supermartingale f ℱ μ)
(hg : Supermartingale g ℱ μ) : Supermartingale (f + g) ℱ μ := by
refine ⟨hf.1.add hg.1, fun i j hij => ?_, fun i => (hf.2.2 i).add (hg.2.2 i)⟩
refine (condExp_add (hf.integrable j) (hg.integrable j) _).le.trans ?_
filter_upwards [hf.2.1 i j hij, hg.2.1 i j hij]
intros
refine add_le_add ?_ ?_ <;> assumption
theorem add_martingale [Preorder E] [AddLeftMono E]
(hf : Supermartingale f ℱ μ) (hg : Martingale g ℱ μ) : Supermartingale (f + g) ℱ μ :=
hf.add hg.supermartingale
theorem neg [Preorder E] [AddLeftMono E] (hf : Supermartingale f ℱ μ) :
Submartingale (-f) ℱ μ := by
refine ⟨hf.1.neg, fun i j hij => ?_, fun i => (hf.2.2 i).neg⟩
refine EventuallyLE.trans ?_ (condExp_neg ..).symm.le
filter_upwards [hf.2.1 i j hij] with _ _
simpa
end Supermartingale
namespace Submartingale
protected theorem adapted [LE E] (hf : Submartingale f ℱ μ) : Adapted ℱ f :=
hf.1
protected theorem stronglyMeasurable [LE E] (hf : Submartingale f ℱ μ) (i : ι) :
StronglyMeasurable[ℱ i] (f i) :=
hf.adapted i
protected theorem integrable [LE E] (hf : Submartingale f ℱ μ) (i : ι) : Integrable (f i) μ :=
hf.2.2 i
theorem ae_le_condExp [LE E] (hf : Submartingale f ℱ μ) {i j : ι} (hij : i ≤ j) :
f i ≤ᵐ[μ] μ[f j|ℱ i] :=
hf.2.1 i j hij
@[deprecated (since := "2025-01-21")] alias ae_le_condexp := ae_le_condExp
theorem add [Preorder E] [AddLeftMono E] (hf : Submartingale f ℱ μ)
(hg : Submartingale g ℱ μ) : Submartingale (f + g) ℱ μ := by
refine ⟨hf.1.add hg.1, fun i j hij => ?_, fun i => (hf.2.2 i).add (hg.2.2 i)⟩
refine EventuallyLE.trans ?_ (condExp_add (hf.integrable j) (hg.integrable j) _).symm.le
filter_upwards [hf.2.1 i j hij, hg.2.1 i j hij]
intros
refine add_le_add ?_ ?_ <;> assumption
theorem add_martingale [Preorder E] [AddLeftMono E] (hf : Submartingale f ℱ μ)
(hg : Martingale g ℱ μ) : Submartingale (f + g) ℱ μ :=
hf.add hg.submartingale
theorem neg [Preorder E] [AddLeftMono E] (hf : Submartingale f ℱ μ) :
Supermartingale (-f) ℱ μ := by
refine ⟨hf.1.neg, fun i j hij => (condExp_neg ..).le.trans ?_, fun i => (hf.2.2 i).neg⟩
filter_upwards [hf.2.1 i j hij] with _ _
simpa
/-- The converse of this lemma is `MeasureTheory.submartingale_of_setIntegral_le`. -/
theorem setIntegral_le [SigmaFiniteFiltration μ ℱ] {f : ι → Ω → ℝ} (hf : Submartingale f ℱ μ)
{i j : ι} (hij : i ≤ j) {s : Set Ω} (hs : MeasurableSet[ℱ i] s) :
∫ ω in s, f i ω ∂μ ≤ ∫ ω in s, f j ω ∂μ := by
rw [← neg_le_neg_iff, ← integral_neg, ← integral_neg]
exact Supermartingale.setIntegral_le hf.neg hij hs
theorem sub_supermartingale [Preorder E] [AddLeftMono E]
(hf : Submartingale f ℱ μ) (hg : Supermartingale g ℱ μ) : Submartingale (f - g) ℱ μ := by
rw [sub_eq_add_neg]; exact hf.add hg.neg
theorem sub_martingale [Preorder E] [AddLeftMono E] (hf : Submartingale f ℱ μ)
(hg : Martingale g ℱ μ) : Submartingale (f - g) ℱ μ :=
hf.sub_supermartingale hg.supermartingale
protected theorem sup {f g : ι → Ω → ℝ} (hf : Submartingale f ℱ μ) (hg : Submartingale g ℱ μ) :
Submartingale (f ⊔ g) ℱ μ := by
refine ⟨fun i => @StronglyMeasurable.sup _ _ _ _ (ℱ i) _ _ _ (hf.adapted i) (hg.adapted i),
fun i j hij => ?_, fun i => Integrable.sup (hf.integrable _) (hg.integrable _)⟩
refine EventuallyLE.sup_le ?_ ?_
· exact EventuallyLE.trans (hf.2.1 i j hij)
(condExp_mono (hf.integrable _) (Integrable.sup (hf.integrable j) (hg.integrable j))
(Eventually.of_forall fun x => le_max_left _ _))
· exact EventuallyLE.trans (hg.2.1 i j hij)
(condExp_mono (hg.integrable _) (Integrable.sup (hf.integrable j) (hg.integrable j))
(Eventually.of_forall fun x => le_max_right _ _))
protected theorem pos {f : ι → Ω → ℝ} (hf : Submartingale f ℱ μ) : Submartingale (f⁺) ℱ μ :=
hf.sup (martingale_zero _ _ _).submartingale
end Submartingale
section Submartingale
theorem submartingale_of_setIntegral_le [IsFiniteMeasure μ] {f : ι → Ω → ℝ} (hadp : Adapted ℱ f)
(hint : ∀ i, Integrable (f i) μ) (hf : ∀ i j : ι,
i ≤ j → ∀ s : Set Ω, MeasurableSet[ℱ i] s → ∫ ω in s, f i ω ∂μ ≤ ∫ ω in s, f j ω ∂μ) :
Submartingale f ℱ μ := by
refine ⟨hadp, fun i j hij => ?_, hint⟩
suffices f i ≤ᵐ[μ.trim (ℱ.le i)] μ[f j|ℱ i] by exact ae_le_of_ae_le_trim this
suffices 0 ≤ᵐ[μ.trim (ℱ.le i)] μ[f j|ℱ i] - f i by
filter_upwards [this] with x hx
rwa [← sub_nonneg]
refine ae_nonneg_of_forall_setIntegral_nonneg
((integrable_condExp.sub (hint i)).trim _ (stronglyMeasurable_condExp.sub <| hadp i))
fun s hs _ => ?_
specialize hf i j hij s hs
rwa [← setIntegral_trim _ (stronglyMeasurable_condExp.sub <| hadp i) hs,
integral_sub' integrable_condExp.integrableOn (hint i).integrableOn, sub_nonneg,
setIntegral_condExp (ℱ.le i) (hint j) hs]
theorem submartingale_of_condExp_sub_nonneg [IsFiniteMeasure μ] {f : ι → Ω → ℝ} (hadp : Adapted ℱ f)
(hint : ∀ i, Integrable (f i) μ) (hf : ∀ i j, i ≤ j → 0 ≤ᵐ[μ] μ[f j - f i|ℱ i]) :
Submartingale f ℱ μ := by
refine ⟨hadp, fun i j hij => ?_, hint⟩
rw [← condExp_of_stronglyMeasurable (ℱ.le _) (hadp _) (hint _), ← eventually_sub_nonneg]
exact EventuallyLE.trans (hf i j hij) (condExp_sub (hint _) (hint _) _).le
@[deprecated (since := "2025-01-21")]
alias submartingale_of_condexp_sub_nonneg := submartingale_of_condExp_sub_nonneg
theorem Submartingale.condExp_sub_nonneg {f : ι → Ω → ℝ} (hf : Submartingale f ℱ μ) {i j : ι}
(hij : i ≤ j) : 0 ≤ᵐ[μ] μ[f j - f i|ℱ i] := by
by_cases h : SigmaFinite (μ.trim (ℱ.le i))
swap; · rw [condExp_of_not_sigmaFinite (ℱ.le i) h]
refine EventuallyLE.trans ?_ (condExp_sub (hf.integrable _) (hf.integrable _) _).symm.le
rw [eventually_sub_nonneg,
condExp_of_stronglyMeasurable (ℱ.le _) (hf.adapted _) (hf.integrable _)]
exact hf.2.1 i j hij
@[deprecated (since := "2025-01-21")]
alias Submartingale.condexp_sub_nonneg := Submartingale.condExp_sub_nonneg
theorem submartingale_iff_condExp_sub_nonneg [IsFiniteMeasure μ] {f : ι → Ω → ℝ} :
Submartingale f ℱ μ ↔
Adapted ℱ f ∧ (∀ i, Integrable (f i) μ) ∧ ∀ i j, i ≤ j → 0 ≤ᵐ[μ] μ[f j - f i|ℱ i] :=
⟨fun h => ⟨h.adapted, h.integrable, fun _ _ => h.condExp_sub_nonneg⟩, fun ⟨hadp, hint, h⟩ =>
submartingale_of_condExp_sub_nonneg hadp hint h⟩
@[deprecated (since := "2025-01-21")]
alias submartingale_iff_condexp_sub_nonneg := submartingale_iff_condExp_sub_nonneg
end Submartingale
namespace Supermartingale
theorem sub_submartingale [Preorder E] [AddLeftMono E]
(hf : Supermartingale f ℱ μ) (hg : Submartingale g ℱ μ) : Supermartingale (f - g) ℱ μ := by
rw [sub_eq_add_neg]; exact hf.add hg.neg
theorem sub_martingale [Preorder E] [AddLeftMono E]
(hf : Supermartingale f ℱ μ) (hg : Martingale g ℱ μ) : Supermartingale (f - g) ℱ μ :=
hf.sub_submartingale hg.submartingale
section
variable {F : Type*} [NormedAddCommGroup F] [Lattice F] [NormedSpace ℝ F] [CompleteSpace F]
[OrderedSMul ℝ F]
theorem smul_nonneg {f : ι → Ω → F} {c : ℝ} (hc : 0 ≤ c) (hf : Supermartingale f ℱ μ) :
Supermartingale (c • f) ℱ μ := by
refine ⟨hf.1.smul c, fun i j hij => ?_, fun i => (hf.2.2 i).smul c⟩
filter_upwards [condExp_smul c (f j) (ℱ i), hf.2.1 i j hij] with ω hω hle
simpa only [hω, Pi.smul_apply] using smul_le_smul_of_nonneg_left hle hc
theorem smul_nonpos [IsOrderedAddMonoid F] {f : ι → Ω → F} {c : ℝ}
(hc : c ≤ 0) (hf : Supermartingale f ℱ μ) :
Submartingale (c • f) ℱ μ := by
rw [← neg_neg c, (by ext (i x); simp : - -c • f = -(-c • f))]
exact (hf.smul_nonneg <| neg_nonneg.2 hc).neg
end
end Supermartingale
namespace Submartingale
section
variable {F : Type*} [NormedAddCommGroup F] [Lattice F] [IsOrderedAddMonoid F]
[NormedSpace ℝ F] [CompleteSpace F] [OrderedSMul ℝ F]
theorem smul_nonneg {f : ι → Ω → F} {c : ℝ} (hc : 0 ≤ c) (hf : Submartingale f ℱ μ) :
Submartingale (c • f) ℱ μ := by
rw [← neg_neg c, (by ext (i x); simp : - -c • f = -(c • -f))]
exact Supermartingale.neg (hf.neg.smul_nonneg hc)
theorem smul_nonpos {f : ι → Ω → F} {c : ℝ} (hc : c ≤ 0) (hf : Submartingale f ℱ μ) :
Supermartingale (c • f) ℱ μ := by
rw [← neg_neg c, (by ext (i x); simp : - -c • f = -(-c • f))]
exact (hf.smul_nonneg <| neg_nonneg.2 hc).neg
end
end Submartingale
section Nat
variable {𝒢 : Filtration ℕ m0}
theorem submartingale_of_setIntegral_le_succ [IsFiniteMeasure μ] {f : ℕ → Ω → ℝ}
(hadp : Adapted 𝒢 f) (hint : ∀ i, Integrable (f i) μ)
(hf : ∀ i, ∀ s : Set Ω, MeasurableSet[𝒢 i] s → ∫ ω in s, f i ω ∂μ ≤ ∫ ω in s, f (i + 1) ω ∂μ) :
Submartingale f 𝒢 μ := by
refine submartingale_of_setIntegral_le hadp hint fun i j hij s hs => ?_
induction' hij with k hk₁ hk₂
· exact le_rfl
· exact le_trans hk₂ (hf k s (𝒢.mono hk₁ _ hs))
theorem supermartingale_of_setIntegral_succ_le [IsFiniteMeasure μ] {f : ℕ → Ω → ℝ}
(hadp : Adapted 𝒢 f) (hint : ∀ i, Integrable (f i) μ)
(hf : ∀ i, ∀ s : Set Ω, MeasurableSet[𝒢 i] s → ∫ ω in s, f (i + 1) ω ∂μ ≤ ∫ ω in s, f i ω ∂μ) :
Supermartingale f 𝒢 μ := by
rw [← neg_neg f]
refine (submartingale_of_setIntegral_le_succ hadp.neg (fun i => (hint i).neg) ?_).neg
simpa only [integral_neg, Pi.neg_apply, neg_le_neg_iff]
theorem martingale_of_setIntegral_eq_succ [IsFiniteMeasure μ] {f : ℕ → Ω → ℝ} (hadp : Adapted 𝒢 f)
(hint : ∀ i, Integrable (f i) μ)
(hf : ∀ i, ∀ s : Set Ω, MeasurableSet[𝒢 i] s → ∫ ω in s, f i ω ∂μ = ∫ ω in s, f (i + 1) ω ∂μ) :
Martingale f 𝒢 μ :=
martingale_iff.2 ⟨supermartingale_of_setIntegral_succ_le hadp hint fun i s hs => (hf i s hs).ge,
submartingale_of_setIntegral_le_succ hadp hint fun i s hs => (hf i s hs).le⟩
theorem submartingale_nat [IsFiniteMeasure μ] {f : ℕ → Ω → ℝ} (hadp : Adapted 𝒢 f)
(hint : ∀ i, Integrable (f i) μ) (hf : ∀ i, f i ≤ᵐ[μ] μ[f (i + 1)|𝒢 i]) :
Submartingale f 𝒢 μ := by
refine submartingale_of_setIntegral_le_succ hadp hint fun i s hs => ?_
have : ∫ ω in s, f (i + 1) ω ∂μ = ∫ ω in s, (μ[f (i + 1)|𝒢 i]) ω ∂μ :=
(setIntegral_condExp (𝒢.le i) (hint _) hs).symm
rw [this]
exact setIntegral_mono_ae (hint i).integrableOn integrable_condExp.integrableOn (hf i)
theorem supermartingale_nat [IsFiniteMeasure μ] {f : ℕ → Ω → ℝ} (hadp : Adapted 𝒢 f)
(hint : ∀ i, Integrable (f i) μ) (hf : ∀ i, μ[f (i + 1)|𝒢 i] ≤ᵐ[μ] f i) :
Supermartingale f 𝒢 μ := by
rw [← neg_neg f]
refine (submartingale_nat hadp.neg (fun i => (hint i).neg) fun i =>
EventuallyLE.trans ?_ (condExp_neg ..).symm.le).neg
filter_upwards [hf i] with x hx using neg_le_neg hx
theorem martingale_nat [IsFiniteMeasure μ] {f : ℕ → Ω → ℝ} (hadp : Adapted 𝒢 f)
(hint : ∀ i, Integrable (f i) μ) (hf : ∀ i, f i =ᵐ[μ] μ[f (i + 1)|𝒢 i]) : Martingale f 𝒢 μ :=
martingale_iff.2 ⟨supermartingale_nat hadp hint fun i => (hf i).symm.le,
submartingale_nat hadp hint fun i => (hf i).le⟩
theorem submartingale_of_condExp_sub_nonneg_nat [IsFiniteMeasure μ] {f : ℕ → Ω → ℝ}
(hadp : Adapted 𝒢 f) (hint : ∀ i, Integrable (f i) μ)
(hf : ∀ i, 0 ≤ᵐ[μ] μ[f (i + 1) - f i|𝒢 i]) : Submartingale f 𝒢 μ := by
refine submartingale_nat hadp hint fun i => ?_
rw [← condExp_of_stronglyMeasurable (𝒢.le _) (hadp _) (hint _), ← eventually_sub_nonneg]
exact EventuallyLE.trans (hf i) (condExp_sub (hint _) (hint _) _).le
@[deprecated (since := "2025-01-21")]
alias submartingale_of_condexp_sub_nonneg_nat := submartingale_of_condExp_sub_nonneg_nat
theorem supermartingale_of_condExp_sub_nonneg_nat [IsFiniteMeasure μ] {f : ℕ → Ω → ℝ}
(hadp : Adapted 𝒢 f) (hint : ∀ i, Integrable (f i) μ)
(hf : ∀ i, 0 ≤ᵐ[μ] μ[f i - f (i + 1)|𝒢 i]) : Supermartingale f 𝒢 μ := by
rw [← neg_neg f]
refine (submartingale_of_condExp_sub_nonneg_nat hadp.neg (fun i => (hint i).neg) ?_).neg
simpa only [Pi.zero_apply, Pi.neg_apply, neg_sub_neg]
@[deprecated (since := "2025-01-21")]
alias supermartingale_of_condexp_sub_nonneg_nat := supermartingale_of_condExp_sub_nonneg_nat
theorem martingale_of_condExp_sub_eq_zero_nat [IsFiniteMeasure μ] {f : ℕ → Ω → ℝ}
(hadp : Adapted 𝒢 f) (hint : ∀ i, Integrable (f i) μ)
(hf : ∀ i, μ[f (i + 1) - f i|𝒢 i] =ᵐ[μ] 0) : Martingale f 𝒢 μ := by
refine martingale_iff.2 ⟨supermartingale_of_condExp_sub_nonneg_nat hadp hint fun i => ?_,
submartingale_of_condExp_sub_nonneg_nat hadp hint fun i => (hf i).symm.le⟩
rw [← neg_sub]
refine (EventuallyEq.trans ?_ (condExp_neg ..).symm).le
filter_upwards [hf i] with x hx
simpa only [Pi.zero_apply, Pi.neg_apply, zero_eq_neg]
@[deprecated (since := "2025-01-21")]
alias martingale_of_condexp_sub_eq_zero_nat := martingale_of_condExp_sub_eq_zero_nat
-- Note that one cannot use `Submartingale.zero_le_of_predictable` to prove the other two
-- corresponding lemmas without imposing more restrictions to the ordering of `E`
/-- A predictable submartingale is a.e. greater equal than its initial state. -/
theorem Submartingale.zero_le_of_predictable [Preorder E] [SigmaFiniteFiltration μ 𝒢]
{f : ℕ → Ω → E} (hfmgle : Submartingale f 𝒢 μ) (hfadp : Adapted 𝒢 fun n => f (n + 1)) (n : ℕ) :
f 0 ≤ᵐ[μ] f n := by
induction' n with k ih
· rfl
· exact ih.trans ((hfmgle.2.1 k (k + 1) k.le_succ).trans_eq <| Germ.coe_eq.mp <|
congr_arg Germ.ofFun <| condExp_of_stronglyMeasurable (𝒢.le _) (hfadp _) <| hfmgle.integrable _)
/-- A predictable supermartingale is a.e. less equal than its initial state. -/
theorem Supermartingale.le_zero_of_predictable [Preorder E] [SigmaFiniteFiltration μ 𝒢]
{f : ℕ → Ω → E} (hfmgle : Supermartingale f 𝒢 μ) (hfadp : Adapted 𝒢 fun n => f (n + 1))
(n : ℕ) : f n ≤ᵐ[μ] f 0 := by
induction' n with k ih
· rfl
· exact ((Germ.coe_eq.mp <| congr_arg Germ.ofFun <| condExp_of_stronglyMeasurable (𝒢.le _)
(hfadp _) <| hfmgle.integrable _).symm.trans_le (hfmgle.2.1 k (k + 1) k.le_succ)).trans ih
/-- A predictable martingale is a.e. equal to its initial state. -/
theorem Martingale.eq_zero_of_predictable [SigmaFiniteFiltration μ 𝒢] {f : ℕ → Ω → E}
(hfmgle : Martingale f 𝒢 μ) (hfadp : Adapted 𝒢 fun n => f (n + 1)) (n : ℕ) : f n =ᵐ[μ] f 0 := by
induction' n with k ih
· rfl
· exact ((Germ.coe_eq.mp (congr_arg Germ.ofFun <| condExp_of_stronglyMeasurable (𝒢.le _) (hfadp _)
(hfmgle.integrable _))).symm.trans (hfmgle.2 k (k + 1) k.le_succ)).trans ih
namespace Submartingale
protected theorem integrable_stoppedValue [LE E] {f : ℕ → Ω → E} (hf : Submartingale f 𝒢 μ)
| {τ : Ω → ℕ} (hτ : IsStoppingTime 𝒢 τ) {N : ℕ} (hbdd : ∀ ω, τ ω ≤ N) :
Integrable (stoppedValue f τ) μ :=
integrable_stoppedValue ℕ hτ hf.integrable hbdd
end Submartingale
| Mathlib/Probability/Martingale/Basic.lean | 469 | 474 |
/-
Copyright (c) 2023 Yaël Dillies. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies
-/
import Mathlib.Data.Finset.Lattice.Fold
/-!
# Irreducible and prime elements in an order
This file defines irreducible and prime elements in an order and shows that in a well-founded
lattice every element decomposes as a supremum of irreducible elements.
An element is sup-irreducible (resp. inf-irreducible) if it isn't `⊥` and can't be written as the
supremum of any strictly smaller elements. An element is sup-prime (resp. inf-prime) if it isn't `⊥`
and is greater than the supremum of any two elements less than it.
Primality implies irreducibility in general. The converse only holds in distributive lattices.
Both hold for all (non-minimal) elements in a linear order.
## Main declarations
* `SupIrred a`: Sup-irreducibility, `a` isn't minimal and `a = b ⊔ c → a = b ∨ a = c`
* `InfIrred a`: Inf-irreducibility, `a` isn't maximal and `a = b ⊓ c → a = b ∨ a = c`
* `SupPrime a`: Sup-primality, `a` isn't minimal and `a ≤ b ⊔ c → a ≤ b ∨ a ≤ c`
* `InfIrred a`: Inf-primality, `a` isn't maximal and `a ≥ b ⊓ c → a ≥ b ∨ a ≥ c`
* `exists_supIrred_decomposition`/`exists_infIrred_decomposition`: Decomposition into irreducibles
in a well-founded semilattice.
-/
open Finset OrderDual
variable {ι α : Type*}
/-! ### Irreducible and prime elements -/
section SemilatticeSup
variable [SemilatticeSup α] {a b c : α}
/-- A sup-irreducible element is a non-bottom element which isn't the supremum of anything smaller.
-/
def SupIrred (a : α) : Prop :=
¬IsMin a ∧ ∀ ⦃b c⦄, b ⊔ c = a → b = a ∨ c = a
/-- A sup-prime element is a non-bottom element which isn't less than the supremum of anything
smaller. -/
def SupPrime (a : α) : Prop :=
¬IsMin a ∧ ∀ ⦃b c⦄, a ≤ b ⊔ c → a ≤ b ∨ a ≤ c
theorem SupIrred.not_isMin (ha : SupIrred a) : ¬IsMin a :=
ha.1
theorem SupPrime.not_isMin (ha : SupPrime a) : ¬IsMin a :=
ha.1
theorem IsMin.not_supIrred (ha : IsMin a) : ¬SupIrred a := fun h => h.1 ha
theorem IsMin.not_supPrime (ha : IsMin a) : ¬SupPrime a := fun h => h.1 ha
@[simp]
theorem not_supIrred : ¬SupIrred a ↔ IsMin a ∨ ∃ b c, b ⊔ c = a ∧ b < a ∧ c < a := by
rw [SupIrred, not_and_or]
push_neg
rw [exists₂_congr]
simp +contextual [@eq_comm _ _ a]
@[simp]
theorem not_supPrime : ¬SupPrime a ↔ IsMin a ∨ ∃ b c, a ≤ b ⊔ c ∧ ¬a ≤ b ∧ ¬a ≤ c := by
| rw [SupPrime, not_and_or]; push_neg; rfl
protected theorem SupPrime.supIrred : SupPrime a → SupIrred a :=
And.imp_right fun h b c ha => by simpa [← ha] using h ha.ge
| Mathlib/Order/Irreducible.lean | 72 | 76 |
/-
Copyright (c) 2019 Amelia Livingston. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Amelia Livingston
-/
import Mathlib.Algebra.BigOperators.Group.Multiset.Basic
import Mathlib.Algebra.BigOperators.Group.List.Lemmas
import Mathlib.GroupTheory.Congruence.Defs
import Mathlib.Algebra.BigOperators.Group.Finset.Defs
/-!
# Interactions between `∑, ∏` and `(Add)Con`
-/
namespace Con
/-- Multiplicative congruence relations preserve product indexed by a list. -/
@[to_additive "Additive congruence relations preserve sum indexed by a list."]
protected theorem list_prod {ι M : Type*} [MulOneClass M] (c : Con M) {l : List ι} {f g : ι → M}
(h : ∀ x ∈ l, c (f x) (g x)) :
c (l.map f).prod (l.map g).prod := by
induction l with
| nil =>
simpa only [List.map_nil, List.prod_nil] using c.refl 1
| cons x xs ih =>
rw [List.map_cons, List.map_cons, List.prod_cons, List.prod_cons]
exact c.mul (h _ <| .head _) <| ih fun k hk ↦ h _ (.tail _ hk)
/-- Multiplicative congruence relations preserve product indexed by a multiset. -/
@[to_additive "Additive congruence relations preserve sum indexed by a multiset."]
protected theorem multiset_prod {ι M : Type*} [CommMonoid M] (c : Con M) {s : Multiset ι}
{f g : ι → M} (h : ∀ x ∈ s, c (f x) (g x)) :
| c (s.map f).prod (s.map g).prod := by
rcases s; simpa using c.list_prod h
/-- Multiplicative congruence relations preserve finite product. -/
| Mathlib/GroupTheory/Congruence/BigOperators.lean | 35 | 38 |
/-
Copyright (c) 2021 Eric Wieser. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Eric Wieser
-/
import Mathlib.Algebra.Module.Equiv.Defs
import Mathlib.Data.DFinsupp.Module
import Mathlib.Data.Finsupp.SMul
/-!
# Conversion between `Finsupp` and homogeneous `DFinsupp`
This module provides conversions between `Finsupp` and `DFinsupp`.
It is in its own file since neither `Finsupp` or `DFinsupp` depend on each other.
## Main definitions
* "identity" maps between `Finsupp` and `DFinsupp`:
* `Finsupp.toDFinsupp : (ι →₀ M) → (Π₀ i : ι, M)`
* `DFinsupp.toFinsupp : (Π₀ i : ι, M) → (ι →₀ M)`
* Bundled equiv versions of the above:
* `finsuppEquivDFinsupp : (ι →₀ M) ≃ (Π₀ i : ι, M)`
* `finsuppAddEquivDFinsupp : (ι →₀ M) ≃+ (Π₀ i : ι, M)`
* `finsuppLequivDFinsupp R : (ι →₀ M) ≃ₗ[R] (Π₀ i : ι, M)`
* stronger versions of `Finsupp.split`:
* `sigmaFinsuppEquivDFinsupp : ((Σ i, η i) →₀ N) ≃ (Π₀ i, (η i →₀ N))`
* `sigmaFinsuppAddEquivDFinsupp : ((Σ i, η i) →₀ N) ≃+ (Π₀ i, (η i →₀ N))`
* `sigmaFinsuppLequivDFinsupp : ((Σ i, η i) →₀ N) ≃ₗ[R] (Π₀ i, (η i →₀ N))`
## Theorems
The defining features of these operations is that they preserve the function and support:
* `Finsupp.toDFinsupp_coe`
* `Finsupp.toDFinsupp_support`
* `DFinsupp.toFinsupp_coe`
* `DFinsupp.toFinsupp_support`
and therefore map `Finsupp.single` to `DFinsupp.single` and vice versa:
* `Finsupp.toDFinsupp_single`
* `DFinsupp.toFinsupp_single`
as well as preserving arithmetic operations.
For the bundled equivalences, we provide lemmas that they reduce to `Finsupp.toDFinsupp`:
* `finsupp_add_equiv_dfinsupp_apply`
* `finsupp_lequiv_dfinsupp_apply`
* `finsupp_add_equiv_dfinsupp_symm_apply`
* `finsupp_lequiv_dfinsupp_symm_apply`
## Implementation notes
We provide `DFinsupp.toFinsupp` and `finsuppEquivDFinsupp` computably by adding
`[DecidableEq ι]` and `[Π m : M, Decidable (m ≠ 0)]` arguments. To aid with definitional unfolding,
these arguments are also present on the `noncomputable` equivs.
-/
variable {ι : Type*} {R : Type*} {M : Type*}
/-! ### Basic definitions and lemmas -/
section Defs
/-- Interpret a `Finsupp` as a homogeneous `DFinsupp`. -/
def Finsupp.toDFinsupp [Zero M] (f : ι →₀ M) : Π₀ _ : ι, M where
toFun := f
support' :=
Trunc.mk
⟨f.support.1, fun i => (Classical.em (f i = 0)).symm.imp_left Finsupp.mem_support_iff.mpr⟩
@[simp]
theorem Finsupp.toDFinsupp_coe [Zero M] (f : ι →₀ M) : ⇑f.toDFinsupp = f :=
rfl
section
variable [DecidableEq ι] [Zero M]
@[simp]
theorem Finsupp.toDFinsupp_single (i : ι) (m : M) :
(Finsupp.single i m).toDFinsupp = DFinsupp.single i m := by
ext
simp [Finsupp.single_apply, DFinsupp.single_apply]
variable [∀ m : M, Decidable (m ≠ 0)]
@[simp]
theorem toDFinsupp_support (f : ι →₀ M) : f.toDFinsupp.support = f.support := by
ext
simp
/-- Interpret a homogeneous `DFinsupp` as a `Finsupp`.
Note that the elaborator has a lot of trouble with this definition - it is often necessary to
write `(DFinsupp.toFinsupp f : ι →₀ M)` instead of `f.toFinsupp`, as for some unknown reason
using dot notation or omitting the type ascription prevents the type being resolved correctly. -/
def DFinsupp.toFinsupp (f : Π₀ _ : ι, M) : ι →₀ M :=
⟨f.support, f, fun i => by simp only [DFinsupp.mem_support_iff]⟩
@[simp]
theorem DFinsupp.toFinsupp_coe (f : Π₀ _ : ι, M) : ⇑f.toFinsupp = f :=
rfl
@[simp]
theorem DFinsupp.toFinsupp_support (f : Π₀ _ : ι, M) : f.toFinsupp.support = f.support := by
ext
simp
@[simp]
theorem DFinsupp.toFinsupp_single (i : ι) (m : M) :
(DFinsupp.single i m : Π₀ _ : ι, M).toFinsupp = Finsupp.single i m := by
ext
| simp [Finsupp.single_apply, DFinsupp.single_apply]
@[simp]
| Mathlib/Data/Finsupp/ToDFinsupp.lean | 117 | 119 |
/-
Copyright (c) 2021 Devon Tuma. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Devon Tuma
-/
import Mathlib.Algebra.Polynomial.Eval.Defs
import Mathlib.Analysis.Asymptotics.Lemmas
/-!
# Super-Polynomial Function Decay
This file defines a predicate `Asymptotics.SuperpolynomialDecay f` for a function satisfying
one of following equivalent definitions (The definition is in terms of the first condition):
* `x ^ n * f` tends to `𝓝 0` for all (or sufficiently large) naturals `n`
* `|x ^ n * f|` tends to `𝓝 0` for all naturals `n` (`superpolynomialDecay_iff_abs_tendsto_zero`)
* `|x ^ n * f|` is bounded for all naturals `n` (`superpolynomialDecay_iff_abs_isBoundedUnder`)
* `f` is `o(x ^ c)` for all integers `c` (`superpolynomialDecay_iff_isLittleO`)
* `f` is `O(x ^ c)` for all integers `c` (`superpolynomialDecay_iff_isBigO`)
These conditions are all equivalent to conditions in terms of polynomials, replacing `x ^ c` with
`p(x)` or `p(x)⁻¹` as appropriate, since asymptotically `p(x)` behaves like `X ^ p.natDegree`.
These further equivalences are not proven in mathlib but would be good future projects.
The definition of superpolynomial decay for `f : α → β` is relative to a parameter `k : α → β`.
Super-polynomial decay then means `f x` decays faster than `(k x) ^ c` for all integers `c`.
Equivalently `f x` decays faster than `p.eval (k x)` for all polynomials `p : β[X]`.
The definition is also relative to a filter `l : Filter α` where the decay rate is compared.
When the map `k` is given by `n ↦ ↑n : ℕ → ℝ` this defines negligible functions:
https://en.wikipedia.org/wiki/Negligible_function
When the map `k` is given by `(r₁,...,rₙ) ↦ r₁*...*rₙ : ℝⁿ → ℝ` this is equivalent
to the definition of rapidly decreasing functions given here:
https://ncatlab.org/nlab/show/rapidly+decreasing+function
# Main Theorems
* `SuperpolynomialDecay.polynomial_mul` says that if `f(x)` is negligible,
then so is `p(x) * f(x)` for any polynomial `p`.
* `superpolynomialDecay_iff_zpow_tendsto_zero` gives an equivalence between definitions in terms
of decaying faster than `k(x) ^ n` for all naturals `n` or `k(x) ^ c` for all integer `c`.
-/
namespace Asymptotics
open Topology Polynomial
open Filter
/-- `f` has superpolynomial decay in parameter `k` along filter `l` if
`k ^ n * f` tends to zero at `l` for all naturals `n` -/
def SuperpolynomialDecay {α β : Type*} [TopologicalSpace β] [CommSemiring β] (l : Filter α)
(k : α → β) (f : α → β) :=
∀ n : ℕ, Tendsto (fun a : α => k a ^ n * f a) l (𝓝 0)
variable {α β : Type*} {l : Filter α} {k : α → β} {f g g' : α → β}
section CommSemiring
variable [TopologicalSpace β] [CommSemiring β]
theorem SuperpolynomialDecay.congr' (hf : SuperpolynomialDecay l k f) (hfg : f =ᶠ[l] g) :
SuperpolynomialDecay l k g := fun z =>
(hf z).congr' (EventuallyEq.mul (EventuallyEq.refl l _) hfg)
theorem SuperpolynomialDecay.congr (hf : SuperpolynomialDecay l k f) (hfg : ∀ x, f x = g x) :
SuperpolynomialDecay l k g := fun z =>
(hf z).congr fun x => (congr_arg fun a => k x ^ z * a) <| hfg x
@[simp]
theorem superpolynomialDecay_zero (l : Filter α) (k : α → β) : SuperpolynomialDecay l k 0 :=
fun z => by simpa only [Pi.zero_apply, mul_zero] using tendsto_const_nhds
theorem SuperpolynomialDecay.add [ContinuousAdd β] (hf : SuperpolynomialDecay l k f)
(hg : SuperpolynomialDecay l k g) : SuperpolynomialDecay l k (f + g) := fun z => by
simpa only [mul_add, add_zero, Pi.add_apply] using (hf z).add (hg z)
theorem SuperpolynomialDecay.mul [ContinuousMul β] (hf : SuperpolynomialDecay l k f)
(hg : SuperpolynomialDecay l k g) : SuperpolynomialDecay l k (f * g) := fun z => by
simpa only [mul_assoc, one_mul, mul_zero, pow_zero] using (hf z).mul (hg 0)
theorem SuperpolynomialDecay.mul_const [ContinuousMul β] (hf : SuperpolynomialDecay l k f) (c : β) :
SuperpolynomialDecay l k fun n => f n * c := fun z => by
simpa only [← mul_assoc, zero_mul] using Tendsto.mul_const c (hf z)
theorem SuperpolynomialDecay.const_mul [ContinuousMul β] (hf : SuperpolynomialDecay l k f) (c : β) :
SuperpolynomialDecay l k fun n => c * f n :=
(hf.mul_const c).congr fun _ => mul_comm _ _
theorem SuperpolynomialDecay.param_mul (hf : SuperpolynomialDecay l k f) :
SuperpolynomialDecay l k (k * f) := fun z =>
tendsto_nhds.2 fun s hs hs0 =>
l.sets_of_superset ((tendsto_nhds.1 (hf <| z + 1)) s hs hs0) fun x hx => by
simpa only [Set.mem_preimage, Pi.mul_apply, ← mul_assoc, ← pow_succ] using hx
theorem SuperpolynomialDecay.mul_param (hf : SuperpolynomialDecay l k f) :
SuperpolynomialDecay l k (f * k) :=
hf.param_mul.congr fun _ => mul_comm _ _
theorem SuperpolynomialDecay.param_pow_mul (hf : SuperpolynomialDecay l k f) (n : ℕ) :
SuperpolynomialDecay l k (k ^ n * f) := by
induction n with
| zero => simpa only [one_mul, pow_zero] using hf
| succ n hn => simpa only [pow_succ', mul_assoc] using hn.param_mul
theorem SuperpolynomialDecay.mul_param_pow (hf : SuperpolynomialDecay l k f) (n : ℕ) :
SuperpolynomialDecay l k (f * k ^ n) :=
(hf.param_pow_mul n).congr fun _ => mul_comm _ _
theorem SuperpolynomialDecay.polynomial_mul [ContinuousAdd β] [ContinuousMul β]
(hf : SuperpolynomialDecay l k f) (p : β[X]) :
SuperpolynomialDecay l k fun x => (p.eval <| k x) * f x :=
Polynomial.induction_on' p (fun p q hp hq => by simpa [add_mul] using hp.add hq) fun n c => by
simpa [mul_assoc] using (hf.param_pow_mul n).const_mul c
theorem SuperpolynomialDecay.mul_polynomial [ContinuousAdd β] [ContinuousMul β]
(hf : SuperpolynomialDecay l k f) (p : β[X]) :
SuperpolynomialDecay l k fun x => f x * (p.eval <| k x) :=
(hf.polynomial_mul p).congr fun _ => mul_comm _ _
end CommSemiring
section OrderedCommSemiring
variable [TopologicalSpace β] [CommSemiring β] [PartialOrder β] [IsOrderedRing β] [OrderTopology β]
theorem SuperpolynomialDecay.trans_eventuallyLE (hk : 0 ≤ᶠ[l] k) (hg : SuperpolynomialDecay l k g)
(hg' : SuperpolynomialDecay l k g') (hfg : g ≤ᶠ[l] f) (hfg' : f ≤ᶠ[l] g') :
SuperpolynomialDecay l k f := fun z =>
tendsto_of_tendsto_of_tendsto_of_le_of_le' (hg z) (hg' z)
(hfg.mp (hk.mono fun _ hx hx' => mul_le_mul_of_nonneg_left hx' (pow_nonneg hx z)))
(hfg'.mp (hk.mono fun _ hx hx' => mul_le_mul_of_nonneg_left hx' (pow_nonneg hx z)))
end OrderedCommSemiring
section LinearOrderedCommRing
variable [TopologicalSpace β] [CommRing β] [LinearOrder β] [IsStrictOrderedRing β] [OrderTopology β]
variable (l k f)
theorem superpolynomialDecay_iff_abs_tendsto_zero :
SuperpolynomialDecay l k f ↔ ∀ n : ℕ, Tendsto (fun a : α => |k a ^ n * f a|) l (𝓝 0) :=
⟨fun h z => (tendsto_zero_iff_abs_tendsto_zero _).1 (h z), fun h z =>
(tendsto_zero_iff_abs_tendsto_zero _).2 (h z)⟩
theorem superpolynomialDecay_iff_superpolynomialDecay_abs :
SuperpolynomialDecay l k f ↔ SuperpolynomialDecay l (fun a => |k a|) fun a => |f a| :=
(superpolynomialDecay_iff_abs_tendsto_zero l k f).trans
(by simp_rw [SuperpolynomialDecay, abs_mul, abs_pow])
variable {l k f}
theorem SuperpolynomialDecay.trans_eventually_abs_le (hf : SuperpolynomialDecay l k f)
(hfg : abs ∘ g ≤ᶠ[l] abs ∘ f) : SuperpolynomialDecay l k g := by
rw [superpolynomialDecay_iff_abs_tendsto_zero] at hf ⊢
refine fun z =>
tendsto_of_tendsto_of_tendsto_of_le_of_le' tendsto_const_nhds (hf z)
(Eventually.of_forall fun x => abs_nonneg _) (hfg.mono fun x hx => ?_)
calc
|k x ^ z * g x| = |k x ^ z| * |g x| := abs_mul (k x ^ z) (g x)
_ ≤ |k x ^ z| * |f x| := by gcongr _ * ?_; exact hx
_ = |k x ^ z * f x| := (abs_mul (k x ^ z) (f x)).symm
theorem SuperpolynomialDecay.trans_abs_le (hf : SuperpolynomialDecay l k f)
(hfg : ∀ x, |g x| ≤ |f x|) : SuperpolynomialDecay l k g :=
hf.trans_eventually_abs_le (Eventually.of_forall hfg)
end LinearOrderedCommRing
section Field
variable [TopologicalSpace β] [Field β] (l k f)
| theorem superpolynomialDecay_mul_const_iff [ContinuousMul β] {c : β} (hc0 : c ≠ 0) :
(SuperpolynomialDecay l k fun n => f n * c) ↔ SuperpolynomialDecay l k f :=
⟨fun h => (h.mul_const c⁻¹).congr fun x => by simp [mul_assoc, mul_inv_cancel₀ hc0], fun h =>
h.mul_const c⟩
theorem superpolynomialDecay_const_mul_iff [ContinuousMul β] {c : β} (hc0 : c ≠ 0) :
(SuperpolynomialDecay l k fun n => c * f n) ↔ SuperpolynomialDecay l k f :=
⟨fun h => (h.const_mul c⁻¹).congr fun x => by simp [← mul_assoc, inv_mul_cancel₀ hc0], fun h =>
h.const_mul c⟩
| Mathlib/Analysis/Asymptotics/SuperpolynomialDecay.lean | 176 | 185 |
/-
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.Algebra.BigOperators.Option
import Mathlib.Analysis.BoxIntegral.Box.Basic
import Mathlib.Data.Set.Pairwise.Lattice
/-!
# Partitions of rectangular boxes in `ℝⁿ`
In this file we define (pre)partitions of rectangular boxes in `ℝⁿ`. A partition of a box `I` in
`ℝⁿ` (see `BoxIntegral.Prepartition` and `BoxIntegral.Prepartition.IsPartition`) is a finite set
of pairwise disjoint boxes such that their union is exactly `I`. We use `boxes : Finset (Box ι)` to
store the set of boxes.
Many lemmas about box integrals deal with pairwise disjoint collections of subboxes, so we define a
structure `BoxIntegral.Prepartition (I : BoxIntegral.Box ι)` that stores a collection of boxes
such that
* each box `J ∈ boxes` is a subbox of `I`;
* the boxes are pairwise disjoint as sets in `ℝⁿ`.
Then we define a predicate `BoxIntegral.Prepartition.IsPartition`; `π.IsPartition` means that the
boxes of `π` actually cover the whole `I`. We also define some operations on prepartitions:
* `BoxIntegral.Prepartition.biUnion`: split each box of a partition into smaller boxes;
* `BoxIntegral.Prepartition.restrict`: restrict a partition to a smaller box.
We also define a `SemilatticeInf` structure on `BoxIntegral.Prepartition I` for all
`I : BoxIntegral.Box ι`.
## Tags
rectangular box, partition
-/
open Set Finset Function
open scoped NNReal
noncomputable section
namespace BoxIntegral
variable {ι : Type*}
/-- A prepartition of `I : BoxIntegral.Box ι` is a finite set of pairwise disjoint subboxes of
`I`. -/
structure Prepartition (I : Box ι) where
/-- The underlying set of boxes -/
boxes : Finset (Box ι)
/-- Each box is a sub-box of `I` -/
le_of_mem' : ∀ J ∈ boxes, J ≤ I
/-- The boxes in a prepartition are pairwise disjoint. -/
pairwiseDisjoint : Set.Pairwise (↑boxes) (Disjoint on ((↑) : Box ι → Set (ι → ℝ)))
namespace Prepartition
variable {I J J₁ J₂ : Box ι} (π : Prepartition I) {π₁ π₂ : Prepartition I} {x : ι → ℝ}
instance : Membership (Box ι) (Prepartition I) :=
⟨fun π J => J ∈ π.boxes⟩
@[simp]
theorem mem_boxes : J ∈ π.boxes ↔ J ∈ π := Iff.rfl
@[simp]
theorem mem_mk {s h₁ h₂} : J ∈ (mk s h₁ h₂ : Prepartition I) ↔ J ∈ s := Iff.rfl
theorem disjoint_coe_of_mem (h₁ : J₁ ∈ π) (h₂ : J₂ ∈ π) (h : J₁ ≠ J₂) :
Disjoint (J₁ : Set (ι → ℝ)) J₂ :=
π.pairwiseDisjoint h₁ h₂ h
theorem eq_of_mem_of_mem (h₁ : J₁ ∈ π) (h₂ : J₂ ∈ π) (hx₁ : x ∈ J₁) (hx₂ : x ∈ J₂) : J₁ = J₂ :=
by_contra fun H => (π.disjoint_coe_of_mem h₁ h₂ H).le_bot ⟨hx₁, hx₂⟩
theorem eq_of_le_of_le (h₁ : J₁ ∈ π) (h₂ : J₂ ∈ π) (hle₁ : J ≤ J₁) (hle₂ : J ≤ J₂) : J₁ = J₂ :=
π.eq_of_mem_of_mem h₁ h₂ (hle₁ J.upper_mem) (hle₂ J.upper_mem)
theorem eq_of_le (h₁ : J₁ ∈ π) (h₂ : J₂ ∈ π) (hle : J₁ ≤ J₂) : J₁ = J₂ :=
π.eq_of_le_of_le h₁ h₂ le_rfl hle
theorem le_of_mem (hJ : J ∈ π) : J ≤ I :=
π.le_of_mem' J hJ
theorem lower_le_lower (hJ : J ∈ π) : I.lower ≤ J.lower :=
Box.antitone_lower (π.le_of_mem hJ)
theorem upper_le_upper (hJ : J ∈ π) : J.upper ≤ I.upper :=
Box.monotone_upper (π.le_of_mem hJ)
theorem injective_boxes : Function.Injective (boxes : Prepartition I → Finset (Box ι)) := by
rintro ⟨s₁, h₁, h₁'⟩ ⟨s₂, h₂, h₂'⟩ (rfl : s₁ = s₂)
rfl
@[ext]
theorem ext (h : ∀ J, J ∈ π₁ ↔ J ∈ π₂) : π₁ = π₂ :=
injective_boxes <| Finset.ext h
/-- The singleton prepartition `{J}`, `J ≤ I`. -/
@[simps]
def single (I J : Box ι) (h : J ≤ I) : Prepartition I :=
⟨{J}, by simpa, by simp⟩
@[simp]
theorem mem_single {J'} (h : J ≤ I) : J' ∈ single I J h ↔ J' = J :=
mem_singleton
/-- We say that `π ≤ π'` if each box of `π` is a subbox of some box of `π'`. -/
instance : LE (Prepartition I) :=
⟨fun π π' => ∀ ⦃I⦄, I ∈ π → ∃ I' ∈ π', I ≤ I'⟩
instance partialOrder : PartialOrder (Prepartition I) where
le := (· ≤ ·)
le_refl _ I hI := ⟨I, hI, le_rfl⟩
le_trans _ _ _ h₁₂ h₂₃ _ hI₁ :=
let ⟨_, hI₂, hI₁₂⟩ := h₁₂ hI₁
let ⟨I₃, hI₃, hI₂₃⟩ := h₂₃ hI₂
⟨I₃, hI₃, hI₁₂.trans hI₂₃⟩
le_antisymm := by
suffices ∀ {π₁ π₂ : Prepartition I}, π₁ ≤ π₂ → π₂ ≤ π₁ → π₁.boxes ⊆ π₂.boxes from
fun π₁ π₂ h₁ h₂ => injective_boxes (Subset.antisymm (this h₁ h₂) (this h₂ h₁))
intro π₁ π₂ h₁ h₂ J hJ
rcases h₁ hJ with ⟨J', hJ', hle⟩; rcases h₂ hJ' with ⟨J'', hJ'', hle'⟩
obtain rfl : J = J'' := π₁.eq_of_le hJ hJ'' (hle.trans hle')
obtain rfl : J' = J := le_antisymm ‹_› ‹_›
assumption
instance : OrderTop (Prepartition I) where
top := single I I le_rfl
le_top π _ hJ := ⟨I, by simp, π.le_of_mem hJ⟩
instance : OrderBot (Prepartition I) where
bot := ⟨∅,
fun _ hJ => (Finset.not_mem_empty _ hJ).elim,
fun _ hJ => (Set.not_mem_empty _ <| Finset.coe_empty ▸ hJ).elim⟩
bot_le _ _ hJ := (Finset.not_mem_empty _ hJ).elim
instance : Inhabited (Prepartition I) := ⟨⊤⟩
theorem le_def : π₁ ≤ π₂ ↔ ∀ J ∈ π₁, ∃ J' ∈ π₂, J ≤ J' := Iff.rfl
@[simp]
theorem mem_top : J ∈ (⊤ : Prepartition I) ↔ J = I :=
mem_singleton
@[simp]
theorem top_boxes : (⊤ : Prepartition I).boxes = {I} := rfl
@[simp]
theorem not_mem_bot : J ∉ (⊥ : Prepartition I) :=
Finset.not_mem_empty _
@[simp]
theorem bot_boxes : (⊥ : Prepartition I).boxes = ∅ := rfl
/-- An auxiliary lemma used to prove that the same point can't belong to more than
`2 ^ Fintype.card ι` closed boxes of a prepartition. -/
theorem injOn_setOf_mem_Icc_setOf_lower_eq (x : ι → ℝ) :
InjOn (fun J : Box ι => { i | J.lower i = x i }) { J | J ∈ π ∧ x ∈ Box.Icc J } := by
rintro J₁ ⟨h₁, hx₁⟩ J₂ ⟨h₂, hx₂⟩ (H : { i | J₁.lower i = x i } = { i | J₂.lower i = x i })
suffices ∀ i, (Ioc (J₁.lower i) (J₁.upper i) ∩ Ioc (J₂.lower i) (J₂.upper i)).Nonempty by
choose y hy₁ hy₂ using this
exact π.eq_of_mem_of_mem h₁ h₂ hy₁ hy₂
intro i
simp only [Set.ext_iff, mem_setOf] at H
rcases (hx₁.1 i).eq_or_lt with hi₁ | hi₁
· have hi₂ : J₂.lower i = x i := (H _).1 hi₁
have H₁ : x i < J₁.upper i := by simpa only [hi₁] using J₁.lower_lt_upper i
have H₂ : x i < J₂.upper i := by simpa only [hi₂] using J₂.lower_lt_upper i
rw [Set.Ioc_inter_Ioc, hi₁, hi₂, sup_idem, Set.nonempty_Ioc]
exact lt_min H₁ H₂
· have hi₂ : J₂.lower i < x i := (hx₂.1 i).lt_of_ne (mt (H _).2 hi₁.ne)
exact ⟨x i, ⟨hi₁, hx₁.2 i⟩, ⟨hi₂, hx₂.2 i⟩⟩
open scoped Classical in
/-- The set of boxes of a prepartition that contain `x` in their closures has cardinality
at most `2 ^ Fintype.card ι`. -/
theorem card_filter_mem_Icc_le [Fintype ι] (x : ι → ℝ) :
#{J ∈ π.boxes | x ∈ Box.Icc J} ≤ 2 ^ Fintype.card ι := by
rw [← Fintype.card_set]
refine Finset.card_le_card_of_injOn (fun J : Box ι => { i | J.lower i = x i })
(fun _ _ => Finset.mem_univ _) ?_
simpa using π.injOn_setOf_mem_Icc_setOf_lower_eq x
/-- Given a prepartition `π : BoxIntegral.Prepartition I`, `π.iUnion` is the part of `I` covered by
the boxes of `π`. -/
protected def iUnion : Set (ι → ℝ) :=
⋃ J ∈ π, ↑J
theorem iUnion_def : π.iUnion = ⋃ J ∈ π, ↑J := rfl
theorem iUnion_def' : π.iUnion = ⋃ J ∈ π.boxes, ↑J := 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, exists_prop]
@[simp]
theorem iUnion_single (h : J ≤ I) : (single I J h).iUnion = J := by simp [iUnion_def]
@[simp]
theorem iUnion_top : (⊤ : Prepartition I).iUnion = I := by simp [Prepartition.iUnion]
@[simp]
theorem iUnion_eq_empty : π₁.iUnion = ∅ ↔ π₁ = ⊥ := by
simp [← injective_boxes.eq_iff, Finset.ext_iff, Prepartition.iUnion, imp_false]
@[simp]
theorem iUnion_bot : (⊥ : Prepartition I).iUnion = ∅ :=
iUnion_eq_empty.2 rfl
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'
@[mono]
theorem iUnion_mono (h : π₁ ≤ π₂) : π₁.iUnion ⊆ π₂.iUnion := fun _ hx =>
let ⟨_, hJ₁, hx⟩ := π₁.mem_iUnion.1 hx
let ⟨J₂, hJ₂, hle⟩ := h hJ₁
π₂.mem_iUnion.2 ⟨J₂, hJ₂, hle hx⟩
theorem disjoint_boxes_of_disjoint_iUnion (h : Disjoint π₁.iUnion π₂.iUnion) :
Disjoint π₁.boxes π₂.boxes :=
Finset.disjoint_left.2 fun J h₁ h₂ =>
Disjoint.le_bot (h.mono (π₁.subset_iUnion h₁) (π₂.subset_iUnion h₂)) ⟨J.upper_mem, J.upper_mem⟩
theorem le_iff_nonempty_imp_le_and_iUnion_subset :
π₁ ≤ π₂ ↔
(∀ J ∈ π₁, ∀ J' ∈ π₂, (J ∩ J' : Set (ι → ℝ)).Nonempty → J ≤ J') ∧ π₁.iUnion ⊆ π₂.iUnion := by
constructor
· refine fun H => ⟨fun J hJ J' hJ' Hne => ?_, iUnion_mono H⟩
rcases H hJ with ⟨J'', hJ'', Hle⟩
rcases Hne with ⟨x, hx, hx'⟩
rwa [π₂.eq_of_mem_of_mem hJ' hJ'' hx' (Hle hx)]
· rintro ⟨H, HU⟩ J hJ
simp only [Set.subset_def, mem_iUnion] at HU
rcases HU J.upper ⟨J, hJ, J.upper_mem⟩ with ⟨J₂, hJ₂, hx⟩
exact ⟨J₂, hJ₂, H _ hJ _ hJ₂ ⟨_, J.upper_mem, hx⟩⟩
theorem eq_of_boxes_subset_iUnion_superset (h₁ : π₁.boxes ⊆ π₂.boxes) (h₂ : π₂.iUnion ⊆ π₁.iUnion) :
π₁ = π₂ :=
le_antisymm (fun J hJ => ⟨J, h₁ hJ, le_rfl⟩) <|
le_iff_nonempty_imp_le_and_iUnion_subset.2
⟨fun _ hJ₁ _ hJ₂ Hne =>
(π₂.eq_of_mem_of_mem hJ₁ (h₁ hJ₂) Hne.choose_spec.1 Hne.choose_spec.2).le, h₂⟩
open scoped Classical in
/-- Given a prepartition `π` of a box `I` and a collection of prepartitions `πi J` of all boxes
`J ∈ π`, returns the prepartition of `I` into the union of the boxes of all `πi J`.
Though we only use the values of `πi` on the boxes of `π`, we require `πi` to be a globally defined
function. -/
@[simps]
def biUnion (πi : ∀ J : Box ι, Prepartition J) : Prepartition I where
boxes := π.boxes.biUnion fun J => (πi J).boxes
le_of_mem' J hJ := by
simp only [Finset.mem_biUnion, exists_prop, mem_boxes] at hJ
rcases hJ with ⟨J', hJ', hJ⟩
exact ((πi J').le_of_mem hJ).trans (π.le_of_mem hJ')
pairwiseDisjoint := by
simp only [Set.Pairwise, Finset.mem_coe, Finset.mem_biUnion]
rintro J₁' ⟨J₁, hJ₁, hJ₁'⟩ J₂' ⟨J₂, hJ₂, hJ₂'⟩ Hne
rw [Function.onFun, Set.disjoint_left]
rintro x hx₁ hx₂; apply Hne
obtain rfl : J₁ = J₂ :=
π.eq_of_mem_of_mem hJ₁ hJ₂ ((πi J₁).le_of_mem hJ₁' hx₁) ((πi J₂).le_of_mem hJ₂' hx₂)
exact (πi J₁).eq_of_mem_of_mem hJ₁' hJ₂' hx₁ hx₂
variable {πi πi₁ πi₂ : ∀ J : Box ι, Prepartition J}
@[simp]
theorem mem_biUnion : J ∈ π.biUnion πi ↔ ∃ J' ∈ π, J ∈ πi J' := by simp [biUnion]
theorem biUnion_le (πi : ∀ J, Prepartition J) : π.biUnion πi ≤ π := fun _ hJ =>
let ⟨J', hJ', hJ⟩ := π.mem_biUnion.1 hJ
⟨J', hJ', (πi J').le_of_mem hJ⟩
@[simp]
theorem biUnion_top : (π.biUnion fun _ => ⊤) = π := by
ext
simp
@[congr]
theorem biUnion_congr (h : π₁ = π₂) (hi : ∀ J ∈ π₁, πi₁ J = πi₂ J) :
π₁.biUnion πi₁ = π₂.biUnion πi₂ := by
subst π₂
ext J
simp only [mem_biUnion]
constructor <;> exact fun ⟨J', h₁, h₂⟩ => ⟨J', h₁, hi J' h₁ ▸ h₂⟩
theorem biUnion_congr_of_le (h : π₁ = π₂) (hi : ∀ J ≤ I, πi₁ J = πi₂ J) :
π₁.biUnion πi₁ = π₂.biUnion πi₂ :=
biUnion_congr h fun J hJ => hi J (π₁.le_of_mem hJ)
@[simp]
theorem iUnion_biUnion (πi : ∀ J : Box ι, Prepartition J) :
(π.biUnion πi).iUnion = ⋃ J ∈ π, (πi J).iUnion := by simp [Prepartition.iUnion]
open scoped Classical in
@[simp]
theorem sum_biUnion_boxes {M : Type*} [AddCommMonoid M] (π : Prepartition I)
(πi : ∀ J, Prepartition J) (f : Box ι → M) :
(∑ J ∈ π.boxes.biUnion fun J => (πi J).boxes, f J) =
∑ J ∈ π.boxes, ∑ J' ∈ (πi J).boxes, f J' := by
refine Finset.sum_biUnion fun J₁ h₁ J₂ h₂ hne => Finset.disjoint_left.2 fun J' h₁' h₂' => ?_
exact hne (π.eq_of_le_of_le h₁ h₂ ((πi J₁).le_of_mem h₁') ((πi J₂).le_of_mem h₂'))
open scoped Classical in
/-- Given a box `J ∈ π.biUnion πi`, returns the box `J' ∈ π` such that `J ∈ πi J'`.
For `J ∉ π.biUnion πi`, returns `I`. -/
def biUnionIndex (πi : ∀ (J : Box ι), Prepartition J) (J : Box ι) : Box ι :=
if hJ : J ∈ π.biUnion πi then (π.mem_biUnion.1 hJ).choose else I
theorem biUnionIndex_mem (hJ : J ∈ π.biUnion πi) : π.biUnionIndex πi J ∈ π := by
rw [biUnionIndex, dif_pos hJ]
exact (π.mem_biUnion.1 hJ).choose_spec.1
theorem biUnionIndex_le (πi : ∀ J, Prepartition J) (J : Box ι) : π.biUnionIndex πi J ≤ I := by
by_cases hJ : J ∈ π.biUnion πi
· exact π.le_of_mem (π.biUnionIndex_mem hJ)
· rw [biUnionIndex, dif_neg hJ]
theorem mem_biUnionIndex (hJ : J ∈ π.biUnion πi) : J ∈ πi (π.biUnionIndex πi J) := by
convert (π.mem_biUnion.1 hJ).choose_spec.2 <;> exact dif_pos hJ
theorem le_biUnionIndex (hJ : J ∈ π.biUnion πi) : J ≤ π.biUnionIndex πi J :=
le_of_mem _ (π.mem_biUnionIndex hJ)
/-- Uniqueness property of `BoxIntegral.Prepartition.biUnionIndex`. -/
theorem biUnionIndex_of_mem (hJ : J ∈ π) {J'} (hJ' : J' ∈ πi J) : π.biUnionIndex πi J' = J :=
have : J' ∈ π.biUnion πi := π.mem_biUnion.2 ⟨J, hJ, hJ'⟩
π.eq_of_le_of_le (π.biUnionIndex_mem this) hJ (π.le_biUnionIndex this) (le_of_mem _ hJ')
theorem biUnion_assoc (πi : ∀ J, Prepartition J) (πi' : Box ι → ∀ J : Box ι, Prepartition J) :
(π.biUnion fun J => (πi J).biUnion (πi' J)) =
(π.biUnion πi).biUnion fun J => πi' (π.biUnionIndex πi J) J := by
ext J
simp only [mem_biUnion, exists_prop]
constructor
· rintro ⟨J₁, hJ₁, J₂, hJ₂, hJ⟩
refine ⟨J₂, ⟨J₁, hJ₁, hJ₂⟩, ?_⟩
rwa [π.biUnionIndex_of_mem hJ₁ hJ₂]
· rintro ⟨J₁, ⟨J₂, hJ₂, hJ₁⟩, hJ⟩
refine ⟨J₂, hJ₂, J₁, hJ₁, ?_⟩
rwa [π.biUnionIndex_of_mem hJ₂ hJ₁] at hJ
/-- Create a `BoxIntegral.Prepartition` from a collection of possibly empty boxes by filtering out
the empty one if it exists. -/
def ofWithBot (boxes : Finset (WithBot (Box ι)))
(le_of_mem : ∀ J ∈ boxes, (J : WithBot (Box ι)) ≤ I)
(pairwise_disjoint : Set.Pairwise (boxes : Set (WithBot (Box ι))) Disjoint) :
Prepartition I where
boxes := Finset.eraseNone boxes
le_of_mem' J hJ := by
rw [mem_eraseNone] at hJ
simpa only [WithBot.some_eq_coe, WithBot.coe_le_coe] using le_of_mem _ hJ
pairwiseDisjoint J₁ h₁ J₂ h₂ hne := by
simp only [mem_coe, mem_eraseNone] at h₁ h₂
exact Box.disjoint_coe.1 (pairwise_disjoint h₁ h₂ (mt Option.some_inj.1 hne))
@[simp]
theorem mem_ofWithBot {boxes : Finset (WithBot (Box ι))} {h₁ h₂} :
J ∈ (ofWithBot boxes h₁ h₂ : Prepartition I) ↔ (J : WithBot (Box ι)) ∈ boxes :=
mem_eraseNone
@[simp]
theorem iUnion_ofWithBot (boxes : Finset (WithBot (Box ι)))
(le_of_mem : ∀ J ∈ boxes, (J : WithBot (Box ι)) ≤ I)
(pairwise_disjoint : Set.Pairwise (boxes : Set (WithBot (Box ι))) Disjoint) :
(ofWithBot boxes le_of_mem pairwise_disjoint).iUnion = ⋃ J ∈ boxes, ↑J := by
suffices ⋃ (J : Box ι) (_ : ↑J ∈ boxes), ↑J = ⋃ J ∈ boxes, (J : Set (ι → ℝ)) by
simpa [ofWithBot, Prepartition.iUnion]
simp only [← Box.biUnion_coe_eq_coe, @iUnion_comm _ _ (Box ι), @iUnion_comm _ _ (@Eq _ _ _),
iUnion_iUnion_eq_right]
theorem ofWithBot_le {boxes : Finset (WithBot (Box ι))}
{le_of_mem : ∀ J ∈ boxes, (J : WithBot (Box ι)) ≤ I}
{pairwise_disjoint : Set.Pairwise (boxes : Set (WithBot (Box ι))) Disjoint}
(H : ∀ J ∈ boxes, J ≠ ⊥ → ∃ J' ∈ π, J ≤ ↑J') :
ofWithBot boxes le_of_mem pairwise_disjoint ≤ π := by
have : ∀ J : Box ι, ↑J ∈ boxes → ∃ J' ∈ π, J ≤ J' := fun J hJ => by
simpa only [WithBot.coe_le_coe] using H J hJ WithBot.coe_ne_bot
simpa [ofWithBot, le_def]
theorem le_ofWithBot {boxes : Finset (WithBot (Box ι))}
{le_of_mem : ∀ J ∈ boxes, (J : WithBot (Box ι)) ≤ I}
{pairwise_disjoint : Set.Pairwise (boxes : Set (WithBot (Box ι))) Disjoint}
(H : ∀ J ∈ π, ∃ J' ∈ boxes, ↑J ≤ J') : π ≤ ofWithBot boxes le_of_mem pairwise_disjoint := by
intro J hJ
rcases H J hJ with ⟨J', J'mem, hle⟩
lift J' to Box ι using ne_bot_of_le_ne_bot WithBot.coe_ne_bot hle
exact ⟨J', mem_ofWithBot.2 J'mem, WithBot.coe_le_coe.1 hle⟩
theorem ofWithBot_mono {boxes₁ : Finset (WithBot (Box ι))}
{le_of_mem₁ : ∀ J ∈ boxes₁, (J : WithBot (Box ι)) ≤ I}
{pairwise_disjoint₁ : Set.Pairwise (boxes₁ : Set (WithBot (Box ι))) Disjoint}
{boxes₂ : Finset (WithBot (Box ι))} {le_of_mem₂ : ∀ J ∈ boxes₂, (J : WithBot (Box ι)) ≤ I}
{pairwise_disjoint₂ : Set.Pairwise (boxes₂ : Set (WithBot (Box ι))) Disjoint}
(H : ∀ J ∈ boxes₁, J ≠ ⊥ → ∃ J' ∈ boxes₂, J ≤ J') :
ofWithBot boxes₁ le_of_mem₁ pairwise_disjoint₁ ≤
ofWithBot boxes₂ le_of_mem₂ pairwise_disjoint₂ :=
le_ofWithBot _ fun J hJ => H J (mem_ofWithBot.1 hJ) WithBot.coe_ne_bot
theorem sum_ofWithBot {M : Type*} [AddCommMonoid M] (boxes : Finset (WithBot (Box ι)))
(le_of_mem : ∀ J ∈ boxes, (J : WithBot (Box ι)) ≤ I)
(pairwise_disjoint : Set.Pairwise (boxes : Set (WithBot (Box ι))) Disjoint) (f : Box ι → M) :
(∑ J ∈ (ofWithBot boxes le_of_mem pairwise_disjoint).boxes, f J) =
∑ J ∈ boxes, Option.elim' 0 f J :=
Finset.sum_eraseNone _ _
open scoped Classical in
/-- Restrict a prepartition to a box. -/
def restrict (π : Prepartition I) (J : Box ι) : Prepartition J :=
ofWithBot (π.boxes.image fun J' : Box ι => J ⊓ J')
(fun J' hJ' => by
rcases Finset.mem_image.1 hJ' with ⟨J', -, rfl⟩
exact inf_le_left)
(by
simp only [Set.Pairwise, onFun, Finset.mem_coe, Finset.mem_image]
rintro _ ⟨J₁, h₁, rfl⟩ _ ⟨J₂, h₂, rfl⟩ Hne
have : J₁ ≠ J₂ := by
rintro rfl
exact Hne rfl
exact ((Box.disjoint_coe.2 <| π.disjoint_coe_of_mem h₁ h₂ this).inf_left' _).inf_right' _)
@[simp]
theorem mem_restrict : J₁ ∈ π.restrict J ↔ ∃ J' ∈ π, (J₁ : WithBot (Box ι)) = ↑J ⊓ ↑J' := by
simp [restrict, eq_comm]
theorem mem_restrict' : J₁ ∈ π.restrict J ↔ ∃ J' ∈ π, (J₁ : Set (ι → ℝ)) = ↑J ∩ ↑J' := by
simp only [mem_restrict, ← Box.withBotCoe_inj, Box.coe_inf, Box.coe_coe]
@[mono]
theorem restrict_mono {π₁ π₂ : Prepartition I} (Hle : π₁ ≤ π₂) : π₁.restrict J ≤ π₂.restrict J := by
classical
refine ofWithBot_mono fun J₁ hJ₁ hne => ?_
rw [Finset.mem_image] at hJ₁; rcases hJ₁ with ⟨J₁, hJ₁, rfl⟩
rcases Hle hJ₁ with ⟨J₂, hJ₂, hle⟩
exact ⟨_, Finset.mem_image_of_mem _ hJ₂, inf_le_inf_left _ <| WithBot.coe_le_coe.2 hle⟩
theorem monotone_restrict : Monotone fun π : Prepartition I => restrict π J :=
fun _ _ => restrict_mono
/-- Restricting to a larger box does not change the set of boxes. We cannot claim equality
of prepartitions because they have different types. -/
theorem restrict_boxes_of_le (π : Prepartition I) (h : I ≤ J) : (π.restrict J).boxes = π.boxes := by
classical
simp only [restrict, ofWithBot, eraseNone_eq_biUnion]
refine Finset.image_biUnion.trans ?_
refine (Finset.biUnion_congr rfl ?_).trans Finset.biUnion_singleton_eq_self
intro J' hJ'
rw [inf_of_le_right, ← WithBot.some_eq_coe, Option.toFinset_some]
exact WithBot.coe_le_coe.2 ((π.le_of_mem hJ').trans h)
@[simp]
theorem restrict_self : π.restrict I = π :=
injective_boxes <| restrict_boxes_of_le π le_rfl
@[simp]
theorem iUnion_restrict : (π.restrict J).iUnion = (J : Set (ι → ℝ)) ∩ (π.iUnion) := by
simp [restrict, ← inter_iUnion, ← iUnion_def]
@[simp]
theorem restrict_biUnion (πi : ∀ J, Prepartition J) (hJ : J ∈ π) :
(π.biUnion πi).restrict J = πi J := by
refine (eq_of_boxes_subset_iUnion_superset (fun J₁ h₁ => ?_) ?_).symm
· refine (mem_restrict _).2 ⟨J₁, π.mem_biUnion.2 ⟨J, hJ, h₁⟩, (inf_of_le_right ?_).symm⟩
exact WithBot.coe_le_coe.2 (le_of_mem _ h₁)
· simp only [iUnion_restrict, iUnion_biUnion, Set.subset_def, Set.mem_inter_iff, Set.mem_iUnion]
rintro x ⟨hxJ, J₁, h₁, hx⟩
obtain rfl : J = J₁ := π.eq_of_mem_of_mem hJ h₁ hxJ (iUnion_subset _ hx)
exact hx
theorem biUnion_le_iff {πi : ∀ J, Prepartition J} {π' : Prepartition I} :
π.biUnion πi ≤ π' ↔ ∀ J ∈ π, πi J ≤ π'.restrict J := by
constructor <;> intro H J hJ
· rw [← π.restrict_biUnion πi hJ]
exact restrict_mono H
· rw [mem_biUnion] at hJ
rcases hJ with ⟨J₁, h₁, hJ⟩
rcases H J₁ h₁ hJ with ⟨J₂, h₂, Hle⟩
rcases π'.mem_restrict.mp h₂ with ⟨J₃, h₃, H⟩
exact ⟨J₃, h₃, Hle.trans <| WithBot.coe_le_coe.1 <| H.trans_le inf_le_right⟩
theorem le_biUnion_iff {πi : ∀ J, Prepartition J} {π' : Prepartition I} :
π' ≤ π.biUnion πi ↔ π' ≤ π ∧ ∀ J ∈ π, π'.restrict J ≤ πi J := by
refine ⟨fun H => ⟨H.trans (π.biUnion_le πi), fun J hJ => ?_⟩, ?_⟩
· rw [← π.restrict_biUnion πi hJ]
exact restrict_mono H
· rintro ⟨H, Hi⟩ J' hJ'
rcases H hJ' with ⟨J, hJ, hle⟩
have : J' ∈ π'.restrict J :=
π'.mem_restrict.2 ⟨J', hJ', (inf_of_le_right <| WithBot.coe_le_coe.2 hle).symm⟩
rcases Hi J hJ this with ⟨Ji, hJi, hlei⟩
exact ⟨Ji, π.mem_biUnion.2 ⟨J, hJ, hJi⟩, hlei⟩
instance : SemilatticeInf (Prepartition I) :=
{ inf := fun π₁ π₂ => π₁.biUnion fun J => π₂.restrict J
inf_le_left := fun π₁ _ => π₁.biUnion_le _
inf_le_right := fun _ _ => (biUnion_le_iff _).2 fun _ _ => le_rfl
le_inf := fun _ π₁ _ h₁ h₂ => π₁.le_biUnion_iff.2 ⟨h₁, fun _ _ => restrict_mono h₂⟩ }
theorem inf_def (π₁ π₂ : Prepartition I) : π₁ ⊓ π₂ = π₁.biUnion fun J => π₂.restrict J := rfl
@[simp]
theorem mem_inf {π₁ π₂ : Prepartition I} :
J ∈ π₁ ⊓ π₂ ↔ ∃ J₁ ∈ π₁, ∃ J₂ ∈ π₂, (J : WithBot (Box ι)) = ↑J₁ ⊓ ↑J₂ := by
simp only [inf_def, mem_biUnion, mem_restrict]
@[simp]
theorem iUnion_inf (π₁ π₂ : Prepartition I) : (π₁ ⊓ π₂).iUnion = π₁.iUnion ∩ π₂.iUnion := by
simp only [inf_def, iUnion_biUnion, iUnion_restrict, ← iUnion_inter, ← iUnion_def]
open scoped Classical in
/-- The prepartition with boxes `{J ∈ π | p J}`. -/
@[simps]
def filter (π : Prepartition I) (p : Box ι → Prop) : Prepartition I where
boxes := {J ∈ π.boxes | p J}
le_of_mem' _ hJ := π.le_of_mem (mem_filter.1 hJ).1
pairwiseDisjoint _ h₁ _ h₂ := π.disjoint_coe_of_mem (mem_filter.1 h₁).1 (mem_filter.1 h₂).1
@[simp]
theorem mem_filter {p : Box ι → Prop} : J ∈ π.filter p ↔ J ∈ π ∧ p J := by
classical
exact Finset.mem_filter
theorem filter_le (π : Prepartition I) (p : Box ι → Prop) : π.filter p ≤ π := fun J hJ =>
let ⟨hπ, _⟩ := π.mem_filter.1 hJ
⟨J, hπ, le_rfl⟩
theorem filter_of_true {p : Box ι → Prop} (hp : ∀ J ∈ π, p J) : π.filter p = π := by
ext J
simpa using hp J
@[simp]
theorem filter_true : (π.filter fun _ => True) = π :=
π.filter_of_true fun _ _ => trivial
@[simp]
theorem iUnion_filter_not (π : Prepartition I) (p : Box ι → Prop) :
(π.filter fun J => ¬p J).iUnion = π.iUnion \ (π.filter p).iUnion := by
simp only [Prepartition.iUnion]
convert
(@Set.biUnion_diff_biUnion_eq (ι → ℝ) (Box ι) π.boxes (π.filter p).boxes (↑) _).symm using 4
· simp +contextual
· rw [Set.PairwiseDisjoint]
convert π.pairwiseDisjoint
rw [Set.union_eq_left, filter_boxes, coe_filter]
exact fun _ ⟨h, _⟩ => h
open scoped Classical in
theorem sum_fiberwise {α M} [AddCommMonoid M] (π : Prepartition I) (f : Box ι → α) (g : Box ι → M) :
(∑ y ∈ π.boxes.image f, ∑ J ∈ (π.filter fun J => f J = y).boxes, g J) =
∑ J ∈ π.boxes, g J := by
convert sum_fiberwise_of_maps_to (fun _ => Finset.mem_image_of_mem f) g
open scoped Classical in
/-- Union of two disjoint prepartitions. -/
@[simps]
def disjUnion (π₁ π₂ : Prepartition I) (h : Disjoint π₁.iUnion π₂.iUnion) : Prepartition I where
boxes := π₁.boxes ∪ π₂.boxes
le_of_mem' _ hJ := (Finset.mem_union.1 hJ).elim π₁.le_of_mem π₂.le_of_mem
pairwiseDisjoint :=
suffices ∀ J₁ ∈ π₁, ∀ J₂ ∈ π₂, J₁ ≠ J₂ → Disjoint (J₁ : Set (ι → ℝ)) J₂ by
simpa [pairwise_union_of_symmetric (symmetric_disjoint.comap _), pairwiseDisjoint]
fun _ h₁ _ h₂ _ => h.mono (π₁.subset_iUnion h₁) (π₂.subset_iUnion h₂)
@[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 := by
| simp [disjUnion, Prepartition.iUnion, iUnion_or, iUnion_union_distrib]
| Mathlib/Analysis/BoxIntegral/Partition/Basic.lean | 582 | 583 |
/-
Copyright (c) 2021 Julian Kuelshammer. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Julian Kuelshammer
-/
import Mathlib.GroupTheory.SpecificGroups.Cyclic
import Mathlib.GroupTheory.SpecificGroups.Dihedral
/-!
# Quaternion Groups
We define the (generalised) quaternion groups `QuaternionGroup n` of order `4n`, also known as
dicyclic groups, with elements `a i` and `xa i` for `i : ZMod n`. The (generalised) quaternion
groups can be defined by the presentation
$\langle a, x | a^{2n} = 1, x^2 = a^n, x^{-1}ax=a^{-1}\rangle$. We write `a i` for
$a^i$ and `xa i` for $x * a^i$. For `n=2` the quaternion group `QuaternionGroup 2` is isomorphic to
the unit integral quaternions `(Quaternion ℤ)ˣ`.
## Main definition
`QuaternionGroup n`: The (generalised) quaternion group of order `4n`.
## Implementation notes
This file is heavily based on `DihedralGroup` by Shing Tak Lam.
In mathematics, the name "quaternion group" is reserved for the cases `n ≥ 2`. Since it would be
inconvenient to carry around this condition we define `QuaternionGroup` also for `n = 0` and
`n = 1`. `QuaternionGroup 0` is isomorphic to the infinite dihedral group, while
`QuaternionGroup 1` is isomorphic to a cyclic group of order `4`.
## References
* https://en.wikipedia.org/wiki/Dicyclic_group
* https://en.wikipedia.org/wiki/Quaternion_group
## TODO
Show that `QuaternionGroup 2 ≃* (Quaternion ℤ)ˣ`.
-/
/-- The (generalised) quaternion group `QuaternionGroup n` of order `4n`. It can be defined by the
presentation $\langle a, x | a^{2n} = 1, x^2 = a^n, x^{-1}ax=a^{-1}\rangle$. We write `a i` for
$a^i$ and `xa i` for $x * a^i$.
-/
inductive QuaternionGroup (n : ℕ) : Type
| a : ZMod (2 * n) → QuaternionGroup n
| xa : ZMod (2 * n) → QuaternionGroup n
deriving DecidableEq
namespace QuaternionGroup
variable {n : ℕ}
/-- Multiplication of the dihedral group.
-/
private def mul : QuaternionGroup n → QuaternionGroup n → QuaternionGroup n
| a i, a j => a (i + j)
| a i, xa j => xa (j - i)
| xa i, a j => xa (i + j)
| xa i, xa j => a (n + j - i)
/-- The identity `1` is given by `aⁱ`.
-/
private def one : QuaternionGroup n :=
a 0
instance : Inhabited (QuaternionGroup n) :=
⟨one⟩
/-- The inverse of an element of the quaternion group.
-/
private def inv : QuaternionGroup n → QuaternionGroup n
| a i => a (-i)
| xa i => xa (n + i)
/-- The group structure on `QuaternionGroup n`.
-/
instance : Group (QuaternionGroup n) where
mul := mul
mul_assoc := by
rintro (i | i) (j | j) (k | k) <;> simp only [(· * ·), mul] <;> ring_nf
congr
calc
-(n : ZMod (2 * n)) = 0 - n := by rw [zero_sub]
_ = 2 * n - n := by norm_cast; simp
_ = n := by ring
one := one
one_mul := by
rintro (i | i)
· exact congr_arg a (zero_add i)
· exact congr_arg xa (sub_zero i)
mul_one := by
rintro (i | i)
· exact congr_arg a (add_zero i)
· exact congr_arg xa (add_zero i)
inv := inv
inv_mul_cancel := by
rintro (i | i)
· exact congr_arg a (neg_add_cancel i)
· exact congr_arg a (sub_self (n + i))
@[simp]
theorem a_mul_a (i j : ZMod (2 * n)) : a i * a j = a (i + j) :=
rfl
@[simp]
theorem a_mul_xa (i j : ZMod (2 * n)) : a i * xa j = xa (j - i) :=
rfl
@[simp]
theorem xa_mul_a (i j : ZMod (2 * n)) : xa i * a j = xa (i + j) :=
rfl
@[simp]
theorem xa_mul_xa (i j : ZMod (2 * n)) : xa i * xa j = a ((n : ZMod (2 * n)) + j - i) :=
rfl
@[simp]
theorem a_zero : a 0 = (1 : QuaternionGroup n) := by
rfl
theorem one_def : (1 : QuaternionGroup n) = a 0 :=
rfl
private def fintypeHelper : ZMod (2 * n) ⊕ ZMod (2 * n) ≃ QuaternionGroup n where
invFun i :=
match i with
| a j => Sum.inl j
| xa j => Sum.inr j
toFun i :=
match i with
| Sum.inl j => a j
| Sum.inr j => xa j
left_inv := by rintro (x | x) <;> rfl
right_inv := by rintro (x | x) <;> rfl
/-- The special case that more or less by definition `QuaternionGroup 0` is isomorphic to the
infinite dihedral group. -/
def quaternionGroupZeroEquivDihedralGroupZero : QuaternionGroup 0 ≃* DihedralGroup 0 where
toFun
| a j => DihedralGroup.r j
| xa j => DihedralGroup.sr j
invFun
| DihedralGroup.r j => a j
| DihedralGroup.sr j => xa j
left_inv := by rintro (k | k) <;> rfl
right_inv := by rintro (k | k) <;> rfl
map_mul' := by rintro (k | k) (l | l) <;> simp
/-- If `0 < n`, then `QuaternionGroup n` is a finite group.
-/
instance [NeZero n] : Fintype (QuaternionGroup n) :=
Fintype.ofEquiv _ fintypeHelper
instance : Nontrivial (QuaternionGroup n) :=
⟨⟨a 0, xa 0, by simp [← a_zero]⟩⟩
/-- If `0 < n`, then `QuaternionGroup n` has `4n` elements.
-/
theorem card [NeZero n] : Fintype.card (QuaternionGroup n) = 4 * n := by
rw [← Fintype.card_eq.mpr ⟨fintypeHelper⟩, Fintype.card_sum, ZMod.card, two_mul]
ring
@[simp]
theorem a_one_pow (k : ℕ) : (a 1 : QuaternionGroup n) ^ k = a k := by
induction' k with k IH
· rw [Nat.cast_zero]; rfl
· rw [pow_succ, IH, a_mul_a]
congr 1
norm_cast
theorem a_one_pow_n : (a 1 : QuaternionGroup n) ^ (2 * n) = 1 := by
simp
@[simp]
theorem xa_sq (i : ZMod (2 * n)) : xa i ^ 2 = a n := by simp [sq]
@[simp]
theorem xa_pow_four (i : ZMod (2 * n)) : xa i ^ 4 = 1 := by
calc xa i ^ 4
= a (n + n) := by simp [pow_succ, add_sub_assoc, sub_sub_cancel]
_ = a ↑(2 * n) := by simp [Nat.cast_add, two_mul]
_ = 1 := by simp
/-- If `0 < n`, then `xa i` has order 4.
-/
@[simp]
theorem orderOf_xa [NeZero n] (i : ZMod (2 * n)) : orderOf (xa i) = 4 := by
change _ = 2 ^ 2
haveI : Fact (Nat.Prime 2) := Fact.mk Nat.prime_two
apply orderOf_eq_prime_pow
· intro h
simp only [pow_one, xa_sq] at h
injection h with h'
apply_fun ZMod.val at h'
apply_fun (· / n) at h'
simp only [ZMod.val_natCast, ZMod.val_zero, Nat.zero_div, Nat.mod_mul_left_div_self,
Nat.div_self (NeZero.pos n), reduceCtorEq] at h'
· norm_num
/-- In the special case `n = 1`, `Quaternion 1` is a cyclic group (of order `4`). -/
theorem quaternionGroup_one_isCyclic : IsCyclic (QuaternionGroup 1) := by
apply isCyclic_of_orderOf_eq_card
· rw [Nat.card_eq_fintype_card, card, mul_one]
exact orderOf_xa 0
/-- If `0 < n`, then `a 1` has order `2 * n`.
| -/
@[simp]
theorem orderOf_a_one : orderOf (a 1 : QuaternionGroup n) = 2 * n := by
rcases eq_zero_or_neZero n with hn | hn
· subst hn
simp_rw [mul_zero, orderOf_eq_zero_iff']
intro n h
rw [one_def, a_one_pow]
apply mt a.inj
haveI : CharZero (ZMod (2 * 0)) := ZMod.charZero
simpa using h.ne'
apply (Nat.le_of_dvd
| Mathlib/GroupTheory/SpecificGroups/Quaternion.lean | 211 | 222 |
/-
Copyright (c) 2023 Yaël Dillies, Christopher Hoskin. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies, Christopher Hoskin
-/
import Mathlib.Data.Finset.Lattice.Prod
import Mathlib.Data.Finset.Powerset
import Mathlib.Data.Set.Finite.Basic
import Mathlib.Order.Closure
import Mathlib.Order.ConditionallyCompleteLattice.Finset
/-!
# Sets closed under join/meet
This file defines predicates for sets closed under `⊔` and shows that each set in a join-semilattice
generates a join-closed set and that a semilattice where every directed set has a least upper bound
is automatically complete. All dually for `⊓`.
## Main declarations
* `SupClosed`: Predicate for a set to be closed under join (`a ∈ s` and `b ∈ s` imply `a ⊔ b ∈ s`).
* `InfClosed`: Predicate for a set to be closed under meet (`a ∈ s` and `b ∈ s` imply `a ⊓ b ∈ s`).
* `IsSublattice`: Predicate for a set to be closed under meet and join.
* `supClosure`: Sup-closure. Smallest sup-closed set containing a given set.
* `infClosure`: Inf-closure. Smallest inf-closed set containing a given set.
* `latticeClosure`: Smallest sublattice containing a given set.
* `SemilatticeSup.toCompleteSemilatticeSup`: A join-semilattice where every sup-closed set has a
least upper bound is automatically complete.
* `SemilatticeInf.toCompleteSemilatticeInf`: A meet-semilattice where every inf-closed set has a
greatest lower bound is automatically complete.
-/
variable {ι : Sort*} {F α β : Type*}
section SemilatticeSup
variable [SemilatticeSup α] [SemilatticeSup β]
section Set
variable {ι : Sort*} {S : Set (Set α)} {f : ι → Set α} {s t : Set α} {a : α}
open Set
/-- A set `s` is *sup-closed* if `a ⊔ b ∈ s` for all `a ∈ s`, `b ∈ s`. -/
def SupClosed (s : Set α) : Prop := ∀ ⦃a⦄, a ∈ s → ∀ ⦃b⦄, b ∈ s → a ⊔ b ∈ s
| @[simp] lemma supClosed_empty : SupClosed (∅ : Set α) := by simp [SupClosed]
| Mathlib/Order/SupClosed.lean | 45 | 45 |
/-
Copyright (c) 2020 Johan Commelin. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johan Commelin, Eric Wieser
-/
import Mathlib.Algebra.DirectSum.Internal
import Mathlib.Algebra.GradedMonoid
import Mathlib.Algebra.MvPolynomial.CommRing
import Mathlib.Algebra.MvPolynomial.Equiv
import Mathlib.Algebra.MvPolynomial.Variables
import Mathlib.Algebra.Polynomial.Roots
import Mathlib.RingTheory.MvPolynomial.WeightedHomogeneous
import Mathlib.SetTheory.Cardinal.Basic
/-!
# Homogeneous polynomials
A multivariate polynomial `φ` is homogeneous of degree `n`
if all monomials occurring in `φ` have degree `n`.
## Main definitions/lemmas
* `IsHomogeneous φ n`: a predicate that asserts that `φ` is homogeneous of degree `n`.
* `homogeneousSubmodule σ R n`: the submodule of homogeneous polynomials of degree `n`.
* `homogeneousComponent n`: the additive morphism that projects polynomials onto
their summand that is homogeneous of degree `n`.
* `sum_homogeneousComponent`: every polynomial is the sum of its homogeneous components.
-/
namespace MvPolynomial
variable {σ : Type*} {τ : Type*} {R : Type*} {S : Type*}
/-
TODO
* show that `MvPolynomial σ R ≃ₐ[R] ⨁ i, homogeneousSubmodule σ R i`
-/
open Finsupp
/-- A multivariate polynomial `φ` is homogeneous of degree `n`
if all monomials occurring in `φ` have degree `n`. -/
def IsHomogeneous [CommSemiring R] (φ : MvPolynomial σ R) (n : ℕ) :=
IsWeightedHomogeneous 1 φ n
variable [CommSemiring R]
theorem weightedTotalDegree_one (φ : MvPolynomial σ R) :
weightedTotalDegree (1 : σ → ℕ) φ = φ.totalDegree := by
simp only [totalDegree, weightedTotalDegree, weight, LinearMap.toAddMonoidHom_coe,
linearCombination, Pi.one_apply, Finsupp.coe_lsum, LinearMap.coe_smulRight, LinearMap.id_coe,
id, Algebra.id.smul_eq_mul, mul_one]
theorem weightedTotalDegree_rename_of_injective {σ τ : Type*} {e : σ → τ}
{w : τ → ℕ} {P : MvPolynomial σ R} (he : Function.Injective e) :
weightedTotalDegree w (rename e P) = weightedTotalDegree (w ∘ e) P := by
classical
unfold weightedTotalDegree
rw [support_rename_of_injective he, Finset.sup_image]
congr; ext; unfold weight; simp
variable (σ R)
/-- The submodule of homogeneous `MvPolynomial`s of degree `n`. -/
def homogeneousSubmodule (n : ℕ) : Submodule R (MvPolynomial σ R) where
carrier := { x | x.IsHomogeneous n }
smul_mem' r a ha c hc := by
rw [coeff_smul] at hc
apply ha
intro h
apply hc
rw [h]
exact smul_zero r
zero_mem' _ hd := False.elim (hd <| coeff_zero _)
add_mem' {a b} ha hb c hc := by
rw [coeff_add] at hc
obtain h | h : coeff c a ≠ 0 ∨ coeff c b ≠ 0 := by
contrapose! hc
simp only [hc, add_zero]
· exact ha h
· exact hb h
@[simp]
lemma weightedHomogeneousSubmodule_one (n : ℕ) :
weightedHomogeneousSubmodule R 1 n = homogeneousSubmodule σ R n := rfl
variable {σ R}
@[simp]
theorem mem_homogeneousSubmodule (n : ℕ) (p : MvPolynomial σ R) :
p ∈ homogeneousSubmodule σ R n ↔ p.IsHomogeneous n := Iff.rfl
variable (σ R)
/-- While equal, the former has a convenient definitional reduction. -/
theorem homogeneousSubmodule_eq_finsupp_supported (n : ℕ) :
homogeneousSubmodule σ R n = Finsupp.supported _ R { d | d.degree = n } := by
simp_rw [degree_eq_weight_one]
exact weightedHomogeneousSubmodule_eq_finsupp_supported R 1 n
variable {σ R}
theorem homogeneousSubmodule_mul (m n : ℕ) :
homogeneousSubmodule σ R m * homogeneousSubmodule σ R n ≤ homogeneousSubmodule σ R (m + n) :=
weightedHomogeneousSubmodule_mul 1 m n
section
theorem isHomogeneous_monomial {d : σ →₀ ℕ} (r : R) {n : ℕ} (hn : d.degree = n) :
IsHomogeneous (monomial d r) n := by
rw [degree_eq_weight_one] at hn
exact isWeightedHomogeneous_monomial 1 d r hn
variable (σ)
theorem totalDegree_eq_zero_iff (p : MvPolynomial σ R) :
p.totalDegree = 0 ↔ ∀ (m : σ →₀ ℕ) (_ : m ∈ p.support) (x : σ), m x = 0 := by
rw [← weightedTotalDegree_one, weightedTotalDegree_eq_zero_iff _ p]
exact nonTorsionWeight_of (Function.const σ one_ne_zero)
theorem totalDegree_zero_iff_isHomogeneous {p : MvPolynomial σ R} :
p.totalDegree = 0 ↔ IsHomogeneous p 0 := by
rw [← weightedTotalDegree_one,
← isWeightedHomogeneous_zero_iff_weightedTotalDegree_eq_zero, IsHomogeneous]
alias ⟨isHomogeneous_of_totalDegree_zero, _⟩ := totalDegree_zero_iff_isHomogeneous
theorem isHomogeneous_C (r : R) : IsHomogeneous (C r : MvPolynomial σ R) 0 := by
apply isHomogeneous_monomial
simp only [Finsupp.degree, Finsupp.zero_apply, Finset.sum_const_zero]
variable (R)
theorem isHomogeneous_zero (n : ℕ) : IsHomogeneous (0 : MvPolynomial σ R) n :=
(homogeneousSubmodule σ R n).zero_mem
theorem isHomogeneous_one : IsHomogeneous (1 : MvPolynomial σ R) 0 :=
isHomogeneous_C _ _
variable {σ}
theorem isHomogeneous_X (i : σ) : IsHomogeneous (X i : MvPolynomial σ R) 1 := by
apply isHomogeneous_monomial
rw [Finsupp.degree, Finsupp.support_single_ne_zero _ one_ne_zero, Finset.sum_singleton]
exact Finsupp.single_eq_same
end
namespace IsHomogeneous
variable [CommSemiring S] {φ ψ : MvPolynomial σ R} {m n : ℕ}
theorem coeff_eq_zero (hφ : IsHomogeneous φ n) {d : σ →₀ ℕ} (hd : d.degree ≠ n) :
coeff d φ = 0 := by
rw [degree_eq_weight_one] at hd
exact IsWeightedHomogeneous.coeff_eq_zero hφ d hd
theorem inj_right (hm : IsHomogeneous φ m) (hn : IsHomogeneous φ n) (hφ : φ ≠ 0) : m = n := by
obtain ⟨d, hd⟩ : ∃ d, coeff d φ ≠ 0 := exists_coeff_ne_zero hφ
rw [← hm hd, ← hn hd]
theorem add (hφ : IsHomogeneous φ n) (hψ : IsHomogeneous ψ n) : IsHomogeneous (φ + ψ) n :=
(homogeneousSubmodule σ R n).add_mem hφ hψ
theorem sum {ι : Type*} (s : Finset ι) (φ : ι → MvPolynomial σ R) (n : ℕ)
(h : ∀ i ∈ s, IsHomogeneous (φ i) n) : IsHomogeneous (∑ i ∈ s, φ i) n :=
(homogeneousSubmodule σ R n).sum_mem h
theorem mul (hφ : IsHomogeneous φ m) (hψ : IsHomogeneous ψ n) : IsHomogeneous (φ * ψ) (m + n) :=
homogeneousSubmodule_mul m n <| Submodule.mul_mem_mul hφ hψ
theorem prod {ι : Type*} (s : Finset ι) (φ : ι → MvPolynomial σ R) (n : ι → ℕ)
(h : ∀ i ∈ s, IsHomogeneous (φ i) (n i)) : IsHomogeneous (∏ i ∈ s, φ i) (∑ i ∈ s, n i) := by
classical
revert h
refine Finset.induction_on s ?_ ?_
· intro
simp only [isHomogeneous_one, Finset.sum_empty, Finset.prod_empty]
· intro i s his IH h
simp only [his, Finset.prod_insert, Finset.sum_insert, not_false_iff]
apply (h i (Finset.mem_insert_self _ _)).mul (IH _)
intro j hjs
exact h j (Finset.mem_insert_of_mem hjs)
lemma C_mul (hφ : φ.IsHomogeneous m) (r : R) :
(C r * φ).IsHomogeneous m := by
simpa only [zero_add] using (isHomogeneous_C _ _).mul hφ
lemma _root_.MvPolynomial.isHomogeneous_C_mul_X (r : R) (i : σ) :
(C r * X i).IsHomogeneous 1 :=
(isHomogeneous_X _ _).C_mul _
lemma pow (hφ : φ.IsHomogeneous m) (n : ℕ) : (φ ^ n).IsHomogeneous (m * n) := by
rw [show φ ^ n = ∏ _i ∈ Finset.range n, φ by simp]
rw [show m * n = ∑ _i ∈ Finset.range n, m by simp [mul_comm]]
apply IsHomogeneous.prod _ _ _ (fun _ _ ↦ hφ)
lemma _root_.MvPolynomial.isHomogeneous_X_pow (i : σ) (n : ℕ) :
(X (R := R) i ^ n).IsHomogeneous n := by
simpa only [one_mul] using (isHomogeneous_X _ _).pow n
lemma _root_.MvPolynomial.isHomogeneous_C_mul_X_pow (r : R) (i : σ) (n : ℕ) :
(C r * X i ^ n).IsHomogeneous n :=
(isHomogeneous_X_pow _ _).C_mul _
lemma eval₂ (hφ : φ.IsHomogeneous m) (f : R →+* MvPolynomial τ S) (g : σ → MvPolynomial τ S)
(hf : ∀ r, (f r).IsHomogeneous 0) (hg : ∀ i, (g i).IsHomogeneous n) :
(eval₂ f g φ).IsHomogeneous (n * m) := by
apply IsHomogeneous.sum
intro i hi
rw [← zero_add (n * m)]
apply IsHomogeneous.mul (hf _) _
convert IsHomogeneous.prod _ _ (fun k ↦ n * i k) _
· rw [Finsupp.mem_support_iff] at hi
rw [← Finset.mul_sum, ← hφ hi, weight_apply]
simp_rw [smul_eq_mul, Finsupp.sum, Pi.one_apply, mul_one]
· rintro k -
apply (hg k).pow
lemma map (hφ : φ.IsHomogeneous n) (f : R →+* S) : (map f φ).IsHomogeneous n := by
simpa only [one_mul] using hφ.eval₂ _ _ (fun r ↦ isHomogeneous_C _ (f r)) (isHomogeneous_X _)
lemma aeval [Algebra R S] (hφ : φ.IsHomogeneous m)
(g : σ → MvPolynomial τ S) (hg : ∀ i, (g i).IsHomogeneous n) :
(aeval g φ).IsHomogeneous (n * m) :=
hφ.eval₂ _ _ (fun _ ↦ isHomogeneous_C _ _) hg
section CommRing
-- In this section we shadow the semiring `R` with a ring `R`.
variable {R σ : Type*} [CommRing R] {φ ψ : MvPolynomial σ R} {n : ℕ}
theorem neg (hφ : IsHomogeneous φ n) : IsHomogeneous (-φ) n :=
(homogeneousSubmodule σ R n).neg_mem hφ
theorem sub (hφ : IsHomogeneous φ n) (hψ : IsHomogeneous ψ n) : IsHomogeneous (φ - ψ) n :=
(homogeneousSubmodule σ R n).sub_mem hφ hψ
end CommRing
/-- The homogeneous degree bounds the total degree.
See also `MvPolynomial.IsHomogeneous.totalDegree` when `φ` is non-zero. -/
lemma totalDegree_le (hφ : IsHomogeneous φ n) : φ.totalDegree ≤ n := by
apply Finset.sup_le
intro d hd
rw [mem_support_iff] at hd
simp_rw [Finsupp.sum, ← hφ hd, weight_apply, Pi.one_apply, smul_eq_mul, mul_one, Finsupp.sum,
le_rfl]
theorem totalDegree (hφ : IsHomogeneous φ n) (h : φ ≠ 0) : totalDegree φ = n := by
apply le_antisymm hφ.totalDegree_le
obtain ⟨d, hd⟩ : ∃ d, coeff d φ ≠ 0 := exists_coeff_ne_zero h
simp only [← hφ hd, MvPolynomial.totalDegree, Finsupp.sum]
replace hd := Finsupp.mem_support_iff.mpr hd
simp only [weight_apply, Pi.one_apply, smul_eq_mul, mul_one]
-- Porting note: Original proof did not define `f`
exact Finset.le_sup (f := fun s ↦ ∑ x ∈ s.support, s x) hd
theorem rename_isHomogeneous {f : σ → τ} (h : φ.IsHomogeneous n) :
(rename f φ).IsHomogeneous n := by
rw [← φ.support_sum_monomial_coeff, map_sum]; simp_rw [rename_monomial]
apply IsHomogeneous.sum _ _ _ fun d hd ↦ isHomogeneous_monomial _ _
intro d hd
apply (Finsupp.sum_mapDomain_index_addMonoidHom fun _ ↦ .id ℕ).trans
convert h (mem_support_iff.mp hd)
simp only [weight_apply, AddMonoidHom.id_apply, Pi.one_apply, smul_eq_mul, mul_one]
theorem rename_isHomogeneous_iff {f : σ → τ} (hf : f.Injective) :
(rename f φ).IsHomogeneous n ↔ φ.IsHomogeneous n := by
refine ⟨fun h d hd ↦ ?_, rename_isHomogeneous⟩
convert ← @h (d.mapDomain f) _
· simp only [weight_apply, Pi.one_apply, smul_eq_mul, mul_one]
exact Finsupp.sum_mapDomain_index_inj (h := fun _ ↦ id) hf
· rwa [coeff_rename_mapDomain f hf]
lemma finSuccEquiv_coeff_isHomogeneous {N : ℕ} {φ : MvPolynomial (Fin (N+1)) R} {n : ℕ}
(hφ : φ.IsHomogeneous n) (i j : ℕ) (h : i + j = n) :
((finSuccEquiv _ _ φ).coeff i).IsHomogeneous j := by
intro d hd
rw [finSuccEquiv_coeff_coeff] at hd
have h' : (weight 1) (Finsupp.cons i d) = i + j := by
simpa [Finset.sum_subset_zero_on_sdiff (g := d.cons i)
(d.cons_support (y := i)) (by simp) (fun _ _ ↦ rfl), ← h] using hφ hd
simp only [weight_apply, Pi.one_apply, smul_eq_mul, mul_one, Finsupp.sum_cons,
add_right_inj] at h' ⊢
exact h'
-- TODO: develop API for `optionEquivLeft` and get rid of the `[Fintype σ]` assumption
lemma coeff_isHomogeneous_of_optionEquivLeft_symm
[hσ : Finite σ] {p : Polynomial (MvPolynomial σ R)}
(hp : ((optionEquivLeft R σ).symm p).IsHomogeneous n) (i j : ℕ) (h : i + j = n) :
(p.coeff i).IsHomogeneous j := by
obtain ⟨k, ⟨e⟩⟩ := Finite.exists_equiv_fin σ
let e' := e.optionCongr.trans (_root_.finSuccEquiv _).symm
let F := renameEquiv R e
let F' := renameEquiv R e'
let φ := F' ((optionEquivLeft R σ).symm p)
have hφ : φ.IsHomogeneous n := hp.rename_isHomogeneous
suffices IsHomogeneous (F (p.coeff i)) j by
rwa [← (IsHomogeneous.rename_isHomogeneous_iff e.injective)]
convert hφ.finSuccEquiv_coeff_isHomogeneous i j h using 1
dsimp only [φ, F', F, renameEquiv_apply]
rw [finSuccEquiv_rename_finSuccEquiv, AlgEquiv.apply_symm_apply]
simp
open Polynomial in
private
lemma exists_eval_ne_zero_of_coeff_finSuccEquiv_ne_zero_aux
{N : ℕ} {F : MvPolynomial (Fin (Nat.succ N)) R} {n : ℕ} (hF : IsHomogeneous F n)
(hFn : ((finSuccEquiv R N) F).coeff n ≠ 0) :
∃ r, eval r F ≠ 0 := by
have hF₀ : F ≠ 0 := by contrapose! hFn; simp [hFn]
have hdeg : natDegree (finSuccEquiv R N F) < n + 1 := by
linarith [natDegree_finSuccEquiv F, degreeOf_le_totalDegree F 0, hF.totalDegree hF₀]
use Fin.cons 1 0
have aux : ∀ i ∈ Finset.range n, constantCoeff ((finSuccEquiv R N F).coeff i) = 0 := by
intro i hi
rw [Finset.mem_range] at hi
apply (hF.finSuccEquiv_coeff_isHomogeneous i (n-i) (by omega)).coeff_eq_zero
simp only [Finsupp.degree_zero]
rw [← Nat.sub_ne_zero_iff_lt] at hi
exact hi.symm
simp_rw [eval_eq_eval_mv_eval', eval_one_map, Polynomial.eval_eq_sum_range' hdeg,
eval_zero, one_pow, mul_one, map_sum, Finset.sum_range_succ, Finset.sum_eq_zero aux, zero_add]
contrapose! hFn
ext d
rw [coeff_zero]
obtain rfl | hd := eq_or_ne d 0
· apply hFn
· contrapose! hd
ext i
rw [Finsupp.coe_zero, Pi.zero_apply]
by_cases hi : i ∈ d.support
· have := hF.finSuccEquiv_coeff_isHomogeneous n 0 (add_zero _) hd
simp only [weight_apply, Pi.one_apply, smul_eq_mul, mul_one, Finsupp.sum] at this
rw [Finset.sum_eq_zero_iff_of_nonneg (fun _ _ ↦ zero_le')] at this
exact this i hi
· simpa using hi
section IsDomain
-- In this section we shadow the semiring `R` with a domain `R`.
variable {R σ : Type*} [CommRing R] [IsDomain R] {F G : MvPolynomial σ R} {n : ℕ}
open Cardinal Polynomial
private
lemma exists_eval_ne_zero_of_totalDegree_le_card_aux {N : ℕ} {F : MvPolynomial (Fin N) R} {n : ℕ}
(hF : F.IsHomogeneous n) (hF₀ : F ≠ 0) (hnR : n ≤ #R) :
∃ r, eval r F ≠ 0 := by
induction N generalizing n with
| zero =>
use 0
contrapose! hF₀
ext d
simpa only [Subsingleton.elim d 0, eval_zero, coeff_zero] using hF₀
| succ N IH =>
have hdeg : natDegree (finSuccEquiv R N F) < n + 1 := by
linarith [natDegree_finSuccEquiv F, degreeOf_le_totalDegree F 0, hF.totalDegree hF₀]
obtain ⟨i, hi⟩ : ∃ i : ℕ, (finSuccEquiv R N F).coeff i ≠ 0 := by
contrapose! hF₀
exact (finSuccEquiv _ _).injective <| Polynomial.ext <| by simpa using hF₀
have hin : i ≤ n := by
contrapose! hi
exact coeff_eq_zero_of_natDegree_lt <| (Nat.le_of_lt_succ hdeg).trans_lt hi
obtain hFn | hFn := ne_or_eq ((finSuccEquiv R N F).coeff n) 0
· exact hF.exists_eval_ne_zero_of_coeff_finSuccEquiv_ne_zero_aux hFn
have hin : i < n := hin.lt_or_eq.elim id <| by aesop
obtain ⟨j, hj⟩ : ∃ j, i + (j + 1) = n := (Nat.exists_eq_add_of_lt hin).imp <| by omega
obtain ⟨r, hr⟩ : ∃ r, (eval r) (Polynomial.coeff ((finSuccEquiv R N) F) i) ≠ 0 :=
IH (hF.finSuccEquiv_coeff_isHomogeneous _ _ hj) hi (.trans (by norm_cast; omega) hnR)
set φ : R[X] := Polynomial.map (eval r) (finSuccEquiv _ _ F) with hφ
have hφ₀ : φ ≠ 0 := fun hφ₀ ↦ hr <| by
rw [← coeff_eval_eq_eval_coeff, ← hφ, hφ₀, Polynomial.coeff_zero]
have hφR : φ.natDegree < #R := by
refine lt_of_lt_of_le ?_ hnR
norm_cast
refine lt_of_le_of_lt natDegree_map_le ?_
suffices (finSuccEquiv _ _ F).natDegree ≠ n by omega
rintro rfl
refine leadingCoeff_ne_zero.mpr ?_ hFn
simpa using (finSuccEquiv R N).injective.ne hF₀
obtain ⟨r₀, hr₀⟩ : ∃ r₀, Polynomial.eval r₀ φ ≠ 0 :=
φ.exists_eval_ne_zero_of_natDegree_lt_card hφ₀ hφR
use Fin.cons r₀ r
rwa [eval_eq_eval_mv_eval']
/-- See `MvPolynomial.IsHomogeneous.eq_zero_of_forall_eval_eq_zero`
for a version that assumes `Infinite R`. -/
lemma eq_zero_of_forall_eval_eq_zero_of_le_card
(hF : F.IsHomogeneous n) (h : ∀ r : σ → R, eval r F = 0) (hnR : n ≤ #R) :
F = 0 := by
contrapose! h
-- reduce to the case where σ is finite
obtain ⟨k, f, hf, F, rfl⟩ := exists_fin_rename F
have hF₀ : F ≠ 0 := by rintro rfl; simp at h
have hF : F.IsHomogeneous n := by rwa [rename_isHomogeneous_iff hf] at hF
obtain ⟨r, hr⟩ := exists_eval_ne_zero_of_totalDegree_le_card_aux hF hF₀ hnR
obtain ⟨r, rfl⟩ := (Function.factorsThrough_iff _).mp <| (hf.factorsThrough r)
use r
rwa [eval_rename]
/-- See `MvPolynomial.IsHomogeneous.funext`
for a version that assumes `Infinite R`. -/
lemma funext_of_le_card (hF : F.IsHomogeneous n) (hG : G.IsHomogeneous n)
(h : ∀ r : σ → R, eval r F = eval r G) (hnR : n ≤ #R) :
F = G := by
rw [← sub_eq_zero]
apply eq_zero_of_forall_eval_eq_zero_of_le_card (hF.sub hG) _ hnR
simpa [sub_eq_zero] using h
/-- See `MvPolynomial.IsHomogeneous.eq_zero_of_forall_eval_eq_zero_of_le_card`
for a version that assumes `n ≤ #R`. -/
lemma eq_zero_of_forall_eval_eq_zero [Infinite R] {F : MvPolynomial σ R} {n : ℕ}
(hF : F.IsHomogeneous n) (h : ∀ r : σ → R, eval r F = 0) : F = 0 := by
apply eq_zero_of_forall_eval_eq_zero_of_le_card hF h
exact (Cardinal.nat_lt_aleph0 _).le.trans <| Cardinal.infinite_iff.mp ‹Infinite R›
/-- See `MvPolynomial.IsHomogeneous.funext_of_le_card`
for a version that assumes `n ≤ #R`. -/
| lemma funext [Infinite R] {F G : MvPolynomial σ R} {n : ℕ}
(hF : F.IsHomogeneous n) (hG : G.IsHomogeneous n)
(h : ∀ r : σ → R, eval r F = eval r G) : F = G := by
apply funext_of_le_card hF hG h
exact (Cardinal.nat_lt_aleph0 _).le.trans <| Cardinal.infinite_iff.mp ‹Infinite R›
end IsDomain
| Mathlib/RingTheory/MvPolynomial/Homogeneous.lean | 424 | 431 |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Mario Carneiro, Floris van Doorn
-/
import Mathlib.Data.Countable.Small
import Mathlib.Data.Fintype.BigOperators
import Mathlib.Data.Fintype.Powerset
import Mathlib.Data.Nat.Cast.Order.Basic
import Mathlib.Data.Set.Countable
import Mathlib.Logic.Equiv.Fin.Basic
import Mathlib.Logic.Small.Set
import Mathlib.Logic.UnivLE
import Mathlib.SetTheory.Cardinal.Order
/-!
# Basic results on cardinal numbers
We provide a collection of basic results on cardinal numbers, in particular focussing on
finite/countable/small types and sets.
## Main definitions
* `Cardinal.powerlt a b` or `a ^< b` is defined as the supremum of `a ^ c` for `c < b`.
## References
* <https://en.wikipedia.org/wiki/Cardinal_number>
## Tags
cardinal number, cardinal arithmetic, cardinal exponentiation, aleph,
Cantor's theorem, König's theorem, Konig's theorem
-/
assert_not_exists Field
open List (Vector)
open Function Order Set
noncomputable section
universe u v w v' w'
variable {α β : Type u}
namespace Cardinal
/-! ### Lifting cardinals to a higher universe -/
@[simp]
lemma mk_preimage_down {s : Set α} : #(ULift.down.{v} ⁻¹' s) = lift.{v} (#s) := by
rw [← mk_uLift, Cardinal.eq]
constructor
let f : ULift.down ⁻¹' s → ULift s := fun x ↦ ULift.up (restrictPreimage s ULift.down x)
have : Function.Bijective f :=
ULift.up_bijective.comp (restrictPreimage_bijective _ (ULift.down_bijective))
exact Equiv.ofBijective f this
-- `simp` can't figure out universe levels: normal form is `lift_mk_shrink'`.
theorem lift_mk_shrink (α : Type u) [Small.{v} α] :
Cardinal.lift.{max u w} #(Shrink.{v} α) = Cardinal.lift.{max v w} #α :=
lift_mk_eq.2 ⟨(equivShrink α).symm⟩
@[simp]
theorem lift_mk_shrink' (α : Type u) [Small.{v} α] :
Cardinal.lift.{u} #(Shrink.{v} α) = Cardinal.lift.{v} #α :=
lift_mk_shrink.{u, v, 0} α
@[simp]
theorem lift_mk_shrink'' (α : Type max u v) [Small.{v} α] :
Cardinal.lift.{u} #(Shrink.{v} α) = #α := by
rw [← lift_umax, lift_mk_shrink.{max u v, v, 0} α, ← lift_umax, lift_id]
theorem prod_eq_of_fintype {α : Type u} [h : Fintype α] (f : α → Cardinal.{v}) :
prod f = Cardinal.lift.{u} (∏ i, f i) := by
revert f
refine Fintype.induction_empty_option ?_ ?_ ?_ α (h_fintype := h)
· intro α β hβ e h f
letI := Fintype.ofEquiv β e.symm
rw [← e.prod_comp f, ← h]
exact mk_congr (e.piCongrLeft _).symm
· intro f
rw [Fintype.univ_pempty, Finset.prod_empty, lift_one, Cardinal.prod, mk_eq_one]
· intro α hα h f
rw [Cardinal.prod, mk_congr Equiv.piOptionEquivProd, mk_prod, lift_umax.{v, u}, mk_out, ←
Cardinal.prod, lift_prod, Fintype.prod_option, lift_mul, ← h fun a => f (some a)]
simp only [lift_id]
/-! ### Basic cardinals -/
theorem le_one_iff_subsingleton {α : Type u} : #α ≤ 1 ↔ Subsingleton α :=
⟨fun ⟨f⟩ => ⟨fun _ _ => f.injective (Subsingleton.elim _ _)⟩, fun ⟨h⟩ =>
⟨fun _ => ULift.up 0, fun _ _ _ => h _ _⟩⟩
@[simp]
theorem mk_le_one_iff_set_subsingleton {s : Set α} : #s ≤ 1 ↔ s.Subsingleton :=
le_one_iff_subsingleton.trans s.subsingleton_coe
alias ⟨_, _root_.Set.Subsingleton.cardinalMk_le_one⟩ := mk_le_one_iff_set_subsingleton
@[deprecated (since := "2024-11-10")]
alias _root_.Set.Subsingleton.cardinal_mk_le_one := Set.Subsingleton.cardinalMk_le_one
private theorem cast_succ (n : ℕ) : ((n + 1 : ℕ) : Cardinal.{u}) = n + 1 := by
change #(ULift.{u} _) = #(ULift.{u} _) + 1
rw [← mk_option]
simp
/-! ### Order properties -/
theorem one_lt_iff_nontrivial {α : Type u} : 1 < #α ↔ Nontrivial α := by
rw [← not_le, le_one_iff_subsingleton, ← not_nontrivial_iff_subsingleton, Classical.not_not]
lemma sInf_eq_zero_iff {s : Set Cardinal} : sInf s = 0 ↔ s = ∅ ∨ ∃ a ∈ s, a = 0 := by
refine ⟨fun h ↦ ?_, fun h ↦ ?_⟩
· rcases s.eq_empty_or_nonempty with rfl | hne
· exact Or.inl rfl
· exact Or.inr ⟨sInf s, csInf_mem hne, h⟩
· rcases h with rfl | ⟨a, ha, rfl⟩
· exact Cardinal.sInf_empty
· exact eq_bot_iff.2 (csInf_le' ha)
lemma iInf_eq_zero_iff {ι : Sort*} {f : ι → Cardinal} :
(⨅ i, f i) = 0 ↔ IsEmpty ι ∨ ∃ i, f i = 0 := by
simp [iInf, sInf_eq_zero_iff]
/-- A variant of `ciSup_of_empty` but with `0` on the RHS for convenience -/
protected theorem iSup_of_empty {ι} (f : ι → Cardinal) [IsEmpty ι] : iSup f = 0 :=
ciSup_of_empty f
@[simp]
theorem lift_sInf (s : Set Cardinal) : lift.{u, v} (sInf s) = sInf (lift.{u, v} '' s) := by
rcases eq_empty_or_nonempty s with (rfl | hs)
· simp
· exact lift_monotone.map_csInf hs
@[simp]
theorem lift_iInf {ι} (f : ι → Cardinal) : lift.{u, v} (iInf f) = ⨅ i, lift.{u, v} (f i) := by
unfold iInf
convert lift_sInf (range f)
simp_rw [← comp_apply (f := lift), range_comp]
end Cardinal
/-! ### Small sets of cardinals -/
namespace Cardinal
instance small_Iic (a : Cardinal.{u}) : Small.{u} (Iic a) := by
rw [← mk_out a]
apply @small_of_surjective (Set a.out) (Iic #a.out) _ fun x => ⟨#x, mk_set_le x⟩
rintro ⟨x, hx⟩
simpa using le_mk_iff_exists_set.1 hx
instance small_Iio (a : Cardinal.{u}) : Small.{u} (Iio a) := small_subset Iio_subset_Iic_self
instance small_Icc (a b : Cardinal.{u}) : Small.{u} (Icc a b) := small_subset Icc_subset_Iic_self
instance small_Ico (a b : Cardinal.{u}) : Small.{u} (Ico a b) := small_subset Ico_subset_Iio_self
instance small_Ioc (a b : Cardinal.{u}) : Small.{u} (Ioc a b) := small_subset Ioc_subset_Iic_self
instance small_Ioo (a b : Cardinal.{u}) : Small.{u} (Ioo a b) := small_subset Ioo_subset_Iio_self
/-- A set of cardinals is bounded above iff it's small, i.e. it corresponds to a usual ZFC set. -/
theorem bddAbove_iff_small {s : Set Cardinal.{u}} : BddAbove s ↔ Small.{u} s :=
⟨fun ⟨a, ha⟩ => @small_subset _ (Iic a) s (fun _ h => ha h) _, by
rintro ⟨ι, ⟨e⟩⟩
use sum.{u, u} fun x ↦ e.symm x
intro a ha
simpa using le_sum (fun x ↦ e.symm x) (e ⟨a, ha⟩)⟩
theorem bddAbove_of_small (s : Set Cardinal.{u}) [h : Small.{u} s] : BddAbove s :=
bddAbove_iff_small.2 h
theorem bddAbove_range {ι : Type*} [Small.{u} ι] (f : ι → Cardinal.{u}) : BddAbove (Set.range f) :=
bddAbove_of_small _
theorem bddAbove_image (f : Cardinal.{u} → Cardinal.{max u v}) {s : Set Cardinal.{u}}
(hs : BddAbove s) : BddAbove (f '' s) := by
rw [bddAbove_iff_small] at hs ⊢
exact small_lift _
theorem bddAbove_range_comp {ι : Type u} {f : ι → Cardinal.{v}} (hf : BddAbove (range f))
(g : Cardinal.{v} → Cardinal.{max v w}) : BddAbove (range (g ∘ f)) := by
rw [range_comp]
exact bddAbove_image g hf
/-- The type of cardinals in universe `u` is not `Small.{u}`. This is a version of the Burali-Forti
paradox. -/
theorem _root_.not_small_cardinal : ¬ Small.{u} Cardinal.{max u v} := by
intro h
have := small_lift.{_, v} Cardinal.{max u v}
rw [← small_univ_iff, ← bddAbove_iff_small] at this
exact not_bddAbove_univ this
instance uncountable : Uncountable Cardinal.{u} :=
Uncountable.of_not_small not_small_cardinal.{u}
/-! ### Bounds on suprema -/
theorem sum_le_iSup_lift {ι : Type u}
(f : ι → Cardinal.{max u v}) : sum f ≤ Cardinal.lift #ι * iSup f := by
rw [← (iSup f).lift_id, ← lift_umax, lift_umax.{max u v, u}, ← sum_const]
exact sum_le_sum _ _ (le_ciSup <| bddAbove_of_small _)
theorem sum_le_iSup {ι : Type u} (f : ι → Cardinal.{u}) : sum f ≤ #ι * iSup f := by
rw [← lift_id #ι]
exact sum_le_iSup_lift f
/-- The lift of a supremum is the supremum of the lifts. -/
theorem lift_sSup {s : Set Cardinal} (hs : BddAbove s) :
lift.{u} (sSup s) = sSup (lift.{u} '' s) := by
apply ((le_csSup_iff' (bddAbove_image.{_,u} _ hs)).2 fun c hc => _).antisymm (csSup_le' _)
· intro c hc
by_contra h
obtain ⟨d, rfl⟩ := Cardinal.mem_range_lift_of_le (not_le.1 h).le
simp_rw [lift_le] at h hc
rw [csSup_le_iff' hs] at h
exact h fun a ha => lift_le.1 <| hc (mem_image_of_mem _ ha)
· rintro i ⟨j, hj, rfl⟩
exact lift_le.2 (le_csSup hs hj)
/-- The lift of a supremum is the supremum of the lifts. -/
theorem lift_iSup {ι : Type v} {f : ι → Cardinal.{w}} (hf : BddAbove (range f)) :
lift.{u} (iSup f) = ⨆ i, lift.{u} (f i) := by
rw [iSup, iSup, lift_sSup hf, ← range_comp]
simp [Function.comp_def]
/-- To prove that the lift of a supremum is bounded by some cardinal `t`,
it suffices to show that the lift of each cardinal is bounded by `t`. -/
theorem lift_iSup_le {ι : Type v} {f : ι → Cardinal.{w}} {t : Cardinal} (hf : BddAbove (range f))
(w : ∀ i, lift.{u} (f i) ≤ t) : lift.{u} (iSup f) ≤ t := by
rw [lift_iSup hf]
exact ciSup_le' w
@[simp]
theorem lift_iSup_le_iff {ι : Type v} {f : ι → Cardinal.{w}} (hf : BddAbove (range f))
{t : Cardinal} : lift.{u} (iSup f) ≤ t ↔ ∀ i, lift.{u} (f i) ≤ t := by
rw [lift_iSup hf]
exact ciSup_le_iff' (bddAbove_range_comp.{_,_,u} hf _)
/-- To prove an inequality between the lifts to a common universe of two different supremums,
it suffices to show that the lift of each cardinal from the smaller supremum
if bounded by the lift of some cardinal from the larger supremum.
-/
theorem lift_iSup_le_lift_iSup {ι : Type v} {ι' : Type v'} {f : ι → Cardinal.{w}}
{f' : ι' → Cardinal.{w'}} (hf : BddAbove (range f)) (hf' : BddAbove (range f')) {g : ι → ι'}
(h : ∀ i, lift.{w'} (f i) ≤ lift.{w} (f' (g i))) : lift.{w'} (iSup f) ≤ lift.{w} (iSup f') := by
rw [lift_iSup hf, lift_iSup hf']
exact ciSup_mono' (bddAbove_range_comp.{_,_,w} hf' _) fun i => ⟨_, h i⟩
/-- A variant of `lift_iSup_le_lift_iSup` with universes specialized via `w = v` and `w' = v'`.
This is sometimes necessary to avoid universe unification issues. -/
theorem lift_iSup_le_lift_iSup' {ι : Type v} {ι' : Type v'} {f : ι → Cardinal.{v}}
{f' : ι' → Cardinal.{v'}} (hf : BddAbove (range f)) (hf' : BddAbove (range f')) (g : ι → ι')
(h : ∀ i, lift.{v'} (f i) ≤ lift.{v} (f' (g i))) : lift.{v'} (iSup f) ≤ lift.{v} (iSup f') :=
lift_iSup_le_lift_iSup hf hf' h
/-! ### Properties about the cast from `ℕ` -/
theorem mk_finset_of_fintype [Fintype α] : #(Finset α) = 2 ^ Fintype.card α := by
simp [Pow.pow]
@[norm_cast]
theorem nat_succ (n : ℕ) : (n.succ : Cardinal) = succ ↑n := by
rw [Nat.cast_succ]
refine (add_one_le_succ _).antisymm (succ_le_of_lt ?_)
rw [← Nat.cast_succ]
exact Nat.cast_lt.2 (Nat.lt_succ_self _)
lemma succ_natCast (n : ℕ) : Order.succ (n : Cardinal) = n + 1 := by
rw [← Cardinal.nat_succ]
norm_cast
lemma natCast_add_one_le_iff {n : ℕ} {c : Cardinal} : n + 1 ≤ c ↔ n < c := by
rw [← Order.succ_le_iff, Cardinal.succ_natCast]
lemma two_le_iff_one_lt {c : Cardinal} : 2 ≤ c ↔ 1 < c := by
convert natCast_add_one_le_iff
norm_cast
@[simp]
theorem succ_zero : succ (0 : Cardinal) = 1 := by norm_cast
-- This works generally to prove inequalities between numeric cardinals.
theorem one_lt_two : (1 : Cardinal) < 2 := by norm_cast
theorem exists_finset_le_card (α : Type*) (n : ℕ) (h : n ≤ #α) :
∃ s : Finset α, n ≤ s.card := by
obtain hα|hα := finite_or_infinite α
· let hα := Fintype.ofFinite α
use Finset.univ
simpa only [mk_fintype, Nat.cast_le] using h
· obtain ⟨s, hs⟩ := Infinite.exists_subset_card_eq α n
exact ⟨s, hs.ge⟩
theorem card_le_of {α : Type u} {n : ℕ} (H : ∀ s : Finset α, s.card ≤ n) : #α ≤ n := by
contrapose! H
apply exists_finset_le_card α (n+1)
simpa only [nat_succ, succ_le_iff] using H
theorem cantor' (a) {b : Cardinal} (hb : 1 < b) : a < b ^ a := by
rw [← succ_le_iff, (by norm_cast : succ (1 : Cardinal) = 2)] at hb
exact (cantor a).trans_le (power_le_power_right hb)
theorem one_le_iff_pos {c : Cardinal} : 1 ≤ c ↔ 0 < c := by
rw [← succ_zero, succ_le_iff]
theorem one_le_iff_ne_zero {c : Cardinal} : 1 ≤ c ↔ c ≠ 0 := by
rw [one_le_iff_pos, pos_iff_ne_zero]
@[simp]
theorem lt_one_iff_zero {c : Cardinal} : c < 1 ↔ c = 0 := by
simpa using lt_succ_bot_iff (a := c)
/-! ### Properties about `aleph0` -/
theorem nat_lt_aleph0 (n : ℕ) : (n : Cardinal.{u}) < ℵ₀ :=
succ_le_iff.1
(by
rw [← nat_succ, ← lift_mk_fin, aleph0, lift_mk_le.{u}]
exact ⟨⟨(↑), fun a b => Fin.ext⟩⟩)
@[simp]
theorem one_lt_aleph0 : 1 < ℵ₀ := by simpa using nat_lt_aleph0 1
@[simp]
theorem one_le_aleph0 : 1 ≤ ℵ₀ :=
one_lt_aleph0.le
theorem lt_aleph0 {c : Cardinal} : c < ℵ₀ ↔ ∃ n : ℕ, c = n :=
⟨fun h => by
rcases lt_lift_iff.1 h with ⟨c, h', rfl⟩
rcases le_mk_iff_exists_set.1 h'.1 with ⟨S, rfl⟩
suffices S.Finite by
lift S to Finset ℕ using this
simp
contrapose! h'
haveI := Infinite.to_subtype h'
exact ⟨Infinite.natEmbedding S⟩, fun ⟨_, e⟩ => e.symm ▸ nat_lt_aleph0 _⟩
lemma succ_eq_of_lt_aleph0 {c : Cardinal} (h : c < ℵ₀) : Order.succ c = c + 1 := by
obtain ⟨n, hn⟩ := Cardinal.lt_aleph0.mp h
rw [hn, succ_natCast]
theorem aleph0_le {c : Cardinal} : ℵ₀ ≤ c ↔ ∀ n : ℕ, ↑n ≤ c :=
⟨fun h _ => (nat_lt_aleph0 _).le.trans h, fun h =>
le_of_not_lt fun hn => by
rcases lt_aleph0.1 hn with ⟨n, rfl⟩
exact (Nat.lt_succ_self _).not_le (Nat.cast_le.1 (h (n + 1)))⟩
theorem isSuccPrelimit_aleph0 : IsSuccPrelimit ℵ₀ :=
isSuccPrelimit_of_succ_lt fun a ha => by
rcases lt_aleph0.1 ha with ⟨n, rfl⟩
rw [← nat_succ]
apply nat_lt_aleph0
theorem isSuccLimit_aleph0 : IsSuccLimit ℵ₀ := by
rw [Cardinal.isSuccLimit_iff]
exact ⟨aleph0_ne_zero, isSuccPrelimit_aleph0⟩
lemma not_isSuccLimit_natCast : (n : ℕ) → ¬ IsSuccLimit (n : Cardinal.{u})
| 0, e => e.1 isMin_bot
| Nat.succ n, e => Order.not_isSuccPrelimit_succ _ (nat_succ n ▸ e.2)
theorem not_isSuccLimit_of_lt_aleph0 {c : Cardinal} (h : c < ℵ₀) : ¬ IsSuccLimit c := by
obtain ⟨n, rfl⟩ := lt_aleph0.1 h
exact not_isSuccLimit_natCast n
theorem aleph0_le_of_isSuccLimit {c : Cardinal} (h : IsSuccLimit c) : ℵ₀ ≤ c := by
contrapose! h
exact not_isSuccLimit_of_lt_aleph0 h
theorem isStrongLimit_aleph0 : IsStrongLimit ℵ₀ := by
refine ⟨aleph0_ne_zero, fun x hx ↦ ?_⟩
obtain ⟨n, rfl⟩ := lt_aleph0.1 hx
exact_mod_cast nat_lt_aleph0 _
theorem IsStrongLimit.aleph0_le {c} (H : IsStrongLimit c) : ℵ₀ ≤ c :=
aleph0_le_of_isSuccLimit H.isSuccLimit
lemma exists_eq_natCast_of_iSup_eq {ι : Type u} [Nonempty ι] (f : ι → Cardinal.{v})
(hf : BddAbove (range f)) (n : ℕ) (h : ⨆ i, f i = n) : ∃ i, f i = n :=
exists_eq_of_iSup_eq_of_not_isSuccLimit.{u, v} f hf (not_isSuccLimit_natCast n) h
@[simp]
theorem range_natCast : range ((↑) : ℕ → Cardinal) = Iio ℵ₀ :=
ext fun x => by simp only [mem_Iio, mem_range, eq_comm, lt_aleph0]
theorem mk_eq_nat_iff {α : Type u} {n : ℕ} : #α = n ↔ Nonempty (α ≃ Fin n) := by
rw [← lift_mk_fin, ← lift_uzero #α, lift_mk_eq']
theorem lt_aleph0_iff_finite {α : Type u} : #α < ℵ₀ ↔ Finite α := by
simp only [lt_aleph0, mk_eq_nat_iff, finite_iff_exists_equiv_fin]
theorem lt_aleph0_iff_fintype {α : Type u} : #α < ℵ₀ ↔ Nonempty (Fintype α) :=
lt_aleph0_iff_finite.trans (finite_iff_nonempty_fintype _)
theorem lt_aleph0_of_finite (α : Type u) [Finite α] : #α < ℵ₀ :=
lt_aleph0_iff_finite.2 ‹_›
theorem lt_aleph0_iff_set_finite {S : Set α} : #S < ℵ₀ ↔ S.Finite :=
lt_aleph0_iff_finite.trans finite_coe_iff
alias ⟨_, _root_.Set.Finite.lt_aleph0⟩ := lt_aleph0_iff_set_finite
@[simp]
theorem lt_aleph0_iff_subtype_finite {p : α → Prop} : #{ x // p x } < ℵ₀ ↔ { x | p x }.Finite :=
lt_aleph0_iff_set_finite
theorem mk_le_aleph0_iff : #α ≤ ℵ₀ ↔ Countable α := by
rw [countable_iff_nonempty_embedding, aleph0, ← lift_uzero #α, lift_mk_le']
@[simp]
theorem mk_le_aleph0 [Countable α] : #α ≤ ℵ₀ :=
mk_le_aleph0_iff.mpr ‹_›
theorem le_aleph0_iff_set_countable {s : Set α} : #s ≤ ℵ₀ ↔ s.Countable := mk_le_aleph0_iff
alias ⟨_, _root_.Set.Countable.le_aleph0⟩ := le_aleph0_iff_set_countable
@[simp]
theorem le_aleph0_iff_subtype_countable {p : α → Prop} :
#{ x // p x } ≤ ℵ₀ ↔ { x | p x }.Countable :=
le_aleph0_iff_set_countable
theorem aleph0_lt_mk_iff : ℵ₀ < #α ↔ Uncountable α := by
rw [← not_le, ← not_countable_iff, not_iff_not, mk_le_aleph0_iff]
@[simp]
theorem aleph0_lt_mk [Uncountable α] : ℵ₀ < #α :=
aleph0_lt_mk_iff.mpr ‹_›
instance canLiftCardinalNat : CanLift Cardinal ℕ (↑) fun x => x < ℵ₀ :=
⟨fun _ hx =>
let ⟨n, hn⟩ := lt_aleph0.mp hx
⟨n, hn.symm⟩⟩
theorem add_lt_aleph0 {a b : Cardinal} (ha : a < ℵ₀) (hb : b < ℵ₀) : a + b < ℵ₀ :=
match a, b, lt_aleph0.1 ha, lt_aleph0.1 hb with
| _, _, ⟨m, rfl⟩, ⟨n, rfl⟩ => by rw [← Nat.cast_add]; apply nat_lt_aleph0
theorem add_lt_aleph0_iff {a b : Cardinal} : a + b < ℵ₀ ↔ a < ℵ₀ ∧ b < ℵ₀ :=
⟨fun h => ⟨(self_le_add_right _ _).trans_lt h, (self_le_add_left _ _).trans_lt h⟩,
fun ⟨h1, h2⟩ => add_lt_aleph0 h1 h2⟩
theorem aleph0_le_add_iff {a b : Cardinal} : ℵ₀ ≤ a + b ↔ ℵ₀ ≤ a ∨ ℵ₀ ≤ b := by
simp only [← not_lt, add_lt_aleph0_iff, not_and_or]
/-- See also `Cardinal.nsmul_lt_aleph0_iff_of_ne_zero` if you already have `n ≠ 0`. -/
theorem nsmul_lt_aleph0_iff {n : ℕ} {a : Cardinal} : n • a < ℵ₀ ↔ n = 0 ∨ a < ℵ₀ := by
cases n with
| zero => simpa using nat_lt_aleph0 0
| succ n =>
simp only [Nat.succ_ne_zero, false_or]
induction' n with n ih
· simp
rw [succ_nsmul, add_lt_aleph0_iff, ih, and_self_iff]
/-- See also `Cardinal.nsmul_lt_aleph0_iff` for a hypothesis-free version. -/
theorem nsmul_lt_aleph0_iff_of_ne_zero {n : ℕ} {a : Cardinal} (h : n ≠ 0) : n • a < ℵ₀ ↔ a < ℵ₀ :=
nsmul_lt_aleph0_iff.trans <| or_iff_right h
theorem mul_lt_aleph0 {a b : Cardinal} (ha : a < ℵ₀) (hb : b < ℵ₀) : a * b < ℵ₀ :=
match a, b, lt_aleph0.1 ha, lt_aleph0.1 hb with
| _, _, ⟨m, rfl⟩, ⟨n, rfl⟩ => by rw [← Nat.cast_mul]; apply nat_lt_aleph0
theorem mul_lt_aleph0_iff {a b : Cardinal} : a * b < ℵ₀ ↔ a = 0 ∨ b = 0 ∨ a < ℵ₀ ∧ b < ℵ₀ := by
refine ⟨fun h => ?_, ?_⟩
· by_cases ha : a = 0
· exact Or.inl ha
right
by_cases hb : b = 0
· exact Or.inl hb
right
rw [← Ne, ← one_le_iff_ne_zero] at ha hb
constructor
· rw [← mul_one a]
exact (mul_le_mul' le_rfl hb).trans_lt h
· rw [← one_mul b]
exact (mul_le_mul' ha le_rfl).trans_lt h
rintro (rfl | rfl | ⟨ha, hb⟩) <;> simp only [*, mul_lt_aleph0, aleph0_pos, zero_mul, mul_zero]
/-- See also `Cardinal.aleph0_le_mul_iff`. -/
theorem aleph0_le_mul_iff {a b : Cardinal} : ℵ₀ ≤ a * b ↔ a ≠ 0 ∧ b ≠ 0 ∧ (ℵ₀ ≤ a ∨ ℵ₀ ≤ b) := by
let h := (@mul_lt_aleph0_iff a b).not
rwa [not_lt, not_or, not_or, not_and_or, not_lt, not_lt] at h
/-- See also `Cardinal.aleph0_le_mul_iff'`. -/
theorem aleph0_le_mul_iff' {a b : Cardinal.{u}} : ℵ₀ ≤ a * b ↔ a ≠ 0 ∧ ℵ₀ ≤ b ∨ ℵ₀ ≤ a ∧ b ≠ 0 := by
have : ∀ {a : Cardinal.{u}}, ℵ₀ ≤ a → a ≠ 0 := fun a => ne_bot_of_le_ne_bot aleph0_ne_zero a
simp only [aleph0_le_mul_iff, and_or_left, and_iff_right_of_imp this, @and_left_comm (a ≠ 0)]
simp only [and_comm, or_comm]
theorem mul_lt_aleph0_iff_of_ne_zero {a b : Cardinal} (ha : a ≠ 0) (hb : b ≠ 0) :
a * b < ℵ₀ ↔ a < ℵ₀ ∧ b < ℵ₀ := by simp [mul_lt_aleph0_iff, ha, hb]
theorem power_lt_aleph0 {a b : Cardinal} (ha : a < ℵ₀) (hb : b < ℵ₀) : a ^ b < ℵ₀ :=
match a, b, lt_aleph0.1 ha, lt_aleph0.1 hb with
| _, _, ⟨m, rfl⟩, ⟨n, rfl⟩ => by rw [power_natCast, ← Nat.cast_pow]; apply nat_lt_aleph0
theorem eq_one_iff_unique {α : Type*} : #α = 1 ↔ Subsingleton α ∧ Nonempty α :=
calc
#α = 1 ↔ #α ≤ 1 ∧ 1 ≤ #α := le_antisymm_iff
_ ↔ Subsingleton α ∧ Nonempty α :=
le_one_iff_subsingleton.and (one_le_iff_ne_zero.trans mk_ne_zero_iff)
theorem infinite_iff {α : Type u} : Infinite α ↔ ℵ₀ ≤ #α := by
rw [← not_lt, lt_aleph0_iff_finite, not_finite_iff_infinite]
lemma aleph0_le_mk_iff : ℵ₀ ≤ #α ↔ Infinite α := infinite_iff.symm
lemma mk_lt_aleph0_iff : #α < ℵ₀ ↔ Finite α := by simp [← not_le, aleph0_le_mk_iff]
@[simp] lemma mk_lt_aleph0 [Finite α] : #α < ℵ₀ := mk_lt_aleph0_iff.2 ‹_›
@[simp]
theorem aleph0_le_mk (α : Type u) [Infinite α] : ℵ₀ ≤ #α :=
infinite_iff.1 ‹_›
@[simp]
theorem mk_eq_aleph0 (α : Type*) [Countable α] [Infinite α] : #α = ℵ₀ :=
mk_le_aleph0.antisymm <| aleph0_le_mk _
theorem denumerable_iff {α : Type u} : Nonempty (Denumerable α) ↔ #α = ℵ₀ :=
⟨fun ⟨h⟩ => mk_congr ((@Denumerable.eqv α h).trans Equiv.ulift.symm), fun h => by
obtain ⟨f⟩ := Quotient.exact h
exact ⟨Denumerable.mk' <| f.trans Equiv.ulift⟩⟩
theorem mk_denumerable (α : Type u) [Denumerable α] : #α = ℵ₀ :=
denumerable_iff.1 ⟨‹_›⟩
theorem _root_.Set.countable_infinite_iff_nonempty_denumerable {α : Type*} {s : Set α} :
s.Countable ∧ s.Infinite ↔ Nonempty (Denumerable s) := by
rw [nonempty_denumerable_iff, ← Set.infinite_coe_iff, countable_coe_iff]
@[simp]
theorem aleph0_add_aleph0 : ℵ₀ + ℵ₀ = ℵ₀ :=
mk_denumerable _
theorem aleph0_mul_aleph0 : ℵ₀ * ℵ₀ = ℵ₀ :=
mk_denumerable _
@[simp]
theorem nat_mul_aleph0 {n : ℕ} (hn : n ≠ 0) : ↑n * ℵ₀ = ℵ₀ :=
le_antisymm (lift_mk_fin n ▸ mk_le_aleph0) <|
le_mul_of_one_le_left (zero_le _) <| by
rwa [← Nat.cast_one, Nat.cast_le, Nat.one_le_iff_ne_zero]
@[simp]
theorem aleph0_mul_nat {n : ℕ} (hn : n ≠ 0) : ℵ₀ * n = ℵ₀ := by rw [mul_comm, nat_mul_aleph0 hn]
@[simp]
theorem ofNat_mul_aleph0 {n : ℕ} [Nat.AtLeastTwo n] : ofNat(n) * ℵ₀ = ℵ₀ :=
nat_mul_aleph0 (NeZero.ne n)
@[simp]
theorem aleph0_mul_ofNat {n : ℕ} [Nat.AtLeastTwo n] : ℵ₀ * ofNat(n) = ℵ₀ :=
aleph0_mul_nat (NeZero.ne n)
@[simp]
theorem add_le_aleph0 {c₁ c₂ : Cardinal} : c₁ + c₂ ≤ ℵ₀ ↔ c₁ ≤ ℵ₀ ∧ c₂ ≤ ℵ₀ :=
⟨fun h => ⟨le_self_add.trans h, le_add_self.trans h⟩, fun h =>
aleph0_add_aleph0 ▸ add_le_add h.1 h.2⟩
@[simp]
theorem aleph0_add_nat (n : ℕ) : ℵ₀ + n = ℵ₀ :=
(add_le_aleph0.2 ⟨le_rfl, (nat_lt_aleph0 n).le⟩).antisymm le_self_add
@[simp]
theorem nat_add_aleph0 (n : ℕ) : ↑n + ℵ₀ = ℵ₀ := by rw [add_comm, aleph0_add_nat]
@[simp]
theorem ofNat_add_aleph0 {n : ℕ} [Nat.AtLeastTwo n] : ofNat(n) + ℵ₀ = ℵ₀ :=
nat_add_aleph0 n
@[simp]
theorem aleph0_add_ofNat {n : ℕ} [Nat.AtLeastTwo n] : ℵ₀ + ofNat(n) = ℵ₀ :=
aleph0_add_nat n
theorem exists_nat_eq_of_le_nat {c : Cardinal} {n : ℕ} (h : c ≤ n) : ∃ m, m ≤ n ∧ c = m := by
lift c to ℕ using h.trans_lt (nat_lt_aleph0 _)
exact ⟨c, mod_cast h, rfl⟩
theorem mk_int : #ℤ = ℵ₀ :=
mk_denumerable ℤ
theorem mk_pnat : #ℕ+ = ℵ₀ :=
mk_denumerable ℕ+
@[deprecated (since := "2025-04-27")]
alias mk_pNat := mk_pnat
/-! ### Cardinalities of basic sets and types -/
@[simp] theorem mk_additive : #(Additive α) = #α := rfl
@[simp] theorem mk_multiplicative : #(Multiplicative α) = #α := rfl
@[to_additive (attr := simp)] theorem mk_mulOpposite : #(MulOpposite α) = #α :=
mk_congr MulOpposite.opEquiv.symm
theorem mk_singleton {α : Type u} (x : α) : #({x} : Set α) = 1 :=
mk_eq_one _
@[simp]
theorem mk_vector (α : Type u) (n : ℕ) : #(List.Vector α n) = #α ^ n :=
(mk_congr (Equiv.vectorEquivFin α n)).trans <| by simp
theorem mk_list_eq_sum_pow (α : Type u) : #(List α) = sum fun n : ℕ => #α ^ n :=
calc
#(List α) = #(Σn, List.Vector α n) := mk_congr (Equiv.sigmaFiberEquiv List.length).symm
_ = sum fun n : ℕ => #α ^ n := by simp
theorem mk_quot_le {α : Type u} {r : α → α → Prop} : #(Quot r) ≤ #α :=
mk_le_of_surjective Quot.exists_rep
theorem mk_quotient_le {α : Type u} {s : Setoid α} : #(Quotient s) ≤ #α :=
mk_quot_le
theorem mk_subtype_le_of_subset {α : Type u} {p q : α → Prop} (h : ∀ ⦃x⦄, p x → q x) :
#(Subtype p) ≤ #(Subtype q) :=
⟨Embedding.subtypeMap (Embedding.refl α) h⟩
theorem mk_emptyCollection (α : Type u) : #(∅ : Set α) = 0 :=
mk_eq_zero _
theorem mk_emptyCollection_iff {α : Type u} {s : Set α} : #s = 0 ↔ s = ∅ := by
constructor
· intro h
rw [mk_eq_zero_iff] at h
exact eq_empty_iff_forall_not_mem.2 fun x hx => h.elim' ⟨x, hx⟩
· rintro rfl
exact mk_emptyCollection _
@[simp]
theorem mk_univ {α : Type u} : #(@univ α) = #α :=
mk_congr (Equiv.Set.univ α)
@[simp] lemma mk_setProd {α β : Type u} (s : Set α) (t : Set β) : #(s ×ˢ t) = #s * #t := by
rw [mul_def, mk_congr (Equiv.Set.prod ..)]
theorem mk_image_le {α β : Type u} {f : α → β} {s : Set α} : #(f '' s) ≤ #s :=
mk_le_of_surjective surjective_onto_image
lemma mk_image2_le {α β γ : Type u} {f : α → β → γ} {s : Set α} {t : Set β} :
#(image2 f s t) ≤ #s * #t := by
rw [← image_uncurry_prod, ← mk_setProd]
exact mk_image_le
theorem mk_image_le_lift {α : Type u} {β : Type v} {f : α → β} {s : Set α} :
lift.{u} #(f '' s) ≤ lift.{v} #s :=
lift_mk_le.{0}.mpr ⟨Embedding.ofSurjective _ surjective_onto_image⟩
theorem mk_range_le {α β : Type u} {f : α → β} : #(range f) ≤ #α :=
mk_le_of_surjective surjective_onto_range
theorem mk_range_le_lift {α : Type u} {β : Type v} {f : α → β} :
lift.{u} #(range f) ≤ lift.{v} #α :=
lift_mk_le.{0}.mpr ⟨Embedding.ofSurjective _ surjective_onto_range⟩
theorem mk_range_eq (f : α → β) (h : Injective f) : #(range f) = #α :=
mk_congr (Equiv.ofInjective f h).symm
theorem mk_range_eq_lift {α : Type u} {β : Type v} {f : α → β} (hf : Injective f) :
lift.{max u w} #(range f) = lift.{max v w} #α :=
lift_mk_eq.{v,u,w}.mpr ⟨(Equiv.ofInjective f hf).symm⟩
theorem mk_range_eq_of_injective {α : Type u} {β : Type v} {f : α → β} (hf : Injective f) :
lift.{u} #(range f) = lift.{v} #α :=
lift_mk_eq'.mpr ⟨(Equiv.ofInjective f hf).symm⟩
lemma lift_mk_le_lift_mk_of_injective {α : Type u} {β : Type v} {f : α → β} (hf : Injective f) :
Cardinal.lift.{v} (#α) ≤ Cardinal.lift.{u} (#β) := by
rw [← Cardinal.mk_range_eq_of_injective hf]
exact Cardinal.lift_le.2 (Cardinal.mk_set_le _)
lemma lift_mk_le_lift_mk_of_surjective {α : Type u} {β : Type v} {f : α → β} (hf : Surjective f) :
Cardinal.lift.{u} (#β) ≤ Cardinal.lift.{v} (#α) :=
lift_mk_le_lift_mk_of_injective (injective_surjInv hf)
theorem mk_image_eq_of_injOn {α β : Type u} (f : α → β) (s : Set α) (h : InjOn f s) :
#(f '' s) = #s :=
mk_congr (Equiv.Set.imageOfInjOn f s h).symm
theorem mk_image_eq_of_injOn_lift {α : Type u} {β : Type v} (f : α → β) (s : Set α)
(h : InjOn f s) : lift.{u} #(f '' s) = lift.{v} #s :=
lift_mk_eq.{v, u, 0}.mpr ⟨(Equiv.Set.imageOfInjOn f s h).symm⟩
theorem mk_image_eq {α β : Type u} {f : α → β} {s : Set α} (hf : Injective f) : #(f '' s) = #s :=
mk_image_eq_of_injOn _ _ hf.injOn
theorem mk_image_eq_lift {α : Type u} {β : Type v} (f : α → β) (s : Set α) (h : Injective f) :
lift.{u} #(f '' s) = lift.{v} #s :=
mk_image_eq_of_injOn_lift _ _ h.injOn
@[simp]
theorem mk_image_embedding_lift {β : Type v} (f : α ↪ β) (s : Set α) :
lift.{u} #(f '' s) = lift.{v} #s :=
mk_image_eq_lift _ _ f.injective
@[simp]
theorem mk_image_embedding (f : α ↪ β) (s : Set α) : #(f '' s) = #s := by
simpa using mk_image_embedding_lift f s
theorem mk_iUnion_le_sum_mk {α ι : Type u} {f : ι → Set α} : #(⋃ i, f i) ≤ sum fun i => #(f i) :=
calc
#(⋃ i, f i) ≤ #(Σi, f i) := mk_le_of_surjective (Set.sigmaToiUnion_surjective f)
_ = sum fun i => #(f i) := mk_sigma _
theorem mk_iUnion_le_sum_mk_lift {α : Type u} {ι : Type v} {f : ι → Set α} :
lift.{v} #(⋃ i, f i) ≤ sum fun i => #(f i) :=
calc
lift.{v} #(⋃ i, f i) ≤ #(Σi, f i) :=
mk_le_of_surjective <| ULift.up_surjective.comp (Set.sigmaToiUnion_surjective f)
_ = sum fun i => #(f i) := mk_sigma _
theorem mk_iUnion_eq_sum_mk {α ι : Type u} {f : ι → Set α}
(h : Pairwise (Disjoint on f)) : #(⋃ i, f i) = sum fun i => #(f i) :=
calc
#(⋃ i, f i) = #(Σi, f i) := mk_congr (Set.unionEqSigmaOfDisjoint h)
_ = sum fun i => #(f i) := mk_sigma _
theorem mk_iUnion_eq_sum_mk_lift {α : Type u} {ι : Type v} {f : ι → Set α}
(h : Pairwise (Disjoint on f)) :
lift.{v} #(⋃ i, f i) = sum fun i => #(f i) :=
calc
lift.{v} #(⋃ i, f i) = #(Σi, f i) :=
mk_congr <| .trans Equiv.ulift (Set.unionEqSigmaOfDisjoint h)
_ = sum fun i => #(f i) := mk_sigma _
theorem mk_iUnion_le {α ι : Type u} (f : ι → Set α) : #(⋃ i, f i) ≤ #ι * ⨆ i, #(f i) :=
mk_iUnion_le_sum_mk.trans (sum_le_iSup _)
theorem mk_iUnion_le_lift {α : Type u} {ι : Type v} (f : ι → Set α) :
lift.{v} #(⋃ i, f i) ≤ lift.{u} #ι * ⨆ i, lift.{v} #(f i) := by
refine mk_iUnion_le_sum_mk_lift.trans <| Eq.trans_le ?_ (sum_le_iSup_lift _)
rw [← lift_sum, lift_id'.{_,u}]
theorem mk_sUnion_le {α : Type u} (A : Set (Set α)) : #(⋃₀ A) ≤ #A * ⨆ s : A, #s := by
rw [sUnion_eq_iUnion]
apply mk_iUnion_le
theorem mk_biUnion_le {ι α : Type u} (A : ι → Set α) (s : Set ι) :
#(⋃ x ∈ s, A x) ≤ #s * ⨆ x : s, #(A x.1) := by
rw [biUnion_eq_iUnion]
apply mk_iUnion_le
theorem mk_biUnion_le_lift {α : Type u} {ι : Type v} (A : ι → Set α) (s : Set ι) :
lift.{v} #(⋃ x ∈ s, A x) ≤ lift.{u} #s * ⨆ x : s, lift.{v} #(A x.1) := by
rw [biUnion_eq_iUnion]
apply mk_iUnion_le_lift
theorem finset_card_lt_aleph0 (s : Finset α) : #(↑s : Set α) < ℵ₀ :=
lt_aleph0_of_finite _
theorem mk_set_eq_nat_iff_finset {α} {s : Set α} {n : ℕ} :
#s = n ↔ ∃ t : Finset α, (t : Set α) = s ∧ t.card = n := by
constructor
· intro h
lift s to Finset α using lt_aleph0_iff_set_finite.1 (h.symm ▸ nat_lt_aleph0 n)
simpa using h
· rintro ⟨t, rfl, rfl⟩
exact mk_coe_finset
theorem mk_eq_nat_iff_finset {n : ℕ} :
#α = n ↔ ∃ t : Finset α, (t : Set α) = univ ∧ t.card = n := by
rw [← mk_univ, mk_set_eq_nat_iff_finset]
theorem mk_eq_nat_iff_fintype {n : ℕ} : #α = n ↔ ∃ h : Fintype α, @Fintype.card α h = n := by
rw [mk_eq_nat_iff_finset]
constructor
· rintro ⟨t, ht, hn⟩
exact ⟨⟨t, eq_univ_iff_forall.1 ht⟩, hn⟩
· rintro ⟨⟨t, ht⟩, hn⟩
exact ⟨t, eq_univ_iff_forall.2 ht, hn⟩
theorem mk_union_add_mk_inter {α : Type u} {S T : Set α} :
#(S ∪ T : Set α) + #(S ∩ T : Set α) = #S + #T := by
classical
exact Quot.sound ⟨Equiv.Set.unionSumInter S T⟩
/-- The cardinality of a union is at most the sum of the cardinalities
of the two sets. -/
theorem mk_union_le {α : Type u} (S T : Set α) : #(S ∪ T : Set α) ≤ #S + #T :=
@mk_union_add_mk_inter α S T ▸ self_le_add_right #(S ∪ T : Set α) #(S ∩ T : Set α)
theorem mk_union_of_disjoint {α : Type u} {S T : Set α} (H : Disjoint S T) :
#(S ∪ T : Set α) = #S + #T := by
classical
exact Quot.sound ⟨Equiv.Set.union H⟩
theorem mk_insert {α : Type u} {s : Set α} {a : α} (h : a ∉ s) :
#(insert a s : Set α) = #s + 1 := by
rw [← union_singleton, mk_union_of_disjoint, mk_singleton]
simpa
theorem mk_insert_le {α : Type u} {s : Set α} {a : α} : #(insert a s : Set α) ≤ #s + 1 := by
by_cases h : a ∈ s
· simp only [insert_eq_of_mem h, self_le_add_right]
· rw [mk_insert h]
theorem mk_sum_compl {α} (s : Set α) : #s + #(sᶜ : Set α) = #α := by
classical
exact mk_congr (Equiv.Set.sumCompl s)
theorem mk_le_mk_of_subset {α} {s t : Set α} (h : s ⊆ t) : #s ≤ #t :=
⟨Set.embeddingOfSubset s t h⟩
theorem mk_le_iff_forall_finset_subset_card_le {α : Type u} {n : ℕ} {t : Set α} :
#t ≤ n ↔ ∀ s : Finset α, (s : Set α) ⊆ t → s.card ≤ n := by
refine ⟨fun H s hs ↦ by simpa using (mk_le_mk_of_subset hs).trans H, fun H ↦ ?_⟩
apply card_le_of (fun s ↦ ?_)
classical
let u : Finset α := s.image Subtype.val
have : u.card = s.card := Finset.card_image_of_injOn Subtype.coe_injective.injOn
rw [← this]
apply H
simp only [u, Finset.coe_image, image_subset_iff, Subtype.coe_preimage_self, subset_univ]
theorem mk_subtype_mono {p q : α → Prop} (h : ∀ x, p x → q x) :
#{ x // p x } ≤ #{ x // q x } :=
⟨embeddingOfSubset _ _ h⟩
theorem le_mk_diff_add_mk (S T : Set α) : #S ≤ #(S \ T : Set α) + #T :=
(mk_le_mk_of_subset <| subset_diff_union _ _).trans <| mk_union_le _ _
theorem mk_diff_add_mk {S T : Set α} (h : T ⊆ S) : #(S \ T : Set α) + #T = #S := by
refine (mk_union_of_disjoint <| ?_).symm.trans <| by rw [diff_union_of_subset h]
exact disjoint_sdiff_self_left
theorem mk_union_le_aleph0 {α} {P Q : Set α} :
#(P ∪ Q : Set α) ≤ ℵ₀ ↔ #P ≤ ℵ₀ ∧ #Q ≤ ℵ₀ := by
simp only [le_aleph0_iff_subtype_countable, mem_union, setOf_mem_eq, Set.union_def,
← countable_union]
theorem mk_sep (s : Set α) (t : α → Prop) : #({ x ∈ s | t x } : Set α) = #{ x : s | t x.1 } :=
mk_congr (Equiv.Set.sep s t)
theorem mk_preimage_of_injective_lift {α : Type u} {β : Type v} (f : α → β) (s : Set β)
(h : Injective f) : lift.{v} #(f ⁻¹' s) ≤ lift.{u} #s := by
rw [lift_mk_le.{0}]
-- Porting note: Needed to insert `mem_preimage.mp` below
use Subtype.coind (fun x => f x.1) fun x => mem_preimage.mp x.2
apply Subtype.coind_injective; exact h.comp Subtype.val_injective
theorem mk_preimage_of_subset_range_lift {α : Type u} {β : Type v} (f : α → β) (s : Set β)
(h : s ⊆ range f) : lift.{u} #s ≤ lift.{v} #(f ⁻¹' s) := by
rw [← image_preimage_eq_iff] at h
nth_rewrite 1 [← h]
apply mk_image_le_lift
theorem mk_preimage_of_injective_of_subset_range_lift {β : Type v} (f : α → β) (s : Set β)
(h : Injective f) (h2 : s ⊆ range f) : lift.{v} #(f ⁻¹' s) = lift.{u} #s :=
le_antisymm (mk_preimage_of_injective_lift f s h) (mk_preimage_of_subset_range_lift f s h2)
theorem mk_preimage_of_injective_of_subset_range (f : α → β) (s : Set β) (h : Injective f)
(h2 : s ⊆ range f) : #(f ⁻¹' s) = #s := by
convert mk_preimage_of_injective_of_subset_range_lift.{u, u} f s h h2 using 1 <;> rw [lift_id]
@[simp]
theorem mk_preimage_equiv_lift {β : Type v} (f : α ≃ β) (s : Set β) :
lift.{v} #(f ⁻¹' s) = lift.{u} #s := by
apply mk_preimage_of_injective_of_subset_range_lift _ _ f.injective
rw [f.range_eq_univ]
exact fun _ _ ↦ ⟨⟩
@[simp]
theorem mk_preimage_equiv (f : α ≃ β) (s : Set β) : #(f ⁻¹' s) = #s := by
simpa using mk_preimage_equiv_lift f s
theorem mk_preimage_of_injective (f : α → β) (s : Set β) (h : Injective f) :
#(f ⁻¹' s) ≤ #s := by
rw [← lift_id #(↑(f ⁻¹' s)), ← lift_id #(↑s)]
exact mk_preimage_of_injective_lift f s h
theorem mk_preimage_of_subset_range (f : α → β) (s : Set β) (h : s ⊆ range f) :
#s ≤ #(f ⁻¹' s) := by
rw [← lift_id #(↑(f ⁻¹' s)), ← lift_id #(↑s)]
exact mk_preimage_of_subset_range_lift f s h
theorem mk_subset_ge_of_subset_image_lift {α : Type u} {β : Type v} (f : α → β) {s : Set α}
{t : Set β} (h : t ⊆ f '' s) : lift.{u} #t ≤ lift.{v} #({ x ∈ s | f x ∈ t } : Set α) := by
rw [image_eq_range] at h
convert mk_preimage_of_subset_range_lift _ _ h using 1
rw [mk_sep]
rfl
theorem mk_subset_ge_of_subset_image (f : α → β) {s : Set α} {t : Set β} (h : t ⊆ f '' s) :
#t ≤ #({ x ∈ s | f x ∈ t } : Set α) := by
rw [image_eq_range] at h
convert mk_preimage_of_subset_range _ _ h using 1
rw [mk_sep]
rfl
theorem le_mk_iff_exists_subset {c : Cardinal} {α : Type u} {s : Set α} :
c ≤ #s ↔ ∃ p : Set α, p ⊆ s ∧ #p = c := by
rw [le_mk_iff_exists_set, ← Subtype.exists_set_subtype]
apply exists_congr; intro t; rw [mk_image_eq]; apply Subtype.val_injective
@[simp]
theorem mk_range_inl {α : Type u} {β : Type v} : #(range (@Sum.inl α β)) = lift.{v} #α := by
rw [← lift_id'.{u, v} #_, (Equiv.Set.rangeInl α β).lift_cardinal_eq, lift_umax.{u, v}]
@[simp]
theorem mk_range_inr {α : Type u} {β : Type v} : #(range (@Sum.inr α β)) = lift.{u} #β := by
rw [← lift_id'.{v, u} #_, (Equiv.Set.rangeInr α β).lift_cardinal_eq, lift_umax.{v, u}]
theorem two_le_iff : (2 : Cardinal) ≤ #α ↔ ∃ x y : α, x ≠ y := by
rw [← Nat.cast_two, nat_succ, succ_le_iff, Nat.cast_one, one_lt_iff_nontrivial, nontrivial_iff]
theorem two_le_iff' (x : α) : (2 : Cardinal) ≤ #α ↔ ∃ y : α, y ≠ x := by
rw [two_le_iff, ← nontrivial_iff, nontrivial_iff_exists_ne x]
theorem mk_eq_two_iff : #α = 2 ↔ ∃ x y : α, x ≠ y ∧ ({x, y} : Set α) = univ := by
classical
simp only [← @Nat.cast_two Cardinal, mk_eq_nat_iff_finset, Finset.card_eq_two]
constructor
· rintro ⟨t, ht, x, y, hne, rfl⟩
exact ⟨x, y, hne, by simpa using ht⟩
· rintro ⟨x, y, hne, h⟩
exact ⟨{x, y}, by simpa using h, x, y, hne, rfl⟩
theorem mk_eq_two_iff' (x : α) : #α = 2 ↔ ∃! y, y ≠ x := by
rw [mk_eq_two_iff]; constructor
· rintro ⟨a, b, hne, h⟩
simp only [eq_univ_iff_forall, mem_insert_iff, mem_singleton_iff] at h
rcases h x with (rfl | rfl)
exacts [⟨b, hne.symm, fun z => (h z).resolve_left⟩, ⟨a, hne, fun z => (h z).resolve_right⟩]
· rintro ⟨y, hne, hy⟩
exact ⟨x, y, hne.symm, eq_univ_of_forall fun z => or_iff_not_imp_left.2 (hy z)⟩
theorem exists_not_mem_of_length_lt {α : Type*} (l : List α) (h : ↑l.length < #α) :
∃ z : α, z ∉ l := by
classical
contrapose! h
calc
#α = #(Set.univ : Set α) := mk_univ.symm
_ ≤ #l.toFinset := mk_le_mk_of_subset fun x _ => List.mem_toFinset.mpr (h x)
_ = l.toFinset.card := Cardinal.mk_coe_finset
_ ≤ l.length := Nat.cast_le.mpr (List.toFinset_card_le l)
theorem three_le {α : Type*} (h : 3 ≤ #α) (x : α) (y : α) : ∃ z : α, z ≠ x ∧ z ≠ y := by
have : ↑(3 : ℕ) ≤ #α := by simpa using h
have : ↑(2 : ℕ) < #α := by rwa [← succ_le_iff, ← Cardinal.nat_succ]
have := exists_not_mem_of_length_lt [x, y] this
simpa [not_or] using this
/-! ### `powerlt` operation -/
/-- The function `a ^< b`, defined as the supremum of `a ^ c` for `c < b`. -/
def powerlt (a b : Cardinal.{u}) : Cardinal.{u} :=
⨆ c : Iio b, a ^ (c : Cardinal)
@[inherit_doc]
infixl:80 " ^< " => powerlt
theorem le_powerlt {b c : Cardinal.{u}} (a) (h : c < b) : (a^c) ≤ a ^< b := by
refine le_ciSup (f := fun y : Iio b => a ^ (y : Cardinal)) ?_ ⟨c, h⟩
rw [← image_eq_range]
exact bddAbove_image.{u, u} _ bddAbove_Iio
theorem powerlt_le {a b c : Cardinal.{u}} : a ^< b ≤ c ↔ ∀ x < b, a ^ x ≤ c := by
rw [powerlt, ciSup_le_iff']
· simp
· rw [← image_eq_range]
exact bddAbove_image.{u, u} _ bddAbove_Iio
theorem powerlt_le_powerlt_left {a b c : Cardinal} (h : b ≤ c) : a ^< b ≤ a ^< c :=
powerlt_le.2 fun _ hx => le_powerlt a <| hx.trans_le h
theorem powerlt_mono_left (a) : Monotone fun c => a ^< c := fun _ _ => powerlt_le_powerlt_left
theorem powerlt_succ {a b : Cardinal} (h : a ≠ 0) : a ^< succ b = a ^ b :=
(powerlt_le.2 fun _ h' => power_le_power_left h <| le_of_lt_succ h').antisymm <|
le_powerlt a (lt_succ b)
theorem powerlt_min {a b c : Cardinal} : a ^< min b c = min (a ^< b) (a ^< c) :=
(powerlt_mono_left a).map_min
theorem powerlt_max {a b c : Cardinal} : a ^< max b c = max (a ^< b) (a ^< c) :=
(powerlt_mono_left a).map_max
theorem zero_powerlt {a : Cardinal} (h : a ≠ 0) : 0 ^< a = 1 := by
apply (powerlt_le.2 fun c _ => zero_power_le _).antisymm
rw [← power_zero]
exact le_powerlt 0 (pos_iff_ne_zero.2 h)
@[simp]
theorem powerlt_zero {a : Cardinal} : a ^< 0 = 0 := by
convert Cardinal.iSup_of_empty _
exact Subtype.isEmpty_of_false fun x => mem_Iio.not.mpr (Cardinal.zero_le x).not_lt
end Cardinal
| Mathlib/SetTheory/Cardinal/Basic.lean | 1,541 | 1,550 | |
/-
Copyright (c) 2020 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Floris van Doorn, Yury Kudryashov
-/
import Mathlib.Topology.Instances.NNReal.Lemmas
import Mathlib.Topology.Order.MonotoneContinuity
/-!
# Square root of a real number
In this file we define
* `NNReal.sqrt` to be the square root of a nonnegative real number.
* `Real.sqrt` to be the square root of a real number, defined to be zero on negative numbers.
Then we prove some basic properties of these functions.
## Implementation notes
We define `NNReal.sqrt` as the noncomputable inverse to the function `x ↦ x * x`. We use general
theory of inverses of strictly monotone functions to prove that `NNReal.sqrt x` exists. As a side
effect, `NNReal.sqrt` is a bundled `OrderIso`, so for `NNReal` numbers we get continuity as well as
theorems like `NNReal.sqrt x ≤ y ↔ x ≤ y * y` for free.
Then we define `Real.sqrt x` to be `NNReal.sqrt (Real.toNNReal x)`.
## Tags
square root
-/
open Set Filter
open scoped Filter NNReal Topology
namespace NNReal
variable {x y : ℝ≥0}
/-- Square root of a nonnegative real number. -/
-- Porting note (kmill): `pp_nodot` has no effect here
-- unless RFC https://github.com/leanprover/lean4/issues/6178 leads to dot notation pp for CoeFun
@[pp_nodot]
noncomputable def sqrt : ℝ≥0 ≃o ℝ≥0 :=
OrderIso.symm <| powOrderIso 2 two_ne_zero
@[simp] lemma sq_sqrt (x : ℝ≥0) : sqrt x ^ 2 = x := sqrt.symm_apply_apply _
@[simp] lemma sqrt_sq (x : ℝ≥0) : sqrt (x ^ 2) = x := sqrt.apply_symm_apply _
@[simp] lemma mul_self_sqrt (x : ℝ≥0) : sqrt x * sqrt x = x := by rw [← sq, sq_sqrt]
@[simp] lemma sqrt_mul_self (x : ℝ≥0) : sqrt (x * x) = x := by rw [← sq, sqrt_sq]
lemma sqrt_le_sqrt : sqrt x ≤ sqrt y ↔ x ≤ y := sqrt.le_iff_le
lemma sqrt_lt_sqrt : sqrt x < sqrt y ↔ x < y := sqrt.lt_iff_lt
lemma sqrt_eq_iff_eq_sq : sqrt x = y ↔ x = y ^ 2 := sqrt.toEquiv.apply_eq_iff_eq_symm_apply
lemma sqrt_le_iff_le_sq : sqrt x ≤ y ↔ x ≤ y ^ 2 := sqrt.to_galoisConnection _ _
lemma le_sqrt_iff_sq_le : x ≤ sqrt y ↔ x ^ 2 ≤ y := (sqrt.symm.to_galoisConnection _ _).symm
@[simp] lemma sqrt_eq_zero : sqrt x = 0 ↔ x = 0 := by simp [sqrt_eq_iff_eq_sq]
@[simp] lemma sqrt_eq_one : sqrt x = 1 ↔ x = 1 := by simp [sqrt_eq_iff_eq_sq]
@[simp] lemma sqrt_zero : sqrt 0 = 0 := by simp
@[simp] lemma sqrt_one : sqrt 1 = 1 := by simp
@[simp] lemma sqrt_le_one : sqrt x ≤ 1 ↔ x ≤ 1 := by rw [← sqrt_one, sqrt_le_sqrt, sqrt_one]
@[simp] lemma one_le_sqrt : 1 ≤ sqrt x ↔ 1 ≤ x := by rw [← sqrt_one, sqrt_le_sqrt, sqrt_one]
theorem sqrt_mul (x y : ℝ≥0) : sqrt (x * y) = sqrt x * sqrt y := by
rw [sqrt_eq_iff_eq_sq, mul_pow, sq_sqrt, sq_sqrt]
/-- `NNReal.sqrt` as a `MonoidWithZeroHom`. -/
noncomputable def sqrtHom : ℝ≥0 →*₀ ℝ≥0 :=
⟨⟨sqrt, sqrt_zero⟩, sqrt_one, sqrt_mul⟩
theorem sqrt_inv (x : ℝ≥0) : sqrt x⁻¹ = (sqrt x)⁻¹ :=
map_inv₀ sqrtHom x
theorem sqrt_div (x y : ℝ≥0) : sqrt (x / y) = sqrt x / sqrt y :=
map_div₀ sqrtHom x y
@[continuity, fun_prop]
theorem continuous_sqrt : Continuous sqrt := sqrt.continuous
@[simp] theorem sqrt_pos : 0 < sqrt x ↔ 0 < x := by simp [pos_iff_ne_zero]
alias ⟨_, sqrt_pos_of_pos⟩ := sqrt_pos
attribute [bound] sqrt_pos_of_pos
end NNReal
namespace Real
/-- The square root of a real number. This returns 0 for negative inputs.
This has notation `√x`. Note that `√x⁻¹` is parsed as `√(x⁻¹)`. -/
noncomputable def sqrt (x : ℝ) : ℝ :=
NNReal.sqrt (Real.toNNReal x)
-- TODO: replace this with a typeclass
@[inherit_doc]
prefix:max "√" => Real.sqrt
variable {x y : ℝ}
@[simp, norm_cast]
theorem coe_sqrt {x : ℝ≥0} : (NNReal.sqrt x : ℝ) = √(x : ℝ) := by
rw [Real.sqrt, Real.toNNReal_coe]
@[continuity]
theorem continuous_sqrt : Continuous (√· : ℝ → ℝ) :=
NNReal.continuous_coe.comp <| NNReal.continuous_sqrt.comp continuous_real_toNNReal
theorem sqrt_eq_zero_of_nonpos (h : x ≤ 0) : sqrt x = 0 := by simp [sqrt, Real.toNNReal_eq_zero.2 h]
@[simp] theorem sqrt_nonneg (x : ℝ) : 0 ≤ √x := NNReal.coe_nonneg _
@[simp]
theorem mul_self_sqrt (h : 0 ≤ x) : √x * √x = x := by
rw [Real.sqrt, ← NNReal.coe_mul, NNReal.mul_self_sqrt, Real.coe_toNNReal _ h]
@[simp]
theorem sqrt_mul_self (h : 0 ≤ x) : √(x * x) = x :=
(mul_self_inj_of_nonneg (sqrt_nonneg _) h).1 (mul_self_sqrt (mul_self_nonneg _))
theorem sqrt_eq_cases : √x = y ↔ y * y = x ∧ 0 ≤ y ∨ x < 0 ∧ y = 0 := by
constructor
· rintro rfl
rcases le_or_lt 0 x with hle | hlt
· exact Or.inl ⟨mul_self_sqrt hle, sqrt_nonneg x⟩
· exact Or.inr ⟨hlt, sqrt_eq_zero_of_nonpos hlt.le⟩
· rintro (⟨rfl, hy⟩ | ⟨hx, rfl⟩)
exacts [sqrt_mul_self hy, sqrt_eq_zero_of_nonpos hx.le]
theorem sqrt_eq_iff_mul_self_eq (hx : 0 ≤ x) (hy : 0 ≤ y) : √x = y ↔ x = y * y :=
⟨fun h => by rw [← h, mul_self_sqrt hx], fun h => by rw [h, sqrt_mul_self hy]⟩
theorem sqrt_eq_iff_mul_self_eq_of_pos (h : 0 < y) : √x = y ↔ y * y = x := by
simp [sqrt_eq_cases, h.ne', h.le]
@[simp]
theorem sqrt_eq_one : √x = 1 ↔ x = 1 :=
calc
√x = 1 ↔ 1 * 1 = x := sqrt_eq_iff_mul_self_eq_of_pos zero_lt_one
_ ↔ x = 1 := by rw [eq_comm, mul_one]
@[simp]
theorem sq_sqrt (h : 0 ≤ x) : √x ^ 2 = x := by rw [sq, mul_self_sqrt h]
@[simp]
theorem sqrt_sq (h : 0 ≤ x) : √(x ^ 2) = x := by rw [sq, sqrt_mul_self h]
theorem sqrt_eq_iff_eq_sq (hx : 0 ≤ x) (hy : 0 ≤ y) : √x = y ↔ x = y ^ 2 := by
rw [sq, sqrt_eq_iff_mul_self_eq hx hy]
theorem sqrt_mul_self_eq_abs (x : ℝ) : √(x * x) = |x| := by
rw [← abs_mul_abs_self x, sqrt_mul_self (abs_nonneg _)]
theorem sqrt_sq_eq_abs (x : ℝ) : √(x ^ 2) = |x| := by rw [sq, sqrt_mul_self_eq_abs]
@[simp]
theorem sqrt_zero : √0 = 0 := by simp [Real.sqrt]
@[simp]
theorem sqrt_one : √1 = 1 := by simp [Real.sqrt]
@[simp]
theorem sqrt_le_sqrt_iff (hy : 0 ≤ y) : √x ≤ √y ↔ x ≤ y := by
rw [Real.sqrt, Real.sqrt, NNReal.coe_le_coe, NNReal.sqrt_le_sqrt, toNNReal_le_toNNReal_iff hy]
@[simp]
theorem sqrt_lt_sqrt_iff (hx : 0 ≤ x) : √x < √y ↔ x < y :=
lt_iff_lt_of_le_iff_le (sqrt_le_sqrt_iff hx)
theorem sqrt_lt_sqrt_iff_of_pos (hy : 0 < y) : √x < √y ↔ x < y := by
rw [Real.sqrt, Real.sqrt, NNReal.coe_lt_coe, NNReal.sqrt_lt_sqrt, toNNReal_lt_toNNReal_iff hy]
@[gcongr, bound]
theorem sqrt_le_sqrt (h : x ≤ y) : √x ≤ √y := by
rw [Real.sqrt, Real.sqrt, NNReal.coe_le_coe, NNReal.sqrt_le_sqrt]
exact toNNReal_le_toNNReal h
@[gcongr, bound]
theorem sqrt_lt_sqrt (hx : 0 ≤ x) (h : x < y) : √x < √y :=
(sqrt_lt_sqrt_iff hx).2 h
theorem sqrt_le_left (hy : 0 ≤ y) : √x ≤ y ↔ x ≤ y ^ 2 := by
rw [sqrt, ← Real.le_toNNReal_iff_coe_le hy, NNReal.sqrt_le_iff_le_sq, sq, ← Real.toNNReal_mul hy,
Real.toNNReal_le_toNNReal_iff (mul_self_nonneg y), sq]
theorem sqrt_le_iff : √x ≤ y ↔ 0 ≤ y ∧ x ≤ y ^ 2 := by
rw [← and_iff_right_of_imp fun h => (sqrt_nonneg x).trans h, and_congr_right_iff]
exact sqrt_le_left
theorem sqrt_lt (hx : 0 ≤ x) (hy : 0 ≤ y) : √x < y ↔ x < y ^ 2 := by
rw [← sqrt_lt_sqrt_iff hx, sqrt_sq hy]
theorem sqrt_lt' (hy : 0 < y) : √x < y ↔ x < y ^ 2 := by
rw [← sqrt_lt_sqrt_iff_of_pos (pow_pos hy _), sqrt_sq hy.le]
/-- Note: if you want to conclude `x ≤ √y`, then use `Real.le_sqrt_of_sq_le`.
If you have `x > 0`, consider using `Real.le_sqrt'` -/
theorem le_sqrt (hx : 0 ≤ x) (hy : 0 ≤ y) : x ≤ √y ↔ x ^ 2 ≤ y :=
le_iff_le_iff_lt_iff_lt.2 <| sqrt_lt hy hx
theorem le_sqrt' (hx : 0 < x) : x ≤ √y ↔ x ^ 2 ≤ y :=
le_iff_le_iff_lt_iff_lt.2 <| sqrt_lt' hx
theorem abs_le_sqrt (h : x ^ 2 ≤ y) : |x| ≤ √y := by
rw [← sqrt_sq_eq_abs]; exact sqrt_le_sqrt h
theorem sq_le (h : 0 ≤ y) : x ^ 2 ≤ y ↔ -√y ≤ x ∧ x ≤ √y := by
constructor
· simpa only [abs_le] using abs_le_sqrt
· rw [← abs_le, ← sq_abs]
exact (le_sqrt (abs_nonneg x) h).mp
theorem neg_sqrt_le_of_sq_le (h : x ^ 2 ≤ y) : -√y ≤ x :=
((sq_le ((sq_nonneg x).trans h)).mp h).1
theorem le_sqrt_of_sq_le (h : x ^ 2 ≤ y) : x ≤ √y :=
((sq_le ((sq_nonneg x).trans h)).mp h).2
@[simp]
theorem sqrt_inj (hx : 0 ≤ x) (hy : 0 ≤ y) : √x = √y ↔ x = y := by
simp [le_antisymm_iff, hx, hy]
@[simp]
theorem sqrt_eq_zero (h : 0 ≤ x) : √x = 0 ↔ x = 0 := by simpa using sqrt_inj h le_rfl
theorem sqrt_eq_zero' : √x = 0 ↔ x ≤ 0 := by
rw [sqrt, NNReal.coe_eq_zero, NNReal.sqrt_eq_zero, Real.toNNReal_eq_zero]
theorem sqrt_ne_zero (h : 0 ≤ x) : √x ≠ 0 ↔ x ≠ 0 := by rw [not_iff_not, sqrt_eq_zero h]
theorem sqrt_ne_zero' : √x ≠ 0 ↔ 0 < x := by rw [← not_le, not_iff_not, sqrt_eq_zero']
@[simp]
theorem sqrt_pos : 0 < √x ↔ 0 < x :=
lt_iff_lt_of_le_iff_le (Iff.trans (by simp [le_antisymm_iff, sqrt_nonneg]) sqrt_eq_zero')
alias ⟨_, sqrt_pos_of_pos⟩ := sqrt_pos
lemma sqrt_le_sqrt_iff' (hx : 0 < x) : √x ≤ √y ↔ x ≤ y := by
obtain hy | hy := le_total y 0
· exact iff_of_false ((sqrt_eq_zero_of_nonpos hy).trans_lt <| sqrt_pos.2 hx).not_le
(hy.trans_lt hx).not_le
· exact sqrt_le_sqrt_iff hy
@[simp] lemma one_le_sqrt : 1 ≤ √x ↔ 1 ≤ x := by
rw [← sqrt_one, sqrt_le_sqrt_iff' zero_lt_one, sqrt_one]
@[simp] lemma sqrt_le_one : √x ≤ 1 ↔ x ≤ 1 := by
rw [← sqrt_one, sqrt_le_sqrt_iff zero_le_one, sqrt_one]
end Real
namespace Mathlib.Meta.Positivity
open Lean Meta Qq Function
/-- Extension for the `positivity` tactic: a square root of a strictly positive nonnegative real is
positive. -/
@[positivity NNReal.sqrt _]
def evalNNRealSqrt : PositivityExt where eval {u α} _zα _pα e := do
match u, α, e with
| 0, ~q(NNReal), ~q(NNReal.sqrt $a) =>
let ra ← core q(inferInstance) q(inferInstance) a
assertInstancesCommute
match ra with
| .positive pa => pure (.positive q(NNReal.sqrt_pos_of_pos $pa))
| _ => failure -- this case is dealt with by generic nonnegativity of nnreals
| _, _, _ => throwError "not NNReal.sqrt"
/-- Extension for the `positivity` tactic: a square root is nonnegative, and is strictly positive if
its input is. -/
@[positivity √_]
def evalSqrt : PositivityExt where eval {u α} _zα _pα e := do
match u, α, e with
| 0, ~q(ℝ), ~q(√$a) =>
let ra ← catchNone <| core q(inferInstance) q(inferInstance) a
assertInstancesCommute
match ra with
| .positive pa => pure (.positive q(Real.sqrt_pos_of_pos $pa))
| _ => pure (.nonnegative q(Real.sqrt_nonneg $a))
| _, _, _ => throwError "not Real.sqrt"
end Mathlib.Meta.Positivity
namespace Real
@[simp]
theorem sqrt_mul {x : ℝ} (hx : 0 ≤ x) (y : ℝ) : √(x * y) = √x * √y := by
simp_rw [Real.sqrt, ← NNReal.coe_mul, NNReal.coe_inj, Real.toNNReal_mul hx, NNReal.sqrt_mul]
@[simp]
theorem sqrt_mul' (x) {y : ℝ} (hy : 0 ≤ y) : √(x * y) = √x * √y := by
rw [mul_comm, sqrt_mul hy, mul_comm]
@[simp]
theorem sqrt_inv (x : ℝ) : √x⁻¹ = (√x)⁻¹ := by
rw [Real.sqrt, Real.toNNReal_inv, NNReal.sqrt_inv, NNReal.coe_inv, Real.sqrt]
@[simp]
theorem sqrt_div {x : ℝ} (hx : 0 ≤ x) (y : ℝ) : √(x / y) = √x / √y := by
rw [division_def, sqrt_mul hx, sqrt_inv, division_def]
@[simp]
theorem sqrt_div' (x) {y : ℝ} (hy : 0 ≤ y) : √(x / y) = √x / √y := by
rw [division_def, sqrt_mul' x (inv_nonneg.2 hy), sqrt_inv, division_def]
variable {x y : ℝ}
@[simp]
theorem div_sqrt : x / √x = √x := by
rcases le_or_lt x 0 with h | h
· rw [sqrt_eq_zero'.mpr h, div_zero]
· rw [div_eq_iff (sqrt_ne_zero'.mpr h), mul_self_sqrt h.le]
theorem sqrt_div_self' : √x / x = 1 / √x := by rw [← div_sqrt, one_div_div, div_sqrt]
theorem sqrt_div_self : √x / x = (√x)⁻¹ := by rw [sqrt_div_self', one_div]
theorem lt_sqrt (hx : 0 ≤ x) : x < √y ↔ x ^ 2 < y := by
rw [← sqrt_lt_sqrt_iff (sq_nonneg _), sqrt_sq hx]
|
theorem sq_lt : x ^ 2 < y ↔ -√y < x ∧ x < √y := by
| Mathlib/Data/Real/Sqrt.lean | 335 | 336 |
/-
Copyright (c) 2022 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov, Yaël Dillies
-/
import Mathlib.MeasureTheory.Integral.Bochner.ContinuousLinearMap
/-!
# Integral average of a function
In this file we define `MeasureTheory.average μ f` (notation: `⨍ x, f x ∂μ`) to be the average
value of `f` with respect to measure `μ`. It is defined as `∫ x, f x ∂((μ univ)⁻¹ • μ)`, so it
is equal to zero if `f` is not integrable or if `μ` is an infinite measure. If `μ` is a probability
measure, then the average of any function is equal to its integral.
For the average on a set, we use `⨍ x in s, f x ∂μ` (notation for `⨍ x, f x ∂(μ.restrict s)`). For
average w.r.t. the volume, one can omit `∂volume`.
Both have a version for the Lebesgue integral rather than Bochner.
We prove several version of the first moment method: An integrable function is below/above its
average on a set of positive measure:
* `measure_le_setLAverage_pos` for the Lebesgue integral
* `measure_le_setAverage_pos` for the Bochner integral
## Implementation notes
The average is defined as an integral over `(μ univ)⁻¹ • μ` so that all theorems about Bochner
integrals work for the average without modifications. For theorems that require integrability of a
function, we provide a convenience lemma `MeasureTheory.Integrable.to_average`.
## Tags
integral, center mass, average value
-/
open ENNReal MeasureTheory MeasureTheory.Measure Metric Set Filter TopologicalSpace Function
open scoped Topology ENNReal Convex
variable {α E F : Type*} {m0 : MeasurableSpace α} [NormedAddCommGroup E] [NormedSpace ℝ E]
[NormedAddCommGroup F] [NormedSpace ℝ F] [CompleteSpace F] {μ ν : Measure α}
{s t : Set α}
/-!
### Average value of a function w.r.t. a measure
The (Bochner, Lebesgue) average value of a function `f` w.r.t. a measure `μ` (notation:
`⨍ x, f x ∂μ`, `⨍⁻ x, f x ∂μ`) is defined as the (Bochner, Lebesgue) integral divided by the total
measure, so it is equal to zero if `μ` is an infinite measure, and (typically) equal to infinity if
`f` is not integrable. If `μ` is a probability measure, then the average of any function is equal to
its integral.
-/
namespace MeasureTheory
section ENNReal
variable (μ) {f g : α → ℝ≥0∞}
/-- Average value of an `ℝ≥0∞`-valued function `f` w.r.t. a measure `μ`, denoted `⨍⁻ x, f x ∂μ`.
It is equal to `(μ univ)⁻¹ * ∫⁻ x, f x ∂μ`, so it takes value zero if `μ` is an infinite measure. If
`μ` is a probability measure, then the average of any function is equal to its integral.
For the average on a set, use `⨍⁻ x in s, f x ∂μ`, defined as `⨍⁻ x, f x ∂(μ.restrict s)`. For the
average w.r.t. the volume, one can omit `∂volume`. -/
noncomputable def laverage (f : α → ℝ≥0∞) := ∫⁻ x, f x ∂(μ univ)⁻¹ • μ
/-- Average value of an `ℝ≥0∞`-valued function `f` w.r.t. a measure `μ`.
It is equal to `(μ univ)⁻¹ * ∫⁻ x, f x ∂μ`, so it takes value zero if `μ` is an infinite measure. If
`μ` is a probability measure, then the average of any function is equal to its integral.
For the average on a set, use `⨍⁻ x in s, f x ∂μ`, defined as `⨍⁻ x, f x ∂(μ.restrict s)`. For the
average w.r.t. the volume, one can omit `∂volume`. -/
notation3 "⨍⁻ "(...)", "r:60:(scoped f => f)" ∂"μ:70 => laverage μ r
/-- Average value of an `ℝ≥0∞`-valued function `f` w.r.t. to the standard measure.
It is equal to `(volume univ)⁻¹ * ∫⁻ x, f x`, so it takes value zero if the space has infinite
measure. In a probability space, the average of any function is equal to its integral.
For the average on a set, use `⨍⁻ x in s, f x`, defined as `⨍⁻ x, f x ∂(volume.restrict s)`. -/
notation3 "⨍⁻ "(...)", "r:60:(scoped f => laverage volume f) => r
/-- Average value of an `ℝ≥0∞`-valued function `f` w.r.t. a measure `μ` on a set `s`.
It is equal to `(μ s)⁻¹ * ∫⁻ x, f x ∂μ`, so it takes value zero if `s` has infinite measure. If `s`
has measure `1`, then the average of any function is equal to its integral.
For the average w.r.t. the volume, one can omit `∂volume`. -/
notation3 "⨍⁻ "(...)" in "s", "r:60:(scoped f => f)" ∂"μ:70 => laverage (Measure.restrict μ s) r
/-- Average value of an `ℝ≥0∞`-valued function `f` w.r.t. to the standard measure on a set `s`.
It is equal to `(volume s)⁻¹ * ∫⁻ x, f x`, so it takes value zero if `s` has infinite measure. If
`s` has measure `1`, then the average of any function is equal to its integral. -/
notation3 (prettyPrint := false)
"⨍⁻ "(...)" in "s", "r:60:(scoped f => laverage Measure.restrict volume s f) => r
@[simp]
theorem laverage_zero : ⨍⁻ _x, (0 : ℝ≥0∞) ∂μ = 0 := by rw [laverage, lintegral_zero]
@[simp]
theorem laverage_zero_measure (f : α → ℝ≥0∞) : ⨍⁻ x, f x ∂(0 : Measure α) = 0 := by simp [laverage]
theorem laverage_eq' (f : α → ℝ≥0∞) : ⨍⁻ x, f x ∂μ = ∫⁻ x, f x ∂(μ univ)⁻¹ • μ := rfl
theorem laverage_eq (f : α → ℝ≥0∞) : ⨍⁻ x, f x ∂μ = (∫⁻ x, f x ∂μ) / μ univ := by
rw [laverage_eq', lintegral_smul_measure, ENNReal.div_eq_inv_mul, smul_eq_mul]
theorem laverage_eq_lintegral [IsProbabilityMeasure μ] (f : α → ℝ≥0∞) :
⨍⁻ x, f x ∂μ = ∫⁻ x, f x ∂μ := by rw [laverage, measure_univ, inv_one, one_smul]
@[simp]
theorem measure_mul_laverage [IsFiniteMeasure μ] (f : α → ℝ≥0∞) :
μ univ * ⨍⁻ x, f x ∂μ = ∫⁻ x, f x ∂μ := by
rcases eq_or_ne μ 0 with hμ | hμ
· rw [hμ, lintegral_zero_measure, laverage_zero_measure, mul_zero]
· rw [laverage_eq, ENNReal.mul_div_cancel (measure_univ_ne_zero.2 hμ) (measure_ne_top _ _)]
theorem setLAverage_eq (f : α → ℝ≥0∞) (s : Set α) :
⨍⁻ x in s, f x ∂μ = (∫⁻ x in s, f x ∂μ) / μ s := by rw [laverage_eq, restrict_apply_univ]
@[deprecated (since := "2025-04-22")] alias setLaverage_eq := setLAverage_eq
theorem setLAverage_eq' (f : α → ℝ≥0∞) (s : Set α) :
⨍⁻ x in s, f x ∂μ = ∫⁻ x, f x ∂(μ s)⁻¹ • μ.restrict s := by
simp only [laverage_eq', restrict_apply_univ]
@[deprecated (since := "2025-04-22")] alias setLaverage_eq' := setLAverage_eq'
variable {μ}
theorem laverage_congr {f g : α → ℝ≥0∞} (h : f =ᵐ[μ] g) : ⨍⁻ x, f x ∂μ = ⨍⁻ x, g x ∂μ := by
simp only [laverage_eq, lintegral_congr_ae h]
theorem setLAverage_congr (h : s =ᵐ[μ] t) : ⨍⁻ x in s, f x ∂μ = ⨍⁻ x in t, f x ∂μ := by
simp only [setLAverage_eq, setLIntegral_congr h, measure_congr h]
@[deprecated (since := "2025-04-22")] alias setLaverage_congr := setLAverage_congr
theorem setLAverage_congr_fun (hs : MeasurableSet s) (h : ∀ᵐ x ∂μ, x ∈ s → f x = g x) :
⨍⁻ x in s, f x ∂μ = ⨍⁻ x in s, g x ∂μ := by
simp only [laverage_eq, setLIntegral_congr_fun hs h]
@[deprecated (since := "2025-04-22")] alias setLaverage_congr_fun := setLAverage_congr_fun
theorem laverage_lt_top (hf : ∫⁻ x, f x ∂μ ≠ ∞) : ⨍⁻ x, f x ∂μ < ∞ := by
obtain rfl | hμ := eq_or_ne μ 0
· simp
· rw [laverage_eq]
exact div_lt_top hf (measure_univ_ne_zero.2 hμ)
theorem setLAverage_lt_top : ∫⁻ x in s, f x ∂μ ≠ ∞ → ⨍⁻ x in s, f x ∂μ < ∞ :=
laverage_lt_top
@[deprecated (since := "2025-04-22")] alias setLaverage_lt_top := setLAverage_lt_top
theorem laverage_add_measure :
⨍⁻ x, f x ∂(μ + ν) =
μ univ / (μ univ + ν univ) * ⨍⁻ x, f x ∂μ + ν univ / (μ univ + ν univ) * ⨍⁻ x, f x ∂ν := by
by_cases hμ : IsFiniteMeasure μ; swap
· rw [not_isFiniteMeasure_iff] at hμ
simp [laverage_eq, hμ]
by_cases hν : IsFiniteMeasure ν; swap
· rw [not_isFiniteMeasure_iff] at hν
simp [laverage_eq, hν]
haveI := hμ; haveI := hν
simp only [← ENNReal.mul_div_right_comm, measure_mul_laverage, ← ENNReal.add_div,
← lintegral_add_measure, ← Measure.add_apply, ← laverage_eq]
theorem measure_mul_setLAverage (f : α → ℝ≥0∞) (h : μ s ≠ ∞) :
μ s * ⨍⁻ x in s, f x ∂μ = ∫⁻ x in s, f x ∂μ := by
have := Fact.mk h.lt_top
rw [← measure_mul_laverage, restrict_apply_univ]
@[deprecated (since := "2025-04-22")] alias measure_mul_setLaverage := measure_mul_setLAverage
theorem laverage_union (hd : AEDisjoint μ s t) (ht : NullMeasurableSet t μ) :
⨍⁻ x in s ∪ t, f x ∂μ =
μ s / (μ s + μ t) * ⨍⁻ x in s, f x ∂μ + μ t / (μ s + μ t) * ⨍⁻ x in t, f x ∂μ := by
rw [restrict_union₀ hd ht, laverage_add_measure, restrict_apply_univ, restrict_apply_univ]
theorem laverage_union_mem_openSegment (hd : AEDisjoint μ s t) (ht : NullMeasurableSet t μ)
(hs₀ : μ s ≠ 0) (ht₀ : μ t ≠ 0) (hsμ : μ s ≠ ∞) (htμ : μ t ≠ ∞) :
⨍⁻ x in s ∪ t, f x ∂μ ∈ openSegment ℝ≥0∞ (⨍⁻ x in s, f x ∂μ) (⨍⁻ x in t, f x ∂μ) := by
refine
⟨μ s / (μ s + μ t), μ t / (μ s + μ t), ENNReal.div_pos hs₀ <| add_ne_top.2 ⟨hsμ, htμ⟩,
ENNReal.div_pos ht₀ <| add_ne_top.2 ⟨hsμ, htμ⟩, ?_, (laverage_union hd ht).symm⟩
rw [← ENNReal.add_div,
ENNReal.div_self (add_eq_zero.not.2 fun h => hs₀ h.1) (add_ne_top.2 ⟨hsμ, htμ⟩)]
theorem laverage_union_mem_segment (hd : AEDisjoint μ s t) (ht : NullMeasurableSet t μ)
(hsμ : μ s ≠ ∞) (htμ : μ t ≠ ∞) :
⨍⁻ x in s ∪ t, f x ∂μ ∈ [⨍⁻ x in s, f x ∂μ -[ℝ≥0∞] ⨍⁻ x in t, f x ∂μ] := by
by_cases hs₀ : μ s = 0
· rw [← ae_eq_empty] at hs₀
rw [restrict_congr_set (hs₀.union EventuallyEq.rfl), empty_union]
exact right_mem_segment _ _ _
· refine
⟨μ s / (μ s + μ t), μ t / (μ s + μ t), zero_le _, zero_le _, ?_, (laverage_union hd ht).symm⟩
rw [← ENNReal.add_div,
ENNReal.div_self (add_eq_zero.not.2 fun h => hs₀ h.1) (add_ne_top.2 ⟨hsμ, htμ⟩)]
theorem laverage_mem_openSegment_compl_self [IsFiniteMeasure μ] (hs : NullMeasurableSet s μ)
(hs₀ : μ s ≠ 0) (hsc₀ : μ sᶜ ≠ 0) :
⨍⁻ x, f x ∂μ ∈ openSegment ℝ≥0∞ (⨍⁻ x in s, f x ∂μ) (⨍⁻ x in sᶜ, f x ∂μ) := by
simpa only [union_compl_self, restrict_univ] using
laverage_union_mem_openSegment aedisjoint_compl_right hs.compl hs₀ hsc₀ (measure_ne_top _ _)
(measure_ne_top _ _)
@[simp]
theorem laverage_const (μ : Measure α) [IsFiniteMeasure μ] [h : NeZero μ] (c : ℝ≥0∞) :
⨍⁻ _x, c ∂μ = c := by
simp only [laverage, lintegral_const, measure_univ, mul_one]
theorem setLAverage_const (hs₀ : μ s ≠ 0) (hs : μ s ≠ ∞) (c : ℝ≥0∞) : ⨍⁻ _x in s, c ∂μ = c := by
simp only [setLAverage_eq, lintegral_const, Measure.restrict_apply, MeasurableSet.univ,
univ_inter, div_eq_mul_inv, mul_assoc, ENNReal.mul_inv_cancel hs₀ hs, mul_one]
@[deprecated (since := "2025-04-22")] alias setLaverage_const := setLAverage_const
theorem laverage_one [IsFiniteMeasure μ] [NeZero μ] : ⨍⁻ _x, (1 : ℝ≥0∞) ∂μ = 1 :=
laverage_const _ _
theorem setLAverage_one (hs₀ : μ s ≠ 0) (hs : μ s ≠ ∞) : ⨍⁻ _x in s, (1 : ℝ≥0∞) ∂μ = 1 :=
setLAverage_const hs₀ hs _
@[deprecated (since := "2025-04-22")] alias setLaverage_one := setLAverage_one
@[simp]
theorem laverage_mul_measure_univ (μ : Measure α) [IsFiniteMeasure μ] (f : α → ℝ≥0∞) :
(⨍⁻ (a : α), f a ∂μ) * μ univ = ∫⁻ x, f x ∂μ := by
obtain rfl | hμ := eq_or_ne μ 0
· simp
· rw [laverage_eq, ENNReal.div_mul_cancel (measure_univ_ne_zero.2 hμ) (measure_ne_top _ _)]
theorem lintegral_laverage (μ : Measure α) [IsFiniteMeasure μ] (f : α → ℝ≥0∞) :
∫⁻ _x, ⨍⁻ a, f a ∂μ ∂μ = ∫⁻ x, f x ∂μ := by
simp
theorem setLIntegral_setLAverage (μ : Measure α) [IsFiniteMeasure μ] (f : α → ℝ≥0∞) (s : Set α) :
∫⁻ _x in s, ⨍⁻ a in s, f a ∂μ ∂μ = ∫⁻ x in s, f x ∂μ :=
lintegral_laverage _ _
@[deprecated (since := "2025-04-22")] alias setLintegral_setLaverage := setLIntegral_setLAverage
end ENNReal
section NormedAddCommGroup
variable (μ)
variable {f g : α → E}
/-- Average value of a function `f` w.r.t. a measure `μ`, denoted `⨍ x, f x ∂μ`.
It is equal to `(μ.real univ)⁻¹ • ∫ x, f x ∂μ`, so it takes value zero if `f` is not integrable or
if `μ` is an infinite measure. If `μ` is a probability measure, then the average of any function is
equal to its integral.
For the average on a set, use `⨍ x in s, f x ∂μ`, defined as `⨍ x, f x ∂(μ.restrict s)`. For the
average w.r.t. the volume, one can omit `∂volume`. -/
noncomputable def average (f : α → E) :=
∫ x, f x ∂(μ univ)⁻¹ • μ
/-- Average value of a function `f` w.r.t. a measure `μ`.
It is equal to `(μ.real univ)⁻¹ • ∫ x, f x ∂μ`, so it takes value zero if `f` is not integrable or
if `μ` is an infinite measure. If `μ` is a probability measure, then the average of any function is
equal to its integral.
For the average on a set, use `⨍ x in s, f x ∂μ`, defined as `⨍ x, f x ∂(μ.restrict s)`. For the
average w.r.t. the volume, one can omit `∂volume`. -/
notation3 "⨍ "(...)", "r:60:(scoped f => f)" ∂"μ:70 => average μ r
/-- Average value of a function `f` w.r.t. to the standard measure.
It is equal to `(volume.real univ)⁻¹ * ∫ x, f x`, so it takes value zero if `f` is not integrable
or if the space has infinite measure. In a probability space, the average of any function is equal
to its integral.
For the average on a set, use `⨍ x in s, f x`, defined as `⨍ x, f x ∂(volume.restrict s)`. -/
notation3 "⨍ "(...)", "r:60:(scoped f => average volume f) => r
/-- Average value of a function `f` w.r.t. a measure `μ` on a set `s`.
It is equal to `(μ.real s)⁻¹ * ∫ x, f x ∂μ`, so it takes value zero if `f` is not integrable on
`s` or if `s` has infinite measure. If `s` has measure `1`, then the average of any function is
equal to its integral.
For the average w.r.t. the volume, one can omit `∂volume`. -/
notation3 "⨍ "(...)" in "s", "r:60:(scoped f => f)" ∂"μ:70 => average (Measure.restrict μ s) r
/-- Average value of a function `f` w.r.t. to the standard measure on a set `s`.
It is equal to `(volume.real s)⁻¹ * ∫ x, f x`, so it takes value zero `f` is not integrable on `s`
or if `s` has infinite measure. If `s` has measure `1`, then the average of any function is equal to
its integral. -/
notation3 "⨍ "(...)" in "s", "r:60:(scoped f => average (Measure.restrict volume s) f) => r
@[simp]
theorem average_zero : ⨍ _, (0 : E) ∂μ = 0 := by rw [average, integral_zero]
@[simp]
theorem average_zero_measure (f : α → E) : ⨍ x, f x ∂(0 : Measure α) = 0 := by
rw [average, smul_zero, integral_zero_measure]
@[simp]
theorem average_neg (f : α → E) : ⨍ x, -f x ∂μ = -⨍ x, f x ∂μ :=
integral_neg f
theorem average_eq' (f : α → E) : ⨍ x, f x ∂μ = ∫ x, f x ∂(μ univ)⁻¹ • μ :=
rfl
theorem average_eq (f : α → E) : ⨍ x, f x ∂μ = (μ.real univ)⁻¹ • ∫ x, f x ∂μ := by
rw [average_eq', integral_smul_measure, ENNReal.toReal_inv, measureReal_def]
theorem average_eq_integral [IsProbabilityMeasure μ] (f : α → E) : ⨍ x, f x ∂μ = ∫ x, f x ∂μ := by
rw [average, measure_univ, inv_one, one_smul]
@[simp]
theorem measure_smul_average [IsFiniteMeasure μ] (f : α → E) :
μ.real univ • ⨍ x, f x ∂μ = ∫ x, f x ∂μ := by
rcases eq_or_ne μ 0 with hμ | hμ
· rw [hμ, integral_zero_measure, average_zero_measure, smul_zero]
· rw [average_eq, smul_inv_smul₀]
refine (ENNReal.toReal_pos ?_ <| measure_ne_top _ _).ne'
rwa [Ne, measure_univ_eq_zero]
theorem setAverage_eq (f : α → E) (s : Set α) :
⨍ x in s, f x ∂μ = (μ.real s)⁻¹ • ∫ x in s, f x ∂μ := by
rw [average_eq, measureReal_restrict_apply_univ]
theorem setAverage_eq' (f : α → E) (s : Set α) :
⨍ x in s, f x ∂μ = ∫ x, f x ∂(μ s)⁻¹ • μ.restrict s := by
simp only [average_eq', restrict_apply_univ]
variable {μ}
theorem average_congr {f g : α → E} (h : f =ᵐ[μ] g) : ⨍ x, f x ∂μ = ⨍ x, g x ∂μ := by
simp only [average_eq, integral_congr_ae h]
theorem setAverage_congr (h : s =ᵐ[μ] t) : ⨍ x in s, f x ∂μ = ⨍ x in t, f x ∂μ := by
simp only [setAverage_eq, setIntegral_congr_set h, measureReal_congr h]
theorem setAverage_congr_fun (hs : MeasurableSet s) (h : ∀ᵐ x ∂μ, x ∈ s → f x = g x) :
⨍ x in s, f x ∂μ = ⨍ x in s, g x ∂μ := by simp only [average_eq, setIntegral_congr_ae hs h]
theorem average_add_measure [IsFiniteMeasure μ] {ν : Measure α} [IsFiniteMeasure ν] {f : α → E}
(hμ : Integrable f μ) (hν : Integrable f ν) :
⨍ x, f x ∂(μ + ν) =
(μ.real univ / (μ.real univ + ν.real univ)) • ⨍ x, f x ∂μ +
(ν.real univ / (μ.real univ + ν.real univ)) • ⨍ x, f x ∂ν := by
simp only [div_eq_inv_mul, mul_smul, measure_smul_average, ← smul_add,
← integral_add_measure hμ hν, ← ENNReal.toReal_add (measure_ne_top μ _) (measure_ne_top ν _)]
rw [average_eq, measureReal_add_apply]
theorem average_pair [CompleteSpace E]
{f : α → E} {g : α → F} (hfi : Integrable f μ) (hgi : Integrable g μ) :
⨍ x, (f x, g x) ∂μ = (⨍ x, f x ∂μ, ⨍ x, g x ∂μ) :=
integral_pair hfi.to_average hgi.to_average
theorem measure_smul_setAverage (f : α → E) {s : Set α} (h : μ s ≠ ∞) :
μ.real s • ⨍ x in s, f x ∂μ = ∫ x in s, f x ∂μ := by
haveI := Fact.mk h.lt_top
rw [← measure_smul_average, measureReal_restrict_apply_univ]
theorem average_union {f : α → E} {s t : Set α} (hd : AEDisjoint μ s t) (ht : NullMeasurableSet t μ)
(hsμ : μ s ≠ ∞) (htμ : μ t ≠ ∞) (hfs : IntegrableOn f s μ) (hft : IntegrableOn f t μ) :
⨍ x in s ∪ t, f x ∂μ =
(μ.real s / (μ.real s + μ.real t)) • ⨍ x in s, f x ∂μ +
(μ.real t / (μ.real s + μ.real t)) • ⨍ x in t, f x ∂μ := by
haveI := Fact.mk hsμ.lt_top; haveI := Fact.mk htμ.lt_top
rw [restrict_union₀ hd ht, average_add_measure hfs hft, measureReal_restrict_apply_univ,
measureReal_restrict_apply_univ]
theorem average_union_mem_openSegment {f : α → E} {s t : Set α} (hd : AEDisjoint μ s t)
(ht : NullMeasurableSet t μ) (hs₀ : μ s ≠ 0) (ht₀ : μ t ≠ 0) (hsμ : μ s ≠ ∞) (htμ : μ t ≠ ∞)
(hfs : IntegrableOn f s μ) (hft : IntegrableOn f t μ) :
⨍ x in s ∪ t, f x ∂μ ∈ openSegment ℝ (⨍ x in s, f x ∂μ) (⨍ x in t, f x ∂μ) := by
replace hs₀ : 0 < μ.real s := ENNReal.toReal_pos hs₀ hsμ
replace ht₀ : 0 < μ.real t := ENNReal.toReal_pos ht₀ htμ
exact mem_openSegment_iff_div.mpr
⟨μ.real s, μ.real t, hs₀, ht₀, (average_union hd ht hsμ htμ hfs hft).symm⟩
theorem average_union_mem_segment {f : α → E} {s t : Set α} (hd : AEDisjoint μ s t)
(ht : NullMeasurableSet t μ) (hsμ : μ s ≠ ∞) (htμ : μ t ≠ ∞) (hfs : IntegrableOn f s μ)
(hft : IntegrableOn f t μ) :
⨍ x in s ∪ t, f x ∂μ ∈ [⨍ x in s, f x ∂μ -[ℝ] ⨍ x in t, f x ∂μ] := by
by_cases hse : μ s = 0
· rw [← ae_eq_empty] at hse
rw [restrict_congr_set (hse.union EventuallyEq.rfl), empty_union]
exact right_mem_segment _ _ _
· refine
mem_segment_iff_div.mpr
⟨μ.real s, μ.real t, ENNReal.toReal_nonneg, ENNReal.toReal_nonneg, ?_,
(average_union hd ht hsμ htμ hfs hft).symm⟩
calc
0 < μ.real s := ENNReal.toReal_pos hse hsμ
_ ≤ _ := le_add_of_nonneg_right ENNReal.toReal_nonneg
theorem average_mem_openSegment_compl_self [IsFiniteMeasure μ] {f : α → E} {s : Set α}
(hs : NullMeasurableSet s μ) (hs₀ : μ s ≠ 0) (hsc₀ : μ sᶜ ≠ 0) (hfi : Integrable f μ) :
⨍ x, f x ∂μ ∈ openSegment ℝ (⨍ x in s, f x ∂μ) (⨍ x in sᶜ, f x ∂μ) := by
simpa only [union_compl_self, restrict_univ] using
average_union_mem_openSegment aedisjoint_compl_right hs.compl hs₀ hsc₀ (measure_ne_top _ _)
(measure_ne_top _ _) hfi.integrableOn hfi.integrableOn
variable [CompleteSpace E]
@[simp]
theorem average_const (μ : Measure α) [IsFiniteMeasure μ] [h : NeZero μ] (c : E) :
⨍ _x, c ∂μ = c := by
rw [average, integral_const, measureReal_def, measure_univ, ENNReal.toReal_one, one_smul]
theorem setAverage_const {s : Set α} (hs₀ : μ s ≠ 0) (hs : μ s ≠ ∞) (c : E) :
⨍ _ in s, c ∂μ = c :=
have := NeZero.mk hs₀; have := Fact.mk hs.lt_top; average_const _ _
theorem integral_average (μ : Measure α) [IsFiniteMeasure μ] (f : α → E) :
∫ _, ⨍ a, f a ∂μ ∂μ = ∫ x, f x ∂μ := by simp
theorem setIntegral_setAverage (μ : Measure α) [IsFiniteMeasure μ] (f : α → E) (s : Set α) :
∫ _ in s, ⨍ a in s, f a ∂μ ∂μ = ∫ x in s, f x ∂μ :=
integral_average _ _
theorem integral_sub_average (μ : Measure α) [IsFiniteMeasure μ] (f : α → E) :
∫ x, f x - ⨍ a, f a ∂μ ∂μ = 0 := by
by_cases hf : Integrable f μ
· rw [integral_sub hf (integrable_const _), integral_average, sub_self]
refine integral_undef fun h => hf ?_
convert h.add (integrable_const (⨍ a, f a ∂μ))
exact (sub_add_cancel _ _).symm
theorem setAverage_sub_setAverage (hs : μ s ≠ ∞) (f : α → E) :
∫ x in s, f x - ⨍ a in s, f a ∂μ ∂μ = 0 :=
haveI : Fact (μ s < ∞) := ⟨lt_top_iff_ne_top.2 hs⟩
integral_sub_average _ _
theorem integral_average_sub [IsFiniteMeasure μ] (hf : Integrable f μ) :
∫ x, ⨍ a, f a ∂μ - f x ∂μ = 0 := by
rw [integral_sub (integrable_const _) hf, integral_average, sub_self]
theorem setIntegral_setAverage_sub (hs : μ s ≠ ∞) (hf : IntegrableOn f s μ) :
∫ x in s, ⨍ a in s, f a ∂μ - f x ∂μ = 0 :=
haveI : Fact (μ s < ∞) := ⟨lt_top_iff_ne_top.2 hs⟩
integral_average_sub hf
end NormedAddCommGroup
theorem ofReal_average {f : α → ℝ} (hf : Integrable f μ) (hf₀ : 0 ≤ᵐ[μ] f) :
ENNReal.ofReal (⨍ x, f x ∂μ) = (∫⁻ x, ENNReal.ofReal (f x) ∂μ) / μ univ := by
obtain rfl | hμ := eq_or_ne μ 0
· simp
· rw [average_eq, smul_eq_mul, measureReal_def, ← toReal_inv, ofReal_mul toReal_nonneg,
ofReal_toReal (inv_ne_top.2 <| measure_univ_ne_zero.2 hμ),
ofReal_integral_eq_lintegral_ofReal hf hf₀, ENNReal.div_eq_inv_mul]
theorem ofReal_setAverage {f : α → ℝ} (hf : IntegrableOn f s μ) (hf₀ : 0 ≤ᵐ[μ.restrict s] f) :
ENNReal.ofReal (⨍ x in s, f x ∂μ) = (∫⁻ x in s, ENNReal.ofReal (f x) ∂μ) / μ s := by
simpa using ofReal_average hf hf₀
theorem toReal_laverage {f : α → ℝ≥0∞} (hf : AEMeasurable f μ) (hf' : ∀ᵐ x ∂μ, f x ≠ ∞) :
(⨍⁻ x, f x ∂μ).toReal = ⨍ x, (f x).toReal ∂μ := by
rw [average_eq, laverage_eq, smul_eq_mul, toReal_div, div_eq_inv_mul, ←
integral_toReal hf (hf'.mono fun _ => lt_top_iff_ne_top.2), measureReal_def]
theorem toReal_setLAverage {f : α → ℝ≥0∞} (hf : AEMeasurable f (μ.restrict s))
(hf' : ∀ᵐ x ∂μ.restrict s, f x ≠ ∞) :
(⨍⁻ x in s, f x ∂μ).toReal = ⨍ x in s, (f x).toReal ∂μ := by
simpa [laverage_eq] using toReal_laverage hf hf'
@[deprecated (since := "2025-04-22")] alias toReal_setLaverage := toReal_setLAverage
/-! ### First moment method -/
section FirstMomentReal
variable {N : Set α} {f : α → ℝ}
/-- **First moment method**. An integrable function is smaller than its mean on a set of positive
measure. -/
theorem measure_le_setAverage_pos (hμ : μ s ≠ 0) (hμ₁ : μ s ≠ ∞) (hf : IntegrableOn f s μ) :
0 < μ ({x ∈ s | f x ≤ ⨍ a in s, f a ∂μ}) := by
refine pos_iff_ne_zero.2 fun H => ?_
replace H : (μ.restrict s) {x | f x ≤ ⨍ a in s, f a ∂μ} = 0 := by
rwa [restrict_apply₀, inter_comm]
exact AEStronglyMeasurable.nullMeasurableSet_le hf.1 aestronglyMeasurable_const
haveI := Fact.mk hμ₁.lt_top
refine (integral_sub_average (μ.restrict s) f).not_gt ?_
refine (setIntegral_pos_iff_support_of_nonneg_ae ?_ ?_).2 ?_
· refine measure_mono_null (fun x hx ↦ ?_) H
simp only [Pi.zero_apply, sub_nonneg, mem_compl_iff, mem_setOf_eq, not_le] at hx
exact hx.le
· exact hf.sub (integrableOn_const.2 <| Or.inr <| lt_top_iff_ne_top.2 hμ₁)
· rwa [pos_iff_ne_zero, inter_comm, ← diff_compl, ← diff_inter_self_eq_diff, measure_diff_null]
refine measure_mono_null ?_ (measure_inter_eq_zero_of_restrict H)
exact inter_subset_inter_left _ fun a ha => (sub_eq_zero.1 <| of_not_not ha).le
/-- **First moment method**. An integrable function is greater than its mean on a set of positive
measure. -/
theorem measure_setAverage_le_pos (hμ : μ s ≠ 0) (hμ₁ : μ s ≠ ∞) (hf : IntegrableOn f s μ) :
0 < μ ({x ∈ s | ⨍ a in s, f a ∂μ ≤ f x}) := by
simpa [integral_neg, neg_div] using measure_le_setAverage_pos hμ hμ₁ hf.neg
/-- **First moment method**. The minimum of an integrable function is smaller than its mean. -/
theorem exists_le_setAverage (hμ : μ s ≠ 0) (hμ₁ : μ s ≠ ∞) (hf : IntegrableOn f s μ) :
∃ x ∈ s, f x ≤ ⨍ a in s, f a ∂μ :=
let ⟨x, hx, h⟩ := nonempty_of_measure_ne_zero (measure_le_setAverage_pos hμ hμ₁ hf).ne'
⟨x, hx, h⟩
/-- **First moment method**. The maximum of an integrable function is greater than its mean. -/
theorem exists_setAverage_le (hμ : μ s ≠ 0) (hμ₁ : μ s ≠ ∞) (hf : IntegrableOn f s μ) :
∃ x ∈ s, ⨍ a in s, f a ∂μ ≤ f x :=
let ⟨x, hx, h⟩ := nonempty_of_measure_ne_zero (measure_setAverage_le_pos hμ hμ₁ hf).ne'
⟨x, hx, h⟩
section FiniteMeasure
| variable [IsFiniteMeasure μ]
/-- **First moment method**. An integrable function is smaller than its mean on a set of positive
measure. -/
theorem measure_le_average_pos (hμ : μ ≠ 0) (hf : Integrable f μ) :
0 < μ {x | f x ≤ ⨍ a, f a ∂μ} := by
simpa using measure_le_setAverage_pos (Measure.measure_univ_ne_zero.2 hμ) (measure_ne_top _ _)
hf.integrableOn
/-- **First moment method**. An integrable function is greater than its mean on a set of positive
measure. -/
theorem measure_average_le_pos (hμ : μ ≠ 0) (hf : Integrable f μ) :
0 < μ {x | ⨍ a, f a ∂μ ≤ f x} := by
simpa using measure_setAverage_le_pos (Measure.measure_univ_ne_zero.2 hμ) (measure_ne_top _ _)
hf.integrableOn
| Mathlib/MeasureTheory/Integral/Average.lean | 520 | 535 |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Abhimanyu Pallavi Sudhir
-/
import Mathlib.Algebra.CharP.Defs
import Mathlib.Algebra.Order.CauSeq.BigOperators
import Mathlib.Algebra.Order.Star.Basic
import Mathlib.Data.Complex.BigOperators
import Mathlib.Data.Complex.Norm
import Mathlib.Data.Nat.Choose.Sum
/-!
# Exponential Function
This file contains the definitions of the real and complex exponential function.
## Main definitions
* `Complex.exp`: The complex exponential function, defined via its Taylor series
* `Real.exp`: The real exponential function, defined as the real part of the complex exponential
-/
open CauSeq Finset IsAbsoluteValue
open scoped ComplexConjugate
namespace Complex
theorem isCauSeq_norm_exp (z : ℂ) :
IsCauSeq abs fun n => ∑ m ∈ range n, ‖z ^ m / m.factorial‖ :=
let ⟨n, hn⟩ := exists_nat_gt ‖z‖
have hn0 : (0 : ℝ) < n := lt_of_le_of_lt (norm_nonneg _) hn
IsCauSeq.series_ratio_test n (‖z‖ / n) (div_nonneg (norm_nonneg _) (le_of_lt hn0))
(by rwa [div_lt_iff₀ hn0, one_mul]) fun m hm => by
rw [abs_norm, abs_norm, Nat.factorial_succ, pow_succ', mul_comm m.succ, Nat.cast_mul,
← div_div, mul_div_assoc, mul_div_right_comm, Complex.norm_mul, Complex.norm_div,
norm_natCast]
gcongr
exact le_trans hm (Nat.le_succ _)
@[deprecated (since := "2025-02-16")] alias isCauSeq_abs_exp := isCauSeq_norm_exp
noncomputable section
theorem isCauSeq_exp (z : ℂ) : IsCauSeq (‖·‖) fun n => ∑ m ∈ range n, z ^ m / m.factorial :=
(isCauSeq_norm_exp z).of_abv
/-- The Cauchy sequence consisting of partial sums of the Taylor series of
the complex exponential function -/
@[pp_nodot]
def exp' (z : ℂ) : CauSeq ℂ (‖·‖) :=
⟨fun n => ∑ m ∈ range n, z ^ m / m.factorial, isCauSeq_exp z⟩
/-- The complex exponential function, defined via its Taylor series -/
@[pp_nodot]
def exp (z : ℂ) : ℂ :=
CauSeq.lim (exp' z)
/-- scoped notation for the complex exponential function -/
scoped notation "cexp" => Complex.exp
end
end Complex
namespace Real
open Complex
noncomputable section
/-- The real exponential function, defined as the real part of the complex exponential -/
@[pp_nodot]
nonrec def exp (x : ℝ) : ℝ :=
(exp x).re
/-- scoped notation for the real exponential function -/
scoped notation "rexp" => Real.exp
end
end Real
namespace Complex
variable (x y : ℂ)
@[simp]
theorem exp_zero : exp 0 = 1 := by
rw [exp]
refine lim_eq_of_equiv_const fun ε ε0 => ⟨1, fun j hj => ?_⟩
convert (config := .unfoldSameFun) ε0 -- ε0 : ε > 0 but goal is _ < ε
rcases j with - | j
· exact absurd hj (not_le_of_gt zero_lt_one)
· dsimp [exp']
induction' j with j ih
· dsimp [exp']; simp [show Nat.succ 0 = 1 from rfl]
· rw [← ih (by simp [Nat.succ_le_succ])]
simp only [sum_range_succ, pow_succ]
simp
theorem exp_add : exp (x + y) = exp x * exp y := by
have hj : ∀ j : ℕ, (∑ m ∈ range j, (x + y) ^ m / m.factorial) =
∑ i ∈ range j, ∑ k ∈ range (i + 1), x ^ k / k.factorial *
(y ^ (i - k) / (i - k).factorial) := by
intro j
refine Finset.sum_congr rfl fun m _ => ?_
rw [add_pow, div_eq_mul_inv, sum_mul]
refine Finset.sum_congr rfl fun I hi => ?_
have h₁ : (m.choose I : ℂ) ≠ 0 :=
Nat.cast_ne_zero.2 (pos_iff_ne_zero.1 (Nat.choose_pos (Nat.le_of_lt_succ (mem_range.1 hi))))
have h₂ := Nat.choose_mul_factorial_mul_factorial (Nat.le_of_lt_succ <| Finset.mem_range.1 hi)
rw [← h₂, Nat.cast_mul, Nat.cast_mul, mul_inv, mul_inv]
simp only [mul_left_comm (m.choose I : ℂ), mul_assoc, mul_left_comm (m.choose I : ℂ)⁻¹,
mul_comm (m.choose I : ℂ)]
rw [inv_mul_cancel₀ h₁]
simp [div_eq_mul_inv, mul_comm, mul_assoc, mul_left_comm]
simp_rw [exp, exp', lim_mul_lim]
apply (lim_eq_lim_of_equiv _).symm
simp only [hj]
exact cauchy_product (isCauSeq_norm_exp x) (isCauSeq_exp y)
/-- the exponential function as a monoid hom from `Multiplicative ℂ` to `ℂ` -/
@[simps]
noncomputable def expMonoidHom : MonoidHom (Multiplicative ℂ) ℂ :=
{ toFun := fun z => exp z.toAdd,
map_one' := by simp,
map_mul' := by simp [exp_add] }
theorem exp_list_sum (l : List ℂ) : exp l.sum = (l.map exp).prod :=
map_list_prod (M := Multiplicative ℂ) expMonoidHom l
theorem exp_multiset_sum (s : Multiset ℂ) : exp s.sum = (s.map exp).prod :=
@MonoidHom.map_multiset_prod (Multiplicative ℂ) ℂ _ _ expMonoidHom s
theorem exp_sum {α : Type*} (s : Finset α) (f : α → ℂ) :
exp (∑ x ∈ s, f x) = ∏ x ∈ s, exp (f x) :=
map_prod (β := Multiplicative ℂ) expMonoidHom f s
lemma exp_nsmul (x : ℂ) (n : ℕ) : exp (n • x) = exp x ^ n :=
@MonoidHom.map_pow (Multiplicative ℂ) ℂ _ _ expMonoidHom _ _
theorem exp_nat_mul (x : ℂ) : ∀ n : ℕ, exp (n * x) = exp x ^ n
| 0 => by rw [Nat.cast_zero, zero_mul, exp_zero, pow_zero]
| Nat.succ n => by rw [pow_succ, Nat.cast_add_one, add_mul, exp_add, ← exp_nat_mul _ n, one_mul]
@[simp]
theorem exp_ne_zero : exp x ≠ 0 := fun h =>
zero_ne_one (α := ℂ) <| by rw [← exp_zero, ← add_neg_cancel x, exp_add, h]; simp
theorem exp_neg : exp (-x) = (exp x)⁻¹ := by
rw [← mul_right_inj' (exp_ne_zero x), ← exp_add]; simp [mul_inv_cancel₀ (exp_ne_zero x)]
theorem exp_sub : exp (x - y) = exp x / exp y := by
simp [sub_eq_add_neg, exp_add, exp_neg, div_eq_mul_inv]
theorem exp_int_mul (z : ℂ) (n : ℤ) : Complex.exp (n * z) = Complex.exp z ^ n := by
cases n
· simp [exp_nat_mul]
· simp [exp_add, add_mul, pow_add, exp_neg, exp_nat_mul]
@[simp]
theorem exp_conj : exp (conj x) = conj (exp x) := by
dsimp [exp]
rw [← lim_conj]
refine congr_arg CauSeq.lim (CauSeq.ext fun _ => ?_)
dsimp [exp', Function.comp_def, cauSeqConj]
rw [map_sum (starRingEnd _)]
refine sum_congr rfl fun n _ => ?_
rw [map_div₀, map_pow, ← ofReal_natCast, conj_ofReal]
@[simp]
theorem ofReal_exp_ofReal_re (x : ℝ) : ((exp x).re : ℂ) = exp x :=
conj_eq_iff_re.1 <| by rw [← exp_conj, conj_ofReal]
@[simp, norm_cast]
theorem ofReal_exp (x : ℝ) : (Real.exp x : ℂ) = exp x :=
ofReal_exp_ofReal_re _
@[simp]
theorem exp_ofReal_im (x : ℝ) : (exp x).im = 0 := by rw [← ofReal_exp_ofReal_re, ofReal_im]
theorem exp_ofReal_re (x : ℝ) : (exp x).re = Real.exp x :=
rfl
end Complex
namespace Real
open Complex
variable (x y : ℝ)
@[simp]
theorem exp_zero : exp 0 = 1 := by simp [Real.exp]
nonrec theorem exp_add : exp (x + y) = exp x * exp y := by simp [exp_add, exp]
/-- the exponential function as a monoid hom from `Multiplicative ℝ` to `ℝ` -/
@[simps]
noncomputable def expMonoidHom : MonoidHom (Multiplicative ℝ) ℝ :=
{ toFun := fun x => exp x.toAdd,
map_one' := by simp,
map_mul' := by simp [exp_add] }
theorem exp_list_sum (l : List ℝ) : exp l.sum = (l.map exp).prod :=
map_list_prod (M := Multiplicative ℝ) expMonoidHom l
theorem exp_multiset_sum (s : Multiset ℝ) : exp s.sum = (s.map exp).prod :=
@MonoidHom.map_multiset_prod (Multiplicative ℝ) ℝ _ _ expMonoidHom s
theorem exp_sum {α : Type*} (s : Finset α) (f : α → ℝ) :
exp (∑ x ∈ s, f x) = ∏ x ∈ s, exp (f x) :=
map_prod (β := Multiplicative ℝ) expMonoidHom f s
lemma exp_nsmul (x : ℝ) (n : ℕ) : exp (n • x) = exp x ^ n :=
@MonoidHom.map_pow (Multiplicative ℝ) ℝ _ _ expMonoidHom _ _
nonrec theorem exp_nat_mul (x : ℝ) (n : ℕ) : exp (n * x) = exp x ^ n :=
ofReal_injective (by simp [exp_nat_mul])
@[simp]
nonrec theorem exp_ne_zero : exp x ≠ 0 := fun h =>
exp_ne_zero x <| by rw [exp, ← ofReal_inj] at h; simp_all
nonrec theorem exp_neg : exp (-x) = (exp x)⁻¹ :=
ofReal_injective <| by simp [exp_neg]
theorem exp_sub : exp (x - y) = exp x / exp y := by
simp [sub_eq_add_neg, exp_add, exp_neg, div_eq_mul_inv]
open IsAbsoluteValue Nat
theorem sum_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) (n : ℕ) : ∑ i ∈ range n, x ^ i / i ! ≤ exp x :=
calc
∑ i ∈ range n, x ^ i / i ! ≤ lim (⟨_, isCauSeq_re (exp' x)⟩ : CauSeq ℝ abs) := by
refine le_lim (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp only [exp', const_apply, re_sum]
norm_cast
refine sum_le_sum_of_subset_of_nonneg (range_mono hj) fun _ _ _ ↦ ?_
positivity
_ = exp x := by rw [exp, Complex.exp, ← cauSeqRe, lim_re]
lemma pow_div_factorial_le_exp (hx : 0 ≤ x) (n : ℕ) : x ^ n / n ! ≤ exp x :=
calc
x ^ n / n ! ≤ ∑ k ∈ range (n + 1), x ^ k / k ! :=
single_le_sum (f := fun k ↦ x ^ k / k !) (fun k _ ↦ by positivity) (self_mem_range_succ n)
_ ≤ exp x := sum_le_exp_of_nonneg hx _
theorem quadratic_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) : 1 + x + x ^ 2 / 2 ≤ exp x :=
calc
1 + x + x ^ 2 / 2 = ∑ i ∈ range 3, x ^ i / i ! := by
simp only [sum_range_succ, range_one, sum_singleton, _root_.pow_zero, factorial, cast_one,
ne_eq, one_ne_zero, not_false_eq_true, div_self, pow_one, mul_one, div_one, Nat.mul_one,
cast_succ, add_right_inj]
ring_nf
_ ≤ exp x := sum_le_exp_of_nonneg hx 3
private theorem add_one_lt_exp_of_pos {x : ℝ} (hx : 0 < x) : x + 1 < exp x :=
(by nlinarith : x + 1 < 1 + x + x ^ 2 / 2).trans_le (quadratic_le_exp_of_nonneg hx.le)
private theorem add_one_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) : x + 1 ≤ exp x := by
rcases eq_or_lt_of_le hx with (rfl | h)
· simp
exact (add_one_lt_exp_of_pos h).le
theorem one_le_exp {x : ℝ} (hx : 0 ≤ x) : 1 ≤ exp x := by linarith [add_one_le_exp_of_nonneg hx]
@[bound]
theorem exp_pos (x : ℝ) : 0 < exp x :=
(le_total 0 x).elim (lt_of_lt_of_le zero_lt_one ∘ one_le_exp) fun h => by
rw [← neg_neg x, Real.exp_neg]
exact inv_pos.2 (lt_of_lt_of_le zero_lt_one (one_le_exp (neg_nonneg.2 h)))
@[bound]
lemma exp_nonneg (x : ℝ) : 0 ≤ exp x := x.exp_pos.le
@[simp]
theorem abs_exp (x : ℝ) : |exp x| = exp x :=
abs_of_pos (exp_pos _)
lemma exp_abs_le (x : ℝ) : exp |x| ≤ exp x + exp (-x) := by
cases le_total x 0 <;> simp [abs_of_nonpos, abs_of_nonneg, exp_nonneg, *]
@[mono]
theorem exp_strictMono : StrictMono exp := fun x y h => by
rw [← sub_add_cancel y x, Real.exp_add]
exact (lt_mul_iff_one_lt_left (exp_pos _)).2
(lt_of_lt_of_le (by linarith) (add_one_le_exp_of_nonneg (by linarith)))
@[gcongr]
theorem exp_lt_exp_of_lt {x y : ℝ} (h : x < y) : exp x < exp y := exp_strictMono h
@[mono]
theorem exp_monotone : Monotone exp :=
exp_strictMono.monotone
@[gcongr, bound]
theorem exp_le_exp_of_le {x y : ℝ} (h : x ≤ y) : exp x ≤ exp y := exp_monotone h
@[simp]
theorem exp_lt_exp {x y : ℝ} : exp x < exp y ↔ x < y :=
exp_strictMono.lt_iff_lt
@[simp]
theorem exp_le_exp {x y : ℝ} : exp x ≤ exp y ↔ x ≤ y :=
exp_strictMono.le_iff_le
theorem exp_injective : Function.Injective exp :=
exp_strictMono.injective
@[simp]
theorem exp_eq_exp {x y : ℝ} : exp x = exp y ↔ x = y :=
exp_injective.eq_iff
@[simp]
theorem exp_eq_one_iff : exp x = 1 ↔ x = 0 :=
exp_injective.eq_iff' exp_zero
@[simp]
theorem one_lt_exp_iff {x : ℝ} : 1 < exp x ↔ 0 < x := by rw [← exp_zero, exp_lt_exp]
@[bound] private alias ⟨_, Bound.one_lt_exp_of_pos⟩ := one_lt_exp_iff
@[simp]
theorem exp_lt_one_iff {x : ℝ} : exp x < 1 ↔ x < 0 := by rw [← exp_zero, exp_lt_exp]
@[simp]
theorem exp_le_one_iff {x : ℝ} : exp x ≤ 1 ↔ x ≤ 0 :=
exp_zero ▸ exp_le_exp
@[simp]
theorem one_le_exp_iff {x : ℝ} : 1 ≤ exp x ↔ 0 ≤ x :=
exp_zero ▸ exp_le_exp
end Real
namespace Complex
theorem sum_div_factorial_le {α : Type*} [Field α] [LinearOrder α] [IsStrictOrderedRing α]
(n j : ℕ) (hn : 0 < n) :
(∑ m ∈ range j with n ≤ m, (1 / m.factorial : α)) ≤ n.succ / (n.factorial * n) :=
calc
(∑ m ∈ range j with n ≤ m, (1 / m.factorial : α)) =
∑ m ∈ range (j - n), (1 / ((m + n).factorial : α)) := by
refine sum_nbij' (· - n) (· + n) ?_ ?_ ?_ ?_ ?_ <;>
simp +contextual [lt_tsub_iff_right, tsub_add_cancel_of_le]
_ ≤ ∑ m ∈ range (j - n), ((n.factorial : α) * (n.succ : α) ^ m)⁻¹ := by
simp_rw [one_div]
gcongr
rw [← Nat.cast_pow, ← Nat.cast_mul, Nat.cast_le, add_comm]
exact Nat.factorial_mul_pow_le_factorial
_ = (n.factorial : α)⁻¹ * ∑ m ∈ range (j - n), (n.succ : α)⁻¹ ^ m := by
simp [mul_inv, ← mul_sum, ← sum_mul, mul_comm, inv_pow]
_ = ((n.succ : α) - n.succ * (n.succ : α)⁻¹ ^ (j - n)) / (n.factorial * n) := by
have h₁ : (n.succ : α) ≠ 1 :=
@Nat.cast_one α _ ▸ mt Nat.cast_inj.1 (mt Nat.succ.inj (pos_iff_ne_zero.1 hn))
have h₂ : (n.succ : α) ≠ 0 := by positivity
have h₃ : (n.factorial * n : α) ≠ 0 := by positivity
have h₄ : (n.succ - 1 : α) = n := by simp
rw [geom_sum_inv h₁ h₂, eq_div_iff_mul_eq h₃, mul_comm _ (n.factorial * n : α),
← mul_assoc (n.factorial⁻¹ : α), ← mul_inv_rev, h₄, ← mul_assoc (n.factorial * n : α),
mul_comm (n : α) n.factorial, mul_inv_cancel₀ h₃, one_mul, mul_comm]
_ ≤ n.succ / (n.factorial * n : α) := by gcongr; apply sub_le_self; positivity
theorem exp_bound {x : ℂ} (hx : ‖x‖ ≤ 1) {n : ℕ} (hn : 0 < n) :
‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤
‖x‖ ^ n * ((n.succ : ℝ) * (n.factorial * n : ℝ)⁻¹) := by
rw [← lim_const (abv := norm) (∑ m ∈ range n, _), exp, sub_eq_add_neg,
← lim_neg, lim_add, ← lim_norm]
refine lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp_rw [← sub_eq_add_neg]
show
‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤
‖x‖ ^ n * ((n.succ : ℝ) * (n.factorial * n : ℝ)⁻¹)
rw [sum_range_sub_sum_range hj]
calc
‖∑ m ∈ range j with n ≤ m, (x ^ m / m.factorial : ℂ)‖
= ‖∑ m ∈ range j with n ≤ m, (x ^ n * (x ^ (m - n) / m.factorial) : ℂ)‖ := by
refine congr_arg norm (sum_congr rfl fun m hm => ?_)
rw [mem_filter, mem_range] at hm
rw [← mul_div_assoc, ← pow_add, add_tsub_cancel_of_le hm.2]
_ ≤ ∑ m ∈ range j with n ≤ m, ‖x ^ n * (x ^ (m - n) / m.factorial)‖ :=
IsAbsoluteValue.abv_sum norm ..
_ ≤ ∑ m ∈ range j with n ≤ m, ‖x‖ ^ n * (1 / m.factorial) := by
simp_rw [Complex.norm_mul, Complex.norm_pow, Complex.norm_div, norm_natCast]
gcongr
rw [Complex.norm_pow]
exact pow_le_one₀ (norm_nonneg _) hx
_ = ‖x‖ ^ n * ∑ m ∈ range j with n ≤ m, (1 / m.factorial : ℝ) := by
simp [abs_mul, abv_pow abs, abs_div, ← mul_sum]
_ ≤ ‖x‖ ^ n * (n.succ * (n.factorial * n : ℝ)⁻¹) := by
gcongr
exact sum_div_factorial_le _ _ hn
theorem exp_bound' {x : ℂ} {n : ℕ} (hx : ‖x‖ / n.succ ≤ 1 / 2) :
‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n / n.factorial * 2 := by
rw [← lim_const (abv := norm) (∑ m ∈ range n, _),
exp, sub_eq_add_neg, ← lim_neg, lim_add, ← lim_norm]
refine lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp_rw [← sub_eq_add_neg]
show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤
‖x‖ ^ n / n.factorial * 2
let k := j - n
have hj : j = n + k := (add_tsub_cancel_of_le hj).symm
rw [hj, sum_range_add_sub_sum_range]
calc
‖∑ i ∈ range k, x ^ (n + i) / ((n + i).factorial : ℂ)‖ ≤
∑ i ∈ range k, ‖x ^ (n + i) / ((n + i).factorial : ℂ)‖ :=
IsAbsoluteValue.abv_sum _ _ _
_ ≤ ∑ i ∈ range k, ‖x‖ ^ (n + i) / (n + i).factorial := by
simp [norm_natCast, Complex.norm_pow]
_ ≤ ∑ i ∈ range k, ‖x‖ ^ (n + i) / ((n.factorial : ℝ) * (n.succ : ℝ) ^ i) := ?_
_ = ∑ i ∈ range k, ‖x‖ ^ n / n.factorial * (‖x‖ ^ i / (n.succ : ℝ) ^ i) := ?_
_ ≤ ‖x‖ ^ n / ↑n.factorial * 2 := ?_
· gcongr
exact mod_cast Nat.factorial_mul_pow_le_factorial
· refine Finset.sum_congr rfl fun _ _ => ?_
simp only [pow_add, div_eq_inv_mul, mul_inv, mul_left_comm, mul_assoc]
· rw [← mul_sum]
gcongr
simp_rw [← div_pow]
rw [geom_sum_eq, div_le_iff_of_neg]
· trans (-1 : ℝ)
· linarith
· simp only [neg_le_sub_iff_le_add, div_pow, Nat.cast_succ, le_add_iff_nonneg_left]
positivity
· linarith
· linarith
theorem norm_exp_sub_one_le {x : ℂ} (hx : ‖x‖ ≤ 1) : ‖exp x - 1‖ ≤ 2 * ‖x‖ :=
calc
‖exp x - 1‖ = ‖exp x - ∑ m ∈ range 1, x ^ m / m.factorial‖ := by simp [sum_range_succ]
_ ≤ ‖x‖ ^ 1 * ((Nat.succ 1 : ℝ) * ((Nat.factorial 1) * (1 : ℕ) : ℝ)⁻¹) :=
(exp_bound hx (by decide))
_ = 2 * ‖x‖ := by simp [two_mul, mul_two, mul_add, mul_comm, add_mul, Nat.factorial]
theorem norm_exp_sub_one_sub_id_le {x : ℂ} (hx : ‖x‖ ≤ 1) : ‖exp x - 1 - x‖ ≤ ‖x‖ ^ 2 :=
calc
‖exp x - 1 - x‖ = ‖exp x - ∑ m ∈ range 2, x ^ m / m.factorial‖ := by
simp [sub_eq_add_neg, sum_range_succ_comm, add_assoc, Nat.factorial]
_ ≤ ‖x‖ ^ 2 * ((Nat.succ 2 : ℝ) * (Nat.factorial 2 * (2 : ℕ) : ℝ)⁻¹) :=
(exp_bound hx (by decide))
_ ≤ ‖x‖ ^ 2 * 1 := by gcongr; norm_num [Nat.factorial]
_ = ‖x‖ ^ 2 := by rw [mul_one]
lemma norm_exp_sub_sum_le_exp_norm_sub_sum (x : ℂ) (n : ℕ) :
‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖
≤ Real.exp ‖x‖ - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by
rw [← CauSeq.lim_const (abv := norm) (∑ m ∈ range n, _), Complex.exp, sub_eq_add_neg,
← CauSeq.lim_neg, CauSeq.lim_add, ← lim_norm]
refine CauSeq.lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp_rw [← sub_eq_add_neg]
calc ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖
_ ≤ (∑ m ∈ range j, ‖x‖ ^ m / m.factorial) - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by
rw [sum_range_sub_sum_range hj, sum_range_sub_sum_range hj]
refine (IsAbsoluteValue.abv_sum norm ..).trans_eq ?_
congr with i
simp [Complex.norm_pow]
_ ≤ Real.exp ‖x‖ - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by
gcongr
exact Real.sum_le_exp_of_nonneg (norm_nonneg _) _
lemma norm_exp_le_exp_norm (x : ℂ) : ‖exp x‖ ≤ Real.exp ‖x‖ := by
convert norm_exp_sub_sum_le_exp_norm_sub_sum x 0 using 1 <;> simp
lemma norm_exp_sub_sum_le_norm_mul_exp (x : ℂ) (n : ℕ) :
‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n * Real.exp ‖x‖ := by
rw [← CauSeq.lim_const (abv := norm) (∑ m ∈ range n, _), Complex.exp, sub_eq_add_neg,
← CauSeq.lim_neg, CauSeq.lim_add, ← lim_norm]
refine CauSeq.lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp_rw [← sub_eq_add_neg]
show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ _
rw [sum_range_sub_sum_range hj]
calc
‖∑ m ∈ range j with n ≤ m, (x ^ m / m.factorial : ℂ)‖
= ‖∑ m ∈ range j with n ≤ m, (x ^ n * (x ^ (m - n) / m.factorial) : ℂ)‖ := by
refine congr_arg norm (sum_congr rfl fun m hm => ?_)
rw [mem_filter, mem_range] at hm
rw [← mul_div_assoc, ← pow_add, add_tsub_cancel_of_le hm.2]
_ ≤ ∑ m ∈ range j with n ≤ m, ‖x ^ n * (x ^ (m - n) / m.factorial)‖ :=
IsAbsoluteValue.abv_sum norm ..
_ ≤ ∑ m ∈ range j with n ≤ m, ‖x‖ ^ n * (‖x‖ ^ (m - n) / (m - n).factorial) := by
simp_rw [Complex.norm_mul, Complex.norm_pow, Complex.norm_div, norm_natCast]
gcongr with i hi
· rw [Complex.norm_pow]
· simp
_ = ‖x‖ ^ n * ∑ m ∈ range j with n ≤ m, (‖x‖ ^ (m - n) / (m - n).factorial) := by
rw [← mul_sum]
_ = ‖x‖ ^ n * ∑ m ∈ range (j - n), (‖x‖ ^ m / m.factorial) := by
congr 1
refine (sum_bij (fun m hm ↦ m + n) ?_ ?_ ?_ ?_).symm
· intro a ha
simp only [mem_filter, mem_range, le_add_iff_nonneg_left, zero_le, and_true]
simp only [mem_range] at ha
rwa [← lt_tsub_iff_right]
· intro a ha b hb hab
simpa using hab
· intro b hb
simp only [mem_range, exists_prop]
simp only [mem_filter, mem_range] at hb
refine ⟨b - n, ?_, ?_⟩
· rw [tsub_lt_tsub_iff_right hb.2]
exact hb.1
· rw [tsub_add_cancel_of_le hb.2]
· simp
_ ≤ ‖x‖ ^ n * Real.exp ‖x‖ := by
gcongr
refine Real.sum_le_exp_of_nonneg ?_ _
exact norm_nonneg _
@[deprecated (since := "2025-02-16")] alias abs_exp_sub_one_le := norm_exp_sub_one_le
@[deprecated (since := "2025-02-16")] alias abs_exp_sub_one_sub_id_le := norm_exp_sub_one_sub_id_le
@[deprecated (since := "2025-02-16")] alias abs_exp_sub_sum_le_exp_abs_sub_sum :=
norm_exp_sub_sum_le_exp_norm_sub_sum
@[deprecated (since := "2025-02-16")] alias abs_exp_le_exp_abs := norm_exp_le_exp_norm
@[deprecated (since := "2025-02-16")] alias abs_exp_sub_sum_le_abs_mul_exp :=
norm_exp_sub_sum_le_norm_mul_exp
end Complex
namespace Real
open Complex Finset
nonrec theorem exp_bound {x : ℝ} (hx : |x| ≤ 1) {n : ℕ} (hn : 0 < n) :
|exp x - ∑ m ∈ range n, x ^ m / m.factorial| ≤ |x| ^ n * (n.succ / (n.factorial * n)) := by
have hxc : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx
convert exp_bound hxc hn using 2 <;>
norm_cast
theorem exp_bound' {x : ℝ} (h1 : 0 ≤ x) (h2 : x ≤ 1) {n : ℕ} (hn : 0 < n) :
Real.exp x ≤ (∑ m ∈ Finset.range n, x ^ m / m.factorial) +
x ^ n * (n + 1) / (n.factorial * n) := by
have h3 : |x| = x := by simpa
have h4 : |x| ≤ 1 := by rwa [h3]
have h' := Real.exp_bound h4 hn
rw [h3] at h'
have h'' := (abs_sub_le_iff.1 h').1
have t := sub_le_iff_le_add'.1 h''
simpa [mul_div_assoc] using t
theorem abs_exp_sub_one_le {x : ℝ} (hx : |x| ≤ 1) : |exp x - 1| ≤ 2 * |x| := by
have : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx
exact_mod_cast Complex.norm_exp_sub_one_le (x := x) this
theorem abs_exp_sub_one_sub_id_le {x : ℝ} (hx : |x| ≤ 1) : |exp x - 1 - x| ≤ x ^ 2 := by
rw [← sq_abs]
have : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx
exact_mod_cast Complex.norm_exp_sub_one_sub_id_le this
/-- A finite initial segment of the exponential series, followed by an arbitrary tail.
For fixed `n` this is just a linear map wrt `r`, and each map is a simple linear function
of the previous (see `expNear_succ`), with `expNear n x r ⟶ exp x` as `n ⟶ ∞`,
for any `r`. -/
noncomputable def expNear (n : ℕ) (x r : ℝ) : ℝ :=
(∑ m ∈ range n, x ^ m / m.factorial) + x ^ n / n.factorial * r
@[simp]
theorem expNear_zero (x r) : expNear 0 x r = r := by simp [expNear]
@[simp]
theorem expNear_succ (n x r) : expNear (n + 1) x r = expNear n x (1 + x / (n + 1) * r) := by
simp [expNear, range_succ, mul_add, add_left_comm, add_assoc, pow_succ, div_eq_mul_inv,
mul_inv, Nat.factorial]
ac_rfl
theorem expNear_sub (n x r₁ r₂) : expNear n x r₁ -
expNear n x r₂ = x ^ n / n.factorial * (r₁ - r₂) := by
simp [expNear, mul_sub]
theorem exp_approx_end (n m : ℕ) (x : ℝ) (e₁ : n + 1 = m) (h : |x| ≤ 1) :
|exp x - expNear m x 0| ≤ |x| ^ m / m.factorial * ((m + 1) / m) := by
simp only [expNear, mul_zero, add_zero]
convert exp_bound (n := m) h ?_ using 1
· field_simp [mul_comm]
· omega
theorem exp_approx_succ {n} {x a₁ b₁ : ℝ} (m : ℕ) (e₁ : n + 1 = m) (a₂ b₂ : ℝ)
(e : |1 + x / m * a₂ - a₁| ≤ b₁ - |x| / m * b₂)
(h : |exp x - expNear m x a₂| ≤ |x| ^ m / m.factorial * b₂) :
|exp x - expNear n x a₁| ≤ |x| ^ n / n.factorial * b₁ := by
refine (abs_sub_le _ _ _).trans ((add_le_add_right h _).trans ?_)
subst e₁; rw [expNear_succ, expNear_sub, abs_mul]
convert mul_le_mul_of_nonneg_left (a := |x| ^ n / ↑(Nat.factorial n))
(le_sub_iff_add_le'.1 e) ?_ using 1
· simp [mul_add, pow_succ', div_eq_mul_inv, abs_mul, abs_inv, ← pow_abs, mul_inv, Nat.factorial]
ac_rfl
· simp [div_nonneg, abs_nonneg]
theorem exp_approx_end' {n} {x a b : ℝ} (m : ℕ) (e₁ : n + 1 = m) (rm : ℝ) (er : ↑m = rm)
(h : |x| ≤ 1) (e : |1 - a| ≤ b - |x| / rm * ((rm + 1) / rm)) :
|exp x - expNear n x a| ≤ |x| ^ n / n.factorial * b := by
subst er
exact exp_approx_succ _ e₁ _ _ (by simpa using e) (exp_approx_end _ _ _ e₁ h)
theorem exp_1_approx_succ_eq {n} {a₁ b₁ : ℝ} {m : ℕ} (en : n + 1 = m) {rm : ℝ} (er : ↑m = rm)
(h : |exp 1 - expNear m 1 ((a₁ - 1) * rm)| ≤ |1| ^ m / m.factorial * (b₁ * rm)) :
|exp 1 - expNear n 1 a₁| ≤ |1| ^ n / n.factorial * b₁ := by
subst er
refine exp_approx_succ _ en _ _ ?_ h
field_simp [show (m : ℝ) ≠ 0 by norm_cast; omega]
theorem exp_approx_start (x a b : ℝ) (h : |exp x - expNear 0 x a| ≤ |x| ^ 0 / Nat.factorial 0 * b) :
|exp x - a| ≤ b := by simpa using h
theorem exp_bound_div_one_sub_of_interval' {x : ℝ} (h1 : 0 < x) (h2 : x < 1) :
Real.exp x < 1 / (1 - x) := by
have H : 0 < 1 - (1 + x + x ^ 2) * (1 - x) := calc
0 < x ^ 3 := by positivity
_ = 1 - (1 + x + x ^ 2) * (1 - x) := by ring
calc
exp x ≤ _ := exp_bound' h1.le h2.le zero_lt_three
_ ≤ 1 + x + x ^ 2 := by
-- Porting note: was `norm_num [Finset.sum] <;> nlinarith`
-- This proof should be restored after the norm_num plugin for big operators is ported.
-- (It may also need the positivity extensions in https://github.com/leanprover-community/mathlib4/pull/3907.)
rw [show 3 = 1 + 1 + 1 from rfl]
repeat rw [Finset.sum_range_succ]
norm_num [Nat.factorial]
nlinarith
_ < 1 / (1 - x) := by rw [lt_div_iff₀] <;> nlinarith
theorem exp_bound_div_one_sub_of_interval {x : ℝ} (h1 : 0 ≤ x) (h2 : x < 1) :
Real.exp x ≤ 1 / (1 - x) := by
rcases eq_or_lt_of_le h1 with (rfl | h1)
· simp
· exact (exp_bound_div_one_sub_of_interval' h1 h2).le
theorem add_one_lt_exp {x : ℝ} (hx : x ≠ 0) : x + 1 < Real.exp x := by
obtain hx | hx := hx.symm.lt_or_lt
· exact add_one_lt_exp_of_pos hx
obtain h' | h' := le_or_lt 1 (-x)
· linarith [x.exp_pos]
have hx' : 0 < x + 1 := by linarith
simpa [add_comm, exp_neg, inv_lt_inv₀ (exp_pos _) hx']
using exp_bound_div_one_sub_of_interval' (neg_pos.2 hx) h'
theorem add_one_le_exp (x : ℝ) : x + 1 ≤ Real.exp x := by
| obtain rfl | hx := eq_or_ne x 0
· simp
| Mathlib/Data/Complex/Exponential.lean | 642 | 643 |
/-
Copyright (c) 2019 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes
-/
import Mathlib.Data.Matrix.Mul
import Mathlib.Data.PEquiv
/-!
# partial equivalences for matrices
Using partial equivalences to represent matrices.
This file introduces the function `PEquiv.toMatrix`, which returns a matrix containing ones and
zeros. For any partial equivalence `f`, `f.toMatrix i j = 1 ↔ f i = some j`.
The following important properties of this function are proved
`toMatrix_trans : (f.trans g).toMatrix = f.toMatrix * g.toMatrix`
`toMatrix_symm : f.symm.toMatrix = f.toMatrixᵀ`
`toMatrix_refl : (PEquiv.refl n).toMatrix = 1`
`toMatrix_bot : ⊥.toMatrix = 0`
This theory gives the matrix representation of projection linear maps, and their right inverses.
For example, the matrix `(single (0 : Fin 1) (i : Fin n)).toMatrix` corresponds to the ith
projection map from R^n to R.
Any injective function `Fin m → Fin n` gives rise to a `PEquiv`, whose matrix is the projection
map from R^m → R^n represented by the same function. The transpose of this matrix is the right
inverse of this map, sending anything not in the image to zero.
## notations
This file uses `ᵀ` for `Matrix.transpose`.
-/
assert_not_exists Field
namespace PEquiv
open Matrix
universe u v
variable {k l m n : Type*}
variable {α β : Type*}
open Matrix
/-- `toMatrix` returns a matrix containing ones and zeros. `f.toMatrix i j` is `1` if
`f i = some j` and `0` otherwise -/
def toMatrix [DecidableEq n] [Zero α] [One α] (f : m ≃. n) : Matrix m n α :=
of fun i j => if j ∈ f i then (1 : α) else 0
-- TODO: set as an equation lemma for `toMatrix`, see https://github.com/leanprover-community/mathlib4/pull/3024
@[simp]
theorem toMatrix_apply [DecidableEq n] [Zero α] [One α] (f : m ≃. n) (i j) :
toMatrix f i j = if j ∈ f i then (1 : α) else 0 :=
rfl
theorem toMatrix_mul_apply [Fintype m] [DecidableEq m] [NonAssocSemiring α] (f : l ≃. m) (i j)
(M : Matrix m n α) : (f.toMatrix * M :) i j = Option.casesOn (f i) 0 fun fi => M fi j := by
dsimp [toMatrix, Matrix.mul_apply]
rcases h : f i with - | fi
· simp [h]
· rw [Finset.sum_eq_single fi] <;> simp +contextual [h, eq_comm]
@[deprecated (since := "2025-01-27")] alias mul_matrix_apply := toMatrix_mul_apply
theorem mul_toMatrix_apply [Fintype m] [NonAssocSemiring α] [DecidableEq n] (M : Matrix l m α)
(f : m ≃. n) (i j) : (M * f.toMatrix :) i j = Option.casesOn (f.symm j) 0 (M i) := by
dsimp [Matrix.mul_apply, toMatrix_apply]
rcases h : f.symm j with - | fj
· simp [h, ← f.eq_some_iff]
· rw [Finset.sum_eq_single fj]
· simp [h, ← f.eq_some_iff]
· rintro b - n
simp [h, ← f.eq_some_iff, n.symm]
· simp
@[deprecated (since := "2025-01-27")] alias matrix_mul_apply := mul_toMatrix_apply
theorem toMatrix_symm [DecidableEq m] [DecidableEq n] [Zero α] [One α] (f : m ≃. n) :
(f.symm.toMatrix : Matrix n m α) = f.toMatrixᵀ := by
ext
simp only [transpose, mem_iff_mem f, toMatrix_apply]
congr
@[simp]
theorem toMatrix_refl [DecidableEq n] [Zero α] [One α] :
((PEquiv.refl n).toMatrix : Matrix n n α) = 1 := by
ext
simp [toMatrix_apply, one_apply]
@[simp]
theorem toMatrix_toPEquiv_apply [DecidableEq n] [Zero α] [One α] (f : m ≃ n) (i) :
f.toPEquiv.toMatrix i = Pi.single (f i) (1 : α) := by
| ext
simp [toMatrix_apply, Pi.single_apply, eq_comm]
@[simp]
| Mathlib/Data/Matrix/PEquiv.lean | 96 | 99 |
/-
Copyright (c) 2021 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kim Morrison
-/
import Mathlib.Algebra.Homology.Linear
import Mathlib.Algebra.Homology.ShortComplex.HomologicalComplex
import Mathlib.Tactic.Abel
/-!
# Chain homotopies
We define chain homotopies, and prove that homotopic chain maps induce the same map on homology.
-/
universe v u
noncomputable section
open CategoryTheory Category Limits HomologicalComplex
variable {ι : Type*}
variable {V : Type u} [Category.{v} V] [Preadditive V]
variable {c : ComplexShape ι} {C D E : HomologicalComplex V c}
variable (f g : C ⟶ D) (h k : D ⟶ E) (i : ι)
section
/-- The composition of `C.d i (c.next i) ≫ f (c.next i) i`. -/
def dNext (i : ι) : (∀ i j, C.X i ⟶ D.X j) →+ (C.X i ⟶ D.X i) :=
AddMonoidHom.mk' (fun f => C.d i (c.next i) ≫ f (c.next i) i) fun _ _ =>
Preadditive.comp_add _ _ _ _ _ _
/-- `f (c.next i) i`. -/
def fromNext (i : ι) : (∀ i j, C.X i ⟶ D.X j) →+ (C.xNext i ⟶ D.X i) :=
AddMonoidHom.mk' (fun f => f (c.next i) i) fun _ _ => rfl
@[simp]
theorem dNext_eq_dFrom_fromNext (f : ∀ i j, C.X i ⟶ D.X j) (i : ι) :
dNext i f = C.dFrom i ≫ fromNext i f :=
rfl
theorem dNext_eq (f : ∀ i j, C.X i ⟶ D.X j) {i i' : ι} (w : c.Rel i i') :
dNext i f = C.d i i' ≫ f i' i := by
obtain rfl := c.next_eq' w
rfl
lemma dNext_eq_zero (f : ∀ i j, C.X i ⟶ D.X j) (i : ι) (hi : ¬ c.Rel i (c.next i)) :
dNext i f = 0 := by
dsimp [dNext]
rw [shape _ _ _ hi, zero_comp]
-- This is not a simp lemma; the LHS already simplifies.
theorem dNext_comp_left (f : C ⟶ D) (g : ∀ i j, D.X i ⟶ E.X j) (i : ι) :
(dNext i fun i j => f.f i ≫ g i j) = f.f i ≫ dNext i g :=
(f.comm_assoc _ _ _).symm
-- This is not a simp lemma; the LHS already simplifies.
theorem dNext_comp_right (f : ∀ i j, C.X i ⟶ D.X j) (g : D ⟶ E) (i : ι) :
(dNext i fun i j => f i j ≫ g.f j) = dNext i f ≫ g.f i :=
(assoc _ _ _).symm
/-- The composition `f j (c.prev j) ≫ D.d (c.prev j) j`. -/
def prevD (j : ι) : (∀ i j, C.X i ⟶ D.X j) →+ (C.X j ⟶ D.X j) :=
AddMonoidHom.mk' (fun f => f j (c.prev j) ≫ D.d (c.prev j) j) fun _ _ =>
Preadditive.add_comp _ _ _ _ _ _
lemma prevD_eq_zero (f : ∀ i j, C.X i ⟶ D.X j) (i : ι) (hi : ¬ c.Rel (c.prev i) i) :
prevD i f = 0 := by
dsimp [prevD]
rw [shape _ _ _ hi, comp_zero]
/-- `f j (c.prev j)`. -/
def toPrev (j : ι) : (∀ i j, C.X i ⟶ D.X j) →+ (C.X j ⟶ D.xPrev j) :=
AddMonoidHom.mk' (fun f => f j (c.prev j)) fun _ _ => rfl
@[simp]
theorem prevD_eq_toPrev_dTo (f : ∀ i j, C.X i ⟶ D.X j) (j : ι) :
prevD j f = toPrev j f ≫ D.dTo j :=
rfl
theorem prevD_eq (f : ∀ i j, C.X i ⟶ D.X j) {j j' : ι} (w : c.Rel j' j) :
prevD j f = f j j' ≫ D.d j' j := by
obtain rfl := c.prev_eq' w
rfl
-- This is not a simp lemma; the LHS already simplifies.
theorem prevD_comp_left (f : C ⟶ D) (g : ∀ i j, D.X i ⟶ E.X j) (j : ι) :
(prevD j fun i j => f.f i ≫ g i j) = f.f j ≫ prevD j g :=
assoc _ _ _
-- This is not a simp lemma; the LHS already simplifies.
theorem prevD_comp_right (f : ∀ i j, C.X i ⟶ D.X j) (g : D ⟶ E) (j : ι) :
(prevD j fun i j => f i j ≫ g.f j) = prevD j f ≫ g.f j := by
dsimp [prevD]
simp only [assoc, g.comm]
theorem dNext_nat (C D : ChainComplex V ℕ) (i : ℕ) (f : ∀ i j, C.X i ⟶ D.X j) :
dNext i f = C.d i (i - 1) ≫ f (i - 1) i := by
dsimp [dNext]
cases i
· simp only [shape, ChainComplex.next_nat_zero, ComplexShape.down_Rel, Nat.one_ne_zero,
not_false_iff, zero_comp, reduceCtorEq]
· congr <;> simp
theorem prevD_nat (C D : CochainComplex V ℕ) (i : ℕ) (f : ∀ i j, C.X i ⟶ D.X j) :
prevD i f = f i (i - 1) ≫ D.d (i - 1) i := by
dsimp [prevD]
cases i
· simp only [shape, CochainComplex.prev_nat_zero, ComplexShape.up_Rel, Nat.one_ne_zero,
not_false_iff, comp_zero, reduceCtorEq]
· congr <;> simp
| /-- A homotopy `h` between chain maps `f` and `g` consists of components `h i j : C.X i ⟶ D.X j`
which are zero unless `c.Rel j i`, satisfying the homotopy condition.
-/
@[ext]
structure Homotopy (f g : C ⟶ D) where
hom : ∀ i j, C.X i ⟶ D.X j
zero : ∀ i j, ¬c.Rel j i → hom i j = 0 := by aesop_cat
| Mathlib/Algebra/Homology/Homotopy.lean | 115 | 121 |
/-
Copyright (c) 2017 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Neil Strickland
-/
import Mathlib.Data.Nat.Prime.Defs
import Mathlib.Data.PNat.Basic
/-!
# Primality and GCD on pnat
This file extends the theory of `ℕ+` with `gcd`, `lcm` and `Prime` functions, analogous to those on
`Nat`.
-/
namespace Nat.Primes
/-- The canonical map from `Nat.Primes` to `ℕ+` -/
@[coe] def toPNat : Nat.Primes → ℕ+ :=
fun p => ⟨(p : ℕ), p.property.pos⟩
instance coePNat : Coe Nat.Primes ℕ+ :=
⟨toPNat⟩
@[norm_cast]
theorem coe_pnat_nat (p : Nat.Primes) : ((p : ℕ+) : ℕ) = p :=
rfl
theorem coe_pnat_injective : Function.Injective ((↑) : Nat.Primes → ℕ+) := fun p q h =>
Subtype.ext (by injection h)
@[norm_cast]
theorem coe_pnat_inj (p q : Nat.Primes) : (p : ℕ+) = (q : ℕ+) ↔ p = q :=
coe_pnat_injective.eq_iff
end Nat.Primes
namespace PNat
open Nat
/-- The greatest common divisor (gcd) of two positive natural numbers,
viewed as positive natural number. -/
def gcd (n m : ℕ+) : ℕ+ :=
⟨Nat.gcd (n : ℕ) (m : ℕ), Nat.gcd_pos_of_pos_left (m : ℕ) n.pos⟩
/-- The least common multiple (lcm) of two positive natural numbers,
viewed as positive natural number. -/
def lcm (n m : ℕ+) : ℕ+ :=
⟨Nat.lcm (n : ℕ) (m : ℕ), by
let h := mul_pos n.pos m.pos
rw [← gcd_mul_lcm (n : ℕ) (m : ℕ), mul_comm] at h
exact pos_of_dvd_of_pos (Dvd.intro (Nat.gcd (n : ℕ) (m : ℕ)) rfl) h⟩
@[simp, norm_cast]
theorem gcd_coe (n m : ℕ+) : (gcd n m : ℕ) = Nat.gcd n m :=
rfl
@[simp, norm_cast]
theorem lcm_coe (n m : ℕ+) : (lcm n m : ℕ) = Nat.lcm n m :=
rfl
theorem gcd_dvd_left (n m : ℕ+) : gcd n m ∣ n :=
dvd_iff.2 (Nat.gcd_dvd_left (n : ℕ) (m : ℕ))
theorem gcd_dvd_right (n m : ℕ+) : gcd n m ∣ m :=
dvd_iff.2 (Nat.gcd_dvd_right (n : ℕ) (m : ℕ))
theorem dvd_gcd {m n k : ℕ+} (hm : k ∣ m) (hn : k ∣ n) : k ∣ gcd m n :=
dvd_iff.2 (Nat.dvd_gcd (dvd_iff.1 hm) (dvd_iff.1 hn))
theorem dvd_lcm_left (n m : ℕ+) : n ∣ lcm n m :=
dvd_iff.2 (Nat.dvd_lcm_left (n : ℕ) (m : ℕ))
theorem dvd_lcm_right (n m : ℕ+) : m ∣ lcm n m :=
dvd_iff.2 (Nat.dvd_lcm_right (n : ℕ) (m : ℕ))
theorem lcm_dvd {m n k : ℕ+} (hm : m ∣ k) (hn : n ∣ k) : lcm m n ∣ k :=
dvd_iff.2 (@Nat.lcm_dvd (m : ℕ) (n : ℕ) (k : ℕ) (dvd_iff.1 hm) (dvd_iff.1 hn))
theorem gcd_mul_lcm (n m : ℕ+) : gcd n m * lcm n m = n * m :=
Subtype.eq (Nat.gcd_mul_lcm (n : ℕ) (m : ℕ))
theorem eq_one_of_lt_two {n : ℕ+} : n < 2 → n = 1 := by
intro h; apply le_antisymm; swap
· apply PNat.one_le
· exact PNat.lt_add_one_iff.1 h
section Prime
/-! ### Prime numbers -/
/-- Primality predicate for `ℕ+`, defined in terms of `Nat.Prime`. -/
def Prime (p : ℕ+) : Prop :=
(p : ℕ).Prime
theorem Prime.one_lt {p : ℕ+} : p.Prime → 1 < p :=
Nat.Prime.one_lt
theorem prime_two : (2 : ℕ+).Prime :=
Nat.prime_two
instance {p : ℕ+} [h : Fact p.Prime] : Fact (p : ℕ).Prime := h
instance fact_prime_two : Fact (2 : ℕ+).Prime :=
⟨prime_two⟩
theorem prime_three : (3 : ℕ+).Prime :=
Nat.prime_three
instance fact_prime_three : Fact (3 : ℕ+).Prime :=
⟨prime_three⟩
theorem prime_five : (5 : ℕ+).Prime :=
Nat.prime_five
instance fact_prime_five : Fact (5 : ℕ+).Prime :=
⟨prime_five⟩
theorem dvd_prime {p m : ℕ+} (pp : p.Prime) : m ∣ p ↔ m = 1 ∨ m = p := by
rw [PNat.dvd_iff]
rw [Nat.dvd_prime pp]
simp
theorem Prime.ne_one {p : ℕ+} : p.Prime → p ≠ 1 := by
intro pp
intro contra
apply Nat.Prime.ne_one pp
rw [PNat.coe_eq_one_iff]
apply contra
@[simp]
theorem not_prime_one : ¬(1 : ℕ+).Prime :=
Nat.not_prime_one
theorem Prime.not_dvd_one {p : ℕ+} : p.Prime → ¬p ∣ 1 := fun pp : p.Prime => by
rw [dvd_iff]
apply Nat.Prime.not_dvd_one pp
theorem exists_prime_and_dvd {n : ℕ+} (hn : n ≠ 1) : ∃ p : ℕ+, p.Prime ∧ p ∣ n := by
obtain ⟨p, hp⟩ := Nat.exists_prime_and_dvd (mt coe_eq_one_iff.mp hn)
exists (⟨p, Nat.Prime.pos hp.left⟩ : ℕ+); rw [dvd_iff]; apply hp
end Prime
section Coprime
/-! ### Coprime numbers and gcd -/
/-- Two pnats are coprime if their gcd is 1. -/
def Coprime (m n : ℕ+) : Prop :=
m.gcd n = 1
@[simp, norm_cast]
theorem coprime_coe {m n : ℕ+} : Nat.Coprime ↑m ↑n ↔ m.Coprime n := by
unfold Nat.Coprime Coprime
rw [← coe_inj]
simp
theorem Coprime.mul {k m n : ℕ+} : m.Coprime k → n.Coprime k → (m * n).Coprime k := by
repeat rw [← coprime_coe]
rw [mul_coe]
apply Nat.Coprime.mul
theorem Coprime.mul_right {k m n : ℕ+} : k.Coprime m → k.Coprime n → k.Coprime (m * n) := by
repeat rw [← coprime_coe]
rw [mul_coe]
apply Nat.Coprime.mul_right
theorem gcd_comm {m n : ℕ+} : m.gcd n = n.gcd m := by
apply eq
simp only [gcd_coe]
apply Nat.gcd_comm
theorem gcd_eq_left_iff_dvd {m n : ℕ+} : m.gcd n = m ↔ m ∣ n := by
rw [dvd_iff, ← Nat.gcd_eq_left_iff_dvd, ← coe_inj]
simp
theorem gcd_eq_right_iff_dvd {m n : ℕ+} : n.gcd m = m ↔ m ∣ n := by
rw [gcd_comm]
apply gcd_eq_left_iff_dvd
theorem Coprime.gcd_mul_left_cancel (m : ℕ+) {n k : ℕ+} :
k.Coprime n → (k * m).gcd n = m.gcd n := by
intro h; apply eq; simp only [gcd_coe, mul_coe]
apply Nat.Coprime.gcd_mul_left_cancel; simpa
theorem Coprime.gcd_mul_right_cancel (m : ℕ+) {n k : ℕ+} :
k.Coprime n → (m * k).gcd n = m.gcd n := by rw [mul_comm]; apply Coprime.gcd_mul_left_cancel
theorem Coprime.gcd_mul_left_cancel_right (m : ℕ+) {n k : ℕ+} :
k.Coprime m → m.gcd (k * n) = m.gcd n := by
intro h; iterate 2 rw [gcd_comm]; symm
apply Coprime.gcd_mul_left_cancel _ h
theorem Coprime.gcd_mul_right_cancel_right (m : ℕ+) {n k : ℕ+} :
k.Coprime m → m.gcd (n * k) = m.gcd n := by
rw [mul_comm]
apply Coprime.gcd_mul_left_cancel_right
@[simp]
theorem one_gcd {n : ℕ+} : gcd 1 n = 1 := by
rw [gcd_eq_left_iff_dvd]
apply one_dvd
@[simp]
| theorem gcd_one {n : ℕ+} : gcd n 1 = 1 := by
rw [gcd_comm]
apply one_gcd
@[symm]
| Mathlib/Data/PNat/Prime.lean | 210 | 214 |
/-
Copyright (c) 2016 Leonardo de Moura. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
import Mathlib.Control.Basic
import Mathlib.Data.Set.Defs
import Mathlib.Data.Set.Lattice.Image
import Mathlib.Data.Set.Notation
/-!
# Functoriality of `Set`
This file defines the functor structure of `Set`.
-/
universe u
open Function Set.Notation
namespace Set
variable {α β : Type u} {s : Set α} {f : α → Set β}
/-- The `Set` functor is a monad.
This is not a global instance because it does not have computational content,
so it does not make much sense using `do` notation in general.
Plus, this would cause monad-related coercions and monad lifting logic to become activated.
Either use `attribute [local instance] Set.monad` to make it be a local instance
or use `SetM.run do ...` when `do` notation is wanted. -/
protected def monad : Monad.{u} Set where
pure a := {a}
bind s f := ⋃ i ∈ s, f i
seq s t := Set.seq s (t ())
map := Set.image
section with_instance
attribute [local instance] Set.monad
@[simp]
theorem bind_def : s >>= f = ⋃ i ∈ s, f i :=
rfl
@[simp]
theorem fmap_eq_image (f : α → β) : f <$> s = f '' s :=
rfl
@[simp]
theorem seq_eq_set_seq (s : Set (α → β)) (t : Set α) : s <*> t = s.seq t :=
rfl
@[simp]
theorem pure_def (a : α) : (pure a : Set α) = {a} :=
rfl
/-- `Set.image2` in terms of monadic operations. Note that this can't be taken as the definition
because of the lack of universe polymorphism. -/
theorem image2_def {α β γ : Type u} (f : α → β → γ) (s : Set α) (t : Set β) :
image2 f s t = f <$> s <*> t := by
ext
simp
instance : LawfulMonad Set := LawfulMonad.mk'
| (id_map := image_id)
(pure_bind := biUnion_singleton)
(bind_assoc := fun _ _ _ => by simp only [bind_def, biUnion_iUnion])
(bind_pure_comp := fun _ _ => (image_eq_iUnion _ _).symm)
| Mathlib/Data/Set/Functor.lean | 65 | 68 |
/-
Copyright (c) 2021 Shing Tak Lam. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Shing Tak Lam
-/
import Mathlib.Topology.Order.ProjIcc
import Mathlib.Topology.ContinuousMap.Ordered
import Mathlib.Topology.CompactOpen
import Mathlib.Topology.UnitInterval
/-!
# Homotopy between functions
In this file, we define a homotopy between two functions `f₀` and `f₁`. First we define
`ContinuousMap.Homotopy` between the two functions, with no restrictions on the intermediate
maps. Then, as in the formalisation in HOL-Analysis, we define
`ContinuousMap.HomotopyWith f₀ f₁ P`, for homotopies between `f₀` and `f₁`, where the
intermediate maps satisfy the predicate `P`. Finally, we define
`ContinuousMap.HomotopyRel f₀ f₁ S`, for homotopies between `f₀` and `f₁` which are fixed
on `S`.
## Definitions
* `ContinuousMap.Homotopy f₀ f₁` is the type of homotopies between `f₀` and `f₁`.
* `ContinuousMap.HomotopyWith f₀ f₁ P` is the type of homotopies between `f₀` and `f₁`, where
the intermediate maps satisfy the predicate `P`.
* `ContinuousMap.HomotopyRel f₀ f₁ S` is the type of homotopies between `f₀` and `f₁` which
are fixed on `S`.
For each of the above, we have
* `refl f`, which is the constant homotopy from `f` to `f`.
* `symm F`, which reverses the homotopy `F`. For example, if `F : ContinuousMap.Homotopy f₀ f₁`,
then `F.symm : ContinuousMap.Homotopy f₁ f₀`.
* `trans F G`, which concatenates the homotopies `F` and `G`. For example, if
`F : ContinuousMap.Homotopy f₀ f₁` and `G : ContinuousMap.Homotopy f₁ f₂`, then
`F.trans G : ContinuousMap.Homotopy f₀ f₂`.
We also define the relations
* `ContinuousMap.Homotopic f₀ f₁` is defined to be `Nonempty (ContinuousMap.Homotopy f₀ f₁)`
* `ContinuousMap.HomotopicWith f₀ f₁ P` is defined to be
`Nonempty (ContinuousMap.HomotopyWith f₀ f₁ P)`
* `ContinuousMap.HomotopicRel f₀ f₁ P` is defined to be
`Nonempty (ContinuousMap.HomotopyRel f₀ f₁ P)`
and for `ContinuousMap.homotopic` and `ContinuousMap.homotopic_rel`, we also define the
`setoid` and `quotient` in `C(X, Y)` by these relations.
## References
- [HOL-Analysis formalisation](https://isabelle.in.tum.de/library/HOL/HOL-Analysis/Homotopy.html)
-/
noncomputable section
universe u v w x
variable {F : Type*} {X : Type u} {Y : Type v} {Z : Type w} {Z' : Type x} {ι : Type*}
variable [TopologicalSpace X] [TopologicalSpace Y] [TopologicalSpace Z] [TopologicalSpace Z']
open unitInterval
namespace ContinuousMap
/-- `ContinuousMap.Homotopy f₀ f₁` is the type of homotopies from `f₀` to `f₁`.
When possible, instead of parametrizing results over `(f : Homotopy f₀ f₁)`,
you should parametrize over `{F : Type*} [HomotopyLike F f₀ f₁] (f : F)`.
When you extend this structure, make sure to extend `ContinuousMap.HomotopyLike`. -/
structure Homotopy (f₀ f₁ : C(X, Y)) extends C(I × X, Y) where
/-- value of the homotopy at 0 -/
map_zero_left : ∀ x, toFun (0, x) = f₀ x
/-- value of the homotopy at 1 -/
map_one_left : ∀ x, toFun (1, x) = f₁ x
section
/-- `ContinuousMap.HomotopyLike F f₀ f₁` states that `F` is a type of homotopies between `f₀` and
`f₁`.
You should extend this class when you extend `ContinuousMap.Homotopy`. -/
class HomotopyLike {X Y : outParam Type*} [TopologicalSpace X] [TopologicalSpace Y]
(F : Type*) (f₀ f₁ : outParam <| C(X, Y)) [FunLike F (I × X) Y] : Prop
extends ContinuousMapClass F (I × X) Y where
/-- value of the homotopy at 0 -/
map_zero_left (f : F) : ∀ x, f (0, x) = f₀ x
/-- value of the homotopy at 1 -/
map_one_left (f : F) : ∀ x, f (1, x) = f₁ x
end
namespace Homotopy
section
variable {f₀ f₁ : C(X, Y)}
instance instFunLike : FunLike (Homotopy f₀ f₁) (I × X) Y where
coe f := f.toFun
coe_injective' f g h := by
obtain ⟨⟨_, _⟩, _⟩ := f
obtain ⟨⟨_, _⟩, _⟩ := g
congr
instance : HomotopyLike (Homotopy f₀ f₁) f₀ f₁ where
map_continuous f := f.continuous_toFun
map_zero_left f := f.map_zero_left
map_one_left f := f.map_one_left
@[ext]
theorem ext {F G : Homotopy f₀ f₁} (h : ∀ x, F x = G x) : F = G :=
DFunLike.ext _ _ h
/-- See Note [custom simps projection]. We need to specify this projection explicitly in this case,
because it is a composition of multiple projections. -/
def Simps.apply (F : Homotopy f₀ f₁) : I × X → Y :=
F
initialize_simps_projections Homotopy (toFun → apply, -toContinuousMap)
/-- Deprecated. Use `map_continuous` instead. -/
protected theorem continuous (F : Homotopy f₀ f₁) : Continuous F :=
F.continuous_toFun
@[simp]
theorem apply_zero (F : Homotopy f₀ f₁) (x : X) : F (0, x) = f₀ x :=
F.map_zero_left x
@[simp]
theorem apply_one (F : Homotopy f₀ f₁) (x : X) : F (1, x) = f₁ x :=
F.map_one_left x
@[simp]
theorem coe_toContinuousMap (F : Homotopy f₀ f₁) : ⇑F.toContinuousMap = F :=
rfl
/-- Currying a homotopy to a continuous function from `I` to `C(X, Y)`.
-/
def curry (F : Homotopy f₀ f₁) : C(I, C(X, Y)) :=
F.toContinuousMap.curry
@[simp]
theorem curry_apply (F : Homotopy f₀ f₁) (t : I) (x : X) : F.curry t x = F (t, x) :=
rfl
/-- Continuously extending a curried homotopy to a function from `ℝ` to `C(X, Y)`.
-/
def extend (F : Homotopy f₀ f₁) : C(ℝ, C(X, Y)) :=
F.curry.IccExtend zero_le_one
theorem extend_apply_of_le_zero (F : Homotopy f₀ f₁) {t : ℝ} (ht : t ≤ 0) (x : X) :
F.extend t x = f₀ x := by
rw [← F.apply_zero]
exact ContinuousMap.congr_fun (Set.IccExtend_of_le_left (zero_le_one' ℝ) F.curry ht) x
theorem extend_apply_of_one_le (F : Homotopy f₀ f₁) {t : ℝ} (ht : 1 ≤ t) (x : X) :
F.extend t x = f₁ x := by
rw [← F.apply_one]
exact ContinuousMap.congr_fun (Set.IccExtend_of_right_le (zero_le_one' ℝ) F.curry ht) x
theorem extend_apply_coe (F : Homotopy f₀ f₁) (t : I) (x : X) : F.extend t x = F (t, x) :=
ContinuousMap.congr_fun (Set.IccExtend_val (zero_le_one' ℝ) F.curry t) x
@[simp]
theorem extend_apply_of_mem_I (F : Homotopy f₀ f₁) {t : ℝ} (ht : t ∈ I) (x : X) :
F.extend t x = F (⟨t, ht⟩, x) :=
ContinuousMap.congr_fun (Set.IccExtend_of_mem (zero_le_one' ℝ) F.curry ht) x
protected theorem congr_fun {F G : Homotopy f₀ f₁} (h : F = G) (x : I × X) : F x = G x :=
ContinuousMap.congr_fun (congr_arg _ h) x
protected theorem congr_arg (F : Homotopy f₀ f₁) {x y : I × X} (h : x = y) : F x = F y :=
F.toContinuousMap.congr_arg h
end
/-- Given a continuous function `f`, we can define a `Homotopy f f` by `F (t, x) = f x`
-/
@[simps]
def refl (f : C(X, Y)) : Homotopy f f where
toFun x := f x.2
map_zero_left _ := rfl
map_one_left _ := rfl
instance : Inhabited (Homotopy (ContinuousMap.id X) (ContinuousMap.id X)) :=
⟨Homotopy.refl _⟩
/-- Given a `Homotopy f₀ f₁`, we can define a `Homotopy f₁ f₀` by reversing the homotopy.
-/
@[simps]
def symm {f₀ f₁ : C(X, Y)} (F : Homotopy f₀ f₁) : Homotopy f₁ f₀ where
toFun x := F (σ x.1, x.2)
map_zero_left := by norm_num
map_one_left := by norm_num
@[simp]
theorem symm_symm {f₀ f₁ : C(X, Y)} (F : Homotopy f₀ f₁) : F.symm.symm = F := by
ext
simp
theorem symm_bijective {f₀ f₁ : C(X, Y)} :
Function.Bijective (Homotopy.symm : Homotopy f₀ f₁ → Homotopy f₁ f₀) :=
Function.bijective_iff_has_inverse.mpr ⟨_, symm_symm, symm_symm⟩
/--
Given `Homotopy f₀ f₁` and `Homotopy f₁ f₂`, we can define a `Homotopy f₀ f₂` by putting the first
homotopy on `[0, 1/2]` and the second on `[1/2, 1]`.
-/
def trans {f₀ f₁ f₂ : C(X, Y)} (F : Homotopy f₀ f₁) (G : Homotopy f₁ f₂) : Homotopy f₀ f₂ where
toFun x := if (x.1 : ℝ) ≤ 1 / 2 then F.extend (2 * x.1) x.2 else G.extend (2 * x.1 - 1) x.2
continuous_toFun := by
refine
continuous_if_le (by fun_prop) continuous_const
(F.continuous.comp (by continuity)).continuousOn
(G.continuous.comp (by continuity)).continuousOn ?_
rintro x hx
norm_num [hx]
map_zero_left x := by norm_num
map_one_left x := by norm_num
theorem trans_apply {f₀ f₁ f₂ : C(X, Y)} (F : Homotopy f₀ f₁) (G : Homotopy f₁ f₂) (x : I × X) :
(F.trans G) x =
if h : (x.1 : ℝ) ≤ 1 / 2 then
F (⟨2 * x.1, (unitInterval.mul_pos_mem_iff zero_lt_two).2 ⟨x.1.2.1, h⟩⟩, x.2)
else
G (⟨2 * x.1 - 1, unitInterval.two_mul_sub_one_mem_iff.2 ⟨(not_le.1 h).le, x.1.2.2⟩⟩, x.2) :=
show ite _ _ _ = _ by
split_ifs <;>
· rw [extend, ContinuousMap.coe_IccExtend, Set.IccExtend_of_mem]
rfl
theorem symm_trans {f₀ f₁ f₂ : C(X, Y)} (F : Homotopy f₀ f₁) (G : Homotopy f₁ f₂) :
(F.trans G).symm = G.symm.trans F.symm := by
ext ⟨t, _⟩
rw [trans_apply, symm_apply, trans_apply]
simp only [coe_symm_eq, symm_apply]
split_ifs with h₁ h₂ h₂
· have ht : (t : ℝ) = 1 / 2 := by linarith
norm_num [ht]
· congr 2
apply Subtype.ext
simp only [coe_symm_eq]
linarith
· congr 2
apply Subtype.ext
simp only [coe_symm_eq]
linarith
· exfalso
linarith
/-- Casting a `Homotopy f₀ f₁` to a `Homotopy g₀ g₁` where `f₀ = g₀` and `f₁ = g₁`.
-/
@[simps]
def cast {f₀ f₁ g₀ g₁ : C(X, Y)} (F : Homotopy f₀ f₁) (h₀ : f₀ = g₀) (h₁ : f₁ = g₁) :
Homotopy g₀ g₁ where
toFun := F
map_zero_left := by simp [← h₀]
map_one_left := by simp [← h₁]
/-- Composition of a `Homotopy g₀ g₁` and `f : C(X, Y)` as a homotopy between `g₀.comp f` and
`g₁.comp f`. -/
@[simps!]
def compContinuousMap {g₀ g₁ : C(Y, Z)} (G : Homotopy g₀ g₁) (f : C(X, Y)) :
Homotopy (g₀.comp f) (g₁.comp f) where
toContinuousMap := G.comp (.prodMap (.id _) f)
map_zero_left _ := G.map_zero_left _
map_one_left _ := G.map_one_left _
/-- If we have a `Homotopy f₀ f₁` and a `Homotopy g₀ g₁`, then we can compose them and get a
`Homotopy (g₀.comp f₀) (g₁.comp f₁)`.
-/
@[simps]
def hcomp {f₀ f₁ : C(X, Y)} {g₀ g₁ : C(Y, Z)} (F : Homotopy f₀ f₁) (G : Homotopy g₀ g₁) :
Homotopy (g₀.comp f₀) (g₁.comp f₁) where
toFun x := G (x.1, F x)
map_zero_left := by simp
map_one_left := by simp
/-- Let `F` be a homotopy between `f₀ : C(X, Y)` and `f₁ : C(X, Y)`. Let `G` be a homotopy between
`g₀ : C(X, Z)` and `g₁ : C(X, Z)`. Then `F.prodMk G` is the homotopy between `f₀.prodMk g₀` and
`f₁.prodMk g₁` that sends `p` to `(F p, G p)`. -/
nonrec def prodMk {f₀ f₁ : C(X, Y)} {g₀ g₁ : C(X, Z)} (F : Homotopy f₀ f₁) (G : Homotopy g₀ g₁) :
Homotopy (f₀.prodMk g₀) (f₁.prodMk g₁) where
toContinuousMap := F.prodMk G
map_zero_left _ := Prod.ext (F.map_zero_left _) (G.map_zero_left _)
map_one_left _ := Prod.ext (F.map_one_left _) (G.map_one_left _)
/-- Let `F` be a homotopy between `f₀ : C(X, Y)` and `f₁ : C(X, Y)`. Let `G` be a homotopy between
`g₀ : C(Z, Z')` and `g₁ : C(Z, Z')`. Then `F.prodMap G` is the homotopy between `f₀.prodMap g₀` and
`f₁.prodMap g₁` that sends `(t, x, z)` to `(F (t, x), G (t, z))`. -/
def prodMap {f₀ f₁ : C(X, Y)} {g₀ g₁ : C(Z, Z')} (F : Homotopy f₀ f₁) (G : Homotopy g₀ g₁) :
Homotopy (f₀.prodMap g₀) (f₁.prodMap g₁) :=
.prodMk (.hcomp (.refl .fst) F) (.hcomp (.refl .snd) G)
/-- Given a family of homotopies `F i` between `f₀ i : C(X, Y i)` and `f₁ i : C(X, Y i)`, returns a
homotopy between `ContinuousMap.pi f₀` and `ContinuousMap.pi f₁`. -/
protected def pi {Y : ι → Type*} [∀ i, TopologicalSpace (Y i)] {f₀ f₁ : ∀ i, C(X, Y i)}
(F : ∀ i, Homotopy (f₀ i) (f₁ i)) :
Homotopy (.pi f₀) (.pi f₁) where
toContinuousMap := .pi fun i ↦ F i
map_zero_left x := funext fun i ↦ (F i).map_zero_left x
map_one_left x := funext fun i ↦ (F i).map_one_left x
/-- Given a family of homotopies `F i` between `f₀ i : C(X i, Y i)` and `f₁ i : C(X i, Y i)`,
returns a homotopy between `ContinuousMap.piMap f₀` and `ContinuousMap.piMap f₁`. -/
protected def piMap {X Y : ι → Type*} [∀ i, TopologicalSpace (X i)] [∀ i, TopologicalSpace (Y i)]
{f₀ f₁ : ∀ i, C(X i, Y i)} (F : ∀ i, Homotopy (f₀ i) (f₁ i)) :
Homotopy (.piMap f₀) (.piMap f₁) :=
.pi fun i ↦ .hcomp (.refl <| .eval i) (F i)
end Homotopy
/-- Given continuous maps `f₀` and `f₁`, we say `f₀` and `f₁` are homotopic if there exists a
`Homotopy f₀ f₁`.
-/
def Homotopic (f₀ f₁ : C(X, Y)) : Prop :=
Nonempty (Homotopy f₀ f₁)
namespace Homotopic
@[refl]
theorem refl (f : C(X, Y)) : Homotopic f f :=
⟨Homotopy.refl f⟩
@[symm]
theorem symm ⦃f g : C(X, Y)⦄ (h : Homotopic f g) : Homotopic g f :=
h.map Homotopy.symm
@[trans]
theorem trans ⦃f g h : C(X, Y)⦄ (h₀ : Homotopic f g) (h₁ : Homotopic g h) : Homotopic f h :=
h₀.map2 Homotopy.trans h₁
theorem hcomp {f₀ f₁ : C(X, Y)} {g₀ g₁ : C(Y, Z)} (h₀ : Homotopic f₀ f₁) (h₁ : Homotopic g₀ g₁) :
Homotopic (g₀.comp f₀) (g₁.comp f₁) :=
h₀.map2 Homotopy.hcomp h₁
theorem equivalence : Equivalence (@Homotopic X Y _ _) :=
⟨refl, by apply symm, by apply trans⟩
nonrec theorem prodMk {f₀ f₁ : C(X, Y)} {g₀ g₁ : C(X, Z)} :
Homotopic f₀ f₁ → Homotopic g₀ g₁ → Homotopic (f₀.prodMk g₀) (f₁.prodMk g₁)
| ⟨F⟩, ⟨G⟩ => ⟨F.prodMk G⟩
nonrec theorem prodMap {f₀ f₁ : C(X, Y)} {g₀ g₁ : C(Z, Z')} :
Homotopic f₀ f₁ → Homotopic g₀ g₁ → Homotopic (f₀.prodMap g₀) (f₁.prodMap g₁)
| ⟨F⟩, ⟨G⟩ => ⟨F.prodMap G⟩
/-- If each `f₀ i : C(X, Y i)` is homotopic to `f₁ i : C(X, Y i)`, then `ContinuousMap.pi f₀` is
homotopic to `ContinuousMap.pi f₁`. -/
protected theorem pi {Y : ι → Type*} [∀ i, TopologicalSpace (Y i)] {f₀ f₁ : ∀ i, C(X, Y i)}
(F : ∀ i, Homotopic (f₀ i) (f₁ i)) :
Homotopic (.pi f₀) (.pi f₁) :=
⟨.pi fun i ↦ (F i).some⟩
/-- If each `f₀ i : C(X, Y i)` is homotopic to `f₁ i : C(X, Y i)`, then `ContinuousMap.pi f₀` is
homotopic to `ContinuousMap.pi f₁`. -/
protected theorem piMap {X Y : ι → Type*} [∀ i, TopologicalSpace (X i)]
[∀ i, TopologicalSpace (Y i)] {f₀ f₁ : ∀ i, C(X i, Y i)} (F : ∀ i, Homotopic (f₀ i) (f₁ i)) :
Homotopic (.piMap f₀) (.piMap f₁) :=
.pi fun i ↦ .hcomp (.refl <| .eval i) (F i)
end Homotopic
/--
The type of homotopies between `f₀ f₁ : C(X, Y)`, where the intermediate maps satisfy the predicate
`P : C(X, Y) → Prop`
-/
structure HomotopyWith (f₀ f₁ : C(X, Y)) (P : C(X, Y) → Prop) extends Homotopy f₀ f₁ where
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: use `toHomotopy.curry t`
/-- the intermediate maps of the homotopy satisfy the property -/
prop' : ∀ t, P ⟨fun x => toFun (t, x),
Continuous.comp continuous_toFun (continuous_const.prodMk continuous_id')⟩
namespace HomotopyWith
section
variable {f₀ f₁ : C(X, Y)} {P : C(X, Y) → Prop}
instance instFunLike : FunLike (HomotopyWith f₀ f₁ P) (I × X) Y where
coe F := ⇑F.toHomotopy
coe_injective'
| ⟨⟨⟨_, _⟩, _, _⟩, _⟩, ⟨⟨⟨_, _⟩, _, _⟩, _⟩, rfl => rfl
instance : HomotopyLike (HomotopyWith f₀ f₁ P) f₀ f₁ where
map_continuous F := F.continuous_toFun
map_zero_left F := F.map_zero_left
map_one_left F := F.map_one_left
theorem coeFn_injective : @Function.Injective (HomotopyWith f₀ f₁ P) (I × X → Y) (⇑) :=
DFunLike.coe_injective'
@[ext]
theorem ext {F G : HomotopyWith f₀ f₁ P} (h : ∀ x, F x = G x) : F = G := DFunLike.ext F G h
/-- See Note [custom simps projection]. We need to specify this projection explicitly in this case,
because it is a composition of multiple projections. -/
def Simps.apply (F : HomotopyWith f₀ f₁ P) : I × X → Y := F
initialize_simps_projections HomotopyWith (toFun → apply, -toHomotopy_toContinuousMap)
@[continuity]
protected theorem continuous (F : HomotopyWith f₀ f₁ P) : Continuous F :=
F.continuous_toFun
@[simp]
theorem apply_zero (F : HomotopyWith f₀ f₁ P) (x : X) : F (0, x) = f₀ x :=
F.map_zero_left x
@[simp]
theorem apply_one (F : HomotopyWith f₀ f₁ P) (x : X) : F (1, x) = f₁ x :=
F.map_one_left x
theorem coe_toContinuousMap (F : HomotopyWith f₀ f₁ P) : ⇑F.toContinuousMap = F :=
rfl
@[simp]
theorem coe_toHomotopy (F : HomotopyWith f₀ f₁ P) : ⇑F.toHomotopy = F :=
rfl
theorem prop (F : HomotopyWith f₀ f₁ P) (t : I) : P (F.toHomotopy.curry t) := F.prop' t
theorem extendProp (F : HomotopyWith f₀ f₁ P) (t : ℝ) : P (F.toHomotopy.extend t) := F.prop _
end
variable {P : C(X, Y) → Prop}
/-- Given a continuous function `f`, and a proof `h : P f`, we can define a `HomotopyWith f f P` by
`F (t, x) = f x`
-/
@[simps!]
def refl (f : C(X, Y)) (hf : P f) : HomotopyWith f f P where
toHomotopy := Homotopy.refl f
prop' := fun _ => hf
instance : Inhabited (HomotopyWith (ContinuousMap.id X) (ContinuousMap.id X) fun _ => True) :=
⟨HomotopyWith.refl _ trivial⟩
/--
Given a `HomotopyWith f₀ f₁ P`, we can define a `HomotopyWith f₁ f₀ P` by reversing the homotopy.
-/
@[simps!]
def symm {f₀ f₁ : C(X, Y)} (F : HomotopyWith f₀ f₁ P) : HomotopyWith f₁ f₀ P where
toHomotopy := F.toHomotopy.symm
prop' := fun t => F.prop (σ t)
@[simp]
theorem symm_symm {f₀ f₁ : C(X, Y)} (F : HomotopyWith f₀ f₁ P) : F.symm.symm = F :=
ext <| Homotopy.congr_fun <| Homotopy.symm_symm _
theorem symm_bijective {f₀ f₁ : C(X, Y)} :
Function.Bijective (HomotopyWith.symm : HomotopyWith f₀ f₁ P → HomotopyWith f₁ f₀ P) :=
Function.bijective_iff_has_inverse.mpr ⟨_, symm_symm, symm_symm⟩
/--
Given `HomotopyWith f₀ f₁ P` and `HomotopyWith f₁ f₂ P`, we can define a `HomotopyWith f₀ f₂ P`
by putting the first homotopy on `[0, 1/2]` and the second on `[1/2, 1]`.
-/
def trans {f₀ f₁ f₂ : C(X, Y)} (F : HomotopyWith f₀ f₁ P) (G : HomotopyWith f₁ f₂ P) :
HomotopyWith f₀ f₂ P :=
{ F.toHomotopy.trans G.toHomotopy with
prop' := fun t => by
simp only [Homotopy.trans]
change P ⟨fun _ => ite ((t : ℝ) ≤ _) _ _, _⟩
split_ifs
· exact F.extendProp _
· exact G.extendProp _ }
theorem trans_apply {f₀ f₁ f₂ : C(X, Y)} (F : HomotopyWith f₀ f₁ P) (G : HomotopyWith f₁ f₂ P)
(x : I × X) :
(F.trans G) x =
if h : (x.1 : ℝ) ≤ 1 / 2 then
F (⟨2 * x.1, (unitInterval.mul_pos_mem_iff zero_lt_two).2 ⟨x.1.2.1, h⟩⟩, x.2)
else
G (⟨2 * x.1 - 1, unitInterval.two_mul_sub_one_mem_iff.2 ⟨(not_le.1 h).le, x.1.2.2⟩⟩, x.2) :=
Homotopy.trans_apply _ _ _
theorem symm_trans {f₀ f₁ f₂ : C(X, Y)} (F : HomotopyWith f₀ f₁ P) (G : HomotopyWith f₁ f₂ P) :
(F.trans G).symm = G.symm.trans F.symm :=
ext <| Homotopy.congr_fun <| Homotopy.symm_trans _ _
/-- Casting a `HomotopyWith f₀ f₁ P` to a `HomotopyWith g₀ g₁ P` where `f₀ = g₀` and `f₁ = g₁`.
-/
@[simps!]
def cast {f₀ f₁ g₀ g₁ : C(X, Y)} (F : HomotopyWith f₀ f₁ P) (h₀ : f₀ = g₀) (h₁ : f₁ = g₁) :
HomotopyWith g₀ g₁ P where
toHomotopy := F.toHomotopy.cast h₀ h₁
prop' := F.prop
end HomotopyWith
/-- Given continuous maps `f₀` and `f₁`, we say `f₀` and `f₁` are homotopic with respect to the
predicate `P` if there exists a `HomotopyWith f₀ f₁ P`.
-/
def HomotopicWith (f₀ f₁ : C(X, Y)) (P : C(X, Y) → Prop) : Prop :=
Nonempty (HomotopyWith f₀ f₁ P)
namespace HomotopicWith
variable {P : C(X, Y) → Prop}
-- Porting note: removed @[refl]
theorem refl (f : C(X, Y)) (hf : P f) : HomotopicWith f f P :=
⟨HomotopyWith.refl f hf⟩
@[symm]
theorem symm ⦃f g : C(X, Y)⦄ (h : HomotopicWith f g P) : HomotopicWith g f P :=
⟨h.some.symm⟩
-- Note: this was formerly tagged with `@[trans]`, and although the `trans` attribute accepted it
-- the `trans` tactic could not use it.
-- An update to the trans tactic coming in https://github.com/leanprover-community/mathlib4/pull/7014 will reject this attribute.
-- It could be restored by changing the argument order to `HomotopicWith P f g`.
@[trans]
theorem trans ⦃f g h : C(X, Y)⦄ (h₀ : HomotopicWith f g P) (h₁ : HomotopicWith g h P) :
HomotopicWith f h P :=
⟨h₀.some.trans h₁.some⟩
end HomotopicWith
/--
A `HomotopyRel f₀ f₁ S` is a homotopy between `f₀` and `f₁` which is fixed on the points in `S`.
-/
abbrev HomotopyRel (f₀ f₁ : C(X, Y)) (S : Set X) :=
HomotopyWith f₀ f₁ fun f ↦ ∀ x ∈ S, f x = f₀ x
namespace HomotopyRel
section
variable {f₀ f₁ : C(X, Y)} {S : Set X}
theorem eq_fst (F : HomotopyRel f₀ f₁ S) (t : I) {x : X} (hx : x ∈ S) : F (t, x) = f₀ x :=
F.prop t x hx
theorem eq_snd (F : HomotopyRel f₀ f₁ S) (t : I) {x : X} (hx : x ∈ S) : F (t, x) = f₁ x := by
rw [F.eq_fst t hx, ← F.eq_fst 1 hx, F.apply_one]
theorem fst_eq_snd (F : HomotopyRel f₀ f₁ S) {x : X} (hx : x ∈ S) : f₀ x = f₁ x :=
F.eq_fst 0 hx ▸ F.eq_snd 0 hx
end
variable {f₀ f₁ f₂ : C(X, Y)} {S : Set X}
/-- Given a map `f : C(X, Y)` and a set `S`, we can define a `HomotopyRel f f S` by setting
`F (t, x) = f x` for all `t`. This is defined using `HomotopyWith.refl`, but with the proof
filled in.
-/
@[simps!]
def refl (f : C(X, Y)) (S : Set X) : HomotopyRel f f S :=
HomotopyWith.refl f fun _ _ ↦ rfl
/--
Given a `HomotopyRel f₀ f₁ S`, we can define a `HomotopyRel f₁ f₀ S` by reversing the homotopy.
-/
@[simps!]
def symm (F : HomotopyRel f₀ f₁ S) : HomotopyRel f₁ f₀ S where
toHomotopy := F.toHomotopy.symm
prop' := fun _ _ hx ↦ F.eq_snd _ hx
@[simp]
theorem symm_symm (F : HomotopyRel f₀ f₁ S) : F.symm.symm = F :=
HomotopyWith.symm_symm F
theorem symm_bijective :
Function.Bijective (HomotopyRel.symm : HomotopyRel f₀ f₁ S → HomotopyRel f₁ f₀ S) :=
Function.bijective_iff_has_inverse.mpr ⟨_, symm_symm, symm_symm⟩
/-- Given `HomotopyRel f₀ f₁ S` and `HomotopyRel f₁ f₂ S`, we can define a `HomotopyRel f₀ f₂ S`
by putting the first homotopy on `[0, 1/2]` and the second on `[1/2, 1]`.
-/
def trans (F : HomotopyRel f₀ f₁ S) (G : HomotopyRel f₁ f₂ S) : HomotopyRel f₀ f₂ S where
toHomotopy := F.toHomotopy.trans G.toHomotopy
prop' t x hx := by
simp only [Homotopy.trans]
split_ifs
· simp [HomotopyWith.extendProp F (2 * t) x hx, F.fst_eq_snd hx, G.fst_eq_snd hx]
· simp [HomotopyWith.extendProp G (2 * t - 1) x hx, F.fst_eq_snd hx, G.fst_eq_snd hx]
theorem trans_apply (F : HomotopyRel f₀ f₁ S) (G : HomotopyRel f₁ f₂ S) (x : I × X) :
(F.trans G) x =
if h : (x.1 : ℝ) ≤ 1 / 2 then
F (⟨2 * x.1, (unitInterval.mul_pos_mem_iff zero_lt_two).2 ⟨x.1.2.1, h⟩⟩, x.2)
else
G (⟨2 * x.1 - 1, unitInterval.two_mul_sub_one_mem_iff.2 ⟨(not_le.1 h).le, x.1.2.2⟩⟩, x.2) :=
Homotopy.trans_apply _ _ _
theorem symm_trans (F : HomotopyRel f₀ f₁ S) (G : HomotopyRel f₁ f₂ S) :
(F.trans G).symm = G.symm.trans F.symm :=
HomotopyWith.ext <| Homotopy.congr_fun <| Homotopy.symm_trans _ _
/-- Casting a `HomotopyRel f₀ f₁ S` to a `HomotopyRel g₀ g₁ S` where `f₀ = g₀` and `f₁ = g₁`.
-/
@[simps!]
def cast {f₀ f₁ g₀ g₁ : C(X, Y)} (F : HomotopyRel f₀ f₁ S) (h₀ : f₀ = g₀) (h₁ : f₁ = g₁) :
HomotopyRel g₀ g₁ S where
toHomotopy := Homotopy.cast F.toHomotopy h₀ h₁
prop' t x hx := by simpa only [← h₀, ← h₁] using F.prop t x hx
/-- Post-compose a homotopy relative to a set by a continuous function. -/
@[simps!] def compContinuousMap {f₀ f₁ : C(X, Y)} (F : f₀.HomotopyRel f₁ S) (g : C(Y, Z)) :
(g.comp f₀).HomotopyRel (g.comp f₁) S where
toHomotopy := F.hcomp (ContinuousMap.Homotopy.refl g)
prop' t x hx := congr_arg g (F.prop t x hx)
end HomotopyRel
/-- Given continuous maps `f₀` and `f₁`, we say `f₀` and `f₁` are homotopic relative to a set `S` if
there exists a `HomotopyRel f₀ f₁ S`.
-/
def HomotopicRel (f₀ f₁ : C(X, Y)) (S : Set X) : Prop :=
Nonempty (HomotopyRel f₀ f₁ S)
namespace HomotopicRel
variable {S : Set X}
/-- If two maps are homotopic relative to a set, then they are homotopic. -/
protected theorem homotopic {f₀ f₁ : C(X, Y)} (h : HomotopicRel f₀ f₁ S) : Homotopic f₀ f₁ :=
h.map fun F ↦ F.1
-- Porting note: removed @[refl]
theorem refl (f : C(X, Y)) : HomotopicRel f f S :=
⟨HomotopyRel.refl f S⟩
@[symm]
theorem symm ⦃f g : C(X, Y)⦄ (h : HomotopicRel f g S) : HomotopicRel g f S :=
h.map HomotopyRel.symm
@[trans]
theorem trans ⦃f g h : C(X, Y)⦄ (h₀ : HomotopicRel f g S) (h₁ : HomotopicRel g h S) :
HomotopicRel f h S :=
h₀.map2 HomotopyRel.trans h₁
theorem equivalence : Equivalence fun f g : C(X, Y) => HomotopicRel f g S :=
⟨refl, by apply symm, by apply trans⟩
theorem comp_continuousMap ⦃f₀ f₁ : C(X, Y)⦄ (h : f₀.HomotopicRel f₁ S) (g : C(Y, Z)) :
(g.comp f₀).HomotopicRel (g.comp f₁) S := h.map (·.compContinuousMap g)
end HomotopicRel
@[simp] theorem homotopicRel_empty {f₀ f₁ : C(X, Y)} : HomotopicRel f₀ f₁ ∅ ↔ Homotopic f₀ f₁ :=
⟨fun h ↦ h.homotopic, fun ⟨F⟩ ↦ ⟨⟨F, fun _ _ ↦ False.elim⟩⟩⟩
end ContinuousMap
| Mathlib/Topology/Homotopy/Basic.lean | 713 | 714 | |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes
-/
import Mathlib.Algebra.CharP.Two
import Mathlib.Data.Nat.Cast.Field
import Mathlib.Data.Nat.Factorization.Basic
import Mathlib.Data.Nat.Factorization.Induction
import Mathlib.Data.Nat.Periodic
/-!
# Euler's totient function
This file defines [Euler's totient function](https://en.wikipedia.org/wiki/Euler's_totient_function)
`Nat.totient n` which counts the number of naturals less than `n` that are coprime with `n`.
We prove the divisor sum formula, namely that `n` equals `φ` summed over the divisors of `n`. See
`sum_totient`. We also prove two lemmas to help compute totients, namely `totient_mul` and
`totient_prime_pow`.
-/
assert_not_exists Algebra LinearMap
open Finset
namespace Nat
/-- Euler's totient function. This counts the number of naturals strictly less than `n` which are
coprime with `n`. -/
def totient (n : ℕ) : ℕ := #{a ∈ range n | n.Coprime a}
@[inherit_doc]
scoped notation "φ" => Nat.totient
@[simp]
theorem totient_zero : φ 0 = 0 :=
rfl
@[simp]
theorem totient_one : φ 1 = 1 := rfl
theorem totient_eq_card_coprime (n : ℕ) : φ n = #{a ∈ range n | n.Coprime a} := rfl
/-- A characterisation of `Nat.totient` that avoids `Finset`. -/
theorem totient_eq_card_lt_and_coprime (n : ℕ) : φ n = Nat.card { m | m < n ∧ n.Coprime m } := by
let e : { m | m < n ∧ n.Coprime m } ≃ {x ∈ range n | n.Coprime x} :=
{ toFun := fun m => ⟨m, by simpa only [Finset.mem_filter, Finset.mem_range] using m.property⟩
invFun := fun m => ⟨m, by simpa only [Finset.mem_filter, Finset.mem_range] using m.property⟩
left_inv := fun m => by simp only [Subtype.coe_mk, Subtype.coe_eta]
right_inv := fun m => by simp only [Subtype.coe_mk, Subtype.coe_eta] }
rw [totient_eq_card_coprime, card_congr e, card_eq_fintype_card, Fintype.card_coe]
theorem totient_le (n : ℕ) : φ n ≤ n :=
((range n).card_filter_le _).trans_eq (card_range n)
theorem totient_lt (n : ℕ) (hn : 1 < n) : φ n < n :=
(card_lt_card (filter_ssubset.2 ⟨0, by simp [hn.ne', pos_of_gt hn]⟩)).trans_eq (card_range n)
@[simp]
theorem totient_eq_zero : ∀ {n : ℕ}, φ n = 0 ↔ n = 0
| 0 => by decide
| n + 1 =>
suffices ∃ x < n + 1, (n + 1).gcd x = 1 by simpa [totient, filter_eq_empty_iff]
⟨1 % (n + 1), mod_lt _ n.succ_pos, by rw [gcd_comm, ← gcd_rec, gcd_one_right]⟩
@[simp] theorem totient_pos {n : ℕ} : 0 < φ n ↔ 0 < n := by simp [pos_iff_ne_zero]
instance neZero_totient {n : ℕ} [NeZero n] : NeZero n.totient :=
⟨(totient_pos.mpr <| NeZero.pos n).ne'⟩
theorem filter_coprime_Ico_eq_totient (a n : ℕ) :
#{x ∈ Ico n (n + a) | a.Coprime x} = totient a := by
rw [totient, filter_Ico_card_eq_of_periodic, count_eq_card_filter_range]
exact periodic_coprime a
theorem Ico_filter_coprime_le {a : ℕ} (k n : ℕ) (a_pos : 0 < a) :
#{x ∈ Ico k (k + n) | a.Coprime x} ≤ totient a * (n / a + 1) := by
conv_lhs => rw [← Nat.mod_add_div n a]
induction' n / a with i ih
· rw [← filter_coprime_Ico_eq_totient a k]
simp only [add_zero, mul_one, mul_zero, le_of_lt (mod_lt n a_pos), zero_add]
gcongr
exact le_of_lt (mod_lt n a_pos)
simp only [mul_succ]
simp_rw [← add_assoc] at ih ⊢
calc
#{x ∈ Ico k (k + n % a + a * i + a) | a.Coprime x}
≤ #{x ∈ Ico k (k + n % a + a * i) ∪
Ico (k + n % a + a * i) (k + n % a + a * i + a) | a.Coprime x} := by
gcongr
apply Ico_subset_Ico_union_Ico
_ ≤ #{x ∈ Ico k (k + n % a + a * i) | a.Coprime x} + a.totient := by
rw [filter_union, ← filter_coprime_Ico_eq_totient a (k + n % a + a * i)]
apply card_union_le
_ ≤ a.totient * i + a.totient + a.totient := add_le_add_right ih (totient a)
open ZMod
/-- Note this takes an explicit `Fintype ((ZMod n)ˣ)` argument to avoid trouble with instance
diamonds. -/
@[simp]
theorem _root_.ZMod.card_units_eq_totient (n : ℕ) [NeZero n] [Fintype (ZMod n)ˣ] :
Fintype.card (ZMod n)ˣ = φ n :=
calc
Fintype.card (ZMod n)ˣ = Fintype.card { x : ZMod n // x.val.Coprime n } :=
Fintype.card_congr ZMod.unitsEquivCoprime
_ = φ n := by
obtain ⟨m, rfl⟩ : ∃ m, n = m + 1 := exists_eq_succ_of_ne_zero NeZero.out
simp only [totient, Finset.card_eq_sum_ones, Fintype.card_subtype, Finset.sum_filter, ←
Fin.sum_univ_eq_sum_range, @Nat.coprime_comm (m + 1)]
rfl
theorem totient_even {n : ℕ} (hn : 2 < n) : Even n.totient := by
haveI : Fact (1 < n) := ⟨one_lt_two.trans hn⟩
haveI : NeZero n := NeZero.of_gt hn
suffices 2 = orderOf (-1 : (ZMod n)ˣ) by
rw [← ZMod.card_units_eq_totient, even_iff_two_dvd, this]
exact orderOf_dvd_card
rw [← orderOf_units, Units.coe_neg_one, orderOf_neg_one, ringChar.eq (ZMod n) n, if_neg hn.ne']
theorem totient_mul {m n : ℕ} (h : m.Coprime n) : φ (m * n) = φ m * φ n :=
if hmn0 : m * n = 0 then by
rcases Nat.mul_eq_zero.1 hmn0 with h | h <;>
simp only [totient_zero, mul_zero, zero_mul, h]
else by
haveI : NeZero (m * n) := ⟨hmn0⟩
haveI : NeZero m := ⟨left_ne_zero_of_mul hmn0⟩
haveI : NeZero n := ⟨right_ne_zero_of_mul hmn0⟩
simp only [← ZMod.card_units_eq_totient]
rw [Fintype.card_congr (Units.mapEquiv (ZMod.chineseRemainder h).toMulEquiv).toEquiv,
Fintype.card_congr (@MulEquiv.prodUnits (ZMod m) (ZMod n) _ _).toEquiv, Fintype.card_prod]
/-- For `d ∣ n`, the totient of `n/d` equals the number of values `k < n` such that `gcd n k = d` -/
| theorem totient_div_of_dvd {n d : ℕ} (hnd : d ∣ n) :
φ (n / d) = #{k ∈ range n | n.gcd k = d} := by
rcases d.eq_zero_or_pos with (rfl | hd0); · simp [eq_zero_of_zero_dvd hnd]
rcases hnd with ⟨x, rfl⟩
rw [Nat.mul_div_cancel_left x hd0]
apply Finset.card_bij fun k _ => d * k
· simp only [mem_filter, mem_range, and_imp, Coprime]
refine fun a ha1 ha2 => ⟨(mul_lt_mul_left hd0).2 ha1, ?_⟩
rw [gcd_mul_left, ha2, mul_one]
· simp [hd0.ne']
· simp only [mem_filter, mem_range, exists_prop, and_imp]
| Mathlib/Data/Nat/Totient.lean | 134 | 144 |
/-
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
| Mathlib/MeasureTheory/Function/SimpleFunc.lean | 1,018 | 1,022 |
/-
Copyright (c) 2019 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov, Sébastien Gouëzel, Rémy Degenne
-/
import Mathlib.Algebra.BigOperators.Expect
import Mathlib.Algebra.BigOperators.Field
import Mathlib.Analysis.Convex.Jensen
import Mathlib.Analysis.Convex.SpecificFunctions.Basic
import Mathlib.Analysis.SpecialFunctions.Pow.NNReal
import Mathlib.Data.Real.ConjExponents
/-!
# Mean value inequalities
In this file we prove several inequalities for finite sums, including AM-GM inequality,
HM-GM inequality, Young's inequality, Hölder inequality, and Minkowski inequality. Versions for
integrals of some of these inequalities are available in
`Mathlib.MeasureTheory.Integral.MeanInequalities`.
## Main theorems
### AM-GM inequality:
The inequality says that the geometric mean of a tuple of non-negative numbers is less than or equal
to their arithmetic mean. We prove the weighted version of this inequality: if $w$ and $z$
are two non-negative vectors and $\sum_{i\in s} w_i=1$, then
$$
\prod_{i\in s} z_i^{w_i} ≤ \sum_{i\in s} w_iz_i.
$$
The classical version is a special case of this inequality for $w_i=\frac{1}{n}$.
We prove a few versions of this inequality. Each of the following lemmas comes in two versions:
a version for real-valued non-negative functions is in the `Real` namespace, and a version for
`NNReal`-valued functions is in the `NNReal` namespace.
- `geom_mean_le_arith_mean_weighted` : weighted version for functions on `Finset`s;
- `geom_mean_le_arith_mean2_weighted` : weighted version for two numbers;
- `geom_mean_le_arith_mean3_weighted` : weighted version for three numbers;
- `geom_mean_le_arith_mean4_weighted` : weighted version for four numbers.
### HM-GM inequality:
The inequality says that the harmonic mean of a tuple of positive numbers is less than or equal
to their geometric mean. We prove the weighted version of this inequality: if $w$ and $z$
are two positive vectors and $\sum_{i\in s} w_i=1$, then
$$
1/(\sum_{i\in s} w_i/z_i) ≤ \prod_{i\in s} z_i^{w_i}
$$
The classical version is proven as a special case of this inequality for $w_i=\frac{1}{n}$.
The inequalities are proven only for real valued positive functions on `Finset`s, and namespaced in
`Real`. The weighted version follows as a corollary of the weighted AM-GM inequality.
### Young's inequality
Young's inequality says that for non-negative numbers `a`, `b`, `p`, `q` such that
$\frac{1}{p}+\frac{1}{q}=1$ we have
$$
ab ≤ \frac{a^p}{p} + \frac{b^q}{q}.
$$
This inequality is a special case of the AM-GM inequality. It is then used to prove Hölder's
inequality (see below).
### Hölder's inequality
The inequality says that for two conjugate exponents `p` and `q` (i.e., for two positive numbers
such that $\frac{1}{p}+\frac{1}{q}=1$) and any two non-negative vectors their inner product is
less than or equal to the product of the $L_p$ norm of the first vector and the $L_q$ norm of the
second vector:
$$
\sum_{i\in s} a_ib_i ≤ \sqrt[p]{\sum_{i\in s} a_i^p}\sqrt[q]{\sum_{i\in s} b_i^q}.
$$
We give versions of this result in `ℝ`, `ℝ≥0` and `ℝ≥0∞`.
There are at least two short proofs of this inequality. In our proof we prenormalize both vectors,
then apply Young's inequality to each $a_ib_i$. Another possible proof would be to deduce this
inequality from the generalized mean inequality for well-chosen vectors and weights.
### Minkowski's inequality
The inequality says that for `p ≥ 1` the function
$$
\|a\|_p=\sqrt[p]{\sum_{i\in s} a_i^p}
$$
satisfies the triangle inequality $\|a+b\|_p\le \|a\|_p+\|b\|_p$.
We give versions of this result in `Real`, `ℝ≥0` and `ℝ≥0∞`.
We deduce this inequality from Hölder's inequality. Namely, Hölder inequality implies that $\|a\|_p$
is the maximum of the inner product $\sum_{i\in s}a_ib_i$ over `b` such that $\|b\|_q\le 1$. Now
Minkowski's inequality follows from the fact that the maximum value of the sum of two functions is
less than or equal to the sum of the maximum values of the summands.
## TODO
- each inequality `A ≤ B` should come with a theorem `A = B ↔ _`; one of the ways to prove them
is to define `StrictConvexOn` functions.
- generalized mean inequality with any `p ≤ q`, including negative numbers;
- prove that the power mean tends to the geometric mean as the exponent tends to zero.
-/
universe u v
open Finset NNReal ENNReal
open scoped BigOperators
noncomputable section
variable {ι : Type u} (s : Finset ι)
section GeomMeanLEArithMean
/-! ### AM-GM inequality -/
namespace Real
/-- **AM-GM inequality**: The geometric mean is less than or equal to the arithmetic mean, weighted
version for real-valued nonnegative functions. -/
theorem geom_mean_le_arith_mean_weighted (w z : ι → ℝ) (hw : ∀ i ∈ s, 0 ≤ w i)
(hw' : ∑ i ∈ s, w i = 1) (hz : ∀ i ∈ s, 0 ≤ z i) :
∏ i ∈ s, z i ^ w i ≤ ∑ i ∈ s, w i * z i := by
-- If some number `z i` equals zero and has non-zero weight, then LHS is 0 and RHS is nonnegative.
by_cases A : ∃ i ∈ s, z i = 0 ∧ w i ≠ 0
· rcases A with ⟨i, his, hzi, hwi⟩
rw [prod_eq_zero his]
· exact sum_nonneg fun j hj => mul_nonneg (hw j hj) (hz j hj)
· rw [hzi]
exact zero_rpow hwi
-- If all numbers `z i` with non-zero weight are positive, then we apply Jensen's inequality
-- for `exp` and numbers `log (z i)` with weights `w i`.
· simp only [not_exists, not_and, Ne, Classical.not_not] at A
have := convexOn_exp.map_sum_le hw hw' fun i _ => Set.mem_univ <| log (z i)
simp only [exp_sum, smul_eq_mul, mul_comm (w _) (log _)] at this
convert this using 1 <;> [apply prod_congr rfl;apply sum_congr rfl] <;> intro i hi
· rcases eq_or_lt_of_le (hz i hi) with hz | hz
· simp [A i hi hz.symm]
· exact rpow_def_of_pos hz _
· rcases eq_or_lt_of_le (hz i hi) with hz | hz
· simp [A i hi hz.symm]
· rw [exp_log hz]
/-- **AM-GM inequality**: The **geometric mean is less than or equal to the arithmetic mean. -/
theorem geom_mean_le_arith_mean {ι : Type*} (s : Finset ι) (w : ι → ℝ) (z : ι → ℝ)
(hw : ∀ i ∈ s, 0 ≤ w i) (hw' : 0 < ∑ i ∈ s, w i) (hz : ∀ i ∈ s, 0 ≤ z i) :
(∏ i ∈ s, z i ^ w i) ^ (∑ i ∈ s, w i)⁻¹ ≤ (∑ i ∈ s, w i * z i) / (∑ i ∈ s, w i) := by
convert geom_mean_le_arith_mean_weighted s (fun i => (w i) / ∑ i ∈ s, w i) z ?_ ?_ hz using 2
· rw [← finset_prod_rpow _ _ (fun i hi => rpow_nonneg (hz _ hi) _) _]
refine Finset.prod_congr rfl (fun _ ih => ?_)
rw [div_eq_mul_inv, rpow_mul (hz _ ih)]
· simp_rw [div_eq_mul_inv, mul_assoc, mul_comm, ← mul_assoc, ← Finset.sum_mul, mul_comm]
· exact fun _ hi => div_nonneg (hw _ hi) (le_of_lt hw')
· simp_rw [div_eq_mul_inv, ← Finset.sum_mul]
exact mul_inv_cancel₀ (by linarith)
theorem geom_mean_weighted_of_constant (w z : ι → ℝ) (x : ℝ) (hw : ∀ i ∈ s, 0 ≤ w i)
(hw' : ∑ i ∈ s, w i = 1) (hz : ∀ i ∈ s, 0 ≤ z i) (hx : ∀ i ∈ s, w i ≠ 0 → z i = x) :
∏ i ∈ s, z i ^ w i = x :=
calc
∏ i ∈ s, z i ^ w i = ∏ i ∈ s, x ^ w i := by
refine prod_congr rfl fun i hi => ?_
rcases eq_or_ne (w i) 0 with h₀ | h₀
· rw [h₀, rpow_zero, rpow_zero]
· rw [hx i hi h₀]
_ = x := by
rw [← rpow_sum_of_nonneg _ hw, hw', rpow_one]
have : (∑ i ∈ s, w i) ≠ 0 := by
rw [hw']
exact one_ne_zero
obtain ⟨i, his, hi⟩ := exists_ne_zero_of_sum_ne_zero this
rw [← hx i his hi]
exact hz i his
theorem arith_mean_weighted_of_constant (w z : ι → ℝ) (x : ℝ) (hw' : ∑ i ∈ s, w i = 1)
(hx : ∀ i ∈ s, w i ≠ 0 → z i = x) : ∑ i ∈ s, w i * z i = x :=
calc
∑ i ∈ s, w i * z i = ∑ i ∈ s, w i * x := by
refine sum_congr rfl fun i hi => ?_
rcases eq_or_ne (w i) 0 with hwi | hwi
· rw [hwi, zero_mul, zero_mul]
· rw [hx i hi hwi]
_ = x := by rw [← sum_mul, hw', one_mul]
theorem geom_mean_eq_arith_mean_weighted_of_constant (w z : ι → ℝ) (x : ℝ) (hw : ∀ i ∈ s, 0 ≤ w i)
(hw' : ∑ i ∈ s, w i = 1) (hz : ∀ i ∈ s, 0 ≤ z i) (hx : ∀ i ∈ s, w i ≠ 0 → z i = x) :
∏ i ∈ s, z i ^ w i = ∑ i ∈ s, w i * z i := by
rw [geom_mean_weighted_of_constant, arith_mean_weighted_of_constant] <;> assumption
/-- **AM-GM inequality - equality condition**: This theorem provides the equality condition for the
*positive* weighted version of the AM-GM inequality for real-valued nonnegative functions. -/
theorem geom_mean_eq_arith_mean_weighted_iff' (w z : ι → ℝ) (hw : ∀ i ∈ s, 0 < w i)
(hw' : ∑ i ∈ s, w i = 1) (hz : ∀ i ∈ s, 0 ≤ z i) :
∏ i ∈ s, z i ^ w i = ∑ i ∈ s, w i * z i ↔ ∀ j ∈ s, z j = ∑ i ∈ s, w i * z i := by
by_cases A : ∃ i ∈ s, z i = 0 ∧ w i ≠ 0
· rcases A with ⟨i, his, hzi, hwi⟩
rw [prod_eq_zero his]
· constructor
· intro h
rw [← h]
intro j hj
apply eq_zero_of_ne_zero_of_mul_left_eq_zero (ne_of_lt (hw j hj)).symm
apply (sum_eq_zero_iff_of_nonneg ?_).mp h.symm j hj
exact fun i hi => (mul_nonneg_iff_of_pos_left (hw i hi)).mpr (hz i hi)
· intro h
convert h i his
exact hzi.symm
· rw [hzi]
exact zero_rpow hwi
· simp only [not_exists, not_and] at A
have hz' := fun i h => lt_of_le_of_ne (hz i h) (fun a => (A i h a.symm) (ne_of_gt (hw i h)))
have := strictConvexOn_exp.map_sum_eq_iff hw hw' fun i _ => Set.mem_univ <| log (z i)
simp only [exp_sum, smul_eq_mul, mul_comm (w _) (log _)] at this
convert this using 1
· apply Eq.congr <;>
[apply prod_congr rfl; apply sum_congr rfl] <;>
intro i hi <;>
simp only [exp_mul, exp_log (hz' i hi)]
· constructor <;> intro h j hj
· rw [← arith_mean_weighted_of_constant s w _ (log (z j)) hw' fun i _ => congrFun rfl]
apply sum_congr rfl
intro x hx
simp only [mul_comm, h j hj, h x hx]
· rw [← arith_mean_weighted_of_constant s w _ (z j) hw' fun i _ => congrFun rfl]
apply sum_congr rfl
intro x hx
simp only [log_injOn_pos (hz' j hj) (hz' x hx), h j hj, h x hx]
/-- **AM-GM inequality - equality condition**: This theorem provides the equality condition for the
weighted version of the AM-GM inequality for real-valued nonnegative functions. -/
theorem geom_mean_eq_arith_mean_weighted_iff (w z : ι → ℝ) (hw : ∀ i ∈ s, 0 ≤ w i)
(hw' : ∑ i ∈ s, w i = 1) (hz : ∀ i ∈ s, 0 ≤ z i) :
∏ i ∈ s, z i ^ w i = ∑ i ∈ s, w i * z i ↔ ∀ j ∈ s, w j ≠ 0 → z j = ∑ i ∈ s, w i * z i := by
have h (i) (_ : i ∈ s) : w i * z i ≠ 0 → w i ≠ 0 := by apply left_ne_zero_of_mul
have h' (i) (_ : i ∈ s) : z i ^ w i ≠ 1 → w i ≠ 0 := by
by_contra!
obtain ⟨h1, h2⟩ := this
simp only [h2, rpow_zero, ne_self_iff_false] at h1
rw [← sum_filter_of_ne h, ← prod_filter_of_ne h', geom_mean_eq_arith_mean_weighted_iff']
· simp
· simp +contextual [(hw _ _).gt_iff_ne]
· rwa [sum_filter_ne_zero]
· simp_all only [ne_eq, mul_eq_zero, not_or, not_false_eq_true, and_imp, implies_true, mem_filter]
/-- **AM-GM inequality - strict inequality condition**: This theorem provides the strict inequality
condition for the *positive* weighted version of the AM-GM inequality for real-valued nonnegative
functions. -/
theorem geom_mean_lt_arith_mean_weighted_iff_of_pos (w z : ι → ℝ) (hw : ∀ i ∈ s, 0 < w i)
(hw' : ∑ i ∈ s, w i = 1) (hz : ∀ i ∈ s, 0 ≤ z i) :
∏ i ∈ s, z i ^ w i < ∑ i ∈ s, w i * z i ↔ ∃ j ∈ s, ∃ k ∈ s, z j ≠ z k:= by
constructor
· intro h
by_contra! h_contra
rw [(geom_mean_eq_arith_mean_weighted_iff' s w z hw hw' hz).mpr ?_] at h
· exact (lt_self_iff_false _).mp h
· intro j hjs
rw [← arith_mean_weighted_of_constant s w (fun _ => z j) (z j) hw' fun _ _ => congrFun rfl]
apply sum_congr rfl (fun x a => congrArg (HMul.hMul (w x)) (h_contra j hjs x a))
· rintro ⟨j, hjs, k, hks, hzjk⟩
have := geom_mean_le_arith_mean_weighted s w z (fun i a => le_of_lt (hw i a)) hw' hz
by_contra! h
apply le_antisymm this at h
apply (geom_mean_eq_arith_mean_weighted_iff' s w z hw hw' hz).mp at h
simp only [h j hjs, h k hks, ne_eq, not_true_eq_false] at hzjk
end Real
namespace NNReal
/-- **AM-GM inequality**: The geometric mean is less than or equal to the arithmetic mean, weighted
version for `NNReal`-valued functions. -/
theorem geom_mean_le_arith_mean_weighted (w z : ι → ℝ≥0) (hw' : ∑ i ∈ s, w i = 1) :
(∏ i ∈ s, z i ^ (w i : ℝ)) ≤ ∑ i ∈ s, w i * z i :=
mod_cast
Real.geom_mean_le_arith_mean_weighted _ _ _ (fun i _ => (w i).coe_nonneg)
(by assumption_mod_cast) fun i _ => (z i).coe_nonneg
/-- **AM-GM inequality**: The geometric mean is less than or equal to the arithmetic mean, weighted
version for two `NNReal` numbers. -/
theorem geom_mean_le_arith_mean2_weighted (w₁ w₂ p₁ p₂ : ℝ≥0) :
w₁ + w₂ = 1 → p₁ ^ (w₁ : ℝ) * p₂ ^ (w₂ : ℝ) ≤ w₁ * p₁ + w₂ * p₂ := by
simpa only [Fin.prod_univ_succ, Fin.sum_univ_succ, Finset.prod_empty, Finset.sum_empty,
Finset.univ_eq_empty, Fin.cons_succ, Fin.cons_zero, add_zero, mul_one] using
geom_mean_le_arith_mean_weighted univ ![w₁, w₂] ![p₁, p₂]
theorem geom_mean_le_arith_mean3_weighted (w₁ w₂ w₃ p₁ p₂ p₃ : ℝ≥0) :
w₁ + w₂ + w₃ = 1 →
p₁ ^ (w₁ : ℝ) * p₂ ^ (w₂ : ℝ) * p₃ ^ (w₃ : ℝ) ≤ w₁ * p₁ + w₂ * p₂ + w₃ * p₃ := by
simpa only [Fin.prod_univ_succ, Fin.sum_univ_succ, Finset.prod_empty, Finset.sum_empty,
Finset.univ_eq_empty, Fin.cons_succ, Fin.cons_zero, add_zero, mul_one, ← add_assoc,
mul_assoc] using geom_mean_le_arith_mean_weighted univ ![w₁, w₂, w₃] ![p₁, p₂, p₃]
theorem geom_mean_le_arith_mean4_weighted (w₁ w₂ w₃ w₄ p₁ p₂ p₃ p₄ : ℝ≥0) :
w₁ + w₂ + w₃ + w₄ = 1 →
p₁ ^ (w₁ : ℝ) * p₂ ^ (w₂ : ℝ) * p₃ ^ (w₃ : ℝ) * p₄ ^ (w₄ : ℝ) ≤
w₁ * p₁ + w₂ * p₂ + w₃ * p₃ + w₄ * p₄ := by
simpa only [Fin.prod_univ_succ, Fin.sum_univ_succ, Finset.prod_empty, Finset.sum_empty,
Finset.univ_eq_empty, Fin.cons_succ, Fin.cons_zero, add_zero, mul_one, ← add_assoc,
mul_assoc] using geom_mean_le_arith_mean_weighted univ ![w₁, w₂, w₃, w₄] ![p₁, p₂, p₃, p₄]
end NNReal
namespace Real
theorem geom_mean_le_arith_mean2_weighted {w₁ w₂ p₁ p₂ : ℝ} (hw₁ : 0 ≤ w₁) (hw₂ : 0 ≤ w₂)
(hp₁ : 0 ≤ p₁) (hp₂ : 0 ≤ p₂) (hw : w₁ + w₂ = 1) : p₁ ^ w₁ * p₂ ^ w₂ ≤ w₁ * p₁ + w₂ * p₂ :=
NNReal.geom_mean_le_arith_mean2_weighted ⟨w₁, hw₁⟩ ⟨w₂, hw₂⟩ ⟨p₁, hp₁⟩ ⟨p₂, hp₂⟩ <|
NNReal.coe_inj.1 <| by assumption
theorem geom_mean_le_arith_mean3_weighted {w₁ w₂ w₃ p₁ p₂ p₃ : ℝ} (hw₁ : 0 ≤ w₁) (hw₂ : 0 ≤ w₂)
(hw₃ : 0 ≤ w₃) (hp₁ : 0 ≤ p₁) (hp₂ : 0 ≤ p₂) (hp₃ : 0 ≤ p₃) (hw : w₁ + w₂ + w₃ = 1) :
p₁ ^ w₁ * p₂ ^ w₂ * p₃ ^ w₃ ≤ w₁ * p₁ + w₂ * p₂ + w₃ * p₃ :=
NNReal.geom_mean_le_arith_mean3_weighted ⟨w₁, hw₁⟩ ⟨w₂, hw₂⟩ ⟨w₃, hw₃⟩ ⟨p₁, hp₁⟩ ⟨p₂, hp₂⟩
⟨p₃, hp₃⟩ <|
NNReal.coe_inj.1 hw
theorem geom_mean_le_arith_mean4_weighted {w₁ w₂ w₃ w₄ p₁ p₂ p₃ p₄ : ℝ} (hw₁ : 0 ≤ w₁)
(hw₂ : 0 ≤ w₂) (hw₃ : 0 ≤ w₃) (hw₄ : 0 ≤ w₄) (hp₁ : 0 ≤ p₁) (hp₂ : 0 ≤ p₂) (hp₃ : 0 ≤ p₃)
(hp₄ : 0 ≤ p₄) (hw : w₁ + w₂ + w₃ + w₄ = 1) :
p₁ ^ w₁ * p₂ ^ w₂ * p₃ ^ w₃ * p₄ ^ w₄ ≤ w₁ * p₁ + w₂ * p₂ + w₃ * p₃ + w₄ * p₄ :=
NNReal.geom_mean_le_arith_mean4_weighted ⟨w₁, hw₁⟩ ⟨w₂, hw₂⟩ ⟨w₃, hw₃⟩ ⟨w₄, hw₄⟩ ⟨p₁, hp₁⟩
⟨p₂, hp₂⟩ ⟨p₃, hp₃⟩ ⟨p₄, hp₄⟩ <|
NNReal.coe_inj.1 <| by assumption
/-- As an example application of AM-GM we prove that the **Motzkin polynomial** is nonnegative.
This bivariate polynomial cannot be written as a sum of squares. -/
lemma motzkin_polynomial_nonneg (x y : ℝ) :
0 ≤ x ^ 4 * y ^ 2 + x ^ 2 * y ^ 4 - 3 * x ^ 2 * y ^ 2 + 1 := by
have nn₁ : 0 ≤ x ^ 4 * y ^ 2 := by positivity
have nn₂ : 0 ≤ x ^ 2 * y ^ 4 := by positivity
have key := geom_mean_le_arith_mean3_weighted (by norm_num) (by norm_num) (by norm_num)
nn₁ nn₂ zero_le_one (add_thirds 1)
rw [one_rpow, mul_one, ← mul_rpow nn₁ nn₂, ← mul_add, ← mul_add,
show x ^ 4 * y ^ 2 * (x ^ 2 * y ^ 4) = (x ^ 2) ^ 3 * (y ^ 2) ^ 3 by ring,
mul_rpow (by positivity) (by positivity),
← rpow_natCast _ 3, ← rpow_mul (sq_nonneg x), ← rpow_natCast _ 3, ← rpow_mul (sq_nonneg y),
show ((3 : ℕ) * ((1 : ℝ) / 3)) = 1 by norm_num, rpow_one, rpow_one] at key
linarith
end Real
end GeomMeanLEArithMean
section HarmMeanLEGeomMean
/-! ### HM-GM inequality -/
namespace Real
/-- **HM-GM inequality**: The harmonic mean is less than or equal to the geometric mean, weighted
version for real-valued nonnegative functions. -/
theorem harm_mean_le_geom_mean_weighted (w z : ι → ℝ) (hs : s.Nonempty) (hw : ∀ i ∈ s, 0 < w i)
(hw' : ∑ i ∈ s, w i = 1) (hz : ∀ i ∈ s, 0 < z i) :
(∑ i ∈ s, w i / z i)⁻¹ ≤ ∏ i ∈ s, z i ^ w i := by
have : ∏ i ∈ s, (1 / z) i ^ w i ≤ ∑ i ∈ s, w i * (1 / z) i :=
geom_mean_le_arith_mean_weighted s w (1/z) (fun i hi ↦ le_of_lt (hw i hi)) hw'
(fun i hi ↦ one_div_nonneg.2 (le_of_lt (hz i hi)))
have p_pos : 0 < ∏ i ∈ s, (z i)⁻¹ ^ w i :=
prod_pos fun i hi => rpow_pos_of_pos (inv_pos.2 (hz i hi)) _
have s_pos : 0 < ∑ i ∈ s, w i * (z i)⁻¹ :=
sum_pos (fun i hi => mul_pos (hw i hi) (inv_pos.2 (hz i hi))) hs
norm_num at this
rw [← inv_le_inv₀ s_pos p_pos] at this
apply le_trans this
have p_pos₂ : 0 < (∏ i ∈ s, (z i) ^ w i)⁻¹ :=
inv_pos.2 (prod_pos fun i hi => rpow_pos_of_pos ((hz i hi)) _ )
rw [← inv_inv (∏ i ∈ s, z i ^ w i), inv_le_inv₀ p_pos p_pos₂, ← Finset.prod_inv_distrib]
gcongr
· exact fun i hi ↦ inv_nonneg.mpr (Real.rpow_nonneg (le_of_lt (hz i hi)) _)
· rw [Real.inv_rpow]; apply fun i hi ↦ le_of_lt (hz i hi); assumption
/-- **HM-GM inequality**: The **harmonic mean is less than or equal to the geometric mean. -/
theorem harm_mean_le_geom_mean {ι : Type*} (s : Finset ι) (hs : s.Nonempty) (w : ι → ℝ)
(z : ι → ℝ) (hw : ∀ i ∈ s, 0 < w i) (hw' : 0 < ∑ i ∈ s, w i) (hz : ∀ i ∈ s, 0 < z i) :
(∑ i ∈ s, w i) / (∑ i ∈ s, w i / z i) ≤ (∏ i ∈ s, z i ^ w i) ^ (∑ i ∈ s, w i)⁻¹ := by
have := harm_mean_le_geom_mean_weighted s (fun i => (w i) / ∑ i ∈ s, w i) z hs ?_ ?_ hz
· simp only at this
set n := ∑ i ∈ s, w i
nth_rw 1 [div_eq_mul_inv, (show n = (n⁻¹)⁻¹ by norm_num), ← mul_inv, Finset.mul_sum _ _ n⁻¹]
simp_rw [inv_mul_eq_div n ((w _)/(z _)), div_right_comm _ _ n]
convert this
rw [← Real.finset_prod_rpow s _ (fun i hi ↦ Real.rpow_nonneg (le_of_lt <| hz i hi) _)]
refine Finset.prod_congr rfl (fun i hi => ?_)
rw [← Real.rpow_mul (le_of_lt <| hz i hi) (w _) n⁻¹, div_eq_mul_inv (w _) n]
· exact fun i hi ↦ div_pos (hw i hi) hw'
· simp_rw [div_eq_mul_inv (w _) (∑ i ∈ s, w i), ← Finset.sum_mul _ _ (∑ i ∈ s, w i)⁻¹]
exact mul_inv_cancel₀ hw'.ne'
end Real
end HarmMeanLEGeomMean
section Young
/-! ### Young's inequality -/
namespace Real
/-- **Young's inequality**, a version for nonnegative real numbers. -/
theorem young_inequality_of_nonneg {a b p q : ℝ} (ha : 0 ≤ a) (hb : 0 ≤ b)
(hpq : p.HolderConjugate q) : a * b ≤ a ^ p / p + b ^ q / q := by
simpa [← rpow_mul, ha, hb, hpq.ne_zero, hpq.symm.ne_zero, _root_.div_eq_inv_mul] using
geom_mean_le_arith_mean2_weighted hpq.inv_nonneg hpq.symm.inv_nonneg
(rpow_nonneg ha p) (rpow_nonneg hb q) hpq.inv_add_inv_eq_one
/-- **Young's inequality**, a version for arbitrary real numbers. -/
theorem young_inequality (a b : ℝ) {p q : ℝ} (hpq : p.HolderConjugate q) :
a * b ≤ |a| ^ p / p + |b| ^ q / q :=
calc
a * b ≤ |a * b| := le_abs_self (a * b)
_ = |a| * |b| := abs_mul a b
_ ≤ |a| ^ p / p + |b| ^ q / q :=
Real.young_inequality_of_nonneg (abs_nonneg a) (abs_nonneg b) hpq
end Real
namespace NNReal
/-- **Young's inequality**, `ℝ≥0` version. We use `{p q : ℝ≥0}` in order to avoid constructing
witnesses of `0 ≤ p` and `0 ≤ q` for the denominators. -/
theorem young_inequality (a b : ℝ≥0) {p q : ℝ≥0} (hpq : p.HolderConjugate q) :
a * b ≤ a ^ (p : ℝ) / p + b ^ (q : ℝ) / q :=
Real.young_inequality_of_nonneg a.coe_nonneg b.coe_nonneg hpq.coe
/-- **Young's inequality**, `ℝ≥0` version with real conjugate exponents. -/
theorem young_inequality_real (a b : ℝ≥0) {p q : ℝ} (hpq : p.HolderConjugate q) :
a * b ≤ a ^ p / Real.toNNReal p + b ^ q / Real.toNNReal q := by
simpa [Real.coe_toNNReal, hpq.nonneg, hpq.symm.nonneg] using young_inequality a b hpq.toNNReal
end NNReal
namespace ENNReal
/-- **Young's inequality**, `ℝ≥0∞` version with real conjugate exponents. -/
theorem young_inequality (a b : ℝ≥0∞) {p q : ℝ} (hpq : p.HolderConjugate q) :
a * b ≤ a ^ p / ENNReal.ofReal p + b ^ q / ENNReal.ofReal q := by
by_cases h : a = ⊤ ∨ b = ⊤
· refine le_trans le_top (le_of_eq ?_)
repeat rw [div_eq_mul_inv]
rcases h with h | h <;> rw [h] <;> simp [h, hpq.pos, hpq.symm.pos]
push_neg at h
-- if a ≠ ⊤ and b ≠ ⊤, use the nnreal version: nnreal.young_inequality_real
rw [← coe_toNNReal h.left, ← coe_toNNReal h.right, ← coe_mul, ← coe_rpow_of_nonneg _ hpq.nonneg,
| ← coe_rpow_of_nonneg _ hpq.symm.nonneg, ENNReal.ofReal, ENNReal.ofReal, ←
@coe_div (Real.toNNReal p) _ (by simp [hpq.pos]), ←
@coe_div (Real.toNNReal q) _ (by simp [hpq.symm.pos]), ← coe_add, coe_le_coe]
exact NNReal.young_inequality_real a.toNNReal b.toNNReal hpq
end ENNReal
end Young
section HoelderMinkowski
/-! ### Hölder's and Minkowski's inequalities -/
namespace NNReal
private theorem inner_le_Lp_mul_Lp_of_norm_le_one (f g : ι → ℝ≥0) {p q : ℝ}
| Mathlib/Analysis/MeanInequalities.lean | 452 | 468 |
/-
Copyright (c) 2021 Anne Baanen. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Anne Baanen
-/
import Mathlib.FieldTheory.RatFunc.Defs
import Mathlib.RingTheory.EuclideanDomain
import Mathlib.RingTheory.Localization.FractionRing
import Mathlib.RingTheory.Polynomial.Content
/-!
# The field structure of rational functions
## Main definitions
Working with rational functions as polynomials:
- `RatFunc.instField` provides a field structure
You can use `IsFractionRing` API to treat `RatFunc` as the field of fractions of polynomials:
* `algebraMap K[X] (RatFunc K)` maps polynomials to rational functions
* `IsFractionRing.algEquiv` maps other fields of fractions of `K[X]` to `RatFunc K`,
in particular:
* `FractionRing.algEquiv K[X] (RatFunc K)` maps the generic field of
fraction construction to `RatFunc K`. Combine this with `AlgEquiv.restrictScalars` to change
the `FractionRing K[X] ≃ₐ[K[X]] RatFunc K` to `FractionRing K[X] ≃ₐ[K] RatFunc K`.
Working with rational functions as fractions:
- `RatFunc.num` and `RatFunc.denom` give the numerator and denominator.
These values are chosen to be coprime and such that `RatFunc.denom` is monic.
Lifting homomorphisms of polynomials to other types, by mapping and dividing, as long
as the homomorphism retains the non-zero-divisor property:
- `RatFunc.liftMonoidWithZeroHom` lifts a `K[X] →*₀ G₀` to
a `RatFunc K →*₀ G₀`, where `[CommRing K] [CommGroupWithZero G₀]`
- `RatFunc.liftRingHom` lifts a `K[X] →+* L` to a `RatFunc K →+* L`,
where `[CommRing K] [Field L]`
- `RatFunc.liftAlgHom` lifts a `K[X] →ₐ[S] L` to a `RatFunc K →ₐ[S] L`,
where `[CommRing K] [Field L] [CommSemiring S] [Algebra S K[X]] [Algebra S L]`
This is satisfied by injective homs.
We also have lifting homomorphisms of polynomials to other polynomials,
with the same condition on retaining the non-zero-divisor property across the map:
- `RatFunc.map` lifts `K[X] →* R[X]` when `[CommRing K] [CommRing R]`
- `RatFunc.mapRingHom` lifts `K[X] →+* R[X]` when `[CommRing K] [CommRing R]`
- `RatFunc.mapAlgHom` lifts `K[X] →ₐ[S] R[X]` when
`[CommRing K] [IsDomain K] [CommRing R] [IsDomain R]`
-/
universe u v
noncomputable section
open scoped nonZeroDivisors Polynomial
variable {K : Type u}
namespace RatFunc
section Field
variable [CommRing K]
/-- The zero rational function. -/
protected irreducible_def zero : RatFunc K :=
⟨0⟩
instance : Zero (RatFunc K) :=
⟨RatFunc.zero⟩
theorem ofFractionRing_zero : (ofFractionRing 0 : RatFunc K) = 0 :=
zero_def.symm
/-- Addition of rational functions. -/
protected irreducible_def add : RatFunc K → RatFunc K → RatFunc K
| ⟨p⟩, ⟨q⟩ => ⟨p + q⟩
instance : Add (RatFunc K) :=
⟨RatFunc.add⟩
theorem ofFractionRing_add (p q : FractionRing K[X]) :
ofFractionRing (p + q) = ofFractionRing p + ofFractionRing q :=
(add_def _ _).symm
/-- Subtraction of rational functions. -/
protected irreducible_def sub : RatFunc K → RatFunc K → RatFunc K
| ⟨p⟩, ⟨q⟩ => ⟨p - q⟩
instance : Sub (RatFunc K) :=
⟨RatFunc.sub⟩
theorem ofFractionRing_sub (p q : FractionRing K[X]) :
ofFractionRing (p - q) = ofFractionRing p - ofFractionRing q :=
(sub_def _ _).symm
/-- Additive inverse of a rational function. -/
protected irreducible_def neg : RatFunc K → RatFunc K
| ⟨p⟩ => ⟨-p⟩
instance : Neg (RatFunc K) :=
⟨RatFunc.neg⟩
theorem ofFractionRing_neg (p : FractionRing K[X]) :
ofFractionRing (-p) = -ofFractionRing p :=
(neg_def _).symm
/-- The multiplicative unit of rational functions. -/
protected irreducible_def one : RatFunc K :=
⟨1⟩
instance : One (RatFunc K) :=
⟨RatFunc.one⟩
theorem ofFractionRing_one : (ofFractionRing 1 : RatFunc K) = 1 :=
one_def.symm
/-- Multiplication of rational functions. -/
protected irreducible_def mul : RatFunc K → RatFunc K → RatFunc K
| ⟨p⟩, ⟨q⟩ => ⟨p * q⟩
instance : Mul (RatFunc K) :=
⟨RatFunc.mul⟩
theorem ofFractionRing_mul (p q : FractionRing K[X]) :
ofFractionRing (p * q) = ofFractionRing p * ofFractionRing q :=
(mul_def _ _).symm
section IsDomain
variable [IsDomain K]
/-- Division of rational functions. -/
protected irreducible_def div : RatFunc K → RatFunc K → RatFunc K
| ⟨p⟩, ⟨q⟩ => ⟨p / q⟩
instance : Div (RatFunc K) :=
⟨RatFunc.div⟩
theorem ofFractionRing_div (p q : FractionRing K[X]) :
ofFractionRing (p / q) = ofFractionRing p / ofFractionRing q :=
(div_def _ _).symm
/-- Multiplicative inverse of a rational function. -/
protected irreducible_def inv : RatFunc K → RatFunc K
| ⟨p⟩ => ⟨p⁻¹⟩
instance : Inv (RatFunc K) :=
⟨RatFunc.inv⟩
theorem ofFractionRing_inv (p : FractionRing K[X]) :
ofFractionRing p⁻¹ = (ofFractionRing p)⁻¹ :=
(inv_def _).symm
-- Auxiliary lemma for the `Field` instance
theorem mul_inv_cancel : ∀ {p : RatFunc K}, p ≠ 0 → p * p⁻¹ = 1
| ⟨p⟩, h => by
have : p ≠ 0 := fun hp => h <| by rw [hp, ofFractionRing_zero]
simpa only [← ofFractionRing_inv, ← ofFractionRing_mul, ← ofFractionRing_one,
ofFractionRing.injEq] using
mul_inv_cancel₀ this
end IsDomain
section SMul
variable {R : Type*}
/-- Scalar multiplication of rational functions. -/
protected irreducible_def smul [SMul R (FractionRing K[X])] : R → RatFunc K → RatFunc K
| r, ⟨p⟩ => ⟨r • p⟩
instance [SMul R (FractionRing K[X])] : SMul R (RatFunc K) :=
⟨RatFunc.smul⟩
theorem ofFractionRing_smul [SMul R (FractionRing K[X])] (c : R) (p : FractionRing K[X]) :
ofFractionRing (c • p) = c • ofFractionRing p :=
(smul_def _ _).symm
theorem toFractionRing_smul [SMul R (FractionRing K[X])] (c : R) (p : RatFunc K) :
toFractionRing (c • p) = c • toFractionRing p := by
cases p
rw [← ofFractionRing_smul]
theorem smul_eq_C_smul (x : RatFunc K) (r : K) : r • x = Polynomial.C r • x := by
obtain ⟨x⟩ := x
induction x using Localization.induction_on
rw [← ofFractionRing_smul, ← ofFractionRing_smul, Localization.smul_mk,
Localization.smul_mk, smul_eq_mul, Polynomial.smul_eq_C_mul]
section IsDomain
variable [IsDomain K]
variable [Monoid R] [DistribMulAction R K[X]]
variable [IsScalarTower R K[X] K[X]]
theorem mk_smul (c : R) (p q : K[X]) : RatFunc.mk (c • p) q = c • RatFunc.mk p q := by
letI : SMulZeroClass R (FractionRing K[X]) := inferInstance
by_cases hq : q = 0
· rw [hq, mk_zero, mk_zero, ← ofFractionRing_smul, smul_zero]
· rw [mk_eq_localization_mk _ hq, mk_eq_localization_mk _ hq, ← Localization.smul_mk, ←
ofFractionRing_smul]
instance : IsScalarTower R K[X] (RatFunc K) :=
⟨fun c p q => q.induction_on' fun q r _ => by rw [← mk_smul, smul_assoc, mk_smul, mk_smul]⟩
end IsDomain
end SMul
variable (K)
instance [Subsingleton K] : Subsingleton (RatFunc K) :=
toFractionRing_injective.subsingleton
instance : Inhabited (RatFunc K) :=
⟨0⟩
instance instNontrivial [Nontrivial K] : Nontrivial (RatFunc K) :=
ofFractionRing_injective.nontrivial
/-- `RatFunc K` is isomorphic to the field of fractions of `K[X]`, as rings.
This is an auxiliary definition; `simp`-normal form is `IsLocalization.algEquiv`.
-/
@[simps apply]
def toFractionRingRingEquiv : RatFunc K ≃+* FractionRing K[X] where
toFun := toFractionRing
invFun := ofFractionRing
left_inv := fun ⟨_⟩ => rfl
right_inv _ := rfl
map_add' := fun ⟨_⟩ ⟨_⟩ => by simp [← ofFractionRing_add]
map_mul' := fun ⟨_⟩ ⟨_⟩ => by simp [← ofFractionRing_mul]
end Field
section TacticInterlude
| /-- Solve equations for `RatFunc K` by working in `FractionRing K[X]`. -/
macro "frac_tac" : tactic => `(tactic|
· repeat (rintro (⟨⟩ : RatFunc _))
try simp only [← ofFractionRing_zero, ← ofFractionRing_add, ← ofFractionRing_sub,
← ofFractionRing_neg, ← ofFractionRing_one, ← ofFractionRing_mul, ← ofFractionRing_div,
| Mathlib/FieldTheory/RatFunc/Basic.lean | 235 | 239 |
/-
Copyright (c) 2021 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov, Alex Kontorovich, Heather Macbeth
-/
import Mathlib.MeasureTheory.Integral.IntervalIntegral.Periodic
deprecated_module (since := "2025-04-13")
| Mathlib/MeasureTheory/Integral/Periodic.lean | 49 | 55 | |
/-
Copyright (c) 2020 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kim Morrison
-/
import Mathlib.Algebra.BigOperators.Group.Finset.Piecewise
import Mathlib.Algebra.Group.Ext
import Mathlib.CategoryTheory.Limits.Preserves.Shapes.BinaryProducts
import Mathlib.CategoryTheory.Limits.Preserves.Shapes.Biproducts
import Mathlib.CategoryTheory.Limits.Preserves.Shapes.Products
import Mathlib.CategoryTheory.Preadditive.Basic
import Mathlib.Tactic.Abel
/-!
# Basic facts about biproducts in preadditive categories.
In (or between) preadditive categories,
* Any biproduct satisfies the equality
`total : ∑ j : J, biproduct.π f j ≫ biproduct.ι f j = 𝟙 (⨁ f)`,
or, in the binary case, `total : fst ≫ inl + snd ≫ inr = 𝟙 X`.
* Any (binary) `product` or (binary) `coproduct` is a (binary) `biproduct`.
* In any category (with zero morphisms), if `biprod.map f g` is an isomorphism,
then both `f` and `g` are isomorphisms.
* If `f` is a morphism `X₁ ⊞ X₂ ⟶ Y₁ ⊞ Y₂` whose `X₁ ⟶ Y₁` entry is an isomorphism,
then we can construct isomorphisms `L : X₁ ⊞ X₂ ≅ X₁ ⊞ X₂` and `R : Y₁ ⊞ Y₂ ≅ Y₁ ⊞ Y₂`
so that `L.hom ≫ g ≫ R.hom` is diagonal (with `X₁ ⟶ Y₁` component still `f`),
via Gaussian elimination.
* As a corollary of the previous two facts,
if we have an isomorphism `X₁ ⊞ X₂ ≅ Y₁ ⊞ Y₂` whose `X₁ ⟶ Y₁` entry is an isomorphism,
we can construct an isomorphism `X₂ ≅ Y₂`.
* If `f : W ⊞ X ⟶ Y ⊞ Z` is an isomorphism, either `𝟙 W = 0`,
or at least one of the component maps `W ⟶ Y` and `W ⟶ Z` is nonzero.
* If `f : ⨁ S ⟶ ⨁ T` is an isomorphism,
then every column (corresponding to a nonzero summand in the domain)
has some nonzero matrix entry.
* A functor preserves a biproduct if and only if it preserves
the corresponding product if and only if it preserves the corresponding coproduct.
There are connections between this material and the special case of the category whose morphisms are
matrices over a ring, in particular the Schur complement (see
`Mathlib.LinearAlgebra.Matrix.SchurComplement`). In particular, the declarations
`CategoryTheory.Biprod.isoElim`, `CategoryTheory.Biprod.gaussian`
and `Matrix.invertibleOfFromBlocks₁₁Invertible` are all closely related.
-/
open CategoryTheory
open CategoryTheory.Preadditive
open CategoryTheory.Limits
open CategoryTheory.Functor
open CategoryTheory.Preadditive
universe v v' u u'
noncomputable section
namespace CategoryTheory
variable {C : Type u} [Category.{v} C] [Preadditive C]
namespace Limits
section Fintype
variable {J : Type} [Fintype J]
/-- In a preadditive category, we can construct a biproduct for `f : J → C` from
any bicone `b` for `f` satisfying `total : ∑ j : J, b.π j ≫ b.ι j = 𝟙 b.X`.
(That is, such a bicone is a limit cone and a colimit cocone.)
-/
def isBilimitOfTotal {f : J → C} (b : Bicone f) (total : ∑ j : J, b.π j ≫ b.ι j = 𝟙 b.pt) :
b.IsBilimit where
isLimit :=
{ lift := fun s => ∑ j : J, s.π.app ⟨j⟩ ≫ b.ι j
uniq := fun s m h => by
erw [← Category.comp_id m, ← total, comp_sum]
apply Finset.sum_congr rfl
intro j _
have reassoced : m ≫ Bicone.π b j ≫ Bicone.ι b j = s.π.app ⟨j⟩ ≫ Bicone.ι b j := by
erw [← Category.assoc, eq_whisker (h ⟨j⟩)]
rw [reassoced]
fac := fun s j => by
classical
cases j
simp only [sum_comp, Category.assoc, Bicone.toCone_π_app, b.ι_π, comp_dite]
-- See note [dsimp, simp].
dsimp
simp }
isColimit :=
{ desc := fun s => ∑ j : J, b.π j ≫ s.ι.app ⟨j⟩
uniq := fun s m h => by
erw [← Category.id_comp m, ← total, sum_comp]
apply Finset.sum_congr rfl
intro j _
erw [Category.assoc, h ⟨j⟩]
fac := fun s j => by
classical
cases j
simp only [comp_sum, ← Category.assoc, Bicone.toCocone_ι_app, b.ι_π, dite_comp]
dsimp; simp }
theorem IsBilimit.total {f : J → C} {b : Bicone f} (i : b.IsBilimit) :
∑ j : J, b.π j ≫ b.ι j = 𝟙 b.pt :=
i.isLimit.hom_ext fun j => by
classical
cases j
simp [sum_comp, b.ι_π, comp_dite]
/-- In a preadditive category, we can construct a biproduct for `f : J → C` from
any bicone `b` for `f` satisfying `total : ∑ j : J, b.π j ≫ b.ι j = 𝟙 b.X`.
(That is, such a bicone is a limit cone and a colimit cocone.)
-/
theorem hasBiproduct_of_total {f : J → C} (b : Bicone f)
(total : ∑ j : J, b.π j ≫ b.ι j = 𝟙 b.pt) : HasBiproduct f :=
HasBiproduct.mk
{ bicone := b
isBilimit := isBilimitOfTotal b total }
/-- In a preadditive category, any finite bicone which is a limit cone is in fact a bilimit
bicone. -/
def isBilimitOfIsLimit {f : J → C} (t : Bicone f) (ht : IsLimit t.toCone) : t.IsBilimit :=
isBilimitOfTotal _ <|
ht.hom_ext fun j => by
classical
cases j
simp [sum_comp, t.ι_π, dite_comp, comp_dite]
/-- We can turn any limit cone over a pair into a bilimit bicone. -/
def biconeIsBilimitOfLimitConeOfIsLimit {f : J → C} {t : Cone (Discrete.functor f)}
(ht : IsLimit t) : (Bicone.ofLimitCone ht).IsBilimit :=
isBilimitOfIsLimit _ <| IsLimit.ofIsoLimit ht <| Cones.ext (Iso.refl _) (by simp)
/-- In a preadditive category, any finite bicone which is a colimit cocone is in fact a bilimit
bicone. -/
def isBilimitOfIsColimit {f : J → C} (t : Bicone f) (ht : IsColimit t.toCocone) : t.IsBilimit :=
isBilimitOfTotal _ <|
ht.hom_ext fun j => by
classical
cases j
simp_rw [Bicone.toCocone_ι_app, comp_sum, ← Category.assoc, t.ι_π, dite_comp]
simp
/-- We can turn any limit cone over a pair into a bilimit bicone. -/
def biconeIsBilimitOfColimitCoconeOfIsColimit {f : J → C} {t : Cocone (Discrete.functor f)}
(ht : IsColimit t) : (Bicone.ofColimitCocone ht).IsBilimit :=
isBilimitOfIsColimit _ <| IsColimit.ofIsoColimit ht <| Cocones.ext (Iso.refl _) <| by
rintro ⟨j⟩; simp
end Fintype
section Finite
variable {J : Type} [Finite J]
/-- In a preadditive category, if the product over `f : J → C` exists,
then the biproduct over `f` exists. -/
theorem HasBiproduct.of_hasProduct (f : J → C) [HasProduct f] : HasBiproduct f := by
cases nonempty_fintype J
exact HasBiproduct.mk
{ bicone := _
isBilimit := biconeIsBilimitOfLimitConeOfIsLimit (limit.isLimit _) }
/-- In a preadditive category, if the coproduct over `f : J → C` exists,
then the biproduct over `f` exists. -/
theorem HasBiproduct.of_hasCoproduct (f : J → C) [HasCoproduct f] : HasBiproduct f := by
cases nonempty_fintype J
exact HasBiproduct.mk
{ bicone := _
isBilimit := biconeIsBilimitOfColimitCoconeOfIsColimit (colimit.isColimit _) }
end Finite
/-- A preadditive category with finite products has finite biproducts. -/
theorem HasFiniteBiproducts.of_hasFiniteProducts [HasFiniteProducts C] : HasFiniteBiproducts C :=
⟨fun _ => { has_biproduct := fun _ => HasBiproduct.of_hasProduct _ }⟩
/-- A preadditive category with finite coproducts has finite biproducts. -/
theorem HasFiniteBiproducts.of_hasFiniteCoproducts [HasFiniteCoproducts C] :
HasFiniteBiproducts C :=
⟨fun _ => { has_biproduct := fun _ => HasBiproduct.of_hasCoproduct _ }⟩
section HasBiproduct
variable {J : Type} [Fintype J] {f : J → C} [HasBiproduct f]
/-- In any preadditive category, any biproduct satisfies
`∑ j : J, biproduct.π f j ≫ biproduct.ι f j = 𝟙 (⨁ f)`
-/
@[simp]
theorem biproduct.total : ∑ j : J, biproduct.π f j ≫ biproduct.ι f j = 𝟙 (⨁ f) :=
IsBilimit.total (biproduct.isBilimit _)
theorem biproduct.lift_eq {T : C} {g : ∀ j, T ⟶ f j} :
biproduct.lift g = ∑ j, g j ≫ biproduct.ι f j := by
classical
ext j
simp only [sum_comp, biproduct.ι_π, comp_dite, biproduct.lift_π, Category.assoc, comp_zero,
Finset.sum_dite_eq', Finset.mem_univ, eqToHom_refl, Category.comp_id, if_true]
theorem biproduct.desc_eq {T : C} {g : ∀ j, f j ⟶ T} :
biproduct.desc g = ∑ j, biproduct.π f j ≫ g j := by
classical
ext j
simp [comp_sum, biproduct.ι_π_assoc, dite_comp]
@[reassoc]
theorem biproduct.lift_desc {T U : C} {g : ∀ j, T ⟶ f j} {h : ∀ j, f j ⟶ U} :
biproduct.lift g ≫ biproduct.desc h = ∑ j : J, g j ≫ h j := by
classical
simp [biproduct.lift_eq, biproduct.desc_eq, comp_sum, sum_comp, biproduct.ι_π_assoc, comp_dite,
dite_comp]
theorem biproduct.map_eq [HasFiniteBiproducts C] {f g : J → C} {h : ∀ j, f j ⟶ g j} :
biproduct.map h = ∑ j : J, biproduct.π f j ≫ h j ≫ biproduct.ι g j := by
classical
ext
simp [biproduct.ι_π, biproduct.ι_π_assoc, comp_sum, sum_comp, comp_dite, dite_comp]
@[reassoc]
theorem biproduct.lift_matrix {K : Type} [Finite K] [HasFiniteBiproducts C] {f : J → C} {g : K → C}
{P} (x : ∀ j, P ⟶ f j) (m : ∀ j k, f j ⟶ g k) :
biproduct.lift x ≫ biproduct.matrix m = biproduct.lift fun k => ∑ j, x j ≫ m j k := by
ext
simp [biproduct.lift_desc]
end HasBiproduct
section HasFiniteBiproducts
variable {J K : Type} [Finite J] {f : J → C} [HasFiniteBiproducts C]
@[reassoc]
theorem biproduct.matrix_desc [Fintype K] {f : J → C} {g : K → C}
(m : ∀ j k, f j ⟶ g k) {P} (x : ∀ k, g k ⟶ P) :
biproduct.matrix m ≫ biproduct.desc x = biproduct.desc fun j => ∑ k, m j k ≫ x k := by
ext
simp [lift_desc]
variable [Finite K]
@[reassoc]
theorem biproduct.matrix_map {f : J → C} {g : K → C} {h : K → C} (m : ∀ j k, f j ⟶ g k)
(n : ∀ k, g k ⟶ h k) :
biproduct.matrix m ≫ biproduct.map n = biproduct.matrix fun j k => m j k ≫ n k := by
ext
simp
@[reassoc]
theorem biproduct.map_matrix {f : J → C} {g : J → C} {h : K → C} (m : ∀ k, f k ⟶ g k)
(n : ∀ j k, g j ⟶ h k) :
biproduct.map m ≫ biproduct.matrix n = biproduct.matrix fun j k => m j ≫ n j k := by
ext
simp
end HasFiniteBiproducts
/-- Reindex a categorical biproduct via an equivalence of the index types. -/
@[simps]
def biproduct.reindex {β γ : Type} [Finite β] (ε : β ≃ γ)
(f : γ → C) [HasBiproduct f] [HasBiproduct (f ∘ ε)] : ⨁ f ∘ ε ≅ ⨁ f where
hom := biproduct.desc fun b => biproduct.ι f (ε b)
inv := biproduct.lift fun b => biproduct.π f (ε b)
hom_inv_id := by
ext b b'
by_cases h : b' = b
· subst h; simp
· have : ε b' ≠ ε b := by simp [h]
simp [biproduct.ι_π_ne _ h, biproduct.ι_π_ne _ this]
inv_hom_id := by
classical
cases nonempty_fintype β
ext g g'
by_cases h : g' = g <;>
simp [Preadditive.sum_comp, Preadditive.comp_sum, biproduct.lift_desc,
biproduct.ι_π, biproduct.ι_π_assoc, comp_dite, Equiv.apply_eq_iff_eq_symm_apply,
Finset.sum_dite_eq' Finset.univ (ε.symm g') _, h]
/-- In a preadditive category, we can construct a binary biproduct for `X Y : C` from
any binary bicone `b` satisfying `total : b.fst ≫ b.inl + b.snd ≫ b.inr = 𝟙 b.X`.
(That is, such a bicone is a limit cone and a colimit cocone.)
-/
def isBinaryBilimitOfTotal {X Y : C} (b : BinaryBicone X Y)
(total : b.fst ≫ b.inl + b.snd ≫ b.inr = 𝟙 b.pt) : b.IsBilimit where
isLimit :=
{ lift := fun s =>
(BinaryFan.fst s ≫ b.inl : s.pt ⟶ b.pt) + (BinaryFan.snd s ≫ b.inr : s.pt ⟶ b.pt)
uniq := fun s m h => by
have reassoced (j : WalkingPair) {W : C} (h' : _ ⟶ W) :
m ≫ b.toCone.π.app ⟨j⟩ ≫ h' = s.π.app ⟨j⟩ ≫ h' := by
rw [← Category.assoc, eq_whisker (h ⟨j⟩)]
erw [← Category.comp_id m, ← total, comp_add, reassoced WalkingPair.left,
reassoced WalkingPair.right]
fac := fun s j => by rcases j with ⟨⟨⟩⟩ <;> simp }
isColimit :=
{ desc := fun s =>
(b.fst ≫ BinaryCofan.inl s : b.pt ⟶ s.pt) + (b.snd ≫ BinaryCofan.inr s : b.pt ⟶ s.pt)
uniq := fun s m h => by
erw [← Category.id_comp m, ← total, add_comp, Category.assoc, Category.assoc,
h ⟨WalkingPair.left⟩, h ⟨WalkingPair.right⟩]
fac := fun s j => by rcases j with ⟨⟨⟩⟩ <;> simp }
theorem IsBilimit.binary_total {X Y : C} {b : BinaryBicone X Y} (i : b.IsBilimit) :
b.fst ≫ b.inl + b.snd ≫ b.inr = 𝟙 b.pt :=
i.isLimit.hom_ext fun j => by rcases j with ⟨⟨⟩⟩ <;> simp
/-- In a preadditive category, we can construct a binary biproduct for `X Y : C` from
any binary bicone `b` satisfying `total : b.fst ≫ b.inl + b.snd ≫ b.inr = 𝟙 b.X`.
(That is, such a bicone is a limit cone and a colimit cocone.)
-/
theorem hasBinaryBiproduct_of_total {X Y : C} (b : BinaryBicone X Y)
(total : b.fst ≫ b.inl + b.snd ≫ b.inr = 𝟙 b.pt) : HasBinaryBiproduct X Y :=
HasBinaryBiproduct.mk
{ bicone := b
isBilimit := isBinaryBilimitOfTotal b total }
/-- We can turn any limit cone over a pair into a bicone. -/
@[simps]
def BinaryBicone.ofLimitCone {X Y : C} {t : Cone (pair X Y)} (ht : IsLimit t) :
BinaryBicone X Y where
pt := t.pt
fst := t.π.app ⟨WalkingPair.left⟩
snd := t.π.app ⟨WalkingPair.right⟩
inl := ht.lift (BinaryFan.mk (𝟙 X) 0)
inr := ht.lift (BinaryFan.mk 0 (𝟙 Y))
theorem inl_of_isLimit {X Y : C} {t : BinaryBicone X Y} (ht : IsLimit t.toCone) :
t.inl = ht.lift (BinaryFan.mk (𝟙 X) 0) := by
apply ht.uniq (BinaryFan.mk (𝟙 X) 0); rintro ⟨⟨⟩⟩ <;> dsimp <;> simp
theorem inr_of_isLimit {X Y : C} {t : BinaryBicone X Y} (ht : IsLimit t.toCone) :
t.inr = ht.lift (BinaryFan.mk 0 (𝟙 Y)) := by
apply ht.uniq (BinaryFan.mk 0 (𝟙 Y)); rintro ⟨⟨⟩⟩ <;> dsimp <;> simp
/-- In a preadditive category, any binary bicone which is a limit cone is in fact a bilimit
bicone. -/
def isBinaryBilimitOfIsLimit {X Y : C} (t : BinaryBicone X Y) (ht : IsLimit t.toCone) :
t.IsBilimit :=
isBinaryBilimitOfTotal _ (by refine BinaryFan.IsLimit.hom_ext ht ?_ ?_ <;> simp)
/-- We can turn any limit cone over a pair into a bilimit bicone. -/
def binaryBiconeIsBilimitOfLimitConeOfIsLimit {X Y : C} {t : Cone (pair X Y)} (ht : IsLimit t) :
(BinaryBicone.ofLimitCone ht).IsBilimit :=
isBinaryBilimitOfTotal _ <| BinaryFan.IsLimit.hom_ext ht (by simp) (by simp)
/-- In a preadditive category, if the product of `X` and `Y` exists, then the
binary biproduct of `X` and `Y` exists. -/
theorem HasBinaryBiproduct.of_hasBinaryProduct (X Y : C) [HasBinaryProduct X Y] :
HasBinaryBiproduct X Y :=
HasBinaryBiproduct.mk
{ bicone := _
isBilimit := binaryBiconeIsBilimitOfLimitConeOfIsLimit (limit.isLimit _) }
/-- In a preadditive category, if all binary products exist, then all binary biproducts exist. -/
theorem HasBinaryBiproducts.of_hasBinaryProducts [HasBinaryProducts C] : HasBinaryBiproducts C :=
{ has_binary_biproduct := fun X Y => HasBinaryBiproduct.of_hasBinaryProduct X Y }
/-- We can turn any colimit cocone over a pair into a bicone. -/
@[simps]
def BinaryBicone.ofColimitCocone {X Y : C} {t : Cocone (pair X Y)} (ht : IsColimit t) :
BinaryBicone X Y where
pt := t.pt
fst := ht.desc (BinaryCofan.mk (𝟙 X) 0)
snd := ht.desc (BinaryCofan.mk 0 (𝟙 Y))
inl := t.ι.app ⟨WalkingPair.left⟩
inr := t.ι.app ⟨WalkingPair.right⟩
theorem fst_of_isColimit {X Y : C} {t : BinaryBicone X Y} (ht : IsColimit t.toCocone) :
t.fst = ht.desc (BinaryCofan.mk (𝟙 X) 0) := by
apply ht.uniq (BinaryCofan.mk (𝟙 X) 0)
rintro ⟨⟨⟩⟩ <;> dsimp <;> simp
theorem snd_of_isColimit {X Y : C} {t : BinaryBicone X Y} (ht : IsColimit t.toCocone) :
t.snd = ht.desc (BinaryCofan.mk 0 (𝟙 Y)) := by
apply ht.uniq (BinaryCofan.mk 0 (𝟙 Y))
rintro ⟨⟨⟩⟩ <;> dsimp <;> simp
/-- In a preadditive category, any binary bicone which is a colimit cocone is in fact a
bilimit bicone. -/
def isBinaryBilimitOfIsColimit {X Y : C} (t : BinaryBicone X Y) (ht : IsColimit t.toCocone) :
t.IsBilimit :=
isBinaryBilimitOfTotal _ <| by
refine BinaryCofan.IsColimit.hom_ext ht ?_ ?_ <;> simp
/-- We can turn any colimit cocone over a pair into a bilimit bicone. -/
def binaryBiconeIsBilimitOfColimitCoconeOfIsColimit {X Y : C} {t : Cocone (pair X Y)}
(ht : IsColimit t) : (BinaryBicone.ofColimitCocone ht).IsBilimit :=
isBinaryBilimitOfIsColimit (BinaryBicone.ofColimitCocone ht) <|
IsColimit.ofIsoColimit ht <|
Cocones.ext (Iso.refl _) fun j => by
rcases j with ⟨⟨⟩⟩ <;> simp
/-- In a preadditive category, if the coproduct of `X` and `Y` exists, then the
binary biproduct of `X` and `Y` exists. -/
theorem HasBinaryBiproduct.of_hasBinaryCoproduct (X Y : C) [HasBinaryCoproduct X Y] :
HasBinaryBiproduct X Y :=
HasBinaryBiproduct.mk
{ bicone := _
| isBilimit := binaryBiconeIsBilimitOfColimitCoconeOfIsColimit (colimit.isColimit _) }
/-- In a preadditive category, if all binary coproducts exist, then all binary biproducts exist. -/
theorem HasBinaryBiproducts.of_hasBinaryCoproducts [HasBinaryCoproducts C] :
| Mathlib/CategoryTheory/Preadditive/Biproducts.lean | 415 | 418 |
/-
Copyright (c) 2021 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel, Yaël Dillies
-/
import Mathlib.Analysis.Normed.Group.Bounded
import Mathlib.Analysis.Normed.Group.Uniform
import Mathlib.Topology.MetricSpace.Thickening
/-!
# Properties of pointwise addition of sets in normed groups
We explore the relationships between pointwise addition of sets in normed groups, and the norm.
Notably, we show that the sum of bounded sets remain bounded.
-/
open Metric Set Pointwise Topology
variable {E : Type*}
section SeminormedGroup
variable [SeminormedGroup E] {s t : Set E}
-- note: we can't use `LipschitzOnWith.isBounded_image2` here without adding `[IsIsometricSMul E E]`
@[to_additive]
theorem Bornology.IsBounded.mul (hs : IsBounded s) (ht : IsBounded t) : IsBounded (s * t) := by
obtain ⟨Rs, hRs⟩ : ∃ R, ∀ x ∈ s, ‖x‖ ≤ R := hs.exists_norm_le'
obtain ⟨Rt, hRt⟩ : ∃ R, ∀ x ∈ t, ‖x‖ ≤ R := ht.exists_norm_le'
refine isBounded_iff_forall_norm_le'.2 ⟨Rs + Rt, ?_⟩
rintro z ⟨x, hx, y, hy, rfl⟩
exact norm_mul_le_of_le' (hRs x hx) (hRt y hy)
@[to_additive]
theorem Bornology.IsBounded.of_mul (hst : IsBounded (s * t)) : IsBounded s ∨ IsBounded t :=
AntilipschitzWith.isBounded_of_image2_left _ (fun x => (isometry_mul_right x).antilipschitz) hst
@[to_additive]
theorem Bornology.IsBounded.inv : IsBounded s → IsBounded s⁻¹ := by
simp_rw [isBounded_iff_forall_norm_le', ← image_inv_eq_inv, forall_mem_image, norm_inv']
exact id
@[to_additive]
theorem Bornology.IsBounded.div (hs : IsBounded s) (ht : IsBounded t) : IsBounded (s / t) :=
div_eq_mul_inv s t ▸ hs.mul ht.inv
end SeminormedGroup
section SeminormedCommGroup
variable [SeminormedCommGroup E] {δ : ℝ} {s : Set E} {x y : E}
section EMetric
open EMetric
@[to_additive (attr := simp)]
theorem infEdist_inv_inv (x : E) (s : Set E) : infEdist x⁻¹ s⁻¹ = infEdist x s := by
rw [← image_inv_eq_inv, infEdist_image isometry_inv]
@[to_additive]
theorem infEdist_inv (x : E) (s : Set E) : infEdist x⁻¹ s = infEdist x s⁻¹ := by
rw [← infEdist_inv_inv, inv_inv]
@[to_additive]
theorem ediam_mul_le (x y : Set E) : EMetric.diam (x * y) ≤ EMetric.diam x + EMetric.diam y :=
(LipschitzOnWith.ediam_image2_le (· * ·) _ _
(fun _ _ => (isometry_mul_right _).lipschitz.lipschitzOnWith) fun _ _ =>
(isometry_mul_left _).lipschitz.lipschitzOnWith).trans_eq <|
by simp only [ENNReal.coe_one, one_mul]
end EMetric
variable (δ s x y)
@[to_additive (attr := simp)]
theorem inv_thickening : (thickening δ s)⁻¹ = thickening δ s⁻¹ := by
simp_rw [thickening, ← infEdist_inv]
rfl
@[to_additive (attr := simp)]
theorem inv_cthickening : (cthickening δ s)⁻¹ = cthickening δ s⁻¹ := by
simp_rw [cthickening, ← infEdist_inv]
rfl
@[to_additive (attr := simp)]
theorem inv_ball : (ball x δ)⁻¹ = ball x⁻¹ δ := (IsometryEquiv.inv E).preimage_ball x δ
@[to_additive (attr := simp)]
theorem inv_closedBall : (closedBall x δ)⁻¹ = closedBall x⁻¹ δ :=
(IsometryEquiv.inv E).preimage_closedBall x δ
@[to_additive]
theorem singleton_mul_ball : {x} * ball y δ = ball (x * y) δ := by
simp only [preimage_mul_ball, image_mul_left, singleton_mul, div_inv_eq_mul, mul_comm y x]
@[to_additive]
theorem singleton_div_ball : {x} / ball y δ = ball (x / y) δ := by
simp_rw [div_eq_mul_inv, inv_ball, singleton_mul_ball]
@[to_additive]
theorem ball_mul_singleton : ball x δ * {y} = ball (x * y) δ := by
rw [mul_comm, singleton_mul_ball, mul_comm y]
@[to_additive]
theorem ball_div_singleton : ball x δ / {y} = ball (x / y) δ := by
simp_rw [div_eq_mul_inv, inv_singleton, ball_mul_singleton]
@[to_additive]
theorem singleton_mul_ball_one : {x} * ball 1 δ = ball x δ := by simp
@[to_additive]
theorem singleton_div_ball_one : {x} / ball 1 δ = ball x δ := by
rw [singleton_div_ball, div_one]
@[to_additive]
theorem ball_one_mul_singleton : ball 1 δ * {x} = ball x δ := by simp [ball_mul_singleton]
@[to_additive]
theorem ball_one_div_singleton : ball 1 δ / {x} = ball x⁻¹ δ := by
rw [ball_div_singleton, one_div]
@[to_additive]
theorem smul_ball_one : x • ball (1 : E) δ = ball x δ := by
rw [smul_ball, smul_eq_mul, mul_one]
@[to_additive (attr := simp 1100)]
theorem singleton_mul_closedBall : {x} * closedBall y δ = closedBall (x * y) δ := by
simp_rw [singleton_mul, ← smul_eq_mul, image_smul, smul_closedBall]
@[to_additive (attr := simp 1100)]
theorem singleton_div_closedBall : {x} / closedBall y δ = closedBall (x / y) δ := by
simp_rw [div_eq_mul_inv, inv_closedBall, singleton_mul_closedBall]
@[to_additive (attr := simp 1100)]
theorem closedBall_mul_singleton : closedBall x δ * {y} = closedBall (x * y) δ := by
simp [mul_comm _ {y}, mul_comm y]
@[to_additive (attr := simp 1100)]
theorem closedBall_div_singleton : closedBall x δ / {y} = closedBall (x / y) δ := by
simp [div_eq_mul_inv]
@[to_additive]
theorem singleton_mul_closedBall_one : {x} * closedBall 1 δ = closedBall x δ := by simp
@[to_additive]
theorem singleton_div_closedBall_one : {x} / closedBall 1 δ = closedBall x δ := by
rw [singleton_div_closedBall, div_one]
@[to_additive]
theorem closedBall_one_mul_singleton : closedBall 1 δ * {x} = closedBall x δ := by simp
@[to_additive]
theorem closedBall_one_div_singleton : closedBall 1 δ / {x} = closedBall x⁻¹ δ := by simp
@[to_additive (attr := simp 1100)]
theorem smul_closedBall_one : x • closedBall (1 : E) δ = closedBall x δ := by simp
@[to_additive]
theorem mul_ball_one : s * ball 1 δ = thickening δ s := by
rw [thickening_eq_biUnion_ball]
convert iUnion₂_mul (fun x (_ : x ∈ s) => {x}) (ball (1 : E) δ)
· exact s.biUnion_of_singleton.symm
ext x
simp_rw [singleton_mul_ball, mul_one]
@[to_additive]
theorem div_ball_one : s / ball 1 δ = thickening δ s := by simp [div_eq_mul_inv, mul_ball_one]
@[to_additive]
theorem ball_mul_one : ball 1 δ * s = thickening δ s := by rw [mul_comm, mul_ball_one]
@[to_additive]
theorem ball_div_one : ball 1 δ / s = thickening δ s⁻¹ := by simp [div_eq_mul_inv, ball_mul_one]
@[to_additive (attr := simp)]
theorem mul_ball : s * ball x δ = x • thickening δ s := by
rw [← smul_ball_one, mul_smul_comm, mul_ball_one]
@[to_additive (attr := simp)]
theorem div_ball : s / ball x δ = x⁻¹ • thickening δ s := by simp [div_eq_mul_inv]
@[to_additive (attr := simp)]
theorem ball_mul : ball x δ * s = x • thickening δ s := by rw [mul_comm, mul_ball]
@[to_additive (attr := simp)]
theorem ball_div : ball x δ / s = x • thickening δ s⁻¹ := by simp [div_eq_mul_inv]
variable {δ s x y}
@[to_additive]
theorem IsCompact.mul_closedBall_one (hs : IsCompact s) (hδ : 0 ≤ δ) :
s * closedBall (1 : E) δ = cthickening δ s := by
rw [hs.cthickening_eq_biUnion_closedBall hδ]
ext x
simp only [mem_mul, dist_eq_norm_div, exists_prop, mem_iUnion, mem_closedBall, exists_and_left,
mem_closedBall_one_iff, ← eq_div_iff_mul_eq'', div_one, exists_eq_right]
@[to_additive]
theorem IsCompact.div_closedBall_one (hs : IsCompact s) (hδ : 0 ≤ δ) :
s / closedBall 1 δ = cthickening δ s := by simp [div_eq_mul_inv, hs.mul_closedBall_one hδ]
@[to_additive]
theorem IsCompact.closedBall_one_mul (hs : IsCompact s) (hδ : 0 ≤ δ) :
closedBall 1 δ * s = cthickening δ s := by rw [mul_comm, hs.mul_closedBall_one hδ]
@[to_additive]
theorem IsCompact.closedBall_one_div (hs : IsCompact s) (hδ : 0 ≤ δ) :
closedBall 1 δ / s = cthickening δ s⁻¹ := by
simp [div_eq_mul_inv, mul_comm, hs.inv.mul_closedBall_one hδ]
@[to_additive]
theorem IsCompact.mul_closedBall (hs : IsCompact s) (hδ : 0 ≤ δ) (x : E) :
s * closedBall x δ = x • cthickening δ s := by
| rw [← smul_closedBall_one, mul_smul_comm, hs.mul_closedBall_one hδ]
| Mathlib/Analysis/Normed/Group/Pointwise.lean | 217 | 217 |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Abhimanyu Pallavi Sudhir
-/
import Mathlib.Algebra.CharP.Defs
import Mathlib.Algebra.Order.CauSeq.BigOperators
import Mathlib.Algebra.Order.Star.Basic
import Mathlib.Data.Complex.BigOperators
import Mathlib.Data.Complex.Norm
import Mathlib.Data.Nat.Choose.Sum
/-!
# Exponential Function
This file contains the definitions of the real and complex exponential function.
## Main definitions
* `Complex.exp`: The complex exponential function, defined via its Taylor series
* `Real.exp`: The real exponential function, defined as the real part of the complex exponential
-/
open CauSeq Finset IsAbsoluteValue
open scoped ComplexConjugate
namespace Complex
theorem isCauSeq_norm_exp (z : ℂ) :
IsCauSeq abs fun n => ∑ m ∈ range n, ‖z ^ m / m.factorial‖ :=
let ⟨n, hn⟩ := exists_nat_gt ‖z‖
have hn0 : (0 : ℝ) < n := lt_of_le_of_lt (norm_nonneg _) hn
IsCauSeq.series_ratio_test n (‖z‖ / n) (div_nonneg (norm_nonneg _) (le_of_lt hn0))
(by rwa [div_lt_iff₀ hn0, one_mul]) fun m hm => by
rw [abs_norm, abs_norm, Nat.factorial_succ, pow_succ', mul_comm m.succ, Nat.cast_mul,
← div_div, mul_div_assoc, mul_div_right_comm, Complex.norm_mul, Complex.norm_div,
norm_natCast]
gcongr
exact le_trans hm (Nat.le_succ _)
@[deprecated (since := "2025-02-16")] alias isCauSeq_abs_exp := isCauSeq_norm_exp
noncomputable section
theorem isCauSeq_exp (z : ℂ) : IsCauSeq (‖·‖) fun n => ∑ m ∈ range n, z ^ m / m.factorial :=
(isCauSeq_norm_exp z).of_abv
/-- The Cauchy sequence consisting of partial sums of the Taylor series of
the complex exponential function -/
@[pp_nodot]
def exp' (z : ℂ) : CauSeq ℂ (‖·‖) :=
⟨fun n => ∑ m ∈ range n, z ^ m / m.factorial, isCauSeq_exp z⟩
/-- The complex exponential function, defined via its Taylor series -/
@[pp_nodot]
def exp (z : ℂ) : ℂ :=
CauSeq.lim (exp' z)
/-- scoped notation for the complex exponential function -/
scoped notation "cexp" => Complex.exp
end
end Complex
namespace Real
open Complex
noncomputable section
/-- The real exponential function, defined as the real part of the complex exponential -/
@[pp_nodot]
nonrec def exp (x : ℝ) : ℝ :=
(exp x).re
/-- scoped notation for the real exponential function -/
scoped notation "rexp" => Real.exp
end
end Real
namespace Complex
variable (x y : ℂ)
@[simp]
theorem exp_zero : exp 0 = 1 := by
rw [exp]
refine lim_eq_of_equiv_const fun ε ε0 => ⟨1, fun j hj => ?_⟩
convert (config := .unfoldSameFun) ε0 -- ε0 : ε > 0 but goal is _ < ε
rcases j with - | j
· exact absurd hj (not_le_of_gt zero_lt_one)
· dsimp [exp']
induction' j with j ih
· dsimp [exp']; simp [show Nat.succ 0 = 1 from rfl]
· rw [← ih (by simp [Nat.succ_le_succ])]
simp only [sum_range_succ, pow_succ]
simp
theorem exp_add : exp (x + y) = exp x * exp y := by
have hj : ∀ j : ℕ, (∑ m ∈ range j, (x + y) ^ m / m.factorial) =
∑ i ∈ range j, ∑ k ∈ range (i + 1), x ^ k / k.factorial *
(y ^ (i - k) / (i - k).factorial) := by
intro j
refine Finset.sum_congr rfl fun m _ => ?_
rw [add_pow, div_eq_mul_inv, sum_mul]
refine Finset.sum_congr rfl fun I hi => ?_
have h₁ : (m.choose I : ℂ) ≠ 0 :=
Nat.cast_ne_zero.2 (pos_iff_ne_zero.1 (Nat.choose_pos (Nat.le_of_lt_succ (mem_range.1 hi))))
have h₂ := Nat.choose_mul_factorial_mul_factorial (Nat.le_of_lt_succ <| Finset.mem_range.1 hi)
rw [← h₂, Nat.cast_mul, Nat.cast_mul, mul_inv, mul_inv]
simp only [mul_left_comm (m.choose I : ℂ), mul_assoc, mul_left_comm (m.choose I : ℂ)⁻¹,
mul_comm (m.choose I : ℂ)]
rw [inv_mul_cancel₀ h₁]
simp [div_eq_mul_inv, mul_comm, mul_assoc, mul_left_comm]
simp_rw [exp, exp', lim_mul_lim]
apply (lim_eq_lim_of_equiv _).symm
simp only [hj]
exact cauchy_product (isCauSeq_norm_exp x) (isCauSeq_exp y)
/-- the exponential function as a monoid hom from `Multiplicative ℂ` to `ℂ` -/
@[simps]
noncomputable def expMonoidHom : MonoidHom (Multiplicative ℂ) ℂ :=
{ toFun := fun z => exp z.toAdd,
map_one' := by simp,
map_mul' := by simp [exp_add] }
theorem exp_list_sum (l : List ℂ) : exp l.sum = (l.map exp).prod :=
map_list_prod (M := Multiplicative ℂ) expMonoidHom l
theorem exp_multiset_sum (s : Multiset ℂ) : exp s.sum = (s.map exp).prod :=
@MonoidHom.map_multiset_prod (Multiplicative ℂ) ℂ _ _ expMonoidHom s
theorem exp_sum {α : Type*} (s : Finset α) (f : α → ℂ) :
exp (∑ x ∈ s, f x) = ∏ x ∈ s, exp (f x) :=
map_prod (β := Multiplicative ℂ) expMonoidHom f s
lemma exp_nsmul (x : ℂ) (n : ℕ) : exp (n • x) = exp x ^ n :=
@MonoidHom.map_pow (Multiplicative ℂ) ℂ _ _ expMonoidHom _ _
theorem exp_nat_mul (x : ℂ) : ∀ n : ℕ, exp (n * x) = exp x ^ n
| 0 => by rw [Nat.cast_zero, zero_mul, exp_zero, pow_zero]
| Nat.succ n => by rw [pow_succ, Nat.cast_add_one, add_mul, exp_add, ← exp_nat_mul _ n, one_mul]
@[simp]
theorem exp_ne_zero : exp x ≠ 0 := fun h =>
zero_ne_one (α := ℂ) <| by rw [← exp_zero, ← add_neg_cancel x, exp_add, h]; simp
theorem exp_neg : exp (-x) = (exp x)⁻¹ := by
rw [← mul_right_inj' (exp_ne_zero x), ← exp_add]; simp [mul_inv_cancel₀ (exp_ne_zero x)]
theorem exp_sub : exp (x - y) = exp x / exp y := by
simp [sub_eq_add_neg, exp_add, exp_neg, div_eq_mul_inv]
theorem exp_int_mul (z : ℂ) (n : ℤ) : Complex.exp (n * z) = Complex.exp z ^ n := by
cases n
· simp [exp_nat_mul]
· simp [exp_add, add_mul, pow_add, exp_neg, exp_nat_mul]
@[simp]
theorem exp_conj : exp (conj x) = conj (exp x) := by
dsimp [exp]
rw [← lim_conj]
refine congr_arg CauSeq.lim (CauSeq.ext fun _ => ?_)
dsimp [exp', Function.comp_def, cauSeqConj]
rw [map_sum (starRingEnd _)]
refine sum_congr rfl fun n _ => ?_
rw [map_div₀, map_pow, ← ofReal_natCast, conj_ofReal]
@[simp]
theorem ofReal_exp_ofReal_re (x : ℝ) : ((exp x).re : ℂ) = exp x :=
conj_eq_iff_re.1 <| by rw [← exp_conj, conj_ofReal]
@[simp, norm_cast]
theorem ofReal_exp (x : ℝ) : (Real.exp x : ℂ) = exp x :=
ofReal_exp_ofReal_re _
@[simp]
theorem exp_ofReal_im (x : ℝ) : (exp x).im = 0 := by rw [← ofReal_exp_ofReal_re, ofReal_im]
theorem exp_ofReal_re (x : ℝ) : (exp x).re = Real.exp x :=
rfl
end Complex
namespace Real
open Complex
variable (x y : ℝ)
@[simp]
theorem exp_zero : exp 0 = 1 := by simp [Real.exp]
nonrec theorem exp_add : exp (x + y) = exp x * exp y := by simp [exp_add, exp]
/-- the exponential function as a monoid hom from `Multiplicative ℝ` to `ℝ` -/
@[simps]
noncomputable def expMonoidHom : MonoidHom (Multiplicative ℝ) ℝ :=
{ toFun := fun x => exp x.toAdd,
map_one' := by simp,
map_mul' := by simp [exp_add] }
theorem exp_list_sum (l : List ℝ) : exp l.sum = (l.map exp).prod :=
map_list_prod (M := Multiplicative ℝ) expMonoidHom l
theorem exp_multiset_sum (s : Multiset ℝ) : exp s.sum = (s.map exp).prod :=
@MonoidHom.map_multiset_prod (Multiplicative ℝ) ℝ _ _ expMonoidHom s
theorem exp_sum {α : Type*} (s : Finset α) (f : α → ℝ) :
exp (∑ x ∈ s, f x) = ∏ x ∈ s, exp (f x) :=
map_prod (β := Multiplicative ℝ) expMonoidHom f s
lemma exp_nsmul (x : ℝ) (n : ℕ) : exp (n • x) = exp x ^ n :=
@MonoidHom.map_pow (Multiplicative ℝ) ℝ _ _ expMonoidHom _ _
nonrec theorem exp_nat_mul (x : ℝ) (n : ℕ) : exp (n * x) = exp x ^ n :=
ofReal_injective (by simp [exp_nat_mul])
@[simp]
nonrec theorem exp_ne_zero : exp x ≠ 0 := fun h =>
exp_ne_zero x <| by rw [exp, ← ofReal_inj] at h; simp_all
nonrec theorem exp_neg : exp (-x) = (exp x)⁻¹ :=
ofReal_injective <| by simp [exp_neg]
theorem exp_sub : exp (x - y) = exp x / exp y := by
simp [sub_eq_add_neg, exp_add, exp_neg, div_eq_mul_inv]
open IsAbsoluteValue Nat
theorem sum_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) (n : ℕ) : ∑ i ∈ range n, x ^ i / i ! ≤ exp x :=
calc
∑ i ∈ range n, x ^ i / i ! ≤ lim (⟨_, isCauSeq_re (exp' x)⟩ : CauSeq ℝ abs) := by
refine le_lim (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp only [exp', const_apply, re_sum]
norm_cast
refine sum_le_sum_of_subset_of_nonneg (range_mono hj) fun _ _ _ ↦ ?_
positivity
_ = exp x := by rw [exp, Complex.exp, ← cauSeqRe, lim_re]
lemma pow_div_factorial_le_exp (hx : 0 ≤ x) (n : ℕ) : x ^ n / n ! ≤ exp x :=
calc
x ^ n / n ! ≤ ∑ k ∈ range (n + 1), x ^ k / k ! :=
single_le_sum (f := fun k ↦ x ^ k / k !) (fun k _ ↦ by positivity) (self_mem_range_succ n)
_ ≤ exp x := sum_le_exp_of_nonneg hx _
theorem quadratic_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) : 1 + x + x ^ 2 / 2 ≤ exp x :=
calc
1 + x + x ^ 2 / 2 = ∑ i ∈ range 3, x ^ i / i ! := by
simp only [sum_range_succ, range_one, sum_singleton, _root_.pow_zero, factorial, cast_one,
ne_eq, one_ne_zero, not_false_eq_true, div_self, pow_one, mul_one, div_one, Nat.mul_one,
cast_succ, add_right_inj]
ring_nf
_ ≤ exp x := sum_le_exp_of_nonneg hx 3
private theorem add_one_lt_exp_of_pos {x : ℝ} (hx : 0 < x) : x + 1 < exp x :=
(by nlinarith : x + 1 < 1 + x + x ^ 2 / 2).trans_le (quadratic_le_exp_of_nonneg hx.le)
private theorem add_one_le_exp_of_nonneg {x : ℝ} (hx : 0 ≤ x) : x + 1 ≤ exp x := by
rcases eq_or_lt_of_le hx with (rfl | h)
· simp
exact (add_one_lt_exp_of_pos h).le
theorem one_le_exp {x : ℝ} (hx : 0 ≤ x) : 1 ≤ exp x := by linarith [add_one_le_exp_of_nonneg hx]
@[bound]
theorem exp_pos (x : ℝ) : 0 < exp x :=
(le_total 0 x).elim (lt_of_lt_of_le zero_lt_one ∘ one_le_exp) fun h => by
rw [← neg_neg x, Real.exp_neg]
exact inv_pos.2 (lt_of_lt_of_le zero_lt_one (one_le_exp (neg_nonneg.2 h)))
@[bound]
lemma exp_nonneg (x : ℝ) : 0 ≤ exp x := x.exp_pos.le
@[simp]
theorem abs_exp (x : ℝ) : |exp x| = exp x :=
abs_of_pos (exp_pos _)
lemma exp_abs_le (x : ℝ) : exp |x| ≤ exp x + exp (-x) := by
cases le_total x 0 <;> simp [abs_of_nonpos, abs_of_nonneg, exp_nonneg, *]
@[mono]
theorem exp_strictMono : StrictMono exp := fun x y h => by
rw [← sub_add_cancel y x, Real.exp_add]
exact (lt_mul_iff_one_lt_left (exp_pos _)).2
(lt_of_lt_of_le (by linarith) (add_one_le_exp_of_nonneg (by linarith)))
@[gcongr]
theorem exp_lt_exp_of_lt {x y : ℝ} (h : x < y) : exp x < exp y := exp_strictMono h
@[mono]
theorem exp_monotone : Monotone exp :=
exp_strictMono.monotone
@[gcongr, bound]
theorem exp_le_exp_of_le {x y : ℝ} (h : x ≤ y) : exp x ≤ exp y := exp_monotone h
@[simp]
theorem exp_lt_exp {x y : ℝ} : exp x < exp y ↔ x < y :=
exp_strictMono.lt_iff_lt
@[simp]
theorem exp_le_exp {x y : ℝ} : exp x ≤ exp y ↔ x ≤ y :=
exp_strictMono.le_iff_le
theorem exp_injective : Function.Injective exp :=
exp_strictMono.injective
@[simp]
theorem exp_eq_exp {x y : ℝ} : exp x = exp y ↔ x = y :=
exp_injective.eq_iff
@[simp]
theorem exp_eq_one_iff : exp x = 1 ↔ x = 0 :=
exp_injective.eq_iff' exp_zero
@[simp]
theorem one_lt_exp_iff {x : ℝ} : 1 < exp x ↔ 0 < x := by rw [← exp_zero, exp_lt_exp]
@[bound] private alias ⟨_, Bound.one_lt_exp_of_pos⟩ := one_lt_exp_iff
@[simp]
theorem exp_lt_one_iff {x : ℝ} : exp x < 1 ↔ x < 0 := by rw [← exp_zero, exp_lt_exp]
@[simp]
theorem exp_le_one_iff {x : ℝ} : exp x ≤ 1 ↔ x ≤ 0 :=
exp_zero ▸ exp_le_exp
@[simp]
theorem one_le_exp_iff {x : ℝ} : 1 ≤ exp x ↔ 0 ≤ x :=
exp_zero ▸ exp_le_exp
end Real
namespace Complex
theorem sum_div_factorial_le {α : Type*} [Field α] [LinearOrder α] [IsStrictOrderedRing α]
(n j : ℕ) (hn : 0 < n) :
(∑ m ∈ range j with n ≤ m, (1 / m.factorial : α)) ≤ n.succ / (n.factorial * n) :=
calc
(∑ m ∈ range j with n ≤ m, (1 / m.factorial : α)) =
∑ m ∈ range (j - n), (1 / ((m + n).factorial : α)) := by
refine sum_nbij' (· - n) (· + n) ?_ ?_ ?_ ?_ ?_ <;>
simp +contextual [lt_tsub_iff_right, tsub_add_cancel_of_le]
_ ≤ ∑ m ∈ range (j - n), ((n.factorial : α) * (n.succ : α) ^ m)⁻¹ := by
simp_rw [one_div]
gcongr
rw [← Nat.cast_pow, ← Nat.cast_mul, Nat.cast_le, add_comm]
exact Nat.factorial_mul_pow_le_factorial
_ = (n.factorial : α)⁻¹ * ∑ m ∈ range (j - n), (n.succ : α)⁻¹ ^ m := by
simp [mul_inv, ← mul_sum, ← sum_mul, mul_comm, inv_pow]
_ = ((n.succ : α) - n.succ * (n.succ : α)⁻¹ ^ (j - n)) / (n.factorial * n) := by
have h₁ : (n.succ : α) ≠ 1 :=
@Nat.cast_one α _ ▸ mt Nat.cast_inj.1 (mt Nat.succ.inj (pos_iff_ne_zero.1 hn))
have h₂ : (n.succ : α) ≠ 0 := by positivity
have h₃ : (n.factorial * n : α) ≠ 0 := by positivity
have h₄ : (n.succ - 1 : α) = n := by simp
rw [geom_sum_inv h₁ h₂, eq_div_iff_mul_eq h₃, mul_comm _ (n.factorial * n : α),
← mul_assoc (n.factorial⁻¹ : α), ← mul_inv_rev, h₄, ← mul_assoc (n.factorial * n : α),
mul_comm (n : α) n.factorial, mul_inv_cancel₀ h₃, one_mul, mul_comm]
_ ≤ n.succ / (n.factorial * n : α) := by gcongr; apply sub_le_self; positivity
theorem exp_bound {x : ℂ} (hx : ‖x‖ ≤ 1) {n : ℕ} (hn : 0 < n) :
‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤
‖x‖ ^ n * ((n.succ : ℝ) * (n.factorial * n : ℝ)⁻¹) := by
rw [← lim_const (abv := norm) (∑ m ∈ range n, _), exp, sub_eq_add_neg,
← lim_neg, lim_add, ← lim_norm]
refine lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp_rw [← sub_eq_add_neg]
show
‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤
‖x‖ ^ n * ((n.succ : ℝ) * (n.factorial * n : ℝ)⁻¹)
rw [sum_range_sub_sum_range hj]
calc
‖∑ m ∈ range j with n ≤ m, (x ^ m / m.factorial : ℂ)‖
= ‖∑ m ∈ range j with n ≤ m, (x ^ n * (x ^ (m - n) / m.factorial) : ℂ)‖ := by
refine congr_arg norm (sum_congr rfl fun m hm => ?_)
rw [mem_filter, mem_range] at hm
rw [← mul_div_assoc, ← pow_add, add_tsub_cancel_of_le hm.2]
_ ≤ ∑ m ∈ range j with n ≤ m, ‖x ^ n * (x ^ (m - n) / m.factorial)‖ :=
IsAbsoluteValue.abv_sum norm ..
_ ≤ ∑ m ∈ range j with n ≤ m, ‖x‖ ^ n * (1 / m.factorial) := by
simp_rw [Complex.norm_mul, Complex.norm_pow, Complex.norm_div, norm_natCast]
gcongr
rw [Complex.norm_pow]
exact pow_le_one₀ (norm_nonneg _) hx
_ = ‖x‖ ^ n * ∑ m ∈ range j with n ≤ m, (1 / m.factorial : ℝ) := by
simp [abs_mul, abv_pow abs, abs_div, ← mul_sum]
_ ≤ ‖x‖ ^ n * (n.succ * (n.factorial * n : ℝ)⁻¹) := by
gcongr
exact sum_div_factorial_le _ _ hn
theorem exp_bound' {x : ℂ} {n : ℕ} (hx : ‖x‖ / n.succ ≤ 1 / 2) :
‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n / n.factorial * 2 := by
rw [← lim_const (abv := norm) (∑ m ∈ range n, _),
exp, sub_eq_add_neg, ← lim_neg, lim_add, ← lim_norm]
refine lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp_rw [← sub_eq_add_neg]
show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤
‖x‖ ^ n / n.factorial * 2
let k := j - n
have hj : j = n + k := (add_tsub_cancel_of_le hj).symm
rw [hj, sum_range_add_sub_sum_range]
calc
‖∑ i ∈ range k, x ^ (n + i) / ((n + i).factorial : ℂ)‖ ≤
∑ i ∈ range k, ‖x ^ (n + i) / ((n + i).factorial : ℂ)‖ :=
IsAbsoluteValue.abv_sum _ _ _
_ ≤ ∑ i ∈ range k, ‖x‖ ^ (n + i) / (n + i).factorial := by
simp [norm_natCast, Complex.norm_pow]
_ ≤ ∑ i ∈ range k, ‖x‖ ^ (n + i) / ((n.factorial : ℝ) * (n.succ : ℝ) ^ i) := ?_
_ = ∑ i ∈ range k, ‖x‖ ^ n / n.factorial * (‖x‖ ^ i / (n.succ : ℝ) ^ i) := ?_
_ ≤ ‖x‖ ^ n / ↑n.factorial * 2 := ?_
· gcongr
exact mod_cast Nat.factorial_mul_pow_le_factorial
· refine Finset.sum_congr rfl fun _ _ => ?_
simp only [pow_add, div_eq_inv_mul, mul_inv, mul_left_comm, mul_assoc]
· rw [← mul_sum]
gcongr
simp_rw [← div_pow]
rw [geom_sum_eq, div_le_iff_of_neg]
· trans (-1 : ℝ)
· linarith
· simp only [neg_le_sub_iff_le_add, div_pow, Nat.cast_succ, le_add_iff_nonneg_left]
positivity
· linarith
· linarith
theorem norm_exp_sub_one_le {x : ℂ} (hx : ‖x‖ ≤ 1) : ‖exp x - 1‖ ≤ 2 * ‖x‖ :=
calc
‖exp x - 1‖ = ‖exp x - ∑ m ∈ range 1, x ^ m / m.factorial‖ := by simp [sum_range_succ]
_ ≤ ‖x‖ ^ 1 * ((Nat.succ 1 : ℝ) * ((Nat.factorial 1) * (1 : ℕ) : ℝ)⁻¹) :=
(exp_bound hx (by decide))
_ = 2 * ‖x‖ := by simp [two_mul, mul_two, mul_add, mul_comm, add_mul, Nat.factorial]
theorem norm_exp_sub_one_sub_id_le {x : ℂ} (hx : ‖x‖ ≤ 1) : ‖exp x - 1 - x‖ ≤ ‖x‖ ^ 2 :=
calc
‖exp x - 1 - x‖ = ‖exp x - ∑ m ∈ range 2, x ^ m / m.factorial‖ := by
simp [sub_eq_add_neg, sum_range_succ_comm, add_assoc, Nat.factorial]
_ ≤ ‖x‖ ^ 2 * ((Nat.succ 2 : ℝ) * (Nat.factorial 2 * (2 : ℕ) : ℝ)⁻¹) :=
(exp_bound hx (by decide))
_ ≤ ‖x‖ ^ 2 * 1 := by gcongr; norm_num [Nat.factorial]
_ = ‖x‖ ^ 2 := by rw [mul_one]
lemma norm_exp_sub_sum_le_exp_norm_sub_sum (x : ℂ) (n : ℕ) :
‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖
≤ Real.exp ‖x‖ - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by
rw [← CauSeq.lim_const (abv := norm) (∑ m ∈ range n, _), Complex.exp, sub_eq_add_neg,
← CauSeq.lim_neg, CauSeq.lim_add, ← lim_norm]
refine CauSeq.lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp_rw [← sub_eq_add_neg]
calc ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖
_ ≤ (∑ m ∈ range j, ‖x‖ ^ m / m.factorial) - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by
rw [sum_range_sub_sum_range hj, sum_range_sub_sum_range hj]
refine (IsAbsoluteValue.abv_sum norm ..).trans_eq ?_
congr with i
simp [Complex.norm_pow]
_ ≤ Real.exp ‖x‖ - ∑ m ∈ range n, ‖x‖ ^ m / m.factorial := by
gcongr
exact Real.sum_le_exp_of_nonneg (norm_nonneg _) _
lemma norm_exp_le_exp_norm (x : ℂ) : ‖exp x‖ ≤ Real.exp ‖x‖ := by
convert norm_exp_sub_sum_le_exp_norm_sub_sum x 0 using 1 <;> simp
lemma norm_exp_sub_sum_le_norm_mul_exp (x : ℂ) (n : ℕ) :
‖exp x - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ ‖x‖ ^ n * Real.exp ‖x‖ := by
rw [← CauSeq.lim_const (abv := norm) (∑ m ∈ range n, _), Complex.exp, sub_eq_add_neg,
← CauSeq.lim_neg, CauSeq.lim_add, ← lim_norm]
refine CauSeq.lim_le (CauSeq.le_of_exists ⟨n, fun j hj => ?_⟩)
simp_rw [← sub_eq_add_neg]
show ‖(∑ m ∈ range j, x ^ m / m.factorial) - ∑ m ∈ range n, x ^ m / m.factorial‖ ≤ _
rw [sum_range_sub_sum_range hj]
calc
‖∑ m ∈ range j with n ≤ m, (x ^ m / m.factorial : ℂ)‖
= ‖∑ m ∈ range j with n ≤ m, (x ^ n * (x ^ (m - n) / m.factorial) : ℂ)‖ := by
refine congr_arg norm (sum_congr rfl fun m hm => ?_)
rw [mem_filter, mem_range] at hm
rw [← mul_div_assoc, ← pow_add, add_tsub_cancel_of_le hm.2]
_ ≤ ∑ m ∈ range j with n ≤ m, ‖x ^ n * (x ^ (m - n) / m.factorial)‖ :=
IsAbsoluteValue.abv_sum norm ..
_ ≤ ∑ m ∈ range j with n ≤ m, ‖x‖ ^ n * (‖x‖ ^ (m - n) / (m - n).factorial) := by
simp_rw [Complex.norm_mul, Complex.norm_pow, Complex.norm_div, norm_natCast]
gcongr with i hi
· rw [Complex.norm_pow]
· simp
_ = ‖x‖ ^ n * ∑ m ∈ range j with n ≤ m, (‖x‖ ^ (m - n) / (m - n).factorial) := by
rw [← mul_sum]
_ = ‖x‖ ^ n * ∑ m ∈ range (j - n), (‖x‖ ^ m / m.factorial) := by
congr 1
refine (sum_bij (fun m hm ↦ m + n) ?_ ?_ ?_ ?_).symm
· intro a ha
simp only [mem_filter, mem_range, le_add_iff_nonneg_left, zero_le, and_true]
simp only [mem_range] at ha
rwa [← lt_tsub_iff_right]
· intro a ha b hb hab
simpa using hab
· intro b hb
simp only [mem_range, exists_prop]
simp only [mem_filter, mem_range] at hb
refine ⟨b - n, ?_, ?_⟩
· rw [tsub_lt_tsub_iff_right hb.2]
exact hb.1
· rw [tsub_add_cancel_of_le hb.2]
· simp
_ ≤ ‖x‖ ^ n * Real.exp ‖x‖ := by
gcongr
refine Real.sum_le_exp_of_nonneg ?_ _
exact norm_nonneg _
@[deprecated (since := "2025-02-16")] alias abs_exp_sub_one_le := norm_exp_sub_one_le
@[deprecated (since := "2025-02-16")] alias abs_exp_sub_one_sub_id_le := norm_exp_sub_one_sub_id_le
@[deprecated (since := "2025-02-16")] alias abs_exp_sub_sum_le_exp_abs_sub_sum :=
norm_exp_sub_sum_le_exp_norm_sub_sum
@[deprecated (since := "2025-02-16")] alias abs_exp_le_exp_abs := norm_exp_le_exp_norm
@[deprecated (since := "2025-02-16")] alias abs_exp_sub_sum_le_abs_mul_exp :=
norm_exp_sub_sum_le_norm_mul_exp
end Complex
namespace Real
open Complex Finset
nonrec theorem exp_bound {x : ℝ} (hx : |x| ≤ 1) {n : ℕ} (hn : 0 < n) :
|exp x - ∑ m ∈ range n, x ^ m / m.factorial| ≤ |x| ^ n * (n.succ / (n.factorial * n)) := by
have hxc : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx
convert exp_bound hxc hn using 2 <;>
norm_cast
theorem exp_bound' {x : ℝ} (h1 : 0 ≤ x) (h2 : x ≤ 1) {n : ℕ} (hn : 0 < n) :
Real.exp x ≤ (∑ m ∈ Finset.range n, x ^ m / m.factorial) +
x ^ n * (n + 1) / (n.factorial * n) := by
have h3 : |x| = x := by simpa
have h4 : |x| ≤ 1 := by rwa [h3]
have h' := Real.exp_bound h4 hn
rw [h3] at h'
have h'' := (abs_sub_le_iff.1 h').1
have t := sub_le_iff_le_add'.1 h''
simpa [mul_div_assoc] using t
theorem abs_exp_sub_one_le {x : ℝ} (hx : |x| ≤ 1) : |exp x - 1| ≤ 2 * |x| := by
have : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx
exact_mod_cast Complex.norm_exp_sub_one_le (x := x) this
theorem abs_exp_sub_one_sub_id_le {x : ℝ} (hx : |x| ≤ 1) : |exp x - 1 - x| ≤ x ^ 2 := by
rw [← sq_abs]
have : ‖(x : ℂ)‖ ≤ 1 := mod_cast hx
exact_mod_cast Complex.norm_exp_sub_one_sub_id_le this
/-- A finite initial segment of the exponential series, followed by an arbitrary tail.
For fixed `n` this is just a linear map wrt `r`, and each map is a simple linear function
of the previous (see `expNear_succ`), with `expNear n x r ⟶ exp x` as `n ⟶ ∞`,
for any `r`. -/
noncomputable def expNear (n : ℕ) (x r : ℝ) : ℝ :=
(∑ m ∈ range n, x ^ m / m.factorial) + x ^ n / n.factorial * r
@[simp]
theorem expNear_zero (x r) : expNear 0 x r = r := by simp [expNear]
@[simp]
theorem expNear_succ (n x r) : expNear (n + 1) x r = expNear n x (1 + x / (n + 1) * r) := by
simp [expNear, range_succ, mul_add, add_left_comm, add_assoc, pow_succ, div_eq_mul_inv,
mul_inv, Nat.factorial]
ac_rfl
theorem expNear_sub (n x r₁ r₂) : expNear n x r₁ -
expNear n x r₂ = x ^ n / n.factorial * (r₁ - r₂) := by
simp [expNear, mul_sub]
theorem exp_approx_end (n m : ℕ) (x : ℝ) (e₁ : n + 1 = m) (h : |x| ≤ 1) :
|exp x - expNear m x 0| ≤ |x| ^ m / m.factorial * ((m + 1) / m) := by
simp only [expNear, mul_zero, add_zero]
convert exp_bound (n := m) h ?_ using 1
· field_simp [mul_comm]
· omega
theorem exp_approx_succ {n} {x a₁ b₁ : ℝ} (m : ℕ) (e₁ : n + 1 = m) (a₂ b₂ : ℝ)
(e : |1 + x / m * a₂ - a₁| ≤ b₁ - |x| / m * b₂)
(h : |exp x - expNear m x a₂| ≤ |x| ^ m / m.factorial * b₂) :
|exp x - expNear n x a₁| ≤ |x| ^ n / n.factorial * b₁ := by
refine (abs_sub_le _ _ _).trans ((add_le_add_right h _).trans ?_)
subst e₁; rw [expNear_succ, expNear_sub, abs_mul]
convert mul_le_mul_of_nonneg_left (a := |x| ^ n / ↑(Nat.factorial n))
(le_sub_iff_add_le'.1 e) ?_ using 1
· simp [mul_add, pow_succ', div_eq_mul_inv, abs_mul, abs_inv, ← pow_abs, mul_inv, Nat.factorial]
ac_rfl
· simp [div_nonneg, abs_nonneg]
theorem exp_approx_end' {n} {x a b : ℝ} (m : ℕ) (e₁ : n + 1 = m) (rm : ℝ) (er : ↑m = rm)
(h : |x| ≤ 1) (e : |1 - a| ≤ b - |x| / rm * ((rm + 1) / rm)) :
|exp x - expNear n x a| ≤ |x| ^ n / n.factorial * b := by
subst er
exact exp_approx_succ _ e₁ _ _ (by simpa using e) (exp_approx_end _ _ _ e₁ h)
theorem exp_1_approx_succ_eq {n} {a₁ b₁ : ℝ} {m : ℕ} (en : n + 1 = m) {rm : ℝ} (er : ↑m = rm)
(h : |exp 1 - expNear m 1 ((a₁ - 1) * rm)| ≤ |1| ^ m / m.factorial * (b₁ * rm)) :
|exp 1 - expNear n 1 a₁| ≤ |1| ^ n / n.factorial * b₁ := by
subst er
refine exp_approx_succ _ en _ _ ?_ h
field_simp [show (m : ℝ) ≠ 0 by norm_cast; omega]
theorem exp_approx_start (x a b : ℝ) (h : |exp x - expNear 0 x a| ≤ |x| ^ 0 / Nat.factorial 0 * b) :
|exp x - a| ≤ b := by simpa using h
theorem exp_bound_div_one_sub_of_interval' {x : ℝ} (h1 : 0 < x) (h2 : x < 1) :
Real.exp x < 1 / (1 - x) := by
have H : 0 < 1 - (1 + x + x ^ 2) * (1 - x) := calc
0 < x ^ 3 := by positivity
_ = 1 - (1 + x + x ^ 2) * (1 - x) := by ring
calc
exp x ≤ _ := exp_bound' h1.le h2.le zero_lt_three
_ ≤ 1 + x + x ^ 2 := by
-- Porting note: was `norm_num [Finset.sum] <;> nlinarith`
-- This proof should be restored after the norm_num plugin for big operators is ported.
-- (It may also need the positivity extensions in https://github.com/leanprover-community/mathlib4/pull/3907.)
rw [show 3 = 1 + 1 + 1 from rfl]
repeat rw [Finset.sum_range_succ]
norm_num [Nat.factorial]
nlinarith
_ < 1 / (1 - x) := by rw [lt_div_iff₀] <;> nlinarith
theorem exp_bound_div_one_sub_of_interval {x : ℝ} (h1 : 0 ≤ x) (h2 : x < 1) :
Real.exp x ≤ 1 / (1 - x) := by
rcases eq_or_lt_of_le h1 with (rfl | h1)
· simp
· exact (exp_bound_div_one_sub_of_interval' h1 h2).le
theorem add_one_lt_exp {x : ℝ} (hx : x ≠ 0) : x + 1 < Real.exp x := by
obtain hx | hx := hx.symm.lt_or_lt
· exact add_one_lt_exp_of_pos hx
obtain h' | h' := le_or_lt 1 (-x)
· linarith [x.exp_pos]
have hx' : 0 < x + 1 := by linarith
simpa [add_comm, exp_neg, inv_lt_inv₀ (exp_pos _) hx']
using exp_bound_div_one_sub_of_interval' (neg_pos.2 hx) h'
theorem add_one_le_exp (x : ℝ) : x + 1 ≤ Real.exp x := by
obtain rfl | hx := eq_or_ne x 0
· simp
· exact (add_one_lt_exp hx).le
lemma one_sub_lt_exp_neg {x : ℝ} (hx : x ≠ 0) : 1 - x < exp (-x) :=
(sub_eq_neg_add _ _).trans_lt <| add_one_lt_exp <| neg_ne_zero.2 hx
lemma one_sub_le_exp_neg (x : ℝ) : 1 - x ≤ exp (-x) :=
(sub_eq_neg_add _ _).trans_le <| add_one_le_exp _
theorem one_sub_div_pow_le_exp_neg {n : ℕ} {t : ℝ} (ht' : t ≤ n) : (1 - t / n) ^ n ≤ exp (-t) := by
rcases eq_or_ne n 0 with (rfl | hn)
· simp
rwa [Nat.cast_zero] at ht'
calc
(1 - t / n) ^ n ≤ rexp (-(t / n)) ^ n := by
gcongr
· exact sub_nonneg.2 <| div_le_one_of_le₀ ht' n.cast_nonneg
· exact one_sub_le_exp_neg _
_ = rexp (-t) := by rw [← Real.exp_nat_mul, mul_neg, mul_comm, div_mul_cancel₀]; positivity
lemma le_inv_mul_exp (x : ℝ) {c : ℝ} (hc : 0 < c) : x ≤ c⁻¹ * exp (c * x) := by
rw [le_inv_mul_iff₀ hc]
calc c * x
_ ≤ c * x + 1 := le_add_of_nonneg_right zero_le_one
_ ≤ _ := Real.add_one_le_exp (c * x)
end Real
namespace Mathlib.Meta.Positivity
open Lean.Meta Qq
/-- Extension for the `positivity` tactic: `Real.exp` is always positive. -/
@[positivity Real.exp _]
def evalExp : PositivityExt where eval {u α} _ _ e := do
match u, α, e with
| 0, ~q(ℝ), ~q(Real.exp $a) =>
assertInstancesCommute
pure (.positive q(Real.exp_pos $a))
| _, _, _ => throwError "not Real.exp"
end Mathlib.Meta.Positivity
namespace Complex
@[simp]
theorem norm_exp_ofReal (x : ℝ) : ‖exp x‖ = Real.exp x := by
rw [← ofReal_exp]
exact Complex.norm_of_nonneg (le_of_lt (Real.exp_pos _))
@[deprecated (since := "2025-02-16")] alias abs_exp_ofReal := norm_exp_ofReal
end Complex
| Mathlib/Data/Complex/Exponential.lean | 1,083 | 1,084 | |
/-
Copyright (c) 2019 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Mario Carneiro
-/
import Mathlib.Algebra.GroupWithZero.Divisibility
import Mathlib.Algebra.Ring.Rat
import Mathlib.Algebra.Ring.Int.Parity
import Mathlib.Data.PNat.Defs
/-!
# Further lemmas for the Rational Numbers
-/
namespace Rat
theorem num_dvd (a) {b : ℤ} (b0 : b ≠ 0) : (a /. b).num ∣ a := by
rcases e : a /. b with ⟨n, d, h, c⟩
rw [Rat.mk'_eq_divInt, divInt_eq_iff b0 (mod_cast h)] at e
refine Int.natAbs_dvd.1 <| Int.dvd_natAbs.1 <| Int.natCast_dvd_natCast.2 <|
c.dvd_of_dvd_mul_right ?_
have := congr_arg Int.natAbs e
simp only [Int.natAbs_mul, Int.natAbs_natCast] at this; simp [this]
theorem den_dvd (a b : ℤ) : ((a /. b).den : ℤ) ∣ b := by
by_cases b0 : b = 0; · simp [b0]
rcases e : a /. b with ⟨n, d, h, c⟩
rw [mk'_eq_divInt, divInt_eq_iff b0 (ne_of_gt (Int.natCast_pos.2 (Nat.pos_of_ne_zero h)))] at e
refine Int.dvd_natAbs.1 <| Int.natCast_dvd_natCast.2 <| c.symm.dvd_of_dvd_mul_left ?_
rw [← Int.natAbs_mul, ← Int.natCast_dvd_natCast, Int.dvd_natAbs, ← e]; simp
theorem num_den_mk {q : ℚ} {n d : ℤ} (hd : d ≠ 0) (qdf : q = n /. d) :
∃ c : ℤ, n = c * q.num ∧ d = c * q.den := by
obtain rfl | hn := eq_or_ne n 0
· simp [qdf]
have : q.num * d = n * ↑q.den := by
refine (divInt_eq_iff ?_ hd).mp ?_
· exact Int.natCast_ne_zero.mpr (Rat.den_nz _)
· rwa [num_divInt_den]
have hqdn : q.num ∣ n := by
rw [qdf]
exact Rat.num_dvd _ hd
refine ⟨n / q.num, ?_, ?_⟩
· rw [Int.ediv_mul_cancel hqdn]
· refine Int.eq_mul_div_of_mul_eq_mul_of_dvd_left ?_ hqdn this
rw [qdf]
exact Rat.num_ne_zero.2 ((divInt_ne_zero hd).mpr hn)
theorem num_mk (n d : ℤ) : (n /. d).num = d.sign * n / n.gcd d := by
have (m : ℕ) : Int.natAbs (m + 1) = m + 1 := by
rw [← Nat.cast_one, ← Nat.cast_add, Int.natAbs_cast]
rcases d with ((_ | _) | _) <;>
rw [← Int.tdiv_eq_ediv_of_dvd] <;>
simp [divInt, mkRat, Rat.normalize, Nat.succPNat, Int.sign, Int.gcd,
Int.zero_ediv, Int.ofNat_dvd_left, Nat.gcd_dvd_left, this]
theorem den_mk (n d : ℤ) : (n /. d).den = if d = 0 then 1 else d.natAbs / n.gcd d := by
have (m : ℕ) : Int.natAbs (m + 1) = m + 1 := by
rw [← Nat.cast_one, ← Nat.cast_add, Int.natAbs_cast]
rcases d with ((_ | _) | _) <;>
simp [divInt, mkRat, Rat.normalize, Nat.succPNat, Int.sign, Int.gcd,
if_neg (Nat.cast_add_one_ne_zero _), this]
theorem add_den_dvd_lcm (q₁ q₂ : ℚ) : (q₁ + q₂).den ∣ q₁.den.lcm q₂.den := by
rw [add_def, normalize_eq, Nat.div_dvd_iff_dvd_mul (Nat.gcd_dvd_right _ _)
(Nat.gcd_ne_zero_right (by simp)), ← Nat.gcd_mul_lcm,
mul_dvd_mul_iff_right (Nat.lcm_ne_zero (by simp) (by simp)), Nat.dvd_gcd_iff]
refine ⟨?_, dvd_mul_right _ _⟩
rw [← Int.natCast_dvd_natCast, Int.dvd_natAbs]
apply Int.dvd_add
<;> apply dvd_mul_of_dvd_right <;> rw [Int.natCast_dvd_natCast]
<;> [exact Nat.gcd_dvd_right _ _; exact Nat.gcd_dvd_left _ _]
theorem add_den_dvd (q₁ q₂ : ℚ) : (q₁ + q₂).den ∣ q₁.den * q₂.den := by
rw [add_def, normalize_eq]
apply Nat.div_dvd_of_dvd
apply Nat.gcd_dvd_right
theorem mul_den_dvd (q₁ q₂ : ℚ) : (q₁ * q₂).den ∣ q₁.den * q₂.den := by
rw [mul_def, normalize_eq]
apply Nat.div_dvd_of_dvd
apply Nat.gcd_dvd_right
theorem mul_num (q₁ q₂ : ℚ) :
(q₁ * q₂).num = q₁.num * q₂.num / Nat.gcd (q₁.num * q₂.num).natAbs (q₁.den * q₂.den) := by
rw [mul_def, normalize_eq]
theorem mul_den (q₁ q₂ : ℚ) :
(q₁ * q₂).den =
q₁.den * q₂.den / Nat.gcd (q₁.num * q₂.num).natAbs (q₁.den * q₂.den) := by
rw [mul_def, normalize_eq]
theorem mul_self_num (q : ℚ) : (q * q).num = q.num * q.num := by
rw [mul_num, Int.natAbs_mul, Nat.Coprime.gcd_eq_one, Int.ofNat_one, Int.ediv_one]
exact (q.reduced.mul_right q.reduced).mul (q.reduced.mul_right q.reduced)
theorem mul_self_den (q : ℚ) : (q * q).den = q.den * q.den := by
rw [Rat.mul_den, Int.natAbs_mul, Nat.Coprime.gcd_eq_one, Nat.div_one]
exact (q.reduced.mul_right q.reduced).mul (q.reduced.mul_right q.reduced)
theorem add_num_den (q r : ℚ) :
q + r = (q.num * r.den + q.den * r.num : ℤ) /. (↑q.den * ↑r.den : ℤ) := by
have hqd : (q.den : ℤ) ≠ 0 := Int.natCast_ne_zero_iff_pos.2 q.den_pos
have hrd : (r.den : ℤ) ≠ 0 := Int.natCast_ne_zero_iff_pos.2 r.den_pos
conv_lhs => rw [← num_divInt_den q, ← num_divInt_den r, divInt_add_divInt _ _ hqd hrd]
rw [mul_comm r.num q.den]
theorem isSquare_iff {q : ℚ} : IsSquare q ↔ IsSquare q.num ∧ IsSquare q.den := by
constructor
· rintro ⟨qr, rfl⟩
rw [Rat.mul_self_num, mul_self_den]
simp only [IsSquare.mul_self, and_self]
· rintro ⟨⟨nr, hnr⟩, ⟨dr, hdr⟩⟩
refine ⟨nr / dr, ?_⟩
rw [div_mul_div_comm, ← Int.cast_mul, ← Nat.cast_mul, ← hnr, ← hdr, num_div_den]
@[norm_cast, simp]
theorem isSquare_natCast_iff {n : ℕ} : IsSquare (n : ℚ) ↔ IsSquare n := by
simp_rw [isSquare_iff, num_natCast, den_natCast, IsSquare.one, and_true, Int.isSquare_natCast_iff]
@[norm_cast, simp]
theorem isSquare_intCast_iff {z : ℤ} : IsSquare (z : ℚ) ↔ IsSquare z := by
simp_rw [isSquare_iff, intCast_num, intCast_den, IsSquare.one, and_true]
@[simp]
theorem isSquare_ofNat_iff {n : ℕ} :
IsSquare (ofNat(n) : ℚ) ↔ IsSquare (OfNat.ofNat n : ℕ) :=
isSquare_natCast_iff
section Casts
theorem exists_eq_mul_div_num_and_eq_mul_div_den (n : ℤ) {d : ℤ} (d_ne_zero : d ≠ 0) :
∃ c : ℤ, n = c * ((n : ℚ) / d).num ∧ (d : ℤ) = c * ((n : ℚ) / d).den :=
haveI : (n : ℚ) / d = Rat.divInt n d := by rw [← Rat.divInt_eq_div]
Rat.num_den_mk d_ne_zero this
theorem mul_num_den' (q r : ℚ) :
(q * r).num * q.den * r.den = q.num * r.num * (q * r).den := by
let s := q.num * r.num /. (q.den * r.den : ℤ)
have hs : (q.den * r.den : ℤ) ≠ 0 := Int.natCast_ne_zero_iff_pos.mpr (Nat.mul_pos q.pos r.pos)
obtain ⟨c, ⟨c_mul_num, c_mul_den⟩⟩ :=
exists_eq_mul_div_num_and_eq_mul_div_den (q.num * r.num) hs
rw [c_mul_num, mul_assoc, mul_comm]
nth_rw 1 [c_mul_den]
rw [Int.mul_assoc, Int.mul_assoc, mul_eq_mul_left_iff, or_iff_not_imp_right]
intro
have h : _ = s := divInt_mul_divInt q.num r.num (mod_cast q.den_ne_zero) (mod_cast r.den_ne_zero)
rw [num_divInt_den, num_divInt_den] at h
rw [h, mul_comm, ← Rat.eq_iff_mul_eq_mul, ← divInt_eq_div]
theorem add_num_den' (q r : ℚ) :
(q + r).num * q.den * r.den = (q.num * r.den + r.num * q.den) * (q + r).den := by
let s := divInt (q.num * r.den + r.num * q.den) (q.den * r.den : ℤ)
have hs : (q.den * r.den : ℤ) ≠ 0 := Int.natCast_ne_zero_iff_pos.mpr (Nat.mul_pos q.pos r.pos)
obtain ⟨c, ⟨c_mul_num, c_mul_den⟩⟩ :=
exists_eq_mul_div_num_and_eq_mul_div_den (q.num * r.den + r.num * q.den) hs
rw [c_mul_num, mul_assoc, mul_comm]
nth_rw 1 [c_mul_den]
repeat rw [Int.mul_assoc]
apply mul_eq_mul_left_iff.2
rw [or_iff_not_imp_right]
intro
have h : _ = s := divInt_add_divInt q.num r.num (mod_cast q.den_ne_zero) (mod_cast r.den_ne_zero)
rw [num_divInt_den, num_divInt_den] at h
rw [h]
rw [mul_comm]
apply Rat.eq_iff_mul_eq_mul.mp
rw [← divInt_eq_div]
theorem substr_num_den' (q r : ℚ) :
(q - r).num * q.den * r.den = (q.num * r.den - r.num * q.den) * (q - r).den := by
rw [sub_eq_add_neg, sub_eq_add_neg, ← neg_mul, ← num_neg_eq_neg_num, ← den_neg_eq_den r,
add_num_den' q (-r)]
end Casts
protected theorem inv_neg (q : ℚ) : (-q)⁻¹ = -q⁻¹ := by
rw [← num_divInt_den q]
simp only [Rat.neg_divInt, Rat.inv_divInt', eq_self_iff_true, Rat.divInt_neg]
theorem num_div_eq_of_coprime {a b : ℤ} (hb0 : 0 < b) (h : Nat.Coprime a.natAbs b.natAbs) :
(a / b : ℚ).num = a := by
lift b to ℕ using hb0.le
simp only [Int.natAbs_natCast, Int.ofNat_pos] at h hb0
rw [← Rat.divInt_eq_div, ← mk_eq_divInt _ _ hb0.ne' h]
theorem den_div_eq_of_coprime {a b : ℤ} (hb0 : 0 < b) (h : Nat.Coprime a.natAbs b.natAbs) :
((a / b : ℚ).den : ℤ) = b := by
lift b to ℕ using hb0.le
simp only [Int.natAbs_natCast, Int.ofNat_pos] at h hb0
rw [← Rat.divInt_eq_div, ← mk_eq_divInt _ _ hb0.ne' h]
theorem div_int_inj {a b c d : ℤ} (hb0 : 0 < b) (hd0 : 0 < d) (h1 : Nat.Coprime a.natAbs b.natAbs)
(h2 : Nat.Coprime c.natAbs d.natAbs) (h : (a : ℚ) / b = (c : ℚ) / d) : a = c ∧ b = d := by
apply And.intro
· rw [← num_div_eq_of_coprime hb0 h1, h, num_div_eq_of_coprime hd0 h2]
· rw [← den_div_eq_of_coprime hb0 h1, h, den_div_eq_of_coprime hd0 h2]
@[norm_cast]
theorem intCast_div_self (n : ℤ) : ((n / n : ℤ) : ℚ) = n / n := by
by_cases hn : n = 0
· subst hn
simp only [Int.cast_zero, Int.zero_tdiv, zero_div, Int.ediv_zero]
· have : (n : ℚ) ≠ 0 := by rwa [← coe_int_inj] at hn
simp only [Int.ediv_self hn, Int.cast_one, Ne, not_false_iff, div_self this]
@[norm_cast]
theorem natCast_div_self (n : ℕ) : ((n / n : ℕ) : ℚ) = n / n :=
intCast_div_self n
theorem intCast_div (a b : ℤ) (h : b ∣ a) : ((a / b : ℤ) : ℚ) = a / b := by
rcases h with ⟨c, rfl⟩
rw [mul_comm b, Int.mul_ediv_assoc c (dvd_refl b), Int.cast_mul,
intCast_div_self, Int.cast_mul, mul_div_assoc]
theorem natCast_div (a b : ℕ) (h : b ∣ a) : ((a / b : ℕ) : ℚ) = a / b :=
intCast_div a b (Int.ofNat_dvd.mpr h)
theorem den_div_intCast_eq_one_iff (m n : ℤ) (hn : n ≠ 0) : ((m : ℚ) / n).den = 1 ↔ n ∣ m := by
replace hn : (n : ℚ) ≠ 0 := num_ne_zero.mp hn
constructor
· rw [Rat.den_eq_one_iff, eq_div_iff hn]
exact mod_cast (Dvd.intro_left _)
· exact (intCast_div _ _ · ▸ rfl)
theorem den_div_natCast_eq_one_iff (m n : ℕ) (hn : n ≠ 0) : ((m : ℚ) / n).den = 1 ↔ n ∣ m :=
(den_div_intCast_eq_one_iff m n (Int.ofNat_ne_zero.mpr hn)).trans Int.ofNat_dvd
theorem inv_intCast_num_of_pos {a : ℤ} (ha0 : 0 < a) : (a : ℚ)⁻¹.num = 1 := by
rw [← ofInt_eq_cast, ofInt, mk_eq_divInt, Rat.inv_divInt', divInt_eq_div, Nat.cast_one]
apply num_div_eq_of_coprime ha0
rw [Int.natAbs_one]
exact Nat.coprime_one_left _
theorem inv_natCast_num_of_pos {a : ℕ} (ha0 : 0 < a) : (a : ℚ)⁻¹.num = 1 :=
inv_intCast_num_of_pos (mod_cast ha0 : 0 < (a : ℤ))
theorem inv_intCast_den_of_pos {a : ℤ} (ha0 : 0 < a) : ((a : ℚ)⁻¹.den : ℤ) = a := by
rw [← ofInt_eq_cast, ofInt, mk_eq_divInt, Rat.inv_divInt', divInt_eq_div, Nat.cast_one]
apply den_div_eq_of_coprime ha0
rw [Int.natAbs_one]
exact Nat.coprime_one_left _
theorem inv_natCast_den_of_pos {a : ℕ} (ha0 : 0 < a) : (a : ℚ)⁻¹.den = a := by
rw [← Int.ofNat_inj, ← Int.cast_natCast a, inv_intCast_den_of_pos]
rwa [Int.natCast_pos]
@[simp]
theorem inv_intCast_num (a : ℤ) : (a : ℚ)⁻¹.num = Int.sign a := by
rcases lt_trichotomy a 0 with lt | rfl | gt
· obtain ⟨a, rfl⟩ : ∃ b, -b = a := ⟨-a, a.neg_neg⟩
simp at lt
simp [Rat.inv_neg, inv_intCast_num_of_pos lt, Int.sign_eq_one_iff_pos.mpr lt]
· simp
· simp [inv_intCast_num_of_pos gt, Int.sign_eq_one_iff_pos.mpr gt]
@[simp]
theorem inv_natCast_num (a : ℕ) : (a : ℚ)⁻¹.num = Int.sign a :=
inv_intCast_num a
@[simp]
theorem inv_ofNat_num (a : ℕ) [a.AtLeastTwo] : (ofNat(a) : ℚ)⁻¹.num = 1 :=
inv_natCast_num_of_pos (Nat.pos_of_neZero a)
@[simp]
theorem inv_intCast_den (a : ℤ) : (a : ℚ)⁻¹.den = if a = 0 then 1 else a.natAbs := by
rw [← Int.ofNat_inj]
rcases lt_trichotomy a 0 with lt | rfl | gt
· obtain ⟨a, rfl⟩ : ∃ b, -b = a := ⟨-a, a.neg_neg⟩
simp at lt
rw [if_neg (by omega)]
simp only [Int.cast_neg, Rat.inv_neg, neg_den, inv_intCast_den_of_pos lt, Int.natAbs_neg]
exact Int.eq_natAbs_of_nonneg (by omega)
· simp
· rw [if_neg (by omega)]
simp only [inv_intCast_den_of_pos gt]
exact Int.eq_natAbs_of_nonneg (by omega)
@[simp]
theorem inv_natCast_den (a : ℕ) : (a : ℚ)⁻¹.den = if a = 0 then 1 else a := by
simpa [-inv_intCast_den, ofInt_eq_cast] using inv_intCast_den a
@[simp]
theorem inv_ofNat_den (a : ℕ) [a.AtLeastTwo] :
(ofNat(a) : ℚ)⁻¹.den = OfNat.ofNat a :=
inv_natCast_den_of_pos (Nat.pos_of_neZero a)
protected theorem «forall» {p : ℚ → Prop} : (∀ r, p r) ↔ ∀ a b : ℤ, p (a / b) :=
⟨fun h _ _ => h _,
fun h q => by
have := h q.num q.den
rwa [Int.cast_natCast, num_div_den q] at this⟩
protected theorem «exists» {p : ℚ → Prop} : (∃ r, p r) ↔ ∃ a b : ℤ, p (a / b) :=
⟨fun ⟨r, hr⟩ => ⟨r.num, r.den, by convert hr; convert num_div_den r⟩, fun ⟨_, _, h⟩ => ⟨_, h⟩⟩
/-!
### Denominator as `ℕ+`
-/
section PNatDen
/-- Denominator as `ℕ+`. -/
def pnatDen (x : ℚ) : ℕ+ :=
⟨x.den, x.pos⟩
@[simp]
theorem coe_pnatDen (x : ℚ) : (x.pnatDen : ℕ) = x.den :=
rfl
theorem pnatDen_eq_iff_den_eq {x : ℚ} {n : ℕ+} : x.pnatDen = n ↔ x.den = ↑n :=
Subtype.ext_iff
@[simp]
theorem pnatDen_one : (1 : ℚ).pnatDen = 1 :=
rfl
@[simp]
theorem pnatDen_zero : (0 : ℚ).pnatDen = 1 :=
rfl
end PNatDen
end Rat
| Mathlib/Data/Rat/Lemmas.lean | 345 | 346 | |
/-
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.Algebra.BigOperators.Ring.Finset
import Mathlib.Algebra.Module.BigOperators
import Mathlib.NumberTheory.Divisors
import Mathlib.Data.Nat.Squarefree
import Mathlib.Data.Nat.GCD.BigOperators
import Mathlib.Data.Nat.Factorization.Induction
import Mathlib.Tactic.ArithMult
/-!
# Arithmetic Functions and Dirichlet Convolution
This file defines arithmetic functions, which are functions from `ℕ` to a specified type that map 0
to 0. In the literature, they are often instead defined as functions from `ℕ+`. These arithmetic
functions are endowed with a multiplication, given by Dirichlet convolution, and pointwise addition,
to form the Dirichlet ring.
## Main Definitions
* `ArithmeticFunction R` consists of functions `f : ℕ → R` such that `f 0 = 0`.
* An arithmetic function `f` `IsMultiplicative` when `x.Coprime y → f (x * y) = f x * f y`.
* The pointwise operations `pmul` and `ppow` differ from the multiplication
and power instances on `ArithmeticFunction R`, which use Dirichlet multiplication.
* `ζ` is the arithmetic function such that `ζ x = 1` for `0 < x`.
* `σ k` is the arithmetic function such that `σ k x = ∑ y ∈ divisors x, y ^ k` for `0 < x`.
* `pow k` is the arithmetic function such that `pow k x = x ^ k` for `0 < x`.
* `id` is the identity arithmetic function on `ℕ`.
* `ω n` is the number of distinct prime factors of `n`.
* `Ω n` is the number of prime factors of `n` counted with multiplicity.
* `μ` is the Möbius function (spelled `moebius` in code).
## Main Results
* Several forms of Möbius inversion:
* `sum_eq_iff_sum_mul_moebius_eq` for functions to a `CommRing`
* `sum_eq_iff_sum_smul_moebius_eq` for functions to an `AddCommGroup`
* `prod_eq_iff_prod_pow_moebius_eq` for functions to a `CommGroup`
* `prod_eq_iff_prod_pow_moebius_eq_of_nonzero` for functions to a `CommGroupWithZero`
* And variants that apply when the equalities only hold on a set `S : Set ℕ` such that
`m ∣ n → n ∈ S → m ∈ S`:
* `sum_eq_iff_sum_mul_moebius_eq_on` for functions to a `CommRing`
* `sum_eq_iff_sum_smul_moebius_eq_on` for functions to an `AddCommGroup`
* `prod_eq_iff_prod_pow_moebius_eq_on` for functions to a `CommGroup`
* `prod_eq_iff_prod_pow_moebius_eq_on_of_nonzero` for functions to a `CommGroupWithZero`
## Notation
All notation is localized in the namespace `ArithmeticFunction`.
The arithmetic functions `ζ`, `σ`, `ω`, `Ω` and `μ` have Greek letter names.
In addition, there are separate locales `ArithmeticFunction.zeta` for `ζ`,
`ArithmeticFunction.sigma` for `σ`, `ArithmeticFunction.omega` for `ω`,
`ArithmeticFunction.Omega` for `Ω`, and `ArithmeticFunction.Moebius` for `μ`,
to allow for selective access to these notations.
The arithmetic function $$n \mapsto \prod_{p \mid n} f(p)$$ is given custom notation
`∏ᵖ p ∣ n, f p` when applied to `n`.
## Tags
arithmetic functions, dirichlet convolution, divisors
-/
open Finset
open Nat
variable (R : Type*)
/-- An arithmetic function is a function from `ℕ` that maps 0 to 0. In the literature, they are
often instead defined as functions from `ℕ+`. Multiplication on `ArithmeticFunctions` is by
Dirichlet convolution. -/
def ArithmeticFunction [Zero R] :=
ZeroHom ℕ R
instance ArithmeticFunction.zero [Zero R] : Zero (ArithmeticFunction R) :=
inferInstanceAs (Zero (ZeroHom ℕ R))
instance [Zero R] : Inhabited (ArithmeticFunction R) := inferInstanceAs (Inhabited (ZeroHom ℕ R))
variable {R}
namespace ArithmeticFunction
section Zero
variable [Zero R]
instance : FunLike (ArithmeticFunction R) ℕ R :=
inferInstanceAs (FunLike (ZeroHom ℕ R) ℕ R)
@[simp]
theorem toFun_eq (f : ArithmeticFunction R) : f.toFun = f := rfl
@[simp]
theorem coe_mk (f : ℕ → R) (hf) : @DFunLike.coe (ArithmeticFunction R) _ _ _
(ZeroHom.mk f hf) = f := rfl
@[simp]
theorem map_zero {f : ArithmeticFunction R} : f 0 = 0 :=
ZeroHom.map_zero' f
theorem coe_inj {f g : ArithmeticFunction R} : (f : ℕ → R) = g ↔ f = g :=
DFunLike.coe_fn_eq
@[simp]
theorem zero_apply {x : ℕ} : (0 : ArithmeticFunction R) x = 0 :=
ZeroHom.zero_apply x
@[ext]
theorem ext ⦃f g : ArithmeticFunction R⦄ (h : ∀ x, f x = g x) : f = g :=
ZeroHom.ext h
section One
variable [One R]
instance one : One (ArithmeticFunction R) :=
⟨⟨fun x => ite (x = 1) 1 0, rfl⟩⟩
theorem one_apply {x : ℕ} : (1 : ArithmeticFunction R) x = ite (x = 1) 1 0 :=
rfl
@[simp]
theorem one_one : (1 : ArithmeticFunction R) 1 = 1 :=
rfl
@[simp]
theorem one_apply_ne {x : ℕ} (h : x ≠ 1) : (1 : ArithmeticFunction R) x = 0 :=
if_neg h
end One
end Zero
/-- Coerce an arithmetic function with values in `ℕ` to one with values in `R`. We cannot inline
this in `natCoe` because it gets unfolded too much. -/
@[coe]
def natToArithmeticFunction [AddMonoidWithOne R] :
(ArithmeticFunction ℕ) → (ArithmeticFunction R) :=
fun f => ⟨fun n => ↑(f n), by simp⟩
instance natCoe [AddMonoidWithOne R] : Coe (ArithmeticFunction ℕ) (ArithmeticFunction R) :=
⟨natToArithmeticFunction⟩
@[simp]
theorem natCoe_nat (f : ArithmeticFunction ℕ) : natToArithmeticFunction f = f :=
ext fun _ => cast_id _
@[simp]
theorem natCoe_apply [AddMonoidWithOne R] {f : ArithmeticFunction ℕ} {x : ℕ} :
(f : ArithmeticFunction R) x = f x :=
rfl
/-- Coerce an arithmetic function with values in `ℤ` to one with values in `R`. We cannot inline
this in `intCoe` because it gets unfolded too much. -/
@[coe]
def ofInt [AddGroupWithOne R] :
(ArithmeticFunction ℤ) → (ArithmeticFunction R) :=
fun f => ⟨fun n => ↑(f n), by simp⟩
instance intCoe [AddGroupWithOne R] : Coe (ArithmeticFunction ℤ) (ArithmeticFunction R) :=
⟨ofInt⟩
@[simp]
theorem intCoe_int (f : ArithmeticFunction ℤ) : ofInt f = f :=
ext fun _ => Int.cast_id
@[simp]
theorem intCoe_apply [AddGroupWithOne R] {f : ArithmeticFunction ℤ} {x : ℕ} :
(f : ArithmeticFunction R) x = f x := rfl
@[simp]
theorem coe_coe [AddGroupWithOne R] {f : ArithmeticFunction ℕ} :
((f : ArithmeticFunction ℤ) : ArithmeticFunction R) = (f : ArithmeticFunction R) := by
ext
simp
@[simp]
theorem natCoe_one [AddMonoidWithOne R] :
((1 : ArithmeticFunction ℕ) : ArithmeticFunction R) = 1 := by
ext n
simp [one_apply]
@[simp]
theorem intCoe_one [AddGroupWithOne R] : ((1 : ArithmeticFunction ℤ) :
ArithmeticFunction R) = 1 := by
ext n
simp [one_apply]
section AddMonoid
variable [AddMonoid R]
instance add : Add (ArithmeticFunction R) :=
⟨fun f g => ⟨fun n => f n + g n, by simp⟩⟩
@[simp]
theorem add_apply {f g : ArithmeticFunction R} {n : ℕ} : (f + g) n = f n + g n :=
rfl
instance instAddMonoid : AddMonoid (ArithmeticFunction R) :=
{ ArithmeticFunction.zero R,
ArithmeticFunction.add with
add_assoc := fun _ _ _ => ext fun _ => add_assoc _ _ _
zero_add := fun _ => ext fun _ => zero_add _
add_zero := fun _ => ext fun _ => add_zero _
nsmul := nsmulRec }
end AddMonoid
instance instAddMonoidWithOne [AddMonoidWithOne R] : AddMonoidWithOne (ArithmeticFunction R) :=
{ ArithmeticFunction.instAddMonoid,
ArithmeticFunction.one with
natCast := fun n => ⟨fun x => if x = 1 then (n : R) else 0, by simp⟩
natCast_zero := by ext; simp
natCast_succ := fun n => by ext x; by_cases h : x = 1 <;> simp [h] }
instance instAddCommMonoid [AddCommMonoid R] : AddCommMonoid (ArithmeticFunction R) :=
{ ArithmeticFunction.instAddMonoid with add_comm := fun _ _ => ext fun _ => add_comm _ _ }
instance [NegZeroClass R] : Neg (ArithmeticFunction R) where
neg f := ⟨fun n => -f n, by simp⟩
instance [AddGroup R] : AddGroup (ArithmeticFunction R) :=
{ ArithmeticFunction.instAddMonoid with
neg_add_cancel := fun _ => ext fun _ => neg_add_cancel _
zsmul := zsmulRec }
instance [AddCommGroup R] : AddCommGroup (ArithmeticFunction R) :=
{ show AddGroup (ArithmeticFunction R) by infer_instance with
add_comm := fun _ _ ↦ add_comm _ _ }
section SMul
variable {M : Type*} [Zero R] [AddCommMonoid M] [SMul R M]
/-- The Dirichlet convolution of two arithmetic functions `f` and `g` is another arithmetic function
such that `(f * g) n` is the sum of `f x * g y` over all `(x,y)` such that `x * y = n`. -/
instance : SMul (ArithmeticFunction R) (ArithmeticFunction M) :=
⟨fun f g => ⟨fun n => ∑ x ∈ divisorsAntidiagonal n, f x.fst • g x.snd, by simp⟩⟩
@[simp]
theorem smul_apply {f : ArithmeticFunction R} {g : ArithmeticFunction M} {n : ℕ} :
(f • g) n = ∑ x ∈ divisorsAntidiagonal n, f x.fst • g x.snd :=
rfl
end SMul
/-- The Dirichlet convolution of two arithmetic functions `f` and `g` is another arithmetic function
such that `(f * g) n` is the sum of `f x * g y` over all `(x,y)` such that `x * y = n`. -/
instance [Semiring R] : Mul (ArithmeticFunction R) :=
⟨(· • ·)⟩
@[simp]
theorem mul_apply [Semiring R] {f g : ArithmeticFunction R} {n : ℕ} :
(f * g) n = ∑ x ∈ divisorsAntidiagonal n, f x.fst * g x.snd :=
rfl
theorem mul_apply_one [Semiring R] {f g : ArithmeticFunction R} : (f * g) 1 = f 1 * g 1 := by simp
@[simp, norm_cast]
theorem natCoe_mul [Semiring R] {f g : ArithmeticFunction ℕ} :
(↑(f * g) : ArithmeticFunction R) = f * g := by
ext n
simp
@[simp, norm_cast]
theorem intCoe_mul [Ring R] {f g : ArithmeticFunction ℤ} :
(↑(f * g) : ArithmeticFunction R) = ↑f * g := by
ext n
simp
section Module
variable {M : Type*} [Semiring R] [AddCommMonoid M] [Module R M]
theorem mul_smul' (f g : ArithmeticFunction R) (h : ArithmeticFunction M) :
(f * g) • h = f • g • h := by
ext n
simp only [mul_apply, smul_apply, sum_smul, mul_smul, smul_sum, Finset.sum_sigma']
apply Finset.sum_nbij' (fun ⟨⟨_i, j⟩, ⟨k, l⟩⟩ ↦ ⟨(k, l * j), (l, j)⟩)
(fun ⟨⟨i, _j⟩, ⟨k, l⟩⟩ ↦ ⟨(i * k, l), (i, k)⟩) <;> aesop (add simp mul_assoc)
theorem one_smul' (b : ArithmeticFunction M) : (1 : ArithmeticFunction R) • b = b := by
ext x
rw [smul_apply]
by_cases x0 : x = 0
· simp [x0]
have h : {(1, x)} ⊆ divisorsAntidiagonal x := by simp [x0]
rw [← sum_subset h]
· simp
intro y ymem ynmem
have y1ne : y.fst ≠ 1 := fun con => by simp_all [Prod.ext_iff]
simp [y1ne]
end Module
section Semiring
variable [Semiring R]
instance instMonoid : Monoid (ArithmeticFunction R) :=
{ one := One.one
mul := Mul.mul
one_mul := one_smul'
mul_one := fun f => by
ext x
rw [mul_apply]
by_cases x0 : x = 0
· simp [x0]
have h : {(x, 1)} ⊆ divisorsAntidiagonal x := by simp [x0]
rw [← sum_subset h]
· simp
intro ⟨y₁, y₂⟩ ymem ynmem
have y2ne : y₂ ≠ 1 := by
intro con
simp_all
simp [y2ne]
mul_assoc := mul_smul' }
instance instSemiring : Semiring (ArithmeticFunction R) :=
{ ArithmeticFunction.instAddMonoidWithOne,
ArithmeticFunction.instMonoid,
ArithmeticFunction.instAddCommMonoid with
zero_mul := fun f => by
ext
simp
mul_zero := fun f => by
ext
simp
left_distrib := fun a b c => by
ext
simp [← sum_add_distrib, mul_add]
right_distrib := fun a b c => by
ext
simp [← sum_add_distrib, add_mul] }
end Semiring
instance [CommSemiring R] : CommSemiring (ArithmeticFunction R) :=
{ ArithmeticFunction.instSemiring with
mul_comm := fun f g => by
ext
rw [mul_apply, ← map_swap_divisorsAntidiagonal, sum_map]
simp [mul_comm] }
instance [CommRing R] : CommRing (ArithmeticFunction R) :=
{ ArithmeticFunction.instSemiring with
neg_add_cancel := neg_add_cancel
mul_comm := mul_comm
zsmul := (· • ·) }
instance {M : Type*} [Semiring R] [AddCommMonoid M] [Module R M] :
Module (ArithmeticFunction R) (ArithmeticFunction M) where
one_smul := one_smul'
mul_smul := mul_smul'
smul_add r x y := by
ext
simp only [sum_add_distrib, smul_add, smul_apply, add_apply]
smul_zero r := by
ext
simp only [smul_apply, sum_const_zero, smul_zero, zero_apply]
add_smul r s x := by
ext
simp only [add_smul, sum_add_distrib, smul_apply, add_apply]
zero_smul r := by
ext
simp only [smul_apply, sum_const_zero, zero_smul, zero_apply]
section Zeta
/-- `ζ 0 = 0`, otherwise `ζ x = 1`. The Dirichlet Series is the Riemann `ζ`. -/
def zeta : ArithmeticFunction ℕ :=
⟨fun x => ite (x = 0) 0 1, rfl⟩
@[inherit_doc]
scoped[ArithmeticFunction] notation "ζ" => ArithmeticFunction.zeta
@[inherit_doc]
scoped[ArithmeticFunction.zeta] notation "ζ" => ArithmeticFunction.zeta
@[simp]
theorem zeta_apply {x : ℕ} : ζ x = if x = 0 then 0 else 1 :=
rfl
theorem zeta_apply_ne {x : ℕ} (h : x ≠ 0) : ζ x = 1 :=
if_neg h
-- Porting note: removed `@[simp]`, LHS not in normal form
theorem coe_zeta_smul_apply {M} [Semiring R] [AddCommMonoid M] [MulAction R M]
{f : ArithmeticFunction M} {x : ℕ} :
((↑ζ : ArithmeticFunction R) • f) x = ∑ i ∈ divisors x, f i := by
rw [smul_apply]
trans ∑ i ∈ divisorsAntidiagonal x, f i.snd
· refine sum_congr rfl fun i hi => ?_
rcases mem_divisorsAntidiagonal.1 hi with ⟨rfl, h⟩
rw [natCoe_apply, zeta_apply_ne (left_ne_zero_of_mul h), cast_one, one_smul]
· rw [← map_div_left_divisors, sum_map, Function.Embedding.coeFn_mk]
theorem coe_zeta_mul_apply [Semiring R] {f : ArithmeticFunction R} {x : ℕ} :
(↑ζ * f) x = ∑ i ∈ divisors x, f i :=
coe_zeta_smul_apply
theorem coe_mul_zeta_apply [Semiring R] {f : ArithmeticFunction R} {x : ℕ} :
(f * ζ) x = ∑ i ∈ divisors x, f i := by
rw [mul_apply]
trans ∑ i ∈ divisorsAntidiagonal x, f i.1
· refine sum_congr rfl fun i hi => ?_
rcases mem_divisorsAntidiagonal.1 hi with ⟨rfl, h⟩
rw [natCoe_apply, zeta_apply_ne (right_ne_zero_of_mul h), cast_one, mul_one]
· rw [← map_div_right_divisors, sum_map, Function.Embedding.coeFn_mk]
theorem zeta_mul_apply {f : ArithmeticFunction ℕ} {x : ℕ} : (ζ * f) x = ∑ i ∈ divisors x, f i := by
rw [← natCoe_nat ζ, coe_zeta_mul_apply]
theorem mul_zeta_apply {f : ArithmeticFunction ℕ} {x : ℕ} : (f * ζ) x = ∑ i ∈ divisors x, f i := by
rw [← natCoe_nat ζ, coe_mul_zeta_apply]
end Zeta
open ArithmeticFunction
section Pmul
/-- This is the pointwise product of `ArithmeticFunction`s. -/
def pmul [MulZeroClass R] (f g : ArithmeticFunction R) : ArithmeticFunction R :=
⟨fun x => f x * g x, by simp⟩
@[simp]
theorem pmul_apply [MulZeroClass R] {f g : ArithmeticFunction R} {x : ℕ} : f.pmul g x = f x * g x :=
rfl
theorem pmul_comm [CommMonoidWithZero R] (f g : ArithmeticFunction R) : f.pmul g = g.pmul f := by
ext
simp [mul_comm]
lemma pmul_assoc [SemigroupWithZero R] (f₁ f₂ f₃ : ArithmeticFunction R) :
pmul (pmul f₁ f₂) f₃ = pmul f₁ (pmul f₂ f₃) := by
ext
simp only [pmul_apply, mul_assoc]
section NonAssocSemiring
variable [NonAssocSemiring R]
@[simp]
theorem pmul_zeta (f : ArithmeticFunction R) : f.pmul ↑ζ = f := by
ext x
cases x <;> simp [Nat.succ_ne_zero]
@[simp]
theorem zeta_pmul (f : ArithmeticFunction R) : (ζ : ArithmeticFunction R).pmul f = f := by
ext x
cases x <;> simp [Nat.succ_ne_zero]
end NonAssocSemiring
variable [Semiring R]
/-- This is the pointwise power of `ArithmeticFunction`s. -/
def ppow (f : ArithmeticFunction R) (k : ℕ) : ArithmeticFunction R :=
if h0 : k = 0 then ζ else ⟨fun x ↦ f x ^ k, by simp_rw [map_zero, zero_pow h0]⟩
@[simp]
theorem ppow_zero {f : ArithmeticFunction R} : f.ppow 0 = ζ := by rw [ppow, dif_pos rfl]
@[simp]
theorem ppow_apply {f : ArithmeticFunction R} {k x : ℕ} (kpos : 0 < k) : f.ppow k x = f x ^ k := by
rw [ppow, dif_neg (Nat.ne_of_gt kpos), coe_mk]
theorem ppow_succ' {f : ArithmeticFunction R} {k : ℕ} : f.ppow (k + 1) = f.pmul (f.ppow k) := by
ext x
rw [ppow_apply (Nat.succ_pos k), _root_.pow_succ']
induction k <;> simp
theorem ppow_succ {f : ArithmeticFunction R} {k : ℕ} {kpos : 0 < k} :
f.ppow (k + 1) = (f.ppow k).pmul f := by
ext x
rw [ppow_apply (Nat.succ_pos k), _root_.pow_succ]
induction k <;> simp
end Pmul
section Pdiv
/-- This is the pointwise division of `ArithmeticFunction`s. -/
def pdiv [GroupWithZero R] (f g : ArithmeticFunction R) : ArithmeticFunction R :=
⟨fun n => f n / g n, by simp only [map_zero, ne_eq, not_true, div_zero]⟩
@[simp]
theorem pdiv_apply [GroupWithZero R] (f g : ArithmeticFunction R) (n : ℕ) :
pdiv f g n = f n / g n := rfl
/-- This result only holds for `DivisionSemiring`s instead of `GroupWithZero`s because zeta takes
values in ℕ, and hence the coercion requires an `AddMonoidWithOne`. TODO: Generalise zeta -/
@[simp]
theorem pdiv_zeta [DivisionSemiring R] (f : ArithmeticFunction R) :
pdiv f zeta = f := by
ext n
cases n <;> simp [succ_ne_zero]
end Pdiv
section ProdPrimeFactors
/-- The map $n \mapsto \prod_{p \mid n} f(p)$ as an arithmetic function -/
def prodPrimeFactors [CommMonoidWithZero R] (f : ℕ → R) : ArithmeticFunction R where
toFun d := if d = 0 then 0 else ∏ p ∈ d.primeFactors, f p
map_zero' := if_pos rfl
open Batteries.ExtendedBinder
/-- `∏ᵖ p ∣ n, f p` is custom notation for `prodPrimeFactors f n` -/
scoped syntax (name := bigproddvd) "∏ᵖ " extBinder " ∣ " term ", " term:67 : term
scoped macro_rules (kind := bigproddvd)
| `(∏ᵖ $x:ident ∣ $n, $r) => `(prodPrimeFactors (fun $x ↦ $r) $n)
@[simp]
theorem prodPrimeFactors_apply [CommMonoidWithZero R] {f : ℕ → R} {n : ℕ} (hn : n ≠ 0) :
∏ᵖ p ∣ n, f p = ∏ p ∈ n.primeFactors, f p :=
if_neg hn
end ProdPrimeFactors
/-- Multiplicative functions -/
def IsMultiplicative [MonoidWithZero R] (f : ArithmeticFunction R) : Prop :=
f 1 = 1 ∧ ∀ {m n : ℕ}, m.Coprime n → f (m * n) = f m * f n
namespace IsMultiplicative
section MonoidWithZero
variable [MonoidWithZero R]
@[simp, arith_mult]
theorem map_one {f : ArithmeticFunction R} (h : f.IsMultiplicative) : f 1 = 1 :=
h.1
@[simp]
theorem map_mul_of_coprime {f : ArithmeticFunction R} (hf : f.IsMultiplicative) {m n : ℕ}
(h : m.Coprime n) : f (m * n) = f m * f n :=
hf.2 h
end MonoidWithZero
open scoped Function in -- required for scoped `on` notation
theorem map_prod {ι : Type*} [CommMonoidWithZero R] (g : ι → ℕ) {f : ArithmeticFunction R}
(hf : f.IsMultiplicative) (s : Finset ι) (hs : (s : Set ι).Pairwise (Coprime on g)) :
f (∏ i ∈ s, g i) = ∏ i ∈ s, f (g i) := by
classical
induction s using Finset.induction_on with
| empty => simp [hf]
| insert _ _ has ih =>
rw [coe_insert, Set.pairwise_insert_of_symmetric (Coprime.symmetric.comap g)] at hs
rw [prod_insert has, prod_insert has, hf.map_mul_of_coprime, ih hs.1]
exact .prod_right fun i hi => hs.2 _ hi (hi.ne_of_not_mem has).symm
theorem map_prod_of_prime [CommMonoidWithZero R] {f : ArithmeticFunction R}
(h_mult : ArithmeticFunction.IsMultiplicative f)
(t : Finset ℕ) (ht : ∀ p ∈ t, p.Prime) :
f (∏ a ∈ t, a) = ∏ a ∈ t, f a :=
map_prod _ h_mult t fun x hx y hy hxy => (coprime_primes (ht x hx) (ht y hy)).mpr hxy
theorem map_prod_of_subset_primeFactors [CommMonoidWithZero R] {f : ArithmeticFunction R}
(h_mult : ArithmeticFunction.IsMultiplicative f) (l : ℕ)
(t : Finset ℕ) (ht : t ⊆ l.primeFactors) :
f (∏ a ∈ t, a) = ∏ a ∈ t, f a :=
map_prod_of_prime h_mult t fun _ a => prime_of_mem_primeFactors (ht a)
theorem map_div_of_coprime [GroupWithZero R] {f : ArithmeticFunction R}
(hf : IsMultiplicative f) {l d : ℕ} (hdl : d ∣ l) (hl : (l / d).Coprime d) (hd : f d ≠ 0) :
f (l / d) = f l / f d := by
apply (div_eq_of_eq_mul hd ..).symm
rw [← hf.right hl, Nat.div_mul_cancel hdl]
@[arith_mult]
theorem natCast {f : ArithmeticFunction ℕ} [Semiring R] (h : f.IsMultiplicative) :
IsMultiplicative (f : ArithmeticFunction R) :=
⟨by simp [h], fun {m n} cop => by simp [h.2 cop]⟩
@[arith_mult]
theorem intCast {f : ArithmeticFunction ℤ} [Ring R] (h : f.IsMultiplicative) :
IsMultiplicative (f : ArithmeticFunction R) :=
⟨by simp [h], fun {m n} cop => by simp [h.2 cop]⟩
@[arith_mult]
theorem mul [CommSemiring R] {f g : ArithmeticFunction R} (hf : f.IsMultiplicative)
(hg : g.IsMultiplicative) : IsMultiplicative (f * g) := by
refine ⟨by simp [hf.1, hg.1], ?_⟩
simp only [mul_apply]
intro m n cop
rw [sum_mul_sum, ← sum_product']
symm
apply sum_nbij fun ((i, j), k, l) ↦ (i * k, j * l)
· rintro ⟨⟨a1, a2⟩, ⟨b1, b2⟩⟩ h
simp only [mem_divisorsAntidiagonal, Ne, mem_product] at h
rcases h with ⟨⟨rfl, ha⟩, ⟨rfl, hb⟩⟩
simp only [mem_divisorsAntidiagonal, Nat.mul_eq_zero, Ne]
constructor
· ring
rw [Nat.mul_eq_zero] at *
apply not_or_intro ha hb
· simp only [Set.InjOn, mem_coe, mem_divisorsAntidiagonal, Ne, mem_product, Prod.mk_inj]
rintro ⟨⟨a1, a2⟩, ⟨b1, b2⟩⟩ ⟨⟨rfl, ha⟩, ⟨rfl, hb⟩⟩ ⟨⟨c1, c2⟩, ⟨d1, d2⟩⟩ hcd h
simp only [Prod.mk_inj] at h
ext <;> dsimp only
· trans Nat.gcd (a1 * a2) (a1 * b1)
· rw [Nat.gcd_mul_left, cop.coprime_mul_left.coprime_mul_right_right.gcd_eq_one, mul_one]
· rw [← hcd.1.1, ← hcd.2.1] at cop
rw [← hcd.1.1, h.1, Nat.gcd_mul_left,
cop.coprime_mul_left.coprime_mul_right_right.gcd_eq_one, mul_one]
· trans Nat.gcd (a1 * a2) (a2 * b2)
· rw [mul_comm, Nat.gcd_mul_left, cop.coprime_mul_right.coprime_mul_left_right.gcd_eq_one,
mul_one]
· rw [← hcd.1.1, ← hcd.2.1] at cop
rw [← hcd.1.1, h.2, mul_comm, Nat.gcd_mul_left,
cop.coprime_mul_right.coprime_mul_left_right.gcd_eq_one, mul_one]
· trans Nat.gcd (b1 * b2) (a1 * b1)
· rw [mul_comm, Nat.gcd_mul_right,
cop.coprime_mul_right.coprime_mul_left_right.symm.gcd_eq_one, one_mul]
· rw [← hcd.1.1, ← hcd.2.1] at cop
rw [← hcd.2.1, h.1, mul_comm c1 d1, Nat.gcd_mul_left,
cop.coprime_mul_right.coprime_mul_left_right.symm.gcd_eq_one, mul_one]
· trans Nat.gcd (b1 * b2) (a2 * b2)
· rw [Nat.gcd_mul_right, cop.coprime_mul_left.coprime_mul_right_right.symm.gcd_eq_one,
one_mul]
· rw [← hcd.1.1, ← hcd.2.1] at cop
rw [← hcd.2.1, h.2, Nat.gcd_mul_right,
cop.coprime_mul_left.coprime_mul_right_right.symm.gcd_eq_one, one_mul]
· simp only [Set.SurjOn, Set.subset_def, mem_coe, mem_divisorsAntidiagonal, Ne, mem_product,
Set.mem_image, exists_prop, Prod.mk_inj]
rintro ⟨b1, b2⟩ h
dsimp at h
use ((b1.gcd m, b2.gcd m), (b1.gcd n, b2.gcd n))
rw [← cop.gcd_mul _, ← cop.gcd_mul _, ← h.1, Nat.gcd_mul_gcd_of_coprime_of_mul_eq_mul cop h.1,
Nat.gcd_mul_gcd_of_coprime_of_mul_eq_mul cop.symm _]
· rw [Nat.mul_eq_zero, not_or] at h
simp [h.2.1, h.2.2]
rw [mul_comm n m, h.1]
· simp only [mem_divisorsAntidiagonal, Ne, mem_product]
rintro ⟨⟨a1, a2⟩, ⟨b1, b2⟩⟩ ⟨⟨rfl, ha⟩, ⟨rfl, hb⟩⟩
dsimp only
rw [hf.map_mul_of_coprime cop.coprime_mul_right.coprime_mul_right_right,
hg.map_mul_of_coprime cop.coprime_mul_left.coprime_mul_left_right]
ring
@[arith_mult]
theorem pmul [CommSemiring R] {f g : ArithmeticFunction R} (hf : f.IsMultiplicative)
(hg : g.IsMultiplicative) : IsMultiplicative (f.pmul g) :=
⟨by simp [hf, hg], fun {m n} cop => by
simp only [pmul_apply, hf.map_mul_of_coprime cop, hg.map_mul_of_coprime cop]
ring⟩
@[arith_mult]
theorem pdiv [CommGroupWithZero R] {f g : ArithmeticFunction R} (hf : IsMultiplicative f)
(hg : IsMultiplicative g) : IsMultiplicative (pdiv f g) :=
⟨by simp [hf, hg], fun {m n} cop => by
simp only [pdiv_apply, map_mul_of_coprime hf cop, map_mul_of_coprime hg cop,
div_eq_mul_inv, mul_inv]
apply mul_mul_mul_comm ⟩
/-- For any multiplicative function `f` and any `n > 0`,
we can evaluate `f n` by evaluating `f` at `p ^ k` over the factorization of `n` -/
theorem multiplicative_factorization [CommMonoidWithZero R] (f : ArithmeticFunction R)
(hf : f.IsMultiplicative) {n : ℕ} (hn : n ≠ 0) :
f n = n.factorization.prod fun p k => f (p ^ k) :=
Nat.multiplicative_factorization f (fun _ _ => hf.2) hf.1 hn
/-- A recapitulation of the definition of multiplicative that is simpler for proofs -/
theorem iff_ne_zero [MonoidWithZero R] {f : ArithmeticFunction R} :
IsMultiplicative f ↔
f 1 = 1 ∧ ∀ {m n : ℕ}, m ≠ 0 → n ≠ 0 → m.Coprime n → f (m * n) = f m * f n := by
refine and_congr_right' (forall₂_congr fun m n => ⟨fun h _ _ => h, fun h hmn => ?_⟩)
rcases eq_or_ne m 0 with (rfl | hm)
· simp
rcases eq_or_ne n 0 with (rfl | hn)
· simp
exact h hm hn hmn
/-- Two multiplicative functions `f` and `g` are equal if and only if
they agree on prime powers -/
theorem eq_iff_eq_on_prime_powers [CommMonoidWithZero R] (f : ArithmeticFunction R)
(hf : f.IsMultiplicative) (g : ArithmeticFunction R) (hg : g.IsMultiplicative) :
f = g ↔ ∀ p i : ℕ, Nat.Prime p → f (p ^ i) = g (p ^ i) := by
constructor
· intro h p i _
rw [h]
intro h
ext n
by_cases hn : n = 0
· rw [hn, ArithmeticFunction.map_zero, ArithmeticFunction.map_zero]
rw [multiplicative_factorization f hf hn, multiplicative_factorization g hg hn]
exact Finset.prod_congr rfl fun p hp ↦ h p _ (Nat.prime_of_mem_primeFactors hp)
@[arith_mult]
theorem prodPrimeFactors [CommMonoidWithZero R] (f : ℕ → R) :
IsMultiplicative (prodPrimeFactors f) := by
rw [iff_ne_zero]
simp only [ne_eq, one_ne_zero, not_false_eq_true, prodPrimeFactors_apply, primeFactors_one,
prod_empty, true_and]
intro x y hx hy hxy
have hxy₀ : x * y ≠ 0 := mul_ne_zero hx hy
rw [prodPrimeFactors_apply hxy₀, prodPrimeFactors_apply hx, prodPrimeFactors_apply hy,
Nat.primeFactors_mul hx hy, ← Finset.prod_union hxy.disjoint_primeFactors]
theorem prodPrimeFactors_add_of_squarefree [CommSemiring R] {f g : ArithmeticFunction R}
(hf : IsMultiplicative f) (hg : IsMultiplicative g) {n : ℕ} (hn : Squarefree n) :
∏ᵖ p ∣ n, (f + g) p = (f * g) n := by
rw [prodPrimeFactors_apply hn.ne_zero]
simp_rw [add_apply (f := f) (g := g)]
rw [Finset.prod_add, mul_apply, sum_divisorsAntidiagonal (f · * g ·),
← divisors_filter_squarefree_of_squarefree hn, sum_divisors_filter_squarefree hn.ne_zero,
factors_eq]
apply Finset.sum_congr rfl
intro t ht
rw [t.prod_val, Function.id_def,
← prod_primeFactors_sdiff_of_squarefree hn (Finset.mem_powerset.mp ht),
hf.map_prod_of_subset_primeFactors n t (Finset.mem_powerset.mp ht),
← hg.map_prod_of_subset_primeFactors n (_ \ t) Finset.sdiff_subset]
theorem lcm_apply_mul_gcd_apply [CommMonoidWithZero R] {f : ArithmeticFunction R}
(hf : f.IsMultiplicative) {x y : ℕ} :
f (x.lcm y) * f (x.gcd y) = f x * f y := by
by_cases hx : x = 0
· simp only [hx, f.map_zero, zero_mul, Nat.lcm_zero_left, Nat.gcd_zero_left]
by_cases hy : y = 0
· simp only [hy, f.map_zero, mul_zero, Nat.lcm_zero_right, Nat.gcd_zero_right, zero_mul]
have hgcd_ne_zero : x.gcd y ≠ 0 := gcd_ne_zero_left hx
have hlcm_ne_zero : x.lcm y ≠ 0 := lcm_ne_zero hx hy
have hfi_zero : ∀ {i}, f (i ^ 0) = 1 := by
intro i; rw [Nat.pow_zero, hf.1]
iterate 4 rw [hf.multiplicative_factorization f (by assumption),
Finsupp.prod_of_support_subset _ _ _ (fun _ _ => hfi_zero)
(s := (x.primeFactors ∪ y.primeFactors))]
· rw [← Finset.prod_mul_distrib, ← Finset.prod_mul_distrib]
apply Finset.prod_congr rfl
intro p _
rcases Nat.le_or_le (x.factorization p) (y.factorization p) with h | h <;>
simp only [factorization_lcm hx hy, Finsupp.sup_apply, h, sup_of_le_right,
sup_of_le_left, inf_of_le_right, Nat.factorization_gcd hx hy, Finsupp.inf_apply,
inf_of_le_left, mul_comm]
· apply Finset.subset_union_right
· apply Finset.subset_union_left
· rw [factorization_gcd hx hy, Finsupp.support_inf]
apply Finset.inter_subset_union
· simp [factorization_lcm hx hy]
theorem map_gcd [CommGroupWithZero R] {f : ArithmeticFunction R}
(hf : f.IsMultiplicative) {x y : ℕ} (hf_lcm : f (x.lcm y) ≠ 0) :
f (x.gcd y) = f x * f y / f (x.lcm y) := by
rw [← hf.lcm_apply_mul_gcd_apply, mul_div_cancel_left₀ _ hf_lcm]
theorem map_lcm [CommGroupWithZero R] {f : ArithmeticFunction R}
(hf : f.IsMultiplicative) {x y : ℕ} (hf_gcd : f (x.gcd y) ≠ 0) :
f (x.lcm y) = f x * f y / f (x.gcd y) := by
rw [← hf.lcm_apply_mul_gcd_apply, mul_div_cancel_right₀ _ hf_gcd]
theorem eq_zero_of_squarefree_of_dvd_eq_zero [MonoidWithZero R] {f : ArithmeticFunction R}
(hf : IsMultiplicative f) {m n : ℕ} (hn : Squarefree n) (hmn : m ∣ n)
(h_zero : f m = 0) :
f n = 0 := by
rcases hmn with ⟨k, rfl⟩
simp only [MulZeroClass.zero_mul, eq_self_iff_true, hf.map_mul_of_coprime
(coprime_of_squarefree_mul hn), h_zero]
end IsMultiplicative
section SpecialFunctions
/-- The identity on `ℕ` as an `ArithmeticFunction`. -/
def id : ArithmeticFunction ℕ :=
⟨_root_.id, rfl⟩
@[simp]
theorem id_apply {x : ℕ} : id x = x :=
rfl
/-- `pow k n = n ^ k`, except `pow 0 0 = 0`. -/
def pow (k : ℕ) : ArithmeticFunction ℕ :=
id.ppow k
@[simp]
theorem pow_apply {k n : ℕ} : pow k n = if k = 0 ∧ n = 0 then 0 else n ^ k := by
cases k <;> simp [pow]
theorem pow_zero_eq_zeta : pow 0 = ζ := by
ext n
simp
/-- `σ k n` is the sum of the `k`th powers of the divisors of `n` -/
def sigma (k : ℕ) : ArithmeticFunction ℕ :=
⟨fun n => ∑ d ∈ divisors n, d ^ k, by simp⟩
@[inherit_doc]
scoped[ArithmeticFunction] notation "σ" => ArithmeticFunction.sigma
@[inherit_doc]
scoped[ArithmeticFunction.sigma] notation "σ" => ArithmeticFunction.sigma
theorem sigma_apply {k n : ℕ} : σ k n = ∑ d ∈ divisors n, d ^ k :=
rfl
theorem sigma_apply_prime_pow {k p i : ℕ} (hp : p.Prime) :
σ k (p ^ i) = ∑ j ∈ .range (i + 1), p ^ (j * k) := by
simp [sigma_apply, divisors_prime_pow hp, Nat.pow_mul]
theorem sigma_one_apply (n : ℕ) : σ 1 n = ∑ d ∈ divisors n, d := by simp [sigma_apply]
theorem sigma_one_apply_prime_pow {p i : ℕ} (hp : p.Prime) :
σ 1 (p ^ i) = ∑ k ∈ .range (i + 1), p ^ k := by
simp [sigma_apply_prime_pow hp]
theorem sigma_zero_apply (n : ℕ) : σ 0 n = #n.divisors := by simp [sigma_apply]
theorem sigma_zero_apply_prime_pow {p i : ℕ} (hp : p.Prime) : σ 0 (p ^ i) = i + 1 := by
simp [sigma_apply_prime_pow hp]
theorem zeta_mul_pow_eq_sigma {k : ℕ} : ζ * pow k = σ k := by
ext
rw [sigma, zeta_mul_apply]
apply sum_congr rfl
intro x hx
rw [pow_apply, if_neg (not_and_of_not_right _ _)]
contrapose! hx
simp [hx]
@[arith_mult]
theorem isMultiplicative_one [MonoidWithZero R] : IsMultiplicative (1 : ArithmeticFunction R) :=
IsMultiplicative.iff_ne_zero.2
⟨by simp, by
intro m n hm _hn hmn
rcases eq_or_ne m 1 with (rfl | hm')
· simp
rw [one_apply_ne, one_apply_ne hm', zero_mul]
rw [Ne, mul_eq_one, not_and_or]
exact Or.inl hm'⟩
@[arith_mult]
theorem isMultiplicative_zeta : IsMultiplicative ζ :=
IsMultiplicative.iff_ne_zero.2 ⟨by simp, by simp +contextual⟩
@[arith_mult]
theorem isMultiplicative_id : IsMultiplicative ArithmeticFunction.id :=
⟨rfl, fun {_ _} _ => rfl⟩
@[arith_mult]
theorem IsMultiplicative.ppow [CommSemiring R] {f : ArithmeticFunction R} (hf : f.IsMultiplicative)
{k : ℕ} : IsMultiplicative (f.ppow k) := by
induction k with
| zero => exact isMultiplicative_zeta.natCast
| succ k hi => rw [ppow_succ']; apply hf.pmul hi
@[arith_mult]
theorem isMultiplicative_pow {k : ℕ} : IsMultiplicative (pow k) :=
isMultiplicative_id.ppow
@[arith_mult]
theorem isMultiplicative_sigma {k : ℕ} : IsMultiplicative (σ k) := by
rw [← zeta_mul_pow_eq_sigma]
apply isMultiplicative_zeta.mul isMultiplicative_pow
/-- `Ω n` is the number of prime factors of `n`. -/
def cardFactors : ArithmeticFunction ℕ :=
⟨fun n => n.primeFactorsList.length, by simp⟩
@[inherit_doc]
scoped[ArithmeticFunction] notation "Ω" => ArithmeticFunction.cardFactors
@[inherit_doc]
scoped[ArithmeticFunction.Omega] notation "Ω" => ArithmeticFunction.cardFactors
theorem cardFactors_apply {n : ℕ} : Ω n = n.primeFactorsList.length :=
rfl
lemma cardFactors_zero : Ω 0 = 0 := by simp
@[simp] theorem cardFactors_one : Ω 1 = 0 := by simp [cardFactors_apply]
@[simp]
theorem cardFactors_eq_one_iff_prime {n : ℕ} : Ω n = 1 ↔ n.Prime := by
refine ⟨fun h => ?_, fun h => List.length_eq_one_iff.2 ⟨n, primeFactorsList_prime h⟩⟩
cases n with | zero => simp at h | succ n =>
rcases List.length_eq_one_iff.1 h with ⟨x, hx⟩
rw [← prod_primeFactorsList n.add_one_ne_zero, hx, List.prod_singleton]
apply prime_of_mem_primeFactorsList
rw [hx, List.mem_singleton]
theorem cardFactors_mul {m n : ℕ} (m0 : m ≠ 0) (n0 : n ≠ 0) : Ω (m * n) = Ω m + Ω n := by
rw [cardFactors_apply, cardFactors_apply, cardFactors_apply, ← Multiset.coe_card, ← factors_eq,
UniqueFactorizationMonoid.normalizedFactors_mul m0 n0, factors_eq, factors_eq,
Multiset.card_add, Multiset.coe_card, Multiset.coe_card]
theorem cardFactors_multiset_prod {s : Multiset ℕ} (h0 : s.prod ≠ 0) :
Ω s.prod = (Multiset.map Ω s).sum := by
induction s using Multiset.induction_on with
| empty => simp
| cons ih => simp_all [cardFactors_mul, not_or]
@[simp]
theorem cardFactors_apply_prime {p : ℕ} (hp : p.Prime) : Ω p = 1 :=
cardFactors_eq_one_iff_prime.2 hp
@[simp]
theorem cardFactors_apply_prime_pow {p k : ℕ} (hp : p.Prime) : Ω (p ^ k) = k := by
rw [cardFactors_apply, hp.primeFactorsList_pow, List.length_replicate]
/-- `ω n` is the number of distinct prime factors of `n`. -/
def cardDistinctFactors : ArithmeticFunction ℕ :=
⟨fun n => n.primeFactorsList.dedup.length, by simp⟩
@[inherit_doc]
scoped[ArithmeticFunction] notation "ω" => ArithmeticFunction.cardDistinctFactors
@[inherit_doc]
scoped[ArithmeticFunction.omega] notation "ω" => ArithmeticFunction.cardDistinctFactors
theorem cardDistinctFactors_zero : ω 0 = 0 := by simp
@[simp]
theorem cardDistinctFactors_one : ω 1 = 0 := by simp [cardDistinctFactors]
theorem cardDistinctFactors_apply {n : ℕ} : ω n = n.primeFactorsList.dedup.length :=
rfl
theorem cardDistinctFactors_eq_cardFactors_iff_squarefree {n : ℕ} (h0 : n ≠ 0) :
ω n = Ω n ↔ Squarefree n := by
rw [squarefree_iff_nodup_primeFactorsList h0, cardDistinctFactors_apply]
constructor <;> intro h
· rw [← n.primeFactorsList.dedup_sublist.eq_of_length h]
apply List.nodup_dedup
· simp [h.dedup, cardFactors]
@[simp]
theorem cardDistinctFactors_apply_prime_pow {p k : ℕ} (hp : p.Prime) (hk : k ≠ 0) :
ω (p ^ k) = 1 := by
rw [cardDistinctFactors_apply, hp.primeFactorsList_pow, List.replicate_dedup hk,
List.length_singleton]
@[simp]
theorem cardDistinctFactors_apply_prime {p : ℕ} (hp : p.Prime) : ω p = 1 := by
rw [← pow_one p, cardDistinctFactors_apply_prime_pow hp one_ne_zero]
/-- `μ` is the Möbius function. If `n` is squarefree with an even number of distinct prime factors,
`μ n = 1`. If `n` is squarefree with an odd number of distinct prime factors, `μ n = -1`.
If `n` is not squarefree, `μ n = 0`. -/
def moebius : ArithmeticFunction ℤ :=
⟨fun n => if Squarefree n then (-1) ^ cardFactors n else 0, by simp⟩
@[inherit_doc]
scoped[ArithmeticFunction] notation "μ" => ArithmeticFunction.moebius
@[inherit_doc]
scoped[ArithmeticFunction.Moebius] notation "μ" => ArithmeticFunction.moebius
@[simp]
theorem moebius_apply_of_squarefree {n : ℕ} (h : Squarefree n) : μ n = (-1) ^ cardFactors n :=
if_pos h
@[simp]
theorem moebius_eq_zero_of_not_squarefree {n : ℕ} (h : ¬Squarefree n) : μ n = 0 :=
if_neg h
theorem moebius_apply_one : μ 1 = 1 := by simp
theorem moebius_ne_zero_iff_squarefree {n : ℕ} : μ n ≠ 0 ↔ Squarefree n := by
constructor <;> intro h
· contrapose! h
simp [h]
· simp [h, pow_ne_zero]
theorem moebius_eq_or (n : ℕ) : μ n = 0 ∨ μ n = 1 ∨ μ n = -1 := by
simp only [moebius, coe_mk]
split_ifs
· right
exact neg_one_pow_eq_or ..
· left
rfl
theorem moebius_ne_zero_iff_eq_or {n : ℕ} : μ n ≠ 0 ↔ μ n = 1 ∨ μ n = -1 := by
have := moebius_eq_or n
aesop
theorem moebius_sq_eq_one_of_squarefree {l : ℕ} (hl : Squarefree l) : μ l ^ 2 = 1 := by
rw [moebius_apply_of_squarefree hl, ← pow_mul, mul_comm, pow_mul, neg_one_sq, one_pow]
theorem abs_moebius_eq_one_of_squarefree {l : ℕ} (hl : Squarefree l) : |μ l| = 1 := by
simp only [moebius_apply_of_squarefree hl, abs_pow, abs_neg, abs_one, one_pow]
theorem moebius_sq {n : ℕ} :
μ n ^ 2 = if Squarefree n then 1 else 0 := by
split_ifs with h
· exact moebius_sq_eq_one_of_squarefree h
· simp only [pow_eq_zero_iff, moebius_eq_zero_of_not_squarefree h,
zero_pow (show 2 ≠ 0 by norm_num)]
theorem abs_moebius {n : ℕ} :
|μ n| = if Squarefree n then 1 else 0 := by
split_ifs with h
· exact abs_moebius_eq_one_of_squarefree h
· simp only [moebius_eq_zero_of_not_squarefree h, abs_zero]
theorem abs_moebius_le_one {n : ℕ} : |μ n| ≤ 1 := by
rw [abs_moebius, apply_ite (· ≤ 1)]
simp
theorem moebius_apply_prime {p : ℕ} (hp : p.Prime) : μ p = -1 := by
rw [moebius_apply_of_squarefree hp.squarefree, cardFactors_apply_prime hp, pow_one]
theorem moebius_apply_prime_pow {p k : ℕ} (hp : p.Prime) (hk : k ≠ 0) :
μ (p ^ k) = if k = 1 then -1 else 0 := by
split_ifs with h
· rw [h, pow_one, moebius_apply_prime hp]
rw [moebius_eq_zero_of_not_squarefree]
rw [squarefree_pow_iff hp.ne_one hk, not_and_or]
exact Or.inr h
theorem moebius_apply_isPrimePow_not_prime {n : ℕ} (hn : IsPrimePow n) (hn' : ¬n.Prime) :
μ n = 0 := by
obtain ⟨p, k, hp, hk, rfl⟩ := (isPrimePow_nat_iff _).1 hn
rw [moebius_apply_prime_pow hp hk.ne', if_neg]
rintro rfl
exact hn' (by simpa)
@[arith_mult]
theorem isMultiplicative_moebius : IsMultiplicative μ := by
rw [IsMultiplicative.iff_ne_zero]
refine ⟨by simp, fun {n m} hn hm hnm => ?_⟩
simp only [moebius, ZeroHom.coe_mk, coe_mk, ZeroHom.toFun_eq_coe, Eq.ndrec, ZeroHom.coe_mk,
IsUnit.mul_iff, Nat.isUnit_iff, squarefree_mul hnm, ite_zero_mul_ite_zero,
cardFactors_mul hn hm, pow_add]
theorem IsMultiplicative.prodPrimeFactors_one_add_of_squarefree [CommSemiring R]
{f : ArithmeticFunction R} (h_mult : f.IsMultiplicative) {n : ℕ} (hn : Squarefree n) :
∏ p ∈ n.primeFactors, (1 + f p) = ∑ d ∈ n.divisors, f d := by
trans (∏ᵖ p ∣ n, ((ζ : ArithmeticFunction R) + f) p)
· simp_rw [prodPrimeFactors_apply hn.ne_zero, add_apply, natCoe_apply]
apply Finset.prod_congr rfl; intro p hp
rw [zeta_apply_ne (prime_of_mem_primeFactorsList <| List.mem_toFinset.mp hp).ne_zero, cast_one]
rw [isMultiplicative_zeta.natCast.prodPrimeFactors_add_of_squarefree h_mult hn,
coe_zeta_mul_apply]
theorem IsMultiplicative.prodPrimeFactors_one_sub_of_squarefree [CommRing R]
(f : ArithmeticFunction R) (hf : f.IsMultiplicative) {n : ℕ} (hn : Squarefree n) :
∏ p ∈ n.primeFactors, (1 - f p) = ∑ d ∈ n.divisors, μ d * f d := by
trans (∏ p ∈ n.primeFactors, (1 + (ArithmeticFunction.pmul (μ : ArithmeticFunction R) f) p))
· apply Finset.prod_congr rfl; intro p hp
rw [pmul_apply, intCoe_apply, ArithmeticFunction.moebius_apply_prime
(prime_of_mem_primeFactorsList (List.mem_toFinset.mp hp))]
ring
· rw [(isMultiplicative_moebius.intCast.pmul hf).prodPrimeFactors_one_add_of_squarefree hn]
simp_rw [pmul_apply, intCoe_apply]
open UniqueFactorizationMonoid
@[simp]
theorem moebius_mul_coe_zeta : (μ * ζ : ArithmeticFunction ℤ) = 1 := by
ext n
refine recOnPosPrimePosCoprime ?_ ?_ ?_ ?_ n
· intro p n hp hn
rw [coe_mul_zeta_apply, sum_divisors_prime_pow hp, sum_range_succ']
simp_rw [Nat.pow_zero, moebius_apply_one,
moebius_apply_prime_pow hp (Nat.succ_ne_zero _), Nat.succ_inj, sum_ite_eq', mem_range,
if_pos hn, neg_add_cancel]
rw [one_apply_ne]
rw [Ne, pow_eq_one_iff]
· exact hp.ne_one
· exact hn.ne'
· rw [ZeroHom.map_zero, ZeroHom.map_zero]
· simp
· intro a b _ha _hb hab ha' hb'
rw [IsMultiplicative.map_mul_of_coprime _ hab, ha', hb',
IsMultiplicative.map_mul_of_coprime isMultiplicative_one hab]
exact isMultiplicative_moebius.mul isMultiplicative_zeta.natCast
@[simp]
theorem coe_zeta_mul_moebius : (ζ * μ : ArithmeticFunction ℤ) = 1 := by
rw [mul_comm, moebius_mul_coe_zeta]
@[simp]
theorem coe_moebius_mul_coe_zeta [Ring R] : (μ * ζ : ArithmeticFunction R) = 1 := by
rw [← coe_coe, ← intCoe_mul, moebius_mul_coe_zeta, intCoe_one]
@[simp]
theorem coe_zeta_mul_coe_moebius [Ring R] : (ζ * μ : ArithmeticFunction R) = 1 := by
rw [← coe_coe, ← intCoe_mul, coe_zeta_mul_moebius, intCoe_one]
section CommRing
variable [CommRing R]
instance : Invertible (ζ : ArithmeticFunction R) where
invOf := μ
invOf_mul_self := coe_moebius_mul_coe_zeta
mul_invOf_self := coe_zeta_mul_coe_moebius
/-- A unit in `ArithmeticFunction R` that evaluates to `ζ`, with inverse `μ`. -/
def zetaUnit : (ArithmeticFunction R)ˣ :=
⟨ζ, μ, coe_zeta_mul_coe_moebius, coe_moebius_mul_coe_zeta⟩
@[simp]
theorem coe_zetaUnit : ((zetaUnit : (ArithmeticFunction R)ˣ) : ArithmeticFunction R) = ζ :=
rfl
@[simp]
theorem inv_zetaUnit : ((zetaUnit⁻¹ : (ArithmeticFunction R)ˣ) : ArithmeticFunction R) = μ :=
rfl
end CommRing
/-- Möbius inversion for functions to an `AddCommGroup`. -/
theorem sum_eq_iff_sum_smul_moebius_eq [AddCommGroup R] {f g : ℕ → R} :
(∀ n > 0, ∑ i ∈ n.divisors, f i = g n) ↔
∀ n > 0, ∑ x ∈ n.divisorsAntidiagonal, μ x.fst • g x.snd = f n := by
let f' : ArithmeticFunction R := ⟨fun x => if x = 0 then 0 else f x, if_pos rfl⟩
let g' : ArithmeticFunction R := ⟨fun x => if x = 0 then 0 else g x, if_pos rfl⟩
trans (ζ : ArithmeticFunction ℤ) • f' = g'
· rw [ArithmeticFunction.ext_iff]
apply forall_congr'
intro n
cases n with
| zero => simp
| succ n =>
rw [coe_zeta_smul_apply]
simp only [n.succ_ne_zero, forall_prop_of_true, succ_pos', if_false, ZeroHom.coe_mk]
simp only [f', g', coe_mk, succ_ne_zero, ite_false]
rw [sum_congr rfl fun x hx => ?_]
rw [if_neg (Nat.pos_of_mem_divisors hx).ne']
trans μ • g' = f'
· constructor <;> intro h
· rw [← h, ← mul_smul, moebius_mul_coe_zeta, one_smul]
· rw [← h, ← mul_smul, coe_zeta_mul_moebius, one_smul]
· rw [ArithmeticFunction.ext_iff]
apply forall_congr'
intro n
cases n with
| zero => simp
| succ n =>
simp only [forall_prop_of_true, succ_pos', smul_apply, f', g', coe_mk, succ_ne_zero,
ite_false]
rw [sum_congr rfl fun x hx => ?_]
simp [if_neg (Nat.pos_of_mem_divisors (snd_mem_divisors_of_mem_antidiagonal hx)).ne']
/-- Möbius inversion for functions to a `Ring`. -/
theorem sum_eq_iff_sum_mul_moebius_eq [NonAssocRing R] {f g : ℕ → R} :
(∀ n > 0, ∑ i ∈ n.divisors, f i = g n) ↔
∀ n > 0, ∑ x ∈ n.divisorsAntidiagonal, (μ x.fst : R) * g x.snd = f n := by
rw [sum_eq_iff_sum_smul_moebius_eq]
apply forall_congr'
refine fun a => imp_congr_right fun _ => (sum_congr rfl fun x _hx => ?_).congr_left
rw [zsmul_eq_mul]
/-- Möbius inversion for functions to a `CommGroup`. -/
theorem prod_eq_iff_prod_pow_moebius_eq [CommGroup R] {f g : ℕ → R} :
(∀ n > 0, ∏ i ∈ n.divisors, f i = g n) ↔
∀ n > 0, ∏ x ∈ n.divisorsAntidiagonal, g x.snd ^ μ x.fst = f n :=
@sum_eq_iff_sum_smul_moebius_eq (Additive R) _ _ _
/-- Möbius inversion for functions to a `CommGroupWithZero`. -/
theorem prod_eq_iff_prod_pow_moebius_eq_of_nonzero [CommGroupWithZero R] {f g : ℕ → R}
(hf : ∀ n : ℕ, 0 < n → f n ≠ 0) (hg : ∀ n : ℕ, 0 < n → g n ≠ 0) :
(∀ n > 0, ∏ i ∈ n.divisors, f i = g n) ↔
∀ n > 0, ∏ x ∈ n.divisorsAntidiagonal, g x.snd ^ μ x.fst = f n := by
refine
Iff.trans
(Iff.trans (forall_congr' fun n => ?_)
(@prod_eq_iff_prod_pow_moebius_eq Rˣ _
(fun n => if h : 0 < n then Units.mk0 (f n) (hf n h) else 1) fun n =>
if h : 0 < n then Units.mk0 (g n) (hg n h) else 1))
(forall_congr' fun n => ?_) <;>
refine imp_congr_right fun hn => ?_
· dsimp
rw [dif_pos hn, ← Units.eq_iff, ← Units.coeHom_apply, map_prod, Units.val_mk0,
prod_congr rfl _]
intro x hx
rw [dif_pos (Nat.pos_of_mem_divisors hx), Units.coeHom_apply, Units.val_mk0]
· dsimp
rw [dif_pos hn, ← Units.eq_iff, ← Units.coeHom_apply, map_prod, Units.val_mk0,
prod_congr rfl _]
intro x hx
rw [dif_pos (Nat.pos_of_mem_divisors (Nat.snd_mem_divisors_of_mem_antidiagonal hx)),
Units.coeHom_apply, Units.val_zpow_eq_zpow_val, Units.val_mk0]
/-- Möbius inversion for functions to an `AddCommGroup`, where the equalities only hold on a
well-behaved set. -/
theorem sum_eq_iff_sum_smul_moebius_eq_on [AddCommGroup R] {f g : ℕ → R}
(s : Set ℕ) (hs : ∀ m n, m ∣ n → n ∈ s → m ∈ s) :
(∀ n > 0, n ∈ s → (∑ i ∈ n.divisors, f i) = g n) ↔
∀ n > 0, n ∈ s → (∑ x ∈ n.divisorsAntidiagonal, μ x.fst • g x.snd) = f n := by
constructor
· intro h
let G := fun (n : ℕ) => (∑ i ∈ n.divisors, f i)
intro n hn hnP
suffices ∑ d ∈ n.divisors, μ (n/d) • G d = f n by
rw [Nat.sum_divisorsAntidiagonal' (f := fun x y => μ x • g y), ← this, sum_congr rfl]
intro d hd
rw [← h d (Nat.pos_of_mem_divisors hd) <| hs d n (Nat.dvd_of_mem_divisors hd) hnP]
rw [← Nat.sum_divisorsAntidiagonal' (f := fun x y => μ x • G y)]
apply sum_eq_iff_sum_smul_moebius_eq.mp _ n hn
intro _ _; rfl
· intro h
let F := fun (n : ℕ) => ∑ x ∈ n.divisorsAntidiagonal, μ x.fst • g x.snd
intro n hn hnP
suffices ∑ d ∈ n.divisors, F d = g n by
rw [← this, sum_congr rfl]
intro d hd
rw [← h d (Nat.pos_of_mem_divisors hd) <| hs d n (Nat.dvd_of_mem_divisors hd) hnP]
apply sum_eq_iff_sum_smul_moebius_eq.mpr _ n hn
intro _ _; rfl
theorem sum_eq_iff_sum_smul_moebius_eq_on' [AddCommGroup R] {f g : ℕ → R}
(s : Set ℕ) (hs : ∀ m n, m ∣ n → n ∈ s → m ∈ s) (hs₀ : 0 ∉ s) :
(∀ n ∈ s, (∑ i ∈ n.divisors, f i) = g n) ↔
∀ n ∈ s, (∑ x ∈ n.divisorsAntidiagonal, μ x.fst • g x.snd) = f n := by
have : ∀ P : ℕ → Prop, ((∀ n ∈ s, P n) ↔ (∀ n > 0, n ∈ s → P n)) := fun P ↦ by
refine forall_congr' (fun n ↦ ⟨fun h _ ↦ h, fun h hn ↦ h ?_ hn⟩)
contrapose! hs₀
simpa [nonpos_iff_eq_zero.mp hs₀] using hn
simpa only [this] using sum_eq_iff_sum_smul_moebius_eq_on s hs
/-- Möbius inversion for functions to a `Ring`, where the equalities only hold on a well-behaved
set. -/
theorem sum_eq_iff_sum_mul_moebius_eq_on [NonAssocRing R] {f g : ℕ → R}
(s : Set ℕ) (hs : ∀ m n, m ∣ n → n ∈ s → m ∈ s) :
(∀ n > 0, n ∈ s → (∑ i ∈ n.divisors, f i) = g n) ↔
∀ n > 0, n ∈ s →
(∑ x ∈ n.divisorsAntidiagonal, (μ x.fst : R) * g x.snd) = f n := by
rw [sum_eq_iff_sum_smul_moebius_eq_on s hs]
apply forall_congr'
intro a; refine imp_congr_right ?_
refine fun _ => imp_congr_right fun _ => (sum_congr rfl fun x _hx => ?_).congr_left
rw [zsmul_eq_mul]
/-- Möbius inversion for functions to a `CommGroup`, where the equalities only hold on a
well-behaved set. -/
theorem prod_eq_iff_prod_pow_moebius_eq_on [CommGroup R] {f g : ℕ → R}
(s : Set ℕ) (hs : ∀ m n, m ∣ n → n ∈ s → m ∈ s) :
(∀ n > 0, n ∈ s → (∏ i ∈ n.divisors, f i) = g n) ↔
∀ n > 0, n ∈ s → (∏ x ∈ n.divisorsAntidiagonal, g x.snd ^ μ x.fst) = f n :=
@sum_eq_iff_sum_smul_moebius_eq_on (Additive R) _ _ _ s hs
/-- Möbius inversion for functions to a `CommGroupWithZero`, where the equalities only hold on
a well-behaved set. -/
theorem prod_eq_iff_prod_pow_moebius_eq_on_of_nonzero [CommGroupWithZero R]
(s : Set ℕ) (hs : ∀ m n, m ∣ n → n ∈ s → m ∈ s) {f g : ℕ → R}
(hf : ∀ n > 0, f n ≠ 0) (hg : ∀ n > 0, g n ≠ 0) :
(∀ n > 0, n ∈ s → (∏ i ∈ n.divisors, f i) = g n) ↔
∀ n > 0, n ∈ s → (∏ x ∈ n.divisorsAntidiagonal, g x.snd ^ μ x.fst) = f n := by
refine
Iff.trans
(Iff.trans (forall_congr' fun n => ?_)
(@prod_eq_iff_prod_pow_moebius_eq_on Rˣ _
(fun n => if h : 0 < n then Units.mk0 (f n) (hf n h) else 1)
(fun n => if h : 0 < n then Units.mk0 (g n) (hg n h) else 1)
s hs) )
(forall_congr' fun n => ?_) <;>
refine imp_congr_right fun hn => ?_
· dsimp
rw [dif_pos hn, ← Units.eq_iff, ← Units.coeHom_apply, map_prod, Units.val_mk0,
prod_congr rfl _]
intro x hx
rw [dif_pos (Nat.pos_of_mem_divisors hx), Units.coeHom_apply, Units.val_mk0]
· dsimp
rw [dif_pos hn, ← Units.eq_iff, ← Units.coeHom_apply, map_prod, Units.val_mk0,
prod_congr rfl _]
intro x hx
rw [dif_pos (Nat.pos_of_mem_divisors (Nat.snd_mem_divisors_of_mem_antidiagonal hx)),
Units.coeHom_apply, Units.val_zpow_eq_zpow_val, Units.val_mk0]
end SpecialFunctions
theorem _root_.Nat.card_divisors {n : ℕ} (hn : n ≠ 0) :
#n.divisors = n.primeFactors.prod (n.factorization · + 1) := by
rw [← sigma_zero_apply, isMultiplicative_sigma.multiplicative_factorization _ hn]
exact Finset.prod_congr n.support_factorization fun _ h =>
sigma_zero_apply_prime_pow <| Nat.prime_of_mem_primeFactors h
theorem _root_.Nat.sum_divisors {n : ℕ} (hn : n ≠ 0) :
| ∑ d ∈ n.divisors, d = ∏ p ∈ n.primeFactors, ∑ k ∈ .range (n.factorization p + 1), p ^ k := by
rw [← sigma_one_apply, isMultiplicative_sigma.multiplicative_factorization _ hn]
exact Finset.prod_congr n.support_factorization fun _ h =>
sigma_one_apply_prime_pow <| Nat.prime_of_mem_primeFactors h
end ArithmeticFunction
namespace Nat.Coprime
open ArithmeticFunction
theorem card_divisors_mul {m n : ℕ} (hmn : m.Coprime n) :
#(m * n).divisors = #m.divisors * #n.divisors := by
simp only [← sigma_zero_apply, isMultiplicative_sigma.map_mul_of_coprime hmn]
theorem sum_divisors_mul {m n : ℕ} (hmn : m.Coprime n) :
∑ d ∈ (m * n).divisors, d = (∑ d ∈ m.divisors, d) * ∑ d ∈ n.divisors, d := by
simp only [← sigma_one_apply, isMultiplicative_sigma.map_mul_of_coprime hmn]
end Nat.Coprime
| Mathlib/NumberTheory/ArithmeticFunction.lean | 1,285 | 1,307 |
/-
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.Algebra.Order.Ring.Int
import Mathlib.Data.Nat.SuccPred
/-!
# Successors and predecessors of integers
In this file, we show that `ℤ` is both an archimedean `SuccOrder` and an archimedean `PredOrder`.
-/
open Function Order
namespace Int
-- so that Lean reads `Int.succ` through `SuccOrder.succ`
@[instance] abbrev instSuccOrder : SuccOrder ℤ :=
{ SuccOrder.ofSuccLeIff succ fun {_ _} => Iff.rfl with succ := succ }
instance instSuccAddOrder : SuccAddOrder ℤ := ⟨fun _ => rfl⟩
-- so that Lean reads `Int.pred` through `PredOrder.pred`
@[instance] abbrev instPredOrder : PredOrder ℤ where
pred := pred
pred_le _ := (sub_one_lt_of_le le_rfl).le
min_of_le_pred ha := ((sub_one_lt_of_le le_rfl).not_le ha).elim
le_pred_of_lt {_ _} := le_sub_one_of_lt
instance instPredSubOrder : PredSubOrder ℤ := ⟨fun _ => rfl⟩
@[simp]
theorem succ_eq_succ : Order.succ = succ :=
rfl
@[simp]
theorem pred_eq_pred : Order.pred = pred :=
rfl
instance : IsSuccArchimedean ℤ :=
⟨fun {a b} h =>
⟨(b - a).toNat, by rw [succ_iterate, toNat_sub_of_le h, ← add_sub_assoc, add_sub_cancel_left]⟩⟩
instance : IsPredArchimedean ℤ :=
⟨fun {a b} h =>
⟨(b - a).toNat, by rw [pred_iterate, toNat_sub_of_le h, sub_sub_cancel]⟩⟩
/-! ### Covering relation -/
@[simp, norm_cast]
| theorem natCast_covBy {a b : ℕ} : (a : ℤ) ⋖ b ↔ a ⋖ b := by
rw [Order.covBy_iff_add_one_eq, Order.covBy_iff_add_one_eq]
exact Int.natCast_inj
end Int
| Mathlib/Data/Int/SuccPred.lean | 55 | 59 |
/-
Copyright (c) 2018 Ellen Arlt. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Ellen Arlt, Blair Shi, Sean Leather, Mario Carneiro, Johan Commelin, Lu-Ming Zhang
-/
import Mathlib.Algebra.Algebra.Opposite
import Mathlib.Algebra.Algebra.Pi
import Mathlib.Algebra.BigOperators.RingEquiv
import Mathlib.Data.Finite.Prod
import Mathlib.Data.Matrix.Mul
import Mathlib.LinearAlgebra.Pi
/-!
# Matrices
This file contains basic results on matrices including bundled versions of matrix operators.
## Implementation notes
For convenience, `Matrix m n α` is defined as `m → n → α`, as this allows elements of the matrix
to be accessed with `A i j`. However, it is not advisable to _construct_ matrices using terms of the
form `fun i j ↦ _` or even `(fun i j ↦ _ : Matrix m n α)`, as these are not recognized by Lean
as having the right type. Instead, `Matrix.of` should be used.
## TODO
Under various conditions, multiplication of infinite matrices makes sense.
These have not yet been implemented.
-/
assert_not_exists Star
universe u u' v w
variable {l m n o : Type*} {m' : o → Type*} {n' : o → Type*}
variable {R : Type*} {S : Type*} {α : Type v} {β : Type w} {γ : Type*}
namespace Matrix
instance decidableEq [DecidableEq α] [Fintype m] [Fintype n] : DecidableEq (Matrix m n α) :=
Fintype.decidablePiFintype
instance {n m} [Fintype m] [DecidableEq m] [Fintype n] [DecidableEq n] (α) [Fintype α] :
Fintype (Matrix m n α) := inferInstanceAs (Fintype (m → n → α))
instance {n m} [Finite m] [Finite n] (α) [Finite α] :
Finite (Matrix m n α) := inferInstanceAs (Finite (m → n → α))
section
variable (R)
/-- This is `Matrix.of` bundled as a linear equivalence. -/
def ofLinearEquiv [Semiring R] [AddCommMonoid α] [Module R α] : (m → n → α) ≃ₗ[R] Matrix m n α where
__ := ofAddEquiv
map_smul' _ _ := rfl
@[simp] lemma coe_ofLinearEquiv [Semiring R] [AddCommMonoid α] [Module R α] :
⇑(ofLinearEquiv _ : (m → n → α) ≃ₗ[R] Matrix m n α) = of := rfl
@[simp] lemma coe_ofLinearEquiv_symm [Semiring R] [AddCommMonoid α] [Module R α] :
⇑((ofLinearEquiv _).symm : Matrix m n α ≃ₗ[R] (m → n → α)) = of.symm := rfl
end
theorem sum_apply [AddCommMonoid α] (i : m) (j : n) (s : Finset β) (g : β → Matrix m n α) :
(∑ c ∈ s, g c) i j = ∑ c ∈ s, g c i j :=
(congr_fun (s.sum_apply i g) j).trans (s.sum_apply j _)
end Matrix
open Matrix
namespace Matrix
section Diagonal
variable [DecidableEq n]
variable (n α)
/-- `Matrix.diagonal` as an `AddMonoidHom`. -/
@[simps]
def diagonalAddMonoidHom [AddZeroClass α] : (n → α) →+ Matrix n n α where
toFun := diagonal
map_zero' := diagonal_zero
map_add' x y := (diagonal_add x y).symm
variable (R)
/-- `Matrix.diagonal` as a `LinearMap`. -/
@[simps]
def diagonalLinearMap [Semiring R] [AddCommMonoid α] [Module R α] : (n → α) →ₗ[R] Matrix n n α :=
{ diagonalAddMonoidHom n α with map_smul' := diagonal_smul }
variable {n α R}
section One
variable [Zero α] [One α]
lemma zero_le_one_elem [Preorder α] [ZeroLEOneClass α] (i j : n) :
0 ≤ (1 : Matrix n n α) i j := by
by_cases hi : i = j
· subst hi
simp
· simp [hi]
lemma zero_le_one_row [Preorder α] [ZeroLEOneClass α] (i : n) :
0 ≤ (1 : Matrix n n α) i :=
zero_le_one_elem i
end One
end Diagonal
section Diag
variable (n α)
/-- `Matrix.diag` as an `AddMonoidHom`. -/
@[simps]
def diagAddMonoidHom [AddZeroClass α] : Matrix n n α →+ n → α where
toFun := diag
map_zero' := diag_zero
map_add' := diag_add
variable (R)
/-- `Matrix.diag` as a `LinearMap`. -/
@[simps]
def diagLinearMap [Semiring R] [AddCommMonoid α] [Module R α] : Matrix n n α →ₗ[R] n → α :=
{ diagAddMonoidHom n α with map_smul' := diag_smul }
variable {n α R}
@[simp]
theorem diag_list_sum [AddMonoid α] (l : List (Matrix n n α)) : diag l.sum = (l.map diag).sum :=
map_list_sum (diagAddMonoidHom n α) l
@[simp]
theorem diag_multiset_sum [AddCommMonoid α] (s : Multiset (Matrix n n α)) :
diag s.sum = (s.map diag).sum :=
map_multiset_sum (diagAddMonoidHom n α) s
@[simp]
theorem diag_sum {ι} [AddCommMonoid α] (s : Finset ι) (f : ι → Matrix n n α) :
diag (∑ i ∈ s, f i) = ∑ i ∈ s, diag (f i) :=
map_sum (diagAddMonoidHom n α) f s
end Diag
open Matrix
section AddCommMonoid
variable [AddCommMonoid α] [Mul α]
end AddCommMonoid
section NonAssocSemiring
variable [NonAssocSemiring α]
variable (α n)
/-- `Matrix.diagonal` as a `RingHom`. -/
@[simps]
def diagonalRingHom [Fintype n] [DecidableEq n] : (n → α) →+* Matrix n n α :=
{ diagonalAddMonoidHom n α with
toFun := diagonal
map_one' := diagonal_one
map_mul' := fun _ _ => (diagonal_mul_diagonal' _ _).symm }
end NonAssocSemiring
section Semiring
variable [Semiring α]
theorem diagonal_pow [Fintype n] [DecidableEq n] (v : n → α) (k : ℕ) :
diagonal v ^ k = diagonal (v ^ k) :=
(map_pow (diagonalRingHom n α) v k).symm
/-- The ring homomorphism `α →+* Matrix n n α`
sending `a` to the diagonal matrix with `a` on the diagonal.
-/
def scalar (n : Type u) [DecidableEq n] [Fintype n] : α →+* Matrix n n α :=
(diagonalRingHom n α).comp <| Pi.constRingHom n α
section Scalar
variable [DecidableEq n] [Fintype n]
@[simp]
theorem scalar_apply (a : α) : scalar n a = diagonal fun _ => a :=
rfl
theorem scalar_inj [Nonempty n] {r s : α} : scalar n r = scalar n s ↔ r = s :=
(diagonal_injective.comp Function.const_injective).eq_iff
theorem scalar_commute_iff {r : α} {M : Matrix n n α} :
Commute (scalar n r) M ↔ r • M = MulOpposite.op r • M := by
simp_rw [Commute, SemiconjBy, scalar_apply, ← smul_eq_diagonal_mul, ← op_smul_eq_mul_diagonal]
theorem scalar_commute (r : α) (hr : ∀ r', Commute r r') (M : Matrix n n α) :
Commute (scalar n r) M := scalar_commute_iff.2 <| ext fun _ _ => hr _
end Scalar
end Semiring
section Algebra
variable [Fintype n] [DecidableEq n]
variable [CommSemiring R] [Semiring α] [Semiring β] [Algebra R α] [Algebra R β]
instance instAlgebra : Algebra R (Matrix n n α) where
algebraMap := (Matrix.scalar n).comp (algebraMap R α)
commutes' _ _ := scalar_commute _ (fun _ => Algebra.commutes _ _) _
smul_def' r x := by ext; simp [Matrix.scalar, Algebra.smul_def r]
theorem algebraMap_matrix_apply {r : R} {i j : n} :
algebraMap R (Matrix n n α) r i j = if i = j then algebraMap R α r else 0 := by
dsimp [algebraMap, Algebra.algebraMap, Matrix.scalar]
split_ifs with h <;> simp [h, Matrix.one_apply_ne]
theorem algebraMap_eq_diagonal (r : R) :
algebraMap R (Matrix n n α) r = diagonal (algebraMap R (n → α) r) := rfl
theorem algebraMap_eq_diagonalRingHom :
algebraMap R (Matrix n n α) = (diagonalRingHom n α).comp (algebraMap R _) := rfl
@[simp]
theorem map_algebraMap (r : R) (f : α → β) (hf : f 0 = 0)
(hf₂ : f (algebraMap R α r) = algebraMap R β r) :
(algebraMap R (Matrix n n α) r).map f = algebraMap R (Matrix n n β) r := by
rw [algebraMap_eq_diagonal, algebraMap_eq_diagonal, diagonal_map hf]
simp [hf₂]
variable (R)
/-- `Matrix.diagonal` as an `AlgHom`. -/
@[simps]
def diagonalAlgHom : (n → α) →ₐ[R] Matrix n n α :=
{ diagonalRingHom n α with
toFun := diagonal
commutes' := fun r => (algebraMap_eq_diagonal r).symm }
end Algebra
section AddHom
variable [Add α]
variable (R α) in
/-- Extracting entries from a matrix as an additive homomorphism. -/
@[simps]
def entryAddHom (i : m) (j : n) : AddHom (Matrix m n α) α where
toFun M := M i j
map_add' _ _ := rfl
-- It is necessary to spell out the name of the coercion explicitly on the RHS
-- for unification to succeed
lemma entryAddHom_eq_comp {i : m} {j : n} :
entryAddHom α i j =
((Pi.evalAddHom (fun _ => α) j).comp (Pi.evalAddHom _ i)).comp
(AddHomClass.toAddHom ofAddEquiv.symm) :=
rfl
end AddHom
section AddMonoidHom
variable [AddZeroClass α]
variable (R α) in
/--
Extracting entries from a matrix as an additive monoid homomorphism. Note this cannot be upgraded to
a ring homomorphism, as it does not respect multiplication.
-/
@[simps]
def entryAddMonoidHom (i : m) (j : n) : Matrix m n α →+ α where
toFun M := M i j
map_add' _ _ := rfl
map_zero' := rfl
-- It is necessary to spell out the name of the coercion explicitly on the RHS
-- for unification to succeed
lemma entryAddMonoidHom_eq_comp {i : m} {j : n} :
entryAddMonoidHom α i j =
((Pi.evalAddMonoidHom (fun _ => α) j).comp (Pi.evalAddMonoidHom _ i)).comp
(AddMonoidHomClass.toAddMonoidHom ofAddEquiv.symm) := by
rfl
@[simp] lemma evalAddMonoidHom_comp_diagAddMonoidHom (i : m) :
(Pi.evalAddMonoidHom _ i).comp (diagAddMonoidHom m α) = entryAddMonoidHom α i i := by
simp [AddMonoidHom.ext_iff]
@[simp] lemma entryAddMonoidHom_toAddHom {i : m} {j : n} :
(entryAddMonoidHom α i j : AddHom _ _) = entryAddHom α i j := rfl
end AddMonoidHom
section LinearMap
variable [Semiring R] [AddCommMonoid α] [Module R α]
variable (R α) in
/--
Extracting entries from a matrix as a linear map. Note this cannot be upgraded to an algebra
homomorphism, as it does not respect multiplication.
-/
@[simps]
def entryLinearMap (i : m) (j : n) :
Matrix m n α →ₗ[R] α where
toFun M := M i j
map_add' _ _ := rfl
map_smul' _ _ := rfl
-- It is necessary to spell out the name of the coercion explicitly on the RHS
-- for unification to succeed
lemma entryLinearMap_eq_comp {i : m} {j : n} :
entryLinearMap R α i j =
LinearMap.proj j ∘ₗ LinearMap.proj i ∘ₗ (ofLinearEquiv R).symm.toLinearMap := by
rfl
@[simp] lemma proj_comp_diagLinearMap (i : m) :
LinearMap.proj i ∘ₗ diagLinearMap m R α = entryLinearMap R α i i := by
simp [LinearMap.ext_iff]
@[simp] lemma entryLinearMap_toAddMonoidHom {i : m} {j : n} :
(entryLinearMap R α i j : _ →+ _) = entryAddMonoidHom α i j := rfl
@[simp] lemma entryLinearMap_toAddHom {i : m} {j : n} :
(entryLinearMap R α i j : AddHom _ _) = entryAddHom α i j := rfl
end LinearMap
end Matrix
/-!
### Bundled versions of `Matrix.map`
-/
namespace Equiv
/-- The `Equiv` between spaces of matrices induced by an `Equiv` between their
coefficients. This is `Matrix.map` as an `Equiv`. -/
@[simps apply]
def mapMatrix (f : α ≃ β) : Matrix m n α ≃ Matrix m n β where
toFun M := M.map f
invFun M := M.map f.symm
left_inv _ := Matrix.ext fun _ _ => f.symm_apply_apply _
right_inv _ := Matrix.ext fun _ _ => f.apply_symm_apply _
@[simp]
theorem mapMatrix_refl : (Equiv.refl α).mapMatrix = Equiv.refl (Matrix m n α) :=
rfl
@[simp]
theorem mapMatrix_symm (f : α ≃ β) : f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m n β ≃ _) :=
rfl
@[simp]
theorem mapMatrix_trans (f : α ≃ β) (g : β ≃ γ) :
f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m n α ≃ _) :=
rfl
end Equiv
namespace AddMonoidHom
variable [AddZeroClass α] [AddZeroClass β] [AddZeroClass γ]
/-- The `AddMonoidHom` between spaces of matrices induced by an `AddMonoidHom` between their
coefficients. This is `Matrix.map` as an `AddMonoidHom`. -/
@[simps]
def mapMatrix (f : α →+ β) : Matrix m n α →+ Matrix m n β where
toFun M := M.map f
map_zero' := Matrix.map_zero f f.map_zero
map_add' := Matrix.map_add f f.map_add
@[simp]
theorem mapMatrix_id : (AddMonoidHom.id α).mapMatrix = AddMonoidHom.id (Matrix m n α) :=
rfl
@[simp]
theorem mapMatrix_comp (f : β →+ γ) (g : α →+ β) :
f.mapMatrix.comp g.mapMatrix = ((f.comp g).mapMatrix : Matrix m n α →+ _) :=
rfl
@[simp] lemma entryAddMonoidHom_comp_mapMatrix (f : α →+ β) (i : m) (j : n) :
(entryAddMonoidHom β i j).comp f.mapMatrix = f.comp (entryAddMonoidHom α i j) := rfl
end AddMonoidHom
namespace AddEquiv
variable [Add α] [Add β] [Add γ]
/-- The `AddEquiv` between spaces of matrices induced by an `AddEquiv` between their
coefficients. This is `Matrix.map` as an `AddEquiv`. -/
@[simps apply]
def mapMatrix (f : α ≃+ β) : Matrix m n α ≃+ Matrix m n β :=
{ f.toEquiv.mapMatrix with
toFun := fun M => M.map f
invFun := fun M => M.map f.symm
map_add' := Matrix.map_add f (map_add f) }
@[simp]
theorem mapMatrix_refl : (AddEquiv.refl α).mapMatrix = AddEquiv.refl (Matrix m n α) :=
rfl
@[simp]
theorem mapMatrix_symm (f : α ≃+ β) : f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m n β ≃+ _) :=
rfl
@[simp]
theorem mapMatrix_trans (f : α ≃+ β) (g : β ≃+ γ) :
f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m n α ≃+ _) :=
rfl
@[simp] lemma entryAddHom_comp_mapMatrix (f : α ≃+ β) (i : m) (j : n) :
(entryAddHom β i j).comp (AddHomClass.toAddHom f.mapMatrix) =
(f : AddHom α β).comp (entryAddHom _ i j) := rfl
end AddEquiv
namespace LinearMap
variable [Semiring R] [AddCommMonoid α] [AddCommMonoid β] [AddCommMonoid γ]
variable [Module R α] [Module R β] [Module R γ]
/-- The `LinearMap` between spaces of matrices induced by a `LinearMap` between their
coefficients. This is `Matrix.map` as a `LinearMap`. -/
@[simps]
def mapMatrix (f : α →ₗ[R] β) : Matrix m n α →ₗ[R] Matrix m n β where
toFun M := M.map f
map_add' := Matrix.map_add f f.map_add
map_smul' r := Matrix.map_smul f r (f.map_smul r)
@[simp]
theorem mapMatrix_id : LinearMap.id.mapMatrix = (LinearMap.id : Matrix m n α →ₗ[R] _) :=
rfl
@[simp]
theorem mapMatrix_comp (f : β →ₗ[R] γ) (g : α →ₗ[R] β) :
f.mapMatrix.comp g.mapMatrix = ((f.comp g).mapMatrix : Matrix m n α →ₗ[R] _) :=
rfl
@[simp] lemma entryLinearMap_comp_mapMatrix (f : α →ₗ[R] β) (i : m) (j : n) :
entryLinearMap R _ i j ∘ₗ f.mapMatrix = f ∘ₗ entryLinearMap R _ i j := rfl
end LinearMap
namespace LinearEquiv
variable [Semiring R] [AddCommMonoid α] [AddCommMonoid β] [AddCommMonoid γ]
variable [Module R α] [Module R β] [Module R γ]
/-- The `LinearEquiv` between spaces of matrices induced by a `LinearEquiv` between their
coefficients. This is `Matrix.map` as a `LinearEquiv`. -/
@[simps apply]
def mapMatrix (f : α ≃ₗ[R] β) : Matrix m n α ≃ₗ[R] Matrix m n β :=
{ f.toEquiv.mapMatrix,
f.toLinearMap.mapMatrix with
toFun := fun M => M.map f
invFun := fun M => M.map f.symm }
@[simp]
theorem mapMatrix_refl : (LinearEquiv.refl R α).mapMatrix = LinearEquiv.refl R (Matrix m n α) :=
rfl
@[simp]
theorem mapMatrix_symm (f : α ≃ₗ[R] β) :
f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m n β ≃ₗ[R] _) :=
rfl
@[simp]
theorem mapMatrix_trans (f : α ≃ₗ[R] β) (g : β ≃ₗ[R] γ) :
f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m n α ≃ₗ[R] _) :=
rfl
@[simp] lemma mapMatrix_toLinearMap (f : α ≃ₗ[R] β) :
(f.mapMatrix : _ ≃ₗ[R] Matrix m n β).toLinearMap = f.toLinearMap.mapMatrix := by
rfl
@[simp] lemma entryLinearMap_comp_mapMatrix (f : α ≃ₗ[R] β) (i : m) (j : n) :
entryLinearMap R _ i j ∘ₗ f.mapMatrix.toLinearMap =
f.toLinearMap ∘ₗ entryLinearMap R _ i j := by
simp only [mapMatrix_toLinearMap, LinearMap.entryLinearMap_comp_mapMatrix]
end LinearEquiv
namespace RingHom
variable [Fintype m] [DecidableEq m]
variable [NonAssocSemiring α] [NonAssocSemiring β] [NonAssocSemiring γ]
/-- The `RingHom` between spaces of square matrices induced by a `RingHom` between their
coefficients. This is `Matrix.map` as a `RingHom`. -/
@[simps]
def mapMatrix (f : α →+* β) : Matrix m m α →+* Matrix m m β :=
{ f.toAddMonoidHom.mapMatrix with
toFun := fun M => M.map f
map_one' := by simp
map_mul' := fun _ _ => Matrix.map_mul }
@[simp]
theorem mapMatrix_id : (RingHom.id α).mapMatrix = RingHom.id (Matrix m m α) :=
rfl
@[simp]
theorem mapMatrix_comp (f : β →+* γ) (g : α →+* β) :
f.mapMatrix.comp g.mapMatrix = ((f.comp g).mapMatrix : Matrix m m α →+* _) :=
rfl
end RingHom
namespace RingEquiv
variable [Fintype m] [DecidableEq m]
variable [NonAssocSemiring α] [NonAssocSemiring β] [NonAssocSemiring γ]
/-- The `RingEquiv` between spaces of square matrices induced by a `RingEquiv` between their
coefficients. This is `Matrix.map` as a `RingEquiv`. -/
@[simps apply]
def mapMatrix (f : α ≃+* β) : Matrix m m α ≃+* Matrix m m β :=
{ f.toRingHom.mapMatrix,
f.toAddEquiv.mapMatrix with
toFun := fun M => M.map f
invFun := fun M => M.map f.symm }
@[simp]
theorem mapMatrix_refl : (RingEquiv.refl α).mapMatrix = RingEquiv.refl (Matrix m m α) :=
rfl
@[simp]
theorem mapMatrix_symm (f : α ≃+* β) : f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m m β ≃+* _) :=
rfl
@[simp]
theorem mapMatrix_trans (f : α ≃+* β) (g : β ≃+* γ) :
f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m m α ≃+* _) :=
rfl
open MulOpposite in
/--
For any ring `R`, we have ring isomorphism `Matₙₓₙ(Rᵒᵖ) ≅ (Matₙₓₙ(R))ᵒᵖ` given by transpose.
-/
@[simps apply symm_apply]
def mopMatrix : Matrix m m αᵐᵒᵖ ≃+* (Matrix m m α)ᵐᵒᵖ where
toFun M := op (M.transpose.map unop)
invFun M := M.unop.transpose.map op
left_inv _ := by aesop
right_inv _ := by aesop
map_mul' _ _ := unop_injective <| by ext; simp [transpose, mul_apply]
map_add' _ _ := by aesop
end RingEquiv
namespace AlgHom
variable [Fintype m] [DecidableEq m]
variable [CommSemiring R] [Semiring α] [Semiring β] [Semiring γ]
variable [Algebra R α] [Algebra R β] [Algebra R γ]
/-- The `AlgHom` between spaces of square matrices induced by an `AlgHom` between their
coefficients. This is `Matrix.map` as an `AlgHom`. -/
@[simps]
def mapMatrix (f : α →ₐ[R] β) : Matrix m m α →ₐ[R] Matrix m m β :=
{ f.toRingHom.mapMatrix with
toFun := fun M => M.map f
commutes' := fun r => Matrix.map_algebraMap r f (map_zero _) (f.commutes r) }
@[simp]
theorem mapMatrix_id : (AlgHom.id R α).mapMatrix = AlgHom.id R (Matrix m m α) :=
rfl
@[simp]
theorem mapMatrix_comp (f : β →ₐ[R] γ) (g : α →ₐ[R] β) :
f.mapMatrix.comp g.mapMatrix = ((f.comp g).mapMatrix : Matrix m m α →ₐ[R] _) :=
rfl
end AlgHom
namespace AlgEquiv
variable [Fintype m] [DecidableEq m]
variable [CommSemiring R] [Semiring α] [Semiring β] [Semiring γ]
variable [Algebra R α] [Algebra R β] [Algebra R γ]
/-- The `AlgEquiv` between spaces of square matrices induced by an `AlgEquiv` between their
coefficients. This is `Matrix.map` as an `AlgEquiv`. -/
@[simps apply]
def mapMatrix (f : α ≃ₐ[R] β) : Matrix m m α ≃ₐ[R] Matrix m m β :=
{ f.toAlgHom.mapMatrix,
f.toRingEquiv.mapMatrix with
toFun := fun M => M.map f
invFun := fun M => M.map f.symm }
@[simp]
theorem mapMatrix_refl : AlgEquiv.refl.mapMatrix = (AlgEquiv.refl : Matrix m m α ≃ₐ[R] _) :=
rfl
@[simp]
theorem mapMatrix_symm (f : α ≃ₐ[R] β) :
f.mapMatrix.symm = (f.symm.mapMatrix : Matrix m m β ≃ₐ[R] _) :=
rfl
@[simp]
theorem mapMatrix_trans (f : α ≃ₐ[R] β) (g : β ≃ₐ[R] γ) :
f.mapMatrix.trans g.mapMatrix = ((f.trans g).mapMatrix : Matrix m m α ≃ₐ[R] _) :=
rfl
/-- For any algebra `α` over a ring `R`, we have an `R`-algebra isomorphism
`Matₙₓₙ(αᵒᵖ) ≅ (Matₙₓₙ(R))ᵒᵖ` given by transpose. If `α` is commutative,
we can get rid of the `ᵒᵖ` in the left-hand side, see `Matrix.transposeAlgEquiv`. -/
@[simps!] def mopMatrix : Matrix m m αᵐᵒᵖ ≃ₐ[R] (Matrix m m α)ᵐᵒᵖ where
__ := RingEquiv.mopMatrix
commutes' _ := MulOpposite.unop_injective <| by
ext; simp [algebraMap_matrix_apply, eq_comm, apply_ite MulOpposite.unop]
end AlgEquiv
open Matrix
namespace Matrix
section Transpose
open Matrix
variable (m n α)
/-- `Matrix.transpose` as an `AddEquiv` -/
@[simps apply]
def transposeAddEquiv [Add α] : Matrix m n α ≃+ Matrix n m α where
toFun := transpose
invFun := transpose
left_inv := transpose_transpose
right_inv := transpose_transpose
map_add' := transpose_add
@[simp]
theorem transposeAddEquiv_symm [Add α] : (transposeAddEquiv m n α).symm = transposeAddEquiv n m α :=
rfl
variable {m n α}
theorem transpose_list_sum [AddMonoid α] (l : List (Matrix m n α)) :
l.sumᵀ = (l.map transpose).sum :=
map_list_sum (transposeAddEquiv m n α) l
theorem transpose_multiset_sum [AddCommMonoid α] (s : Multiset (Matrix m n α)) :
s.sumᵀ = (s.map transpose).sum :=
(transposeAddEquiv m n α).toAddMonoidHom.map_multiset_sum s
theorem transpose_sum [AddCommMonoid α] {ι : Type*} (s : Finset ι) (M : ι → Matrix m n α) :
(∑ i ∈ s, M i)ᵀ = ∑ i ∈ s, (M i)ᵀ :=
map_sum (transposeAddEquiv m n α) _ s
variable (m n R α)
/-- `Matrix.transpose` as a `LinearMap` -/
@[simps apply]
def transposeLinearEquiv [Semiring R] [AddCommMonoid α] [Module R α] :
Matrix m n α ≃ₗ[R] Matrix n m α :=
{ transposeAddEquiv m n α with map_smul' := transpose_smul }
@[simp]
theorem transposeLinearEquiv_symm [Semiring R] [AddCommMonoid α] [Module R α] :
(transposeLinearEquiv m n R α).symm = transposeLinearEquiv n m R α :=
rfl
variable {m n R α}
variable (m α)
/-- `Matrix.transpose` as a `RingEquiv` to the opposite ring -/
@[simps]
def transposeRingEquiv [AddCommMonoid α] [CommSemigroup α] [Fintype m] :
Matrix m m α ≃+* (Matrix m m α)ᵐᵒᵖ :=
{ (transposeAddEquiv m m α).trans MulOpposite.opAddEquiv with
toFun := fun M => MulOpposite.op Mᵀ
invFun := fun M => M.unopᵀ
map_mul' := fun M N =>
(congr_arg MulOpposite.op (transpose_mul M N)).trans (MulOpposite.op_mul _ _)
left_inv := fun M => transpose_transpose M
right_inv := fun M => MulOpposite.unop_injective <| transpose_transpose M.unop }
variable {m α}
@[simp]
theorem transpose_pow [CommSemiring α] [Fintype m] [DecidableEq m] (M : Matrix m m α) (k : ℕ) :
(M ^ k)ᵀ = Mᵀ ^ k :=
MulOpposite.op_injective <| map_pow (transposeRingEquiv m α) M k
theorem transpose_list_prod [CommSemiring α] [Fintype m] [DecidableEq m] (l : List (Matrix m m α)) :
l.prodᵀ = (l.map transpose).reverse.prod :=
(transposeRingEquiv m α).unop_map_list_prod l
variable (R m α)
/-- `Matrix.transpose` as an `AlgEquiv` to the opposite ring -/
@[simps]
def transposeAlgEquiv [CommSemiring R] [CommSemiring α] [Fintype m] [DecidableEq m] [Algebra R α] :
Matrix m m α ≃ₐ[R] (Matrix m m α)ᵐᵒᵖ :=
{ (transposeAddEquiv m m α).trans MulOpposite.opAddEquiv,
transposeRingEquiv m α with
toFun := fun M => MulOpposite.op Mᵀ
commutes' := fun r => by
simp only [algebraMap_eq_diagonal, diagonal_transpose, MulOpposite.algebraMap_apply] }
variable {R m α}
end Transpose
end Matrix
| Mathlib/Data/Matrix/Basic.lean | 1,055 | 1,058 | |
/-
Copyright (c) 2022 Wrenna Robson. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Wrenna Robson
-/
import Mathlib.Topology.MetricSpace.Basic
/-!
# Infimum separation
This file defines the extended infimum separation of a set. This is approximately dual to the
diameter of a set, but where the extended diameter of a set is the supremum of the extended distance
between elements of the set, the extended infimum separation is the infimum of the (extended)
distance between *distinct* elements in the set.
We also define the infimum separation as the cast of the extended infimum separation to the reals.
This is the infimum of the distance between distinct elements of the set when in a pseudometric
space.
All lemmas and definitions are in the `Set` namespace to give access to dot notation.
## Main definitions
* `Set.einfsep`: Extended infimum separation of a set.
* `Set.infsep`: Infimum separation of a set (when in a pseudometric space).
-/
variable {α β : Type*}
namespace Set
section Einfsep
open ENNReal
open Function
/-- The "extended infimum separation" of a set with an edist function. -/
noncomputable def einfsep [EDist α] (s : Set α) : ℝ≥0∞ :=
⨅ (x ∈ s) (y ∈ s) (_ : x ≠ y), edist x y
section EDist
variable [EDist α] {x y : α} {s t : Set α}
theorem le_einfsep_iff {d} :
d ≤ s.einfsep ↔ ∀ x ∈ s, ∀ y ∈ s, x ≠ y → d ≤ edist x y := by
simp_rw [einfsep, le_iInf_iff]
theorem einfsep_zero : s.einfsep = 0 ↔ ∀ C > 0, ∃ x ∈ s, ∃ y ∈ s, x ≠ y ∧ edist x y < C := by
simp_rw [einfsep, ← _root_.bot_eq_zero, iInf_eq_bot, iInf_lt_iff, exists_prop]
theorem einfsep_pos : 0 < s.einfsep ↔ ∃ C > 0, ∀ x ∈ s, ∀ y ∈ s, x ≠ y → C ≤ edist x y := by
rw [pos_iff_ne_zero, Ne, einfsep_zero]
simp only [not_forall, not_exists, not_lt, exists_prop, not_and]
theorem einfsep_top :
s.einfsep = ∞ ↔ ∀ x ∈ s, ∀ y ∈ s, x ≠ y → edist x y = ∞ := by
simp_rw [einfsep, iInf_eq_top]
theorem einfsep_lt_top :
s.einfsep < ∞ ↔ ∃ x ∈ s, ∃ y ∈ s, x ≠ y ∧ edist x y < ∞ := by
simp_rw [einfsep, iInf_lt_iff, exists_prop]
theorem einfsep_ne_top :
s.einfsep ≠ ∞ ↔ ∃ x ∈ s, ∃ y ∈ s, x ≠ y ∧ edist x y ≠ ∞ := by
simp_rw [← lt_top_iff_ne_top, einfsep_lt_top]
theorem einfsep_lt_iff {d} :
s.einfsep < d ↔ ∃ x ∈ s, ∃ y ∈ s, x ≠ y ∧ edist x y < d := by
simp_rw [einfsep, iInf_lt_iff, exists_prop]
theorem nontrivial_of_einfsep_lt_top (hs : s.einfsep < ∞) : s.Nontrivial := by
rcases einfsep_lt_top.1 hs with ⟨_, hx, _, hy, hxy, _⟩
exact ⟨_, hx, _, hy, hxy⟩
theorem nontrivial_of_einfsep_ne_top (hs : s.einfsep ≠ ∞) : s.Nontrivial :=
nontrivial_of_einfsep_lt_top (lt_top_iff_ne_top.mpr hs)
theorem Subsingleton.einfsep (hs : s.Subsingleton) : s.einfsep = ∞ := by
rw [einfsep_top]
exact fun _ hx _ hy hxy => (hxy <| hs hx hy).elim
theorem le_einfsep_image_iff {d} {f : β → α} {s : Set β} : d ≤ einfsep (f '' s)
↔ ∀ x ∈ s, ∀ y ∈ s, f x ≠ f y → d ≤ edist (f x) (f y) := by
simp_rw [le_einfsep_iff, forall_mem_image]
theorem le_edist_of_le_einfsep {d x} (hx : x ∈ s) {y} (hy : y ∈ s) (hxy : x ≠ y)
(hd : d ≤ s.einfsep) : d ≤ edist x y :=
le_einfsep_iff.1 hd x hx y hy hxy
theorem einfsep_le_edist_of_mem {x} (hx : x ∈ s) {y} (hy : y ∈ s) (hxy : x ≠ y) :
s.einfsep ≤ edist x y :=
le_edist_of_le_einfsep hx hy hxy le_rfl
theorem einfsep_le_of_mem_of_edist_le {d x} (hx : x ∈ s) {y} (hy : y ∈ s) (hxy : x ≠ y)
(hxy' : edist x y ≤ d) : s.einfsep ≤ d :=
le_trans (einfsep_le_edist_of_mem hx hy hxy) hxy'
theorem le_einfsep {d} (h : ∀ x ∈ s, ∀ y ∈ s, x ≠ y → d ≤ edist x y) : d ≤ s.einfsep :=
le_einfsep_iff.2 h
@[simp]
theorem einfsep_empty : (∅ : Set α).einfsep = ∞ :=
subsingleton_empty.einfsep
@[simp]
theorem einfsep_singleton : ({x} : Set α).einfsep = ∞ :=
subsingleton_singleton.einfsep
theorem einfsep_iUnion_mem_option {ι : Type*} (o : Option ι) (s : ι → Set α) :
(⋃ i ∈ o, s i).einfsep = ⨅ i ∈ o, (s i).einfsep := by cases o <;> simp
theorem einfsep_anti (hst : s ⊆ t) : t.einfsep ≤ s.einfsep :=
le_einfsep fun _x hx _y hy => einfsep_le_edist_of_mem (hst hx) (hst hy)
theorem einfsep_insert_le : (insert x s).einfsep ≤ ⨅ (y ∈ s) (_ : x ≠ y), edist x y := by
simp_rw [le_iInf_iff]
exact fun _ hy hxy => einfsep_le_edist_of_mem (mem_insert _ _) (mem_insert_of_mem _ hy) hxy
theorem le_einfsep_pair : edist x y ⊓ edist y x ≤ ({x, y} : Set α).einfsep := by
simp_rw [le_einfsep_iff, inf_le_iff, mem_insert_iff, mem_singleton_iff]
rintro a (rfl | rfl) b (rfl | rfl) hab <;> (try simp only [le_refl, true_or, or_true]) <;>
contradiction
theorem einfsep_pair_le_left (hxy : x ≠ y) : ({x, y} : Set α).einfsep ≤ edist x y :=
einfsep_le_edist_of_mem (mem_insert _ _) (mem_insert_of_mem _ (mem_singleton _)) hxy
theorem einfsep_pair_le_right (hxy : x ≠ y) : ({x, y} : Set α).einfsep ≤ edist y x := by
rw [pair_comm]; exact einfsep_pair_le_left hxy.symm
theorem einfsep_pair_eq_inf (hxy : x ≠ y) : ({x, y} : Set α).einfsep = edist x y ⊓ edist y x :=
le_antisymm (le_inf (einfsep_pair_le_left hxy) (einfsep_pair_le_right hxy)) le_einfsep_pair
theorem einfsep_eq_iInf : s.einfsep = ⨅ d : s.offDiag, (uncurry edist) (d : α × α) := by
refine eq_of_forall_le_iff fun _ => ?_
simp_rw [le_einfsep_iff, le_iInf_iff, imp_forall_iff, SetCoe.forall, mem_offDiag,
Prod.forall, uncurry_apply_pair, and_imp]
theorem einfsep_of_fintype [DecidableEq α] [Fintype s] :
s.einfsep = s.offDiag.toFinset.inf (uncurry edist) := by
refine eq_of_forall_le_iff fun _ => ?_
simp_rw [le_einfsep_iff, imp_forall_iff, Finset.le_inf_iff, mem_toFinset, mem_offDiag,
Prod.forall, uncurry_apply_pair, and_imp]
theorem Finite.einfsep (hs : s.Finite) : s.einfsep = hs.offDiag.toFinset.inf (uncurry edist) := by
refine eq_of_forall_le_iff fun _ => ?_
simp_rw [le_einfsep_iff, imp_forall_iff, Finset.le_inf_iff, Finite.mem_toFinset, mem_offDiag,
Prod.forall, uncurry_apply_pair, and_imp]
theorem Finset.coe_einfsep [DecidableEq α] {s : Finset α} :
(s : Set α).einfsep = s.offDiag.inf (uncurry edist) := by
simp_rw [einfsep_of_fintype, ← Finset.coe_offDiag, Finset.toFinset_coe]
theorem Nontrivial.einfsep_exists_of_finite [Finite s] (hs : s.Nontrivial) :
∃ x ∈ s, ∃ y ∈ s, x ≠ y ∧ s.einfsep = edist x y := by
classical
cases nonempty_fintype s
simp_rw [einfsep_of_fintype]
rcases Finset.exists_mem_eq_inf s.offDiag.toFinset (by simpa) (uncurry edist) with ⟨w, hxy, hed⟩
simp_rw [mem_toFinset] at hxy
exact ⟨w.fst, hxy.1, w.snd, hxy.2.1, hxy.2.2, hed⟩
theorem Finite.einfsep_exists_of_nontrivial (hsf : s.Finite) (hs : s.Nontrivial) :
∃ x ∈ s, ∃ y ∈ s, x ≠ y ∧ s.einfsep = edist x y :=
letI := hsf.fintype
hs.einfsep_exists_of_finite
end EDist
section PseudoEMetricSpace
variable [PseudoEMetricSpace α] {x y z : α} {s : Set α}
| theorem einfsep_pair (hxy : x ≠ y) : ({x, y} : Set α).einfsep = edist x y := by
nth_rw 1 [← min_self (edist x y)]
convert einfsep_pair_eq_inf hxy using 2
rw [edist_comm]
| Mathlib/Topology/MetricSpace/Infsep.lean | 176 | 179 |
/-
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.Tuple.Basic
/-!
# Lists from functions
Theorems and lemmas for dealing with `List.ofFn`, which converts a function on `Fin n` to a list
of length `n`.
## Main Statements
The main statements pertain to lists generated using `List.ofFn`
- `List.get?_ofFn`, which tells us the nth element of such a list
- `List.equivSigmaTuple`, which is an `Equiv` between lists and the functions that generate them
via `List.ofFn`.
-/
assert_not_exists Monoid
universe u
variable {α : Type u}
open Nat
namespace List
theorem get_ofFn {n} (f : Fin n → α) (i) : get (ofFn f) i = f (Fin.cast (by simp) i) := by
simp; congr
@[deprecated (since := "2025-02-15")] alias get?_ofFn := List.getElem?_ofFn
@[simp]
theorem map_ofFn {β : Type*} {n : ℕ} (f : Fin n → α) (g : α → β) :
map g (ofFn f) = ofFn (g ∘ f) :=
ext_get (by simp) fun i h h' => by simp
@[congr]
theorem ofFn_congr {m n : ℕ} (h : m = n) (f : Fin m → α) :
ofFn f = ofFn fun i : Fin n => f (Fin.cast h.symm i) := by
subst h
simp_rw [Fin.cast_refl, id]
theorem ofFn_succ' {n} (f : Fin (succ n) → α) :
ofFn f = (ofFn fun i => f (Fin.castSucc i)).concat (f (Fin.last _)) := by
induction' n with n IH
· rw [ofFn_zero, concat_nil, ofFn_succ, ofFn_zero]
rfl
· rw [ofFn_succ, IH, ofFn_succ, concat_cons, Fin.castSucc_zero]
congr
/-- Note this matches the convention of `List.ofFn_succ'`, putting the `Fin m` elements first. -/
theorem ofFn_add {m n} (f : Fin (m + n) → α) :
List.ofFn f =
(List.ofFn fun i => f (Fin.castAdd n i)) ++ List.ofFn fun j => f (Fin.natAdd m j) := by
induction' n with n IH
· rw [ofFn_zero, append_nil, Fin.castAdd_zero, Fin.cast_refl]
rfl
· rw [ofFn_succ', ofFn_succ', IH, append_concat]
rfl
@[simp]
theorem ofFn_fin_append {m n} (a : Fin m → α) (b : Fin n → α) :
List.ofFn (Fin.append a b) = List.ofFn a ++ List.ofFn b := by
simp_rw [ofFn_add, Fin.append_left, Fin.append_right]
/-- This breaks a list of `m*n` items into `m` groups each containing `n` elements. -/
theorem ofFn_mul {m n} (f : Fin (m * n) → α) :
List.ofFn f = List.flatten (List.ofFn fun i : Fin m => List.ofFn fun j : Fin n => f ⟨i * n + j,
calc
↑i * n + j < (i + 1) * n :=
(Nat.add_lt_add_left j.prop _).trans_eq (by rw [Nat.add_mul, Nat.one_mul])
_ ≤ _ := Nat.mul_le_mul_right _ i.prop⟩) := by
induction' m with m IH
· simp [ofFn_zero, Nat.zero_mul, ofFn_zero, flatten]
· simp_rw [ofFn_succ', succ_mul]
simp [flatten_concat, ofFn_add, IH]
rfl
/-- This breaks a list of `m*n` items into `n` groups each containing `m` elements. -/
theorem ofFn_mul' {m n} (f : Fin (m * n) → α) :
List.ofFn f = List.flatten (List.ofFn fun i : Fin n => List.ofFn fun j : Fin m => f ⟨m * i + j,
calc
m * i + j < m * (i + 1) :=
(Nat.add_lt_add_left j.prop _).trans_eq (by rw [Nat.mul_add, Nat.mul_one])
_ ≤ _ := Nat.mul_le_mul_left _ i.prop⟩) := by simp_rw [m.mul_comm, ofFn_mul, Fin.cast_mk]
@[simp]
theorem ofFn_get : ∀ l : List α, (ofFn (get l)) = l
| [] => by rw [ofFn_zero]
| a :: l => by
rw [ofFn_succ]
congr
exact ofFn_get l
@[simp]
theorem ofFn_getElem : ∀ l : List α, (ofFn (fun i : Fin l.length => l[(i : Nat)])) = l
| [] => by rw [ofFn_zero]
| a :: l => by
rw [ofFn_succ]
congr
exact ofFn_get l
@[simp]
theorem ofFn_getElem_eq_map {β : Type*} (l : List α) (f : α → β) :
ofFn (fun i : Fin l.length => f <| l[(i : Nat)]) = l.map f := by
rw [← Function.comp_def, ← map_ofFn, ofFn_getElem]
-- Note there is a now another `mem_ofFn` defined in Lean, with an existential on the RHS,
-- which is marked as a simp lemma.
theorem mem_ofFn' {n} (f : Fin n → α) (a : α) : a ∈ ofFn f ↔ a ∈ Set.range f := by
simp only [mem_iff_get, Set.mem_range, get_ofFn]
exact ⟨fun ⟨i, hi⟩ => ⟨Fin.cast (by simp) i, hi⟩, fun ⟨i, hi⟩ => ⟨Fin.cast (by simp) i, hi⟩⟩
theorem forall_mem_ofFn_iff {n : ℕ} {f : Fin n → α} {P : α → Prop} :
(∀ i ∈ ofFn f, P i) ↔ ∀ j : Fin n, P (f j) := by simp
@[simp]
theorem ofFn_const : ∀ (n : ℕ) (c : α), (ofFn fun _ : Fin n => c) = replicate n c
| 0, c => by rw [ofFn_zero, replicate_zero]
| n+1, c => by rw [replicate, ← ofFn_const n]; simp
@[simp]
theorem ofFn_fin_repeat {m} (a : Fin m → α) (n : ℕ) :
List.ofFn (Fin.repeat n a) = (List.replicate n (List.ofFn a)).flatten := by
simp_rw [ofFn_mul, ← ofFn_const, Fin.repeat, Fin.modNat, Nat.add_comm,
Nat.add_mul_mod_self_right, Nat.mod_eq_of_lt (Fin.is_lt _)]
@[simp]
theorem pairwise_ofFn {R : α → α → Prop} {n} {f : Fin n → α} :
(ofFn f).Pairwise R ↔ ∀ ⦃i j⦄, i < j → R (f i) (f j) := by
simp only [pairwise_iff_getElem, length_ofFn, List.getElem_ofFn,
(Fin.rightInverse_cast length_ofFn).surjective.forall, Fin.forall_iff, Fin.cast_mk,
Fin.mk_lt_mk, forall_comm (α := (_ : Prop)) (β := ℕ)]
lemma getLast_ofFn_succ {n : ℕ} (f : Fin n.succ → α) :
(ofFn f).getLast (mt ofFn_eq_nil_iff.1 (Nat.succ_ne_zero _)) = f (Fin.last _) :=
getLast_ofFn _
@[deprecated getLast_ofFn (since := "2024-11-06")]
theorem last_ofFn {n : ℕ} (f : Fin n → α) (h : ofFn f ≠ [])
(hn : n - 1 < n := Nat.pred_lt <| ofFn_eq_nil_iff.not.mp h) :
getLast (ofFn f) h = f ⟨n - 1, hn⟩ := by simp [getLast_eq_getElem]
@[deprecated getLast_ofFn_succ (since := "2024-11-06")]
theorem last_ofFn_succ {n : ℕ} (f : Fin n.succ → α)
(h : ofFn f ≠ [] := mt ofFn_eq_nil_iff.mp (Nat.succ_ne_zero _)) :
getLast (ofFn f) h = f (Fin.last _) :=
getLast_ofFn_succ _
lemma ofFn_cons {n} (a : α) (f : Fin n → α) : ofFn (Fin.cons a f) = a :: ofFn f := by
rw [ofFn_succ]
rfl
lemma find?_ofFn_eq_some {n} {f : Fin n → α} {p : α → Bool} {b : α} :
(ofFn f).find? p = some b ↔ p b = true ∧ ∃ i, f i = b ∧ ∀ j < i, ¬(p (f j) = true) := by
rw [find?_eq_some_iff_getElem]
exact ⟨fun ⟨hpb, i, hi, hfb, h⟩ ↦
⟨hpb, ⟨⟨i, length_ofFn (f := f) ▸ hi⟩, by simpa using hfb, fun j hj ↦ by simpa using h j hj⟩⟩,
fun ⟨hpb, i, hfb, h⟩ ↦
⟨hpb, ⟨i, (length_ofFn (f := f)).symm ▸ i.isLt, by simpa using hfb,
fun j hj ↦ by simpa using h ⟨j, by omega⟩ (by simpa using hj)⟩⟩⟩
lemma find?_ofFn_eq_some_of_injective {n} {f : Fin n → α} {p : α → Bool} {i : Fin n}
(h : Function.Injective f) :
(ofFn f).find? p = some (f i) ↔ p (f i) = true ∧ ∀ j < i, ¬(p (f j) = true) := by
simp only [find?_ofFn_eq_some, h.eq_iff, Bool.not_eq_true, exists_eq_left]
/-- Lists are equivalent to the sigma type of tuples of a given length. -/
@[simps]
def equivSigmaTuple : List α ≃ Σn, Fin n → α where
toFun l := ⟨l.length, l.get⟩
invFun f := List.ofFn f.2
left_inv := List.ofFn_get
right_inv := fun ⟨_, f⟩ =>
Fin.sigma_eq_of_eq_comp_cast length_ofFn <| funext fun i => get_ofFn f i
/-- A recursor for lists that expands a list into a function mapping to its elements.
This can be used with `induction l using List.ofFnRec`. -/
@[elab_as_elim]
def ofFnRec {C : List α → Sort*} (h : ∀ (n) (f : Fin n → α), C (List.ofFn f)) (l : List α) : C l :=
cast (congr_arg C l.ofFn_get) <|
h l.length l.get
@[simp]
theorem ofFnRec_ofFn {C : List α → Sort*} (h : ∀ (n) (f : Fin n → α), C (List.ofFn f)) {n : ℕ}
(f : Fin n → α) : @ofFnRec _ C h (List.ofFn f) = h _ f :=
equivSigmaTuple.rightInverse_symm.cast_eq (fun s => h s.1 s.2) ⟨n, f⟩
theorem exists_iff_exists_tuple {P : List α → Prop} :
(∃ l : List α, P l) ↔ ∃ (n : _) (f : Fin n → α), P (List.ofFn f) :=
equivSigmaTuple.symm.surjective.exists.trans Sigma.exists
theorem forall_iff_forall_tuple {P : List α → Prop} :
(∀ l : List α, P l) ↔ ∀ (n) (f : Fin n → α), P (List.ofFn f) :=
equivSigmaTuple.symm.surjective.forall.trans Sigma.forall
/-- `Fin.sigma_eq_iff_eq_comp_cast` may be useful to work with the RHS of this expression. -/
theorem ofFn_inj' {m n : ℕ} {f : Fin m → α} {g : Fin n → α} :
ofFn f = ofFn g ↔ (⟨m, f⟩ : Σn, Fin n → α) = ⟨n, g⟩ :=
Iff.symm <| equivSigmaTuple.symm.injective.eq_iff.symm
/-- Note we can only state this when the two functions are indexed by defeq `n`. -/
theorem ofFn_injective {n : ℕ} : Function.Injective (ofFn : (Fin n → α) → List α) := fun f g h =>
eq_of_heq <| by rw [ofFn_inj'] at h; cases h; rfl
/-- A special case of `List.ofFn_inj` for when the two functions are indexed by defeq `n`. -/
@[simp]
theorem ofFn_inj {n : ℕ} {f g : Fin n → α} : ofFn f = ofFn g ↔ f = g :=
ofFn_injective.eq_iff
end List
| Mathlib/Data/List/OfFn.lean | 257 | 260 | |
/-
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.
-/
| Mathlib/Data/PNat/Xgcd.lean | 217 | 219 |
/-
Copyright (c) 2024 Oliver Nash. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Oliver Nash
-/
import Mathlib.Algebra.Lie.Derivation.Killing
import Mathlib.Algebra.Lie.Killing
import Mathlib.Algebra.Lie.Sl2
import Mathlib.Algebra.Lie.Weights.Chain
import Mathlib.LinearAlgebra.Eigenspace.Semisimple
import Mathlib.LinearAlgebra.JordanChevalley
/-!
# Roots of Lie algebras with non-degenerate Killing forms
The file contains definitions and results about roots of Lie algebras with non-degenerate Killing
forms.
## Main definitions
* `LieAlgebra.IsKilling.ker_restrict_eq_bot_of_isCartanSubalgebra`: if the Killing form of
a Lie algebra is non-singular, it remains non-singular when restricted to a Cartan subalgebra.
* `LieAlgebra.IsKilling.instIsLieAbelianOfIsCartanSubalgebra`: if the Killing form of a Lie
algebra is non-singular, then its Cartan subalgebras are Abelian.
* `LieAlgebra.IsKilling.isSemisimple_ad_of_mem_isCartanSubalgebra`: over a perfect field, if a Lie
algebra has non-degenerate Killing form, Cartan subalgebras contain only semisimple elements.
* `LieAlgebra.IsKilling.span_weight_eq_top`: given a splitting Cartan subalgebra `H` of a
finite-dimensional Lie algebra with non-singular Killing form, the corresponding roots span the
dual space of `H`.
* `LieAlgebra.IsKilling.coroot`: the coroot corresponding to a root.
* `LieAlgebra.IsKilling.isCompl_ker_weight_span_coroot`: given a root `α` with respect to a Cartan
subalgebra `H`, we have a natural decomposition of `H` as the kernel of `α` and the span of the
coroot corresponding to `α`.
* `LieAlgebra.IsKilling.finrank_rootSpace_eq_one`: root spaces are one-dimensional.
-/
variable (R K L : Type*) [CommRing R] [LieRing L] [LieAlgebra R L] [Field K] [LieAlgebra K L]
namespace LieAlgebra
lemma restrict_killingForm (H : LieSubalgebra R L) :
(killingForm R L).restrict H = LieModule.traceForm R H L :=
rfl
namespace IsKilling
variable [IsKilling R L]
/-- If the Killing form of a Lie algebra is non-singular, it remains non-singular when restricted
to a Cartan subalgebra. -/
lemma ker_restrict_eq_bot_of_isCartanSubalgebra
[IsNoetherian R L] [IsArtinian R L] (H : LieSubalgebra R L) [H.IsCartanSubalgebra] :
LinearMap.ker ((killingForm R L).restrict H) = ⊥ := by
have h : Codisjoint (rootSpace H 0) (LieModule.posFittingComp R H L) :=
(LieModule.isCompl_genWeightSpace_zero_posFittingComp R H L).codisjoint
replace h : Codisjoint (H : Submodule R L) (LieModule.posFittingComp R H L : Submodule R L) := by
rwa [codisjoint_iff, ← LieSubmodule.toSubmodule_inj, LieSubmodule.sup_toSubmodule,
LieSubmodule.top_toSubmodule, rootSpace_zero_eq R L H, LieSubalgebra.coe_toLieSubmodule,
← codisjoint_iff] at h
suffices this : ∀ m₀ ∈ H, ∀ m₁ ∈ LieModule.posFittingComp R H L, killingForm R L m₀ m₁ = 0 by
simp [LinearMap.BilinForm.ker_restrict_eq_of_codisjoint h this]
intro m₀ h₀ m₁ h₁
exact killingForm_eq_zero_of_mem_zeroRoot_mem_posFitting R L H (le_zeroRootSubalgebra R L H h₀) h₁
@[simp] lemma ker_traceForm_eq_bot_of_isCartanSubalgebra
[IsNoetherian R L] [IsArtinian R L] (H : LieSubalgebra R L) [H.IsCartanSubalgebra] :
LinearMap.ker (LieModule.traceForm R H L) = ⊥ :=
ker_restrict_eq_bot_of_isCartanSubalgebra R L H
lemma traceForm_cartan_nondegenerate
[IsNoetherian R L] [IsArtinian R L] (H : LieSubalgebra R L) [H.IsCartanSubalgebra] :
(LieModule.traceForm R H L).Nondegenerate := by
simp [LinearMap.BilinForm.nondegenerate_iff_ker_eq_bot]
variable [Module.Free R L] [Module.Finite R L]
instance instIsLieAbelianOfIsCartanSubalgebra
[IsDomain R] [IsPrincipalIdealRing R] [IsArtinian R L]
(H : LieSubalgebra R L) [H.IsCartanSubalgebra] :
IsLieAbelian H :=
LieModule.isLieAbelian_of_ker_traceForm_eq_bot R H L <|
ker_restrict_eq_bot_of_isCartanSubalgebra R L H
end IsKilling
section Field
open Module LieModule Set
open Submodule (span subset_span)
variable [FiniteDimensional K L] (H : LieSubalgebra K L) [H.IsCartanSubalgebra]
section
variable [IsTriangularizable K H L]
/-- For any `α` and `β`, the corresponding root spaces are orthogonal with respect to the Killing
form, provided `α + β ≠ 0`. -/
lemma killingForm_apply_eq_zero_of_mem_rootSpace_of_add_ne_zero {α β : H → K} {x y : L}
(hx : x ∈ rootSpace H α) (hy : y ∈ rootSpace H β) (hαβ : α + β ≠ 0) :
killingForm K L x y = 0 := by
/- If `ad R L z` is semisimple for all `z ∈ H` then writing `⟪x, y⟫ = killingForm K L x y`, there
is a slick proof of this lemma that requires only invariance of the Killing form as follows.
For any `z ∈ H`, we have:
`α z • ⟪x, y⟫ = ⟪α z • x, y⟫ = ⟪⁅z, x⁆, y⟫ = - ⟪x, ⁅z, y⁆⟫ = - ⟪x, β z • y⟫ = - β z • ⟪x, y⟫`.
Since this is true for any `z`, we thus have: `(α + β) • ⟪x, y⟫ = 0`, and hence the result.
However the semisimplicity of `ad R L z` is (a) non-trivial and (b) requires the assumption
that `K` is a perfect field and `L` has non-degenerate Killing form. -/
let σ : (H → K) → (H → K) := fun γ ↦ α + (β + γ)
have hσ : ∀ γ, σ γ ≠ γ := fun γ ↦ by simpa only [σ, ← add_assoc] using add_ne_right.mpr hαβ
let f : Module.End K L := (ad K L x) ∘ₗ (ad K L y)
have hf : ∀ γ, MapsTo f (rootSpace H γ) (rootSpace H (σ γ)) := fun γ ↦
(mapsTo_toEnd_genWeightSpace_add_of_mem_rootSpace K L H L α (β + γ) hx).comp <|
mapsTo_toEnd_genWeightSpace_add_of_mem_rootSpace K L H L β γ hy
classical
have hds := DirectSum.isInternal_submodule_of_iSupIndep_of_iSup_eq_top
(LieSubmodule.iSupIndep_toSubmodule.mpr <| iSupIndep_genWeightSpace K H L)
(LieSubmodule.iSup_toSubmodule_eq_top.mpr <| iSup_genWeightSpace_eq_top K H L)
exact LinearMap.trace_eq_zero_of_mapsTo_ne hds σ hσ hf
/-- Elements of the `α` root space which are Killing-orthogonal to the `-α` root space are
Killing-orthogonal to all of `L`. -/
lemma mem_ker_killingForm_of_mem_rootSpace_of_forall_rootSpace_neg
{α : H → K} {x : L} (hx : x ∈ rootSpace H α)
(hx' : ∀ y ∈ rootSpace H (-α), killingForm K L x y = 0) :
x ∈ LinearMap.ker (killingForm K L) := by
rw [LinearMap.mem_ker]
ext y
have hy : y ∈ ⨆ β, rootSpace H β := by simp [iSup_genWeightSpace_eq_top K H L]
induction hy using LieSubmodule.iSup_induction' with
| mem β y hy =>
by_cases hαβ : α + β = 0
· exact hx' _ (add_eq_zero_iff_neg_eq.mp hαβ ▸ hy)
· exact killingForm_apply_eq_zero_of_mem_rootSpace_of_add_ne_zero K L H hx hy hαβ
| zero => simp
| add => simp_all
end
namespace IsKilling
variable [IsKilling K L]
/-- If a Lie algebra `L` has non-degenerate Killing form, the only element of a Cartan subalgebra
whose adjoint action on `L` is nilpotent, is the zero element.
Over a perfect field a much stronger result is true, see
`LieAlgebra.IsKilling.isSemisimple_ad_of_mem_isCartanSubalgebra`. -/
lemma eq_zero_of_isNilpotent_ad_of_mem_isCartanSubalgebra {x : L} (hx : x ∈ H)
(hx' : _root_.IsNilpotent (ad K L x)) : x = 0 := by
suffices ⟨x, hx⟩ ∈ LinearMap.ker (traceForm K H L) by
simp at this
exact (AddSubmonoid.mk_eq_zero H.toAddSubmonoid).mp this
simp only [LinearMap.mem_ker]
ext y
have comm : Commute (toEnd K H L ⟨x, hx⟩) (toEnd K H L y) := by
rw [commute_iff_lie_eq, ← LieHom.map_lie, trivial_lie_zero, LieHom.map_zero]
rw [traceForm_apply_apply, ← Module.End.mul_eq_comp, LinearMap.zero_apply]
exact (LinearMap.isNilpotent_trace_of_isNilpotent (comm.isNilpotent_mul_left hx')).eq_zero
@[simp]
lemma corootSpace_zero_eq_bot :
corootSpace (0 : H → K) = ⊥ := by
refine eq_bot_iff.mpr fun x hx ↦ ?_
suffices {x | ∃ y ∈ H, ∃ z ∈ H, ⁅y, z⁆ = x} = {0} by simpa [mem_corootSpace, this] using hx
refine eq_singleton_iff_unique_mem.mpr ⟨⟨0, H.zero_mem, 0, H.zero_mem, zero_lie 0⟩, ?_⟩
rintro - ⟨y, hy, z, hz, rfl⟩
suffices ⁅(⟨y, hy⟩ : H), (⟨z, hz⟩ : H)⁆ = 0 by
simpa only [Subtype.ext_iff, LieSubalgebra.coe_bracket, ZeroMemClass.coe_zero] using this
simp
variable {K L} in
/-- The restriction of the Killing form to a Cartan subalgebra, as a linear equivalence to the
dual. -/
@[simps! apply_apply]
noncomputable def cartanEquivDual :
H ≃ₗ[K] Module.Dual K H :=
(traceForm K H L).toDual <| traceForm_cartan_nondegenerate K L H
variable {K L H}
/-- The coroot corresponding to a root. -/
noncomputable def coroot (α : Weight K H L) : H :=
2 • (α <| (cartanEquivDual H).symm α)⁻¹ • (cartanEquivDual H).symm α
lemma traceForm_coroot (α : Weight K H L) (x : H) :
traceForm K H L (coroot α) x = 2 • (α <| (cartanEquivDual H).symm α)⁻¹ • α x := by
have : cartanEquivDual H ((cartanEquivDual H).symm α) x = α x := by
rw [LinearEquiv.apply_symm_apply, Weight.toLinear_apply]
rw [coroot, map_nsmul, map_smul, LinearMap.smul_apply, LinearMap.smul_apply]
congr 2
variable [IsTriangularizable K H L]
lemma lie_eq_killingForm_smul_of_mem_rootSpace_of_mem_rootSpace_neg_aux
{α : Weight K H L} {e f : L} (heα : e ∈ rootSpace H α) (hfα : f ∈ rootSpace H (-α))
(aux : ∀ (h : H), ⁅h, e⁆ = α h • e) :
⁅e, f⁆ = killingForm K L e f • (cartanEquivDual H).symm α := by
set α' := (cartanEquivDual H).symm α
rw [← sub_eq_zero, ← Submodule.mem_bot (R := K), ← ker_killingForm_eq_bot]
apply mem_ker_killingForm_of_mem_rootSpace_of_forall_rootSpace_neg (α := (0 : H → K))
· simp only [rootSpace_zero_eq, LieSubalgebra.mem_toLieSubmodule]
refine sub_mem ?_ (H.smul_mem _ α'.property)
simpa using mapsTo_toEnd_genWeightSpace_add_of_mem_rootSpace K L H L α (-α) heα hfα
· intro z hz
replace hz : z ∈ H := by simpa using hz
have he : ⁅z, e⁆ = α ⟨z, hz⟩ • e := aux ⟨z, hz⟩
have hαz : killingForm K L α' (⟨z, hz⟩ : H) = α ⟨z, hz⟩ :=
LinearMap.BilinForm.apply_toDual_symm_apply (hB := traceForm_cartan_nondegenerate K L H) _ _
simp [traceForm_comm K L L ⁅e, f⁆, ← traceForm_apply_lie_apply, he, mul_comm _ (α ⟨z, hz⟩), hαz]
/-- This is Proposition 4.18 from [carter2005] except that we use
`LieModule.exists_forall_lie_eq_smul` instead of Lie's theorem (and so avoid
assuming `K` has characteristic zero). -/
lemma cartanEquivDual_symm_apply_mem_corootSpace (α : Weight K H L) :
(cartanEquivDual H).symm α ∈ corootSpace α := by
obtain ⟨e : L, he₀ : e ≠ 0, he : ∀ x, ⁅x, e⁆ = α x • e⟩ := exists_forall_lie_eq_smul K H L α
have heα : e ∈ rootSpace H α := (mem_genWeightSpace L α e).mpr fun x ↦ ⟨1, by simp [← he x]⟩
obtain ⟨f, hfα, hf⟩ : ∃ f ∈ rootSpace H (-α), killingForm K L e f ≠ 0 := by
contrapose! he₀
simpa using mem_ker_killingForm_of_mem_rootSpace_of_forall_rootSpace_neg K L H heα he₀
suffices ⁅e, f⁆ = killingForm K L e f • ((cartanEquivDual H).symm α : L) from
(mem_corootSpace α).mpr <| Submodule.subset_span ⟨(killingForm K L e f)⁻¹ • e,
Submodule.smul_mem _ _ heα, f, hfα, by simpa [inv_smul_eq_iff₀ hf]⟩
exact lie_eq_killingForm_smul_of_mem_rootSpace_of_mem_rootSpace_neg_aux heα hfα he
/-- Given a splitting Cartan subalgebra `H` of a finite-dimensional Lie algebra with non-singular
Killing form, the corresponding roots span the dual space of `H`. -/
@[simp]
lemma span_weight_eq_top :
span K (range (Weight.toLinear K H L)) = ⊤ := by
refine eq_top_iff.mpr (le_trans ?_ (LieModule.range_traceForm_le_span_weight K H L))
rw [← traceForm_flip K H L, ← LinearMap.dualAnnihilator_ker_eq_range_flip,
ker_traceForm_eq_bot_of_isCartanSubalgebra, Submodule.dualAnnihilator_bot]
variable (K L H) in
@[simp]
lemma span_weight_isNonZero_eq_top :
span K ({α : Weight K H L | α.IsNonZero}.image (Weight.toLinear K H L)) = ⊤ := by
rw [← span_weight_eq_top]
refine le_antisymm (Submodule.span_mono <| by simp) ?_
suffices range (Weight.toLinear K H L) ⊆
insert 0 ({α : Weight K H L | α.IsNonZero}.image (Weight.toLinear K H L)) by
simpa only [Submodule.span_insert_zero] using Submodule.span_mono this
rintro - ⟨α, rfl⟩
simp only [mem_insert_iff, Weight.coe_toLinear_eq_zero_iff, mem_image, mem_setOf_eq]
tauto
@[simp]
lemma iInf_ker_weight_eq_bot :
⨅ α : Weight K H L, α.ker = ⊥ := by
rw [← Subspace.dualAnnihilator_inj, Subspace.dualAnnihilator_iInf_eq,
Submodule.dualAnnihilator_bot]
simp [← LinearMap.range_dualMap_eq_dualAnnihilator_ker, ← Submodule.span_range_eq_iSup]
section PerfectField
variable [PerfectField K]
open Module.End in
lemma isSemisimple_ad_of_mem_isCartanSubalgebra {x : L} (hx : x ∈ H) :
(ad K L x).IsSemisimple := by
/- Using Jordan-Chevalley, write `ad K L x` as a sum of its semisimple and nilpotent parts. -/
obtain ⟨N, -, S, hS₀, hN, hS, hSN⟩ := (ad K L x).exists_isNilpotent_isSemisimple
replace hS₀ : Commute (ad K L x) S := Algebra.commute_of_mem_adjoin_self hS₀
set x' : H := ⟨x, hx⟩
rw [eq_sub_of_add_eq hSN.symm] at hN
/- Note that the semisimple part `S` is just a scalar action on each root space. -/
have aux {α : H → K} {y : L} (hy : y ∈ rootSpace H α) : S y = α x' • y := by
replace hy : y ∈ (ad K L x).maxGenEigenspace (α x') :=
(genWeightSpace_le_genWeightSpaceOf L x' α) hy
rw [maxGenEigenspace_eq] at hy
set k := maxGenEigenspaceIndex (ad K L x) (α x')
rw [apply_eq_of_mem_of_comm_of_isFinitelySemisimple_of_isNil hy hS₀ hS.isFinitelySemisimple hN]
/- So `S` obeys the derivation axiom if we restrict to root spaces. -/
have h_der (y z : L) (α β : H → K) (hy : y ∈ rootSpace H α) (hz : z ∈ rootSpace H β) :
S ⁅y, z⁆ = ⁅S y, z⁆ + ⁅y, S z⁆ := by
have hyz : ⁅y, z⁆ ∈ rootSpace H (α + β) :=
mapsTo_toEnd_genWeightSpace_add_of_mem_rootSpace K L H L α β hy hz
rw [aux hy, aux hz, aux hyz, smul_lie, lie_smul, ← add_smul, ← Pi.add_apply]
/- Thus `S` is a derivation since root spaces span. -/
replace h_der (y z : L) : S ⁅y, z⁆ = ⁅S y, z⁆ + ⁅y, S z⁆ := by
have hy : y ∈ ⨆ α : H → K, rootSpace H α := by simp [iSup_genWeightSpace_eq_top]
have hz : z ∈ ⨆ α : H → K, rootSpace H α := by simp [iSup_genWeightSpace_eq_top]
induction hy using LieSubmodule.iSup_induction' with
| mem α y hy =>
induction hz using LieSubmodule.iSup_induction' with
| mem β z hz => exact h_der y z α β hy hz
| zero => simp
| add _ _ _ _ h h' => simp only [lie_add, map_add, h, h']; abel
| zero => simp
| add _ _ _ _ h h' => simp only [add_lie, map_add, h, h']; abel
/- An equivalent form of the derivation axiom used in `LieDerivation`. -/
replace h_der : ∀ y z : L, S ⁅y, z⁆ = ⁅y, S z⁆ - ⁅z, S y⁆ := by
simp_rw [← lie_skew (S _) _, add_comm, ← sub_eq_add_neg] at h_der; assumption
/- Bundle `S` as a `LieDerivation`. -/
let S' : LieDerivation K L L := ⟨S, h_der⟩
/- Since `L` has non-degenerate Killing form, `S` must be inner, corresponding to some `y : L`. -/
obtain ⟨y, hy⟩ := LieDerivation.IsKilling.exists_eq_ad S'
/- `y` commutes with all elements of `H` because `S` has eigenvalue 0 on `H`, `S = ad K L y`. -/
have hy' (z : L) (hz : z ∈ H) : ⁅y, z⁆ = 0 := by
rw [← LieSubalgebra.mem_toLieSubmodule, ← rootSpace_zero_eq] at hz
simp [S', ← ad_apply (R := K), ← LieDerivation.coe_ad_apply_eq_ad_apply, hy, aux hz]
/- Thus `y` belongs to `H` since `H` is self-normalizing. -/
replace hy' : y ∈ H := by
suffices y ∈ H.normalizer by rwa [LieSubalgebra.IsCartanSubalgebra.self_normalizing] at this
exact (H.mem_normalizer_iff y).mpr fun z hz ↦ hy' z hz ▸ LieSubalgebra.zero_mem H
/- It suffices to show `x = y` since `S = ad K L y` is semisimple. -/
suffices x = y by rwa [this, ← LieDerivation.coe_ad_apply_eq_ad_apply y, hy]
rw [← sub_eq_zero]
/- This will follow if we can show that `ad K L (x - y)` is nilpotent. -/
apply eq_zero_of_isNilpotent_ad_of_mem_isCartanSubalgebra K L H (H.sub_mem hx hy')
/- Which is true because `ad K L (x - y) = N`. -/
replace hy : S = ad K L y := by rw [← LieDerivation.coe_ad_apply_eq_ad_apply y, hy]
rwa [LieHom.map_sub, hSN, hy, add_sub_cancel_right, eq_sub_of_add_eq hSN.symm]
lemma lie_eq_smul_of_mem_rootSpace {α : H → K} {x : L} (hx : x ∈ rootSpace H α) (h : H) :
⁅h, x⁆ = α h • x := by
replace hx : x ∈ (ad K L h).maxGenEigenspace (α h) :=
genWeightSpace_le_genWeightSpaceOf L h α hx
rw [(isSemisimple_ad_of_mem_isCartanSubalgebra
h.property).isFinitelySemisimple.maxGenEigenspace_eq_eigenspace,
Module.End.mem_eigenspace_iff] at hx
simpa using hx
lemma lie_eq_killingForm_smul_of_mem_rootSpace_of_mem_rootSpace_neg
{α : Weight K H L} {e f : L} (heα : e ∈ rootSpace H α) (hfα : f ∈ rootSpace H (-α)) :
⁅e, f⁆ = killingForm K L e f • (cartanEquivDual H).symm α := by
apply lie_eq_killingForm_smul_of_mem_rootSpace_of_mem_rootSpace_neg_aux heα hfα
exact lie_eq_smul_of_mem_rootSpace heα
lemma coe_corootSpace_eq_span_singleton' (α : Weight K H L) :
(corootSpace α).toSubmodule = K ∙ (cartanEquivDual H).symm α := by
refine le_antisymm ?_ ?_
· intro ⟨x, hx⟩ hx'
have : {⁅y, z⁆ | (y ∈ rootSpace H α) (z ∈ rootSpace H (-α))} ⊆
K ∙ ((cartanEquivDual H).symm α : L) := by
rintro - ⟨e, heα, f, hfα, rfl⟩
rw [lie_eq_killingForm_smul_of_mem_rootSpace_of_mem_rootSpace_neg heα hfα, SetLike.mem_coe,
Submodule.mem_span_singleton]
exact ⟨killingForm K L e f, rfl⟩
simp only [LieSubmodule.mem_toSubmodule, mem_corootSpace] at hx'
replace this := Submodule.span_mono this hx'
rw [Submodule.span_span] at this
rw [Submodule.mem_span_singleton] at this ⊢
obtain ⟨t, rfl⟩ := this
use t
simp only [Subtype.ext_iff]
rw [Submodule.coe_smul_of_tower]
· simp only [Submodule.span_singleton_le_iff_mem, LieSubmodule.mem_toSubmodule]
exact cartanEquivDual_symm_apply_mem_corootSpace α
end PerfectField
section CharZero
variable [CharZero K]
/-- The contrapositive of this result is very useful, taking `x` to be the element of `H`
corresponding to a root `α` under the identification between `H` and `H^*` provided by the Killing
form. -/
lemma eq_zero_of_apply_eq_zero_of_mem_corootSpace
(x : H) (α : H → K) (hαx : α x = 0) (hx : x ∈ corootSpace α) :
x = 0 := by
rcases eq_or_ne α 0 with rfl | hα; · simpa using hx
replace hx : x ∈ ⨅ β : Weight K H L, β.ker := by
refine (Submodule.mem_iInf _).mpr fun β ↦ ?_
obtain ⟨a, b, hb, hab⟩ :=
exists_forall_mem_corootSpace_smul_add_eq_zero L α β hα β.genWeightSpace_ne_bot
simpa [hαx, hb.ne'] using hab _ hx
simpa using hx
lemma disjoint_ker_weight_corootSpace (α : Weight K H L) :
Disjoint α.ker (corootSpace α) := by
rw [disjoint_iff]
| refine (Submodule.eq_bot_iff _).mpr fun x ⟨hαx, hx⟩ ↦ ?_
replace hαx : α x = 0 := by simpa using hαx
exact eq_zero_of_apply_eq_zero_of_mem_corootSpace x α hαx hx
lemma root_apply_cartanEquivDual_symm_ne_zero {α : Weight K H L} (hα : α.IsNonZero) :
α ((cartanEquivDual H).symm α) ≠ 0 := by
| Mathlib/Algebra/Lie/Weights/Killing.lean | 374 | 379 |
/-
Copyright (c) 2023 Antoine Chambert-Loir. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Antoine Chambert-Loir
-/
import Mathlib.Algebra.Module.Submodule.Range
import Mathlib.LinearAlgebra.Prod
import Mathlib.LinearAlgebra.Quotient.Basic
/-! # Exactness of a pair
* For two maps `f : M → N` and `g : N → P`, with `Zero P`,
`Function.Exact f g` says that `Set.range f = Set.preimage g {0}`
* For additive maps `f : M →+ N` and `g : N →+ P`,
`Exact f g` says that `range f = ker g`
* For linear maps `f : M →ₗ[R] N` and `g : N →ₗ[R] P`,
`Exact f g` says that `range f = ker g`
## TODO :
* generalize to `SemilinearMap`, even `SemilinearMapClass`
* add the multiplicative case (`Function.Exact` will become `Function.AddExact`?)
-/
variable {R M M' N N' P P' : Type*}
namespace Function
variable (f : M → N) (g : N → P) (g' : P → P')
/-- The maps `f` and `g` form an exact pair :
`g y = 0` iff `y` belongs to the image of `f` -/
def Exact [Zero P] : Prop := ∀ y, g y = 0 ↔ y ∈ Set.range f
variable {f g}
namespace Exact
lemma apply_apply_eq_zero [Zero P] (h : Exact f g) (x : M) :
g (f x) = 0 := (h _).mpr <| Set.mem_range_self _
lemma comp_eq_zero [Zero P] (h : Exact f g) : g.comp f = 0 :=
funext h.apply_apply_eq_zero
lemma of_comp_of_mem_range [Zero P] (h1 : g ∘ f = 0)
(h2 : ∀ x, g x = 0 → x ∈ Set.range f) : Exact f g :=
fun y => Iff.intro (h2 y) <|
Exists.rec ((forall_apply_eq_imp_iff (p := (g · = 0))).mpr (congrFun h1) y)
lemma comp_injective [Zero P] [Zero P'] (exact : Exact f g)
(inj : Function.Injective g') (h0 : g' 0 = 0) :
Exact f (g' ∘ g) := by
intro x
refine ⟨fun H => exact x |>.mp <| inj <| h0 ▸ H, ?_⟩
intro H
rw [Function.comp_apply, exact x |>.mpr H, h0]
lemma of_comp_eq_zero_of_ker_in_range [Zero P] (hc : g.comp f = 0)
(hr : ∀ y, g y = 0 → y ∈ Set.range f) :
Exact f g :=
fun y ↦ ⟨hr y, fun ⟨x, hx⟩ ↦ hx ▸ congrFun hc x⟩
/-- Two maps `f : M → N` and `g : N → P` are exact if and only if the induced maps
`Set.range f → N → Set.range g` are exact.
Note that if you already have an instance `[Zero (Set.range g)]` (which is unlikely) this lemma
may not apply if the zero of `Set.range g` is not definitionally equal to `⟨0, hg⟩`. -/
lemma iff_rangeFactorization [Zero P] (hg : 0 ∈ Set.range g) :
letI : Zero (Set.range g) := ⟨⟨0, hg⟩⟩
Exact f g ↔ Exact ((↑) : Set.range f → N) (Set.rangeFactorization g) := by
rw [Exact, Exact, Subtype.range_coe]
congr! 2
rw [Set.rangeFactorization]
exact ⟨fun _ ↦ by rwa [Subtype.ext_iff], fun h ↦ by rwa [Subtype.ext_iff] at h⟩
/-- If two maps `f : M → N` and `g : N → P` are exact, then the induced maps
`Set.range f → N → Set.range g` are exact.
Note that if you already have an instance `[Zero (Set.range g)]` (which is unlikely) this lemma
may not apply if the zero of `Set.range g` is not definitionally equal to `⟨0, hg⟩`. -/
lemma rangeFactorization [Zero P] (h : Exact f g) (hg : 0 ∈ Set.range g) :
letI : Zero (Set.range g) := ⟨⟨0, hg⟩⟩
Exact ((↑) : Set.range f → N) (Set.rangeFactorization g) :=
(iff_rangeFactorization hg).1 h
end Exact
end Function
section AddMonoidHom
| variable [AddGroup M] [AddGroup N] [AddGroup P] {f : M →+ N} {g : N →+ P}
namespace AddMonoidHom
| Mathlib/Algebra/Exact.lean | 98 | 101 |
/-
Copyright (c) 2018 Kenny Lau. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kenny Lau, Mario Carneiro
-/
import Mathlib.Algebra.Module.Submodule.Bilinear
import Mathlib.Algebra.Module.Equiv.Basic
import Mathlib.GroupTheory.Congruence.Hom
import Mathlib.Tactic.Abel
import Mathlib.Tactic.SuppressCompilation
/-!
# Tensor product of modules over commutative semirings.
This file constructs the tensor product of modules over commutative semirings. Given a semiring `R`
and modules over it `M` and `N`, the standard construction of the tensor product is
`TensorProduct R M N`. It is also a module over `R`.
It comes with a canonical bilinear map
`TensorProduct.mk R M N : M →ₗ[R] N →ₗ[R] TensorProduct R M N`.
Given any bilinear map `f : M →ₗ[R] N →ₗ[R] P`, there is a unique linear map
`TensorProduct.lift f : TensorProduct R M N →ₗ[R] P` whose composition with the canonical bilinear
map `TensorProduct.mk` is the given bilinear map `f`. Uniqueness is shown in the theorem
`TensorProduct.lift.unique`.
## Notation
* This file introduces the notation `M ⊗ N` and `M ⊗[R] N` for the tensor product space
`TensorProduct R M N`.
* It introduces the notation `m ⊗ₜ n` and `m ⊗ₜ[R] n` for the tensor product of two elements,
otherwise written as `TensorProduct.tmul R m n`.
## Tags
bilinear, tensor, tensor product
-/
suppress_compilation
section Semiring
variable {R : Type*} [CommSemiring R]
variable {R' : Type*} [Monoid R']
variable {R'' : Type*} [Semiring R'']
variable {A M N P Q S T : Type*}
variable [AddCommMonoid M] [AddCommMonoid N] [AddCommMonoid P]
variable [AddCommMonoid Q] [AddCommMonoid S] [AddCommMonoid T]
variable [Module R M] [Module R N] [Module R Q] [Module R S] [Module R T]
variable [DistribMulAction R' M]
variable [Module R'' M]
variable (M N)
namespace TensorProduct
section
variable (R)
/-- The relation on `FreeAddMonoid (M × N)` that generates a congruence whose quotient is
the tensor product. -/
inductive Eqv : FreeAddMonoid (M × N) → FreeAddMonoid (M × N) → Prop
| of_zero_left : ∀ n : N, Eqv (.of (0, n)) 0
| of_zero_right : ∀ m : M, Eqv (.of (m, 0)) 0
| of_add_left : ∀ (m₁ m₂ : M) (n : N), Eqv (.of (m₁, n) + .of (m₂, n)) (.of (m₁ + m₂, n))
| of_add_right : ∀ (m : M) (n₁ n₂ : N), Eqv (.of (m, n₁) + .of (m, n₂)) (.of (m, n₁ + n₂))
| of_smul : ∀ (r : R) (m : M) (n : N), Eqv (.of (r • m, n)) (.of (m, r • n))
| add_comm : ∀ x y, Eqv (x + y) (y + x)
end
end TensorProduct
variable (R) in
/-- The tensor product of two modules `M` and `N` over the same commutative semiring `R`.
The localized notations are `M ⊗ N` and `M ⊗[R] N`, accessed by `open scoped TensorProduct`. -/
def TensorProduct : Type _ :=
(addConGen (TensorProduct.Eqv R M N)).Quotient
set_option quotPrecheck false in
@[inherit_doc TensorProduct] scoped[TensorProduct] infixl:100 " ⊗ " => TensorProduct _
@[inherit_doc] scoped[TensorProduct] notation:100 M " ⊗[" R "] " N:100 => TensorProduct R M N
namespace TensorProduct
section Module
protected instance zero : Zero (M ⊗[R] N) :=
(addConGen (TensorProduct.Eqv R M N)).zero
protected instance add : Add (M ⊗[R] N) :=
(addConGen (TensorProduct.Eqv R M N)).hasAdd
instance addZeroClass : AddZeroClass (M ⊗[R] N) :=
{ (addConGen (TensorProduct.Eqv R M N)).addMonoid with
/- The `toAdd` field is given explicitly as `TensorProduct.add` for performance reasons.
This avoids any need to unfold `Con.addMonoid` when the type checker is checking
that instance diagrams commute -/
toAdd := TensorProduct.add _ _
toZero := TensorProduct.zero _ _ }
instance addSemigroup : AddSemigroup (M ⊗[R] N) :=
{ (addConGen (TensorProduct.Eqv R M N)).addMonoid with
toAdd := TensorProduct.add _ _ }
instance addCommSemigroup : AddCommSemigroup (M ⊗[R] N) :=
{ (addConGen (TensorProduct.Eqv R M N)).addMonoid with
toAddSemigroup := TensorProduct.addSemigroup _ _
add_comm := fun x y =>
AddCon.induction_on₂ x y fun _ _ =>
Quotient.sound' <| AddConGen.Rel.of _ _ <| Eqv.add_comm _ _ }
instance : Inhabited (M ⊗[R] N) :=
⟨0⟩
variable {M N}
variable (R) in
/-- The canonical function `M → N → M ⊗ N`. The localized notations are `m ⊗ₜ n` and `m ⊗ₜ[R] n`,
accessed by `open scoped TensorProduct`. -/
def tmul (m : M) (n : N) : M ⊗[R] N :=
AddCon.mk' _ <| FreeAddMonoid.of (m, n)
/-- The canonical function `M → N → M ⊗ N`. -/
infixl:100 " ⊗ₜ " => tmul _
/-- The canonical function `M → N → M ⊗ N`. -/
notation:100 x " ⊗ₜ[" R "] " y:100 => tmul R x y
@[elab_as_elim, induction_eliminator]
protected theorem induction_on {motive : M ⊗[R] N → Prop} (z : M ⊗[R] N)
(zero : motive 0)
(tmul : ∀ x y, motive <| x ⊗ₜ[R] y)
(add : ∀ x y, motive x → motive y → motive (x + y)) : motive z :=
AddCon.induction_on z fun x =>
FreeAddMonoid.recOn x zero fun ⟨m, n⟩ y ih => by
rw [AddCon.coe_add]
exact add _ _ (tmul ..) ih
/-- Lift an `R`-balanced map to the tensor product.
A map `f : M →+ N →+ P` additive in both components is `R`-balanced, or middle linear with respect
to `R`, if scalar multiplication in either argument is equivalent, `f (r • m) n = f m (r • n)`.
Note that strictly the first action should be a right-action by `R`, but for now `R` is commutative
so it doesn't matter. -/
-- TODO: use this to implement `lift` and `SMul.aux`. For now we do not do this as it causes
-- performance issues elsewhere.
def liftAddHom (f : M →+ N →+ P)
(hf : ∀ (r : R) (m : M) (n : N), f (r • m) n = f m (r • n)) :
M ⊗[R] N →+ P :=
(addConGen (TensorProduct.Eqv R M N)).lift (FreeAddMonoid.lift (fun mn : M × N => f mn.1 mn.2)) <|
AddCon.addConGen_le fun x y hxy =>
match x, y, hxy with
| _, _, .of_zero_left n =>
(AddCon.ker_rel _).2 <| by simp_rw [map_zero, FreeAddMonoid.lift_eval_of, map_zero,
AddMonoidHom.zero_apply]
| _, _, .of_zero_right m =>
(AddCon.ker_rel _).2 <| by simp_rw [map_zero, FreeAddMonoid.lift_eval_of, map_zero]
| _, _, .of_add_left m₁ m₂ n =>
(AddCon.ker_rel _).2 <| by simp_rw [map_add, FreeAddMonoid.lift_eval_of, map_add,
AddMonoidHom.add_apply]
| _, _, .of_add_right m n₁ n₂ =>
(AddCon.ker_rel _).2 <| by simp_rw [map_add, FreeAddMonoid.lift_eval_of, map_add]
| _, _, .of_smul s m n =>
(AddCon.ker_rel _).2 <| by rw [FreeAddMonoid.lift_eval_of, FreeAddMonoid.lift_eval_of, hf]
| _, _, .add_comm x y =>
(AddCon.ker_rel _).2 <| by simp_rw [map_add, add_comm]
@[simp]
theorem liftAddHom_tmul (f : M →+ N →+ P)
(hf : ∀ (r : R) (m : M) (n : N), f (r • m) n = f m (r • n)) (m : M) (n : N) :
liftAddHom f hf (m ⊗ₜ n) = f m n :=
rfl
variable (M) in
@[simp]
theorem zero_tmul (n : N) : (0 : M) ⊗ₜ[R] n = 0 :=
Quotient.sound' <| AddConGen.Rel.of _ _ <| Eqv.of_zero_left _
theorem add_tmul (m₁ m₂ : M) (n : N) : (m₁ + m₂) ⊗ₜ n = m₁ ⊗ₜ n + m₂ ⊗ₜ[R] n :=
Eq.symm <| Quotient.sound' <| AddConGen.Rel.of _ _ <| Eqv.of_add_left _ _ _
variable (N) in
@[simp]
theorem tmul_zero (m : M) : m ⊗ₜ[R] (0 : N) = 0 :=
Quotient.sound' <| AddConGen.Rel.of _ _ <| Eqv.of_zero_right _
theorem tmul_add (m : M) (n₁ n₂ : N) : m ⊗ₜ (n₁ + n₂) = m ⊗ₜ n₁ + m ⊗ₜ[R] n₂ :=
Eq.symm <| Quotient.sound' <| AddConGen.Rel.of _ _ <| Eqv.of_add_right _ _ _
instance uniqueLeft [Subsingleton M] : Unique (M ⊗[R] N) where
default := 0
uniq z := z.induction_on rfl (fun x y ↦ by rw [Subsingleton.elim x 0, zero_tmul]) <| by
rintro _ _ rfl rfl; apply add_zero
instance uniqueRight [Subsingleton N] : Unique (M ⊗[R] N) where
default := 0
uniq z := z.induction_on rfl (fun x y ↦ by rw [Subsingleton.elim y 0, tmul_zero]) <| by
rintro _ _ rfl rfl; apply add_zero
section
variable (R R' M N)
/-- A typeclass for `SMul` structures which can be moved across a tensor product.
This typeclass is generated automatically from an `IsScalarTower` instance, but exists so that
we can also add an instance for `AddCommGroup.toIntModule`, allowing `z •` to be moved even if
`R` does not support negation.
Note that `Module R' (M ⊗[R] N)` is available even without this typeclass on `R'`; it's only
needed if `TensorProduct.smul_tmul`, `TensorProduct.smul_tmul'`, or `TensorProduct.tmul_smul` is
used.
-/
class CompatibleSMul [DistribMulAction R' N] : Prop where
smul_tmul : ∀ (r : R') (m : M) (n : N), (r • m) ⊗ₜ n = m ⊗ₜ[R] (r • n)
end
/-- Note that this provides the default `CompatibleSMul R R M N` instance through
`IsScalarTower.left`. -/
instance (priority := 100) CompatibleSMul.isScalarTower [SMul R' R] [IsScalarTower R' R M]
[DistribMulAction R' N] [IsScalarTower R' R N] : CompatibleSMul R R' M N :=
⟨fun r m n => by
conv_lhs => rw [← one_smul R m]
conv_rhs => rw [← one_smul R n]
rw [← smul_assoc, ← smul_assoc]
exact Quotient.sound' <| AddConGen.Rel.of _ _ <| Eqv.of_smul _ _ _⟩
/-- `smul` can be moved from one side of the product to the other . -/
theorem smul_tmul [DistribMulAction R' N] [CompatibleSMul R R' M N] (r : R') (m : M) (n : N) :
(r • m) ⊗ₜ n = m ⊗ₜ[R] (r • n) :=
CompatibleSMul.smul_tmul _ _ _
private def addMonoidWithWrongNSMul : AddMonoid (M ⊗[R] N) :=
{ (addConGen (TensorProduct.Eqv R M N)).addMonoid with }
attribute [local instance] addMonoidWithWrongNSMul in
/-- Auxiliary function to defining scalar multiplication on tensor product. -/
def SMul.aux {R' : Type*} [SMul R' M] (r : R') : FreeAddMonoid (M × N) →+ M ⊗[R] N :=
FreeAddMonoid.lift fun p : M × N => (r • p.1) ⊗ₜ p.2
theorem SMul.aux_of {R' : Type*} [SMul R' M] (r : R') (m : M) (n : N) :
SMul.aux r (.of (m, n)) = (r • m) ⊗ₜ[R] n :=
rfl
variable [SMulCommClass R R' M] [SMulCommClass R R'' M]
/-- Given two modules over a commutative semiring `R`, if one of the factors carries a
(distributive) action of a second type of scalars `R'`, which commutes with the action of `R`, then
the tensor product (over `R`) carries an action of `R'`.
This instance defines this `R'` action in the case that it is the left module which has the `R'`
action. Two natural ways in which this situation arises are:
* Extension of scalars
* A tensor product of a group representation with a module not carrying an action
Note that in the special case that `R = R'`, since `R` is commutative, we just get the usual scalar
action on a tensor product of two modules. This special case is important enough that, for
performance reasons, we define it explicitly below. -/
instance leftHasSMul : SMul R' (M ⊗[R] N) :=
⟨fun r =>
(addConGen (TensorProduct.Eqv R M N)).lift (SMul.aux r : _ →+ M ⊗[R] N) <|
AddCon.addConGen_le fun x y hxy =>
match x, y, hxy with
| _, _, .of_zero_left n =>
(AddCon.ker_rel _).2 <| by simp_rw [map_zero, SMul.aux_of, smul_zero, zero_tmul]
| _, _, .of_zero_right m =>
(AddCon.ker_rel _).2 <| by simp_rw [map_zero, SMul.aux_of, tmul_zero]
| _, _, .of_add_left m₁ m₂ n =>
(AddCon.ker_rel _).2 <| by simp_rw [map_add, SMul.aux_of, smul_add, add_tmul]
| _, _, .of_add_right m n₁ n₂ =>
(AddCon.ker_rel _).2 <| by simp_rw [map_add, SMul.aux_of, tmul_add]
| _, _, .of_smul s m n =>
(AddCon.ker_rel _).2 <| by rw [SMul.aux_of, SMul.aux_of, ← smul_comm, smul_tmul]
| _, _, .add_comm x y =>
(AddCon.ker_rel _).2 <| by simp_rw [map_add, add_comm]⟩
instance : SMul R (M ⊗[R] N) :=
TensorProduct.leftHasSMul
protected theorem smul_zero (r : R') : r • (0 : M ⊗[R] N) = 0 :=
AddMonoidHom.map_zero _
protected theorem smul_add (r : R') (x y : M ⊗[R] N) : r • (x + y) = r • x + r • y :=
AddMonoidHom.map_add _ _ _
protected theorem zero_smul (x : M ⊗[R] N) : (0 : R'') • x = 0 :=
have : ∀ (r : R'') (m : M) (n : N), r • m ⊗ₜ[R] n = (r • m) ⊗ₜ n := fun _ _ _ => rfl
x.induction_on (by rw [TensorProduct.smul_zero])
(fun m n => by rw [this, zero_smul, zero_tmul]) fun x y ihx ihy => by
rw [TensorProduct.smul_add, ihx, ihy, add_zero]
protected theorem one_smul (x : M ⊗[R] N) : (1 : R') • x = x :=
have : ∀ (r : R') (m : M) (n : N), r • m ⊗ₜ[R] n = (r • m) ⊗ₜ n := fun _ _ _ => rfl
x.induction_on (by rw [TensorProduct.smul_zero])
(fun m n => by rw [this, one_smul])
fun x y ihx ihy => by rw [TensorProduct.smul_add, ihx, ihy]
protected theorem add_smul (r s : R'') (x : M ⊗[R] N) : (r + s) • x = r • x + s • x :=
have : ∀ (r : R'') (m : M) (n : N), r • m ⊗ₜ[R] n = (r • m) ⊗ₜ n := fun _ _ _ => rfl
x.induction_on (by simp_rw [TensorProduct.smul_zero, add_zero])
(fun m n => by simp_rw [this, add_smul, add_tmul]) fun x y ihx ihy => by
simp_rw [TensorProduct.smul_add]
rw [ihx, ihy, add_add_add_comm]
instance addMonoid : AddMonoid (M ⊗[R] N) :=
{ TensorProduct.addZeroClass _ _ with
toAddSemigroup := TensorProduct.addSemigroup _ _
toZero := TensorProduct.zero _ _
nsmul := fun n v => n • v
nsmul_zero := by simp [TensorProduct.zero_smul]
nsmul_succ := by simp only [TensorProduct.one_smul, TensorProduct.add_smul, add_comm,
forall_const] }
instance addCommMonoid : AddCommMonoid (M ⊗[R] N) :=
{ TensorProduct.addCommSemigroup _ _ with
toAddMonoid := TensorProduct.addMonoid }
instance leftDistribMulAction : DistribMulAction R' (M ⊗[R] N) :=
have : ∀ (r : R') (m : M) (n : N), r • m ⊗ₜ[R] n = (r • m) ⊗ₜ n := fun _ _ _ => rfl
{ smul_add := fun r x y => TensorProduct.smul_add r x y
mul_smul := fun r s x =>
x.induction_on (by simp_rw [TensorProduct.smul_zero])
(fun m n => by simp_rw [this, mul_smul]) fun x y ihx ihy => by
simp_rw [TensorProduct.smul_add]
rw [ihx, ihy]
one_smul := TensorProduct.one_smul
smul_zero := TensorProduct.smul_zero }
instance : DistribMulAction R (M ⊗[R] N) :=
TensorProduct.leftDistribMulAction
theorem smul_tmul' (r : R') (m : M) (n : N) : r • m ⊗ₜ[R] n = (r • m) ⊗ₜ n :=
rfl
@[simp]
theorem tmul_smul [DistribMulAction R' N] [CompatibleSMul R R' M N] (r : R') (x : M) (y : N) :
x ⊗ₜ (r • y) = r • x ⊗ₜ[R] y :=
(smul_tmul _ _ _).symm
theorem smul_tmul_smul (r s : R) (m : M) (n : N) : (r • m) ⊗ₜ[R] (s • n) = (r * s) • m ⊗ₜ[R] n := by
simp_rw [smul_tmul, tmul_smul, mul_smul]
instance leftModule : Module R'' (M ⊗[R] N) :=
{ add_smul := TensorProduct.add_smul
zero_smul := TensorProduct.zero_smul }
instance : Module R (M ⊗[R] N) :=
TensorProduct.leftModule
instance [Module R''ᵐᵒᵖ M] [IsCentralScalar R'' M] : IsCentralScalar R'' (M ⊗[R] N) where
op_smul_eq_smul r x :=
x.induction_on (by rw [smul_zero, smul_zero])
(fun x y => by rw [smul_tmul', smul_tmul', op_smul_eq_smul]) fun x y hx hy => by
rw [smul_add, smul_add, hx, hy]
section
-- Like `R'`, `R'₂` provides a `DistribMulAction R'₂ (M ⊗[R] N)`
variable {R'₂ : Type*} [Monoid R'₂] [DistribMulAction R'₂ M]
variable [SMulCommClass R R'₂ M]
/-- `SMulCommClass R' R'₂ M` implies `SMulCommClass R' R'₂ (M ⊗[R] N)` -/
instance smulCommClass_left [SMulCommClass R' R'₂ M] : SMulCommClass R' R'₂ (M ⊗[R] N) where
smul_comm r' r'₂ x :=
TensorProduct.induction_on x (by simp_rw [TensorProduct.smul_zero])
(fun m n => by simp_rw [smul_tmul', smul_comm]) fun x y ihx ihy => by
simp_rw [TensorProduct.smul_add]; rw [ihx, ihy]
variable [SMul R'₂ R']
/-- `IsScalarTower R'₂ R' M` implies `IsScalarTower R'₂ R' (M ⊗[R] N)` -/
instance isScalarTower_left [IsScalarTower R'₂ R' M] : IsScalarTower R'₂ R' (M ⊗[R] N) :=
⟨fun s r x =>
x.induction_on (by simp)
(fun m n => by rw [smul_tmul', smul_tmul', smul_tmul', smul_assoc]) fun x y ihx ihy => by
rw [smul_add, smul_add, smul_add, ihx, ihy]⟩
variable [DistribMulAction R'₂ N] [DistribMulAction R' N]
variable [CompatibleSMul R R'₂ M N] [CompatibleSMul R R' M N]
/-- `IsScalarTower R'₂ R' N` implies `IsScalarTower R'₂ R' (M ⊗[R] N)` -/
instance isScalarTower_right [IsScalarTower R'₂ R' N] : IsScalarTower R'₂ R' (M ⊗[R] N) :=
⟨fun s r x =>
x.induction_on (by simp)
(fun m n => by rw [← tmul_smul, ← tmul_smul, ← tmul_smul, smul_assoc]) fun x y ihx ihy => by
rw [smul_add, smul_add, smul_add, ihx, ihy]⟩
end
/-- A short-cut instance for the common case, where the requirements for the `compatible_smul`
instances are sufficient. -/
instance isScalarTower [SMul R' R] [IsScalarTower R' R M] : IsScalarTower R' R (M ⊗[R] N) :=
TensorProduct.isScalarTower_left
-- or right
variable (R M N) in
/-- The canonical bilinear map `M → N → M ⊗[R] N`. -/
def mk : M →ₗ[R] N →ₗ[R] M ⊗[R] N :=
LinearMap.mk₂ R (· ⊗ₜ ·) add_tmul (fun c m n => by simp_rw [smul_tmul, tmul_smul])
tmul_add tmul_smul
@[simp]
theorem mk_apply (m : M) (n : N) : mk R M N m n = m ⊗ₜ n :=
rfl
theorem ite_tmul (x₁ : M) (x₂ : N) (P : Prop) [Decidable P] :
(if P then x₁ else 0) ⊗ₜ[R] x₂ = if P then x₁ ⊗ₜ x₂ else 0 := by split_ifs <;> simp
theorem tmul_ite (x₁ : M) (x₂ : N) (P : Prop) [Decidable P] :
(x₁ ⊗ₜ[R] if P then x₂ else 0) = if P then x₁ ⊗ₜ x₂ else 0 := by split_ifs <;> simp
lemma tmul_single {ι : Type*} [DecidableEq ι] {M : ι → Type*} [∀ i, AddCommMonoid (M i)]
[∀ i, Module R (M i)] (i : ι) (x : N) (m : M i) (j : ι) :
x ⊗ₜ[R] Pi.single i m j = (Pi.single i (x ⊗ₜ[R] m) : ∀ i, N ⊗[R] M i) j := by
by_cases h : i = j <;> aesop
lemma single_tmul {ι : Type*} [DecidableEq ι] {M : ι → Type*} [∀ i, AddCommMonoid (M i)]
[∀ i, Module R (M i)] (i : ι) (x : N) (m : M i) (j : ι) :
Pi.single i m j ⊗ₜ[R] x = (Pi.single i (m ⊗ₜ[R] x) : ∀ i, M i ⊗[R] N) j := by
by_cases h : i = j <;> aesop
section
theorem sum_tmul {α : Type*} (s : Finset α) (m : α → M) (n : N) :
(∑ a ∈ s, m a) ⊗ₜ[R] n = ∑ a ∈ s, m a ⊗ₜ[R] n := by
classical
induction s using Finset.induction with
| empty => simp
| insert _ _ has ih => simp [Finset.sum_insert has, add_tmul, ih]
theorem tmul_sum (m : M) {α : Type*} (s : Finset α) (n : α → N) :
(m ⊗ₜ[R] ∑ a ∈ s, n a) = ∑ a ∈ s, m ⊗ₜ[R] n a := by
classical
induction s using Finset.induction with
| empty => simp
| insert _ _ has ih => simp [Finset.sum_insert has, tmul_add, ih]
end
variable (R M N)
/-- The simple (aka pure) elements span the tensor product. -/
theorem span_tmul_eq_top : Submodule.span R { t : M ⊗[R] N | ∃ m n, m ⊗ₜ n = t } = ⊤ := by
ext t; simp only [Submodule.mem_top, iff_true]
refine t.induction_on ?_ ?_ ?_
· exact Submodule.zero_mem _
· intro m n
apply Submodule.subset_span
use m, n
· intro t₁ t₂ ht₁ ht₂
exact Submodule.add_mem _ ht₁ ht₂
@[simp]
theorem map₂_mk_top_top_eq_top : Submodule.map₂ (mk R M N) ⊤ ⊤ = ⊤ := by
rw [← top_le_iff, ← span_tmul_eq_top, Submodule.map₂_eq_span_image2]
exact Submodule.span_mono fun _ ⟨m, n, h⟩ => ⟨m, trivial, n, trivial, h⟩
theorem exists_eq_tmul_of_forall (x : TensorProduct R M N)
(h : ∀ (m₁ m₂ : M) (n₁ n₂ : N), ∃ m n, m₁ ⊗ₜ n₁ + m₂ ⊗ₜ n₂ = m ⊗ₜ[R] n) :
∃ m n, x = m ⊗ₜ n := by
induction x with
| zero =>
use 0, 0
rw [TensorProduct.zero_tmul]
| tmul m n => use m, n
| add x y h₁ h₂ =>
obtain ⟨m₁, n₁, rfl⟩ := h₁
obtain ⟨m₂, n₂, rfl⟩ := h₂
apply h
end Module
variable [Module R P]
section UniversalProperty
variable {M N}
variable (f : M →ₗ[R] N →ₗ[R] P)
/-- Auxiliary function to constructing a linear map `M ⊗ N → P` given a bilinear map `M → N → P`
with the property that its composition with the canonical bilinear map `M → N → M ⊗ N` is
the given bilinear map `M → N → P`. -/
def liftAux : M ⊗[R] N →+ P :=
liftAddHom (LinearMap.toAddMonoidHom'.comp <| f.toAddMonoidHom)
fun r m n => by dsimp; rw [LinearMap.map_smul₂, map_smul]
theorem liftAux_tmul (m n) : liftAux f (m ⊗ₜ n) = f m n :=
rfl
variable {f}
@[simp]
theorem liftAux.smul (r : R) (x) : liftAux f (r • x) = r • liftAux f x :=
TensorProduct.induction_on x (smul_zero _).symm
(fun p q => by simp_rw [← tmul_smul, liftAux_tmul, (f p).map_smul])
fun p q ih1 ih2 => by simp_rw [smul_add, (liftAux f).map_add, ih1, ih2, smul_add]
variable (f) in
/-- Constructing a linear map `M ⊗ N → P` given a bilinear map `M → N → P` with the property that
its composition with the canonical bilinear map `M → N → M ⊗ N` is
the given bilinear map `M → N → P`. -/
def lift : M ⊗[R] N →ₗ[R] P :=
{ liftAux f with map_smul' := liftAux.smul }
@[simp]
theorem lift.tmul (x y) : lift f (x ⊗ₜ y) = f x y :=
rfl
@[simp]
theorem lift.tmul' (x y) : (lift f).1 (x ⊗ₜ y) = f x y :=
rfl
theorem ext' {g h : M ⊗[R] N →ₗ[R] P} (H : ∀ x y, g (x ⊗ₜ y) = h (x ⊗ₜ y)) : g = h :=
LinearMap.ext fun z =>
TensorProduct.induction_on z (by simp_rw [LinearMap.map_zero]) H fun x y ihx ihy => by
rw [g.map_add, h.map_add, ihx, ihy]
theorem lift.unique {g : M ⊗[R] N →ₗ[R] P} (H : ∀ x y, g (x ⊗ₜ y) = f x y) : g = lift f :=
ext' fun m n => by rw [H, lift.tmul]
theorem lift_mk : lift (mk R M N) = LinearMap.id :=
Eq.symm <| lift.unique fun _ _ => rfl
theorem lift_compr₂ (g : P →ₗ[R] Q) : lift (f.compr₂ g) = g.comp (lift f) :=
Eq.symm <| lift.unique fun _ _ => by simp
theorem lift_mk_compr₂ (f : M ⊗ N →ₗ[R] P) : lift ((mk R M N).compr₂ f) = f := by
rw [lift_compr₂ f, lift_mk, LinearMap.comp_id]
/-- This used to be an `@[ext]` lemma, but it fails very slowly when the `ext` tactic tries to apply
it in some cases, notably when one wants to show equality of two linear maps. The `@[ext]`
attribute is now added locally where it is needed. Using this as the `@[ext]` lemma instead of
`TensorProduct.ext'` allows `ext` to apply lemmas specific to `M →ₗ _` and `N →ₗ _`.
See note [partially-applied ext lemmas]. -/
theorem ext {g h : M ⊗ N →ₗ[R] P} (H : (mk R M N).compr₂ g = (mk R M N).compr₂ h) : g = h := by
rw [← lift_mk_compr₂ g, H, lift_mk_compr₂]
attribute [local ext high] ext
example : M → N → (M → N → P) → P := fun m => flip fun f => f m
variable (R M N P) in
/-- Linearly constructing a linear map `M ⊗ N → P` given a bilinear map `M → N → P`
with the property that its composition with the canonical bilinear map `M → N → M ⊗ N` is
the given bilinear map `M → N → P`. -/
def uncurry : (M →ₗ[R] N →ₗ[R] P) →ₗ[R] M ⊗[R] N →ₗ[R] P :=
LinearMap.flip <| lift <| LinearMap.lflip.comp (LinearMap.flip LinearMap.id)
@[simp]
theorem uncurry_apply (f : M →ₗ[R] N →ₗ[R] P) (m : M) (n : N) :
uncurry R M N P f (m ⊗ₜ n) = f m n := by rw [uncurry, LinearMap.flip_apply, lift.tmul]; rfl
variable (R M N P)
/-- A linear equivalence constructing a linear map `M ⊗ N → P` given a bilinear map `M → N → P`
with the property that its composition with the canonical bilinear map `M → N → M ⊗ N` is
the given bilinear map `M → N → P`. -/
def lift.equiv : (M →ₗ[R] N →ₗ[R] P) ≃ₗ[R] M ⊗[R] N →ₗ[R] P :=
{ uncurry R M N P with
invFun := fun f => (mk R M N).compr₂ f
left_inv := fun _ => LinearMap.ext₂ fun _ _ => lift.tmul _ _
right_inv := fun _ => ext' fun _ _ => lift.tmul _ _ }
@[simp]
theorem lift.equiv_apply (f : M →ₗ[R] N →ₗ[R] P) (m : M) (n : N) :
lift.equiv R M N P f (m ⊗ₜ n) = f m n :=
uncurry_apply f m n
@[simp]
theorem lift.equiv_symm_apply (f : M ⊗[R] N →ₗ[R] P) (m : M) (n : N) :
(lift.equiv R M N P).symm f m n = f (m ⊗ₜ n) :=
rfl
/-- Given a linear map `M ⊗ N → P`, compose it with the canonical bilinear map `M → N → M ⊗ N` to
form a bilinear map `M → N → P`. -/
def lcurry : (M ⊗[R] N →ₗ[R] P) →ₗ[R] M →ₗ[R] N →ₗ[R] P :=
(lift.equiv R M N P).symm
variable {R M N P}
@[simp]
theorem lcurry_apply (f : M ⊗[R] N →ₗ[R] P) (m : M) (n : N) : lcurry R M N P f m n = f (m ⊗ₜ n) :=
rfl
/-- Given a linear map `M ⊗ N → P`, compose it with the canonical bilinear map `M → N → M ⊗ N` to
form a bilinear map `M → N → P`. -/
def curry (f : M ⊗[R] N →ₗ[R] P) : M →ₗ[R] N →ₗ[R] P :=
lcurry R M N P f
@[simp]
theorem curry_apply (f : M ⊗ N →ₗ[R] P) (m : M) (n : N) : curry f m n = f (m ⊗ₜ n) :=
rfl
theorem curry_injective : Function.Injective (curry : (M ⊗[R] N →ₗ[R] P) → M →ₗ[R] N →ₗ[R] P) :=
fun _ _ H => ext H
theorem ext_threefold {g h : (M ⊗[R] N) ⊗[R] P →ₗ[R] Q}
(H : ∀ x y z, g (x ⊗ₜ y ⊗ₜ z) = h (x ⊗ₜ y ⊗ₜ z)) : g = h := by
ext x y z
exact H x y z
-- We'll need this one for checking the pentagon identity!
theorem ext_fourfold {g h : ((M ⊗[R] N) ⊗[R] P) ⊗[R] Q →ₗ[R] S}
(H : ∀ w x y z, g (w ⊗ₜ x ⊗ₜ y ⊗ₜ z) = h (w ⊗ₜ x ⊗ₜ y ⊗ₜ z)) : g = h := by
ext w x y z
exact H w x y z
/-- Two linear maps (M ⊗ N) ⊗ (P ⊗ Q) → S which agree on all elements of the
form (m ⊗ₜ n) ⊗ₜ (p ⊗ₜ q) are equal. -/
theorem ext_fourfold' {φ ψ : (M ⊗[R] N) ⊗[R] P ⊗[R] Q →ₗ[R] S}
(H : ∀ w x y z, φ (w ⊗ₜ x ⊗ₜ (y ⊗ₜ z)) = ψ (w ⊗ₜ x ⊗ₜ (y ⊗ₜ z))) : φ = ψ := by
ext m n p q
exact H m n p q
end UniversalProperty
variable {M N}
section
variable (R M N)
/-- The tensor product of modules is commutative, up to linear equivalence.
-/
protected def comm : M ⊗[R] N ≃ₗ[R] N ⊗[R] M :=
LinearEquiv.ofLinear (lift (mk R N M).flip) (lift (mk R M N).flip) (ext' fun _ _ => rfl)
(ext' fun _ _ => rfl)
@[simp]
theorem comm_tmul (m : M) (n : N) : (TensorProduct.comm R M N) (m ⊗ₜ n) = n ⊗ₜ m :=
rfl
@[simp]
theorem comm_symm_tmul (m : M) (n : N) : (TensorProduct.comm R M N).symm (n ⊗ₜ m) = m ⊗ₜ n :=
rfl
lemma lift_comp_comm_eq (f : M →ₗ[R] N →ₗ[R] P) :
lift f ∘ₗ TensorProduct.comm R N M = lift f.flip :=
ext rfl
end
section CompatibleSMul
variable (R A M N) [CommSemiring A] [Module A M] [Module A N] [SMulCommClass R A M]
[CompatibleSMul R A M N]
/-- If M and N are both R- and A-modules and their actions on them commute,
and if the A-action on `M ⊗[R] N` can switch between the two factors, then there is a
canonical A-linear map from `M ⊗[A] N` to `M ⊗[R] N`. -/
def mapOfCompatibleSMul : M ⊗[A] N →ₗ[A] M ⊗[R] N :=
lift
{ toFun := fun m ↦
{ __ := mk R M N m
map_smul' := fun _ _ ↦ (smul_tmul _ _ _).symm }
map_add' := fun _ _ ↦ LinearMap.ext <| by simp
map_smul' := fun _ _ ↦ rfl }
@[simp] theorem mapOfCompatibleSMul_tmul (m n) : mapOfCompatibleSMul R A M N (m ⊗ₜ n) = m ⊗ₜ n :=
rfl
theorem mapOfCompatibleSMul_surjective : Function.Surjective (mapOfCompatibleSMul R A M N) :=
fun x ↦ x.induction_on (⟨0, map_zero _⟩) (fun m n ↦ ⟨_, mapOfCompatibleSMul_tmul ..⟩)
fun _ _ ⟨x, hx⟩ ⟨y, hy⟩ ↦ ⟨x + y, by simpa using congr($hx + $hy)⟩
attribute [local instance] SMulCommClass.symm
/-- `mapOfCompatibleSMul R A M N` is also R-linear. -/
def mapOfCompatibleSMul' : M ⊗[A] N →ₗ[R] M ⊗[R] N where
__ := mapOfCompatibleSMul R A M N
map_smul' _ x := x.induction_on (map_zero _) (fun _ _ ↦ by simp [smul_tmul'])
fun _ _ h h' ↦ by simpa using congr($h + $h')
/-- If the R- and A-actions on M and N satisfy `CompatibleSMul` both ways,
then `M ⊗[A] N` is canonically isomorphic to `M ⊗[R] N`. -/
def equivOfCompatibleSMul [CompatibleSMul A R M N] : M ⊗[A] N ≃ₗ[A] M ⊗[R] N where
__ := mapOfCompatibleSMul R A M N
invFun := mapOfCompatibleSMul A R M N
left_inv x := x.induction_on (map_zero _) (fun _ _ ↦ rfl)
fun _ _ h h' ↦ by simpa using congr($h + $h')
right_inv x := x.induction_on (map_zero _) (fun _ _ ↦ rfl)
fun _ _ h h' ↦ by simpa using congr($h + $h')
omit [SMulCommClass R A M]
end CompatibleSMul
open LinearMap
/-- The tensor product of a pair of linear maps between modules. -/
def map (f : M →ₗ[R] P) (g : N →ₗ[R] Q) : M ⊗[R] N →ₗ[R] P ⊗[R] Q :=
lift <| comp (compl₂ (mk _ _ _) g) f
@[simp]
theorem map_tmul (f : M →ₗ[R] P) (g : N →ₗ[R] Q) (m : M) (n : N) : map f g (m ⊗ₜ n) = f m ⊗ₜ g n :=
rfl
/-- Given linear maps `f : M → P`, `g : N → Q`, if we identify `M ⊗ N` with `N ⊗ M` and `P ⊗ Q`
with `Q ⊗ P`, then this lemma states that `f ⊗ g = g ⊗ f`. -/
lemma map_comp_comm_eq (f : M →ₗ[R] P) (g : N →ₗ[R] Q) :
map f g ∘ₗ TensorProduct.comm R N M = TensorProduct.comm R Q P ∘ₗ map g f :=
ext rfl
lemma map_comm (f : M →ₗ[R] P) (g : N →ₗ[R] Q) (x : N ⊗[R] M) :
map f g (TensorProduct.comm R N M x) = TensorProduct.comm R Q P (map g f x) :=
DFunLike.congr_fun (map_comp_comm_eq _ _) _
theorem map_range_eq_span_tmul (f : M →ₗ[R] P) (g : N →ₗ[R] Q) :
range (map f g) = Submodule.span R { t | ∃ m n, f m ⊗ₜ g n = t } := by
simp only [← Submodule.map_top, ← span_tmul_eq_top, Submodule.map_span, Set.mem_image,
Set.mem_setOf_eq]
congr; ext t
constructor
· rintro ⟨_, ⟨⟨m, n, rfl⟩, rfl⟩⟩
use m, n
simp only [map_tmul]
· rintro ⟨m, n, rfl⟩
refine ⟨_, ⟨⟨m, n, rfl⟩, ?_⟩⟩
simp only [map_tmul]
/-- Given submodules `p ⊆ P` and `q ⊆ Q`, this is the natural map: `p ⊗ q → P ⊗ Q`. -/
@[simp]
def mapIncl (p : Submodule R P) (q : Submodule R Q) : p ⊗[R] q →ₗ[R] P ⊗[R] Q :=
map p.subtype q.subtype
lemma range_mapIncl (p : Submodule R P) (q : Submodule R Q) :
LinearMap.range (mapIncl p q) = Submodule.span R (Set.image2 (· ⊗ₜ ·) p q) := by
rw [mapIncl, map_range_eq_span_tmul]
congr; ext; simp
theorem map₂_eq_range_lift_comp_mapIncl (f : P →ₗ[R] Q →ₗ[R] M)
(p : Submodule R P) (q : Submodule R Q) :
Submodule.map₂ f p q = LinearMap.range (lift f ∘ₗ mapIncl p q) := by
simp_rw [LinearMap.range_comp, range_mapIncl, Submodule.map_span,
Set.image_image2, Submodule.map₂_eq_span_image2, lift.tmul]
section
variable {P' Q' : Type*}
variable [AddCommMonoid P'] [Module R P']
variable [AddCommMonoid Q'] [Module R Q']
theorem map_comp (f₂ : P →ₗ[R] P') (f₁ : M →ₗ[R] P) (g₂ : Q →ₗ[R] Q') (g₁ : N →ₗ[R] Q) :
map (f₂.comp f₁) (g₂.comp g₁) = (map f₂ g₂).comp (map f₁ g₁) :=
ext' fun _ _ => rfl
lemma range_mapIncl_mono {p p' : Submodule R P} {q q' : Submodule R Q} (hp : p ≤ p') (hq : q ≤ q') :
LinearMap.range (mapIncl p q) ≤ LinearMap.range (mapIncl p' q') := by
simp_rw [range_mapIncl]
exact Submodule.span_mono (Set.image2_subset hp hq)
theorem lift_comp_map (i : P →ₗ[R] Q →ₗ[R] Q') (f : M →ₗ[R] P) (g : N →ₗ[R] Q) :
(lift i).comp (map f g) = lift ((i.comp f).compl₂ g) :=
ext' fun _ _ => rfl
attribute [local ext high] ext
@[simp]
theorem map_id : map (id : M →ₗ[R] M) (id : N →ₗ[R] N) = .id := by
ext
simp only [mk_apply, id_coe, compr₂_apply, _root_.id, map_tmul]
@[simp]
protected theorem map_one : map (1 : M →ₗ[R] M) (1 : N →ₗ[R] N) = 1 :=
map_id
protected theorem map_mul (f₁ f₂ : M →ₗ[R] M) (g₁ g₂ : N →ₗ[R] N) :
map (f₁ * f₂) (g₁ * g₂) = map f₁ g₁ * map f₂ g₂ :=
map_comp f₁ f₂ g₁ g₂
@[simp]
protected theorem map_pow (f : M →ₗ[R] M) (g : N →ₗ[R] N) (n : ℕ) :
map f g ^ n = map (f ^ n) (g ^ n) := by
induction n with
| zero => simp only [pow_zero, TensorProduct.map_one]
| succ n ih => simp only [pow_succ', ih, TensorProduct.map_mul]
theorem map_add_left (f₁ f₂ : M →ₗ[R] P) (g : N →ₗ[R] Q) :
map (f₁ + f₂) g = map f₁ g + map f₂ g := by
ext
simp only [add_tmul, compr₂_apply, mk_apply, map_tmul, add_apply]
theorem map_add_right (f : M →ₗ[R] P) (g₁ g₂ : N →ₗ[R] Q) :
map f (g₁ + g₂) = map f g₁ + map f g₂ := by
ext
simp only [tmul_add, compr₂_apply, mk_apply, map_tmul, add_apply]
theorem map_smul_left (r : R) (f : M →ₗ[R] P) (g : N →ₗ[R] Q) : map (r • f) g = r • map f g := by
ext
simp only [smul_tmul, compr₂_apply, mk_apply, map_tmul, smul_apply, tmul_smul]
theorem map_smul_right (r : R) (f : M →ₗ[R] P) (g : N →ₗ[R] Q) : map f (r • g) = r • map f g := by
ext
simp only [smul_tmul, compr₂_apply, mk_apply, map_tmul, smul_apply, tmul_smul]
variable (R M N P Q)
/-- The tensor product of a pair of linear maps between modules, bilinear in both maps. -/
def mapBilinear : (M →ₗ[R] P) →ₗ[R] (N →ₗ[R] Q) →ₗ[R] M ⊗[R] N →ₗ[R] P ⊗[R] Q :=
LinearMap.mk₂ R map map_add_left map_smul_left map_add_right map_smul_right
/-- The canonical linear map from `P ⊗[R] (M →ₗ[R] Q)` to `(M →ₗ[R] P ⊗[R] Q)` -/
def lTensorHomToHomLTensor : P ⊗[R] (M →ₗ[R] Q) →ₗ[R] M →ₗ[R] P ⊗[R] Q :=
TensorProduct.lift (llcomp R M Q _ ∘ₗ mk R P Q)
/-- The canonical linear map from `(M →ₗ[R] P) ⊗[R] Q` to `(M →ₗ[R] P ⊗[R] Q)` -/
def rTensorHomToHomRTensor : (M →ₗ[R] P) ⊗[R] Q →ₗ[R] M →ₗ[R] P ⊗[R] Q :=
TensorProduct.lift (llcomp R M P _ ∘ₗ (mk R P Q).flip).flip
/-- The linear map from `(M →ₗ P) ⊗ (N →ₗ Q)` to `(M ⊗ N →ₗ P ⊗ Q)` sending `f ⊗ₜ g` to
the `TensorProduct.map f g`, the tensor product of the two maps. -/
def homTensorHomMap : (M →ₗ[R] P) ⊗[R] (N →ₗ[R] Q) →ₗ[R] M ⊗[R] N →ₗ[R] P ⊗[R] Q :=
lift (mapBilinear R M N P Q)
variable {R M N P Q}
/--
This is a binary version of `TensorProduct.map`: Given a bilinear map `f : M ⟶ P ⟶ Q` and a
bilinear map `g : N ⟶ S ⟶ T`, if we think `f` and `g` as linear maps with two inputs, then
`map₂ f g` is a bilinear map taking two inputs `M ⊗ N → P ⊗ S → Q ⊗ S` defined by
`map₂ f g (m ⊗ n) (p ⊗ s) = f m p ⊗ g n s`.
Mathematically, `TensorProduct.map₂` is defined as the composition
`M ⊗ N -map→ Hom(P, Q) ⊗ Hom(S, T) -homTensorHomMap→ Hom(P ⊗ S, Q ⊗ T)`.
-/
def map₂ (f : M →ₗ[R] P →ₗ[R] Q) (g : N →ₗ[R] S →ₗ[R] T) :
M ⊗[R] N →ₗ[R] P ⊗[R] S →ₗ[R] Q ⊗[R] T :=
homTensorHomMap R _ _ _ _ ∘ₗ map f g
@[simp]
theorem mapBilinear_apply (f : M →ₗ[R] P) (g : N →ₗ[R] Q) : mapBilinear R M N P Q f g = map f g :=
rfl
@[simp]
theorem lTensorHomToHomLTensor_apply (p : P) (f : M →ₗ[R] Q) (m : M) :
lTensorHomToHomLTensor R M P Q (p ⊗ₜ f) m = p ⊗ₜ f m :=
rfl
@[simp]
theorem rTensorHomToHomRTensor_apply (f : M →ₗ[R] P) (q : Q) (m : M) :
rTensorHomToHomRTensor R M P Q (f ⊗ₜ q) m = f m ⊗ₜ q :=
rfl
@[simp]
theorem homTensorHomMap_apply (f : M →ₗ[R] P) (g : N →ₗ[R] Q) :
homTensorHomMap R M N P Q (f ⊗ₜ g) = map f g :=
rfl
@[simp]
theorem map₂_apply_tmul (f : M →ₗ[R] P →ₗ[R] Q) (g : N →ₗ[R] S →ₗ[R] T) (m : M) (n : N) :
map₂ f g (m ⊗ₜ n) = map (f m) (g n) := rfl
@[simp]
theorem map_zero_left (g : N →ₗ[R] Q) : map (0 : M →ₗ[R] P) g = 0 :=
(mapBilinear R M N P Q).map_zero₂ _
@[simp]
theorem map_zero_right (f : M →ₗ[R] P) : map f (0 : N →ₗ[R] Q) = 0 :=
(mapBilinear R M N P Q _).map_zero
end
/-- If `M` and `P` are linearly equivalent and `N` and `Q` are linearly equivalent
then `M ⊗ N` and `P ⊗ Q` are linearly equivalent. -/
def congr (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) : M ⊗[R] N ≃ₗ[R] P ⊗[R] Q :=
LinearEquiv.ofLinear (map f g) (map f.symm g.symm)
(ext' fun m n => by simp)
(ext' fun m n => by simp)
@[simp]
theorem congr_tmul (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) (m : M) (n : N) :
congr f g (m ⊗ₜ n) = f m ⊗ₜ g n :=
rfl
@[simp]
theorem congr_symm_tmul (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) (p : P) (q : Q) :
(congr f g).symm (p ⊗ₜ q) = f.symm p ⊗ₜ g.symm q :=
rfl
theorem congr_symm (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) : (congr f g).symm = congr f.symm g.symm := rfl
@[simp] theorem congr_refl_refl : congr (.refl R M) (.refl R N) = .refl R _ :=
LinearEquiv.toLinearMap_injective <| ext' fun _ _ ↦ rfl
theorem congr_trans (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) (f' : P ≃ₗ[R] S) (g' : Q ≃ₗ[R] T) :
congr (f ≪≫ₗ f') (g ≪≫ₗ g') = congr f g ≪≫ₗ congr f' g' :=
LinearEquiv.toLinearMap_injective <| map_comp _ _ _ _
theorem congr_mul (f : M ≃ₗ[R] M) (g : N ≃ₗ[R] N) (f' : M ≃ₗ[R] M) (g' : N ≃ₗ[R] N) :
congr (f * f') (g * g') = congr f g * congr f' g' := congr_trans _ _ _ _
@[simp] theorem congr_pow (f : M ≃ₗ[R] M) (g : N ≃ₗ[R] N) (n : ℕ) :
congr f g ^ n = congr (f ^ n) (g ^ n) := by
induction n with
| zero => exact congr_refl_refl.symm
| succ n ih => simp_rw [pow_succ, ih, congr_mul]
@[simp] theorem congr_zpow (f : M ≃ₗ[R] M) (g : N ≃ₗ[R] N) (n : ℤ) :
congr f g ^ n = congr (f ^ n) (g ^ n) := by
cases n with
| ofNat n => exact congr_pow _ _ _
| negSucc n => simp_rw [zpow_negSucc, congr_pow]; exact congr_symm _ _
end TensorProduct
open scoped TensorProduct
variable [Module R P]
namespace LinearMap
variable {N}
/-- `LinearMap.lTensor M f : M ⊗ N →ₗ M ⊗ P` is the natural linear map
induced by `f : N →ₗ P`. -/
def lTensor (f : N →ₗ[R] P) : M ⊗[R] N →ₗ[R] M ⊗[R] P :=
TensorProduct.map id f
/-- `LinearMap.rTensor M f : N₁ ⊗ M →ₗ N₂ ⊗ M` is the natural linear map
induced by `f : N₁ →ₗ N₂`. -/
def rTensor (f : N →ₗ[R] P) : N ⊗[R] M →ₗ[R] P ⊗[R] M :=
TensorProduct.map f id
variable (g : P →ₗ[R] Q) (f : N →ₗ[R] P)
theorem lTensor_def : f.lTensor M = TensorProduct.map LinearMap.id f := rfl
theorem rTensor_def : f.rTensor M = TensorProduct.map f LinearMap.id := rfl
@[simp]
theorem lTensor_tmul (m : M) (n : N) : f.lTensor M (m ⊗ₜ n) = m ⊗ₜ f n :=
rfl
@[simp]
theorem rTensor_tmul (m : M) (n : N) : f.rTensor M (n ⊗ₜ m) = f n ⊗ₜ m :=
rfl
@[simp]
theorem lTensor_comp_mk (m : M) :
f.lTensor M ∘ₗ TensorProduct.mk R M N m = TensorProduct.mk R M P m ∘ₗ f :=
rfl
@[simp]
theorem rTensor_comp_flip_mk (m : M) :
f.rTensor M ∘ₗ (TensorProduct.mk R N M).flip m = (TensorProduct.mk R P M).flip m ∘ₗ f :=
rfl
lemma comm_comp_rTensor_comp_comm_eq (g : N →ₗ[R] P) :
TensorProduct.comm R P Q ∘ₗ rTensor Q g ∘ₗ TensorProduct.comm R Q N =
lTensor Q g :=
TensorProduct.ext rfl
lemma comm_comp_lTensor_comp_comm_eq (g : N →ₗ[R] P) :
TensorProduct.comm R Q P ∘ₗ lTensor Q g ∘ₗ TensorProduct.comm R N Q =
rTensor Q g :=
TensorProduct.ext rfl
/-- Given a linear map `f : N → P`, `f ⊗ M` is injective if and only if `M ⊗ f` is injective. -/
theorem lTensor_inj_iff_rTensor_inj :
Function.Injective (lTensor M f) ↔ Function.Injective (rTensor M f) := by
simp [← comm_comp_rTensor_comp_comm_eq]
/-- Given a linear map `f : N → P`, `f ⊗ M` is surjective if and only if `M ⊗ f` is surjective. -/
theorem lTensor_surj_iff_rTensor_surj :
Function.Surjective (lTensor M f) ↔ Function.Surjective (rTensor M f) := by
simp [← comm_comp_rTensor_comp_comm_eq]
/-- Given a linear map `f : N → P`, `f ⊗ M` is bijective if and only if `M ⊗ f` is bijective. -/
theorem lTensor_bij_iff_rTensor_bij :
Function.Bijective (lTensor M f) ↔ Function.Bijective (rTensor M f) := by
simp [← comm_comp_rTensor_comp_comm_eq]
open TensorProduct
attribute [local ext high] TensorProduct.ext
/-- `lTensorHom M` is the natural linear map that sends a linear map `f : N →ₗ P` to `M ⊗ f`.
See also `Module.End.lTensorAlgHom`. -/
def lTensorHom : (N →ₗ[R] P) →ₗ[R] M ⊗[R] N →ₗ[R] M ⊗[R] P where
toFun := lTensor M
map_add' f g := by
ext x y
simp only [compr₂_apply, mk_apply, add_apply, lTensor_tmul, tmul_add]
map_smul' r f := by
dsimp
ext x y
simp only [compr₂_apply, mk_apply, tmul_smul, smul_apply, lTensor_tmul]
/-- `rTensorHom M` is the natural linear map that sends a linear map `f : N →ₗ P` to `f ⊗ M`.
See also `Module.End.rTensorAlgHom`. -/
def rTensorHom : (N →ₗ[R] P) →ₗ[R] N ⊗[R] M →ₗ[R] P ⊗[R] M where
toFun f := f.rTensor M
map_add' f g := by
ext x y
simp only [compr₂_apply, mk_apply, add_apply, rTensor_tmul, add_tmul]
map_smul' r f := by
dsimp
ext x y
simp only [compr₂_apply, mk_apply, smul_tmul, tmul_smul, smul_apply, rTensor_tmul]
@[simp]
theorem coe_lTensorHom : (lTensorHom M : (N →ₗ[R] P) → M ⊗[R] N →ₗ[R] M ⊗[R] P) = lTensor M :=
rfl
@[simp]
theorem coe_rTensorHom : (rTensorHom M : (N →ₗ[R] P) → N ⊗[R] M →ₗ[R] P ⊗[R] M) = rTensor M :=
rfl
@[simp]
theorem lTensor_add (f g : N →ₗ[R] P) : (f + g).lTensor M = f.lTensor M + g.lTensor M :=
(lTensorHom M).map_add f g
@[simp]
theorem rTensor_add (f g : N →ₗ[R] P) : (f + g).rTensor M = f.rTensor M + g.rTensor M :=
(rTensorHom M).map_add f g
@[simp]
theorem lTensor_zero : lTensor M (0 : N →ₗ[R] P) = 0 :=
(lTensorHom M).map_zero
@[simp]
theorem rTensor_zero : rTensor M (0 : N →ₗ[R] P) = 0 :=
(rTensorHom M).map_zero
@[simp]
theorem lTensor_smul (r : R) (f : N →ₗ[R] P) : (r • f).lTensor M = r • f.lTensor M :=
(lTensorHom M).map_smul r f
@[simp]
theorem rTensor_smul (r : R) (f : N →ₗ[R] P) : (r • f).rTensor M = r • f.rTensor M :=
(rTensorHom M).map_smul r f
theorem lTensor_comp : (g.comp f).lTensor M = (g.lTensor M).comp (f.lTensor M) := by
ext m n
simp only [compr₂_apply, mk_apply, comp_apply, lTensor_tmul]
theorem lTensor_comp_apply (x : M ⊗[R] N) :
(g.comp f).lTensor M x = (g.lTensor M) ((f.lTensor M) x) := by rw [lTensor_comp, coe_comp]; rfl
theorem rTensor_comp : (g.comp f).rTensor M = (g.rTensor M).comp (f.rTensor M) := by
ext m n
simp only [compr₂_apply, mk_apply, comp_apply, rTensor_tmul]
theorem rTensor_comp_apply (x : N ⊗[R] M) :
(g.comp f).rTensor M x = (g.rTensor M) ((f.rTensor M) x) := by rw [rTensor_comp, coe_comp]; rfl
theorem lTensor_mul (f g : Module.End R N) : (f * g).lTensor M = f.lTensor M * g.lTensor M :=
lTensor_comp M f g
theorem rTensor_mul (f g : Module.End R N) : (f * g).rTensor M = f.rTensor M * g.rTensor M :=
rTensor_comp M f g
variable (N)
@[simp]
theorem lTensor_id : (id : N →ₗ[R] N).lTensor M = id :=
map_id
-- `simp` can prove this.
theorem lTensor_id_apply (x : M ⊗[R] N) : (LinearMap.id : N →ₗ[R] N).lTensor M x = x := by
rw [lTensor_id, id_coe, _root_.id]
@[simp]
theorem rTensor_id : (id : N →ₗ[R] N).rTensor M = id :=
map_id
-- `simp` can prove this.
theorem rTensor_id_apply (x : N ⊗[R] M) : (LinearMap.id : N →ₗ[R] N).rTensor M x = x := by
rw [rTensor_id, id_coe, _root_.id]
@[simp]
theorem lTensor_smul_action (r : R) :
(DistribMulAction.toLinearMap R N r).lTensor M =
DistribMulAction.toLinearMap R (M ⊗[R] N) r :=
(lTensor_smul M r LinearMap.id).trans (congrArg _ (lTensor_id M N))
@[simp]
theorem rTensor_smul_action (r : R) :
(DistribMulAction.toLinearMap R N r).rTensor M =
DistribMulAction.toLinearMap R (N ⊗[R] M) r :=
(rTensor_smul M r LinearMap.id).trans (congrArg _ (rTensor_id M N))
variable {N}
@[simp]
theorem lTensor_comp_rTensor (f : M →ₗ[R] P) (g : N →ₗ[R] Q) :
(g.lTensor P).comp (f.rTensor N) = map f g := by
simp only [lTensor, rTensor, ← map_comp, id_comp, comp_id]
@[simp]
theorem rTensor_comp_lTensor (f : M →ₗ[R] P) (g : N →ₗ[R] Q) :
(f.rTensor Q).comp (g.lTensor M) = map f g := by
simp only [lTensor, rTensor, ← map_comp, id_comp, comp_id]
@[simp]
theorem map_comp_rTensor (f : M →ₗ[R] P) (g : N →ₗ[R] Q) (f' : S →ₗ[R] M) :
(map f g).comp (f'.rTensor _) = map (f.comp f') g := by
simp only [lTensor, rTensor, ← map_comp, id_comp, comp_id]
@[simp]
theorem map_comp_lTensor (f : M →ₗ[R] P) (g : N →ₗ[R] Q) (g' : S →ₗ[R] N) :
(map f g).comp (g'.lTensor _) = map f (g.comp g') := by
simp only [lTensor, rTensor, ← map_comp, id_comp, comp_id]
@[simp]
theorem rTensor_comp_map (f' : P →ₗ[R] S) (f : M →ₗ[R] P) (g : N →ₗ[R] Q) :
(f'.rTensor _).comp (map f g) = map (f'.comp f) g := by
simp only [lTensor, rTensor, ← map_comp, id_comp, comp_id]
@[simp]
theorem lTensor_comp_map (g' : Q →ₗ[R] S) (f : M →ₗ[R] P) (g : N →ₗ[R] Q) :
(g'.lTensor _).comp (map f g) = map f (g'.comp g) := by
simp only [lTensor, rTensor, ← map_comp, id_comp, comp_id]
variable {M}
@[simp]
theorem rTensor_pow (f : M →ₗ[R] M) (n : ℕ) : f.rTensor N ^ n = (f ^ n).rTensor N := by
have h := TensorProduct.map_pow f (id : N →ₗ[R] N) n
rwa [Module.End.id_pow] at h
@[simp]
theorem lTensor_pow (f : N →ₗ[R] N) (n : ℕ) : f.lTensor M ^ n = (f ^ n).lTensor M := by
have h := TensorProduct.map_pow (id : M →ₗ[R] M) f n
rwa [Module.End.id_pow] at h
end LinearMap
namespace LinearEquiv
variable {N}
/-- `LinearEquiv.lTensor M f : M ⊗ N ≃ₗ M ⊗ P` is the natural linear equivalence
induced by `f : N ≃ₗ P`. -/
def lTensor (f : N ≃ₗ[R] P) : M ⊗[R] N ≃ₗ[R] M ⊗[R] P := TensorProduct.congr (refl R M) f
/-- `LinearEquiv.rTensor M f : N₁ ⊗ M ≃ₗ N₂ ⊗ M` is the natural linear equivalence
induced by `f : N₁ ≃ₗ N₂`. -/
def rTensor (f : N ≃ₗ[R] P) : N ⊗[R] M ≃ₗ[R] P ⊗[R] M := TensorProduct.congr f (refl R M)
variable (g : P ≃ₗ[R] Q) (f : N ≃ₗ[R] P) (m : M) (n : N) (p : P) (x : M ⊗[R] N) (y : N ⊗[R] M)
@[simp] theorem coe_lTensor : lTensor M f = (f : N →ₗ[R] P).lTensor M := rfl
@[simp] theorem coe_lTensor_symm : (lTensor M f).symm = (f.symm : P →ₗ[R] N).lTensor M := rfl
@[simp] theorem coe_rTensor : rTensor M f = (f : N →ₗ[R] P).rTensor M := rfl
@[simp] theorem coe_rTensor_symm : (rTensor M f).symm = (f.symm : P →ₗ[R] N).rTensor M := rfl
@[simp] theorem lTensor_tmul : f.lTensor M (m ⊗ₜ n) = m ⊗ₜ f n := rfl
@[simp] theorem lTensor_symm_tmul : (f.lTensor M).symm (m ⊗ₜ p) = m ⊗ₜ f.symm p := rfl
@[simp] theorem rTensor_tmul : f.rTensor M (n ⊗ₜ m) = f n ⊗ₜ m := rfl
@[simp] theorem rTensor_symm_tmul : (f.rTensor M).symm (p ⊗ₜ m) = f.symm p ⊗ₜ m := rfl
lemma comm_trans_rTensor_trans_comm_eq (g : N ≃ₗ[R] P) :
TensorProduct.comm R Q N ≪≫ₗ rTensor Q g ≪≫ₗ TensorProduct.comm R P Q = lTensor Q g :=
toLinearMap_injective <| TensorProduct.ext rfl
lemma comm_trans_lTensor_trans_comm_eq (g : N ≃ₗ[R] P) :
TensorProduct.comm R N Q ≪≫ₗ lTensor Q g ≪≫ₗ TensorProduct.comm R Q P = rTensor Q g :=
toLinearMap_injective <| TensorProduct.ext rfl
theorem lTensor_trans : (f ≪≫ₗ g).lTensor M = f.lTensor M ≪≫ₗ g.lTensor M :=
toLinearMap_injective <| LinearMap.lTensor_comp M _ _
theorem lTensor_trans_apply : (f ≪≫ₗ g).lTensor M x = g.lTensor M (f.lTensor M x) :=
LinearMap.lTensor_comp_apply M _ _ x
theorem rTensor_trans : (f ≪≫ₗ g).rTensor M = f.rTensor M ≪≫ₗ g.rTensor M :=
toLinearMap_injective <| LinearMap.rTensor_comp M _ _
theorem rTensor_trans_apply : (f ≪≫ₗ g).rTensor M y = g.rTensor M (f.rTensor M y) :=
LinearMap.rTensor_comp_apply M _ _ y
theorem lTensor_mul (f g : N ≃ₗ[R] N) : (f * g).lTensor M = f.lTensor M * g.lTensor M :=
lTensor_trans M f g
theorem rTensor_mul (f g : N ≃ₗ[R] N) : (f * g).rTensor M = f.rTensor M * g.rTensor M :=
rTensor_trans M f g
variable (N)
@[simp] theorem lTensor_refl : (refl R N).lTensor M = refl R _ := TensorProduct.congr_refl_refl
theorem lTensor_refl_apply : (refl R N).lTensor M x = x := by rw [lTensor_refl, refl_apply]
@[simp] theorem rTensor_refl : (refl R N).rTensor M = refl R _ := TensorProduct.congr_refl_refl
theorem rTensor_refl_apply : (refl R N).rTensor M y = y := by rw [rTensor_refl, refl_apply]
variable {N}
@[simp] theorem rTensor_trans_lTensor (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) :
f.rTensor N ≪≫ₗ g.lTensor P = TensorProduct.congr f g :=
toLinearMap_injective <| LinearMap.lTensor_comp_rTensor M _ _
@[simp] theorem lTensor_trans_rTensor (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) :
g.lTensor M ≪≫ₗ f.rTensor Q = TensorProduct.congr f g :=
toLinearMap_injective <| LinearMap.rTensor_comp_lTensor M _ _
@[simp] theorem rTensor_trans_congr (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) (f' : S ≃ₗ[R] M) :
f'.rTensor _ ≪≫ₗ TensorProduct.congr f g = TensorProduct.congr (f' ≪≫ₗ f) g :=
toLinearMap_injective <| LinearMap.map_comp_rTensor M _ _ _
@[simp] theorem lTensor_trans_congr (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) (g' : S ≃ₗ[R] N) :
g'.lTensor _ ≪≫ₗ TensorProduct.congr f g = TensorProduct.congr f (g' ≪≫ₗ g) :=
toLinearMap_injective <| LinearMap.map_comp_lTensor M _ _ _
@[simp] theorem congr_trans_rTensor (f' : P ≃ₗ[R] S) (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) :
TensorProduct.congr f g ≪≫ₗ f'.rTensor _ = TensorProduct.congr (f ≪≫ₗ f') g :=
toLinearMap_injective <| LinearMap.rTensor_comp_map M _ _ _
@[simp] theorem congr_trans_lTensor (g' : Q ≃ₗ[R] S) (f : M ≃ₗ[R] P) (g : N ≃ₗ[R] Q) :
TensorProduct.congr f g ≪≫ₗ g'.lTensor _ = TensorProduct.congr f (g ≪≫ₗ g') :=
toLinearMap_injective <| LinearMap.lTensor_comp_map M _ _ _
variable {M}
@[simp] theorem rTensor_pow (f : M ≃ₗ[R] M) (n : ℕ) : f.rTensor N ^ n = (f ^ n).rTensor N := by
simpa only [one_pow] using TensorProduct.congr_pow f (1 : N ≃ₗ[R] N) n
@[simp] theorem rTensor_zpow (f : M ≃ₗ[R] M) (n : ℤ) : f.rTensor N ^ n = (f ^ n).rTensor N := by
simpa only [one_zpow] using TensorProduct.congr_zpow f (1 : N ≃ₗ[R] N) n
@[simp] theorem lTensor_pow (f : N ≃ₗ[R] N) (n : ℕ) : f.lTensor M ^ n = (f ^ n).lTensor M := by
simpa only [one_pow] using TensorProduct.congr_pow (1 : M ≃ₗ[R] M) f n
@[simp] theorem lTensor_zpow (f : N ≃ₗ[R] N) (n : ℤ) : f.lTensor M ^ n = (f ^ n).lTensor M := by
simpa only [one_zpow] using TensorProduct.congr_zpow (1 : M ≃ₗ[R] M) f n
end LinearEquiv
end Semiring
section Ring
variable {R : Type*} [CommSemiring R]
variable {M : Type*} {N : Type*} {P : Type*} {Q : Type*} {S : Type*}
variable [AddCommGroup M] [AddCommGroup N] [AddCommGroup P] [AddCommGroup Q] [AddCommGroup S]
variable [Module R M] [Module R N] [Module R P] [Module R Q] [Module R S]
namespace TensorProduct
open TensorProduct
open LinearMap
variable (R) in
/-- Auxiliary function to defining negation multiplication on tensor product. -/
def Neg.aux : M ⊗[R] N →ₗ[R] M ⊗[R] N :=
lift <| (mk R M N).comp (-LinearMap.id)
instance neg : Neg (M ⊗[R] N) where
neg := Neg.aux R
protected theorem neg_add_cancel (x : M ⊗[R] N) : -x + x = 0 :=
x.induction_on
(by rw [add_zero]; apply (Neg.aux R).map_zero)
(fun x y => by convert (add_tmul (R := R) (-x) x y).symm; rw [neg_add_cancel, zero_tmul])
fun x y hx hy => by
suffices -x + x + (-y + y) = 0 by
rw [← this]
unfold Neg.neg neg
simp only
rw [map_add]
abel
rw [hx, hy, add_zero]
instance addCommGroup : AddCommGroup (M ⊗[R] N) :=
{ TensorProduct.addCommMonoid with
neg := Neg.neg
sub := _
sub_eq_add_neg := fun _ _ => rfl
neg_add_cancel := fun x => TensorProduct.neg_add_cancel x
zsmul := fun n v => n • v
zsmul_zero' := by simp [TensorProduct.zero_smul]
zsmul_succ' := by simp [add_comm, TensorProduct.one_smul, TensorProduct.add_smul]
zsmul_neg' := fun n x => by
change (-n.succ : ℤ) • x = -(((n : ℤ) + 1) • x)
rw [← zero_add (_ • x), ← TensorProduct.neg_add_cancel ((n.succ : ℤ) • x), add_assoc,
← add_smul, ← sub_eq_add_neg, sub_self, zero_smul, add_zero]
rfl }
theorem neg_tmul (m : M) (n : N) : (-m) ⊗ₜ n = -m ⊗ₜ[R] n :=
rfl
theorem tmul_neg (m : M) (n : N) : m ⊗ₜ (-n) = -m ⊗ₜ[R] n :=
(mk R M N _).map_neg _
theorem tmul_sub (m : M) (n₁ n₂ : N) : m ⊗ₜ (n₁ - n₂) = m ⊗ₜ[R] n₁ - m ⊗ₜ[R] n₂ :=
(mk R M N _).map_sub _ _
theorem sub_tmul (m₁ m₂ : M) (n : N) : (m₁ - m₂) ⊗ₜ n = m₁ ⊗ₜ[R] n - m₂ ⊗ₜ[R] n :=
(mk R M N).map_sub₂ _ _ _
/-- While the tensor product will automatically inherit a ℤ-module structure from
`AddCommGroup.toIntModule`, that structure won't be compatible with lemmas like `tmul_smul` unless
we use a `ℤ-Module` instance provided by `TensorProduct.left_module`.
When `R` is a `Ring` we get the required `TensorProduct.compatible_smul` instance through
`IsScalarTower`, but when it is only a `Semiring` we need to build it from scratch.
The instance diamond in `compatible_smul` doesn't matter because it's in `Prop`.
-/
instance CompatibleSMul.int : CompatibleSMul R ℤ M N :=
⟨fun r m n =>
Int.induction_on r (by simp) (fun r ih => by simpa [add_smul, tmul_add, add_tmul] using ih)
fun r ih => by simpa [sub_smul, tmul_sub, sub_tmul] using ih⟩
instance CompatibleSMul.unit {S} [Monoid S] [DistribMulAction S M] [DistribMulAction S N]
[CompatibleSMul R S M N] : CompatibleSMul R Sˣ M N :=
⟨fun s m n => CompatibleSMul.smul_tmul (s : S) m n⟩
end TensorProduct
namespace LinearMap
@[simp]
theorem lTensor_sub (f g : N →ₗ[R] P) : (f - g).lTensor M = f.lTensor M - g.lTensor M := by
simp_rw [← coe_lTensorHom]
exact (lTensorHom (R := R) (N := N) (P := P) M).map_sub f g
@[simp]
theorem rTensor_sub (f g : N →ₗ[R] P) : (f - g).rTensor M = f.rTensor M - g.rTensor M := by
simp only [← coe_rTensorHom]
exact (rTensorHom (R := R) (N := N) (P := P) M).map_sub f g
@[simp]
theorem lTensor_neg (f : N →ₗ[R] P) : (-f).lTensor M = -f.lTensor M := by
simp only [← coe_lTensorHom]
exact (lTensorHom (R := R) (N := N) (P := P) M).map_neg f
@[simp]
theorem rTensor_neg (f : N →ₗ[R] P) : (-f).rTensor M = -f.rTensor M := by
simp only [← coe_rTensorHom]
exact (rTensorHom (R := R) (N := N) (P := P) M).map_neg f
end LinearMap
end Ring
| Mathlib/LinearAlgebra/TensorProduct/Basic.lean | 1,502 | 1,503 | |
/-
Copyright (c) 2019 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov
-/
import Mathlib.Analysis.Calculus.Deriv.Add
/-!
# Local extrema of differentiable functions
## Main definitions
In a real normed space `E` we define `posTangentConeAt (s : Set E) (x : E)`.
This would be the same as `tangentConeAt ℝ≥0 s x` if we had a theory of normed semifields.
This set is used in the proof of Fermat's Theorem (see below), and can be used to formalize
[Lagrange multipliers](https://en.wikipedia.org/wiki/Lagrange_multiplier) and/or
[Karush–Kuhn–Tucker conditions](https://en.wikipedia.org/wiki/Karush–Kuhn–Tucker_conditions).
## Main statements
For each theorem name listed below,
we also prove similar theorems for `min`, `extr` (if applicable),
and `fderiv`/`deriv` instead of `HasFDerivAt`/`HasDerivAt`.
* `IsLocalMaxOn.hasFDerivWithinAt_nonpos` : `f' y ≤ 0` whenever `a` is a local maximum
of `f` on `s`, `f` has derivative `f'` at `a` within `s`, and `y` belongs to the positive tangent
cone of `s` at `a`.
* `IsLocalMaxOn.hasFDerivWithinAt_eq_zero` : In the settings of the previous theorem, if both
`y` and `-y` belong to the positive tangent cone, then `f' y = 0`.
* `IsLocalMax.hasFDerivAt_eq_zero` :
[Fermat's Theorem](https://en.wikipedia.org/wiki/Fermat's_theorem_(stationary_points)),
the derivative of a differentiable function at a local extremum point equals zero.
## Implementation notes
For each mathematical fact we prove several versions of its formalization:
* for maxima and minima;
* using `HasFDeriv*`/`HasDeriv*` or `fderiv*`/`deriv*`.
For the `fderiv*`/`deriv*` versions we omit the differentiability condition whenever it is possible
due to the fact that `fderiv` and `deriv` are defined to be zero for non-differentiable functions.
## References
* [Fermat's Theorem](https://en.wikipedia.org/wiki/Fermat's_theorem_(stationary_points));
* [Tangent cone](https://en.wikipedia.org/wiki/Tangent_cone);
## Tags
local extremum, tangent cone, Fermat's Theorem
-/
universe u v
open Filter Set
open scoped Topology Convex
section Module
variable {E : Type u} [NormedAddCommGroup E] [NormedSpace ℝ E]
{f : E → ℝ} {f' : E →L[ℝ] ℝ} {s : Set E} {a x y : E}
/-!
### Positive tangent cone
-/
/-- "Positive" tangent cone to `s` at `x`; the only difference from `tangentConeAt`
is that we require `c n → ∞` instead of `‖c n‖ → ∞`. One can think about `posTangentConeAt`
as `tangentConeAt NNReal` but we have no theory of normed semifields yet. -/
def posTangentConeAt (s : Set E) (x : E) : Set E :=
{ y : E | ∃ (c : ℕ → ℝ) (d : ℕ → E), (∀ᶠ n in atTop, x + d n ∈ s) ∧
Tendsto c atTop atTop ∧ Tendsto (fun n => c n • d n) atTop (𝓝 y) }
theorem posTangentConeAt_mono : Monotone fun s => posTangentConeAt s a := by
rintro s t hst y ⟨c, d, hd, hc, hcd⟩
exact ⟨c, d, mem_of_superset hd fun h hn => hst hn, hc, hcd⟩
theorem mem_posTangentConeAt_of_frequently_mem (h : ∃ᶠ t : ℝ in 𝓝[>] 0, x + t • y ∈ s) :
y ∈ posTangentConeAt s x := by
obtain ⟨a, ha, has⟩ := Filter.exists_seq_forall_of_frequently h
refine ⟨a⁻¹, (a · • y), Eventually.of_forall has, tendsto_inv_nhdsGT_zero.comp ha, ?_⟩
refine tendsto_const_nhds.congr' ?_
filter_upwards [(tendsto_nhdsWithin_iff.1 ha).2] with n (hn : 0 < a n)
simp [ne_of_gt hn]
/-- If `[x -[ℝ] x + y] ⊆ s`, then `y` belongs to the positive tangnet cone of `s`.
Before 2024-07-13, this lemma used to be called `mem_posTangentConeAt_of_segment_subset`.
See also `sub_mem_posTangentConeAt_of_segment_subset`
for the lemma that used to be called `mem_posTangentConeAt_of_segment_subset`. -/
theorem mem_posTangentConeAt_of_segment_subset (h : [x -[ℝ] x + y] ⊆ s) :
y ∈ posTangentConeAt s x := by
refine mem_posTangentConeAt_of_frequently_mem (Eventually.frequently ?_)
rw [eventually_nhdsWithin_iff]
filter_upwards [ge_mem_nhds one_pos] with t ht₁ ht₀
apply h
rw [segment_eq_image', add_sub_cancel_left]
exact mem_image_of_mem _ ⟨le_of_lt ht₀, ht₁⟩
theorem sub_mem_posTangentConeAt_of_segment_subset (h : segment ℝ x y ⊆ s) :
y - x ∈ posTangentConeAt s x :=
mem_posTangentConeAt_of_segment_subset <| by rwa [add_sub_cancel]
@[simp]
theorem posTangentConeAt_univ : posTangentConeAt univ a = univ :=
eq_univ_of_forall fun _ => mem_posTangentConeAt_of_segment_subset (subset_univ _)
/-!
### Fermat's Theorem (vector space)
-/
/-- If `f` has a local max on `s` at `a`, `f'` is the derivative of `f` at `a` within `s`, and
`y` belongs to the positive tangent cone of `s` at `a`, then `f' y ≤ 0`. -/
theorem IsLocalMaxOn.hasFDerivWithinAt_nonpos (h : IsLocalMaxOn f s a)
(hf : HasFDerivWithinAt f f' s a) (hy : y ∈ posTangentConeAt s a) : f' y ≤ 0 := by
rcases hy with ⟨c, d, hd, hc, hcd⟩
have hc' : Tendsto (‖c ·‖) atTop atTop := tendsto_abs_atTop_atTop.comp hc
suffices ∀ᶠ n in atTop, c n • (f (a + d n) - f a) ≤ 0 from
le_of_tendsto (hf.lim atTop hd hc' hcd) this
replace hd : Tendsto (fun n => a + d n) atTop (𝓝[s] (a + 0)) :=
tendsto_nhdsWithin_iff.2 ⟨tendsto_const_nhds.add (tangentConeAt.lim_zero _ hc' hcd), hd⟩
rw [add_zero] at hd
filter_upwards [hd.eventually h, hc.eventually_ge_atTop 0] with n hfn hcn
exact mul_nonpos_of_nonneg_of_nonpos hcn (sub_nonpos.2 hfn)
/-- If `f` has a local max on `s` at `a` and `y` belongs to the positive tangent cone
of `s` at `a`, then `f' y ≤ 0`. -/
theorem IsLocalMaxOn.fderivWithin_nonpos (h : IsLocalMaxOn f s a)
(hy : y ∈ posTangentConeAt s a) : (fderivWithin ℝ f s a : E → ℝ) y ≤ 0 := by
classical
exact
if hf : DifferentiableWithinAt ℝ f s a then h.hasFDerivWithinAt_nonpos hf.hasFDerivWithinAt hy
else by rw [fderivWithin_zero_of_not_differentiableWithinAt hf]; rfl
/-- If `f` has a local max on `s` at `a`, `f'` is a derivative of `f` at `a` within `s`, and
both `y` and `-y` belong to the positive tangent cone of `s` at `a`, then `f' y ≤ 0`. -/
theorem IsLocalMaxOn.hasFDerivWithinAt_eq_zero (h : IsLocalMaxOn f s a)
(hf : HasFDerivWithinAt f f' s a) (hy : y ∈ posTangentConeAt s a)
(hy' : -y ∈ posTangentConeAt s a) : f' y = 0 :=
le_antisymm (h.hasFDerivWithinAt_nonpos hf hy) <| by simpa using h.hasFDerivWithinAt_nonpos hf hy'
/-- If `f` has a local max on `s` at `a` and both `y` and `-y` belong to the positive tangent cone
of `s` at `a`, then `f' y = 0`. -/
theorem IsLocalMaxOn.fderivWithin_eq_zero (h : IsLocalMaxOn f s a)
(hy : y ∈ posTangentConeAt s a) (hy' : -y ∈ posTangentConeAt s a) :
(fderivWithin ℝ f s a : E → ℝ) y = 0 := by
classical
exact if hf : DifferentiableWithinAt ℝ f s a then
h.hasFDerivWithinAt_eq_zero hf.hasFDerivWithinAt hy hy'
else by rw [fderivWithin_zero_of_not_differentiableWithinAt hf]; rfl
/-- If `f` has a local min on `s` at `a`, `f'` is the derivative of `f` at `a` within `s`, and
`y` belongs to the positive tangent cone of `s` at `a`, then `0 ≤ f' y`. -/
theorem IsLocalMinOn.hasFDerivWithinAt_nonneg (h : IsLocalMinOn f s a)
(hf : HasFDerivWithinAt f f' s a) (hy : y ∈ posTangentConeAt s a) : 0 ≤ f' y := by
simpa using h.neg.hasFDerivWithinAt_nonpos hf.neg hy
|
/-- If `f` has a local min on `s` at `a` and `y` belongs to the positive tangent cone
of `s` at `a`, then `0 ≤ f' y`. -/
theorem IsLocalMinOn.fderivWithin_nonneg (h : IsLocalMinOn f s a)
| Mathlib/Analysis/Calculus/LocalExtr/Basic.lean | 162 | 165 |
/-
Copyright (c) 2021 Oliver Nash. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Oliver Nash
-/
import Mathlib.Algebra.Lie.Abelian
import Mathlib.Algebra.Lie.BaseChange
import Mathlib.Algebra.Lie.IdealOperations
import Mathlib.Order.Hom.Basic
import Mathlib.RingTheory.Flat.FaithfullyFlat.Basic
/-!
# Solvable Lie algebras
Like groups, Lie algebras admit a natural concept of solvability. We define this here via the
derived series and prove some related results. We also define the radical of a Lie algebra and
prove that it is solvable when the Lie algebra is Noetherian.
## Main definitions
* `LieAlgebra.derivedSeriesOfIdeal`
* `LieAlgebra.derivedSeries`
* `LieAlgebra.IsSolvable`
* `LieAlgebra.isSolvableAdd`
* `LieAlgebra.radical`
* `LieAlgebra.radicalIsSolvable`
* `LieAlgebra.derivedLengthOfIdeal`
* `LieAlgebra.derivedLength`
* `LieAlgebra.derivedAbelianOfIdeal`
## Tags
lie algebra, derived series, derived length, solvable, radical
-/
universe u v w w₁ w₂
variable (R : Type u) (L : Type v) (M : Type w) {L' : Type w₁}
variable [CommRing R] [LieRing L] [LieAlgebra R L] [LieRing L'] [LieAlgebra R L']
variable (I J : LieIdeal R L) {f : L' →ₗ⁅R⁆ L}
namespace LieAlgebra
/-- A generalisation of the derived series of a Lie algebra, whose zeroth term is a specified ideal.
It can be more convenient to work with this generalisation when considering the derived series of
an ideal since it provides a type-theoretic expression of the fact that the terms of the ideal's
derived series are also ideals of the enclosing algebra.
See also `LieIdeal.derivedSeries_eq_derivedSeriesOfIdeal_comap` and
`LieIdeal.derivedSeries_eq_derivedSeriesOfIdeal_map` below. -/
def derivedSeriesOfIdeal (k : ℕ) : LieIdeal R L → LieIdeal R L :=
(fun I => ⁅I, I⁆)^[k]
@[simp]
theorem derivedSeriesOfIdeal_zero : derivedSeriesOfIdeal R L 0 I = I :=
rfl
@[simp]
theorem derivedSeriesOfIdeal_succ (k : ℕ) :
derivedSeriesOfIdeal R L (k + 1) I =
⁅derivedSeriesOfIdeal R L k I, derivedSeriesOfIdeal R L k I⁆ :=
Function.iterate_succ_apply' (fun I => ⁅I, I⁆) k I
/-- The derived series of Lie ideals of a Lie algebra. -/
abbrev derivedSeries (k : ℕ) : LieIdeal R L :=
derivedSeriesOfIdeal R L k ⊤
theorem derivedSeries_def (k : ℕ) : derivedSeries R L k = derivedSeriesOfIdeal R L k ⊤ :=
rfl
variable {R L}
local notation "D" => derivedSeriesOfIdeal R L
theorem derivedSeriesOfIdeal_add (k l : ℕ) : D (k + l) I = D k (D l I) := by
induction k with
| zero => rw [Nat.zero_add, derivedSeriesOfIdeal_zero]
| succ k ih => rw [Nat.succ_add k l, derivedSeriesOfIdeal_succ, derivedSeriesOfIdeal_succ, ih]
@[gcongr, mono]
theorem derivedSeriesOfIdeal_le {I J : LieIdeal R L} {k l : ℕ} (h₁ : I ≤ J) (h₂ : l ≤ k) :
D k I ≤ D l J := by
revert l; induction' k with k ih <;> intro l h₂
· rw [le_zero_iff] at h₂; rw [h₂, derivedSeriesOfIdeal_zero]; exact h₁
· have h : l = k.succ ∨ l ≤ k := by rwa [le_iff_eq_or_lt, Nat.lt_succ_iff] at h₂
rcases h with h | h
· rw [h, derivedSeriesOfIdeal_succ, derivedSeriesOfIdeal_succ]
exact LieSubmodule.mono_lie (ih (le_refl k)) (ih (le_refl k))
· rw [derivedSeriesOfIdeal_succ]; exact le_trans (LieSubmodule.lie_le_left _ _) (ih h)
theorem derivedSeriesOfIdeal_succ_le (k : ℕ) : D (k + 1) I ≤ D k I :=
derivedSeriesOfIdeal_le (le_refl I) k.le_succ
theorem derivedSeriesOfIdeal_le_self (k : ℕ) : D k I ≤ I :=
derivedSeriesOfIdeal_le (le_refl I) (zero_le k)
theorem derivedSeriesOfIdeal_mono {I J : LieIdeal R L} (h : I ≤ J) (k : ℕ) : D k I ≤ D k J :=
derivedSeriesOfIdeal_le h (le_refl k)
theorem derivedSeriesOfIdeal_antitone {k l : ℕ} (h : l ≤ k) : D k I ≤ D l I :=
derivedSeriesOfIdeal_le (le_refl I) h
theorem derivedSeriesOfIdeal_add_le_add (J : LieIdeal R L) (k l : ℕ) :
D (k + l) (I + J) ≤ D k I + D l J := by
let D₁ : LieIdeal R L →o LieIdeal R L :=
{ toFun := fun I => ⁅I, I⁆
monotone' := fun I J h => LieSubmodule.mono_lie h h }
have h₁ : ∀ I J : LieIdeal R L, D₁ (I ⊔ J) ≤ D₁ I ⊔ J := by
simp [D₁, LieSubmodule.lie_le_right, LieSubmodule.lie_le_left, le_sup_of_le_right]
rw [← D₁.iterate_sup_le_sup_iff] at h₁
exact h₁ k l I J
theorem derivedSeries_of_bot_eq_bot (k : ℕ) : derivedSeriesOfIdeal R L k ⊥ = ⊥ := by
rw [eq_bot_iff]; exact derivedSeriesOfIdeal_le_self ⊥ k
theorem abelian_iff_derived_one_eq_bot : IsLieAbelian I ↔ derivedSeriesOfIdeal R L 1 I = ⊥ := by
rw [derivedSeriesOfIdeal_succ, derivedSeriesOfIdeal_zero,
LieSubmodule.lie_abelian_iff_lie_self_eq_bot]
theorem abelian_iff_derived_succ_eq_bot (I : LieIdeal R L) (k : ℕ) :
IsLieAbelian (derivedSeriesOfIdeal R L k I) ↔ derivedSeriesOfIdeal R L (k + 1) I = ⊥ := by
rw [add_comm, derivedSeriesOfIdeal_add I 1 k, abelian_iff_derived_one_eq_bot]
open TensorProduct in
@[simp] theorem derivedSeriesOfIdeal_baseChange {A : Type*} [CommRing A] [Algebra R A] (k : ℕ) :
derivedSeriesOfIdeal A (A ⊗[R] L) k (I.baseChange A) =
(derivedSeriesOfIdeal R L k I).baseChange A := by
induction k with
| zero => simp
| succ k ih => simp only [derivedSeriesOfIdeal_succ, ih, ← LieSubmodule.baseChange_top,
LieSubmodule.lie_baseChange]
open TensorProduct in
@[simp] theorem derivedSeries_baseChange {A : Type*} [CommRing A] [Algebra R A] (k : ℕ) :
derivedSeries A (A ⊗[R] L) k = (derivedSeries R L k).baseChange A := by
rw [derivedSeries_def, derivedSeries_def, ← derivedSeriesOfIdeal_baseChange,
LieSubmodule.baseChange_top]
end LieAlgebra
namespace LieIdeal
open LieAlgebra
variable {R L}
theorem derivedSeries_eq_derivedSeriesOfIdeal_comap (k : ℕ) :
derivedSeries R I k = (derivedSeriesOfIdeal R L k I).comap I.incl := by
induction k with
| zero => simp only [derivedSeries_def, comap_incl_self, derivedSeriesOfIdeal_zero]
| succ k ih =>
simp only [derivedSeries_def, derivedSeriesOfIdeal_succ] at ih ⊢; rw [ih]
exact comap_bracket_incl_of_le I (derivedSeriesOfIdeal_le_self I k)
(derivedSeriesOfIdeal_le_self I k)
theorem derivedSeries_eq_derivedSeriesOfIdeal_map (k : ℕ) :
(derivedSeries R I k).map I.incl = derivedSeriesOfIdeal R L k I := by
rw [derivedSeries_eq_derivedSeriesOfIdeal_comap, map_comap_incl, inf_eq_right]
apply derivedSeriesOfIdeal_le_self
theorem derivedSeries_eq_bot_iff (k : ℕ) :
derivedSeries R I k = ⊥ ↔ derivedSeriesOfIdeal R L k I = ⊥ := by
rw [← derivedSeries_eq_derivedSeriesOfIdeal_map, map_eq_bot_iff, ker_incl, eq_bot_iff]
theorem derivedSeries_add_eq_bot {k l : ℕ} {I J : LieIdeal R L} (hI : derivedSeries R I k = ⊥)
(hJ : derivedSeries R J l = ⊥) : derivedSeries R (I + J) (k + l) = ⊥ := by
rw [LieIdeal.derivedSeries_eq_bot_iff] at hI hJ ⊢
rw [← le_bot_iff]
let D := derivedSeriesOfIdeal R L; change D k I = ⊥ at hI; change D l J = ⊥ at hJ
calc
D (k + l) (I + J) ≤ D k I + D l J := derivedSeriesOfIdeal_add_le_add I J k l
_ ≤ ⊥ := by rw [hI, hJ]; simp
theorem derivedSeries_map_le (k : ℕ) : (derivedSeries R L' k).map f ≤ derivedSeries R L k := by
induction k with
| zero => simp only [derivedSeries_def, derivedSeriesOfIdeal_zero, le_top]
| succ k ih =>
simp only [derivedSeries_def, derivedSeriesOfIdeal_succ] at ih ⊢
exact le_trans (map_bracket_le f) (LieSubmodule.mono_lie ih ih)
theorem derivedSeries_map_eq (k : ℕ) (h : Function.Surjective f) :
(derivedSeries R L' k).map f = derivedSeries R L k := by
induction k with
| zero =>
change (⊤ : LieIdeal R L').map f = ⊤
rw [← f.idealRange_eq_map]
exact f.idealRange_eq_top_of_surjective h
| succ k ih => simp only [derivedSeries_def, map_bracket_eq f h, ih, derivedSeriesOfIdeal_succ]
theorem derivedSeries_succ_eq_top_iff (n : ℕ) :
derivedSeries R L (n + 1) = ⊤ ↔ derivedSeries R L 1 = ⊤ := by
simp only [derivedSeries_def]
induction n with
| zero => simp
| succ n ih =>
rw [derivedSeriesOfIdeal_succ]
refine ⟨fun h ↦ ?_, fun h ↦ by rwa [ih.mpr h]⟩
rw [← ih, eq_top_iff]
conv_lhs => rw [← h]
exact LieSubmodule.lie_le_right _ _
theorem derivedSeries_eq_top (n : ℕ) (h : derivedSeries R L 1 = ⊤) :
derivedSeries R L n = ⊤ := by
cases n
· rfl
· rwa [derivedSeries_succ_eq_top_iff]
private theorem coe_derivedSeries_eq_int_aux (R₁ R₂ L : Type*) [CommRing R₁] [CommRing R₂]
[LieRing L] [LieAlgebra R₁ L] [LieAlgebra R₂ L] (k : ℕ)
(ih : ∀ (x : L), x ∈ derivedSeriesOfIdeal R₁ L k ⊤ ↔ x ∈ derivedSeriesOfIdeal R₂ L k ⊤) :
let I := derivedSeriesOfIdeal R₂ L k ⊤; let S : Set L := {⁅a, b⁆ | (a ∈ I) (b ∈ I)}
(Submodule.span R₁ S : Set L) ≤ (Submodule.span R₂ S : Set L) := by
intro I S x hx
simp only [SetLike.mem_coe] at hx ⊢
induction hx using Submodule.closure_induction with
| zero => exact Submodule.zero_mem _
| add y z hy₁ hz₁ hy₂ hz₂ => exact Submodule.add_mem _ hy₂ hz₂
| smul_mem c y hy =>
obtain ⟨a, ha, b, hb, rfl⟩ := hy
rw [← smul_lie]
refine Submodule.subset_span ⟨c • a, ?_, b, hb, rfl⟩
rw [← ih] at ha ⊢
exact Submodule.smul_mem _ _ ha
theorem coe_derivedSeries_eq_int (k : ℕ) :
(derivedSeries R L k : Set L) = (derivedSeries ℤ L k : Set L) := by
rw [← LieSubmodule.coe_toSubmodule, ← LieSubmodule.coe_toSubmodule, derivedSeries_def,
derivedSeries_def]
induction k with
| zero => rfl
| succ k ih =>
rw [derivedSeriesOfIdeal_succ, derivedSeriesOfIdeal_succ]
rw [LieSubmodule.lieIdeal_oper_eq_linear_span', LieSubmodule.lieIdeal_oper_eq_linear_span']
rw [Set.ext_iff] at ih
simp only [SetLike.mem_coe, LieSubmodule.mem_toSubmodule] at ih
simp only [Subtype.exists, exists_prop, ih]
apply le_antisymm
· exact coe_derivedSeries_eq_int_aux _ _ L k ih
· simp only [← ih]
apply coe_derivedSeries_eq_int_aux _ _ L k
simp [ih]
end LieIdeal
namespace LieAlgebra
/-- A Lie algebra is solvable if its derived series reaches 0 (in a finite number of steps). -/
@[mk_iff isSolvable_iff_int]
class IsSolvable : Prop where
mk_int ::
solvable_int : ∃ k, derivedSeries ℤ L k = ⊥
instance isSolvableBot : IsSolvable (⊥ : LieIdeal R L) :=
⟨⟨0, Subsingleton.elim _ ⊥⟩⟩
lemma isSolvable_iff : IsSolvable L ↔ ∃ k, derivedSeries R L k = ⊥ := by
simp [isSolvable_iff_int, SetLike.ext'_iff, LieIdeal.coe_derivedSeries_eq_int]
lemma IsSolvable.solvable [IsSolvable L] : ∃ k, derivedSeries R L k = ⊥ :=
(isSolvable_iff R L).mp ‹_›
variable {R L} in
lemma IsSolvable.mk {k : ℕ} (h : derivedSeries R L k = ⊥) : IsSolvable L :=
(isSolvable_iff R L).mpr ⟨k, h⟩
instance isSolvableAdd {I J : LieIdeal R L} [IsSolvable I] [IsSolvable J] :
IsSolvable (I + J) := by
obtain ⟨k, hk⟩ := IsSolvable.solvable R I
obtain ⟨l, hl⟩ := IsSolvable.solvable R J
exact IsSolvable.mk (LieIdeal.derivedSeries_add_eq_bot hk hl)
theorem derivedSeries_lt_top_of_solvable [IsSolvable L] [Nontrivial L] :
derivedSeries R L 1 < ⊤ := by
obtain ⟨n, hn⟩ := IsSolvable.solvable (R := R) (L := L)
rw [lt_top_iff_ne_top]
intro contra
rw [LieIdeal.derivedSeries_eq_top n contra] at hn
exact top_ne_bot hn
open TensorProduct in
instance {A : Type*} [CommRing A] [Algebra R A] [IsSolvable L] : IsSolvable (A ⊗[R] L) := by
obtain ⟨k, hk⟩ := IsSolvable.solvable R L
rw [isSolvable_iff A]
use k
rw [derivedSeries_baseChange, hk, LieSubmodule.baseChange_bot]
open TensorProduct in
variable {A : Type*} [CommRing A] [Algebra R A] [Module.FaithfullyFlat R A] in
theorem isSolvable_tensorProduct_iff : IsSolvable (A ⊗[R] L) ↔ IsSolvable L := by
refine ⟨?_, fun _ ↦ inferInstance⟩
rw [isSolvable_iff A, isSolvable_iff R]
rintro ⟨k, h⟩
use k
rw [eq_bot_iff] at h ⊢
intro x hx
rw [derivedSeries_baseChange] at h
specialize h <| Submodule.tmul_mem_baseChange_of_mem 1 hx
rw [LieSubmodule.mem_bot] at h ⊢
rwa [Module.FaithfullyFlat.one_tmul_eq_zero_iff] at h
end LieAlgebra
variable {R L}
namespace Function
open LieAlgebra
theorem Injective.lieAlgebra_isSolvable [hL : IsSolvable L] (h : Injective f) :
IsSolvable L' := by
rw [isSolvable_iff R] at hL ⊢
apply hL.imp
intro k hk
apply LieIdeal.bot_of_map_eq_bot h; rw [eq_bot_iff, ← hk]
apply LieIdeal.derivedSeries_map_le
instance (A : LieIdeal R L) [IsSolvable L] : IsSolvable A :=
A.incl_injective.lieAlgebra_isSolvable
theorem Surjective.lieAlgebra_isSolvable [hL' : IsSolvable L'] (h : Surjective f) :
IsSolvable L := by
rw [isSolvable_iff R] at hL' ⊢
apply hL'.imp
intro k hk
rw [← LieIdeal.derivedSeries_map_eq k h, hk]
simp only [LieIdeal.map_eq_bot_iff, bot_le]
end Function
instance LieHom.isSolvable_range (f : L' →ₗ⁅R⁆ L) [LieAlgebra.IsSolvable L'] :
LieAlgebra.IsSolvable f.range :=
f.surjective_rangeRestrict.lieAlgebra_isSolvable
namespace LieAlgebra
theorem solvable_iff_equiv_solvable (e : L' ≃ₗ⁅R⁆ L) : IsSolvable L' ↔ IsSolvable L := by
constructor <;> intro h
· exact e.symm.injective.lieAlgebra_isSolvable
· exact e.injective.lieAlgebra_isSolvable
theorem le_solvable_ideal_solvable {I J : LieIdeal R L} (h₁ : I ≤ J) (_ : IsSolvable J) :
IsSolvable I :=
(LieIdeal.inclusion_injective h₁).lieAlgebra_isSolvable
variable (R L)
|
instance (priority := 100) ofAbelianIsSolvable [IsLieAbelian L] : IsSolvable L := by
use 1
rw [← abelian_iff_derived_one_eq_bot, lie_abelian_iff_equiv_lie_abelian LieIdeal.topEquiv]
infer_instance
| Mathlib/Algebra/Lie/Solvable.lean | 348 | 353 |
/-
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.MFDeriv.Defs
import Mathlib.Geometry.Manifold.ContMDiff.Defs
/-!
# Basic properties of the manifold Fréchet derivative
In this file, we show various properties of the manifold Fréchet derivative,
mimicking the API for Fréchet derivatives.
- basic properties of unique differentiability sets
- various general lemmas about the manifold Fréchet derivative
- deducing differentiability from smoothness,
- deriving continuity from differentiability on manifolds,
- congruence lemmas for derivatives on manifolds
- composition lemmas and the chain rule
-/
noncomputable section
assert_not_exists tangentBundleCore
open scoped Topology Manifold
open Set Bundle ChartedSpace
section DerivativesProperties
/-! ### Unique differentiability sets in manifolds -/
variable
{𝕜 : Type*} [NontriviallyNormedField 𝕜]
{E : Type*} [NormedAddCommGroup E] [NormedSpace 𝕜 E]
{H : Type*} [TopologicalSpace H] (I : ModelWithCorners 𝕜 E H)
{M : Type*} [TopologicalSpace M] [ChartedSpace H M]
{E' : Type*} [NormedAddCommGroup E'] [NormedSpace 𝕜 E']
{H' : Type*} [TopologicalSpace H'] {I' : ModelWithCorners 𝕜 E' H'}
{M' : Type*} [TopologicalSpace M'] [ChartedSpace H' M']
{E'' : Type*} [NormedAddCommGroup E''] [NormedSpace 𝕜 E'']
{H'' : Type*} [TopologicalSpace H''] {I'' : ModelWithCorners 𝕜 E'' H''}
{M'' : Type*} [TopologicalSpace M''] [ChartedSpace H'' M'']
{f f₁ : M → M'} {x : M} {s t : Set M} {g : M' → M''} {u : Set M'}
theorem uniqueMDiffWithinAt_univ : UniqueMDiffWithinAt I univ x := by
unfold UniqueMDiffWithinAt
simp only [preimage_univ, univ_inter]
exact I.uniqueDiffOn _ (mem_range_self _)
variable {I}
theorem uniqueMDiffWithinAt_iff_inter_range {s : Set M} {x : M} :
UniqueMDiffWithinAt I s x ↔
UniqueDiffWithinAt 𝕜 ((extChartAt I x).symm ⁻¹' s ∩ range I)
((extChartAt I x) x) := Iff.rfl
theorem uniqueMDiffWithinAt_iff {s : Set M} {x : M} :
UniqueMDiffWithinAt I s x ↔
UniqueDiffWithinAt 𝕜 ((extChartAt I x).symm ⁻¹' s ∩ (extChartAt I x).target)
| ((extChartAt I x) x) := by
apply uniqueDiffWithinAt_congr
rw [nhdsWithin_inter, nhdsWithin_inter, nhdsWithin_extChartAt_target_eq]
| Mathlib/Geometry/Manifold/MFDeriv/Basic.lean | 62 | 64 |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker, Andrew Yang, Yuyang Zhao
-/
import Mathlib.Algebra.Polynomial.Monic
import Mathlib.RingTheory.Polynomial.ScaleRoots
/-!
# Theory of monic polynomials
We define `integralNormalization`, which relate arbitrary polynomials to monic ones.
-/
open Polynomial
namespace Polynomial
universe u v y
variable {R : Type u} {S : Type v} {a b : R} {m n : ℕ} {ι : Type y}
section IntegralNormalization
section Semiring
variable [Semiring R]
/-- If `p : R[X]` is a nonzero polynomial with root `z`, `integralNormalization p` is
a monic polynomial with root `leadingCoeff f * z`.
Moreover, `integralNormalization 0 = 0`.
-/
noncomputable def integralNormalization (p : R[X]) : R[X] :=
p.sum fun i a ↦
monomial i (if p.degree = i then 1 else a * p.leadingCoeff ^ (p.natDegree - 1 - i))
@[simp]
theorem integralNormalization_zero : integralNormalization (0 : R[X]) = 0 := by
simp [integralNormalization]
@[simp]
theorem integralNormalization_C {x : R} (hx : x ≠ 0) : integralNormalization (C x) = 1 := by
simp [integralNormalization, sum_def, support_C hx, degree_C hx]
variable {p : R[X]}
theorem integralNormalization_coeff {i : ℕ} :
(integralNormalization p).coeff i =
if p.degree = i then 1 else coeff p i * p.leadingCoeff ^ (p.natDegree - 1 - i) := by
have : p.coeff i = 0 → p.degree ≠ i := fun hc hd => coeff_ne_zero_of_eq_degree hd hc
simp +contextual [sum_def, integralNormalization, coeff_monomial, this,
mem_support_iff]
theorem support_integralNormalization_subset :
(integralNormalization p).support ⊆ p.support := by
intro
simp +contextual [sum_def, integralNormalization, coeff_monomial, mem_support_iff]
@[deprecated (since := "2024-11-30")]
alias integralNormalization_support := support_integralNormalization_subset
theorem integralNormalization_coeff_degree {i : ℕ} (hi : p.degree = i) :
(integralNormalization p).coeff i = 1 := by rw [integralNormalization_coeff, if_pos hi]
theorem integralNormalization_coeff_natDegree (hp : p ≠ 0) :
(integralNormalization p).coeff (natDegree p) = 1 :=
integralNormalization_coeff_degree (degree_eq_natDegree hp)
| theorem integralNormalization_coeff_degree_ne {i : ℕ} (hi : p.degree ≠ i) :
coeff (integralNormalization p) i = coeff p i * p.leadingCoeff ^ (p.natDegree - 1 - i) := by
rw [integralNormalization_coeff, if_neg hi]
| Mathlib/RingTheory/Polynomial/IntegralNormalization.lean | 71 | 73 |
/-
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.Algebra.BigOperators.Ring.Finset
import Mathlib.Algebra.Module.BigOperators
import Mathlib.NumberTheory.Divisors
import Mathlib.Data.Nat.Squarefree
import Mathlib.Data.Nat.GCD.BigOperators
import Mathlib.Data.Nat.Factorization.Induction
import Mathlib.Tactic.ArithMult
/-!
# Arithmetic Functions and Dirichlet Convolution
This file defines arithmetic functions, which are functions from `ℕ` to a specified type that map 0
to 0. In the literature, they are often instead defined as functions from `ℕ+`. These arithmetic
functions are endowed with a multiplication, given by Dirichlet convolution, and pointwise addition,
to form the Dirichlet ring.
## Main Definitions
* `ArithmeticFunction R` consists of functions `f : ℕ → R` such that `f 0 = 0`.
* An arithmetic function `f` `IsMultiplicative` when `x.Coprime y → f (x * y) = f x * f y`.
* The pointwise operations `pmul` and `ppow` differ from the multiplication
and power instances on `ArithmeticFunction R`, which use Dirichlet multiplication.
* `ζ` is the arithmetic function such that `ζ x = 1` for `0 < x`.
* `σ k` is the arithmetic function such that `σ k x = ∑ y ∈ divisors x, y ^ k` for `0 < x`.
* `pow k` is the arithmetic function such that `pow k x = x ^ k` for `0 < x`.
* `id` is the identity arithmetic function on `ℕ`.
* `ω n` is the number of distinct prime factors of `n`.
* `Ω n` is the number of prime factors of `n` counted with multiplicity.
* `μ` is the Möbius function (spelled `moebius` in code).
## Main Results
* Several forms of Möbius inversion:
* `sum_eq_iff_sum_mul_moebius_eq` for functions to a `CommRing`
* `sum_eq_iff_sum_smul_moebius_eq` for functions to an `AddCommGroup`
* `prod_eq_iff_prod_pow_moebius_eq` for functions to a `CommGroup`
* `prod_eq_iff_prod_pow_moebius_eq_of_nonzero` for functions to a `CommGroupWithZero`
* And variants that apply when the equalities only hold on a set `S : Set ℕ` such that
`m ∣ n → n ∈ S → m ∈ S`:
* `sum_eq_iff_sum_mul_moebius_eq_on` for functions to a `CommRing`
* `sum_eq_iff_sum_smul_moebius_eq_on` for functions to an `AddCommGroup`
* `prod_eq_iff_prod_pow_moebius_eq_on` for functions to a `CommGroup`
* `prod_eq_iff_prod_pow_moebius_eq_on_of_nonzero` for functions to a `CommGroupWithZero`
## Notation
All notation is localized in the namespace `ArithmeticFunction`.
The arithmetic functions `ζ`, `σ`, `ω`, `Ω` and `μ` have Greek letter names.
In addition, there are separate locales `ArithmeticFunction.zeta` for `ζ`,
`ArithmeticFunction.sigma` for `σ`, `ArithmeticFunction.omega` for `ω`,
`ArithmeticFunction.Omega` for `Ω`, and `ArithmeticFunction.Moebius` for `μ`,
to allow for selective access to these notations.
The arithmetic function $$n \mapsto \prod_{p \mid n} f(p)$$ is given custom notation
`∏ᵖ p ∣ n, f p` when applied to `n`.
## Tags
arithmetic functions, dirichlet convolution, divisors
-/
open Finset
open Nat
variable (R : Type*)
/-- An arithmetic function is a function from `ℕ` that maps 0 to 0. In the literature, they are
often instead defined as functions from `ℕ+`. Multiplication on `ArithmeticFunctions` is by
Dirichlet convolution. -/
def ArithmeticFunction [Zero R] :=
ZeroHom ℕ R
instance ArithmeticFunction.zero [Zero R] : Zero (ArithmeticFunction R) :=
inferInstanceAs (Zero (ZeroHom ℕ R))
instance [Zero R] : Inhabited (ArithmeticFunction R) := inferInstanceAs (Inhabited (ZeroHom ℕ R))
variable {R}
namespace ArithmeticFunction
section Zero
variable [Zero R]
instance : FunLike (ArithmeticFunction R) ℕ R :=
inferInstanceAs (FunLike (ZeroHom ℕ R) ℕ R)
@[simp]
theorem toFun_eq (f : ArithmeticFunction R) : f.toFun = f := rfl
@[simp]
theorem coe_mk (f : ℕ → R) (hf) : @DFunLike.coe (ArithmeticFunction R) _ _ _
(ZeroHom.mk f hf) = f := rfl
@[simp]
theorem map_zero {f : ArithmeticFunction R} : f 0 = 0 :=
ZeroHom.map_zero' f
theorem coe_inj {f g : ArithmeticFunction R} : (f : ℕ → R) = g ↔ f = g :=
DFunLike.coe_fn_eq
@[simp]
theorem zero_apply {x : ℕ} : (0 : ArithmeticFunction R) x = 0 :=
ZeroHom.zero_apply x
@[ext]
theorem ext ⦃f g : ArithmeticFunction R⦄ (h : ∀ x, f x = g x) : f = g :=
ZeroHom.ext h
section One
variable [One R]
instance one : One (ArithmeticFunction R) :=
⟨⟨fun x => ite (x = 1) 1 0, rfl⟩⟩
theorem one_apply {x : ℕ} : (1 : ArithmeticFunction R) x = ite (x = 1) 1 0 :=
rfl
@[simp]
theorem one_one : (1 : ArithmeticFunction R) 1 = 1 :=
rfl
@[simp]
theorem one_apply_ne {x : ℕ} (h : x ≠ 1) : (1 : ArithmeticFunction R) x = 0 :=
if_neg h
end One
end Zero
/-- Coerce an arithmetic function with values in `ℕ` to one with values in `R`. We cannot inline
this in `natCoe` because it gets unfolded too much. -/
@[coe]
def natToArithmeticFunction [AddMonoidWithOne R] :
(ArithmeticFunction ℕ) → (ArithmeticFunction R) :=
fun f => ⟨fun n => ↑(f n), by simp⟩
instance natCoe [AddMonoidWithOne R] : Coe (ArithmeticFunction ℕ) (ArithmeticFunction R) :=
⟨natToArithmeticFunction⟩
@[simp]
theorem natCoe_nat (f : ArithmeticFunction ℕ) : natToArithmeticFunction f = f :=
ext fun _ => cast_id _
@[simp]
theorem natCoe_apply [AddMonoidWithOne R] {f : ArithmeticFunction ℕ} {x : ℕ} :
(f : ArithmeticFunction R) x = f x :=
rfl
/-- Coerce an arithmetic function with values in `ℤ` to one with values in `R`. We cannot inline
this in `intCoe` because it gets unfolded too much. -/
@[coe]
def ofInt [AddGroupWithOne R] :
(ArithmeticFunction ℤ) → (ArithmeticFunction R) :=
fun f => ⟨fun n => ↑(f n), by simp⟩
instance intCoe [AddGroupWithOne R] : Coe (ArithmeticFunction ℤ) (ArithmeticFunction R) :=
⟨ofInt⟩
@[simp]
theorem intCoe_int (f : ArithmeticFunction ℤ) : ofInt f = f :=
ext fun _ => Int.cast_id
@[simp]
theorem intCoe_apply [AddGroupWithOne R] {f : ArithmeticFunction ℤ} {x : ℕ} :
(f : ArithmeticFunction R) x = f x := rfl
@[simp]
theorem coe_coe [AddGroupWithOne R] {f : ArithmeticFunction ℕ} :
((f : ArithmeticFunction ℤ) : ArithmeticFunction R) = (f : ArithmeticFunction R) := by
ext
simp
@[simp]
theorem natCoe_one [AddMonoidWithOne R] :
((1 : ArithmeticFunction ℕ) : ArithmeticFunction R) = 1 := by
ext n
simp [one_apply]
@[simp]
theorem intCoe_one [AddGroupWithOne R] : ((1 : ArithmeticFunction ℤ) :
ArithmeticFunction R) = 1 := by
ext n
simp [one_apply]
section AddMonoid
variable [AddMonoid R]
instance add : Add (ArithmeticFunction R) :=
⟨fun f g => ⟨fun n => f n + g n, by simp⟩⟩
@[simp]
theorem add_apply {f g : ArithmeticFunction R} {n : ℕ} : (f + g) n = f n + g n :=
rfl
instance instAddMonoid : AddMonoid (ArithmeticFunction R) :=
{ ArithmeticFunction.zero R,
ArithmeticFunction.add with
add_assoc := fun _ _ _ => ext fun _ => add_assoc _ _ _
zero_add := fun _ => ext fun _ => zero_add _
add_zero := fun _ => ext fun _ => add_zero _
nsmul := nsmulRec }
end AddMonoid
instance instAddMonoidWithOne [AddMonoidWithOne R] : AddMonoidWithOne (ArithmeticFunction R) :=
{ ArithmeticFunction.instAddMonoid,
ArithmeticFunction.one with
natCast := fun n => ⟨fun x => if x = 1 then (n : R) else 0, by simp⟩
natCast_zero := by ext; simp
natCast_succ := fun n => by ext x; by_cases h : x = 1 <;> simp [h] }
instance instAddCommMonoid [AddCommMonoid R] : AddCommMonoid (ArithmeticFunction R) :=
{ ArithmeticFunction.instAddMonoid with add_comm := fun _ _ => ext fun _ => add_comm _ _ }
instance [NegZeroClass R] : Neg (ArithmeticFunction R) where
neg f := ⟨fun n => -f n, by simp⟩
instance [AddGroup R] : AddGroup (ArithmeticFunction R) :=
{ ArithmeticFunction.instAddMonoid with
neg_add_cancel := fun _ => ext fun _ => neg_add_cancel _
zsmul := zsmulRec }
instance [AddCommGroup R] : AddCommGroup (ArithmeticFunction R) :=
{ show AddGroup (ArithmeticFunction R) by infer_instance with
add_comm := fun _ _ ↦ add_comm _ _ }
section SMul
variable {M : Type*} [Zero R] [AddCommMonoid M] [SMul R M]
/-- The Dirichlet convolution of two arithmetic functions `f` and `g` is another arithmetic function
such that `(f * g) n` is the sum of `f x * g y` over all `(x,y)` such that `x * y = n`. -/
instance : SMul (ArithmeticFunction R) (ArithmeticFunction M) :=
⟨fun f g => ⟨fun n => ∑ x ∈ divisorsAntidiagonal n, f x.fst • g x.snd, by simp⟩⟩
@[simp]
theorem smul_apply {f : ArithmeticFunction R} {g : ArithmeticFunction M} {n : ℕ} :
(f • g) n = ∑ x ∈ divisorsAntidiagonal n, f x.fst • g x.snd :=
rfl
end SMul
/-- The Dirichlet convolution of two arithmetic functions `f` and `g` is another arithmetic function
such that `(f * g) n` is the sum of `f x * g y` over all `(x,y)` such that `x * y = n`. -/
instance [Semiring R] : Mul (ArithmeticFunction R) :=
⟨(· • ·)⟩
@[simp]
theorem mul_apply [Semiring R] {f g : ArithmeticFunction R} {n : ℕ} :
(f * g) n = ∑ x ∈ divisorsAntidiagonal n, f x.fst * g x.snd :=
rfl
theorem mul_apply_one [Semiring R] {f g : ArithmeticFunction R} : (f * g) 1 = f 1 * g 1 := by simp
@[simp, norm_cast]
theorem natCoe_mul [Semiring R] {f g : ArithmeticFunction ℕ} :
(↑(f * g) : ArithmeticFunction R) = f * g := by
ext n
simp
@[simp, norm_cast]
theorem intCoe_mul [Ring R] {f g : ArithmeticFunction ℤ} :
(↑(f * g) : ArithmeticFunction R) = ↑f * g := by
ext n
simp
section Module
variable {M : Type*} [Semiring R] [AddCommMonoid M] [Module R M]
theorem mul_smul' (f g : ArithmeticFunction R) (h : ArithmeticFunction M) :
(f * g) • h = f • g • h := by
ext n
simp only [mul_apply, smul_apply, sum_smul, mul_smul, smul_sum, Finset.sum_sigma']
apply Finset.sum_nbij' (fun ⟨⟨_i, j⟩, ⟨k, l⟩⟩ ↦ ⟨(k, l * j), (l, j)⟩)
(fun ⟨⟨i, _j⟩, ⟨k, l⟩⟩ ↦ ⟨(i * k, l), (i, k)⟩) <;> aesop (add simp mul_assoc)
theorem one_smul' (b : ArithmeticFunction M) : (1 : ArithmeticFunction R) • b = b := by
ext x
rw [smul_apply]
by_cases x0 : x = 0
· simp [x0]
have h : {(1, x)} ⊆ divisorsAntidiagonal x := by simp [x0]
rw [← sum_subset h]
· simp
intro y ymem ynmem
have y1ne : y.fst ≠ 1 := fun con => by simp_all [Prod.ext_iff]
simp [y1ne]
end Module
section Semiring
| variable [Semiring R]
instance instMonoid : Monoid (ArithmeticFunction R) :=
{ one := One.one
| Mathlib/NumberTheory/ArithmeticFunction.lean | 307 | 310 |
/-
Copyright (c) 2019 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov
-/
import Mathlib.Algebra.Order.BigOperators.Ring.Finset
import Mathlib.Analysis.Convex.Hull
import Mathlib.LinearAlgebra.AffineSpace.Basis
/-!
# Convex combinations
This file defines convex combinations of points in a vector space.
## Main declarations
* `Finset.centerMass`: Center of mass of a finite family of points.
## Implementation notes
We divide by the sum of the weights in the definition of `Finset.centerMass` because of the way
mathematical arguments go: one doesn't change weights, but merely adds some. This also makes a few
lemmas unconditional on the sum of the weights being `1`.
-/
open Set Function Pointwise
universe u u'
section
variable {R R' E F ι ι' α : Type*} [Field R] [Field R'] [AddCommGroup E] [AddCommGroup F]
[AddCommGroup α] [LinearOrder α] [Module R E] [Module R F] [Module R α] {s : Set E}
/-- Center of mass of a finite collection of points with prescribed weights.
Note that we require neither `0 ≤ w i` nor `∑ w = 1`. -/
def Finset.centerMass (t : Finset ι) (w : ι → R) (z : ι → E) : E :=
(∑ i ∈ t, w i)⁻¹ • ∑ i ∈ t, w i • z i
variable (i j : ι) (c : R) (t : Finset ι) (w : ι → R) (z : ι → E)
open Finset
theorem Finset.centerMass_empty : (∅ : Finset ι).centerMass w z = 0 := by
simp only [centerMass, sum_empty, smul_zero]
theorem Finset.centerMass_pair [DecidableEq ι] (hne : i ≠ j) :
({i, j} : Finset ι).centerMass w z = (w i / (w i + w j)) • z i + (w j / (w i + w j)) • z j := by
simp only [centerMass, sum_pair hne]
module
variable {w}
theorem Finset.centerMass_insert [DecidableEq ι] (ha : i ∉ t) (hw : ∑ j ∈ t, w j ≠ 0) :
(insert i t).centerMass w z =
(w i / (w i + ∑ j ∈ t, w j)) • z i +
((∑ j ∈ t, w j) / (w i + ∑ j ∈ t, w j)) • t.centerMass w z := by
simp only [centerMass, sum_insert ha, smul_add, (mul_smul _ _ _).symm, ← div_eq_inv_mul]
congr 2
rw [div_mul_eq_mul_div, mul_inv_cancel₀ hw, one_div]
theorem Finset.centerMass_singleton (hw : w i ≠ 0) : ({i} : Finset ι).centerMass w z = z i := by
rw [centerMass, sum_singleton, sum_singleton]
match_scalars
field_simp
@[simp] lemma Finset.centerMass_neg_left : t.centerMass (-w) z = t.centerMass w z := by
simp [centerMass, inv_neg]
lemma Finset.centerMass_smul_left {c : R'} [Module R' R] [Module R' E] [SMulCommClass R' R R]
[IsScalarTower R' R R] [SMulCommClass R R' E] [IsScalarTower R' R E] (hc : c ≠ 0) :
t.centerMass (c • w) z = t.centerMass w z := by
simp [centerMass, -smul_assoc, smul_assoc c, ← smul_sum, smul_inv₀, smul_smul_smul_comm, hc]
theorem Finset.centerMass_eq_of_sum_1 (hw : ∑ i ∈ t, w i = 1) :
t.centerMass w z = ∑ i ∈ t, w i • z i := by
simp only [Finset.centerMass, hw, inv_one, one_smul]
theorem Finset.centerMass_smul : (t.centerMass w fun i => c • z i) = c • t.centerMass w z := by
simp only [Finset.centerMass, Finset.smul_sum, (mul_smul _ _ _).symm, mul_comm c, mul_assoc]
/-- A convex combination of two centers of mass is a center of mass as well. This version
deals with two different index types. -/
theorem Finset.centerMass_segment' (s : Finset ι) (t : Finset ι') (ws : ι → R) (zs : ι → E)
(wt : ι' → R) (zt : ι' → E) (hws : ∑ i ∈ s, ws i = 1) (hwt : ∑ i ∈ t, wt i = 1) (a b : R)
(hab : a + b = 1) : a • s.centerMass ws zs + b • t.centerMass wt zt = (s.disjSum t).centerMass
(Sum.elim (fun i => a * ws i) fun j => b * wt j) (Sum.elim zs zt) := by
rw [s.centerMass_eq_of_sum_1 _ hws, t.centerMass_eq_of_sum_1 _ hwt, smul_sum, smul_sum, ←
Finset.sum_sumElim, Finset.centerMass_eq_of_sum_1]
· congr with ⟨⟩ <;> simp only [Sum.elim_inl, Sum.elim_inr, mul_smul]
· rw [sum_sumElim, ← mul_sum, ← mul_sum, hws, hwt, mul_one, mul_one, hab]
/-- A convex combination of two centers of mass is a center of mass as well. This version
works if two centers of mass share the set of original points. -/
theorem Finset.centerMass_segment (s : Finset ι) (w₁ w₂ : ι → R) (z : ι → E)
(hw₁ : ∑ i ∈ s, w₁ i = 1) (hw₂ : ∑ i ∈ s, w₂ i = 1) (a b : R) (hab : a + b = 1) :
a • s.centerMass w₁ z + b • s.centerMass w₂ z =
s.centerMass (fun i => a * w₁ i + b * w₂ i) z := by
have hw : (∑ i ∈ s, (a * w₁ i + b * w₂ i)) = 1 := by
simp only [← mul_sum, sum_add_distrib, mul_one, *]
simp only [Finset.centerMass_eq_of_sum_1, Finset.centerMass_eq_of_sum_1 _ _ hw,
smul_sum, sum_add_distrib, add_smul, mul_smul, *]
theorem Finset.centerMass_ite_eq [DecidableEq ι] (hi : i ∈ t) :
t.centerMass (fun j => if i = j then (1 : R) else 0) z = z i := by
rw [Finset.centerMass_eq_of_sum_1]
· trans ∑ j ∈ t, if i = j then z i else 0
· congr with i
split_ifs with h
exacts [h ▸ one_smul _ _, zero_smul _ _]
· rw [sum_ite_eq, if_pos hi]
· rw [sum_ite_eq, if_pos hi]
variable {t}
theorem Finset.centerMass_subset {t' : Finset ι} (ht : t ⊆ t') (h : ∀ i ∈ t', i ∉ t → w i = 0) :
t.centerMass w z = t'.centerMass w z := by
rw [centerMass, sum_subset ht h, smul_sum, centerMass, smul_sum]
apply sum_subset ht
intro i hit' hit
rw [h i hit' hit, zero_smul, smul_zero]
theorem Finset.centerMass_filter_ne_zero [∀ i, Decidable (w i ≠ 0)] :
{i ∈ t | w i ≠ 0}.centerMass w z = t.centerMass w z :=
Finset.centerMass_subset z (filter_subset _ _) fun i hit hit' => by
simpa only [hit, mem_filter, true_and, Ne, Classical.not_not] using hit'
namespace Finset
variable [LinearOrder R] [IsStrictOrderedRing R] [IsOrderedAddMonoid α] [OrderedSMul R α]
theorem centerMass_le_sup {s : Finset ι} {f : ι → α} {w : ι → R} (hw₀ : ∀ i ∈ s, 0 ≤ w i)
(hw₁ : 0 < ∑ i ∈ s, w i) :
s.centerMass w f ≤ s.sup' (nonempty_of_ne_empty <| by rintro rfl; simp at hw₁) f := by
rw [centerMass, inv_smul_le_iff_of_pos hw₁, sum_smul]
exact sum_le_sum fun i hi => smul_le_smul_of_nonneg_left (le_sup' _ hi) <| hw₀ i hi
theorem inf_le_centerMass {s : Finset ι} {f : ι → α} {w : ι → R} (hw₀ : ∀ i ∈ s, 0 ≤ w i)
(hw₁ : 0 < ∑ i ∈ s, w i) :
s.inf' (nonempty_of_ne_empty <| by rintro rfl; simp at hw₁) f ≤ s.centerMass w f :=
centerMass_le_sup (α := αᵒᵈ) hw₀ hw₁
end Finset
variable {z}
lemma Finset.centerMass_of_sum_add_sum_eq_zero {s t : Finset ι}
(hw : ∑ i ∈ s, w i + ∑ i ∈ t, w i = 0) (hz : ∑ i ∈ s, w i • z i + ∑ i ∈ t, w i • z i = 0) :
s.centerMass w z = t.centerMass w z := by
simp [centerMass, eq_neg_of_add_eq_zero_right hw, eq_neg_of_add_eq_zero_left hz, ← neg_inv]
variable [LinearOrder R] [IsStrictOrderedRing R] [IsOrderedAddMonoid α] [OrderedSMul R α]
/-- The center of mass of a finite subset of a convex set belongs to the set
provided that all weights are non-negative, and the total weight is positive. -/
theorem Convex.centerMass_mem (hs : Convex R s) :
(∀ i ∈ t, 0 ≤ w i) → (0 < ∑ i ∈ t, w i) → (∀ i ∈ t, z i ∈ s) → t.centerMass w z ∈ s := by
classical
induction' t using Finset.induction with i t hi ht
· simp [lt_irrefl]
intro h₀ hpos hmem
have zi : z i ∈ s := hmem _ (mem_insert_self _ _)
have hs₀ : ∀ j ∈ t, 0 ≤ w j := fun j hj => h₀ j <| mem_insert_of_mem hj
rw [sum_insert hi] at hpos
by_cases hsum_t : ∑ j ∈ t, w j = 0
· have ws : ∀ j ∈ t, w j = 0 := (sum_eq_zero_iff_of_nonneg hs₀).1 hsum_t
have wz : ∑ j ∈ t, w j • z j = 0 := sum_eq_zero fun i hi => by simp [ws i hi]
simp only [centerMass, sum_insert hi, wz, hsum_t, add_zero]
simp only [hsum_t, add_zero] at hpos
rw [← mul_smul, inv_mul_cancel₀ (ne_of_gt hpos), one_smul]
exact zi
· rw [Finset.centerMass_insert _ _ _ hi hsum_t]
refine convex_iff_div.1 hs zi (ht hs₀ ?_ ?_) ?_ (sum_nonneg hs₀) hpos
· exact lt_of_le_of_ne (sum_nonneg hs₀) (Ne.symm hsum_t)
· intro j hj
exact hmem j (mem_insert_of_mem hj)
· exact h₀ _ (mem_insert_self _ _)
theorem Convex.sum_mem (hs : Convex R s) (h₀ : ∀ i ∈ t, 0 ≤ w i) (h₁ : ∑ i ∈ t, w i = 1)
(hz : ∀ i ∈ t, z i ∈ s) : (∑ i ∈ t, w i • z i) ∈ s := by
simpa only [h₁, centerMass, inv_one, one_smul] using
hs.centerMass_mem h₀ (h₁.symm ▸ zero_lt_one) hz
/-- A version of `Convex.sum_mem` for `finsum`s. If `s` is a convex set, `w : ι → R` is a family of
nonnegative weights with sum one and `z : ι → E` is a family of elements of a module over `R` such
that `z i ∈ s` whenever `w i ≠ 0`, then the sum `∑ᶠ i, w i • z i` belongs to `s`. See also
`PartitionOfUnity.finsum_smul_mem_convex`. -/
theorem Convex.finsum_mem {ι : Sort*} {w : ι → R} {z : ι → E} {s : Set E} (hs : Convex R s)
(h₀ : ∀ i, 0 ≤ w i) (h₁ : ∑ᶠ i, w i = 1) (hz : ∀ i, w i ≠ 0 → z i ∈ s) :
(∑ᶠ i, w i • z i) ∈ s := by
| have hfin_w : (support (w ∘ PLift.down)).Finite := by
by_contra H
rw [finsum, dif_neg H] at h₁
exact zero_ne_one h₁
| Mathlib/Analysis/Convex/Combination.lean | 191 | 194 |
/-
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 :=
| Mathlib/Order/Filter/Basic.lean | 1,185 | 1,187 |
/-
Copyright (c) 2020 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov
-/
import Mathlib.Algebra.Group.Submonoid.BigOperators
import Mathlib.Algebra.Ring.Action.Subobjects
import Mathlib.Algebra.Ring.Equiv
import Mathlib.Algebra.Ring.Prod
import Mathlib.Algebra.Ring.Subsemiring.Defs
import Mathlib.GroupTheory.Submonoid.Centralizer
import Mathlib.RingTheory.NonUnitalSubsemiring.Basic
import Mathlib.Algebra.Module.Defs
/-!
# Bundled subsemirings
We define some standard constructions on bundled subsemirings: `CompleteLattice` structure,
subsemiring `map`, `comap` and range (`rangeS`) of a `RingHom` etc.
-/
universe u v w
variable {R : Type u} {S : Type v} {T : Type w} [NonAssocSemiring R] (M : Submonoid R)
section SubsemiringClass
variable [SetLike S R] [hSR : SubsemiringClass S R] (s : S)
namespace SubsemiringClass
instance instCharZero [CharZero R] : CharZero s :=
⟨Function.Injective.of_comp (f := Subtype.val) (g := Nat.cast (R := s)) Nat.cast_injective⟩
end SubsemiringClass
end SubsemiringClass
variable [NonAssocSemiring S] [NonAssocSemiring T]
namespace Subsemiring
variable (s : Subsemiring R)
@[mono]
theorem toSubmonoid_strictMono : StrictMono (toSubmonoid : Subsemiring R → Submonoid R) :=
fun _ _ => id
@[mono]
theorem toSubmonoid_mono : Monotone (toSubmonoid : Subsemiring R → Submonoid R) :=
toSubmonoid_strictMono.monotone
@[mono]
theorem toAddSubmonoid_strictMono : StrictMono (toAddSubmonoid : Subsemiring R → AddSubmonoid R) :=
fun _ _ => id
@[mono]
theorem toAddSubmonoid_mono : Monotone (toAddSubmonoid : Subsemiring R → AddSubmonoid R) :=
toAddSubmonoid_strictMono.monotone
/-- Product of a list of elements in a `Subsemiring` is in the `Subsemiring`. -/
nonrec theorem list_prod_mem {R : Type*} [Semiring R] (s : Subsemiring R) {l : List R} :
(∀ x ∈ l, x ∈ s) → l.prod ∈ s :=
list_prod_mem
/-- Sum of a list of elements in a `Subsemiring` is in the `Subsemiring`. -/
protected theorem list_sum_mem {l : List R} : (∀ x ∈ l, x ∈ s) → l.sum ∈ s :=
list_sum_mem
/-- Product of a multiset of elements in a `Subsemiring` of a `CommSemiring`
is in the `Subsemiring`. -/
protected theorem multiset_prod_mem {R} [CommSemiring R] (s : Subsemiring R) (m : Multiset R) :
(∀ a ∈ m, a ∈ s) → m.prod ∈ s :=
multiset_prod_mem m
/-- Sum of a multiset of elements in a `Subsemiring` of a `NonAssocSemiring` is
in the `Subsemiring`. -/
protected theorem multiset_sum_mem (m : Multiset R) : (∀ a ∈ m, a ∈ s) → m.sum ∈ s :=
multiset_sum_mem m
/-- Product of elements of a subsemiring of a `CommSemiring` indexed by a `Finset` is in the
`Subsemiring`. -/
protected theorem prod_mem {R : Type*} [CommSemiring R] (s : Subsemiring R) {ι : Type*}
{t : Finset ι} {f : ι → R} (h : ∀ c ∈ t, f c ∈ s) : (∏ i ∈ t, f i) ∈ s :=
prod_mem h
/-- Sum of elements in a `Subsemiring` of a `NonAssocSemiring` indexed by a `Finset`
is in the `Subsemiring`. -/
protected theorem sum_mem (s : Subsemiring R) {ι : Type*} {t : Finset ι} {f : ι → R}
(h : ∀ c ∈ t, f c ∈ s) : (∑ i ∈ t, f i) ∈ s :=
sum_mem h
/-- The ring equiv between the top element of `Subsemiring R` and `R`. -/
@[simps]
def topEquiv : (⊤ : Subsemiring R) ≃+* R where
toFun r := r
invFun r := ⟨r, Subsemiring.mem_top r⟩
left_inv _ := rfl
right_inv _ := rfl
map_mul' := (⊤ : Subsemiring R).coe_mul
map_add' := (⊤ : Subsemiring R).coe_add
/-- The preimage of a subsemiring along a ring homomorphism is a subsemiring. -/
@[simps coe toSubmonoid]
def comap (f : R →+* S) (s : Subsemiring S) : Subsemiring R :=
{ s.toSubmonoid.comap (f : R →* S), s.toAddSubmonoid.comap (f : R →+ S) with carrier := f ⁻¹' s }
@[simp]
theorem mem_comap {s : Subsemiring S} {f : R →+* S} {x : R} : x ∈ s.comap f ↔ f x ∈ s :=
Iff.rfl
theorem comap_comap (s : Subsemiring T) (g : S →+* T) (f : R →+* S) :
(s.comap g).comap f = s.comap (g.comp f) :=
rfl
/-- The image of a subsemiring along a ring homomorphism is a subsemiring. -/
@[simps coe toSubmonoid]
def map (f : R →+* S) (s : Subsemiring R) : Subsemiring S :=
{ s.toSubmonoid.map (f : R →* S), s.toAddSubmonoid.map (f : R →+ S) with carrier := f '' s }
@[simp]
lemma mem_map {f : R →+* S} {s : Subsemiring R} {y : S} : y ∈ s.map f ↔ ∃ x ∈ s, f x = y := Iff.rfl
@[simp]
theorem map_id : s.map (RingHom.id R) = s :=
SetLike.coe_injective <| Set.image_id _
theorem map_map (g : S →+* T) (f : R →+* S) : (s.map f).map g = s.map (g.comp f) :=
SetLike.coe_injective <| Set.image_image _ _ _
theorem map_le_iff_le_comap {f : R →+* S} {s : Subsemiring R} {t : Subsemiring S} :
s.map f ≤ t ↔ s ≤ t.comap f :=
Set.image_subset_iff
theorem gc_map_comap (f : R →+* S) : GaloisConnection (map f) (comap f) := fun _ _ =>
map_le_iff_le_comap
/-- A subsemiring is isomorphic to its image under an injective function -/
noncomputable def equivMapOfInjective (f : R →+* S) (hf : Function.Injective f) : s ≃+* s.map f :=
{ Equiv.Set.image f s hf with
map_mul' := fun _ _ => Subtype.ext (f.map_mul _ _)
map_add' := fun _ _ => Subtype.ext (f.map_add _ _) }
@[simp]
theorem coe_equivMapOfInjective_apply (f : R →+* S) (hf : Function.Injective f) (x : s) :
(equivMapOfInjective s f hf x : S) = f x :=
rfl
end Subsemiring
namespace RingHom
variable (g : S →+* T) (f : R →+* S)
/-- The range of a ring homomorphism is a subsemiring. See Note [range copy pattern]. -/
@[simps! coe toSubmonoid]
def rangeS : Subsemiring S :=
((⊤ : Subsemiring R).map f).copy (Set.range f) Set.image_univ.symm
@[simp]
theorem mem_rangeS {f : R →+* S} {y : S} : y ∈ f.rangeS ↔ ∃ x, f x = y :=
Iff.rfl
theorem rangeS_eq_map (f : R →+* S) : f.rangeS = (⊤ : Subsemiring R).map f := by
ext
simp
theorem mem_rangeS_self (f : R →+* S) (x : R) : f x ∈ f.rangeS :=
mem_rangeS.mpr ⟨x, rfl⟩
theorem map_rangeS : f.rangeS.map g = (g.comp f).rangeS := by
simpa only [rangeS_eq_map] using (⊤ : Subsemiring R).map_map g f
/-- The range of a morphism of semirings is a fintype, if the domain is a fintype.
Note: this instance can form a diamond with `Subtype.fintype` in the
presence of `Fintype S`. -/
instance fintypeRangeS [Fintype R] [DecidableEq S] (f : R →+* S) : Fintype (rangeS f) :=
Set.fintypeRange f
end RingHom
namespace Subsemiring
instance : Bot (Subsemiring R) :=
⟨(Nat.castRingHom R).rangeS⟩
instance : Inhabited (Subsemiring R) :=
⟨⊥⟩
theorem coe_bot : ((⊥ : Subsemiring R) : Set R) = Set.range ((↑) : ℕ → R) :=
(Nat.castRingHom R).coe_rangeS
theorem mem_bot {x : R} : x ∈ (⊥ : Subsemiring R) ↔ ∃ n : ℕ, ↑n = x :=
RingHom.mem_rangeS
instance : InfSet (Subsemiring R) :=
⟨fun s =>
Subsemiring.mk' (⋂ t ∈ s, ↑t) (⨅ t ∈ s, Subsemiring.toSubmonoid t) (by simp)
(⨅ t ∈ s, Subsemiring.toAddSubmonoid t)
(by simp)⟩
@[simp, norm_cast]
theorem coe_sInf (S : Set (Subsemiring R)) : ((sInf S : Subsemiring R) : Set R) = ⋂ s ∈ S, ↑s :=
rfl
theorem mem_sInf {S : Set (Subsemiring R)} {x : R} : x ∈ sInf S ↔ ∀ p ∈ S, x ∈ p :=
Set.mem_iInter₂
@[simp, norm_cast]
theorem coe_iInf {ι : Sort*} {S : ι → Subsemiring R} : (↑(⨅ i, S i) : Set R) = ⋂ i, S i := by
simp only [iInf, coe_sInf, Set.biInter_range]
theorem mem_iInf {ι : Sort*} {S : ι → Subsemiring R} {x : R} : (x ∈ ⨅ i, S i) ↔ ∀ i, x ∈ S i := by
simp only [iInf, mem_sInf, Set.forall_mem_range]
@[simp]
theorem sInf_toSubmonoid (s : Set (Subsemiring R)) :
(sInf s).toSubmonoid = ⨅ t ∈ s, Subsemiring.toSubmonoid t :=
mk'_toSubmonoid _ _
@[simp]
theorem sInf_toAddSubmonoid (s : Set (Subsemiring R)) :
(sInf s).toAddSubmonoid = ⨅ t ∈ s, Subsemiring.toAddSubmonoid t :=
mk'_toAddSubmonoid _ _
/-- Subsemirings of a semiring form a complete lattice. -/
instance : CompleteLattice (Subsemiring R) :=
{ completeLatticeOfInf (Subsemiring R) fun _ =>
IsGLB.of_image
(fun {s t : Subsemiring R} => show (s : Set R) ⊆ t ↔ s ≤ t from SetLike.coe_subset_coe)
isGLB_biInf with
bot := ⊥
bot_le := fun s _ hx =>
let ⟨n, hn⟩ := mem_bot.1 hx
hn ▸ natCast_mem s n
top := ⊤
le_top := fun _ _ _ => mem_top _
inf := (· ⊓ ·)
inf_le_left := fun _ _ _ => And.left
inf_le_right := fun _ _ _ => And.right
le_inf := fun _ _ _ h₁ h₂ _ hx => ⟨h₁ hx, h₂ hx⟩ }
theorem eq_top_iff' (A : Subsemiring R) : A = ⊤ ↔ ∀ x : R, x ∈ A :=
eq_top_iff.trans ⟨fun h m => h <| mem_top m, fun h m _ => h m⟩
section NonAssocSemiring
variable (R)
/-- The center of a non-associative semiring `R` is the set of elements that commute and associate
with everything in `R` -/
@[simps coe toSubmonoid]
def center : Subsemiring R :=
{ NonUnitalSubsemiring.center R with
one_mem' := Set.one_mem_center }
/-- The center is commutative and associative.
This is not an instance as it forms a non-defeq diamond with
`NonUnitalSubringClass.toNonUnitalRing` in the `npow` field. -/
abbrev center.commSemiring' : CommSemiring (center R) :=
{ Submonoid.center.commMonoid', (center R).toNonAssocSemiring with }
variable {R}
/-- The center of isomorphic (not necessarily associative) semirings are isomorphic. -/
@[simps!] def centerCongr [NonAssocSemiring S] (e : R ≃+* S) : center R ≃+* center S :=
NonUnitalSubsemiring.centerCongr e
/-- The center of a (not necessarily associative) semiring
is isomorphic to the center of its opposite. -/
@[simps!] def centerToMulOpposite : center R ≃+* center Rᵐᵒᵖ :=
NonUnitalSubsemiring.centerToMulOpposite
end NonAssocSemiring
section Semiring
/-- The center is commutative. -/
instance center.commSemiring {R} [Semiring R] : CommSemiring (center R) :=
{ Submonoid.center.commMonoid, (center R).toSemiring with }
-- no instance diamond, unlike the primed version
example {R} [Semiring R] :
center.commSemiring.toSemiring = Subsemiring.toSemiring (center R) := by
with_reducible_and_instances rfl
theorem mem_center_iff {R} [Semiring R] {z : R} : z ∈ center R ↔ ∀ g, g * z = z * g :=
Subsemigroup.mem_center_iff
instance decidableMemCenter {R} [Semiring R] [DecidableEq R] [Fintype R] :
DecidablePred (· ∈ center R) := fun _ => decidable_of_iff' _ mem_center_iff
@[simp]
theorem center_eq_top (R) [CommSemiring R] : center R = ⊤ :=
SetLike.coe_injective (Set.center_eq_univ R)
end Semiring
section Centralizer
/-- The centralizer of a set as subsemiring. -/
def centralizer {R} [Semiring R] (s : Set R) : Subsemiring R :=
{ Submonoid.centralizer s with
carrier := s.centralizer
zero_mem' := Set.zero_mem_centralizer
add_mem' := Set.add_mem_centralizer }
@[simp, norm_cast]
theorem coe_centralizer {R} [Semiring R] (s : Set R) : (centralizer s : Set R) = s.centralizer :=
rfl
theorem centralizer_toSubmonoid {R} [Semiring R] (s : Set R) :
(centralizer s).toSubmonoid = Submonoid.centralizer s :=
rfl
theorem mem_centralizer_iff {R} [Semiring R] {s : Set R} {z : R} :
z ∈ centralizer s ↔ ∀ g ∈ s, g * z = z * g :=
Iff.rfl
theorem center_le_centralizer {R} [Semiring R] (s) : center R ≤ centralizer s :=
s.center_subset_centralizer
theorem centralizer_le {R} [Semiring R] (s t : Set R) (h : s ⊆ t) : centralizer t ≤ centralizer s :=
Set.centralizer_subset h
@[simp]
theorem centralizer_eq_top_iff_subset {R} [Semiring R] {s : Set R} :
centralizer s = ⊤ ↔ s ⊆ center R :=
SetLike.ext'_iff.trans Set.centralizer_eq_top_iff_subset
@[simp]
theorem centralizer_univ {R} [Semiring R] : centralizer Set.univ = center R :=
SetLike.ext' (Set.centralizer_univ R)
lemma le_centralizer_centralizer {R} [Semiring R] {s : Subsemiring R} :
s ≤ centralizer (centralizer (s : Set R)) :=
Set.subset_centralizer_centralizer
@[simp]
lemma centralizer_centralizer_centralizer {R} [Semiring R] {s : Set R} :
centralizer s.centralizer.centralizer = centralizer s := by
apply SetLike.coe_injective
simp only [coe_centralizer, Set.centralizer_centralizer_centralizer]
end Centralizer
/-- The `Subsemiring` generated by a set. -/
def closure (s : Set R) : Subsemiring R :=
sInf { S | s ⊆ S }
theorem mem_closure {x : R} {s : Set R} : x ∈ closure s ↔ ∀ S : Subsemiring R, s ⊆ S → x ∈ S :=
mem_sInf
/-- The subsemiring generated by a set includes the set. -/
@[simp, aesop safe 20 apply (rule_sets := [SetLike])]
theorem subset_closure {s : Set R} : s ⊆ closure s := fun _ hx => mem_closure.2 fun _ hS => hS hx
theorem not_mem_of_not_mem_closure {s : Set R} {P : R} (hP : P ∉ closure s) : P ∉ s := fun h =>
hP (subset_closure h)
/-- A subsemiring `S` includes `closure s` if and only if it includes `s`. -/
@[simp]
theorem closure_le {s : Set R} {t : Subsemiring R} : closure s ≤ t ↔ s ⊆ t :=
⟨Set.Subset.trans subset_closure, fun h => sInf_le h⟩
/-- Subsemiring closure of a set is monotone in its argument: if `s ⊆ t`,
then `closure s ≤ closure t`. -/
@[gcongr]
theorem closure_mono ⦃s t : Set R⦄ (h : s ⊆ t) : closure s ≤ closure t :=
closure_le.2 <| Set.Subset.trans h subset_closure
theorem closure_eq_of_le {s : Set R} {t : Subsemiring R} (h₁ : s ⊆ t) (h₂ : t ≤ closure s) :
closure s = t :=
le_antisymm (closure_le.2 h₁) h₂
theorem mem_map_equiv {f : R ≃+* S} {K : Subsemiring R} {x : S} :
x ∈ K.map (f : R →+* S) ↔ f.symm x ∈ K := by
convert @Set.mem_image_equiv _ _ (↑K) f.toEquiv x using 1
theorem map_equiv_eq_comap_symm (f : R ≃+* S) (K : Subsemiring R) :
K.map (f : R →+* S) = K.comap f.symm :=
SetLike.coe_injective (f.toEquiv.image_eq_preimage K)
theorem comap_equiv_eq_map_symm (f : R ≃+* S) (K : Subsemiring S) :
K.comap (f : R →+* S) = K.map f.symm :=
(map_equiv_eq_comap_symm f.symm K).symm
end Subsemiring
namespace Submonoid
/-- The additive closure of a submonoid is a subsemiring. -/
def subsemiringClosure (M : Submonoid R) : Subsemiring R :=
{ AddSubmonoid.closure (M : Set R) with
one_mem' := AddSubmonoid.mem_closure.mpr fun _ hy => hy M.one_mem
mul_mem' := MulMemClass.mul_mem_add_closure }
theorem subsemiringClosure_coe :
(M.subsemiringClosure : Set R) = AddSubmonoid.closure (M : Set R) :=
rfl
theorem subsemiringClosure_mem {x : R} :
x ∈ M.subsemiringClosure ↔ x ∈ AddSubmonoid.closure (M : Set R) :=
Iff.rfl
theorem subsemiringClosure_toAddSubmonoid :
M.subsemiringClosure.toAddSubmonoid = AddSubmonoid.closure (M : Set R) :=
rfl
@[simp] lemma subsemiringClosure_toNonUnitalSubsemiring (M : Submonoid R) :
M.subsemiringClosure.toNonUnitalSubsemiring = .closure M := by
refine Eq.symm (NonUnitalSubsemiring.closure_eq_of_le ?_ fun _ hx ↦ ?_)
· simp [Submonoid.subsemiringClosure_coe]
· simp only [Subsemiring.mem_toNonUnitalSubsemiring, subsemiringClosure_mem] at hx
induction hx using AddSubmonoid.closure_induction <;> aesop
/-- The `Subsemiring` generated by a multiplicative submonoid coincides with the
`Subsemiring.closure` of the submonoid itself . -/
theorem subsemiringClosure_eq_closure : M.subsemiringClosure = Subsemiring.closure (M : Set R) := by
ext
refine
⟨fun hx => ?_, fun hx =>
(Subsemiring.mem_closure.mp hx) M.subsemiringClosure fun s sM => ?_⟩
<;> rintro - ⟨H1, rfl⟩
<;> rintro - ⟨H2, rfl⟩
· exact AddSubmonoid.mem_closure.mp hx H1.toAddSubmonoid H2
· exact H2 sM
end Submonoid
namespace Subsemiring
@[simp]
theorem closure_submonoid_closure (s : Set R) : closure ↑(Submonoid.closure s) = closure s :=
le_antisymm
(closure_le.mpr fun _ hy =>
(Submonoid.mem_closure.mp hy) (closure s).toSubmonoid subset_closure)
(closure_mono Submonoid.subset_closure)
/-- The elements of the subsemiring closure of `M` are exactly the elements of the additive closure
of a multiplicative submonoid `M`. -/
theorem coe_closure_eq (s : Set R) :
(closure s : Set R) = AddSubmonoid.closure (Submonoid.closure s : Set R) := by
simp [← Submonoid.subsemiringClosure_toAddSubmonoid, Submonoid.subsemiringClosure_eq_closure]
theorem mem_closure_iff {s : Set R} {x} :
x ∈ closure s ↔ x ∈ AddSubmonoid.closure (Submonoid.closure s : Set R) :=
Set.ext_iff.mp (coe_closure_eq s) x
@[simp]
theorem closure_addSubmonoid_closure {s : Set R} :
closure ↑(AddSubmonoid.closure s) = closure s := by
ext x
refine ⟨fun hx => ?_, fun hx => closure_mono AddSubmonoid.subset_closure hx⟩
rintro - ⟨H, rfl⟩
rintro - ⟨J, rfl⟩
refine (AddSubmonoid.mem_closure.mp (mem_closure_iff.mp hx)) H.toAddSubmonoid fun y hy => ?_
refine (Submonoid.mem_closure.mp hy) H.toSubmonoid fun z hz => ?_
exact (AddSubmonoid.mem_closure.mp hz) H.toAddSubmonoid fun w hw => J hw
/-- An induction principle for closure membership. If `p` holds for `0`, `1`, and all elements
of `s`, and is preserved under addition and multiplication, then `p` holds for all elements
of the closure of `s`. -/
@[elab_as_elim]
theorem closure_induction {s : Set R} {p : (x : R) → x ∈ closure s → Prop}
(mem : ∀ (x) (hx : x ∈ s), p x (subset_closure hx))
(zero : p 0 (zero_mem _)) (one : p 1 (one_mem _))
(add : ∀ x y hx hy, p x hx → p y hy → p (x + y) (add_mem hx hy))
(mul : ∀ x y hx hy, p x hx → p y hy → p (x * y) (mul_mem hx hy))
{x} (hx : x ∈ closure s) : p x hx :=
let K : Subsemiring R :=
{ carrier := { x | ∃ hx, p x hx }
mul_mem' := fun ⟨_, hpx⟩ ⟨_, hpy⟩ ↦ ⟨_, mul _ _ _ _ hpx hpy⟩
add_mem' := fun ⟨_, hpx⟩ ⟨_, hpy⟩ ↦ ⟨_, add _ _ _ _ hpx hpy⟩
one_mem' := ⟨_, one⟩
zero_mem' := ⟨_, zero⟩ }
closure_le (t := K) |>.mpr (fun y hy ↦ ⟨subset_closure hy, mem y hy⟩) hx |>.elim fun _ ↦ id
/-- An induction principle for closure membership for predicates with two arguments. -/
@[elab_as_elim]
theorem closure_induction₂ {s : Set R} {p : (x y : R) → x ∈ closure s → y ∈ closure s → Prop}
(mem_mem : ∀ (x) (y) (hx : x ∈ s) (hy : y ∈ s), p x y (subset_closure hx) (subset_closure hy))
(zero_left : ∀ x hx, p 0 x (zero_mem _) hx) (zero_right : ∀ x hx, p x 0 hx (zero_mem _))
(one_left : ∀ x hx, p 1 x (one_mem _) hx) (one_right : ∀ x hx, p x 1 hx (one_mem _))
(add_left : ∀ x y z hx hy hz, p x z hx hz → p y z hy hz → p (x + y) z (add_mem hx hy) hz)
(add_right : ∀ x y z hx hy hz, p x y hx hy → p x z hx hz → p x (y + z) hx (add_mem hy hz))
(mul_left : ∀ x y z hx hy hz, p x z hx hz → p y z hy hz → p (x * y) z (mul_mem hx hy) hz)
(mul_right : ∀ x y z hx hy hz, p x y hx hy → p x z hx hz → p x (y * z) hx (mul_mem hy hz))
{x y : R} (hx : x ∈ closure s) (hy : y ∈ closure s) :
p x y hx hy := by
induction hy using closure_induction with
| mem z hz => induction hx using closure_induction with
| mem _ h => exact mem_mem _ _ h hz
| zero => exact zero_left _ _
| one => exact one_left _ _
| mul _ _ _ _ h₁ h₂ => exact mul_left _ _ _ _ _ _ h₁ h₂
| add _ _ _ _ h₁ h₂ => exact add_left _ _ _ _ _ _ h₁ h₂
| zero => exact zero_right x hx
| one => exact one_right x hx
| mul _ _ _ _ h₁ h₂ => exact mul_right _ _ _ _ _ _ h₁ h₂
| add _ _ _ _ h₁ h₂ => exact add_right _ _ _ _ _ _ h₁ h₂
theorem mem_closure_iff_exists_list {R} [Semiring R] {s : Set R} {x} :
x ∈ closure s ↔ ∃ L : List (List R), (∀ t ∈ L, ∀ y ∈ t, y ∈ s) ∧ (L.map List.prod).sum = x := by
constructor
· intro hx
rw [mem_closure_iff] at hx
induction hx using AddSubmonoid.closure_induction with
| mem x hx =>
suffices ∃ t : List R, (∀ y ∈ t, y ∈ s) ∧ t.prod = x from
let ⟨t, ht1, ht2⟩ := this
⟨[t], List.forall_mem_singleton.2 ht1, by
rw [List.map_singleton, List.sum_singleton, ht2]⟩
induction hx using Submonoid.closure_induction with
| mem x hx => exact ⟨[x], List.forall_mem_singleton.2 hx, List.prod_singleton⟩
| one => exact ⟨[], List.forall_mem_nil _, rfl⟩
| mul x y _ _ ht hu =>
obtain ⟨⟨t, ht1, ht2⟩, ⟨u, hu1, hu2⟩⟩ := And.intro ht hu
exact ⟨t ++ u, List.forall_mem_append.2 ⟨ht1, hu1⟩, by rw [List.prod_append, ht2, hu2]⟩
| one => exact ⟨[], List.forall_mem_nil _, rfl⟩
| mul x y _ _ hL hM =>
obtain ⟨⟨L, HL1, HL2⟩, ⟨M, HM1, HM2⟩⟩ := And.intro hL hM
exact ⟨L ++ M, List.forall_mem_append.2 ⟨HL1, HM1⟩, by
rw [List.map_append, List.sum_append, HL2, HM2]⟩
· rintro ⟨L, HL1, rfl⟩
exact
list_sum_mem fun r hr =>
let ⟨t, ht1, ht2⟩ := List.mem_map.1 hr
ht2 ▸ list_prod_mem _ fun y hy => subset_closure <| HL1 t ht1 y hy
variable (R) in
/-- `closure` forms a Galois insertion with the coercion to set. -/
protected def gi : GaloisInsertion (@closure R _) (↑) where
choice s _ := closure s
gc _ _ := closure_le
le_l_u _ := subset_closure
choice_eq _ _ := rfl
/-- Closure of a subsemiring `S` equals `S`. -/
@[simp]
theorem closure_eq (s : Subsemiring R) : closure (s : Set R) = s :=
(Subsemiring.gi R).l_u_eq s
@[simp]
theorem closure_empty : closure (∅ : Set R) = ⊥ :=
(Subsemiring.gi R).gc.l_bot
@[simp]
theorem closure_univ : closure (Set.univ : Set R) = ⊤ :=
@coe_top R _ ▸ closure_eq ⊤
theorem closure_union (s t : Set R) : closure (s ∪ t) = closure s ⊔ closure t :=
(Subsemiring.gi R).gc.l_sup
theorem closure_iUnion {ι} (s : ι → Set R) : closure (⋃ i, s i) = ⨆ i, closure (s i) :=
(Subsemiring.gi R).gc.l_iSup
theorem closure_sUnion (s : Set (Set R)) : closure (⋃₀ s) = ⨆ t ∈ s, closure t :=
(Subsemiring.gi R).gc.l_sSup
@[simp]
theorem closure_singleton_natCast (n : ℕ) : closure {(n : R)} = ⊥ :=
bot_unique <| closure_le.2 <| Set.singleton_subset_iff.mpr <| natCast_mem _ _
@[simp]
theorem closure_singleton_zero : closure {(0 : R)} = ⊥ := mod_cast closure_singleton_natCast 0
@[simp]
theorem closure_singleton_one : closure {(1 : R)} = ⊥ := mod_cast closure_singleton_natCast 1
@[simp]
theorem closure_insert_natCast (n : ℕ) (s : Set R) : closure (insert (n : R) s) = closure s := by
rw [Set.insert_eq, closure_union]
simp
@[simp]
theorem closure_insert_zero (s : Set R) : closure (insert 0 s) = closure s :=
mod_cast closure_insert_natCast 0 s
@[simp]
theorem closure_insert_one (s : Set R) : closure (insert 1 s) = closure s :=
mod_cast closure_insert_natCast 1 s
theorem map_sup (s t : Subsemiring R) (f : R →+* S) : (s ⊔ t).map f = s.map f ⊔ t.map f :=
(gc_map_comap f).l_sup
theorem map_iSup {ι : Sort*} (f : R →+* S) (s : ι → Subsemiring R) :
(iSup s).map f = ⨆ i, (s i).map f :=
(gc_map_comap f).l_iSup
theorem map_inf (s t : Subsemiring R) (f : R →+* S) (hf : Function.Injective f) :
(s ⊓ t).map f = s.map f ⊓ t.map f := SetLike.coe_injective (Set.image_inter hf)
theorem map_iInf {ι : Sort*} [Nonempty ι] (f : R →+* S) (hf : Function.Injective f)
(s : ι → Subsemiring R) : (iInf s).map f = ⨅ i, (s i).map f := by
apply SetLike.coe_injective
simpa using (Set.injOn_of_injective hf).image_iInter_eq (s := SetLike.coe ∘ s)
theorem comap_inf (s t : Subsemiring S) (f : R →+* S) : (s ⊓ t).comap f = s.comap f ⊓ t.comap f :=
(gc_map_comap f).u_inf
theorem comap_iInf {ι : Sort*} (f : R →+* S) (s : ι → Subsemiring S) :
(iInf s).comap f = ⨅ i, (s i).comap f :=
(gc_map_comap f).u_iInf
@[simp]
theorem map_bot (f : R →+* S) : (⊥ : Subsemiring R).map f = ⊥ :=
(gc_map_comap f).l_bot
@[simp]
theorem comap_top (f : R →+* S) : (⊤ : Subsemiring S).comap f = ⊤ :=
(gc_map_comap f).u_top
/-- Given `Subsemiring`s `s`, `t` of semirings `R`, `S` respectively, `s.prod t` is `s × t`
as a subsemiring of `R × S`. -/
def prod (s : Subsemiring R) (t : Subsemiring S) : Subsemiring (R × S) :=
{ s.toSubmonoid.prod t.toSubmonoid, s.toAddSubmonoid.prod t.toAddSubmonoid with
carrier := s ×ˢ t }
@[norm_cast]
theorem coe_prod (s : Subsemiring R) (t : Subsemiring S) :
(s.prod t : Set (R × S)) = (s : Set R) ×ˢ (t : Set S) :=
rfl
theorem mem_prod {s : Subsemiring R} {t : Subsemiring S} {p : R × S} :
p ∈ s.prod t ↔ p.1 ∈ s ∧ p.2 ∈ t :=
Iff.rfl
@[gcongr, mono]
theorem prod_mono ⦃s₁ s₂ : Subsemiring R⦄ (hs : s₁ ≤ s₂) ⦃t₁ t₂ : Subsemiring S⦄ (ht : t₁ ≤ t₂) :
s₁.prod t₁ ≤ s₂.prod t₂ :=
Set.prod_mono hs ht
theorem prod_mono_right (s : Subsemiring R) : Monotone fun t : Subsemiring S => s.prod t :=
prod_mono (le_refl s)
theorem prod_mono_left (t : Subsemiring S) : Monotone fun s : Subsemiring R => s.prod t :=
fun _ _ hs => prod_mono hs (le_refl t)
theorem prod_top (s : Subsemiring R) : s.prod (⊤ : Subsemiring S) = s.comap (RingHom.fst R S) :=
ext fun x => by simp [mem_prod, MonoidHom.coe_fst]
theorem top_prod (s : Subsemiring S) : (⊤ : Subsemiring R).prod s = s.comap (RingHom.snd R S) :=
ext fun x => by simp [mem_prod, MonoidHom.coe_snd]
@[simp]
theorem top_prod_top : (⊤ : Subsemiring R).prod (⊤ : Subsemiring S) = ⊤ :=
(top_prod _).trans <| comap_top _
/-- Product of subsemirings is isomorphic to their product as monoids. -/
def prodEquiv (s : Subsemiring R) (t : Subsemiring S) : s.prod t ≃+* s × t :=
{ Equiv.Set.prod (s : Set R) (t : Set S) with
map_mul' := fun _ _ => rfl
map_add' := fun _ _ => rfl }
theorem mem_iSup_of_directed {ι} [hι : Nonempty ι] {S : ι → Subsemiring R} (hS : Directed (· ≤ ·) S)
{x : R} : (x ∈ ⨆ i, S i) ↔ ∃ i, x ∈ S i := by
refine ⟨?_, fun ⟨i, hi⟩ ↦ le_iSup S i hi⟩
let U : Subsemiring R :=
Subsemiring.mk' (⋃ i, (S i : Set R))
(⨆ i, (S i).toSubmonoid) (Submonoid.coe_iSup_of_directed hS)
(⨆ i, (S i).toAddSubmonoid) (AddSubmonoid.coe_iSup_of_directed hS)
suffices ⨆ i, S i ≤ U by simpa [U] using @this x
exact iSup_le fun i x hx ↦ Set.mem_iUnion.2 ⟨i, hx⟩
theorem coe_iSup_of_directed {ι} [hι : Nonempty ι] {S : ι → Subsemiring R}
(hS : Directed (· ≤ ·) S) : ((⨆ i, S i : Subsemiring R) : Set R) = ⋃ i, S i :=
Set.ext fun x ↦ by simp [mem_iSup_of_directed hS]
theorem mem_sSup_of_directedOn {S : Set (Subsemiring R)} (Sne : S.Nonempty)
(hS : DirectedOn (· ≤ ·) S) {x : R} : x ∈ sSup S ↔ ∃ s ∈ S, x ∈ s := by
haveI : Nonempty S := Sne.to_subtype
simp only [sSup_eq_iSup', mem_iSup_of_directed hS.directed_val, SetCoe.exists, Subtype.coe_mk,
exists_prop]
theorem coe_sSup_of_directedOn {S : Set (Subsemiring R)} (Sne : S.Nonempty)
(hS : DirectedOn (· ≤ ·) S) : (↑(sSup S) : Set R) = ⋃ s ∈ S, ↑s :=
Set.ext fun x => by simp [mem_sSup_of_directedOn Sne hS]
end Subsemiring
namespace RingHom
variable [NonAssocSemiring T] {s : Subsemiring R}
variable {σR σS : Type*}
variable [SetLike σR R] [SetLike σS S] [SubsemiringClass σR R] [SubsemiringClass σS S]
open Subsemiring
/-- Restriction of a ring homomorphism to a subsemiring of the codomain. -/
def codRestrict (f : R →+* S) (s : σS) (h : ∀ x, f x ∈ s) : R →+* s :=
{ (f : R →* S).codRestrict s h, (f : R →+ S).codRestrict s h with toFun := fun n => ⟨f n, h n⟩ }
@[simp]
theorem codRestrict_apply (f : R →+* S) (s : σS) (h : ∀ x, f x ∈ s) (x : R) :
(f.codRestrict s h x : S) = f x :=
rfl
/-- The ring homomorphism from the preimage of `s` to `s`. -/
def restrict (f : R →+* S) (s' : σR) (s : σS) (h : ∀ x ∈ s', f x ∈ s) : s' →+* s :=
(f.domRestrict s').codRestrict s fun x => h x x.2
@[simp]
theorem coe_restrict_apply (f : R →+* S) (s' : σR) (s : σS) (h : ∀ x ∈ s', f x ∈ s) (x : s') :
(f.restrict s' s h x : S) = f x :=
rfl
@[simp]
theorem comp_restrict (f : R →+* S) (s' : σR) (s : σS) (h : ∀ x ∈ s', f x ∈ s) :
(SubsemiringClass.subtype s).comp (f.restrict s' s h) = f.comp (SubsemiringClass.subtype s') :=
rfl
/-- Restriction of a ring homomorphism to its range interpreted as a subsemiring.
This is the bundled version of `Set.rangeFactorization`. -/
def rangeSRestrict (f : R →+* S) : R →+* f.rangeS :=
f.codRestrict (R := R) (S := S) (σS := Subsemiring S) f.rangeS f.mem_rangeS_self
@[simp]
theorem coe_rangeSRestrict (f : R →+* S) (x : R) : (f.rangeSRestrict x : S) = f x :=
rfl
theorem rangeSRestrict_surjective (f : R →+* S) : Function.Surjective f.rangeSRestrict :=
fun ⟨_, hy⟩ =>
let ⟨x, hx⟩ := mem_rangeS.mp hy
⟨x, Subtype.ext hx⟩
theorem rangeS_top_iff_surjective {f : R →+* S} :
f.rangeS = (⊤ : Subsemiring S) ↔ Function.Surjective f :=
SetLike.ext'_iff.trans <| Iff.trans (by rw [coe_rangeS, coe_top]) Set.range_eq_univ
/-- The range of a surjective ring homomorphism is the whole of the codomain. -/
@[simp]
theorem rangeS_top_of_surjective (f : R →+* S) (hf : Function.Surjective f) :
f.rangeS = (⊤ : Subsemiring S) :=
rangeS_top_iff_surjective.2 hf
/-- If two ring homomorphisms are equal on a set, then they are equal on its subsemiring closure. -/
theorem eqOn_sclosure {f g : R →+* S} {s : Set R} (h : Set.EqOn f g s) : Set.EqOn f g (closure s) :=
show closure s ≤ f.eqLocusS g from closure_le.2 h
theorem eq_of_eqOn_stop {f g : R →+* S} (h : Set.EqOn f g (⊤ : Subsemiring R)) : f = g :=
ext fun _ => h (mem_top _)
theorem eq_of_eqOn_sdense {s : Set R} (hs : closure s = ⊤) {f g : R →+* S} (h : s.EqOn f g) :
f = g :=
eq_of_eqOn_stop <| hs ▸ eqOn_sclosure h
theorem sclosure_preimage_le (f : R →+* S) (s : Set S) : closure (f ⁻¹' s) ≤ (closure s).comap f :=
closure_le.2 fun _ hx => SetLike.mem_coe.2 <| mem_comap.2 <| subset_closure hx
/-- The image under a ring homomorphism of the subsemiring generated by a set equals
the subsemiring generated by the image of the set. -/
theorem map_closureS (f : R →+* S) (s : Set R) : (closure s).map f = closure (f '' s) :=
Set.image_preimage.l_comm_of_u_comm (gc_map_comap f) (Subsemiring.gi S).gc (Subsemiring.gi R).gc
fun _ ↦ coe_comap _ _
end RingHom
namespace Subsemiring
open RingHom
/-- The ring homomorphism associated to an inclusion of subsemirings. -/
def inclusion {S T : Subsemiring R} (h : S ≤ T) : S →+* T :=
S.subtype.codRestrict _ fun x => h x.2
theorem inclusion_injective {S T : Subsemiring R} (h : S ≤ T) :
Function.Injective (inclusion h) := Set.inclusion_injective h
@[simp]
theorem rangeS_subtype (s : Subsemiring R) : s.subtype.rangeS = s :=
SetLike.coe_injective <| (coe_rangeS _).trans Subtype.range_coe
@[simp]
theorem range_fst : (fst R S).rangeS = ⊤ :=
(fst R S).rangeS_top_of_surjective <| Prod.fst_surjective
@[simp]
theorem range_snd : (snd R S).rangeS = ⊤ :=
(snd R S).rangeS_top_of_surjective <| Prod.snd_surjective
@[simp]
theorem prod_bot_sup_bot_prod (s : Subsemiring R) (t : Subsemiring S) :
s.prod ⊥ ⊔ prod ⊥ t = s.prod t :=
le_antisymm (sup_le (prod_mono_right s bot_le) (prod_mono_left t bot_le)) fun p hp =>
Prod.fst_mul_snd p ▸
mul_mem
((le_sup_left : s.prod ⊥ ≤ s.prod ⊥ ⊔ prod ⊥ t) ⟨hp.1, SetLike.mem_coe.2 <| one_mem ⊥⟩)
((le_sup_right : prod ⊥ t ≤ s.prod ⊥ ⊔ prod ⊥ t) ⟨SetLike.mem_coe.2 <| one_mem ⊥, hp.2⟩)
end Subsemiring
namespace RingEquiv
variable {s t : Subsemiring R}
/-- Makes the identity isomorphism from a proof two subsemirings of a multiplicative
monoid are equal. -/
def subsemiringCongr (h : s = t) : s ≃+* t :=
{ Equiv.setCongr <| congr_arg _ h with
map_mul' := fun _ _ => rfl
map_add' := fun _ _ => rfl }
/-- Restrict a ring homomorphism with a left inverse to a ring isomorphism to its
`RingHom.rangeS`. -/
def ofLeftInverseS {g : S → R} {f : R →+* S} (h : Function.LeftInverse g f) : R ≃+* f.rangeS :=
{ f.rangeSRestrict with
toFun := fun x => f.rangeSRestrict x
invFun := fun x => (g ∘ f.rangeS.subtype) x
left_inv := h
right_inv := fun x =>
Subtype.ext <| by
let ⟨x', hx'⟩ := RingHom.mem_rangeS.mp x.prop
simp [← hx', h x'] }
@[simp]
theorem ofLeftInverseS_apply {g : S → R} {f : R →+* S} (h : Function.LeftInverse g f) (x : R) :
↑(ofLeftInverseS h x) = f x :=
rfl
@[simp]
theorem ofLeftInverseS_symm_apply {g : S → R} {f : R →+* S} (h : Function.LeftInverse g f)
(x : f.rangeS) : (ofLeftInverseS h).symm x = g x :=
rfl
/-- Given an equivalence `e : R ≃+* S` of semirings and a subsemiring `s` of `R`,
`subsemiringMap e s` is the induced equivalence between `s` and `s.map e` -/
def subsemiringMap (e : R ≃+* S) (s : Subsemiring R) : s ≃+* s.map (e : R →+* S) :=
{ e.toAddEquiv.addSubmonoidMap s.toAddSubmonoid, e.toMulEquiv.submonoidMap s.toSubmonoid with }
@[simp]
theorem subsemiringMap_apply_coe (e : R ≃+* S) (s : Subsemiring R) (x : s) :
((subsemiringMap e s) x : S) = e x :=
rfl
@[simp]
theorem subsemiringMap_symm_apply_coe (e : R ≃+* S) (s : Subsemiring R) (x : s.map e.toRingHom) :
((subsemiringMap e s).symm x : R) = e.symm x :=
rfl
end RingEquiv
/-! ### Actions by `Subsemiring`s
These are just copies of the definitions about `Submonoid` starting from `Submonoid.mulAction`.
The only new result is `Subsemiring.module`.
When `R` is commutative, `Algebra.ofSubsemiring` provides a stronger result than those found in
this file, which uses the same scalar action.
-/
section Actions
namespace Subsemiring
variable {R' α β : Type*}
variable {S' : Type*} [SetLike S' R'] (s : S)
section NonAssocSemiring
variable [NonAssocSemiring R']
/-- The action by a subsemiring is the action by the underlying semiring. -/
instance smul [SMul R' α] (S : Subsemiring R') : SMul S α :=
inferInstance
theorem smul_def [SMul R' α] {S : Subsemiring R'} (g : S) (m : α) : g • m = (g : R') • m :=
rfl
instance smulCommClass_left [SMul R' β] [SMul α β] [SMulCommClass R' α β] (S : Subsemiring R') :
SMulCommClass S α β :=
inferInstance
instance smulCommClass_right [SMul α β] [SMul R' β] [SMulCommClass α R' β] (S : Subsemiring R') :
SMulCommClass α S β :=
inferInstance
/-- Note that this provides `IsScalarTower S R R` which is needed by `smul_mul_assoc`. -/
instance isScalarTower [SMul α β] [SMul R' α] [SMul R' β] [IsScalarTower R' α β]
(S : Subsemiring R') :
IsScalarTower S α β :=
inferInstance
instance (priority := low) {M' α : Type*} [SMul M' α] {S' : Type*}
[SetLike S' M'] (s : S') [FaithfulSMul M' α] : FaithfulSMul s α :=
⟨fun h => Subtype.ext <| eq_of_smul_eq_smul h⟩
instance faithfulSMul [SMul R' α] [FaithfulSMul R' α] (S : Subsemiring R') : FaithfulSMul S α :=
inferInstance
instance (priority := low) {S' : Type*} [SetLike S' R'] [SubsemiringClass S' R'] (s : S')
[Zero α] [SMulWithZero R' α] : SMulWithZero s α where
smul_zero r := smul_zero (r : R')
zero_smul := zero_smul R'
/-- The action by a subsemiring is the action by the underlying semiring. -/
instance [Zero α] [SMulWithZero R' α] (S : Subsemiring R') : SMulWithZero S α :=
inferInstance
end NonAssocSemiring
variable [Semiring R']
/-- The action by a subsemiring is the action by the underlying semiring. -/
instance mulAction [MulAction R' α] (S : Subsemiring R') : MulAction S α :=
inferInstance
/-- The action by a subsemiring is the action by the underlying semiring. -/
instance distribMulAction [AddMonoid α] [DistribMulAction R' α] (S : Subsemiring R') :
DistribMulAction S α :=
inferInstance
instance (priority := low) [AddCommMonoid α] [Module R' α] {S' : Type*} [SetLike S' R']
[SubsemiringClass S' R'] (s : S') : Module s α where
add_smul r₁ r₂ := add_smul (r₁ : R') r₂
zero_smul := zero_smul R'
/-- The action by a subsemiring is the action by the underlying semiring. -/
instance mulDistribMulAction [Monoid α] [MulDistribMulAction R' α] (S : Subsemiring R') :
MulDistribMulAction S α :=
inferInstance
instance (priority := low) {S' : Type*} [SetLike S' R'] [SubsemiringClass S' R'] (s : S')
[Zero α] [MulActionWithZero R' α] : MulActionWithZero s α where
smul_zero r := smul_zero (r : R')
zero_smul := zero_smul R'
/-- The action by a subsemiring is the action by the underlying semiring. -/
instance mulActionWithZero [Zero α] [MulActionWithZero R' α] (S : Subsemiring R') :
MulActionWithZero S α :=
inferInstance
instance (priority := low) [AddCommMonoid α] [Module R' α] {S' : Type*} [SetLike S' R']
[SubsemiringClass S' R'] (s : S') : Module s α where
toDistribMulAction := inferInstance
add_smul r₁ r₂ := add_smul (r₁ : R') r₂
zero_smul := zero_smul R'
/-- The action by a subsemiring is the action by the underlying semiring. -/
instance module [AddCommMonoid α] [Module R' α] (S : Subsemiring R') : Module S α :=
inferInstance
/-- The action by a subsemiring is the action by the underlying semiring. -/
instance [Semiring α] [MulSemiringAction R' α] (S : Subsemiring R') : MulSemiringAction S α :=
inferInstance
/-- The center of a semiring acts commutatively on that semiring. -/
instance center.smulCommClass_left : SMulCommClass (center R') R' R' :=
Submonoid.center.smulCommClass_left
/-- The center of a semiring acts commutatively on that semiring. -/
instance center.smulCommClass_right : SMulCommClass R' (center R') R' :=
Submonoid.center.smulCommClass_right
lemma closure_le_centralizer_centralizer (s : Set R') :
closure s ≤ centralizer (centralizer s) :=
closure_le.mpr Set.subset_centralizer_centralizer
/-- If all the elements of a set `s` commute, then `closure s` is a commutative semiring. -/
abbrev closureCommSemiringOfComm {s : Set R'} (hcomm : ∀ x ∈ s, ∀ y ∈ s, x * y = y * x) :
CommSemiring (closure s) :=
{ (closure s).toSemiring with
mul_comm := fun ⟨_, h₁⟩ ⟨_, h₂⟩ ↦
have := closure_le_centralizer_centralizer s
Subtype.ext <| Set.centralizer_centralizer_comm_of_comm hcomm _ (this h₁) _ (this h₂) }
end Subsemiring
end Actions
namespace Subsemiring
theorem map_comap_eq (f : R →+* S) (t : Subsemiring S) : (t.comap f).map f = t ⊓ f.rangeS :=
SetLike.coe_injective Set.image_preimage_eq_inter_range
theorem map_comap_eq_self
{f : R →+* S} {t : Subsemiring S} (h : t ≤ f.rangeS) : (t.comap f).map f = t := by
simpa only [inf_of_le_left h] using map_comap_eq f t
theorem map_comap_eq_self_of_surjective
{f : R →+* S} (hf : Function.Surjective f) (t : Subsemiring S) : (t.comap f).map f = t :=
map_comap_eq_self <| by simp [hf]
theorem comap_map_eq_self_of_injective
{f : R →+* S} (hf : Function.Injective f) (s : Subsemiring R) : (s.map f).comap f = s :=
SetLike.coe_injective (Set.preimage_image_eq _ hf)
end Subsemiring
| Mathlib/Algebra/Ring/Subsemiring/Basic.lean | 1,046 | 1,055 | |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Floris van Doorn
-/
import Mathlib.Algebra.Order.SuccPred
import Mathlib.Data.Sum.Order
import Mathlib.SetTheory.Cardinal.Basic
import Mathlib.Tactic.PPWithUniv
/-!
# Ordinals
Ordinals are defined as equivalences of well-ordered sets under order isomorphism. They are endowed
with a total order, where an ordinal is smaller than another one if it embeds into it as an
initial segment (or, equivalently, in any way). This total order is well founded.
## Main definitions
* `Ordinal`: the type of ordinals (in a given universe)
* `Ordinal.type r`: given a well-founded order `r`, this is the corresponding ordinal
* `Ordinal.typein r a`: given a well-founded order `r` on a type `α`, and `a : α`, the ordinal
corresponding to all elements smaller than `a`.
* `enum r ⟨o, h⟩`: given a well-order `r` on a type `α`, and an ordinal `o` strictly smaller than
the ordinal corresponding to `r` (this is the assumption `h`), returns the `o`-th element of `α`.
In other words, the elements of `α` can be enumerated using ordinals up to `type r`.
* `Ordinal.card o`: the cardinality of an ordinal `o`.
* `Ordinal.lift` lifts an ordinal in universe `u` to an ordinal in universe `max u v`.
For a version registering additionally that this is an initial segment embedding, see
`Ordinal.liftInitialSeg`.
For a version registering that it is a principal segment embedding if `u < v`, see
`Ordinal.liftPrincipalSeg`.
* `Ordinal.omega0` or `ω` is the order type of `ℕ`. It is called this to match `Cardinal.aleph0`
and so that the omega function can be named `Ordinal.omega`. This definition is universe
polymorphic: `Ordinal.omega0.{u} : Ordinal.{u}` (contrast with `ℕ : Type`, which lives in
a specific universe). In some cases the universe level has to be given explicitly.
* `o₁ + o₂` is the order on the disjoint union of `o₁` and `o₂` obtained by declaring that
every element of `o₁` is smaller than every element of `o₂`.
The main properties of addition (and the other operations on ordinals) are stated and proved in
`Mathlib/SetTheory/Ordinal/Arithmetic.lean`.
Here, we only introduce it and prove its basic properties to deduce the fact that the order on
ordinals is total (and well founded).
* `succ o` is the successor of the ordinal `o`.
* `Cardinal.ord c`: when `c` is a cardinal, `ord c` is the smallest ordinal with this cardinality.
It is the canonical way to represent a cardinal with an ordinal.
A conditionally complete linear order with bot structure is registered on ordinals, where `⊥` is
`0`, the ordinal corresponding to the empty type, and `Inf` is the minimum for nonempty sets and `0`
for the empty set by convention.
## Notations
* `ω` is a notation for the first infinite ordinal in the locale `Ordinal`.
-/
assert_not_exists Module Field
noncomputable section
open Function Cardinal Set Equiv Order
open scoped Cardinal InitialSeg
universe u v w
variable {α : Type u} {β : Type v} {γ : Type w}
{r : α → α → Prop} {s : β → β → Prop} {t : γ → γ → Prop}
/-! ### Definition of ordinals -/
/-- Bundled structure registering a well order on a type. Ordinals will be defined as a quotient
of this type. -/
structure WellOrder : Type (u + 1) where
/-- The underlying type of the order. -/
α : Type u
/-- The underlying relation of the order. -/
r : α → α → Prop
/-- The proposition that `r` is a well-ordering for `α`. -/
wo : IsWellOrder α r
attribute [instance] WellOrder.wo
namespace WellOrder
instance inhabited : Inhabited WellOrder :=
⟨⟨PEmpty, _, inferInstanceAs (IsWellOrder PEmpty EmptyRelation)⟩⟩
end WellOrder
/-- Equivalence relation on well orders on arbitrary types in universe `u`, given by order
isomorphism. -/
instance Ordinal.isEquivalent : Setoid WellOrder where
r := fun ⟨_, r, _⟩ ⟨_, s, _⟩ => Nonempty (r ≃r s)
iseqv :=
⟨fun _ => ⟨RelIso.refl _⟩, fun ⟨e⟩ => ⟨e.symm⟩, fun ⟨e₁⟩ ⟨e₂⟩ => ⟨e₁.trans e₂⟩⟩
/-- `Ordinal.{u}` is the type of well orders in `Type u`, up to order isomorphism. -/
@[pp_with_univ]
def Ordinal : Type (u + 1) :=
Quotient Ordinal.isEquivalent
/-- A "canonical" type order-isomorphic to the ordinal `o`, living in the same universe. This is
defined through the axiom of choice.
Use this over `Iio o` only when it is paramount to have a `Type u` rather than a `Type (u + 1)`. -/
def Ordinal.toType (o : Ordinal.{u}) : Type u :=
o.out.α
instance hasWellFounded_toType (o : Ordinal) : WellFoundedRelation o.toType :=
⟨o.out.r, o.out.wo.wf⟩
instance linearOrder_toType (o : Ordinal) : LinearOrder o.toType :=
@IsWellOrder.linearOrder _ o.out.r o.out.wo
instance wellFoundedLT_toType_lt (o : Ordinal) : WellFoundedLT o.toType :=
o.out.wo.toIsWellFounded
namespace Ordinal
noncomputable instance (o : Ordinal) : SuccOrder o.toType :=
SuccOrder.ofLinearWellFoundedLT o.toType
/-! ### Basic properties of the order type -/
/-- The order type of a well order is an ordinal. -/
def type (r : α → α → Prop) [wo : IsWellOrder α r] : Ordinal :=
⟦⟨α, r, wo⟩⟧
/-- `typeLT α` is an abbreviation for the order type of the `<` relation of `α`. -/
scoped notation "typeLT " α:70 => @Ordinal.type α (· < ·) inferInstance
instance zero : Zero Ordinal :=
⟨type <| @EmptyRelation PEmpty⟩
instance inhabited : Inhabited Ordinal :=
⟨0⟩
instance one : One Ordinal :=
⟨type <| @EmptyRelation PUnit⟩
@[simp]
theorem type_toType (o : Ordinal) : typeLT o.toType = o :=
o.out_eq
theorem type_eq {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s] :
type r = type s ↔ Nonempty (r ≃r s) :=
Quotient.eq'
theorem _root_.RelIso.ordinal_type_eq {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r]
[IsWellOrder β s] (h : r ≃r s) : type r = type s :=
type_eq.2 ⟨h⟩
theorem type_eq_zero_of_empty (r) [IsWellOrder α r] [IsEmpty α] : type r = 0 :=
(RelIso.relIsoOfIsEmpty r _).ordinal_type_eq
@[simp]
theorem type_eq_zero_iff_isEmpty [IsWellOrder α r] : type r = 0 ↔ IsEmpty α :=
⟨fun h =>
let ⟨s⟩ := type_eq.1 h
s.toEquiv.isEmpty,
@type_eq_zero_of_empty α r _⟩
theorem type_ne_zero_iff_nonempty [IsWellOrder α r] : type r ≠ 0 ↔ Nonempty α := by simp
theorem type_ne_zero_of_nonempty (r) [IsWellOrder α r] [h : Nonempty α] : type r ≠ 0 :=
type_ne_zero_iff_nonempty.2 h
theorem type_pEmpty : type (@EmptyRelation PEmpty) = 0 :=
rfl
theorem type_empty : type (@EmptyRelation Empty) = 0 :=
type_eq_zero_of_empty _
theorem type_eq_one_of_unique (r) [IsWellOrder α r] [Nonempty α] [Subsingleton α] : type r = 1 := by
cases nonempty_unique α
exact (RelIso.ofUniqueOfIrrefl r _).ordinal_type_eq
@[simp]
theorem type_eq_one_iff_unique [IsWellOrder α r] : type r = 1 ↔ Nonempty (Unique α) :=
⟨fun h ↦ let ⟨s⟩ := type_eq.1 h; ⟨s.toEquiv.unique⟩,
fun ⟨_⟩ ↦ type_eq_one_of_unique r⟩
theorem type_pUnit : type (@EmptyRelation PUnit) = 1 :=
rfl
theorem type_unit : type (@EmptyRelation Unit) = 1 :=
rfl
@[simp]
theorem toType_empty_iff_eq_zero {o : Ordinal} : IsEmpty o.toType ↔ o = 0 := by
rw [← @type_eq_zero_iff_isEmpty o.toType (· < ·), type_toType]
instance isEmpty_toType_zero : IsEmpty (toType 0) :=
toType_empty_iff_eq_zero.2 rfl
@[simp]
theorem toType_nonempty_iff_ne_zero {o : Ordinal} : Nonempty o.toType ↔ o ≠ 0 := by
rw [← @type_ne_zero_iff_nonempty o.toType (· < ·), type_toType]
protected theorem one_ne_zero : (1 : Ordinal) ≠ 0 :=
type_ne_zero_of_nonempty _
instance nontrivial : Nontrivial Ordinal.{u} :=
⟨⟨1, 0, Ordinal.one_ne_zero⟩⟩
/-- `Quotient.inductionOn` specialized to ordinals.
Not to be confused with well-founded recursion `Ordinal.induction`. -/
@[elab_as_elim]
theorem inductionOn {C : Ordinal → Prop} (o : Ordinal)
(H : ∀ (α r) [IsWellOrder α r], C (type r)) : C o :=
Quot.inductionOn o fun ⟨α, r, wo⟩ => @H α r wo
/-- `Quotient.inductionOn₂` specialized to ordinals.
Not to be confused with well-founded recursion `Ordinal.induction`. -/
@[elab_as_elim]
theorem inductionOn₂ {C : Ordinal → Ordinal → Prop} (o₁ o₂ : Ordinal)
(H : ∀ (α r) [IsWellOrder α r] (β s) [IsWellOrder β s], C (type r) (type s)) : C o₁ o₂ :=
Quotient.inductionOn₂ o₁ o₂ fun ⟨α, r, wo₁⟩ ⟨β, s, wo₂⟩ => @H α r wo₁ β s wo₂
/-- `Quotient.inductionOn₃` specialized to ordinals.
Not to be confused with well-founded recursion `Ordinal.induction`. -/
@[elab_as_elim]
theorem inductionOn₃ {C : Ordinal → Ordinal → Ordinal → Prop} (o₁ o₂ o₃ : Ordinal)
(H : ∀ (α r) [IsWellOrder α r] (β s) [IsWellOrder β s] (γ t) [IsWellOrder γ t],
C (type r) (type s) (type t)) : C o₁ o₂ o₃ :=
Quotient.inductionOn₃ o₁ o₂ o₃ fun ⟨α, r, wo₁⟩ ⟨β, s, wo₂⟩ ⟨γ, t, wo₃⟩ =>
@H α r wo₁ β s wo₂ γ t wo₃
open Classical in
/-- To prove a result on ordinals, it suffices to prove it for order types of well-orders. -/
@[elab_as_elim]
theorem inductionOnWellOrder {C : Ordinal → Prop} (o : Ordinal)
(H : ∀ (α) [LinearOrder α] [WellFoundedLT α], C (typeLT α)) : C o :=
inductionOn o fun α r wo ↦ @H α (linearOrderOfSTO r) wo.toIsWellFounded
open Classical in
/-- To define a function on ordinals, it suffices to define them on order types of well-orders.
Since `LinearOrder` is data-carrying, `liftOnWellOrder_type` is not a definitional equality, unlike
`Quotient.liftOn_mk` which is always def-eq. -/
def liftOnWellOrder {δ : Sort v} (o : Ordinal) (f : ∀ (α) [LinearOrder α] [WellFoundedLT α], δ)
(c : ∀ (α) [LinearOrder α] [WellFoundedLT α] (β) [LinearOrder β] [WellFoundedLT β],
typeLT α = typeLT β → f α = f β) : δ :=
Quotient.liftOn o (fun w ↦ @f w.α (linearOrderOfSTO w.r) w.wo.toIsWellFounded)
fun w₁ w₂ h ↦ @c
w₁.α (linearOrderOfSTO w₁.r) w₁.wo.toIsWellFounded
w₂.α (linearOrderOfSTO w₂.r) w₂.wo.toIsWellFounded
(Quotient.sound h)
@[simp]
theorem liftOnWellOrder_type {δ : Sort v} (f : ∀ (α) [LinearOrder α] [WellFoundedLT α], δ)
(c : ∀ (α) [LinearOrder α] [WellFoundedLT α] (β) [LinearOrder β] [WellFoundedLT β],
typeLT α = typeLT β → f α = f β) {γ} [LinearOrder γ] [WellFoundedLT γ] :
liftOnWellOrder (typeLT γ) f c = f γ := by
change Quotient.liftOn' ⟦_⟧ _ _ = _
rw [Quotient.liftOn'_mk]
congr
exact LinearOrder.ext_lt fun _ _ ↦ Iff.rfl
/-! ### The order on ordinals -/
/--
For `Ordinal`:
* less-equal is defined such that well orders `r` and `s` satisfy `type r ≤ type s` if there exists
a function embedding `r` as an *initial* segment of `s`.
* less-than is defined such that well orders `r` and `s` satisfy `type r < type s` if there exists
a function embedding `r` as a *principal* segment of `s`.
Note that most of the relevant results on initial and principal segments are proved in the
`Order.InitialSeg` file.
-/
instance partialOrder : PartialOrder Ordinal where
le a b :=
Quotient.liftOn₂ a b (fun ⟨_, r, _⟩ ⟨_, s, _⟩ => Nonempty (r ≼i s))
fun _ _ _ _ ⟨f⟩ ⟨g⟩ => propext
⟨fun ⟨h⟩ => ⟨f.symm.toInitialSeg.trans <| h.trans g.toInitialSeg⟩, fun ⟨h⟩ =>
⟨f.toInitialSeg.trans <| h.trans g.symm.toInitialSeg⟩⟩
lt a b :=
Quotient.liftOn₂ a b (fun ⟨_, r, _⟩ ⟨_, s, _⟩ => Nonempty (r ≺i s))
fun _ _ _ _ ⟨f⟩ ⟨g⟩ => propext
⟨fun ⟨h⟩ => ⟨PrincipalSeg.relIsoTrans f.symm <| h.transRelIso g⟩,
fun ⟨h⟩ => ⟨PrincipalSeg.relIsoTrans f <| h.transRelIso g.symm⟩⟩
le_refl := Quot.ind fun ⟨_, _, _⟩ => ⟨InitialSeg.refl _⟩
le_trans a b c :=
Quotient.inductionOn₃ a b c fun _ _ _ ⟨f⟩ ⟨g⟩ => ⟨f.trans g⟩
lt_iff_le_not_le a b :=
Quotient.inductionOn₂ a b fun _ _ =>
⟨fun ⟨f⟩ => ⟨⟨f⟩, fun ⟨g⟩ => (f.transInitial g).irrefl⟩, fun ⟨⟨f⟩, h⟩ =>
f.principalSumRelIso.recOn (fun g => ⟨g⟩) fun g => (h ⟨g.symm.toInitialSeg⟩).elim⟩
le_antisymm a b :=
Quotient.inductionOn₂ a b fun _ _ ⟨h₁⟩ ⟨h₂⟩ =>
Quot.sound ⟨InitialSeg.antisymm h₁ h₂⟩
instance : LinearOrder Ordinal :=
{inferInstanceAs (PartialOrder Ordinal) with
le_total := fun a b => Quotient.inductionOn₂ a b fun ⟨_, r, _⟩ ⟨_, s, _⟩ =>
(InitialSeg.total r s).recOn (fun f => Or.inl ⟨f⟩) fun f => Or.inr ⟨f⟩
toDecidableLE := Classical.decRel _ }
theorem _root_.InitialSeg.ordinal_type_le {α β} {r : α → α → Prop} {s : β → β → Prop}
[IsWellOrder α r] [IsWellOrder β s] (h : r ≼i s) : type r ≤ type s :=
⟨h⟩
theorem _root_.RelEmbedding.ordinal_type_le {α β} {r : α → α → Prop} {s : β → β → Prop}
[IsWellOrder α r] [IsWellOrder β s] (h : r ↪r s) : type r ≤ type s :=
⟨h.collapse⟩
theorem _root_.PrincipalSeg.ordinal_type_lt {α β} {r : α → α → Prop} {s : β → β → Prop}
[IsWellOrder α r] [IsWellOrder β s] (h : r ≺i s) : type r < type s :=
⟨h⟩
@[simp]
protected theorem zero_le (o : Ordinal) : 0 ≤ o :=
inductionOn o fun _ r _ => (InitialSeg.ofIsEmpty _ r).ordinal_type_le
instance : OrderBot Ordinal where
bot := 0
bot_le := Ordinal.zero_le
@[simp]
theorem bot_eq_zero : (⊥ : Ordinal) = 0 :=
rfl
instance instIsEmptyIioZero : IsEmpty (Iio (0 : Ordinal)) := by
simp [← bot_eq_zero]
@[simp]
protected theorem le_zero {o : Ordinal} : o ≤ 0 ↔ o = 0 :=
le_bot_iff
protected theorem pos_iff_ne_zero {o : Ordinal} : 0 < o ↔ o ≠ 0 :=
bot_lt_iff_ne_bot
protected theorem not_lt_zero (o : Ordinal) : ¬o < 0 :=
not_lt_bot
theorem eq_zero_or_pos : ∀ a : Ordinal, a = 0 ∨ 0 < a :=
eq_bot_or_bot_lt
instance : ZeroLEOneClass Ordinal :=
⟨Ordinal.zero_le _⟩
instance instNeZeroOne : NeZero (1 : Ordinal) :=
⟨Ordinal.one_ne_zero⟩
theorem type_le_iff {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r]
[IsWellOrder β s] : type r ≤ type s ↔ Nonempty (r ≼i s) :=
Iff.rfl
theorem type_le_iff' {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r]
[IsWellOrder β s] : type r ≤ type s ↔ Nonempty (r ↪r s) :=
⟨fun ⟨f⟩ => ⟨f⟩, fun ⟨f⟩ => ⟨f.collapse⟩⟩
theorem type_lt_iff {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r]
[IsWellOrder β s] : type r < type s ↔ Nonempty (r ≺i s) :=
Iff.rfl
/-- Given two ordinals `α ≤ β`, then `initialSegToType α β` is the initial segment embedding of
`α.toType` into `β.toType`. -/
def initialSegToType {α β : Ordinal} (h : α ≤ β) : α.toType ≤i β.toType := by
apply Classical.choice (type_le_iff.mp _)
rwa [type_toType, type_toType]
/-- Given two ordinals `α < β`, then `principalSegToType α β` is the principal segment embedding
of `α.toType` into `β.toType`. -/
def principalSegToType {α β : Ordinal} (h : α < β) : α.toType <i β.toType := by
apply Classical.choice (type_lt_iff.mp _)
rwa [type_toType, type_toType]
/-! ### Enumerating elements in a well-order with ordinals -/
/-- The order type of an element inside a well order.
This is registered as a principal segment embedding into the ordinals, with top `type r`. -/
def typein (r : α → α → Prop) [IsWellOrder α r] : @PrincipalSeg α Ordinal.{u} r (· < ·) := by
refine ⟨RelEmbedding.ofMonotone _ fun a b ha ↦
((PrincipalSeg.ofElement r a).codRestrict _ ?_ ?_).ordinal_type_lt, type r, fun a ↦ ⟨?_, ?_⟩⟩
· rintro ⟨c, hc⟩
exact trans hc ha
· exact ha
· rintro ⟨b, rfl⟩
exact (PrincipalSeg.ofElement _ _).ordinal_type_lt
· refine inductionOn a ?_
rintro β s wo ⟨g⟩
exact ⟨_, g.subrelIso.ordinal_type_eq⟩
@[simp]
theorem type_subrel (r : α → α → Prop) [IsWellOrder α r] (a : α) :
type (Subrel r (r · a)) = typein r a :=
rfl
@[simp]
theorem top_typein (r : α → α → Prop) [IsWellOrder α r] : (typein r).top = type r :=
rfl
theorem typein_lt_type (r : α → α → Prop) [IsWellOrder α r] (a : α) : typein r a < type r :=
(typein r).lt_top a
theorem typein_lt_self {o : Ordinal} (i : o.toType) : typein (α := o.toType) (· < ·) i < o := by
simp_rw [← type_toType o]
apply typein_lt_type
@[simp]
theorem typein_top {α β} {r : α → α → Prop} {s : β → β → Prop}
[IsWellOrder α r] [IsWellOrder β s] (f : r ≺i s) : typein s f.top = type r :=
f.subrelIso.ordinal_type_eq
@[simp]
theorem typein_lt_typein (r : α → α → Prop) [IsWellOrder α r] {a b : α} :
typein r a < typein r b ↔ r a b :=
(typein r).map_rel_iff
@[simp]
theorem typein_le_typein (r : α → α → Prop) [IsWellOrder α r] {a b : α} :
typein r a ≤ typein r b ↔ ¬r b a := by
rw [← not_lt, typein_lt_typein]
theorem typein_injective (r : α → α → Prop) [IsWellOrder α r] : Injective (typein r) :=
(typein r).injective
theorem typein_inj (r : α → α → Prop) [IsWellOrder α r] {a b} : typein r a = typein r b ↔ a = b :=
(typein_injective r).eq_iff
theorem mem_range_typein_iff (r : α → α → Prop) [IsWellOrder α r] {o} :
o ∈ Set.range (typein r) ↔ o < type r :=
(typein r).mem_range_iff_rel
theorem typein_surj (r : α → α → Prop) [IsWellOrder α r] {o} (h : o < type r) :
o ∈ Set.range (typein r) :=
(typein r).mem_range_of_rel_top h
theorem typein_surjOn (r : α → α → Prop) [IsWellOrder α r] :
Set.SurjOn (typein r) Set.univ (Set.Iio (type r)) :=
(typein r).surjOn
/-- A well order `r` is order-isomorphic to the set of ordinals smaller than `type r`.
`enum r ⟨o, h⟩` is the `o`-th element of `α` ordered by `r`.
That is, `enum` maps an initial segment of the ordinals, those less than the order type of `r`, to
the elements of `α`. -/
@[simps! symm_apply_coe]
def enum (r : α → α → Prop) [IsWellOrder α r] : (· < · : Iio (type r) → Iio (type r) → Prop) ≃r r :=
(typein r).subrelIso
@[simp]
theorem typein_enum (r : α → α → Prop) [IsWellOrder α r] {o} (h : o < type r) :
typein r (enum r ⟨o, h⟩) = o :=
(typein r).apply_subrelIso _
theorem enum_type {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s]
(f : s ≺i r) {h : type s < type r} : enum r ⟨type s, h⟩ = f.top :=
(typein r).injective <| (typein_enum _ _).trans (typein_top _).symm
@[simp]
theorem enum_typein (r : α → α → Prop) [IsWellOrder α r] (a : α) :
enum r ⟨typein r a, typein_lt_type r a⟩ = a :=
enum_type (PrincipalSeg.ofElement r a)
theorem enum_lt_enum {r : α → α → Prop} [IsWellOrder α r] {o₁ o₂ : Iio (type r)} :
r (enum r o₁) (enum r o₂) ↔ o₁ < o₂ :=
(enum _).map_rel_iff
theorem enum_le_enum (r : α → α → Prop) [IsWellOrder α r] {o₁ o₂ : Iio (type r)} :
¬r (enum r o₁) (enum r o₂) ↔ o₂ ≤ o₁ := by
rw [enum_lt_enum (r := r), not_lt]
-- TODO: generalize to other well-orders
@[simp]
theorem enum_le_enum' (a : Ordinal) {o₁ o₂ : Iio (type (· < ·))} :
enum (· < ·) o₁ ≤ enum (α := a.toType) (· < ·) o₂ ↔ o₁ ≤ o₂ := by
rw [← enum_le_enum, not_lt]
theorem enum_inj {r : α → α → Prop} [IsWellOrder α r] {o₁ o₂ : Iio (type r)} :
enum r o₁ = enum r o₂ ↔ o₁ = o₂ :=
EmbeddingLike.apply_eq_iff_eq _
theorem enum_zero_le {r : α → α → Prop} [IsWellOrder α r] (h0 : 0 < type r) (a : α) :
¬r a (enum r ⟨0, h0⟩) := by
rw [← enum_typein r a, enum_le_enum r]
apply Ordinal.zero_le
theorem enum_zero_le' {o : Ordinal} (h0 : 0 < o) (a : o.toType) :
enum (α := o.toType) (· < ·) ⟨0, type_toType _ ▸ h0⟩ ≤ a := by
rw [← not_lt]
apply enum_zero_le
theorem relIso_enum' {α β : Type u} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r]
[IsWellOrder β s] (f : r ≃r s) (o : Ordinal) :
∀ (hr : o < type r) (hs : o < type s), f (enum r ⟨o, hr⟩) = enum s ⟨o, hs⟩ := by
refine inductionOn o ?_; rintro γ t wo ⟨g⟩ ⟨h⟩
rw [enum_type g, enum_type (g.transRelIso f)]; rfl
theorem relIso_enum {α β : Type u} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r]
[IsWellOrder β s] (f : r ≃r s) (o : Ordinal) (hr : o < type r) :
f (enum r ⟨o, hr⟩) = enum s ⟨o, hr.trans_eq (Quotient.sound ⟨f⟩)⟩ :=
relIso_enum' _ _ _ _
/-- The order isomorphism between ordinals less than `o` and `o.toType`. -/
@[simps! -isSimp]
noncomputable def enumIsoToType (o : Ordinal) : Set.Iio o ≃o o.toType where
toFun x := enum (α := o.toType) (· < ·) ⟨x.1, type_toType _ ▸ x.2⟩
invFun x := ⟨typein (α := o.toType) (· < ·) x, typein_lt_self x⟩
left_inv _ := Subtype.ext_val (typein_enum _ _)
right_inv _ := enum_typein _ _
map_rel_iff' := enum_le_enum' _
instance small_Iio (o : Ordinal.{u}) : Small.{u} (Iio o) :=
⟨_, ⟨(enumIsoToType _).toEquiv⟩⟩
instance small_Iic (o : Ordinal.{u}) : Small.{u} (Iic o) := by
rw [← Iio_union_right]
infer_instance
instance small_Ico (a b : Ordinal.{u}) : Small.{u} (Ico a b) := small_subset Ico_subset_Iio_self
instance small_Icc (a b : Ordinal.{u}) : Small.{u} (Icc a b) := small_subset Icc_subset_Iic_self
instance small_Ioo (a b : Ordinal.{u}) : Small.{u} (Ioo a b) := small_subset Ioo_subset_Iio_self
instance small_Ioc (a b : Ordinal.{u}) : Small.{u} (Ioc a b) := small_subset Ioc_subset_Iic_self
/-- `o.toType` is an `OrderBot` whenever `o ≠ 0`. -/
def toTypeOrderBot {o : Ordinal} (ho : o ≠ 0) : OrderBot o.toType where
bot := (enum (· < ·)) ⟨0, _⟩
bot_le := enum_zero_le' (by rwa [Ordinal.pos_iff_ne_zero])
/-- `o.toType` is an `OrderBot` whenever `0 < o`. -/
@[deprecated "use toTypeOrderBot" (since := "2025-02-13")]
def toTypeOrderBotOfPos {o : Ordinal} (ho : 0 < o) : OrderBot o.toType where
bot := (enum (· < ·)) ⟨0, _⟩
bot_le := enum_zero_le' ho
theorem enum_zero_eq_bot {o : Ordinal} (ho : 0 < o) :
enum (α := o.toType) (· < ·) ⟨0, by rwa [type_toType]⟩ =
have H := toTypeOrderBot (o := o) (by rintro rfl; simp at ho)
(⊥ : o.toType) :=
rfl
theorem lt_wf : @WellFounded Ordinal (· < ·) :=
wellFounded_iff_wellFounded_subrel.mpr (·.induction_on fun ⟨_, _, wo⟩ ↦
RelHomClass.wellFounded (enum _) wo.wf)
instance wellFoundedRelation : WellFoundedRelation Ordinal :=
⟨(· < ·), lt_wf⟩
instance wellFoundedLT : WellFoundedLT Ordinal :=
⟨lt_wf⟩
instance : ConditionallyCompleteLinearOrderBot Ordinal :=
WellFoundedLT.conditionallyCompleteLinearOrderBot _
/-- Reformulation of well founded induction on ordinals as a lemma that works with the
`induction` tactic, as in `induction i using Ordinal.induction with | h i IH => ?_`. -/
theorem induction {p : Ordinal.{u} → Prop} (i : Ordinal.{u}) (h : ∀ j, (∀ k, k < j → p k) → p j) :
p i :=
lt_wf.induction i h
theorem typein_apply {α β} {r : α → α → Prop} {s : β → β → Prop} [IsWellOrder α r] [IsWellOrder β s]
(f : r ≼i s) (a : α) : typein s (f a) = typein r a := by
rw [← f.transPrincipal_apply _ a, (f.transPrincipal _).eq]
/-! ### Cardinality of ordinals -/
/-- The cardinal of an ordinal is the cardinality of any type on which a relation with that order
type is defined. -/
def card : Ordinal → Cardinal :=
Quotient.map WellOrder.α fun _ _ ⟨e⟩ => ⟨e.toEquiv⟩
@[simp]
theorem card_type (r : α → α → Prop) [IsWellOrder α r] : card (type r) = #α :=
rfl
@[simp]
theorem card_typein {r : α → α → Prop} [IsWellOrder α r] (x : α) :
#{ y // r y x } = (typein r x).card :=
rfl
theorem card_le_card {o₁ o₂ : Ordinal} : o₁ ≤ o₂ → card o₁ ≤ card o₂ :=
inductionOn o₁ fun _ _ _ => inductionOn o₂ fun _ _ _ ⟨⟨⟨f, _⟩, _⟩⟩ => ⟨f⟩
@[simp]
theorem card_zero : card 0 = 0 := mk_eq_zero _
@[simp]
theorem card_one : card 1 = 1 := mk_eq_one _
/-! ### Lifting ordinals to a higher universe -/
-- Porting note: Needed to add universe hint .{u} below
/-- The universe lift operation for ordinals, which embeds `Ordinal.{u}` as
a proper initial segment of `Ordinal.{v}` for `v > u`. For the initial segment version,
see `liftInitialSeg`. -/
@[pp_with_univ]
def lift (o : Ordinal.{v}) : Ordinal.{max v u} :=
Quotient.liftOn o (fun w => type <| ULift.down.{u} ⁻¹'o w.r) fun ⟨_, r, _⟩ ⟨_, s, _⟩ ⟨f⟩ =>
Quot.sound
⟨(RelIso.preimage Equiv.ulift r).trans <| f.trans (RelIso.preimage Equiv.ulift s).symm⟩
@[simp]
theorem type_uLift (r : α → α → Prop) [IsWellOrder α r] :
type (ULift.down ⁻¹'o r) = lift.{v} (type r) :=
rfl
theorem _root_.RelIso.ordinal_lift_type_eq {r : α → α → Prop} {s : β → β → Prop}
[IsWellOrder α r] [IsWellOrder β s] (f : r ≃r s) : lift.{v} (type r) = lift.{u} (type s) :=
((RelIso.preimage Equiv.ulift r).trans <|
f.trans (RelIso.preimage Equiv.ulift s).symm).ordinal_type_eq
@[simp]
theorem type_preimage {α β : Type u} (r : α → α → Prop) [IsWellOrder α r] (f : β ≃ α) :
type (f ⁻¹'o r) = type r :=
(RelIso.preimage f r).ordinal_type_eq
@[simp]
theorem type_lift_preimage (r : α → α → Prop) [IsWellOrder α r]
(f : β ≃ α) : lift.{u} (type (f ⁻¹'o r)) = lift.{v} (type r) :=
(RelIso.preimage f r).ordinal_lift_type_eq
/-- `lift.{max u v, u}` equals `lift.{v, u}`.
Unfortunately, the simp lemma doesn't seem to work. -/
theorem lift_umax : lift.{max u v, u} = lift.{v, u} :=
funext fun a =>
inductionOn a fun _ r _ =>
Quotient.sound ⟨(RelIso.preimage Equiv.ulift r).trans (RelIso.preimage Equiv.ulift r).symm⟩
/-- An ordinal lifted to a lower or equal universe equals itself.
Unfortunately, the simp lemma doesn't work. -/
theorem lift_id' (a : Ordinal) : lift a = a :=
inductionOn a fun _ r _ => Quotient.sound ⟨RelIso.preimage Equiv.ulift r⟩
/-- An ordinal lifted to the same universe equals itself. -/
@[simp]
theorem lift_id : ∀ a, lift.{u, u} a = a :=
lift_id'.{u, u}
/-- An ordinal lifted to the zero universe equals itself. -/
@[simp]
theorem lift_uzero (a : Ordinal.{u}) : lift.{0} a = a :=
lift_id' a
theorem lift_type_le {α : Type u} {β : Type v} {r s} [IsWellOrder α r] [IsWellOrder β s] :
lift.{max v w} (type r) ≤ lift.{max u w} (type s) ↔ Nonempty (r ≼i s) := by
constructor <;> refine fun ⟨f⟩ ↦ ⟨?_⟩
· exact (RelIso.preimage Equiv.ulift r).symm.toInitialSeg.trans
(f.trans (RelIso.preimage Equiv.ulift s).toInitialSeg)
· exact (RelIso.preimage Equiv.ulift r).toInitialSeg.trans
(f.trans (RelIso.preimage Equiv.ulift s).symm.toInitialSeg)
theorem lift_type_eq {α : Type u} {β : Type v} {r s} [IsWellOrder α r] [IsWellOrder β s] :
lift.{max v w} (type r) = lift.{max u w} (type s) ↔ Nonempty (r ≃r s) := by
refine Quotient.eq'.trans ⟨?_, ?_⟩ <;> refine fun ⟨f⟩ ↦ ⟨?_⟩
· exact (RelIso.preimage Equiv.ulift r).symm.trans <| f.trans (RelIso.preimage Equiv.ulift s)
· exact (RelIso.preimage Equiv.ulift r).trans <| f.trans (RelIso.preimage Equiv.ulift s).symm
theorem lift_type_lt {α : Type u} {β : Type v} {r s} [IsWellOrder α r] [IsWellOrder β s] :
lift.{max v w} (type r) < lift.{max u w} (type s) ↔ Nonempty (r ≺i s) := by
constructor <;> refine fun ⟨f⟩ ↦ ⟨?_⟩
· exact (f.relIsoTrans (RelIso.preimage Equiv.ulift r).symm).transInitial
(RelIso.preimage Equiv.ulift s).toInitialSeg
· exact (f.relIsoTrans (RelIso.preimage Equiv.ulift r)).transInitial
(RelIso.preimage Equiv.ulift s).symm.toInitialSeg
@[simp]
theorem lift_le {a b : Ordinal} : lift.{u, v} a ≤ lift.{u, v} b ↔ a ≤ b :=
inductionOn₂ a b fun α r _ β s _ => by
rw [← lift_umax]
exact lift_type_le.{_,_,u}
@[simp]
theorem lift_inj {a b : Ordinal} : lift.{u, v} a = lift.{u, v} b ↔ a = b := by
simp_rw [le_antisymm_iff, lift_le]
@[simp]
theorem lift_lt {a b : Ordinal} : lift.{u, v} a < lift.{u, v} b ↔ a < b := by
simp_rw [lt_iff_le_not_le, lift_le]
@[simp]
theorem lift_typein_top {r : α → α → Prop} {s : β → β → Prop}
[IsWellOrder α r] [IsWellOrder β s] (f : r ≺i s) : lift.{u} (typein s f.top) = lift (type r) :=
f.subrelIso.ordinal_lift_type_eq
/-- Initial segment version of the lift operation on ordinals, embedding `Ordinal.{u}` in
`Ordinal.{v}` as an initial segment when `u ≤ v`. -/
def liftInitialSeg : Ordinal.{v} ≤i Ordinal.{max u v} := by
refine ⟨RelEmbedding.ofMonotone lift.{u} (by simp),
fun a b ↦ Ordinal.inductionOn₂ a b fun α r _ β s _ h ↦ ?_⟩
rw [RelEmbedding.ofMonotone_coe, ← lift_id'.{max u v} (type s),
← lift_umax.{v, u}, lift_type_lt] at h
obtain ⟨f⟩ := h
use typein r f.top
rw [RelEmbedding.ofMonotone_coe, ← lift_umax, lift_typein_top, lift_id']
@[simp]
theorem liftInitialSeg_coe : (liftInitialSeg.{v, u} : Ordinal → Ordinal) = lift.{v, u} :=
rfl
@[simp]
theorem lift_lift (a : Ordinal.{u}) : lift.{w} (lift.{v} a) = lift.{max v w} a :=
(liftInitialSeg.trans liftInitialSeg).eq liftInitialSeg a
@[simp]
theorem lift_zero : lift 0 = 0 :=
type_eq_zero_of_empty _
@[simp]
theorem lift_one : lift 1 = 1 :=
type_eq_one_of_unique _
@[simp]
theorem lift_card (a) : Cardinal.lift.{u, v} (card a) = card (lift.{u} a) :=
inductionOn a fun _ _ _ => rfl
theorem mem_range_lift_of_le {a : Ordinal.{u}} {b : Ordinal.{max u v}} (h : b ≤ lift.{v} a) :
b ∈ Set.range lift.{v} :=
liftInitialSeg.mem_range_of_le h
theorem le_lift_iff {a : Ordinal.{u}} {b : Ordinal.{max u v}} :
b ≤ lift.{v} a ↔ ∃ a' ≤ a, lift.{v} a' = b :=
liftInitialSeg.le_apply_iff
theorem lt_lift_iff {a : Ordinal.{u}} {b : Ordinal.{max u v}} :
b < lift.{v} a ↔ ∃ a' < a, lift.{v} a' = b :=
liftInitialSeg.lt_apply_iff
/-! ### The first infinite ordinal ω -/
/-- `ω` is the first infinite ordinal, defined as the order type of `ℕ`. -/
def omega0 : Ordinal.{u} :=
lift (typeLT ℕ)
@[inherit_doc]
scoped notation "ω" => Ordinal.omega0
/-- Note that the presence of this lemma makes `simp [omega0]` form a loop. -/
@[simp]
theorem type_nat_lt : typeLT ℕ = ω :=
(lift_id _).symm
@[simp]
theorem card_omega0 : card ω = ℵ₀ :=
rfl
@[simp]
theorem lift_omega0 : lift ω = ω :=
lift_lift _
/-!
### Definition and first properties of addition on ordinals
In this paragraph, we introduce the addition on ordinals, and prove just enough properties to
deduce that the order on ordinals is total (and therefore well-founded). Further properties of
the addition, together with properties of the other operations, are proved in
`Mathlib/SetTheory/Ordinal/Arithmetic.lean`.
-/
/-- `o₁ + o₂` is the order on the disjoint union of `o₁` and `o₂` obtained by declaring that
every element of `o₁` is smaller than every element of `o₂`. -/
instance add : Add Ordinal.{u} :=
⟨fun o₁ o₂ => Quotient.liftOn₂ o₁ o₂ (fun ⟨_, r, _⟩ ⟨_, s, _⟩ => type (Sum.Lex r s))
fun _ _ _ _ ⟨f⟩ ⟨g⟩ => (RelIso.sumLexCongr f g).ordinal_type_eq⟩
instance addMonoidWithOne : AddMonoidWithOne Ordinal.{u} where
add := (· + ·)
zero := 0
one := 1
zero_add o :=
inductionOn o fun α _ _ =>
Eq.symm <| Quotient.sound ⟨⟨(emptySum PEmpty α).symm, Sum.lex_inr_inr⟩⟩
add_zero o :=
inductionOn o fun α _ _ =>
Eq.symm <| Quotient.sound ⟨⟨(sumEmpty α PEmpty).symm, Sum.lex_inl_inl⟩⟩
add_assoc o₁ o₂ o₃ :=
Quotient.inductionOn₃ o₁ o₂ o₃ fun ⟨α, r, _⟩ ⟨β, s, _⟩ ⟨γ, t, _⟩ =>
Quot.sound
⟨⟨sumAssoc _ _ _, by
intros a b
rcases a with (⟨a | a⟩ | a) <;> rcases b with (⟨b | b⟩ | b) <;>
simp only [sumAssoc_apply_inl_inl, sumAssoc_apply_inl_inr, sumAssoc_apply_inr,
Sum.lex_inl_inl, Sum.lex_inr_inr, Sum.Lex.sep, Sum.lex_inr_inl]⟩⟩
nsmul := nsmulRec
@[simp]
theorem card_add (o₁ o₂ : Ordinal) : card (o₁ + o₂) = card o₁ + card o₂ :=
inductionOn o₁ fun _ __ => inductionOn o₂ fun _ _ _ => rfl
@[simp]
theorem type_sum_lex {α β : Type u} (r : α → α → Prop) (s : β → β → Prop) [IsWellOrder α r]
[IsWellOrder β s] : type (Sum.Lex r s) = type r + type s :=
rfl
@[simp]
theorem card_nat (n : ℕ) : card.{u} n = n := by
induction n <;> [simp; simp only [card_add, card_one, Nat.cast_succ, *]]
@[simp]
theorem card_ofNat (n : ℕ) [n.AtLeastTwo] :
card.{u} ofNat(n) = OfNat.ofNat n :=
card_nat n
instance instAddLeftMono : AddLeftMono Ordinal.{u} where
elim c a b := by
refine inductionOn₃ a b c fun α r _ β s _ γ t _ ⟨f⟩ ↦
(RelEmbedding.ofMonotone (Sum.recOn · Sum.inl (Sum.inr ∘ f)) ?_).ordinal_type_le
simp [f.map_rel_iff]
instance instAddRightMono : AddRightMono Ordinal.{u} where
elim c a b := by
refine inductionOn₃ a b c fun α r _ β s _ γ t _ ⟨f⟩ ↦
(RelEmbedding.ofMonotone (Sum.recOn · (Sum.inl ∘ f) Sum.inr) ?_).ordinal_type_le
simp [f.map_rel_iff]
theorem le_add_right (a b : Ordinal) : a ≤ a + b := by
simpa only [add_zero] using add_le_add_left (Ordinal.zero_le b) a
theorem le_add_left (a b : Ordinal) : a ≤ b + a := by
simpa only [zero_add] using add_le_add_right (Ordinal.zero_le b) a
theorem max_zero_left : ∀ a : Ordinal, max 0 a = a :=
max_bot_left
theorem max_zero_right : ∀ a : Ordinal, max a 0 = a :=
max_bot_right
@[simp]
theorem max_eq_zero {a b : Ordinal} : max a b = 0 ↔ a = 0 ∧ b = 0 :=
max_eq_bot
@[simp]
theorem sInf_empty : sInf (∅ : Set Ordinal) = 0 :=
dif_neg Set.not_nonempty_empty
/-! ### Successor order properties -/
private theorem succ_le_iff' {a b : Ordinal} : a + 1 ≤ b ↔ a < b := by
refine inductionOn₂ a b fun α r _ β s _ ↦ ⟨?_, ?_⟩ <;> rintro ⟨f⟩
· refine ⟨((InitialSeg.leAdd _ _).trans f).toPrincipalSeg fun h ↦ ?_⟩
simpa using h (f (Sum.inr PUnit.unit))
· apply (RelEmbedding.ofMonotone (Sum.recOn · f fun _ ↦ f.top) ?_).ordinal_type_le
simpa [f.map_rel_iff] using f.lt_top
instance : NoMaxOrder Ordinal :=
⟨fun _ => ⟨_, succ_le_iff'.1 le_rfl⟩⟩
instance : SuccOrder Ordinal.{u} :=
SuccOrder.ofSuccLeIff (fun o => o + 1) succ_le_iff'
instance : SuccAddOrder Ordinal := ⟨fun _ => rfl⟩
@[simp]
theorem add_one_eq_succ (o : Ordinal) : o + 1 = succ o :=
rfl
@[simp]
theorem succ_zero : succ (0 : Ordinal) = 1 :=
zero_add 1
-- Porting note: Proof used to be rfl
@[simp]
theorem succ_one : succ (1 : Ordinal) = 2 := by congr; simp only [Nat.unaryCast, zero_add]
theorem add_succ (o₁ o₂ : Ordinal) : o₁ + succ o₂ = succ (o₁ + o₂) :=
(add_assoc _ _ _).symm
theorem one_le_iff_ne_zero {o : Ordinal} : 1 ≤ o ↔ o ≠ 0 := by
rw [Order.one_le_iff_pos, Ordinal.pos_iff_ne_zero]
theorem succ_pos (o : Ordinal) : 0 < succ o :=
bot_lt_succ o
theorem succ_ne_zero (o : Ordinal) : succ o ≠ 0 :=
ne_of_gt <| succ_pos o
@[simp]
theorem lt_one_iff_zero {a : Ordinal} : a < 1 ↔ a = 0 := by
simpa using @lt_succ_bot_iff _ _ _ a _ _
theorem le_one_iff {a : Ordinal} : a ≤ 1 ↔ a = 0 ∨ a = 1 := by
simpa using @le_succ_bot_iff _ _ _ a _
@[simp]
theorem card_succ (o : Ordinal) : card (succ o) = card o + 1 := by
simp only [← add_one_eq_succ, card_add, card_one]
theorem natCast_succ (n : ℕ) : ↑n.succ = succ (n : Ordinal) :=
rfl
instance uniqueIioOne : Unique (Iio (1 : Ordinal)) where
default := ⟨0, zero_lt_one' Ordinal⟩
uniq a := Subtype.ext <| lt_one_iff_zero.1 a.2
@[simp]
theorem Iio_one_default_eq : (default : Iio (1 : Ordinal)) = ⟨0, zero_lt_one' Ordinal⟩ :=
rfl
instance uniqueToTypeOne : Unique (toType 1) where
default := enum (α := toType 1) (· < ·) ⟨0, by simp⟩
uniq a := by
rw [← enum_typein (α := toType 1) (· < ·) a]
congr
rw [← lt_one_iff_zero]
apply typein_lt_self
theorem one_toType_eq (x : toType 1) : x = enum (· < ·) ⟨0, by simp⟩ :=
Unique.eq_default x
/-! ### Extra properties of typein and enum -/
-- TODO: use `enumIsoToType` for lemmas on `toType` rather than `enum` and `typein`.
@[simp]
theorem typein_one_toType (x : toType 1) : typein (α := toType 1) (· < ·) x = 0 := by
rw [one_toType_eq x, typein_enum]
theorem typein_le_typein' (o : Ordinal) {x y : o.toType} :
typein (α := o.toType) (· < ·) x ≤ typein (α := o.toType) (· < ·) y ↔ x ≤ y := by
simp
theorem le_enum_succ {o : Ordinal} (a : (succ o).toType) :
a ≤ enum (α := (succ o).toType) (· < ·) ⟨o, (type_toType _ ▸ lt_succ o)⟩ := by
rw [← enum_typein (α := (succ o).toType) (· < ·) a, enum_le_enum', Subtype.mk_le_mk,
← lt_succ_iff]
apply typein_lt_self
/-! ### Universal ordinal -/
-- intended to be used with explicit universe parameters
/-- `univ.{u v}` is the order type of the ordinals of `Type u` as a member
of `Ordinal.{v}` (when `u < v`). It is an inaccessible cardinal. -/
@[pp_with_univ, nolint checkUnivs]
def univ : Ordinal.{max (u + 1) v} :=
lift.{v, u + 1} (typeLT Ordinal)
theorem univ_id : univ.{u, u + 1} = typeLT Ordinal :=
lift_id _
@[simp]
theorem lift_univ : lift.{w} univ.{u, v} = univ.{u, max v w} :=
lift_lift _
theorem univ_umax : univ.{u, max (u + 1) v} = univ.{u, v} :=
congr_fun lift_umax _
/-- Principal segment version of the lift operation on ordinals, embedding `Ordinal.{u}` in
`Ordinal.{v}` as a principal segment when `u < v`. -/
def liftPrincipalSeg : Ordinal.{u} <i Ordinal.{max (u + 1) v} :=
⟨↑liftInitialSeg.{max (u + 1) v, u}, univ.{u, v}, by
refine fun b => inductionOn b ?_; intro β s _
rw [univ, ← lift_umax]; constructor <;> intro h
· obtain ⟨a, e⟩ := h
rw [← e]
refine inductionOn a ?_
intro α r _
exact lift_type_lt.{u, u + 1, max (u + 1) v}.2 ⟨typein r⟩
· rw [← lift_id (type s)] at h ⊢
obtain ⟨f⟩ := lift_type_lt.{_,_,v}.1 h
obtain ⟨f, a, hf⟩ := f
exists a
revert hf
-- Porting note: apply inductionOn does not work, refine does
refine inductionOn a ?_
intro α r _ hf
refine lift_type_eq.{u, max (u + 1) v, max (u + 1) v}.2
⟨(RelIso.ofSurjective (RelEmbedding.ofMonotone ?_ ?_) ?_).symm⟩
· exact fun b => enum r ⟨f b, (hf _).1 ⟨_, rfl⟩⟩
· refine fun a b h => (typein_lt_typein r).1 ?_
rw [typein_enum, typein_enum]
exact f.map_rel_iff.2 h
· intro a'
obtain ⟨b, e⟩ := (hf _).2 (typein_lt_type _ a')
exists b
simp only [RelEmbedding.ofMonotone_coe]
simp [e]⟩
@[simp]
theorem liftPrincipalSeg_coe :
(liftPrincipalSeg.{u, v} : Ordinal → Ordinal) = lift.{max (u + 1) v} :=
rfl
@[simp]
theorem liftPrincipalSeg_top : (liftPrincipalSeg.{u, v}).top = univ.{u, v} :=
rfl
theorem liftPrincipalSeg_top' : liftPrincipalSeg.{u, u + 1}.top = typeLT Ordinal := by
simp only [liftPrincipalSeg_top, univ_id]
end Ordinal
/-! ### Representing a cardinal with an ordinal -/
namespace Cardinal
open Ordinal
@[simp]
theorem mk_toType (o : Ordinal) : #o.toType = o.card :=
(Ordinal.card_type _).symm.trans <| by rw [Ordinal.type_toType]
/-- The ordinal corresponding to a cardinal `c` is the least ordinal
whose cardinal is `c`. For the order-embedding version, see `ord.order_embedding`. -/
def ord (c : Cardinal) : Ordinal :=
let F := fun α : Type u => ⨅ r : { r // IsWellOrder α r }, @type α r.1 r.2
Quot.liftOn c F
(by
suffices ∀ {α β}, α ≈ β → F α ≤ F β from
fun α β h => (this h).antisymm (this (Setoid.symm h))
rintro α β ⟨f⟩
refine le_ciInf_iff'.2 fun i => ?_
haveI := @RelEmbedding.isWellOrder _ _ (f ⁻¹'o i.1) _ (↑(RelIso.preimage f i.1)) i.2
exact
(ciInf_le' _
(Subtype.mk (f ⁻¹'o i.val)
(@RelEmbedding.isWellOrder _ _ _ _ (↑(RelIso.preimage f i.1)) i.2))).trans_eq
(Quot.sound ⟨RelIso.preimage f i.1⟩))
theorem ord_eq_Inf (α : Type u) : ord #α = ⨅ r : { r // IsWellOrder α r }, @type α r.1 r.2 :=
rfl
theorem ord_eq (α) : ∃ (r : α → α → Prop) (wo : IsWellOrder α r), ord #α = @type α r wo :=
let ⟨r, wo⟩ := ciInf_mem fun r : { r // IsWellOrder α r } => @type α r.1 r.2
⟨r.1, r.2, wo.symm⟩
theorem ord_le_type (r : α → α → Prop) [h : IsWellOrder α r] : ord #α ≤ type r :=
ciInf_le' _ (Subtype.mk r h)
theorem ord_le {c o} : ord c ≤ o ↔ c ≤ o.card :=
inductionOn c fun α =>
Ordinal.inductionOn o fun β s _ => by
let ⟨r, _, e⟩ := ord_eq α
simp only [card_type]; constructor <;> intro h
· rw [e] at h
exact
let ⟨f⟩ := h
⟨f.toEmbedding⟩
· obtain ⟨f⟩ := h
have g := RelEmbedding.preimage f s
haveI := RelEmbedding.isWellOrder g
exact le_trans (ord_le_type _) g.ordinal_type_le
theorem gc_ord_card : GaloisConnection ord card := fun _ _ => ord_le
theorem lt_ord {c o} : o < ord c ↔ o.card < c :=
gc_ord_card.lt_iff_lt
@[simp]
theorem card_ord (c) : (ord c).card = c :=
c.inductionOn fun α ↦ let ⟨r, _, e⟩ := ord_eq α; e ▸ card_type r
theorem card_surjective : Function.Surjective card :=
fun c ↦ ⟨_, card_ord c⟩
/-- Galois coinsertion between `Cardinal.ord` and `Ordinal.card`. -/
def gciOrdCard : GaloisCoinsertion ord card :=
gc_ord_card.toGaloisCoinsertion fun c => c.card_ord.le
theorem ord_card_le (o : Ordinal) : o.card.ord ≤ o :=
gc_ord_card.l_u_le _
theorem lt_ord_succ_card (o : Ordinal) : o < (succ o.card).ord :=
lt_ord.2 <| lt_succ _
theorem card_le_iff {o : Ordinal} {c : Cardinal} : o.card ≤ c ↔ o < (succ c).ord := by
rw [lt_ord, lt_succ_iff]
/--
A variation on `Cardinal.lt_ord` using `≤`: If `o` is no greater than the
initial ordinal of cardinality `c`, then its cardinal is no greater than `c`.
The converse, however, is false (for instance, `o = ω+1` and `c = ℵ₀`).
-/
lemma card_le_of_le_ord {o : Ordinal} {c : Cardinal} (ho : o ≤ c.ord) :
o.card ≤ c := by
rw [← card_ord c]; exact Ordinal.card_le_card ho
@[mono]
theorem ord_strictMono : StrictMono ord :=
gciOrdCard.strictMono_l
@[mono]
theorem ord_mono : Monotone ord :=
gc_ord_card.monotone_l
@[simp]
theorem ord_le_ord {c₁ c₂} : ord c₁ ≤ ord c₂ ↔ c₁ ≤ c₂ :=
gciOrdCard.l_le_l_iff
@[simp]
theorem ord_lt_ord {c₁ c₂} : ord c₁ < ord c₂ ↔ c₁ < c₂ :=
ord_strictMono.lt_iff_lt
@[simp]
theorem ord_zero : ord 0 = 0 :=
gc_ord_card.l_bot
@[simp]
theorem ord_nat (n : ℕ) : ord n = n :=
(ord_le.2 (card_nat n).ge).antisymm
(by
induction' n with n IH
· apply Ordinal.zero_le
· exact succ_le_of_lt (IH.trans_lt <| ord_lt_ord.2 <| Nat.cast_lt.2 (Nat.lt_succ_self n)))
@[simp]
theorem ord_one : ord 1 = 1 := by simpa using ord_nat 1
| @[simp]
theorem ord_ofNat (n : ℕ) [n.AtLeastTwo] : ord ofNat(n) = OfNat.ofNat n :=
| Mathlib/SetTheory/Ordinal/Basic.lean | 1,113 | 1,114 |
/-
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.Order.Bounds.Defs
import Mathlib.Order.Directed
import Mathlib.Order.BoundedOrder.Monotone
import Mathlib.Order.Interval.Set.Basic
/-!
# Upper / lower bounds
In this file we prove various lemmas about upper/lower bounds of a set:
monotonicity, behaviour under `∪`, `∩`, `insert`,
and provide formulas for `∅`, `univ`, and intervals.
-/
open Function Set
open OrderDual (toDual ofDual)
universe u v
variable {α : Type u} {γ : Type v}
section
variable [Preorder α] {s t : Set α} {a b : α}
theorem mem_upperBounds : a ∈ upperBounds s ↔ ∀ x ∈ s, x ≤ a :=
Iff.rfl
theorem mem_lowerBounds : a ∈ lowerBounds s ↔ ∀ x ∈ s, a ≤ x :=
Iff.rfl
lemma mem_upperBounds_iff_subset_Iic : a ∈ upperBounds s ↔ s ⊆ Iic a := Iff.rfl
lemma mem_lowerBounds_iff_subset_Ici : a ∈ lowerBounds s ↔ s ⊆ Ici a := Iff.rfl
theorem bddAbove_def : BddAbove s ↔ ∃ x, ∀ y ∈ s, y ≤ x :=
Iff.rfl
theorem bddBelow_def : BddBelow s ↔ ∃ x, ∀ y ∈ s, x ≤ y :=
Iff.rfl
theorem bot_mem_lowerBounds [OrderBot α] (s : Set α) : ⊥ ∈ lowerBounds s := fun _ _ => bot_le
theorem top_mem_upperBounds [OrderTop α] (s : Set α) : ⊤ ∈ upperBounds s := fun _ _ => le_top
@[simp]
theorem isLeast_bot_iff [OrderBot α] : IsLeast s ⊥ ↔ ⊥ ∈ s :=
and_iff_left <| bot_mem_lowerBounds _
@[simp]
theorem isGreatest_top_iff [OrderTop α] : IsGreatest s ⊤ ↔ ⊤ ∈ s :=
and_iff_left <| top_mem_upperBounds _
/-- A set `s` is not bounded above if and only if for each `x` there exists `y ∈ s` such that `x`
is not greater than or equal to `y`. This version only assumes `Preorder` structure and uses
`¬(y ≤ x)`. A version for linear orders is called `not_bddAbove_iff`. -/
theorem not_bddAbove_iff' : ¬BddAbove s ↔ ∀ x, ∃ y ∈ s, ¬y ≤ x := by
simp [BddAbove, upperBounds, Set.Nonempty]
/-- A set `s` is not bounded below if and only if for each `x` there exists `y ∈ s` such that `x`
is not less than or equal to `y`. This version only assumes `Preorder` structure and uses
`¬(x ≤ y)`. A version for linear orders is called `not_bddBelow_iff`. -/
theorem not_bddBelow_iff' : ¬BddBelow s ↔ ∀ x, ∃ y ∈ s, ¬x ≤ y :=
@not_bddAbove_iff' αᵒᵈ _ _
/-- A set `s` is not bounded above if and only if for each `x` there exists `y ∈ s` that is greater
than `x`. A version for preorders is called `not_bddAbove_iff'`. -/
theorem not_bddAbove_iff {α : Type*} [LinearOrder α] {s : Set α} :
¬BddAbove s ↔ ∀ x, ∃ y ∈ s, x < y := by
simp only [not_bddAbove_iff', not_le]
/-- A set `s` is not bounded below if and only if for each `x` there exists `y ∈ s` that is less
than `x`. A version for preorders is called `not_bddBelow_iff'`. -/
theorem not_bddBelow_iff {α : Type*} [LinearOrder α] {s : Set α} :
¬BddBelow s ↔ ∀ x, ∃ y ∈ s, y < x :=
@not_bddAbove_iff αᵒᵈ _ _
@[simp] lemma bddBelow_preimage_ofDual {s : Set α} : BddBelow (ofDual ⁻¹' s) ↔ BddAbove s := Iff.rfl
@[simp] lemma bddAbove_preimage_ofDual {s : Set α} : BddAbove (ofDual ⁻¹' s) ↔ BddBelow s := Iff.rfl
@[simp] lemma bddBelow_preimage_toDual {s : Set αᵒᵈ} :
BddBelow (toDual ⁻¹' s) ↔ BddAbove s := Iff.rfl
@[simp] lemma bddAbove_preimage_toDual {s : Set αᵒᵈ} :
BddAbove (toDual ⁻¹' s) ↔ BddBelow s := Iff.rfl
theorem BddAbove.dual (h : BddAbove s) : BddBelow (ofDual ⁻¹' s) :=
h
theorem BddBelow.dual (h : BddBelow s) : BddAbove (ofDual ⁻¹' s) :=
h
theorem IsLeast.dual (h : IsLeast s a) : IsGreatest (ofDual ⁻¹' s) (toDual a) :=
h
theorem IsGreatest.dual (h : IsGreatest s a) : IsLeast (ofDual ⁻¹' s) (toDual a) :=
h
theorem IsLUB.dual (h : IsLUB s a) : IsGLB (ofDual ⁻¹' s) (toDual a) :=
h
theorem IsGLB.dual (h : IsGLB s a) : IsLUB (ofDual ⁻¹' s) (toDual a) :=
h
/-- If `a` is the least element of a set `s`, then subtype `s` is an order with bottom element. -/
abbrev IsLeast.orderBot (h : IsLeast s a) :
OrderBot s where
bot := ⟨a, h.1⟩
bot_le := Subtype.forall.2 h.2
/-- If `a` is the greatest element of a set `s`, then subtype `s` is an order with top element. -/
abbrev IsGreatest.orderTop (h : IsGreatest s a) :
OrderTop s where
top := ⟨a, h.1⟩
le_top := Subtype.forall.2 h.2
theorem isLUB_congr (h : upperBounds s = upperBounds t) : IsLUB s a ↔ IsLUB t a := by
rw [IsLUB, IsLUB, h]
theorem isGLB_congr (h : lowerBounds s = lowerBounds t) : IsGLB s a ↔ IsGLB t a := by
rw [IsGLB, IsGLB, h]
/-!
### Monotonicity
-/
theorem upperBounds_mono_set ⦃s t : Set α⦄ (hst : s ⊆ t) : upperBounds t ⊆ upperBounds s :=
fun _ hb _ h => hb <| hst h
theorem lowerBounds_mono_set ⦃s t : Set α⦄ (hst : s ⊆ t) : lowerBounds t ⊆ lowerBounds s :=
fun _ hb _ h => hb <| hst h
theorem upperBounds_mono_mem ⦃a b⦄ (hab : a ≤ b) : a ∈ upperBounds s → b ∈ upperBounds s :=
fun ha _ h => le_trans (ha h) hab
theorem lowerBounds_mono_mem ⦃a b⦄ (hab : a ≤ b) : b ∈ lowerBounds s → a ∈ lowerBounds s :=
fun hb _ h => le_trans hab (hb h)
theorem upperBounds_mono ⦃s t : Set α⦄ (hst : s ⊆ t) ⦃a b⦄ (hab : a ≤ b) :
a ∈ upperBounds t → b ∈ upperBounds s := fun ha =>
upperBounds_mono_set hst <| upperBounds_mono_mem hab ha
theorem lowerBounds_mono ⦃s t : Set α⦄ (hst : s ⊆ t) ⦃a b⦄ (hab : a ≤ b) :
b ∈ lowerBounds t → a ∈ lowerBounds s := fun hb =>
lowerBounds_mono_set hst <| lowerBounds_mono_mem hab hb
/-- If `s ⊆ t` and `t` is bounded above, then so is `s`. -/
theorem BddAbove.mono ⦃s t : Set α⦄ (h : s ⊆ t) : BddAbove t → BddAbove s :=
Nonempty.mono <| upperBounds_mono_set h
/-- If `s ⊆ t` and `t` is bounded below, then so is `s`. -/
theorem BddBelow.mono ⦃s t : Set α⦄ (h : s ⊆ t) : BddBelow t → BddBelow s :=
Nonempty.mono <| lowerBounds_mono_set h
/-- If `a` is a least upper bound for sets `s` and `p`, then it is a least upper bound for any
set `t`, `s ⊆ t ⊆ p`. -/
theorem IsLUB.of_subset_of_superset {s t p : Set α} (hs : IsLUB s a) (hp : IsLUB p a) (hst : s ⊆ t)
(htp : t ⊆ p) : IsLUB t a :=
⟨upperBounds_mono_set htp hp.1, lowerBounds_mono_set (upperBounds_mono_set hst) hs.2⟩
/-- If `a` is a greatest lower bound for sets `s` and `p`, then it is a greater lower bound for any
set `t`, `s ⊆ t ⊆ p`. -/
theorem IsGLB.of_subset_of_superset {s t p : Set α} (hs : IsGLB s a) (hp : IsGLB p a) (hst : s ⊆ t)
(htp : t ⊆ p) : IsGLB t a :=
hs.dual.of_subset_of_superset hp hst htp
theorem IsLeast.mono (ha : IsLeast s a) (hb : IsLeast t b) (hst : s ⊆ t) : b ≤ a :=
hb.2 (hst ha.1)
theorem IsGreatest.mono (ha : IsGreatest s a) (hb : IsGreatest t b) (hst : s ⊆ t) : a ≤ b :=
hb.2 (hst ha.1)
theorem IsLUB.mono (ha : IsLUB s a) (hb : IsLUB t b) (hst : s ⊆ t) : a ≤ b :=
IsLeast.mono hb ha <| upperBounds_mono_set hst
theorem IsGLB.mono (ha : IsGLB s a) (hb : IsGLB t b) (hst : s ⊆ t) : b ≤ a :=
IsGreatest.mono hb ha <| lowerBounds_mono_set hst
theorem subset_lowerBounds_upperBounds (s : Set α) : s ⊆ lowerBounds (upperBounds s) :=
fun _ hx _ hy => hy hx
theorem subset_upperBounds_lowerBounds (s : Set α) : s ⊆ upperBounds (lowerBounds s) :=
fun _ hx _ hy => hy hx
theorem Set.Nonempty.bddAbove_lowerBounds (hs : s.Nonempty) : BddAbove (lowerBounds s) :=
hs.mono (subset_upperBounds_lowerBounds s)
theorem Set.Nonempty.bddBelow_upperBounds (hs : s.Nonempty) : BddBelow (upperBounds s) :=
hs.mono (subset_lowerBounds_upperBounds s)
/-!
### Conversions
-/
theorem IsLeast.isGLB (h : IsLeast s a) : IsGLB s a :=
⟨h.2, fun _ hb => hb h.1⟩
theorem IsGreatest.isLUB (h : IsGreatest s a) : IsLUB s a :=
⟨h.2, fun _ hb => hb h.1⟩
theorem IsLUB.upperBounds_eq (h : IsLUB s a) : upperBounds s = Ici a :=
Set.ext fun _ => ⟨fun hb => h.2 hb, fun hb => upperBounds_mono_mem hb h.1⟩
theorem IsGLB.lowerBounds_eq (h : IsGLB s a) : lowerBounds s = Iic a :=
h.dual.upperBounds_eq
theorem IsLeast.lowerBounds_eq (h : IsLeast s a) : lowerBounds s = Iic a :=
h.isGLB.lowerBounds_eq
theorem IsGreatest.upperBounds_eq (h : IsGreatest s a) : upperBounds s = Ici a :=
h.isLUB.upperBounds_eq
theorem IsGreatest.lt_iff (h : IsGreatest s a) : a < b ↔ ∀ x ∈ s, x < b :=
⟨fun hlt _x hx => (h.2 hx).trans_lt hlt, fun h' => h' _ h.1⟩
theorem IsLeast.lt_iff (h : IsLeast s a) : b < a ↔ ∀ x ∈ s, b < x :=
h.dual.lt_iff
theorem isLUB_le_iff (h : IsLUB s a) : a ≤ b ↔ b ∈ upperBounds s := by
rw [h.upperBounds_eq]
rfl
theorem le_isGLB_iff (h : IsGLB s a) : b ≤ a ↔ b ∈ lowerBounds s := by
rw [h.lowerBounds_eq]
rfl
theorem isLUB_iff_le_iff : IsLUB s a ↔ ∀ b, a ≤ b ↔ b ∈ upperBounds s :=
⟨fun h _ => isLUB_le_iff h, fun H => ⟨(H _).1 le_rfl, fun b hb => (H b).2 hb⟩⟩
theorem isGLB_iff_le_iff : IsGLB s a ↔ ∀ b, b ≤ a ↔ b ∈ lowerBounds s :=
@isLUB_iff_le_iff αᵒᵈ _ _ _
/-- If `s` has a least upper bound, then it is bounded above. -/
theorem IsLUB.bddAbove (h : IsLUB s a) : BddAbove s :=
⟨a, h.1⟩
/-- If `s` has a greatest lower bound, then it is bounded below. -/
theorem IsGLB.bddBelow (h : IsGLB s a) : BddBelow s :=
⟨a, h.1⟩
/-- If `s` has a greatest element, then it is bounded above. -/
theorem IsGreatest.bddAbove (h : IsGreatest s a) : BddAbove s :=
⟨a, h.2⟩
/-- If `s` has a least element, then it is bounded below. -/
theorem IsLeast.bddBelow (h : IsLeast s a) : BddBelow s :=
⟨a, h.2⟩
theorem IsLeast.nonempty (h : IsLeast s a) : s.Nonempty :=
⟨a, h.1⟩
theorem IsGreatest.nonempty (h : IsGreatest s a) : s.Nonempty :=
⟨a, h.1⟩
/-!
### Union and intersection
-/
@[simp]
theorem upperBounds_union : upperBounds (s ∪ t) = upperBounds s ∩ upperBounds t :=
Subset.antisymm (fun _ hb => ⟨fun _ hx => hb (Or.inl hx), fun _ hx => hb (Or.inr hx)⟩)
fun _ hb _ hx => hx.elim (fun hs => hb.1 hs) fun ht => hb.2 ht
@[simp]
theorem lowerBounds_union : lowerBounds (s ∪ t) = lowerBounds s ∩ lowerBounds t :=
@upperBounds_union αᵒᵈ _ s t
theorem union_upperBounds_subset_upperBounds_inter :
upperBounds s ∪ upperBounds t ⊆ upperBounds (s ∩ t) :=
union_subset (upperBounds_mono_set inter_subset_left)
(upperBounds_mono_set inter_subset_right)
theorem union_lowerBounds_subset_lowerBounds_inter :
lowerBounds s ∪ lowerBounds t ⊆ lowerBounds (s ∩ t) :=
@union_upperBounds_subset_upperBounds_inter αᵒᵈ _ s t
theorem isLeast_union_iff {a : α} {s t : Set α} :
IsLeast (s ∪ t) a ↔ IsLeast s a ∧ a ∈ lowerBounds t ∨ a ∈ lowerBounds s ∧ IsLeast t a := by
simp [IsLeast, lowerBounds_union, or_and_right, and_comm (a := a ∈ t), and_assoc]
theorem isGreatest_union_iff :
IsGreatest (s ∪ t) a ↔
IsGreatest s a ∧ a ∈ upperBounds t ∨ a ∈ upperBounds s ∧ IsGreatest t a :=
@isLeast_union_iff αᵒᵈ _ a s t
/-- If `s` is bounded, then so is `s ∩ t` -/
theorem BddAbove.inter_of_left (h : BddAbove s) : BddAbove (s ∩ t) :=
h.mono inter_subset_left
/-- If `t` is bounded, then so is `s ∩ t` -/
theorem BddAbove.inter_of_right (h : BddAbove t) : BddAbove (s ∩ t) :=
h.mono inter_subset_right
/-- If `s` is bounded, then so is `s ∩ t` -/
theorem BddBelow.inter_of_left (h : BddBelow s) : BddBelow (s ∩ t) :=
h.mono inter_subset_left
/-- If `t` is bounded, then so is `s ∩ t` -/
theorem BddBelow.inter_of_right (h : BddBelow t) : BddBelow (s ∩ t) :=
h.mono inter_subset_right
/-- In a directed order, the union of bounded above sets is bounded above. -/
theorem BddAbove.union [IsDirected α (· ≤ ·)] {s t : Set α} :
BddAbove s → BddAbove t → BddAbove (s ∪ t) := by
rintro ⟨a, ha⟩ ⟨b, hb⟩
obtain ⟨c, hca, hcb⟩ := exists_ge_ge a b
rw [BddAbove, upperBounds_union]
exact ⟨c, upperBounds_mono_mem hca ha, upperBounds_mono_mem hcb hb⟩
/-- In a directed order, the union of two sets is bounded above if and only if both sets are. -/
theorem bddAbove_union [IsDirected α (· ≤ ·)] {s t : Set α} :
BddAbove (s ∪ t) ↔ BddAbove s ∧ BddAbove t :=
⟨fun h => ⟨h.mono subset_union_left, h.mono subset_union_right⟩, fun h =>
h.1.union h.2⟩
/-- In a codirected order, the union of bounded below sets is bounded below. -/
theorem BddBelow.union [IsDirected α (· ≥ ·)] {s t : Set α} :
BddBelow s → BddBelow t → BddBelow (s ∪ t) :=
@BddAbove.union αᵒᵈ _ _ _ _
/-- In a codirected order, the union of two sets is bounded below if and only if both sets are. -/
theorem bddBelow_union [IsDirected α (· ≥ ·)] {s t : Set α} :
BddBelow (s ∪ t) ↔ BddBelow s ∧ BddBelow t :=
@bddAbove_union αᵒᵈ _ _ _ _
/-- If `a` is the least upper bound of `s` and `b` is the least upper bound of `t`,
then `a ⊔ b` is the least upper bound of `s ∪ t`. -/
theorem IsLUB.union [SemilatticeSup γ] {a b : γ} {s t : Set γ} (hs : IsLUB s a) (ht : IsLUB t b) :
IsLUB (s ∪ t) (a ⊔ b) :=
⟨fun _ h =>
h.casesOn (fun h => le_sup_of_le_left <| hs.left h) fun h => le_sup_of_le_right <| ht.left h,
fun _ hc =>
sup_le (hs.right fun _ hd => hc <| Or.inl hd) (ht.right fun _ hd => hc <| Or.inr hd)⟩
/-- If `a` is the greatest lower bound of `s` and `b` is the greatest lower bound of `t`,
then `a ⊓ b` is the greatest lower bound of `s ∪ t`. -/
theorem IsGLB.union [SemilatticeInf γ] {a₁ a₂ : γ} {s t : Set γ} (hs : IsGLB s a₁)
(ht : IsGLB t a₂) : IsGLB (s ∪ t) (a₁ ⊓ a₂) :=
hs.dual.union ht
/-- If `a` is the least element of `s` and `b` is the least element of `t`,
then `min a b` is the least element of `s ∪ t`. -/
theorem IsLeast.union [LinearOrder γ] {a b : γ} {s t : Set γ} (ha : IsLeast s a)
(hb : IsLeast t b) : IsLeast (s ∪ t) (min a b) :=
⟨by rcases le_total a b with h | h <;> simp [h, ha.1, hb.1], (ha.isGLB.union hb.isGLB).1⟩
/-- If `a` is the greatest element of `s` and `b` is the greatest element of `t`,
then `max a b` is the greatest element of `s ∪ t`. -/
theorem IsGreatest.union [LinearOrder γ] {a b : γ} {s t : Set γ} (ha : IsGreatest s a)
(hb : IsGreatest t b) : IsGreatest (s ∪ t) (max a b) :=
⟨by rcases le_total a b with h | h <;> simp [h, ha.1, hb.1], (ha.isLUB.union hb.isLUB).1⟩
theorem IsLUB.inter_Ici_of_mem [LinearOrder γ] {s : Set γ} {a b : γ} (ha : IsLUB s a) (hb : b ∈ s) :
IsLUB (s ∩ Ici b) a :=
⟨fun _ hx => ha.1 hx.1, fun c hc =>
have hbc : b ≤ c := hc ⟨hb, le_rfl⟩
ha.2 fun x hx => ((le_total x b).elim fun hxb => hxb.trans hbc) fun hbx => hc ⟨hx, hbx⟩⟩
theorem IsGLB.inter_Iic_of_mem [LinearOrder γ] {s : Set γ} {a b : γ} (ha : IsGLB s a) (hb : b ∈ s) :
IsGLB (s ∩ Iic b) a :=
ha.dual.inter_Ici_of_mem hb
theorem bddAbove_iff_exists_ge [SemilatticeSup γ] {s : Set γ} (x₀ : γ) :
BddAbove s ↔ ∃ x, x₀ ≤ x ∧ ∀ y ∈ s, y ≤ x := by
rw [bddAbove_def, exists_ge_and_iff_exists]
exact Monotone.ball fun x _ => monotone_le
theorem bddBelow_iff_exists_le [SemilatticeInf γ] {s : Set γ} (x₀ : γ) :
BddBelow s ↔ ∃ x, x ≤ x₀ ∧ ∀ y ∈ s, x ≤ y :=
bddAbove_iff_exists_ge (toDual x₀)
theorem BddAbove.exists_ge [SemilatticeSup γ] {s : Set γ} (hs : BddAbove s) (x₀ : γ) :
∃ x, x₀ ≤ x ∧ ∀ y ∈ s, y ≤ x :=
(bddAbove_iff_exists_ge x₀).mp hs
theorem BddBelow.exists_le [SemilatticeInf γ] {s : Set γ} (hs : BddBelow s) (x₀ : γ) :
∃ x, x ≤ x₀ ∧ ∀ y ∈ s, x ≤ y :=
(bddBelow_iff_exists_le x₀).mp hs
/-!
### Specific sets
#### Unbounded intervals
-/
theorem isLeast_Ici : IsLeast (Ici a) a :=
⟨left_mem_Ici, fun _ => id⟩
theorem isGreatest_Iic : IsGreatest (Iic a) a :=
⟨right_mem_Iic, fun _ => id⟩
theorem isLUB_Iic : IsLUB (Iic a) a :=
isGreatest_Iic.isLUB
theorem isGLB_Ici : IsGLB (Ici a) a :=
isLeast_Ici.isGLB
theorem upperBounds_Iic : upperBounds (Iic a) = Ici a :=
isLUB_Iic.upperBounds_eq
theorem lowerBounds_Ici : lowerBounds (Ici a) = Iic a :=
isGLB_Ici.lowerBounds_eq
theorem bddAbove_Iic : BddAbove (Iic a) :=
isLUB_Iic.bddAbove
theorem bddBelow_Ici : BddBelow (Ici a) :=
isGLB_Ici.bddBelow
theorem bddAbove_Iio : BddAbove (Iio a) :=
⟨a, fun _ hx => le_of_lt hx⟩
theorem bddBelow_Ioi : BddBelow (Ioi a) :=
⟨a, fun _ hx => le_of_lt hx⟩
theorem lub_Iio_le (a : α) (hb : IsLUB (Iio a) b) : b ≤ a :=
(isLUB_le_iff hb).mpr fun _ hk => le_of_lt hk
theorem le_glb_Ioi (a : α) (hb : IsGLB (Ioi a) b) : a ≤ b :=
@lub_Iio_le αᵒᵈ _ _ a hb
theorem lub_Iio_eq_self_or_Iio_eq_Iic [PartialOrder γ] {j : γ} (i : γ) (hj : IsLUB (Iio i) j) :
j = i ∨ Iio i = Iic j := by
rcases eq_or_lt_of_le (lub_Iio_le i hj) with hj_eq_i | hj_lt_i
· exact Or.inl hj_eq_i
· right
exact Set.ext fun k => ⟨fun hk_lt => hj.1 hk_lt, fun hk_le_j => lt_of_le_of_lt hk_le_j hj_lt_i⟩
theorem glb_Ioi_eq_self_or_Ioi_eq_Ici [PartialOrder γ] {j : γ} (i : γ) (hj : IsGLB (Ioi i) j) :
j = i ∨ Ioi i = Ici j :=
@lub_Iio_eq_self_or_Iio_eq_Iic γᵒᵈ _ j i hj
section
variable [LinearOrder γ]
theorem exists_lub_Iio (i : γ) : ∃ j, IsLUB (Iio i) j := by
by_cases h_exists_lt : ∃ j, j ∈ upperBounds (Iio i) ∧ j < i
· obtain ⟨j, hj_ub, hj_lt_i⟩ := h_exists_lt
exact ⟨j, hj_ub, fun k hk_ub => hk_ub hj_lt_i⟩
· refine ⟨i, fun j hj => le_of_lt hj, ?_⟩
rw [mem_lowerBounds]
by_contra h
refine h_exists_lt ?_
push_neg at h
exact h
theorem exists_glb_Ioi (i : γ) : ∃ j, IsGLB (Ioi i) j :=
@exists_lub_Iio γᵒᵈ _ i
variable [DenselyOrdered γ]
theorem isLUB_Iio {a : γ} : IsLUB (Iio a) a :=
⟨fun _ hx => le_of_lt hx, fun _ hy => le_of_forall_lt_imp_le_of_dense hy⟩
theorem isGLB_Ioi {a : γ} : IsGLB (Ioi a) a :=
@isLUB_Iio γᵒᵈ _ _ a
theorem upperBounds_Iio {a : γ} : upperBounds (Iio a) = Ici a :=
isLUB_Iio.upperBounds_eq
theorem lowerBounds_Ioi {a : γ} : lowerBounds (Ioi a) = Iic a :=
isGLB_Ioi.lowerBounds_eq
end
/-!
#### Singleton
-/
@[simp] theorem isGreatest_singleton : IsGreatest {a} a :=
⟨mem_singleton a, fun _ hx => le_of_eq <| eq_of_mem_singleton hx⟩
@[simp] theorem isLeast_singleton : IsLeast {a} a :=
@isGreatest_singleton αᵒᵈ _ a
@[simp] theorem isLUB_singleton : IsLUB {a} a :=
isGreatest_singleton.isLUB
@[simp] theorem isGLB_singleton : IsGLB {a} a :=
isLeast_singleton.isGLB
@[simp] lemma bddAbove_singleton : BddAbove ({a} : Set α) := isLUB_singleton.bddAbove
@[simp] lemma bddBelow_singleton : BddBelow ({a} : Set α) := isGLB_singleton.bddBelow
@[simp]
theorem upperBounds_singleton : upperBounds {a} = Ici a :=
isLUB_singleton.upperBounds_eq
@[simp]
theorem lowerBounds_singleton : lowerBounds {a} = Iic a :=
isGLB_singleton.lowerBounds_eq
/-!
#### Bounded intervals
-/
theorem bddAbove_Icc : BddAbove (Icc a b) :=
⟨b, fun _ => And.right⟩
theorem bddBelow_Icc : BddBelow (Icc a b) :=
⟨a, fun _ => And.left⟩
theorem bddAbove_Ico : BddAbove (Ico a b) :=
bddAbove_Icc.mono Ico_subset_Icc_self
theorem bddBelow_Ico : BddBelow (Ico a b) :=
bddBelow_Icc.mono Ico_subset_Icc_self
theorem bddAbove_Ioc : BddAbove (Ioc a b) :=
bddAbove_Icc.mono Ioc_subset_Icc_self
theorem bddBelow_Ioc : BddBelow (Ioc a b) :=
bddBelow_Icc.mono Ioc_subset_Icc_self
theorem bddAbove_Ioo : BddAbove (Ioo a b) :=
bddAbove_Icc.mono Ioo_subset_Icc_self
theorem bddBelow_Ioo : BddBelow (Ioo a b) :=
bddBelow_Icc.mono Ioo_subset_Icc_self
theorem isGreatest_Icc (h : a ≤ b) : IsGreatest (Icc a b) b :=
⟨right_mem_Icc.2 h, fun _ => And.right⟩
theorem isLUB_Icc (h : a ≤ b) : IsLUB (Icc a b) b :=
(isGreatest_Icc h).isLUB
theorem upperBounds_Icc (h : a ≤ b) : upperBounds (Icc a b) = Ici b :=
(isLUB_Icc h).upperBounds_eq
theorem isLeast_Icc (h : a ≤ b) : IsLeast (Icc a b) a :=
⟨left_mem_Icc.2 h, fun _ => And.left⟩
theorem isGLB_Icc (h : a ≤ b) : IsGLB (Icc a b) a :=
(isLeast_Icc h).isGLB
theorem lowerBounds_Icc (h : a ≤ b) : lowerBounds (Icc a b) = Iic a :=
(isGLB_Icc h).lowerBounds_eq
theorem isGreatest_Ioc (h : a < b) : IsGreatest (Ioc a b) b :=
⟨right_mem_Ioc.2 h, fun _ => And.right⟩
theorem isLUB_Ioc (h : a < b) : IsLUB (Ioc a b) b :=
(isGreatest_Ioc h).isLUB
theorem upperBounds_Ioc (h : a < b) : upperBounds (Ioc a b) = Ici b :=
(isLUB_Ioc h).upperBounds_eq
theorem isLeast_Ico (h : a < b) : IsLeast (Ico a b) a :=
⟨left_mem_Ico.2 h, fun _ => And.left⟩
theorem isGLB_Ico (h : a < b) : IsGLB (Ico a b) a :=
(isLeast_Ico h).isGLB
theorem lowerBounds_Ico (h : a < b) : lowerBounds (Ico a b) = Iic a :=
(isGLB_Ico h).lowerBounds_eq
section
variable [SemilatticeSup γ] [DenselyOrdered γ]
theorem isGLB_Ioo {a b : γ} (h : a < b) : IsGLB (Ioo a b) a :=
⟨fun _ hx => hx.1.le, fun x hx => by
rcases eq_or_lt_of_le (le_sup_right : a ≤ x ⊔ a) with h₁ | h₂
· exact h₁.symm ▸ le_sup_left
obtain ⟨y, lty, ylt⟩ := exists_between h₂
apply (not_lt_of_le (sup_le (hx ⟨lty, ylt.trans_le (sup_le _ h.le)⟩) lty.le) ylt).elim
obtain ⟨u, au, ub⟩ := exists_between h
apply (hx ⟨au, ub⟩).trans ub.le⟩
theorem lowerBounds_Ioo {a b : γ} (hab : a < b) : lowerBounds (Ioo a b) = Iic a :=
(isGLB_Ioo hab).lowerBounds_eq
theorem isGLB_Ioc {a b : γ} (hab : a < b) : IsGLB (Ioc a b) a :=
(isGLB_Ioo hab).of_subset_of_superset (isGLB_Icc hab.le) Ioo_subset_Ioc_self Ioc_subset_Icc_self
theorem lowerBounds_Ioc {a b : γ} (hab : a < b) : lowerBounds (Ioc a b) = Iic a :=
(isGLB_Ioc hab).lowerBounds_eq
end
section
variable [SemilatticeInf γ] [DenselyOrdered γ]
theorem isLUB_Ioo {a b : γ} (hab : a < b) : IsLUB (Ioo a b) b := by
simpa only [Ioo_toDual] using isGLB_Ioo hab.dual
theorem upperBounds_Ioo {a b : γ} (hab : a < b) : upperBounds (Ioo a b) = Ici b :=
(isLUB_Ioo hab).upperBounds_eq
theorem isLUB_Ico {a b : γ} (hab : a < b) : IsLUB (Ico a b) b := by
simpa only [Ioc_toDual] using isGLB_Ioc hab.dual
theorem upperBounds_Ico {a b : γ} (hab : a < b) : upperBounds (Ico a b) = Ici b :=
(isLUB_Ico hab).upperBounds_eq
end
theorem bddBelow_iff_subset_Ici : BddBelow s ↔ ∃ a, s ⊆ Ici a :=
Iff.rfl
theorem bddAbove_iff_subset_Iic : BddAbove s ↔ ∃ a, s ⊆ Iic a :=
Iff.rfl
theorem bddBelow_bddAbove_iff_subset_Icc : BddBelow s ∧ BddAbove s ↔ ∃ a b, s ⊆ Icc a b := by
simp [Ici_inter_Iic.symm, subset_inter_iff, bddBelow_iff_subset_Ici,
bddAbove_iff_subset_Iic, exists_and_left, exists_and_right]
/-!
#### Univ
-/
@[simp] theorem isGreatest_univ_iff : IsGreatest univ a ↔ IsTop a := by
simp [IsGreatest, mem_upperBounds, IsTop]
theorem isGreatest_univ [OrderTop α] : IsGreatest (univ : Set α) ⊤ :=
isGreatest_univ_iff.2 isTop_top
@[simp]
theorem OrderTop.upperBounds_univ [PartialOrder γ] [OrderTop γ] :
upperBounds (univ : Set γ) = {⊤} := by rw [isGreatest_univ.upperBounds_eq, Ici_top]
theorem isLUB_univ [OrderTop α] : IsLUB (univ : Set α) ⊤ :=
isGreatest_univ.isLUB
@[simp]
theorem OrderBot.lowerBounds_univ [PartialOrder γ] [OrderBot γ] :
lowerBounds (univ : Set γ) = {⊥} :=
@OrderTop.upperBounds_univ γᵒᵈ _ _
@[simp] theorem isLeast_univ_iff : IsLeast univ a ↔ IsBot a :=
@isGreatest_univ_iff αᵒᵈ _ _
theorem isLeast_univ [OrderBot α] : IsLeast (univ : Set α) ⊥ :=
@isGreatest_univ αᵒᵈ _ _
theorem isGLB_univ [OrderBot α] : IsGLB (univ : Set α) ⊥ :=
isLeast_univ.isGLB
@[simp]
theorem NoTopOrder.upperBounds_univ [NoTopOrder α] : upperBounds (univ : Set α) = ∅ :=
eq_empty_of_subset_empty fun b hb =>
not_isTop b fun x => hb (mem_univ x)
@[deprecated (since := "2025-04-18")]
alias NoMaxOrder.upperBounds_univ := NoTopOrder.upperBounds_univ
@[simp]
theorem NoBotOrder.lowerBounds_univ [NoBotOrder α] : lowerBounds (univ : Set α) = ∅ :=
@NoTopOrder.upperBounds_univ αᵒᵈ _ _
@[deprecated (since := "2025-04-18")]
alias NoMinOrder.lowerBounds_univ := NoBotOrder.lowerBounds_univ
@[simp]
theorem not_bddAbove_univ [NoTopOrder α] : ¬BddAbove (univ : Set α) := by simp [BddAbove]
@[simp]
theorem not_bddBelow_univ [NoBotOrder α] : ¬BddBelow (univ : Set α) :=
@not_bddAbove_univ αᵒᵈ _ _
/-!
#### Empty set
-/
@[simp]
theorem upperBounds_empty : upperBounds (∅ : Set α) = univ := by
simp only [upperBounds, eq_univ_iff_forall, mem_setOf_eq, forall_mem_empty, forall_true_iff]
@[simp]
theorem lowerBounds_empty : lowerBounds (∅ : Set α) = univ :=
@upperBounds_empty αᵒᵈ _
@[simp]
theorem bddAbove_empty [Nonempty α] : BddAbove (∅ : Set α) := by
simp only [BddAbove, upperBounds_empty, univ_nonempty]
@[simp]
theorem bddBelow_empty [Nonempty α] : BddBelow (∅ : Set α) := by
simp only [BddBelow, lowerBounds_empty, univ_nonempty]
@[simp] theorem isGLB_empty_iff : IsGLB ∅ a ↔ IsTop a := by
simp [IsGLB]
@[simp] theorem isLUB_empty_iff : IsLUB ∅ a ↔ IsBot a :=
@isGLB_empty_iff αᵒᵈ _ _
theorem isGLB_empty [OrderTop α] : IsGLB ∅ (⊤ : α) :=
isGLB_empty_iff.2 isTop_top
theorem isLUB_empty [OrderBot α] : IsLUB ∅ (⊥ : α) :=
@isGLB_empty αᵒᵈ _ _
theorem IsLUB.nonempty [NoBotOrder α] (hs : IsLUB s a) : s.Nonempty :=
nonempty_iff_ne_empty.2 fun h =>
not_isBot a fun _ => hs.right <| by rw [h, upperBounds_empty]; exact mem_univ _
theorem IsGLB.nonempty [NoTopOrder α] (hs : IsGLB s a) : s.Nonempty :=
hs.dual.nonempty
theorem nonempty_of_not_bddAbove [ha : Nonempty α] (h : ¬BddAbove s) : s.Nonempty :=
(Nonempty.elim ha) fun x => (not_bddAbove_iff'.1 h x).imp fun _ ha => ha.1
theorem nonempty_of_not_bddBelow [Nonempty α] (h : ¬BddBelow s) : s.Nonempty :=
@nonempty_of_not_bddAbove αᵒᵈ _ _ _ h
/-!
#### insert
-/
/-- Adding a point to a set preserves its boundedness above. -/
@[simp]
theorem bddAbove_insert [IsDirected α (· ≤ ·)] {s : Set α} {a : α} :
BddAbove (insert a s) ↔ BddAbove s := by
simp only [insert_eq, bddAbove_union, bddAbove_singleton, true_and]
protected theorem BddAbove.insert [IsDirected α (· ≤ ·)] {s : Set α} (a : α) :
BddAbove s → BddAbove (insert a s) :=
bddAbove_insert.2
/-- Adding a point to a set preserves its boundedness below. -/
@[simp]
theorem bddBelow_insert [IsDirected α (· ≥ ·)] {s : Set α} {a : α} :
BddBelow (insert a s) ↔ BddBelow s := by
simp only [insert_eq, bddBelow_union, bddBelow_singleton, true_and]
protected theorem BddBelow.insert [IsDirected α (· ≥ ·)] {s : Set α} (a : α) :
BddBelow s → BddBelow (insert a s) :=
bddBelow_insert.2
protected theorem IsLUB.insert [SemilatticeSup γ] (a) {b} {s : Set γ} (hs : IsLUB s b) :
IsLUB (insert a s) (a ⊔ b) := by
rw [insert_eq]
exact isLUB_singleton.union hs
protected theorem IsGLB.insert [SemilatticeInf γ] (a) {b} {s : Set γ} (hs : IsGLB s b) :
IsGLB (insert a s) (a ⊓ b) := by
rw [insert_eq]
exact isGLB_singleton.union hs
protected theorem IsGreatest.insert [LinearOrder γ] (a) {b} {s : Set γ} (hs : IsGreatest s b) :
IsGreatest (insert a s) (max a b) := by
rw [insert_eq]
exact isGreatest_singleton.union hs
protected theorem IsLeast.insert [LinearOrder γ] (a) {b} {s : Set γ} (hs : IsLeast s b) :
IsLeast (insert a s) (min a b) := by
rw [insert_eq]
exact isLeast_singleton.union hs
@[simp]
theorem upperBounds_insert (a : α) (s : Set α) :
upperBounds (insert a s) = Ici a ∩ upperBounds s := by
rw [insert_eq, upperBounds_union, upperBounds_singleton]
@[simp]
theorem lowerBounds_insert (a : α) (s : Set α) :
lowerBounds (insert a s) = Iic a ∩ lowerBounds s := by
rw [insert_eq, lowerBounds_union, lowerBounds_singleton]
/-- When there is a global maximum, every set is bounded above. -/
@[simp]
protected theorem OrderTop.bddAbove [OrderTop α] (s : Set α) : BddAbove s :=
⟨⊤, fun a _ => OrderTop.le_top a⟩
/-- When there is a global minimum, every set is bounded below. -/
@[simp]
protected theorem OrderBot.bddBelow [OrderBot α] (s : Set α) : BddBelow s :=
⟨⊥, fun a _ => OrderBot.bot_le a⟩
/-- Sets are automatically bounded or cobounded in complete lattices. To use the same statements
in complete and conditionally complete lattices but let automation fill automatically the
boundedness proofs in complete lattices, we use the tactic `bddDefault` in the statements,
in the form `(hA : BddAbove A := by bddDefault)`. -/
macro "bddDefault" : tactic =>
`(tactic| first
| apply OrderTop.bddAbove
| apply OrderBot.bddBelow)
/-!
#### Pair
-/
theorem isLUB_pair [SemilatticeSup γ] {a b : γ} : IsLUB {a, b} (a ⊔ b) :=
isLUB_singleton.insert _
theorem isGLB_pair [SemilatticeInf γ] {a b : γ} : IsGLB {a, b} (a ⊓ b) :=
isGLB_singleton.insert _
theorem isLeast_pair [LinearOrder γ] {a b : γ} : IsLeast {a, b} (min a b) :=
isLeast_singleton.insert _
theorem isGreatest_pair [LinearOrder γ] {a b : γ} : IsGreatest {a, b} (max a b) :=
isGreatest_singleton.insert _
| /-!
#### Lower/upper bounds
| Mathlib/Order/Bounds/Basic.lean | 811 | 812 |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Johan Commelin, Mario Carneiro
-/
import Mathlib.Algebra.Algebra.Subalgebra.Lattice
import Mathlib.Algebra.Algebra.Tower
import Mathlib.Algebra.GroupWithZero.Divisibility
import Mathlib.Algebra.MonoidAlgebra.Basic
import Mathlib.Algebra.MonoidAlgebra.Support
import Mathlib.Algebra.Regular.Pow
import Mathlib.Data.Finsupp.Antidiagonal
import Mathlib.Order.SymmDiff
/-!
# Multivariate polynomials
This file defines polynomial rings over a base ring (or even semiring),
with variables from a general type `σ` (which could be infinite).
## Important definitions
Let `R` be a commutative ring (or a semiring) and let `σ` be an arbitrary
type. This file creates the type `MvPolynomial σ R`, which mathematicians
might denote $R[X_i : i \in σ]$. It is the type of multivariate
(a.k.a. multivariable) polynomials, with variables
corresponding to the terms in `σ`, and coefficients in `R`.
### Notation
In the definitions below, we use the following notation:
+ `σ : Type*` (indexing the variables)
+ `R : Type*` `[CommSemiring R]` (the coefficients)
+ `s : σ →₀ ℕ`, a function from `σ` to `ℕ` which is zero away from a finite set.
This will give rise to a monomial in `MvPolynomial σ R` which mathematicians might call `X^s`
+ `a : R`
+ `i : σ`, with corresponding monomial `X i`, often denoted `X_i` by mathematicians
+ `p : MvPolynomial σ R`
### Definitions
* `MvPolynomial σ R` : the type of polynomials with variables of type `σ` and coefficients
in the commutative semiring `R`
* `monomial s a` : the monomial which mathematically would be denoted `a * X^s`
* `C a` : the constant polynomial with value `a`
* `X i` : the degree one monomial corresponding to i; mathematically this might be denoted `Xᵢ`.
* `coeff s p` : the coefficient of `s` in `p`.
## Implementation notes
Recall that if `Y` has a zero, then `X →₀ Y` is the type of functions from `X` to `Y` with finite
support, i.e. such that only finitely many elements of `X` get sent to non-zero terms in `Y`.
The definition of `MvPolynomial σ R` is `(σ →₀ ℕ) →₀ R`; here `σ →₀ ℕ` denotes the space of all
monomials in the variables, and the function to `R` sends a monomial to its coefficient in
the polynomial being represented.
## Tags
polynomial, multivariate polynomial, multivariable polynomial
-/
noncomputable section
open Set Function Finsupp AddMonoidAlgebra
open scoped Pointwise
universe u v w x
variable {R : Type u} {S₁ : Type v} {S₂ : Type w} {S₃ : Type x}
/-- Multivariate polynomial, where `σ` is the index set of the variables and
`R` is the coefficient ring -/
def MvPolynomial (σ : Type*) (R : Type*) [CommSemiring R] :=
AddMonoidAlgebra R (σ →₀ ℕ)
namespace MvPolynomial
-- Porting note: because of `MvPolynomial.C` and `MvPolynomial.X` this linter throws
-- tons of warnings in this file, and it's easier to just disable them globally in the file
variable {σ : Type*} {a a' a₁ a₂ : R} {e : ℕ} {n m : σ} {s : σ →₀ ℕ}
section CommSemiring
section Instances
instance decidableEqMvPolynomial [CommSemiring R] [DecidableEq σ] [DecidableEq R] :
DecidableEq (MvPolynomial σ R) :=
Finsupp.instDecidableEq
instance commSemiring [CommSemiring R] : CommSemiring (MvPolynomial σ R) :=
AddMonoidAlgebra.commSemiring
instance inhabited [CommSemiring R] : Inhabited (MvPolynomial σ R) :=
⟨0⟩
instance distribuMulAction [Monoid R] [CommSemiring S₁] [DistribMulAction R S₁] :
DistribMulAction R (MvPolynomial σ S₁) :=
AddMonoidAlgebra.distribMulAction
instance smulZeroClass [CommSemiring S₁] [SMulZeroClass R S₁] :
SMulZeroClass R (MvPolynomial σ S₁) :=
AddMonoidAlgebra.smulZeroClass
instance faithfulSMul [CommSemiring S₁] [SMulZeroClass R S₁] [FaithfulSMul R S₁] :
FaithfulSMul R (MvPolynomial σ S₁) :=
AddMonoidAlgebra.faithfulSMul
instance module [Semiring R] [CommSemiring S₁] [Module R S₁] : Module R (MvPolynomial σ S₁) :=
AddMonoidAlgebra.module
instance isScalarTower [CommSemiring S₂] [SMul R S₁] [SMulZeroClass R S₂] [SMulZeroClass S₁ S₂]
[IsScalarTower R S₁ S₂] : IsScalarTower R S₁ (MvPolynomial σ S₂) :=
AddMonoidAlgebra.isScalarTower
instance smulCommClass [CommSemiring S₂] [SMulZeroClass R S₂] [SMulZeroClass S₁ S₂]
[SMulCommClass R S₁ S₂] : SMulCommClass R S₁ (MvPolynomial σ S₂) :=
AddMonoidAlgebra.smulCommClass
instance isCentralScalar [CommSemiring S₁] [SMulZeroClass R S₁] [SMulZeroClass Rᵐᵒᵖ S₁]
[IsCentralScalar R S₁] : IsCentralScalar R (MvPolynomial σ S₁) :=
AddMonoidAlgebra.isCentralScalar
instance algebra [CommSemiring R] [CommSemiring S₁] [Algebra R S₁] :
Algebra R (MvPolynomial σ S₁) :=
AddMonoidAlgebra.algebra
instance isScalarTower_right [CommSemiring S₁] [DistribSMul R S₁] [IsScalarTower R S₁ S₁] :
IsScalarTower R (MvPolynomial σ S₁) (MvPolynomial σ S₁) :=
AddMonoidAlgebra.isScalarTower_self _
instance smulCommClass_right [CommSemiring S₁] [DistribSMul R S₁] [SMulCommClass R S₁ S₁] :
SMulCommClass R (MvPolynomial σ S₁) (MvPolynomial σ S₁) :=
AddMonoidAlgebra.smulCommClass_self _
/-- If `R` is a subsingleton, then `MvPolynomial σ R` has a unique element -/
instance unique [CommSemiring R] [Subsingleton R] : Unique (MvPolynomial σ R) :=
AddMonoidAlgebra.unique
end Instances
variable [CommSemiring R] [CommSemiring S₁] {p q : MvPolynomial σ R}
/-- `monomial s a` is the monomial with coefficient `a` and exponents given by `s` -/
def monomial (s : σ →₀ ℕ) : R →ₗ[R] MvPolynomial σ R :=
AddMonoidAlgebra.lsingle s
theorem one_def : (1 : MvPolynomial σ R) = monomial 0 1 := rfl
theorem single_eq_monomial (s : σ →₀ ℕ) (a : R) : Finsupp.single s a = monomial s a :=
rfl
theorem mul_def : p * q = p.sum fun m a => q.sum fun n b => monomial (m + n) (a * b) :=
AddMonoidAlgebra.mul_def
/-- `C a` is the constant polynomial with value `a` -/
def C : R →+* MvPolynomial σ R :=
{ singleZeroRingHom with toFun := monomial 0 }
variable (R σ)
@[simp]
theorem algebraMap_eq : algebraMap R (MvPolynomial σ R) = C :=
rfl
variable {R σ}
/-- `X n` is the degree `1` monomial $X_n$. -/
def X (n : σ) : MvPolynomial σ R :=
monomial (Finsupp.single n 1) 1
theorem monomial_left_injective {r : R} (hr : r ≠ 0) :
Function.Injective fun s : σ →₀ ℕ => monomial s r :=
Finsupp.single_left_injective hr
@[simp]
theorem monomial_left_inj {s t : σ →₀ ℕ} {r : R} (hr : r ≠ 0) :
monomial s r = monomial t r ↔ s = t :=
Finsupp.single_left_inj hr
theorem C_apply : (C a : MvPolynomial σ R) = monomial 0 a :=
rfl
@[simp]
theorem C_0 : C 0 = (0 : MvPolynomial σ R) := map_zero _
@[simp]
theorem C_1 : C 1 = (1 : MvPolynomial σ R) :=
rfl
theorem C_mul_monomial : C a * monomial s a' = monomial s (a * a') := by
-- Porting note: this `show` feels like defeq abuse, but I can't find the appropriate lemmas
show AddMonoidAlgebra.single _ _ * AddMonoidAlgebra.single _ _ = AddMonoidAlgebra.single _ _
simp [C_apply, single_mul_single]
@[simp]
theorem C_add : (C (a + a') : MvPolynomial σ R) = C a + C a' :=
Finsupp.single_add _ _ _
@[simp]
theorem C_mul : (C (a * a') : MvPolynomial σ R) = C a * C a' :=
C_mul_monomial.symm
@[simp]
theorem C_pow (a : R) (n : ℕ) : (C (a ^ n) : MvPolynomial σ R) = C a ^ n :=
map_pow _ _ _
theorem C_injective (σ : Type*) (R : Type*) [CommSemiring R] :
Function.Injective (C : R → MvPolynomial σ R) :=
Finsupp.single_injective _
theorem C_surjective {R : Type*} [CommSemiring R] (σ : Type*) [IsEmpty σ] :
Function.Surjective (C : R → MvPolynomial σ R) := by
refine fun p => ⟨p.toFun 0, Finsupp.ext fun a => ?_⟩
simp only [C_apply, ← single_eq_monomial, (Finsupp.ext isEmptyElim (α := σ) : a = 0),
single_eq_same]
rfl
@[simp]
theorem C_inj {σ : Type*} (R : Type*) [CommSemiring R] (r s : R) :
(C r : MvPolynomial σ R) = C s ↔ r = s :=
(C_injective σ R).eq_iff
@[simp] lemma C_eq_zero : (C a : MvPolynomial σ R) = 0 ↔ a = 0 := by rw [← map_zero C, C_inj]
lemma C_ne_zero : (C a : MvPolynomial σ R) ≠ 0 ↔ a ≠ 0 :=
C_eq_zero.ne
instance nontrivial_of_nontrivial (σ : Type*) (R : Type*) [CommSemiring R] [Nontrivial R] :
Nontrivial (MvPolynomial σ R) :=
inferInstanceAs (Nontrivial <| AddMonoidAlgebra R (σ →₀ ℕ))
instance infinite_of_infinite (σ : Type*) (R : Type*) [CommSemiring R] [Infinite R] :
Infinite (MvPolynomial σ R) :=
Infinite.of_injective C (C_injective _ _)
instance infinite_of_nonempty (σ : Type*) (R : Type*) [Nonempty σ] [CommSemiring R]
[Nontrivial R] : Infinite (MvPolynomial σ R) :=
Infinite.of_injective ((fun s : σ →₀ ℕ => monomial s 1) ∘ Finsupp.single (Classical.arbitrary σ))
<| (monomial_left_injective one_ne_zero).comp (Finsupp.single_injective _)
theorem C_eq_coe_nat (n : ℕ) : (C ↑n : MvPolynomial σ R) = n := by
induction n <;> simp [*]
theorem C_mul' : MvPolynomial.C a * p = a • p :=
(Algebra.smul_def a p).symm
theorem smul_eq_C_mul (p : MvPolynomial σ R) (a : R) : a • p = C a * p :=
C_mul'.symm
theorem C_eq_smul_one : (C a : MvPolynomial σ R) = a • (1 : MvPolynomial σ R) := by
rw [← C_mul', mul_one]
theorem smul_monomial {S₁ : Type*} [SMulZeroClass S₁ R] (r : S₁) :
r • monomial s a = monomial s (r • a) :=
Finsupp.smul_single _ _ _
theorem X_injective [Nontrivial R] : Function.Injective (X : σ → MvPolynomial σ R) :=
(monomial_left_injective one_ne_zero).comp (Finsupp.single_left_injective one_ne_zero)
@[simp]
theorem X_inj [Nontrivial R] (m n : σ) : X m = (X n : MvPolynomial σ R) ↔ m = n :=
X_injective.eq_iff
theorem monomial_pow : monomial s a ^ e = monomial (e • s) (a ^ e) :=
AddMonoidAlgebra.single_pow e
@[simp]
theorem monomial_mul {s s' : σ →₀ ℕ} {a b : R} :
monomial s a * monomial s' b = monomial (s + s') (a * b) :=
AddMonoidAlgebra.single_mul_single
variable (σ R)
/-- `fun s ↦ monomial s 1` as a homomorphism. -/
def monomialOneHom : Multiplicative (σ →₀ ℕ) →* MvPolynomial σ R :=
AddMonoidAlgebra.of _ _
variable {σ R}
@[simp]
theorem monomialOneHom_apply : monomialOneHom R σ s = (monomial s 1 : MvPolynomial σ R) :=
rfl
theorem X_pow_eq_monomial : X n ^ e = monomial (Finsupp.single n e) (1 : R) := by
simp [X, monomial_pow]
theorem monomial_add_single : monomial (s + Finsupp.single n e) a = monomial s a * X n ^ e := by
rw [X_pow_eq_monomial, monomial_mul, mul_one]
theorem monomial_single_add : monomial (Finsupp.single n e + s) a = X n ^ e * monomial s a := by
rw [X_pow_eq_monomial, monomial_mul, one_mul]
theorem C_mul_X_pow_eq_monomial {s : σ} {a : R} {n : ℕ} :
C a * X s ^ n = monomial (Finsupp.single s n) a := by
rw [← zero_add (Finsupp.single s n), monomial_add_single, C_apply]
theorem C_mul_X_eq_monomial {s : σ} {a : R} : C a * X s = monomial (Finsupp.single s 1) a := by
rw [← C_mul_X_pow_eq_monomial, pow_one]
@[simp]
theorem monomial_zero {s : σ →₀ ℕ} : monomial s (0 : R) = 0 :=
Finsupp.single_zero _
@[simp]
theorem monomial_zero' : (monomial (0 : σ →₀ ℕ) : R → MvPolynomial σ R) = C :=
rfl
@[simp]
theorem monomial_eq_zero {s : σ →₀ ℕ} {b : R} : monomial s b = 0 ↔ b = 0 :=
Finsupp.single_eq_zero
@[simp]
theorem sum_monomial_eq {A : Type*} [AddCommMonoid A] {u : σ →₀ ℕ} {r : R} {b : (σ →₀ ℕ) → R → A}
(w : b u 0 = 0) : sum (monomial u r) b = b u r :=
Finsupp.sum_single_index w
@[simp]
theorem sum_C {A : Type*} [AddCommMonoid A] {b : (σ →₀ ℕ) → R → A} (w : b 0 0 = 0) :
sum (C a) b = b 0 a :=
sum_monomial_eq w
theorem monomial_sum_one {α : Type*} (s : Finset α) (f : α → σ →₀ ℕ) :
(monomial (∑ i ∈ s, f i) 1 : MvPolynomial σ R) = ∏ i ∈ s, monomial (f i) 1 :=
map_prod (monomialOneHom R σ) (fun i => Multiplicative.ofAdd (f i)) s
theorem monomial_sum_index {α : Type*} (s : Finset α) (f : α → σ →₀ ℕ) (a : R) :
monomial (∑ i ∈ s, f i) a = C a * ∏ i ∈ s, monomial (f i) 1 := by
rw [← monomial_sum_one, C_mul', ← (monomial _).map_smul, smul_eq_mul, mul_one]
theorem monomial_finsupp_sum_index {α β : Type*} [Zero β] (f : α →₀ β) (g : α → β → σ →₀ ℕ)
(a : R) : monomial (f.sum g) a = C a * f.prod fun a b => monomial (g a b) 1 :=
monomial_sum_index _ _ _
theorem monomial_eq_monomial_iff {α : Type*} (a₁ a₂ : α →₀ ℕ) (b₁ b₂ : R) :
monomial a₁ b₁ = monomial a₂ b₂ ↔ a₁ = a₂ ∧ b₁ = b₂ ∨ b₁ = 0 ∧ b₂ = 0 :=
Finsupp.single_eq_single_iff _ _ _ _
theorem monomial_eq : monomial s a = C a * (s.prod fun n e => X n ^ e : MvPolynomial σ R) := by
simp only [X_pow_eq_monomial, ← monomial_finsupp_sum_index, Finsupp.sum_single]
@[simp]
lemma prod_X_pow_eq_monomial : ∏ x ∈ s.support, X x ^ s x = monomial s (1 : R) := by
simp only [monomial_eq, map_one, one_mul, Finsupp.prod]
@[elab_as_elim]
theorem induction_on_monomial {motive : MvPolynomial σ R → Prop}
(C : ∀ a, motive (C a))
(mul_X : ∀ p n, motive p → motive (p * X n)) : ∀ s a, motive (monomial s a) := by
intro s a
apply @Finsupp.induction σ ℕ _ _ s
· show motive (monomial 0 a)
exact C a
· intro n e p _hpn _he ih
have : ∀ e : ℕ, motive (monomial p a * X n ^ e) := by
intro e
induction e with
| zero => simp [ih]
| succ e e_ih => simp [ih, pow_succ, (mul_assoc _ _ _).symm, mul_X, e_ih]
simp [add_comm, monomial_add_single, this]
/-- Analog of `Polynomial.induction_on'`.
To prove something about mv_polynomials,
it suffices to show the condition is closed under taking sums,
and it holds for monomials. -/
@[elab_as_elim]
theorem induction_on' {P : MvPolynomial σ R → Prop} (p : MvPolynomial σ R)
(monomial : ∀ (u : σ →₀ ℕ) (a : R), P (monomial u a))
(add : ∀ p q : MvPolynomial σ R, P p → P q → P (p + q)) : P p :=
Finsupp.induction p
(suffices P (MvPolynomial.monomial 0 0) by rwa [monomial_zero] at this
show P (MvPolynomial.monomial 0 0) from monomial 0 0)
fun _ _ _ _ha _hb hPf => add _ _ (monomial _ _) hPf
/--
Similar to `MvPolynomial.induction_on` but only a weak form of `h_add` is required.
In particular, this version only requires us to show
that `motive` is closed under addition of nontrivial monomials not present in the support.
-/
@[elab_as_elim]
theorem monomial_add_induction_on {motive : MvPolynomial σ R → Prop} (p : MvPolynomial σ R)
(C : ∀ a, motive (C a))
(monomial_add :
∀ (a : σ →₀ ℕ) (b : R) (f : MvPolynomial σ R),
a ∉ f.support → b ≠ 0 → motive f → motive ((monomial a b) + f)) :
motive p :=
Finsupp.induction p (C_0.rec <| C 0) monomial_add
@[deprecated (since := "2025-03-11")]
alias induction_on''' := monomial_add_induction_on
/--
Similar to `MvPolynomial.induction_on` but only a yet weaker form of `h_add` is required.
In particular, this version only requires us to show
that `motive` is closed under addition of monomials not present in the support
| for which `motive` is already known to hold.
-/
theorem induction_on'' {motive : MvPolynomial σ R → Prop} (p : MvPolynomial σ R)
| Mathlib/Algebra/MvPolynomial/Basic.lean | 398 | 400 |
/-
Copyright (c) 2021 Bolton Bailey. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Bolton Bailey
-/
import Mathlib.Algebra.Ring.Periodic
import Mathlib.Data.Nat.Count
/-!
# Periodic Functions on ℕ
This file identifies a few functions on `ℕ` which are periodic, and also proves a lemma about
periodic predicates which helps determine their cardinality when filtering intervals over them.
-/
assert_not_exists TwoSidedIdeal
namespace Nat
open Function
theorem periodic_gcd (a : ℕ) : Periodic (gcd a) a := by
simp only [forall_const, gcd_add_self_right, eq_self_iff_true, Periodic]
theorem periodic_coprime (a : ℕ) : Periodic (Coprime a) a := by
simp only [coprime_add_self_right, forall_const, eq_iff_iff, Periodic]
theorem periodic_mod (a : ℕ) : Periodic (fun n => n % a) a := by
| simp only [forall_const, eq_self_iff_true, add_mod_right, Periodic]
| Mathlib/Data/Nat/Periodic.lean | 29 | 30 |
/-
Copyright (c) 2022 Xavier Roblot. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Xavier Roblot
-/
import Mathlib.Algebra.Module.ZLattice.Basic
import Mathlib.Analysis.InnerProductSpace.ProdL2
import Mathlib.MeasureTheory.Measure.Haar.Unique
import Mathlib.NumberTheory.NumberField.FractionalIdeal
import Mathlib.NumberTheory.NumberField.Units.Basic
/-!
# Canonical embedding of a number field
The canonical embedding of a number field `K` of degree `n` is the ring homomorphism
`K →+* ℂ^n` that sends `x ∈ K` to `(φ_₁(x),...,φ_n(x))` where the `φ_i`'s are the complex
embeddings of `K`. Note that we do not choose an ordering of the embeddings, but instead map `K`
into the type `(K →+* ℂ) → ℂ` of `ℂ`-vectors indexed by the complex embeddings.
## Main definitions and results
* `NumberField.canonicalEmbedding`: the ring homomorphism `K →+* ((K →+* ℂ) → ℂ)` defined by
sending `x : K` to the vector `(φ x)` indexed by `φ : K →+* ℂ`.
* `NumberField.canonicalEmbedding.integerLattice.inter_ball_finite`: the intersection of the
image of the ring of integers by the canonical embedding and any ball centered at `0` of finite
radius is finite.
* `NumberField.mixedEmbedding`: the ring homomorphism from `K` to the mixed space
`K →+* ({ w // IsReal w } → ℝ) × ({ w // IsComplex w } → ℂ)` that sends `x ∈ K` to `(φ_w x)_w`
where `φ_w` is the embedding associated to the infinite place `w`. In particular, if `w` is real
then `φ_w : K →+* ℝ` and, if `w` is complex, `φ_w` is an arbitrary choice between the two complex
embeddings defining the place `w`.
## Tags
number field, infinite places
-/
variable (K : Type*) [Field K]
namespace NumberField.canonicalEmbedding
/-- The canonical embedding of a number field `K` of degree `n` into `ℂ^n`. -/
def _root_.NumberField.canonicalEmbedding : K →+* ((K →+* ℂ) → ℂ) := Pi.ringHom fun φ => φ
theorem _root_.NumberField.canonicalEmbedding_injective [NumberField K] :
Function.Injective (NumberField.canonicalEmbedding K) := RingHom.injective _
variable {K}
@[simp]
theorem apply_at (φ : K →+* ℂ) (x : K) : (NumberField.canonicalEmbedding K x) φ = φ x := rfl
open scoped ComplexConjugate
/-- The image of `canonicalEmbedding` lives in the `ℝ`-submodule of the `x ∈ ((K →+* ℂ) → ℂ)` such
that `conj x_φ = x_(conj φ)` for all `∀ φ : K →+* ℂ`. -/
theorem conj_apply {x : ((K →+* ℂ) → ℂ)} (φ : K →+* ℂ)
(hx : x ∈ Submodule.span ℝ (Set.range (canonicalEmbedding K))) :
conj (x φ) = x (ComplexEmbedding.conjugate φ) := by
refine Submodule.span_induction ?_ ?_ (fun _ _ _ _ hx hy => ?_) (fun a _ _ hx => ?_) hx
· rintro _ ⟨x, rfl⟩
rw [apply_at, apply_at, ComplexEmbedding.conjugate_coe_eq]
· rw [Pi.zero_apply, Pi.zero_apply, map_zero]
· rw [Pi.add_apply, Pi.add_apply, map_add, hx, hy]
· rw [Pi.smul_apply, Complex.real_smul, map_mul, Complex.conj_ofReal]
exact congrArg ((a : ℂ) * ·) hx
theorem nnnorm_eq [NumberField K] (x : K) :
‖canonicalEmbedding K x‖₊ = Finset.univ.sup (fun φ : K →+* ℂ => ‖φ x‖₊) := by
simp_rw [Pi.nnnorm_def, apply_at]
theorem norm_le_iff [NumberField K] (x : K) (r : ℝ) :
‖canonicalEmbedding K x‖ ≤ r ↔ ∀ φ : K →+* ℂ, ‖φ x‖ ≤ r := by
obtain hr | hr := lt_or_le r 0
· obtain ⟨φ⟩ := (inferInstance : Nonempty (K →+* ℂ))
refine iff_of_false ?_ ?_
· exact (hr.trans_le (norm_nonneg _)).not_le
· exact fun h => hr.not_le (le_trans (norm_nonneg _) (h φ))
· lift r to NNReal using hr
simp_rw [← coe_nnnorm, nnnorm_eq, NNReal.coe_le_coe, Finset.sup_le_iff, Finset.mem_univ,
forall_true_left]
variable (K)
/-- The image of `𝓞 K` as a subring of `ℂ^n`. -/
def integerLattice : Subring ((K →+* ℂ) → ℂ) :=
(RingHom.range (algebraMap (𝓞 K) K)).map (canonicalEmbedding K)
theorem integerLattice.inter_ball_finite [NumberField K] (r : ℝ) :
((integerLattice K : Set ((K →+* ℂ) → ℂ)) ∩ Metric.closedBall 0 r).Finite := by
obtain hr | _ := lt_or_le r 0
· simp [Metric.closedBall_eq_empty.2 hr]
· have heq : ∀ x, canonicalEmbedding K x ∈ Metric.closedBall 0 r ↔
∀ φ : K →+* ℂ, ‖φ x‖ ≤ r := by
intro x; rw [← norm_le_iff, mem_closedBall_zero_iff]
convert (Embeddings.finite_of_norm_le K ℂ r).image (canonicalEmbedding K)
ext; constructor
· rintro ⟨⟨_, ⟨x, rfl⟩, rfl⟩, hx⟩
exact ⟨x, ⟨SetLike.coe_mem x, fun φ => (heq _).mp hx φ⟩, rfl⟩
· rintro ⟨x, ⟨hx1, hx2⟩, rfl⟩
exact ⟨⟨x, ⟨⟨x, hx1⟩, rfl⟩, rfl⟩, (heq x).mpr hx2⟩
open Module Fintype Module
/-- A `ℂ`-basis of `ℂ^n` that is also a `ℤ`-basis of the `integerLattice`. -/
noncomputable def latticeBasis [NumberField K] :
Basis (Free.ChooseBasisIndex ℤ (𝓞 K)) ℂ ((K →+* ℂ) → ℂ) := by
classical
-- Let `B` be the canonical basis of `(K →+* ℂ) → ℂ`. We prove that the determinant of
-- the image by `canonicalEmbedding` of the integral basis of `K` is nonzero. This
-- will imply the result.
let B := Pi.basisFun ℂ (K →+* ℂ)
let e : (K →+* ℂ) ≃ Free.ChooseBasisIndex ℤ (𝓞 K) :=
equivOfCardEq ((Embeddings.card K ℂ).trans (finrank_eq_card_basis (integralBasis K)))
let M := B.toMatrix (fun i => canonicalEmbedding K (integralBasis K (e i)))
suffices M.det ≠ 0 by
rw [← isUnit_iff_ne_zero, ← Basis.det_apply, ← is_basis_iff_det] at this
exact (basisOfPiSpaceOfLinearIndependent this.1).reindex e
-- In order to prove that the determinant is nonzero, we show that it is equal to the
-- square of the discriminant of the integral basis and thus it is not zero
let N := Algebra.embeddingsMatrixReindex ℚ ℂ (fun i => integralBasis K (e i))
RingHom.equivRatAlgHom
rw [show M = N.transpose by { ext : 2; rfl }]
rw [Matrix.det_transpose, ← pow_ne_zero_iff two_ne_zero]
convert (map_ne_zero_iff _ (algebraMap ℚ ℂ).injective).mpr
(Algebra.discr_not_zero_of_basis ℚ (integralBasis K))
rw [← Algebra.discr_reindex ℚ (integralBasis K) e.symm]
exact (Algebra.discr_eq_det_embeddingsMatrixReindex_pow_two ℚ ℂ
(fun i => integralBasis K (e i)) RingHom.equivRatAlgHom).symm
@[simp]
theorem latticeBasis_apply [NumberField K] (i : Free.ChooseBasisIndex ℤ (𝓞 K)) :
latticeBasis K i = (canonicalEmbedding K) (integralBasis K i) := by
simp [latticeBasis, integralBasis_apply, coe_basisOfPiSpaceOfLinearIndependent,
Function.comp_apply, Equiv.apply_symm_apply]
| theorem mem_span_latticeBasis [NumberField K] {x : (K →+* ℂ) → ℂ} :
x ∈ Submodule.span ℤ (Set.range (latticeBasis K)) ↔
x ∈ ((canonicalEmbedding K).comp (algebraMap (𝓞 K) K)).range := by
rw [show Set.range (latticeBasis K) =
| Mathlib/NumberTheory/NumberField/CanonicalEmbedding/Basic.lean | 139 | 142 |
/-
Copyright (c) 2020 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kim Morrison, Bhavik Mehta, Daniel Carranza, Joël Riou
-/
import Mathlib.CategoryTheory.Monoidal.Functor
import Mathlib.CategoryTheory.Monoidal.CoherenceLemmas
import Mathlib.CategoryTheory.Adjunction.Limits
import Mathlib.CategoryTheory.Adjunction.Mates
/-!
# Closed monoidal categories
Define (right) closed objects and (right) closed monoidal categories.
## TODO
Some of the theorems proved about cartesian closed categories
should be generalised and moved to this file.
-/
universe v u u₂ v₂
namespace CategoryTheory
open Category MonoidalCategory
-- Note that this class carries a particular choice of right adjoint,
-- (which is only unique up to isomorphism),
-- not merely the existence of such, and
-- so definitional properties of instances may be important.
/-- An object `X` is (right) closed if `(X ⊗ -)` is a left adjoint. -/
class Closed {C : Type u} [Category.{v} C] [MonoidalCategory.{v} C] (X : C) where
/-- a choice of a right adjoint for `tensorLeft X` -/
rightAdj : C ⥤ C
/-- `tensorLeft X` is a left adjoint -/
adj : tensorLeft X ⊣ rightAdj
/-- A monoidal category `C` is (right) monoidal closed if every object is (right) closed. -/
class MonoidalClosed (C : Type u) [Category.{v} C] [MonoidalCategory.{v} C] where
closed (X : C) : Closed X := by infer_instance
attribute [instance 100] MonoidalClosed.closed
variable {C : Type u} [Category.{v} C] [MonoidalCategory.{v} C]
/-- If `X` and `Y` are closed then `X ⊗ Y` is.
This isn't an instance because it's not usually how we want to construct internal homs,
we'll usually prove all objects are closed uniformly.
-/
def tensorClosed {X Y : C} (hX : Closed X) (hY : Closed Y) : Closed (X ⊗ Y) where
rightAdj := Closed.rightAdj X ⋙ Closed.rightAdj Y
adj := (hY.adj.comp hX.adj).ofNatIsoLeft (MonoidalCategory.tensorLeftTensor X Y).symm
/-- The unit object is always closed.
This isn't an instance because most of the time we'll prove closedness for all objects at once,
rather than just for this one.
-/
def unitClosed : Closed (𝟙_ C) where
rightAdj := 𝟭 C
adj := Adjunction.id.ofNatIsoLeft (MonoidalCategory.leftUnitorNatIso C).symm
variable (A B : C) {X X' Y Y' Z : C}
variable [Closed A]
/-- This is the internal hom `A ⟶[C] -`.
-/
def ihom : C ⥤ C :=
Closed.rightAdj (X := A)
namespace ihom
/-- The adjunction between `A ⊗ -` and `A ⟹ -`. -/
def adjunction : tensorLeft A ⊣ ihom A :=
Closed.adj
instance : (tensorLeft A).IsLeftAdjoint :=
(ihom.adjunction A).isLeftAdjoint
/-- The evaluation natural transformation. -/
def ev : ihom A ⋙ tensorLeft A ⟶ 𝟭 C :=
(ihom.adjunction A).counit
/-- The coevaluation natural transformation. -/
def coev : 𝟭 C ⟶ tensorLeft A ⋙ ihom A :=
(ihom.adjunction A).unit
@[simp]
theorem ihom_adjunction_counit : (ihom.adjunction A).counit = ev A :=
rfl
@[simp]
theorem ihom_adjunction_unit : (ihom.adjunction A).unit = coev A :=
rfl
@[reassoc (attr := simp)]
theorem ev_naturality {X Y : C} (f : X ⟶ Y) :
A ◁ (ihom A).map f ≫ (ev A).app Y = (ev A).app X ≫ f :=
(ev A).naturality f
@[reassoc (attr := simp)]
theorem coev_naturality {X Y : C} (f : X ⟶ Y) :
f ≫ (coev A).app Y = (coev A).app X ≫ (ihom A).map (A ◁ f) :=
(coev A).naturality f
set_option quotPrecheck false in
/-- `A ⟶[C] B` denotes the internal hom from `A` to `B` -/
notation A " ⟶[" C "] " B:10 => (@ihom C _ _ A _).obj B
@[reassoc (attr := simp)]
theorem ev_coev : (A ◁ (coev A).app B) ≫ (ev A).app (A ⊗ B) = 𝟙 (A ⊗ B) :=
(ihom.adjunction A).left_triangle_components _
@[reassoc (attr := simp)]
theorem coev_ev : (coev A).app (A ⟶[C] B) ≫ (ihom A).map ((ev A).app B) = 𝟙 (A ⟶[C] B) :=
Adjunction.right_triangle_components (ihom.adjunction A) _
end ihom
open CategoryTheory.Limits
instance : PreservesColimits (tensorLeft A) :=
(ihom.adjunction A).leftAdjoint_preservesColimits
variable {A}
-- Wrap these in a namespace so we don't clash with the core versions.
namespace MonoidalClosed
/-- Currying in a monoidal closed category. -/
def curry : (A ⊗ Y ⟶ X) → (Y ⟶ A ⟶[C] X) :=
(ihom.adjunction A).homEquiv _ _
/-- Uncurrying in a monoidal closed category. -/
def uncurry : (Y ⟶ A ⟶[C] X) → (A ⊗ Y ⟶ X) :=
((ihom.adjunction A).homEquiv _ _).symm
theorem homEquiv_apply_eq (f : A ⊗ Y ⟶ X) : (ihom.adjunction A).homEquiv _ _ f = curry f :=
rfl
theorem homEquiv_symm_apply_eq (f : Y ⟶ A ⟶[C] X) :
((ihom.adjunction A).homEquiv _ _).symm f = uncurry f :=
rfl
@[reassoc]
theorem curry_natural_left (f : X ⟶ X') (g : A ⊗ X' ⟶ Y) : curry (_ ◁ f ≫ g) = f ≫ curry g :=
Adjunction.homEquiv_naturality_left _ _ _
@[reassoc]
theorem curry_natural_right (f : A ⊗ X ⟶ Y) (g : Y ⟶ Y') :
curry (f ≫ g) = curry f ≫ (ihom _).map g :=
Adjunction.homEquiv_naturality_right _ _ _
@[reassoc]
theorem uncurry_natural_right (f : X ⟶ A ⟶[C] Y) (g : Y ⟶ Y') :
uncurry (f ≫ (ihom _).map g) = uncurry f ≫ g :=
Adjunction.homEquiv_naturality_right_symm _ _ _
@[reassoc]
theorem uncurry_natural_left (f : X ⟶ X') (g : X' ⟶ A ⟶[C] Y) :
uncurry (f ≫ g) = _ ◁ f ≫ uncurry g :=
Adjunction.homEquiv_naturality_left_symm _ _ _
@[simp]
theorem uncurry_curry (f : A ⊗ X ⟶ Y) : uncurry (curry f) = f :=
(Closed.adj.homEquiv _ _).left_inv f
@[simp]
theorem curry_uncurry (f : X ⟶ A ⟶[C] Y) : curry (uncurry f) = f :=
(Closed.adj.homEquiv _ _).right_inv f
theorem curry_eq_iff (f : A ⊗ Y ⟶ X) (g : Y ⟶ A ⟶[C] X) : curry f = g ↔ f = uncurry g :=
Adjunction.homEquiv_apply_eq (ihom.adjunction A) f g
theorem eq_curry_iff (f : A ⊗ Y ⟶ X) (g : Y ⟶ A ⟶[C] X) : g = curry f ↔ uncurry g = f :=
Adjunction.eq_homEquiv_apply (ihom.adjunction A) f g
-- I don't think these two should be simp.
theorem uncurry_eq (g : Y ⟶ A ⟶[C] X) : uncurry g = (A ◁ g) ≫ (ihom.ev A).app X := by
rfl
theorem curry_eq (g : A ⊗ Y ⟶ X) : curry g = (ihom.coev A).app Y ≫ (ihom A).map g :=
rfl
theorem curry_injective : Function.Injective (curry : (A ⊗ Y ⟶ X) → (Y ⟶ A ⟶[C] X)) :=
(Closed.adj.homEquiv _ _).injective
theorem uncurry_injective : Function.Injective (uncurry : (Y ⟶ A ⟶[C] X) → (A ⊗ Y ⟶ X)) :=
(Closed.adj.homEquiv _ _).symm.injective
variable (A X)
theorem uncurry_id_eq_ev : uncurry (𝟙 (A ⟶[C] X)) = (ihom.ev A).app X := by
simp [uncurry_eq]
theorem curry_id_eq_coev : curry (𝟙 _) = (ihom.coev A).app X := by
rw [curry_eq, (ihom A).map_id (A ⊗ _)]
apply comp_id
@[reassoc (attr := simp)]
lemma whiskerLeft_curry_ihom_ev_app (g : A ⊗ Y ⟶ X) :
A ◁ curry g ≫ (ihom.ev A).app X = g := by
simp [curry_eq]
theorem uncurry_ihom_map (g : Y ⟶ Y') :
uncurry ((ihom A).map g) = (ihom.ev A).app Y ≫ g := by
apply curry_injective
rw [curry_uncurry, curry_natural_right, ← uncurry_id_eq_ev, curry_uncurry, id_comp]
/-- The internal hom out of the unit is naturally isomorphic to the identity functor. -/
def unitNatIso [Closed (𝟙_ C)] : 𝟭 C ≅ ihom (𝟙_ C) :=
conjugateIsoEquiv (Adjunction.id (C := C)) (ihom.adjunction (𝟙_ C))
(leftUnitorNatIso C)
section Pre
variable {A B}
variable [Closed B]
/-- Pre-compose an internal hom with an external hom. -/
def pre (f : B ⟶ A) : ihom A ⟶ ihom B :=
conjugateEquiv (ihom.adjunction _) (ihom.adjunction _) ((tensoringLeft C).map f)
@[reassoc (attr := simp)]
theorem id_tensor_pre_app_comp_ev (f : B ⟶ A) (X : C) :
B ◁ (pre f).app X ≫ (ihom.ev B).app X = f ▷ (A ⟶[C] X) ≫ (ihom.ev A).app X :=
conjugateEquiv_counit _ _ ((tensoringLeft C).map f) X
@[simp]
theorem uncurry_pre (f : B ⟶ A) (X : C) :
MonoidalClosed.uncurry ((pre f).app X) = f ▷ _ ≫ (ihom.ev A).app X := by
simp [uncurry_eq]
@[reassoc]
lemma curry_pre_app (f : B ⟶ A) {X Y : C} (g : A ⊗ Y ⟶ X) :
curry g ≫ (pre f).app X = curry (f ▷ _ ≫ g) := uncurry_injective (by
rw [uncurry_curry, uncurry_eq, MonoidalCategory.whiskerLeft_comp, assoc,
id_tensor_pre_app_comp_ev, whisker_exchange_assoc, whiskerLeft_curry_ihom_ev_app])
@[reassoc (attr := simp)]
theorem coev_app_comp_pre_app (f : B ⟶ A) :
(ihom.coev A).app X ≫ (pre f).app (A ⊗ X) = (ihom.coev B).app X ≫ (ihom B).map (f ▷ _) :=
unit_conjugateEquiv _ _ ((tensoringLeft C).map f) X
@[reassoc]
lemma uncurry_pre_app (f : Y ⟶ A ⟶[C] X) (g : B ⟶ A) :
uncurry (f ≫ (pre g).app X) = g ▷ _ ≫ uncurry f :=
curry_injective (by
rw [curry_uncurry, ← curry_pre_app, curry_uncurry])
@[simp]
theorem pre_id (A : C) [Closed A] : pre (𝟙 A) = 𝟙 _ := by
rw [pre, Functor.map_id]
apply conjugateEquiv_id
@[simp]
theorem pre_map {A₁ A₂ A₃ : C} [Closed A₁] [Closed A₂] [Closed A₃] (f : A₁ ⟶ A₂) (g : A₂ ⟶ A₃) :
pre (f ≫ g) = pre g ≫ pre f := by
rw [pre, pre, pre, conjugateEquiv_comp, (tensoringLeft C).map_comp]
theorem pre_comm_ihom_map {W X Y Z : C} [Closed W] [Closed X] (f : W ⟶ X) (g : Y ⟶ Z) :
(pre f).app Y ≫ (ihom W).map g = (ihom X).map g ≫ (pre f).app Z := by simp
|
end Pre
| Mathlib/CategoryTheory/Closed/Monoidal.lean | 262 | 264 |
/-
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.Abelian
import Mathlib.Algebra.Category.ModuleCat.Presheaf.Sheafify
import Mathlib.Algebra.Category.ModuleCat.Presheaf.Limits
import Mathlib.Algebra.Category.ModuleCat.Sheaf.Limits
import Mathlib.CategoryTheory.Sites.LocallyBijective
import Mathlib.CategoryTheory.Sites.Sheafification
import Mathlib.CategoryTheory.Functor.ReflectsIso.Balanced
/-!
# The sheafification functor for presheaves of modules
In this file, we construct a functor
`PresheafOfModules.sheafification α : PresheafOfModules R₀ ⥤ SheafOfModules R`
for a locally bijective morphism `α : R₀ ⟶ R.val` where `R₀` is a presheaf of rings
and `R` a sheaf of rings.
In particular, if `α` is the identity of `R.val`, we obtain the
sheafification functor `PresheafOfModules R.val ⥤ SheafOfModules R`.
-/
universe v v' u u'
open CategoryTheory Category Limits
variable {C : Type u'} [Category.{v'} C] {J : GrothendieckTopology C}
{R₀ : Cᵒᵖ ⥤ RingCat.{u}} {R : Sheaf J RingCat.{u}} (α : R₀ ⟶ R.val)
[Presheaf.IsLocallyInjective J α] [Presheaf.IsLocallySurjective J α]
[J.WEqualsLocallyBijective AddCommGrp.{v}]
namespace PresheafOfModules
section
variable [HasWeakSheafify J AddCommGrp.{v}]
/-- Given a locally bijective morphism `α : R₀ ⟶ R.val` where `R₀` is a presheaf of rings
and `R` a sheaf of rings (i.e. `R` identifies to the sheafification of `R₀`), this is
the associated sheaf of modules functor `PresheafOfModules.{v} R₀ ⥤ SheafOfModules.{v} R`. -/
@[simps! -isSimp map]
noncomputable def sheafification : PresheafOfModules.{v} R₀ ⥤ SheafOfModules.{v} R where
obj M₀ := sheafify α (CategoryTheory.toSheafify J M₀.presheaf)
map f := sheafifyMap _ _ _ f
((toPresheaf R₀ ⋙ presheafToSheaf J AddCommGrp).map f)
(by apply toSheafify_naturality)
map_id M₀ := by
ext1
apply (toPresheaf _).map_injective
simp
rfl
map_comp _ _ := by
ext1
apply (toPresheaf _).map_injective
simp
rfl
/-- The sheafification of presheaves of modules commutes with the functor which
forgets the module structures. -/
noncomputable def sheafificationCompToSheaf :
sheafification.{v} α ⋙ SheafOfModules.toSheaf _ ≅
toPresheaf _ ⋙ presheafToSheaf J AddCommGrp :=
Iso.refl _
/-- The sheafification of presheaves of modules commutes with the functor which
forgets the module structures. -/
noncomputable def sheafificationCompForgetCompToPresheaf :
sheafification.{v} α ⋙ SheafOfModules.forget _ ⋙ toPresheaf _ ≅
toPresheaf _ ⋙ presheafToSheaf J AddCommGrp ⋙ sheafToPresheaf J AddCommGrp :=
Iso.refl _
/-- The bijection between types of morphisms which is part of the adjunction
`sheafificationAdjunction`. -/
noncomputable def sheafificationHomEquiv
{P : PresheafOfModules.{v} R₀} {F : SheafOfModules.{v} R} :
((sheafification α).obj P ⟶ F) ≃
(P ⟶ (restrictScalars α).obj ((SheafOfModules.forget _).obj F)) := by
apply sheafifyHomEquiv
lemma toPresheaf_map_sheafificationHomEquiv_def
| {P : PresheafOfModules.{v} R₀} {F : SheafOfModules.{v} R}
(f : (sheafification α).obj P ⟶ F) :
(toPresheaf R₀).map (sheafificationHomEquiv α f) =
CategoryTheory.toSheafify J P.presheaf ≫ (toPresheaf R.val).map f.val := rfl
lemma toPresheaf_map_sheafificationHomEquiv
{P : PresheafOfModules.{v} R₀} {F : SheafOfModules.{v} R}
(f : (sheafification α).obj P ⟶ F) :
| Mathlib/Algebra/Category/ModuleCat/Presheaf/Sheafification.lean | 84 | 91 |
/-
Copyright (c) 2021 Oliver Nash. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Oliver Nash
-/
import Mathlib.Algebra.Lie.Ideal
/-!
# Ideal operations for Lie algebras
Given a Lie module `M` over a Lie algebra `L`, there is a natural action of the Lie ideals of `L`
on the Lie submodules of `M`. In the special case that `M = L` with the adjoint action, this
provides a pairing of Lie ideals which is especially important. For example, it can be used to
define solvability / nilpotency of a Lie algebra via the derived / lower-central series.
## Main definitions
* `LieSubmodule.hasBracket`
* `LieSubmodule.lieIdeal_oper_eq_linear_span`
* `LieIdeal.map_bracket_le`
* `LieIdeal.comap_bracket_le`
## Notation
Given a Lie module `M` over a Lie algebra `L`, together with a Lie submodule `N ⊆ M` and a Lie
ideal `I ⊆ L`, we introduce the notation `⁅I, N⁆` for the Lie submodule of `M` corresponding to
the action defined in this file.
## Tags
lie algebra, ideal operation
-/
universe u v w w₁ w₂
namespace LieSubmodule
variable {R : Type u} {L : Type v} {M : Type w} {M₂ : Type w₁}
variable [CommRing R] [LieRing L]
variable [AddCommGroup M] [Module R M] [LieRingModule L M]
variable [AddCommGroup M₂] [Module R M₂] [LieRingModule L M₂]
variable (N N' : LieSubmodule R L M) (N₂ : LieSubmodule R L M₂)
variable (f : M →ₗ⁅R,L⁆ M₂)
section LieIdealOperations
theorem map_comap_le : map f (comap f N₂) ≤ N₂ :=
(N₂ : Set M₂).image_preimage_subset f
theorem map_comap_eq (hf : N₂ ≤ f.range) : map f (comap f N₂) = N₂ := by
rw [SetLike.ext'_iff]
exact Set.image_preimage_eq_of_subset hf
theorem le_comap_map : N ≤ comap f (map f N) :=
(N : Set M).subset_preimage_image f
theorem comap_map_eq (hf : f.ker = ⊥) : comap f (map f N) = N := by
rw [SetLike.ext'_iff]
exact (N : Set M).preimage_image_eq (f.ker_eq_bot.mp hf)
@[simp]
theorem map_comap_incl : map N.incl (comap N.incl N') = N ⊓ N' := by
rw [← toSubmodule_inj]
exact (N : Submodule R M).map_comap_subtype N'
variable [LieAlgebra R L] [LieModule R L M₂] (I J : LieIdeal R L)
/-- Given a Lie module `M` over a Lie algebra `L`, the set of Lie ideals of `L` acts on the set
of submodules of `M`. -/
instance hasBracket : Bracket (LieIdeal R L) (LieSubmodule R L M) :=
⟨fun I N => lieSpan R L { ⁅(x : L), (n : M)⁆ | (x : I) (n : N) }⟩
theorem lieIdeal_oper_eq_span :
⁅I, N⁆ = lieSpan R L { ⁅(x : L), (n : M)⁆ | (x : I) (n : N) } :=
rfl
/-- See also `LieSubmodule.lieIdeal_oper_eq_linear_span'` and
`LieSubmodule.lieIdeal_oper_eq_tensor_map_range`. -/
theorem lieIdeal_oper_eq_linear_span [LieModule R L M] :
(↑⁅I, N⁆ : Submodule R M) = Submodule.span R { ⁅(x : L), (n : M)⁆ | (x : I) (n : N) } := by
apply le_antisymm
· let s := { ⁅(x : L), (n : M)⁆ | (x : I) (n : N) }
have aux : ∀ (y : L), ∀ m' ∈ Submodule.span R s, ⁅y, m'⁆ ∈ Submodule.span R s := by
intro y m' hm'
refine Submodule.span_induction (R := R) (M := M) (s := s)
(p := fun m' _ ↦ ⁅y, m'⁆ ∈ Submodule.span R s) ?_ ?_ ?_ ?_ hm'
· rintro m'' ⟨x, n, hm''⟩; rw [← hm'', leibniz_lie]
refine Submodule.add_mem _ ?_ ?_ <;> apply Submodule.subset_span
· use ⟨⁅y, ↑x⁆, I.lie_mem x.property⟩, n
· use x, ⟨⁅y, ↑n⁆, N.lie_mem n.property⟩
· simp only [lie_zero, Submodule.zero_mem]
· intro m₁ m₂ _ _ hm₁ hm₂; rw [lie_add]; exact Submodule.add_mem _ hm₁ hm₂
· intro t m'' _ hm''; rw [lie_smul]; exact Submodule.smul_mem _ t hm''
change _ ≤ ({ Submodule.span R s with lie_mem := fun hm' => aux _ _ hm' } : LieSubmodule R L M)
rw [lieIdeal_oper_eq_span, lieSpan_le]
exact Submodule.subset_span
· rw [lieIdeal_oper_eq_span]; apply submodule_span_le_lieSpan
theorem lieIdeal_oper_eq_linear_span' [LieModule R L M] :
(↑⁅I, N⁆ : Submodule R M) = Submodule.span R { ⁅x, n⁆ | (x ∈ I) (n ∈ N) } := by
rw [lieIdeal_oper_eq_linear_span]
congr
ext m
constructor
· rintro ⟨⟨x, hx⟩, ⟨n, hn⟩, rfl⟩
exact ⟨x, hx, n, hn, rfl⟩
· rintro ⟨x, hx, n, hn, rfl⟩
exact ⟨⟨x, hx⟩, ⟨n, hn⟩, rfl⟩
| theorem lie_le_iff : ⁅I, N⁆ ≤ N' ↔ ∀ x ∈ I, ∀ m ∈ N, ⁅x, m⁆ ∈ N' := by
rw [lieIdeal_oper_eq_span, LieSubmodule.lieSpan_le]
refine ⟨fun h x hx m hm => h ⟨⟨x, hx⟩, ⟨m, hm⟩, rfl⟩, ?_⟩
rintro h _ ⟨⟨x, hx⟩, ⟨m, hm⟩, rfl⟩
exact h x hx m hm
| Mathlib/Algebra/Lie/IdealOperations.lean | 111 | 116 |
/-
Copyright (c) 2022 Joseph Myers. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joseph Myers
-/
import Mathlib.Analysis.Convex.Between
import Mathlib.Analysis.Normed.Group.AddTorsor
import Mathlib.Analysis.Normed.Module.Convex
/-!
# Sides of affine subspaces
This file defines notions of two points being on the same or opposite sides of an affine subspace.
## Main definitions
* `s.WSameSide x y`: The points `x` and `y` are weakly on the same side of the affine
subspace `s`.
* `s.SSameSide x y`: The points `x` and `y` are strictly on the same side of the affine
subspace `s`.
* `s.WOppSide x y`: The points `x` and `y` are weakly on opposite sides of the affine
subspace `s`.
* `s.SOppSide x y`: The points `x` and `y` are strictly on opposite sides of the affine
subspace `s`.
-/
variable {R V V' P P' : Type*}
open AffineEquiv AffineMap
namespace AffineSubspace
section StrictOrderedCommRing
variable [CommRing R] [PartialOrder R] [IsStrictOrderedRing R]
[AddCommGroup V] [Module R V] [AddTorsor V P]
variable [AddCommGroup V'] [Module R V'] [AddTorsor V' P']
/-- The points `x` and `y` are weakly on the same side of `s`. -/
def WSameSide (s : AffineSubspace R P) (x y : P) : Prop :=
∃ᵉ (p₁ ∈ s) (p₂ ∈ s), SameRay R (x -ᵥ p₁) (y -ᵥ p₂)
/-- The points `x` and `y` are strictly on the same side of `s`. -/
def SSameSide (s : AffineSubspace R P) (x y : P) : Prop :=
s.WSameSide x y ∧ x ∉ s ∧ y ∉ s
/-- The points `x` and `y` are weakly on opposite sides of `s`. -/
def WOppSide (s : AffineSubspace R P) (x y : P) : Prop :=
∃ᵉ (p₁ ∈ s) (p₂ ∈ s), SameRay R (x -ᵥ p₁) (p₂ -ᵥ y)
/-- The points `x` and `y` are strictly on opposite sides of `s`. -/
def SOppSide (s : AffineSubspace R P) (x y : P) : Prop :=
s.WOppSide x y ∧ x ∉ s ∧ y ∉ s
theorem WSameSide.map {s : AffineSubspace R P} {x y : P} (h : s.WSameSide x y) (f : P →ᵃ[R] P') :
(s.map f).WSameSide (f x) (f y) := by
rcases h with ⟨p₁, hp₁, p₂, hp₂, h⟩
refine ⟨f p₁, mem_map_of_mem f hp₁, f p₂, mem_map_of_mem f hp₂, ?_⟩
simp_rw [← linearMap_vsub]
exact h.map f.linear
theorem _root_.Function.Injective.wSameSide_map_iff {s : AffineSubspace R P} {x y : P}
{f : P →ᵃ[R] P'} (hf : Function.Injective f) :
(s.map f).WSameSide (f x) (f y) ↔ s.WSameSide x y := by
refine ⟨fun h => ?_, fun h => h.map _⟩
rcases h with ⟨fp₁, hfp₁, fp₂, hfp₂, h⟩
rw [mem_map] at hfp₁ hfp₂
rcases hfp₁ with ⟨p₁, hp₁, rfl⟩
rcases hfp₂ with ⟨p₂, hp₂, rfl⟩
refine ⟨p₁, hp₁, p₂, hp₂, ?_⟩
simp_rw [← linearMap_vsub, (f.linear_injective_iff.2 hf).sameRay_map_iff] at h
exact h
theorem _root_.Function.Injective.sSameSide_map_iff {s : AffineSubspace R P} {x y : P}
{f : P →ᵃ[R] P'} (hf : Function.Injective f) :
(s.map f).SSameSide (f x) (f y) ↔ s.SSameSide x y := by
simp_rw [SSameSide, hf.wSameSide_map_iff, mem_map_iff_mem_of_injective hf]
@[simp]
theorem _root_.AffineEquiv.wSameSide_map_iff {s : AffineSubspace R P} {x y : P} (f : P ≃ᵃ[R] P') :
(s.map ↑f).WSameSide (f x) (f y) ↔ s.WSameSide x y :=
(show Function.Injective f.toAffineMap from f.injective).wSameSide_map_iff
@[simp]
theorem _root_.AffineEquiv.sSameSide_map_iff {s : AffineSubspace R P} {x y : P} (f : P ≃ᵃ[R] P') :
(s.map ↑f).SSameSide (f x) (f y) ↔ s.SSameSide x y :=
(show Function.Injective f.toAffineMap from f.injective).sSameSide_map_iff
theorem WOppSide.map {s : AffineSubspace R P} {x y : P} (h : s.WOppSide x y) (f : P →ᵃ[R] P') :
(s.map f).WOppSide (f x) (f y) := by
rcases h with ⟨p₁, hp₁, p₂, hp₂, h⟩
refine ⟨f p₁, mem_map_of_mem f hp₁, f p₂, mem_map_of_mem f hp₂, ?_⟩
simp_rw [← linearMap_vsub]
exact h.map f.linear
theorem _root_.Function.Injective.wOppSide_map_iff {s : AffineSubspace R P} {x y : P}
{f : P →ᵃ[R] P'} (hf : Function.Injective f) :
(s.map f).WOppSide (f x) (f y) ↔ s.WOppSide x y := by
refine ⟨fun h => ?_, fun h => h.map _⟩
rcases h with ⟨fp₁, hfp₁, fp₂, hfp₂, h⟩
rw [mem_map] at hfp₁ hfp₂
rcases hfp₁ with ⟨p₁, hp₁, rfl⟩
rcases hfp₂ with ⟨p₂, hp₂, rfl⟩
refine ⟨p₁, hp₁, p₂, hp₂, ?_⟩
simp_rw [← linearMap_vsub, (f.linear_injective_iff.2 hf).sameRay_map_iff] at h
exact h
theorem _root_.Function.Injective.sOppSide_map_iff {s : AffineSubspace R P} {x y : P}
{f : P →ᵃ[R] P'} (hf : Function.Injective f) :
(s.map f).SOppSide (f x) (f y) ↔ s.SOppSide x y := by
simp_rw [SOppSide, hf.wOppSide_map_iff, mem_map_iff_mem_of_injective hf]
@[simp]
theorem _root_.AffineEquiv.wOppSide_map_iff {s : AffineSubspace R P} {x y : P} (f : P ≃ᵃ[R] P') :
(s.map ↑f).WOppSide (f x) (f y) ↔ s.WOppSide x y :=
(show Function.Injective f.toAffineMap from f.injective).wOppSide_map_iff
@[simp]
theorem _root_.AffineEquiv.sOppSide_map_iff {s : AffineSubspace R P} {x y : P} (f : P ≃ᵃ[R] P') :
(s.map ↑f).SOppSide (f x) (f y) ↔ s.SOppSide x y :=
(show Function.Injective f.toAffineMap from f.injective).sOppSide_map_iff
theorem WSameSide.nonempty {s : AffineSubspace R P} {x y : P} (h : s.WSameSide x y) :
(s : Set P).Nonempty :=
⟨h.choose, h.choose_spec.left⟩
theorem SSameSide.nonempty {s : AffineSubspace R P} {x y : P} (h : s.SSameSide x y) :
(s : Set P).Nonempty :=
⟨h.1.choose, h.1.choose_spec.left⟩
theorem WOppSide.nonempty {s : AffineSubspace R P} {x y : P} (h : s.WOppSide x y) :
(s : Set P).Nonempty :=
⟨h.choose, h.choose_spec.left⟩
theorem SOppSide.nonempty {s : AffineSubspace R P} {x y : P} (h : s.SOppSide x y) :
(s : Set P).Nonempty :=
⟨h.1.choose, h.1.choose_spec.left⟩
theorem SSameSide.wSameSide {s : AffineSubspace R P} {x y : P} (h : s.SSameSide x y) :
s.WSameSide x y :=
h.1
theorem SSameSide.left_not_mem {s : AffineSubspace R P} {x y : P} (h : s.SSameSide x y) : x ∉ s :=
h.2.1
theorem SSameSide.right_not_mem {s : AffineSubspace R P} {x y : P} (h : s.SSameSide x y) : y ∉ s :=
h.2.2
theorem SOppSide.wOppSide {s : AffineSubspace R P} {x y : P} (h : s.SOppSide x y) :
s.WOppSide x y :=
h.1
theorem SOppSide.left_not_mem {s : AffineSubspace R P} {x y : P} (h : s.SOppSide x y) : x ∉ s :=
h.2.1
theorem SOppSide.right_not_mem {s : AffineSubspace R P} {x y : P} (h : s.SOppSide x y) : y ∉ s :=
h.2.2
theorem wSameSide_comm {s : AffineSubspace R P} {x y : P} : s.WSameSide x y ↔ s.WSameSide y x :=
⟨fun ⟨p₁, hp₁, p₂, hp₂, h⟩ => ⟨p₂, hp₂, p₁, hp₁, h.symm⟩,
fun ⟨p₁, hp₁, p₂, hp₂, h⟩ => ⟨p₂, hp₂, p₁, hp₁, h.symm⟩⟩
alias ⟨WSameSide.symm, _⟩ := wSameSide_comm
theorem sSameSide_comm {s : AffineSubspace R P} {x y : P} : s.SSameSide x y ↔ s.SSameSide y x := by
rw [SSameSide, SSameSide, wSameSide_comm, and_comm (b := x ∉ s)]
alias ⟨SSameSide.symm, _⟩ := sSameSide_comm
theorem wOppSide_comm {s : AffineSubspace R P} {x y : P} : s.WOppSide x y ↔ s.WOppSide y x := by
constructor
· rintro ⟨p₁, hp₁, p₂, hp₂, h⟩
refine ⟨p₂, hp₂, p₁, hp₁, ?_⟩
rwa [SameRay.sameRay_comm, ← sameRay_neg_iff, neg_vsub_eq_vsub_rev, neg_vsub_eq_vsub_rev]
· rintro ⟨p₁, hp₁, p₂, hp₂, h⟩
refine ⟨p₂, hp₂, p₁, hp₁, ?_⟩
rwa [SameRay.sameRay_comm, ← sameRay_neg_iff, neg_vsub_eq_vsub_rev, neg_vsub_eq_vsub_rev]
alias ⟨WOppSide.symm, _⟩ := wOppSide_comm
theorem sOppSide_comm {s : AffineSubspace R P} {x y : P} : s.SOppSide x y ↔ s.SOppSide y x := by
rw [SOppSide, SOppSide, wOppSide_comm, and_comm (b := x ∉ s)]
alias ⟨SOppSide.symm, _⟩ := sOppSide_comm
theorem not_wSameSide_bot (x y : P) : ¬(⊥ : AffineSubspace R P).WSameSide x y :=
fun ⟨_, h, _⟩ => h.elim
theorem not_sSameSide_bot (x y : P) : ¬(⊥ : AffineSubspace R P).SSameSide x y :=
fun h => not_wSameSide_bot x y h.wSameSide
theorem not_wOppSide_bot (x y : P) : ¬(⊥ : AffineSubspace R P).WOppSide x y :=
fun ⟨_, h, _⟩ => h.elim
theorem not_sOppSide_bot (x y : P) : ¬(⊥ : AffineSubspace R P).SOppSide x y :=
fun h => not_wOppSide_bot x y h.wOppSide
@[simp]
theorem wSameSide_self_iff {s : AffineSubspace R P} {x : P} :
s.WSameSide x x ↔ (s : Set P).Nonempty :=
⟨fun h => h.nonempty, fun ⟨p, hp⟩ => ⟨p, hp, p, hp, SameRay.rfl⟩⟩
theorem sSameSide_self_iff {s : AffineSubspace R P} {x : P} :
s.SSameSide x x ↔ (s : Set P).Nonempty ∧ x ∉ s :=
⟨fun ⟨h, hx, _⟩ => ⟨wSameSide_self_iff.1 h, hx⟩, fun ⟨h, hx⟩ => ⟨wSameSide_self_iff.2 h, hx, hx⟩⟩
theorem wSameSide_of_left_mem {s : AffineSubspace R P} {x : P} (y : P) (hx : x ∈ s) :
s.WSameSide x y := by
refine ⟨x, hx, x, hx, ?_⟩
rw [vsub_self]
apply SameRay.zero_left
theorem wSameSide_of_right_mem {s : AffineSubspace R P} (x : P) {y : P} (hy : y ∈ s) :
s.WSameSide x y :=
(wSameSide_of_left_mem x hy).symm
theorem wOppSide_of_left_mem {s : AffineSubspace R P} {x : P} (y : P) (hx : x ∈ s) :
s.WOppSide x y := by
refine ⟨x, hx, x, hx, ?_⟩
rw [vsub_self]
apply SameRay.zero_left
theorem wOppSide_of_right_mem {s : AffineSubspace R P} (x : P) {y : P} (hy : y ∈ s) :
s.WOppSide x y :=
(wOppSide_of_left_mem x hy).symm
theorem wSameSide_vadd_left_iff {s : AffineSubspace R P} {x y : P} {v : V} (hv : v ∈ s.direction) :
s.WSameSide (v +ᵥ x) y ↔ s.WSameSide x y := by
constructor
· rintro ⟨p₁, hp₁, p₂, hp₂, h⟩
refine
⟨-v +ᵥ p₁, AffineSubspace.vadd_mem_of_mem_direction (Submodule.neg_mem _ hv) hp₁, p₂, hp₂, ?_⟩
rwa [vsub_vadd_eq_vsub_sub, sub_neg_eq_add, add_comm, ← vadd_vsub_assoc]
· rintro ⟨p₁, hp₁, p₂, hp₂, h⟩
refine ⟨v +ᵥ p₁, AffineSubspace.vadd_mem_of_mem_direction hv hp₁, p₂, hp₂, ?_⟩
rwa [vadd_vsub_vadd_cancel_left]
theorem wSameSide_vadd_right_iff {s : AffineSubspace R P} {x y : P} {v : V} (hv : v ∈ s.direction) :
s.WSameSide x (v +ᵥ y) ↔ s.WSameSide x y := by
rw [wSameSide_comm, wSameSide_vadd_left_iff hv, wSameSide_comm]
theorem sSameSide_vadd_left_iff {s : AffineSubspace R P} {x y : P} {v : V} (hv : v ∈ s.direction) :
s.SSameSide (v +ᵥ x) y ↔ s.SSameSide x y := by
rw [SSameSide, SSameSide, wSameSide_vadd_left_iff hv, vadd_mem_iff_mem_of_mem_direction hv]
theorem sSameSide_vadd_right_iff {s : AffineSubspace R P} {x y : P} {v : V} (hv : v ∈ s.direction) :
s.SSameSide x (v +ᵥ y) ↔ s.SSameSide x y := by
rw [sSameSide_comm, sSameSide_vadd_left_iff hv, sSameSide_comm]
theorem wOppSide_vadd_left_iff {s : AffineSubspace R P} {x y : P} {v : V} (hv : v ∈ s.direction) :
s.WOppSide (v +ᵥ x) y ↔ s.WOppSide x y := by
constructor
· rintro ⟨p₁, hp₁, p₂, hp₂, h⟩
refine
⟨-v +ᵥ p₁, AffineSubspace.vadd_mem_of_mem_direction (Submodule.neg_mem _ hv) hp₁, p₂, hp₂, ?_⟩
rwa [vsub_vadd_eq_vsub_sub, sub_neg_eq_add, add_comm, ← vadd_vsub_assoc]
· rintro ⟨p₁, hp₁, p₂, hp₂, h⟩
refine ⟨v +ᵥ p₁, AffineSubspace.vadd_mem_of_mem_direction hv hp₁, p₂, hp₂, ?_⟩
rwa [vadd_vsub_vadd_cancel_left]
theorem wOppSide_vadd_right_iff {s : AffineSubspace R P} {x y : P} {v : V} (hv : v ∈ s.direction) :
s.WOppSide x (v +ᵥ y) ↔ s.WOppSide x y := by
rw [wOppSide_comm, wOppSide_vadd_left_iff hv, wOppSide_comm]
theorem sOppSide_vadd_left_iff {s : AffineSubspace R P} {x y : P} {v : V} (hv : v ∈ s.direction) :
s.SOppSide (v +ᵥ x) y ↔ s.SOppSide x y := by
rw [SOppSide, SOppSide, wOppSide_vadd_left_iff hv, vadd_mem_iff_mem_of_mem_direction hv]
theorem sOppSide_vadd_right_iff {s : AffineSubspace R P} {x y : P} {v : V} (hv : v ∈ s.direction) :
s.SOppSide x (v +ᵥ y) ↔ s.SOppSide x y := by
rw [sOppSide_comm, sOppSide_vadd_left_iff hv, sOppSide_comm]
theorem wSameSide_smul_vsub_vadd_left {s : AffineSubspace R P} {p₁ p₂ : P} (x : P) (hp₁ : p₁ ∈ s)
(hp₂ : p₂ ∈ s) {t : R} (ht : 0 ≤ t) : s.WSameSide (t • (x -ᵥ p₁) +ᵥ p₂) x := by
refine ⟨p₂, hp₂, p₁, hp₁, ?_⟩
rw [vadd_vsub]
exact SameRay.sameRay_nonneg_smul_left _ ht
theorem wSameSide_smul_vsub_vadd_right {s : AffineSubspace R P} {p₁ p₂ : P} (x : P) (hp₁ : p₁ ∈ s)
(hp₂ : p₂ ∈ s) {t : R} (ht : 0 ≤ t) : s.WSameSide x (t • (x -ᵥ p₁) +ᵥ p₂) :=
(wSameSide_smul_vsub_vadd_left x hp₁ hp₂ ht).symm
theorem wSameSide_lineMap_left {s : AffineSubspace R P} {x : P} (y : P) (h : x ∈ s) {t : R}
(ht : 0 ≤ t) : s.WSameSide (lineMap x y t) y :=
wSameSide_smul_vsub_vadd_left y h h ht
theorem wSameSide_lineMap_right {s : AffineSubspace R P} {x : P} (y : P) (h : x ∈ s) {t : R}
(ht : 0 ≤ t) : s.WSameSide y (lineMap x y t) :=
(wSameSide_lineMap_left y h ht).symm
theorem wOppSide_smul_vsub_vadd_left {s : AffineSubspace R P} {p₁ p₂ : P} (x : P) (hp₁ : p₁ ∈ s)
(hp₂ : p₂ ∈ s) {t : R} (ht : t ≤ 0) : s.WOppSide (t • (x -ᵥ p₁) +ᵥ p₂) x := by
refine ⟨p₂, hp₂, p₁, hp₁, ?_⟩
rw [vadd_vsub, ← neg_neg t, neg_smul, ← smul_neg, neg_vsub_eq_vsub_rev]
exact SameRay.sameRay_nonneg_smul_left _ (neg_nonneg.2 ht)
theorem wOppSide_smul_vsub_vadd_right {s : AffineSubspace R P} {p₁ p₂ : P} (x : P) (hp₁ : p₁ ∈ s)
(hp₂ : p₂ ∈ s) {t : R} (ht : t ≤ 0) : s.WOppSide x (t • (x -ᵥ p₁) +ᵥ p₂) :=
(wOppSide_smul_vsub_vadd_left x hp₁ hp₂ ht).symm
theorem wOppSide_lineMap_left {s : AffineSubspace R P} {x : P} (y : P) (h : x ∈ s) {t : R}
(ht : t ≤ 0) : s.WOppSide (lineMap x y t) y :=
wOppSide_smul_vsub_vadd_left y h h ht
theorem wOppSide_lineMap_right {s : AffineSubspace R P} {x : P} (y : P) (h : x ∈ s) {t : R}
(ht : t ≤ 0) : s.WOppSide y (lineMap x y t) :=
(wOppSide_lineMap_left y h ht).symm
theorem _root_.Wbtw.wSameSide₂₃ {s : AffineSubspace R P} {x y z : P} (h : Wbtw R x y z)
(hx : x ∈ s) : s.WSameSide y z := by
rcases h with ⟨t, ⟨ht0, -⟩, rfl⟩
exact wSameSide_lineMap_left z hx ht0
theorem _root_.Wbtw.wSameSide₃₂ {s : AffineSubspace R P} {x y z : P} (h : Wbtw R x y z)
(hx : x ∈ s) : s.WSameSide z y :=
(h.wSameSide₂₃ hx).symm
theorem _root_.Wbtw.wSameSide₁₂ {s : AffineSubspace R P} {x y z : P} (h : Wbtw R x y z)
(hz : z ∈ s) : s.WSameSide x y :=
h.symm.wSameSide₃₂ hz
theorem _root_.Wbtw.wSameSide₂₁ {s : AffineSubspace R P} {x y z : P} (h : Wbtw R x y z)
(hz : z ∈ s) : s.WSameSide y x :=
h.symm.wSameSide₂₃ hz
theorem _root_.Wbtw.wOppSide₁₃ {s : AffineSubspace R P} {x y z : P} (h : Wbtw R x y z)
(hy : y ∈ s) : s.WOppSide x z := by
rcases h with ⟨t, ⟨ht0, ht1⟩, rfl⟩
refine ⟨_, hy, _, hy, ?_⟩
rcases ht1.lt_or_eq with (ht1' | rfl); swap
· rw [lineMap_apply_one]; simp
rcases ht0.lt_or_eq with (ht0' | rfl); swap
· rw [lineMap_apply_zero]; simp
refine Or.inr (Or.inr ⟨1 - t, t, sub_pos.2 ht1', ht0', ?_⟩)
rw [lineMap_apply, vadd_vsub_assoc, vsub_vadd_eq_vsub_sub, ← neg_vsub_eq_vsub_rev z, vsub_self]
module
theorem _root_.Wbtw.wOppSide₃₁ {s : AffineSubspace R P} {x y z : P} (h : Wbtw R x y z)
(hy : y ∈ s) : s.WOppSide z x :=
h.symm.wOppSide₁₃ hy
end StrictOrderedCommRing
section LinearOrderedField
variable [Field R] [LinearOrder R] [IsStrictOrderedRing R]
[AddCommGroup V] [Module R V] [AddTorsor V P]
@[simp]
theorem wOppSide_self_iff {s : AffineSubspace R P} {x : P} : s.WOppSide x x ↔ x ∈ s := by
constructor
· rintro ⟨p₁, hp₁, p₂, hp₂, h⟩
obtain ⟨a, -, -, -, -, h₁, -⟩ := h.exists_eq_smul_add
rw [add_comm, vsub_add_vsub_cancel, ← eq_vadd_iff_vsub_eq] at h₁
rw [h₁]
exact s.smul_vsub_vadd_mem a hp₂ hp₁ hp₁
· exact fun h => ⟨x, h, x, h, SameRay.rfl⟩
theorem not_sOppSide_self (s : AffineSubspace R P) (x : P) : ¬s.SOppSide x x := by
rw [SOppSide]
simp
theorem wSameSide_iff_exists_left {s : AffineSubspace R P} {x y p₁ : P} (h : p₁ ∈ s) :
s.WSameSide x y ↔ x ∈ s ∨ ∃ p₂ ∈ s, SameRay R (x -ᵥ p₁) (y -ᵥ p₂) := by
constructor
· rintro ⟨p₁', hp₁', p₂', hp₂', h0 | h0 | ⟨r₁, r₂, hr₁, hr₂, hr⟩⟩
· rw [vsub_eq_zero_iff_eq] at h0
rw [h0]
exact Or.inl hp₁'
· refine Or.inr ⟨p₂', hp₂', ?_⟩
rw [h0]
exact SameRay.zero_right _
· refine Or.inr ⟨(r₁ / r₂) • (p₁ -ᵥ p₁') +ᵥ p₂', s.smul_vsub_vadd_mem _ h hp₁' hp₂',
Or.inr (Or.inr ⟨r₁, r₂, hr₁, hr₂, ?_⟩)⟩
rw [vsub_vadd_eq_vsub_sub, smul_sub, ← hr, smul_smul, mul_div_cancel₀ _ hr₂.ne.symm,
← smul_sub, vsub_sub_vsub_cancel_right]
· rintro (h' | ⟨h₁, h₂, h₃⟩)
· exact wSameSide_of_left_mem y h'
· exact ⟨p₁, h, h₁, h₂, h₃⟩
theorem wSameSide_iff_exists_right {s : AffineSubspace R P} {x y p₂ : P} (h : p₂ ∈ s) :
s.WSameSide x y ↔ y ∈ s ∨ ∃ p₁ ∈ s, SameRay R (x -ᵥ p₁) (y -ᵥ p₂) := by
rw [wSameSide_comm, wSameSide_iff_exists_left h]
simp_rw [SameRay.sameRay_comm]
theorem sSameSide_iff_exists_left {s : AffineSubspace R P} {x y p₁ : P} (h : p₁ ∈ s) :
s.SSameSide x y ↔ x ∉ s ∧ y ∉ s ∧ ∃ p₂ ∈ s, SameRay R (x -ᵥ p₁) (y -ᵥ p₂) := by
rw [SSameSide, and_comm, wSameSide_iff_exists_left h, and_assoc, and_congr_right_iff]
intro hx
rw [or_iff_right hx]
theorem sSameSide_iff_exists_right {s : AffineSubspace R P} {x y p₂ : P} (h : p₂ ∈ s) :
s.SSameSide x y ↔ x ∉ s ∧ y ∉ s ∧ ∃ p₁ ∈ s, SameRay R (x -ᵥ p₁) (y -ᵥ p₂) := by
rw [sSameSide_comm, sSameSide_iff_exists_left h, ← and_assoc, and_comm (a := y ∉ s), and_assoc]
simp_rw [SameRay.sameRay_comm]
theorem wOppSide_iff_exists_left {s : AffineSubspace R P} {x y p₁ : P} (h : p₁ ∈ s) :
s.WOppSide x y ↔ x ∈ s ∨ ∃ p₂ ∈ s, SameRay R (x -ᵥ p₁) (p₂ -ᵥ y) := by
constructor
· rintro ⟨p₁', hp₁', p₂', hp₂', h0 | h0 | ⟨r₁, r₂, hr₁, hr₂, hr⟩⟩
· rw [vsub_eq_zero_iff_eq] at h0
rw [h0]
exact Or.inl hp₁'
· refine Or.inr ⟨p₂', hp₂', ?_⟩
rw [h0]
exact SameRay.zero_right _
· refine Or.inr ⟨(-r₁ / r₂) • (p₁ -ᵥ p₁') +ᵥ p₂', s.smul_vsub_vadd_mem _ h hp₁' hp₂',
Or.inr (Or.inr ⟨r₁, r₂, hr₁, hr₂, ?_⟩)⟩
rw [vadd_vsub_assoc, ← vsub_sub_vsub_cancel_right x p₁ p₁']
linear_combination (norm := match_scalars <;> field_simp) hr
ring
· rintro (h' | ⟨h₁, h₂, h₃⟩)
· exact wOppSide_of_left_mem y h'
· exact ⟨p₁, h, h₁, h₂, h₃⟩
theorem wOppSide_iff_exists_right {s : AffineSubspace R P} {x y p₂ : P} (h : p₂ ∈ s) :
s.WOppSide x y ↔ y ∈ s ∨ ∃ p₁ ∈ s, SameRay R (x -ᵥ p₁) (p₂ -ᵥ y) := by
rw [wOppSide_comm, wOppSide_iff_exists_left h]
constructor
· rintro (hy | ⟨p, hp, hr⟩)
· exact Or.inl hy
refine Or.inr ⟨p, hp, ?_⟩
rwa [SameRay.sameRay_comm, ← sameRay_neg_iff, neg_vsub_eq_vsub_rev, neg_vsub_eq_vsub_rev]
· rintro (hy | ⟨p, hp, hr⟩)
· exact Or.inl hy
refine Or.inr ⟨p, hp, ?_⟩
rwa [SameRay.sameRay_comm, ← sameRay_neg_iff, neg_vsub_eq_vsub_rev, neg_vsub_eq_vsub_rev]
theorem sOppSide_iff_exists_left {s : AffineSubspace R P} {x y p₁ : P} (h : p₁ ∈ s) :
s.SOppSide x y ↔ x ∉ s ∧ y ∉ s ∧ ∃ p₂ ∈ s, SameRay R (x -ᵥ p₁) (p₂ -ᵥ y) := by
rw [SOppSide, and_comm, wOppSide_iff_exists_left h, and_assoc, and_congr_right_iff]
intro hx
rw [or_iff_right hx]
theorem sOppSide_iff_exists_right {s : AffineSubspace R P} {x y p₂ : P} (h : p₂ ∈ s) :
s.SOppSide x y ↔ x ∉ s ∧ y ∉ s ∧ ∃ p₁ ∈ s, SameRay R (x -ᵥ p₁) (p₂ -ᵥ y) := by
rw [SOppSide, and_comm, wOppSide_iff_exists_right h, and_assoc, and_congr_right_iff,
and_congr_right_iff]
rintro _ hy
rw [or_iff_right hy]
theorem WSameSide.trans {s : AffineSubspace R P} {x y z : P} (hxy : s.WSameSide x y)
(hyz : s.WSameSide y z) (hy : y ∉ s) : s.WSameSide x z := by
rcases hxy with ⟨p₁, hp₁, p₂, hp₂, hxy⟩
rw [wSameSide_iff_exists_left hp₂, or_iff_right hy] at hyz
rcases hyz with ⟨p₃, hp₃, hyz⟩
refine ⟨p₁, hp₁, p₃, hp₃, hxy.trans hyz ?_⟩
refine fun h => False.elim ?_
rw [vsub_eq_zero_iff_eq] at h
exact hy (h.symm ▸ hp₂)
theorem WSameSide.trans_sSameSide {s : AffineSubspace R P} {x y z : P} (hxy : s.WSameSide x y)
(hyz : s.SSameSide y z) : s.WSameSide x z :=
hxy.trans hyz.1 hyz.2.1
theorem WSameSide.trans_wOppSide {s : AffineSubspace R P} {x y z : P} (hxy : s.WSameSide x y)
(hyz : s.WOppSide y z) (hy : y ∉ s) : s.WOppSide x z := by
rcases hxy with ⟨p₁, hp₁, p₂, hp₂, hxy⟩
rw [wOppSide_iff_exists_left hp₂, or_iff_right hy] at hyz
rcases hyz with ⟨p₃, hp₃, hyz⟩
refine ⟨p₁, hp₁, p₃, hp₃, hxy.trans hyz ?_⟩
refine fun h => False.elim ?_
rw [vsub_eq_zero_iff_eq] at h
exact hy (h.symm ▸ hp₂)
theorem WSameSide.trans_sOppSide {s : AffineSubspace R P} {x y z : P} (hxy : s.WSameSide x y)
(hyz : s.SOppSide y z) : s.WOppSide x z :=
hxy.trans_wOppSide hyz.1 hyz.2.1
theorem SSameSide.trans_wSameSide {s : AffineSubspace R P} {x y z : P} (hxy : s.SSameSide x y)
(hyz : s.WSameSide y z) : s.WSameSide x z :=
(hyz.symm.trans_sSameSide hxy.symm).symm
theorem SSameSide.trans {s : AffineSubspace R P} {x y z : P} (hxy : s.SSameSide x y)
(hyz : s.SSameSide y z) : s.SSameSide x z :=
⟨hxy.wSameSide.trans_sSameSide hyz, hxy.2.1, hyz.2.2⟩
theorem SSameSide.trans_wOppSide {s : AffineSubspace R P} {x y z : P} (hxy : s.SSameSide x y)
(hyz : s.WOppSide y z) : s.WOppSide x z :=
hxy.wSameSide.trans_wOppSide hyz hxy.2.2
theorem SSameSide.trans_sOppSide {s : AffineSubspace R P} {x y z : P} (hxy : s.SSameSide x y)
(hyz : s.SOppSide y z) : s.SOppSide x z :=
⟨hxy.trans_wOppSide hyz.1, hxy.2.1, hyz.2.2⟩
theorem WOppSide.trans_wSameSide {s : AffineSubspace R P} {x y z : P} (hxy : s.WOppSide x y)
(hyz : s.WSameSide y z) (hy : y ∉ s) : s.WOppSide x z :=
(hyz.symm.trans_wOppSide hxy.symm hy).symm
theorem WOppSide.trans_sSameSide {s : AffineSubspace R P} {x y z : P} (hxy : s.WOppSide x y)
(hyz : s.SSameSide y z) : s.WOppSide x z :=
hxy.trans_wSameSide hyz.1 hyz.2.1
theorem WOppSide.trans {s : AffineSubspace R P} {x y z : P} (hxy : s.WOppSide x y)
(hyz : s.WOppSide y z) (hy : y ∉ s) : s.WSameSide x z := by
rcases hxy with ⟨p₁, hp₁, p₂, hp₂, hxy⟩
rw [wOppSide_iff_exists_left hp₂, or_iff_right hy] at hyz
rcases hyz with ⟨p₃, hp₃, hyz⟩
rw [← sameRay_neg_iff, neg_vsub_eq_vsub_rev, neg_vsub_eq_vsub_rev] at hyz
refine ⟨p₁, hp₁, p₃, hp₃, hxy.trans hyz ?_⟩
refine fun h => False.elim ?_
rw [vsub_eq_zero_iff_eq] at h
exact hy (h ▸ hp₂)
theorem WOppSide.trans_sOppSide {s : AffineSubspace R P} {x y z : P} (hxy : s.WOppSide x y)
(hyz : s.SOppSide y z) : s.WSameSide x z :=
hxy.trans hyz.1 hyz.2.1
theorem SOppSide.trans_wSameSide {s : AffineSubspace R P} {x y z : P} (hxy : s.SOppSide x y)
(hyz : s.WSameSide y z) : s.WOppSide x z :=
(hyz.symm.trans_sOppSide hxy.symm).symm
theorem SOppSide.trans_sSameSide {s : AffineSubspace R P} {x y z : P} (hxy : s.SOppSide x y)
(hyz : s.SSameSide y z) : s.SOppSide x z :=
(hyz.symm.trans_sOppSide hxy.symm).symm
theorem SOppSide.trans_wOppSide {s : AffineSubspace R P} {x y z : P} (hxy : s.SOppSide x y)
(hyz : s.WOppSide y z) : s.WSameSide x z :=
(hyz.symm.trans_sOppSide hxy.symm).symm
theorem SOppSide.trans {s : AffineSubspace R P} {x y z : P} (hxy : s.SOppSide x y)
(hyz : s.SOppSide y z) : s.SSameSide x z :=
⟨hxy.trans_wOppSide hyz.1, hxy.2.1, hyz.2.2⟩
theorem wSameSide_and_wOppSide_iff {s : AffineSubspace R P} {x y : P} :
s.WSameSide x y ∧ s.WOppSide x y ↔ x ∈ s ∨ y ∈ s := by
constructor
· rintro ⟨hs, ho⟩
rw [wOppSide_comm] at ho
by_contra h
rw [not_or] at h
exact h.1 (wOppSide_self_iff.1 (hs.trans_wOppSide ho h.2))
· rintro (h | h)
· exact ⟨wSameSide_of_left_mem y h, wOppSide_of_left_mem y h⟩
· exact ⟨wSameSide_of_right_mem x h, wOppSide_of_right_mem x h⟩
theorem WSameSide.not_sOppSide {s : AffineSubspace R P} {x y : P} (h : s.WSameSide x y) :
¬s.SOppSide x y := by
intro ho
have hxy := wSameSide_and_wOppSide_iff.1 ⟨h, ho.1⟩
rcases hxy with (hx | hy)
· exact ho.2.1 hx
· exact ho.2.2 hy
theorem SSameSide.not_wOppSide {s : AffineSubspace R P} {x y : P} (h : s.SSameSide x y) :
¬s.WOppSide x y := by
intro ho
have hxy := wSameSide_and_wOppSide_iff.1 ⟨h.1, ho⟩
rcases hxy with (hx | hy)
· exact h.2.1 hx
· exact h.2.2 hy
theorem SSameSide.not_sOppSide {s : AffineSubspace R P} {x y : P} (h : s.SSameSide x y) :
¬s.SOppSide x y :=
fun ho => h.not_wOppSide ho.1
theorem WOppSide.not_sSameSide {s : AffineSubspace R P} {x y : P} (h : s.WOppSide x y) :
¬s.SSameSide x y :=
fun hs => hs.not_wOppSide h
theorem SOppSide.not_wSameSide {s : AffineSubspace R P} {x y : P} (h : s.SOppSide x y) :
¬s.WSameSide x y :=
fun hs => hs.not_sOppSide h
theorem SOppSide.not_sSameSide {s : AffineSubspace R P} {x y : P} (h : s.SOppSide x y) :
¬s.SSameSide x y :=
fun hs => h.not_wSameSide hs.1
theorem wOppSide_iff_exists_wbtw {s : AffineSubspace R P} {x y : P} :
s.WOppSide x y ↔ ∃ p ∈ s, Wbtw R x p y := by
refine ⟨fun h => ?_, fun ⟨p, hp, h⟩ => h.wOppSide₁₃ hp⟩
rcases h with ⟨p₁, hp₁, p₂, hp₂, h | h | ⟨r₁, r₂, hr₁, hr₂, h⟩⟩
· rw [vsub_eq_zero_iff_eq] at h
rw [h]
exact ⟨p₁, hp₁, wbtw_self_left _ _ _⟩
· rw [vsub_eq_zero_iff_eq] at h
rw [← h]
exact ⟨p₂, hp₂, wbtw_self_right _ _ _⟩
· refine ⟨lineMap x y (r₂ / (r₁ + r₂)), ?_, ?_⟩
· have : (r₂ / (r₁ + r₂)) • (y -ᵥ p₂ + (p₂ -ᵥ p₁) - (x -ᵥ p₁)) + (x -ᵥ p₁) =
(r₂ / (r₁ + r₂)) • (p₂ -ᵥ p₁) := by
rw [← neg_vsub_eq_vsub_rev p₂ y]
linear_combination (norm := match_scalars <;> field_simp) (r₁ + r₂)⁻¹ • h
rw [lineMap_apply, ← vsub_vadd x p₁, ← vsub_vadd y p₂, vsub_vadd_eq_vsub_sub, vadd_vsub_assoc,
← vadd_assoc, vadd_eq_add, this]
exact s.smul_vsub_vadd_mem (r₂ / (r₁ + r₂)) hp₂ hp₁ hp₁
· exact Set.mem_image_of_mem _
⟨by positivity,
div_le_one_of_le₀ (le_add_of_nonneg_left hr₁.le) (Left.add_pos hr₁ hr₂).le⟩
theorem SOppSide.exists_sbtw {s : AffineSubspace R P} {x y : P} (h : s.SOppSide x y) :
∃ p ∈ s, Sbtw R x p y := by
obtain ⟨p, hp, hw⟩ := wOppSide_iff_exists_wbtw.1 h.wOppSide
refine ⟨p, hp, hw, ?_, ?_⟩
· rintro rfl
exact h.2.1 hp
· rintro rfl
exact h.2.2 hp
theorem _root_.Sbtw.sOppSide_of_not_mem_of_mem {s : AffineSubspace R P} {x y z : P}
(h : Sbtw R x y z) (hx : x ∉ s) (hy : y ∈ s) : s.SOppSide x z := by
refine ⟨h.wbtw.wOppSide₁₃ hy, hx, fun hz => hx ?_⟩
rcases h with ⟨⟨t, ⟨ht0, ht1⟩, rfl⟩, hyx, hyz⟩
rw [lineMap_apply] at hy
have ht : t ≠ 1 := by
rintro rfl
simp [lineMap_apply] at hyz
have hy' := vsub_mem_direction hy hz
rw [vadd_vsub_assoc, ← neg_vsub_eq_vsub_rev z, ← neg_one_smul R (z -ᵥ x), ← add_smul,
← sub_eq_add_neg, s.direction.smul_mem_iff (sub_ne_zero_of_ne ht)] at hy'
rwa [vadd_mem_iff_mem_of_mem_direction (Submodule.smul_mem _ _ hy')] at hy
theorem sSameSide_smul_vsub_vadd_left {s : AffineSubspace R P} {x p₁ p₂ : P} (hx : x ∉ s)
(hp₁ : p₁ ∈ s) (hp₂ : p₂ ∈ s) {t : R} (ht : 0 < t) : s.SSameSide (t • (x -ᵥ p₁) +ᵥ p₂) x := by
refine ⟨wSameSide_smul_vsub_vadd_left x hp₁ hp₂ ht.le, fun h => hx ?_, hx⟩
rwa [vadd_mem_iff_mem_direction _ hp₂, s.direction.smul_mem_iff ht.ne.symm,
vsub_right_mem_direction_iff_mem hp₁] at h
theorem sSameSide_smul_vsub_vadd_right {s : AffineSubspace R P} {x p₁ p₂ : P} (hx : x ∉ s)
(hp₁ : p₁ ∈ s) (hp₂ : p₂ ∈ s) {t : R} (ht : 0 < t) : s.SSameSide x (t • (x -ᵥ p₁) +ᵥ p₂) :=
(sSameSide_smul_vsub_vadd_left hx hp₁ hp₂ ht).symm
theorem sSameSide_lineMap_left {s : AffineSubspace R P} {x y : P} (hx : x ∈ s) (hy : y ∉ s) {t : R}
(ht : 0 < t) : s.SSameSide (lineMap x y t) y :=
sSameSide_smul_vsub_vadd_left hy hx hx ht
theorem sSameSide_lineMap_right {s : AffineSubspace R P} {x y : P} (hx : x ∈ s) (hy : y ∉ s) {t : R}
(ht : 0 < t) : s.SSameSide y (lineMap x y t) :=
(sSameSide_lineMap_left hx hy ht).symm
theorem sOppSide_smul_vsub_vadd_left {s : AffineSubspace R P} {x p₁ p₂ : P} (hx : x ∉ s)
(hp₁ : p₁ ∈ s) (hp₂ : p₂ ∈ s) {t : R} (ht : t < 0) : s.SOppSide (t • (x -ᵥ p₁) +ᵥ p₂) x := by
| refine ⟨wOppSide_smul_vsub_vadd_left x hp₁ hp₂ ht.le, fun h => hx ?_, hx⟩
rwa [vadd_mem_iff_mem_direction _ hp₂, s.direction.smul_mem_iff ht.ne,
vsub_right_mem_direction_iff_mem hp₁] at h
theorem sOppSide_smul_vsub_vadd_right {s : AffineSubspace R P} {x p₁ p₂ : P} (hx : x ∉ s)
(hp₁ : p₁ ∈ s) (hp₂ : p₂ ∈ s) {t : R} (ht : t < 0) : s.SOppSide x (t • (x -ᵥ p₁) +ᵥ p₂) :=
(sOppSide_smul_vsub_vadd_left hx hp₁ hp₂ ht).symm
| Mathlib/Analysis/Convex/Side.lean | 635 | 641 |
/-
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 | 132 | 139 | |
/-
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, Floris van Doorn, Yury Kudryashov, Neil Strickland
-/
import Mathlib.Algebra.Ring.Semiconj
import Mathlib.Algebra.Ring.Units
import Mathlib.Algebra.Group.Commute.Defs
import Mathlib.Data.Bracket
/-!
# Semirings and rings
This file gives lemmas about semirings, rings and domains.
This is analogous to `Mathlib.Algebra.Group.Basic`,
the difference being that the former is about `+` and `*` separately, while
the present file is about their interaction.
For the definitions of semirings and rings see `Mathlib.Algebra.Ring.Defs`.
-/
universe u
variable {R : Type u}
open Function
namespace Commute
@[simp]
theorem add_right [Distrib R] {a b c : R} : Commute a b → Commute a c → Commute a (b + c) :=
SemiconjBy.add_right
-- for some reason mathport expected `Semiring` instead of `Distrib`?
@[simp]
theorem add_left [Distrib R] {a b c : R} : Commute a c → Commute b c → Commute (a + b) c :=
SemiconjBy.add_left
-- for some reason mathport expected `Semiring` instead of `Distrib`?
/-- Representation of a difference of two squares of commuting elements as a product. -/
theorem mul_self_sub_mul_self_eq [NonUnitalNonAssocRing R] {a b : R} (h : Commute a b) :
a * a - b * b = (a + b) * (a - b) := by
rw [add_mul, mul_sub, mul_sub, h.eq, sub_add_sub_cancel]
theorem mul_self_sub_mul_self_eq' [NonUnitalNonAssocRing R] {a b : R} (h : Commute a b) :
a * a - b * b = (a - b) * (a + b) := by
rw [mul_add, sub_mul, sub_mul, h.eq, sub_add_sub_cancel]
theorem mul_self_eq_mul_self_iff [NonUnitalNonAssocRing R] [NoZeroDivisors R] {a b : R}
(h : Commute a b) : a * a = b * b ↔ a = b ∨ a = -b := by
rw [← sub_eq_zero, h.mul_self_sub_mul_self_eq, mul_eq_zero, or_comm, sub_eq_zero,
add_eq_zero_iff_eq_neg]
section
variable [Mul R] [HasDistribNeg R] {a b : R}
theorem neg_right : Commute a b → Commute a (-b) :=
SemiconjBy.neg_right
@[simp]
theorem neg_right_iff : Commute a (-b) ↔ Commute a b :=
SemiconjBy.neg_right_iff
theorem neg_left : Commute a b → Commute (-a) b :=
SemiconjBy.neg_left
@[simp]
theorem neg_left_iff : Commute (-a) b ↔ Commute a b :=
SemiconjBy.neg_left_iff
end
section
|
variable [MulOneClass R] [HasDistribNeg R]
| Mathlib/Algebra/Ring/Commute.lean | 77 | 79 |
/-
Copyright (c) 2023 Andrew Yang, Patrick Lutz. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Andrew Yang
-/
import Mathlib.RingTheory.RootsOfUnity.PrimitiveRoots
import Mathlib.FieldTheory.Galois.Basic
import Mathlib.FieldTheory.KummerPolynomial
import Mathlib.LinearAlgebra.Eigenspace.Minpoly
import Mathlib.RingTheory.Norm.Basic
/-!
# Kummer Extensions
## Main result
- `isCyclic_tfae`:
Suppose `L/K` is a finite extension of dimension `n`, and `K` contains all `n`-th roots of unity.
Then `L/K` is cyclic iff
`L` is a splitting field of some irreducible polynomial of the form `Xⁿ - a : K[X]` iff
`L = K[α]` for some `αⁿ ∈ K`.
- `autEquivRootsOfUnity`:
Given an instance `IsSplittingField K L (X ^ n - C a)`
(perhaps via `isSplittingField_X_pow_sub_C_of_root_adjoin_eq_top`),
then the galois group is isomorphic to `rootsOfUnity n K`, by sending
`σ ↦ σ α / α` for `α ^ n = a`, and the inverse is given by `μ ↦ (α ↦ μ • α)`.
- `autEquivZmod`:
Furthermore, given an explicit choice `ζ` of a primitive `n`-th root of unity, the galois group is
then isomorphic to `Multiplicative (ZMod n)` whose inverse is given by
`i ↦ (α ↦ ζⁱ • α)`.
## Other results
Criteria for `X ^ n - C a` to be irreducible is given:
- `X_pow_sub_C_irreducible_iff_of_prime_pow`:
For `n = p ^ k` an odd prime power, `X ^ n - C a` is irreducible iff `a` is not a `p`-power.
- `X_pow_sub_C_irreducible_iff_forall_prime_of_odd`:
For `n` odd, `X ^ n - C a` is irreducible iff `a` is not a `p`-power for all prime `p ∣ n`.
- `X_pow_sub_C_irreducible_iff_of_odd`:
For `n` odd, `X ^ n - C a` is irreducible iff `a` is not a `d`-power for `d ∣ n` and `d ≠ 1`.
TODO: criteria for even `n`. See [serge_lang_algebra] VI,§9.
TODO: relate Kummer extensions of degree 2 with the class `Algebra.IsQuadraticExtension`.
-/
universe u
variable {K : Type u} [Field K]
open Polynomial IntermediateField AdjoinRoot
section Splits
theorem X_pow_sub_C_splits_of_isPrimitiveRoot
{n : ℕ} {ζ : K} (hζ : IsPrimitiveRoot ζ n) {α a : K} (e : α ^ n = a) :
(X ^ n - C a).Splits (RingHom.id _) := by
cases n.eq_zero_or_pos with
| inl hn =>
rw [hn, pow_zero, ← C.map_one, ← map_sub]
exact splits_C _ _
| inr hn =>
rw [splits_iff_card_roots, ← nthRoots, hζ.card_nthRoots, natDegree_X_pow_sub_C, if_pos ⟨α, e⟩]
-- make this private, as we only use it to prove a strictly more general version
private
theorem X_pow_sub_C_eq_prod'
{n : ℕ} {ζ : K} (hζ : IsPrimitiveRoot ζ n) {α a : K} (hn : 0 < n) (e : α ^ n = a) :
(X ^ n - C a) = ∏ i ∈ Finset.range n, (X - C (ζ ^ i * α)) := by
rw [eq_prod_roots_of_monic_of_splits_id (monic_X_pow_sub_C _ (Nat.pos_iff_ne_zero.mp hn))
(X_pow_sub_C_splits_of_isPrimitiveRoot hζ e), ← nthRoots, hζ.nthRoots_eq e, Multiset.map_map]
rfl
lemma X_pow_sub_C_eq_prod {R : Type*} [CommRing R] [IsDomain R]
{n : ℕ} {ζ : R} (hζ : IsPrimitiveRoot ζ n) {α a : R} (hn : 0 < n) (e : α ^ n = a) :
(X ^ n - C a) = ∏ i ∈ Finset.range n, (X - C (ζ ^ i * α)) := by
let K := FractionRing R
let i := algebraMap R K
have h := FaithfulSMul.algebraMap_injective R K
apply_fun Polynomial.map i using map_injective i h
simpa only [Polynomial.map_sub, Polynomial.map_pow, map_X, map_C, map_mul, map_pow,
Polynomial.map_prod, Polynomial.map_mul]
using X_pow_sub_C_eq_prod' (hζ.map_of_injective h) hn <| map_pow i α n ▸ congrArg i e
end Splits
section Irreducible
theorem X_pow_mul_sub_C_irreducible
{n m : ℕ} {a : K} (hm : Irreducible (X ^ m - C a))
(hn : ∀ (E : Type u) [Field E] [Algebra K E] (x : E) (_ : minpoly K x = X ^ m - C a),
Irreducible (X ^ n - C (AdjoinSimple.gen K x))) :
Irreducible (X ^ (n * m) - C a) := by
have hm' : m ≠ 0 := by
rintro rfl
rw [pow_zero, ← C.map_one, ← map_sub] at hm
exact not_irreducible_C _ hm
simpa [pow_mul] using irreducible_comp (monic_X_pow_sub_C a hm') (monic_X_pow n) hm
(by simpa only [Polynomial.map_pow, map_X] using hn)
-- TODO: generalize to even `n`
theorem X_pow_sub_C_irreducible_of_odd
{n : ℕ} (hn : Odd n) {a : K} (ha : ∀ p : ℕ, p.Prime → p ∣ n → ∀ b : K, b ^ p ≠ a) :
Irreducible (X ^ n - C a) := by
induction n using induction_on_primes generalizing K a with
| h₀ => simp [← Nat.not_even_iff_odd] at hn
| h₁ => simpa using irreducible_X_sub_C a
| h p n hp IH =>
rw [mul_comm]
apply X_pow_mul_sub_C_irreducible
(X_pow_sub_C_irreducible_of_prime hp (ha p hp (dvd_mul_right _ _)))
intro E _ _ x hx
have : IsIntegral K x := not_not.mp fun h ↦ by
simpa only [degree_zero, degree_X_pow_sub_C hp.pos,
WithBot.natCast_ne_bot] using congr_arg degree (hx.symm.trans (dif_neg h))
apply IH (Nat.odd_mul.mp hn).2
intros q hq hqn b hb
apply ha q hq (dvd_mul_of_dvd_right hqn p) (Algebra.norm _ b)
rw [← map_pow, hb, ← adjoin.powerBasis_gen this,
Algebra.PowerBasis.norm_gen_eq_coeff_zero_minpoly]
simp [minpoly_gen, hx, hp.ne_zero.symm, (Nat.odd_mul.mp hn).1.neg_pow]
theorem X_pow_sub_C_irreducible_iff_forall_prime_of_odd {n : ℕ} (hn : Odd n) {a : K} :
Irreducible (X ^ n - C a) ↔ (∀ p : ℕ, p.Prime → p ∣ n → ∀ b : K, b ^ p ≠ a) :=
⟨fun e _ hp hpn ↦ pow_ne_of_irreducible_X_pow_sub_C e hpn hp.ne_one,
X_pow_sub_C_irreducible_of_odd hn⟩
theorem X_pow_sub_C_irreducible_iff_of_odd {n : ℕ} (hn : Odd n) {a : K} :
Irreducible (X ^ n - C a) ↔ (∀ d, d ∣ n → d ≠ 1 → ∀ b : K, b ^ d ≠ a) :=
⟨fun e _ ↦ pow_ne_of_irreducible_X_pow_sub_C e,
fun H ↦ X_pow_sub_C_irreducible_of_odd hn fun p hp hpn ↦ (H p hpn hp.ne_one)⟩
-- TODO: generalize to `p = 2`
theorem X_pow_sub_C_irreducible_of_prime_pow
{p : ℕ} (hp : p.Prime) (hp' : p ≠ 2) (n : ℕ) {a : K} (ha : ∀ b : K, b ^ p ≠ a) :
Irreducible (X ^ (p ^ n) - C a) := by
apply X_pow_sub_C_irreducible_of_odd (hp.odd_of_ne_two hp').pow
intros q hq hq'
simpa [(Nat.prime_dvd_prime_iff_eq hq hp).mp (hq.dvd_of_dvd_pow hq')] using ha
theorem X_pow_sub_C_irreducible_iff_of_prime_pow
{p : ℕ} (hp : p.Prime) (hp' : p ≠ 2) {n} (hn : n ≠ 0) {a : K} :
Irreducible (X ^ p ^ n - C a) ↔ ∀ b, b ^ p ≠ a :=
⟨(pow_ne_of_irreducible_X_pow_sub_C · (dvd_pow dvd_rfl hn) hp.ne_one),
X_pow_sub_C_irreducible_of_prime_pow hp hp' n⟩
end Irreducible
/-!
### Galois Group of `K[n√a]`
We first develop the theory for a specific `K[n√a] := AdjoinRoot (X ^ n - C a)`.
The main result is the description of the galois group: `autAdjoinRootXPowSubCEquiv`.
-/
variable {n : ℕ} (hζ : (primitiveRoots n K).Nonempty)
variable (a : K) (H : Irreducible (X ^ n - C a))
set_option quotPrecheck false in
scoped[KummerExtension] notation3 "K[" n "√" a "]" => AdjoinRoot (Polynomial.X ^ n - Polynomial.C a)
attribute [nolint docBlame] KummerExtension.«termK[_√_]»
open scoped KummerExtension
section AdjoinRoot
include hζ H in
/-- Also see `Polynomial.separable_X_pow_sub_C_unit` -/
theorem Polynomial.separable_X_pow_sub_C_of_irreducible : (X ^ n - C a).Separable := by
letI := Fact.mk H
letI : Algebra K K[n√a] := inferInstance
have hn := Nat.pos_iff_ne_zero.mpr (ne_zero_of_irreducible_X_pow_sub_C H)
by_cases hn' : n = 1
· rw [hn', pow_one]; exact separable_X_sub_C
have ⟨ζ, hζ⟩ := hζ
rw [mem_primitiveRoots (Nat.pos_of_ne_zero <| ne_zero_of_irreducible_X_pow_sub_C H)] at hζ
rw [← separable_map (algebraMap K K[n√a]), Polynomial.map_sub, Polynomial.map_pow, map_C, map_X,
AdjoinRoot.algebraMap_eq,
X_pow_sub_C_eq_prod (hζ.map_of_injective (algebraMap K _).injective) hn
(root_X_pow_sub_C_pow n a), separable_prod_X_sub_C_iff']
#adaptation_note /-- https://github.com/leanprover/lean4/pull/5376
we need to provide this helper instance. -/
have : MonoidHomClass (K →+* K[n√a]) K K[n√a] := inferInstance
exact (hζ.map_of_injective (algebraMap K K[n√a]).injective).injOn_pow_mul
(root_X_pow_sub_C_ne_zero (lt_of_le_of_ne (show 1 ≤ n from hn) (Ne.symm hn')) _)
variable (n)
/-- The natural embedding of the roots of unity of `K` into `Gal(K[ⁿ√a]/K)`, by sending
`η ↦ (ⁿ√a ↦ η • ⁿ√a)`. Also see `autAdjoinRootXPowSubC` for the `AlgEquiv` version. -/
noncomputable
def autAdjoinRootXPowSubCHom :
rootsOfUnity n K →* (K[n√a] →ₐ[K] K[n√a]) where
toFun := fun η ↦ liftHom (X ^ n - C a) (((η : Kˣ) : K) • (root _) : K[n√a]) <| by
have := (mem_rootsOfUnity' _ _).mp η.prop
rw [map_sub, map_pow, aeval_C, aeval_X, Algebra.smul_def, mul_pow, root_X_pow_sub_C_pow,
AdjoinRoot.algebraMap_eq, ← map_pow, this, map_one, one_mul, sub_self]
map_one' := algHom_ext <| by simp
map_mul' := fun ε η ↦ algHom_ext <| by simp [mul_smul, smul_comm ((ε : Kˣ) : K)]
/-- The natural embedding of the roots of unity of `K` into `Gal(K[ⁿ√a]/K)`, by sending
`η ↦ (ⁿ√a ↦ η • ⁿ√a)`. This is an isomorphism when `K` contains a primitive root of unity.
See `autAdjoinRootXPowSubCEquiv`. -/
noncomputable
def autAdjoinRootXPowSubC :
rootsOfUnity n K →* (K[n√a] ≃ₐ[K] K[n√a]) :=
(AlgEquiv.algHomUnitsEquiv _ _).toMonoidHom.comp (autAdjoinRootXPowSubCHom n a).toHomUnits
variable {n}
lemma autAdjoinRootXPowSubC_root (η) :
autAdjoinRootXPowSubC n a η (root _) = ((η : Kˣ) : K) • root _ := by
dsimp [autAdjoinRootXPowSubC, autAdjoinRootXPowSubCHom, AlgEquiv.algHomUnitsEquiv]
apply liftHom_root
variable {a}
/-- The inverse function of `autAdjoinRootXPowSubC` if `K` has all roots of unity.
See `autAdjoinRootXPowSubCEquiv`. -/
noncomputable
def AdjoinRootXPowSubCEquivToRootsOfUnity [NeZero n] (σ : K[n√a] ≃ₐ[K] K[n√a]) :
rootsOfUnity n K :=
letI := Fact.mk H
letI : IsDomain K[n√a] := inferInstance
letI := Classical.decEq K
(rootsOfUnityEquivOfPrimitiveRoots (n := n) (algebraMap K K[n√a]).injective hζ).symm
(rootsOfUnity.mkOfPowEq (if a = 0 then 1 else σ (root _) / root _) (by
-- The if is needed in case `n = 1` and `a = 0` and `K[n√a] = K`.
split
· exact one_pow _
rw [div_pow, ← map_pow]
simp only [root_X_pow_sub_C_pow, ← AdjoinRoot.algebraMap_eq, AlgEquiv.commutes]
rw [div_self]
rwa [Ne, map_eq_zero_iff _ (algebraMap K _).injective]))
/-- The equivalence between the roots of unity of `K` and `Gal(K[ⁿ√a]/K)`. -/
noncomputable
def autAdjoinRootXPowSubCEquiv [NeZero n] :
rootsOfUnity n K ≃* (K[n√a] ≃ₐ[K] K[n√a]) where
__ := autAdjoinRootXPowSubC n a
invFun := AdjoinRootXPowSubCEquivToRootsOfUnity hζ H
left_inv := by
intro η
have := Fact.mk H
have : IsDomain K[n√a] := inferInstance
letI : Algebra K K[n√a] := inferInstance
apply (rootsOfUnityEquivOfPrimitiveRoots (algebraMap K K[n√a]).injective hζ).injective
ext
simp only [AdjoinRoot.algebraMap_eq, OneHom.toFun_eq_coe, MonoidHom.toOneHom_coe,
autAdjoinRootXPowSubC_root, Algebra.smul_def, ne_eq, MulEquiv.apply_symm_apply,
rootsOfUnity.val_mkOfPowEq_coe, val_rootsOfUnityEquivOfPrimitiveRoots_apply_coe,
AdjoinRootXPowSubCEquivToRootsOfUnity]
split_ifs with h
· obtain rfl := not_imp_not.mp (fun hn ↦ ne_zero_of_irreducible_X_pow_sub_C' hn H) h
have : (η : Kˣ) = 1 := (pow_one _).symm.trans η.prop
simp only [this, Units.val_one, map_one]
· exact mul_div_cancel_right₀ _ (root_X_pow_sub_C_ne_zero' (NeZero.pos n) h)
right_inv := by
intro e
have := Fact.mk H
letI : Algebra K K[n√a] := inferInstance
apply AlgEquiv.coe_algHom_injective
apply AdjoinRoot.algHom_ext
simp only [AdjoinRootXPowSubCEquivToRootsOfUnity, AdjoinRoot.algebraMap_eq, OneHom.toFun_eq_coe,
MonoidHom.toOneHom_coe, AlgHom.coe_coe, autAdjoinRootXPowSubC_root, Algebra.smul_def]
rw [rootsOfUnityEquivOfPrimitiveRoots_symm_apply, rootsOfUnity.val_mkOfPowEq_coe]
split_ifs with h
· obtain rfl := not_imp_not.mp (fun hn ↦ ne_zero_of_irreducible_X_pow_sub_C' hn H) h
rw [(pow_one _).symm.trans (root_X_pow_sub_C_pow 1 a), one_mul,
← AdjoinRoot.algebraMap_eq, AlgEquiv.commutes]
· refine div_mul_cancel₀ _ (root_X_pow_sub_C_ne_zero' (NeZero.pos n) h)
lemma autAdjoinRootXPowSubCEquiv_root [NeZero n] (η) :
autAdjoinRootXPowSubCEquiv hζ H η (root _) = ((η : Kˣ) : K) • root _ :=
autAdjoinRootXPowSubC_root a η
lemma autAdjoinRootXPowSubCEquiv_symm_smul [NeZero n] (σ) :
((autAdjoinRootXPowSubCEquiv hζ H).symm σ : Kˣ) • (root _ : K[n√a]) = σ (root _) := by
have := Fact.mk H
simp only [autAdjoinRootXPowSubCEquiv, OneHom.toFun_eq_coe, MonoidHom.toOneHom_coe,
MulEquiv.symm_mk, MulEquiv.coe_mk, Equiv.coe_fn_symm_mk, AdjoinRootXPowSubCEquivToRootsOfUnity,
AdjoinRoot.algebraMap_eq, rootsOfUnity.mkOfPowEq, Units.smul_def, Algebra.smul_def,
rootsOfUnityEquivOfPrimitiveRoots_symm_apply, Units.val_ofPowEqOne, ite_mul, one_mul]
simp_rw [← root_X_pow_sub_C_eq_zero_iff H]
split_ifs with h
· rw [h, map_zero]
· rw [div_mul_cancel₀ _ h]
end AdjoinRoot
/-! ### Galois Group of `IsSplittingField K L (X ^ n - C a)` -/
section IsSplittingField
variable {a}
variable {L : Type*} [Field L] [Algebra K L] [IsSplittingField K L (X ^ n - C a)]
include hζ in
lemma isSplittingField_AdjoinRoot_X_pow_sub_C :
haveI := Fact.mk H
letI : Algebra K K[n√a] := inferInstance
IsSplittingField K K[n√a] (X ^ n - C a) := by
have := Fact.mk H
letI : Algebra K K[n√a] := inferInstance
constructor
· rw [← splits_id_iff_splits, Polynomial.map_sub, Polynomial.map_pow, Polynomial.map_C,
Polynomial.map_X]
have ⟨_, hζ⟩ := hζ
rw [mem_primitiveRoots (Nat.pos_of_ne_zero <| ne_zero_of_irreducible_X_pow_sub_C H)] at hζ
exact X_pow_sub_C_splits_of_isPrimitiveRoot (hζ.map_of_injective (algebraMap K _).injective)
(root_X_pow_sub_C_pow n a)
· rw [eq_top_iff, ← AdjoinRoot.adjoinRoot_eq_top]
apply Algebra.adjoin_mono
have := ne_zero_of_irreducible_X_pow_sub_C H
rw [Set.singleton_subset_iff, mem_rootSet_of_ne (X_pow_sub_C_ne_zero
(Nat.pos_of_ne_zero this) a), aeval_def, AdjoinRoot.algebraMap_eq, AdjoinRoot.eval₂_root]
variable {α : L} (hα : α ^ n = algebraMap K L a)
/-- Suppose `L/K` is the splitting field of `Xⁿ - a`, then a choice of `ⁿ√a` gives an equivalence of
`L` with `K[n√a]`. -/
noncomputable
def adjoinRootXPowSubCEquiv (hζ : (primitiveRoots n K).Nonempty) (H : Irreducible (X ^ n - C a))
(hα : α ^ n = algebraMap K L a) : K[n√a] ≃ₐ[K] L :=
AlgEquiv.ofBijective (AdjoinRoot.liftHom (X ^ n - C a) α (by simp [hα])) <| by
haveI := Fact.mk H
letI := isSplittingField_AdjoinRoot_X_pow_sub_C hζ H
refine ⟨(liftHom (X ^ n - C a) α _).injective, ?_⟩
rw [← AlgHom.range_eq_top, ← IsSplittingField.adjoin_rootSet _ (X ^ n - C a),
eq_comm, adjoin_rootSet_eq_range, IsSplittingField.adjoin_rootSet]
exact IsSplittingField.splits _ _
lemma adjoinRootXPowSubCEquiv_root :
adjoinRootXPowSubCEquiv hζ H hα (root _) = α := by
rw [adjoinRootXPowSubCEquiv, AlgEquiv.coe_ofBijective, liftHom_root]
lemma adjoinRootXPowSubCEquiv_symm_eq_root :
(adjoinRootXPowSubCEquiv hζ H hα).symm α = root _ := by
apply (adjoinRootXPowSubCEquiv hζ H hα).injective
rw [(adjoinRootXPowSubCEquiv hζ H hα).apply_symm_apply, adjoinRootXPowSubCEquiv_root]
include hζ H hα in
lemma Algebra.adjoin_root_eq_top_of_isSplittingField :
Algebra.adjoin K {α} = ⊤ := by
apply Subalgebra.map_injective (B := K[n√a]) (f := (adjoinRootXPowSubCEquiv hζ H hα).symm)
(adjoinRootXPowSubCEquiv hζ H hα).symm.injective
rw [Algebra.map_top, (AlgHom.range_eq_top _).mpr
(adjoinRootXPowSubCEquiv hζ H hα).symm.surjective, AlgHom.map_adjoin,
Set.image_singleton, AlgHom.coe_coe, adjoinRootXPowSubCEquiv_symm_eq_root, adjoinRoot_eq_top]
include hζ H hα in
lemma IntermediateField.adjoin_root_eq_top_of_isSplittingField :
K⟮α⟯ = ⊤ := by
refine (IntermediateField.eq_adjoin_of_eq_algebra_adjoin _ _ _ ?_).symm
exact (Algebra.adjoin_root_eq_top_of_isSplittingField hζ H hα).symm
variable (a) (L)
/-- An arbitrary choice of `ⁿ√a` in the splitting field of `Xⁿ - a`. -/
noncomputable
abbrev rootOfSplitsXPowSubC (hn : 0 < n) (a : K)
(L) [Field L] [Algebra K L] [IsSplittingField K L (X ^ n - C a)] : L :=
(rootOfSplits _ (IsSplittingField.splits L (X ^ n - C a))
(by simpa [degree_X_pow_sub_C hn] using Nat.pos_iff_ne_zero.mp hn))
lemma rootOfSplitsXPowSubC_pow [NeZero n] :
(rootOfSplitsXPowSubC (NeZero.pos n) a L) ^ n = algebraMap K L a := by
have := map_rootOfSplits _ (IsSplittingField.splits L (X ^ n - C a))
simp only [eval₂_sub, eval₂_X_pow, eval₂_C, sub_eq_zero] at this
exact this _
variable {a}
/-- Suppose `L/K` is the splitting field of `Xⁿ - a`, then `Gal(L/K)` is isomorphic to the
roots of unity in `K` if `K` contains all of them.
Note that this does not depend on a choice of `ⁿ√a`. -/
noncomputable
def autEquivRootsOfUnity [NeZero n] :
(L ≃ₐ[K] L) ≃* (rootsOfUnity n K) :=
(AlgEquiv.autCongr (adjoinRootXPowSubCEquiv hζ H (rootOfSplitsXPowSubC_pow a L)).symm).trans
(autAdjoinRootXPowSubCEquiv hζ H).symm
lemma autEquivRootsOfUnity_apply_rootOfSplit [NeZero n] (σ : L ≃ₐ[K] L) :
σ (rootOfSplitsXPowSubC (NeZero.pos n) a L) =
autEquivRootsOfUnity hζ H L σ • (rootOfSplitsXPowSubC (NeZero.pos n) a L) := by
obtain ⟨η, rfl⟩ := (autEquivRootsOfUnity hζ H L).symm.surjective σ
rw [MulEquiv.apply_symm_apply, autEquivRootsOfUnity]
simp only [MulEquiv.symm_trans_apply, AlgEquiv.autCongr_symm, AlgEquiv.symm_symm,
MulEquiv.symm_symm, AlgEquiv.autCongr_apply, AlgEquiv.trans_apply,
adjoinRootXPowSubCEquiv_symm_eq_root, autAdjoinRootXPowSubCEquiv_root, map_smul,
adjoinRootXPowSubCEquiv_root]
rfl
include hα in
lemma autEquivRootsOfUnity_smul [NeZero n] (σ : L ≃ₐ[K] L) :
autEquivRootsOfUnity hζ H L σ • α = σ α := by
have ⟨ζ, hζ'⟩ := hζ
have hn := NeZero.pos n
rw [mem_primitiveRoots hn] at hζ'
rw [← mem_nthRoots hn, (hζ'.map_of_injective (algebraMap K L).injective).nthRoots_eq
(rootOfSplitsXPowSubC_pow a L)] at hα
simp only [Finset.range_val, Multiset.mem_map, Multiset.mem_range] at hα
obtain ⟨i, _, rfl⟩ := hα
simp only [map_mul, ← map_pow, ← Algebra.smul_def, map_smul,
autEquivRootsOfUnity_apply_rootOfSplit hζ H L]
exact smul_comm _ _ _
/-- Suppose `L/K` is the splitting field of `Xⁿ - a`, and `ζ` is a `n`-th primitive root of unity
in `K`, then `Gal(L/K)` is isomorphic to `ZMod n`. -/
noncomputable
def autEquivZmod [NeZero n] {ζ : K} (hζ : IsPrimitiveRoot ζ n) :
(L ≃ₐ[K] L) ≃* Multiplicative (ZMod n) :=
haveI hn := Nat.pos_iff_ne_zero.mpr (ne_zero_of_irreducible_X_pow_sub_C H)
(autEquivRootsOfUnity ⟨ζ, (mem_primitiveRoots hn).mpr hζ⟩ H L).trans
((MulEquiv.subgroupCongr (IsPrimitiveRoot.zpowers_eq
(hζ.isUnit_unit' hn)).symm).trans (AddEquiv.toMultiplicative'
(hζ.isUnit_unit' hn).zmodEquivZPowers.symm))
include hα in
lemma autEquivZmod_symm_apply_intCast [NeZero n] {ζ : K} (hζ : IsPrimitiveRoot ζ n) (m : ℤ) :
(autEquivZmod H L hζ).symm (Multiplicative.ofAdd (m : ZMod n)) α = ζ ^ m • α := by
have hn := Nat.pos_iff_ne_zero.mpr (ne_zero_of_irreducible_X_pow_sub_C H)
rw [← autEquivRootsOfUnity_smul ⟨ζ, (mem_primitiveRoots hn).mpr hζ⟩ H L hα]
simp [MulEquiv.subgroupCongr_symm_apply, Subgroup.smul_def, Units.smul_def, autEquivZmod]
include hα in
lemma autEquivZmod_symm_apply_natCast [NeZero n] {ζ : K} (hζ : IsPrimitiveRoot ζ n) (m : ℕ) :
(autEquivZmod H L hζ).symm (Multiplicative.ofAdd (m : ZMod n)) α = ζ ^ m • α := by
simpa only [Int.cast_natCast, zpow_natCast] using autEquivZmod_symm_apply_intCast H L hα hζ m
include hζ H in
lemma isCyclic_of_isSplittingField_X_pow_sub_C [NeZero n] : IsCyclic (L ≃ₐ[K] L) :=
have hn := Nat.pos_iff_ne_zero.mpr (ne_zero_of_irreducible_X_pow_sub_C H)
isCyclic_of_surjective _
(autEquivZmod H _ <| (mem_primitiveRoots hn).mp hζ.choose_spec).symm.surjective
|
include hζ H in
lemma isGalois_of_isSplittingField_X_pow_sub_C : IsGalois K L :=
IsGalois.of_separable_splitting_field (separable_X_pow_sub_C_of_irreducible hζ a H)
include hζ H in
lemma finrank_of_isSplittingField_X_pow_sub_C : Module.finrank K L = n := by
| Mathlib/FieldTheory/KummerExtension.lean | 434 | 440 |
/-
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.MvPolynomial.Expand
import Mathlib.FieldTheory.Finite.Basic
import Mathlib.LinearAlgebra.Dual.Lemmas
import Mathlib.LinearAlgebra.FiniteDimensional.Lemmas
import Mathlib.RingTheory.MvPolynomial.Basic
/-!
## Polynomials over finite fields
-/
namespace MvPolynomial
variable {σ : Type*}
/-- A polynomial over the integers is divisible by `n : ℕ`
if and only if it is zero over `ZMod n`. -/
theorem C_dvd_iff_zmod (n : ℕ) (φ : MvPolynomial σ ℤ) :
C (n : ℤ) ∣ φ ↔ map (Int.castRingHom (ZMod n)) φ = 0 :=
C_dvd_iff_map_hom_eq_zero _ _ (CharP.intCast_eq_zero_iff (ZMod n) n) _
section frobenius
variable {p : ℕ} [Fact p.Prime]
theorem frobenius_zmod (f : MvPolynomial σ (ZMod p)) : frobenius _ p f = expand p f := by
apply induction_on f
· intro a; rw [expand_C, frobenius_def, ← C_pow, ZMod.pow_card]
· simp only [map_add]; intro _ _ hf hg; rw [hf, hg]
· simp only [expand_X, map_mul]
intro _ _ hf; rw [hf, frobenius_def]
theorem expand_zmod (f : MvPolynomial σ (ZMod p)) : expand p f = f ^ p :=
(frobenius_zmod _).symm
end frobenius
end MvPolynomial
namespace MvPolynomial
noncomputable section
open Set LinearMap Submodule
variable {K : Type*} {σ : Type*}
section Indicator
variable [Fintype K] [Fintype σ]
/-- Over a field, this is the indicator function as an `MvPolynomial`. -/
def indicator [CommRing K] (a : σ → K) : MvPolynomial σ K :=
∏ n, (1 - (X n - C (a n)) ^ (Fintype.card K - 1))
section CommRing
variable [CommRing K]
theorem eval_indicator_apply_eq_one (a : σ → K) : eval a (indicator a) = 1 := by
nontriviality
have : 0 < Fintype.card K - 1 := tsub_pos_of_lt Fintype.one_lt_card
simp only [indicator, map_prod, map_sub, map_one, map_pow, eval_X, eval_C, sub_self,
zero_pow this.ne', sub_zero, Finset.prod_const_one]
theorem degrees_indicator (c : σ → K) :
degrees (indicator c) ≤ ∑ s : σ, (Fintype.card K - 1) • {s} := by
rw [indicator]
classical
refine degrees_prod_le.trans <| Finset.sum_le_sum fun s _ ↦ degrees_sub_le.trans ?_
rw [degrees_one, Multiset.zero_union]
refine le_trans degrees_pow_le (nsmul_le_nsmul_right ?_ _)
refine degrees_sub_le.trans ?_
rw [degrees_C, Multiset.union_zero]
exact degrees_X' _
theorem indicator_mem_restrictDegree (c : σ → K) :
indicator c ∈ restrictDegree σ K (Fintype.card K - 1) := by
classical
rw [mem_restrictDegree_iff_sup, indicator]
intro n
refine le_trans (Multiset.count_le_of_le _ <| degrees_indicator _) (le_of_eq ?_)
simp_rw [← Multiset.coe_countAddMonoidHom, map_sum,
AddMonoidHom.map_nsmul, Multiset.coe_countAddMonoidHom, nsmul_eq_mul, Nat.cast_id]
trans
· refine Finset.sum_eq_single n ?_ ?_
· intro b _ ne
simp [Multiset.count_singleton, ne, if_neg (Ne.symm _)]
· intro h; exact (h <| Finset.mem_univ _).elim
· rw [Multiset.count_singleton_self, mul_one]
end CommRing
variable [Field K]
theorem eval_indicator_apply_eq_zero (a b : σ → K) (h : a ≠ b) : eval a (indicator b) = 0 := by
obtain ⟨i, hi⟩ : ∃ i, a i ≠ b i := by rwa [Ne, funext_iff, not_forall] at h
simp only [indicator, map_prod, map_sub, map_one, map_pow, eval_X, eval_C, sub_self,
Finset.prod_eq_zero_iff]
refine ⟨i, Finset.mem_univ _, ?_⟩
rw [FiniteField.pow_card_sub_one_eq_one, sub_self]
rwa [Ne, sub_eq_zero]
end Indicator
section
variable (K σ)
/-- `MvPolynomial.eval` as a `K`-linear map. -/
@[simps]
def evalₗ [CommSemiring K] : MvPolynomial σ K →ₗ[K] (σ → K) → K where
toFun p e := eval e p
map_add' p q := by ext x; simp
map_smul' a p := by ext e; simp
variable [Field K] [Fintype K] [Finite σ]
theorem map_restrict_dom_evalₗ : (restrictDegree σ K (Fintype.card K - 1)).map (evalₗ K σ) = ⊤ := by
cases nonempty_fintype σ
refine top_unique (SetLike.le_def.2 fun e _ => mem_map.2 ?_)
classical
refine ⟨∑ n : σ → K, e n • indicator n, ?_, ?_⟩
· exact sum_mem fun c _ => smul_mem _ _ (indicator_mem_restrictDegree _)
· ext n
simp only [_root_.map_sum, @Finset.sum_apply (σ → K) (fun _ => K) _ _ _ _ _, Pi.smul_apply,
map_smul]
simp only [evalₗ_apply]
trans
· refine Finset.sum_eq_single n (fun b _ h => ?_) ?_
· rw [eval_indicator_apply_eq_zero _ _ h.symm, smul_zero]
· exact fun h => (h <| Finset.mem_univ n).elim
· rw [eval_indicator_apply_eq_one, smul_eq_mul, mul_one]
end
end
end MvPolynomial
namespace MvPolynomial
open scoped Cardinal
open LinearMap Submodule
universe u
variable (σ : Type u) (K : Type u) [Fintype K]
/-- The submodule of multivariate polynomials whose degree of each variable is strictly less
than the cardinality of K. -/
def R [CommRing K] : Type u :=
restrictDegree σ K (Fintype.card K - 1)
-- The `AddCommGroup, Module K, Inhabited` instances should be constructed by a deriving handler.
noncomputable instance [CommRing K] : AddCommGroup (R σ K) :=
inferInstanceAs (AddCommGroup (restrictDegree σ K (Fintype.card K - 1)))
noncomputable instance [CommRing K] : Module K (R σ K) :=
inferInstanceAs (Module K (restrictDegree σ K (Fintype.card K - 1)))
noncomputable instance [CommRing K] : Inhabited (R σ K) :=
inferInstanceAs (Inhabited (restrictDegree σ K (Fintype.card K - 1)))
/-- Evaluation in the `MvPolynomial.R` subtype. -/
def evalᵢ [CommRing K] : R σ K →ₗ[K] (σ → K) → K :=
(evalₗ K σ).comp (restrictDegree σ K (Fintype.card K - 1)).subtype
-- TODO: would be nice to replace this by suitable decidability assumptions
open Classical in
noncomputable instance decidableRestrictDegree (m : ℕ) :
DecidablePred (· ∈ { n : σ →₀ ℕ | ∀ i, n i ≤ m }) := by
simp only [Set.mem_setOf_eq]; infer_instance
variable [Field K]
open Classical in
theorem rank_R [Fintype σ] : Module.rank K (R σ K) = Fintype.card (σ → K) :=
calc
Module.rank K (R σ K) =
Module.rank K (↥{ s : σ →₀ ℕ | ∀ n : σ, s n ≤ Fintype.card K - 1 } →₀ K) :=
LinearEquiv.rank_eq
(Finsupp.supportedEquivFinsupp { s : σ →₀ ℕ | ∀ n : σ, s n ≤ Fintype.card K - 1 })
_ = #{ s : σ →₀ ℕ | ∀ n : σ, s n ≤ Fintype.card K - 1 } := by rw [rank_finsupp_self']
_ = #{ s : σ → ℕ | ∀ n : σ, s n < Fintype.card K } := by
refine Quotient.sound ⟨Equiv.subtypeEquiv Finsupp.equivFunOnFinite fun f => ?_⟩
refine forall_congr' fun n => le_tsub_iff_right ?_
exact Fintype.card_pos_iff.2 ⟨0⟩
_ = #(σ → { n // n < Fintype.card K }) :=
(@Equiv.subtypePiEquivPi σ (fun _ => ℕ) fun _ n => n < Fintype.card K).cardinal_eq
_ = #(σ → Fin (Fintype.card K)) :=
(Equiv.arrowCongr (Equiv.refl σ) Fin.equivSubtype.symm).cardinal_eq
_ = #(σ → K) := (Equiv.arrowCongr (Equiv.refl σ) (Fintype.equivFin K).symm).cardinal_eq
_ = Fintype.card (σ → K) := Cardinal.mk_fintype _
instance [Finite σ] : FiniteDimensional K (R σ K) := by
cases nonempty_fintype σ
classical
exact
IsNoetherian.iff_fg.1
(IsNoetherian.iff_rank_lt_aleph0.mpr <| by
simpa only [rank_R] using Cardinal.nat_lt_aleph0 (Fintype.card (σ → K)))
open Classical in
theorem finrank_R [Fintype σ] : Module.finrank K (R σ K) = Fintype.card (σ → K) :=
Module.finrank_eq_of_rank_eq (rank_R σ K)
theorem range_evalᵢ [Finite σ] : range (evalᵢ σ K) = ⊤ := by
rw [evalᵢ, LinearMap.range_comp, range_subtype]
exact map_restrict_dom_evalₗ K σ
theorem ker_evalₗ [Finite σ] : ker (evalᵢ σ K) = ⊥ := by
cases nonempty_fintype σ
refine (ker_eq_bot_iff_range_eq_top_of_finrank_eq_finrank ?_).mpr (range_evalᵢ σ K)
classical
rw [Module.finrank_fintype_fun_eq_card, finrank_R]
theorem eq_zero_of_eval_eq_zero [Finite σ] (p : MvPolynomial σ K) (h : ∀ v : σ → K, eval v p = 0)
(hp : p ∈ restrictDegree σ K (Fintype.card K - 1)) : p = 0 :=
let p' : R σ K := ⟨p, hp⟩
have : p' ∈ ker (evalᵢ σ K) := funext h
show p'.1 = (0 : R σ K).1 from congr_arg _ <| by rwa [ker_evalₗ, mem_bot] at this
end MvPolynomial
| Mathlib/FieldTheory/Finite/Polynomial.lean | 249 | 253 | |
/-
Copyright (c) 2022 Praneeth Kolichala. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Praneeth Kolichala
-/
import Mathlib.Data.Nat.Basic
import Mathlib.Data.Nat.BinaryRec
import Mathlib.Data.List.Defs
import Mathlib.Tactic.Convert
import Mathlib.Tactic.GeneralizeProofs
import Mathlib.Tactic.Says
/-!
# Additional properties of binary recursion on `Nat`
This file documents additional properties of binary recursion,
which allows us to more easily work with operations which do depend
on the number of leading zeros in the binary representation of `n`.
For example, we can more easily work with `Nat.bits` and `Nat.size`.
See also: `Nat.bitwise`, `Nat.pow` (for various lemmas about `size` and `shiftLeft`/`shiftRight`),
and `Nat.digits`.
-/
assert_not_exists Monoid
-- Once we're in the `Nat` namespace, `xor` will inconveniently resolve to `Nat.xor`.
/-- `bxor` denotes the `xor` function i.e. the exclusive-or function on type `Bool`. -/
local notation "bxor" => xor
namespace Nat
universe u
variable {m n : ℕ}
/-- `boddDiv2 n` returns a 2-tuple of type `(Bool, Nat)` where the `Bool` value indicates whether
`n` is odd or not and the `Nat` value returns `⌊n/2⌋` -/
def boddDiv2 : ℕ → Bool × ℕ
| 0 => (false, 0)
| succ n =>
match boddDiv2 n with
| (false, m) => (true, m)
| (true, m) => (false, succ m)
/-- `div2 n = ⌊n/2⌋` the greatest integer smaller than `n/2` -/
def div2 (n : ℕ) : ℕ := (boddDiv2 n).2
/-- `bodd n` returns `true` if `n` is odd -/
def bodd (n : ℕ) : Bool := (boddDiv2 n).1
@[simp] lemma bodd_zero : bodd 0 = false := rfl
@[simp] lemma bodd_one : bodd 1 = true := rfl
lemma bodd_two : bodd 2 = false := rfl
@[simp]
lemma bodd_succ (n : ℕ) : bodd (succ n) = not (bodd n) := by
simp only [bodd, boddDiv2]
let ⟨b,m⟩ := boddDiv2 n
cases b <;> rfl
@[simp]
lemma bodd_add (m n : ℕ) : bodd (m + n) = bxor (bodd m) (bodd n) := by
induction n
case zero => simp
case succ n ih => simp [← Nat.add_assoc, Bool.xor_not, ih]
@[simp]
lemma bodd_mul (m n : ℕ) : bodd (m * n) = (bodd m && bodd n) := by
induction n with
| zero => simp
| succ n IH =>
simp only [mul_succ, bodd_add, IH, bodd_succ]
cases bodd m <;> cases bodd n <;> rfl
lemma mod_two_of_bodd (n : ℕ) : n % 2 = (bodd n).toNat := by
have := congr_arg bodd (mod_add_div n 2)
simp? [not] at this says
simp only [bodd_add, bodd_mul, bodd_succ, not, bodd_zero, Bool.false_and, Bool.bne_false]
at this
have _ : ∀ b, and false b = false := by
intro b
cases b <;> rfl
have _ : ∀ b, bxor b false = b := by
intro b
cases b <;> rfl
rw [← this]
rcases mod_two_eq_zero_or_one n with h | h <;> rw [h] <;> rfl
@[simp] lemma div2_zero : div2 0 = 0 := rfl
@[simp] lemma div2_one : div2 1 = 0 := rfl
lemma div2_two : div2 2 = 1 := rfl
@[simp]
lemma div2_succ (n : ℕ) : div2 (n + 1) = cond (bodd n) (succ (div2 n)) (div2 n) := by
simp only [bodd, boddDiv2, div2]
rcases boddDiv2 n with ⟨_|_, _⟩ <;> simp
attribute [local simp] Nat.add_comm Nat.add_assoc Nat.add_left_comm Nat.mul_comm Nat.mul_assoc
lemma bodd_add_div2 : ∀ n, (bodd n).toNat + 2 * div2 n = n
| 0 => rfl
| succ n => by
simp only [bodd_succ, Bool.cond_not, div2_succ, Nat.mul_comm]
refine Eq.trans ?_ (congr_arg succ (bodd_add_div2 n))
cases bodd n
· simp
· simp; omega
lemma div2_val (n) : div2 n = n / 2 := by
refine Nat.eq_of_mul_eq_mul_left (by decide)
(Nat.add_left_cancel (Eq.trans ?_ (Nat.mod_add_div n 2).symm))
rw [mod_two_of_bodd, bodd_add_div2]
lemma bit_decomp (n : Nat) : bit (bodd n) (div2 n) = n :=
(bit_val _ _).trans <| (Nat.add_comm _ _).trans <| bodd_add_div2 _
lemma bit_zero : bit false 0 = 0 :=
rfl
/-- `shiftLeft' b m n` performs a left shift of `m` `n` times
and adds the bit `b` as the least significant bit each time.
Returns the corresponding natural number -/
def shiftLeft' (b : Bool) (m : ℕ) : ℕ → ℕ
| 0 => m
| n + 1 => bit b (shiftLeft' b m n)
@[simp]
lemma shiftLeft'_false : ∀ n, shiftLeft' false m n = m <<< n
| 0 => rfl
| n + 1 => by
have : 2 * (m * 2^n) = 2^(n+1)*m := by
rw [Nat.mul_comm, Nat.mul_assoc, ← Nat.pow_succ]; simp
simp [shiftLeft_eq, shiftLeft', bit_val, shiftLeft'_false, this]
/-- Lean takes the unprimed name for `Nat.shiftLeft_eq m n : m <<< n = m * 2 ^ n`. -/
@[simp] lemma shiftLeft_eq' (m n : Nat) : shiftLeft m n = m <<< n := rfl
@[simp] lemma shiftRight_eq (m n : Nat) : shiftRight m n = m >>> n := rfl
lemma binaryRec_decreasing (h : n ≠ 0) : div2 n < n := by
rw [div2_val]
apply (div_lt_iff_lt_mul <| succ_pos 1).2
have := Nat.mul_lt_mul_of_pos_left (lt_succ_self 1)
(lt_of_le_of_ne n.zero_le h.symm)
rwa [Nat.mul_one] at this
/-- `size n` : Returns the size of a natural number in
bits i.e. the length of its binary representation -/
def size : ℕ → ℕ :=
binaryRec 0 fun _ _ => succ
/-- `bits n` returns a list of Bools which correspond to the binary representation of n, where
the head of the list represents the least significant bit -/
def bits : ℕ → List Bool :=
binaryRec [] fun b _ IH => b :: IH
/-- `ldiff a b` performs bitwise set difference. For each corresponding
pair of bits taken as booleans, say `aᵢ` and `bᵢ`, it applies the
boolean operation `aᵢ ∧ ¬bᵢ` to obtain the `iᵗʰ` bit of the result. -/
def ldiff : ℕ → ℕ → ℕ :=
bitwise fun a b => a && not b
/-! bitwise ops -/
lemma bodd_bit (b n) : bodd (bit b n) = b := by
rw [bit_val]
simp only [Nat.mul_comm, Nat.add_comm, bodd_add, bodd_mul, bodd_succ, bodd_zero, Bool.not_false,
Bool.not_true, Bool.and_false, Bool.xor_false]
cases b <;> cases bodd n <;> rfl
lemma div2_bit (b n) : div2 (bit b n) = n := by
rw [bit_val, div2_val, Nat.add_comm, add_mul_div_left, div_eq_of_lt, Nat.zero_add]
<;> cases b
<;> decide
lemma shiftLeft'_add (b m n) : ∀ k, shiftLeft' b m (n + k) = shiftLeft' b (shiftLeft' b m n) k
| 0 => rfl
| k + 1 => congr_arg (bit b) (shiftLeft'_add b m n k)
lemma shiftLeft'_sub (b m) : ∀ {n k}, k ≤ n → shiftLeft' b m (n - k) = (shiftLeft' b m n) >>> k
| _, 0, _ => rfl
| n + 1, k + 1, h => by
rw [succ_sub_succ_eq_sub, shiftLeft', Nat.add_comm, shiftRight_add]
simp only [shiftLeft'_sub, Nat.le_of_succ_le_succ h, shiftRight_succ, shiftRight_zero]
simp [← div2_val, div2_bit]
lemma shiftLeft_sub : ∀ (m : Nat) {n k}, k ≤ n → m <<< (n - k) = (m <<< n) >>> k :=
fun _ _ _ hk => by simp only [← shiftLeft'_false, shiftLeft'_sub false _ hk]
lemma bodd_eq_one_and_ne_zero : ∀ n, bodd n = (1 &&& n != 0)
| 0 => rfl
| 1 => rfl
| n + 2 => by simpa using bodd_eq_one_and_ne_zero n
lemma testBit_bit_succ (m b n) : testBit (bit b n) (succ m) = testBit n m := by
have : bodd (((bit b n) >>> 1) >>> m) = bodd (n >>> m) := by
simp only [shiftRight_eq_div_pow]
simp [← div2_val, div2_bit]
rw [← shiftRight_add, Nat.add_comm] at this
simp only [bodd_eq_one_and_ne_zero] at this
exact this
/-! ### `boddDiv2_eq` and `bodd` -/
@[simp]
theorem boddDiv2_eq (n : ℕ) : boddDiv2 n = (bodd n, div2 n) := rfl
@[simp]
theorem div2_bit0 (n) : div2 (2 * n) = n :=
div2_bit false n
-- simp can prove this
theorem div2_bit1 (n) : div2 (2 * n + 1) = n :=
div2_bit true n
/-! ### `bit0` and `bit1` -/
theorem bit_add : ∀ (b : Bool) (n m : ℕ), bit b (n + m) = bit false n + bit b m
| true, _, _ => by dsimp [bit]; omega
| false, _, _ => by dsimp [bit]; omega
theorem bit_add' : ∀ (b : Bool) (n m : ℕ), bit b (n + m) = bit b n + bit false m
| true, _, _ => by dsimp [bit]; omega
| false, _, _ => by dsimp [bit]; omega
theorem bit_ne_zero (b) {n} (h : n ≠ 0) : bit b n ≠ 0 := by
cases b <;> dsimp [bit] <;> omega
@[simp]
theorem bitCasesOn_bit0 {motive : ℕ → Sort u} (H : ∀ b n, motive (bit b n)) (n : ℕ) :
bitCasesOn (2 * n) H = H false n :=
bitCasesOn_bit H false n
@[simp]
theorem bitCasesOn_bit1 {motive : ℕ → Sort u} (H : ∀ b n, motive (bit b n)) (n : ℕ) :
bitCasesOn (2 * n + 1) H = H true n :=
bitCasesOn_bit H true n
theorem bit_cases_on_injective {motive : ℕ → Sort u} :
Function.Injective fun H : ∀ b n, motive (bit b n) => fun n => bitCasesOn n H := by
intro H₁ H₂ h
ext b n
simpa only [bitCasesOn_bit] using congr_fun h (bit b n)
@[simp]
theorem bit_cases_on_inj {motive : ℕ → Sort u} (H₁ H₂ : ∀ b n, motive (bit b n)) :
((fun n => bitCasesOn n H₁) = fun n => bitCasesOn n H₂) ↔ H₁ = H₂ :=
bit_cases_on_injective.eq_iff
lemma bit_le : ∀ (b : Bool) {m n : ℕ}, m ≤ n → bit b m ≤ bit b n
| true, _, _, h => by dsimp [bit]; omega
| false, _, _, h => by dsimp [bit]; omega
lemma bit_lt_bit (a b) (h : m < n) : bit a m < bit b n := calc
bit a m < 2 * n := by cases a <;> dsimp [bit] <;> omega
_ ≤ bit b n := by cases b <;> dsimp [bit] <;> omega
@[simp]
theorem zero_bits : bits 0 = [] := by simp [Nat.bits]
@[simp]
theorem bits_append_bit (n : ℕ) (b : Bool) (hn : n = 0 → b = true) :
(bit b n).bits = b :: n.bits := by
rw [Nat.bits, Nat.bits, binaryRec_eq]
simpa
@[simp]
theorem bit0_bits (n : ℕ) (hn : n ≠ 0) : (2 * n).bits = false :: n.bits :=
bits_append_bit n false fun hn' => absurd hn' hn
@[simp]
theorem bit1_bits (n : ℕ) : (2 * n + 1).bits = true :: n.bits :=
bits_append_bit n true fun _ => rfl
@[simp]
theorem one_bits : Nat.bits 1 = [true] := by
convert bit1_bits 0
simp
-- TODO Find somewhere this can live.
-- example : bits 3423 = [true, true, true, true, true, false, true, false, true, false, true, true]
-- := by norm_num
theorem bodd_eq_bits_head (n : ℕ) : n.bodd = n.bits.headI := by
induction n using Nat.binaryRec' with
| z => simp
| f _ _ h _ => simp [bodd_bit, bits_append_bit _ _ h]
theorem div2_bits_eq_tail (n : ℕ) : n.div2.bits = n.bits.tail := by
induction n using Nat.binaryRec' with
| z => simp
| f _ _ h _ => simp [div2_bit, bits_append_bit _ _ h]
end Nat
| Mathlib/Data/Nat/Bits.lean | 410 | 412 | |
/-
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
| Mathlib/CategoryTheory/Idempotents/Karoubi.lean | 97 | 98 |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Abhimanyu Pallavi Sudhir, Jean Lo, Calle Sönne, Benjamin Davidson
-/
import Mathlib.Algebra.Field.NegOnePow
import Mathlib.Algebra.Field.Periodic
import Mathlib.Algebra.QuadraticDiscriminant
import Mathlib.Analysis.SpecialFunctions.Exp
/-!
# Trigonometric functions
## Main definitions
This file contains the definition of `π`.
See also `Analysis.SpecialFunctions.Trigonometric.Inverse` and
`Analysis.SpecialFunctions.Trigonometric.Arctan` for the inverse trigonometric functions.
See also `Analysis.SpecialFunctions.Complex.Arg` and
`Analysis.SpecialFunctions.Complex.Log` for the complex argument function
and the complex logarithm.
## Main statements
Many basic inequalities on the real trigonometric functions are established.
The continuity of the usual trigonometric functions is proved.
Several facts about the real trigonometric functions have the proofs deferred to
`Analysis.SpecialFunctions.Trigonometric.Complex`,
as they are most easily proved by appealing to the corresponding fact for
complex trigonometric functions.
See also `Analysis.SpecialFunctions.Trigonometric.Chebyshev` for the multiple angle formulas
in terms of Chebyshev polynomials.
## Tags
sin, cos, tan, angle
-/
noncomputable section
open Topology Filter Set
namespace Complex
@[continuity, fun_prop]
theorem continuous_sin : Continuous sin := by
change Continuous fun z => (exp (-z * I) - exp (z * I)) * I / 2
fun_prop
@[fun_prop]
theorem continuousOn_sin {s : Set ℂ} : ContinuousOn sin s :=
continuous_sin.continuousOn
@[continuity, fun_prop]
theorem continuous_cos : Continuous cos := by
change Continuous fun z => (exp (z * I) + exp (-z * I)) / 2
fun_prop
@[fun_prop]
theorem continuousOn_cos {s : Set ℂ} : ContinuousOn cos s :=
continuous_cos.continuousOn
@[continuity, fun_prop]
theorem continuous_sinh : Continuous sinh := by
change Continuous fun z => (exp z - exp (-z)) / 2
fun_prop
@[continuity, fun_prop]
theorem continuous_cosh : Continuous cosh := by
change Continuous fun z => (exp z + exp (-z)) / 2
fun_prop
end Complex
namespace Real
variable {x y z : ℝ}
@[continuity, fun_prop]
theorem continuous_sin : Continuous sin :=
Complex.continuous_re.comp (Complex.continuous_sin.comp Complex.continuous_ofReal)
@[fun_prop]
theorem continuousOn_sin {s} : ContinuousOn sin s :=
continuous_sin.continuousOn
@[continuity, fun_prop]
theorem continuous_cos : Continuous cos :=
Complex.continuous_re.comp (Complex.continuous_cos.comp Complex.continuous_ofReal)
@[fun_prop]
theorem continuousOn_cos {s} : ContinuousOn cos s :=
continuous_cos.continuousOn
@[continuity, fun_prop]
theorem continuous_sinh : Continuous sinh :=
Complex.continuous_re.comp (Complex.continuous_sinh.comp Complex.continuous_ofReal)
@[continuity, fun_prop]
theorem continuous_cosh : Continuous cosh :=
Complex.continuous_re.comp (Complex.continuous_cosh.comp Complex.continuous_ofReal)
end Real
namespace Real
theorem exists_cos_eq_zero : 0 ∈ cos '' Icc (1 : ℝ) 2 :=
intermediate_value_Icc' (by norm_num) continuousOn_cos
⟨le_of_lt cos_two_neg, le_of_lt cos_one_pos⟩
/-- The number π = 3.14159265... Defined here using choice as twice a zero of cos in [1,2], from
which one can derive all its properties. For explicit bounds on π, see `Data.Real.Pi.Bounds`.
Denoted `π`, once the `Real` namespace is opened. -/
protected noncomputable def pi : ℝ :=
2 * Classical.choose exists_cos_eq_zero
@[inherit_doc]
scoped notation "π" => Real.pi
@[simp]
theorem cos_pi_div_two : cos (π / 2) = 0 := by
rw [Real.pi, mul_div_cancel_left₀ _ (two_ne_zero' ℝ)]
exact (Classical.choose_spec exists_cos_eq_zero).2
theorem one_le_pi_div_two : (1 : ℝ) ≤ π / 2 := by
rw [Real.pi, mul_div_cancel_left₀ _ (two_ne_zero' ℝ)]
exact (Classical.choose_spec exists_cos_eq_zero).1.1
theorem pi_div_two_le_two : π / 2 ≤ 2 := by
rw [Real.pi, mul_div_cancel_left₀ _ (two_ne_zero' ℝ)]
exact (Classical.choose_spec exists_cos_eq_zero).1.2
theorem two_le_pi : (2 : ℝ) ≤ π :=
(div_le_div_iff_of_pos_right (show (0 : ℝ) < 2 by norm_num)).1
(by rw [div_self (two_ne_zero' ℝ)]; exact one_le_pi_div_two)
theorem pi_le_four : π ≤ 4 :=
(div_le_div_iff_of_pos_right (show (0 : ℝ) < 2 by norm_num)).1
(calc
π / 2 ≤ 2 := pi_div_two_le_two
_ = 4 / 2 := by norm_num)
@[bound]
theorem pi_pos : 0 < π :=
lt_of_lt_of_le (by norm_num) two_le_pi
@[bound]
theorem pi_nonneg : 0 ≤ π :=
pi_pos.le
theorem pi_ne_zero : π ≠ 0 :=
pi_pos.ne'
theorem pi_div_two_pos : 0 < π / 2 :=
half_pos pi_pos
theorem two_pi_pos : 0 < 2 * π := by linarith [pi_pos]
end Real
namespace Mathlib.Meta.Positivity
open Lean.Meta Qq
/-- Extension for the `positivity` tactic: `π` is always positive. -/
@[positivity Real.pi]
def evalRealPi : PositivityExt where eval {u α} _zα _pα e := do
match u, α, e with
| 0, ~q(ℝ), ~q(Real.pi) =>
assertInstancesCommute
pure (.positive q(Real.pi_pos))
| _, _, _ => throwError "not Real.pi"
end Mathlib.Meta.Positivity
namespace NNReal
open Real
open Real NNReal
/-- `π` considered as a nonnegative real. -/
noncomputable def pi : ℝ≥0 :=
⟨π, Real.pi_pos.le⟩
@[simp]
theorem coe_real_pi : (pi : ℝ) = π :=
rfl
theorem pi_pos : 0 < pi := mod_cast Real.pi_pos
theorem pi_ne_zero : pi ≠ 0 :=
pi_pos.ne'
end NNReal
namespace Real
@[simp]
theorem sin_pi : sin π = 0 := by
rw [← mul_div_cancel_left₀ π (two_ne_zero' ℝ), two_mul, add_div, sin_add, cos_pi_div_two]; simp
@[simp]
theorem cos_pi : cos π = -1 := by
rw [← mul_div_cancel_left₀ π (two_ne_zero' ℝ), mul_div_assoc, cos_two_mul, cos_pi_div_two]
norm_num
@[simp]
theorem sin_two_pi : sin (2 * π) = 0 := by simp [two_mul, sin_add]
@[simp]
theorem cos_two_pi : cos (2 * π) = 1 := by simp [two_mul, cos_add]
theorem sin_antiperiodic : Function.Antiperiodic sin π := by simp [sin_add]
theorem sin_periodic : Function.Periodic sin (2 * π) :=
sin_antiperiodic.periodic_two_mul
@[simp]
theorem sin_add_pi (x : ℝ) : sin (x + π) = -sin x :=
sin_antiperiodic x
@[simp]
theorem sin_add_two_pi (x : ℝ) : sin (x + 2 * π) = sin x :=
sin_periodic x
@[simp]
theorem sin_sub_pi (x : ℝ) : sin (x - π) = -sin x :=
sin_antiperiodic.sub_eq x
@[simp]
theorem sin_sub_two_pi (x : ℝ) : sin (x - 2 * π) = sin x :=
sin_periodic.sub_eq x
@[simp]
theorem sin_pi_sub (x : ℝ) : sin (π - x) = sin x :=
neg_neg (sin x) ▸ sin_neg x ▸ sin_antiperiodic.sub_eq'
@[simp]
theorem sin_two_pi_sub (x : ℝ) : sin (2 * π - x) = -sin x :=
sin_neg x ▸ sin_periodic.sub_eq'
@[simp]
theorem sin_nat_mul_pi (n : ℕ) : sin (n * π) = 0 :=
sin_antiperiodic.nat_mul_eq_of_eq_zero sin_zero n
@[simp]
theorem sin_int_mul_pi (n : ℤ) : sin (n * π) = 0 :=
sin_antiperiodic.int_mul_eq_of_eq_zero sin_zero n
@[simp]
theorem sin_add_nat_mul_two_pi (x : ℝ) (n : ℕ) : sin (x + n * (2 * π)) = sin x :=
sin_periodic.nat_mul n x
@[simp]
theorem sin_add_int_mul_two_pi (x : ℝ) (n : ℤ) : sin (x + n * (2 * π)) = sin x :=
sin_periodic.int_mul n x
@[simp]
theorem sin_sub_nat_mul_two_pi (x : ℝ) (n : ℕ) : sin (x - n * (2 * π)) = sin x :=
sin_periodic.sub_nat_mul_eq n
@[simp]
theorem sin_sub_int_mul_two_pi (x : ℝ) (n : ℤ) : sin (x - n * (2 * π)) = sin x :=
sin_periodic.sub_int_mul_eq n
@[simp]
theorem sin_nat_mul_two_pi_sub (x : ℝ) (n : ℕ) : sin (n * (2 * π) - x) = -sin x :=
sin_neg x ▸ sin_periodic.nat_mul_sub_eq n
@[simp]
theorem sin_int_mul_two_pi_sub (x : ℝ) (n : ℤ) : sin (n * (2 * π) - x) = -sin x :=
sin_neg x ▸ sin_periodic.int_mul_sub_eq n
theorem sin_add_int_mul_pi (x : ℝ) (n : ℤ) : sin (x + n * π) = (-1) ^ n * sin x :=
n.cast_negOnePow ℝ ▸ sin_antiperiodic.add_int_mul_eq n
theorem sin_add_nat_mul_pi (x : ℝ) (n : ℕ) : sin (x + n * π) = (-1) ^ n * sin x :=
sin_antiperiodic.add_nat_mul_eq n
theorem sin_sub_int_mul_pi (x : ℝ) (n : ℤ) : sin (x - n * π) = (-1) ^ n * sin x :=
n.cast_negOnePow ℝ ▸ sin_antiperiodic.sub_int_mul_eq n
theorem sin_sub_nat_mul_pi (x : ℝ) (n : ℕ) : sin (x - n * π) = (-1) ^ n * sin x :=
sin_antiperiodic.sub_nat_mul_eq n
theorem sin_int_mul_pi_sub (x : ℝ) (n : ℤ) : sin (n * π - x) = -((-1) ^ n * sin x) := by
simpa only [sin_neg, mul_neg, Int.cast_negOnePow] using sin_antiperiodic.int_mul_sub_eq n
theorem sin_nat_mul_pi_sub (x : ℝ) (n : ℕ) : sin (n * π - x) = -((-1) ^ n * sin x) := by
simpa only [sin_neg, mul_neg] using sin_antiperiodic.nat_mul_sub_eq n
theorem cos_antiperiodic : Function.Antiperiodic cos π := by simp [cos_add]
theorem cos_periodic : Function.Periodic cos (2 * π) :=
cos_antiperiodic.periodic_two_mul
@[simp]
theorem abs_cos_int_mul_pi (k : ℤ) : |cos (k * π)| = 1 := by
simp [abs_cos_eq_sqrt_one_sub_sin_sq]
@[simp]
theorem cos_add_pi (x : ℝ) : cos (x + π) = -cos x :=
cos_antiperiodic x
@[simp]
theorem cos_add_two_pi (x : ℝ) : cos (x + 2 * π) = cos x :=
cos_periodic x
@[simp]
theorem cos_sub_pi (x : ℝ) : cos (x - π) = -cos x :=
cos_antiperiodic.sub_eq x
@[simp]
theorem cos_sub_two_pi (x : ℝ) : cos (x - 2 * π) = cos x :=
cos_periodic.sub_eq x
@[simp]
theorem cos_pi_sub (x : ℝ) : cos (π - x) = -cos x :=
cos_neg x ▸ cos_antiperiodic.sub_eq'
@[simp]
theorem cos_two_pi_sub (x : ℝ) : cos (2 * π - x) = cos x :=
cos_neg x ▸ cos_periodic.sub_eq'
@[simp]
theorem cos_nat_mul_two_pi (n : ℕ) : cos (n * (2 * π)) = 1 :=
(cos_periodic.nat_mul_eq n).trans cos_zero
@[simp]
theorem cos_int_mul_two_pi (n : ℤ) : cos (n * (2 * π)) = 1 :=
(cos_periodic.int_mul_eq n).trans cos_zero
@[simp]
theorem cos_add_nat_mul_two_pi (x : ℝ) (n : ℕ) : cos (x + n * (2 * π)) = cos x :=
cos_periodic.nat_mul n x
@[simp]
theorem cos_add_int_mul_two_pi (x : ℝ) (n : ℤ) : cos (x + n * (2 * π)) = cos x :=
cos_periodic.int_mul n x
@[simp]
theorem cos_sub_nat_mul_two_pi (x : ℝ) (n : ℕ) : cos (x - n * (2 * π)) = cos x :=
cos_periodic.sub_nat_mul_eq n
@[simp]
theorem cos_sub_int_mul_two_pi (x : ℝ) (n : ℤ) : cos (x - n * (2 * π)) = cos x :=
cos_periodic.sub_int_mul_eq n
@[simp]
theorem cos_nat_mul_two_pi_sub (x : ℝ) (n : ℕ) : cos (n * (2 * π) - x) = cos x :=
cos_neg x ▸ cos_periodic.nat_mul_sub_eq n
@[simp]
theorem cos_int_mul_two_pi_sub (x : ℝ) (n : ℤ) : cos (n * (2 * π) - x) = cos x :=
cos_neg x ▸ cos_periodic.int_mul_sub_eq n
theorem cos_add_int_mul_pi (x : ℝ) (n : ℤ) : cos (x + n * π) = (-1) ^ n * cos x :=
n.cast_negOnePow ℝ ▸ cos_antiperiodic.add_int_mul_eq n
theorem cos_add_nat_mul_pi (x : ℝ) (n : ℕ) : cos (x + n * π) = (-1) ^ n * cos x :=
cos_antiperiodic.add_nat_mul_eq n
theorem cos_sub_int_mul_pi (x : ℝ) (n : ℤ) : cos (x - n * π) = (-1) ^ n * cos x :=
n.cast_negOnePow ℝ ▸ cos_antiperiodic.sub_int_mul_eq n
theorem cos_sub_nat_mul_pi (x : ℝ) (n : ℕ) : cos (x - n * π) = (-1) ^ n * cos x :=
cos_antiperiodic.sub_nat_mul_eq n
theorem cos_int_mul_pi_sub (x : ℝ) (n : ℤ) : cos (n * π - x) = (-1) ^ n * cos x :=
n.cast_negOnePow ℝ ▸ cos_neg x ▸ cos_antiperiodic.int_mul_sub_eq n
theorem cos_nat_mul_pi_sub (x : ℝ) (n : ℕ) : cos (n * π - x) = (-1) ^ n * cos x :=
cos_neg x ▸ cos_antiperiodic.nat_mul_sub_eq n
theorem cos_nat_mul_two_pi_add_pi (n : ℕ) : cos (n * (2 * π) + π) = -1 := by
simpa only [cos_zero] using (cos_periodic.nat_mul n).add_antiperiod_eq cos_antiperiodic
theorem cos_int_mul_two_pi_add_pi (n : ℤ) : cos (n * (2 * π) + π) = -1 := by
simpa only [cos_zero] using (cos_periodic.int_mul n).add_antiperiod_eq cos_antiperiodic
theorem cos_nat_mul_two_pi_sub_pi (n : ℕ) : cos (n * (2 * π) - π) = -1 := by
simpa only [cos_zero] using (cos_periodic.nat_mul n).sub_antiperiod_eq cos_antiperiodic
theorem cos_int_mul_two_pi_sub_pi (n : ℤ) : cos (n * (2 * π) - π) = -1 := by
simpa only [cos_zero] using (cos_periodic.int_mul n).sub_antiperiod_eq cos_antiperiodic
theorem sin_pos_of_pos_of_lt_pi {x : ℝ} (h0x : 0 < x) (hxp : x < π) : 0 < sin x :=
if hx2 : x ≤ 2 then sin_pos_of_pos_of_le_two h0x hx2
else
have : (2 : ℝ) + 2 = 4 := by norm_num
have : π - x ≤ 2 :=
sub_le_iff_le_add.2 (le_trans pi_le_four (this ▸ add_le_add_left (le_of_not_ge hx2) _))
sin_pi_sub x ▸ sin_pos_of_pos_of_le_two (sub_pos.2 hxp) this
theorem sin_pos_of_mem_Ioo {x : ℝ} (hx : x ∈ Ioo 0 π) : 0 < sin x :=
sin_pos_of_pos_of_lt_pi hx.1 hx.2
theorem sin_nonneg_of_mem_Icc {x : ℝ} (hx : x ∈ Icc 0 π) : 0 ≤ sin x := by
rw [← closure_Ioo pi_ne_zero.symm] at hx
exact
closure_lt_subset_le continuous_const continuous_sin
(closure_mono (fun y => sin_pos_of_mem_Ioo) hx)
theorem sin_nonneg_of_nonneg_of_le_pi {x : ℝ} (h0x : 0 ≤ x) (hxp : x ≤ π) : 0 ≤ sin x :=
sin_nonneg_of_mem_Icc ⟨h0x, hxp⟩
theorem sin_neg_of_neg_of_neg_pi_lt {x : ℝ} (hx0 : x < 0) (hpx : -π < x) : sin x < 0 :=
neg_pos.1 <| sin_neg x ▸ sin_pos_of_pos_of_lt_pi (neg_pos.2 hx0) (neg_lt.1 hpx)
theorem sin_nonpos_of_nonnpos_of_neg_pi_le {x : ℝ} (hx0 : x ≤ 0) (hpx : -π ≤ x) : sin x ≤ 0 :=
neg_nonneg.1 <| sin_neg x ▸ sin_nonneg_of_nonneg_of_le_pi (neg_nonneg.2 hx0) (neg_le.1 hpx)
@[simp]
theorem sin_pi_div_two : sin (π / 2) = 1 :=
have : sin (π / 2) = 1 ∨ sin (π / 2) = -1 := by
simpa [sq, mul_self_eq_one_iff] using sin_sq_add_cos_sq (π / 2)
this.resolve_right fun h =>
show ¬(0 : ℝ) < -1 by norm_num <|
h ▸ sin_pos_of_pos_of_lt_pi pi_div_two_pos (half_lt_self pi_pos)
theorem sin_add_pi_div_two (x : ℝ) : sin (x + π / 2) = cos x := by simp [sin_add]
theorem sin_sub_pi_div_two (x : ℝ) : sin (x - π / 2) = -cos x := by simp [sub_eq_add_neg, sin_add]
theorem sin_pi_div_two_sub (x : ℝ) : sin (π / 2 - x) = cos x := by simp [sub_eq_add_neg, sin_add]
theorem cos_add_pi_div_two (x : ℝ) : cos (x + π / 2) = -sin x := by simp [cos_add]
theorem cos_sub_pi_div_two (x : ℝ) : cos (x - π / 2) = sin x := by simp [sub_eq_add_neg, cos_add]
theorem cos_pi_div_two_sub (x : ℝ) : cos (π / 2 - x) = sin x := by
rw [← cos_neg, neg_sub, cos_sub_pi_div_two]
theorem cos_pos_of_mem_Ioo {x : ℝ} (hx : x ∈ Ioo (-(π / 2)) (π / 2)) : 0 < cos x :=
sin_add_pi_div_two x ▸ sin_pos_of_mem_Ioo ⟨by linarith [hx.1], by linarith [hx.2]⟩
theorem cos_nonneg_of_mem_Icc {x : ℝ} (hx : x ∈ Icc (-(π / 2)) (π / 2)) : 0 ≤ cos x :=
sin_add_pi_div_two x ▸ sin_nonneg_of_mem_Icc ⟨by linarith [hx.1], by linarith [hx.2]⟩
theorem cos_nonneg_of_neg_pi_div_two_le_of_le {x : ℝ} (hl : -(π / 2) ≤ x) (hu : x ≤ π / 2) :
0 ≤ cos x :=
cos_nonneg_of_mem_Icc ⟨hl, hu⟩
theorem cos_neg_of_pi_div_two_lt_of_lt {x : ℝ} (hx₁ : π / 2 < x) (hx₂ : x < π + π / 2) :
cos x < 0 :=
neg_pos.1 <| cos_pi_sub x ▸ cos_pos_of_mem_Ioo ⟨by linarith, by linarith⟩
theorem cos_nonpos_of_pi_div_two_le_of_le {x : ℝ} (hx₁ : π / 2 ≤ x) (hx₂ : x ≤ π + π / 2) :
cos x ≤ 0 :=
neg_nonneg.1 <| cos_pi_sub x ▸ cos_nonneg_of_mem_Icc ⟨by linarith, by linarith⟩
theorem sin_eq_sqrt_one_sub_cos_sq {x : ℝ} (hl : 0 ≤ x) (hu : x ≤ π) :
sin x = √(1 - cos x ^ 2) := by
rw [← abs_sin_eq_sqrt_one_sub_cos_sq, abs_of_nonneg (sin_nonneg_of_nonneg_of_le_pi hl hu)]
theorem cos_eq_sqrt_one_sub_sin_sq {x : ℝ} (hl : -(π / 2) ≤ x) (hu : x ≤ π / 2) :
cos x = √(1 - sin x ^ 2) := by
rw [← abs_cos_eq_sqrt_one_sub_sin_sq, abs_of_nonneg (cos_nonneg_of_mem_Icc ⟨hl, hu⟩)]
lemma cos_half {x : ℝ} (hl : -π ≤ x) (hr : x ≤ π) : cos (x / 2) = sqrt ((1 + cos x) / 2) := by
have : 0 ≤ cos (x / 2) := cos_nonneg_of_mem_Icc <| by constructor <;> linarith
rw [← sqrt_sq this, cos_sq, add_div, two_mul, add_halves]
lemma abs_sin_half (x : ℝ) : |sin (x / 2)| = sqrt ((1 - cos x) / 2) := by
rw [← sqrt_sq_eq_abs, sin_sq_eq_half_sub, two_mul, add_halves, sub_div]
lemma sin_half_eq_sqrt {x : ℝ} (hl : 0 ≤ x) (hr : x ≤ 2 * π) :
sin (x / 2) = sqrt ((1 - cos x) / 2) := by
rw [← abs_sin_half, abs_of_nonneg]
apply sin_nonneg_of_nonneg_of_le_pi <;> linarith
lemma sin_half_eq_neg_sqrt {x : ℝ} (hl : -(2 * π) ≤ x) (hr : x ≤ 0) :
sin (x / 2) = -sqrt ((1 - cos x) / 2) := by
rw [← abs_sin_half, abs_of_nonpos, neg_neg]
apply sin_nonpos_of_nonnpos_of_neg_pi_le <;> linarith
theorem sin_eq_zero_iff_of_lt_of_lt {x : ℝ} (hx₁ : -π < x) (hx₂ : x < π) : sin x = 0 ↔ x = 0 :=
⟨fun h => by
contrapose! h
cases h.lt_or_lt with
| inl h0 => exact (sin_neg_of_neg_of_neg_pi_lt h0 hx₁).ne
| inr h0 => exact (sin_pos_of_pos_of_lt_pi h0 hx₂).ne',
fun h => by simp [h]⟩
theorem sin_eq_zero_iff {x : ℝ} : sin x = 0 ↔ ∃ n : ℤ, (n : ℝ) * π = x :=
⟨fun h =>
⟨⌊x / π⌋,
le_antisymm (sub_nonneg.1 (Int.sub_floor_div_mul_nonneg _ pi_pos))
(sub_nonpos.1 <|
le_of_not_gt fun h₃ =>
(sin_pos_of_pos_of_lt_pi h₃ (Int.sub_floor_div_mul_lt _ pi_pos)).ne
(by simp [sub_eq_add_neg, sin_add, h, sin_int_mul_pi]))⟩,
fun ⟨_, hn⟩ => hn ▸ sin_int_mul_pi _⟩
theorem sin_ne_zero_iff {x : ℝ} : sin x ≠ 0 ↔ ∀ n : ℤ, (n : ℝ) * π ≠ x := by
rw [← not_exists, not_iff_not, sin_eq_zero_iff]
theorem sin_eq_zero_iff_cos_eq {x : ℝ} : sin x = 0 ↔ cos x = 1 ∨ cos x = -1 := by
rw [← mul_self_eq_one_iff, ← sin_sq_add_cos_sq x, sq, sq, ← sub_eq_iff_eq_add, sub_self]
exact ⟨fun h => by rw [h, mul_zero], eq_zero_of_mul_self_eq_zero ∘ Eq.symm⟩
theorem cos_eq_one_iff (x : ℝ) : cos x = 1 ↔ ∃ n : ℤ, (n : ℝ) * (2 * π) = x :=
⟨fun h =>
let ⟨n, hn⟩ := sin_eq_zero_iff.1 (sin_eq_zero_iff_cos_eq.2 (Or.inl h))
⟨n / 2,
(Int.emod_two_eq_zero_or_one n).elim
(fun hn0 => by
rwa [← mul_assoc, ← @Int.cast_two ℝ, ← Int.cast_mul,
Int.ediv_mul_cancel (Int.dvd_iff_emod_eq_zero.2 hn0)])
fun hn1 => by
rw [← Int.emod_add_ediv n 2, hn1, Int.cast_add, Int.cast_one, add_mul, one_mul, add_comm,
mul_comm (2 : ℤ), Int.cast_mul, mul_assoc, Int.cast_two] at hn
rw [← hn, cos_int_mul_two_pi_add_pi] at h
exact absurd h (by norm_num)⟩,
fun ⟨_, hn⟩ => hn ▸ cos_int_mul_two_pi _⟩
theorem cos_eq_one_iff_of_lt_of_lt {x : ℝ} (hx₁ : -(2 * π) < x) (hx₂ : x < 2 * π) :
cos x = 1 ↔ x = 0 :=
⟨fun h => by
rcases (cos_eq_one_iff _).1 h with ⟨n, rfl⟩
rw [mul_lt_iff_lt_one_left two_pi_pos] at hx₂
rw [neg_lt, neg_mul_eq_neg_mul, mul_lt_iff_lt_one_left two_pi_pos] at hx₁
norm_cast at hx₁ hx₂
obtain rfl : n = 0 := le_antisymm (by omega) (by omega)
simp, fun h => by simp [h]⟩
theorem sin_lt_sin_of_lt_of_le_pi_div_two {x y : ℝ} (hx₁ : -(π / 2) ≤ x) (hy₂ : y ≤ π / 2)
(hxy : x < y) : sin x < sin y := by
rw [← sub_pos, sin_sub_sin]
have : 0 < sin ((y - x) / 2) := by apply sin_pos_of_pos_of_lt_pi <;> linarith
have : 0 < cos ((y + x) / 2) := by refine cos_pos_of_mem_Ioo ⟨?_, ?_⟩ <;> linarith
positivity
theorem strictMonoOn_sin : StrictMonoOn sin (Icc (-(π / 2)) (π / 2)) := fun _ hx _ hy hxy =>
sin_lt_sin_of_lt_of_le_pi_div_two hx.1 hy.2 hxy
theorem cos_lt_cos_of_nonneg_of_le_pi {x y : ℝ} (hx₁ : 0 ≤ x) (hy₂ : y ≤ π) (hxy : x < y) :
cos y < cos x := by
rw [← sin_pi_div_two_sub, ← sin_pi_div_two_sub]
apply sin_lt_sin_of_lt_of_le_pi_div_two <;> linarith
theorem cos_lt_cos_of_nonneg_of_le_pi_div_two {x y : ℝ} (hx₁ : 0 ≤ x) (hy₂ : y ≤ π / 2)
(hxy : x < y) : cos y < cos x :=
cos_lt_cos_of_nonneg_of_le_pi hx₁ (hy₂.trans (by linarith)) hxy
theorem strictAntiOn_cos : StrictAntiOn cos (Icc 0 π) := fun _ hx _ hy hxy =>
cos_lt_cos_of_nonneg_of_le_pi hx.1 hy.2 hxy
theorem cos_le_cos_of_nonneg_of_le_pi {x y : ℝ} (hx₁ : 0 ≤ x) (hy₂ : y ≤ π) (hxy : x ≤ y) :
cos y ≤ cos x :=
(strictAntiOn_cos.le_iff_le ⟨hx₁.trans hxy, hy₂⟩ ⟨hx₁, hxy.trans hy₂⟩).2 hxy
theorem sin_le_sin_of_le_of_le_pi_div_two {x y : ℝ} (hx₁ : -(π / 2) ≤ x) (hy₂ : y ≤ π / 2)
(hxy : x ≤ y) : sin x ≤ sin y :=
(strictMonoOn_sin.le_iff_le ⟨hx₁, hxy.trans hy₂⟩ ⟨hx₁.trans hxy, hy₂⟩).2 hxy
theorem injOn_sin : InjOn sin (Icc (-(π / 2)) (π / 2)) :=
strictMonoOn_sin.injOn
theorem injOn_cos : InjOn cos (Icc 0 π) :=
strictAntiOn_cos.injOn
theorem surjOn_sin : SurjOn sin (Icc (-(π / 2)) (π / 2)) (Icc (-1) 1) := by
simpa only [sin_neg, sin_pi_div_two] using
intermediate_value_Icc (neg_le_self pi_div_two_pos.le) continuous_sin.continuousOn
theorem surjOn_cos : SurjOn cos (Icc 0 π) (Icc (-1) 1) := by
simpa only [cos_zero, cos_pi] using intermediate_value_Icc' pi_pos.le continuous_cos.continuousOn
theorem sin_mem_Icc (x : ℝ) : sin x ∈ Icc (-1 : ℝ) 1 :=
⟨neg_one_le_sin x, sin_le_one x⟩
theorem cos_mem_Icc (x : ℝ) : cos x ∈ Icc (-1 : ℝ) 1 :=
⟨neg_one_le_cos x, cos_le_one x⟩
theorem mapsTo_sin (s : Set ℝ) : MapsTo sin s (Icc (-1 : ℝ) 1) := fun x _ => sin_mem_Icc x
theorem mapsTo_cos (s : Set ℝ) : MapsTo cos s (Icc (-1 : ℝ) 1) := fun x _ => cos_mem_Icc x
theorem bijOn_sin : BijOn sin (Icc (-(π / 2)) (π / 2)) (Icc (-1) 1) :=
⟨mapsTo_sin _, injOn_sin, surjOn_sin⟩
theorem bijOn_cos : BijOn cos (Icc 0 π) (Icc (-1) 1) :=
⟨mapsTo_cos _, injOn_cos, surjOn_cos⟩
@[simp]
theorem range_cos : range cos = (Icc (-1) 1 : Set ℝ) :=
Subset.antisymm (range_subset_iff.2 cos_mem_Icc) surjOn_cos.subset_range
@[simp]
theorem range_sin : range sin = (Icc (-1) 1 : Set ℝ) :=
Subset.antisymm (range_subset_iff.2 sin_mem_Icc) surjOn_sin.subset_range
theorem range_cos_infinite : (range Real.cos).Infinite := by
rw [Real.range_cos]
exact Icc_infinite (by norm_num)
theorem range_sin_infinite : (range Real.sin).Infinite := by
rw [Real.range_sin]
exact Icc_infinite (by norm_num)
section CosDivSq
variable (x : ℝ)
/-- the series `sqrtTwoAddSeries x n` is `sqrt(2 + sqrt(2 + ... ))` with `n` square roots,
starting with `x`. We define it here because `cos (pi / 2 ^ (n+1)) = sqrtTwoAddSeries 0 n / 2`
-/
@[simp]
noncomputable def sqrtTwoAddSeries (x : ℝ) : ℕ → ℝ
| 0 => x
| n + 1 => √(2 + sqrtTwoAddSeries x n)
theorem sqrtTwoAddSeries_zero : sqrtTwoAddSeries x 0 = x := by simp
theorem sqrtTwoAddSeries_one : sqrtTwoAddSeries 0 1 = √2 := by simp
theorem sqrtTwoAddSeries_two : sqrtTwoAddSeries 0 2 = √(2 + √2) := by simp
theorem sqrtTwoAddSeries_zero_nonneg : ∀ n : ℕ, 0 ≤ sqrtTwoAddSeries 0 n
| 0 => le_refl 0
| _ + 1 => sqrt_nonneg _
theorem sqrtTwoAddSeries_nonneg {x : ℝ} (h : 0 ≤ x) : ∀ n : ℕ, 0 ≤ sqrtTwoAddSeries x n
| 0 => h
| _ + 1 => sqrt_nonneg _
theorem sqrtTwoAddSeries_lt_two : ∀ n : ℕ, sqrtTwoAddSeries 0 n < 2
| 0 => by norm_num
| n + 1 => by
refine lt_of_lt_of_le ?_ (sqrt_sq zero_lt_two.le).le
rw [sqrtTwoAddSeries, sqrt_lt_sqrt_iff, ← lt_sub_iff_add_lt']
· refine (sqrtTwoAddSeries_lt_two n).trans_le ?_
norm_num
· exact add_nonneg zero_le_two (sqrtTwoAddSeries_zero_nonneg n)
theorem sqrtTwoAddSeries_succ (x : ℝ) :
∀ n : ℕ, sqrtTwoAddSeries x (n + 1) = sqrtTwoAddSeries (√(2 + x)) n
| 0 => rfl
| n + 1 => by rw [sqrtTwoAddSeries, sqrtTwoAddSeries_succ _ _, sqrtTwoAddSeries]
theorem sqrtTwoAddSeries_monotone_left {x y : ℝ} (h : x ≤ y) :
∀ n : ℕ, sqrtTwoAddSeries x n ≤ sqrtTwoAddSeries y n
| 0 => h
| n + 1 => by
rw [sqrtTwoAddSeries, sqrtTwoAddSeries]
exact sqrt_le_sqrt (add_le_add_left (sqrtTwoAddSeries_monotone_left h _) _)
@[simp]
theorem cos_pi_over_two_pow : ∀ n : ℕ, cos (π / 2 ^ (n + 1)) = sqrtTwoAddSeries 0 n / 2
| 0 => by simp
| n + 1 => by
have A : (1 : ℝ) < 2 ^ (n + 1) := one_lt_pow₀ one_lt_two n.succ_ne_zero
have B : π / 2 ^ (n + 1) < π := div_lt_self pi_pos A
have C : 0 < π / 2 ^ (n + 1) := by positivity
rw [pow_succ, div_mul_eq_div_div, cos_half, cos_pi_over_two_pow n, sqrtTwoAddSeries,
add_div_eq_mul_add_div, one_mul, ← div_mul_eq_div_div, sqrt_div, sqrt_mul_self] <;>
linarith [sqrtTwoAddSeries_nonneg le_rfl n]
theorem sin_sq_pi_over_two_pow (n : ℕ) :
sin (π / 2 ^ (n + 1)) ^ 2 = 1 - (sqrtTwoAddSeries 0 n / 2) ^ 2 := by
rw [sin_sq, cos_pi_over_two_pow]
theorem sin_sq_pi_over_two_pow_succ (n : ℕ) :
sin (π / 2 ^ (n + 2)) ^ 2 = 1 / 2 - sqrtTwoAddSeries 0 n / 4 := by
rw [sin_sq_pi_over_two_pow, sqrtTwoAddSeries, div_pow, sq_sqrt, add_div, ← sub_sub]
· congr
· norm_num
· norm_num
· exact add_nonneg two_pos.le (sqrtTwoAddSeries_zero_nonneg _)
@[simp]
theorem sin_pi_over_two_pow_succ (n : ℕ) :
sin (π / 2 ^ (n + 2)) = √(2 - sqrtTwoAddSeries 0 n) / 2 := by
rw [eq_div_iff_mul_eq two_ne_zero, eq_comm, sqrt_eq_iff_eq_sq, mul_pow,
sin_sq_pi_over_two_pow_succ, sub_mul]
· congr <;> norm_num
· rw [sub_nonneg]
exact (sqrtTwoAddSeries_lt_two _).le
refine mul_nonneg (sin_nonneg_of_nonneg_of_le_pi ?_ ?_) zero_le_two
· positivity
· exact div_le_self pi_pos.le <| one_le_pow₀ one_le_two
@[simp]
theorem cos_pi_div_four : cos (π / 4) = √2 / 2 := by
trans cos (π / 2 ^ 2)
· congr
norm_num
· simp
@[simp]
theorem sin_pi_div_four : sin (π / 4) = √2 / 2 := by
trans sin (π / 2 ^ 2)
· congr
norm_num
· simp
@[simp]
theorem cos_pi_div_eight : cos (π / 8) = √(2 + √2) / 2 := by
trans cos (π / 2 ^ 3)
· congr
norm_num
· simp
@[simp]
theorem sin_pi_div_eight : sin (π / 8) = √(2 - √2) / 2 := by
trans sin (π / 2 ^ 3)
· congr
norm_num
· simp
@[simp]
theorem cos_pi_div_sixteen : cos (π / 16) = √(2 + √(2 + √2)) / 2 := by
trans cos (π / 2 ^ 4)
· congr
norm_num
· simp
@[simp]
theorem sin_pi_div_sixteen : sin (π / 16) = √(2 - √(2 + √2)) / 2 := by
trans sin (π / 2 ^ 4)
· congr
norm_num
· simp
@[simp]
theorem cos_pi_div_thirty_two : cos (π / 32) = √(2 + √(2 + √(2 + √2))) / 2 := by
trans cos (π / 2 ^ 5)
· congr
norm_num
· simp
@[simp]
theorem sin_pi_div_thirty_two : sin (π / 32) = √(2 - √(2 + √(2 + √2))) / 2 := by
trans sin (π / 2 ^ 5)
· congr
norm_num
· simp
-- This section is also a convenient location for other explicit values of `sin` and `cos`.
/-- The cosine of `π / 3` is `1 / 2`. -/
@[simp]
theorem cos_pi_div_three : cos (π / 3) = 1 / 2 := by
have h₁ : (2 * cos (π / 3) - 1) ^ 2 * (2 * cos (π / 3) + 2) = 0 := by
have : cos (3 * (π / 3)) = cos π := by
congr 1
ring
linarith [cos_pi, cos_three_mul (π / 3)]
rcases mul_eq_zero.mp h₁ with h | h
· linarith [pow_eq_zero h]
· have : cos π < cos (π / 3) := by
refine cos_lt_cos_of_nonneg_of_le_pi ?_ le_rfl ?_ <;> linarith [pi_pos]
linarith [cos_pi]
/-- The cosine of `π / 6` is `√3 / 2`. -/
@[simp]
theorem cos_pi_div_six : cos (π / 6) = √3 / 2 := by
rw [show (6 : ℝ) = 3 * 2 by norm_num, div_mul_eq_div_div, cos_half, cos_pi_div_three, one_add_div,
← div_mul_eq_div_div, two_add_one_eq_three, sqrt_div, sqrt_mul_self] <;> linarith [pi_pos]
/-- The square of the cosine of `π / 6` is `3 / 4` (this is sometimes more convenient than the
result for cosine itself). -/
theorem sq_cos_pi_div_six : cos (π / 6) ^ 2 = 3 / 4 := by
rw [cos_pi_div_six, div_pow, sq_sqrt] <;> norm_num
/-- The sine of `π / 6` is `1 / 2`. -/
@[simp]
theorem sin_pi_div_six : sin (π / 6) = 1 / 2 := by
rw [← cos_pi_div_two_sub, ← cos_pi_div_three]
congr
ring
/-- The square of the sine of `π / 3` is `3 / 4` (this is sometimes more convenient than the
result for cosine itself). -/
theorem sq_sin_pi_div_three : sin (π / 3) ^ 2 = 3 / 4 := by
rw [← cos_pi_div_two_sub, ← sq_cos_pi_div_six]
congr
ring
/-- The sine of `π / 3` is `√3 / 2`. -/
@[simp]
theorem sin_pi_div_three : sin (π / 3) = √3 / 2 := by
rw [← cos_pi_div_two_sub, ← cos_pi_div_six]
congr
ring
theorem quadratic_root_cos_pi_div_five :
letI c := cos (π / 5)
4 * c ^ 2 - 2 * c - 1 = 0 := by
set θ := π / 5 with hθ
set c := cos θ
set s := sin θ
suffices 2 * c = 4 * c ^ 2 - 1 by simp [this]
have hs : s ≠ 0 := by
rw [ne_eq, sin_eq_zero_iff, hθ]
push_neg
intro n hn
replace hn : n * 5 = 1 := by field_simp [mul_comm _ π, mul_assoc] at hn; norm_cast at hn
omega
suffices s * (2 * c) = s * (4 * c ^ 2 - 1) from mul_left_cancel₀ hs this
calc s * (2 * c) = 2 * s * c := by rw [← mul_assoc, mul_comm 2]
_ = sin (2 * θ) := by rw [sin_two_mul]
_ = sin (π - 2 * θ) := by rw [sin_pi_sub]
_ = sin (2 * θ + θ) := by congr; field_simp [hθ]; linarith
_ = sin (2 * θ) * c + cos (2 * θ) * s := sin_add (2 * θ) θ
_ = 2 * s * c * c + cos (2 * θ) * s := by rw [sin_two_mul]
_ = 2 * s * c * c + (2 * c ^ 2 - 1) * s := by rw [cos_two_mul]
_ = s * (2 * c * c) + s * (2 * c ^ 2 - 1) := by linarith
_ = s * (4 * c ^ 2 - 1) := by linarith
open Polynomial in
theorem Polynomial.isRoot_cos_pi_div_five :
(4 • X ^ 2 - 2 • X - C 1 : ℝ[X]).IsRoot (cos (π / 5)) := by
simpa using quadratic_root_cos_pi_div_five
/-- The cosine of `π / 5` is `(1 + √5) / 4`. -/
@[simp]
theorem cos_pi_div_five : cos (π / 5) = (1 + √5) / 4 := by
set c := cos (π / 5)
have : 4 * (c * c) + (-2) * c + (-1) = 0 := by
rw [← sq, neg_mul, ← sub_eq_add_neg, ← sub_eq_add_neg]
exact quadratic_root_cos_pi_div_five
have hd : discrim 4 (-2) (-1) = (2 * √5) * (2 * √5) := by norm_num [discrim, mul_mul_mul_comm]
rcases (quadratic_eq_zero_iff (by norm_num) hd c).mp this with h | h
· field_simp [h]; linarith
· absurd (show 0 ≤ c from cos_nonneg_of_mem_Icc <| by constructor <;> linarith [pi_pos.le])
rw [not_le, h]
exact div_neg_of_neg_of_pos (by norm_num [lt_sqrt]) (by positivity)
end CosDivSq
/-- `Real.sin` as an `OrderIso` between `[-(π / 2), π / 2]` and `[-1, 1]`. -/
def sinOrderIso : Icc (-(π / 2)) (π / 2) ≃o Icc (-1 : ℝ) 1 :=
(strictMonoOn_sin.orderIso _ _).trans <| OrderIso.setCongr _ _ bijOn_sin.image_eq
@[simp]
theorem coe_sinOrderIso_apply (x : Icc (-(π / 2)) (π / 2)) : (sinOrderIso x : ℝ) = sin x :=
rfl
theorem sinOrderIso_apply (x : Icc (-(π / 2)) (π / 2)) : sinOrderIso x = ⟨sin x, sin_mem_Icc x⟩ :=
rfl
@[simp]
theorem tan_pi_div_four : tan (π / 4) = 1 := by
rw [tan_eq_sin_div_cos, cos_pi_div_four, sin_pi_div_four]
have h : √2 / 2 > 0 := by positivity
exact div_self (ne_of_gt h)
@[simp]
theorem tan_pi_div_two : tan (π / 2) = 0 := by simp [tan_eq_sin_div_cos]
@[simp]
theorem tan_pi_div_six : tan (π / 6) = 1 / sqrt 3 := by
rw [tan_eq_sin_div_cos, sin_pi_div_six, cos_pi_div_six]
ring
@[simp]
theorem tan_pi_div_three : tan (π / 3) = sqrt 3 := by
rw [tan_eq_sin_div_cos, sin_pi_div_three, cos_pi_div_three]
ring
theorem tan_pos_of_pos_of_lt_pi_div_two {x : ℝ} (h0x : 0 < x) (hxp : x < π / 2) : 0 < tan x := by
rw [tan_eq_sin_div_cos]
exact div_pos (sin_pos_of_pos_of_lt_pi h0x (by linarith)) (cos_pos_of_mem_Ioo ⟨by linarith, hxp⟩)
theorem tan_nonneg_of_nonneg_of_le_pi_div_two {x : ℝ} (h0x : 0 ≤ x) (hxp : x ≤ π / 2) : 0 ≤ tan x :=
match lt_or_eq_of_le h0x, lt_or_eq_of_le hxp with
| Or.inl hx0, Or.inl hxp => le_of_lt (tan_pos_of_pos_of_lt_pi_div_two hx0 hxp)
| Or.inl _, Or.inr hxp => by simp [hxp, tan_eq_sin_div_cos]
| Or.inr hx0, _ => by simp [hx0.symm]
theorem tan_neg_of_neg_of_pi_div_two_lt {x : ℝ} (hx0 : x < 0) (hpx : -(π / 2) < x) : tan x < 0 :=
neg_pos.1 (tan_neg x ▸ tan_pos_of_pos_of_lt_pi_div_two (by linarith) (by linarith [pi_pos]))
theorem tan_nonpos_of_nonpos_of_neg_pi_div_two_le {x : ℝ} (hx0 : x ≤ 0) (hpx : -(π / 2) ≤ x) :
tan x ≤ 0 :=
neg_nonneg.1 (tan_neg x ▸ tan_nonneg_of_nonneg_of_le_pi_div_two (by linarith) (by linarith))
theorem strictMonoOn_tan : StrictMonoOn tan (Ioo (-(π / 2)) (π / 2)) := by
rintro x hx y hy hlt
rw [tan_eq_sin_div_cos, tan_eq_sin_div_cos,
div_lt_div_iff₀ (cos_pos_of_mem_Ioo hx) (cos_pos_of_mem_Ioo hy), mul_comm, ← sub_pos, ← sin_sub]
exact sin_pos_of_pos_of_lt_pi (sub_pos.2 hlt) <| by linarith [hx.1, hy.2]
theorem tan_lt_tan_of_lt_of_lt_pi_div_two {x y : ℝ} (hx₁ : -(π / 2) < x) (hy₂ : y < π / 2)
(hxy : x < y) : tan x < tan y :=
strictMonoOn_tan ⟨hx₁, hxy.trans hy₂⟩ ⟨hx₁.trans hxy, hy₂⟩ hxy
theorem tan_lt_tan_of_nonneg_of_lt_pi_div_two {x y : ℝ} (hx₁ : 0 ≤ x) (hy₂ : y < π / 2)
(hxy : x < y) : tan x < tan y :=
tan_lt_tan_of_lt_of_lt_pi_div_two (by linarith) hy₂ hxy
theorem injOn_tan : InjOn tan (Ioo (-(π / 2)) (π / 2)) :=
strictMonoOn_tan.injOn
theorem tan_inj_of_lt_of_lt_pi_div_two {x y : ℝ} (hx₁ : -(π / 2) < x) (hx₂ : x < π / 2)
(hy₁ : -(π / 2) < y) (hy₂ : y < π / 2) (hxy : tan x = tan y) : x = y :=
injOn_tan ⟨hx₁, hx₂⟩ ⟨hy₁, hy₂⟩ hxy
theorem tan_periodic : Function.Periodic tan π := by
simpa only [Function.Periodic, tan_eq_sin_div_cos] using sin_antiperiodic.div cos_antiperiodic
@[simp]
theorem tan_pi : tan π = 0 := by rw [tan_periodic.eq, tan_zero]
theorem tan_add_pi (x : ℝ) : tan (x + π) = tan x :=
tan_periodic x
theorem tan_sub_pi (x : ℝ) : tan (x - π) = tan x :=
tan_periodic.sub_eq x
theorem tan_pi_sub (x : ℝ) : tan (π - x) = -tan x :=
tan_neg x ▸ tan_periodic.sub_eq'
theorem tan_pi_div_two_sub (x : ℝ) : tan (π / 2 - x) = (tan x)⁻¹ := by
rw [tan_eq_sin_div_cos, tan_eq_sin_div_cos, inv_div, sin_pi_div_two_sub, cos_pi_div_two_sub]
theorem tan_nat_mul_pi (n : ℕ) : tan (n * π) = 0 :=
tan_zero ▸ tan_periodic.nat_mul_eq n
theorem tan_int_mul_pi (n : ℤ) : tan (n * π) = 0 :=
tan_zero ▸ tan_periodic.int_mul_eq n
theorem tan_add_nat_mul_pi (x : ℝ) (n : ℕ) : tan (x + n * π) = tan x :=
tan_periodic.nat_mul n x
theorem tan_add_int_mul_pi (x : ℝ) (n : ℤ) : tan (x + n * π) = tan x :=
tan_periodic.int_mul n x
theorem tan_sub_nat_mul_pi (x : ℝ) (n : ℕ) : tan (x - n * π) = tan x :=
tan_periodic.sub_nat_mul_eq n
theorem tan_sub_int_mul_pi (x : ℝ) (n : ℤ) : tan (x - n * π) = tan x :=
tan_periodic.sub_int_mul_eq n
theorem tan_nat_mul_pi_sub (x : ℝ) (n : ℕ) : tan (n * π - x) = -tan x :=
tan_neg x ▸ tan_periodic.nat_mul_sub_eq n
theorem tan_int_mul_pi_sub (x : ℝ) (n : ℤ) : tan (n * π - x) = -tan x :=
tan_neg x ▸ tan_periodic.int_mul_sub_eq n
theorem tendsto_sin_pi_div_two : Tendsto sin (𝓝[<] (π / 2)) (𝓝 1) := by
convert continuous_sin.continuousWithinAt.tendsto
simp
theorem tendsto_cos_pi_div_two : Tendsto cos (𝓝[<] (π / 2)) (𝓝[>] 0) := by
apply tendsto_nhdsWithin_of_tendsto_nhds_of_eventually_within
· convert continuous_cos.continuousWithinAt.tendsto
simp
· filter_upwards [Ioo_mem_nhdsLT (neg_lt_self pi_div_two_pos)] with x hx
exact cos_pos_of_mem_Ioo hx
theorem tendsto_tan_pi_div_two : Tendsto tan (𝓝[<] (π / 2)) atTop := by
convert tendsto_cos_pi_div_two.inv_tendsto_nhdsGT_zero.atTop_mul_pos zero_lt_one
tendsto_sin_pi_div_two using 1
simp only [Pi.inv_apply, ← div_eq_inv_mul, ← tan_eq_sin_div_cos]
theorem tendsto_sin_neg_pi_div_two : Tendsto sin (𝓝[>] (-(π / 2))) (𝓝 (-1)) := by
convert continuous_sin.continuousWithinAt.tendsto using 2
simp
theorem tendsto_cos_neg_pi_div_two : Tendsto cos (𝓝[>] (-(π / 2))) (𝓝[>] 0) := by
apply tendsto_nhdsWithin_of_tendsto_nhds_of_eventually_within
· convert continuous_cos.continuousWithinAt.tendsto
simp
· filter_upwards [Ioo_mem_nhdsGT (neg_lt_self pi_div_two_pos)] with x hx
exact cos_pos_of_mem_Ioo hx
theorem tendsto_tan_neg_pi_div_two : Tendsto tan (𝓝[>] (-(π / 2))) atBot := by
convert tendsto_cos_neg_pi_div_two.inv_tendsto_nhdsGT_zero.atTop_mul_neg (by norm_num)
tendsto_sin_neg_pi_div_two using 1
simp only [Pi.inv_apply, ← div_eq_inv_mul, ← tan_eq_sin_div_cos]
end Real
namespace Complex
|
open Real
| Mathlib/Analysis/SpecialFunctions/Trigonometric/Basic.lean | 984 | 985 |
/-
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.Tape
import Mathlib.Data.Fintype.Option
import Mathlib.Data.Fintype.Prod
import Mathlib.Data.Fintype.Pi
import Mathlib.Data.PFun
import Mathlib.Computability.PostTuringMachine
/-!
# Turing machines
The files `PostTuringMachine.lean` and `TuringMachine.lean` define
a sequence of simple machine languages, starting with Turing machines and working
up to more complex languages based on Wang B-machines.
`PostTuringMachine.lean` covers the TM0 model and TM1 model;
`TuringMachine.lean` adds the TM2 model.
## Naming conventions
Each model of computation in this file shares a naming convention for the elements of a model of
computation. These are the parameters for the language:
* `Γ` is the alphabet on the tape.
* `Λ` is the set of labels, or internal machine states.
* `σ` is the type of internal memory, not on the tape. This does not exist in the TM0 model, and
later models achieve this by mixing it into `Λ`.
* `K` is used in the TM2 model, which has multiple stacks, and denotes the number of such stacks.
All of these variables denote "essentially finite" types, but for technical reasons it is
convenient to allow them to be infinite anyway. When using an infinite type, we will be interested
to prove that only finitely many values of the type are ever interacted with.
Given these parameters, there are a few common structures for the model that arise:
* `Stmt` is the set of all actions that can be performed in one step. For the TM0 model this set is
finite, and for later models it is an infinite inductive type representing "possible program
texts".
* `Cfg` is the set of instantaneous configurations, that is, the state of the machine together with
its environment.
* `Machine` is the set of all machines in the model. Usually this is approximately a function
`Λ → Stmt`, although different models have different ways of halting and other actions.
* `step : Cfg → Option Cfg` is the function that describes how the state evolves over one step.
If `step c = none`, then `c` is a terminal state, and the result of the computation is read off
from `c`. Because of the type of `step`, these models are all deterministic by construction.
* `init : Input → Cfg` sets up the initial state. The type `Input` depends on the model;
in most cases it is `List Γ`.
* `eval : Machine → Input → Part Output`, given a machine `M` and input `i`, starts from
`init i`, runs `step` until it reaches an output, and then applies a function `Cfg → Output` to
the final state to obtain the result. The type `Output` depends on the model.
* `Supports : Machine → Finset Λ → Prop` asserts that a machine `M` starts in `S : Finset Λ`, and
can only ever jump to other states inside `S`. This implies that the behavior of `M` on any input
cannot depend on its values outside `S`. We use this to allow `Λ` to be an infinite set when
convenient, and prove that only finitely many of these states are actually accessible. This
formalizes "essentially finite" mentioned above.
-/
assert_not_exists MonoidWithZero
open List (Vector)
open Relation
open Nat (iterate)
open Function (update iterate_succ iterate_succ_apply iterate_succ' iterate_succ_apply'
iterate_zero_apply)
namespace Turing
/-!
## The TM2 model
The TM2 model removes the tape entirely from the TM1 model, replacing it with an arbitrary (finite)
collection of stacks, each with elements of different types (the alphabet of stack `k : K` is
`Γ k`). The statements are:
* `push k (f : σ → Γ k) q` puts `f a` on the `k`-th stack, then does `q`.
* `pop k (f : σ → Option (Γ k) → σ) q` changes the state to `f a (S k).head`, where `S k` is the
value of the `k`-th stack, and removes this element from the stack, then does `q`.
* `peek k (f : σ → Option (Γ k) → σ) q` changes the state to `f a (S k).head`, where `S k` is the
value of the `k`-th stack, then does `q`.
* `load (f : σ → σ) q` reads nothing but applies `f` to the internal state, then does `q`.
* `branch (f : σ → Bool) qtrue qfalse` does `qtrue` or `qfalse` according to `f a`.
* `goto (f : σ → Λ)` jumps to label `f a`.
* `halt` halts on the next step.
The configuration is a tuple `(l, var, stk)` where `l : Option Λ` is the current label to run or
`none` for the halting state, `var : σ` is the (finite) internal state, and `stk : ∀ k, List (Γ k)`
is the collection of stacks. (Note that unlike the `TM0` and `TM1` models, these are not
`ListBlank`s, they have definite ends that can be detected by the `pop` command.)
Given a designated stack `k` and a value `L : List (Γ k)`, the initial configuration has all the
stacks empty except the designated "input" stack; in `eval` this designated stack also functions
as the output stack.
-/
namespace TM2
variable {K : Type*}
-- Index type of stacks
variable (Γ : K → Type*)
-- Type of stack elements
variable (Λ : Type*)
-- Type of function labels
variable (σ : Type*)
-- Type of variable settings
/-- The TM2 model removes the tape entirely from the TM1 model,
replacing it with an arbitrary (finite) collection of stacks.
The operation `push` puts an element on one of the stacks,
and `pop` removes an element from a stack (and modifying the
internal state based on the result). `peek` modifies the
internal state but does not remove an element. -/
inductive Stmt
| push : ∀ k, (σ → Γ k) → Stmt → Stmt
| peek : ∀ k, (σ → Option (Γ k) → σ) → Stmt → Stmt
| pop : ∀ k, (σ → Option (Γ k) → σ) → Stmt → Stmt
| load : (σ → σ) → Stmt → Stmt
| branch : (σ → Bool) → Stmt → Stmt → Stmt
| goto : (σ → Λ) → Stmt
| halt : Stmt
open Stmt
instance Stmt.inhabited : Inhabited (Stmt Γ Λ σ) :=
⟨halt⟩
/-- A configuration in the TM2 model is a label (or `none` for the halt state), the state of
local variables, and the stacks. (Note that the stacks are not `ListBlank`s, they have a definite
size.) -/
structure Cfg where
/-- The current label to run (or `none` for the halting state) -/
l : Option Λ
/-- The internal state -/
var : σ
/-- The (finite) collection of internal stacks -/
stk : ∀ k, List (Γ k)
instance Cfg.inhabited [Inhabited σ] : Inhabited (Cfg Γ Λ σ) :=
⟨⟨default, default, default⟩⟩
variable {Γ Λ σ}
section
variable [DecidableEq K]
/-- The step function for the TM2 model. -/
def stepAux : Stmt Γ Λ σ → σ → (∀ k, List (Γ k)) → Cfg Γ Λ σ
| push k f q, v, S => stepAux q v (update S k (f v :: S k))
| peek k f q, v, S => stepAux q (f v (S k).head?) S
| pop k f q, v, S => stepAux q (f v (S k).head?) (update S k (S k).tail)
| load a q, v, S => stepAux q (a v) S
| branch f q₁ q₂, v, S => cond (f v) (stepAux q₁ v S) (stepAux q₂ v S)
| goto f, v, S => ⟨some (f v), v, S⟩
| halt, v, S => ⟨none, v, S⟩
/-- The step function for the TM2 model. -/
def step (M : Λ → Stmt Γ Λ σ) : Cfg Γ Λ σ → Option (Cfg Γ Λ σ)
| ⟨none, _, _⟩ => none
| ⟨some l, v, S⟩ => some (stepAux (M l) v S)
attribute [simp] stepAux.eq_1 stepAux.eq_2 stepAux.eq_3
stepAux.eq_4 stepAux.eq_5 stepAux.eq_6 stepAux.eq_7 step.eq_1 step.eq_2
/-- The (reflexive) reachability relation for the TM2 model. -/
def Reaches (M : Λ → Stmt Γ Λ σ) : Cfg Γ Λ σ → Cfg Γ Λ σ → Prop :=
ReflTransGen fun a b ↦ b ∈ step M a
end
/-- Given a set `S` of states, `SupportsStmt S q` means that `q` only jumps to states in `S`. -/
def SupportsStmt (S : Finset Λ) : Stmt Γ Λ σ → Prop
| push _ _ q => SupportsStmt S q
| peek _ _ q => SupportsStmt S q
| pop _ _ q => SupportsStmt S q
| load _ q => SupportsStmt S q
| branch _ q₁ q₂ => SupportsStmt S q₁ ∧ SupportsStmt S q₂
| goto l => ∀ v, l v ∈ S
| halt => True
section
open scoped Classical in
/-- The set of subtree statements in a statement. -/
noncomputable def stmts₁ : Stmt Γ Λ σ → Finset (Stmt Γ Λ σ)
| Q@(push _ _ q) => insert Q (stmts₁ q)
| Q@(peek _ _ q) => insert Q (stmts₁ q)
| Q@(pop _ _ q) => insert Q (stmts₁ q)
| Q@(load _ q) => insert Q (stmts₁ q)
| Q@(branch _ q₁ q₂) => insert Q (stmts₁ q₁ ∪ stmts₁ q₂)
| Q@(goto _) => {Q}
| Q@halt => {Q}
theorem stmts₁_self {q : Stmt Γ Λ σ} : q ∈ stmts₁ q := by
cases q <;> simp only [Finset.mem_insert_self, Finset.mem_singleton_self, stmts₁]
theorem stmts₁_trans {q₁ q₂ : Stmt Γ Λ σ} : q₁ ∈ stmts₁ q₂ → stmts₁ q₁ ⊆ stmts₁ q₂ := by
classical
intro h₁₂ q₀ h₀₁
induction q₂ with (
simp only [stmts₁] at h₁₂ ⊢
simp only [Finset.mem_insert, Finset.mem_singleton, Finset.mem_union] at h₁₂)
| branch f q₁ q₂ IH₁ IH₂ =>
rcases h₁₂ with (rfl | h₁₂ | h₁₂)
· unfold stmts₁ at h₀₁
exact h₀₁
· exact Finset.mem_insert_of_mem (Finset.mem_union_left _ (IH₁ h₁₂))
· exact Finset.mem_insert_of_mem (Finset.mem_union_right _ (IH₂ h₁₂))
| goto l => subst h₁₂; exact h₀₁
| halt => subst h₁₂; exact h₀₁
| load _ q IH | _ _ _ q IH =>
rcases h₁₂ with (rfl | h₁₂)
· unfold stmts₁ at h₀₁
exact h₀₁
· exact Finset.mem_insert_of_mem (IH h₁₂)
theorem stmts₁_supportsStmt_mono {S : Finset Λ} {q₁ q₂ : Stmt Γ Λ σ} (h : q₁ ∈ stmts₁ q₂)
(hs : SupportsStmt S q₂) : SupportsStmt S q₁ := by
induction q₂ with
simp only [stmts₁, SupportsStmt, Finset.mem_insert, Finset.mem_union, Finset.mem_singleton]
at h hs
| branch f q₁ q₂ IH₁ IH₂ => rcases h with (rfl | h | h); exacts [hs, IH₁ h hs.1, IH₂ h hs.2]
| goto l => subst h; exact hs
| halt => subst h; trivial
| load _ _ IH | _ _ _ _ IH => rcases h with (rfl | h) <;> [exact hs; exact IH h hs]
open scoped Classical in
/-- The set of statements accessible from initial set `S` of labels. -/
noncomputable def stmts (M : Λ → Stmt Γ Λ σ) (S : Finset Λ) : Finset (Option (Stmt Γ Λ σ)) :=
Finset.insertNone (S.biUnion fun q ↦ stmts₁ (M q))
theorem stmts_trans {M : Λ → Stmt Γ Λ σ} {S : Finset Λ} {q₁ q₂ : Stmt Γ Λ σ} (h₁ : q₁ ∈ stmts₁ q₂) :
some q₂ ∈ stmts M S → some q₁ ∈ stmts M S := by
simp only [stmts, Finset.mem_insertNone, Finset.mem_biUnion, Option.mem_def, Option.some.injEq,
forall_eq', exists_imp, and_imp]
exact fun l ls h₂ ↦ ⟨_, ls, stmts₁_trans h₂ h₁⟩
end
variable [Inhabited Λ]
/-- Given a TM2 machine `M` and a set `S` of states, `Supports M S` means that all states in
`S` jump only to other states in `S`. -/
def Supports (M : Λ → Stmt Γ Λ σ) (S : Finset Λ) :=
default ∈ S ∧ ∀ q ∈ S, SupportsStmt S (M q)
theorem stmts_supportsStmt {M : Λ → Stmt Γ Λ σ} {S : Finset Λ} {q : Stmt Γ Λ σ}
(ss : Supports M S) : some q ∈ stmts M S → SupportsStmt S q := by
simp only [stmts, Finset.mem_insertNone, Finset.mem_biUnion, Option.mem_def, Option.some.injEq,
forall_eq', exists_imp, and_imp]
exact fun l ls h ↦ stmts₁_supportsStmt_mono h (ss.2 _ ls)
variable [DecidableEq K]
theorem step_supports (M : Λ → Stmt Γ Λ σ) {S : Finset Λ} (ss : Supports M S) :
∀ {c c' : Cfg Γ Λ σ}, c' ∈ step M c → c.l ∈ Finset.insertNone S → c'.l ∈ Finset.insertNone S
| ⟨some l₁, v, T⟩, c', h₁, h₂ => by
replace h₂ := ss.2 _ (Finset.some_mem_insertNone.1 h₂)
simp only [step, Option.mem_def, Option.some.injEq] at h₁; subst c'
revert h₂; induction M l₁ generalizing v T with intro hs
| branch p q₁' q₂' IH₁ IH₂ =>
unfold stepAux; cases p v
· exact IH₂ _ _ hs.2
· exact IH₁ _ _ hs.1
| goto => exact Finset.some_mem_insertNone.2 (hs _)
| halt => apply Multiset.mem_cons_self
| load _ _ IH | _ _ _ _ IH => exact IH _ _ hs
variable [Inhabited σ]
/-- The initial state of the TM2 model. The input is provided on a designated stack. -/
def init (k : K) (L : List (Γ k)) : Cfg Γ Λ σ :=
⟨some default, default, update (fun _ ↦ []) k L⟩
/-- Evaluates a TM2 program to completion, with the output on the same stack as the input. -/
def eval (M : Λ → Stmt Γ Λ σ) (k : K) (L : List (Γ k)) : Part (List (Γ k)) :=
(Turing.eval (step M) (init k L)).map fun c ↦ c.stk k
end TM2
/-!
## TM2 emulator in TM1
To prove that TM2 computable functions are TM1 computable, we need to reduce each TM2 program to a
TM1 program. So suppose a TM2 program is given. This program has to maintain a whole collection of
stacks, but we have only one tape, so we must "multiplex" them all together. Pictorially, if stack
1 contains `[a, b]` and stack 2 contains `[c, d, e, f]` then the tape looks like this:
```
bottom: ... | _ | T | _ | _ | _ | _ | ...
stack 1: ... | _ | b | a | _ | _ | _ | ...
stack 2: ... | _ | f | e | d | c | _ | ...
```
where a tape element is a vertical slice through the diagram. Here the alphabet is
`Γ' := Bool × ∀ k, Option (Γ k)`, where:
* `bottom : Bool` is marked only in one place, the initial position of the TM, and represents the
tail of all stacks. It is never modified.
* `stk k : Option (Γ k)` is the value of the `k`-th stack, if in range, otherwise `none` (which is
the blank value). Note that the head of the stack is at the far end; this is so that push and pop
don't have to do any shifting.
In "resting" position, the TM is sitting at the position marked `bottom`. For non-stack actions,
it operates in place, but for the stack actions `push`, `peek`, and `pop`, it must shuttle to the
end of the appropriate stack, make its changes, and then return to the bottom. So the states are:
* `normal (l : Λ)`: waiting at `bottom` to execute function `l`
* `go k (s : StAct k) (q : Stmt₂)`: travelling to the right to get to the end of stack `k` in
order to perform stack action `s`, and later continue with executing `q`
* `ret (q : Stmt₂)`: travelling to the left after having performed a stack action, and executing
`q` once we arrive
Because of the shuttling, emulation overhead is `O(n)`, where `n` is the current maximum of the
length of all stacks. Therefore a program that takes `k` steps to run in TM2 takes `O((m+k)k)`
steps to run when emulated in TM1, where `m` is the length of the input.
-/
namespace TM2to1
-- A displaced lemma proved in unnecessary generality
theorem stk_nth_val {K : Type*} {Γ : K → Type*} {L : ListBlank (∀ k, Option (Γ k))} {k S} (n)
(hL : ListBlank.map (proj k) L = ListBlank.mk (List.map some S).reverse) :
L.nth n k = S.reverse[n]? := by
rw [← proj_map_nth, hL, ← List.map_reverse, ListBlank.nth_mk,
List.getI_eq_iget_getElem?, List.getElem?_map]
cases S.reverse[n]? <;> rfl
variable (K : Type*)
variable (Γ : K → Type*)
variable {Λ σ : Type*}
/-- The alphabet of the TM2 simulator on TM1 is a marker for the stack bottom,
plus a vector of stack elements for each stack, or none if the stack does not extend this far. -/
def Γ' :=
Bool × ∀ k, Option (Γ k)
variable {K Γ}
instance Γ'.inhabited : Inhabited (Γ' K Γ) :=
⟨⟨false, fun _ ↦ none⟩⟩
instance Γ'.fintype [DecidableEq K] [Fintype K] [∀ k, Fintype (Γ k)] : Fintype (Γ' K Γ) :=
instFintypeProd _ _
/-- The bottom marker is fixed throughout the calculation, so we use the `addBottom` function
to express the program state in terms of a tape with only the stacks themselves. -/
def addBottom (L : ListBlank (∀ k, Option (Γ k))) : ListBlank (Γ' K Γ) :=
ListBlank.cons (true, L.head) (L.tail.map ⟨Prod.mk false, rfl⟩)
theorem addBottom_map (L : ListBlank (∀ k, Option (Γ k))) :
(addBottom L).map ⟨Prod.snd, by rfl⟩ = L := by
simp only [addBottom, ListBlank.map_cons]
convert ListBlank.cons_head_tail L
generalize ListBlank.tail L = L'
refine L'.induction_on fun l ↦ ?_; simp
theorem addBottom_modifyNth (f : (∀ k, Option (Γ k)) → ∀ k, Option (Γ k))
(L : ListBlank (∀ k, Option (Γ k))) (n : ℕ) :
(addBottom L).modifyNth (fun a ↦ (a.1, f a.2)) n = addBottom (L.modifyNth f n) := by
cases n <;>
simp only [addBottom, ListBlank.head_cons, ListBlank.modifyNth, ListBlank.tail_cons]
congr; symm; apply ListBlank.map_modifyNth; intro; rfl
theorem addBottom_nth_snd (L : ListBlank (∀ k, Option (Γ k))) (n : ℕ) :
((addBottom L).nth n).2 = L.nth n := by
conv => rhs; rw [← addBottom_map L, ListBlank.nth_map]
theorem addBottom_nth_succ_fst (L : ListBlank (∀ k, Option (Γ k))) (n : ℕ) :
((addBottom L).nth (n + 1)).1 = false := by
rw [ListBlank.nth_succ, addBottom, ListBlank.tail_cons, ListBlank.nth_map]
theorem addBottom_head_fst (L : ListBlank (∀ k, Option (Γ k))) : (addBottom L).head.1 = true := by
rw [addBottom, ListBlank.head_cons]
variable (K Γ σ) in
/-- A stack action is a command that interacts with the top of a stack. Our default position
is at the bottom of all the stacks, so we have to hold on to this action while going to the end
to modify the stack. -/
inductive StAct (k : K)
| push : (σ → Γ k) → StAct k
| peek : (σ → Option (Γ k) → σ) → StAct k
| pop : (σ → Option (Γ k) → σ) → StAct k
instance StAct.inhabited {k : K} : Inhabited (StAct K Γ σ k) :=
⟨StAct.peek fun s _ ↦ s⟩
section
open StAct
/-- The TM2 statement corresponding to a stack action. -/
def stRun {k : K} : StAct K Γ σ k → TM2.Stmt Γ Λ σ → TM2.Stmt Γ Λ σ
| push f => TM2.Stmt.push k f
| peek f => TM2.Stmt.peek k f
| pop f => TM2.Stmt.pop k f
/-- The effect of a stack action on the local variables, given the value of the stack. -/
def stVar {k : K} (v : σ) (l : List (Γ k)) : StAct K Γ σ k → σ
| push _ => v
| peek f => f v l.head?
| pop f => f v l.head?
/-- The effect of a stack action on the stack. -/
def stWrite {k : K} (v : σ) (l : List (Γ k)) : StAct K Γ σ k → List (Γ k)
| push f => f v :: l
| peek _ => l
| pop _ => l.tail
/-- We have partitioned the TM2 statements into "stack actions", which require going to the end
of the stack, and all other actions, which do not. This is a modified recursor which lumps the
stack actions into one. -/
@[elab_as_elim]
def stmtStRec.{l} {motive : TM2.Stmt Γ Λ σ → Sort l}
(run : ∀ (k) (s : StAct K Γ σ k) (q) (_ : motive q), motive (stRun s q))
(load : ∀ (a q) (_ : motive q), motive (TM2.Stmt.load a q))
(branch : ∀ (p q₁ q₂) (_ : motive q₁) (_ : motive q₂), motive (TM2.Stmt.branch p q₁ q₂))
(goto : ∀ l, motive (TM2.Stmt.goto l)) (halt : motive TM2.Stmt.halt) : ∀ n, motive n
| TM2.Stmt.push _ f q => run _ (push f) _ (stmtStRec run load branch goto halt q)
| TM2.Stmt.peek _ f q => run _ (peek f) _ (stmtStRec run load branch goto halt q)
| TM2.Stmt.pop _ f q => run _ (pop f) _ (stmtStRec run load branch goto halt q)
| TM2.Stmt.load _ q => load _ _ (stmtStRec run load branch goto halt q)
| TM2.Stmt.branch _ q₁ q₂ =>
branch _ _ _ (stmtStRec run load branch goto halt q₁) (stmtStRec run load branch goto halt q₂)
| TM2.Stmt.goto _ => goto _
| TM2.Stmt.halt => halt
theorem supports_run (S : Finset Λ) {k : K} (s : StAct K Γ σ k) (q : TM2.Stmt Γ Λ σ) :
TM2.SupportsStmt S (stRun s q) ↔ TM2.SupportsStmt S q := by
cases s <;> rfl
end
variable (K Γ Λ σ)
/-- The machine states of the TM2 emulator. We can either be in a normal state when waiting for the
next TM2 action, or we can be in the "go" and "return" states to go to the top of the stack and
return to the bottom, respectively. -/
inductive Λ'
| normal : Λ → Λ'
| go (k : K) : StAct K Γ σ k → TM2.Stmt Γ Λ σ → Λ'
| ret : TM2.Stmt Γ Λ σ → Λ'
variable {K Γ Λ σ}
open Λ'
instance Λ'.inhabited [Inhabited Λ] : Inhabited (Λ' K Γ Λ σ) :=
⟨normal default⟩
open TM1.Stmt
section
variable [DecidableEq K]
/-- The program corresponding to state transitions at the end of a stack. Here we start out just
after the top of the stack, and should end just after the new top of the stack. -/
def trStAct {k : K} (q : TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ) :
StAct K Γ σ k → TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ
| StAct.push f => (write fun a s ↦ (a.1, update a.2 k <| some <| f s)) <| move Dir.right q
| StAct.peek f => move Dir.left <| (load fun a s ↦ f s (a.2 k)) <| move Dir.right q
| StAct.pop f =>
branch (fun a _ ↦ a.1) (load (fun _ s ↦ f s none) q)
(move Dir.left <|
(load fun a s ↦ f s (a.2 k)) <| write (fun a _ ↦ (a.1, update a.2 k none)) q)
/-- The initial state for the TM2 emulator, given an initial TM2 state. All stacks start out empty
except for the input stack, and the stack bottom mark is set at the head. -/
def trInit (k : K) (L : List (Γ k)) : List (Γ' K Γ) :=
let L' : List (Γ' K Γ) := L.reverse.map fun a ↦ (false, update (fun _ ↦ none) k (some a))
(true, L'.headI.2) :: L'.tail
theorem step_run {k : K} (q : TM2.Stmt Γ Λ σ) (v : σ) (S : ∀ k, List (Γ k)) : ∀ s : StAct K Γ σ k,
TM2.stepAux (stRun s q) v S = TM2.stepAux q (stVar v (S k) s) (update S k (stWrite v (S k) s))
| StAct.push _ => rfl
| StAct.peek f => by unfold stWrite; rw [Function.update_eq_self]; rfl
| StAct.pop _ => rfl
end
/-- The translation of TM2 statements to TM1 statements. regular actions have direct equivalents,
but stack actions are deferred by going to the corresponding `go` state, so that we can find the
appropriate stack top. -/
def trNormal : TM2.Stmt Γ Λ σ → TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ
| TM2.Stmt.push k f q => goto fun _ _ ↦ go k (StAct.push f) q
| TM2.Stmt.peek k f q => goto fun _ _ ↦ go k (StAct.peek f) q
| TM2.Stmt.pop k f q => goto fun _ _ ↦ go k (StAct.pop f) q
| TM2.Stmt.load a q => load (fun _ ↦ a) (trNormal q)
| TM2.Stmt.branch f q₁ q₂ => branch (fun _ ↦ f) (trNormal q₁) (trNormal q₂)
| TM2.Stmt.goto l => goto fun _ s ↦ normal (l s)
| TM2.Stmt.halt => halt
theorem trNormal_run {k : K} (s : StAct K Γ σ k) (q : TM2.Stmt Γ Λ σ) :
trNormal (stRun s q) = goto fun _ _ ↦ go k s q := by
cases s <;> rfl
section
open scoped Classical in
/-- The set of machine states accessible from an initial TM2 statement. -/
noncomputable def trStmts₁ : TM2.Stmt Γ Λ σ → Finset (Λ' K Γ Λ σ)
| TM2.Stmt.push k f q => {go k (StAct.push f) q, ret q} ∪ trStmts₁ q
| TM2.Stmt.peek k f q => {go k (StAct.peek f) q, ret q} ∪ trStmts₁ q
| TM2.Stmt.pop k f q => {go k (StAct.pop f) q, ret q} ∪ trStmts₁ q
| TM2.Stmt.load _ q => trStmts₁ q
| TM2.Stmt.branch _ q₁ q₂ => trStmts₁ q₁ ∪ trStmts₁ q₂
| _ => ∅
theorem trStmts₁_run {k : K} {s : StAct K Γ σ k} {q : TM2.Stmt Γ Λ σ} :
open scoped Classical in
trStmts₁ (stRun s q) = {go k s q, ret q} ∪ trStmts₁ q := by
cases s <;> simp only [trStmts₁, stRun]
theorem tr_respects_aux₂ [DecidableEq K] {k : K} {q : TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ} {v : σ}
{S : ∀ k, List (Γ k)} {L : ListBlank (∀ k, Option (Γ k))}
(hL : ∀ k, L.map (proj k) = ListBlank.mk ((S k).map some).reverse) (o : StAct K Γ σ k) :
let v' := stVar v (S k) o
let Sk' := stWrite v (S k) o
let S' := update S k Sk'
∃ L' : ListBlank (∀ k, Option (Γ k)),
(∀ k, L'.map (proj k) = ListBlank.mk ((S' k).map some).reverse) ∧
TM1.stepAux (trStAct q o) v
((Tape.move Dir.right)^[(S k).length] (Tape.mk' ∅ (addBottom L))) =
TM1.stepAux q v' ((Tape.move Dir.right)^[(S' k).length] (Tape.mk' ∅ (addBottom L'))) := by
simp only [Function.update_self]; cases o with simp only [stWrite, stVar, trStAct, TM1.stepAux]
| push f =>
have := Tape.write_move_right_n fun a : Γ' K Γ ↦ (a.1, update a.2 k (some (f v)))
refine
⟨_, fun k' ↦ ?_, by
-- Porting note: `rw [...]` to `erw [...]; rfl`.
-- https://github.com/leanprover-community/mathlib4/issues/5164
rw [Tape.move_right_n_head, List.length, Tape.mk'_nth_nat, this]
erw [addBottom_modifyNth fun a ↦ update a k (some (f v))]
rw [Nat.add_one, iterate_succ']
rfl⟩
refine ListBlank.ext fun i ↦ ?_
rw [ListBlank.nth_map, ListBlank.nth_modifyNth, proj, PointedMap.mk_val]
by_cases h' : k' = k
· subst k'
split_ifs with h
<;> simp only [List.reverse_cons, Function.update_self, ListBlank.nth_mk, List.map]
· rw [List.getI_eq_getElem _, List.getElem_append_right] <;>
simp only [List.length_append, List.length_reverse, List.length_map, ← h,
Nat.sub_self, List.length_singleton, List.getElem_singleton,
le_refl, Nat.lt_succ_self]
rw [← proj_map_nth, hL, ListBlank.nth_mk]
rcases lt_or_gt_of_ne h with h | h
· rw [List.getI_append]
simpa only [List.length_map, List.length_reverse] using h
· rw [gt_iff_lt] at h
rw [List.getI_eq_default, List.getI_eq_default] <;>
simp only [Nat.add_one_le_iff, h, List.length, le_of_lt, List.length_reverse,
List.length_append, List.length_map]
· split_ifs <;> rw [Function.update_of_ne h', ← proj_map_nth, hL]
rw [Function.update_of_ne h']
| peek f =>
rw [Function.update_eq_self]
use L, hL; rw [Tape.move_left_right]; congr
cases e : S k; · rfl
rw [List.length_cons, iterate_succ', Function.comp, Tape.move_right_left,
Tape.move_right_n_head, Tape.mk'_nth_nat, addBottom_nth_snd, stk_nth_val _ (hL k), e,
List.reverse_cons, ← List.length_reverse, List.getElem?_concat_length]
rfl
| pop f =>
rcases e : S k with - | ⟨hd, tl⟩
· simp only [Tape.mk'_head, ListBlank.head_cons, Tape.move_left_mk', List.length,
Tape.write_mk', List.head?, iterate_zero_apply, List.tail_nil]
rw [← e, Function.update_eq_self]
exact ⟨L, hL, by rw [addBottom_head_fst, cond]⟩
· refine
⟨_, fun k' ↦ ?_, by
erw [List.length_cons, Tape.move_right_n_head, Tape.mk'_nth_nat, addBottom_nth_succ_fst,
cond_false, iterate_succ', Function.comp, Tape.move_right_left, Tape.move_right_n_head,
Tape.mk'_nth_nat, Tape.write_move_right_n fun a : Γ' K Γ ↦ (a.1, update a.2 k none),
addBottom_modifyNth fun a ↦ update a k none, addBottom_nth_snd,
stk_nth_val _ (hL k), e,
show (List.cons hd tl).reverse[tl.length]? = some hd by
rw [List.reverse_cons, ← List.length_reverse, List.getElem?_concat_length],
List.head?, List.tail]⟩
refine ListBlank.ext fun i ↦ ?_
rw [ListBlank.nth_map, ListBlank.nth_modifyNth, proj, PointedMap.mk_val]
by_cases h' : k' = k
· subst k'
split_ifs with h <;> simp only [Function.update_self, ListBlank.nth_mk, List.tail]
· rw [List.getI_eq_default]
· rfl
rw [h, List.length_reverse, List.length_map]
rw [← proj_map_nth, hL, ListBlank.nth_mk, e, List.map, List.reverse_cons]
rcases lt_or_gt_of_ne h with h | h
· rw [List.getI_append]
simpa only [List.length_map, List.length_reverse] using h
· rw [gt_iff_lt] at h
rw [List.getI_eq_default, List.getI_eq_default] <;>
simp only [Nat.add_one_le_iff, h, List.length, le_of_lt, List.length_reverse,
List.length_append, List.length_map]
· split_ifs <;> rw [Function.update_of_ne h', ← proj_map_nth, hL]
rw [Function.update_of_ne h']
end
variable [DecidableEq K]
variable (M : Λ → TM2.Stmt Γ Λ σ)
/-- The TM2 emulator machine states written as a TM1 program.
This handles the `go` and `ret` states, which shuttle to and from a stack top. -/
def tr : Λ' K Γ Λ σ → TM1.Stmt (Γ' K Γ) (Λ' K Γ Λ σ) σ
| normal q => trNormal (M q)
| go k s q =>
branch (fun a _ ↦ (a.2 k).isNone) (trStAct (goto fun _ _ ↦ ret q) s)
(move Dir.right <| goto fun _ _ ↦ go k s q)
| ret q => branch (fun a _ ↦ a.1) (trNormal q) (move Dir.left <| goto fun _ _ ↦ ret q)
/-- The relation between TM2 configurations and TM1 configurations of the TM2 emulator. -/
inductive TrCfg : TM2.Cfg Γ Λ σ → TM1.Cfg (Γ' K Γ) (Λ' K Γ Λ σ) σ → Prop
| mk {q : Option Λ} {v : σ} {S : ∀ k, List (Γ k)} (L : ListBlank (∀ k, Option (Γ k))) :
(∀ k, L.map (proj k) = ListBlank.mk ((S k).map some).reverse) →
TrCfg ⟨q, v, S⟩ ⟨q.map normal, v, Tape.mk' ∅ (addBottom L)⟩
theorem tr_respects_aux₁ {k} (o q v) {S : List (Γ k)} {L : ListBlank (∀ k, Option (Γ k))}
(hL : L.map (proj k) = ListBlank.mk (S.map some).reverse) (n) (H : n ≤ S.length) :
Reaches₀ (TM1.step (tr M)) ⟨some (go k o q), v, Tape.mk' ∅ (addBottom L)⟩
⟨some (go k o q), v, (Tape.move Dir.right)^[n] (Tape.mk' ∅ (addBottom L))⟩ := by
induction' n with n IH; · rfl
apply (IH (le_of_lt H)).tail
rw [iterate_succ_apply']
simp only [TM1.step, TM1.stepAux, tr, Tape.mk'_nth_nat, Tape.move_right_n_head,
addBottom_nth_snd, Option.mem_def]
rw [stk_nth_val _ hL, List.getElem?_eq_getElem]
· rfl
· rwa [List.length_reverse]
theorem tr_respects_aux₃ {q v} {L : ListBlank (∀ k, Option (Γ k))} (n) : Reaches₀ (TM1.step (tr M))
⟨some (ret q), v, (Tape.move Dir.right)^[n] (Tape.mk' ∅ (addBottom L))⟩
⟨some (ret q), v, Tape.mk' ∅ (addBottom L)⟩ := by
induction' n with n IH; · rfl
refine Reaches₀.head ?_ IH
simp only [Option.mem_def, TM1.step]
rw [Option.some_inj, tr, TM1.stepAux, Tape.move_right_n_head, Tape.mk'_nth_nat,
addBottom_nth_succ_fst, TM1.stepAux, iterate_succ', Function.comp_apply, Tape.move_right_left]
rfl
theorem tr_respects_aux {q v T k} {S : ∀ k, List (Γ k)}
(hT : ∀ k, ListBlank.map (proj k) T = ListBlank.mk ((S k).map some).reverse)
(o : StAct K Γ σ k)
(IH : ∀ {v : σ} {S : ∀ k : K, List (Γ k)} {T : ListBlank (∀ k, Option (Γ k))},
(∀ k, ListBlank.map (proj k) T = ListBlank.mk ((S k).map some).reverse) →
∃ b, TrCfg (TM2.stepAux q v S) b ∧
Reaches (TM1.step (tr M)) (TM1.stepAux (trNormal q) v (Tape.mk' ∅ (addBottom T))) b) :
∃ b, TrCfg (TM2.stepAux (stRun o q) v S) b ∧ Reaches (TM1.step (tr M))
(TM1.stepAux (trNormal (stRun o q)) v (Tape.mk' ∅ (addBottom T))) b := by
simp only [trNormal_run, step_run]
have hgo := tr_respects_aux₁ M o q v (hT k) _ le_rfl
obtain ⟨T', hT', hrun⟩ := tr_respects_aux₂ (Λ := Λ) hT o
have := hgo.tail' rfl
rw [tr, TM1.stepAux, Tape.move_right_n_head, Tape.mk'_nth_nat, addBottom_nth_snd,
stk_nth_val _ (hT k), List.getElem?_eq_none (le_of_eq List.length_reverse),
Option.isNone, cond, hrun, TM1.stepAux] at this
obtain ⟨c, gc, rc⟩ := IH hT'
refine ⟨c, gc, (this.to₀.trans (tr_respects_aux₃ M _) c (TransGen.head' rfl ?_)).to_reflTransGen⟩
rw [tr, TM1.stepAux, Tape.mk'_head, addBottom_head_fst]
exact rc
attribute [local simp] Respects TM2.step TM2.stepAux trNormal
theorem tr_respects : Respects (TM2.step M) (TM1.step (tr M)) TrCfg := by
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/12129): additional beta reduction needed
intro c₁ c₂ h
obtain @⟨- | l, v, S, L, hT⟩ := h; · constructor
rsuffices ⟨b, c, r⟩ : ∃ b, _ ∧ Reaches (TM1.step (tr M)) _ _
· exact ⟨b, c, TransGen.head' rfl r⟩
simp only [tr]
generalize M l = N
induction N using stmtStRec generalizing v S L hT with
| run k s q IH => exact tr_respects_aux M hT s @IH
| load a _ IH => exact IH _ hT
| branch p q₁ q₂ IH₁ IH₂ =>
unfold TM2.stepAux trNormal TM1.stepAux
beta_reduce
cases p v <;> [exact IH₂ _ hT; exact IH₁ _ hT]
| goto => exact ⟨_, ⟨_, hT⟩, ReflTransGen.refl⟩
| halt => exact ⟨_, ⟨_, hT⟩, ReflTransGen.refl⟩
section
variable [Inhabited Λ] [Inhabited σ]
theorem trCfg_init (k) (L : List (Γ k)) : TrCfg (TM2.init k L)
(TM1.init (trInit k L) : TM1.Cfg (Γ' K Γ) (Λ' K Γ Λ σ) σ) := by
rw [(_ : TM1.init _ = _)]
· refine ⟨ListBlank.mk (L.reverse.map fun a ↦ update default k (some a)), fun k' ↦ ?_⟩
refine ListBlank.ext fun i ↦ ?_
rw [ListBlank.map_mk, ListBlank.nth_mk, List.getI_eq_iget_getElem?, List.map_map]
have : ((proj k').f ∘ fun a => update (β := fun k => Option (Γ k)) default k (some a))
= fun a => (proj k').f (update (β := fun k => Option (Γ k)) default k (some a)) := rfl
rw [this, List.getElem?_map, proj, PointedMap.mk_val]
simp only []
by_cases h : k' = k
· subst k'
simp only [Function.update_self]
rw [ListBlank.nth_mk, List.getI_eq_iget_getElem?, ← List.map_reverse, List.getElem?_map]
· simp only [Function.update_of_ne h]
rw [ListBlank.nth_mk, List.getI_eq_iget_getElem?, List.map, List.reverse_nil]
cases L.reverse[i]? <;> rfl
· rw [trInit, TM1.init]
congr <;> cases L.reverse <;> try rfl
simp only [List.map_map, List.tail_cons, List.map]
rfl
theorem tr_eval_dom (k) (L : List (Γ k)) :
(TM1.eval (tr M) (trInit k L)).Dom ↔ (TM2.eval M k L).Dom :=
Turing.tr_eval_dom (tr_respects M) (trCfg_init k L)
theorem tr_eval (k) (L : List (Γ k)) {L₁ L₂} (H₁ : L₁ ∈ TM1.eval (tr M) (trInit k L))
(H₂ : L₂ ∈ TM2.eval M k L) :
∃ (S : ∀ k, List (Γ k)) (L' : ListBlank (∀ k, Option (Γ k))),
addBottom L' = L₁ ∧
(∀ k, L'.map (proj k) = ListBlank.mk ((S k).map some).reverse) ∧ S k = L₂ := by
obtain ⟨c₁, h₁, rfl⟩ := (Part.mem_map_iff _).1 H₁
obtain ⟨c₂, h₂, rfl⟩ := (Part.mem_map_iff _).1 H₂
obtain ⟨_, ⟨L', hT⟩, h₃⟩ := Turing.tr_eval (tr_respects M) (trCfg_init k L) h₂
cases Part.mem_unique h₁ h₃
exact ⟨_, L', by simp only [Tape.mk'_right₀], hT, rfl⟩
end
section
variable [Inhabited Λ]
open scoped Classical in
/-- The support of a set of TM2 states in the TM2 emulator. -/
noncomputable def trSupp (S : Finset Λ) : Finset (Λ' K Γ Λ σ) :=
S.biUnion fun l ↦ insert (normal l) (trStmts₁ (M l))
open scoped Classical in
theorem tr_supports {S} (ss : TM2.Supports M S) : TM1.Supports (tr M) (trSupp M S) :=
⟨Finset.mem_biUnion.2 ⟨_, ss.1, Finset.mem_insert.2 <| Or.inl rfl⟩, fun l' h ↦ by
suffices ∀ (q) (_ : TM2.SupportsStmt S q) (_ : ∀ x ∈ trStmts₁ q, x ∈ trSupp M S),
TM1.SupportsStmt (trSupp M S) (trNormal q) ∧
∀ l' ∈ trStmts₁ q, TM1.SupportsStmt (trSupp M S) (tr M l') by
rcases Finset.mem_biUnion.1 h with ⟨l, lS, h⟩
have :=
this _ (ss.2 l lS) fun x hx ↦ Finset.mem_biUnion.2 ⟨_, lS, Finset.mem_insert_of_mem hx⟩
rcases Finset.mem_insert.1 h with (rfl | h) <;> [exact this.1; exact this.2 _ h]
clear h l'
refine stmtStRec ?_ ?_ ?_ ?_ ?_
· intro _ s _ IH ss' sub -- stack op
rw [TM2to1.supports_run] at ss'
simp only [TM2to1.trStmts₁_run, Finset.mem_union, Finset.mem_insert, Finset.mem_singleton]
at sub
have hgo := sub _ (Or.inl <| Or.inl rfl)
have hret := sub _ (Or.inl <| Or.inr rfl)
obtain ⟨IH₁, IH₂⟩ := IH ss' fun x hx ↦ sub x <| Or.inr hx
refine ⟨by simp only [trNormal_run, TM1.SupportsStmt]; intros; exact hgo, fun l h ↦ ?_⟩
rw [trStmts₁_run] at h
simp only [TM2to1.trStmts₁_run, Finset.mem_union, Finset.mem_insert, Finset.mem_singleton]
at h
rcases h with (⟨rfl | rfl⟩ | h)
· cases s
· exact ⟨fun _ _ ↦ hret, fun _ _ ↦ hgo⟩
· exact ⟨fun _ _ ↦ hret, fun _ _ ↦ hgo⟩
· exact ⟨⟨fun _ _ ↦ hret, fun _ _ ↦ hret⟩, fun _ _ ↦ hgo⟩
· unfold TM1.SupportsStmt TM2to1.tr
exact ⟨IH₁, fun _ _ ↦ hret⟩
· exact IH₂ _ h
· intro _ _ IH ss' sub -- load
unfold TM2to1.trStmts₁ at sub ⊢
exact IH ss' sub
· intro _ _ _ IH₁ IH₂ ss' sub -- branch
unfold TM2to1.trStmts₁ at sub
obtain ⟨IH₁₁, IH₁₂⟩ := IH₁ ss'.1 fun x hx ↦ sub x <| Finset.mem_union_left _ hx
obtain ⟨IH₂₁, IH₂₂⟩ := IH₂ ss'.2 fun x hx ↦ sub x <| Finset.mem_union_right _ hx
refine ⟨⟨IH₁₁, IH₂₁⟩, fun l h ↦ ?_⟩
rw [trStmts₁] at h
rcases Finset.mem_union.1 h with (h | h) <;> [exact IH₁₂ _ h; exact IH₂₂ _ h]
· intro _ ss' _ -- goto
simp only [trStmts₁, Finset.not_mem_empty]; refine ⟨?_, fun _ ↦ False.elim⟩
exact fun _ v ↦ Finset.mem_biUnion.2 ⟨_, ss' v, Finset.mem_insert_self _ _⟩
· intro _ _ -- halt
simp only [trStmts₁, Finset.not_mem_empty]
exact ⟨trivial, fun _ ↦ False.elim⟩⟩
end
end TM2to1
end Turing
| Mathlib/Computability/TuringMachine.lean | 2,547 | 2,549 | |
/-
Copyright (c) 2014 Parikshit Khanna. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Parikshit Khanna, Jeremy Avigad, Leonardo de Moura, Floris van Doorn, Mario Carneiro
-/
import Mathlib.Control.Basic
import Mathlib.Data.Nat.Basic
import Mathlib.Data.Option.Basic
import Mathlib.Data.List.Defs
import Mathlib.Data.List.Monad
import Mathlib.Logic.OpClass
import Mathlib.Logic.Unique
import Mathlib.Order.Basic
import Mathlib.Tactic.Common
/-!
# Basic properties of lists
-/
assert_not_exists GroupWithZero
assert_not_exists Lattice
assert_not_exists Prod.swap_eq_iff_eq_swap
assert_not_exists Ring
assert_not_exists Set.range
open Function
open Nat hiding one_pos
namespace List
universe u v w
variable {ι : Type*} {α : Type u} {β : Type v} {γ : Type w} {l₁ l₂ : List α}
/-- There is only one list of an empty type -/
instance uniqueOfIsEmpty [IsEmpty α] : Unique (List α) :=
{ instInhabitedList with
uniq := fun l =>
match l with
| [] => rfl
| a :: _ => isEmptyElim a }
instance : Std.LawfulIdentity (α := List α) Append.append [] where
left_id := nil_append
right_id := append_nil
instance : Std.Associative (α := List α) Append.append where
assoc := append_assoc
@[simp] theorem cons_injective {a : α} : Injective (cons a) := fun _ _ => tail_eq_of_cons_eq
theorem singleton_injective : Injective fun a : α => [a] := fun _ _ h => (cons_eq_cons.1 h).1
theorem set_of_mem_cons (l : List α) (a : α) : { x | x ∈ a :: l } = insert a { x | x ∈ l } :=
Set.ext fun _ => mem_cons
/-! ### mem -/
theorem _root_.Decidable.List.eq_or_ne_mem_of_mem [DecidableEq α]
{a b : α} {l : List α} (h : a ∈ b :: l) : a = b ∨ a ≠ b ∧ a ∈ l := by
by_cases hab : a = b
· exact Or.inl hab
· exact ((List.mem_cons.1 h).elim Or.inl (fun h => Or.inr ⟨hab, h⟩))
lemma mem_pair {a b c : α} : a ∈ [b, c] ↔ a = b ∨ a = c := by
rw [mem_cons, mem_singleton]
-- The simpNF linter says that the LHS can be simplified via `List.mem_map`.
-- However this is a higher priority lemma.
-- It seems the side condition `hf` is not applied by `simpNF`.
-- https://github.com/leanprover/std4/issues/207
@[simp 1100, nolint simpNF]
theorem mem_map_of_injective {f : α → β} (H : Injective f) {a : α} {l : List α} :
f a ∈ map f l ↔ a ∈ l :=
⟨fun m => let ⟨_, m', e⟩ := exists_of_mem_map m; H e ▸ m', mem_map_of_mem⟩
@[simp]
theorem _root_.Function.Involutive.exists_mem_and_apply_eq_iff {f : α → α}
(hf : Function.Involutive f) (x : α) (l : List α) : (∃ y : α, y ∈ l ∧ f y = x) ↔ f x ∈ l :=
⟨by rintro ⟨y, h, rfl⟩; rwa [hf y], fun h => ⟨f x, h, hf _⟩⟩
theorem mem_map_of_involutive {f : α → α} (hf : Involutive f) {a : α} {l : List α} :
a ∈ map f l ↔ f a ∈ l := by rw [mem_map, hf.exists_mem_and_apply_eq_iff]
/-! ### length -/
alias ⟨_, length_pos_of_ne_nil⟩ := length_pos_iff
theorem length_pos_iff_ne_nil {l : List α} : 0 < length l ↔ l ≠ [] :=
⟨ne_nil_of_length_pos, length_pos_of_ne_nil⟩
theorem exists_of_length_succ {n} : ∀ l : List α, l.length = n + 1 → ∃ h t, l = h :: t
| [], H => absurd H.symm <| succ_ne_zero n
| h :: t, _ => ⟨h, t, rfl⟩
@[simp] lemma length_injective_iff : Injective (List.length : List α → ℕ) ↔ Subsingleton α := by
constructor
· intro h; refine ⟨fun x y => ?_⟩; (suffices [x] = [y] by simpa using this); apply h; rfl
· intros hα l1 l2 hl
induction l1 generalizing l2 <;> cases l2
· rfl
· cases hl
· cases hl
· next ih _ _ =>
congr
· subsingleton
· apply ih; simpa using hl
@[simp default+1] -- Raise priority above `length_injective_iff`.
lemma length_injective [Subsingleton α] : Injective (length : List α → ℕ) :=
length_injective_iff.mpr inferInstance
theorem length_eq_two {l : List α} : l.length = 2 ↔ ∃ a b, l = [a, b] :=
⟨fun _ => let [a, b] := l; ⟨a, b, rfl⟩, fun ⟨_, _, e⟩ => e ▸ rfl⟩
theorem length_eq_three {l : List α} : l.length = 3 ↔ ∃ a b c, l = [a, b, c] :=
⟨fun _ => let [a, b, c] := l; ⟨a, b, c, rfl⟩, fun ⟨_, _, _, e⟩ => e ▸ rfl⟩
/-! ### set-theoretic notation of lists -/
instance instSingletonList : Singleton α (List α) := ⟨fun x => [x]⟩
instance [DecidableEq α] : Insert α (List α) := ⟨List.insert⟩
instance [DecidableEq α] : LawfulSingleton α (List α) :=
{ insert_empty_eq := fun x =>
show (if x ∈ ([] : List α) then [] else [x]) = [x] from if_neg not_mem_nil }
theorem singleton_eq (x : α) : ({x} : List α) = [x] :=
rfl
theorem insert_neg [DecidableEq α] {x : α} {l : List α} (h : x ∉ l) :
Insert.insert x l = x :: l :=
insert_of_not_mem h
theorem insert_pos [DecidableEq α] {x : α} {l : List α} (h : x ∈ l) : Insert.insert x l = l :=
insert_of_mem h
theorem doubleton_eq [DecidableEq α] {x y : α} (h : x ≠ y) : ({x, y} : List α) = [x, y] := by
rw [insert_neg, singleton_eq]
rwa [singleton_eq, mem_singleton]
/-! ### bounded quantifiers over lists -/
theorem forall_mem_of_forall_mem_cons {p : α → Prop} {a : α} {l : List α} (h : ∀ x ∈ a :: l, p x) :
∀ x ∈ l, p x := (forall_mem_cons.1 h).2
theorem exists_mem_cons_of {p : α → Prop} {a : α} (l : List α) (h : p a) : ∃ x ∈ a :: l, p x :=
⟨a, mem_cons_self, h⟩
theorem exists_mem_cons_of_exists {p : α → Prop} {a : α} {l : List α} : (∃ x ∈ l, p x) →
∃ x ∈ a :: l, p x :=
fun ⟨x, xl, px⟩ => ⟨x, mem_cons_of_mem _ xl, px⟩
theorem or_exists_of_exists_mem_cons {p : α → Prop} {a : α} {l : List α} : (∃ x ∈ a :: l, p x) →
p a ∨ ∃ x ∈ l, p x :=
fun ⟨x, xal, px⟩ =>
Or.elim (eq_or_mem_of_mem_cons xal) (fun h : x = a => by rw [← h]; left; exact px)
fun h : x ∈ l => Or.inr ⟨x, h, px⟩
theorem exists_mem_cons_iff (p : α → Prop) (a : α) (l : List α) :
(∃ x ∈ a :: l, p x) ↔ p a ∨ ∃ x ∈ l, p x :=
Iff.intro or_exists_of_exists_mem_cons fun h =>
Or.elim h (exists_mem_cons_of l) exists_mem_cons_of_exists
/-! ### list subset -/
theorem cons_subset_of_subset_of_mem {a : α} {l m : List α}
(ainm : a ∈ m) (lsubm : l ⊆ m) : a::l ⊆ m :=
cons_subset.2 ⟨ainm, lsubm⟩
theorem append_subset_of_subset_of_subset {l₁ l₂ l : List α} (l₁subl : l₁ ⊆ l) (l₂subl : l₂ ⊆ l) :
l₁ ++ l₂ ⊆ l :=
fun _ h ↦ (mem_append.1 h).elim (@l₁subl _) (@l₂subl _)
theorem map_subset_iff {l₁ l₂ : List α} (f : α → β) (h : Injective f) :
map f l₁ ⊆ map f l₂ ↔ l₁ ⊆ l₂ := by
refine ⟨?_, map_subset f⟩; intro h2 x hx
rcases mem_map.1 (h2 (mem_map_of_mem hx)) with ⟨x', hx', hxx'⟩
cases h hxx'; exact hx'
/-! ### append -/
theorem append_eq_has_append {L₁ L₂ : List α} : List.append L₁ L₂ = L₁ ++ L₂ :=
rfl
theorem append_right_injective (s : List α) : Injective fun t ↦ s ++ t :=
fun _ _ ↦ append_cancel_left
theorem append_left_injective (t : List α) : Injective fun s ↦ s ++ t :=
fun _ _ ↦ append_cancel_right
/-! ### replicate -/
theorem eq_replicate_length {a : α} : ∀ {l : List α}, l = replicate l.length a ↔ ∀ b ∈ l, b = a
| [] => by simp
| (b :: l) => by simp [eq_replicate_length, replicate_succ]
theorem replicate_add (m n) (a : α) : replicate (m + n) a = replicate m a ++ replicate n a := by
rw [replicate_append_replicate]
theorem replicate_subset_singleton (n) (a : α) : replicate n a ⊆ [a] := fun _ h =>
mem_singleton.2 (eq_of_mem_replicate h)
theorem subset_singleton_iff {a : α} {L : List α} : L ⊆ [a] ↔ ∃ n, L = replicate n a := by
simp only [eq_replicate_iff, subset_def, mem_singleton, exists_eq_left']
theorem replicate_right_injective {n : ℕ} (hn : n ≠ 0) : Injective (@replicate α n) :=
fun _ _ h => (eq_replicate_iff.1 h).2 _ <| mem_replicate.2 ⟨hn, rfl⟩
theorem replicate_right_inj {a b : α} {n : ℕ} (hn : n ≠ 0) :
replicate n a = replicate n b ↔ a = b :=
(replicate_right_injective hn).eq_iff
theorem replicate_right_inj' {a b : α} : ∀ {n},
replicate n a = replicate n b ↔ n = 0 ∨ a = b
| 0 => by simp
| n + 1 => (replicate_right_inj n.succ_ne_zero).trans <| by simp only [n.succ_ne_zero, false_or]
theorem replicate_left_injective (a : α) : Injective (replicate · a) :=
LeftInverse.injective (length_replicate (n := ·))
theorem replicate_left_inj {a : α} {n m : ℕ} : replicate n a = replicate m a ↔ n = m :=
(replicate_left_injective a).eq_iff
@[simp]
theorem head?_flatten_replicate {n : ℕ} (h : n ≠ 0) (l : List α) :
(List.replicate n l).flatten.head? = l.head? := by
obtain ⟨n, rfl⟩ := Nat.exists_eq_succ_of_ne_zero h
induction l <;> simp [replicate]
@[simp]
theorem getLast?_flatten_replicate {n : ℕ} (h : n ≠ 0) (l : List α) :
(List.replicate n l).flatten.getLast? = l.getLast? := by
rw [← List.head?_reverse, ← List.head?_reverse, List.reverse_flatten, List.map_replicate,
List.reverse_replicate, head?_flatten_replicate h]
/-! ### pure -/
theorem mem_pure (x y : α) : x ∈ (pure y : List α) ↔ x = y := by simp
/-! ### bind -/
@[simp]
theorem bind_eq_flatMap {α β} (f : α → List β) (l : List α) : l >>= f = l.flatMap f :=
rfl
/-! ### concat -/
/-! ### reverse -/
theorem reverse_cons' (a : α) (l : List α) : reverse (a :: l) = concat (reverse l) a := by
simp only [reverse_cons, concat_eq_append]
theorem reverse_concat' (l : List α) (a : α) : (l ++ [a]).reverse = a :: l.reverse := by
rw [reverse_append]; rfl
@[simp]
theorem reverse_singleton (a : α) : reverse [a] = [a] :=
rfl
@[simp]
theorem reverse_involutive : Involutive (@reverse α) :=
reverse_reverse
@[simp]
theorem reverse_injective : Injective (@reverse α) :=
reverse_involutive.injective
theorem reverse_surjective : Surjective (@reverse α) :=
reverse_involutive.surjective
theorem reverse_bijective : Bijective (@reverse α) :=
reverse_involutive.bijective
theorem concat_eq_reverse_cons (a : α) (l : List α) : concat l a = reverse (a :: reverse l) := by
simp only [concat_eq_append, reverse_cons, reverse_reverse]
theorem map_reverseAux (f : α → β) (l₁ l₂ : List α) :
map f (reverseAux l₁ l₂) = reverseAux (map f l₁) (map f l₂) := by
simp only [reverseAux_eq, map_append, map_reverse]
-- TODO: Rename `List.reverse_perm` to `List.reverse_perm_self`
@[simp] lemma reverse_perm' : l₁.reverse ~ l₂ ↔ l₁ ~ l₂ where
mp := l₁.reverse_perm.symm.trans
mpr := l₁.reverse_perm.trans
@[simp] lemma perm_reverse : l₁ ~ l₂.reverse ↔ l₁ ~ l₂ where
mp hl := hl.trans l₂.reverse_perm
mpr hl := hl.trans l₂.reverse_perm.symm
/-! ### getLast -/
attribute [simp] getLast_cons
theorem getLast_append_singleton {a : α} (l : List α) :
getLast (l ++ [a]) (append_ne_nil_of_right_ne_nil l (cons_ne_nil a _)) = a := by
simp [getLast_append]
theorem getLast_append_of_right_ne_nil (l₁ l₂ : List α) (h : l₂ ≠ []) :
getLast (l₁ ++ l₂) (append_ne_nil_of_right_ne_nil l₁ h) = getLast l₂ h := by
induction l₁ with
| nil => simp
| cons _ _ ih => simp only [cons_append]; rw [List.getLast_cons]; exact ih
@[deprecated (since := "2025-02-06")]
alias getLast_append' := getLast_append_of_right_ne_nil
theorem getLast_concat' {a : α} (l : List α) : getLast (concat l a) (by simp) = a := by
simp
@[simp]
theorem getLast_singleton' (a : α) : getLast [a] (cons_ne_nil a []) = a := rfl
@[simp]
theorem getLast_cons_cons (a₁ a₂ : α) (l : List α) :
getLast (a₁ :: a₂ :: l) (cons_ne_nil _ _) = getLast (a₂ :: l) (cons_ne_nil a₂ l) :=
rfl
theorem dropLast_append_getLast : ∀ {l : List α} (h : l ≠ []), dropLast l ++ [getLast l h] = l
| [], h => absurd rfl h
| [_], _ => rfl
| a :: b :: l, h => by
rw [dropLast_cons₂, cons_append, getLast_cons (cons_ne_nil _ _)]
congr
exact dropLast_append_getLast (cons_ne_nil b l)
theorem getLast_congr {l₁ l₂ : List α} (h₁ : l₁ ≠ []) (h₂ : l₂ ≠ []) (h₃ : l₁ = l₂) :
getLast l₁ h₁ = getLast l₂ h₂ := by subst l₁; rfl
theorem getLast_replicate_succ (m : ℕ) (a : α) :
(replicate (m + 1) a).getLast (ne_nil_of_length_eq_add_one length_replicate) = a := by
simp only [replicate_succ']
exact getLast_append_singleton _
@[deprecated (since := "2025-02-07")]
alias getLast_filter' := getLast_filter_of_pos
/-! ### getLast? -/
theorem mem_getLast?_eq_getLast : ∀ {l : List α} {x : α}, x ∈ l.getLast? → ∃ h, x = getLast l h
| [], x, hx => False.elim <| by simp at hx
| [a], x, hx =>
have : a = x := by simpa using hx
this ▸ ⟨cons_ne_nil a [], rfl⟩
| a :: b :: l, x, hx => by
rw [getLast?_cons_cons] at hx
rcases mem_getLast?_eq_getLast hx with ⟨_, h₂⟩
use cons_ne_nil _ _
assumption
theorem getLast?_eq_getLast_of_ne_nil : ∀ {l : List α} (h : l ≠ []), l.getLast? = some (l.getLast h)
| [], h => (h rfl).elim
| [_], _ => rfl
| _ :: b :: l, _ => @getLast?_eq_getLast_of_ne_nil (b :: l) (cons_ne_nil _ _)
theorem mem_getLast?_cons {x y : α} : ∀ {l : List α}, x ∈ l.getLast? → x ∈ (y :: l).getLast?
| [], _ => by contradiction
| _ :: _, h => h
theorem dropLast_append_getLast? : ∀ {l : List α}, ∀ a ∈ l.getLast?, dropLast l ++ [a] = l
| [], a, ha => (Option.not_mem_none a ha).elim
| [a], _, rfl => rfl
| a :: b :: l, c, hc => by
rw [getLast?_cons_cons] at hc
rw [dropLast_cons₂, cons_append, dropLast_append_getLast? _ hc]
theorem getLastI_eq_getLast? [Inhabited α] : ∀ l : List α, l.getLastI = l.getLast?.iget
| [] => by simp [getLastI, Inhabited.default]
| [_] => rfl
| [_, _] => rfl
| [_, _, _] => rfl
| _ :: _ :: c :: l => by simp [getLastI, getLastI_eq_getLast? (c :: l)]
theorem getLast?_append_cons :
∀ (l₁ : List α) (a : α) (l₂ : List α), getLast? (l₁ ++ a :: l₂) = getLast? (a :: l₂)
| [], _, _ => rfl
| [_], _, _ => rfl
| b :: c :: l₁, a, l₂ => by rw [cons_append, cons_append, getLast?_cons_cons,
← cons_append, getLast?_append_cons (c :: l₁)]
theorem getLast?_append_of_ne_nil (l₁ : List α) :
∀ {l₂ : List α} (_ : l₂ ≠ []), getLast? (l₁ ++ l₂) = getLast? l₂
| [], hl₂ => by contradiction
| b :: l₂, _ => getLast?_append_cons l₁ b l₂
theorem mem_getLast?_append_of_mem_getLast? {l₁ l₂ : List α} {x : α} (h : x ∈ l₂.getLast?) :
x ∈ (l₁ ++ l₂).getLast? := by
cases l₂
· contradiction
· rw [List.getLast?_append_cons]
exact h
/-! ### head(!?) and tail -/
@[simp]
theorem head!_nil [Inhabited α] : ([] : List α).head! = default := rfl
@[simp] theorem head_cons_tail (x : List α) (h : x ≠ []) : x.head h :: x.tail = x := by
cases x <;> simp at h ⊢
theorem head_eq_getElem_zero {l : List α} (hl : l ≠ []) :
l.head hl = l[0]'(length_pos_iff.2 hl) :=
(getElem_zero _).symm
theorem head!_eq_head? [Inhabited α] (l : List α) : head! l = (head? l).iget := by cases l <;> rfl
theorem surjective_head! [Inhabited α] : Surjective (@head! α _) := fun x => ⟨[x], rfl⟩
theorem surjective_head? : Surjective (@head? α) :=
Option.forall.2 ⟨⟨[], rfl⟩, fun x => ⟨[x], rfl⟩⟩
theorem surjective_tail : Surjective (@tail α)
| [] => ⟨[], rfl⟩
| a :: l => ⟨a :: a :: l, rfl⟩
theorem eq_cons_of_mem_head? {x : α} : ∀ {l : List α}, x ∈ l.head? → l = x :: tail l
| [], h => (Option.not_mem_none _ h).elim
| a :: l, h => by
simp only [head?, Option.mem_def, Option.some_inj] at h
exact h ▸ rfl
@[simp] theorem head!_cons [Inhabited α] (a : α) (l : List α) : head! (a :: l) = a := rfl
@[simp]
theorem head!_append [Inhabited α] (t : List α) {s : List α} (h : s ≠ []) :
head! (s ++ t) = head! s := by
induction s
· contradiction
· rfl
theorem mem_head?_append_of_mem_head? {s t : List α} {x : α} (h : x ∈ s.head?) :
x ∈ (s ++ t).head? := by
cases s
· contradiction
· exact h
theorem head?_append_of_ne_nil :
∀ (l₁ : List α) {l₂ : List α} (_ : l₁ ≠ []), head? (l₁ ++ l₂) = head? l₁
| _ :: _, _, _ => rfl
theorem tail_append_singleton_of_ne_nil {a : α} {l : List α} (h : l ≠ nil) :
tail (l ++ [a]) = tail l ++ [a] := by
induction l
· contradiction
· rw [tail, cons_append, tail]
theorem cons_head?_tail : ∀ {l : List α} {a : α}, a ∈ head? l → a :: tail l = l
| [], a, h => by contradiction
| b :: l, a, h => by
simp? at h says simp only [head?_cons, Option.mem_def, Option.some.injEq] at h
simp [h]
theorem head!_mem_head? [Inhabited α] : ∀ {l : List α}, l ≠ [] → head! l ∈ head? l
| [], h => by contradiction
| _ :: _, _ => rfl
theorem cons_head!_tail [Inhabited α] {l : List α} (h : l ≠ []) : head! l :: tail l = l :=
cons_head?_tail (head!_mem_head? h)
theorem head!_mem_self [Inhabited α] {l : List α} (h : l ≠ nil) : l.head! ∈ l := by
have h' : l.head! ∈ l.head! :: l.tail := mem_cons_self
rwa [cons_head!_tail h] at h'
theorem get_eq_getElem? (l : List α) (i : Fin l.length) :
l.get i = l[i]?.get (by simp [getElem?_eq_getElem]) := by
simp
@[deprecated (since := "2025-02-15")] alias get_eq_get? := get_eq_getElem?
theorem exists_mem_iff_getElem {l : List α} {p : α → Prop} :
(∃ x ∈ l, p x) ↔ ∃ (i : ℕ) (_ : i < l.length), p l[i] := by
simp only [mem_iff_getElem]
exact ⟨fun ⟨_x, ⟨i, hi, hix⟩, hxp⟩ ↦ ⟨i, hi, hix ▸ hxp⟩, fun ⟨i, hi, hp⟩ ↦ ⟨_, ⟨i, hi, rfl⟩, hp⟩⟩
theorem forall_mem_iff_getElem {l : List α} {p : α → Prop} :
(∀ x ∈ l, p x) ↔ ∀ (i : ℕ) (_ : i < l.length), p l[i] := by
simp [mem_iff_getElem, @forall_swap α]
theorem get_tail (l : List α) (i) (h : i < l.tail.length)
(h' : i + 1 < l.length := (by simp only [length_tail] at h; omega)) :
l.tail.get ⟨i, h⟩ = l.get ⟨i + 1, h'⟩ := by
cases l <;> [cases h; rfl]
/-! ### sublists -/
attribute [refl] List.Sublist.refl
theorem Sublist.cons_cons {l₁ l₂ : List α} (a : α) (s : l₁ <+ l₂) : a :: l₁ <+ a :: l₂ :=
Sublist.cons₂ _ s
lemma cons_sublist_cons' {a b : α} : a :: l₁ <+ b :: l₂ ↔ a :: l₁ <+ l₂ ∨ a = b ∧ l₁ <+ l₂ := by
constructor
· rintro (_ | _)
· exact Or.inl ‹_›
· exact Or.inr ⟨rfl, ‹_›⟩
· rintro (h | ⟨rfl, h⟩)
· exact h.cons _
· rwa [cons_sublist_cons]
theorem sublist_cons_of_sublist (a : α) (h : l₁ <+ l₂) : l₁ <+ a :: l₂ := h.cons _
@[deprecated (since := "2025-02-07")]
alias sublist_nil_iff_eq_nil := sublist_nil
@[simp] lemma sublist_singleton {l : List α} {a : α} : l <+ [a] ↔ l = [] ∨ l = [a] := by
constructor <;> rintro (_ | _) <;> aesop
theorem Sublist.antisymm (s₁ : l₁ <+ l₂) (s₂ : l₂ <+ l₁) : l₁ = l₂ :=
s₁.eq_of_length_le s₂.length_le
/-- If the first element of two lists are different, then a sublist relation can be reduced. -/
theorem Sublist.of_cons_of_ne {a b} (h₁ : a ≠ b) (h₂ : a :: l₁ <+ b :: l₂) : a :: l₁ <+ l₂ :=
match h₁, h₂ with
| _, .cons _ h => h
/-! ### indexOf -/
section IndexOf
variable [DecidableEq α]
theorem idxOf_cons_eq {a b : α} (l : List α) : b = a → idxOf a (b :: l) = 0
| e => by rw [← e]; exact idxOf_cons_self
@[deprecated (since := "2025-01-30")] alias indexOf_cons_eq := idxOf_cons_eq
@[simp]
theorem idxOf_cons_ne {a b : α} (l : List α) : b ≠ a → idxOf a (b :: l) = succ (idxOf a l)
| h => by simp only [idxOf_cons, Bool.cond_eq_ite, beq_iff_eq, if_neg h]
@[deprecated (since := "2025-01-30")] alias indexOf_cons_ne := idxOf_cons_ne
theorem idxOf_eq_length_iff {a : α} {l : List α} : idxOf a l = length l ↔ a ∉ l := by
induction l with
| nil => exact iff_of_true rfl not_mem_nil
| cons b l ih =>
simp only [length, mem_cons, idxOf_cons, eq_comm]
rw [cond_eq_if]
split_ifs with h <;> simp at h
· exact iff_of_false (by rintro ⟨⟩) fun H => H <| Or.inl h.symm
· simp only [Ne.symm h, false_or]
rw [← ih]
exact succ_inj
@[simp]
theorem idxOf_of_not_mem {l : List α} {a : α} : a ∉ l → idxOf a l = length l :=
idxOf_eq_length_iff.2
@[deprecated (since := "2025-01-30")] alias indexOf_of_not_mem := idxOf_of_not_mem
theorem idxOf_le_length {a : α} {l : List α} : idxOf a l ≤ length l := by
induction l with | nil => rfl | cons b l ih => ?_
simp only [length, idxOf_cons, cond_eq_if, beq_iff_eq]
by_cases h : b = a
· rw [if_pos h]; exact Nat.zero_le _
· rw [if_neg h]; exact succ_le_succ ih
@[deprecated (since := "2025-01-30")] alias indexOf_le_length := idxOf_le_length
theorem idxOf_lt_length_iff {a} {l : List α} : idxOf a l < length l ↔ a ∈ l :=
⟨fun h => Decidable.byContradiction fun al => Nat.ne_of_lt h <| idxOf_eq_length_iff.2 al,
fun al => (lt_of_le_of_ne idxOf_le_length) fun h => idxOf_eq_length_iff.1 h al⟩
@[deprecated (since := "2025-01-30")] alias indexOf_lt_length_iff := idxOf_lt_length_iff
theorem idxOf_append_of_mem {a : α} (h : a ∈ l₁) : idxOf a (l₁ ++ l₂) = idxOf a l₁ := by
induction l₁ with
| nil =>
exfalso
exact not_mem_nil h
| cons d₁ t₁ ih =>
rw [List.cons_append]
by_cases hh : d₁ = a
· iterate 2 rw [idxOf_cons_eq _ hh]
rw [idxOf_cons_ne _ hh, idxOf_cons_ne _ hh, ih (mem_of_ne_of_mem (Ne.symm hh) h)]
@[deprecated (since := "2025-01-30")] alias indexOf_append_of_mem := idxOf_append_of_mem
theorem idxOf_append_of_not_mem {a : α} (h : a ∉ l₁) :
idxOf a (l₁ ++ l₂) = l₁.length + idxOf a l₂ := by
induction l₁ with
| nil => rw [List.nil_append, List.length, Nat.zero_add]
| cons d₁ t₁ ih =>
rw [List.cons_append, idxOf_cons_ne _ (ne_of_not_mem_cons h).symm, List.length,
ih (not_mem_of_not_mem_cons h), Nat.succ_add]
@[deprecated (since := "2025-01-30")] alias indexOf_append_of_not_mem := idxOf_append_of_not_mem
end IndexOf
/-! ### nth element -/
section deprecated
@[simp]
theorem getElem?_length (l : List α) : l[l.length]? = none := getElem?_eq_none le_rfl
/-- A version of `getElem_map` that can be used for rewriting. -/
theorem getElem_map_rev (f : α → β) {l} {n : Nat} {h : n < l.length} :
f l[n] = (map f l)[n]'((l.length_map f).symm ▸ h) := Eq.symm (getElem_map _)
theorem get_length_sub_one {l : List α} (h : l.length - 1 < l.length) :
l.get ⟨l.length - 1, h⟩ = l.getLast (by rintro rfl; exact Nat.lt_irrefl 0 h) :=
(getLast_eq_getElem _).symm
theorem take_one_drop_eq_of_lt_length {l : List α} {n : ℕ} (h : n < l.length) :
(l.drop n).take 1 = [l.get ⟨n, h⟩] := by
rw [drop_eq_getElem_cons h, take, take]
simp
theorem ext_getElem?' {l₁ l₂ : List α} (h' : ∀ n < max l₁.length l₂.length, l₁[n]? = l₂[n]?) :
l₁ = l₂ := by
apply ext_getElem?
intro n
rcases Nat.lt_or_ge n <| max l₁.length l₂.length with hn | hn
· exact h' n hn
· simp_all [Nat.max_le, getElem?_eq_none]
@[deprecated (since := "2025-02-15")] alias ext_get?' := ext_getElem?'
@[deprecated (since := "2025-02-15")] alias ext_get?_iff := List.ext_getElem?_iff
theorem ext_get_iff {l₁ l₂ : List α} :
l₁ = l₂ ↔ l₁.length = l₂.length ∧ ∀ n h₁ h₂, get l₁ ⟨n, h₁⟩ = get l₂ ⟨n, h₂⟩ := by
constructor
· rintro rfl
exact ⟨rfl, fun _ _ _ ↦ rfl⟩
· intro ⟨h₁, h₂⟩
exact ext_get h₁ h₂
theorem ext_getElem?_iff' {l₁ l₂ : List α} : l₁ = l₂ ↔
∀ n < max l₁.length l₂.length, l₁[n]? = l₂[n]? :=
⟨by rintro rfl _ _; rfl, ext_getElem?'⟩
@[deprecated (since := "2025-02-15")] alias ext_get?_iff' := ext_getElem?_iff'
/-- If two lists `l₁` and `l₂` are the same length and `l₁[n]! = l₂[n]!` for all `n`,
then the lists are equal. -/
theorem ext_getElem! [Inhabited α] (hl : length l₁ = length l₂) (h : ∀ n : ℕ, l₁[n]! = l₂[n]!) :
l₁ = l₂ :=
ext_getElem hl fun n h₁ h₂ ↦ by simpa only [← getElem!_pos] using h n
@[simp]
theorem getElem_idxOf [DecidableEq α] {a : α} : ∀ {l : List α} (h : idxOf a l < l.length),
l[idxOf a l] = a
| b :: l, h => by
by_cases h' : b = a <;>
simp [h', if_pos, if_false, getElem_idxOf]
@[deprecated (since := "2025-01-30")] alias getElem_indexOf := getElem_idxOf
-- This is incorrectly named and should be `get_idxOf`;
-- this already exists, so will require a deprecation dance.
theorem idxOf_get [DecidableEq α] {a : α} {l : List α} (h) : get l ⟨idxOf a l, h⟩ = a := by
simp
@[deprecated (since := "2025-01-30")] alias indexOf_get := idxOf_get
@[simp]
theorem getElem?_idxOf [DecidableEq α] {a : α} {l : List α} (h : a ∈ l) :
l[idxOf a l]? = some a := by
rw [getElem?_eq_getElem, getElem_idxOf (idxOf_lt_length_iff.2 h)]
@[deprecated (since := "2025-01-30")] alias getElem?_indexOf := getElem?_idxOf
@[deprecated (since := "2025-02-15")] alias idxOf_get? := getElem?_idxOf
@[deprecated (since := "2025-01-30")] alias indexOf_get? := getElem?_idxOf
theorem idxOf_inj [DecidableEq α] {l : List α} {x y : α} (hx : x ∈ l) (hy : y ∈ l) :
idxOf x l = idxOf y l ↔ x = y :=
⟨fun h => by
have x_eq_y :
get l ⟨idxOf x l, idxOf_lt_length_iff.2 hx⟩ =
get l ⟨idxOf y l, idxOf_lt_length_iff.2 hy⟩ := by
simp only [h]
simp only [idxOf_get] at x_eq_y; exact x_eq_y, fun h => by subst h; rfl⟩
@[deprecated (since := "2025-01-30")] alias indexOf_inj := idxOf_inj
theorem get_reverse' (l : List α) (n) (hn') :
l.reverse.get n = l.get ⟨l.length - 1 - n, hn'⟩ := by
simp
theorem eq_cons_of_length_one {l : List α} (h : l.length = 1) : l = [l.get ⟨0, by omega⟩] := by
refine ext_get (by convert h) fun n h₁ h₂ => ?_
simp
congr
omega
end deprecated
@[simp]
theorem getElem_set_of_ne {l : List α} {i j : ℕ} (h : i ≠ j) (a : α)
(hj : j < (l.set i a).length) :
(l.set i a)[j] = l[j]'(by simpa using hj) := by
rw [← Option.some_inj, ← List.getElem?_eq_getElem, List.getElem?_set_ne h,
List.getElem?_eq_getElem]
/-! ### map -/
-- `List.map_const` (the version with `Function.const` instead of a lambda) is already tagged
-- `simp` in Core
-- TODO: Upstream the tagging to Core?
attribute [simp] map_const'
theorem flatMap_pure_eq_map (f : α → β) (l : List α) : l.flatMap (pure ∘ f) = map f l :=
.symm <| map_eq_flatMap ..
theorem flatMap_congr {l : List α} {f g : α → List β} (h : ∀ x ∈ l, f x = g x) :
l.flatMap f = l.flatMap g :=
(congr_arg List.flatten <| map_congr_left h :)
theorem infix_flatMap_of_mem {a : α} {as : List α} (h : a ∈ as) (f : α → List α) :
f a <:+: as.flatMap f :=
infix_of_mem_flatten (mem_map_of_mem h)
@[simp]
theorem map_eq_map {α β} (f : α → β) (l : List α) : f <$> l = map f l :=
rfl
/-- A single `List.map` of a composition of functions is equal to
composing a `List.map` with another `List.map`, fully applied.
This is the reverse direction of `List.map_map`.
-/
theorem comp_map (h : β → γ) (g : α → β) (l : List α) : map (h ∘ g) l = map h (map g l) :=
map_map.symm
/-- Composing a `List.map` with another `List.map` is equal to
a single `List.map` of composed functions.
-/
@[simp]
theorem map_comp_map (g : β → γ) (f : α → β) : map g ∘ map f = map (g ∘ f) := by
ext l; rw [comp_map, Function.comp_apply]
section map_bijectivity
theorem _root_.Function.LeftInverse.list_map {f : α → β} {g : β → α} (h : LeftInverse f g) :
LeftInverse (map f) (map g)
| [] => by simp_rw [map_nil]
| x :: xs => by simp_rw [map_cons, h x, h.list_map xs]
nonrec theorem _root_.Function.RightInverse.list_map {f : α → β} {g : β → α}
(h : RightInverse f g) : RightInverse (map f) (map g) :=
h.list_map
nonrec theorem _root_.Function.Involutive.list_map {f : α → α}
(h : Involutive f) : Involutive (map f) :=
Function.LeftInverse.list_map h
@[simp]
theorem map_leftInverse_iff {f : α → β} {g : β → α} :
LeftInverse (map f) (map g) ↔ LeftInverse f g :=
⟨fun h x => by injection h [x], (·.list_map)⟩
@[simp]
theorem map_rightInverse_iff {f : α → β} {g : β → α} :
RightInverse (map f) (map g) ↔ RightInverse f g := map_leftInverse_iff
@[simp]
theorem map_involutive_iff {f : α → α} :
Involutive (map f) ↔ Involutive f := map_leftInverse_iff
theorem _root_.Function.Injective.list_map {f : α → β} (h : Injective f) :
Injective (map f)
| [], [], _ => rfl
| x :: xs, y :: ys, hxy => by
injection hxy with hxy hxys
rw [h hxy, h.list_map hxys]
@[simp]
theorem map_injective_iff {f : α → β} : Injective (map f) ↔ Injective f := by
refine ⟨fun h x y hxy => ?_, (·.list_map)⟩
suffices [x] = [y] by simpa using this
apply h
simp [hxy]
theorem _root_.Function.Surjective.list_map {f : α → β} (h : Surjective f) :
Surjective (map f) :=
let ⟨_, h⟩ := h.hasRightInverse; h.list_map.surjective
@[simp]
theorem map_surjective_iff {f : α → β} : Surjective (map f) ↔ Surjective f := by
refine ⟨fun h x => ?_, (·.list_map)⟩
let ⟨[y], hxy⟩ := h [x]
exact ⟨_, List.singleton_injective hxy⟩
theorem _root_.Function.Bijective.list_map {f : α → β} (h : Bijective f) : Bijective (map f) :=
⟨h.1.list_map, h.2.list_map⟩
@[simp]
theorem map_bijective_iff {f : α → β} : Bijective (map f) ↔ Bijective f := by
simp_rw [Function.Bijective, map_injective_iff, map_surjective_iff]
end map_bijectivity
theorem eq_of_mem_map_const {b₁ b₂ : β} {l : List α} (h : b₁ ∈ map (const α b₂) l) :
b₁ = b₂ := by rw [map_const] at h; exact eq_of_mem_replicate h
/-- `eq_nil_or_concat` in simp normal form -/
lemma eq_nil_or_concat' (l : List α) : l = [] ∨ ∃ L b, l = L ++ [b] := by
simpa using l.eq_nil_or_concat
/-! ### foldl, foldr -/
theorem foldl_ext (f g : α → β → α) (a : α) {l : List β} (H : ∀ a : α, ∀ b ∈ l, f a b = g a b) :
foldl f a l = foldl g a l := by
induction l generalizing a with
| nil => rfl
| cons hd tl ih =>
unfold foldl
rw [ih _ fun a b bin => H a b <| mem_cons_of_mem _ bin, H a hd mem_cons_self]
theorem foldr_ext (f g : α → β → β) (b : β) {l : List α} (H : ∀ a ∈ l, ∀ b : β, f a b = g a b) :
foldr f b l = foldr g b l := by
induction l with | nil => rfl | cons hd tl ih => ?_
simp only [mem_cons, or_imp, forall_and, forall_eq] at H
simp only [foldr, ih H.2, H.1]
theorem foldl_concat
(f : β → α → β) (b : β) (x : α) (xs : List α) :
List.foldl f b (xs ++ [x]) = f (List.foldl f b xs) x := by
simp only [List.foldl_append, List.foldl]
theorem foldr_concat
(f : α → β → β) (b : β) (x : α) (xs : List α) :
List.foldr f b (xs ++ [x]) = (List.foldr f (f x b) xs) := by
simp only [List.foldr_append, List.foldr]
theorem foldl_fixed' {f : α → β → α} {a : α} (hf : ∀ b, f a b = a) : ∀ l : List β, foldl f a l = a
| [] => rfl
| b :: l => by rw [foldl_cons, hf b, foldl_fixed' hf l]
theorem foldr_fixed' {f : α → β → β} {b : β} (hf : ∀ a, f a b = b) : ∀ l : List α, foldr f b l = b
| [] => rfl
| a :: l => by rw [foldr_cons, foldr_fixed' hf l, hf a]
@[simp]
theorem foldl_fixed {a : α} : ∀ l : List β, foldl (fun a _ => a) a l = a :=
foldl_fixed' fun _ => rfl
@[simp]
theorem foldr_fixed {b : β} : ∀ l : List α, foldr (fun _ b => b) b l = b :=
foldr_fixed' fun _ => rfl
@[deprecated foldr_cons_nil (since := "2025-02-10")]
theorem foldr_eta (l : List α) : foldr cons [] l = l := foldr_cons_nil
theorem reverse_foldl {l : List α} : reverse (foldl (fun t h => h :: t) [] l) = l := by
simp
theorem foldl_hom₂ (l : List ι) (f : α → β → γ) (op₁ : α → ι → α) (op₂ : β → ι → β)
(op₃ : γ → ι → γ) (a : α) (b : β) (h : ∀ a b i, f (op₁ a i) (op₂ b i) = op₃ (f a b) i) :
foldl op₃ (f a b) l = f (foldl op₁ a l) (foldl op₂ b l) :=
Eq.symm <| by
revert a b
induction l <;> intros <;> [rfl; simp only [*, foldl]]
theorem foldr_hom₂ (l : List ι) (f : α → β → γ) (op₁ : ι → α → α) (op₂ : ι → β → β)
(op₃ : ι → γ → γ) (a : α) (b : β) (h : ∀ a b i, f (op₁ i a) (op₂ i b) = op₃ i (f a b)) :
foldr op₃ (f a b) l = f (foldr op₁ a l) (foldr op₂ b l) := by
revert a
induction l <;> intros <;> [rfl; simp only [*, foldr]]
theorem injective_foldl_comp {l : List (α → α)} {f : α → α}
(hl : ∀ f ∈ l, Function.Injective f) (hf : Function.Injective f) :
Function.Injective (@List.foldl (α → α) (α → α) Function.comp f l) := by
induction l generalizing f with
| nil => exact hf
| cons lh lt l_ih =>
apply l_ih fun _ h => hl _ (List.mem_cons_of_mem _ h)
apply Function.Injective.comp hf
apply hl _ mem_cons_self
/-- Consider two lists `l₁` and `l₂` with designated elements `a₁` and `a₂` somewhere in them:
`l₁ = x₁ ++ [a₁] ++ z₁` and `l₂ = x₂ ++ [a₂] ++ z₂`.
Assume the designated element `a₂` is present in neither `x₁` nor `z₁`.
We conclude that the lists are equal (`l₁ = l₂`) if and only if their respective parts are equal
(`x₁ = x₂ ∧ a₁ = a₂ ∧ z₁ = z₂`). -/
lemma append_cons_inj_of_not_mem {x₁ x₂ z₁ z₂ : List α} {a₁ a₂ : α}
(notin_x : a₂ ∉ x₁) (notin_z : a₂ ∉ z₁) :
x₁ ++ a₁ :: z₁ = x₂ ++ a₂ :: z₂ ↔ x₁ = x₂ ∧ a₁ = a₂ ∧ z₁ = z₂ := by
constructor
· simp only [append_eq_append_iff, cons_eq_append_iff, cons_eq_cons]
rintro (⟨c, rfl, ⟨rfl, rfl, rfl⟩ | ⟨d, rfl, rfl⟩⟩ |
⟨c, rfl, ⟨rfl, rfl, rfl⟩ | ⟨d, rfl, rfl⟩⟩) <;> simp_all
· rintro ⟨rfl, rfl, rfl⟩
rfl
section FoldlEqFoldr
-- foldl and foldr coincide when f is commutative and associative
variable {f : α → α → α}
theorem foldl1_eq_foldr1 [hassoc : Std.Associative f] :
∀ a b l, foldl f a (l ++ [b]) = foldr f b (a :: l)
| _, _, nil => rfl
| a, b, c :: l => by
simp only [cons_append, foldl_cons, foldr_cons, foldl1_eq_foldr1 _ _ l]
rw [hassoc.assoc]
theorem foldl_eq_of_comm_of_assoc [hcomm : Std.Commutative f] [hassoc : Std.Associative f] :
∀ a b l, foldl f a (b :: l) = f b (foldl f a l)
| a, b, nil => hcomm.comm a b
| a, b, c :: l => by
simp only [foldl_cons]
have : RightCommutative f := inferInstance
rw [← foldl_eq_of_comm_of_assoc .., this.right_comm, foldl_cons]
theorem foldl_eq_foldr [Std.Commutative f] [Std.Associative f] :
∀ a l, foldl f a l = foldr f a l
| _, nil => rfl
| a, b :: l => by
simp only [foldr_cons, foldl_eq_of_comm_of_assoc]
rw [foldl_eq_foldr a l]
end FoldlEqFoldr
section FoldlEqFoldlr'
variable {f : α → β → α}
variable (hf : ∀ a b c, f (f a b) c = f (f a c) b)
include hf
theorem foldl_eq_of_comm' : ∀ a b l, foldl f a (b :: l) = f (foldl f a l) b
| _, _, [] => rfl
| a, b, c :: l => by rw [foldl, foldl, foldl, ← foldl_eq_of_comm' .., foldl, hf]
theorem foldl_eq_foldr' : ∀ a l, foldl f a l = foldr (flip f) a l
| _, [] => rfl
| a, b :: l => by rw [foldl_eq_of_comm' hf, foldr, foldl_eq_foldr' ..]; rfl
end FoldlEqFoldlr'
section FoldlEqFoldlr'
variable {f : α → β → β}
theorem foldr_eq_of_comm' (hf : ∀ a b c, f a (f b c) = f b (f a c)) :
∀ a b l, foldr f a (b :: l) = foldr f (f b a) l
| _, _, [] => rfl
| a, b, c :: l => by rw [foldr, foldr, foldr, hf, ← foldr_eq_of_comm' hf ..]; rfl
end FoldlEqFoldlr'
section
variable {op : α → α → α} [ha : Std.Associative op]
/-- Notation for `op a b`. -/
local notation a " ⋆ " b => op a b
/-- Notation for `foldl op a l`. -/
local notation l " <*> " a => foldl op a l
theorem foldl_op_eq_op_foldr_assoc :
∀ {l : List α} {a₁ a₂}, ((l <*> a₁) ⋆ a₂) = a₁ ⋆ l.foldr (· ⋆ ·) a₂
| [], _, _ => rfl
| a :: l, a₁, a₂ => by
simp only [foldl_cons, foldr_cons, foldl_assoc, ha.assoc]; rw [foldl_op_eq_op_foldr_assoc]
variable [hc : Std.Commutative op]
theorem foldl_assoc_comm_cons {l : List α} {a₁ a₂} : ((a₁ :: l) <*> a₂) = a₁ ⋆ l <*> a₂ := by
rw [foldl_cons, hc.comm, foldl_assoc]
end
/-! ### foldlM, foldrM, mapM -/
section FoldlMFoldrM
variable {m : Type v → Type w} [Monad m]
variable [LawfulMonad m]
theorem foldrM_eq_foldr (f : α → β → m β) (b l) :
foldrM f b l = foldr (fun a mb => mb >>= f a) (pure b) l := by induction l <;> simp [*]
theorem foldlM_eq_foldl (f : β → α → m β) (b l) :
List.foldlM f b l = foldl (fun mb a => mb >>= fun b => f b a) (pure b) l := by
suffices h :
∀ mb : m β, (mb >>= fun b => List.foldlM f b l) = foldl (fun mb a => mb >>= fun b => f b a) mb l
by simp [← h (pure b)]
induction l with
| nil => intro; simp
| cons _ _ l_ih => intro; simp only [List.foldlM, foldl, ← l_ih, functor_norm]
end FoldlMFoldrM
/-! ### intersperse -/
@[deprecated (since := "2025-02-07")] alias intersperse_singleton := intersperse_single
@[deprecated (since := "2025-02-07")] alias intersperse_cons_cons := intersperse_cons₂
|
/-! ### map for partial functions -/
@[deprecated "Deprecated without replacement." (since := "2025-02-07")]
theorem sizeOf_lt_sizeOf_of_mem [SizeOf α] {x : α} {l : List α} (hx : x ∈ l) :
SizeOf.sizeOf x < SizeOf.sizeOf l := by
induction l with | nil => ?_ | cons h t ih => ?_ <;> cases hx <;> rw [cons.sizeOf_spec]
· omega
· specialize ih ‹_›
omega
/-! ### filter -/
theorem length_eq_length_filter_add {l : List (α)} (f : α → Bool) :
l.length = (l.filter f).length + (l.filter (! f ·)).length := by
simp_rw [← List.countP_eq_length_filter, l.length_eq_countP_add_countP f, Bool.not_eq_true,
Bool.decide_eq_false]
/-! ### filterMap -/
theorem filterMap_eq_flatMap_toList (f : α → Option β) (l : List α) :
| Mathlib/Data/List/Basic.lean | 996 | 1,016 |
/-
Copyright (c) 2020 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov
-/
import Mathlib.Logic.Function.Iterate
import Mathlib.Order.Monotone.Basic
/-!
# Inequalities on iterates
In this file we prove some inequalities comparing `f^[n] x` and `g^[n] x` where `f` and `g` are
two self-maps that commute with each other.
Current selection of inequalities is motivated by formalization of the rotation number of
a circle homeomorphism.
-/
open Function
open Function (Commute)
namespace Monotone
variable {α : Type*} [Preorder α] {f : α → α} {x y : ℕ → α}
/-!
### Comparison of two sequences
If $f$ is a monotone function, then $∀ k, x_{k+1} ≤ f(x_k)$ implies that $x_k$ grows slower than
$f^k(x_0)$, and similarly for the reversed inequalities. If $x_k$ and $y_k$ are two sequences such
that $x_{k+1} ≤ f(x_k)$ and $y_{k+1} ≥ f(y_k)$ for all $k < n$, then $x_0 ≤ y_0$ implies
$x_n ≤ y_n$, see `Monotone.seq_le_seq`.
If some of the inequalities in this lemma are strict, then we have $x_n < y_n$. The rest of the
lemmas in this section formalize this fact for different inequalities made strict.
-/
theorem seq_le_seq (hf : Monotone f) (n : ℕ) (h₀ : x 0 ≤ y 0) (hx : ∀ k < n, x (k + 1) ≤ f (x k))
(hy : ∀ k < n, f (y k) ≤ y (k + 1)) : x n ≤ y n := by
induction n with
| zero => exact h₀
| succ n ihn =>
refine (hx _ n.lt_succ_self).trans ((hf <| ihn ?_ ?_).trans (hy _ n.lt_succ_self))
· exact fun k hk => hx _ (hk.trans n.lt_succ_self)
· exact fun k hk => hy _ (hk.trans n.lt_succ_self)
theorem seq_pos_lt_seq_of_lt_of_le (hf : Monotone f) {n : ℕ} (hn : 0 < n) (h₀ : x 0 ≤ y 0)
(hx : ∀ k < n, x (k + 1) < f (x k)) (hy : ∀ k < n, f (y k) ≤ y (k + 1)) : x n < y n := by
induction n with
| zero => exact hn.false.elim
| succ n ihn =>
suffices x n ≤ y n from (hx n n.lt_succ_self).trans_le ((hf this).trans <| hy n n.lt_succ_self)
cases n with
| zero => exact h₀
| succ n =>
refine (ihn n.zero_lt_succ (fun k hk => hx _ ?_) fun k hk => hy _ ?_).le <;>
exact hk.trans n.succ.lt_succ_self
theorem seq_pos_lt_seq_of_le_of_lt (hf : Monotone f) {n : ℕ} (hn : 0 < n) (h₀ : x 0 ≤ y 0)
(hx : ∀ k < n, x (k + 1) ≤ f (x k)) (hy : ∀ k < n, f (y k) < y (k + 1)) : x n < y n :=
hf.dual.seq_pos_lt_seq_of_lt_of_le hn h₀ hy hx
theorem seq_lt_seq_of_lt_of_le (hf : Monotone f) (n : ℕ) (h₀ : x 0 < y 0)
(hx : ∀ k < n, x (k + 1) < f (x k)) (hy : ∀ k < n, f (y k) ≤ y (k + 1)) : x n < y n := by
cases n
exacts [h₀, hf.seq_pos_lt_seq_of_lt_of_le (Nat.zero_lt_succ _) h₀.le hx hy]
theorem seq_lt_seq_of_le_of_lt (hf : Monotone f) (n : ℕ) (h₀ : x 0 < y 0)
(hx : ∀ k < n, x (k + 1) ≤ f (x k)) (hy : ∀ k < n, f (y k) < y (k + 1)) : x n < y n :=
hf.dual.seq_lt_seq_of_lt_of_le n h₀ hy hx
/-!
### Iterates of two functions
In this section we compare the iterates of a monotone function `f : α → α` to iterates of any
function `g : β → β`. If `h : β → α` satisfies `h ∘ g ≤ f ∘ h`, then `h (g^[n] x)` grows slower
than `f^[n] (h x)`, and similarly for the reversed inequality.
Then we specialize these two lemmas to the case `β = α`, `h = id`.
-/
variable {β : Type*} {g : β → β} {h : β → α}
open Function
theorem le_iterate_comp_of_le (hf : Monotone f) (H : h ∘ g ≤ f ∘ h) (n : ℕ) :
h ∘ g^[n] ≤ f^[n] ∘ h := fun x => by
apply hf.seq_le_seq n <;> intros <;>
simp [iterate_succ', -iterate_succ, comp_apply, id_eq, le_refl]
case hx => exact H _
theorem iterate_comp_le_of_le (hf : Monotone f) (H : f ∘ h ≤ h ∘ g) (n : ℕ) :
f^[n] ∘ h ≤ h ∘ g^[n] :=
hf.dual.le_iterate_comp_of_le H n
/-- If `f ≤ g` and `f` is monotone, then `f^[n] ≤ g^[n]`. -/
theorem iterate_le_of_le {g : α → α} (hf : Monotone f) (h : f ≤ g) (n : ℕ) : f^[n] ≤ g^[n] :=
hf.iterate_comp_le_of_le h n
/-- If `f ≤ g` and `g` is monotone, then `f^[n] ≤ g^[n]`. -/
theorem le_iterate_of_le {g : α → α} (hg : Monotone g) (h : f ≤ g) (n : ℕ) : f^[n] ≤ g^[n] :=
hg.dual.iterate_le_of_le h n
end Monotone
/-!
### Comparison of iterations and the identity function
If $f(x) ≤ x$ for all $x$ (we express this as `f ≤ id` in the code), then the same is true for
any iterate of $f$, and similarly for the reversed inequality.
-/
namespace Function
section Preorder
variable {α : Type*} [Preorder α] {f : α → α}
/-- If $x ≤ f x$ for all $x$ (we write this as `id ≤ f`), then the same is true for any iterate
`f^[n]` of `f`. -/
theorem id_le_iterate_of_id_le (h : id ≤ f) (n : ℕ) : id ≤ f^[n] := by
simpa only [iterate_id] using monotone_id.iterate_le_of_le h n
theorem iterate_le_id_of_le_id (h : f ≤ id) (n : ℕ) : f^[n] ≤ id :=
@id_le_iterate_of_id_le αᵒᵈ _ f h n
theorem monotone_iterate_of_id_le (h : id ≤ f) : Monotone fun m => f^[m] :=
monotone_nat_of_le_succ fun n x => by
rw [iterate_succ_apply']
exact h _
theorem antitone_iterate_of_le_id (h : f ≤ id) : Antitone fun m => f^[m] := fun m n hmn =>
@monotone_iterate_of_id_le αᵒᵈ _ f h m n hmn
end Preorder
/-!
### Iterates of commuting functions
If `f` and `g` are monotone and commute, then `f x ≤ g x` implies `f^[n] x ≤ g^[n] x`, see
`Function.Commute.iterate_le_of_map_le`. We also prove two strict inequality versions of this lemma,
as well as `iff` versions.
-/
namespace Commute
section Preorder
variable {α : Type*} [Preorder α] {f g : α → α}
theorem iterate_le_of_map_le (h : Commute f g) (hf : Monotone f) (hg : Monotone g) {x}
(hx : f x ≤ g x) (n : ℕ) : f^[n] x ≤ g^[n] x := by
apply hf.seq_le_seq n
· rfl
· intros; rw [iterate_succ_apply']
· intros; simp [h.iterate_right _ _, hg.iterate _ hx]
theorem iterate_pos_lt_of_map_lt (h : Commute f g) (hf : Monotone f) (hg : StrictMono g) {x}
(hx : f x < g x) {n} (hn : 0 < n) : f^[n] x < g^[n] x := by
apply hf.seq_pos_lt_seq_of_le_of_lt hn
· rfl
· intros; rw [iterate_succ_apply']
· intros; simp [h.iterate_right _ _, hg.iterate _ hx]
theorem iterate_pos_lt_of_map_lt' (h : Commute f g) (hf : StrictMono f) (hg : Monotone g) {x}
(hx : f x < g x) {n} (hn : 0 < n) : f^[n] x < g^[n] x :=
@iterate_pos_lt_of_map_lt αᵒᵈ _ g f h.symm hg.dual hf.dual x hx n hn
end Preorder
variable {α : Type*} [LinearOrder α] {f g : α → α}
|
theorem iterate_pos_lt_iff_map_lt (h : Commute f g) (hf : Monotone f) (hg : StrictMono g) {x n}
(hn : 0 < n) : f^[n] x < g^[n] x ↔ f x < g x := by
rcases lt_trichotomy (f x) (g x) with (H | H | H)
· simp only [*, iterate_pos_lt_of_map_lt]
· simp only [*, h.iterate_eq_of_map_eq, lt_irrefl]
| Mathlib/Order/Iterate.lean | 177 | 182 |
/-
Copyright (c) 2020 Rémy Degenne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Rémy Degenne
-/
import Mathlib.Analysis.MeanInequalities
import Mathlib.Analysis.MeanInequalitiesPow
import Mathlib.MeasureTheory.Function.SpecialFunctions.Basic
import Mathlib.MeasureTheory.Integral.Lebesgue.Add
/-!
# Mean value inequalities for integrals
In this file we prove several inequalities on integrals, notably the Hölder inequality and
the Minkowski inequality. The versions for finite sums are in `Analysis.MeanInequalities`.
## Main results
Hölder's inequality for the Lebesgue integral of `ℝ≥0∞` and `ℝ≥0` functions: we prove
`∫ (f * g) ∂μ ≤ (∫ f^p ∂μ) ^ (1/p) * (∫ g^q ∂μ) ^ (1/q)` for `p`, `q` conjugate real exponents
and `α → (E)NNReal` functions in two cases,
* `ENNReal.lintegral_mul_le_Lp_mul_Lq` : ℝ≥0∞ functions,
* `NNReal.lintegral_mul_le_Lp_mul_Lq` : ℝ≥0 functions.
`ENNReal.lintegral_mul_norm_pow_le` is a variant where the exponents are not reciprocals:
`∫ (f ^ p * g ^ q) ∂μ ≤ (∫ f ∂μ) ^ p * (∫ g ∂μ) ^ q` where `p, q ≥ 0` and `p + q = 1`.
`ENNReal.lintegral_prod_norm_pow_le` generalizes this to a finite family of functions:
`∫ (∏ i, f i ^ p i) ∂μ ≤ ∏ i, (∫ f i ∂μ) ^ p i` when the `p` is a collection
of nonnegative weights with sum 1.
Minkowski's inequality for the Lebesgue integral of measurable functions with `ℝ≥0∞` values:
we prove `(∫ (f + g)^p ∂μ) ^ (1/p) ≤ (∫ f^p ∂μ) ^ (1/p) + (∫ g^p ∂μ) ^ (1/p)` for `1 ≤ p`.
-/
section LIntegral
/-!
### Hölder's inequality for the Lebesgue integral of ℝ≥0∞ and ℝ≥0 functions
We prove `∫ (f * g) ∂μ ≤ (∫ f^p ∂μ) ^ (1/p) * (∫ g^q ∂μ) ^ (1/q)` for `p`, `q`
conjugate real exponents and `α → (E)NNReal` functions in several cases, the first two being useful
only to prove the more general results:
* `ENNReal.lintegral_mul_le_one_of_lintegral_rpow_eq_one` : ℝ≥0∞ functions for which the
integrals on the right are equal to 1,
* `ENNReal.lintegral_mul_le_Lp_mul_Lq_of_ne_zero_of_ne_top` : ℝ≥0∞ functions for which the
integrals on the right are neither ⊤ nor 0,
* `ENNReal.lintegral_mul_le_Lp_mul_Lq` : ℝ≥0∞ functions,
* `NNReal.lintegral_mul_le_Lp_mul_Lq` : ℝ≥0 functions.
-/
noncomputable section
open NNReal ENNReal MeasureTheory Finset
variable {α : Type*} [MeasurableSpace α] {μ : Measure α}
namespace ENNReal
theorem lintegral_mul_le_one_of_lintegral_rpow_eq_one {p q : ℝ} (hpq : p.HolderConjugate q)
{f g : α → ℝ≥0∞} (hf : AEMeasurable f μ) (hf_norm : ∫⁻ a, f a ^ p ∂μ = 1)
(hg_norm : ∫⁻ a, g a ^ q ∂μ = 1) : (∫⁻ a, (f * g) a ∂μ) ≤ 1 := by
calc
(∫⁻ a : α, (f * g) a ∂μ) ≤
∫⁻ a : α, f a ^ p / ENNReal.ofReal p + g a ^ q / ENNReal.ofReal q ∂μ :=
lintegral_mono fun a => young_inequality (f a) (g a) hpq
_ = 1 := by
simp only [div_eq_mul_inv]
rw [lintegral_add_left']
· rw [lintegral_mul_const'' _ (hf.pow_const p), lintegral_mul_const', hf_norm, hg_norm,
one_mul, one_mul, hpq.inv_add_inv_ennreal]
simp [hpq.symm.pos]
· exact (hf.pow_const _).mul_const _
/-- Function multiplied by the inverse of its p-seminorm `(∫⁻ f^p ∂μ) ^ 1/p` -/
def funMulInvSnorm (f : α → ℝ≥0∞) (p : ℝ) (μ : Measure α) : α → ℝ≥0∞ := fun a =>
f a * ((∫⁻ c, f c ^ p ∂μ) ^ (1 / p))⁻¹
theorem fun_eq_funMulInvSnorm_mul_eLpNorm {p : ℝ} (f : α → ℝ≥0∞)
(hf_nonzero : (∫⁻ a, f a ^ p ∂μ) ≠ 0) (hf_top : (∫⁻ a, f a ^ p ∂μ) ≠ ⊤) {a : α} :
f a = funMulInvSnorm f p μ a * (∫⁻ c, f c ^ p ∂μ) ^ (1 / p) := by
simp [funMulInvSnorm, mul_assoc, ENNReal.inv_mul_cancel, hf_nonzero, hf_top]
theorem funMulInvSnorm_rpow {p : ℝ} (hp0 : 0 < p) {f : α → ℝ≥0∞} {a : α} :
funMulInvSnorm f p μ a ^ p = f a ^ p * (∫⁻ c, f c ^ p ∂μ)⁻¹ := by
rw [funMulInvSnorm, mul_rpow_of_nonneg _ _ (le_of_lt hp0)]
suffices h_inv_rpow : ((∫⁻ c : α, f c ^ p ∂μ) ^ (1 / p))⁻¹ ^ p = (∫⁻ c : α, f c ^ p ∂μ)⁻¹ by
rw [h_inv_rpow]
rw [inv_rpow, ← rpow_mul, one_div_mul_cancel hp0.ne', rpow_one]
theorem lintegral_rpow_funMulInvSnorm_eq_one {p : ℝ} (hp0_lt : 0 < p) {f : α → ℝ≥0∞}
(hf_nonzero : (∫⁻ a, f a ^ p ∂μ) ≠ 0) (hf_top : (∫⁻ a, f a ^ p ∂μ) ≠ ⊤) :
∫⁻ c, funMulInvSnorm f p μ c ^ p ∂μ = 1 := by
simp_rw [funMulInvSnorm_rpow hp0_lt]
rw [lintegral_mul_const', ENNReal.mul_inv_cancel hf_nonzero hf_top]
rwa [inv_ne_top]
/-- Hölder's inequality in case of finite non-zero integrals -/
theorem lintegral_mul_le_Lp_mul_Lq_of_ne_zero_of_ne_top {p q : ℝ} (hpq : p.HolderConjugate q)
{f g : α → ℝ≥0∞} (hf : AEMeasurable f μ) (hf_nontop : (∫⁻ a, f a ^ p ∂μ) ≠ ⊤)
(hg_nontop : (∫⁻ a, g a ^ q ∂μ) ≠ ⊤) (hf_nonzero : (∫⁻ a, f a ^ p ∂μ) ≠ 0)
(hg_nonzero : (∫⁻ a, g a ^ q ∂μ) ≠ 0) :
(∫⁻ a, (f * g) a ∂μ) ≤ (∫⁻ a, f a ^ p ∂μ) ^ (1 / p) * (∫⁻ a, g a ^ q ∂μ) ^ (1 / q) := by
let npf := (∫⁻ c : α, f c ^ p ∂μ) ^ (1 / p)
let nqg := (∫⁻ c : α, g c ^ q ∂μ) ^ (1 / q)
calc
(∫⁻ a : α, (f * g) a ∂μ) =
∫⁻ a : α, (funMulInvSnorm f p μ * funMulInvSnorm g q μ) a * (npf * nqg) ∂μ := by
refine lintegral_congr fun a => ?_
rw [Pi.mul_apply, fun_eq_funMulInvSnorm_mul_eLpNorm f hf_nonzero hf_nontop,
fun_eq_funMulInvSnorm_mul_eLpNorm g hg_nonzero hg_nontop, Pi.mul_apply]
ring
_ ≤ npf * nqg := by
rw [lintegral_mul_const' (npf * nqg) _
(by simp [npf, nqg, hf_nontop, hg_nontop, hf_nonzero, hg_nonzero, ENNReal.mul_eq_top])]
refine mul_le_of_le_one_left' ?_
have hf1 := lintegral_rpow_funMulInvSnorm_eq_one hpq.pos hf_nonzero hf_nontop
have hg1 := lintegral_rpow_funMulInvSnorm_eq_one hpq.symm.pos hg_nonzero hg_nontop
exact lintegral_mul_le_one_of_lintegral_rpow_eq_one hpq (hf.mul_const _) hf1 hg1
theorem ae_eq_zero_of_lintegral_rpow_eq_zero {p : ℝ} (hp0 : 0 ≤ p) {f : α → ℝ≥0∞}
(hf : AEMeasurable f μ) (hf_zero : ∫⁻ a, f a ^ p ∂μ = 0) : f =ᵐ[μ] 0 := by
rw [lintegral_eq_zero_iff' (hf.pow_const p)] at hf_zero
filter_upwards [hf_zero] with x
rw [Pi.zero_apply, ← not_imp_not]
exact fun hx => (rpow_pos_of_nonneg (pos_iff_ne_zero.2 hx) hp0).ne'
theorem lintegral_mul_eq_zero_of_lintegral_rpow_eq_zero {p : ℝ} (hp0 : 0 ≤ p) {f g : α → ℝ≥0∞}
(hf : AEMeasurable f μ) (hf_zero : ∫⁻ a, f a ^ p ∂μ = 0) : (∫⁻ a, (f * g) a ∂μ) = 0 := by
rw [← @lintegral_zero_fun α _ μ]
refine lintegral_congr_ae ?_
suffices h_mul_zero : f * g =ᵐ[μ] 0 * g by rwa [zero_mul] at h_mul_zero
have hf_eq_zero : f =ᵐ[μ] 0 := ae_eq_zero_of_lintegral_rpow_eq_zero hp0 hf hf_zero
exact hf_eq_zero.mul (ae_eq_refl g)
theorem lintegral_mul_le_Lp_mul_Lq_of_ne_zero_of_eq_top {p q : ℝ} (hp0_lt : 0 < p) (hq0 : 0 ≤ q)
{f g : α → ℝ≥0∞} (hf_top : ∫⁻ a, f a ^ p ∂μ = ⊤) (hg_nonzero : (∫⁻ a, g a ^ q ∂μ) ≠ 0) :
(∫⁻ a, (f * g) a ∂μ) ≤ (∫⁻ a, f a ^ p ∂μ) ^ (1 / p) * (∫⁻ a, g a ^ q ∂μ) ^ (1 / q) := by
refine le_trans le_top (le_of_eq ?_)
have hp0_inv_lt : 0 < 1 / p := by simp [hp0_lt]
rw [hf_top, ENNReal.top_rpow_of_pos hp0_inv_lt]
simp [hq0, hg_nonzero]
/-- Hölder's inequality for functions `α → ℝ≥0∞`. The integral of the product of two functions
is bounded by the product of their `ℒp` and `ℒq` seminorms when `p` and `q` are conjugate
exponents. -/
theorem lintegral_mul_le_Lp_mul_Lq (μ : Measure α) {p q : ℝ} (hpq : p.HolderConjugate q)
{f g : α → ℝ≥0∞} (hf : AEMeasurable f μ) (hg : AEMeasurable g μ) :
(∫⁻ a, (f * g) a ∂μ) ≤ (∫⁻ a, f a ^ p ∂μ) ^ (1 / p) * (∫⁻ a, g a ^ q ∂μ) ^ (1 / q) := by
by_cases hf_zero : ∫⁻ a, f a ^ p ∂μ = 0
· refine Eq.trans_le ?_ (zero_le _)
exact lintegral_mul_eq_zero_of_lintegral_rpow_eq_zero hpq.nonneg hf hf_zero
by_cases hg_zero : ∫⁻ a, g a ^ q ∂μ = 0
· refine Eq.trans_le ?_ (zero_le _)
rw [mul_comm]
exact lintegral_mul_eq_zero_of_lintegral_rpow_eq_zero hpq.symm.nonneg hg hg_zero
by_cases hf_top : ∫⁻ a, f a ^ p ∂μ = ⊤
· exact lintegral_mul_le_Lp_mul_Lq_of_ne_zero_of_eq_top hpq.pos hpq.symm.nonneg hf_top hg_zero
by_cases hg_top : ∫⁻ a, g a ^ q ∂μ = ⊤
· rw [mul_comm, mul_comm ((∫⁻ a : α, f a ^ p ∂μ) ^ (1 / p))]
exact lintegral_mul_le_Lp_mul_Lq_of_ne_zero_of_eq_top hpq.symm.pos hpq.nonneg hg_top hf_zero
-- non-⊤ non-zero case
exact ENNReal.lintegral_mul_le_Lp_mul_Lq_of_ne_zero_of_ne_top hpq hf hf_top hg_top hf_zero hg_zero
/-- A different formulation of Hölder's inequality for two functions, with two exponents that sum to
1, instead of reciprocals of -/
theorem lintegral_mul_norm_pow_le {α} [MeasurableSpace α] {μ : Measure α}
{f g : α → ℝ≥0∞} (hf : AEMeasurable f μ) (hg : AEMeasurable g μ)
{p q : ℝ} (hp : 0 ≤ p) (hq : 0 ≤ q) (hpq : p + q = 1) :
∫⁻ a, f a ^ p * g a ^ q ∂μ ≤ (∫⁻ a, f a ∂μ) ^ p * (∫⁻ a, g a ∂μ) ^ q := by
rcases hp.eq_or_lt with rfl|hp
· rw [zero_add] at hpq
simp [hpq]
rcases hq.eq_or_lt with rfl|hq
· rw [add_zero] at hpq
simp [hpq]
have h2p : 1 < 1 / p := by
rw [one_div, one_lt_inv₀ hp]
linarith
have h2pq : (1 / p)⁻¹ + (1 / q)⁻¹ = 1 := by simp [hp.ne', hq.ne', hpq]
have := ENNReal.lintegral_mul_le_Lp_mul_Lq μ (Real.holderConjugate_iff.mpr ⟨h2p, h2pq⟩)
(hf.pow_const p) (hg.pow_const q)
simpa [← ENNReal.rpow_mul, hp.ne', hq.ne'] using this
/-- A version of Hölder with multiple arguments -/
theorem lintegral_prod_norm_pow_le {α ι : Type*} [MeasurableSpace α] {μ : Measure α}
(s : Finset ι) {f : ι → α → ℝ≥0∞} (hf : ∀ i ∈ s, AEMeasurable (f i) μ)
{p : ι → ℝ} (hp : ∑ i ∈ s, p i = 1) (h2p : ∀ i ∈ s, 0 ≤ p i) :
∫⁻ a, ∏ i ∈ s, f i a ^ p i ∂μ ≤ ∏ i ∈ s, (∫⁻ a, f i a ∂μ) ^ p i := by
classical
induction s using Finset.induction generalizing p with
| empty =>
simp at hp
| insert i₀ s hi₀ ih =>
rcases eq_or_ne (p i₀) 1 with h2i₀|h2i₀
· simp only [hi₀, not_false_eq_true, prod_insert]
have h2p : ∀ i ∈ s, p i = 0 := by
simpa [hi₀, h2i₀, sum_eq_zero_iff_of_nonneg (fun i hi ↦ h2p i <| mem_insert_of_mem hi)]
using hp
calc ∫⁻ a, f i₀ a ^ p i₀ * ∏ i ∈ s, f i a ^ p i ∂μ
= ∫⁻ a, f i₀ a ^ p i₀ * ∏ i ∈ s, 1 ∂μ := by
congr! 3 with x
apply prod_congr rfl fun i hi ↦ by rw [h2p i hi, ENNReal.rpow_zero]
_ ≤ (∫⁻ a, f i₀ a ∂μ) ^ p i₀ * ∏ i ∈ s, 1 := by simp [h2i₀]
_ = (∫⁻ a, f i₀ a ∂μ) ^ p i₀ * ∏ i ∈ s, (∫⁻ a, f i a ∂μ) ^ p i := by
congr 1
apply prod_congr rfl fun i hi ↦ by rw [h2p i hi, ENNReal.rpow_zero]
· have hpi₀ : 0 ≤ 1 - p i₀ := by
simp_rw [sub_nonneg, ← hp, single_le_sum h2p (mem_insert_self ..)]
have h2pi₀ : 1 - p i₀ ≠ 0 := by
rwa [sub_ne_zero, ne_comm]
let q := fun i ↦ p i / (1 - p i₀)
have hq : ∑ i ∈ s, q i = 1 := by
rw [← Finset.sum_div, ← sum_insert_sub hi₀, hp, div_self h2pi₀]
have h2q : ∀ i ∈ s, 0 ≤ q i :=
fun i hi ↦ div_nonneg (h2p i <| mem_insert_of_mem hi) hpi₀
calc ∫⁻ a, ∏ i ∈ insert i₀ s, f i a ^ p i ∂μ
= ∫⁻ a, f i₀ a ^ p i₀ * ∏ i ∈ s, f i a ^ p i ∂μ := by simp [hi₀]
_ = ∫⁻ a, f i₀ a ^ p i₀ * (∏ i ∈ s, f i a ^ q i) ^ (1 - p i₀) ∂μ := by
simp [q, ← ENNReal.prod_rpow_of_nonneg hpi₀, ← ENNReal.rpow_mul,
div_mul_cancel₀ (h := h2pi₀)]
_ ≤ (∫⁻ a, f i₀ a ∂μ) ^ p i₀ * (∫⁻ a, ∏ i ∈ s, f i a ^ q i ∂μ) ^ (1 - p i₀) := by
apply ENNReal.lintegral_mul_norm_pow_le
· exact hf i₀ <| mem_insert_self ..
· exact s.aemeasurable_prod fun i hi ↦ (hf i <| mem_insert_of_mem hi).pow_const _
· exact h2p i₀ <| mem_insert_self ..
· exact hpi₀
· apply add_sub_cancel
_ ≤ (∫⁻ a, f i₀ a ∂μ) ^ p i₀ * (∏ i ∈ s, (∫⁻ a, f i a ∂μ) ^ q i) ^ (1 - p i₀) := by
gcongr -- behavior of gcongr is heartbeat-dependent, which makes code really fragile...
exact ih (fun i hi ↦ hf i <| mem_insert_of_mem hi) hq h2q
_ = (∫⁻ a, f i₀ a ∂μ) ^ p i₀ * ∏ i ∈ s, (∫⁻ a, f i a ∂μ) ^ p i := by
simp [q, ← ENNReal.prod_rpow_of_nonneg hpi₀, ← ENNReal.rpow_mul,
div_mul_cancel₀ (h := h2pi₀)]
_ = ∏ i ∈ insert i₀ s, (∫⁻ a, f i a ∂μ) ^ p i := by simp [hi₀]
/-- A version of Hölder with multiple arguments, one of which plays a distinguished role. -/
theorem lintegral_mul_prod_norm_pow_le {α ι : Type*} [MeasurableSpace α] {μ : Measure α}
(s : Finset ι) {g : α → ℝ≥0∞} {f : ι → α → ℝ≥0∞} (hg : AEMeasurable g μ)
(hf : ∀ i ∈ s, AEMeasurable (f i) μ) (q : ℝ) {p : ι → ℝ} (hpq : q + ∑ i ∈ s, p i = 1)
(hq : 0 ≤ q) (hp : ∀ i ∈ s, 0 ≤ p i) :
∫⁻ a, g a ^ q * ∏ i ∈ s, f i a ^ p i ∂μ ≤
(∫⁻ a, g a ∂μ) ^ q * ∏ i ∈ s, (∫⁻ a, f i a ∂μ) ^ p i := by
suffices
∫⁻ t, ∏ j ∈ insertNone s, Option.elim j (g t) (fun j ↦ f j t) ^ Option.elim j q p ∂μ
≤ ∏ j ∈ insertNone s, (∫⁻ t, Option.elim j (g t) (fun j ↦ f j t) ∂μ) ^ Option.elim j q p by
simpa using this
refine ENNReal.lintegral_prod_norm_pow_le _ ?_ ?_ ?_
· rintro (_|i) hi
· exact hg
· refine hf i ?_
simpa using hi
· simp_rw [sum_insertNone, Option.elim]
exact hpq
· rintro (_|i) hi
· exact hq
· refine hp i ?_
simpa using hi
theorem lintegral_rpow_add_lt_top_of_lintegral_rpow_lt_top {p : ℝ} {f g : α → ℝ≥0∞}
(hf : AEMeasurable f μ) (hf_top : (∫⁻ a, f a ^ p ∂μ) < ⊤) (hg_top : (∫⁻ a, g a ^ p ∂μ) < ⊤)
(hp1 : 1 ≤ p) : (∫⁻ a, (f + g) a ^ p ∂μ) < ⊤ := by
have hp0_lt : 0 < p := lt_of_lt_of_le zero_lt_one hp1
have hp0 : 0 ≤ p := le_of_lt hp0_lt
calc
(∫⁻ a : α, (f a + g a) ^ p ∂μ) ≤
∫⁻ a, (2 : ℝ≥0∞) ^ (p - 1) * f a ^ p + (2 : ℝ≥0∞) ^ (p - 1) * g a ^ p ∂μ := by
refine lintegral_mono fun a => ?_
dsimp only
have h_zero_lt_half_rpow : (0 : ℝ≥0∞) < (1 / 2 : ℝ≥0∞) ^ p := by
rw [← ENNReal.zero_rpow_of_pos hp0_lt]
exact ENNReal.rpow_lt_rpow (by simp [zero_lt_one]) hp0_lt
have h_rw : (1 / 2 : ℝ≥0∞) ^ p * (2 : ℝ≥0∞) ^ (p - 1) = 1 / 2 := by
rw [sub_eq_add_neg, ENNReal.rpow_add _ _ two_ne_zero ENNReal.coe_ne_top, ← mul_assoc, ←
ENNReal.mul_rpow_of_nonneg _ _ hp0, one_div,
ENNReal.inv_mul_cancel two_ne_zero ENNReal.coe_ne_top, ENNReal.one_rpow, one_mul,
ENNReal.rpow_neg_one]
rw [← ENNReal.mul_le_mul_left (ne_of_lt h_zero_lt_half_rpow).symm _]
· rw [mul_add, ← mul_assoc, ← mul_assoc, h_rw, ← ENNReal.mul_rpow_of_nonneg _ _ hp0, mul_add]
refine
ENNReal.rpow_arith_mean_le_arith_mean2_rpow (1 / 2 : ℝ≥0∞) (1 / 2 : ℝ≥0∞) (f a) (g a) ?_
hp1
rw [ENNReal.div_add_div_same, one_add_one_eq_two,
ENNReal.div_self two_ne_zero ENNReal.coe_ne_top]
· rw [← lt_top_iff_ne_top]
refine ENNReal.rpow_lt_top_of_nonneg hp0 ?_
rw [one_div, ENNReal.inv_ne_top]
exact two_ne_zero
_ < ⊤ := by
have h_two : (2 : ℝ≥0∞) ^ (p - 1) ≠ ⊤ :=
ENNReal.rpow_ne_top_of_nonneg (by simp [hp1]) ENNReal.coe_ne_top
rw [lintegral_add_left', lintegral_const_mul'' _ (hf.pow_const p),
lintegral_const_mul' _ _ h_two, ENNReal.add_lt_top]
· exact ⟨ENNReal.mul_lt_top h_two.lt_top hf_top, ENNReal.mul_lt_top h_two.lt_top hg_top⟩
· exact (hf.pow_const p).const_mul _
theorem lintegral_Lp_mul_le_Lq_mul_Lr {α} [MeasurableSpace α] {p q r : ℝ} (hp0_lt : 0 < p)
(hpq : p < q) (hpqr : 1 / p = 1 / q + 1 / r) (μ : Measure α) {f g : α → ℝ≥0∞}
(hf : AEMeasurable f μ) (hg : AEMeasurable g μ) :
(∫⁻ a, (f * g) a ^ p ∂μ) ^ (1 / p) ≤
(∫⁻ a, f a ^ q ∂μ) ^ (1 / q) * (∫⁻ a, g a ^ r ∂μ) ^ (1 / r) := by
have hp0_ne : p ≠ 0 := (ne_of_lt hp0_lt).symm
have hp0 : 0 ≤ p := le_of_lt hp0_lt
have hq0_lt : 0 < q := lt_of_le_of_lt hp0 hpq
have hq0_ne : q ≠ 0 := (ne_of_lt hq0_lt).symm
have h_one_div_r : 1 / r = 1 / p - 1 / q := by rw [hpqr]; simp
let p2 := q / p
let q2 := p2.conjExponent
have hp2q2 : p2.HolderConjugate q2 :=
.conjExponent (by simp [p2, q2, _root_.lt_div_iff₀, hpq, hp0_lt])
calc
(∫⁻ a : α, (f * g) a ^ p ∂μ) ^ (1 / p) = (∫⁻ a : α, f a ^ p * g a ^ p ∂μ) ^ (1 / p) := by
simp_rw [Pi.mul_apply, ENNReal.mul_rpow_of_nonneg _ _ hp0]
_ ≤ ((∫⁻ a, f a ^ (p * p2) ∂μ) ^ (1 / p2) *
(∫⁻ a, g a ^ (p * q2) ∂μ) ^ (1 / q2)) ^ (1 / p) := by
gcongr
simp_rw [ENNReal.rpow_mul]
exact ENNReal.lintegral_mul_le_Lp_mul_Lq μ hp2q2 (hf.pow_const _) (hg.pow_const _)
_ = (∫⁻ a : α, f a ^ q ∂μ) ^ (1 / q) * (∫⁻ a : α, g a ^ r ∂μ) ^ (1 / r) := by
rw [@ENNReal.mul_rpow_of_nonneg _ _ (1 / p) (by simp [hp0]), ← ENNReal.rpow_mul, ←
ENNReal.rpow_mul]
have hpp2 : p * p2 = q := by
symm
rw [mul_comm, ← div_eq_iff hp0_ne]
have hpq2 : p * q2 = r := by
rw [← inv_inv r, ← one_div, ← one_div, h_one_div_r]
field_simp [p2, q2, Real.conjExponent, hp0_ne, hq0_ne]
simp_rw [div_mul_div_comm, mul_one, mul_comm p2, mul_comm q2, hpp2, hpq2]
theorem lintegral_mul_rpow_le_lintegral_rpow_mul_lintegral_rpow {p q : ℝ}
(hpq : p.HolderConjugate q) {f g : α → ℝ≥0∞} (hf : AEMeasurable f μ) (hg : AEMeasurable g μ)
(hf_top : (∫⁻ a, f a ^ p ∂μ) ≠ ⊤) :
(∫⁻ a, f a * g a ^ (p - 1) ∂μ) ≤
(∫⁻ a, f a ^ p ∂μ) ^ (1 / p) * (∫⁻ a, g a ^ p ∂μ) ^ (1 / q) := by
refine le_trans (ENNReal.lintegral_mul_le_Lp_mul_Lq μ hpq hf (hg.pow_const _)) ?_
by_cases hf_zero_rpow : (∫⁻ a : α, f a ^ p ∂μ) ^ (1 / p) = 0
· rw [hf_zero_rpow, zero_mul]
exact zero_le _
have hf_top_rpow : (∫⁻ a : α, f a ^ p ∂μ) ^ (1 / p) ≠ ⊤ := by
by_contra h
refine hf_top ?_
have hp_not_neg : ¬p < 0 := by simp [hpq.nonneg]
simpa [hpq.pos, hp_not_neg] using h
refine (ENNReal.mul_le_mul_left hf_zero_rpow hf_top_rpow).mpr (le_of_eq ?_)
congr
ext1 a
rw [← ENNReal.rpow_mul, hpq.sub_one_mul_conj]
theorem lintegral_rpow_add_le_add_eLpNorm_mul_lintegral_rpow_add {p q : ℝ}
(hpq : p.HolderConjugate q) {f g : α → ℝ≥0∞} (hf : AEMeasurable f μ)
(hf_top : (∫⁻ a, f a ^ p ∂μ) ≠ ⊤) (hg : AEMeasurable g μ) (hg_top : (∫⁻ a, g a ^ p ∂μ) ≠ ⊤) :
(∫⁻ a, (f + g) a ^ p ∂μ) ≤
((∫⁻ a, f a ^ p ∂μ) ^ (1 / p) + (∫⁻ a, g a ^ p ∂μ) ^ (1 / p)) *
(∫⁻ a, (f a + g a) ^ p ∂μ) ^ (1 / q) := by
calc
(∫⁻ a, (f + g) a ^ p ∂μ) ≤ ∫⁻ a, (f + g) a * (f + g) a ^ (p - 1) ∂μ := by
gcongr with a
by_cases h_zero : (f + g) a = 0
· rw [h_zero, ENNReal.zero_rpow_of_pos hpq.pos]
exact zero_le _
by_cases h_top : (f + g) a = ⊤
· rw [h_top, ENNReal.top_rpow_of_pos hpq.sub_one_pos, ENNReal.top_mul_top]
exact le_top
refine le_of_eq ?_
nth_rw 2 [← ENNReal.rpow_one ((f + g) a)]
rw [← ENNReal.rpow_add _ _ h_zero h_top, add_sub_cancel]
_ = (∫⁻ a : α, f a * (f + g) a ^ (p - 1) ∂μ) + ∫⁻ a : α, g a * (f + g) a ^ (p - 1) ∂μ := by
have h_add_m : AEMeasurable (fun a : α => (f + g) a ^ (p - 1 : ℝ)) μ :=
(hf.add hg).pow_const _
have h_add_apply :
(∫⁻ a : α, (f + g) a * (f + g) a ^ (p - 1) ∂μ) =
∫⁻ a : α, (f a + g a) * (f + g) a ^ (p - 1) ∂μ :=
rfl
simp_rw [h_add_apply, add_mul]
rw [lintegral_add_left' (hf.mul h_add_m)]
_ ≤
((∫⁻ a, f a ^ p ∂μ) ^ (1 / p) + (∫⁻ a, g a ^ p ∂μ) ^ (1 / p)) *
(∫⁻ a, (f a + g a) ^ p ∂μ) ^ (1 / q) := by
rw [add_mul]
gcongr
· exact lintegral_mul_rpow_le_lintegral_rpow_mul_lintegral_rpow hpq hf (hf.add hg) hf_top
· exact lintegral_mul_rpow_le_lintegral_rpow_mul_lintegral_rpow hpq hg (hf.add hg) hg_top
private theorem lintegral_Lp_add_le_aux {p q : ℝ} (hpq : p.HolderConjugate q) {f g : α → ℝ≥0∞}
(hf : AEMeasurable f μ) (hf_top : (∫⁻ a, f a ^ p ∂μ) ≠ ⊤) (hg : AEMeasurable g μ)
(hg_top : (∫⁻ a, g a ^ p ∂μ) ≠ ⊤) (h_add_zero : (∫⁻ a, (f + g) a ^ p ∂μ) ≠ 0)
(h_add_top : (∫⁻ a, (f + g) a ^ p ∂μ) ≠ ⊤) :
(∫⁻ a, (f + g) a ^ p ∂μ) ^ (1 / p) ≤
(∫⁻ a, f a ^ p ∂μ) ^ (1 / p) + (∫⁻ a, g a ^ p ∂μ) ^ (1 / p) := by
have hp_not_nonpos : ¬p ≤ 0 := by simp [hpq.pos]
have htop_rpow : (∫⁻ a, (f + g) a ^ p ∂μ) ^ (1 / p) ≠ ⊤ := by
by_contra h
exact h_add_top (@ENNReal.rpow_eq_top_of_nonneg _ (1 / p) (by simp [hpq.nonneg]) h)
have h0_rpow : (∫⁻ a, (f + g) a ^ p ∂μ) ^ (1 / p) ≠ 0 := by
simp [h_add_zero, h_add_top, hpq.nonneg, hp_not_nonpos, -Pi.add_apply]
suffices h :
1 ≤
(∫⁻ a : α, (f + g) a ^ p ∂μ) ^ (-(1 / p)) *
((∫⁻ a : α, f a ^ p ∂μ) ^ (1 / p) + (∫⁻ a : α, g a ^ p ∂μ) ^ (1 / p)) by
rwa [← mul_le_mul_left h0_rpow htop_rpow, ← mul_assoc, ← rpow_add _ _ h_add_zero h_add_top, ←
| sub_eq_add_neg, _root_.sub_self, rpow_zero, one_mul, mul_one] at h
have h :
(∫⁻ a : α, (f + g) a ^ p ∂μ) ≤
((∫⁻ a : α, f a ^ p ∂μ) ^ (1 / p) + (∫⁻ a : α, g a ^ p ∂μ) ^ (1 / p)) *
(∫⁻ a : α, (f + g) a ^ p ∂μ) ^ (1 / q) :=
lintegral_rpow_add_le_add_eLpNorm_mul_lintegral_rpow_add hpq hf hf_top hg hg_top
have h_one_div_q : 1 / q = 1 - 1 / p := by
nth_rw 2 [← hpq.inv_add_inv_eq_one]
ring
simp_rw [h_one_div_q, sub_eq_add_neg 1 (1 / p), ENNReal.rpow_add _ _ h_add_zero h_add_top,
rpow_one] at h
conv_rhs at h => enter [2]; rw [mul_comm]
conv_lhs at h => rw [← one_mul (∫⁻ a : α, (f + g) a ^ p ∂μ)]
rwa [← mul_assoc, ENNReal.mul_le_mul_right h_add_zero h_add_top, mul_comm] at h
/-- **Minkowski's inequality for functions** `α → ℝ≥0∞`: the `ℒp` seminorm of the sum of two
functions is bounded by the sum of their `ℒp` seminorms. -/
theorem lintegral_Lp_add_le {p : ℝ} {f g : α → ℝ≥0∞} (hf : AEMeasurable f μ) (hg : AEMeasurable g μ)
(hp1 : 1 ≤ p) :
(∫⁻ a, (f + g) a ^ p ∂μ) ^ (1 / p) ≤
(∫⁻ a, f a ^ p ∂μ) ^ (1 / p) + (∫⁻ a, g a ^ p ∂μ) ^ (1 / p) := by
have hp_pos : 0 < p := lt_of_lt_of_le zero_lt_one hp1
by_cases hf_top : ∫⁻ a, f a ^ p ∂μ = ⊤
· simp [hf_top, hp_pos]
by_cases hg_top : ∫⁻ a, g a ^ p ∂μ = ⊤
· simp [hg_top, hp_pos]
by_cases h1 : p = 1
· refine le_of_eq ?_
simp_rw [h1, one_div_one, ENNReal.rpow_one]
exact lintegral_add_left' hf _
have hp1_lt : 1 < p := by
| Mathlib/MeasureTheory/Integral/MeanInequalities.lean | 403 | 433 |
/-
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
| Mathlib/Data/Fin/Basic.lean | 133 | 134 |
/-
Copyright (c) 2021 Rémy Degenne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Zhouhang Zhou, Yury Kudryashov, Sébastien Gouëzel, Rémy Degenne
-/
import Mathlib.MeasureTheory.Integral.FinMeasAdditive
/-!
# Extension of a linear function from indicators to L1
Given `T : Set α → E →L[ℝ] F` with `DominatedFinMeasAdditive μ T C`, we construct an extension
of `T` to integrable simple functions, which are finite sums of indicators of measurable sets
with finite measure, then to integrable functions, which are limits of integrable simple functions.
The main result is a continuous linear map `(α →₁[μ] E) →L[ℝ] F`.
This extension process is used to define the Bochner integral
in the `Mathlib.MeasureTheory.Integral.Bochner.Basic` file
and the conditional expectation of an integrable function
in `Mathlib.MeasureTheory.Function.ConditionalExpectation.CondexpL1`.
## Main definitions
- `setToL1 (hT : DominatedFinMeasAdditive μ T C) : (α →₁[μ] E) →L[ℝ] F`: the extension of `T`
from indicators to L1.
- `setToFun μ T (hT : DominatedFinMeasAdditive μ T C) (f : α → E) : F`: a version of the
extension which applies to functions (with value 0 if the function is not integrable).
## Properties
For most properties of `setToFun`, we provide two lemmas. One version uses hypotheses valid on
all sets, like `T = T'`, and a second version which uses a primed name uses hypotheses on
measurable sets with finite measure, like `∀ s, MeasurableSet s → μ s < ∞ → T s = T' s`.
The lemmas listed here don't show all hypotheses. Refer to the actual lemmas for details.
Linearity:
- `setToFun_zero_left : setToFun μ 0 hT f = 0`
- `setToFun_add_left : setToFun μ (T + T') _ f = setToFun μ T hT f + setToFun μ T' hT' f`
- `setToFun_smul_left : setToFun μ (fun s ↦ c • (T s)) (hT.smul c) f = c • setToFun μ T hT f`
- `setToFun_zero : setToFun μ T hT (0 : α → E) = 0`
- `setToFun_neg : setToFun μ T hT (-f) = - setToFun μ T hT f`
If `f` and `g` are integrable:
- `setToFun_add : setToFun μ T hT (f + g) = setToFun μ T hT f + setToFun μ T hT g`
- `setToFun_sub : setToFun μ T hT (f - g) = setToFun μ T hT f - setToFun μ T hT g`
If `T` is verifies `∀ c : 𝕜, ∀ s x, T s (c • x) = c • T s x`:
- `setToFun_smul : setToFun μ T hT (c • f) = c • setToFun μ T hT f`
Other:
- `setToFun_congr_ae (h : f =ᵐ[μ] g) : setToFun μ T hT f = setToFun μ T hT g`
- `setToFun_measure_zero (h : μ = 0) : setToFun μ T hT f = 0`
If the space is also an ordered additive group with an order closed topology and `T` is such that
`0 ≤ T s x` for `0 ≤ x`, we also prove order-related properties:
- `setToFun_mono_left (h : ∀ s x, T s x ≤ T' s x) : setToFun μ T hT f ≤ setToFun μ T' hT' f`
- `setToFun_nonneg (hf : 0 ≤ᵐ[μ] f) : 0 ≤ setToFun μ T hT f`
- `setToFun_mono (hfg : f ≤ᵐ[μ] g) : setToFun μ T hT f ≤ setToFun μ T hT g`
-/
noncomputable section
open scoped Topology NNReal
open Set Filter TopologicalSpace ENNReal
namespace MeasureTheory
variable {α E F F' G 𝕜 : Type*} [NormedAddCommGroup E] [NormedSpace ℝ E]
[NormedAddCommGroup F] [NormedSpace ℝ F] [NormedAddCommGroup F'] [NormedSpace ℝ F']
[NormedAddCommGroup G] {m : MeasurableSpace α} {μ : Measure α}
namespace L1
open AEEqFun Lp.simpleFunc Lp
namespace SimpleFunc
theorem norm_eq_sum_mul (f : α →₁ₛ[μ] G) :
‖f‖ = ∑ x ∈ (toSimpleFunc f).range, μ.real (toSimpleFunc f ⁻¹' {x}) * ‖x‖ := by
rw [norm_toSimpleFunc, eLpNorm_one_eq_lintegral_enorm]
have h_eq := SimpleFunc.map_apply (‖·‖ₑ) (toSimpleFunc f)
simp_rw [← h_eq, measureReal_def]
rw [SimpleFunc.lintegral_eq_lintegral, SimpleFunc.map_lintegral, ENNReal.toReal_sum]
· congr
ext1 x
rw [ENNReal.toReal_mul, mul_comm, ← ofReal_norm_eq_enorm,
ENNReal.toReal_ofReal (norm_nonneg _)]
· intro x _
by_cases hx0 : x = 0
· rw [hx0]; simp
· exact
ENNReal.mul_ne_top ENNReal.coe_ne_top
(SimpleFunc.measure_preimage_lt_top_of_integrable _ (SimpleFunc.integrable f) hx0).ne
section SetToL1S
variable [NormedField 𝕜] [NormedSpace 𝕜 E]
attribute [local instance] Lp.simpleFunc.module
attribute [local instance] Lp.simpleFunc.normedSpace
/-- Extend `Set α → (E →L[ℝ] F')` to `(α →₁ₛ[μ] E) → F'`. -/
def setToL1S (T : Set α → E →L[ℝ] F) (f : α →₁ₛ[μ] E) : F :=
(toSimpleFunc f).setToSimpleFunc T
theorem setToL1S_eq_setToSimpleFunc (T : Set α → E →L[ℝ] F) (f : α →₁ₛ[μ] E) :
setToL1S T f = (toSimpleFunc f).setToSimpleFunc T :=
rfl
@[simp]
theorem setToL1S_zero_left (f : α →₁ₛ[μ] E) : setToL1S (0 : Set α → E →L[ℝ] F) f = 0 :=
SimpleFunc.setToSimpleFunc_zero _
theorem setToL1S_zero_left' {T : Set α → E →L[ℝ] F}
(h_zero : ∀ s, MeasurableSet s → μ s < ∞ → T s = 0) (f : α →₁ₛ[μ] E) : setToL1S T f = 0 :=
SimpleFunc.setToSimpleFunc_zero' h_zero _ (SimpleFunc.integrable f)
theorem setToL1S_congr (T : Set α → E →L[ℝ] F) (h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0)
(h_add : FinMeasAdditive μ T) {f g : α →₁ₛ[μ] E} (h : toSimpleFunc f =ᵐ[μ] toSimpleFunc g) :
setToL1S T f = setToL1S T g :=
SimpleFunc.setToSimpleFunc_congr T h_zero h_add (SimpleFunc.integrable f) h
theorem setToL1S_congr_left (T T' : Set α → E →L[ℝ] F)
(h : ∀ s, MeasurableSet s → μ s < ∞ → T s = T' s) (f : α →₁ₛ[μ] E) :
setToL1S T f = setToL1S T' f :=
SimpleFunc.setToSimpleFunc_congr_left T T' h (simpleFunc.toSimpleFunc f) (SimpleFunc.integrable f)
/-- `setToL1S` does not change if we replace the measure `μ` by `μ'` with `μ ≪ μ'`. The statement
uses two functions `f` and `f'` because they have to belong to different types, but morally these
are the same function (we have `f =ᵐ[μ] f'`). -/
theorem setToL1S_congr_measure {μ' : Measure α} (T : Set α → E →L[ℝ] F)
(h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0) (h_add : FinMeasAdditive μ T) (hμ : μ ≪ μ')
(f : α →₁ₛ[μ] E) (f' : α →₁ₛ[μ'] E) (h : (f : α → E) =ᵐ[μ] f') :
setToL1S T f = setToL1S T f' := by
refine SimpleFunc.setToSimpleFunc_congr T h_zero h_add (SimpleFunc.integrable f) ?_
refine (toSimpleFunc_eq_toFun f).trans ?_
suffices (f' : α → E) =ᵐ[μ] simpleFunc.toSimpleFunc f' from h.trans this
have goal' : (f' : α → E) =ᵐ[μ'] simpleFunc.toSimpleFunc f' := (toSimpleFunc_eq_toFun f').symm
exact hμ.ae_eq goal'
theorem setToL1S_add_left (T T' : Set α → E →L[ℝ] F) (f : α →₁ₛ[μ] E) :
setToL1S (T + T') f = setToL1S T f + setToL1S T' f :=
SimpleFunc.setToSimpleFunc_add_left T T'
theorem setToL1S_add_left' (T T' T'' : Set α → E →L[ℝ] F)
(h_add : ∀ s, MeasurableSet s → μ s < ∞ → T'' s = T s + T' s) (f : α →₁ₛ[μ] E) :
setToL1S T'' f = setToL1S T f + setToL1S T' f :=
SimpleFunc.setToSimpleFunc_add_left' T T' T'' h_add (SimpleFunc.integrable f)
theorem setToL1S_smul_left (T : Set α → E →L[ℝ] F) (c : ℝ) (f : α →₁ₛ[μ] E) :
setToL1S (fun s => c • T s) f = c • setToL1S T f :=
SimpleFunc.setToSimpleFunc_smul_left T c _
theorem setToL1S_smul_left' (T T' : Set α → E →L[ℝ] F) (c : ℝ)
(h_smul : ∀ s, MeasurableSet s → μ s < ∞ → T' s = c • T s) (f : α →₁ₛ[μ] E) :
setToL1S T' f = c • setToL1S T f :=
SimpleFunc.setToSimpleFunc_smul_left' T T' c h_smul (SimpleFunc.integrable f)
theorem setToL1S_add (T : Set α → E →L[ℝ] F) (h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0)
(h_add : FinMeasAdditive μ T) (f g : α →₁ₛ[μ] E) :
setToL1S T (f + g) = setToL1S T f + setToL1S T g := by
simp_rw [setToL1S]
rw [← SimpleFunc.setToSimpleFunc_add T h_add (SimpleFunc.integrable f)
(SimpleFunc.integrable g)]
exact
SimpleFunc.setToSimpleFunc_congr T h_zero h_add (SimpleFunc.integrable _)
(add_toSimpleFunc f g)
theorem setToL1S_neg {T : Set α → E →L[ℝ] F} (h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0)
(h_add : FinMeasAdditive μ T) (f : α →₁ₛ[μ] E) : setToL1S T (-f) = -setToL1S T f := by
simp_rw [setToL1S]
have : simpleFunc.toSimpleFunc (-f) =ᵐ[μ] ⇑(-simpleFunc.toSimpleFunc f) :=
neg_toSimpleFunc f
rw [SimpleFunc.setToSimpleFunc_congr T h_zero h_add (SimpleFunc.integrable _) this]
exact SimpleFunc.setToSimpleFunc_neg T h_add (SimpleFunc.integrable f)
theorem setToL1S_sub {T : Set α → E →L[ℝ] F} (h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0)
(h_add : FinMeasAdditive μ T) (f g : α →₁ₛ[μ] E) :
setToL1S T (f - g) = setToL1S T f - setToL1S T g := by
rw [sub_eq_add_neg, setToL1S_add T h_zero h_add, setToL1S_neg h_zero h_add, sub_eq_add_neg]
theorem setToL1S_smul_real (T : Set α → E →L[ℝ] F)
(h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0) (h_add : FinMeasAdditive μ T) (c : ℝ)
(f : α →₁ₛ[μ] E) : setToL1S T (c • f) = c • setToL1S T f := by
simp_rw [setToL1S]
rw [← SimpleFunc.setToSimpleFunc_smul_real T h_add c (SimpleFunc.integrable f)]
refine SimpleFunc.setToSimpleFunc_congr T h_zero h_add (SimpleFunc.integrable _) ?_
exact smul_toSimpleFunc c f
theorem setToL1S_smul {E} [NormedAddCommGroup E] [NormedSpace ℝ E] [NormedSpace 𝕜 E]
[DistribSMul 𝕜 F] (T : Set α → E →L[ℝ] F) (h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0)
(h_add : FinMeasAdditive μ T) (h_smul : ∀ c : 𝕜, ∀ s x, T s (c • x) = c • T s x) (c : 𝕜)
(f : α →₁ₛ[μ] E) : setToL1S T (c • f) = c • setToL1S T f := by
simp_rw [setToL1S]
rw [← SimpleFunc.setToSimpleFunc_smul T h_add h_smul c (SimpleFunc.integrable f)]
refine SimpleFunc.setToSimpleFunc_congr T h_zero h_add (SimpleFunc.integrable _) ?_
exact smul_toSimpleFunc c f
theorem norm_setToL1S_le (T : Set α → E →L[ℝ] F) {C : ℝ}
(hT_norm : ∀ s, MeasurableSet s → μ s < ∞ → ‖T s‖ ≤ C * μ.real s) (f : α →₁ₛ[μ] E) :
‖setToL1S T f‖ ≤ C * ‖f‖ := by
rw [setToL1S, norm_eq_sum_mul f]
exact
SimpleFunc.norm_setToSimpleFunc_le_sum_mul_norm_of_integrable T hT_norm _
(SimpleFunc.integrable f)
theorem setToL1S_indicatorConst {T : Set α → E →L[ℝ] F} {s : Set α}
(h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0) (h_add : FinMeasAdditive μ T)
(hs : MeasurableSet s) (hμs : μ s < ∞) (x : E) :
setToL1S T (simpleFunc.indicatorConst 1 hs hμs.ne x) = T s x := by
have h_empty : T ∅ = 0 := h_zero _ MeasurableSet.empty measure_empty
rw [setToL1S_eq_setToSimpleFunc]
refine Eq.trans ?_ (SimpleFunc.setToSimpleFunc_indicator T h_empty hs x)
refine SimpleFunc.setToSimpleFunc_congr T h_zero h_add (SimpleFunc.integrable _) ?_
exact toSimpleFunc_indicatorConst hs hμs.ne x
theorem setToL1S_const [IsFiniteMeasure μ] {T : Set α → E →L[ℝ] F}
(h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0) (h_add : FinMeasAdditive μ T) (x : E) :
setToL1S T (simpleFunc.indicatorConst 1 MeasurableSet.univ (measure_ne_top μ _) x) = T univ x :=
setToL1S_indicatorConst h_zero h_add MeasurableSet.univ (measure_lt_top _ _) x
section Order
variable {G'' G' : Type*}
[NormedAddCommGroup G'] [PartialOrder G'] [IsOrderedAddMonoid G'] [NormedSpace ℝ G']
[NormedAddCommGroup G''] [PartialOrder G''] [IsOrderedAddMonoid G''] [NormedSpace ℝ G'']
{T : Set α → G'' →L[ℝ] G'}
theorem setToL1S_mono_left {T T' : Set α → E →L[ℝ] G''} (hTT' : ∀ s x, T s x ≤ T' s x)
(f : α →₁ₛ[μ] E) : setToL1S T f ≤ setToL1S T' f :=
SimpleFunc.setToSimpleFunc_mono_left T T' hTT' _
theorem setToL1S_mono_left' {T T' : Set α → E →L[ℝ] G''}
(hTT' : ∀ s, MeasurableSet s → μ s < ∞ → ∀ x, T s x ≤ T' s x) (f : α →₁ₛ[μ] E) :
setToL1S T f ≤ setToL1S T' f :=
SimpleFunc.setToSimpleFunc_mono_left' T T' hTT' _ (SimpleFunc.integrable f)
omit [IsOrderedAddMonoid G''] in
theorem setToL1S_nonneg (h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0)
(h_add : FinMeasAdditive μ T)
(hT_nonneg : ∀ s, MeasurableSet s → μ s < ∞ → ∀ x, 0 ≤ x → 0 ≤ T s x) {f : α →₁ₛ[μ] G''}
(hf : 0 ≤ f) : 0 ≤ setToL1S T f := by
simp_rw [setToL1S]
obtain ⟨f', hf', hff'⟩ := exists_simpleFunc_nonneg_ae_eq hf
replace hff' : simpleFunc.toSimpleFunc f =ᵐ[μ] f' :=
(Lp.simpleFunc.toSimpleFunc_eq_toFun f).trans hff'
rw [SimpleFunc.setToSimpleFunc_congr _ h_zero h_add (SimpleFunc.integrable _) hff']
exact
SimpleFunc.setToSimpleFunc_nonneg' T hT_nonneg _ hf' ((SimpleFunc.integrable f).congr hff')
theorem setToL1S_mono (h_zero : ∀ s, MeasurableSet s → μ s = 0 → T s = 0)
(h_add : FinMeasAdditive μ T)
(hT_nonneg : ∀ s, MeasurableSet s → μ s < ∞ → ∀ x, 0 ≤ x → 0 ≤ T s x) {f g : α →₁ₛ[μ] G''}
(hfg : f ≤ g) : setToL1S T f ≤ setToL1S T g := by
rw [← sub_nonneg] at hfg ⊢
rw [← setToL1S_sub h_zero h_add]
exact setToL1S_nonneg h_zero h_add hT_nonneg hfg
end Order
variable [NormedSpace 𝕜 F]
variable (α E μ 𝕜)
/-- Extend `Set α → E →L[ℝ] F` to `(α →₁ₛ[μ] E) →L[𝕜] F`. -/
def setToL1SCLM' {T : Set α → E →L[ℝ] F} {C : ℝ} (hT : DominatedFinMeasAdditive μ T C)
(h_smul : ∀ c : 𝕜, ∀ s x, T s (c • x) = c • T s x) : (α →₁ₛ[μ] E) →L[𝕜] F :=
LinearMap.mkContinuous
⟨⟨setToL1S T, setToL1S_add T (fun _ => hT.eq_zero_of_measure_zero) hT.1⟩,
setToL1S_smul T (fun _ => hT.eq_zero_of_measure_zero) hT.1 h_smul⟩
C fun f => norm_setToL1S_le T hT.2 f
/-- Extend `Set α → E →L[ℝ] F` to `(α →₁ₛ[μ] E) →L[ℝ] F`. -/
def setToL1SCLM {T : Set α → E →L[ℝ] F} {C : ℝ} (hT : DominatedFinMeasAdditive μ T C) :
(α →₁ₛ[μ] E) →L[ℝ] F :=
LinearMap.mkContinuous
⟨⟨setToL1S T, setToL1S_add T (fun _ => hT.eq_zero_of_measure_zero) hT.1⟩,
setToL1S_smul_real T (fun _ => hT.eq_zero_of_measure_zero) hT.1⟩
C fun f => norm_setToL1S_le T hT.2 f
variable {α E μ 𝕜}
variable {T T' T'' : Set α → E →L[ℝ] F} {C C' C'' : ℝ}
@[simp]
theorem setToL1SCLM_zero_left (hT : DominatedFinMeasAdditive μ (0 : Set α → E →L[ℝ] F) C)
(f : α →₁ₛ[μ] E) : setToL1SCLM α E μ hT f = 0 :=
setToL1S_zero_left _
|
theorem setToL1SCLM_zero_left' (hT : DominatedFinMeasAdditive μ T C)
(h_zero : ∀ s, MeasurableSet s → μ s < ∞ → T s = 0) (f : α →₁ₛ[μ] E) :
setToL1SCLM α E μ hT f = 0 :=
setToL1S_zero_left' h_zero f
theorem setToL1SCLM_congr_left (hT : DominatedFinMeasAdditive μ T C)
(hT' : DominatedFinMeasAdditive μ T' C') (h : T = T') (f : α →₁ₛ[μ] E) :
setToL1SCLM α E μ hT f = setToL1SCLM α E μ hT' f :=
setToL1S_congr_left T T' (fun _ _ _ => by rw [h]) f
| Mathlib/MeasureTheory/Integral/SetToL1.lean | 288 | 297 |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Thomas Browning
-/
import Mathlib.Algebra.Order.Archimedean.Basic
import Mathlib.Data.SetLike.Fintype
import Mathlib.GroupTheory.PGroup
import Mathlib.GroupTheory.NoncommPiCoprod
/-!
# Sylow theorems
The Sylow theorems are the following results for every finite group `G` and every prime number `p`.
* There exists a Sylow `p`-subgroup of `G`.
* All Sylow `p`-subgroups of `G` are conjugate to each other.
* Let `nₚ` be the number of Sylow `p`-subgroups of `G`, then `nₚ` divides the index of the Sylow
`p`-subgroup, `nₚ ≡ 1 [MOD p]`, and `nₚ` is equal to the index of the normalizer of the Sylow
`p`-subgroup in `G`.
## Main definitions
* `Sylow p G` : The type of Sylow `p`-subgroups of `G`.
## Main statements
* `Sylow.exists_subgroup_card_pow_prime`: A generalization of Sylow's first theorem:
For every prime power `pⁿ` dividing the cardinality of `G`,
there exists a subgroup of `G` of order `pⁿ`.
* `IsPGroup.exists_le_sylow`: A generalization of Sylow's first theorem:
Every `p`-subgroup is contained in a Sylow `p`-subgroup.
* `Sylow.card_eq_multiplicity`: The cardinality of a Sylow subgroup is `p ^ n`
where `n` is the multiplicity of `p` in the group order.
* `Sylow.isPretransitive_of_finite`: a generalization of Sylow's second theorem:
If the number of Sylow `p`-subgroups is finite, then all Sylow `p`-subgroups are conjugate.
* `card_sylow_modEq_one`: a generalization of Sylow's third theorem:
If the number of Sylow `p`-subgroups is finite, then it is congruent to `1` modulo `p`.
-/
open MulAction Subgroup
section InfiniteSylow
variable (p : ℕ) (G : Type*) [Group G]
/-- A Sylow `p`-subgroup is a maximal `p`-subgroup. -/
structure Sylow extends Subgroup G where
isPGroup' : IsPGroup p toSubgroup
is_maximal' : ∀ {Q : Subgroup G}, IsPGroup p Q → toSubgroup ≤ Q → Q = toSubgroup
variable {p} {G}
namespace Sylow
attribute [coe] toSubgroup
instance : CoeOut (Sylow p G) (Subgroup G) :=
⟨toSubgroup⟩
@[ext]
theorem ext {P Q : Sylow p G} (h : (P : Subgroup G) = Q) : P = Q := by cases P; cases Q; congr
instance : SetLike (Sylow p G) G where
coe := (↑)
coe_injective' _ _ h := ext (SetLike.coe_injective h)
instance : SubgroupClass (Sylow p G) G where
mul_mem := Subgroup.mul_mem _
one_mem _ := Subgroup.one_mem _
inv_mem := Subgroup.inv_mem _
/-- A `p`-subgroup with index indivisible by `p` is a Sylow subgroup. -/
def _root_.IsPGroup.toSylow [Fact p.Prime] {P : Subgroup G}
(hP1 : IsPGroup p P) (hP2 : ¬ p ∣ P.index) : Sylow p G :=
{ P with
isPGroup' := hP1
is_maximal' := by
intro Q hQ hPQ
have : P.FiniteIndex := ⟨fun h ↦ hP2 (h ▸ (dvd_zero p))⟩
obtain ⟨k, hk⟩ := (hQ.to_quotient (P.normalCore.subgroupOf Q)).exists_card_eq
have h := hk ▸ Nat.Prime.coprime_pow_of_not_dvd (m := k) Fact.out hP2
exact le_antisymm (Subgroup.relindex_eq_one.mp
(Nat.eq_one_of_dvd_coprimes h (Subgroup.relindex_dvd_index_of_le hPQ)
(Subgroup.relindex_dvd_of_le_left Q P.normalCore_le))) hPQ }
@[simp] theorem _root_.IsPGroup.toSylow_coe [Fact p.Prime] {P : Subgroup G}
(hP1 : IsPGroup p P) (hP2 : ¬ p ∣ P.index) : (hP1.toSylow hP2) = P :=
rfl
@[simp] theorem _root_.IsPGroup.mem_toSylow [Fact p.Prime] {P : Subgroup G}
(hP1 : IsPGroup p P) (hP2 : ¬ p ∣ P.index) {g : G} : g ∈ hP1.toSylow hP2 ↔ g ∈ P :=
.rfl
/-- A subgroup with cardinality `p ^ n` is a Sylow subgroup
where `n` is the multiplicity of `p` in the group order. -/
def ofCard [Finite G] {p : ℕ} [Fact p.Prime] (H : Subgroup G)
(card_eq : Nat.card H = p ^ (Nat.card G).factorization p) : Sylow p G :=
(IsPGroup.of_card card_eq).toSylow (by
rw [← mul_dvd_mul_iff_left (Nat.card_pos (α := H)).ne', card_mul_index, card_eq, ← pow_succ]
exact Nat.pow_succ_factorization_not_dvd Nat.card_pos.ne' Fact.out)
@[simp, norm_cast]
theorem coe_ofCard [Finite G] {p : ℕ} [Fact p.Prime] (H : Subgroup G)
(card_eq : Nat.card H = p ^ (Nat.card G).factorization p) : ofCard H card_eq = H :=
rfl
variable (P : Sylow p G)
variable {K : Type*} [Group K] (ϕ : K →* G) {N : Subgroup G}
/-- The preimage of a Sylow subgroup under a p-group-kernel homomorphism is a Sylow subgroup. -/
def comapOfKerIsPGroup (hϕ : IsPGroup p ϕ.ker) (h : P ≤ ϕ.range) : Sylow p K :=
{ P.1.comap ϕ with
isPGroup' := P.2.comap_of_ker_isPGroup ϕ hϕ
is_maximal' := fun {Q} hQ hle => by
show Q = P.1.comap ϕ
rw [← P.3 (hQ.map ϕ) (le_trans (ge_of_eq (map_comap_eq_self h)) (map_mono hle))]
exact (comap_map_eq_self ((P.1.ker_le_comap ϕ).trans hle)).symm }
@[simp]
theorem coe_comapOfKerIsPGroup (hϕ : IsPGroup p ϕ.ker) (h : P ≤ ϕ.range) :
P.comapOfKerIsPGroup ϕ hϕ h = P.comap ϕ :=
rfl
/-- The preimage of a Sylow subgroup under an injective homomorphism is a Sylow subgroup. -/
def comapOfInjective (hϕ : Function.Injective ϕ) (h : P ≤ ϕ.range) : Sylow p K :=
P.comapOfKerIsPGroup ϕ (IsPGroup.ker_isPGroup_of_injective hϕ) h
@[simp]
theorem coe_comapOfInjective (hϕ : Function.Injective ϕ) (h : P ≤ ϕ.range) :
P.comapOfInjective ϕ hϕ h = P.comap ϕ :=
rfl
/-- A sylow subgroup of G is also a sylow subgroup of a subgroup of G. -/
protected def subtype (h : P ≤ N) : Sylow p N :=
P.comapOfInjective N.subtype Subtype.coe_injective (by rwa [range_subtype])
@[simp]
theorem coe_subtype (h : P ≤ N) : P.subtype h = subgroupOf P N :=
rfl
theorem subtype_injective {P Q : Sylow p G} {hP : P ≤ N} {hQ : Q ≤ N}
(h : P.subtype hP = Q.subtype hQ) : P = Q := by
rw [SetLike.ext_iff] at h ⊢
exact fun g => ⟨fun hg => (h ⟨g, hP hg⟩).mp hg, fun hg => (h ⟨g, hQ hg⟩).mpr hg⟩
end Sylow
/-- A generalization of **Sylow's first theorem**.
Every `p`-subgroup is contained in a Sylow `p`-subgroup. -/
theorem IsPGroup.exists_le_sylow {P : Subgroup G} (hP : IsPGroup p P) : ∃ Q : Sylow p G, P ≤ Q :=
Exists.elim
(zorn_le_nonempty₀ { Q : Subgroup G | IsPGroup p Q }
(fun c hc1 hc2 Q hQ =>
⟨{ carrier := ⋃ R : c, R
one_mem' := ⟨Q, ⟨⟨Q, hQ⟩, rfl⟩, Q.one_mem⟩
inv_mem' := fun {_} ⟨_, ⟨R, rfl⟩, hg⟩ => ⟨R, ⟨R, rfl⟩, R.1.inv_mem hg⟩
mul_mem' := fun {_} _ ⟨_, ⟨R, rfl⟩, hg⟩ ⟨_, ⟨S, rfl⟩, hh⟩ =>
(hc2.total R.2 S.2).elim (fun T => ⟨S, ⟨S, rfl⟩, S.1.mul_mem (T hg) hh⟩) fun T =>
⟨R, ⟨R, rfl⟩, R.1.mul_mem hg (T hh)⟩ },
fun ⟨g, _, ⟨S, rfl⟩, hg⟩ => by
refine Exists.imp (fun k hk => ?_) (hc1 S.2 ⟨g, hg⟩)
rwa [Subtype.ext_iff, coe_pow] at hk ⊢, fun M hM _ hg => ⟨M, ⟨⟨M, hM⟩, rfl⟩, hg⟩⟩)
P hP)
fun {Q} h => ⟨⟨Q, h.2.prop, h.2.eq_of_ge⟩, h.1⟩
namespace Sylow
instance nonempty : Nonempty (Sylow p G) :=
nonempty_of_exists IsPGroup.of_bot.exists_le_sylow
noncomputable instance inhabited : Inhabited (Sylow p G) :=
Classical.inhabited_of_nonempty nonempty
theorem exists_comap_eq_of_ker_isPGroup {H : Type*} [Group H] (P : Sylow p H) {f : H →* G}
(hf : IsPGroup p f.ker) : ∃ Q : Sylow p G, Q.comap f = P :=
Exists.imp (fun Q hQ => P.3 (Q.2.comap_of_ker_isPGroup f hf) (map_le_iff_le_comap.mp hQ))
(P.2.map f).exists_le_sylow
theorem exists_comap_eq_of_injective {H : Type*} [Group H] (P : Sylow p H) {f : H →* G}
(hf : Function.Injective f) : ∃ Q : Sylow p G, Q.comap f = P :=
P.exists_comap_eq_of_ker_isPGroup (IsPGroup.ker_isPGroup_of_injective hf)
theorem exists_comap_subtype_eq {H : Subgroup G} (P : Sylow p H) :
∃ Q : Sylow p G, Q.comap H.subtype = P :=
P.exists_comap_eq_of_injective Subtype.coe_injective
/-- If the kernel of `f : H →* G` is a `p`-group,
then `Finite (Sylow p G)` implies `Finite (Sylow p H)`. -/
theorem finite_of_ker_is_pGroup {H : Type*} [Group H] {f : H →* G}
(hf : IsPGroup p f.ker) [Finite (Sylow p G)] : Finite (Sylow p H) :=
let h_exists := fun P : Sylow p H => P.exists_comap_eq_of_ker_isPGroup hf
let g : Sylow p H → Sylow p G := fun P => Classical.choose (h_exists P)
have hg : ∀ P : Sylow p H, (g P).1.comap f = P := fun P => Classical.choose_spec (h_exists P)
Finite.of_injective g fun P Q h => ext (by rw [← hg, h]; exact (h_exists Q).choose_spec)
/-- If `f : H →* G` is injective, then `Finite (Sylow p G)` implies `Finite (Sylow p H)`. -/
theorem finite_of_injective {H : Type*} [Group H] {f : H →* G}
(hf : Function.Injective f) [Finite (Sylow p G)] : Finite (Sylow p H) :=
finite_of_ker_is_pGroup (IsPGroup.ker_isPGroup_of_injective hf)
/-- If `H` is a subgroup of `G`, then `Finite (Sylow p G)` implies `Finite (Sylow p H)`. -/
instance (H : Subgroup G) [Finite (Sylow p G)] : Finite (Sylow p H) :=
finite_of_injective H.subtype_injective
open Pointwise
/-- `Subgroup.pointwiseMulAction` preserves Sylow subgroups. -/
instance pointwiseMulAction {α : Type*} [Group α] [MulDistribMulAction α G] :
MulAction α (Sylow p G) where
smul g P :=
⟨g • P.toSubgroup, P.2.map _, fun {Q} hQ hS =>
inv_smul_eq_iff.mp
(P.3 (hQ.map _) fun s hs =>
(congr_arg (· ∈ g⁻¹ • Q) (inv_smul_smul g s)).mp
(smul_mem_pointwise_smul (g • s) g⁻¹ Q (hS (smul_mem_pointwise_smul s g P hs))))⟩
one_smul P := ext (one_smul α P.toSubgroup)
mul_smul g h P := ext (mul_smul g h P.toSubgroup)
theorem pointwise_smul_def {α : Type*} [Group α] [MulDistribMulAction α G] {g : α}
{P : Sylow p G} : ↑(g • P) = g • (P : Subgroup G) :=
rfl
instance mulAction : MulAction G (Sylow p G) :=
compHom _ MulAut.conj
theorem smul_def {g : G} {P : Sylow p G} : g • P = MulAut.conj g • P :=
rfl
theorem coe_subgroup_smul {g : G} {P : Sylow p G} :
↑(g • P) = MulAut.conj g • (P : Subgroup G) :=
rfl
theorem coe_smul {g : G} {P : Sylow p G} : ↑(g • P) = MulAut.conj g • (P : Set G) :=
rfl
theorem smul_le {P : Sylow p G} {H : Subgroup G} (hP : P ≤ H) (h : H) : ↑(h • P) ≤ H :=
Subgroup.conj_smul_le_of_le hP h
theorem smul_subtype {P : Sylow p G} {H : Subgroup G} (hP : P ≤ H) (h : H) :
h • P.subtype hP = (h • P).subtype (smul_le hP h) :=
ext (Subgroup.conj_smul_subgroupOf hP h)
theorem smul_eq_iff_mem_normalizer {g : G} {P : Sylow p G} :
g • P = P ↔ g ∈ P.normalizer := by
rw [eq_comm, SetLike.ext_iff, ← inv_mem_iff (G := G) (H := normalizer P.toSubgroup),
mem_normalizer_iff, inv_inv]
exact
forall_congr' fun h =>
iff_congr Iff.rfl
⟨fun ⟨a, b, c⟩ => c ▸ by simpa [mul_assoc] using b,
fun hh => ⟨(MulAut.conj g)⁻¹ h, hh, MulAut.apply_inv_self G (MulAut.conj g) h⟩⟩
theorem smul_eq_of_normal {g : G} {P : Sylow p G} [h : P.Normal] :
g • P = P := by simp only [smul_eq_iff_mem_normalizer, P.normalizer_eq_top, mem_top]
end Sylow
theorem Subgroup.sylow_mem_fixedPoints_iff (H : Subgroup G) {P : Sylow p G} :
P ∈ fixedPoints H (Sylow p G) ↔ H ≤ P.normalizer := by
simp_rw [SetLike.le_def, ← Sylow.smul_eq_iff_mem_normalizer]; exact Subtype.forall
theorem IsPGroup.inf_normalizer_sylow {P : Subgroup G} (hP : IsPGroup p P) (Q : Sylow p G) :
P ⊓ Q.normalizer = P ⊓ Q :=
le_antisymm
(le_inf inf_le_left
(sup_eq_right.mp
(Q.3 (hP.to_inf_left.to_sup_of_normal_right' Q.2 inf_le_right) le_sup_right)))
(inf_le_inf_left P le_normalizer)
theorem IsPGroup.sylow_mem_fixedPoints_iff {P : Subgroup G} (hP : IsPGroup p P) {Q : Sylow p G} :
Q ∈ fixedPoints P (Sylow p G) ↔ P ≤ Q := by
rw [P.sylow_mem_fixedPoints_iff, ← inf_eq_left, hP.inf_normalizer_sylow, inf_eq_left]
/-- A generalization of **Sylow's second theorem**.
If the number of Sylow `p`-subgroups is finite, then all Sylow `p`-subgroups are conjugate. -/
instance Sylow.isPretransitive_of_finite [hp : Fact p.Prime] [Finite (Sylow p G)] :
IsPretransitive G (Sylow p G) :=
⟨fun P Q => by
classical
have H := fun {R : Sylow p G} {S : orbit G P} =>
calc
S ∈ fixedPoints R (orbit G P) ↔ S.1 ∈ fixedPoints R (Sylow p G) :=
forall_congr' fun a => Subtype.ext_iff
_ ↔ R.1 ≤ S := R.2.sylow_mem_fixedPoints_iff
_ ↔ S.1.1 = R := ⟨fun h => R.3 S.1.2 h, ge_of_eq⟩
suffices Set.Nonempty (fixedPoints Q (orbit G P)) by
exact Exists.elim this fun R hR => by
rw [← Sylow.ext (H.mp hR)]
exact R.2
apply Q.2.nonempty_fixed_point_of_prime_not_dvd_card
refine fun h => hp.out.not_dvd_one (Nat.modEq_zero_iff_dvd.mp ?_)
calc
1 = Nat.card (fixedPoints P (orbit G P)) := ?_
_ ≡ Nat.card (orbit G P) [MOD p] := (P.2.card_modEq_card_fixedPoints (orbit G P)).symm
_ ≡ 0 [MOD p] := Nat.modEq_zero_iff_dvd.mpr h
rw [← Nat.card_unique (α := ({⟨P, mem_orbit_self P⟩} : Set (orbit G P))), eq_comm]
congr
rw [Set.eq_singleton_iff_unique_mem]
exact ⟨H.mpr rfl, fun R h => Subtype.ext (Sylow.ext (H.mp h))⟩⟩
variable (p) (G)
/-- A generalization of **Sylow's third theorem**.
If the number of Sylow `p`-subgroups is finite, then it is congruent to `1` modulo `p`. -/
theorem card_sylow_modEq_one [Fact p.Prime] [Finite (Sylow p G)] :
Nat.card (Sylow p G) ≡ 1 [MOD p] := by
refine Sylow.nonempty.elim fun P : Sylow p G => ?_
have : fixedPoints P.1 (Sylow p G) = {P} :=
Set.ext fun Q : Sylow p G =>
calc
Q ∈ fixedPoints P (Sylow p G) ↔ P.1 ≤ Q := P.2.sylow_mem_fixedPoints_iff
_ ↔ Q.1 = P.1 := ⟨P.3 Q.2, ge_of_eq⟩
_ ↔ Q ∈ {P} := Sylow.ext_iff.symm.trans Set.mem_singleton_iff.symm
have : Nat.card (fixedPoints P.1 (Sylow p G)) = 1 := by simp [this]
exact (P.2.card_modEq_card_fixedPoints (Sylow p G)).trans (by rw [this])
theorem not_dvd_card_sylow [hp : Fact p.Prime] [Finite (Sylow p G)] : ¬p ∣ Nat.card (Sylow p G) :=
fun h =>
hp.1.ne_one
(Nat.dvd_one.mp
((Nat.modEq_iff_dvd' zero_le_one).mp
((Nat.modEq_zero_iff_dvd.mpr h).symm.trans (card_sylow_modEq_one p G))))
variable {p} {G}
namespace Sylow
/-- Sylow subgroups are isomorphic -/
nonrec def equivSMul (P : Sylow p G) (g : G) : P ≃* (g • P : Sylow p G) :=
equivSMul (MulAut.conj g) P.toSubgroup
/-- Sylow subgroups are isomorphic -/
noncomputable def equiv [Fact p.Prime] [Finite (Sylow p G)] (P Q : Sylow p G) : P ≃* Q := by
rw [← Classical.choose_spec (exists_smul_eq G P Q)]
exact P.equivSMul (Classical.choose (exists_smul_eq G P Q))
@[simp]
theorem orbit_eq_top [Fact p.Prime] [Finite (Sylow p G)] (P : Sylow p G) : orbit G P = ⊤ :=
top_le_iff.mp fun Q _ => exists_smul_eq G P Q
theorem stabilizer_eq_normalizer (P : Sylow p G) :
stabilizer G P = P.normalizer := by
ext; simp [smul_eq_iff_mem_normalizer]
theorem conj_eq_normalizer_conj_of_mem_centralizer [Fact p.Prime] [Finite (Sylow p G)]
(P : Sylow p G) (x g : G) (hx : x ∈ centralizer P)
(hy : g⁻¹ * x * g ∈ centralizer P) :
∃ n ∈ P.normalizer, g⁻¹ * x * g = n⁻¹ * x * n := by
have h1 : P ≤ centralizer (zpowers x : Set G) := by rwa [le_centralizer_iff, zpowers_le]
have h2 : ↑(g • P) ≤ centralizer (zpowers x : Set G) := by
rw [le_centralizer_iff, zpowers_le]
rintro - ⟨z, hz, rfl⟩
specialize hy z hz
rwa [← mul_assoc, ← eq_mul_inv_iff_mul_eq, mul_assoc, mul_assoc, mul_assoc, ← mul_assoc,
eq_inv_mul_iff_mul_eq, ← mul_assoc, ← mul_assoc] at hy
obtain ⟨h, hh⟩ :=
exists_smul_eq (centralizer (zpowers x : Set G)) ((g • P).subtype h2) (P.subtype h1)
simp_rw [smul_subtype, Subgroup.smul_def, smul_smul] at hh
refine ⟨h * g, smul_eq_iff_mem_normalizer.mp (subtype_injective hh), ?_⟩
rw [← mul_assoc, Commute.right_comm (h.prop x (mem_zpowers x)), mul_inv_rev, inv_mul_cancel_right]
theorem conj_eq_normalizer_conj_of_mem [Fact p.Prime] [Finite (Sylow p G)] (P : Sylow p G)
[_hP : IsMulCommutative P] (x g : G) (hx : x ∈ P) (hy : g⁻¹ * x * g ∈ P) :
∃ n ∈ P.normalizer, g⁻¹ * x * g = n⁻¹ * x * n :=
P.conj_eq_normalizer_conj_of_mem_centralizer x g
(P.le_centralizer hx) (P.le_centralizer hy)
/-- Sylow `p`-subgroups are in bijection with cosets of the normalizer of a Sylow `p`-subgroup -/
noncomputable def equivQuotientNormalizer [Fact p.Prime] [Finite (Sylow p G)]
(P : Sylow p G) : Sylow p G ≃ G ⧸ P.normalizer :=
calc
Sylow p G ≃ (⊤ : Set (Sylow p G)) := (Equiv.Set.univ (Sylow p G)).symm
_ ≃ orbit G P := Equiv.setCongr P.orbit_eq_top.symm
_ ≃ G ⧸ stabilizer G P := orbitEquivQuotientStabilizer G P
_ ≃ G ⧸ P.normalizer := by rw [P.stabilizer_eq_normalizer]
instance [Fact p.Prime] [Finite (Sylow p G)] (P : Sylow p G) :
Finite (G ⧸ P.normalizer) :=
Finite.of_equiv (Sylow p G) P.equivQuotientNormalizer
theorem card_eq_card_quotient_normalizer [Fact p.Prime] [Finite (Sylow p G)]
(P : Sylow p G) : Nat.card (Sylow p G) = Nat.card (G ⧸ P.normalizer) :=
Nat.card_congr P.equivQuotientNormalizer
@[deprecated (since := "2024-11-07")]
alias _root_.card_sylow_eq_card_quotient_normalizer := card_eq_card_quotient_normalizer
theorem card_eq_index_normalizer [Fact p.Prime] [Finite (Sylow p G)] (P : Sylow p G) :
Nat.card (Sylow p G) = P.normalizer.index :=
P.card_eq_card_quotient_normalizer
@[deprecated (since := "2024-11-07")]
alias _root_.card_sylow_eq_index_normalizer := card_eq_index_normalizer
theorem card_dvd_index [Fact p.Prime] [Finite (Sylow p G)] (P : Sylow p G) :
Nat.card (Sylow p G) ∣ P.index :=
((congr_arg _ P.card_eq_index_normalizer).mp dvd_rfl).trans
(index_dvd_of_le le_normalizer)
@[deprecated (since := "2024-11-07")]
alias _root_.card_sylow_dvd_index := card_dvd_index
/-- Auxiliary lemma for `Sylow.not_dvd_index` which is strictly stronger. -/
private theorem not_dvd_index_aux [hp : Fact p.Prime] (P : Sylow p G) [P.Normal]
[P.FiniteIndex] : ¬ p ∣ P.index := by
intro h
rw [P.index_eq_card] at h
obtain ⟨x, hx⟩ := exists_prime_orderOf_dvd_card' (G := G ⧸ (P : Subgroup G)) p h
have h := IsPGroup.of_card (((Nat.card_zpowers x).trans hx).trans (pow_one p).symm)
let Q := (zpowers x).comap (QuotientGroup.mk' (P : Subgroup G))
have hQ : IsPGroup p Q := by
apply h.comap_of_ker_isPGroup
rw [QuotientGroup.ker_mk']
exact P.2
replace hp := mt orderOf_eq_one_iff.mpr (ne_of_eq_of_ne hx hp.1.ne_one)
rw [← zpowers_eq_bot, ← Ne, ← bot_lt_iff_ne_bot, ←
comap_lt_comap_of_surjective (QuotientGroup.mk'_surjective _), MonoidHom.comap_bot,
QuotientGroup.ker_mk'] at hp
exact hp.ne' (P.3 hQ hp.le)
/-- A Sylow p-subgroup has index indivisible by `p`, assuming [N(P) : P] < ∞. -/
theorem not_dvd_index' [hp : Fact p.Prime] [Finite (Sylow p G)] (P : Sylow p G)
(hP : P.relindex P.normalizer ≠ 0) : ¬ p ∣ P.index := by
rw [← relindex_mul_index le_normalizer, ← card_eq_index_normalizer]
haveI : (P.subtype le_normalizer).Normal :=
Subgroup.normal_in_normalizer
haveI : (P.subtype le_normalizer).FiniteIndex := ⟨hP⟩
replace hP := not_dvd_index_aux (P.subtype le_normalizer)
exact hp.1.not_dvd_mul hP (not_dvd_card_sylow p G)
@[deprecated (since := "2024-11-03")]
alias _root_.not_dvd_index_sylow := not_dvd_index'
/-- A Sylow p-subgroup has index indivisible by `p`. -/
theorem not_dvd_index [Fact p.Prime] [Finite (Sylow p G)] (P : Sylow p G) [P.FiniteIndex] :
¬ p ∣ P.index :=
P.not_dvd_index' Nat.card_pos.ne'
@[deprecated (since := "2024-11-03")]
alias _root_.not_dvd_index_sylow' := not_dvd_index
section mapSurjective
variable [Finite G] {G' : Type*} [Group G'] {f : G →* G'} (hf : Function.Surjective f)
/-- Surjective group homomorphisms map Sylow subgroups to Sylow subgroups. -/
def mapSurjective [Fact p.Prime] (P : Sylow p G) : Sylow p G' :=
{ P.1.map f with
isPGroup' := P.2.map f
is_maximal' := fun hQ hPQ ↦ ((P.2.map f).toSylow
(fun h ↦ P.not_dvd_index (h.trans (P.index_map_dvd hf)))).3 hQ hPQ }
@[simp] theorem coe_mapSurjective [Fact p.Prime] (P : Sylow p G) : P.mapSurjective hf = P.map f :=
rfl
theorem mapSurjective_surjective (p : ℕ) [Fact p.Prime] :
Function.Surjective (Sylow.mapSurjective hf : Sylow p G → Sylow p G') := by
have : Finite G' := Finite.of_surjective f hf
intro P
let Q₀ : Sylow p (P.comap f) := Sylow.nonempty.some
let Q : Subgroup G := Q₀.map (P.comap f).subtype
have hPQ : Q.map f ≤ P := Subgroup.map_le_iff_le_comap.mpr (Subgroup.map_subtype_le Q₀.1)
have hpQ : IsPGroup p Q := Q₀.2.map (P.comap f).subtype
have hQ : ¬ p ∣ Q.index := by
rw [Subgroup.index_map_subtype Q₀.1, P.index_comap_of_surjective hf]
exact Nat.Prime.not_dvd_mul Fact.out Q₀.not_dvd_index P.not_dvd_index
use hpQ.toSylow hQ
rw [Sylow.ext_iff, Sylow.coe_mapSurjective, eq_comm]
exact ((hpQ.map f).toSylow (fun h ↦ hQ (h.trans (Q.index_map_dvd hf)))).3 P.2 hPQ
end mapSurjective
/-- **Frattini's Argument**: If `N` is a normal subgroup of `G`, and if `P` is a Sylow `p`-subgroup
of `N`, then `N_G(P) ⊔ N = G`. -/
theorem normalizer_sup_eq_top {p : ℕ} [Fact p.Prime] {N : Subgroup G} [N.Normal]
[Finite (Sylow p N)] (P : Sylow p N) :
(P.map N.subtype).normalizer ⊔ N = ⊤ := by
refine top_le_iff.mp fun g _ => ?_
obtain ⟨n, hn⟩ := exists_smul_eq N ((MulAut.conjNormal g : MulAut N) • P) P
rw [← inv_mul_cancel_left (↑n) g, sup_comm]
apply mul_mem_sup (N.inv_mem n.2)
rw [smul_def, ← mul_smul, ← MulAut.conjNormal_val, ← MulAut.conjNormal.map_mul,
Sylow.ext_iff, pointwise_smul_def, Subgroup.pointwise_smul_def] at hn
have : Function.Injective (MulAut.conj (n * g)).toMonoidHom := (MulAut.conj (n * g)).injective
refine fun x ↦ (mem_map_iff_mem this).symm.trans ?_
rw [map_map, ← congr_arg (map N.subtype) hn, map_map]
rfl
/-- **Frattini's Argument**: If `N` is a normal subgroup of `G`, and if `P` is a Sylow `p`-subgroup
of `N`, then `N_G(P) ⊔ N = G`. -/
theorem normalizer_sup_eq_top' {p : ℕ} [Fact p.Prime] {N : Subgroup G} [N.Normal]
[Finite (Sylow p N)] (P : Sylow p G) (hP : P ≤ N) : P.normalizer ⊔ N = ⊤ := by
rw [← normalizer_sup_eq_top (P.subtype hP), P.coe_subtype, subgroupOf_map_subtype,
inf_of_le_left hP]
end Sylow
end InfiniteSylow
open Equiv Equiv.Perm Finset Function List QuotientGroup
universe u
variable {G : Type u} [Group G]
theorem QuotientGroup.card_preimage_mk (s : Subgroup G) (t : Set (G ⧸ s)) :
Nat.card (QuotientGroup.mk ⁻¹' t) = Nat.card s * Nat.card t := by
rw [← Nat.card_prod, Nat.card_congr (preimageMkEquivSubgroupProdSet _ _)]
namespace Sylow
theorem mem_fixedPoints_mul_left_cosets_iff_mem_normalizer {H : Subgroup G} [Finite (H : Set G)]
{x : G} : (x : G ⧸ H) ∈ MulAction.fixedPoints H (G ⧸ H) ↔ x ∈ normalizer H :=
⟨fun hx =>
have ha : ∀ {y : G ⧸ H}, y ∈ orbit H (x : G ⧸ H) → y = x := mem_fixedPoints'.1 hx _
(inv_mem_iff (G := G)).1
(mem_normalizer_fintype fun n (hn : n ∈ H) =>
have : (n⁻¹ * x)⁻¹ * x ∈ H := QuotientGroup.eq.1 (ha ⟨⟨n⁻¹, inv_mem hn⟩, rfl⟩)
show _ ∈ H by
rw [mul_inv_rev, inv_inv] at this
convert this
rw [inv_inv]),
fun hx : ∀ n : G, n ∈ H ↔ x * n * x⁻¹ ∈ H =>
mem_fixedPoints'.2 fun y =>
Quotient.inductionOn' y fun y hy =>
QuotientGroup.eq.2
(let ⟨⟨b, hb₁⟩, hb₂⟩ := hy
have hb₂ : (b * x)⁻¹ * y ∈ H := QuotientGroup.eq.1 hb₂
(inv_mem_iff (G := G)).1 <|
(hx _).2 <|
(mul_mem_cancel_left (inv_mem hb₁)).1 <| by
rw [hx] at hb₂; simpa [mul_inv_rev, mul_assoc] using hb₂)⟩
/-- The fixed points of the action of `H` on its cosets correspond to `normalizer H / H`. -/
def fixedPointsMulLeftCosetsEquivQuotient (H : Subgroup G) [Finite (H : Set G)] :
MulAction.fixedPoints H (G ⧸ H) ≃
normalizer H ⧸ Subgroup.comap ((normalizer H).subtype : normalizer H →* G) H :=
@subtypeQuotientEquivQuotientSubtype G (normalizer H : Set G) (_) (_)
(MulAction.fixedPoints H (G ⧸ H))
(fun _ => (@mem_fixedPoints_mul_left_cosets_iff_mem_normalizer _ _ _ ‹_› _).symm)
(by
intros
unfold_projs
rw [leftRel_apply (α := normalizer H), leftRel_apply]
rfl)
/-- If `H` is a `p`-subgroup of `G`, then the index of `H` inside its normalizer is congruent
mod `p` to the index of `H`. -/
theorem card_quotient_normalizer_modEq_card_quotient [Finite G] {p : ℕ} {n : ℕ} [hp : Fact p.Prime]
{H : Subgroup G} (hH : Nat.card H = p ^ n) :
Nat.card (normalizer H ⧸ Subgroup.comap ((normalizer H).subtype : normalizer H →* G) H) ≡
Nat.card (G ⧸ H) [MOD p] := by
rw [← Nat.card_congr (fixedPointsMulLeftCosetsEquivQuotient H)]
exact ((IsPGroup.of_card hH).card_modEq_card_fixedPoints _).symm
/-- If `H` is a subgroup of `G` of cardinality `p ^ n`, then the cardinality of the
normalizer of `H` is congruent mod `p ^ (n + 1)` to the cardinality of `G`. -/
theorem card_normalizer_modEq_card [Finite G] {p : ℕ} {n : ℕ} [hp : Fact p.Prime] {H : Subgroup G}
(hH : Nat.card H = p ^ n) : Nat.card (normalizer H) ≡ Nat.card G [MOD p ^ (n + 1)] := by
have : H.subgroupOf (normalizer H) ≃ H := (subgroupOfEquivOfLe le_normalizer).toEquiv
rw [card_eq_card_quotient_mul_card_subgroup H,
card_eq_card_quotient_mul_card_subgroup (H.subgroupOf (normalizer H)), Nat.card_congr this,
hH, pow_succ']
exact (card_quotient_normalizer_modEq_card_quotient hH).mul_right' _
/-- If `H` is a `p`-subgroup but not a Sylow `p`-subgroup, then `p` divides the
index of `H` inside its normalizer. -/
theorem prime_dvd_card_quotient_normalizer [Finite G] {p : ℕ} {n : ℕ} [Fact p.Prime]
(hdvd : p ^ (n + 1) ∣ Nat.card G) {H : Subgroup G} (hH : Nat.card H = p ^ n) :
p ∣ Nat.card (normalizer H ⧸ Subgroup.comap ((normalizer H).subtype : normalizer H →* G) H) :=
let ⟨s, hs⟩ := exists_eq_mul_left_of_dvd hdvd
have hcard : Nat.card (G ⧸ H) = s * p :=
(mul_left_inj' (show Nat.card H ≠ 0 from Nat.card_pos.ne')).1
(by
rw [← card_eq_card_quotient_mul_card_subgroup H, hH, hs, pow_succ', mul_assoc, mul_comm p])
have hm :
s * p % p =
Nat.card (normalizer H ⧸ Subgroup.comap ((normalizer H).subtype : normalizer H →* G) H) % p :=
hcard ▸ (card_quotient_normalizer_modEq_card_quotient hH).symm
Nat.dvd_of_mod_eq_zero (by rwa [Nat.mod_eq_zero_of_dvd (dvd_mul_left _ _), eq_comm] at hm)
/-- If `H` is a `p`-subgroup but not a Sylow `p`-subgroup of cardinality `p ^ n`,
then `p ^ (n + 1)` divides the cardinality of the normalizer of `H`. -/
theorem prime_pow_dvd_card_normalizer [Finite G] {p : ℕ} {n : ℕ} [_hp : Fact p.Prime]
(hdvd : p ^ (n + 1) ∣ Nat.card G) {H : Subgroup G} (hH : Nat.card H = p ^ n) :
p ^ (n + 1) ∣ Nat.card (normalizer H) :=
Nat.modEq_zero_iff_dvd.1 ((card_normalizer_modEq_card hH).trans hdvd.modEq_zero_nat)
/-- If `H` is a subgroup of `G` of cardinality `p ^ n`,
then `H` is contained in a subgroup of cardinality `p ^ (n + 1)`
if `p ^ (n + 1)` divides the cardinality of `G` -/
theorem exists_subgroup_card_pow_succ [Finite G] {p : ℕ} {n : ℕ} [hp : Fact p.Prime]
(hdvd : p ^ (n + 1) ∣ Nat.card G) {H : Subgroup G} (hH : Nat.card H = p ^ n) :
∃ K : Subgroup G, Nat.card K = p ^ (n + 1) ∧ H ≤ K :=
let ⟨s, hs⟩ := exists_eq_mul_left_of_dvd hdvd
have hcard : Nat.card (G ⧸ H) = s * p :=
(mul_left_inj' (show Nat.card H ≠ 0 from Nat.card_pos.ne')).1
(by
rw [← card_eq_card_quotient_mul_card_subgroup H, hH, hs, pow_succ', mul_assoc, mul_comm p])
have hm : s * p % p = Nat.card (normalizer H ⧸ H.subgroupOf H.normalizer) % p :=
Nat.card_congr (fixedPointsMulLeftCosetsEquivQuotient H) ▸
hcard ▸ (IsPGroup.of_card hH).card_modEq_card_fixedPoints _
have hm' : p ∣ Nat.card (normalizer H ⧸ H.subgroupOf H.normalizer) :=
Nat.dvd_of_mod_eq_zero (by rwa [Nat.mod_eq_zero_of_dvd (dvd_mul_left _ _), eq_comm] at hm)
let ⟨x, hx⟩ := @exists_prime_orderOf_dvd_card' _ (QuotientGroup.Quotient.group _) _ _ hp hm'
have hequiv : H ≃ H.subgroupOf H.normalizer := (subgroupOfEquivOfLe le_normalizer).symm.toEquiv
⟨Subgroup.map (normalizer H).subtype
(Subgroup.comap (mk' (H.subgroupOf H.normalizer)) (zpowers x)), by
show Nat.card (Subgroup.map H.normalizer.subtype
(comap (mk' (H.subgroupOf H.normalizer)) (Subgroup.zpowers x))) = p ^ (n + 1)
suffices Nat.card (Subtype.val ''
(Subgroup.comap (mk' (H.subgroupOf H.normalizer)) (zpowers x) : Set H.normalizer)) =
p ^ (n + 1)
by convert this using 2
rw [Nat.card_image_of_injective Subtype.val_injective
(Subgroup.comap (mk' (H.subgroupOf H.normalizer)) (zpowers x) : Set H.normalizer),
pow_succ, ← hH, Nat.card_congr hequiv, ← hx, ← Nat.card_zpowers, ←
Nat.card_prod]
exact Nat.card_congr
(preimageMkEquivSubgroupProdSet (H.subgroupOf H.normalizer) (zpowers x)), by
intro y hy
simp only [exists_prop, Subgroup.coe_subtype, mk'_apply, Subgroup.mem_map, Subgroup.mem_comap]
refine ⟨⟨y, le_normalizer hy⟩, ⟨0, ?_⟩, rfl⟩
dsimp only
rw [zpow_zero, eq_comm, QuotientGroup.eq_one_iff]
simpa using hy⟩
/-- If `H` is a subgroup of `G` of cardinality `p ^ n`,
then `H` is contained in a subgroup of cardinality `p ^ m`
if `n ≤ m` and `p ^ m` divides the cardinality of `G` -/
theorem exists_subgroup_card_pow_prime_le [Finite G] (p : ℕ) :
∀ {n m : ℕ} [_hp : Fact p.Prime] (_hdvd : p ^ m ∣ Nat.card G) (H : Subgroup G)
(_hH : Nat.card H = p ^ n) (_hnm : n ≤ m), ∃ K : Subgroup G, Nat.card K = p ^ m ∧ H ≤ K
| n, m => fun {hdvd H hH hnm} =>
(lt_or_eq_of_le hnm).elim
(fun hnm : n < m =>
have h0m : 0 < m := lt_of_le_of_lt n.zero_le hnm
have _wf : m - 1 < m := Nat.sub_lt h0m zero_lt_one
have hnm1 : n ≤ m - 1 := le_tsub_of_add_le_right hnm
let ⟨K, hK⟩ :=
@exists_subgroup_card_pow_prime_le _ _ n (m - 1) _
(Nat.pow_dvd_of_le_of_pow_dvd tsub_le_self hdvd) H hH hnm1
have hdvd' : p ^ (m - 1 + 1) ∣ Nat.card G := by rwa [tsub_add_cancel_of_le h0m.nat_succ_le]
let ⟨K', hK'⟩ := @exists_subgroup_card_pow_succ _ _ _ _ _ _ hdvd' K hK.1
⟨K', by rw [hK'.1, tsub_add_cancel_of_le h0m.nat_succ_le], le_trans hK.2 hK'.2⟩)
fun hnm : n = m => ⟨H, by simp [hH, hnm]⟩
/-- A generalisation of **Sylow's first theorem**. If `p ^ n` divides
the cardinality of `G`, then there is a subgroup of cardinality `p ^ n` -/
theorem exists_subgroup_card_pow_prime [Finite G] (p : ℕ) {n : ℕ} [Fact p.Prime]
(hdvd : p ^ n ∣ Nat.card G) : ∃ K : Subgroup G, Nat.card K = p ^ n :=
let ⟨K, hK⟩ := exists_subgroup_card_pow_prime_le p hdvd ⊥
(by rw [card_bot, pow_zero]) n.zero_le
⟨K, hK.1⟩
/-- A special case of **Sylow's first theorem**. If `G` is a `p`-group of size at least `p ^ n`
then there is a subgroup of cardinality `p ^ n`. -/
lemma exists_subgroup_card_pow_prime_of_le_card {n p : ℕ} (hp : p.Prime) (h : IsPGroup p G)
(hn : p ^ n ≤ Nat.card G) : ∃ H : Subgroup G, Nat.card H = p ^ n := by
have : Fact p.Prime := ⟨hp⟩
have : Finite G := Nat.finite_of_card_ne_zero <| by linarith [Nat.one_le_pow n p hp.pos]
obtain ⟨m, hm⟩ := h.exists_card_eq
refine exists_subgroup_card_pow_prime _ ?_
rw [hm] at hn ⊢
exact pow_dvd_pow _ <| (Nat.pow_le_pow_iff_right hp.one_lt).1 hn
/-- A special case of **Sylow's first theorem**. If `G` is a `p`-group and `H` a subgroup of size at
least `p ^ n` then there is a subgroup of `H` of cardinality `p ^ n`. -/
lemma exists_subgroup_le_card_pow_prime_of_le_card {n p : ℕ} (hp : p.Prime) (h : IsPGroup p G)
{H : Subgroup G} (hn : p ^ n ≤ Nat.card H) : ∃ H' ≤ H, Nat.card H' = p ^ n := by
obtain ⟨H', H'card⟩ := exists_subgroup_card_pow_prime_of_le_card hp (h.to_subgroup H) hn
refine ⟨H'.map H.subtype, map_subtype_le _, ?_⟩
rw [← H'card]
let e : H' ≃* H'.map H.subtype := H'.equivMapOfInjective (Subgroup.subtype H) H.subtype_injective
exact Nat.card_congr e.symm.toEquiv
/-- A special case of **Sylow's first theorem**. If `G` is a `p`-group and `H` a subgroup of size at
least `k` then there is a subgroup of `H` of cardinality between `k / p` and `k`. -/
| lemma exists_subgroup_le_card_le {k p : ℕ} (hp : p.Prime) (h : IsPGroup p G) {H : Subgroup G}
(hk : k ≤ Nat.card H) (hk₀ : k ≠ 0) : ∃ H' ≤ H, Nat.card H' ≤ k ∧ k < p * Nat.card H' := by
obtain ⟨m, hmk, hkm⟩ : ∃ s, p ^ s ≤ k ∧ k < p ^ (s + 1) :=
exists_nat_pow_near (Nat.one_le_iff_ne_zero.2 hk₀) hp.one_lt
obtain ⟨H', H'H, H'card⟩ := exists_subgroup_le_card_pow_prime_of_le_card hp h (hmk.trans hk)
refine ⟨H', H'H, ?_⟩
simpa only [pow_succ', H'card] using And.intro hmk hkm
theorem pow_dvd_card_of_pow_dvd_card [Finite G] {p n : ℕ} [hp : Fact p.Prime] (P : Sylow p G)
| Mathlib/GroupTheory/Sylow.lean | 681 | 689 |
/-
Copyright (c) 2019 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Reid Barton, Mario Carneiro, Isabel Longbottom, Kim Morrison, Apurva Nakade, Yuyang Zhao
-/
import Mathlib.Algebra.Order.Monoid.Defs
import Mathlib.SetTheory.PGame.Algebra
import Mathlib.Tactic.Abel
/-!
# Combinatorial games.
In this file we construct an instance `OrderedAddCommGroup SetTheory.Game`.
## Multiplication on pre-games
We define the operations of multiplication and inverse on pre-games, and prove a few basic theorems
about them. Multiplication is not well-behaved under equivalence of pre-games i.e. `x ≈ y` does not
imply `x * z ≈ y * z`. Hence, multiplication is not a well-defined operation on games. Nevertheless,
the abelian group structure on games allows us to simplify many proofs for pre-games.
-/
-- Porting note: many definitions here are noncomputable as the compiler does not support PGame.rec
noncomputable section
namespace SetTheory
open Function PGame
universe u
-- Porting note: moved the setoid instance to PGame.lean
/-- The type of combinatorial games. In ZFC, a combinatorial game is constructed from
two sets of combinatorial games that have been constructed at an earlier
stage. To do this in type theory, we say that a combinatorial pre-game is built
inductively from two families of combinatorial games indexed over any type
in Type u. The resulting type `PGame.{u}` lives in `Type (u+1)`,
reflecting that it is a proper class in ZFC.
A combinatorial game is then constructed by quotienting by the equivalence
`x ≈ y ↔ x ≤ y ∧ y ≤ x`. -/
abbrev Game :=
Quotient PGame.setoid
namespace Game
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/11445): added this definition
/-- Negation of games. -/
instance : Neg Game where
neg := Quot.map Neg.neg <| fun _ _ => (neg_equiv_neg_iff).2
instance : Zero Game where zero := ⟦0⟧
instance : Add Game where
add := Quotient.map₂ HAdd.hAdd <| fun _ _ hx _ _ hy => PGame.add_congr hx hy
instance instAddCommGroupWithOneGame : AddCommGroupWithOne Game where
zero := ⟦0⟧
one := ⟦1⟧
add_zero := by
rintro ⟨x⟩
exact Quot.sound (add_zero_equiv x)
zero_add := by
rintro ⟨x⟩
exact Quot.sound (zero_add_equiv x)
add_assoc := by
rintro ⟨x⟩ ⟨y⟩ ⟨z⟩
exact Quot.sound add_assoc_equiv
neg_add_cancel := Quotient.ind <| fun x => Quot.sound (neg_add_cancel_equiv x)
add_comm := by
rintro ⟨x⟩ ⟨y⟩
exact Quot.sound add_comm_equiv
nsmul := nsmulRec
zsmul := zsmulRec
instance : Inhabited Game :=
⟨0⟩
theorem zero_def : (0 : Game) = ⟦0⟧ :=
rfl
instance instPartialOrderGame : PartialOrder Game where
le := Quotient.lift₂ (· ≤ ·) fun _ _ _ _ hx hy => propext (le_congr hx hy)
le_refl := by
rintro ⟨x⟩
exact le_refl x
le_trans := by
rintro ⟨x⟩ ⟨y⟩ ⟨z⟩
exact @le_trans _ _ x y z
le_antisymm := by
rintro ⟨x⟩ ⟨y⟩ h₁ h₂
apply Quot.sound
exact ⟨h₁, h₂⟩
lt := Quotient.lift₂ (· < ·) fun _ _ _ _ hx hy => propext (lt_congr hx hy)
lt_iff_le_not_le := by
rintro ⟨x⟩ ⟨y⟩
exact @lt_iff_le_not_le _ _ x y
/-- The less or fuzzy relation on games.
If `0 ⧏ x` (less or fuzzy with), then Left can win `x` as the first player. -/
def LF : Game → Game → Prop :=
Quotient.lift₂ PGame.LF fun _ _ _ _ hx hy => propext (lf_congr hx hy)
/-- On `Game`, simp-normal inequalities should use as few negations as possible. -/
@[simp]
theorem not_le : ∀ {x y : Game}, ¬x ≤ y ↔ Game.LF y x := by
rintro ⟨x⟩ ⟨y⟩
exact PGame.not_le
/-- On `Game`, simp-normal inequalities should use as few negations as possible. -/
@[simp]
theorem not_lf : ∀ {x y : Game}, ¬Game.LF x y ↔ y ≤ x := by
rintro ⟨x⟩ ⟨y⟩
exact PGame.not_lf
/-- The fuzzy, confused, or incomparable relation on games.
If `x ‖ 0`, then the first player can always win `x`. -/
def Fuzzy : Game → Game → Prop :=
Quotient.lift₂ PGame.Fuzzy fun _ _ _ _ hx hy => propext (fuzzy_congr hx hy)
-- Porting note: had to replace ⧏ with LF, otherwise cannot differentiate with the operator on PGame
instance : IsTrichotomous Game LF :=
⟨by
rintro ⟨x⟩ ⟨y⟩
change _ ∨ ⟦x⟧ = ⟦y⟧ ∨ _
rw [Quotient.eq]
apply lf_or_equiv_or_gf⟩
/-! It can be useful to use these lemmas to turn `PGame` inequalities into `Game` inequalities, as
the `AddCommGroup` structure on `Game` often simplifies many proofs. -/
end Game
namespace PGame
-- Porting note: In a lot of places, I had to add explicitly that the quotient element was a Game.
-- In Lean4, quotients don't have the setoid as an instance argument,
-- but as an explicit argument, see https://leanprover.zulipchat.com/#narrow/stream/113489-new-members/topic/confusion.20between.20equivalence.20and.20instance.20setoid/near/360822354
theorem le_iff_game_le {x y : PGame} : x ≤ y ↔ (⟦x⟧ : Game) ≤ ⟦y⟧ :=
Iff.rfl
theorem lf_iff_game_lf {x y : PGame} : x ⧏ y ↔ Game.LF ⟦x⟧ ⟦y⟧ :=
Iff.rfl
theorem lt_iff_game_lt {x y : PGame} : x < y ↔ (⟦x⟧ : Game) < ⟦y⟧ :=
Iff.rfl
theorem equiv_iff_game_eq {x y : PGame} : x ≈ y ↔ (⟦x⟧ : Game) = ⟦y⟧ :=
(@Quotient.eq' _ _ x y).symm
alias ⟨game_eq, _⟩ := equiv_iff_game_eq
theorem fuzzy_iff_game_fuzzy {x y : PGame} : x ‖ y ↔ Game.Fuzzy ⟦x⟧ ⟦y⟧ :=
Iff.rfl
end PGame
namespace Game
local infixl:50 " ⧏ " => LF
local infixl:50 " ‖ " => Fuzzy
instance addLeftMono : AddLeftMono Game :=
⟨by
rintro ⟨a⟩ ⟨b⟩ ⟨c⟩ h
exact @add_le_add_left _ _ _ _ b c h a⟩
instance addRightMono : AddRightMono Game :=
⟨by
rintro ⟨a⟩ ⟨b⟩ ⟨c⟩ h
exact @add_le_add_right _ _ _ _ b c h a⟩
instance addLeftStrictMono : AddLeftStrictMono Game :=
⟨by
rintro ⟨a⟩ ⟨b⟩ ⟨c⟩ h
exact @add_lt_add_left _ _ _ _ b c h a⟩
instance addRightStrictMono : AddRightStrictMono Game :=
⟨by
rintro ⟨a⟩ ⟨b⟩ ⟨c⟩ h
exact @add_lt_add_right _ _ _ _ b c h a⟩
theorem add_lf_add_right : ∀ {b c : Game} (_ : b ⧏ c) (a), (b + a : Game) ⧏ c + a := by
rintro ⟨b⟩ ⟨c⟩ h ⟨a⟩
apply PGame.add_lf_add_right h
theorem add_lf_add_left : ∀ {b c : Game} (_ : b ⧏ c) (a), (a + b : Game) ⧏ a + c := by
rintro ⟨b⟩ ⟨c⟩ h ⟨a⟩
apply PGame.add_lf_add_left h
instance isOrderedAddMonoid : IsOrderedAddMonoid Game :=
{ add_le_add_left := @add_le_add_left _ _ _ Game.addLeftMono }
/-- A small family of games is bounded above. -/
lemma bddAbove_range_of_small {ι : Type*} [Small.{u} ι] (f : ι → Game.{u}) :
BddAbove (Set.range f) := by
obtain ⟨x, hx⟩ := PGame.bddAbove_range_of_small (Quotient.out ∘ f)
refine ⟨⟦x⟧, Set.forall_mem_range.2 fun i ↦ ?_⟩
simpa [PGame.le_iff_game_le] using hx <| Set.mem_range_self i
/-- A small set of games is bounded above. -/
lemma bddAbove_of_small (s : Set Game.{u}) [Small.{u} s] : BddAbove s := by
simpa using bddAbove_range_of_small (Subtype.val : s → Game.{u})
/-- A small family of games is bounded below. -/
lemma bddBelow_range_of_small {ι : Type*} [Small.{u} ι] (f : ι → Game.{u}) :
BddBelow (Set.range f) := by
obtain ⟨x, hx⟩ := PGame.bddBelow_range_of_small (Quotient.out ∘ f)
refine ⟨⟦x⟧, Set.forall_mem_range.2 fun i ↦ ?_⟩
simpa [PGame.le_iff_game_le] using hx <| Set.mem_range_self i
/-- A small set of games is bounded below. -/
lemma bddBelow_of_small (s : Set Game.{u}) [Small.{u} s] : BddBelow s := by
simpa using bddBelow_range_of_small (Subtype.val : s → Game.{u})
end Game
namespace PGame
@[simp] theorem quot_zero : (⟦0⟧ : Game) = 0 := rfl
@[simp] theorem quot_one : (⟦1⟧ : Game) = 1 := rfl
@[simp] theorem quot_neg (a : PGame) : (⟦-a⟧ : Game) = -⟦a⟧ := rfl
@[simp] theorem quot_add (a b : PGame) : ⟦a + b⟧ = (⟦a⟧ : Game) + ⟦b⟧ := rfl
@[simp] theorem quot_sub (a b : PGame) : ⟦a - b⟧ = (⟦a⟧ : Game) - ⟦b⟧ := rfl
@[simp]
theorem quot_natCast : ∀ n : ℕ, ⟦(n : PGame)⟧ = (n : Game)
| 0 => rfl
| n + 1 => by
rw [PGame.nat_succ, quot_add, Nat.cast_add, Nat.cast_one, quot_natCast]
rfl
theorem quot_eq_of_mk'_quot_eq {x y : PGame} (L : x.LeftMoves ≃ y.LeftMoves)
(R : x.RightMoves ≃ y.RightMoves) (hl : ∀ i, (⟦x.moveLeft i⟧ : Game) = ⟦y.moveLeft (L i)⟧)
(hr : ∀ j, (⟦x.moveRight j⟧ : Game) = ⟦y.moveRight (R j)⟧) : (⟦x⟧ : Game) = ⟦y⟧ :=
game_eq (.of_equiv L R (fun _ => equiv_iff_game_eq.2 (hl _))
(fun _ => equiv_iff_game_eq.2 (hr _)))
/-! Multiplicative operations can be defined at the level of pre-games,
but to prove their properties we need to use the abelian group structure of games.
Hence we define them here. -/
/-- The product of `x = {xL | xR}` and `y = {yL | yR}` is
`{xL*y + x*yL - xL*yL, xR*y + x*yR - xR*yR | xL*y + x*yR - xL*yR, xR*y + x*yL - xR*yL}`. -/
instance : Mul PGame.{u} :=
⟨fun x y => by
induction x generalizing y with | mk xl xr _ _ IHxl IHxr => _
induction y with | mk yl yr yL yR IHyl IHyr => _
have y := mk yl yr yL yR
refine ⟨(xl × yl) ⊕ (xr × yr), (xl × yr) ⊕ (xr × yl), ?_, ?_⟩ <;> rintro (⟨i, j⟩ | ⟨i, j⟩)
· exact IHxl i y + IHyl j - IHxl i (yL j)
· exact IHxr i y + IHyr j - IHxr i (yR j)
· exact IHxl i y + IHyr j - IHxl i (yR j)
· exact IHxr i y + IHyl j - IHxr i (yL j)⟩
theorem leftMoves_mul :
∀ x y : PGame.{u},
(x * y).LeftMoves = (x.LeftMoves × y.LeftMoves ⊕ x.RightMoves × y.RightMoves)
| ⟨_, _, _, _⟩, ⟨_, _, _, _⟩ => rfl
theorem rightMoves_mul :
∀ x y : PGame.{u},
(x * y).RightMoves = (x.LeftMoves × y.RightMoves ⊕ x.RightMoves × y.LeftMoves)
| ⟨_, _, _, _⟩, ⟨_, _, _, _⟩ => rfl
/-- Turns two left or right moves for `x` and `y` into a left move for `x * y` and vice versa.
Even though these types are the same (not definitionally so), this is the preferred way to convert
between them. -/
def toLeftMovesMul {x y : PGame} :
(x.LeftMoves × y.LeftMoves) ⊕ (x.RightMoves × y.RightMoves) ≃ (x * y).LeftMoves :=
Equiv.cast (leftMoves_mul x y).symm
/-- Turns a left and a right move for `x` and `y` into a right move for `x * y` and vice versa.
Even though these types are the same (not definitionally so), this is the preferred way to convert
between them. -/
def toRightMovesMul {x y : PGame} :
(x.LeftMoves × y.RightMoves) ⊕ (x.RightMoves × y.LeftMoves) ≃ (x * y).RightMoves :=
Equiv.cast (rightMoves_mul x y).symm
@[simp]
theorem mk_mul_moveLeft_inl {xl xr yl yr} {xL xR yL yR} {i j} :
(mk xl xr xL xR * mk yl yr yL yR).moveLeft (Sum.inl (i, j)) =
xL i * mk yl yr yL yR + mk xl xr xL xR * yL j - xL i * yL j :=
rfl
@[simp]
theorem mul_moveLeft_inl {x y : PGame} {i j} :
(x * y).moveLeft (toLeftMovesMul (Sum.inl (i, j))) =
x.moveLeft i * y + x * y.moveLeft j - x.moveLeft i * y.moveLeft j := by
cases x
cases y
rfl
@[simp]
theorem mk_mul_moveLeft_inr {xl xr yl yr} {xL xR yL yR} {i j} :
(mk xl xr xL xR * mk yl yr yL yR).moveLeft (Sum.inr (i, j)) =
xR i * mk yl yr yL yR + mk xl xr xL xR * yR j - xR i * yR j :=
rfl
@[simp]
theorem mul_moveLeft_inr {x y : PGame} {i j} :
(x * y).moveLeft (toLeftMovesMul (Sum.inr (i, j))) =
x.moveRight i * y + x * y.moveRight j - x.moveRight i * y.moveRight j := by
cases x
cases y
rfl
@[simp]
theorem mk_mul_moveRight_inl {xl xr yl yr} {xL xR yL yR} {i j} :
(mk xl xr xL xR * mk yl yr yL yR).moveRight (Sum.inl (i, j)) =
xL i * mk yl yr yL yR + mk xl xr xL xR * yR j - xL i * yR j :=
rfl
@[simp]
theorem mul_moveRight_inl {x y : PGame} {i j} :
(x * y).moveRight (toRightMovesMul (Sum.inl (i, j))) =
x.moveLeft i * y + x * y.moveRight j - x.moveLeft i * y.moveRight j := by
cases x
cases y
rfl
@[simp]
theorem mk_mul_moveRight_inr {xl xr yl yr} {xL xR yL yR} {i j} :
(mk xl xr xL xR * mk yl yr yL yR).moveRight (Sum.inr (i, j)) =
xR i * mk yl yr yL yR + mk xl xr xL xR * yL j - xR i * yL j :=
rfl
@[simp]
theorem mul_moveRight_inr {x y : PGame} {i j} :
(x * y).moveRight (toRightMovesMul (Sum.inr (i, j))) =
x.moveRight i * y + x * y.moveLeft j - x.moveRight i * y.moveLeft j := by
cases x
cases y
rfl
@[simp]
theorem neg_mk_mul_moveLeft_inl {xl xr yl yr} {xL xR yL yR} {i j} :
(-(mk xl xr xL xR * mk yl yr yL yR)).moveLeft (Sum.inl (i, j)) =
-(xL i * mk yl yr yL yR + mk xl xr xL xR * yR j - xL i * yR j) :=
rfl
@[simp]
theorem neg_mk_mul_moveLeft_inr {xl xr yl yr} {xL xR yL yR} {i j} :
(-(mk xl xr xL xR * mk yl yr yL yR)).moveLeft (Sum.inr (i, j)) =
-(xR i * mk yl yr yL yR + mk xl xr xL xR * yL j - xR i * yL j) :=
rfl
@[simp]
theorem neg_mk_mul_moveRight_inl {xl xr yl yr} {xL xR yL yR} {i j} :
(-(mk xl xr xL xR * mk yl yr yL yR)).moveRight (Sum.inl (i, j)) =
-(xL i * mk yl yr yL yR + mk xl xr xL xR * yL j - xL i * yL j) :=
rfl
@[simp]
theorem neg_mk_mul_moveRight_inr {xl xr yl yr} {xL xR yL yR} {i j} :
(-(mk xl xr xL xR * mk yl yr yL yR)).moveRight (Sum.inr (i, j)) =
-(xR i * mk yl yr yL yR + mk xl xr xL xR * yR j - xR i * yR j) :=
rfl
theorem leftMoves_mul_cases {x y : PGame} (k) {P : (x * y).LeftMoves → Prop}
(hl : ∀ ix iy, P <| toLeftMovesMul (Sum.inl ⟨ix, iy⟩))
(hr : ∀ jx jy, P <| toLeftMovesMul (Sum.inr ⟨jx, jy⟩)) : P k := by
rw [← toLeftMovesMul.apply_symm_apply k]
rcases toLeftMovesMul.symm k with (⟨ix, iy⟩ | ⟨jx, jy⟩)
· apply hl
· apply hr
theorem rightMoves_mul_cases {x y : PGame} (k) {P : (x * y).RightMoves → Prop}
(hl : ∀ ix jy, P <| toRightMovesMul (Sum.inl ⟨ix, jy⟩))
(hr : ∀ jx iy, P <| toRightMovesMul (Sum.inr ⟨jx, iy⟩)) : P k := by
rw [← toRightMovesMul.apply_symm_apply k]
rcases toRightMovesMul.symm k with (⟨ix, iy⟩ | ⟨jx, jy⟩)
· apply hl
· apply hr
/-- `x * y` and `y * x` have the same moves. -/
protected lemma mul_comm (x y : PGame) : x * y ≡ y * x :=
match x, y with
| ⟨xl, xr, xL, xR⟩, ⟨yl, yr, yL, yR⟩ => by
refine Identical.of_equiv ((Equiv.prodComm _ _).sumCongr (Equiv.prodComm _ _))
((Equiv.sumComm _ _).trans ((Equiv.prodComm _ _).sumCongr (Equiv.prodComm _ _))) ?_ ?_ <;>
· rintro (⟨_, _⟩ | ⟨_, _⟩) <;>
exact ((((PGame.mul_comm _ (mk _ _ _ _)).add (PGame.mul_comm (mk _ _ _ _) _)).trans
(PGame.add_comm _ _)).sub (PGame.mul_comm _ _))
termination_by (x, y)
/-- `x * y` and `y * x` have the same moves. -/
def mulCommRelabelling (x y : PGame.{u}) : x * y ≡r y * x :=
match x, y with
| ⟨xl, xr, xL, xR⟩, ⟨yl, yr, yL, yR⟩ => by
refine ⟨Equiv.sumCongr (Equiv.prodComm _ _) (Equiv.prodComm _ _),
(Equiv.sumComm _ _).trans (Equiv.sumCongr (Equiv.prodComm _ _) (Equiv.prodComm _ _)), ?_, ?_⟩
<;>
rintro (⟨i, j⟩ | ⟨i, j⟩) <;>
{ dsimp
exact ((addCommRelabelling _ _).trans <|
(mulCommRelabelling _ _).addCongr (mulCommRelabelling _ _)).subCongr
(mulCommRelabelling _ _) }
termination_by (x, y)
theorem quot_mul_comm (x y : PGame.{u}) : (⟦x * y⟧ : Game) = ⟦y * x⟧ :=
game_eq (x.mul_comm y).equiv
/-- `x * y` is equivalent to `y * x`. -/
theorem mul_comm_equiv (x y : PGame) : x * y ≈ y * x :=
Quotient.exact <| quot_mul_comm _ _
instance isEmpty_leftMoves_mul (x y : PGame.{u})
[IsEmpty (x.LeftMoves × y.LeftMoves ⊕ x.RightMoves × y.RightMoves)] :
IsEmpty (x * y).LeftMoves := by
cases x
cases y
assumption
instance isEmpty_rightMoves_mul (x y : PGame.{u})
[IsEmpty (x.LeftMoves × y.RightMoves ⊕ x.RightMoves × y.LeftMoves)] :
IsEmpty (x * y).RightMoves := by
cases x
cases y
assumption
/-- `x * 0` has exactly the same moves as `0`. -/
protected lemma mul_zero (x : PGame) : x * 0 ≡ 0 := identical_zero _
/-- `x * 0` has exactly the same moves as `0`. -/
def mulZeroRelabelling (x : PGame) : x * 0 ≡r 0 :=
Relabelling.isEmpty _
/-- `x * 0` is equivalent to `0`. -/
theorem mul_zero_equiv (x : PGame) : x * 0 ≈ 0 :=
x.mul_zero.equiv
@[simp]
theorem quot_mul_zero (x : PGame) : (⟦x * 0⟧ : Game) = 0 :=
game_eq x.mul_zero_equiv
/-- `0 * x` has exactly the same moves as `0`. -/
protected lemma zero_mul (x : PGame) : 0 * x ≡ 0 := identical_zero _
/-- `0 * x` has exactly the same moves as `0`. -/
def zeroMulRelabelling (x : PGame) : 0 * x ≡r 0 :=
Relabelling.isEmpty _
/-- `0 * x` is equivalent to `0`. -/
theorem zero_mul_equiv (x : PGame) : 0 * x ≈ 0 :=
x.zero_mul.equiv
@[simp]
theorem quot_zero_mul (x : PGame) : (⟦0 * x⟧ : Game) = 0 :=
game_eq x.zero_mul_equiv
/-- `-x * y` and `-(x * y)` have the same moves. -/
def negMulRelabelling (x y : PGame.{u}) : -x * y ≡r -(x * y) :=
match x, y with
| ⟨xl, xr, xL, xR⟩, ⟨yl, yr, yL, yR⟩ => by
refine ⟨Equiv.sumComm _ _, Equiv.sumComm _ _, ?_, ?_⟩ <;>
rintro (⟨i, j⟩ | ⟨i, j⟩) <;>
· dsimp
apply ((negAddRelabelling _ _).trans _).symm
apply ((negAddRelabelling _ _).trans (Relabelling.addCongr _ _)).subCongr
-- Porting note: we used to just do `<;> exact (negMulRelabelling _ _).symm` from here.
· exact (negMulRelabelling _ _).symm
· exact (negMulRelabelling _ _).symm
-- Porting note: not sure what has gone wrong here.
-- The goal is hideous here, and the `exact` doesn't work,
-- but if we just `change` it to look like the mathlib3 goal then we're fine!?
change -(mk xl xr xL xR * _) ≡r _
exact (negMulRelabelling _ _).symm
termination_by (x, y)
/-- `x * -y` and `-(x * y)` have the same moves. -/
@[simp]
lemma mul_neg (x y : PGame) : x * -y = -(x * y) :=
match x, y with
| mk xl xr xL xR, mk yl yr yL yR => by
refine ext rfl rfl ?_ ?_ <;> rintro (⟨i, j⟩ | ⟨i, j⟩) _ ⟨rfl⟩
all_goals
dsimp
rw [PGame.neg_sub', PGame.neg_add]
congr
exacts [mul_neg _ (mk ..), mul_neg .., mul_neg ..]
termination_by (x, y)
/-- `-x * y` and `-(x * y)` have the same moves. -/
lemma neg_mul (x y : PGame) : -x * y ≡ -(x * y) :=
((PGame.mul_comm _ _).trans (of_eq (mul_neg _ _))).trans (PGame.mul_comm _ _).neg
@[simp]
theorem quot_neg_mul (x y : PGame) : (⟦-x * y⟧ : Game) = -⟦x * y⟧ :=
game_eq (x.neg_mul y).equiv
/-- `x * -y` and `-(x * y)` have the same moves. -/
def mulNegRelabelling (x y : PGame) : x * -y ≡r -(x * y) :=
(mulCommRelabelling x _).trans <| (negMulRelabelling _ x).trans (mulCommRelabelling y x).negCongr
theorem quot_mul_neg (x y : PGame) : ⟦x * -y⟧ = (-⟦x * y⟧ : Game) :=
game_eq (by rw [mul_neg])
theorem quot_neg_mul_neg (x y : PGame) : ⟦-x * -y⟧ = (⟦x * y⟧ : Game) := by simp
@[simp]
theorem quot_left_distrib (x y z : PGame) : (⟦x * (y + z)⟧ : Game) = ⟦x * y⟧ + ⟦x * z⟧ :=
match x, y, z with
| mk xl xr xL xR, mk yl yr yL yR, mk zl zr zL zR => by
let x := mk xl xr xL xR
let y := mk yl yr yL yR
let z := mk zl zr zL zR
refine quot_eq_of_mk'_quot_eq ?_ ?_ ?_ ?_
· fconstructor
· rintro (⟨_, _ | _⟩ | ⟨_, _ | _⟩) <;>
-- Porting note: we've increased `maxDepth` here from `5` to `6`.
-- Likely this sort of off-by-one error is just a change in the implementation
-- of `solve_by_elim`.
solve_by_elim (config := { maxDepth := 6 }) [Sum.inl, Sum.inr, Prod.mk]
· rintro (⟨⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, _⟩ | ⟨_, _⟩) <;>
solve_by_elim (config := { maxDepth := 6 }) [Sum.inl, Sum.inr, Prod.mk]
· rintro (⟨_, _ | _⟩ | ⟨_, _ | _⟩) <;> rfl
· rintro (⟨⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, _⟩ | ⟨_, _⟩) <;> rfl
· fconstructor
· rintro (⟨_, _ | _⟩ | ⟨_, _ | _⟩) <;>
solve_by_elim (config := { maxDepth := 6 }) [Sum.inl, Sum.inr, Prod.mk]
· rintro (⟨⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, _⟩ | ⟨_, _⟩) <;>
solve_by_elim (config := { maxDepth := 6 }) [Sum.inl, Sum.inr, Prod.mk]
· rintro (⟨_, _ | _⟩ | ⟨_, _ | _⟩) <;> rfl
· rintro (⟨⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, _⟩ | ⟨_, _⟩) <;> rfl
-- Porting note: explicitly wrote out arguments to each recursive
-- quot_left_distrib reference below, because otherwise the decreasing_by block
-- failed. Previously, each branch ended with: `simp [quot_left_distrib]; abel`
-- See https://github.com/leanprover/lean4/issues/2288
· rintro (⟨i, j | k⟩ | ⟨i, j | k⟩)
· change
⟦xL i * (y + z) + x * (yL j + z) - xL i * (yL j + z)⟧ =
⟦xL i * y + x * yL j - xL i * yL j + x * z⟧
simp only [quot_sub, quot_add]
rw [quot_left_distrib (xL i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_left_distrib (mk xl xr xL xR) (yL j) (mk zl zr zL zR)]
rw [quot_left_distrib (xL i) (yL j) (mk zl zr zL zR)]
abel
· change
⟦xL i * (y + z) + x * (y + zL k) - xL i * (y + zL k)⟧ =
⟦x * y + (xL i * z + x * zL k - xL i * zL k)⟧
simp only [quot_sub, quot_add]
rw [quot_left_distrib (xL i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_left_distrib (mk xl xr xL xR) (mk yl yr yL yR) (zL k)]
rw [quot_left_distrib (xL i) (mk yl yr yL yR) (zL k)]
abel
· change
⟦xR i * (y + z) + x * (yR j + z) - xR i * (yR j + z)⟧ =
⟦xR i * y + x * yR j - xR i * yR j + x * z⟧
simp only [quot_sub, quot_add]
rw [quot_left_distrib (xR i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_left_distrib (mk xl xr xL xR) (yR j) (mk zl zr zL zR)]
rw [quot_left_distrib (xR i) (yR j) (mk zl zr zL zR)]
abel
· change
⟦xR i * (y + z) + x * (y + zR k) - xR i * (y + zR k)⟧ =
⟦x * y + (xR i * z + x * zR k - xR i * zR k)⟧
simp only [quot_sub, quot_add]
rw [quot_left_distrib (xR i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_left_distrib (mk xl xr xL xR) (mk yl yr yL yR) (zR k)]
rw [quot_left_distrib (xR i) (mk yl yr yL yR) (zR k)]
abel
· rintro (⟨i, j | k⟩ | ⟨i, j | k⟩)
· change
⟦xL i * (y + z) + x * (yR j + z) - xL i * (yR j + z)⟧ =
⟦xL i * y + x * yR j - xL i * yR j + x * z⟧
simp only [quot_sub, quot_add]
rw [quot_left_distrib (xL i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_left_distrib (mk xl xr xL xR) (yR j) (mk zl zr zL zR)]
rw [quot_left_distrib (xL i) (yR j) (mk zl zr zL zR)]
abel
· change
⟦xL i * (y + z) + x * (y + zR k) - xL i * (y + zR k)⟧ =
⟦x * y + (xL i * z + x * zR k - xL i * zR k)⟧
simp only [quot_sub, quot_add]
rw [quot_left_distrib (xL i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_left_distrib (mk xl xr xL xR) (mk yl yr yL yR) (zR k)]
rw [quot_left_distrib (xL i) (mk yl yr yL yR) (zR k)]
abel
· change
⟦xR i * (y + z) + x * (yL j + z) - xR i * (yL j + z)⟧ =
⟦xR i * y + x * yL j - xR i * yL j + x * z⟧
simp only [quot_sub, quot_add]
rw [quot_left_distrib (xR i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_left_distrib (mk xl xr xL xR) (yL j) (mk zl zr zL zR)]
rw [quot_left_distrib (xR i) (yL j) (mk zl zr zL zR)]
abel
· change
⟦xR i * (y + z) + x * (y + zL k) - xR i * (y + zL k)⟧ =
⟦x * y + (xR i * z + x * zL k - xR i * zL k)⟧
simp only [quot_sub, quot_add]
rw [quot_left_distrib (xR i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_left_distrib (mk xl xr xL xR) (mk yl yr yL yR) (zL k)]
rw [quot_left_distrib (xR i) (mk yl yr yL yR) (zL k)]
abel
termination_by (x, y, z)
/-- `x * (y + z)` is equivalent to `x * y + x * z`. -/
theorem left_distrib_equiv (x y z : PGame) : x * (y + z) ≈ x * y + x * z :=
Quotient.exact <| quot_left_distrib _ _ _
@[simp]
theorem quot_left_distrib_sub (x y z : PGame) : (⟦x * (y - z)⟧ : Game) = ⟦x * y⟧ - ⟦x * z⟧ := by
change (⟦x * (y + -z)⟧ : Game) = ⟦x * y⟧ + -⟦x * z⟧
rw [quot_left_distrib, quot_mul_neg]
@[simp]
theorem quot_right_distrib (x y z : PGame) : (⟦(x + y) * z⟧ : Game) = ⟦x * z⟧ + ⟦y * z⟧ := by
simp only [quot_mul_comm, quot_left_distrib]
/-- `(x + y) * z` is equivalent to `x * z + y * z`. -/
theorem right_distrib_equiv (x y z : PGame) : (x + y) * z ≈ x * z + y * z :=
Quotient.exact <| quot_right_distrib _ _ _
@[simp]
theorem quot_right_distrib_sub (x y z : PGame) : (⟦(y - z) * x⟧ : Game) = ⟦y * x⟧ - ⟦z * x⟧ := by
change (⟦(y + -z) * x⟧ : Game) = ⟦y * x⟧ + -⟦z * x⟧
rw [quot_right_distrib, quot_neg_mul]
/-- `x * 1` has the same moves as `x`. -/
def mulOneRelabelling : ∀ x : PGame.{u}, x * 1 ≡r x
| ⟨xl, xr, xL, xR⟩ => by
-- Porting note: the next four lines were just `unfold has_one.one,`
show _ * One.one ≡r _
unfold One.one
unfold instOnePGame
change mk _ _ _ _ * mk _ _ _ _ ≡r _
refine ⟨(Equiv.sumEmpty _ _).trans (Equiv.prodPUnit _),
(Equiv.emptySum _ _).trans (Equiv.prodPUnit _), ?_, ?_⟩ <;>
(try rintro (⟨i, ⟨⟩⟩ | ⟨i, ⟨⟩⟩)) <;>
{ dsimp
apply (Relabelling.subCongr (Relabelling.refl _) (mulZeroRelabelling _)).trans
rw [sub_zero_eq_add_zero]
exact (addZeroRelabelling _).trans <|
(((mulOneRelabelling _).addCongr (mulZeroRelabelling _)).trans <| addZeroRelabelling _) }
/-- `1 * x` has the same moves as `x`. -/
protected lemma one_mul : ∀ (x : PGame), 1 * x ≡ x
| ⟨xl, xr, xL, xR⟩ => by
refine Identical.of_equiv ((Equiv.sumEmpty _ _).trans (Equiv.punitProd _))
((Equiv.sumEmpty _ _).trans (Equiv.punitProd _)) ?_ ?_ <;>
· rintro (⟨⟨⟩, _⟩ | ⟨⟨⟩, _⟩)
exact ((((PGame.zero_mul (mk _ _ _ _)).add (PGame.one_mul _)).trans (PGame.zero_add _)).sub
(PGame.zero_mul _)).trans (PGame.sub_zero _)
/-- `x * 1` has the same moves as `x`. -/
protected lemma mul_one (x : PGame) : x * 1 ≡ x := (x.mul_comm _).trans x.one_mul
@[simp]
theorem quot_mul_one (x : PGame) : (⟦x * 1⟧ : Game) = ⟦x⟧ :=
game_eq x.mul_one.equiv
/-- `x * 1` is equivalent to `x`. -/
theorem mul_one_equiv (x : PGame) : x * 1 ≈ x :=
Quotient.exact <| quot_mul_one x
/-- `1 * x` has the same moves as `x`. -/
def oneMulRelabelling (x : PGame) : 1 * x ≡r x :=
(mulCommRelabelling 1 x).trans <| mulOneRelabelling x
@[simp]
theorem quot_one_mul (x : PGame) : (⟦1 * x⟧ : Game) = ⟦x⟧ :=
game_eq x.one_mul.equiv
/-- `1 * x` is equivalent to `x`. -/
theorem one_mul_equiv (x : PGame) : 1 * x ≈ x :=
Quotient.exact <| quot_one_mul x
theorem quot_mul_assoc (x y z : PGame) : (⟦x * y * z⟧ : Game) = ⟦x * (y * z)⟧ :=
match x, y, z with
| mk xl xr xL xR, mk yl yr yL yR, mk zl zr zL zR => by
let x := mk xl xr xL xR
let y := mk yl yr yL yR
let z := mk zl zr zL zR
refine quot_eq_of_mk'_quot_eq ?_ ?_ ?_ ?_
· fconstructor
· rintro (⟨⟨_, _⟩ | ⟨_, _⟩, _⟩ | ⟨⟨_, _⟩ | ⟨_, _⟩, _⟩) <;>
-- Porting note: as above, increased the `maxDepth` here by 1.
solve_by_elim (config := { maxDepth := 8 }) [Sum.inl, Sum.inr, Prod.mk]
· rintro (⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩) <;>
solve_by_elim (config := { maxDepth := 8 }) [Sum.inl, Sum.inr, Prod.mk]
· rintro (⟨⟨_, _⟩ | ⟨_, _⟩, _⟩ | ⟨⟨_, _⟩ | ⟨_, _⟩, _⟩) <;> rfl
· rintro (⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩) <;> rfl
· fconstructor
· rintro (⟨⟨_, _⟩ | ⟨_, _⟩, _⟩ | ⟨⟨_, _⟩ | ⟨_, _⟩, _⟩) <;>
solve_by_elim (config := { maxDepth := 8 }) [Sum.inl, Sum.inr, Prod.mk]
· rintro (⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩) <;>
solve_by_elim (config := { maxDepth := 8 }) [Sum.inl, Sum.inr, Prod.mk]
· rintro (⟨⟨_, _⟩ | ⟨_, _⟩, _⟩ | ⟨⟨_, _⟩ | ⟨_, _⟩, _⟩) <;> rfl
· rintro (⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩ | ⟨_, ⟨_, _⟩ | ⟨_, _⟩⟩) <;> rfl
-- Porting note: explicitly wrote out arguments to each recursive
-- quot_mul_assoc reference below, because otherwise the decreasing_by block
-- failed. Each branch previously ended with: `simp [quot_mul_assoc]; abel`
-- See https://github.com/leanprover/lean4/issues/2288
· rintro (⟨⟨i, j⟩ | ⟨i, j⟩, k⟩ | ⟨⟨i, j⟩ | ⟨i, j⟩, k⟩)
· change
⟦(xL i * y + x * yL j - xL i * yL j) * z + x * y * zL k -
(xL i * y + x * yL j - xL i * yL j) * zL k⟧ =
⟦xL i * (y * z) + x * (yL j * z + y * zL k - yL j * zL k) -
xL i * (yL j * z + y * zL k - yL j * zL k)⟧
simp only [quot_sub, quot_add, quot_right_distrib_sub, quot_right_distrib,
quot_left_distrib_sub, quot_left_distrib]
rw [quot_mul_assoc (xL i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (yL j) (mk zl zr zL zR)]
rw [quot_mul_assoc (xL i) (yL j) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (mk yl yr yL yR) (zL k)]
rw [quot_mul_assoc (xL i) (mk yl yr yL yR) (zL k)]
rw [quot_mul_assoc (mk xl xr xL xR) (yL j) (zL k)]
rw [quot_mul_assoc (xL i) (yL j) (zL k)]
abel
· change
⟦(xR i * y + x * yR j - xR i * yR j) * z + x * y * zL k -
(xR i * y + x * yR j - xR i * yR j) * zL k⟧ =
⟦xR i * (y * z) + x * (yR j * z + y * zL k - yR j * zL k) -
xR i * (yR j * z + y * zL k - yR j * zL k)⟧
simp only [quot_sub, quot_add, quot_right_distrib_sub, quot_right_distrib,
quot_left_distrib_sub, quot_left_distrib]
rw [quot_mul_assoc (xR i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (yR j) (mk zl zr zL zR)]
rw [quot_mul_assoc (xR i) (yR j) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (mk yl yr yL yR) (zL k)]
rw [quot_mul_assoc (xR i) (mk yl yr yL yR) (zL k)]
rw [quot_mul_assoc (mk xl xr xL xR) (yR j) (zL k)]
rw [quot_mul_assoc (xR i) (yR j) (zL k)]
abel
· change
⟦(xL i * y + x * yR j - xL i * yR j) * z + x * y * zR k -
(xL i * y + x * yR j - xL i * yR j) * zR k⟧ =
⟦xL i * (y * z) + x * (yR j * z + y * zR k - yR j * zR k) -
xL i * (yR j * z + y * zR k - yR j * zR k)⟧
simp only [quot_sub, quot_add, quot_right_distrib_sub, quot_right_distrib,
quot_left_distrib_sub, quot_left_distrib]
rw [quot_mul_assoc (xL i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (yR j) (mk zl zr zL zR)]
rw [quot_mul_assoc (xL i) (yR j) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (mk yl yr yL yR) (zR k)]
rw [quot_mul_assoc (xL i) (mk yl yr yL yR) (zR k)]
rw [quot_mul_assoc (mk xl xr xL xR) (yR j) (zR k)]
rw [quot_mul_assoc (xL i) (yR j) (zR k)]
abel
· change
⟦(xR i * y + x * yL j - xR i * yL j) * z + x * y * zR k -
(xR i * y + x * yL j - xR i * yL j) * zR k⟧ =
⟦xR i * (y * z) + x * (yL j * z + y * zR k - yL j * zR k) -
xR i * (yL j * z + y * zR k - yL j * zR k)⟧
simp only [quot_sub, quot_add, quot_right_distrib_sub, quot_right_distrib,
quot_left_distrib_sub, quot_left_distrib]
rw [quot_mul_assoc (xR i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (yL j) (mk zl zr zL zR)]
rw [quot_mul_assoc (xR i) (yL j) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (mk yl yr yL yR) (zR k)]
rw [quot_mul_assoc (xR i) (mk yl yr yL yR) (zR k)]
rw [quot_mul_assoc (mk xl xr xL xR) (yL j) (zR k)]
rw [quot_mul_assoc (xR i) (yL j) (zR k)]
abel
· rintro (⟨⟨i, j⟩ | ⟨i, j⟩, k⟩ | ⟨⟨i, j⟩ | ⟨i, j⟩, k⟩)
· change
⟦(xL i * y + x * yL j - xL i * yL j) * z + x * y * zR k -
(xL i * y + x * yL j - xL i * yL j) * zR k⟧ =
⟦xL i * (y * z) + x * (yL j * z + y * zR k - yL j * zR k) -
xL i * (yL j * z + y * zR k - yL j * zR k)⟧
simp only [quot_sub, quot_add, quot_right_distrib_sub, quot_right_distrib,
quot_left_distrib_sub, quot_left_distrib]
rw [quot_mul_assoc (xL i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (yL j) (mk zl zr zL zR)]
rw [quot_mul_assoc (xL i) (yL j) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (mk yl yr yL yR) (zR k)]
rw [quot_mul_assoc (xL i) (mk yl yr yL yR) (zR k)]
rw [quot_mul_assoc (mk xl xr xL xR) (yL j) (zR k)]
rw [quot_mul_assoc (xL i) (yL j) (zR k)]
abel
· change
⟦(xR i * y + x * yR j - xR i * yR j) * z + x * y * zR k -
(xR i * y + x * yR j - xR i * yR j) * zR k⟧ =
⟦xR i * (y * z) + x * (yR j * z + y * zR k - yR j * zR k) -
xR i * (yR j * z + y * zR k - yR j * zR k)⟧
simp only [quot_sub, quot_add, quot_right_distrib_sub, quot_right_distrib,
quot_left_distrib_sub, quot_left_distrib]
rw [quot_mul_assoc (xR i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (yR j) (mk zl zr zL zR)]
rw [quot_mul_assoc (xR i) (yR j) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (mk yl yr yL yR) (zR k)]
rw [quot_mul_assoc (xR i) (mk yl yr yL yR) (zR k)]
rw [quot_mul_assoc (mk xl xr xL xR) (yR j) (zR k)]
rw [quot_mul_assoc (xR i) (yR j) (zR k)]
abel
· change
⟦(xL i * y + x * yR j - xL i * yR j) * z + x * y * zL k -
(xL i * y + x * yR j - xL i * yR j) * zL k⟧ =
⟦xL i * (y * z) + x * (yR j * z + y * zL k - yR j * zL k) -
xL i * (yR j * z + y * zL k - yR j * zL k)⟧
simp only [quot_sub, quot_add, quot_right_distrib_sub, quot_right_distrib,
quot_left_distrib_sub, quot_left_distrib]
rw [quot_mul_assoc (xL i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (yR j) (mk zl zr zL zR)]
rw [quot_mul_assoc (xL i) (yR j) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (mk yl yr yL yR) (zL k)]
rw [quot_mul_assoc (xL i) (mk yl yr yL yR) (zL k)]
rw [quot_mul_assoc (mk xl xr xL xR) (yR j) (zL k)]
rw [quot_mul_assoc (xL i) (yR j) (zL k)]
abel
· change
⟦(xR i * y + x * yL j - xR i * yL j) * z + x * y * zL k -
(xR i * y + x * yL j - xR i * yL j) * zL k⟧ =
⟦xR i * (y * z) + x * (yL j * z + y * zL k - yL j * zL k) -
xR i * (yL j * z + y * zL k - yL j * zL k)⟧
simp only [quot_sub, quot_add, quot_right_distrib_sub, quot_right_distrib,
quot_left_distrib_sub, quot_left_distrib]
rw [quot_mul_assoc (xR i) (mk yl yr yL yR) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (yL j) (mk zl zr zL zR)]
rw [quot_mul_assoc (xR i) (yL j) (mk zl zr zL zR)]
rw [quot_mul_assoc (mk xl xr xL xR) (mk yl yr yL yR) (zL k)]
rw [quot_mul_assoc (xR i) (mk yl yr yL yR) (zL k)]
rw [quot_mul_assoc (mk xl xr xL xR) (yL j) (zL k)]
rw [quot_mul_assoc (xR i) (yL j) (zL k)]
abel
termination_by (x, y, z)
/-- `x * y * z` is equivalent to `x * (y * z)`. -/
theorem mul_assoc_equiv (x y z : PGame) : x * y * z ≈ x * (y * z) :=
Quotient.exact <| quot_mul_assoc _ _ _
/-- The left options of `x * y` of the first kind, i.e. of the form `xL * y + x * yL - xL * yL`. -/
def mulOption (x y : PGame) (i : LeftMoves x) (j : LeftMoves y) : PGame :=
x.moveLeft i * y + x * y.moveLeft j - x.moveLeft i * y.moveLeft j
/-- Any left option of `x * y` of the first kind is also a left option of `x * -(-y)` of
the first kind. -/
lemma mulOption_neg_neg {x} (y) {i j} :
mulOption x y i j = mulOption x (-(-y)) i (toLeftMovesNeg <| toRightMovesNeg j) := by
simp [mulOption]
/-- The left options of `x * y` agree with that of `y * x` up to equivalence. -/
lemma mulOption_symm (x y) {i j} : ⟦mulOption x y i j⟧ = (⟦mulOption y x j i⟧ : Game) := by
dsimp only [mulOption, quot_sub, quot_add]
rw [add_comm]
congr 1
on_goal 1 => congr 1
all_goals rw [quot_mul_comm]
/-- The left options of `x * y` of the second kind are the left options of `(-x) * (-y)` of the
first kind, up to equivalence. -/
lemma leftMoves_mul_iff {x y : PGame} (P : Game → Prop) :
(∀ k, P ⟦(x * y).moveLeft k⟧) ↔
(∀ i j, P ⟦mulOption x y i j⟧) ∧ (∀ i j, P ⟦mulOption (-x) (-y) i j⟧) := by
cases x; cases y
constructor <;> intro h
on_goal 1 =>
constructor <;> intros i j
· exact h (Sum.inl (i, j))
convert h (Sum.inr (i, j)) using 1
on_goal 2 =>
rintro (⟨i, j⟩ | ⟨i, j⟩)
· exact h.1 i j
convert h.2 i j using 1
all_goals
dsimp only [mk_mul_moveLeft_inr, quot_sub, quot_add, neg_def, mulOption, moveLeft_mk]
| rw [← neg_def, ← neg_def]
congr 1
on_goal 1 => congr 1
all_goals rw [quot_neg_mul_neg]
/-- The right options of `x * y` are the left options of `x * (-y)` and of `(-x) * y` of the first
kind, up to equivalence. -/
| Mathlib/SetTheory/Game/Basic.lean | 862 | 868 |
/-
Copyright (c) 2024 Joël Riou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joël Riou
-/
import Mathlib.CategoryTheory.Localization.LocalizerMorphism
/-!
# Resolutions for a morphism of localizers
Given a morphism of localizers `Φ : LocalizerMorphism W₁ W₂` (i.e. `W₁` and `W₂` are
morphism properties on categories `C₁` and `C₂`, and we have a functor
`Φ.functor : C₁ ⥤ C₂` which sends morphisms in `W₁` to morphisms in `W₂`), we introduce
the notion of right resolutions of objects in `C₂`: if `X₂ : C₂`.
A right resolution consists of an object `X₁ : C₁` and a morphism
`w : X₂ ⟶ Φ.functor.obj X₁` that is in `W₂`. Then, the typeclass
`Φ.HasRightResolutions` holds when any `X₂ : C₂` has a right resolution.
The type of right resolutions `Φ.RightResolution X₂` is endowed with a category
structure when the morphism property `W₁` is multiplicative.
Similar definitions are done from left resolutions.
## Future works
* formalize right derivability structures as localizer morphisms admitting right resolutions
and forming a Guitart exact square, as it is defined in
[the paper by Kahn and Maltsiniotis][KahnMaltsiniotis2008] (TODO @joelriou)
* show that if `C` is an abelian category with enough injectives, there is a derivability
structure associated to the inclusion of the full subcategory of complexes of injective
objects into the bounded below homotopy category of `C` (TODO @joelriou)
* formalize dual results
## References
* [Bruno Kahn and Georges Maltsiniotis, *Structures de dérivabilité*][KahnMaltsiniotis2008]
-/
universe v₁ v₂ v₂' u₁ u₂ u₂'
namespace CategoryTheory
open Category Localization
variable {C₁ C₂ D₂ H : Type*} [Category C₁] [Category C₂] [Category D₂] [Category H]
{W₁ : MorphismProperty C₁} {W₂ : MorphismProperty C₂}
namespace LocalizerMorphism
variable (Φ : LocalizerMorphism W₁ W₂)
/-- The category of right resolutions of an object in the target category
of a localizer morphism. -/
structure RightResolution (X₂ : C₂) where
/-- an object in the source category -/
{X₁ : C₁}
/-- a morphism to an object of the form `Φ.functor.obj X₁` -/
w : X₂ ⟶ Φ.functor.obj X₁
hw : W₂ w
/-- The category of left resolutions of an object in the target category
of a localizer morphism. -/
structure LeftResolution (X₂ : C₂) where
/-- an object in the source category -/
{X₁ : C₁}
/-- a morphism from an object of the form `Φ.functor.obj X₁` -/
w : Φ.functor.obj X₁ ⟶ X₂
hw : W₂ w
variable {Φ X₂} in
lemma RightResolution.mk_surjective (R : Φ.RightResolution X₂) :
∃ (X₁ : C₁) (w : X₂ ⟶ Φ.functor.obj X₁) (hw : W₂ w), R = RightResolution.mk w hw :=
⟨_, R.w, R.hw, rfl⟩
variable {Φ X₂} in
lemma LeftResolution.mk_surjective (L : Φ.LeftResolution X₂) :
∃ (X₁ : C₁) (w : Φ.functor.obj X₁ ⟶ X₂) (hw : W₂ w), L = LeftResolution.mk w hw :=
⟨_, L.w, L.hw, rfl⟩
/-- A localizer morphism has right resolutions when any object has a right resolution. -/
abbrev HasRightResolutions := ∀ (X₂ : C₂), Nonempty (Φ.RightResolution X₂)
/-- A localizer morphism has right resolutions when any object has a right resolution. -/
abbrev HasLeftResolutions := ∀ (X₂ : C₂), Nonempty (Φ.LeftResolution X₂)
namespace RightResolution
variable {Φ} {X₂ : C₂}
/-- The type of morphisms in the category `Φ.RightResolution X₂` (when `W₁` is multiplicative). -/
@[ext]
structure Hom (R R' : Φ.RightResolution X₂) where
/-- a morphism in the source category -/
f : R.X₁ ⟶ R'.X₁
hf : W₁ f
comm : R.w ≫ Φ.functor.map f = R'.w := by aesop_cat
attribute [reassoc (attr := simp)] Hom.comm
/-- The identity of a object in `Φ.RightResolution X₂`. -/
@[simps]
def Hom.id [W₁.ContainsIdentities] (R : Φ.RightResolution X₂) : Hom R R where
f := 𝟙 _
hf := W₁.id_mem _
variable [W₁.IsMultiplicative]
/-- The composition of morphisms in `Φ.RightResolution X₂`. -/
@[simps]
def Hom.comp {R R' R'' : Φ.RightResolution X₂}
(φ : Hom R R') (ψ : Hom R' R'') :
Hom R R'' where
f := φ.f ≫ ψ.f
hf := W₁.comp_mem _ _ φ.hf ψ.hf
instance : Category (Φ.RightResolution X₂) where
Hom := Hom
id := Hom.id
comp := Hom.comp
@[simp]
lemma id_f (R : Φ.RightResolution X₂) : Hom.f (𝟙 R) = 𝟙 R.X₁ := rfl
@[simp, reassoc]
lemma comp_f {R R' R'' : Φ.RightResolution X₂} (φ : R ⟶ R') (ψ : R' ⟶ R'') :
(φ ≫ ψ).f = φ.f ≫ ψ.f := rfl
@[ext]
lemma hom_ext {R R' : Φ.RightResolution X₂} {φ₁ φ₂ : R ⟶ R'} (h : φ₁.f = φ₂.f) :
φ₁ = φ₂ :=
Hom.ext h
end RightResolution
namespace LeftResolution
variable {Φ} {X₂ : C₂}
/-- The type of morphisms in the category `Φ.LeftResolution X₂` (when `W₁` is multiplicative). -/
@[ext]
structure Hom (L L' : Φ.LeftResolution X₂) where
/-- a morphism in the source category -/
f : L.X₁ ⟶ L'.X₁
hf : W₁ f
comm : Φ.functor.map f ≫ L'.w = L.w := by aesop_cat
attribute [reassoc (attr := simp)] Hom.comm
/-- The identity of a object in `Φ.LeftResolution X₂`. -/
@[simps]
def Hom.id [W₁.ContainsIdentities] (L : Φ.LeftResolution X₂) : Hom L L where
f := 𝟙 _
hf := W₁.id_mem _
variable [W₁.IsMultiplicative]
/-- The composition of morphisms in `Φ.LeftResolution X₂`. -/
@[simps]
def Hom.comp {L L' L'' : Φ.LeftResolution X₂}
(φ : Hom L L') (ψ : Hom L' L'') :
Hom L L'' where
f := φ.f ≫ ψ.f
hf := W₁.comp_mem _ _ φ.hf ψ.hf
instance : Category (Φ.LeftResolution X₂) where
Hom := Hom
id := Hom.id
comp := Hom.comp
@[simp]
lemma id_f (L : Φ.LeftResolution X₂) : Hom.f (𝟙 L) = 𝟙 L.X₁ := rfl
@[simp, reassoc]
lemma comp_f {L L' L'' : Φ.LeftResolution X₂} (φ : L ⟶ L') (ψ : L' ⟶ L'') :
(φ ≫ ψ).f = φ.f ≫ ψ.f := rfl
@[ext]
lemma hom_ext {L L' : Φ.LeftResolution X₂} {φ₁ φ₂ : L ⟶ L'} (h : φ₁.f = φ₂.f) :
φ₁ = φ₂ :=
Hom.ext h
end LeftResolution
variable {Φ}
/-- The canonical map `Φ.LeftResolution X₂ → Φ.op.RightResolution (Opposite.op X₂)`. -/
@[simps]
def LeftResolution.op {X₂ : C₂} (L : Φ.LeftResolution X₂) :
Φ.op.RightResolution (Opposite.op X₂) where
X₁ := Opposite.op L.X₁
w := L.w.op
hw := L.hw
/-- The canonical map `Φ.op.LeftResolution X₂ → Φ.RightResolution X₂`. -/
@[simps]
def LeftResolution.unop {X₂ : C₂ᵒᵖ} (L : Φ.op.LeftResolution X₂) :
Φ.RightResolution X₂.unop where
X₁ := Opposite.unop L.X₁
w := L.w.unop
hw := L.hw
/-- The canonical map `Φ.RightResolution X₂ → Φ.op.LeftResolution (Opposite.op X₂)`. -/
@[simps]
def RightResolution.op {X₂ : C₂} (L : Φ.RightResolution X₂) :
Φ.op.LeftResolution (Opposite.op X₂) where
X₁ := Opposite.op L.X₁
w := L.w.op
hw := L.hw
/-- The canonical map `Φ.op.RightResolution X₂ → Φ.LeftResolution X₂`. -/
@[simps]
def RightResolution.unop {X₂ : C₂ᵒᵖ} (L : Φ.op.RightResolution X₂) :
Φ.LeftResolution X₂.unop where
X₁ := Opposite.unop L.X₁
w := L.w.unop
hw := L.hw
variable (Φ)
lemma nonempty_leftResolution_iff_op (X₂ : C₂) :
Nonempty (Φ.LeftResolution X₂) ↔ Nonempty (Φ.op.RightResolution (Opposite.op X₂)) :=
Equiv.nonempty_congr
{ toFun := fun L => L.op
invFun := fun R => R.unop
left_inv := fun _ => rfl
right_inv := fun _ => rfl }
lemma nonempty_rightResolution_iff_op (X₂ : C₂) :
Nonempty (Φ.RightResolution X₂) ↔ Nonempty (Φ.op.LeftResolution (Opposite.op X₂)) :=
Equiv.nonempty_congr
{ toFun := fun R => R.op
invFun := fun L => L.unop
left_inv := fun _ => rfl
right_inv := fun _ => rfl }
lemma hasLeftResolutions_iff_op : Φ.HasLeftResolutions ↔ Φ.op.HasRightResolutions :=
⟨fun _ X₂ => ⟨(Classical.arbitrary (Φ.LeftResolution X₂.unop)).op⟩,
fun _ X₂ => ⟨(Classical.arbitrary (Φ.op.RightResolution (Opposite.op X₂))).unop⟩⟩
lemma hasRightResolutions_iff_op : Φ.HasRightResolutions ↔ Φ.op.HasLeftResolutions :=
⟨fun _ X₂ => ⟨(Classical.arbitrary (Φ.RightResolution X₂.unop)).op⟩,
fun _ X₂ => ⟨(Classical.arbitrary (Φ.op.LeftResolution (Opposite.op X₂))).unop⟩⟩
instance [Φ.HasRightResolutions] : Φ.op.HasLeftResolutions := by
rwa [← hasRightResolutions_iff_op]
instance [Φ.HasLeftResolutions] : Φ.op.HasRightResolutions := by
rwa [← hasLeftResolutions_iff_op]
/-- The functor `(Φ.LeftResolution X₂)ᵒᵖ ⥤ Φ.op.RightResolution (Opposite.op X₂)`. -/
@[simps]
def LeftResolution.opFunctor (X₂ : C₂) [W₁.IsMultiplicative] :
(Φ.LeftResolution X₂)ᵒᵖ ⥤ Φ.op.RightResolution (Opposite.op X₂) where
obj L := L.unop.op
map φ :=
{ f := φ.unop.f.op
hf := φ.unop.hf
comm := Quiver.Hom.unop_inj φ.unop.comm }
/-- The functor `(Φ.op.RightResolution X₂)ᵒᵖ ⥤ Φ.LeftResolution X₂.unop`. -/
@[simps]
def RightResolution.unopFunctor (X₂ : C₂ᵒᵖ) [W₁.IsMultiplicative] :
(Φ.op.RightResolution X₂)ᵒᵖ ⥤ Φ.LeftResolution X₂.unop where
obj R := R.unop.unop
map φ :=
{ f := φ.unop.f.unop
hf := φ.unop.hf
comm := Quiver.Hom.op_inj φ.unop.comm }
/-- The equivalence of categories
`(Φ.LeftResolution X₂)ᵒᵖ ≌ Φ.op.RightResolution (Opposite.op X₂)`. -/
@[simps]
def LeftResolution.opEquivalence (X₂ : C₂) [W₁.IsMultiplicative] :
(Φ.LeftResolution X₂)ᵒᵖ ≌ Φ.op.RightResolution (Opposite.op X₂) where
functor := LeftResolution.opFunctor Φ X₂
inverse := (RightResolution.unopFunctor Φ (Opposite.op X₂)).rightOp
unitIso := Iso.refl _
counitIso := Iso.refl _
section
variable (L₂ : C₂ ⥤ D₂) [L₂.IsLocalization W₂]
lemma essSurj_of_hasRightResolutions [Φ.HasRightResolutions] : (Φ.functor ⋙ L₂).EssSurj where
mem_essImage X₂ := by
have := Localization.essSurj L₂ W₂
have R : Φ.RightResolution (L₂.objPreimage X₂) := Classical.arbitrary _
exact ⟨R.X₁, ⟨(Localization.isoOfHom L₂ W₂ _ R.hw).symm ≪≫ L₂.objObjPreimageIso X₂⟩⟩
lemma isIso_iff_of_hasRightResolutions [Φ.HasRightResolutions] {F G : D₂ ⥤ H} (α : F ⟶ G) :
IsIso α ↔ ∀ (X₁ : C₁), IsIso (α.app (L₂.obj (Φ.functor.obj X₁))) := by
constructor
· intros
infer_instance
· intro hα
| have : ∀ (X₂ : D₂), IsIso (α.app X₂) := fun X₂ => by
have := Φ.essSurj_of_hasRightResolutions L₂
rw [← NatTrans.isIso_app_iff_of_iso α ((Φ.functor ⋙ L₂).objObjPreimageIso X₂)]
apply hα
exact NatIso.isIso_of_isIso_app α
| Mathlib/CategoryTheory/Localization/Resolution.lean | 296 | 300 |
/-
Copyright (c) 2019 Zhouhang Zhou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Zhouhang Zhou, Yaël Dillies
-/
import Mathlib.Algebra.Group.Action.Pointwise.Set.Basic
import Mathlib.Algebra.GroupWithZero.Action.Defs
import Mathlib.Algebra.Order.Group.OrderIso
import Mathlib.Algebra.Order.Monoid.Defs
import Mathlib.Algebra.Ring.Defs
import Mathlib.Order.Filter.AtTopBot.Map
import Mathlib.Order.Filter.Finite
import Mathlib.Order.Filter.NAry
import Mathlib.Order.Filter.Ultrafilter.Defs
/-!
# Pointwise operations on filters
This file defines pointwise operations on filters. This is useful because usual algebraic operations
distribute over pointwise operations. For example,
* `(f₁ * f₂).map m = f₁.map m * f₂.map m`
* `𝓝 (x * y) = 𝓝 x * 𝓝 y`
## Main declarations
* `0` (`Filter.instZero`): Pure filter at `0 : α`, or alternatively principal filter at `0 : Set α`.
* `1` (`Filter.instOne`): Pure filter at `1 : α`, or alternatively principal filter at `1 : Set α`.
* `f + g` (`Filter.instAdd`): Addition, filter generated by all `s + t` where `s ∈ f` and `t ∈ g`.
* `f * g` (`Filter.instMul`): Multiplication, filter generated by all `s * t` where `s ∈ f` and
`t ∈ g`.
* `-f` (`Filter.instNeg`): Negation, filter of all `-s` where `s ∈ f`.
* `f⁻¹` (`Filter.instInv`): Inversion, filter of all `s⁻¹` where `s ∈ f`.
* `f - g` (`Filter.instSub`): Subtraction, filter generated by all `s - t` where `s ∈ f` and
`t ∈ g`.
* `f / g` (`Filter.instDiv`): Division, filter generated by all `s / t` where `s ∈ f` and `t ∈ g`.
* `f +ᵥ g` (`Filter.instVAdd`): Scalar addition, filter generated by all `s +ᵥ t` where `s ∈ f` and
`t ∈ g`.
* `f -ᵥ g` (`Filter.instVSub`): Scalar subtraction, filter generated by all `s -ᵥ t` where `s ∈ f`
and `t ∈ g`.
* `f • g` (`Filter.instSMul`): Scalar multiplication, filter generated by all `s • t` where
`s ∈ f` and `t ∈ g`.
* `a +ᵥ f` (`Filter.instVAddFilter`): Translation, filter of all `a +ᵥ s` where `s ∈ f`.
* `a • f` (`Filter.instSMulFilter`): Scaling, filter of all `a • s` where `s ∈ f`.
For `α` a semigroup/monoid, `Filter α` is a semigroup/monoid.
As an unfortunate side effect, this means that `n • f`, where `n : ℕ`, is ambiguous between
pointwise scaling and repeated pointwise addition. See note [pointwise nat action].
## Implementation notes
We put all instances in the locale `Pointwise`, so that these instances are not available by
default. Note that we do not mark them as reducible (as argued by note [reducible non-instances])
since we expect the locale to be open whenever the instances are actually used (and making the
instances reducible changes the behavior of `simp`).
## Tags
filter multiplication, filter addition, pointwise addition, pointwise multiplication,
-/
open Function Set Filter Pointwise
variable {F α β γ δ ε : Type*}
namespace Filter
/-! ### `0`/`1` as filters -/
section One
variable [One α] {f : Filter α} {s : Set α}
/-- `1 : Filter α` is defined as the filter of sets containing `1 : α` in locale `Pointwise`. -/
@[to_additive
"`0 : Filter α` is defined as the filter of sets containing `0 : α` in locale `Pointwise`."]
protected def instOne : One (Filter α) :=
⟨pure 1⟩
scoped[Pointwise] attribute [instance] Filter.instOne Filter.instZero
@[to_additive (attr := simp)]
theorem mem_one : s ∈ (1 : Filter α) ↔ (1 : α) ∈ s :=
mem_pure
@[to_additive]
theorem one_mem_one : (1 : Set α) ∈ (1 : Filter α) :=
mem_pure.2 Set.one_mem_one
@[to_additive (attr := simp)]
theorem pure_one : pure 1 = (1 : Filter α) :=
rfl
@[to_additive (attr := simp) zero_prod]
theorem one_prod {l : Filter β} : (1 : Filter α) ×ˢ l = map (1, ·) l := pure_prod
@[to_additive (attr := simp) prod_zero]
theorem prod_one {l : Filter β} : l ×ˢ (1 : Filter α) = map (·, 1) l := prod_pure
@[to_additive (attr := simp)]
theorem principal_one : 𝓟 1 = (1 : Filter α) :=
principal_singleton _
@[to_additive]
theorem one_neBot : (1 : Filter α).NeBot :=
Filter.pure_neBot
scoped[Pointwise] attribute [instance] one_neBot zero_neBot
@[to_additive (attr := simp)]
protected theorem map_one' (f : α → β) : (1 : Filter α).map f = pure (f 1) :=
rfl
@[to_additive (attr := simp)]
theorem le_one_iff : f ≤ 1 ↔ (1 : Set α) ∈ f :=
le_pure_iff
@[to_additive]
protected theorem NeBot.le_one_iff (h : f.NeBot) : f ≤ 1 ↔ f = 1 :=
h.le_pure_iff
@[to_additive (attr := simp)]
theorem eventually_one {p : α → Prop} : (∀ᶠ x in 1, p x) ↔ p 1 :=
eventually_pure
@[to_additive (attr := simp)]
theorem tendsto_one {a : Filter β} {f : β → α} : Tendsto f a 1 ↔ ∀ᶠ x in a, f x = 1 :=
tendsto_pure
@[to_additive zero_prod_zero]
theorem one_prod_one [One β] : (1 : Filter α) ×ˢ (1 : Filter β) = 1 :=
prod_pure_pure
/-- `pure` as a `OneHom`. -/
@[to_additive "`pure` as a `ZeroHom`."]
def pureOneHom : OneHom α (Filter α) where
toFun := pure; map_one' := pure_one
@[to_additive (attr := simp)]
theorem coe_pureOneHom : (pureOneHom : α → Filter α) = pure :=
rfl
@[to_additive (attr := simp)]
theorem pureOneHom_apply (a : α) : pureOneHom a = pure a :=
rfl
variable [One β]
@[to_additive]
protected theorem map_one [FunLike F α β] [OneHomClass F α β] (φ : F) : map φ 1 = 1 := by
simp
end One
/-! ### Filter negation/inversion -/
section Inv
variable [Inv α] {f g : Filter α} {s : Set α} {a : α}
/-- The inverse of a filter is the pointwise preimage under `⁻¹` of its sets. -/
@[to_additive "The negation of a filter is the pointwise preimage under `-` of its sets."]
instance instInv : Inv (Filter α) :=
⟨map Inv.inv⟩
@[to_additive (attr := simp)]
protected theorem map_inv : f.map Inv.inv = f⁻¹ :=
rfl
@[to_additive]
theorem mem_inv : s ∈ f⁻¹ ↔ Inv.inv ⁻¹' s ∈ f :=
Iff.rfl
@[to_additive]
protected theorem inv_le_inv (hf : f ≤ g) : f⁻¹ ≤ g⁻¹ :=
map_mono hf
@[to_additive (attr := simp)]
theorem inv_pure : (pure a : Filter α)⁻¹ = pure a⁻¹ :=
rfl
@[to_additive (attr := simp)]
theorem inv_eq_bot_iff : f⁻¹ = ⊥ ↔ f = ⊥ :=
map_eq_bot_iff
@[to_additive (attr := simp)]
theorem neBot_inv_iff : f⁻¹.NeBot ↔ NeBot f :=
map_neBot_iff _
@[to_additive]
protected theorem NeBot.inv : f.NeBot → f⁻¹.NeBot := fun h => h.map _
@[to_additive neg.instNeBot]
lemma inv.instNeBot [NeBot f] : NeBot f⁻¹ := .inv ‹_›
scoped[Pointwise] attribute [instance] inv.instNeBot neg.instNeBot
end Inv
section InvolutiveInv
variable [InvolutiveInv α] {f g : Filter α} {s : Set α}
@[to_additive (attr := simp)]
protected lemma comap_inv : comap Inv.inv f = f⁻¹ :=
.symm <| map_eq_comap_of_inverse (inv_comp_inv _) (inv_comp_inv _)
@[to_additive]
theorem inv_mem_inv (hs : s ∈ f) : s⁻¹ ∈ f⁻¹ := by rwa [mem_inv, inv_preimage, inv_inv]
/-- Inversion is involutive on `Filter α` if it is on `α`. -/
@[to_additive "Negation is involutive on `Filter α` if it is on `α`."]
protected def instInvolutiveInv : InvolutiveInv (Filter α) :=
{ Filter.instInv with
inv_inv := fun f => map_map.trans <| by rw [inv_involutive.comp_self, map_id] }
scoped[Pointwise] attribute [instance] Filter.instInvolutiveInv Filter.instInvolutiveNeg
@[to_additive (attr := simp)]
protected theorem inv_le_inv_iff : f⁻¹ ≤ g⁻¹ ↔ f ≤ g :=
⟨fun h => inv_inv f ▸ inv_inv g ▸ Filter.inv_le_inv h, Filter.inv_le_inv⟩
@[to_additive]
theorem inv_le_iff_le_inv : f⁻¹ ≤ g ↔ f ≤ g⁻¹ := by rw [← Filter.inv_le_inv_iff, inv_inv]
@[to_additive (attr := simp)]
theorem inv_le_self : f⁻¹ ≤ f ↔ f⁻¹ = f :=
⟨fun h => h.antisymm <| inv_le_iff_le_inv.1 h, Eq.le⟩
end InvolutiveInv
@[to_additive (attr := simp)]
lemma inv_atTop {G : Type*} [CommGroup G] [PartialOrder G] [IsOrderedMonoid G] :
(atTop : Filter G)⁻¹ = atBot :=
(OrderIso.inv G).map_atTop
/-! ### Filter addition/multiplication -/
section Mul
variable [Mul α] [Mul β] {f f₁ f₂ g g₁ g₂ h : Filter α} {s t : Set α} {a b : α}
/-- The filter `f * g` is generated by `{s * t | s ∈ f, t ∈ g}` in locale `Pointwise`. -/
@[to_additive "The filter `f + g` is generated by `{s + t | s ∈ f, t ∈ g}` in locale `Pointwise`."]
protected def instMul : Mul (Filter α) :=
⟨/- This is defeq to `map₂ (· * ·) f g`, but the hypothesis unfolds to `t₁ * t₂ ⊆ s` rather
than all the way to `Set.image2 (· * ·) t₁ t₂ ⊆ s`. -/
fun f g => { map₂ (· * ·) f g with sets := { s | ∃ t₁ ∈ f, ∃ t₂ ∈ g, t₁ * t₂ ⊆ s } }⟩
scoped[Pointwise] attribute [instance] Filter.instMul Filter.instAdd
@[to_additive (attr := simp)]
theorem map₂_mul : map₂ (· * ·) f g = f * g :=
rfl
@[to_additive]
theorem mem_mul : s ∈ f * g ↔ ∃ t₁ ∈ f, ∃ t₂ ∈ g, t₁ * t₂ ⊆ s :=
Iff.rfl
@[to_additive]
theorem mul_mem_mul : s ∈ f → t ∈ g → s * t ∈ f * g :=
image2_mem_map₂
@[to_additive (attr := simp)]
theorem bot_mul : ⊥ * g = ⊥ :=
map₂_bot_left
| @[to_additive (attr := simp)]
| Mathlib/Order/Filter/Pointwise.lean | 270 | 270 |
/-
Copyright (c) 2020 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov
-/
import Mathlib.Analysis.Calculus.InverseFunctionTheorem.FDeriv
import Mathlib.Analysis.Calculus.FDeriv.Add
import Mathlib.Analysis.Calculus.FDeriv.Prod
import Mathlib.Analysis.Normed.Module.Complemented
/-!
# Implicit function theorem
We prove three versions of the implicit function theorem. First we define a structure
`ImplicitFunctionData` that holds arguments for the most general version of the implicit function
theorem, see `ImplicitFunctionData.implicitFunction` and
`ImplicitFunctionData.implicitFunction_hasStrictFDerivAt`. This version allows a user to choose a
specific implicit function but provides only a little convenience over the inverse function theorem.
Then we define `HasStrictFDerivAt.implicitFunctionDataOfComplemented`: implicit function defined by
`f (g z y) = z`, where `f : E → F` is a function strictly differentiable at `a` such that its
derivative `f'` is surjective and has a `complemented` kernel.
Finally, if the codomain of `f` is a finite dimensional space, then we can automatically prove
that the kernel of `f'` is complemented, hence the only assumptions are `HasStrictFDerivAt`
and `f'.range = ⊤`. This version is named `HasStrictFDerivAt.implicitFunction`.
## TODO
* Add a version for a function `f : E × F → G` such that $$\frac{\partial f}{\partial y}$$ is
invertible.
* Add a version for `f : 𝕜 × 𝕜 → 𝕜` proving `HasStrictDerivAt` and `deriv φ = ...`.
* Prove that in a real vector space the implicit function has the same smoothness as the original
one.
* If the original function is differentiable in a neighborhood, then the implicit function is
differentiable in a neighborhood as well. Current setup only proves differentiability at one
point for the implicit function constructed in this file (as opposed to an unspecified implicit
function). One of the ways to overcome this difficulty is to use uniqueness of the implicit
function in the general version of the theorem. Another way is to prove that *any* implicit
function satisfying some predicate is strictly differentiable.
## Tags
implicit function, inverse function
-/
noncomputable section
open scoped Topology
open Filter
open ContinuousLinearMap (fst snd smulRight ker_prod)
open ContinuousLinearEquiv (ofBijective)
open LinearMap (ker range)
/-!
### General version
Consider two functions `f : E → F` and `g : E → G` and a point `a` such that
* both functions are strictly differentiable at `a`;
* the derivatives are surjective;
* the kernels of the derivatives are complementary subspaces of `E`.
Note that the map `x ↦ (f x, g x)` has a bijective derivative, hence it is a partial homeomorphism
between `E` and `F × G`. We use this fact to define a function `φ : F → G → E`
(see `ImplicitFunctionData.implicitFunction`) such that for `(y, z)` close enough to `(f a, g a)`
we have `f (φ y z) = y` and `g (φ y z) = z`.
We also prove a formula for $$\frac{\partial\varphi}{\partial z}.$$
Though this statement is almost symmetric with respect to `F`, `G`, we interpret it in the following
way. Consider a family of surfaces `{x | f x = y}`, `y ∈ 𝓝 (f a)`. Each of these surfaces is
parametrized by `φ y`.
There are many ways to choose a (differentiable) function `φ` such that `f (φ y z) = y` but the
extra condition `g (φ y z) = z` allows a user to select one of these functions. If we imagine
that the level surfaces `f = const` form a local horizontal foliation, then the choice of
`g` fixes a transverse foliation `g = const`, and `φ` is the inverse function of the projection
of `{x | f x = y}` along this transverse foliation.
This version of the theorem is used to prove the other versions and can be used if a user
needs to have a complete control over the choice of the implicit function.
-/
/-- Data for the general version of the implicit function theorem. It holds two functions
`f : E → F` and `g : E → G` (named `leftFun` and `rightFun`) and a point `a` (named `pt`) such that
* both functions are strictly differentiable at `a`;
* the derivatives are surjective;
* the kernels of the derivatives are complementary subspaces of `E`. -/
structure ImplicitFunctionData (𝕜 : Type*) [NontriviallyNormedField 𝕜] (E : Type*)
[NormedAddCommGroup E] [NormedSpace 𝕜 E] [CompleteSpace E] (F : Type*) [NormedAddCommGroup F]
[NormedSpace 𝕜 F] [CompleteSpace F] (G : Type*) [NormedAddCommGroup G] [NormedSpace 𝕜 G]
[CompleteSpace G] where
/-- Left function -/
leftFun : E → F
/-- Derivative of the left function -/
leftDeriv : E →L[𝕜] F
/-- Right function -/
rightFun : E → G
/-- Derivative of the right function -/
rightDeriv : E →L[𝕜] G
/-- The point at which `leftFun` and `rightFun` are strictly differentiable -/
pt : E
left_has_deriv : HasStrictFDerivAt leftFun leftDeriv pt
right_has_deriv : HasStrictFDerivAt rightFun rightDeriv pt
left_range : range leftDeriv = ⊤
right_range : range rightDeriv = ⊤
isCompl_ker : IsCompl (ker leftDeriv) (ker rightDeriv)
namespace ImplicitFunctionData
variable {𝕜 : Type*} [NontriviallyNormedField 𝕜] {E : Type*} [NormedAddCommGroup E]
[NormedSpace 𝕜 E] [CompleteSpace E] {F : Type*} [NormedAddCommGroup F] [NormedSpace 𝕜 F]
[CompleteSpace F] {G : Type*} [NormedAddCommGroup G] [NormedSpace 𝕜 G] [CompleteSpace G]
(φ : ImplicitFunctionData 𝕜 E F G)
/-- The function given by `x ↦ (leftFun x, rightFun x)`. -/
def prodFun (x : E) : F × G :=
(φ.leftFun x, φ.rightFun x)
@[simp]
theorem prodFun_apply (x : E) : φ.prodFun x = (φ.leftFun x, φ.rightFun x) :=
rfl
protected theorem hasStrictFDerivAt :
HasStrictFDerivAt φ.prodFun
(φ.leftDeriv.equivProdOfSurjectiveOfIsCompl φ.rightDeriv φ.left_range φ.right_range
φ.isCompl_ker :
E →L[𝕜] F × G)
φ.pt :=
φ.left_has_deriv.prodMk φ.right_has_deriv
/-- Implicit function theorem. If `f : E → F` and `g : E → G` are two maps strictly differentiable
at `a`, their derivatives `f'`, `g'` are surjective, and the kernels of these derivatives are
complementary subspaces of `E`, then `x ↦ (f x, g x)` defines a partial homeomorphism between
`E` and `F × G`. In particular, `{x | f x = f a}` is locally homeomorphic to `G`. -/
def toPartialHomeomorph : PartialHomeomorph E (F × G) :=
φ.hasStrictFDerivAt.toPartialHomeomorph _
/-- Implicit function theorem. If `f : E → F` and `g : E → G` are two maps strictly differentiable
at `a`, their derivatives `f'`, `g'` are surjective, and the kernels of these derivatives are
complementary subspaces of `E`, then `implicitFunction` is the unique (germ of a) map
`φ : F → G → E` such that `f (φ y z) = y` and `g (φ y z) = z`. -/
def implicitFunction : F → G → E :=
Function.curry <| φ.toPartialHomeomorph.symm
@[simp]
theorem toPartialHomeomorph_coe : ⇑φ.toPartialHomeomorph = φ.prodFun :=
rfl
theorem toPartialHomeomorph_apply (x : E) : φ.toPartialHomeomorph x = (φ.leftFun x, φ.rightFun x) :=
rfl
theorem pt_mem_toPartialHomeomorph_source : φ.pt ∈ φ.toPartialHomeomorph.source :=
φ.hasStrictFDerivAt.mem_toPartialHomeomorph_source
theorem map_pt_mem_toPartialHomeomorph_target :
(φ.leftFun φ.pt, φ.rightFun φ.pt) ∈ φ.toPartialHomeomorph.target :=
φ.toPartialHomeomorph.map_source <| φ.pt_mem_toPartialHomeomorph_source
theorem prod_map_implicitFunction :
∀ᶠ p : F × G in 𝓝 (φ.prodFun φ.pt), φ.prodFun (φ.implicitFunction p.1 p.2) = p :=
φ.hasStrictFDerivAt.eventually_right_inverse.mono fun ⟨_, _⟩ h => h
theorem left_map_implicitFunction :
∀ᶠ p : F × G in 𝓝 (φ.prodFun φ.pt), φ.leftFun (φ.implicitFunction p.1 p.2) = p.1 :=
φ.prod_map_implicitFunction.mono fun _ => congr_arg Prod.fst
theorem right_map_implicitFunction :
∀ᶠ p : F × G in 𝓝 (φ.prodFun φ.pt), φ.rightFun (φ.implicitFunction p.1 p.2) = p.2 :=
φ.prod_map_implicitFunction.mono fun _ => congr_arg Prod.snd
theorem implicitFunction_apply_image :
∀ᶠ x in 𝓝 φ.pt, φ.implicitFunction (φ.leftFun x) (φ.rightFun x) = x :=
φ.hasStrictFDerivAt.eventually_left_inverse
theorem map_nhds_eq : map φ.leftFun (𝓝 φ.pt) = 𝓝 (φ.leftFun φ.pt) :=
show map (Prod.fst ∘ φ.prodFun) (𝓝 φ.pt) = 𝓝 (φ.prodFun φ.pt).1 by
rw [← map_map, φ.hasStrictFDerivAt.map_nhds_eq_of_equiv, map_fst_nhds]
theorem implicitFunction_hasStrictFDerivAt (g'inv : G →L[𝕜] E)
(hg'inv : φ.rightDeriv.comp g'inv = ContinuousLinearMap.id 𝕜 G)
(hg'invf : φ.leftDeriv.comp g'inv = 0) :
HasStrictFDerivAt (φ.implicitFunction (φ.leftFun φ.pt)) g'inv (φ.rightFun φ.pt) := by
have := φ.hasStrictFDerivAt.to_localInverse
simp only [prodFun] at this
convert this.comp (φ.rightFun φ.pt)
((hasStrictFDerivAt_const _ _).prodMk (hasStrictFDerivAt_id _))
simp only [ContinuousLinearMap.ext_iff, ContinuousLinearMap.comp_apply] at hg'inv hg'invf ⊢
simp [ContinuousLinearEquiv.eq_symm_apply, *]
end ImplicitFunctionData
namespace HasStrictFDerivAt
section Complemented
/-!
### Case of a complemented kernel
In this section we prove the following version of the implicit function theorem. Consider a map
`f : E → F` and a point `a : E` such that `f` is strictly differentiable at `a`, its derivative `f'`
is surjective and the kernel of `f'` is a complemented subspace of `E` (i.e., it has a closed
complementary subspace). Then there exists a function `φ : F → ker f' → E` such that for `(y, z)`
close to `(f a, 0)` we have `f (φ y z) = y` and the derivative of `φ (f a)` at zero is the
embedding `ker f' → E`.
Note that a map with these properties is not unique. E.g., different choices of a subspace
complementary to `ker f'` lead to different maps `φ`.
-/
variable {𝕜 : Type*} [NontriviallyNormedField 𝕜] {E : Type*} [NormedAddCommGroup E]
[NormedSpace 𝕜 E] [CompleteSpace E] {F : Type*} [NormedAddCommGroup F] [NormedSpace 𝕜 F]
[CompleteSpace F] {f : E → F} {f' : E →L[𝕜] F} {a : E}
section Defs
variable (f f')
/-- Data used to apply the generic implicit function theorem to the case of a strictly
differentiable map such that its derivative is surjective and has a complemented kernel. -/
@[simp]
def implicitFunctionDataOfComplemented (hf : HasStrictFDerivAt f f' a) (hf' : range f' = ⊤)
(hker : (ker f').ClosedComplemented) : ImplicitFunctionData 𝕜 E F (ker f') where
leftFun := f
leftDeriv := f'
rightFun x := Classical.choose hker (x - a)
rightDeriv := Classical.choose hker
pt := a
left_has_deriv := hf
right_has_deriv :=
(Classical.choose hker).hasStrictFDerivAt.comp a ((hasStrictFDerivAt_id a).sub_const a)
left_range := hf'
right_range := LinearMap.range_eq_of_proj (Classical.choose_spec hker)
isCompl_ker := LinearMap.isCompl_of_proj (Classical.choose_spec hker)
/-- A partial homeomorphism between `E` and `F × f'.ker` sending level surfaces of `f`
to vertical subspaces. -/
def implicitToPartialHomeomorphOfComplemented (hf : HasStrictFDerivAt f f' a) (hf' : range f' = ⊤)
(hker : (ker f').ClosedComplemented) : PartialHomeomorph E (F × ker f') :=
(implicitFunctionDataOfComplemented f f' hf hf' hker).toPartialHomeomorph
/-- Implicit function `g` defined by `f (g z y) = z`. -/
def implicitFunctionOfComplemented (hf : HasStrictFDerivAt f f' a) (hf' : range f' = ⊤)
(hker : (ker f').ClosedComplemented) : F → ker f' → E :=
(implicitFunctionDataOfComplemented f f' hf hf' hker).implicitFunction
end Defs
@[simp]
theorem implicitToPartialHomeomorphOfComplemented_fst (hf : HasStrictFDerivAt f f' a)
(hf' : range f' = ⊤) (hker : (ker f').ClosedComplemented) (x : E) :
(hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker x).fst = f x :=
rfl
theorem implicitToPartialHomeomorphOfComplemented_apply (hf : HasStrictFDerivAt f f' a)
(hf' : range f' = ⊤) (hker : (ker f').ClosedComplemented) (y : E) :
hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker y =
(f y, Classical.choose hker (y - a)) :=
rfl
@[simp]
theorem implicitToPartialHomeomorphOfComplemented_apply_ker (hf : HasStrictFDerivAt f f' a)
(hf' : range f' = ⊤) (hker : (ker f').ClosedComplemented) (y : ker f') :
hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker (y + a) = (f (y + a), y) := by
simp only [implicitToPartialHomeomorphOfComplemented_apply, add_sub_cancel_right,
Classical.choose_spec hker]
@[simp]
theorem implicitToPartialHomeomorphOfComplemented_self (hf : HasStrictFDerivAt f f' a)
(hf' : range f' = ⊤) (hker : (ker f').ClosedComplemented) :
hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker a = (f a, 0) := by
simp [hf.implicitToPartialHomeomorphOfComplemented_apply]
theorem mem_implicitToPartialHomeomorphOfComplemented_source (hf : HasStrictFDerivAt f f' a)
(hf' : range f' = ⊤) (hker : (ker f').ClosedComplemented) :
a ∈ (hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker).source :=
ImplicitFunctionData.pt_mem_toPartialHomeomorph_source _
theorem mem_implicitToPartialHomeomorphOfComplemented_target (hf : HasStrictFDerivAt f f' a)
(hf' : range f' = ⊤) (hker : (ker f').ClosedComplemented) :
(f a, (0 : ker f')) ∈ (hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker).target := by
simpa only [implicitToPartialHomeomorphOfComplemented_self] using
(hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker).map_source <|
hf.mem_implicitToPartialHomeomorphOfComplemented_source hf' hker
/-- `HasStrictFDerivAt.implicitFunctionOfComplemented` sends `(z, y)` to a point in `f ⁻¹' z`. -/
theorem map_implicitFunctionOfComplemented_eq (hf : HasStrictFDerivAt f f' a) (hf' : range f' = ⊤)
(hker : (ker f').ClosedComplemented) :
∀ᶠ p : F × ker f' in 𝓝 (f a, 0),
f (hf.implicitFunctionOfComplemented f f' hf' hker p.1 p.2) = p.1 :=
((hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker).eventually_right_inverse <|
hf.mem_implicitToPartialHomeomorphOfComplemented_target hf' hker).mono
fun ⟨_, _⟩ h => congr_arg Prod.fst h
/-- Any point in some neighborhood of `a` can be represented as
`HasStrictFDerivAt.implicitFunctionOfComplemented` of some point. -/
theorem eq_implicitFunctionOfComplemented (hf : HasStrictFDerivAt f f' a) (hf' : range f' = ⊤)
(hker : (ker f').ClosedComplemented) :
∀ᶠ x in 𝓝 a, hf.implicitFunctionOfComplemented f f' hf' hker (f x)
(hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker x).snd = x :=
(implicitFunctionDataOfComplemented f f' hf hf' hker).implicitFunction_apply_image
@[simp]
theorem implicitFunctionOfComplemented_apply_image (hf : HasStrictFDerivAt f f' a)
(hf' : range f' = ⊤) (hker : (ker f').ClosedComplemented) :
hf.implicitFunctionOfComplemented f f' hf' hker (f a) 0 = a := by
simpa only [implicitToPartialHomeomorphOfComplemented_self] using
(hf.implicitToPartialHomeomorphOfComplemented f f' hf' hker).left_inv
(hf.mem_implicitToPartialHomeomorphOfComplemented_source hf' hker)
theorem to_implicitFunctionOfComplemented (hf : HasStrictFDerivAt f f' a) (hf' : range f' = ⊤)
(hker : (ker f').ClosedComplemented) :
HasStrictFDerivAt (hf.implicitFunctionOfComplemented f f' hf' hker (f a))
(ker f').subtypeL 0 := by
convert (implicitFunctionDataOfComplemented f f' hf hf' hker).implicitFunction_hasStrictFDerivAt
(ker f').subtypeL _ _
swap
· ext
simp only [Classical.choose_spec hker, implicitFunctionDataOfComplemented,
ContinuousLinearMap.comp_apply, Submodule.coe_subtypeL', Submodule.coe_subtype,
ContinuousLinearMap.id_apply]
swap
· ext
simp only [ContinuousLinearMap.comp_apply, Submodule.coe_subtypeL', Submodule.coe_subtype,
LinearMap.map_coe_ker, ContinuousLinearMap.zero_apply]
simp only [implicitFunctionDataOfComplemented, map_sub, sub_self]
end Complemented
/-!
### Finite dimensional case
In this section we prove the following version of the implicit function theorem. Consider a map
`f : E → F` from a Banach normed space to a finite dimensional space.
Take a point `a : E` such that `f` is strictly differentiable at `a` and its derivative `f'`
is surjective. Then there exists a function `φ : F → ker f' → E` such that for `(y, z)`
close to `(f a, 0)` we have `f (φ y z) = y` and the derivative of `φ (f a)` at zero is the
embedding `ker f' → E`.
This version deduces that `ker f'` is a complemented subspace from the fact that `F` is a finite
| dimensional space, then applies the previous version.
Note that a map with these properties is not unique. E.g., different choices of a subspace
complementary to `ker f'` lead to different maps `φ`.
-/
section FiniteDimensional
variable {𝕜 : Type*} [NontriviallyNormedField 𝕜] [CompleteSpace 𝕜] {E : Type*}
[NormedAddCommGroup E] [NormedSpace 𝕜 E] [CompleteSpace E] {F : Type*} [NormedAddCommGroup F]
[NormedSpace 𝕜 F] [FiniteDimensional 𝕜 F] (f : E → F) (f' : E →L[𝕜] F) {a : E}
/-- Given a map `f : E → F` to a finite dimensional space with a surjective derivative `f'`,
returns a partial homeomorphism between `E` and `F × ker f'`. -/
def implicitToPartialHomeomorph (hf : HasStrictFDerivAt f f' a) (hf' : range f' = ⊤) :
PartialHomeomorph E (F × ker f') :=
haveI := FiniteDimensional.complete 𝕜 F
hf.implicitToPartialHomeomorphOfComplemented f f' hf'
| Mathlib/Analysis/Calculus/Implicit.lean | 349 | 366 |
/-
Copyright (c) 2020 Floris van Doorn. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Floris van Doorn
-/
import Mathlib.Data.Set.Prod
/-!
# N-ary images of sets
This file defines `Set.image2`, the binary image of sets.
This is mostly useful to define pointwise operations and `Set.seq`.
## Notes
This file is very similar to `Data.Finset.NAry`, to `Order.Filter.NAry`, and to
`Data.Option.NAry`. Please keep them in sync.
-/
open Function
namespace Set
variable {α α' β β' γ γ' δ δ' ε ε' ζ ζ' ν : Type*} {f f' : α → β → γ}
variable {s s' : Set α} {t t' : Set β} {u : Set γ} {v : Set δ} {a : α} {b : β}
theorem mem_image2_iff (hf : Injective2 f) : f a b ∈ image2 f s t ↔ a ∈ s ∧ b ∈ t :=
⟨by
rintro ⟨a', ha', b', hb', h⟩
rcases hf h with ⟨rfl, rfl⟩
exact ⟨ha', hb'⟩, fun ⟨ha, hb⟩ => mem_image2_of_mem ha hb⟩
/-- image2 is monotone with respect to `⊆`. -/
@[gcongr]
theorem image2_subset (hs : s ⊆ s') (ht : t ⊆ t') : image2 f s t ⊆ image2 f s' t' := by
rintro _ ⟨a, ha, b, hb, rfl⟩
exact mem_image2_of_mem (hs ha) (ht hb)
@[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) : (fun a => f a b) '' s ⊆ image2 f s t :=
forall_mem_image.2 fun _ ha => mem_image2_of_mem ha hb
theorem image_subset_image2_right (ha : a ∈ s) : f a '' t ⊆ image2 f s t :=
forall_mem_image.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 aesop
lemma exists_mem_image2 {p : γ → Prop} :
(∃ z ∈ image2 f s t, p z) ↔ ∃ x ∈ s, ∃ y ∈ t, p (f x y) := by aesop
@[deprecated (since := "2024-11-23")] alias forall_image2_iff := forall_mem_image2
@[simp]
theorem image2_subset_iff {u : Set γ} : 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, (fun b => f a b) '' t ⊆ u := by
simp_rw [image2_subset_iff, image_subset_iff, subset_def, mem_preimage]
theorem image2_subset_iff_right : image2 f s t ⊆ u ↔ ∀ b ∈ t, (fun a => f a b) '' s ⊆ u := by
simp_rw [image2_subset_iff, image_subset_iff, subset_def, mem_preimage, @forall₂_swap α]
variable (f)
@[simp]
lemma image_prod : (fun x : α × β ↦ f x.1 x.2) '' s ×ˢ t = image2 f s t :=
ext fun _ ↦ by simp [and_assoc]
@[simp] lemma image_uncurry_prod (s : Set α) (t : Set β) : uncurry f '' s ×ˢ t = image2 f s t :=
image_prod _
@[simp] lemma image2_mk_eq_prod : image2 Prod.mk s t = s ×ˢ t := ext <| by simp
@[simp]
lemma image2_curry (f : α × β → γ) (s : Set α) (t : Set β) :
image2 (fun a b ↦ f (a, b)) s t = f '' s ×ˢ t := by
simp [← image_uncurry_prod, uncurry]
theorem image2_swap (s : Set α) (t : Set β) : image2 f s t = image2 (fun a b => f b a) t s := by
ext
constructor <;> rintro ⟨a, ha, b, hb, rfl⟩ <;> exact ⟨b, hb, a, ha, rfl⟩
variable {f}
theorem image2_union_left : image2 f (s ∪ s') t = image2 f s t ∪ image2 f s' t := by
simp_rw [← image_prod, union_prod, image_union]
theorem image2_union_right : image2 f s (t ∪ t') = image2 f s t ∪ image2 f s t' := by
rw [← image2_swap, image2_union_left, image2_swap f, image2_swap f]
lemma image2_inter_left (hf : Injective2 f) :
image2 f (s ∩ s') t = image2 f s t ∩ image2 f s' t := by
simp_rw [← image_uncurry_prod, inter_prod, image_inter hf.uncurry]
lemma image2_inter_right (hf : Injective2 f) :
image2 f s (t ∩ t') = image2 f s t ∩ image2 f s t' := by
simp_rw [← image_uncurry_prod, prod_inter, image_inter hf.uncurry]
@[simp]
theorem image2_empty_left : image2 f ∅ t = ∅ :=
ext <| by simp
@[simp]
theorem image2_empty_right : image2 f s ∅ = ∅ :=
ext <| by simp
theorem Nonempty.image2 : s.Nonempty → t.Nonempty → (image2 f s t).Nonempty :=
fun ⟨_, ha⟩ ⟨_, hb⟩ => ⟨_, mem_image2_of_mem ha hb⟩
@[simp]
theorem image2_nonempty_iff : (image2 f s t).Nonempty ↔ s.Nonempty ∧ t.Nonempty :=
⟨fun ⟨_, a, ha, b, hb, _⟩ => ⟨⟨a, ha⟩, b, hb⟩, fun h => h.1.image2 h.2⟩
theorem Nonempty.of_image2_left (h : (Set.image2 f s t).Nonempty) : s.Nonempty :=
(image2_nonempty_iff.1 h).1
theorem Nonempty.of_image2_right (h : (Set.image2 f s t).Nonempty) : t.Nonempty :=
(image2_nonempty_iff.1 h).2
@[simp]
theorem image2_eq_empty_iff : image2 f s t = ∅ ↔ s = ∅ ∨ t = ∅ := by
rw [← not_nonempty_iff_eq_empty, image2_nonempty_iff, not_and_or]
simp [not_nonempty_iff_eq_empty]
theorem Subsingleton.image2 (hs : s.Subsingleton) (ht : t.Subsingleton) (f : α → β → γ) :
(image2 f s t).Subsingleton := by
rw [← image_prod]
apply (hs.prod ht).image
theorem image2_inter_subset_left : image2 f (s ∩ s') t ⊆ image2 f s t ∩ image2 f s' t :=
Monotone.map_inf_le (fun _ _ ↦ image2_subset_right) s s'
theorem image2_inter_subset_right : image2 f s (t ∩ t') ⊆ image2 f s t ∩ image2 f s t' :=
Monotone.map_inf_le (fun _ _ ↦ image2_subset_left) t t'
@[simp]
theorem image2_singleton_left : image2 f {a} t = f a '' t :=
ext fun x => by simp
@[simp]
theorem image2_singleton_right : image2 f s {b} = (fun a => f a b) '' s :=
ext fun x => by simp
theorem image2_singleton : image2 f {a} {b} = {f a b} := by simp
@[simp]
| theorem image2_insert_left : image2 f (insert a s) t = (fun b => f a b) '' t ∪ image2 f s t := by
rw [insert_eq, image2_union_left, image2_singleton_left]
@[simp]
| Mathlib/Data/Set/NAry.lean | 154 | 157 |
/-
Copyright (c) 2018 Reid Barton. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Reid Barton
-/
import Mathlib.Topology.Hom.ContinuousEval
import Mathlib.Topology.ContinuousMap.Basic
import Mathlib.Topology.Separation.Regular
/-!
# The compact-open topology
In this file, we define the compact-open topology on the set of continuous maps between two
topological spaces.
## Main definitions
* `ContinuousMap.compactOpen` is the compact-open topology on `C(X, Y)`.
It is declared as an instance.
* `ContinuousMap.coev` is the coevaluation map `Y → C(X, Y × X)`. It is always continuous.
* `ContinuousMap.curry` is the currying map `C(X × Y, Z) → C(X, C(Y, Z))`. This map always exists
and it is continuous as long as `X × Y` is locally compact.
* `ContinuousMap.uncurry` is the uncurrying map `C(X, C(Y, Z)) → C(X × Y, Z)`. For this map to
exist, we need `Y` to be locally compact. If `X` is also locally compact, then this map is
continuous.
* `Homeomorph.curry` combines the currying and uncurrying operations into a homeomorphism
`C(X × Y, Z) ≃ₜ C(X, C(Y, Z))`. This homeomorphism exists if `X` and `Y` are locally compact.
## Tags
compact-open, curry, function space
-/
open Set Filter TopologicalSpace Topology
namespace ContinuousMap
section CompactOpen
variable {α X Y Z T : Type*}
variable [TopologicalSpace X] [TopologicalSpace Y] [TopologicalSpace Z] [TopologicalSpace T]
variable {K : Set X} {U : Set Y}
/-- The compact-open topology on the space of continuous maps `C(X, Y)`. -/
instance compactOpen : TopologicalSpace C(X, Y) :=
.generateFrom <| image2 (fun K U ↦ {f | MapsTo f K U}) {K | IsCompact K} {U | IsOpen U}
/-- Definition of `ContinuousMap.compactOpen`. -/
theorem compactOpen_eq : @compactOpen X Y _ _ =
.generateFrom (image2 (fun K U ↦ {f | MapsTo f K U}) {K | IsCompact K} {t | IsOpen t}) :=
rfl
theorem isOpen_setOf_mapsTo (hK : IsCompact K) (hU : IsOpen U) :
IsOpen {f : C(X, Y) | MapsTo f K U} :=
isOpen_generateFrom_of_mem <| mem_image2_of_mem hK hU
lemma eventually_mapsTo {f : C(X, Y)} (hK : IsCompact K) (hU : IsOpen U) (h : MapsTo f K U) :
∀ᶠ g : C(X, Y) in 𝓝 f, MapsTo g K U :=
(isOpen_setOf_mapsTo hK hU).mem_nhds h
lemma nhds_compactOpen (f : C(X, Y)) :
𝓝 f = ⨅ (K : Set X) (_ : IsCompact K) (U : Set Y) (_ : IsOpen U) (_ : MapsTo f K U),
𝓟 {g : C(X, Y) | MapsTo g K U} := by
simp_rw [compactOpen_eq, nhds_generateFrom, mem_setOf_eq, @and_comm (f ∈ _), iInf_and,
← image_prod, iInf_image, biInf_prod, mem_setOf_eq]
lemma tendsto_nhds_compactOpen {l : Filter α} {f : α → C(Y, Z)} {g : C(Y, Z)} :
Tendsto f l (𝓝 g) ↔
∀ K, IsCompact K → ∀ U, IsOpen U → MapsTo g K U → ∀ᶠ a in l, MapsTo (f a) K U := by
simp [nhds_compactOpen]
lemma continuous_compactOpen {f : X → C(Y, Z)} :
Continuous f ↔ ∀ K, IsCompact K → ∀ U, IsOpen U → IsOpen {x | MapsTo (f x) K U} :=
continuous_generateFrom_iff.trans forall_mem_image2
protected lemma hasBasis_nhds (f : C(X, Y)) :
(𝓝 f).HasBasis
(fun S : Set (Set X × Set Y) ↦
S.Finite ∧ ∀ K U, (K, U) ∈ S → IsCompact K ∧ IsOpen U ∧ MapsTo f K U)
(⋂ KU ∈ ·, {g : C(X, Y) | MapsTo g KU.1 KU.2}) := by
refine ⟨fun s ↦ ?_⟩
simp_rw [nhds_compactOpen, iInf_comm.{_, 0, _ + 1}, iInf_prod', iInf_and']
simp [mem_biInf_principal, and_assoc]
protected lemma mem_nhds_iff {f : C(X, Y)} {s : Set C(X, Y)} :
s ∈ 𝓝 f ↔ ∃ S : Set (Set X × Set Y), S.Finite ∧
(∀ K U, (K, U) ∈ S → IsCompact K ∧ IsOpen U ∧ MapsTo f K U) ∧
{g : C(X, Y) | ∀ K U, (K, U) ∈ S → MapsTo g K U} ⊆ s := by
simp [f.hasBasis_nhds.mem_iff, ← setOf_forall, and_assoc]
section Functorial
/-- `C(X, ·)` is a functor. -/
theorem continuous_postcomp (g : C(Y, Z)) : Continuous (ContinuousMap.comp g : C(X, Y) → C(X, Z)) :=
continuous_compactOpen.2 fun _K hK _U hU ↦ isOpen_setOf_mapsTo hK (hU.preimage g.2)
/-- If `g : C(Y, Z)` is a topology inducing map,
then the composition `ContinuousMap.comp g : C(X, Y) → C(X, Z)` is a topology inducing map too. -/
theorem isInducing_postcomp (g : C(Y, Z)) (hg : IsInducing g) :
IsInducing (g.comp : C(X, Y) → C(X, Z)) where
eq_induced := by
simp only [compactOpen_eq, induced_generateFrom_eq, image_image2, hg.setOf_isOpen,
image2_image_right, MapsTo, mem_preimage, preimage_setOf_eq, comp_apply]
@[deprecated (since := "2024-10-28")] alias inducing_postcomp := isInducing_postcomp
/-- If `g : C(Y, Z)` is a topological embedding,
then the composition `ContinuousMap.comp g : C(X, Y) → C(X, Z)` is an embedding too. -/
theorem isEmbedding_postcomp (g : C(Y, Z)) (hg : IsEmbedding g) :
IsEmbedding (g.comp : C(X, Y) → C(X, Z)) :=
⟨isInducing_postcomp g hg.1, fun _ _ ↦ (cancel_left hg.2).1⟩
@[deprecated (since := "2024-10-26")]
alias embedding_postcomp := isEmbedding_postcomp
/-- `C(·, Z)` is a functor. -/
@[continuity, fun_prop]
theorem continuous_precomp (f : C(X, Y)) : Continuous (fun g => g.comp f : C(Y, Z) → C(X, Z)) :=
continuous_compactOpen.2 fun K hK U hU ↦ by
simpa only [mapsTo_image_iff] using isOpen_setOf_mapsTo (hK.image f.2) hU
variable (Z) in
/-- Precomposition by a continuous map is itself a continuous map between spaces of continuous maps.
-/
@[simps apply]
def compRightContinuousMap (f : C(X, Y)) :
C(C(Y, Z), C(X, Z)) where
toFun g := g.comp f
/-- Any pair of homeomorphisms `X ≃ₜ Z` and `Y ≃ₜ T` gives rise to a homeomorphism
`C(X, Y) ≃ₜ C(Z, T)`. -/
protected def _root_.Homeomorph.arrowCongr (φ : X ≃ₜ Z) (ψ : Y ≃ₜ T) :
C(X, Y) ≃ₜ C(Z, T) where
toFun f := .comp ψ <| f.comp φ.symm
invFun f := .comp ψ.symm <| f.comp φ
left_inv f := ext fun _ ↦ ψ.left_inv (f _) |>.trans <| congrArg f <| φ.left_inv _
right_inv f := ext fun _ ↦ ψ.right_inv (f _) |>.trans <| congrArg f <| φ.right_inv _
continuous_toFun := continuous_postcomp _ |>.comp <| continuous_precomp _
continuous_invFun := continuous_postcomp _ |>.comp <| continuous_precomp _
variable [LocallyCompactPair Y Z]
/-- Composition is a continuous map from `C(X, Y) × C(Y, Z)` to `C(X, Z)`,
provided that `Y` is locally compact.
This is Prop. 9 of Chap. X, §3, №. 4 of Bourbaki's *Topologie Générale*. -/
theorem continuous_comp' : Continuous fun x : C(X, Y) × C(Y, Z) => x.2.comp x.1 := by
simp_rw [continuous_iff_continuousAt, ContinuousAt, tendsto_nhds_compactOpen]
intro ⟨f, g⟩ K hK U hU (hKU : MapsTo (g ∘ f) K U)
obtain ⟨L, hKL, hLc, hLU⟩ : ∃ L ∈ 𝓝ˢ (f '' K), IsCompact L ∧ MapsTo g L U :=
exists_mem_nhdsSet_isCompact_mapsTo g.continuous (hK.image f.continuous) hU
(mapsTo_image_iff.2 hKU)
rw [← subset_interior_iff_mem_nhdsSet, ← mapsTo'] at hKL
exact ((eventually_mapsTo hK isOpen_interior hKL).prod_nhds
(eventually_mapsTo hLc hU hLU)).mono fun ⟨f', g'⟩ ⟨hf', hg'⟩ ↦
hg'.comp <| hf'.mono_right interior_subset
lemma _root_.Filter.Tendsto.compCM {α : Type*} {l : Filter α} {g : α → C(Y, Z)} {g₀ : C(Y, Z)}
{f : α → C(X, Y)} {f₀ : C(X, Y)} (hg : Tendsto g l (𝓝 g₀)) (hf : Tendsto f l (𝓝 f₀)) :
Tendsto (fun a ↦ (g a).comp (f a)) l (𝓝 (g₀.comp f₀)) :=
(continuous_comp'.tendsto (f₀, g₀)).comp (hf.prodMk_nhds hg)
variable {X' : Type*} [TopologicalSpace X'] {a : X'} {g : X' → C(Y, Z)} {f : X' → C(X, Y)}
{s : Set X'}
nonrec lemma _root_.ContinuousAt.compCM (hg : ContinuousAt g a) (hf : ContinuousAt f a) :
ContinuousAt (fun x ↦ (g x).comp (f x)) a :=
hg.compCM hf
nonrec lemma _root_.ContinuousWithinAt.compCM (hg : ContinuousWithinAt g s a)
(hf : ContinuousWithinAt f s a) : ContinuousWithinAt (fun x ↦ (g x).comp (f x)) s a :=
hg.compCM hf
lemma _root_.ContinuousOn.compCM (hg : ContinuousOn g s) (hf : ContinuousOn f s) :
ContinuousOn (fun x ↦ (g x).comp (f x)) s := fun a ha ↦
(hg a ha).compCM (hf a ha)
lemma _root_.Continuous.compCM (hg : Continuous g) (hf : Continuous f) :
Continuous fun x => (g x).comp (f x) :=
continuous_comp'.comp (hf.prodMk hg)
end Functorial
section Ev
/-- The evaluation map `C(X, Y) × X → Y` is continuous
if `X, Y` is a locally compact pair of spaces. -/
instance [LocallyCompactPair X Y] : ContinuousEval C(X, Y) X Y where
continuous_eval := by
simp_rw [continuous_iff_continuousAt, ContinuousAt, (nhds_basis_opens _).tendsto_right_iff]
rintro ⟨f, x⟩ U ⟨hx : f x ∈ U, hU : IsOpen U⟩
rcases exists_mem_nhds_isCompact_mapsTo f.continuous (hU.mem_nhds hx) with ⟨K, hxK, hK, hKU⟩
filter_upwards [prod_mem_nhds (eventually_mapsTo hK hU hKU) hxK] using fun _ h ↦ h.1 h.2
instance : ContinuousEvalConst C(X, Y) X Y where
continuous_eval_const x :=
continuous_def.2 fun U hU ↦ by simpa using isOpen_setOf_mapsTo isCompact_singleton hU
lemma isClosed_setOf_mapsTo {t : Set Y} (ht : IsClosed t) (s : Set X) :
IsClosed {f : C(X, Y) | MapsTo f s t} :=
ht.setOf_mapsTo fun _ _ ↦ continuous_eval_const _
lemma isClopen_setOf_mapsTo (hK : IsCompact K) (hU : IsClopen U) :
IsClopen {f : C(X, Y) | MapsTo f K U} :=
⟨isClosed_setOf_mapsTo hU.isClosed K, isOpen_setOf_mapsTo hK hU.isOpen⟩
@[norm_cast]
lemma specializes_coe {f g : C(X, Y)} : ⇑f ⤳ ⇑g ↔ f ⤳ g := by
refine ⟨fun h ↦ ?_, fun h ↦ h.map continuous_coeFun⟩
suffices ∀ K, IsCompact K → ∀ U, IsOpen U → MapsTo g K U → MapsTo f K U by
simpa [specializes_iff_pure, nhds_compactOpen]
exact fun K _ U hU hg x hx ↦ (h.map (continuous_apply x)).mem_open hU (hg hx)
@[norm_cast]
lemma inseparable_coe {f g : C(X, Y)} : Inseparable (f : X → Y) g ↔ Inseparable f g := by
simp only [inseparable_iff_specializes_and, specializes_coe]
instance [T0Space Y] : T0Space C(X, Y) :=
t0Space_of_injective_of_continuous DFunLike.coe_injective continuous_coeFun
instance [R0Space Y] : R0Space C(X, Y) where
specializes_symmetric f g h := by
rw [← specializes_coe] at h ⊢
exact h.symm
instance [T1Space Y] : T1Space C(X, Y) :=
t1Space_of_injective_of_continuous DFunLike.coe_injective continuous_coeFun
instance [R1Space Y] : R1Space C(X, Y) :=
.of_continuous_specializes_imp continuous_coeFun fun _ _ ↦ specializes_coe.1
instance [T2Space Y] : T2Space C(X, Y) := inferInstance
instance [RegularSpace Y] : RegularSpace C(X, Y) :=
.of_lift'_closure_le fun f ↦ by
rw [← tendsto_id', tendsto_nhds_compactOpen]
intro K hK U hU hf
rcases (hK.image f.continuous).exists_isOpen_closure_subset (hU.mem_nhdsSet.2 hf.image_subset)
with ⟨V, hVo, hKV, hVU⟩
filter_upwards [mem_lift' (eventually_mapsTo hK hVo (mapsTo'.2 hKV))] with g hg
refine ((isClosed_setOf_mapsTo isClosed_closure K).closure_subset ?_).mono_right hVU
exact closure_mono (fun _ h ↦ h.mono_right subset_closure) hg
instance [T3Space Y] : T3Space C(X, Y) := inferInstance
end Ev
section InfInduced
/-- For any subset `s` of `X`, the restriction of continuous functions to `s` is continuous
as a function from `C(X, Y)` to `C(s, Y)` with their respective compact-open topologies. -/
theorem continuous_restrict (s : Set X) : Continuous fun F : C(X, Y) => F.restrict s :=
continuous_precomp <| restrict s <| .id X
theorem compactOpen_le_induced (s : Set X) :
(ContinuousMap.compactOpen : TopologicalSpace C(X, Y)) ≤
.induced (restrict s) ContinuousMap.compactOpen :=
(continuous_restrict s).le_induced
/-- The compact-open topology on `C(X, Y)`
is equal to the infimum of the compact-open topologies on `C(s, Y)` for `s` a compact subset of `X`.
The key point of the proof is that for every compact set `K`,
the universal set `Set.univ : Set K` is a compact set as well. -/
theorem compactOpen_eq_iInf_induced :
(ContinuousMap.compactOpen : TopologicalSpace C(X, Y)) =
⨅ (K : Set X) (_ : IsCompact K), .induced (.restrict K) ContinuousMap.compactOpen := by
refine le_antisymm (le_iInf₂ fun s _ ↦ compactOpen_le_induced s) ?_
refine le_generateFrom <| forall_mem_image2.2 fun K (hK : IsCompact K) U hU ↦ ?_
refine TopologicalSpace.le_def.1 (iInf₂_le K hK) _ ?_
convert isOpen_induced (isOpen_setOf_mapsTo (isCompact_iff_isCompact_univ.1 hK) hU)
simp [mapsTo_univ_iff, Subtype.forall, MapsTo]
theorem nhds_compactOpen_eq_iInf_nhds_induced (f : C(X, Y)) :
𝓝 f = ⨅ (s) (_ : IsCompact s), (𝓝 (f.restrict s)).comap (ContinuousMap.restrict s) := by
rw [compactOpen_eq_iInf_induced]
simp only [nhds_iInf, nhds_induced]
theorem tendsto_compactOpen_restrict {ι : Type*} {l : Filter ι} {F : ι → C(X, Y)} {f : C(X, Y)}
(hFf : Filter.Tendsto F l (𝓝 f)) (s : Set X) :
Tendsto (fun i => (F i).restrict s) l (𝓝 (f.restrict s)) :=
(continuous_restrict s).continuousAt.tendsto.comp hFf
theorem tendsto_compactOpen_iff_forall {ι : Type*} {l : Filter ι} (F : ι → C(X, Y)) (f : C(X, Y)) :
Tendsto F l (𝓝 f) ↔
∀ K, IsCompact K → Tendsto (fun i => (F i).restrict K) l (𝓝 (f.restrict K)) := by
rw [compactOpen_eq_iInf_induced]
simp [nhds_iInf, nhds_induced, Filter.tendsto_comap_iff, Function.comp_def]
/-- A family `F` of functions in `C(X, Y)` converges in the compact-open topology, if and only if
it converges in the compact-open topology on each compact subset of `X`. -/
theorem exists_tendsto_compactOpen_iff_forall [WeaklyLocallyCompactSpace X] [T2Space Y]
{ι : Type*} {l : Filter ι} [Filter.NeBot l] (F : ι → C(X, Y)) :
(∃ f, Filter.Tendsto F l (𝓝 f)) ↔
∀ s : Set X, IsCompact s → ∃ f, Filter.Tendsto (fun i => (F i).restrict s) l (𝓝 f) := by
constructor
· rintro ⟨f, hf⟩ s _
exact ⟨f.restrict s, tendsto_compactOpen_restrict hf s⟩
· intro h
choose f hf using h
-- By uniqueness of limits in a `T2Space`, since `fun i ↦ F i x` tends to both `f s₁ hs₁ x` and
-- `f s₂ hs₂ x`, we have `f s₁ hs₁ x = f s₂ hs₂ x`
| have h :
∀ (s₁) (hs₁ : IsCompact s₁) (s₂) (hs₂ : IsCompact s₂) (x : X) (hxs₁ : x ∈ s₁) (hxs₂ : x ∈ s₂),
f s₁ hs₁ ⟨x, hxs₁⟩ = f s₂ hs₂ ⟨x, hxs₂⟩ := by
rintro s₁ hs₁ s₂ hs₂ x hxs₁ hxs₂
haveI := isCompact_iff_compactSpace.mp hs₁
| Mathlib/Topology/CompactOpen.lean | 303 | 307 |
/-
Copyright (c) 2021 Floris van Doorn. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Floris van Doorn
-/
import Mathlib.Algebra.Field.Basic
import Mathlib.Algebra.Order.Field.Canonical
import Mathlib.Algebra.Order.Nonneg.Ring
import Mathlib.Data.Nat.Cast.Order.Ring
/-!
# Semifield structure on the type of nonnegative elements
This file defines instances and prove some properties about the nonnegative elements
`{x : α // 0 ≤ x}` of an arbitrary type `α`.
This is used to derive algebraic structures on `ℝ≥0` and `ℚ≥0` automatically.
## Main declarations
* `{x : α // 0 ≤ x}` is a `CanonicallyLinearOrderedSemifield` if `α` is a `LinearOrderedField`.
-/
assert_not_exists abs_inv
open Set
variable {α : Type*}
section NNRat
variable [Semifield α] [LinearOrder α] [IsStrictOrderedRing α] {a : α}
lemma NNRat.cast_nonneg (q : ℚ≥0) : 0 ≤ (q : α) := by
rw [cast_def]; exact div_nonneg q.num.cast_nonneg q.den.cast_nonneg
lemma nnqsmul_nonneg (q : ℚ≥0) (ha : 0 ≤ a) : 0 ≤ q • a := by
rw [NNRat.smul_def]; exact mul_nonneg q.cast_nonneg ha
end NNRat
namespace Nonneg
section LinearOrderedSemifield
variable [Semifield α] [LinearOrder α] [IsStrictOrderedRing α] {x y : α}
instance inv : Inv { x : α // 0 ≤ x } :=
⟨fun x => ⟨x⁻¹, inv_nonneg.2 x.2⟩⟩
@[simp, norm_cast]
protected theorem coe_inv (a : { x : α // 0 ≤ x }) : ((a⁻¹ : { x : α // 0 ≤ x }) : α) = (a : α)⁻¹ :=
rfl
@[simp]
theorem inv_mk (hx : 0 ≤ x) :
(⟨x, hx⟩ : { x : α // 0 ≤ x })⁻¹ = ⟨x⁻¹, inv_nonneg.2 hx⟩ :=
rfl
instance div : Div { x : α // 0 ≤ x } :=
⟨fun x y => ⟨x / y, div_nonneg x.2 y.2⟩⟩
@[simp, norm_cast]
protected theorem coe_div (a b : { x : α // 0 ≤ x }) : ((a / b : { x : α // 0 ≤ x }) : α) = a / b :=
rfl
@[simp]
theorem mk_div_mk (hx : 0 ≤ x) (hy : 0 ≤ y) :
(⟨x, hx⟩ : { x : α // 0 ≤ x }) / ⟨y, hy⟩ = ⟨x / y, div_nonneg hx hy⟩ :=
rfl
instance zpow : Pow { x : α // 0 ≤ x } ℤ :=
⟨fun a n => ⟨(a : α) ^ n, zpow_nonneg a.2 _⟩⟩
@[simp, norm_cast]
protected theorem coe_zpow (a : { x : α // 0 ≤ x }) (n : ℤ) :
((a ^ n : { x : α // 0 ≤ x }) : α) = (a : α) ^ n :=
rfl
@[simp]
theorem mk_zpow (hx : 0 ≤ x) (n : ℤ) :
(⟨x, hx⟩ : { x : α // 0 ≤ x }) ^ n = ⟨x ^ n, zpow_nonneg hx n⟩ :=
rfl
instance instNNRatCast : NNRatCast {x : α // 0 ≤ x} := ⟨fun q ↦ ⟨q, q.cast_nonneg⟩⟩
instance instNNRatSMul : SMul ℚ≥0 {x : α // 0 ≤ x} where
smul q a := ⟨q • a, by rw [NNRat.smul_def]; exact mul_nonneg q.cast_nonneg a.2⟩
@[simp, norm_cast] lemma coe_nnratCast (q : ℚ≥0) : (q : {x : α // 0 ≤ x}) = (q : α) := rfl
@[simp] lemma mk_nnratCast (q : ℚ≥0) : (⟨q, q.cast_nonneg⟩ : {x : α // 0 ≤ x}) = q := rfl
@[simp, norm_cast] lemma coe_nnqsmul (q : ℚ≥0) (a : {x : α // 0 ≤ x}) :
↑(q • a) = (q • a : α) := rfl
@[simp] lemma mk_nnqsmul (q : ℚ≥0) (a : α) (ha : 0 ≤ a) :
(⟨q • a, by rw [NNRat.smul_def]; exact mul_nonneg q.cast_nonneg ha⟩ : {x : α // 0 ≤ x}) =
q • a := rfl
instance semifield : Semifield { x : α // 0 ≤ x } := fast_instance%
Subtype.coe_injective.semifield _ Nonneg.coe_zero Nonneg.coe_one Nonneg.coe_add
Nonneg.coe_mul Nonneg.coe_inv Nonneg.coe_div (fun _ _ => rfl) coe_nnqsmul Nonneg.coe_pow
Nonneg.coe_zpow Nonneg.coe_natCast coe_nnratCast
| end LinearOrderedSemifield
instance linearOrderedCommGroupWithZero [Field α] [LinearOrder α] [IsStrictOrderedRing α] :
| Mathlib/Algebra/Order/Nonneg/Field.lean | 102 | 104 |
/-
Copyright (c) 2023 David Loeffler. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: David Loeffler
-/
import Mathlib.Analysis.Convolution
import Mathlib.Analysis.SpecialFunctions.Trigonometric.EulerSineProd
import Mathlib.Analysis.SpecialFunctions.Gamma.BohrMollerup
import Mathlib.Analysis.Analytic.IsolatedZeros
import Mathlib.Analysis.Complex.CauchyIntegral
/-!
# The Beta function, and further properties of the Gamma function
In this file we define the Beta integral, relate Beta and Gamma functions, and prove some
refined properties of the Gamma function using these relations.
## Results on the Beta function
* `Complex.betaIntegral`: the Beta function `Β(u, v)`, where `u`, `v` are complex with positive
real part.
* `Complex.Gamma_mul_Gamma_eq_betaIntegral`: the formula
`Gamma u * Gamma v = Gamma (u + v) * betaIntegral u v`.
## Results on the Gamma function
* `Complex.Gamma_ne_zero`: for all `s : ℂ` with `s ∉ {-n : n ∈ ℕ}` we have `Γ s ≠ 0`.
* `Complex.GammaSeq_tendsto_Gamma`: for all `s`, the limit as `n → ∞` of the sequence
`n ↦ n ^ s * n! / (s * (s + 1) * ... * (s + n))` is `Γ(s)`.
* `Complex.Gamma_mul_Gamma_one_sub`: Euler's reflection formula
`Gamma s * Gamma (1 - s) = π / sin π s`.
* `Complex.differentiable_one_div_Gamma`: the function `1 / Γ(s)` is differentiable everywhere.
* `Complex.Gamma_mul_Gamma_add_half`: Legendre's duplication formula
`Gamma s * Gamma (s + 1 / 2) = Gamma (2 * s) * 2 ^ (1 - 2 * s) * √π`.
* `Real.Gamma_ne_zero`, `Real.GammaSeq_tendsto_Gamma`,
`Real.Gamma_mul_Gamma_one_sub`, `Real.Gamma_mul_Gamma_add_half`: real versions of the above.
-/
noncomputable section
open Filter intervalIntegral Set Real MeasureTheory
open scoped Nat Topology Real
section BetaIntegral
/-! ## The Beta function -/
namespace Complex
/-- The Beta function `Β (u, v)`, defined as `∫ x:ℝ in 0..1, x ^ (u - 1) * (1 - x) ^ (v - 1)`. -/
noncomputable def betaIntegral (u v : ℂ) : ℂ :=
∫ x : ℝ in (0)..1, (x : ℂ) ^ (u - 1) * (1 - (x : ℂ)) ^ (v - 1)
/-- Auxiliary lemma for `betaIntegral_convergent`, showing convergence at the left endpoint. -/
theorem betaIntegral_convergent_left {u : ℂ} (hu : 0 < re u) (v : ℂ) :
IntervalIntegrable (fun x =>
(x : ℂ) ^ (u - 1) * (1 - (x : ℂ)) ^ (v - 1) : ℝ → ℂ) volume 0 (1 / 2) := by
apply IntervalIntegrable.mul_continuousOn
· refine intervalIntegral.intervalIntegrable_cpow' ?_
rwa [sub_re, one_re, ← zero_sub, sub_lt_sub_iff_right]
· apply continuousOn_of_forall_continuousAt
intro x hx
rw [uIcc_of_le (by positivity : (0 : ℝ) ≤ 1 / 2)] at hx
apply ContinuousAt.cpow
· exact (continuous_const.sub continuous_ofReal).continuousAt
· exact continuousAt_const
· norm_cast
exact ofReal_mem_slitPlane.2 <| by linarith only [hx.2]
/-- The Beta integral is convergent for all `u, v` of positive real part. -/
theorem betaIntegral_convergent {u v : ℂ} (hu : 0 < re u) (hv : 0 < re v) :
IntervalIntegrable (fun x =>
(x : ℂ) ^ (u - 1) * (1 - (x : ℂ)) ^ (v - 1) : ℝ → ℂ) volume 0 1 := by
refine (betaIntegral_convergent_left hu v).trans ?_
rw [IntervalIntegrable.iff_comp_neg]
convert ((betaIntegral_convergent_left hv u).comp_add_right 1).symm using 1
· ext1 x
conv_lhs => rw [mul_comm]
congr 2 <;> · push_cast; ring
· norm_num
· norm_num
theorem betaIntegral_symm (u v : ℂ) : betaIntegral v u = betaIntegral u v := by
rw [betaIntegral, betaIntegral]
have := intervalIntegral.integral_comp_mul_add (a := 0) (b := 1) (c := -1)
(fun x : ℝ => (x : ℂ) ^ (u - 1) * (1 - (x : ℂ)) ^ (v - 1)) neg_one_lt_zero.ne 1
rw [inv_neg, inv_one, neg_one_smul, ← intervalIntegral.integral_symm] at this
simp? at this says
simp only [neg_mul, one_mul, ofReal_add, ofReal_neg, ofReal_one, sub_add_cancel_right, neg_neg,
mul_one, neg_add_cancel, mul_zero, zero_add] at this
conv_lhs at this => arg 1; intro x; rw [add_comm, ← sub_eq_add_neg, mul_comm]
exact this
theorem betaIntegral_eval_one_right {u : ℂ} (hu : 0 < re u) : betaIntegral u 1 = 1 / u := by
simp_rw [betaIntegral, sub_self, cpow_zero, mul_one]
rw [integral_cpow (Or.inl _)]
· rw [ofReal_zero, ofReal_one, one_cpow, zero_cpow, sub_zero, sub_add_cancel]
rw [sub_add_cancel]
contrapose! hu; rw [hu, zero_re]
· rwa [sub_re, one_re, ← sub_pos, sub_neg_eq_add, sub_add_cancel]
theorem betaIntegral_scaled (s t : ℂ) {a : ℝ} (ha : 0 < a) :
∫ x in (0)..a, (x : ℂ) ^ (s - 1) * ((a : ℂ) - x) ^ (t - 1) =
(a : ℂ) ^ (s + t - 1) * betaIntegral s t := by
have ha' : (a : ℂ) ≠ 0 := ofReal_ne_zero.mpr ha.ne'
rw [betaIntegral]
have A : (a : ℂ) ^ (s + t - 1) = a * ((a : ℂ) ^ (s - 1) * (a : ℂ) ^ (t - 1)) := by
rw [(by abel : s + t - 1 = 1 + (s - 1) + (t - 1)), cpow_add _ _ ha', cpow_add 1 _ ha', cpow_one,
mul_assoc]
rw [A, mul_assoc, ← intervalIntegral.integral_const_mul, ← real_smul, ← zero_div a, ←
div_self ha.ne', ← intervalIntegral.integral_comp_div _ ha.ne', zero_div]
simp_rw [intervalIntegral.integral_of_le ha.le]
refine setIntegral_congr_fun measurableSet_Ioc fun x hx => ?_
rw [mul_mul_mul_comm]
congr 1
· rw [← mul_cpow_ofReal_nonneg ha.le (div_pos hx.1 ha).le, ofReal_div, mul_div_cancel₀ _ ha']
· rw [(by norm_cast : (1 : ℂ) - ↑(x / a) = ↑(1 - x / a)), ←
mul_cpow_ofReal_nonneg ha.le (sub_nonneg.mpr <| (div_le_one ha).mpr hx.2)]
push_cast
rw [mul_sub, mul_one, mul_div_cancel₀ _ ha']
/-- Relation between Beta integral and Gamma function. -/
theorem Gamma_mul_Gamma_eq_betaIntegral {s t : ℂ} (hs : 0 < re s) (ht : 0 < re t) :
Gamma s * Gamma t = Gamma (s + t) * betaIntegral s t := by
-- Note that we haven't proved (yet) that the Gamma function has no zeroes, so we can't formulate
-- this as a formula for the Beta function.
have conv_int := integral_posConvolution
(GammaIntegral_convergent hs) (GammaIntegral_convergent ht) (ContinuousLinearMap.mul ℝ ℂ)
simp_rw [ContinuousLinearMap.mul_apply'] at conv_int
have hst : 0 < re (s + t) := by rw [add_re]; exact add_pos hs ht
rw [Gamma_eq_integral hs, Gamma_eq_integral ht, Gamma_eq_integral hst, GammaIntegral,
GammaIntegral, GammaIntegral, ← conv_int, ← MeasureTheory.integral_mul_const (betaIntegral _ _)]
refine setIntegral_congr_fun measurableSet_Ioi fun x hx => ?_
rw [mul_assoc, ← betaIntegral_scaled s t hx, ← intervalIntegral.integral_const_mul]
congr 1 with y : 1
push_cast
suffices Complex.exp (-x) = Complex.exp (-y) * Complex.exp (-(x - y)) by rw [this]; ring
rw [← Complex.exp_add]; congr 1; abel
/-- Recurrence formula for the Beta function. -/
theorem betaIntegral_recurrence {u v : ℂ} (hu : 0 < re u) (hv : 0 < re v) :
u * betaIntegral u (v + 1) = v * betaIntegral (u + 1) v := by
-- NB: If we knew `Gamma (u + v + 1) ≠ 0` this would be an easy consequence of
-- `Gamma_mul_Gamma_eq_betaIntegral`; but we don't know that yet. We will prove it later, but
-- this lemma is needed in the proof. So we give a (somewhat laborious) direct argument.
let F : ℝ → ℂ := fun x => (x : ℂ) ^ u * (1 - (x : ℂ)) ^ v
have hu' : 0 < re (u + 1) := by rw [add_re, one_re]; positivity
have hv' : 0 < re (v + 1) := by rw [add_re, one_re]; positivity
have hc : ContinuousOn F (Icc 0 1) := by
refine (continuousOn_of_forall_continuousAt fun x hx => ?_).mul
(continuousOn_of_forall_continuousAt fun x hx => ?_)
· refine (continuousAt_cpow_const_of_re_pos (Or.inl ?_) hu).comp continuous_ofReal.continuousAt
rw [ofReal_re]; exact hx.1
· refine (continuousAt_cpow_const_of_re_pos (Or.inl ?_) hv).comp
(continuous_const.sub continuous_ofReal).continuousAt
rw [sub_re, one_re, ofReal_re, sub_nonneg]
exact hx.2
have hder : ∀ x : ℝ, x ∈ Ioo (0 : ℝ) 1 →
HasDerivAt F (u * ((x : ℂ) ^ (u - 1) * (1 - (x : ℂ)) ^ v) -
v * ((x : ℂ) ^ u * (1 - (x : ℂ)) ^ (v - 1))) x := by
intro x hx
have U : HasDerivAt (fun y : ℂ => y ^ u) (u * (x : ℂ) ^ (u - 1)) ↑x := by
have := @HasDerivAt.cpow_const _ _ _ u (hasDerivAt_id (x : ℂ)) (Or.inl ?_)
· simp only [id_eq, mul_one] at this
exact this
· rw [id_eq, ofReal_re]; exact hx.1
have V : HasDerivAt (fun y : ℂ => (1 - y) ^ v) (-v * (1 - (x : ℂ)) ^ (v - 1)) ↑x := by
have A := @HasDerivAt.cpow_const _ _ _ v (hasDerivAt_id (1 - (x : ℂ))) (Or.inl ?_)
swap; · rw [id, sub_re, one_re, ofReal_re, sub_pos]; exact hx.2
simp_rw [id] at A
have B : HasDerivAt (fun y : ℂ => 1 - y) (-1) ↑x := by
apply HasDerivAt.const_sub; apply hasDerivAt_id
convert HasDerivAt.comp (↑x) A B using 1
ring
convert (U.mul V).comp_ofReal using 1
ring
have h_int := ((betaIntegral_convergent hu hv').const_mul u).sub
((betaIntegral_convergent hu' hv).const_mul v)
rw [add_sub_cancel_right, add_sub_cancel_right] at h_int
have int_ev := intervalIntegral.integral_eq_sub_of_hasDerivAt_of_le zero_le_one hc hder h_int
have hF0 : F 0 = 0 := by
simp only [F, mul_eq_zero, ofReal_zero, cpow_eq_zero_iff, eq_self_iff_true, Ne,
true_and, sub_zero, one_cpow, one_ne_zero, or_false]
contrapose! hu; rw [hu, zero_re]
have hF1 : F 1 = 0 := by
simp only [F, mul_eq_zero, ofReal_one, one_cpow, one_ne_zero, sub_self, cpow_eq_zero_iff,
eq_self_iff_true, Ne, true_and, false_or]
contrapose! hv; rw [hv, zero_re]
rw [hF0, hF1, sub_zero, intervalIntegral.integral_sub, intervalIntegral.integral_const_mul,
intervalIntegral.integral_const_mul] at int_ev
· rw [betaIntegral, betaIntegral, ← sub_eq_zero]
convert int_ev <;> ring
· apply IntervalIntegrable.const_mul
convert betaIntegral_convergent hu hv'; ring
· apply IntervalIntegrable.const_mul
convert betaIntegral_convergent hu' hv; ring
/-- Explicit formula for the Beta function when second argument is a positive integer. -/
theorem betaIntegral_eval_nat_add_one_right {u : ℂ} (hu : 0 < re u) (n : ℕ) :
betaIntegral u (n + 1) = n ! / ∏ j ∈ Finset.range (n + 1), (u + j) := by
induction' n with n IH generalizing u
· rw [Nat.cast_zero, zero_add, betaIntegral_eval_one_right hu, Nat.factorial_zero, Nat.cast_one]
simp
· have := betaIntegral_recurrence hu (?_ : 0 < re n.succ)
swap; · rw [← ofReal_natCast, ofReal_re]; positivity
rw [mul_comm u _, ← eq_div_iff] at this
swap; · contrapose! hu; rw [hu, zero_re]
rw [this, Finset.prod_range_succ', Nat.cast_succ, IH]
swap; · rw [add_re, one_re]; positivity
rw [Nat.factorial_succ, Nat.cast_mul, Nat.cast_add, Nat.cast_one, Nat.cast_zero, add_zero, ←
mul_div_assoc, ← div_div]
congr 3 with j : 1
push_cast; abel
end Complex
end BetaIntegral
section LimitFormula
/-! ## The Euler limit formula -/
namespace Complex
/-- The sequence with `n`-th term `n ^ s * n! / (s * (s + 1) * ... * (s + n))`, for complex `s`.
We will show that this tends to `Γ(s)` as `n → ∞`. -/
noncomputable def GammaSeq (s : ℂ) (n : ℕ) :=
(n : ℂ) ^ s * n ! / ∏ j ∈ Finset.range (n + 1), (s + j)
theorem GammaSeq_eq_betaIntegral_of_re_pos {s : ℂ} (hs : 0 < re s) (n : ℕ) :
GammaSeq s n = (n : ℂ) ^ s * betaIntegral s (n + 1) := by
rw [GammaSeq, betaIntegral_eval_nat_add_one_right hs n, ← mul_div_assoc]
theorem GammaSeq_add_one_left (s : ℂ) {n : ℕ} (hn : n ≠ 0) :
GammaSeq (s + 1) n / s = n / (n + 1 + s) * GammaSeq s n := by
conv_lhs => rw [GammaSeq, Finset.prod_range_succ, div_div]
conv_rhs =>
rw [GammaSeq, Finset.prod_range_succ', Nat.cast_zero, add_zero, div_mul_div_comm, ← mul_assoc,
← mul_assoc, mul_comm _ (Finset.prod _ _)]
congr 3
· rw [cpow_add _ _ (Nat.cast_ne_zero.mpr hn), cpow_one, mul_comm]
· refine Finset.prod_congr (by rfl) fun x _ => ?_
push_cast; ring
· abel
theorem GammaSeq_eq_approx_Gamma_integral {s : ℂ} (hs : 0 < re s) {n : ℕ} (hn : n ≠ 0) :
GammaSeq s n = ∫ x : ℝ in (0)..n, ↑((1 - x / n) ^ n) * (x : ℂ) ^ (s - 1) := by
have : ∀ x : ℝ, x = x / n * n := by intro x; rw [div_mul_cancel₀]; exact Nat.cast_ne_zero.mpr hn
conv_rhs => enter [1, x, 2, 1]; rw [this x]
rw [GammaSeq_eq_betaIntegral_of_re_pos hs]
have := intervalIntegral.integral_comp_div (a := 0) (b := n)
(fun x => ↑((1 - x) ^ n) * ↑(x * ↑n) ^ (s - 1) : ℝ → ℂ) (Nat.cast_ne_zero.mpr hn)
dsimp only at this
rw [betaIntegral, this, real_smul, zero_div, div_self, add_sub_cancel_right,
← intervalIntegral.integral_const_mul, ← intervalIntegral.integral_const_mul]
swap; · exact Nat.cast_ne_zero.mpr hn
simp_rw [intervalIntegral.integral_of_le zero_le_one]
refine setIntegral_congr_fun measurableSet_Ioc fun x hx => ?_
push_cast
have hn' : (n : ℂ) ≠ 0 := Nat.cast_ne_zero.mpr hn
have A : (n : ℂ) ^ s = (n : ℂ) ^ (s - 1) * n := by
conv_lhs => rw [(by ring : s = s - 1 + 1), cpow_add _ _ hn']
simp
have B : ((x : ℂ) * ↑n) ^ (s - 1) = (x : ℂ) ^ (s - 1) * (n : ℂ) ^ (s - 1) := by
rw [← ofReal_natCast,
mul_cpow_ofReal_nonneg hx.1.le (Nat.cast_pos.mpr (Nat.pos_of_ne_zero hn)).le]
rw [A, B, cpow_natCast]; ring
/-- The main technical lemma for `GammaSeq_tendsto_Gamma`, expressing the integral defining the
Gamma function for `0 < re s` as the limit of a sequence of integrals over finite intervals. -/
theorem approx_Gamma_integral_tendsto_Gamma_integral {s : ℂ} (hs : 0 < re s) :
Tendsto (fun n : ℕ => ∫ x : ℝ in (0)..n, ((1 - x / n) ^ n : ℝ) * (x : ℂ) ^ (s - 1)) atTop
(𝓝 <| Gamma s) := by
rw [Gamma_eq_integral hs]
-- We apply dominated convergence to the following function, which we will show is uniformly
-- bounded above by the Gamma integrand `exp (-x) * x ^ (re s - 1)`.
let f : ℕ → ℝ → ℂ := fun n =>
indicator (Ioc 0 (n : ℝ)) fun x : ℝ => ((1 - x / n) ^ n : ℝ) * (x : ℂ) ^ (s - 1)
-- integrability of f
have f_ible : ∀ n : ℕ, Integrable (f n) (volume.restrict (Ioi 0)) := by
intro n
rw [integrable_indicator_iff (measurableSet_Ioc : MeasurableSet (Ioc (_ : ℝ) _)), IntegrableOn,
Measure.restrict_restrict_of_subset Ioc_subset_Ioi_self, ← IntegrableOn, ←
intervalIntegrable_iff_integrableOn_Ioc_of_le (by positivity : (0 : ℝ) ≤ n)]
apply IntervalIntegrable.continuousOn_mul
· refine intervalIntegral.intervalIntegrable_cpow' ?_
rwa [sub_re, one_re, ← zero_sub, sub_lt_sub_iff_right]
· apply Continuous.continuousOn
continuity
-- pointwise limit of f
have f_tends : ∀ x : ℝ, x ∈ Ioi (0 : ℝ) →
Tendsto (fun n : ℕ => f n x) atTop (𝓝 <| ↑(Real.exp (-x)) * (x : ℂ) ^ (s - 1)) := by
intro x hx
apply Tendsto.congr'
· show ∀ᶠ n : ℕ in atTop, ↑((1 - x / n) ^ n) * (x : ℂ) ^ (s - 1) = f n x
filter_upwards [eventually_ge_atTop ⌈x⌉₊] with n hn
rw [Nat.ceil_le] at hn
dsimp only [f]
rw [indicator_of_mem]
exact ⟨hx, hn⟩
· simp_rw [mul_comm]
refine (Tendsto.comp (continuous_ofReal.tendsto _) ?_).const_mul _
convert tendsto_one_plus_div_pow_exp (-x) using 1
ext1 n
rw [neg_div, ← sub_eq_add_neg]
-- let `convert` identify the remaining goals
convert tendsto_integral_of_dominated_convergence _ (fun n => (f_ible n).1)
(Real.GammaIntegral_convergent hs) _
((ae_restrict_iff' measurableSet_Ioi).mpr (ae_of_all _ f_tends)) using 1
-- limit of f is the integrand we want
· ext1 n
rw [MeasureTheory.integral_indicator (measurableSet_Ioc : MeasurableSet (Ioc (_ : ℝ) _)),
intervalIntegral.integral_of_le (by positivity : 0 ≤ (n : ℝ)),
Measure.restrict_restrict_of_subset Ioc_subset_Ioi_self]
-- f is uniformly bounded by the Gamma integrand
· intro n
rw [ae_restrict_iff' measurableSet_Ioi]
filter_upwards with x hx
dsimp only [f]
rcases lt_or_le (n : ℝ) x with (hxn | hxn)
· rw [indicator_of_not_mem (not_mem_Ioc_of_gt hxn), norm_zero,
mul_nonneg_iff_right_nonneg_of_pos (exp_pos _)]
exact rpow_nonneg (le_of_lt hx) _
· rw [indicator_of_mem (mem_Ioc.mpr ⟨mem_Ioi.mp hx, hxn⟩), norm_mul, Complex.norm_of_nonneg
(pow_nonneg (sub_nonneg.mpr <| div_le_one_of_le₀ hxn <| by positivity) _),
norm_cpow_eq_rpow_re_of_pos hx, sub_re, one_re, mul_le_mul_right (rpow_pos_of_pos hx _)]
exact one_sub_div_pow_le_exp_neg hxn
/-- Euler's limit formula for the complex Gamma function. -/
theorem GammaSeq_tendsto_Gamma (s : ℂ) : Tendsto (GammaSeq s) atTop (𝓝 <| Gamma s) := by
suffices ∀ m : ℕ, -↑m < re s → Tendsto (GammaSeq s) atTop (𝓝 <| GammaAux m s) by
rw [Gamma]
apply this
rw [neg_lt]
rcases lt_or_le 0 (re s) with (hs | hs)
· exact (neg_neg_of_pos hs).trans_le (Nat.cast_nonneg _)
· refine (Nat.lt_floor_add_one _).trans_le ?_
rw [sub_eq_neg_add, Nat.floor_add_one (neg_nonneg.mpr hs), Nat.cast_add_one]
intro m
induction' m with m IH generalizing s
· -- Base case: `0 < re s`, so Gamma is given by the integral formula
intro hs
rw [Nat.cast_zero, neg_zero] at hs
rw [← Gamma_eq_GammaAux]
· refine Tendsto.congr' ?_ (approx_Gamma_integral_tendsto_Gamma_integral hs)
refine (eventually_ne_atTop 0).mp (Eventually.of_forall fun n hn => ?_)
exact (GammaSeq_eq_approx_Gamma_integral hs hn).symm
· rwa [Nat.cast_zero, neg_lt_zero]
· -- Induction step: use recurrence formulae in `s` for Gamma and GammaSeq
intro hs
rw [Nat.cast_succ, neg_add, ← sub_eq_add_neg, sub_lt_iff_lt_add, ← one_re, ← add_re] at hs
rw [GammaAux]
have := @Tendsto.congr' _ _ _ ?_ _ _
((eventually_ne_atTop 0).mp (Eventually.of_forall fun n hn => ?_)) ((IH _ hs).div_const s)
pick_goal 3; · exact GammaSeq_add_one_left s hn -- doesn't work if inlined?
conv at this => arg 1; intro n; rw [mul_comm]
rwa [← mul_one (GammaAux m (s + 1) / s), tendsto_mul_iff_of_ne_zero _ (one_ne_zero' ℂ)] at this
simp_rw [add_assoc]
exact tendsto_natCast_div_add_atTop (1 + s)
end Complex
end LimitFormula
section GammaReflection
/-! ## The reflection formula -/
namespace Complex
theorem GammaSeq_mul (z : ℂ) {n : ℕ} (hn : n ≠ 0) :
GammaSeq z n * GammaSeq (1 - z) n =
n / (n + ↑1 - z) * (↑1 / (z * ∏ j ∈ Finset.range n, (↑1 - z ^ 2 / ((j : ℂ) + 1) ^ 2))) := by
-- also true for n = 0 but we don't need it
have aux : ∀ a b c d : ℂ, a * b * (c * d) = a * c * (b * d) := by intros; ring
rw [GammaSeq, GammaSeq, div_mul_div_comm, aux, ← pow_two]
have : (n : ℂ) ^ z * (n : ℂ) ^ (1 - z) = n := by
rw [← cpow_add _ _ (Nat.cast_ne_zero.mpr hn), add_sub_cancel, cpow_one]
rw [this, Finset.prod_range_succ', Finset.prod_range_succ, aux, ← Finset.prod_mul_distrib,
Nat.cast_zero, add_zero, add_comm (1 - z) n, ← add_sub_assoc]
have : ∀ j : ℕ, (z + ↑(j + 1)) * (↑1 - z + ↑j) =
((j + 1) ^ 2 :) * (↑1 - z ^ 2 / ((j : ℂ) + 1) ^ 2) := by
intro j
push_cast
have : (j : ℂ) + 1 ≠ 0 := by rw [← Nat.cast_succ, Nat.cast_ne_zero]; exact Nat.succ_ne_zero j
field_simp; ring
simp_rw [this]
rw [Finset.prod_mul_distrib, ← Nat.cast_prod, Finset.prod_pow,
Finset.prod_range_add_one_eq_factorial, Nat.cast_pow,
(by intros; ring : ∀ a b c d : ℂ, a * b * (c * d) = a * (d * (b * c))), ← div_div,
mul_div_cancel_right₀, ← div_div, mul_comm z _, mul_one_div]
exact pow_ne_zero 2 (Nat.cast_ne_zero.mpr <| Nat.factorial_ne_zero n)
/-- Euler's reflection formula for the complex Gamma function. -/
theorem Gamma_mul_Gamma_one_sub (z : ℂ) : Gamma z * Gamma (1 - z) = π / sin (π * z) := by
have pi_ne : (π : ℂ) ≠ 0 := Complex.ofReal_ne_zero.mpr pi_ne_zero
by_cases hs : sin (↑π * z) = 0
· -- first deal with silly case z = integer
rw [hs, div_zero]
rw [← neg_eq_zero, ← Complex.sin_neg, ← mul_neg, Complex.sin_eq_zero_iff, mul_comm] at hs
obtain ⟨k, hk⟩ := hs
rw [mul_eq_mul_right_iff, eq_false (ofReal_ne_zero.mpr pi_pos.ne'), or_false,
neg_eq_iff_eq_neg] at hk
rw [hk]
cases k
· rw [Int.ofNat_eq_coe, Int.cast_natCast, Complex.Gamma_neg_nat_eq_zero, zero_mul]
· rw [Int.cast_negSucc, neg_neg, Nat.cast_add, Nat.cast_one, add_comm, sub_add_cancel_left,
Complex.Gamma_neg_nat_eq_zero, mul_zero]
refine tendsto_nhds_unique ((GammaSeq_tendsto_Gamma z).mul (GammaSeq_tendsto_Gamma <| 1 - z)) ?_
have : ↑π / sin (↑π * z) = 1 * (π / sin (π * z)) := by rw [one_mul]
convert Tendsto.congr' ((eventually_ne_atTop 0).mp (Eventually.of_forall fun n hn =>
(GammaSeq_mul z hn).symm)) (Tendsto.mul _ _)
· convert tendsto_natCast_div_add_atTop (1 - z) using 1; ext1 n; rw [add_sub_assoc]
· have : ↑π / sin (↑π * z) = 1 / (sin (π * z) / π) := by field_simp
convert tendsto_const_nhds.div _ (div_ne_zero hs pi_ne)
rw [← tendsto_mul_iff_of_ne_zero tendsto_const_nhds pi_ne, div_mul_cancel₀ _ pi_ne]
convert tendsto_euler_sin_prod z using 1
ext1 n; rw [mul_comm, ← mul_assoc]
/-- The Gamma function does not vanish on `ℂ` (except at non-positive integers, where the function
is mathematically undefined and we set it to `0` by convention). -/
theorem Gamma_ne_zero {s : ℂ} (hs : ∀ m : ℕ, s ≠ -m) : Gamma s ≠ 0 := by
by_cases h_im : s.im = 0
· have : s = ↑s.re := by
conv_lhs => rw [← Complex.re_add_im s]
rw [h_im, ofReal_zero, zero_mul, add_zero]
rw [this, Gamma_ofReal, ofReal_ne_zero]
refine Real.Gamma_ne_zero fun n => ?_
specialize hs n
contrapose! hs
rwa [this, ← ofReal_natCast, ← ofReal_neg, ofReal_inj]
· have : sin (↑π * s) ≠ 0 := by
rw [Complex.sin_ne_zero_iff]
intro k
apply_fun im
rw [im_ofReal_mul, ← ofReal_intCast, ← ofReal_mul, ofReal_im]
exact mul_ne_zero Real.pi_pos.ne' h_im
have A := div_ne_zero (ofReal_ne_zero.mpr Real.pi_pos.ne') this
rw [← Complex.Gamma_mul_Gamma_one_sub s, mul_ne_zero_iff] at A
exact A.1
theorem Gamma_eq_zero_iff (s : ℂ) : Gamma s = 0 ↔ ∃ m : ℕ, s = -m := by
constructor
| · contrapose!; exact Gamma_ne_zero
· rintro ⟨m, rfl⟩; exact Gamma_neg_nat_eq_zero m
/-- A weaker, but easier-to-apply, version of `Complex.Gamma_ne_zero`. -/
theorem Gamma_ne_zero_of_re_pos {s : ℂ} (hs : 0 < re s) : Gamma s ≠ 0 := by
refine Gamma_ne_zero fun m => ?_
contrapose! hs
simpa only [hs, neg_re, ← ofReal_natCast, ofReal_re, neg_nonpos] using Nat.cast_nonneg _
end Complex
namespace Real
/-- The sequence with `n`-th term `n ^ s * n! / (s * (s + 1) * ... * (s + n))`, for real `s`. We
will show that this tends to `Γ(s)` as `n → ∞`. -/
noncomputable def GammaSeq (s : ℝ) (n : ℕ) :=
(n : ℝ) ^ s * n ! / ∏ j ∈ Finset.range (n + 1), (s + j)
/-- Euler's limit formula for the real Gamma function. -/
| Mathlib/Analysis/SpecialFunctions/Gamma/Beta.lean | 450 | 468 |
/-
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
instance : BoundedOrder SignType where
top := 1
le_top := LE.of_pos
bot := -1
bot_le :=
#adaptation_note /-- https://github.com/leanprover/lean4/pull/6053
Added `by exact`, but don't understand why it was needed. -/
by exact LE.of_neg
instance : HasDistribNeg SignType :=
{ neg_neg := fun x => by cases x <;> rfl
neg_mul := fun x y => by cases x <;> cases y <;> rfl
mul_neg := fun x y => by cases x <;> cases y <;> rfl }
/-- `SignType` is equivalent to `Fin 3`. -/
def fin3Equiv : SignType ≃* Fin 3 where
toFun a :=
match a with
| 0 => ⟨0, by simp⟩
| 1 => ⟨1, by simp⟩
| -1 => ⟨2, by simp⟩
invFun a :=
match a with
| ⟨0, _⟩ => 0
| ⟨1, _⟩ => 1
| ⟨2, _⟩ => -1
left_inv a := by cases a <;> rfl
right_inv a :=
match a with
| ⟨0, _⟩ => by simp
| ⟨1, _⟩ => by simp
| ⟨2, _⟩ => by simp
map_mul' a b := by
cases a <;> cases b <;> rfl
section CaseBashing
theorem nonneg_iff {a : SignType} : 0 ≤ a ↔ a = 0 ∨ a = 1 := by decide +revert
theorem nonneg_iff_ne_neg_one {a : SignType} : 0 ≤ a ↔ a ≠ -1 := by decide +revert
theorem neg_one_lt_iff {a : SignType} : -1 < a ↔ 0 ≤ a := by decide +revert
theorem nonpos_iff {a : SignType} : a ≤ 0 ↔ a = -1 ∨ a = 0 := by decide +revert
theorem nonpos_iff_ne_one {a : SignType} : a ≤ 0 ↔ a ≠ 1 := by decide +revert
theorem lt_one_iff {a : SignType} : a < 1 ↔ a ≤ 0 := by decide +revert
@[simp]
theorem neg_iff {a : SignType} : a < 0 ↔ a = -1 := by decide +revert
@[simp]
theorem le_neg_one_iff {a : SignType} : a ≤ -1 ↔ a = -1 :=
le_bot_iff
@[simp]
theorem pos_iff {a : SignType} : 0 < a ↔ a = 1 := by decide +revert
@[simp]
theorem one_le_iff {a : SignType} : 1 ≤ a ↔ a = 1 :=
top_le_iff
@[simp]
theorem neg_one_le (a : SignType) : -1 ≤ a :=
bot_le
@[simp]
theorem le_one (a : SignType) : a ≤ 1 :=
le_top
@[simp]
theorem not_lt_neg_one (a : SignType) : ¬a < -1 :=
not_lt_bot
@[simp]
theorem not_one_lt (a : SignType) : ¬1 < a :=
not_top_lt
@[simp]
theorem self_eq_neg_iff (a : SignType) : a = -a ↔ a = 0 := by decide +revert
@[simp]
theorem neg_eq_self_iff (a : SignType) : -a = a ↔ a = 0 := by decide +revert
@[simp]
theorem neg_one_lt_one : (-1 : SignType) < 1 :=
bot_lt_top
end CaseBashing
section cast
variable {α : Type*} [Zero α] [One α] [Neg α]
/-- Turn a `SignType` into zero, one, or minus one. This is a coercion instance. -/
@[coe]
def cast : SignType → α
| zero => 0
| pos => 1
| neg => -1
/-- This is a `CoeTail` since the type on the right (trivially) determines the type on the left.
`outParam`-wise it could be a `Coe`, but we don't want to try applying this instance for a
coercion to any `α`.
-/
instance : CoeTail SignType α :=
⟨cast⟩
/-- Casting out of `SignType` respects composition with functions preserving `0, 1, -1`. -/
lemma map_cast' {β : Type*} [One β] [Neg β] [Zero β]
(f : α → β) (h₁ : f 1 = 1) (h₂ : f 0 = 0) (h₃ : f (-1) = -1) (s : SignType) :
f s = s := by
cases s <;> simp only [SignType.cast, h₁, h₂, h₃]
/-- Casting out of `SignType` respects composition with suitable bundled homomorphism types. -/
lemma map_cast {α β F : Type*} [AddGroupWithOne α] [One β] [SubtractionMonoid β]
[FunLike F α β] [AddMonoidHomClass F α β] [OneHomClass F α β] (f : F) (s : SignType) :
f s = s := by
apply map_cast' <;> simp
@[simp]
theorem coe_zero : ↑(0 : SignType) = (0 : α) :=
rfl
@[simp]
theorem coe_one : ↑(1 : SignType) = (1 : α) :=
rfl
@[simp]
theorem coe_neg_one : ↑(-1 : SignType) = (-1 : α) :=
rfl
@[simp, norm_cast]
lemma coe_neg {α : Type*} [One α] [SubtractionMonoid α] (s : SignType) :
(↑(-s) : α) = -↑s := by
cases s <;> simp
/-- Casting `SignType → ℤ → α` is the same as casting directly `SignType → α`. -/
@[simp, norm_cast]
lemma intCast_cast {α : Type*} [AddGroupWithOne α] (s : SignType) : ((s : ℤ) : α) = s :=
map_cast' _ Int.cast_one Int.cast_zero (@Int.cast_one α _ ▸ Int.cast_neg 1) _
end cast
/-- `SignType.cast` as a `MulWithZeroHom`. -/
@[simps]
def castHom {α} [MulZeroOneClass α] [HasDistribNeg α] : SignType →*₀ α where
toFun := cast
map_zero' := rfl
map_one' := rfl
map_mul' x y := by cases x <;> cases y <;> simp [zero_eq_zero, pos_eq_one, neg_eq_neg_one]
theorem univ_eq : (Finset.univ : Finset SignType) = {0, -1, 1} := by
decide
theorem range_eq {α} (f : SignType → α) : Set.range f = {f zero, f neg, f pos} := by
classical rw [← Fintype.coe_image_univ, univ_eq]
classical simp [Finset.coe_insert]
@[simp, norm_cast] lemma coe_mul {α} [MulZeroOneClass α] [HasDistribNeg α] (a b : SignType) :
↑(a * b) = (a : α) * b :=
map_mul SignType.castHom _ _
@[simp, norm_cast] lemma coe_pow {α} [MonoidWithZero α] [HasDistribNeg α] (a : SignType) (k : ℕ) :
↑(a ^ k) = (a : α) ^ k :=
map_pow SignType.castHom _ _
@[simp, norm_cast] lemma coe_zpow {α} [GroupWithZero α] [HasDistribNeg α] (a : SignType) (k : ℤ) :
↑(a ^ k) = (a : α) ^ k :=
map_zpow₀ SignType.castHom _ _
end SignType
-- The lemma `exists_signed_sum` needs explicit universe handling in its statement.
universe u
variable {α : Type u}
open SignType
section Preorder
variable [Zero α] [Preorder α] [DecidableLT α] {a : α}
/-- The sign of an element is 1 if it's positive, -1 if negative, 0 otherwise. -/
def SignType.sign : α →o SignType :=
⟨fun a => if 0 < a then 1 else if a < 0 then -1 else 0, fun a b h => by
dsimp
split_ifs with h₁ h₂ h₃ h₄ _ _ h₂ h₃ <;> try constructor
· cases lt_irrefl 0 (h₁.trans <| h.trans_lt h₃)
· cases h₂ (h₁.trans_le h)
· cases h₄ (h.trans_lt h₃)⟩
theorem sign_apply : sign a = ite (0 < a) 1 (ite (a < 0) (-1) 0) :=
rfl
@[simp]
theorem sign_zero : sign (0 : α) = 0 := by simp [sign_apply]
@[simp]
theorem sign_pos (ha : 0 < a) : sign a = 1 := by rwa [sign_apply, if_pos]
@[simp]
theorem sign_neg (ha : a < 0) : sign a = -1 := by rwa [sign_apply, if_neg <| asymm ha, if_pos]
theorem sign_eq_one_iff : sign a = 1 ↔ 0 < a := by
refine ⟨fun h => ?_, fun h => sign_pos h⟩
by_contra hn
rw [sign_apply, if_neg hn] at h
split_ifs at h
theorem sign_eq_neg_one_iff : sign a = -1 ↔ a < 0 := by
refine ⟨fun h => ?_, fun h => sign_neg h⟩
rw [sign_apply] at h
split_ifs at h
assumption
end Preorder
section LinearOrder
variable [Zero α] [LinearOrder α] {a : α}
/-- `SignType.sign` respects strictly monotone zero-preserving maps. -/
lemma StrictMono.sign_comp {β F : Type*} [Zero β] [Preorder β] [DecidableLT β]
[FunLike F α β] [ZeroHomClass F α β] {f : F} (hf : StrictMono f) (a : α) :
sign (f a) = sign a := by
simp only [sign_apply, ← map_zero f, hf.lt_iff_lt]
@[simp]
theorem sign_eq_zero_iff : sign a = 0 ↔ a = 0 := by
refine ⟨fun h => ?_, fun h => h.symm ▸ sign_zero⟩
rw [sign_apply] at h
split_ifs at h with h_1 h_2
cases h
exact (le_of_not_lt h_1).eq_of_not_lt h_2
theorem sign_ne_zero : sign a ≠ 0 ↔ a ≠ 0 :=
sign_eq_zero_iff.not
@[simp]
theorem sign_nonneg_iff : 0 ≤ sign a ↔ 0 ≤ a := by
rcases lt_trichotomy 0 a with (h | h | h)
· simp [h, h.le]
· simp [← h]
· simp [h, h.not_le]
@[simp]
theorem sign_nonpos_iff : sign a ≤ 0 ↔ a ≤ 0 := by
rcases lt_trichotomy 0 a with (h | h | h)
· simp [h, h.not_le]
· simp [← h]
· simp [h, h.le]
end LinearOrder
section OrderedSemiring
variable [Semiring α] [PartialOrder α] [IsOrderedRing α] [DecidableLT α] [Nontrivial α]
theorem sign_one : sign (1 : α) = 1 :=
sign_pos zero_lt_one
end OrderedSemiring
section OrderedRing
@[simp]
lemma sign_intCast {α : Type*} [Ring α] [PartialOrder α] [IsOrderedRing α]
[Nontrivial α] [DecidableLT α] (n : ℤ) :
sign (n : α) = sign n := by
simp only [sign_apply, Int.cast_pos, Int.cast_lt_zero]
end OrderedRing
section LinearOrderedRing
variable [Ring α] [LinearOrder α] [IsStrictOrderedRing α]
theorem sign_mul (x y : α) : sign (x * y) = sign x * sign y := by
rcases lt_trichotomy x 0 with (hx | hx | hx) <;> rcases lt_trichotomy y 0 with (hy | hy | hy) <;>
simp [hx, hy, mul_pos_of_neg_of_neg, mul_neg_of_neg_of_pos, mul_neg_of_pos_of_neg]
@[simp] theorem sign_mul_abs (x : α) : (sign x * |x| : α) = x := by
rcases lt_trichotomy x 0 with hx | rfl | hx <;> simp [*, abs_of_pos, abs_of_neg]
@[simp] theorem abs_mul_sign (x : α) : (|x| * sign x : α) = x := by
rcases lt_trichotomy x 0 with hx | rfl | hx <;> simp [*, abs_of_pos, abs_of_neg]
@[simp]
theorem sign_mul_self (x : α) : sign x * x = |x| := by
rcases lt_trichotomy x 0 with hx | rfl | hx <;> simp [*, abs_of_pos, abs_of_neg]
@[simp]
theorem self_mul_sign (x : α) : x * sign x = |x| := by
rcases lt_trichotomy x 0 with hx | rfl | hx <;> simp [*, abs_of_pos, abs_of_neg]
/-- `SignType.sign` as a `MonoidWithZeroHom` for a nontrivial ordered semiring. Note that linearity
is required; consider ℂ with the order `z ≤ w` iff they have the same imaginary part and
`z - w ≤ 0` in the reals; then `1 + I` and `1 - I` are incomparable to zero, and thus we have:
`0 * 0 = SignType.sign (1 + I) * SignType.sign (1 - I) ≠ SignType.sign 2 = 1`.
(`Complex.orderedCommRing`) -/
def signHom : α →*₀ SignType where
toFun := sign
map_zero' := sign_zero
map_one' := sign_one
map_mul' := sign_mul
theorem sign_pow (x : α) (n : ℕ) : sign (x ^ n) = sign x ^ n := map_pow signHom x n
end LinearOrderedRing
section AddGroup
variable [AddGroup α] [Preorder α] [DecidableLT α]
theorem Left.sign_neg [AddLeftStrictMono α] (a : α) : sign (-a) = -sign a := by
simp_rw [sign_apply, Left.neg_pos_iff, Left.neg_neg_iff]
split_ifs with h h'
· exact False.elim (lt_asymm h h')
· simp
· simp
· simp
theorem Right.sign_neg [AddRightStrictMono α] (a : α) :
sign (-a) = -sign a := by
simp_rw [sign_apply, Right.neg_pos_iff, Right.neg_neg_iff]
split_ifs with h h'
· exact False.elim (lt_asymm h h')
· simp
· simp
· simp
end AddGroup
section LinearOrderedAddCommGroup
|
variable [AddCommGroup α] [LinearOrder α] [IsOrderedAddMonoid α]
| Mathlib/Data/Sign.lean | 451 | 452 |
/-
Copyright (c) 2014 Parikshit Khanna. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Parikshit Khanna, Jeremy Avigad, Leonardo de Moura, Floris van Doorn, Mario Carneiro
-/
import Mathlib.Control.Basic
import Mathlib.Data.Nat.Basic
import Mathlib.Data.Option.Basic
import Mathlib.Data.List.Defs
import Mathlib.Data.List.Monad
import Mathlib.Logic.OpClass
import Mathlib.Logic.Unique
import Mathlib.Order.Basic
import Mathlib.Tactic.Common
/-!
# Basic properties of lists
-/
assert_not_exists GroupWithZero
assert_not_exists Lattice
assert_not_exists Prod.swap_eq_iff_eq_swap
assert_not_exists Ring
assert_not_exists Set.range
open Function
open Nat hiding one_pos
namespace List
universe u v w
variable {ι : Type*} {α : Type u} {β : Type v} {γ : Type w} {l₁ l₂ : List α}
/-- There is only one list of an empty type -/
instance uniqueOfIsEmpty [IsEmpty α] : Unique (List α) :=
{ instInhabitedList with
uniq := fun l =>
match l with
| [] => rfl
| a :: _ => isEmptyElim a }
instance : Std.LawfulIdentity (α := List α) Append.append [] where
left_id := nil_append
right_id := append_nil
instance : Std.Associative (α := List α) Append.append where
assoc := append_assoc
@[simp] theorem cons_injective {a : α} : Injective (cons a) := fun _ _ => tail_eq_of_cons_eq
theorem singleton_injective : Injective fun a : α => [a] := fun _ _ h => (cons_eq_cons.1 h).1
theorem set_of_mem_cons (l : List α) (a : α) : { x | x ∈ a :: l } = insert a { x | x ∈ l } :=
Set.ext fun _ => mem_cons
/-! ### mem -/
theorem _root_.Decidable.List.eq_or_ne_mem_of_mem [DecidableEq α]
{a b : α} {l : List α} (h : a ∈ b :: l) : a = b ∨ a ≠ b ∧ a ∈ l := by
by_cases hab : a = b
· exact Or.inl hab
· exact ((List.mem_cons.1 h).elim Or.inl (fun h => Or.inr ⟨hab, h⟩))
lemma mem_pair {a b c : α} : a ∈ [b, c] ↔ a = b ∨ a = c := by
rw [mem_cons, mem_singleton]
-- The simpNF linter says that the LHS can be simplified via `List.mem_map`.
-- However this is a higher priority lemma.
-- It seems the side condition `hf` is not applied by `simpNF`.
-- https://github.com/leanprover/std4/issues/207
@[simp 1100, nolint simpNF]
theorem mem_map_of_injective {f : α → β} (H : Injective f) {a : α} {l : List α} :
f a ∈ map f l ↔ a ∈ l :=
⟨fun m => let ⟨_, m', e⟩ := exists_of_mem_map m; H e ▸ m', mem_map_of_mem⟩
@[simp]
theorem _root_.Function.Involutive.exists_mem_and_apply_eq_iff {f : α → α}
(hf : Function.Involutive f) (x : α) (l : List α) : (∃ y : α, y ∈ l ∧ f y = x) ↔ f x ∈ l :=
⟨by rintro ⟨y, h, rfl⟩; rwa [hf y], fun h => ⟨f x, h, hf _⟩⟩
theorem mem_map_of_involutive {f : α → α} (hf : Involutive f) {a : α} {l : List α} :
a ∈ map f l ↔ f a ∈ l := by rw [mem_map, hf.exists_mem_and_apply_eq_iff]
/-! ### length -/
alias ⟨_, length_pos_of_ne_nil⟩ := length_pos_iff
theorem length_pos_iff_ne_nil {l : List α} : 0 < length l ↔ l ≠ [] :=
⟨ne_nil_of_length_pos, length_pos_of_ne_nil⟩
theorem exists_of_length_succ {n} : ∀ l : List α, l.length = n + 1 → ∃ h t, l = h :: t
| [], H => absurd H.symm <| succ_ne_zero n
| h :: t, _ => ⟨h, t, rfl⟩
@[simp] lemma length_injective_iff : Injective (List.length : List α → ℕ) ↔ Subsingleton α := by
constructor
· intro h; refine ⟨fun x y => ?_⟩; (suffices [x] = [y] by simpa using this); apply h; rfl
· intros hα l1 l2 hl
induction l1 generalizing l2 <;> cases l2
· rfl
· cases hl
· cases hl
· next ih _ _ =>
congr
· subsingleton
· apply ih; simpa using hl
@[simp default+1] -- Raise priority above `length_injective_iff`.
lemma length_injective [Subsingleton α] : Injective (length : List α → ℕ) :=
length_injective_iff.mpr inferInstance
theorem length_eq_two {l : List α} : l.length = 2 ↔ ∃ a b, l = [a, b] :=
⟨fun _ => let [a, b] := l; ⟨a, b, rfl⟩, fun ⟨_, _, e⟩ => e ▸ rfl⟩
theorem length_eq_three {l : List α} : l.length = 3 ↔ ∃ a b c, l = [a, b, c] :=
⟨fun _ => let [a, b, c] := l; ⟨a, b, c, rfl⟩, fun ⟨_, _, _, e⟩ => e ▸ rfl⟩
/-! ### set-theoretic notation of lists -/
instance instSingletonList : Singleton α (List α) := ⟨fun x => [x]⟩
instance [DecidableEq α] : Insert α (List α) := ⟨List.insert⟩
instance [DecidableEq α] : LawfulSingleton α (List α) :=
{ insert_empty_eq := fun x =>
show (if x ∈ ([] : List α) then [] else [x]) = [x] from if_neg not_mem_nil }
theorem singleton_eq (x : α) : ({x} : List α) = [x] :=
rfl
theorem insert_neg [DecidableEq α] {x : α} {l : List α} (h : x ∉ l) :
Insert.insert x l = x :: l :=
insert_of_not_mem h
theorem insert_pos [DecidableEq α] {x : α} {l : List α} (h : x ∈ l) : Insert.insert x l = l :=
insert_of_mem h
theorem doubleton_eq [DecidableEq α] {x y : α} (h : x ≠ y) : ({x, y} : List α) = [x, y] := by
rw [insert_neg, singleton_eq]
rwa [singleton_eq, mem_singleton]
/-! ### bounded quantifiers over lists -/
theorem forall_mem_of_forall_mem_cons {p : α → Prop} {a : α} {l : List α} (h : ∀ x ∈ a :: l, p x) :
∀ x ∈ l, p x := (forall_mem_cons.1 h).2
theorem exists_mem_cons_of {p : α → Prop} {a : α} (l : List α) (h : p a) : ∃ x ∈ a :: l, p x :=
⟨a, mem_cons_self, h⟩
theorem exists_mem_cons_of_exists {p : α → Prop} {a : α} {l : List α} : (∃ x ∈ l, p x) →
∃ x ∈ a :: l, p x :=
fun ⟨x, xl, px⟩ => ⟨x, mem_cons_of_mem _ xl, px⟩
theorem or_exists_of_exists_mem_cons {p : α → Prop} {a : α} {l : List α} : (∃ x ∈ a :: l, p x) →
p a ∨ ∃ x ∈ l, p x :=
fun ⟨x, xal, px⟩ =>
Or.elim (eq_or_mem_of_mem_cons xal) (fun h : x = a => by rw [← h]; left; exact px)
fun h : x ∈ l => Or.inr ⟨x, h, px⟩
theorem exists_mem_cons_iff (p : α → Prop) (a : α) (l : List α) :
(∃ x ∈ a :: l, p x) ↔ p a ∨ ∃ x ∈ l, p x :=
Iff.intro or_exists_of_exists_mem_cons fun h =>
Or.elim h (exists_mem_cons_of l) exists_mem_cons_of_exists
/-! ### list subset -/
theorem cons_subset_of_subset_of_mem {a : α} {l m : List α}
(ainm : a ∈ m) (lsubm : l ⊆ m) : a::l ⊆ m :=
cons_subset.2 ⟨ainm, lsubm⟩
theorem append_subset_of_subset_of_subset {l₁ l₂ l : List α} (l₁subl : l₁ ⊆ l) (l₂subl : l₂ ⊆ l) :
l₁ ++ l₂ ⊆ l :=
fun _ h ↦ (mem_append.1 h).elim (@l₁subl _) (@l₂subl _)
theorem map_subset_iff {l₁ l₂ : List α} (f : α → β) (h : Injective f) :
map f l₁ ⊆ map f l₂ ↔ l₁ ⊆ l₂ := by
refine ⟨?_, map_subset f⟩; intro h2 x hx
rcases mem_map.1 (h2 (mem_map_of_mem hx)) with ⟨x', hx', hxx'⟩
cases h hxx'; exact hx'
/-! ### append -/
theorem append_eq_has_append {L₁ L₂ : List α} : List.append L₁ L₂ = L₁ ++ L₂ :=
rfl
theorem append_right_injective (s : List α) : Injective fun t ↦ s ++ t :=
fun _ _ ↦ append_cancel_left
theorem append_left_injective (t : List α) : Injective fun s ↦ s ++ t :=
fun _ _ ↦ append_cancel_right
/-! ### replicate -/
theorem eq_replicate_length {a : α} : ∀ {l : List α}, l = replicate l.length a ↔ ∀ b ∈ l, b = a
| [] => by simp
| (b :: l) => by simp [eq_replicate_length, replicate_succ]
theorem replicate_add (m n) (a : α) : replicate (m + n) a = replicate m a ++ replicate n a := by
rw [replicate_append_replicate]
theorem replicate_subset_singleton (n) (a : α) : replicate n a ⊆ [a] := fun _ h =>
mem_singleton.2 (eq_of_mem_replicate h)
theorem subset_singleton_iff {a : α} {L : List α} : L ⊆ [a] ↔ ∃ n, L = replicate n a := by
simp only [eq_replicate_iff, subset_def, mem_singleton, exists_eq_left']
theorem replicate_right_injective {n : ℕ} (hn : n ≠ 0) : Injective (@replicate α n) :=
fun _ _ h => (eq_replicate_iff.1 h).2 _ <| mem_replicate.2 ⟨hn, rfl⟩
theorem replicate_right_inj {a b : α} {n : ℕ} (hn : n ≠ 0) :
replicate n a = replicate n b ↔ a = b :=
(replicate_right_injective hn).eq_iff
theorem replicate_right_inj' {a b : α} : ∀ {n},
replicate n a = replicate n b ↔ n = 0 ∨ a = b
| 0 => by simp
| n + 1 => (replicate_right_inj n.succ_ne_zero).trans <| by simp only [n.succ_ne_zero, false_or]
theorem replicate_left_injective (a : α) : Injective (replicate · a) :=
LeftInverse.injective (length_replicate (n := ·))
theorem replicate_left_inj {a : α} {n m : ℕ} : replicate n a = replicate m a ↔ n = m :=
(replicate_left_injective a).eq_iff
@[simp]
theorem head?_flatten_replicate {n : ℕ} (h : n ≠ 0) (l : List α) :
(List.replicate n l).flatten.head? = l.head? := by
obtain ⟨n, rfl⟩ := Nat.exists_eq_succ_of_ne_zero h
induction l <;> simp [replicate]
@[simp]
theorem getLast?_flatten_replicate {n : ℕ} (h : n ≠ 0) (l : List α) :
(List.replicate n l).flatten.getLast? = l.getLast? := by
rw [← List.head?_reverse, ← List.head?_reverse, List.reverse_flatten, List.map_replicate,
List.reverse_replicate, head?_flatten_replicate h]
/-! ### pure -/
theorem mem_pure (x y : α) : x ∈ (pure y : List α) ↔ x = y := by simp
/-! ### bind -/
@[simp]
theorem bind_eq_flatMap {α β} (f : α → List β) (l : List α) : l >>= f = l.flatMap f :=
rfl
/-! ### concat -/
/-! ### reverse -/
theorem reverse_cons' (a : α) (l : List α) : reverse (a :: l) = concat (reverse l) a := by
simp only [reverse_cons, concat_eq_append]
theorem reverse_concat' (l : List α) (a : α) : (l ++ [a]).reverse = a :: l.reverse := by
rw [reverse_append]; rfl
@[simp]
theorem reverse_singleton (a : α) : reverse [a] = [a] :=
rfl
@[simp]
theorem reverse_involutive : Involutive (@reverse α) :=
reverse_reverse
@[simp]
theorem reverse_injective : Injective (@reverse α) :=
reverse_involutive.injective
theorem reverse_surjective : Surjective (@reverse α) :=
reverse_involutive.surjective
theorem reverse_bijective : Bijective (@reverse α) :=
reverse_involutive.bijective
theorem concat_eq_reverse_cons (a : α) (l : List α) : concat l a = reverse (a :: reverse l) := by
simp only [concat_eq_append, reverse_cons, reverse_reverse]
theorem map_reverseAux (f : α → β) (l₁ l₂ : List α) :
map f (reverseAux l₁ l₂) = reverseAux (map f l₁) (map f l₂) := by
simp only [reverseAux_eq, map_append, map_reverse]
-- TODO: Rename `List.reverse_perm` to `List.reverse_perm_self`
@[simp] lemma reverse_perm' : l₁.reverse ~ l₂ ↔ l₁ ~ l₂ where
mp := l₁.reverse_perm.symm.trans
mpr := l₁.reverse_perm.trans
@[simp] lemma perm_reverse : l₁ ~ l₂.reverse ↔ l₁ ~ l₂ where
mp hl := hl.trans l₂.reverse_perm
mpr hl := hl.trans l₂.reverse_perm.symm
/-! ### getLast -/
attribute [simp] getLast_cons
theorem getLast_append_singleton {a : α} (l : List α) :
getLast (l ++ [a]) (append_ne_nil_of_right_ne_nil l (cons_ne_nil a _)) = a := by
simp [getLast_append]
theorem getLast_append_of_right_ne_nil (l₁ l₂ : List α) (h : l₂ ≠ []) :
getLast (l₁ ++ l₂) (append_ne_nil_of_right_ne_nil l₁ h) = getLast l₂ h := by
induction l₁ with
| nil => simp
| cons _ _ ih => simp only [cons_append]; rw [List.getLast_cons]; exact ih
@[deprecated (since := "2025-02-06")]
alias getLast_append' := getLast_append_of_right_ne_nil
theorem getLast_concat' {a : α} (l : List α) : getLast (concat l a) (by simp) = a := by
simp
@[simp]
theorem getLast_singleton' (a : α) : getLast [a] (cons_ne_nil a []) = a := rfl
@[simp]
theorem getLast_cons_cons (a₁ a₂ : α) (l : List α) :
getLast (a₁ :: a₂ :: l) (cons_ne_nil _ _) = getLast (a₂ :: l) (cons_ne_nil a₂ l) :=
rfl
theorem dropLast_append_getLast : ∀ {l : List α} (h : l ≠ []), dropLast l ++ [getLast l h] = l
| [], h => absurd rfl h
| [_], _ => rfl
| a :: b :: l, h => by
rw [dropLast_cons₂, cons_append, getLast_cons (cons_ne_nil _ _)]
congr
exact dropLast_append_getLast (cons_ne_nil b l)
theorem getLast_congr {l₁ l₂ : List α} (h₁ : l₁ ≠ []) (h₂ : l₂ ≠ []) (h₃ : l₁ = l₂) :
getLast l₁ h₁ = getLast l₂ h₂ := by subst l₁; rfl
theorem getLast_replicate_succ (m : ℕ) (a : α) :
(replicate (m + 1) a).getLast (ne_nil_of_length_eq_add_one length_replicate) = a := by
simp only [replicate_succ']
exact getLast_append_singleton _
@[deprecated (since := "2025-02-07")]
alias getLast_filter' := getLast_filter_of_pos
/-! ### getLast? -/
theorem mem_getLast?_eq_getLast : ∀ {l : List α} {x : α}, x ∈ l.getLast? → ∃ h, x = getLast l h
| [], x, hx => False.elim <| by simp at hx
| [a], x, hx =>
have : a = x := by simpa using hx
this ▸ ⟨cons_ne_nil a [], rfl⟩
| a :: b :: l, x, hx => by
rw [getLast?_cons_cons] at hx
rcases mem_getLast?_eq_getLast hx with ⟨_, h₂⟩
use cons_ne_nil _ _
assumption
theorem getLast?_eq_getLast_of_ne_nil : ∀ {l : List α} (h : l ≠ []), l.getLast? = some (l.getLast h)
| [], h => (h rfl).elim
| [_], _ => rfl
| _ :: b :: l, _ => @getLast?_eq_getLast_of_ne_nil (b :: l) (cons_ne_nil _ _)
theorem mem_getLast?_cons {x y : α} : ∀ {l : List α}, x ∈ l.getLast? → x ∈ (y :: l).getLast?
| [], _ => by contradiction
| _ :: _, h => h
theorem dropLast_append_getLast? : ∀ {l : List α}, ∀ a ∈ l.getLast?, dropLast l ++ [a] = l
| [], a, ha => (Option.not_mem_none a ha).elim
| [a], _, rfl => rfl
| a :: b :: l, c, hc => by
rw [getLast?_cons_cons] at hc
rw [dropLast_cons₂, cons_append, dropLast_append_getLast? _ hc]
theorem getLastI_eq_getLast? [Inhabited α] : ∀ l : List α, l.getLastI = l.getLast?.iget
| [] => by simp [getLastI, Inhabited.default]
| [_] => rfl
| [_, _] => rfl
| [_, _, _] => rfl
| _ :: _ :: c :: l => by simp [getLastI, getLastI_eq_getLast? (c :: l)]
theorem getLast?_append_cons :
∀ (l₁ : List α) (a : α) (l₂ : List α), getLast? (l₁ ++ a :: l₂) = getLast? (a :: l₂)
| [], _, _ => rfl
| [_], _, _ => rfl
| b :: c :: l₁, a, l₂ => by rw [cons_append, cons_append, getLast?_cons_cons,
← cons_append, getLast?_append_cons (c :: l₁)]
theorem getLast?_append_of_ne_nil (l₁ : List α) :
∀ {l₂ : List α} (_ : l₂ ≠ []), getLast? (l₁ ++ l₂) = getLast? l₂
| [], hl₂ => by contradiction
| b :: l₂, _ => getLast?_append_cons l₁ b l₂
theorem mem_getLast?_append_of_mem_getLast? {l₁ l₂ : List α} {x : α} (h : x ∈ l₂.getLast?) :
x ∈ (l₁ ++ l₂).getLast? := by
cases l₂
· contradiction
· rw [List.getLast?_append_cons]
exact h
/-! ### head(!?) and tail -/
@[simp]
theorem head!_nil [Inhabited α] : ([] : List α).head! = default := rfl
@[simp] theorem head_cons_tail (x : List α) (h : x ≠ []) : x.head h :: x.tail = x := by
cases x <;> simp at h ⊢
theorem head_eq_getElem_zero {l : List α} (hl : l ≠ []) :
l.head hl = l[0]'(length_pos_iff.2 hl) :=
(getElem_zero _).symm
theorem head!_eq_head? [Inhabited α] (l : List α) : head! l = (head? l).iget := by cases l <;> rfl
theorem surjective_head! [Inhabited α] : Surjective (@head! α _) := fun x => ⟨[x], rfl⟩
theorem surjective_head? : Surjective (@head? α) :=
Option.forall.2 ⟨⟨[], rfl⟩, fun x => ⟨[x], rfl⟩⟩
theorem surjective_tail : Surjective (@tail α)
| [] => ⟨[], rfl⟩
| a :: l => ⟨a :: a :: l, rfl⟩
theorem eq_cons_of_mem_head? {x : α} : ∀ {l : List α}, x ∈ l.head? → l = x :: tail l
| [], h => (Option.not_mem_none _ h).elim
| a :: l, h => by
simp only [head?, Option.mem_def, Option.some_inj] at h
exact h ▸ rfl
@[simp] theorem head!_cons [Inhabited α] (a : α) (l : List α) : head! (a :: l) = a := rfl
@[simp]
theorem head!_append [Inhabited α] (t : List α) {s : List α} (h : s ≠ []) :
head! (s ++ t) = head! s := by
induction s
· contradiction
· rfl
theorem mem_head?_append_of_mem_head? {s t : List α} {x : α} (h : x ∈ s.head?) :
x ∈ (s ++ t).head? := by
cases s
· contradiction
· exact h
theorem head?_append_of_ne_nil :
∀ (l₁ : List α) {l₂ : List α} (_ : l₁ ≠ []), head? (l₁ ++ l₂) = head? l₁
| _ :: _, _, _ => rfl
theorem tail_append_singleton_of_ne_nil {a : α} {l : List α} (h : l ≠ nil) :
tail (l ++ [a]) = tail l ++ [a] := by
induction l
· contradiction
· rw [tail, cons_append, tail]
theorem cons_head?_tail : ∀ {l : List α} {a : α}, a ∈ head? l → a :: tail l = l
| [], a, h => by contradiction
| b :: l, a, h => by
simp? at h says simp only [head?_cons, Option.mem_def, Option.some.injEq] at h
simp [h]
theorem head!_mem_head? [Inhabited α] : ∀ {l : List α}, l ≠ [] → head! l ∈ head? l
| [], h => by contradiction
| _ :: _, _ => rfl
theorem cons_head!_tail [Inhabited α] {l : List α} (h : l ≠ []) : head! l :: tail l = l :=
cons_head?_tail (head!_mem_head? h)
theorem head!_mem_self [Inhabited α] {l : List α} (h : l ≠ nil) : l.head! ∈ l := by
have h' : l.head! ∈ l.head! :: l.tail := mem_cons_self
rwa [cons_head!_tail h] at h'
theorem get_eq_getElem? (l : List α) (i : Fin l.length) :
l.get i = l[i]?.get (by simp [getElem?_eq_getElem]) := by
simp
@[deprecated (since := "2025-02-15")] alias get_eq_get? := get_eq_getElem?
theorem exists_mem_iff_getElem {l : List α} {p : α → Prop} :
(∃ x ∈ l, p x) ↔ ∃ (i : ℕ) (_ : i < l.length), p l[i] := by
simp only [mem_iff_getElem]
exact ⟨fun ⟨_x, ⟨i, hi, hix⟩, hxp⟩ ↦ ⟨i, hi, hix ▸ hxp⟩, fun ⟨i, hi, hp⟩ ↦ ⟨_, ⟨i, hi, rfl⟩, hp⟩⟩
theorem forall_mem_iff_getElem {l : List α} {p : α → Prop} :
(∀ x ∈ l, p x) ↔ ∀ (i : ℕ) (_ : i < l.length), p l[i] := by
simp [mem_iff_getElem, @forall_swap α]
theorem get_tail (l : List α) (i) (h : i < l.tail.length)
(h' : i + 1 < l.length := (by simp only [length_tail] at h; omega)) :
l.tail.get ⟨i, h⟩ = l.get ⟨i + 1, h'⟩ := by
cases l <;> [cases h; rfl]
/-! ### sublists -/
attribute [refl] List.Sublist.refl
theorem Sublist.cons_cons {l₁ l₂ : List α} (a : α) (s : l₁ <+ l₂) : a :: l₁ <+ a :: l₂ :=
Sublist.cons₂ _ s
lemma cons_sublist_cons' {a b : α} : a :: l₁ <+ b :: l₂ ↔ a :: l₁ <+ l₂ ∨ a = b ∧ l₁ <+ l₂ := by
constructor
· rintro (_ | _)
· exact Or.inl ‹_›
· exact Or.inr ⟨rfl, ‹_›⟩
· rintro (h | ⟨rfl, h⟩)
· exact h.cons _
· rwa [cons_sublist_cons]
theorem sublist_cons_of_sublist (a : α) (h : l₁ <+ l₂) : l₁ <+ a :: l₂ := h.cons _
@[deprecated (since := "2025-02-07")]
alias sublist_nil_iff_eq_nil := sublist_nil
@[simp] lemma sublist_singleton {l : List α} {a : α} : l <+ [a] ↔ l = [] ∨ l = [a] := by
constructor <;> rintro (_ | _) <;> aesop
theorem Sublist.antisymm (s₁ : l₁ <+ l₂) (s₂ : l₂ <+ l₁) : l₁ = l₂ :=
s₁.eq_of_length_le s₂.length_le
/-- If the first element of two lists are different, then a sublist relation can be reduced. -/
theorem Sublist.of_cons_of_ne {a b} (h₁ : a ≠ b) (h₂ : a :: l₁ <+ b :: l₂) : a :: l₁ <+ l₂ :=
match h₁, h₂ with
| _, .cons _ h => h
/-! ### indexOf -/
section IndexOf
variable [DecidableEq α]
theorem idxOf_cons_eq {a b : α} (l : List α) : b = a → idxOf a (b :: l) = 0
| e => by rw [← e]; exact idxOf_cons_self
@[deprecated (since := "2025-01-30")] alias indexOf_cons_eq := idxOf_cons_eq
@[simp]
theorem idxOf_cons_ne {a b : α} (l : List α) : b ≠ a → idxOf a (b :: l) = succ (idxOf a l)
| h => by simp only [idxOf_cons, Bool.cond_eq_ite, beq_iff_eq, if_neg h]
@[deprecated (since := "2025-01-30")] alias indexOf_cons_ne := idxOf_cons_ne
theorem idxOf_eq_length_iff {a : α} {l : List α} : idxOf a l = length l ↔ a ∉ l := by
induction l with
| nil => exact iff_of_true rfl not_mem_nil
| cons b l ih =>
simp only [length, mem_cons, idxOf_cons, eq_comm]
rw [cond_eq_if]
split_ifs with h <;> simp at h
· exact iff_of_false (by rintro ⟨⟩) fun H => H <| Or.inl h.symm
· simp only [Ne.symm h, false_or]
rw [← ih]
exact succ_inj
@[simp]
theorem idxOf_of_not_mem {l : List α} {a : α} : a ∉ l → idxOf a l = length l :=
idxOf_eq_length_iff.2
@[deprecated (since := "2025-01-30")] alias indexOf_of_not_mem := idxOf_of_not_mem
theorem idxOf_le_length {a : α} {l : List α} : idxOf a l ≤ length l := by
induction l with | nil => rfl | cons b l ih => ?_
simp only [length, idxOf_cons, cond_eq_if, beq_iff_eq]
by_cases h : b = a
· rw [if_pos h]; exact Nat.zero_le _
· rw [if_neg h]; exact succ_le_succ ih
@[deprecated (since := "2025-01-30")] alias indexOf_le_length := idxOf_le_length
theorem idxOf_lt_length_iff {a} {l : List α} : idxOf a l < length l ↔ a ∈ l :=
⟨fun h => Decidable.byContradiction fun al => Nat.ne_of_lt h <| idxOf_eq_length_iff.2 al,
fun al => (lt_of_le_of_ne idxOf_le_length) fun h => idxOf_eq_length_iff.1 h al⟩
@[deprecated (since := "2025-01-30")] alias indexOf_lt_length_iff := idxOf_lt_length_iff
theorem idxOf_append_of_mem {a : α} (h : a ∈ l₁) : idxOf a (l₁ ++ l₂) = idxOf a l₁ := by
induction l₁ with
| nil =>
exfalso
exact not_mem_nil h
| cons d₁ t₁ ih =>
rw [List.cons_append]
by_cases hh : d₁ = a
· iterate 2 rw [idxOf_cons_eq _ hh]
rw [idxOf_cons_ne _ hh, idxOf_cons_ne _ hh, ih (mem_of_ne_of_mem (Ne.symm hh) h)]
@[deprecated (since := "2025-01-30")] alias indexOf_append_of_mem := idxOf_append_of_mem
theorem idxOf_append_of_not_mem {a : α} (h : a ∉ l₁) :
idxOf a (l₁ ++ l₂) = l₁.length + idxOf a l₂ := by
induction l₁ with
| nil => rw [List.nil_append, List.length, Nat.zero_add]
| cons d₁ t₁ ih =>
rw [List.cons_append, idxOf_cons_ne _ (ne_of_not_mem_cons h).symm, List.length,
ih (not_mem_of_not_mem_cons h), Nat.succ_add]
@[deprecated (since := "2025-01-30")] alias indexOf_append_of_not_mem := idxOf_append_of_not_mem
end IndexOf
/-! ### nth element -/
section deprecated
@[simp]
theorem getElem?_length (l : List α) : l[l.length]? = none := getElem?_eq_none le_rfl
/-- A version of `getElem_map` that can be used for rewriting. -/
theorem getElem_map_rev (f : α → β) {l} {n : Nat} {h : n < l.length} :
f l[n] = (map f l)[n]'((l.length_map f).symm ▸ h) := Eq.symm (getElem_map _)
theorem get_length_sub_one {l : List α} (h : l.length - 1 < l.length) :
l.get ⟨l.length - 1, h⟩ = l.getLast (by rintro rfl; exact Nat.lt_irrefl 0 h) :=
(getLast_eq_getElem _).symm
theorem take_one_drop_eq_of_lt_length {l : List α} {n : ℕ} (h : n < l.length) :
(l.drop n).take 1 = [l.get ⟨n, h⟩] := by
rw [drop_eq_getElem_cons h, take, take]
simp
theorem ext_getElem?' {l₁ l₂ : List α} (h' : ∀ n < max l₁.length l₂.length, l₁[n]? = l₂[n]?) :
l₁ = l₂ := by
apply ext_getElem?
intro n
rcases Nat.lt_or_ge n <| max l₁.length l₂.length with hn | hn
· exact h' n hn
· simp_all [Nat.max_le, getElem?_eq_none]
@[deprecated (since := "2025-02-15")] alias ext_get?' := ext_getElem?'
@[deprecated (since := "2025-02-15")] alias ext_get?_iff := List.ext_getElem?_iff
theorem ext_get_iff {l₁ l₂ : List α} :
l₁ = l₂ ↔ l₁.length = l₂.length ∧ ∀ n h₁ h₂, get l₁ ⟨n, h₁⟩ = get l₂ ⟨n, h₂⟩ := by
constructor
· rintro rfl
exact ⟨rfl, fun _ _ _ ↦ rfl⟩
· intro ⟨h₁, h₂⟩
exact ext_get h₁ h₂
theorem ext_getElem?_iff' {l₁ l₂ : List α} : l₁ = l₂ ↔
∀ n < max l₁.length l₂.length, l₁[n]? = l₂[n]? :=
⟨by rintro rfl _ _; rfl, ext_getElem?'⟩
@[deprecated (since := "2025-02-15")] alias ext_get?_iff' := ext_getElem?_iff'
/-- If two lists `l₁` and `l₂` are the same length and `l₁[n]! = l₂[n]!` for all `n`,
then the lists are equal. -/
| theorem ext_getElem! [Inhabited α] (hl : length l₁ = length l₂) (h : ∀ n : ℕ, l₁[n]! = l₂[n]!) :
l₁ = l₂ :=
| Mathlib/Data/List/Basic.lean | 641 | 642 |
/-
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.ExactSequence
import Mathlib.Algebra.Homology.ShortComplex.Limits
import Mathlib.CategoryTheory.Abelian.Refinements
/-!
# The snake lemma
The snake lemma is a standard tool in homological algebra. The basic situation
is when we have a diagram as follows in an abelian category `C`, with exact rows:
L₁.X₁ ⟶ L₁.X₂ ⟶ L₁.X₃ ⟶ 0
| | |
|v₁₂.τ₁ |v₁₂.τ₂ |v₁₂.τ₃
v v v
0 ⟶ L₂.X₁ ⟶ L₂.X₂ ⟶ L₂.X₃
We shall think of this diagram as the datum of a morphism `v₁₂ : L₁ ⟶ L₂` in the
category `ShortComplex C` such that both `L₁` and `L₂` are exact, and `L₁.g` is epi
and `L₂.f` is a mono (which is equivalent to saying that `L₁.X₃` is the cokernel
of `L₁.f` and `L₂.X₁` is the kernel of `L₂.g`). Then, we may introduce the kernels
and cokernels of the vertical maps. In other words, we may introduce short complexes
`L₀` and `L₃` that are respectively the kernel and the cokernel of `v₁₂`. All these
data constitute a `SnakeInput C`.
Given such a `S : SnakeInput C`, we define a connecting homomorphism
`S.δ : L₀.X₃ ⟶ L₃.X₁` and show that it is part of an exact sequence
`L₀.X₁ ⟶ L₀.X₂ ⟶ L₀.X₃ ⟶ L₃.X₁ ⟶ L₃.X₂ ⟶ L₃.X₃`. Each of the four exactness
statement is first stated separately as lemmas `L₀_exact`, `L₁'_exact`,
`L₂'_exact` and `L₃_exact` and the full 6-term exact sequence is stated
as `snake_lemma`. This sequence can even be extended with an extra `0`
on the left (see `mono_L₀_f`) if `L₁.X₁ ⟶ L₁.X₂` is a mono (i.e. `L₁` is short exact),
and similarly an extra `0` can be added on the right (`epi_L₃_g`)
if `L₂.X₂ ⟶ L₂.X₃` is an epi (i.e. `L₂` is short exact).
These results were also obtained in the Liquid Tensor Experiment. The code and the proof
here are slightly easier because of the use of the category `ShortComplex C`,
the use of duality (which allows to construct only half of the sequence, and deducing
the other half by arguing in the opposite category), and the use of "refinements"
(see `CategoryTheory.Abelian.Refinements`) instead of a weak form of pseudo-elements.
-/
namespace CategoryTheory
open Category Limits Preadditive
variable (C : Type*) [Category C] [Abelian C]
namespace ShortComplex
/-- A snake input in an abelian category `C` consists of morphisms
of short complexes `L₀ ⟶ L₁ ⟶ L₂ ⟶ L₃` (which should be visualized vertically) such
that `L₀` and `L₃` are respectively the kernel and the cokernel of `L₁ ⟶ L₂`,
`L₁` and `L₂` are exact, `L₁.g` is epi and `L₂.f` is mono. -/
structure SnakeInput where
/-- the zeroth row -/
L₀ : ShortComplex C
/-- the first row -/
L₁ : ShortComplex C
/-- the second row -/
L₂ : ShortComplex C
/-- the third row -/
L₃ : ShortComplex C
/-- the morphism from the zeroth row to the first row -/
v₀₁ : L₀ ⟶ L₁
/-- the morphism from the first row to the second row -/
v₁₂ : L₁ ⟶ L₂
/-- the morphism from the second row to the third row -/
v₂₃ : L₂ ⟶ L₃
w₀₂ : v₀₁ ≫ v₁₂ = 0 := by aesop_cat
w₁₃ : v₁₂ ≫ v₂₃ = 0 := by aesop_cat
/-- `L₀` is the kernel of `v₁₂ : L₁ ⟶ L₂`. -/
h₀ : IsLimit (KernelFork.ofι _ w₀₂)
/-- `L₃` is the cokernel of `v₁₂ : L₁ ⟶ L₂`. -/
h₃ : IsColimit (CokernelCofork.ofπ _ w₁₃)
L₁_exact : L₁.Exact
epi_L₁_g : Epi L₁.g
L₂_exact : L₂.Exact
mono_L₂_f : Mono L₂.f
initialize_simps_projections SnakeInput (-h₀, -h₃)
namespace SnakeInput
attribute [reassoc (attr := simp)] w₀₂ w₁₃
attribute [instance] epi_L₁_g
attribute [instance] mono_L₂_f
variable {C}
variable (S : SnakeInput C)
/-- The snake input in the opposite category that is deduced from a snake input. -/
@[simps]
noncomputable def op : SnakeInput Cᵒᵖ where
L₀ := S.L₃.op
L₁ := S.L₂.op
L₂ := S.L₁.op
L₃ := S.L₀.op
epi_L₁_g := by dsimp; infer_instance
mono_L₂_f := by dsimp; infer_instance
v₀₁ := opMap S.v₂₃
v₁₂ := opMap S.v₁₂
v₂₃ := opMap S.v₀₁
w₀₂ := congr_arg opMap S.w₁₃
w₁₃ := congr_arg opMap S.w₀₂
h₀ := isLimitForkMapOfIsLimit' (ShortComplex.opEquiv C).functor _
(CokernelCofork.IsColimit.ofπOp _ _ S.h₃)
h₃ := isColimitCoforkMapOfIsColimit' (ShortComplex.opEquiv C).functor _
(KernelFork.IsLimit.ofιOp _ _ S.h₀)
L₁_exact := S.L₂_exact.op
L₂_exact := S.L₁_exact.op
@[reassoc (attr := simp)] lemma w₀₂_τ₁ : S.v₀₁.τ₁ ≫ S.v₁₂.τ₁ = 0 := by
rw [← comp_τ₁, S.w₀₂, zero_τ₁]
@[reassoc (attr := simp)] lemma w₀₂_τ₂ : S.v₀₁.τ₂ ≫ S.v₁₂.τ₂ = 0 := by
rw [← comp_τ₂, S.w₀₂, zero_τ₂]
@[reassoc (attr := simp)] lemma w₀₂_τ₃ : S.v₀₁.τ₃ ≫ S.v₁₂.τ₃ = 0 := by
rw [← comp_τ₃, S.w₀₂, zero_τ₃]
@[reassoc (attr := simp)] lemma w₁₃_τ₁ : S.v₁₂.τ₁ ≫ S.v₂₃.τ₁ = 0 := by
rw [← comp_τ₁, S.w₁₃, zero_τ₁]
@[reassoc (attr := simp)] lemma w₁₃_τ₂ : S.v₁₂.τ₂ ≫ S.v₂₃.τ₂ = 0 := by
rw [← comp_τ₂, S.w₁₃, zero_τ₂]
@[reassoc (attr := simp)] lemma w₁₃_τ₃ : S.v₁₂.τ₃ ≫ S.v₂₃.τ₃ = 0 := by
rw [← comp_τ₃, S.w₁₃, zero_τ₃]
/-- `L₀.X₁` is the kernel of `v₁₂.τ₁ : L₁.X₁ ⟶ L₂.X₁`. -/
noncomputable def h₀τ₁ : IsLimit (KernelFork.ofι S.v₀₁.τ₁ S.w₀₂_τ₁) :=
isLimitForkMapOfIsLimit' π₁ S.w₀₂ S.h₀
/-- `L₀.X₂` is the kernel of `v₁₂.τ₂ : L₁.X₂ ⟶ L₂.X₂`. -/
noncomputable def h₀τ₂ : IsLimit (KernelFork.ofι S.v₀₁.τ₂ S.w₀₂_τ₂) :=
isLimitForkMapOfIsLimit' π₂ S.w₀₂ S.h₀
/-- `L₀.X₃` is the kernel of `v₁₂.τ₃ : L₁.X₃ ⟶ L₂.X₃`. -/
noncomputable def h₀τ₃ : IsLimit (KernelFork.ofι S.v₀₁.τ₃ S.w₀₂_τ₃) :=
isLimitForkMapOfIsLimit' π₃ S.w₀₂ S.h₀
instance mono_v₀₁_τ₁ : Mono S.v₀₁.τ₁ := mono_of_isLimit_fork S.h₀τ₁
instance mono_v₀₁_τ₂ : Mono S.v₀₁.τ₂ := mono_of_isLimit_fork S.h₀τ₂
instance mono_v₀₁_τ₃ : Mono S.v₀₁.τ₃ := mono_of_isLimit_fork S.h₀τ₃
/-- The upper part of the first column of the snake diagram is exact. -/
lemma exact_C₁_up : (ShortComplex.mk S.v₀₁.τ₁ S.v₁₂.τ₁
(by rw [← comp_τ₁, S.w₀₂, zero_τ₁])).Exact :=
exact_of_f_is_kernel _ S.h₀τ₁
/-- The upper part of the second column of the snake diagram is exact. -/
lemma exact_C₂_up : (ShortComplex.mk S.v₀₁.τ₂ S.v₁₂.τ₂
(by rw [← comp_τ₂, S.w₀₂, zero_τ₂])).Exact :=
exact_of_f_is_kernel _ S.h₀τ₂
| /-- The upper part of the third column of the snake diagram is exact. -/
lemma exact_C₃_up : (ShortComplex.mk S.v₀₁.τ₃ S.v₁₂.τ₃
(by rw [← comp_τ₃, S.w₀₂, zero_τ₃])).Exact :=
exact_of_f_is_kernel _ S.h₀τ₃
| Mathlib/Algebra/Homology/ShortComplex/SnakeLemma.lean | 157 | 160 |
/-
Copyright (c) 2023 María Inés de Frutos-Fernández. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: María Inés de Frutos-Fernández
-/
import Mathlib.RingTheory.DedekindDomain.AdicValuation
import Mathlib.RingTheory.DedekindDomain.Factorization
import Mathlib.Topology.Algebra.RestrictedProduct
/-!
# The finite adèle ring of a Dedekind domain
We define the ring of finite adèles of a Dedekind domain `R`.
## Main definitions
- `IsDedekindDomain.FiniteAdeleRing` : The finite adèle ring of `R`, defined as the
restricted product `Πʳ_v K_v`. We give this ring a `K`-algebra structure.
## Implementation notes
We are only interested on Dedekind domains of Krull dimension 1 (i.e., not fields). If `R` is a
field, its finite adèle ring is just defined to be the trivial ring.
## References
* [J.W.S. Cassels, A. Fröhlich, *Algebraic Number Theory*][cassels1967algebraic]
## Tags
finite adèle ring, dedekind domain
-/
variable (R : Type*) [CommRing R] [IsDedekindDomain R] {K : Type*}
[Field K] [Algebra R K] [IsFractionRing R K]
namespace IsDedekindDomain
/--
The support of an element `k` of the field of fractions of a Dedekind domain is
the set of maximal ideals of the Dedekind domain at which `k` is not integral.
-/
def HeightOneSpectrum.Support (k : K) : Set (HeightOneSpectrum R) :=
{v : HeightOneSpectrum R | 1 < v.valuation K k}
/--
The support of an element of the field of fractions of a Dedekind domain
is finite.
-/
lemma HeightOneSpectrum.Support.finite (k : K) : (Support R k).Finite := by
-- We write k=n/d.
obtain ⟨⟨n, ⟨d, hd⟩⟩, hk⟩ := IsLocalization.surj (nonZeroDivisors R) k
have hd' : d ≠ 0 := nonZeroDivisors.ne_zero hd
suffices {v : HeightOneSpectrum R | v.valuation K (algebraMap R K d) < 1}.Finite by
apply Set.Finite.subset this
intro v hv
apply_fun v.valuation K at hk
simp only [Valuation.map_mul, valuation_of_algebraMap] at hk
rw [Set.mem_setOf_eq, valuation_of_algebraMap]
have := intValuation_le_one v n
contrapose! this
rw [← intValuation_apply, ← hk, mul_comm]
exact (lt_mul_of_one_lt_right (by simp) hv).trans_le <|
mul_le_mul_of_nonneg_right this (by simp)
simp_rw [valuation_of_algebraMap, intValuation_apply, intValuation_lt_one_iff_dvd]
apply Ideal.finite_factors
simpa only [Submodule.zero_eq_bot, ne_eq, Ideal.span_singleton_eq_bot]
end IsDedekindDomain
noncomputable section
open Function Set IsDedekindDomain.HeightOneSpectrum
namespace IsDedekindDomain
variable (K)
open scoped RestrictedProduct
/-! ### The finite adèle ring of a Dedekind domain
We define the finite adèle ring of `R` as the restricted product over all maximal ideals `v` of `R`
of `adicCompletion` with respect to `adicCompletionIntegers`. We prove that it is a commutative
ring. -/
/--
If `K` is the field of fractions of the Dedekind domain `R` then `FiniteAdeleRing R K` is
the ring of finite adeles of `K`, defined as the restricted product of the completions
`K_v` with respect to the subrings `R_v`. Here `v` runs through the nonzero primes of `R`
and the restricted product is the subring of `∏_v K_v` consisting of elements which
are in `R_v` for all but finitely many `v`.
-/
abbrev FiniteAdeleRing : Type _ :=
Πʳ v : HeightOneSpectrum R, [v.adicCompletion K, v.adicCompletionIntegers K]
namespace FiniteAdeleRing
/--
The canonical map from `K` to the finite adeles of `K`.
The content of the existence of this map is the fact that an element `k` of `K` is integral at
all but finitely many places, which is `IsDedekindDomain.HeightOneSpectrum.Support.finite R k`.
-/
protected def algebraMap : K →+* FiniteAdeleRing R K where
toFun k := ⟨fun i ↦ k, by
simp only [Filter.eventually_cofinite, SetLike.mem_coe, mem_adicCompletionIntegers R K,
adicCompletion, Valued.valuedCompletion_apply, not_le]
exact HeightOneSpectrum.Support.finite R k⟩
map_one' := rfl
map_mul' x y := Subtype.eq <| funext (fun v ↦
UniformSpace.Completion.coe_mul ((WithVal.equiv (valuation K v)).symm x) y)
map_zero' := rfl
map_add' x y := Subtype.eq <| funext (fun v ↦
UniformSpace.Completion.coe_add ((WithVal.equiv (valuation K v)).symm x) y)
instance : Algebra K (FiniteAdeleRing R K) := (FiniteAdeleRing.algebraMap R K).toAlgebra
instance : Algebra R (FiniteAdeleRing R K) := Algebra.compHom _ (algebraMap R K)
instance : IsScalarTower R K (FiniteAdeleRing R K) :=
IsScalarTower.of_algebraMap_eq' rfl
variable {R} in
@[ext]
lemma ext {a₁ a₂ : FiniteAdeleRing R K} (h : ∀ v, a₁ v = a₂ v) : a₁ = a₂ :=
Subtype.ext <| funext h
instance : DFunLike (FiniteAdeleRing R K) (HeightOneSpectrum R) (adicCompletion K) where
coe a := a.1
coe_injective' _a _b h := ext K (congrFun h)
section Topology
instance : IsTopologicalRing (FiniteAdeleRing R K) :=
haveI : Fact (∀ v : HeightOneSpectrum R,
IsOpen (v.adicCompletionIntegers K : Set (v.adicCompletion K))) :=
⟨fun _ ↦ Valued.valuationSubring_isOpen _⟩
RestrictedProduct.isTopologicalRing (fun (v : HeightOneSpectrum R) ↦ v.adicCompletion K)
end Topology
end FiniteAdeleRing
end IsDedekindDomain
| Mathlib/RingTheory/DedekindDomain/FiniteAdeleRing.lean | 207 | 221 | |
/-
Copyright (c) 2019 Neil Strickland. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Neil Strickland
-/
import Mathlib.Algebra.BigOperators.Intervals
import Mathlib.Algebra.BigOperators.Ring.Finset
import Mathlib.Algebra.Group.NatPowAssoc
import Mathlib.Algebra.Order.BigOperators.Ring.Finset
import Mathlib.Algebra.Ring.Opposite
import Mathlib.Tactic.Abel
import Mathlib.Algebra.Ring.Regular
/-!
# Partial sums of geometric series
This file determines the values of the geometric series $\sum_{i=0}^{n-1} x^i$ and
$\sum_{i=0}^{n-1} x^i y^{n-1-i}$ and variants thereof. We also provide some bounds on the
"geometric" sum of `a/b^i` where `a b : ℕ`.
## Main statements
* `geom_sum_Ico` proves that $\sum_{i=m}^{n-1} x^i=\frac{x^n-x^m}{x-1}$ in a division ring.
* `geom_sum₂_Ico` proves that $\sum_{i=m}^{n-1} x^iy^{n - 1 - i}=\frac{x^n-y^{n-m}x^m}{x-y}$
in a field.
Several variants are recorded, generalising in particular to the case of a noncommutative ring in
which `x` and `y` commute. Even versions not using division or subtraction, valid in each semiring,
are recorded.
-/
variable {R K : Type*}
open Finset MulOpposite
section Semiring
variable [Semiring R]
theorem geom_sum_succ {x : R} {n : ℕ} :
∑ i ∈ range (n + 1), x ^ i = (x * ∑ i ∈ range n, x ^ i) + 1 := by
simp only [mul_sum, ← pow_succ', sum_range_succ', pow_zero]
theorem geom_sum_succ' {x : R} {n : ℕ} :
∑ i ∈ range (n + 1), x ^ i = x ^ n + ∑ i ∈ range n, x ^ i :=
(sum_range_succ _ _).trans (add_comm _ _)
theorem geom_sum_zero (x : R) : ∑ i ∈ range 0, x ^ i = 0 :=
rfl
theorem geom_sum_one (x : R) : ∑ i ∈ range 1, x ^ i = 1 := by simp [geom_sum_succ']
@[simp]
theorem geom_sum_two {x : R} : ∑ i ∈ range 2, x ^ i = x + 1 := by simp [geom_sum_succ']
@[simp]
theorem zero_geom_sum : ∀ {n}, ∑ i ∈ range n, (0 : R) ^ i = if n = 0 then 0 else 1
| 0 => by simp
| 1 => by simp
| n + 2 => by
rw [geom_sum_succ']
simp [zero_geom_sum]
theorem one_geom_sum (n : ℕ) : ∑ i ∈ range n, (1 : R) ^ i = n := by simp
theorem op_geom_sum (x : R) (n : ℕ) : op (∑ i ∈ range n, x ^ i) = ∑ i ∈ range n, op x ^ i := by
simp
@[simp]
theorem op_geom_sum₂ (x y : R) (n : ℕ) : ∑ i ∈ range n, op y ^ (n - 1 - i) * op x ^ i =
∑ i ∈ range n, op y ^ i * op x ^ (n - 1 - i) := by
rw [← sum_range_reflect]
refine sum_congr rfl fun j j_in => ?_
rw [mem_range, Nat.lt_iff_add_one_le] at j_in
congr
apply tsub_tsub_cancel_of_le
exact le_tsub_of_add_le_right j_in
theorem geom_sum₂_with_one (x : R) (n : ℕ) :
∑ i ∈ range n, x ^ i * 1 ^ (n - 1 - i) = ∑ i ∈ range n, x ^ i :=
sum_congr rfl fun i _ => by rw [one_pow, mul_one]
/-- $x^n-y^n = (x-y) \sum x^ky^{n-1-k}$ reformulated without `-` signs. -/
protected theorem Commute.geom_sum₂_mul_add {x y : R} (h : Commute x y) (n : ℕ) :
(∑ i ∈ range n, (x + y) ^ i * y ^ (n - 1 - i)) * x + y ^ n = (x + y) ^ n := by
let f : ℕ → ℕ → R := fun m i : ℕ => (x + y) ^ i * y ^ (m - 1 - i)
change (∑ i ∈ range n, (f n) i) * x + y ^ n = (x + y) ^ n
induction n with
| zero => rw [range_zero, sum_empty, zero_mul, zero_add, pow_zero, pow_zero]
| succ n ih =>
have f_last : f (n + 1) n = (x + y) ^ n := by
dsimp only [f]
rw [← tsub_add_eq_tsub_tsub, Nat.add_comm, tsub_self, pow_zero, mul_one]
have f_succ : ∀ i, i ∈ range n → f (n + 1) i = y * f n i := fun i hi => by
dsimp only [f]
have : Commute y ((x + y) ^ i) := (h.symm.add_right (Commute.refl y)).pow_right i
rw [← mul_assoc, this.eq, mul_assoc, ← pow_succ' y (n - 1 - i), add_tsub_cancel_right,
← tsub_add_eq_tsub_tsub, add_comm 1 i]
have : i + 1 + (n - (i + 1)) = n := add_tsub_cancel_of_le (mem_range.mp hi)
rw [add_comm (i + 1)] at this
rw [← this, add_tsub_cancel_right, add_comm i 1, ← add_assoc, add_tsub_cancel_right]
rw [pow_succ' (x + y), add_mul, sum_range_succ_comm, add_mul, f_last, add_assoc,
(((Commute.refl x).add_right h).pow_right n).eq, sum_congr rfl f_succ, ← mul_sum,
pow_succ' y, mul_assoc, ← mul_add y, ih]
end Semiring
@[simp]
theorem neg_one_geom_sum [Ring R] {n : ℕ} :
∑ i ∈ range n, (-1 : R) ^ i = if Even n then 0 else 1 := by
induction n with
| zero => simp
| succ k hk =>
simp only [geom_sum_succ', Nat.even_add_one, hk]
split_ifs with h
· rw [h.neg_one_pow, add_zero]
· rw [(Nat.not_even_iff_odd.1 h).neg_one_pow, neg_add_cancel]
theorem geom_sum₂_self {R : Type*} [Semiring R] (x : R) (n : ℕ) :
∑ i ∈ range n, x ^ i * x ^ (n - 1 - i) = n * x ^ (n - 1) :=
calc
∑ i ∈ Finset.range n, x ^ i * x ^ (n - 1 - i) =
∑ i ∈ Finset.range n, x ^ (i + (n - 1 - i)) := by
simp_rw [← pow_add]
_ = ∑ _i ∈ Finset.range n, x ^ (n - 1) :=
Finset.sum_congr rfl fun _ hi =>
congr_arg _ <| add_tsub_cancel_of_le <| Nat.le_sub_one_of_lt <| Finset.mem_range.1 hi
_ = #(range n) • x ^ (n - 1) := sum_const _
_ = n * x ^ (n - 1) := by rw [Finset.card_range, nsmul_eq_mul]
/-- $x^n-y^n = (x-y) \sum x^ky^{n-1-k}$ reformulated without `-` signs. -/
theorem geom_sum₂_mul_add [CommSemiring R] (x y : R) (n : ℕ) :
(∑ i ∈ range n, (x + y) ^ i * y ^ (n - 1 - i)) * x + y ^ n = (x + y) ^ n :=
(Commute.all x y).geom_sum₂_mul_add n
theorem geom_sum_mul_add [Semiring R] (x : R) (n : ℕ) :
(∑ i ∈ range n, (x + 1) ^ i) * x + 1 = (x + 1) ^ n := by
have := (Commute.one_right x).geom_sum₂_mul_add n
rw [one_pow, geom_sum₂_with_one] at this
exact this
protected theorem Commute.geom_sum₂_mul [Ring R] {x y : R} (h : Commute x y) (n : ℕ) :
(∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) * (x - y) = x ^ n - y ^ n := by
have := (h.sub_left (Commute.refl y)).geom_sum₂_mul_add n
rw [sub_add_cancel] at this
rw [← this, add_sub_cancel_right]
theorem Commute.mul_neg_geom_sum₂ [Ring R] {x y : R} (h : Commute x y) (n : ℕ) :
((y - x) * ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) = y ^ n - x ^ n := by
apply op_injective
simp only [op_mul, op_sub, op_geom_sum₂, op_pow]
simp [(Commute.op h.symm).geom_sum₂_mul n]
theorem Commute.mul_geom_sum₂ [Ring R] {x y : R} (h : Commute x y) (n : ℕ) :
((x - y) * ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) = x ^ n - y ^ n := by
rw [← neg_sub (y ^ n), ← h.mul_neg_geom_sum₂, ← neg_mul, neg_sub]
theorem geom_sum₂_mul [CommRing R] (x y : R) (n : ℕ) :
(∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) * (x - y) = x ^ n - y ^ n :=
(Commute.all x y).geom_sum₂_mul n
theorem geom_sum₂_mul_of_ge [CommSemiring R] [PartialOrder R] [AddLeftReflectLE R] [AddLeftMono R]
[ExistsAddOfLE R] [Sub R] [OrderedSub R] {x y : R} (hxy : y ≤ x) (n : ℕ) :
(∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) * (x - y) = x ^ n - y ^ n := by
apply eq_tsub_of_add_eq
simpa only [tsub_add_cancel_of_le hxy] using geom_sum₂_mul_add (x - y) y n
theorem geom_sum₂_mul_of_le [CommSemiring R] [PartialOrder R] [AddLeftReflectLE R] [AddLeftMono R]
[ExistsAddOfLE R] [Sub R] [OrderedSub R] {x y : R} (hxy : x ≤ y) (n : ℕ) :
(∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) * (y - x) = y ^ n - x ^ n := by
rw [← Finset.sum_range_reflect]
convert geom_sum₂_mul_of_ge hxy n using 3
simp_all only [Finset.mem_range]
rw [mul_comm]
congr
omega
theorem Commute.sub_dvd_pow_sub_pow [Ring R] {x y : R} (h : Commute x y) (n : ℕ) :
x - y ∣ x ^ n - y ^ n :=
Dvd.intro _ <| h.mul_geom_sum₂ _
theorem sub_dvd_pow_sub_pow [CommRing R] (x y : R) (n : ℕ) : x - y ∣ x ^ n - y ^ n :=
(Commute.all x y).sub_dvd_pow_sub_pow n
theorem nat_sub_dvd_pow_sub_pow (x y n : ℕ) : x - y ∣ x ^ n - y ^ n := by
rcases le_or_lt y x with h | h
· have : y ^ n ≤ x ^ n := Nat.pow_le_pow_left h _
exact mod_cast sub_dvd_pow_sub_pow (x : ℤ) (↑y) n
· have : x ^ n ≤ y ^ n := Nat.pow_le_pow_left h.le _
exact (Nat.sub_eq_zero_of_le this).symm ▸ dvd_zero (x - y)
theorem one_sub_dvd_one_sub_pow [Ring R] (x : R) (n : ℕ) :
1 - x ∣ 1 - x ^ n := by
conv_rhs => rw [← one_pow n]
exact (Commute.one_left x).sub_dvd_pow_sub_pow n
theorem sub_one_dvd_pow_sub_one [Ring R] (x : R) (n : ℕ) :
x - 1 ∣ x ^ n - 1 := by
conv_rhs => rw [← one_pow n]
exact (Commute.one_right x).sub_dvd_pow_sub_pow n
lemma pow_one_sub_dvd_pow_mul_sub_one [Ring R] (x : R) (m n : ℕ) :
((x ^ m) - 1 : R) ∣ (x ^ (m * n) - 1) := by
rw [npow_mul]
exact sub_one_dvd_pow_sub_one (x := x ^ m) (n := n)
lemma nat_pow_one_sub_dvd_pow_mul_sub_one (x m n : ℕ) : x ^ m - 1 ∣ x ^ (m * n) - 1 := by
nth_rw 2 [← Nat.one_pow n]
rw [Nat.pow_mul x m n]
apply nat_sub_dvd_pow_sub_pow (x ^ m) 1
theorem Odd.add_dvd_pow_add_pow [CommRing R] (x y : R) {n : ℕ} (h : Odd n) :
x + y ∣ x ^ n + y ^ n := by
have h₁ := geom_sum₂_mul x (-y) n
rw [Odd.neg_pow h y, sub_neg_eq_add, sub_neg_eq_add] at h₁
exact Dvd.intro_left _ h₁
theorem Odd.nat_add_dvd_pow_add_pow (x y : ℕ) {n : ℕ} (h : Odd n) : x + y ∣ x ^ n + y ^ n :=
mod_cast Odd.add_dvd_pow_add_pow (x : ℤ) (↑y) h
theorem geom_sum_mul [Ring R] (x : R) (n : ℕ) : (∑ i ∈ range n, x ^ i) * (x - 1) = x ^ n - 1 := by
have := (Commute.one_right x).geom_sum₂_mul n
rw [one_pow, geom_sum₂_with_one] at this
exact this
theorem geom_sum_mul_of_one_le [CommSemiring R] [PartialOrder R] [AddLeftReflectLE R]
[AddLeftMono R] [ExistsAddOfLE R] [Sub R] [OrderedSub R] {x : R} (hx : 1 ≤ x) (n : ℕ) :
(∑ i ∈ range n, x ^ i) * (x - 1) = x ^ n - 1 := by
simpa using geom_sum₂_mul_of_ge hx n
theorem geom_sum_mul_of_le_one [CommSemiring R] [PartialOrder R] [AddLeftReflectLE R]
[AddLeftMono R] [ExistsAddOfLE R] [Sub R] [OrderedSub R] {x : R} (hx : x ≤ 1) (n : ℕ) :
(∑ i ∈ range n, x ^ i) * (1 - x) = 1 - x ^ n := by
simpa using geom_sum₂_mul_of_le hx n
theorem mul_geom_sum [Ring R] (x : R) (n : ℕ) : ((x - 1) * ∑ i ∈ range n, x ^ i) = x ^ n - 1 :=
op_injective <| by simpa using geom_sum_mul (op x) n
theorem geom_sum_mul_neg [Ring R] (x : R) (n : ℕ) :
(∑ i ∈ range n, x ^ i) * (1 - x) = 1 - x ^ n := by
have := congr_arg Neg.neg (geom_sum_mul x n)
rw [neg_sub, ← mul_neg, neg_sub] at this
exact this
theorem mul_neg_geom_sum [Ring R] (x : R) (n : ℕ) : ((1 - x) * ∑ i ∈ range n, x ^ i) = 1 - x ^ n :=
op_injective <| by simpa using geom_sum_mul_neg (op x) n
protected theorem Commute.geom_sum₂_comm [Semiring R] {x y : R} (n : ℕ)
(h : Commute x y) :
∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) = ∑ i ∈ range n, y ^ i * x ^ (n - 1 - i) := by
cases n; · simp
simp only [Nat.succ_eq_add_one, Nat.add_sub_cancel]
rw [← Finset.sum_flip]
refine Finset.sum_congr rfl fun i hi => ?_
simpa [Nat.sub_sub_self (Nat.succ_le_succ_iff.mp (Finset.mem_range.mp hi))] using h.pow_pow _ _
theorem geom_sum₂_comm [CommSemiring R] (x y : R) (n : ℕ) :
∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) = ∑ i ∈ range n, y ^ i * x ^ (n - 1 - i) :=
(Commute.all x y).geom_sum₂_comm n
protected theorem Commute.geom_sum₂ [DivisionRing K] {x y : K} (h' : Commute x y) (h : x ≠ y)
(n : ℕ) : ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) = (x ^ n - y ^ n) / (x - y) := by
have : x - y ≠ 0 := by simp_all [sub_eq_iff_eq_add]
rw [← h'.geom_sum₂_mul, mul_div_cancel_right₀ _ this]
theorem geom₂_sum [Field K] {x y : K} (h : x ≠ y) (n : ℕ) :
∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) = (x ^ n - y ^ n) / (x - y) :=
(Commute.all x y).geom_sum₂ h n
theorem geom₂_sum_of_gt [Semifield K] [LinearOrder K] [IsStrictOrderedRing K]
[CanonicallyOrderedAdd K] [Sub K] [OrderedSub K]
{x y : K} (h : y < x) (n : ℕ) :
∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) = (x ^ n - y ^ n) / (x - y) :=
eq_div_of_mul_eq (tsub_pos_of_lt h).ne' (geom_sum₂_mul_of_ge h.le n)
theorem geom₂_sum_of_lt [Semifield K] [LinearOrder K] [IsStrictOrderedRing K]
[CanonicallyOrderedAdd K] [Sub K] [OrderedSub K]
{x y : K} (h : x < y) (n : ℕ) :
∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) = (y ^ n - x ^ n) / (y - x) :=
eq_div_of_mul_eq (tsub_pos_of_lt h).ne' (geom_sum₂_mul_of_le h.le n)
theorem geom_sum_eq [DivisionRing K] {x : K} (h : x ≠ 1) (n : ℕ) :
∑ i ∈ range n, x ^ i = (x ^ n - 1) / (x - 1) := by
have : x - 1 ≠ 0 := by simp_all [sub_eq_iff_eq_add]
rw [← geom_sum_mul, mul_div_cancel_right₀ _ this]
lemma geom_sum_of_one_lt {x : K} [Semifield K] [LinearOrder K] [IsStrictOrderedRing K]
[CanonicallyOrderedAdd K] [Sub K] [OrderedSub K]
(h : 1 < x) (n : ℕ) :
∑ i ∈ Finset.range n, x ^ i = (x ^ n - 1) / (x - 1) :=
eq_div_of_mul_eq (tsub_pos_of_lt h).ne' (geom_sum_mul_of_one_le h.le n)
lemma geom_sum_of_lt_one {x : K} [Semifield K] [LinearOrder K] [IsStrictOrderedRing K]
[CanonicallyOrderedAdd K] [Sub K] [OrderedSub K]
(h : x < 1) (n : ℕ) :
∑ i ∈ Finset.range n, x ^ i = (1 - x ^ n) / (1 - x) :=
eq_div_of_mul_eq (tsub_pos_of_lt h).ne' (geom_sum_mul_of_le_one h.le n)
theorem geom_sum_lt {x : K} [Semifield K] [LinearOrder K] [IsStrictOrderedRing K]
[CanonicallyOrderedAdd K] [Sub K] [OrderedSub K]
(h0 : x ≠ 0) (h1 : x < 1) (n : ℕ) : ∑ i ∈ range n, x ^ i < (1 - x)⁻¹ := by
rw [← pos_iff_ne_zero] at h0
rw [geom_sum_of_lt_one h1, div_lt_iff₀, inv_mul_cancel₀, tsub_lt_self_iff]
· exact ⟨h0.trans h1, pow_pos h0 n⟩
· rwa [ne_eq, tsub_eq_zero_iff_le, not_le]
· rwa [tsub_pos_iff_lt]
protected theorem Commute.mul_geom_sum₂_Ico [Ring R] {x y : R} (h : Commute x y) {m n : ℕ}
(hmn : m ≤ n) :
((x - y) * ∑ i ∈ Finset.Ico m n, x ^ i * y ^ (n - 1 - i)) = x ^ n - x ^ m * y ^ (n - m) := by
rw [sum_Ico_eq_sub _ hmn]
have :
∑ k ∈ range m, x ^ k * y ^ (n - 1 - k) =
∑ k ∈ range m, x ^ k * (y ^ (n - m) * y ^ (m - 1 - k)) := by
refine sum_congr rfl fun j j_in => ?_
rw [← pow_add]
congr
rw [mem_range] at j_in
omega
rw [this]
simp_rw [pow_mul_comm y (n - m) _]
simp_rw [← mul_assoc]
rw [← sum_mul, mul_sub, h.mul_geom_sum₂, ← mul_assoc, h.mul_geom_sum₂, sub_mul, ← pow_add,
add_tsub_cancel_of_le hmn, sub_sub_sub_cancel_right (x ^ n) (x ^ m * y ^ (n - m)) (y ^ n)]
protected theorem Commute.geom_sum₂_succ_eq [Ring R] {x y : R} (h : Commute x y) {n : ℕ} :
∑ i ∈ range (n + 1), x ^ i * y ^ (n - i) =
x ^ n + y * ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) := by
simp_rw [mul_sum, sum_range_succ_comm, tsub_self, pow_zero, mul_one, add_right_inj, ← mul_assoc,
(h.symm.pow_right _).eq, mul_assoc, ← pow_succ']
refine sum_congr rfl fun i hi => ?_
suffices n - 1 - i + 1 = n - i by rw [this]
rw [Finset.mem_range] at hi
omega
theorem geom_sum₂_succ_eq [CommRing R] (x y : R) {n : ℕ} :
∑ i ∈ range (n + 1), x ^ i * y ^ (n - i) =
x ^ n + y * ∑ i ∈ range n, x ^ i * y ^ (n - 1 - i) :=
(Commute.all x y).geom_sum₂_succ_eq
theorem mul_geom_sum₂_Ico [CommRing R] (x y : R) {m n : ℕ} (hmn : m ≤ n) :
((x - y) * ∑ i ∈ Finset.Ico m n, x ^ i * y ^ (n - 1 - i)) = x ^ n - x ^ m * y ^ (n - m) :=
(Commute.all x y).mul_geom_sum₂_Ico hmn
protected theorem Commute.geom_sum₂_Ico_mul [Ring R] {x y : R} (h : Commute x y) {m n : ℕ}
(hmn : m ≤ n) :
(∑ i ∈ Finset.Ico m n, x ^ i * y ^ (n - 1 - i)) * (x - y) = x ^ n - y ^ (n - m) * x ^ m := by
apply op_injective
simp only [op_sub, op_mul, op_pow, op_sum]
have : (∑ k ∈ Ico m n, MulOpposite.op y ^ (n - 1 - k) * MulOpposite.op x ^ k) =
∑ k ∈ Ico m n, MulOpposite.op x ^ k * MulOpposite.op y ^ (n - 1 - k) := by
refine sum_congr rfl fun k _ => ?_
have hp := Commute.pow_pow (Commute.op h.symm) (n - 1 - k) k
simpa [Commute, SemiconjBy] using hp
simp only [this]
convert (Commute.op h).mul_geom_sum₂_Ico hmn
theorem geom_sum_Ico_mul [Ring R] (x : R) {m n : ℕ} (hmn : m ≤ n) :
(∑ i ∈ Finset.Ico m n, x ^ i) * (x - 1) = x ^ n - x ^ m := by
rw [sum_Ico_eq_sub _ hmn, sub_mul, geom_sum_mul, geom_sum_mul, sub_sub_sub_cancel_right]
theorem geom_sum_Ico_mul_neg [Ring R] (x : R) {m n : ℕ} (hmn : m ≤ n) :
(∑ i ∈ Finset.Ico m n, x ^ i) * (1 - x) = x ^ m - x ^ n := by
rw [sum_Ico_eq_sub _ hmn, sub_mul, geom_sum_mul_neg, geom_sum_mul_neg, sub_sub_sub_cancel_left]
protected theorem Commute.geom_sum₂_Ico [DivisionRing K] {x y : K} (h : Commute x y) (hxy : x ≠ y)
{m n : ℕ} (hmn : m ≤ n) :
(∑ i ∈ Finset.Ico m n, x ^ i * y ^ (n - 1 - i)) = (x ^ n - y ^ (n - m) * x ^ m) / (x - y) := by
have : x - y ≠ 0 := by simp_all [sub_eq_iff_eq_add]
rw [← h.geom_sum₂_Ico_mul hmn, mul_div_cancel_right₀ _ this]
theorem geom_sum₂_Ico [Field K] {x y : K} (hxy : x ≠ y) {m n : ℕ} (hmn : m ≤ n) :
(∑ i ∈ Finset.Ico m n, x ^ i * y ^ (n - 1 - i)) = (x ^ n - y ^ (n - m) * x ^ m) / (x - y) :=
(Commute.all x y).geom_sum₂_Ico hxy hmn
theorem geom_sum_Ico [DivisionRing K] {x : K} (hx : x ≠ 1) {m n : ℕ} (hmn : m ≤ n) :
∑ i ∈ Finset.Ico m n, x ^ i = (x ^ n - x ^ m) / (x - 1) := by
simp only [sum_Ico_eq_sub _ hmn, geom_sum_eq hx, div_sub_div_same, sub_sub_sub_cancel_right]
theorem geom_sum_Ico' [DivisionRing K] {x : K} (hx : x ≠ 1) {m n : ℕ} (hmn : m ≤ n) :
∑ i ∈ Finset.Ico m n, x ^ i = (x ^ m - x ^ n) / (1 - x) := by
simp only [geom_sum_Ico hx hmn]
convert neg_div_neg_eq (x ^ m - x ^ n) (1 - x) using 2 <;> abel
theorem geom_sum_Ico_le_of_lt_one [Field K] [LinearOrder K] [IsStrictOrderedRing K]
{x : K} (hx : 0 ≤ x) (h'x : x < 1)
{m n : ℕ} : ∑ i ∈ Ico m n, x ^ i ≤ x ^ m / (1 - x) := by
rcases le_or_lt m n with (hmn | hmn)
· rw [geom_sum_Ico' h'x.ne hmn]
apply div_le_div₀ (pow_nonneg hx _) _ (sub_pos.2 h'x) le_rfl
simpa using pow_nonneg hx _
· rw [Ico_eq_empty, sum_empty]
· apply div_nonneg (pow_nonneg hx _)
simpa using h'x.le
· simpa using hmn.le
theorem geom_sum_inv [DivisionRing K] {x : K} (hx1 : x ≠ 1) (hx0 : x ≠ 0) (n : ℕ) :
∑ i ∈ range n, x⁻¹ ^ i = (x - 1)⁻¹ * (x - x⁻¹ ^ n * x) := by
have h₁ : x⁻¹ ≠ 1 := by rwa [inv_eq_one_div, Ne, div_eq_iff_mul_eq hx0, one_mul]
have h₂ : x⁻¹ - 1 ≠ 0 := mt sub_eq_zero.1 h₁
have h₃ : x - 1 ≠ 0 := mt sub_eq_zero.1 hx1
have h₄ : x * (x ^ n)⁻¹ = (x ^ n)⁻¹ * x :=
Nat.recOn n (by simp) fun n h => by
rw [pow_succ', mul_inv_rev, ← mul_assoc, h, mul_assoc, mul_inv_cancel₀ hx0, mul_assoc,
inv_mul_cancel₀ hx0]
rw [geom_sum_eq h₁, div_eq_iff_mul_eq h₂, ← mul_right_inj' h₃, ← mul_assoc, ← mul_assoc,
mul_inv_cancel₀ h₃]
simp [mul_add, add_mul, mul_inv_cancel₀ hx0, mul_assoc, h₄, sub_eq_add_neg, add_comm,
add_left_comm]
rw [add_comm _ (-x), add_assoc, add_assoc _ _ 1]
variable {S : Type*}
-- TODO: for consistency, the next two lemmas should be moved to the root namespace
theorem RingHom.map_geom_sum [Semiring R] [Semiring S] (x : R) (n : ℕ) (f : R →+* S) :
f (∑ i ∈ range n, x ^ i) = ∑ i ∈ range n, f x ^ i := by simp [map_sum f]
theorem RingHom.map_geom_sum₂ [Semiring R] [Semiring S] (x y : R) (n : ℕ) (f : R →+* S) :
| f (∑ i ∈ range n, x ^ i * y ^ (n - 1 - i)) = ∑ i ∈ range n, f x ^ i * f y ^ (n - 1 - i) := by
simp [map_sum f]
/-! ### Geometric sum with `ℕ`-division -/
theorem Nat.pred_mul_geom_sum_le (a b n : ℕ) :
((b - 1) * ∑ i ∈ range n.succ, a / b ^ i) ≤ a * b - a / b ^ n :=
calc
((b - 1) * ∑ i ∈ range n.succ, a / b ^ i) =
(∑ i ∈ range n, a / b ^ (i + 1) * b) + a * b - ((∑ i ∈ range n, a / b ^ i) + a / b ^ n) := by
rw [tsub_mul, mul_comm, sum_mul, one_mul, sum_range_succ', sum_range_succ, pow_zero,
Nat.div_one]
| Mathlib/Algebra/GeomSum.lean | 419 | 431 |
/-
Copyright (c) 2021 Kexing Ying. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kexing Ying, Rémy Degenne
-/
import Mathlib.Probability.Process.Adapted
import Mathlib.MeasureTheory.Constructions.BorelSpace.Order
/-!
# Stopping times, stopped processes and stopped values
Definition and properties of stopping times.
## Main definitions
* `MeasureTheory.IsStoppingTime`: a stopping time with respect to some filtration `f` is a
function `τ` such that for all `i`, the preimage of `{j | j ≤ i}` along `τ` is
`f i`-measurable
* `MeasureTheory.IsStoppingTime.measurableSpace`: the σ-algebra associated with a stopping time
## Main results
* `ProgMeasurable.stoppedProcess`: the stopped process of a progressively measurable process is
progressively measurable.
* `memLp_stoppedProcess`: if a process belongs to `ℒp` at every time in `ℕ`, then its stopped
process belongs to `ℒp` as well.
## Tags
stopping time, stochastic process
-/
open Filter Order TopologicalSpace
open scoped MeasureTheory NNReal ENNReal Topology
namespace MeasureTheory
variable {Ω β ι : Type*} {m : MeasurableSpace Ω}
/-! ### Stopping times -/
/-- A stopping time with respect to some filtration `f` is a function
`τ` such that for all `i`, the preimage of `{j | j ≤ i}` along `τ` is measurable
with respect to `f i`.
Intuitively, the stopping time `τ` describes some stopping rule such that at time
`i`, we may determine it with the information we have at time `i`. -/
def IsStoppingTime [Preorder ι] (f : Filtration ι m) (τ : Ω → ι) :=
∀ i : ι, MeasurableSet[f i] <| {ω | τ ω ≤ i}
theorem isStoppingTime_const [Preorder ι] (f : Filtration ι m) (i : ι) :
IsStoppingTime f fun _ => i := fun j => by simp only [MeasurableSet.const]
section MeasurableSet
section Preorder
variable [Preorder ι] {f : Filtration ι m} {τ : Ω → ι}
protected theorem IsStoppingTime.measurableSet_le (hτ : IsStoppingTime f τ) (i : ι) :
MeasurableSet[f i] {ω | τ ω ≤ i} :=
hτ i
theorem IsStoppingTime.measurableSet_lt_of_pred [PredOrder ι] (hτ : IsStoppingTime f τ) (i : ι) :
MeasurableSet[f i] {ω | τ ω < i} := by
by_cases hi_min : IsMin i
· suffices {ω : Ω | τ ω < i} = ∅ by rw [this]; exact @MeasurableSet.empty _ (f i)
ext1 ω
simp only [Set.mem_setOf_eq, Set.mem_empty_iff_false, iff_false]
rw [isMin_iff_forall_not_lt] at hi_min
exact hi_min (τ ω)
have : {ω : Ω | τ ω < i} = τ ⁻¹' Set.Iic (pred i) := by ext; simp [Iic_pred_of_not_isMin hi_min]
rw [this]
exact f.mono (pred_le i) _ (hτ.measurableSet_le <| pred i)
end Preorder
section CountableStoppingTime
namespace IsStoppingTime
variable [PartialOrder ι] {τ : Ω → ι} {f : Filtration ι m}
protected theorem measurableSet_eq_of_countable_range (hτ : IsStoppingTime f τ)
(h_countable : (Set.range τ).Countable) (i : ι) : MeasurableSet[f i] {ω | τ ω = i} := by
have : {ω | τ ω = i} = {ω | τ ω ≤ i} \ ⋃ (j ∈ Set.range τ) (_ : j < i), {ω | τ ω ≤ j} := by
ext1 a
simp only [Set.mem_setOf_eq, Set.mem_range, Set.iUnion_exists, Set.iUnion_iUnion_eq',
Set.mem_diff, Set.mem_iUnion, exists_prop, not_exists, not_and, not_le]
constructor <;> intro h
· simp only [h, lt_iff_le_not_le, le_refl, and_imp, imp_self, imp_true_iff, and_self_iff]
· exact h.1.eq_or_lt.resolve_right fun h_lt => h.2 a h_lt le_rfl
rw [this]
refine (hτ.measurableSet_le i).diff ?_
refine MeasurableSet.biUnion h_countable fun j _ => ?_
classical
rw [Set.iUnion_eq_if]
split_ifs with hji
· exact f.mono hji.le _ (hτ.measurableSet_le j)
· exact @MeasurableSet.empty _ (f i)
protected theorem measurableSet_eq_of_countable [Countable ι] (hτ : IsStoppingTime f τ) (i : ι) :
MeasurableSet[f i] {ω | τ ω = i} :=
hτ.measurableSet_eq_of_countable_range (Set.to_countable _) i
protected theorem measurableSet_lt_of_countable_range (hτ : IsStoppingTime f τ)
(h_countable : (Set.range τ).Countable) (i : ι) : MeasurableSet[f i] {ω | τ ω < i} := by
have : {ω | τ ω < i} = {ω | τ ω ≤ i} \ {ω | τ ω = i} := by ext1 ω; simp [lt_iff_le_and_ne]
rw [this]
exact (hτ.measurableSet_le i).diff (hτ.measurableSet_eq_of_countable_range h_countable i)
protected theorem measurableSet_lt_of_countable [Countable ι] (hτ : IsStoppingTime f τ) (i : ι) :
MeasurableSet[f i] {ω | τ ω < i} :=
hτ.measurableSet_lt_of_countable_range (Set.to_countable _) i
protected theorem measurableSet_ge_of_countable_range {ι} [LinearOrder ι] {τ : Ω → ι}
{f : Filtration ι m} (hτ : IsStoppingTime f τ) (h_countable : (Set.range τ).Countable) (i : ι) :
MeasurableSet[f i] {ω | i ≤ τ ω} := by
have : {ω | i ≤ τ ω} = {ω | τ ω < i}ᶜ := by
ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_compl_iff, not_lt]
rw [this]
exact (hτ.measurableSet_lt_of_countable_range h_countable i).compl
protected theorem measurableSet_ge_of_countable {ι} [LinearOrder ι] {τ : Ω → ι} {f : Filtration ι m}
[Countable ι] (hτ : IsStoppingTime f τ) (i : ι) : MeasurableSet[f i] {ω | i ≤ τ ω} :=
hτ.measurableSet_ge_of_countable_range (Set.to_countable _) i
end IsStoppingTime
end CountableStoppingTime
section LinearOrder
variable [LinearOrder ι] {f : Filtration ι m} {τ : Ω → ι}
theorem IsStoppingTime.measurableSet_gt (hτ : IsStoppingTime f τ) (i : ι) :
MeasurableSet[f i] {ω | i < τ ω} := by
have : {ω | i < τ ω} = {ω | τ ω ≤ i}ᶜ := by
ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_compl_iff, not_le]
rw [this]
exact (hτ.measurableSet_le i).compl
section TopologicalSpace
variable [TopologicalSpace ι] [OrderTopology ι] [FirstCountableTopology ι]
/-- Auxiliary lemma for `MeasureTheory.IsStoppingTime.measurableSet_lt`. -/
theorem IsStoppingTime.measurableSet_lt_of_isLUB (hτ : IsStoppingTime f τ) (i : ι)
(h_lub : IsLUB (Set.Iio i) i) : MeasurableSet[f i] {ω | τ ω < i} := by
by_cases hi_min : IsMin i
· suffices {ω | τ ω < i} = ∅ by rw [this]; exact @MeasurableSet.empty _ (f i)
ext1 ω
simp only [Set.mem_setOf_eq, Set.mem_empty_iff_false, iff_false]
exact isMin_iff_forall_not_lt.mp hi_min (τ ω)
obtain ⟨seq, -, -, h_tendsto, h_bound⟩ :
∃ seq : ℕ → ι, Monotone seq ∧ (∀ j, seq j ≤ i) ∧ Tendsto seq atTop (𝓝 i) ∧ ∀ j, seq j < i :=
h_lub.exists_seq_monotone_tendsto (not_isMin_iff.mp hi_min)
have h_Ioi_eq_Union : Set.Iio i = ⋃ j, {k | k ≤ seq j} := by
ext1 k
simp only [Set.mem_Iio, Set.mem_iUnion, Set.mem_setOf_eq]
refine ⟨fun hk_lt_i => ?_, fun h_exists_k_le_seq => ?_⟩
· rw [tendsto_atTop'] at h_tendsto
have h_nhds : Set.Ici k ∈ 𝓝 i :=
mem_nhds_iff.mpr ⟨Set.Ioi k, Set.Ioi_subset_Ici le_rfl, isOpen_Ioi, hk_lt_i⟩
obtain ⟨a, ha⟩ : ∃ a : ℕ, ∀ b : ℕ, b ≥ a → k ≤ seq b := h_tendsto (Set.Ici k) h_nhds
exact ⟨a, ha a le_rfl⟩
· obtain ⟨j, hk_seq_j⟩ := h_exists_k_le_seq
exact hk_seq_j.trans_lt (h_bound j)
have h_lt_eq_preimage : {ω | τ ω < i} = τ ⁻¹' Set.Iio i := by
ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_preimage, Set.mem_Iio]
rw [h_lt_eq_preimage, h_Ioi_eq_Union]
simp only [Set.preimage_iUnion, Set.preimage_setOf_eq]
exact MeasurableSet.iUnion fun n => f.mono (h_bound n).le _ (hτ.measurableSet_le (seq n))
theorem IsStoppingTime.measurableSet_lt (hτ : IsStoppingTime f τ) (i : ι) :
MeasurableSet[f i] {ω | τ ω < i} := by
obtain ⟨i', hi'_lub⟩ : ∃ i', IsLUB (Set.Iio i) i' := exists_lub_Iio i
rcases lub_Iio_eq_self_or_Iio_eq_Iic i hi'_lub with hi'_eq_i | h_Iio_eq_Iic
· rw [← hi'_eq_i] at hi'_lub ⊢
exact hτ.measurableSet_lt_of_isLUB i' hi'_lub
· have h_lt_eq_preimage : {ω : Ω | τ ω < i} = τ ⁻¹' Set.Iio i := rfl
rw [h_lt_eq_preimage, h_Iio_eq_Iic]
exact f.mono (lub_Iio_le i hi'_lub) _ (hτ.measurableSet_le i')
theorem IsStoppingTime.measurableSet_ge (hτ : IsStoppingTime f τ) (i : ι) :
MeasurableSet[f i] {ω | i ≤ τ ω} := by
have : {ω | i ≤ τ ω} = {ω | τ ω < i}ᶜ := by
ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_compl_iff, not_lt]
rw [this]
exact (hτ.measurableSet_lt i).compl
theorem IsStoppingTime.measurableSet_eq (hτ : IsStoppingTime f τ) (i : ι) :
MeasurableSet[f i] {ω | τ ω = i} := by
have : {ω | τ ω = i} = {ω | τ ω ≤ i} ∩ {ω | τ ω ≥ i} := by
ext1 ω; simp only [Set.mem_setOf_eq, Set.mem_inter_iff, le_antisymm_iff]
rw [this]
exact (hτ.measurableSet_le i).inter (hτ.measurableSet_ge i)
theorem IsStoppingTime.measurableSet_eq_le (hτ : IsStoppingTime f τ) {i j : ι} (hle : i ≤ j) :
MeasurableSet[f j] {ω | τ ω = i} :=
f.mono hle _ <| hτ.measurableSet_eq i
theorem IsStoppingTime.measurableSet_lt_le (hτ : IsStoppingTime f τ) {i j : ι} (hle : i ≤ j) :
MeasurableSet[f j] {ω | τ ω < i} :=
f.mono hle _ <| hτ.measurableSet_lt i
end TopologicalSpace
end LinearOrder
section Countable
theorem isStoppingTime_of_measurableSet_eq [Preorder ι] [Countable ι] {f : Filtration ι m}
{τ : Ω → ι} (hτ : ∀ i, MeasurableSet[f i] {ω | τ ω = i}) : IsStoppingTime f τ := by
intro i
rw [show {ω | τ ω ≤ i} = ⋃ k ≤ i, {ω | τ ω = k} by ext; simp]
refine MeasurableSet.biUnion (Set.to_countable _) fun k hk => ?_
exact f.mono hk _ (hτ k)
end Countable
end MeasurableSet
namespace IsStoppingTime
protected theorem max [LinearOrder ι] {f : Filtration ι m} {τ π : Ω → ι} (hτ : IsStoppingTime f τ)
(hπ : IsStoppingTime f π) : IsStoppingTime f fun ω => max (τ ω) (π ω) := by
intro i
simp_rw [max_le_iff, Set.setOf_and]
exact (hτ i).inter (hπ i)
protected theorem max_const [LinearOrder ι] {f : Filtration ι m} {τ : Ω → ι}
(hτ : IsStoppingTime f τ) (i : ι) : IsStoppingTime f fun ω => max (τ ω) i :=
hτ.max (isStoppingTime_const f i)
protected theorem min [LinearOrder ι] {f : Filtration ι m} {τ π : Ω → ι} (hτ : IsStoppingTime f τ)
(hπ : IsStoppingTime f π) : IsStoppingTime f fun ω => min (τ ω) (π ω) := by
intro i
simp_rw [min_le_iff, Set.setOf_or]
exact (hτ i).union (hπ i)
protected theorem min_const [LinearOrder ι] {f : Filtration ι m} {τ : Ω → ι}
(hτ : IsStoppingTime f τ) (i : ι) : IsStoppingTime f fun ω => min (τ ω) i :=
hτ.min (isStoppingTime_const f i)
theorem add_const [AddGroup ι] [Preorder ι] [AddRightMono ι]
[AddLeftMono ι] {f : Filtration ι m} {τ : Ω → ι} (hτ : IsStoppingTime f τ)
{i : ι} (hi : 0 ≤ i) : IsStoppingTime f fun ω => τ ω + i := by
intro j
simp_rw [← le_sub_iff_add_le]
exact f.mono (sub_le_self j hi) _ (hτ (j - i))
theorem add_const_nat {f : Filtration ℕ m} {τ : Ω → ℕ} (hτ : IsStoppingTime f τ) {i : ℕ} :
IsStoppingTime f fun ω => τ ω + i := by
refine isStoppingTime_of_measurableSet_eq fun j => ?_
by_cases hij : i ≤ j
· simp_rw [eq_comm, ← Nat.sub_eq_iff_eq_add hij, eq_comm]
exact f.mono (j.sub_le i) _ (hτ.measurableSet_eq (j - i))
· rw [not_le] at hij
convert @MeasurableSet.empty _ (f.1 j)
ext ω
simp only [Set.mem_empty_iff_false, iff_false, Set.mem_setOf]
omega
-- generalize to certain countable type?
theorem add {f : Filtration ℕ m} {τ π : Ω → ℕ} (hτ : IsStoppingTime f τ) (hπ : IsStoppingTime f π) :
IsStoppingTime f (τ + π) := by
intro i
rw [(_ : {ω | (τ + π) ω ≤ i} = ⋃ k ≤ i, {ω | π ω = k} ∩ {ω | τ ω + k ≤ i})]
· exact MeasurableSet.iUnion fun k =>
MeasurableSet.iUnion fun hk => (hπ.measurableSet_eq_le hk).inter (hτ.add_const_nat i)
ext ω
simp only [Pi.add_apply, Set.mem_setOf_eq, Set.mem_iUnion, Set.mem_inter_iff, exists_prop]
refine ⟨fun h => ⟨π ω, by omega, rfl, h⟩, ?_⟩
rintro ⟨j, hj, rfl, h⟩
assumption
section Preorder
variable [Preorder ι] {f : Filtration ι m} {τ π : Ω → ι}
/-- The associated σ-algebra with a stopping time. -/
protected def measurableSpace (hτ : IsStoppingTime f τ) : MeasurableSpace Ω where
MeasurableSet' s := ∀ i : ι, MeasurableSet[f i] (s ∩ {ω | τ ω ≤ i})
measurableSet_empty i := (Set.empty_inter {ω | τ ω ≤ i}).symm ▸ @MeasurableSet.empty _ (f i)
measurableSet_compl s hs i := by
rw [(_ : sᶜ ∩ {ω | τ ω ≤ i} = (sᶜ ∪ {ω | τ ω ≤ i}ᶜ) ∩ {ω | τ ω ≤ i})]
· refine MeasurableSet.inter ?_ ?_
· rw [← Set.compl_inter]
exact (hs i).compl
· exact hτ i
· rw [Set.union_inter_distrib_right]
simp only [Set.compl_inter_self, Set.union_empty]
measurableSet_iUnion s hs i := by
rw [forall_swap] at hs
rw [Set.iUnion_inter]
exact MeasurableSet.iUnion (hs i)
protected theorem measurableSet (hτ : IsStoppingTime f τ) (s : Set Ω) :
MeasurableSet[hτ.measurableSpace] s ↔ ∀ i : ι, MeasurableSet[f i] (s ∩ {ω | τ ω ≤ i}) :=
Iff.rfl
theorem measurableSpace_mono (hτ : IsStoppingTime f τ) (hπ : IsStoppingTime f π) (hle : τ ≤ π) :
hτ.measurableSpace ≤ hπ.measurableSpace := by
intro s hs i
rw [(_ : s ∩ {ω | π ω ≤ i} = s ∩ {ω | τ ω ≤ i} ∩ {ω | π ω ≤ i})]
· exact (hs i).inter (hπ i)
· ext
simp only [Set.mem_inter_iff, iff_self_and, and_congr_left_iff, Set.mem_setOf_eq]
intro hle' _
exact le_trans (hle _) hle'
theorem measurableSpace_le_of_countable [Countable ι] (hτ : IsStoppingTime f τ) :
hτ.measurableSpace ≤ m := by
intro s hs
change ∀ i, MeasurableSet[f i] (s ∩ {ω | τ ω ≤ i}) at hs
rw [(_ : s = ⋃ i, s ∩ {ω | τ ω ≤ i})]
· exact MeasurableSet.iUnion fun i => f.le i _ (hs i)
· ext ω; constructor <;> rw [Set.mem_iUnion]
· exact fun hx => ⟨τ ω, hx, le_rfl⟩
· rintro ⟨_, hx, _⟩
exact hx
theorem measurableSpace_le [IsCountablyGenerated (atTop : Filter ι)] [IsDirected ι (· ≤ ·)]
(hτ : IsStoppingTime f τ) : hτ.measurableSpace ≤ m := by
intro s hs
cases isEmpty_or_nonempty ι
· haveI : IsEmpty Ω := ⟨fun ω => IsEmpty.false (τ ω)⟩
apply Subsingleton.measurableSet
· change ∀ i, MeasurableSet[f i] (s ∩ {ω | τ ω ≤ i}) at hs
obtain ⟨seq : ℕ → ι, h_seq_tendsto⟩ := (atTop : Filter ι).exists_seq_tendsto
rw [(_ : s = ⋃ n, s ∩ {ω | τ ω ≤ seq n})]
· exact MeasurableSet.iUnion fun i => f.le (seq i) _ (hs (seq i))
· ext ω; constructor <;> rw [Set.mem_iUnion]
· intro hx
suffices ∃ i, τ ω ≤ seq i from ⟨this.choose, hx, this.choose_spec⟩
rw [tendsto_atTop] at h_seq_tendsto
exact (h_seq_tendsto (τ ω)).exists
· rintro ⟨_, hx, _⟩
exact hx
@[deprecated (since := "2024-12-25")] alias measurableSpace_le' := measurableSpace_le
example {f : Filtration ℕ m} {τ : Ω → ℕ} (hτ : IsStoppingTime f τ) : hτ.measurableSpace ≤ m :=
hτ.measurableSpace_le
example {f : Filtration ℝ m} {τ : Ω → ℝ} (hτ : IsStoppingTime f τ) : hτ.measurableSpace ≤ m :=
hτ.measurableSpace_le
@[simp]
theorem measurableSpace_const (f : Filtration ι m) (i : ι) :
(isStoppingTime_const f i).measurableSpace = f i := by
ext1 s
change MeasurableSet[(isStoppingTime_const f i).measurableSpace] s ↔ MeasurableSet[f i] s
rw [IsStoppingTime.measurableSet]
constructor <;> intro h
· specialize h i
simpa only [le_refl, Set.setOf_true, Set.inter_univ] using h
· intro j
by_cases hij : i ≤ j
· simp only [hij, Set.setOf_true, Set.inter_univ]
exact f.mono hij _ h
· simp only [hij, Set.setOf_false, Set.inter_empty, @MeasurableSet.empty _ (f.1 j)]
theorem measurableSet_inter_eq_iff (hτ : IsStoppingTime f τ) (s : Set Ω) (i : ι) :
MeasurableSet[hτ.measurableSpace] (s ∩ {ω | τ ω = i}) ↔
MeasurableSet[f i] (s ∩ {ω | τ ω = i}) := by
have : ∀ j, {ω : Ω | τ ω = i} ∩ {ω : Ω | τ ω ≤ j} = {ω : Ω | τ ω = i} ∩ {_ω | i ≤ j} := by
intro j
ext1 ω
simp only [Set.mem_inter_iff, Set.mem_setOf_eq, and_congr_right_iff]
intro hxi
rw [hxi]
constructor <;> intro h
· specialize h i
simpa only [Set.inter_assoc, this, le_refl, Set.setOf_true, Set.inter_univ] using h
· intro j
rw [Set.inter_assoc, this]
by_cases hij : i ≤ j
· simp only [hij, Set.setOf_true, Set.inter_univ]
exact f.mono hij _ h
· simp [hij]
theorem measurableSpace_le_of_le_const (hτ : IsStoppingTime f τ) {i : ι} (hτ_le : ∀ ω, τ ω ≤ i) :
hτ.measurableSpace ≤ f i :=
(measurableSpace_mono hτ _ hτ_le).trans (measurableSpace_const _ _).le
theorem measurableSpace_le_of_le (hτ : IsStoppingTime f τ) {n : ι} (hτ_le : ∀ ω, τ ω ≤ n) :
hτ.measurableSpace ≤ m :=
(hτ.measurableSpace_le_of_le_const hτ_le).trans (f.le n)
theorem le_measurableSpace_of_const_le (hτ : IsStoppingTime f τ) {i : ι} (hτ_le : ∀ ω, i ≤ τ ω) :
f i ≤ hτ.measurableSpace :=
(measurableSpace_const _ _).symm.le.trans (measurableSpace_mono _ hτ hτ_le)
end Preorder
instance sigmaFinite_stopping_time {ι} [SemilatticeSup ι] [OrderBot ι]
[(Filter.atTop : Filter ι).IsCountablyGenerated] {μ : Measure Ω} {f : Filtration ι m}
{τ : Ω → ι} [SigmaFiniteFiltration μ f] (hτ : IsStoppingTime f τ) :
SigmaFinite (μ.trim hτ.measurableSpace_le) := by
refine @sigmaFiniteTrim_mono _ _ ?_ _ _ _ ?_ ?_
· exact f ⊥
| · exact hτ.le_measurableSpace_of_const_le fun _ => bot_le
· infer_instance
instance sigmaFinite_stopping_time_of_le {ι} [SemilatticeSup ι] [OrderBot ι] {μ : Measure Ω}
{f : Filtration ι m} {τ : Ω → ι} [SigmaFiniteFiltration μ f] (hτ : IsStoppingTime f τ) {n : ι}
(hτ_le : ∀ ω, τ ω ≤ n) : SigmaFinite (μ.trim (hτ.measurableSpace_le_of_le hτ_le)) := by
refine @sigmaFiniteTrim_mono _ _ ?_ _ _ _ ?_ ?_
· exact f ⊥
· exact hτ.le_measurableSpace_of_const_le fun _ => bot_le
· infer_instance
section LinearOrder
variable [LinearOrder ι] {f : Filtration ι m} {τ π : Ω → ι}
protected theorem measurableSet_le' (hτ : IsStoppingTime f τ) (i : ι) :
MeasurableSet[hτ.measurableSpace] {ω | τ ω ≤ i} := by
intro j
have : {ω : Ω | τ ω ≤ i} ∩ {ω : Ω | τ ω ≤ j} = {ω : Ω | τ ω ≤ min i j} := by
| Mathlib/Probability/Process/Stopping.lean | 407 | 425 |
/-
Copyright (c) 2022 Damiano Testa. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Damiano Testa
-/
import Mathlib.Algebra.Group.Nat.Even
import Mathlib.Data.Nat.Cast.Basic
import Mathlib.Data.Nat.Cast.Commute
import Mathlib.Data.Set.Operations
import Mathlib.Logic.Function.Iterate
/-!
# Even and odd elements in rings
This file defines odd elements and proves some general facts about even and odd elements of rings.
As opposed to `Even`, `Odd` does not have a multiplicative counterpart.
## TODO
Try to generalize `Even` lemmas further. For example, there are still a few lemmas whose `Semiring`
assumptions I (DT) am not convinced are necessary. If that turns out to be true, they could be moved
to `Mathlib.Algebra.Group.Even`.
## See also
`Mathlib.Algebra.Group.Even` for the definition of even elements.
-/
assert_not_exists DenselyOrdered OrderedRing
open MulOpposite
variable {F α β : Type*}
section Monoid
variable [Monoid α] [HasDistribNeg α] {n : ℕ} {a : α}
@[simp] lemma Even.neg_pow : Even n → ∀ a : α, (-a) ^ n = a ^ n := by
rintro ⟨c, rfl⟩ a
simp_rw [← two_mul, pow_mul, neg_sq]
lemma Even.neg_one_pow (h : Even n) : (-1 : α) ^ n = 1 := by rw [h.neg_pow, one_pow]
end Monoid
section DivisionMonoid
variable [DivisionMonoid α] [HasDistribNeg α] {a : α} {n : ℤ}
lemma Even.neg_zpow : Even n → ∀ a : α, (-a) ^ n = a ^ n := by
rintro ⟨c, rfl⟩ a; simp_rw [← Int.two_mul, zpow_mul, zpow_two, neg_mul_neg]
lemma Even.neg_one_zpow (h : Even n) : (-1 : α) ^ n = 1 := by rw [h.neg_zpow, one_zpow]
end DivisionMonoid
@[simp] lemma IsSquare.zero [MulZeroClass α] : IsSquare (0 : α) := ⟨0, (mul_zero _).symm⟩
section Semiring
variable [Semiring α] [Semiring β] {a b : α} {m n : ℕ}
lemma even_iff_exists_two_mul : Even a ↔ ∃ b, a = 2 * b := by simp [even_iff_exists_two_nsmul]
lemma even_iff_two_dvd : Even a ↔ 2 ∣ a := by simp [Even, Dvd.dvd, two_mul]
alias ⟨Even.two_dvd, _⟩ := even_iff_two_dvd
lemma Even.trans_dvd (ha : Even a) (hab : a ∣ b) : Even b :=
even_iff_two_dvd.2 <| ha.two_dvd.trans hab
lemma Dvd.dvd.even (hab : a ∣ b) (ha : Even a) : Even b := ha.trans_dvd hab
@[simp] lemma range_two_mul (α) [NonAssocSemiring α] :
Set.range (fun x : α ↦ 2 * x) = {a | Even a} := by
ext x
simp [eq_comm, two_mul, Even]
@[simp] lemma even_two : Even (2 : α) := ⟨1, by rw [one_add_one_eq_two]⟩
@[simp] lemma Even.mul_left (ha : Even a) (b) : Even (b * a) := ha.map (AddMonoidHom.mulLeft _)
@[simp] lemma Even.mul_right (ha : Even a) (b) : Even (a * b) := ha.map (AddMonoidHom.mulRight _)
lemma even_two_mul (a : α) : Even (2 * a) := ⟨a, two_mul _⟩
lemma Even.pow_of_ne_zero (ha : Even a) : ∀ {n : ℕ}, n ≠ 0 → Even (a ^ n)
| n + 1, _ => by rw [pow_succ]; exact ha.mul_left _
/-- An element `a` of a semiring is odd if there exists `k` such `a = 2*k + 1`. -/
def Odd (a : α) : Prop := ∃ k, a = 2 * k + 1
lemma odd_iff_exists_bit1 : Odd a ↔ ∃ b, a = 2 * b + 1 := exists_congr fun b ↦ by rw [two_mul]
alias ⟨Odd.exists_bit1, _⟩ := odd_iff_exists_bit1
@[simp] lemma range_two_mul_add_one (α : Type*) [Semiring α] :
Set.range (fun x : α ↦ 2 * x + 1) = {a | Odd a} := by ext x; simp [Odd, eq_comm]
lemma Even.add_odd : Even a → Odd b → Odd (a + b) := by
rintro ⟨a, rfl⟩ ⟨b, rfl⟩; exact ⟨a + b, by rw [mul_add, ← two_mul, add_assoc]⟩
lemma Even.odd_add (ha : Even a) (hb : Odd b) : Odd (b + a) := add_comm a b ▸ ha.add_odd hb
lemma Odd.add_even (ha : Odd a) (hb : Even b) : Odd (a + b) := add_comm a b ▸ hb.add_odd ha
lemma Odd.add_odd : Odd a → Odd b → Even (a + b) := by
rintro ⟨a, rfl⟩ ⟨b, rfl⟩
refine ⟨a + b + 1, ?_⟩
rw [two_mul, two_mul]
ac_rfl
@[simp] lemma odd_one : Odd (1 : α) :=
⟨0, (zero_add _).symm.trans (congr_arg (· + (1 : α)) (mul_zero _).symm)⟩
@[simp] lemma Even.add_one (h : Even a) : Odd (a + 1) := h.add_odd odd_one
@[simp] lemma Even.one_add (h : Even a) : Odd (1 + a) := h.odd_add odd_one
@[simp] lemma Odd.add_one (h : Odd a) : Even (a + 1) := h.add_odd odd_one
@[simp] lemma Odd.one_add (h : Odd a) : Even (1 + a) := odd_one.add_odd h
lemma odd_two_mul_add_one (a : α) : Odd (2 * a + 1) := ⟨_, rfl⟩
@[simp] lemma odd_add_self_one' : Odd (a + (a + 1)) := by simp [← add_assoc]
@[simp] lemma odd_add_one_self : Odd (a + 1 + a) := by simp [add_comm _ a]
@[simp] lemma odd_add_one_self' : Odd (a + (1 + a)) := by simp [add_comm 1 a]
lemma Odd.map [FunLike F α β] [RingHomClass F α β] (f : F) : Odd a → Odd (f a) := by
rintro ⟨a, rfl⟩; exact ⟨f a, by simp [two_mul]⟩
lemma Odd.natCast {R : Type*} [Semiring R] {n : ℕ} (hn : Odd n) : Odd (n : R) :=
hn.map <| Nat.castRingHom R
@[simp] lemma Odd.mul : Odd a → Odd b → Odd (a * b) := by
rintro ⟨a, rfl⟩ ⟨b, rfl⟩
refine ⟨2 * a * b + b + a, ?_⟩
rw [mul_add, add_mul, mul_one, ← add_assoc, one_mul, mul_assoc, ← mul_add, ← mul_add, ← mul_assoc,
← Nat.cast_two, ← Nat.cast_comm]
lemma Odd.pow (ha : Odd a) : ∀ {n : ℕ}, Odd (a ^ n)
| 0 => by
rw [pow_zero]
exact odd_one
| n + 1 => by rw [pow_succ]; exact ha.pow.mul ha
lemma Odd.pow_add_pow_eq_zero [IsCancelAdd α] (hn : Odd n) (hab : a + b = 0) :
a ^ n + b ^ n = 0 := by
obtain ⟨k, rfl⟩ := hn
induction k with | zero => simpa | succ k ih => ?_
have : a ^ 2 = b ^ 2 := add_right_cancel <|
calc
a ^ 2 + a * b = 0 := by rw [sq, ← mul_add, hab, mul_zero]
_ = b ^ 2 + a * b := by rw [sq, ← add_mul, add_comm, hab, zero_mul]
refine add_right_cancel (b := b ^ (2 * k + 1) * a ^ 2) ?_
calc
_ = (a ^ (2 * k + 1) + b ^ (2 * k + 1)) * a ^ 2 + b ^ (2 * k + 3) := by
rw [add_mul, ← pow_add, add_right_comm]; rfl
_ = _ := by rw [ih, zero_mul, zero_add, zero_add, this, ← pow_add]
end Semiring
section Monoid
variable [Monoid α] [HasDistribNeg α] {n : ℕ}
lemma Odd.neg_pow : Odd n → ∀ a : α, (-a) ^ n = -a ^ n := by
rintro ⟨c, rfl⟩ a; simp_rw [pow_add, pow_mul, neg_sq, pow_one, mul_neg]
@[simp] lemma Odd.neg_one_pow (h : Odd n) : (-1 : α) ^ n = -1 := by rw [h.neg_pow, one_pow]
end Monoid
section Ring
variable [Ring α] {a b : α} {n : ℕ}
lemma even_neg_two : Even (-2 : α) := by simp only [even_neg, even_two]
lemma Odd.neg (hp : Odd a) : Odd (-a) := by
obtain ⟨k, hk⟩ := hp
use -(k + 1)
rw [mul_neg, mul_add, neg_add, add_assoc, two_mul (1 : α), neg_add, neg_add_cancel_right,
← neg_add, hk]
@[simp] lemma odd_neg : Odd (-a) ↔ Odd a := ⟨fun h ↦ neg_neg a ▸ h.neg, Odd.neg⟩
lemma odd_neg_one : Odd (-1 : α) := by simp
lemma Odd.sub_even (ha : Odd a) (hb : Even b) : Odd (a - b) := by
rw [sub_eq_add_neg]; exact ha.add_even hb.neg
lemma Even.sub_odd (ha : Even a) (hb : Odd b) : Odd (a - b) := by
rw [sub_eq_add_neg]; exact ha.add_odd hb.neg
lemma Odd.sub_odd (ha : Odd a) (hb : Odd b) : Even (a - b) := by
rw [sub_eq_add_neg]; exact ha.add_odd hb.neg
end Ring
namespace Nat
variable {m n : ℕ}
lemma odd_iff : Odd n ↔ n % 2 = 1 :=
⟨fun ⟨m, hm⟩ ↦ by omega, fun h ↦ ⟨n / 2, (mod_add_div n 2).symm.trans (by rw [h, add_comm])⟩⟩
instance : DecidablePred (Odd : ℕ → Prop) := fun _ ↦ decidable_of_iff _ odd_iff.symm
lemma not_odd_iff : ¬Odd n ↔ n % 2 = 0 := by rw [odd_iff, mod_two_not_eq_one]
@[simp] lemma not_odd_iff_even : ¬Odd n ↔ Even n := by rw [not_odd_iff, even_iff]
@[simp] lemma not_even_iff_odd : ¬Even n ↔ Odd n := by rw [not_even_iff, odd_iff]
@[simp] lemma not_odd_zero : ¬Odd 0 := not_odd_iff.mpr rfl
lemma _root_.Odd.not_two_dvd_nat (h : Odd n) : ¬(2 ∣ n) := by
rwa [← even_iff_two_dvd, not_even_iff_odd]
lemma even_xor_odd (n : ℕ) : Xor' (Even n) (Odd n) := by
simp [Xor', ← not_even_iff_odd, Decidable.em (Even n)]
lemma even_or_odd (n : ℕ) : Even n ∨ Odd n := (even_xor_odd n).or
lemma even_or_odd' (n : ℕ) : ∃ k, n = 2 * k ∨ n = 2 * k + 1 := by
simpa only [← two_mul, exists_or, Odd, Even] using even_or_odd n
lemma even_xor_odd' (n : ℕ) : ∃ k, Xor' (n = 2 * k) (n = 2 * k + 1) := by
obtain ⟨k, rfl⟩ | ⟨k, rfl⟩ := even_or_odd n <;> use k
· simpa only [← two_mul, eq_self_iff_true, xor_true] using (succ_ne_self (2 * k)).symm
· simpa only [xor_true, xor_comm] using (succ_ne_self _)
lemma odd_add_one {n : ℕ} : Odd (n + 1) ↔ ¬ Odd n := by
rw [← not_even_iff_odd, Nat.even_add_one, not_even_iff_odd]
lemma mod_two_add_add_odd_mod_two (m : ℕ) {n : ℕ} (hn : Odd n) : m % 2 + (m + n) % 2 = 1 :=
((even_or_odd m).elim fun hm ↦ by rw [even_iff.1 hm, odd_iff.1 (hm.add_odd hn)]) fun hm ↦ by
rw [odd_iff.1 hm, even_iff.1 (hm.add_odd hn)]
@[simp] lemma mod_two_add_succ_mod_two (m : ℕ) : m % 2 + (m + 1) % 2 = 1 :=
mod_two_add_add_odd_mod_two m odd_one
@[simp] lemma succ_mod_two_add_mod_two (m : ℕ) : (m + 1) % 2 + m % 2 = 1 := by
rw [add_comm, mod_two_add_succ_mod_two]
lemma even_add' : Even (m + n) ↔ (Odd m ↔ Odd n) := by
rw [even_add, ← not_odd_iff_even, ← not_odd_iff_even, not_iff_not]
@[simp] lemma not_even_bit1 (n : ℕ) : ¬Even (2 * n + 1) := by simp [parity_simps]
lemma not_even_two_mul_add_one (n : ℕ) : ¬ Even (2 * n + 1) :=
not_even_iff_odd.2 <| odd_two_mul_add_one n
lemma even_sub' (h : n ≤ m) : Even (m - n) ↔ (Odd m ↔ Odd n) := by
rw [even_sub h, ← not_odd_iff_even, ← not_odd_iff_even, not_iff_not]
lemma Odd.sub_odd (hm : Odd m) (hn : Odd n) : Even (m - n) :=
(le_total n m).elim (fun h ↦ by simp only [even_sub' h, *]) fun h ↦ by
simp only [Nat.sub_eq_zero_iff_le.2 h, Even.zero]
alias _root_.Odd.tsub_odd := Nat.Odd.sub_odd
lemma odd_mul : Odd (m * n) ↔ Odd m ∧ Odd n := by simp [not_or, even_mul, ← not_even_iff_odd]
lemma Odd.of_mul_left (h : Odd (m * n)) : Odd m :=
(odd_mul.mp h).1
lemma Odd.of_mul_right (h : Odd (m * n)) : Odd n :=
| (odd_mul.mp h).2
| Mathlib/Algebra/Ring/Parity.lean | 262 | 262 |
/-
Copyright (c) 2021 Thomas Browning. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Thomas Browning
-/
import Mathlib.Algebra.BigOperators.GroupWithZero.Finset
import Mathlib.Algebra.GroupWithZero.Subgroup
import Mathlib.Data.Finite.Card
import Mathlib.Data.Finite.Prod
import Mathlib.Data.Set.Card
import Mathlib.GroupTheory.Coset.Card
import Mathlib.GroupTheory.GroupAction.Quotient
import Mathlib.GroupTheory.QuotientGroup.Basic
/-!
# Index of a Subgroup
In this file we define the index of a subgroup, and prove several divisibility properties.
Several theorems proved in this file are known as Lagrange's theorem.
## Main definitions
- `H.index` : the index of `H : Subgroup G` as a natural number,
and returns 0 if the index is infinite.
- `H.relindex K` : the relative index of `H : Subgroup G` in `K : Subgroup G` as a natural number,
and returns 0 if the relative index is infinite.
# Main results
- `card_mul_index` : `Nat.card H * H.index = Nat.card G`
- `index_mul_card` : `H.index * Fintype.card H = Fintype.card G`
- `index_dvd_card` : `H.index ∣ Fintype.card G`
- `relindex_mul_index` : If `H ≤ K`, then `H.relindex K * K.index = H.index`
- `index_dvd_of_le` : If `H ≤ K`, then `K.index ∣ H.index`
- `relindex_mul_relindex` : `relindex` is multiplicative in towers
- `MulAction.index_stabilizer`: the index of the stabilizer is the cardinality of the orbit
-/
assert_not_exists Field
open scoped Pointwise
namespace Subgroup
open Cardinal Function
variable {G G' : Type*} [Group G] [Group G'] (H K L : Subgroup G)
/-- The index of a subgroup as a natural number. Returns `0` if the index is infinite. -/
@[to_additive "The index of an additive subgroup as a natural number.
Returns 0 if the index is infinite."]
noncomputable def index : ℕ :=
Nat.card (G ⧸ H)
/-- If `H` and `K` are subgroups of a group `G`, then `relindex H K : ℕ` is the index
of `H ∩ K` in `K`. The function returns `0` if the index is infinite. -/
@[to_additive "If `H` and `K` are subgroups of an additive group `G`, then `relindex H K : ℕ`
is the index of `H ∩ K` in `K`. The function returns `0` if the index is infinite."]
noncomputable def relindex : ℕ :=
(H.subgroupOf K).index
@[to_additive]
theorem index_comap_of_surjective {f : G' →* G} (hf : Function.Surjective f) :
(H.comap f).index = H.index := by
have key : ∀ x y : G',
QuotientGroup.leftRel (H.comap f) x y ↔ QuotientGroup.leftRel H (f x) (f y) := by
simp only [QuotientGroup.leftRel_apply]
exact fun x y => iff_of_eq (congr_arg (· ∈ H) (by rw [f.map_mul, f.map_inv]))
refine Cardinal.toNat_congr (Equiv.ofBijective (Quotient.map' f fun x y => (key x y).mp) ⟨?_, ?_⟩)
· simp_rw [← Quotient.eq''] at key
refine Quotient.ind' fun x => ?_
refine Quotient.ind' fun y => ?_
exact (key x y).mpr
· refine Quotient.ind' fun x => ?_
obtain ⟨y, hy⟩ := hf x
exact ⟨y, (Quotient.map'_mk'' f _ y).trans (congr_arg Quotient.mk'' hy)⟩
@[to_additive]
theorem index_comap (f : G' →* G) :
(H.comap f).index = H.relindex f.range :=
Eq.trans (congr_arg index (by rfl))
((H.subgroupOf f.range).index_comap_of_surjective f.rangeRestrict_surjective)
@[to_additive]
theorem relindex_comap (f : G' →* G) (K : Subgroup G') :
relindex (comap f H) K = relindex H (map f K) := by
rw [relindex, subgroupOf, comap_comap, index_comap, ← f.map_range, K.range_subtype]
variable {H K L}
@[to_additive relindex_mul_index]
theorem relindex_mul_index (h : H ≤ K) : H.relindex K * K.index = H.index :=
((mul_comm _ _).trans (Cardinal.toNat_mul _ _).symm).trans
(congr_arg Cardinal.toNat (Equiv.cardinal_eq (quotientEquivProdOfLE h))).symm
@[to_additive]
theorem index_dvd_of_le (h : H ≤ K) : K.index ∣ H.index :=
dvd_of_mul_left_eq (H.relindex K) (relindex_mul_index h)
@[to_additive]
theorem relindex_dvd_index_of_le (h : H ≤ K) : H.relindex K ∣ H.index :=
dvd_of_mul_right_eq K.index (relindex_mul_index h)
@[to_additive]
theorem relindex_subgroupOf (hKL : K ≤ L) :
(H.subgroupOf L).relindex (K.subgroupOf L) = H.relindex K :=
((index_comap (H.subgroupOf L) (inclusion hKL)).trans (congr_arg _ (inclusion_range hKL))).symm
variable (H K L)
@[to_additive relindex_mul_relindex]
theorem relindex_mul_relindex (hHK : H ≤ K) (hKL : K ≤ L) :
H.relindex K * K.relindex L = H.relindex L := by
rw [← relindex_subgroupOf hKL]
exact relindex_mul_index fun x hx => hHK hx
@[to_additive]
theorem inf_relindex_right : (H ⊓ K).relindex K = H.relindex K := by
rw [relindex, relindex, inf_subgroupOf_right]
@[to_additive]
theorem inf_relindex_left : (H ⊓ K).relindex H = K.relindex H := by
rw [inf_comm, inf_relindex_right]
@[to_additive relindex_inf_mul_relindex]
theorem relindex_inf_mul_relindex : H.relindex (K ⊓ L) * K.relindex L = (H ⊓ K).relindex L := by
rw [← inf_relindex_right H (K ⊓ L), ← inf_relindex_right K L, ← inf_relindex_right (H ⊓ K) L,
inf_assoc, relindex_mul_relindex (H ⊓ (K ⊓ L)) (K ⊓ L) L inf_le_right inf_le_right]
@[to_additive (attr := simp)]
theorem relindex_sup_right [K.Normal] : K.relindex (H ⊔ K) = K.relindex H :=
Nat.card_congr (QuotientGroup.quotientInfEquivProdNormalQuotient H K).toEquiv.symm
@[to_additive (attr := simp)]
theorem relindex_sup_left [K.Normal] : K.relindex (K ⊔ H) = K.relindex H := by
rw [sup_comm, relindex_sup_right]
@[to_additive]
theorem relindex_dvd_index_of_normal [H.Normal] : H.relindex K ∣ H.index :=
relindex_sup_right K H ▸ relindex_dvd_index_of_le le_sup_right
variable {H K}
@[to_additive]
theorem relindex_dvd_of_le_left (hHK : H ≤ K) : K.relindex L ∣ H.relindex L :=
inf_of_le_left hHK ▸ dvd_of_mul_left_eq _ (relindex_inf_mul_relindex _ _ _)
/-- A subgroup has index two if and only if there exists `a` such that for all `b`, exactly one
of `b * a` and `b` belong to `H`. -/
@[to_additive "An additive subgroup has index two if and only if there exists `a` such that
for all `b`, exactly one of `b + a` and `b` belong to `H`."]
theorem index_eq_two_iff : H.index = 2 ↔ ∃ a, ∀ b, Xor' (b * a ∈ H) (b ∈ H) := by
simp only [index, Nat.card_eq_two_iff' ((1 : G) : G ⧸ H), ExistsUnique, inv_mem_iff,
QuotientGroup.exists_mk, QuotientGroup.forall_mk, Ne, QuotientGroup.eq, mul_one,
xor_iff_iff_not]
refine exists_congr fun a =>
⟨fun ha b => ⟨fun hba hb => ?_, fun hb => ?_⟩, fun ha => ⟨?_, fun b hb => ?_⟩⟩
· exact ha.1 ((mul_mem_cancel_left hb).1 hba)
· exact inv_inv b ▸ ha.2 _ (mt (inv_mem_iff (x := b)).1 hb)
· rw [← inv_mem_iff (x := a), ← ha, inv_mul_cancel]
exact one_mem _
· rwa [ha, inv_mem_iff (x := b)]
@[to_additive]
theorem mul_mem_iff_of_index_two (h : H.index = 2) {a b : G} : a * b ∈ H ↔ (a ∈ H ↔ b ∈ H) := by
by_cases ha : a ∈ H; · simp only [ha, true_iff, mul_mem_cancel_left ha]
by_cases hb : b ∈ H; · simp only [hb, iff_true, mul_mem_cancel_right hb]
simp only [ha, hb, iff_true]
rcases index_eq_two_iff.1 h with ⟨c, hc⟩
refine (hc _).or.resolve_left ?_
rwa [mul_assoc, mul_mem_cancel_right ((hc _).or.resolve_right hb)]
@[to_additive]
theorem mul_self_mem_of_index_two (h : H.index = 2) (a : G) : a * a ∈ H := by
rw [mul_mem_iff_of_index_two h]
@[to_additive two_smul_mem_of_index_two]
theorem sq_mem_of_index_two (h : H.index = 2) (a : G) : a ^ 2 ∈ H :=
(pow_two a).symm ▸ mul_self_mem_of_index_two h a
variable (H K) {f : G →* G'}
@[to_additive (attr := simp)]
theorem index_top : (⊤ : Subgroup G).index = 1 :=
Nat.card_eq_one_iff_unique.mpr ⟨QuotientGroup.subsingleton_quotient_top, ⟨1⟩⟩
@[to_additive (attr := simp)]
theorem index_bot : (⊥ : Subgroup G).index = Nat.card G :=
Cardinal.toNat_congr QuotientGroup.quotientBot.toEquiv
@[to_additive (attr := simp)]
theorem relindex_top_left : (⊤ : Subgroup G).relindex H = 1 :=
index_top
@[to_additive (attr := simp)]
theorem relindex_top_right : H.relindex ⊤ = H.index := by
rw [← relindex_mul_index (show H ≤ ⊤ from le_top), index_top, mul_one]
@[to_additive (attr := simp)]
theorem relindex_bot_left : (⊥ : Subgroup G).relindex H = Nat.card H := by
rw [relindex, bot_subgroupOf, index_bot]
@[to_additive (attr := simp)]
theorem relindex_bot_right : H.relindex ⊥ = 1 := by rw [relindex, subgroupOf_bot_eq_top, index_top]
@[to_additive (attr := simp)]
theorem relindex_self : H.relindex H = 1 := by rw [relindex, subgroupOf_self, index_top]
@[to_additive]
theorem index_ker (f : G →* G') : f.ker.index = Nat.card f.range := by
rw [← MonoidHom.comap_bot, index_comap, relindex_bot_left]
@[to_additive]
theorem relindex_ker (f : G →* G') : f.ker.relindex K = Nat.card (K.map f) := by
rw [← MonoidHom.comap_bot, relindex_comap, relindex_bot_left]
@[to_additive (attr := simp) card_mul_index]
theorem card_mul_index : Nat.card H * H.index = Nat.card G := by
rw [← relindex_bot_left, ← index_bot]
exact relindex_mul_index bot_le
@[to_additive]
theorem card_dvd_of_surjective (f : G →* G') (hf : Function.Surjective f) :
Nat.card G' ∣ Nat.card G := by
rw [← Nat.card_congr (QuotientGroup.quotientKerEquivOfSurjective f hf).toEquiv]
exact Dvd.intro_left (Nat.card f.ker) f.ker.card_mul_index
@[to_additive]
theorem card_range_dvd (f : G →* G') : Nat.card f.range ∣ Nat.card G :=
card_dvd_of_surjective f.rangeRestrict f.rangeRestrict_surjective
@[to_additive]
theorem card_map_dvd (f : G →* G') : Nat.card (H.map f) ∣ Nat.card H :=
card_dvd_of_surjective (f.subgroupMap H) (f.subgroupMap_surjective H)
@[to_additive]
theorem index_map (f : G →* G') :
(H.map f).index = (H ⊔ f.ker).index * f.range.index := by
rw [← comap_map_eq, index_comap, relindex_mul_index (H.map_le_range f)]
@[to_additive]
theorem index_map_dvd {f : G →* G'} (hf : Function.Surjective f) :
(H.map f).index ∣ H.index := by
rw [index_map, f.range_eq_top_of_surjective hf, index_top, mul_one]
exact index_dvd_of_le le_sup_left
@[to_additive]
theorem dvd_index_map {f : G →* G'} (hf : f.ker ≤ H) :
H.index ∣ (H.map f).index := by
rw [index_map, sup_of_le_left hf]
apply dvd_mul_right
@[to_additive]
theorem index_map_eq (hf1 : Surjective f) (hf2 : f.ker ≤ H) : (H.map f).index = H.index :=
Nat.dvd_antisymm (H.index_map_dvd hf1) (H.dvd_index_map hf2)
@[to_additive]
lemma index_map_of_bijective (hf : Bijective f) (H : Subgroup G) : (H.map f).index = H.index :=
index_map_eq _ hf.2 (by rw [f.ker_eq_bot_iff.2 hf.1]; exact bot_le)
@[to_additive]
theorem index_map_of_injective {f : G →* G'} (hf : Function.Injective f) :
(H.map f).index = H.index * f.range.index := by
rw [H.index_map, f.ker_eq_bot_iff.mpr hf, sup_bot_eq]
@[to_additive]
theorem index_map_subtype {H : Subgroup G} (K : Subgroup H) :
(K.map H.subtype).index = K.index * H.index := by
rw [K.index_map_of_injective H.subtype_injective, H.range_subtype]
@[to_additive]
theorem index_eq_card : H.index = Nat.card (G ⧸ H) :=
rfl
@[to_additive index_mul_card]
theorem index_mul_card : H.index * Nat.card H = Nat.card G := by
rw [mul_comm, card_mul_index]
@[to_additive]
theorem index_dvd_card : H.index ∣ Nat.card G :=
⟨Nat.card H, H.index_mul_card.symm⟩
@[to_additive]
theorem relindex_dvd_card : H.relindex K ∣ Nat.card K :=
(H.subgroupOf K).index_dvd_card
variable {H K L}
@[to_additive]
theorem relindex_eq_zero_of_le_left (hHK : H ≤ K) (hKL : K.relindex L = 0) : H.relindex L = 0 :=
eq_zero_of_zero_dvd (hKL ▸ relindex_dvd_of_le_left L hHK)
@[to_additive]
theorem relindex_eq_zero_of_le_right (hKL : K ≤ L) (hHK : H.relindex K = 0) : H.relindex L = 0 :=
Finite.card_eq_zero_of_embedding (quotientSubgroupOfEmbeddingOfLE H hKL) hHK
@[to_additive]
theorem index_eq_zero_of_relindex_eq_zero (h : H.relindex K = 0) : H.index = 0 :=
H.relindex_top_right.symm.trans (relindex_eq_zero_of_le_right le_top h)
@[to_additive]
theorem relindex_le_of_le_left (hHK : H ≤ K) (hHL : H.relindex L ≠ 0) :
K.relindex L ≤ H.relindex L :=
Nat.le_of_dvd (Nat.pos_of_ne_zero hHL) (relindex_dvd_of_le_left L hHK)
@[to_additive]
theorem relindex_le_of_le_right (hKL : K ≤ L) (hHL : H.relindex L ≠ 0) :
H.relindex K ≤ H.relindex L :=
Finite.card_le_of_embedding' (quotientSubgroupOfEmbeddingOfLE H hKL) fun h => (hHL h).elim
@[to_additive]
theorem relindex_ne_zero_trans (hHK : H.relindex K ≠ 0) (hKL : K.relindex L ≠ 0) :
H.relindex L ≠ 0 := fun h =>
mul_ne_zero (mt (relindex_eq_zero_of_le_right (show K ⊓ L ≤ K from inf_le_left)) hHK) hKL
((relindex_inf_mul_relindex H K L).trans (relindex_eq_zero_of_le_left inf_le_left h))
@[to_additive]
theorem relindex_inf_ne_zero (hH : H.relindex L ≠ 0) (hK : K.relindex L ≠ 0) :
(H ⊓ K).relindex L ≠ 0 := by
replace hH : H.relindex (K ⊓ L) ≠ 0 := mt (relindex_eq_zero_of_le_right inf_le_right) hH
rw [← inf_relindex_right] at hH hK ⊢
rw [inf_assoc]
exact relindex_ne_zero_trans hH hK
@[to_additive]
theorem index_inf_ne_zero (hH : H.index ≠ 0) (hK : K.index ≠ 0) : (H ⊓ K).index ≠ 0 := by
rw [← relindex_top_right] at hH hK ⊢
exact relindex_inf_ne_zero hH hK
@[to_additive]
theorem relindex_inf_le : (H ⊓ K).relindex L ≤ H.relindex L * K.relindex L := by
by_cases h : H.relindex L = 0
· exact (le_of_eq (relindex_eq_zero_of_le_left inf_le_left h)).trans (zero_le _)
rw [← inf_relindex_right, inf_assoc, ← relindex_mul_relindex _ _ L inf_le_right inf_le_right,
inf_relindex_right, inf_relindex_right]
exact mul_le_mul_right' (relindex_le_of_le_right inf_le_right h) (K.relindex L)
@[to_additive]
theorem index_inf_le : (H ⊓ K).index ≤ H.index * K.index := by
simp_rw [← relindex_top_right, relindex_inf_le]
@[to_additive]
theorem relindex_iInf_ne_zero {ι : Type*} [_hι : Finite ι] {f : ι → Subgroup G}
(hf : ∀ i, (f i).relindex L ≠ 0) : (⨅ i, f i).relindex L ≠ 0 :=
haveI := Fintype.ofFinite ι
(Finset.prod_ne_zero_iff.mpr fun i _hi => hf i) ∘
Nat.card_pi.symm.trans ∘
Finite.card_eq_zero_of_embedding (quotientiInfSubgroupOfEmbedding f L)
@[to_additive]
theorem relindex_iInf_le {ι : Type*} [Fintype ι] (f : ι → Subgroup G) :
(⨅ i, f i).relindex L ≤ ∏ i, (f i).relindex L :=
le_of_le_of_eq
(Finite.card_le_of_embedding' (quotientiInfSubgroupOfEmbedding f L) fun h =>
let ⟨i, _hi, h⟩ := Finset.prod_eq_zero_iff.mp (Nat.card_pi.symm.trans h)
relindex_eq_zero_of_le_left (iInf_le f i) h)
Nat.card_pi
@[to_additive]
theorem index_iInf_ne_zero {ι : Type*} [Finite ι] {f : ι → Subgroup G}
(hf : ∀ i, (f i).index ≠ 0) : (⨅ i, f i).index ≠ 0 := by
| simp_rw [← relindex_top_right] at hf ⊢
exact relindex_iInf_ne_zero hf
@[to_additive]
| Mathlib/GroupTheory/Index.lean | 362 | 365 |
/-
Copyright (c) 2021 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kim Morrison, Joël Riou
-/
import Mathlib.Algebra.Homology.Homotopy
import Mathlib.Algebra.Homology.ShortComplex.Retract
import Mathlib.CategoryTheory.MorphismProperty.Composition
/-!
# Quasi-isomorphisms
A chain map is a quasi-isomorphism if it induces isomorphisms on homology.
-/
open CategoryTheory Limits
universe v u
open HomologicalComplex
section
variable {ι : Type*} {C : Type u} [Category.{v} C] [HasZeroMorphisms C]
{c : ComplexShape ι} {K L M K' L' : HomologicalComplex C c}
/-- A morphism of homological complexes `f : K ⟶ L` is a quasi-isomorphism in degree `i`
when it induces a quasi-isomorphism of short complexes `K.sc i ⟶ L.sc i`. -/
class QuasiIsoAt (f : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i] : Prop where
quasiIso : ShortComplex.QuasiIso ((shortComplexFunctor C c i).map f)
lemma quasiIsoAt_iff (f : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i] :
QuasiIsoAt f i ↔
ShortComplex.QuasiIso ((shortComplexFunctor C c i).map f) := by
constructor
· intro h
exact h.quasiIso
· intro h
exact ⟨h⟩
instance quasiIsoAt_of_isIso (f : K ⟶ L) [IsIso f] (i : ι) [K.HasHomology i] [L.HasHomology i] :
QuasiIsoAt f i := by
rw [quasiIsoAt_iff]
infer_instance
lemma quasiIsoAt_iff' (f : K ⟶ L) (i j k : ι) (hi : c.prev j = i) (hk : c.next j = k)
[K.HasHomology j] [L.HasHomology j] [(K.sc' i j k).HasHomology] [(L.sc' i j k).HasHomology] :
QuasiIsoAt f j ↔
ShortComplex.QuasiIso ((shortComplexFunctor' C c i j k).map f) := by
rw [quasiIsoAt_iff]
exact ShortComplex.quasiIso_iff_of_arrow_mk_iso _ _
(Arrow.isoOfNatIso (natIsoSc' C c i j k hi hk) (Arrow.mk f))
lemma quasiIsoAt_of_retract {f : K ⟶ L} {f' : K' ⟶ L'}
(h : RetractArrow f f') (i : ι) [K.HasHomology i] [L.HasHomology i]
[K'.HasHomology i] [L'.HasHomology i] [hf' : QuasiIsoAt f' i] :
QuasiIsoAt f i := by
rw [quasiIsoAt_iff] at hf' ⊢
have : RetractArrow ((shortComplexFunctor C c i).map f)
((shortComplexFunctor C c i).map f') := h.map (shortComplexFunctor C c i).mapArrow
exact ShortComplex.quasiIso_of_retract this
lemma quasiIsoAt_iff_isIso_homologyMap (f : K ⟶ L) (i : ι)
[K.HasHomology i] [L.HasHomology i] :
QuasiIsoAt f i ↔ IsIso (homologyMap f i) := by
rw [quasiIsoAt_iff, ShortComplex.quasiIso_iff]
rfl
lemma quasiIsoAt_iff_exactAt (f : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i]
(hK : K.ExactAt i) :
QuasiIsoAt f i ↔ L.ExactAt i := by
simp only [quasiIsoAt_iff, ShortComplex.quasiIso_iff, exactAt_iff,
ShortComplex.exact_iff_isZero_homology] at hK ⊢
constructor
· intro h
exact IsZero.of_iso hK (@asIso _ _ _ _ _ h).symm
· intro hL
exact ⟨⟨0, IsZero.eq_of_src hK _ _, IsZero.eq_of_tgt hL _ _⟩⟩
lemma quasiIsoAt_iff_exactAt' (f : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i]
(hL : L.ExactAt i) :
QuasiIsoAt f i ↔ K.ExactAt i := by
simp only [quasiIsoAt_iff, ShortComplex.quasiIso_iff, exactAt_iff,
ShortComplex.exact_iff_isZero_homology] at hL ⊢
constructor
· intro h
exact IsZero.of_iso hL (@asIso _ _ _ _ _ h)
· intro hK
exact ⟨⟨0, IsZero.eq_of_src hK _ _, IsZero.eq_of_tgt hL _ _⟩⟩
lemma exactAt_iff_of_quasiIsoAt (f : K ⟶ L) (i : ι)
[K.HasHomology i] [L.HasHomology i] [QuasiIsoAt f i] :
K.ExactAt i ↔ L.ExactAt i :=
⟨fun hK => (quasiIsoAt_iff_exactAt f i hK).1 inferInstance,
fun hL => (quasiIsoAt_iff_exactAt' f i hL).1 inferInstance⟩
instance (f : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i] [hf : QuasiIsoAt f i] :
IsIso (homologyMap f i) := by
simpa only [quasiIsoAt_iff, ShortComplex.quasiIso_iff] using hf
/-- The isomorphism `K.homology i ≅ L.homology i` induced by a morphism `f : K ⟶ L` such
that `[QuasiIsoAt f i]` holds. -/
@[simps! hom]
noncomputable def isoOfQuasiIsoAt (f : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i]
[QuasiIsoAt f i] : K.homology i ≅ L.homology i :=
asIso (homologyMap f i)
@[reassoc (attr := simp)]
lemma isoOfQuasiIsoAt_hom_inv_id (f : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i]
[QuasiIsoAt f i] :
homologyMap f i ≫ (isoOfQuasiIsoAt f i).inv = 𝟙 _ :=
(isoOfQuasiIsoAt f i).hom_inv_id
@[reassoc (attr := simp)]
lemma isoOfQuasiIsoAt_inv_hom_id (f : K ⟶ L) (i : ι) [K.HasHomology i] [L.HasHomology i]
[QuasiIsoAt f i] :
(isoOfQuasiIsoAt f i).inv ≫ homologyMap f i = 𝟙 _ :=
(isoOfQuasiIsoAt f i).inv_hom_id
lemma CochainComplex.quasiIsoAt₀_iff {K L : CochainComplex C ℕ} (f : K ⟶ L)
[K.HasHomology 0] [L.HasHomology 0] [(K.sc' 0 0 1).HasHomology] [(L.sc' 0 0 1).HasHomology] :
QuasiIsoAt f 0 ↔
ShortComplex.QuasiIso ((HomologicalComplex.shortComplexFunctor' C _ 0 0 1).map f) :=
quasiIsoAt_iff' _ _ _ _ (by simp) (by simp)
lemma ChainComplex.quasiIsoAt₀_iff {K L : ChainComplex C ℕ} (f : K ⟶ L)
[K.HasHomology 0] [L.HasHomology 0] [(K.sc' 1 0 0).HasHomology] [(L.sc' 1 0 0).HasHomology] :
QuasiIsoAt f 0 ↔
ShortComplex.QuasiIso ((HomologicalComplex.shortComplexFunctor' C _ 1 0 0).map f) :=
quasiIsoAt_iff' _ _ _ _ (by simp) (by simp)
/-- A morphism of homological complexes `f : K ⟶ L` is a quasi-isomorphism when it
is so in every degree, i.e. when the induced maps `homologyMap f i : K.homology i ⟶ L.homology i`
are all isomorphisms (see `quasiIso_iff` and `quasiIsoAt_iff_isIso_homologyMap`). -/
class QuasiIso (f : K ⟶ L) [∀ i, K.HasHomology i] [∀ i, L.HasHomology i] : Prop where
quasiIsoAt : ∀ i, QuasiIsoAt f i := by infer_instance
lemma quasiIso_iff (f : K ⟶ L) [∀ i, K.HasHomology i] [∀ i, L.HasHomology i] :
QuasiIso f ↔ ∀ i, QuasiIsoAt f i :=
⟨fun h => h.quasiIsoAt, fun h => ⟨h⟩⟩
attribute [instance] QuasiIso.quasiIsoAt
instance quasiIso_of_isIso (f : K ⟶ L) [IsIso f] [∀ i, K.HasHomology i] [∀ i, L.HasHomology i] :
QuasiIso f where
instance quasiIsoAt_comp (φ : K ⟶ L) (φ' : L ⟶ M) (i : ι) [K.HasHomology i]
[L.HasHomology i] [M.HasHomology i]
[hφ : QuasiIsoAt φ i] [hφ' : QuasiIsoAt φ' i] :
QuasiIsoAt (φ ≫ φ') i := by
rw [quasiIsoAt_iff] at hφ hφ' ⊢
rw [Functor.map_comp]
exact ShortComplex.quasiIso_comp _ _
instance quasiIso_comp (φ : K ⟶ L) (φ' : L ⟶ M) [∀ i, K.HasHomology i]
[∀ i, L.HasHomology i] [∀ i, M.HasHomology i]
[hφ : QuasiIso φ] [hφ' : QuasiIso φ'] :
QuasiIso (φ ≫ φ') where
lemma quasiIsoAt_of_comp_left (φ : K ⟶ L) (φ' : L ⟶ M) (i : ι) [K.HasHomology i]
[L.HasHomology i] [M.HasHomology i]
[hφ : QuasiIsoAt φ i] [hφφ' : QuasiIsoAt (φ ≫ φ') i] :
QuasiIsoAt φ' i := by
rw [quasiIsoAt_iff_isIso_homologyMap] at hφ hφφ' ⊢
rw [homologyMap_comp] at hφφ'
exact IsIso.of_isIso_comp_left (homologyMap φ i) (homologyMap φ' i)
lemma quasiIsoAt_iff_comp_left (φ : K ⟶ L) (φ' : L ⟶ M) (i : ι) [K.HasHomology i]
[L.HasHomology i] [M.HasHomology i]
[hφ : QuasiIsoAt φ i] :
QuasiIsoAt (φ ≫ φ') i ↔ QuasiIsoAt φ' i := by
constructor
· intro
exact quasiIsoAt_of_comp_left φ φ' i
· intro
infer_instance
lemma quasiIso_iff_comp_left (φ : K ⟶ L) (φ' : L ⟶ M) [∀ i, K.HasHomology i]
[∀ i, L.HasHomology i] [∀ i, M.HasHomology i]
[hφ : QuasiIso φ] :
QuasiIso (φ ≫ φ') ↔ QuasiIso φ' := by
simp only [quasiIso_iff, quasiIsoAt_iff_comp_left φ φ']
lemma quasiIso_of_comp_left (φ : K ⟶ L) (φ' : L ⟶ M) [∀ i, K.HasHomology i]
[∀ i, L.HasHomology i] [∀ i, M.HasHomology i]
[hφ : QuasiIso φ] [hφφ' : QuasiIso (φ ≫ φ')] :
QuasiIso φ' := by
rw [← quasiIso_iff_comp_left φ φ']
infer_instance
lemma quasiIsoAt_of_comp_right (φ : K ⟶ L) (φ' : L ⟶ M) (i : ι) [K.HasHomology i]
[L.HasHomology i] [M.HasHomology i]
[hφ' : QuasiIsoAt φ' i] [hφφ' : QuasiIsoAt (φ ≫ φ') i] :
QuasiIsoAt φ i := by
rw [quasiIsoAt_iff_isIso_homologyMap] at hφ' hφφ' ⊢
rw [homologyMap_comp] at hφφ'
exact IsIso.of_isIso_comp_right (homologyMap φ i) (homologyMap φ' i)
lemma quasiIsoAt_iff_comp_right (φ : K ⟶ L) (φ' : L ⟶ M) (i : ι) [K.HasHomology i]
[L.HasHomology i] [M.HasHomology i]
[hφ' : QuasiIsoAt φ' i] :
QuasiIsoAt (φ ≫ φ') i ↔ QuasiIsoAt φ i := by
constructor
· intro
exact quasiIsoAt_of_comp_right φ φ' i
· intro
infer_instance
lemma quasiIso_iff_comp_right (φ : K ⟶ L) (φ' : L ⟶ M) [∀ i, K.HasHomology i]
[∀ i, L.HasHomology i] [∀ i, M.HasHomology i]
[hφ' : QuasiIso φ'] :
QuasiIso (φ ≫ φ') ↔ QuasiIso φ := by
simp only [quasiIso_iff, quasiIsoAt_iff_comp_right φ φ']
lemma quasiIso_of_comp_right (φ : K ⟶ L) (φ' : L ⟶ M) [∀ i, K.HasHomology i]
[∀ i, L.HasHomology i] [∀ i, M.HasHomology i]
[hφ : QuasiIso φ'] [hφφ' : QuasiIso (φ ≫ φ')] :
QuasiIso φ := by
rw [← quasiIso_iff_comp_right φ φ']
infer_instance
lemma quasiIso_iff_of_arrow_mk_iso (φ : K ⟶ L) (φ' : K' ⟶ L') (e : Arrow.mk φ ≅ Arrow.mk φ')
[∀ i, K.HasHomology i] [∀ i, L.HasHomology i]
[∀ i, K'.HasHomology i] [∀ i, L'.HasHomology i] :
QuasiIso φ ↔ QuasiIso φ' := by
simp [← quasiIso_iff_comp_left (show K' ⟶ K from e.inv.left) φ,
← quasiIso_iff_comp_right φ' (show L' ⟶ L from e.inv.right)]
lemma quasiIso_of_arrow_mk_iso (φ : K ⟶ L) (φ' : K' ⟶ L') (e : Arrow.mk φ ≅ Arrow.mk φ')
[∀ i, K.HasHomology i] [∀ i, L.HasHomology i]
[∀ i, K'.HasHomology i] [∀ i, L'.HasHomology i]
[hφ : QuasiIso φ] : QuasiIso φ' := by
simpa only [← quasiIso_iff_of_arrow_mk_iso φ φ' e]
lemma quasiIso_of_retractArrow {f : K ⟶ L} {f' : K' ⟶ L'}
(h : RetractArrow f f') [∀ i, K.HasHomology i] [∀ i, L.HasHomology i]
[∀ i, K'.HasHomology i] [∀ i, L'.HasHomology i] [QuasiIso f'] :
QuasiIso f where
quasiIsoAt i := quasiIsoAt_of_retract h i
namespace HomologicalComplex
| section PreservesHomology
variable {C₁ C₂ : Type*} [Category C₁] [Category C₂] [Preadditive C₁] [Preadditive C₂]
{K L : HomologicalComplex C₁ c} (φ : K ⟶ L) (F : C₁ ⥤ C₂) [F.Additive]
[F.PreservesHomology]
section
| Mathlib/Algebra/Homology/QuasiIso.lean | 245 | 251 |
/-
Copyright (c) 2022 Alex J. Best. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Alex J. Best, Yaël Dillies
-/
import Mathlib.Algebra.Order.Archimedean.Hom
import Mathlib.Algebra.Order.Group.Pointwise.CompleteLattice
/-!
# Conditionally complete linear ordered fields
This file shows that the reals are unique, or, more formally, given a type satisfying the common
axioms of the reals (field, conditionally complete, linearly ordered) that there is an isomorphism
preserving these properties to the reals. This is `LinearOrderedField.inducedOrderRingIso` for `ℚ`.
Moreover this isomorphism is unique.
We introduce definitions of conditionally complete linear ordered fields, and show all such are
archimedean. We also construct the natural map from a `LinearOrderedField` to such a field.
## Main definitions
* `ConditionallyCompleteLinearOrderedField`: A field satisfying the standard axiomatization of
the real numbers, being a Dedekind complete and linear ordered field.
* `LinearOrderedField.inducedMap`: A (unique) map from any archimedean linear ordered field to a
conditionally complete linear ordered field. Various bundlings are available.
## Main results
* `LinearOrderedField.uniqueOrderRingHom` : Uniqueness of `OrderRingHom`s from an archimedean
linear ordered field to a conditionally complete linear ordered field.
* `LinearOrderedField.uniqueOrderRingIso` : Uniqueness of `OrderRingIso`s between two
conditionally complete linearly ordered fields.
## References
* https://mathoverflow.net/questions/362991/
who-first-characterized-the-real-numbers-as-the-unique-complete-ordered-field
## Tags
reals, conditionally complete, ordered field, uniqueness
-/
variable {F α β γ : Type*}
noncomputable section
open Function Rat Set
open scoped Pointwise
/-- A field which is both linearly ordered and conditionally complete with respect to the order.
This axiomatizes the reals. -/
-- @[protect_proj] -- Porting note: does not exist anymore
class ConditionallyCompleteLinearOrderedField (α : Type*) extends
Field α, ConditionallyCompleteLinearOrder α where
-- extends `IsStrictOrderedRing α` produces
-- (kernel) declaration has free variables
-- 'ConditionallyCompleteLinearOrderedField.toIsStrictOrderedRing'
[toIsStrictOrderedRing : IsStrictOrderedRing α]
attribute [instance] ConditionallyCompleteLinearOrderedField.toIsStrictOrderedRing
-- see Note [lower instance priority]
/-- Any conditionally complete linearly ordered field is archimedean. -/
instance (priority := 100) ConditionallyCompleteLinearOrderedField.to_archimedean
[ConditionallyCompleteLinearOrderedField α] : Archimedean α :=
archimedean_iff_nat_lt.2
(by
by_contra! h
obtain ⟨x, h⟩ := h
have := csSup_le (range_nonempty Nat.cast)
(forall_mem_range.2 fun m =>
le_sub_iff_add_le.2 <| le_csSup ⟨x, forall_mem_range.2 h⟩ ⟨m+1, Nat.cast_succ m⟩)
linarith)
namespace LinearOrderedField
/-!
### Rational cut map
The idea is that a conditionally complete linear ordered field is fully characterized by its copy of
the rationals. Hence we define `LinearOrderedField.cutMap β : α → Set β` which sends `a : α` to the
"rationals in `β`" that are less than `a`.
-/
section CutMap
variable [Field α] [LinearOrder α]
section DivisionRing
variable (β) [DivisionRing β] {a a₁ a₂ : α} {b : β} {q : ℚ}
/-- The lower cut of rationals inside a linear ordered field that are less than a given element of
another linear ordered field. -/
def cutMap (a : α) : Set β :=
(Rat.cast : ℚ → β) '' {t | ↑t < a}
theorem cutMap_mono (h : a₁ ≤ a₂) : cutMap β a₁ ⊆ cutMap β a₂ := image_subset _ fun _ => h.trans_lt'
variable {β}
@[simp]
theorem mem_cutMap_iff : b ∈ cutMap β a ↔ ∃ q : ℚ, (q : α) < a ∧ (q : β) = b := Iff.rfl
theorem coe_mem_cutMap_iff [CharZero β] : (q : β) ∈ cutMap β a ↔ (q : α) < a :=
Rat.cast_injective.mem_set_image
theorem cutMap_self (a : α) : cutMap α a = Iio a ∩ range (Rat.cast : ℚ → α) := by
ext
constructor
· rintro ⟨q, h, rfl⟩
exact ⟨h, q, rfl⟩
· rintro ⟨h, q, rfl⟩
exact ⟨q, h, rfl⟩
end DivisionRing
variable (β) [IsStrictOrderedRing α] [Field β] [LinearOrder β] [IsStrictOrderedRing β]
{a a₁ a₂ : α} {b : β} {q : ℚ}
theorem cutMap_coe (q : ℚ) : cutMap β (q : α) = Rat.cast '' {r : ℚ | (r : β) < q} := by
simp_rw [cutMap, Rat.cast_lt]
variable [Archimedean α]
omit [LinearOrder β] [IsStrictOrderedRing β] in
theorem cutMap_nonempty (a : α) : (cutMap β a).Nonempty :=
Nonempty.image _ <| exists_rat_lt a
theorem cutMap_bddAbove (a : α) : BddAbove (cutMap β a) := by
obtain ⟨q, hq⟩ := exists_rat_gt a
exact ⟨q, forall_mem_image.2 fun r hr => mod_cast (hq.trans' hr).le⟩
theorem cutMap_add (a b : α) : cutMap β (a + b) = cutMap β a + cutMap β b := by
refine (image_subset_iff.2 fun q hq => ?_).antisymm ?_
· rw [mem_setOf_eq, ← sub_lt_iff_lt_add] at hq
obtain ⟨q₁, hq₁q, hq₁ab⟩ := exists_rat_btwn hq
refine ⟨q₁, by rwa [coe_mem_cutMap_iff], q - q₁, ?_, add_sub_cancel _ _⟩
norm_cast
rw [coe_mem_cutMap_iff]
exact mod_cast sub_lt_comm.mp hq₁q
· rintro _ ⟨_, ⟨qa, ha, rfl⟩, _, ⟨qb, hb, rfl⟩, rfl⟩
-- After https://github.com/leanprover/lean4/pull/2734, `norm_cast` needs help with beta reduction.
refine ⟨qa + qb, ?_, by beta_reduce; norm_cast⟩
rw [mem_setOf_eq, cast_add]
| exact add_lt_add ha hb
end CutMap
/-!
### Induced map
`LinearOrderedField.cutMap` spits out a `Set β`. To get something in `β`, we now take the supremum.
-/
section InducedMap
| Mathlib/Algebra/Order/CompleteField.lean | 149 | 161 |
/-
Copyright (c) 2019 Jan-David Salchow. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jan-David Salchow, Sébastien Gouëzel, Jean Lo
-/
import Mathlib.Algebra.Algebra.Tower
import Mathlib.Analysis.LocallyConvex.WithSeminorms
import Mathlib.Topology.Algebra.Module.StrongTopology
import Mathlib.Analysis.Normed.Operator.LinearIsometry
import Mathlib.Analysis.Normed.Operator.ContinuousLinearMap
import Mathlib.Tactic.SuppressCompilation
/-!
# Operator norm on the space of continuous linear maps
Define the operator (semi)-norm on the space of continuous (semi)linear maps between (semi)-normed
spaces, and prove its basic properties. In particular, show that this space is itself a semi-normed
space.
Since a lot of elementary properties don't require `‖x‖ = 0 → x = 0` we start setting up the
theory for `SeminormedAddCommGroup`. Later we will specialize to `NormedAddCommGroup` in the
file `NormedSpace.lean`.
Note that most of statements that apply to semilinear maps only hold when the ring homomorphism
is isometric, as expressed by the typeclass `[RingHomIsometric σ]`.
-/
suppress_compilation
open Bornology
open Filter hiding map_smul
open scoped NNReal Topology Uniformity
-- the `ₗ` subscript variables are for special cases about linear (as opposed to semilinear) maps
variable {𝕜 𝕜₂ 𝕜₃ E F Fₗ G 𝓕 : Type*}
section SemiNormed
open Metric ContinuousLinearMap
variable [SeminormedAddCommGroup E] [SeminormedAddCommGroup F] [SeminormedAddCommGroup Fₗ]
[SeminormedAddCommGroup G]
variable [NontriviallyNormedField 𝕜] [NontriviallyNormedField 𝕜₂] [NontriviallyNormedField 𝕜₃]
[NormedSpace 𝕜 E] [NormedSpace 𝕜₂ F] [NormedSpace 𝕜 Fₗ] [NormedSpace 𝕜₃ G]
{σ₁₂ : 𝕜 →+* 𝕜₂} {σ₂₃ : 𝕜₂ →+* 𝕜₃} {σ₁₃ : 𝕜 →+* 𝕜₃} [RingHomCompTriple σ₁₂ σ₂₃ σ₁₃]
variable [FunLike 𝓕 E F]
/-- If `‖x‖ = 0` and `f` is continuous then `‖f x‖ = 0`. -/
theorem norm_image_of_norm_zero [SemilinearMapClass 𝓕 σ₁₂ E F] (f : 𝓕) (hf : Continuous f) {x : E}
(hx : ‖x‖ = 0) : ‖f x‖ = 0 := by
rw [← mem_closure_zero_iff_norm, ← specializes_iff_mem_closure, ← map_zero f] at *
exact hx.map hf
section
variable [RingHomIsometric σ₁₂]
theorem SemilinearMapClass.bound_of_shell_semi_normed [SemilinearMapClass 𝓕 σ₁₂ E F] (f : 𝓕)
{ε C : ℝ} (ε_pos : 0 < ε) {c : 𝕜} (hc : 1 < ‖c‖)
(hf : ∀ x, ε / ‖c‖ ≤ ‖x‖ → ‖x‖ < ε → ‖f x‖ ≤ C * ‖x‖) {x : E} (hx : ‖x‖ ≠ 0) :
‖f x‖ ≤ C * ‖x‖ :=
(normSeminorm 𝕜 E).bound_of_shell ((normSeminorm 𝕜₂ F).comp ⟨⟨f, map_add f⟩, map_smulₛₗ f⟩)
ε_pos hc hf hx
/-- A continuous linear map between seminormed spaces is bounded when the field is nontrivially
normed. The continuity ensures boundedness on a ball of some radius `ε`. The nontriviality of the
norm is then used to rescale any element into an element of norm in `[ε/C, ε]`, whose image has a
controlled norm. The norm control for the original element follows by rescaling. -/
theorem SemilinearMapClass.bound_of_continuous [SemilinearMapClass 𝓕 σ₁₂ E F] (f : 𝓕)
(hf : Continuous f) : ∃ C, 0 < C ∧ ∀ x : E, ‖f x‖ ≤ C * ‖x‖ :=
let φ : E →ₛₗ[σ₁₂] F := ⟨⟨f, map_add f⟩, map_smulₛₗ f⟩
((normSeminorm 𝕜₂ F).comp φ).bound_of_continuous_normedSpace (continuous_norm.comp hf)
end
namespace ContinuousLinearMap
theorem bound [RingHomIsometric σ₁₂] (f : E →SL[σ₁₂] F) : ∃ C, 0 < C ∧ ∀ x : E, ‖f x‖ ≤ C * ‖x‖ :=
SemilinearMapClass.bound_of_continuous f f.2
section
open Filter
variable (𝕜 E)
/-- Given a unit-length element `x` of a normed space `E` over a field `𝕜`, the natural linear
isometry map from `𝕜` to `E` by taking multiples of `x`. -/
def _root_.LinearIsometry.toSpanSingleton {v : E} (hv : ‖v‖ = 1) : 𝕜 →ₗᵢ[𝕜] E :=
{ LinearMap.toSpanSingleton 𝕜 E v with norm_map' := fun x => by simp [norm_smul, hv] }
variable {𝕜 E}
@[simp]
theorem _root_.LinearIsometry.toSpanSingleton_apply {v : E} (hv : ‖v‖ = 1) (a : 𝕜) :
LinearIsometry.toSpanSingleton 𝕜 E hv a = a • v :=
rfl
@[simp]
theorem _root_.LinearIsometry.coe_toSpanSingleton {v : E} (hv : ‖v‖ = 1) :
(LinearIsometry.toSpanSingleton 𝕜 E hv).toLinearMap = LinearMap.toSpanSingleton 𝕜 E v :=
rfl
end
section OpNorm
open Set Real
/-- The operator norm of a continuous linear map is the inf of all its bounds. -/
def opNorm (f : E →SL[σ₁₂] F) :=
sInf { c | 0 ≤ c ∧ ∀ x, ‖f x‖ ≤ c * ‖x‖ }
instance hasOpNorm : Norm (E →SL[σ₁₂] F) :=
⟨opNorm⟩
theorem norm_def (f : E →SL[σ₁₂] F) : ‖f‖ = sInf { c | 0 ≤ c ∧ ∀ x, ‖f x‖ ≤ c * ‖x‖ } :=
rfl
-- So that invocations of `le_csInf` make sense: we show that the set of
-- bounds is nonempty and bounded below.
theorem bounds_nonempty [RingHomIsometric σ₁₂] {f : E →SL[σ₁₂] F} :
∃ c, c ∈ { c | 0 ≤ c ∧ ∀ x, ‖f x‖ ≤ c * ‖x‖ } :=
let ⟨M, hMp, hMb⟩ := f.bound
⟨M, le_of_lt hMp, hMb⟩
theorem bounds_bddBelow {f : E →SL[σ₁₂] F} : BddBelow { c | 0 ≤ c ∧ ∀ x, ‖f x‖ ≤ c * ‖x‖ } :=
⟨0, fun _ ⟨hn, _⟩ => hn⟩
theorem isLeast_opNorm [RingHomIsometric σ₁₂] (f : E →SL[σ₁₂] F) :
IsLeast {c | 0 ≤ c ∧ ∀ x, ‖f x‖ ≤ c * ‖x‖} ‖f‖ := by
refine IsClosed.isLeast_csInf ?_ bounds_nonempty bounds_bddBelow
simp only [setOf_and, setOf_forall]
refine isClosed_Ici.inter <| isClosed_iInter fun _ ↦ isClosed_le ?_ ?_ <;> continuity
/-- If one controls the norm of every `A x`, then one controls the norm of `A`. -/
theorem opNorm_le_bound (f : E →SL[σ₁₂] F) {M : ℝ} (hMp : 0 ≤ M) (hM : ∀ x, ‖f x‖ ≤ M * ‖x‖) :
‖f‖ ≤ M :=
csInf_le bounds_bddBelow ⟨hMp, hM⟩
/-- If one controls the norm of every `A x`, `‖x‖ ≠ 0`, then one controls the norm of `A`. -/
theorem opNorm_le_bound' (f : E →SL[σ₁₂] F) {M : ℝ} (hMp : 0 ≤ M)
(hM : ∀ x, ‖x‖ ≠ 0 → ‖f x‖ ≤ M * ‖x‖) : ‖f‖ ≤ M :=
opNorm_le_bound f hMp fun x =>
(ne_or_eq ‖x‖ 0).elim (hM x) fun h => by
simp only [h, mul_zero, norm_image_of_norm_zero f f.2 h, le_refl]
theorem opNorm_le_of_lipschitz {f : E →SL[σ₁₂] F} {K : ℝ≥0} (hf : LipschitzWith K f) : ‖f‖ ≤ K :=
f.opNorm_le_bound K.2 fun x => by
simpa only [dist_zero_right, f.map_zero] using hf.dist_le_mul x 0
theorem opNorm_eq_of_bounds {φ : E →SL[σ₁₂] F} {M : ℝ} (M_nonneg : 0 ≤ M)
(h_above : ∀ x, ‖φ x‖ ≤ M * ‖x‖) (h_below : ∀ N ≥ 0, (∀ x, ‖φ x‖ ≤ N * ‖x‖) → M ≤ N) :
‖φ‖ = M :=
le_antisymm (φ.opNorm_le_bound M_nonneg h_above)
((le_csInf_iff ContinuousLinearMap.bounds_bddBelow ⟨M, M_nonneg, h_above⟩).mpr
fun N ⟨N_nonneg, hN⟩ => h_below N N_nonneg hN)
theorem opNorm_neg (f : E →SL[σ₁₂] F) : ‖-f‖ = ‖f‖ := by simp only [norm_def, neg_apply, norm_neg]
theorem opNorm_nonneg (f : E →SL[σ₁₂] F) : 0 ≤ ‖f‖ :=
Real.sInf_nonneg fun _ ↦ And.left
/-- The norm of the `0` operator is `0`. -/
theorem opNorm_zero : ‖(0 : E →SL[σ₁₂] F)‖ = 0 :=
le_antisymm (opNorm_le_bound _ le_rfl fun _ ↦ by simp) (opNorm_nonneg _)
/-- The norm of the identity is at most `1`. It is in fact `1`, except when the space is trivial
where it is `0`. It means that one can not do better than an inequality in general. -/
theorem norm_id_le : ‖id 𝕜 E‖ ≤ 1 :=
opNorm_le_bound _ zero_le_one fun x => by simp
section
variable [RingHomIsometric σ₁₂] [RingHomIsometric σ₂₃] (f g : E →SL[σ₁₂] F) (h : F →SL[σ₂₃] G)
(x : E)
/-- The fundamental property of the operator norm: `‖f x‖ ≤ ‖f‖ * ‖x‖`. -/
theorem le_opNorm : ‖f x‖ ≤ ‖f‖ * ‖x‖ := (isLeast_opNorm f).1.2 x
theorem dist_le_opNorm (x y : E) : dist (f x) (f y) ≤ ‖f‖ * dist x y := by
simp_rw [dist_eq_norm, ← map_sub, f.le_opNorm]
theorem le_of_opNorm_le_of_le {x} {a b : ℝ} (hf : ‖f‖ ≤ a) (hx : ‖x‖ ≤ b) :
‖f x‖ ≤ a * b :=
(f.le_opNorm x).trans <| by gcongr; exact (opNorm_nonneg f).trans hf
theorem le_opNorm_of_le {c : ℝ} {x} (h : ‖x‖ ≤ c) : ‖f x‖ ≤ ‖f‖ * c :=
f.le_of_opNorm_le_of_le le_rfl h
theorem le_of_opNorm_le {c : ℝ} (h : ‖f‖ ≤ c) (x : E) : ‖f x‖ ≤ c * ‖x‖ :=
f.le_of_opNorm_le_of_le h le_rfl
theorem opNorm_le_iff {f : E →SL[σ₁₂] F} {M : ℝ} (hMp : 0 ≤ M) :
‖f‖ ≤ M ↔ ∀ x, ‖f x‖ ≤ M * ‖x‖ :=
⟨f.le_of_opNorm_le, opNorm_le_bound f hMp⟩
theorem ratio_le_opNorm : ‖f x‖ / ‖x‖ ≤ ‖f‖ :=
div_le_of_le_mul₀ (norm_nonneg _) f.opNorm_nonneg (le_opNorm _ _)
/-- The image of the unit ball under a continuous linear map is bounded. -/
theorem unit_le_opNorm : ‖x‖ ≤ 1 → ‖f x‖ ≤ ‖f‖ :=
mul_one ‖f‖ ▸ f.le_opNorm_of_le
theorem opNorm_le_of_shell {f : E →SL[σ₁₂] F} {ε C : ℝ} (ε_pos : 0 < ε) (hC : 0 ≤ C) {c : 𝕜}
(hc : 1 < ‖c‖) (hf : ∀ x, ε / ‖c‖ ≤ ‖x‖ → ‖x‖ < ε → ‖f x‖ ≤ C * ‖x‖) : ‖f‖ ≤ C :=
f.opNorm_le_bound' hC fun _ hx => SemilinearMapClass.bound_of_shell_semi_normed f ε_pos hc hf hx
theorem opNorm_le_of_ball {f : E →SL[σ₁₂] F} {ε : ℝ} {C : ℝ} (ε_pos : 0 < ε) (hC : 0 ≤ C)
(hf : ∀ x ∈ ball (0 : E) ε, ‖f x‖ ≤ C * ‖x‖) : ‖f‖ ≤ C := by
rcases NormedField.exists_one_lt_norm 𝕜 with ⟨c, hc⟩
refine opNorm_le_of_shell ε_pos hC hc fun x _ hx => hf x ?_
rwa [ball_zero_eq]
theorem opNorm_le_of_nhds_zero {f : E →SL[σ₁₂] F} {C : ℝ} (hC : 0 ≤ C)
(hf : ∀ᶠ x in 𝓝 (0 : E), ‖f x‖ ≤ C * ‖x‖) : ‖f‖ ≤ C :=
let ⟨_, ε0, hε⟩ := Metric.eventually_nhds_iff_ball.1 hf
opNorm_le_of_ball ε0 hC hε
theorem opNorm_le_of_shell' {f : E →SL[σ₁₂] F} {ε C : ℝ} (ε_pos : 0 < ε) (hC : 0 ≤ C) {c : 𝕜}
(hc : ‖c‖ < 1) (hf : ∀ x, ε * ‖c‖ ≤ ‖x‖ → ‖x‖ < ε → ‖f x‖ ≤ C * ‖x‖) : ‖f‖ ≤ C := by
by_cases h0 : c = 0
· refine opNorm_le_of_ball ε_pos hC fun x hx => hf x ?_ ?_
· simp [h0]
· rwa [ball_zero_eq] at hx
· rw [← inv_inv c, norm_inv, inv_lt_one₀ (norm_pos_iff.2 <| inv_ne_zero h0)] at hc
refine opNorm_le_of_shell ε_pos hC hc ?_
rwa [norm_inv, div_eq_mul_inv, inv_inv]
/-- For a continuous real linear map `f`, if one controls the norm of every `f x`, `‖x‖ = 1`, then
one controls the norm of `f`. -/
theorem opNorm_le_of_unit_norm [NormedSpace ℝ E] [NormedSpace ℝ F] {f : E →L[ℝ] F} {C : ℝ}
(hC : 0 ≤ C) (hf : ∀ x, ‖x‖ = 1 → ‖f x‖ ≤ C) : ‖f‖ ≤ C := by
refine opNorm_le_bound' f hC fun x hx => ?_
have H₁ : ‖‖x‖⁻¹ • x‖ = 1 := by rw [norm_smul, norm_inv, norm_norm, inv_mul_cancel₀ hx]
have H₂ := hf _ H₁
rwa [map_smul, norm_smul, norm_inv, norm_norm, ← div_eq_inv_mul, div_le_iff₀] at H₂
exact (norm_nonneg x).lt_of_ne' hx
/-- The operator norm satisfies the triangle inequality. -/
theorem opNorm_add_le : ‖f + g‖ ≤ ‖f‖ + ‖g‖ :=
(f + g).opNorm_le_bound (add_nonneg f.opNorm_nonneg g.opNorm_nonneg) fun x =>
(norm_add_le_of_le (f.le_opNorm x) (g.le_opNorm x)).trans_eq (add_mul _ _ _).symm
/-- If there is an element with norm different from `0`, then the norm of the identity equals `1`.
(Since we are working with seminorms supposing that the space is non-trivial is not enough.) -/
theorem norm_id_of_nontrivial_seminorm (h : ∃ x : E, ‖x‖ ≠ 0) : ‖id 𝕜 E‖ = 1 :=
le_antisymm norm_id_le <| by
let ⟨x, hx⟩ := h
have := (id 𝕜 E).ratio_le_opNorm x
rwa [id_apply, div_self hx] at this
theorem opNorm_smul_le {𝕜' : Type*} [NormedField 𝕜'] [NormedSpace 𝕜' F] [SMulCommClass 𝕜₂ 𝕜' F]
(c : 𝕜') (f : E →SL[σ₁₂] F) : ‖c • f‖ ≤ ‖c‖ * ‖f‖ :=
(c • f).opNorm_le_bound (mul_nonneg (norm_nonneg _) (opNorm_nonneg _)) fun _ => by
rw [smul_apply, norm_smul, mul_assoc]
exact mul_le_mul_of_nonneg_left (le_opNorm _ _) (norm_nonneg _)
/-- Operator seminorm on the space of continuous (semi)linear maps, as `Seminorm`.
We use this seminorm to define a `SeminormedGroup` structure on `E →SL[σ] F`,
but we have to override the projection `UniformSpace`
so that it is definitionally equal to the one coming from the topologies on `E` and `F`. -/
protected def seminorm : Seminorm 𝕜₂ (E →SL[σ₁₂] F) :=
.ofSMulLE norm opNorm_zero opNorm_add_le opNorm_smul_le
private lemma uniformity_eq_seminorm :
𝓤 (E →SL[σ₁₂] F) = ⨅ r > 0, 𝓟 {f | ‖f.1 - f.2‖ < r} := by
refine ContinuousLinearMap.seminorm (σ₁₂ := σ₁₂) (E := E) (F := F) |>.uniformity_eq_of_hasBasis
(ContinuousLinearMap.hasBasis_nhds_zero_of_basis Metric.nhds_basis_closedBall)
?_ fun (s, r) ⟨hs, hr⟩ ↦ ?_
· rcases NormedField.exists_lt_norm 𝕜 1 with ⟨c, hc⟩
refine ⟨‖c‖, ContinuousLinearMap.hasBasis_nhds_zero.mem_iff.2
⟨(closedBall 0 1, closedBall 0 1), ?_⟩⟩
suffices ∀ f : E →SL[σ₁₂] F, (∀ x, ‖x‖ ≤ 1 → ‖f x‖ ≤ 1) → ‖f‖ ≤ ‖c‖ by
simpa [NormedSpace.isVonNBounded_closedBall, closedBall_mem_nhds, subset_def] using this
intro f hf
refine opNorm_le_of_shell (f := f) one_pos (norm_nonneg c) hc fun x hcx hx ↦ ?_
exact (hf x hx.le).trans ((div_le_iff₀' <| one_pos.trans hc).1 hcx)
· rcases (NormedSpace.isVonNBounded_iff' _).1 hs with ⟨ε, hε⟩
| rcases exists_pos_mul_lt hr ε with ⟨δ, hδ₀, hδ⟩
refine ⟨δ, hδ₀, fun f hf x hx ↦ ?_⟩
simp only [Seminorm.mem_ball_zero, mem_closedBall_zero_iff] at hf ⊢
rw [mul_comm] at hδ
exact le_trans (le_of_opNorm_le_of_le _ hf.le (hε _ hx)) hδ.le
instance toPseudoMetricSpace : PseudoMetricSpace (E →SL[σ₁₂] F) := .replaceUniformity
| Mathlib/Analysis/NormedSpace/OperatorNorm/Basic.lean | 307 | 313 |
/-
Copyright (c) 2022 Yaël Dillies, Bhavik Mehta. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies, Bhavik Mehta
-/
import Mathlib.Combinatorics.SimpleGraph.Regularity.Bound
import Mathlib.Combinatorics.SimpleGraph.Regularity.Equitabilise
import Mathlib.Combinatorics.SimpleGraph.Regularity.Uniform
/-!
# Chunk of the increment partition for Szemerédi Regularity Lemma
In the proof of Szemerédi Regularity Lemma, we need to partition each part of a starting partition
to increase the energy. This file defines those partitions of parts and shows that they locally
increase the energy.
This entire file is internal to the proof of Szemerédi Regularity Lemma.
## Main declarations
* `SzemerediRegularity.chunk`: The partition of a part of the starting partition.
* `SzemerediRegularity.edgeDensity_chunk_uniform`: `chunk` does not locally decrease the edge
density between uniform parts too much.
* `SzemerediRegularity.edgeDensity_chunk_not_uniform`: `chunk` locally increases the edge density
between non-uniform parts.
## TODO
Once ported to mathlib4, this file will be a great golfing ground for Heather's new tactic
`gcongr`.
## References
[Yaël Dillies, Bhavik Mehta, *Formalising Szemerédi’s Regularity Lemma in Lean*][srl_itp]
-/
open Finpartition Finset Fintype Rel Nat
open scoped SzemerediRegularity.Positivity
namespace SzemerediRegularity
variable {α : Type*} [Fintype α] [DecidableEq α] {P : Finpartition (univ : Finset α)}
(hP : P.IsEquipartition) (G : SimpleGraph α) [DecidableRel G.Adj] (ε : ℝ) {U : Finset α}
(hU : U ∈ P.parts) (V : Finset α)
local notation3 "m" => (card α / stepBound #P.parts : ℕ)
/-!
### Definitions
We define `chunk`, the partition of a part, and `star`, the sets of parts of `chunk` that are
contained in the corresponding witness of non-uniformity.
-/
/-- The portion of `SzemerediRegularity.increment` which partitions `U`. -/
noncomputable def chunk : Finpartition U :=
if hUcard : #U = m * 4 ^ #P.parts + (card α / #P.parts - m * 4 ^ #P.parts) then
(atomise U <| P.nonuniformWitnesses G ε U).equitabilise <| card_aux₁ hUcard
else (atomise U <| P.nonuniformWitnesses G ε U).equitabilise <| card_aux₂ hP hU hUcard
-- `hP` and `hU` are used to get that `U` has size
-- `m * 4 ^ #P.parts + a or m * 4 ^ #P.parts + a + 1`
/-- The portion of `SzemerediRegularity.chunk` which is contained in the witness of non-uniformity
of `U` and `V`. -/
noncomputable def star (V : Finset α) : Finset (Finset α) :=
{A ∈ (chunk hP G ε hU).parts | A ⊆ G.nonuniformWitness ε U V}
/-!
### Density estimates
We estimate the density between parts of `chunk`.
-/
theorem biUnion_star_subset_nonuniformWitness :
(star hP G ε hU V).biUnion id ⊆ G.nonuniformWitness ε U V :=
biUnion_subset_iff_forall_subset.2 fun _ hA => (mem_filter.1 hA).2
variable {hP G ε hU V} {𝒜 : Finset (Finset α)} {s : Finset α}
theorem star_subset_chunk : star hP G ε hU V ⊆ (chunk hP G ε hU).parts :=
filter_subset _ _
private theorem card_nonuniformWitness_sdiff_biUnion_star (hV : V ∈ P.parts) (hUV : U ≠ V)
(h₂ : ¬G.IsUniform ε U V) :
#(G.nonuniformWitness ε U V \ (star hP G ε hU V).biUnion id) ≤ 2 ^ (#P.parts - 1) * m := by
have hX : G.nonuniformWitness ε U V ∈ P.nonuniformWitnesses G ε U :=
nonuniformWitness_mem_nonuniformWitnesses h₂ hV hUV
have q : G.nonuniformWitness ε U V \ (star hP G ε hU V).biUnion id ⊆
{B ∈ (atomise U <| P.nonuniformWitnesses G ε U).parts |
B ⊆ G.nonuniformWitness ε U V ∧ B.Nonempty}.biUnion
fun B => B \ {A ∈ (chunk hP G ε hU).parts | A ⊆ B}.biUnion id := by
intro x hx
rw [← biUnion_filter_atomise hX (G.nonuniformWitness_subset h₂), star, mem_sdiff,
mem_biUnion] at hx
simp only [not_exists, mem_biUnion, and_imp, exists_prop, mem_filter,
not_and, mem_sdiff, id, mem_sdiff] at hx ⊢
obtain ⟨⟨B, hB₁, hB₂⟩, hx⟩ := hx
exact ⟨B, hB₁, hB₂, fun A hA AB => hx A hA <| AB.trans hB₁.2.1⟩
apply (card_le_card q).trans (card_biUnion_le.trans _)
trans ∑ B ∈ (atomise U <| P.nonuniformWitnesses G ε U).parts with
B ⊆ G.nonuniformWitness ε U V ∧ B.Nonempty, m
· suffices ∀ B ∈ (atomise U <| P.nonuniformWitnesses G ε U).parts,
#(B \ {A ∈ (chunk hP G ε hU).parts | A ⊆ B}.biUnion id) ≤ m by
exact sum_le_sum fun B hB => this B <| filter_subset _ _ hB
intro B hB
unfold chunk
split_ifs with h₁
· convert card_parts_equitabilise_subset_le _ (card_aux₁ h₁) hB
· convert card_parts_equitabilise_subset_le _ (card_aux₂ hP hU h₁) hB
rw [sum_const]
refine mul_le_mul_right' ?_ _
have t := card_filter_atomise_le_two_pow (s := U) hX
refine t.trans (pow_right_mono₀ (by norm_num) <| tsub_le_tsub_right ?_ _)
exact card_image_le.trans (card_le_card <| filter_subset _ _)
private theorem one_sub_eps_mul_card_nonuniformWitness_le_card_star (hV : V ∈ P.parts)
(hUV : U ≠ V) (hunif : ¬G.IsUniform ε U V) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5)
(hε₁ : ε ≤ 1) :
(1 - ε / 10) * #(G.nonuniformWitness ε U V) ≤ #((star hP G ε hU V).biUnion id) := by
have hP₁ : 0 < #P.parts := Finset.card_pos.2 ⟨_, hU⟩
have : (↑2 ^ #P.parts : ℝ) * m / (#U * ε) ≤ ε / 10 := by
rw [← div_div, div_le_iff₀']
swap
· sz_positivity
refine le_of_mul_le_mul_left ?_ (pow_pos zero_lt_two #P.parts)
calc
↑2 ^ #P.parts * ((↑2 ^ #P.parts * m : ℝ) / #U) =
((2 : ℝ) * 2) ^ #P.parts * m / #U := by
rw [mul_pow, ← mul_div_assoc, mul_assoc]
_ = ↑4 ^ #P.parts * m / #U := by norm_num
_ ≤ 1 := div_le_one_of_le₀ (pow_mul_m_le_card_part hP hU) (cast_nonneg _)
_ ≤ ↑2 ^ #P.parts * ε ^ 2 / 10 := by
refine (one_le_sq_iff₀ <| by positivity).1 ?_
rw [div_pow, mul_pow, pow_right_comm, ← pow_mul ε,
one_le_div (sq_pos_of_ne_zero <| by norm_num)]
calc
(↑10 ^ 2) = 100 := by norm_num
_ ≤ ↑4 ^ #P.parts * ε ^ 5 := hPε
_ ≤ ↑4 ^ #P.parts * ε ^ 4 :=
(mul_le_mul_of_nonneg_left (pow_le_pow_of_le_one (by sz_positivity) hε₁ <| le_succ _)
(by positivity))
_ = (↑2 ^ 2) ^ #P.parts * ε ^ (2 * 2) := by norm_num
_ = ↑2 ^ #P.parts * (ε * (ε / 10)) := by rw [mul_div_assoc, sq, mul_div_assoc]
calc
(↑1 - ε / 10) * #(G.nonuniformWitness ε U V) ≤
(↑1 - ↑2 ^ #P.parts * m / (#U * ε)) * #(G.nonuniformWitness ε U V) :=
mul_le_mul_of_nonneg_right (sub_le_sub_left this _) (cast_nonneg _)
_ = #(G.nonuniformWitness ε U V) -
↑2 ^ #P.parts * m / (#U * ε) * #(G.nonuniformWitness ε U V) := by
rw [sub_mul, one_mul]
_ ≤ #(G.nonuniformWitness ε U V) - ↑2 ^ (#P.parts - 1) * m := by
refine sub_le_sub_left ?_ _
have : (2 : ℝ) ^ #P.parts = ↑2 ^ (#P.parts - 1) * 2 := by
rw [← _root_.pow_succ, tsub_add_cancel_of_le (succ_le_iff.2 hP₁)]
rw [← mul_div_right_comm, this, mul_right_comm _ (2 : ℝ), mul_assoc, le_div_iff₀]
· refine mul_le_mul_of_nonneg_left ?_ (by positivity)
exact (G.le_card_nonuniformWitness hunif).trans
(le_mul_of_one_le_left (cast_nonneg _) one_le_two)
have := Finset.card_pos.mpr (P.nonempty_of_mem_parts hU)
sz_positivity
_ ≤ #((star hP G ε hU V).biUnion id) := by
rw [sub_le_comm, ←
cast_sub (card_le_card <| biUnion_star_subset_nonuniformWitness hP G ε hU V), ←
card_sdiff (biUnion_star_subset_nonuniformWitness hP G ε hU V)]
exact mod_cast card_nonuniformWitness_sdiff_biUnion_star hV hUV hunif
/-! ### `chunk` -/
theorem card_chunk (hm : m ≠ 0) : #(chunk hP G ε hU).parts = 4 ^ #P.parts := by
unfold chunk
split_ifs
· rw [card_parts_equitabilise _ _ hm, tsub_add_cancel_of_le]
exact le_of_lt a_add_one_le_four_pow_parts_card
· rw [card_parts_equitabilise _ _ hm, tsub_add_cancel_of_le a_add_one_le_four_pow_parts_card]
theorem card_eq_of_mem_parts_chunk (hs : s ∈ (chunk hP G ε hU).parts) :
#s = m ∨ #s = m + 1 := by
unfold chunk at hs
split_ifs at hs <;> exact card_eq_of_mem_parts_equitabilise hs
theorem m_le_card_of_mem_chunk_parts (hs : s ∈ (chunk hP G ε hU).parts) : m ≤ #s :=
(card_eq_of_mem_parts_chunk hs).elim ge_of_eq fun i => by simp [i]
theorem card_le_m_add_one_of_mem_chunk_parts (hs : s ∈ (chunk hP G ε hU).parts) : #s ≤ m + 1 :=
(card_eq_of_mem_parts_chunk hs).elim (fun i => by simp [i]) fun i => i.le
theorem card_biUnion_star_le_m_add_one_card_star_mul :
(#((star hP G ε hU V).biUnion id) : ℝ) ≤ #(star hP G ε hU V) * (m + 1) :=
mod_cast card_biUnion_le_card_mul _ _ _ fun _ hs =>
card_le_m_add_one_of_mem_chunk_parts <| star_subset_chunk hs
private theorem le_sum_card_subset_chunk_parts (h𝒜 : 𝒜 ⊆ (chunk hP G ε hU).parts) (hs : s ∈ 𝒜) :
(#𝒜 : ℝ) * #s * (m / (m + 1)) ≤ #(𝒜.sup id) := by
rw [mul_div_assoc', div_le_iff₀ coe_m_add_one_pos, mul_right_comm]
refine mul_le_mul ?_ ?_ (cast_nonneg _) (cast_nonneg _)
· rw [← (ofSubset _ h𝒜 rfl).sum_card_parts, ofSubset_parts, ← cast_mul, cast_le]
exact card_nsmul_le_sum _ _ _ fun x hx => m_le_card_of_mem_chunk_parts <| h𝒜 hx
· exact mod_cast card_le_m_add_one_of_mem_chunk_parts (h𝒜 hs)
private theorem sum_card_subset_chunk_parts_le (m_pos : (0 : ℝ) < m)
(h𝒜 : 𝒜 ⊆ (chunk hP G ε hU).parts) (hs : s ∈ 𝒜) :
(#(𝒜.sup id) : ℝ) ≤ #𝒜 * #s * ((m + 1) / m) := by
rw [sup_eq_biUnion, mul_div_assoc', le_div_iff₀ m_pos, mul_right_comm]
refine mul_le_mul ?_ ?_ (cast_nonneg _) (by positivity)
· norm_cast
refine card_biUnion_le_card_mul _ _ _ fun x hx => ?_
apply card_le_m_add_one_of_mem_chunk_parts (h𝒜 hx)
· exact mod_cast m_le_card_of_mem_chunk_parts (h𝒜 hs)
private theorem one_sub_le_m_div_m_add_one_sq [Nonempty α]
(hPα : #P.parts * 16 ^ #P.parts ≤ card α) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5) :
↑1 - ε ^ 5 / ↑50 ≤ (m / (m + 1 : ℝ)) ^ 2 := by
have : (m : ℝ) / (m + 1) = 1 - 1 / (m + 1) := by
rw [one_sub_div coe_m_add_one_pos.ne', add_sub_cancel_right]
rw [this, sub_sq, one_pow, mul_one]
refine le_trans ?_ (le_add_of_nonneg_right <| sq_nonneg _)
rw [sub_le_sub_iff_left, ← le_div_iff₀' (show (0 : ℝ) < 2 by norm_num), div_div,
one_div_le coe_m_add_one_pos, one_div_div]
· refine le_trans ?_ (le_add_of_nonneg_right zero_le_one)
norm_num
apply hundred_div_ε_pow_five_le_m hPα hPε
sz_positivity
private theorem m_add_one_div_m_le_one_add [Nonempty α]
(hPα : #P.parts * 16 ^ #P.parts ≤ card α) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5) (hε₁ : ε ≤ 1) :
((m + 1 : ℝ) / m) ^ 2 ≤ ↑1 + ε ^ 5 / 49 := by
have : 0 ≤ ε := by sz_positivity
rw [same_add_div (by sz_positivity)]
calc
_ ≤ (1 + ε ^ 5 / 100) ^ 2 := by
gcongr (1 + ?_) ^ 2
rw [← one_div_div (100 : ℝ)]
exact one_div_le_one_div_of_le (by sz_positivity) (hundred_div_ε_pow_five_le_m hPα hPε)
_ = 1 + ε ^ 5 * (50⁻¹ + ε ^ 5 / 10000) := by ring
_ ≤ 1 + ε ^ 5 * (50⁻¹ + 1 ^ 5 / 10000) := by gcongr
_ ≤ 1 + ε ^ 5 * 49⁻¹ := by gcongr; norm_num
_ = 1 + ε ^ 5 / 49 := by rw [div_eq_mul_inv]
private theorem density_sub_eps_le_sum_density_div_card [Nonempty α]
(hPα : #P.parts * 16 ^ #P.parts ≤ card α) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5)
{hU : U ∈ P.parts} {hV : V ∈ P.parts} {A B : Finset (Finset α)}
(hA : A ⊆ (chunk hP G ε hU).parts) (hB : B ⊆ (chunk hP G ε hV).parts) :
(G.edgeDensity (A.biUnion id) (B.biUnion id)) - ε ^ 5 / 50 ≤
(∑ ab ∈ A.product B, (G.edgeDensity ab.1 ab.2 : ℝ)) / (#A * #B) := by
have : ↑(G.edgeDensity (A.biUnion id) (B.biUnion id)) - ε ^ 5 / ↑50 ≤
(↑1 - ε ^ 5 / 50) * G.edgeDensity (A.biUnion id) (B.biUnion id) := by
rw [sub_mul, one_mul, sub_le_sub_iff_left]
refine mul_le_of_le_one_right (by sz_positivity) ?_
exact mod_cast G.edgeDensity_le_one _ _
refine this.trans ?_
conv_rhs => -- Porting note: LHS and RHS need separate treatment to get the desired form
simp only [SimpleGraph.edgeDensity_def, sum_div, Rat.cast_div, div_div]
conv_lhs =>
rw [SimpleGraph.edgeDensity_def, SimpleGraph.interedges, ← sup_eq_biUnion, ← sup_eq_biUnion,
Rel.card_interedges_finpartition _ (ofSubset _ hA rfl) (ofSubset _ hB rfl), ofSubset_parts,
ofSubset_parts]
simp only [cast_sum, sum_div, mul_sum, Rat.cast_sum, Rat.cast_div,
mul_div_left_comm ((1 : ℝ) - _)]
push_cast
apply sum_le_sum
simp only [and_imp, Prod.forall, mem_product]
rintro x y hx hy
rw [mul_mul_mul_comm, mul_comm (#x : ℝ), mul_comm (#y : ℝ), le_div_iff₀, mul_assoc]
· refine mul_le_of_le_one_right (cast_nonneg _) ?_
rw [div_mul_eq_mul_div, ← mul_assoc, mul_assoc]
refine div_le_one_of_le₀ ?_ (by positivity)
refine (mul_le_mul_of_nonneg_right (one_sub_le_m_div_m_add_one_sq hPα hPε) ?_).trans ?_
· exact mod_cast _root_.zero_le _
rw [sq, mul_mul_mul_comm, mul_comm ((m : ℝ) / _), mul_comm ((m : ℝ) / _)]
refine mul_le_mul ?_ ?_ ?_ (cast_nonneg _)
· apply le_sum_card_subset_chunk_parts hA hx
· apply le_sum_card_subset_chunk_parts hB hy
· positivity
refine mul_pos (mul_pos ?_ ?_) (mul_pos ?_ ?_) <;> rw [cast_pos, Finset.card_pos]
exacts [⟨_, hx⟩, nonempty_of_mem_parts _ (hA hx), ⟨_, hy⟩, nonempty_of_mem_parts _ (hB hy)]
private theorem sum_density_div_card_le_density_add_eps [Nonempty α]
(hPα : #P.parts * 16 ^ #P.parts ≤ card α) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5)
(hε₁ : ε ≤ 1) {hU : U ∈ P.parts} {hV : V ∈ P.parts} {A B : Finset (Finset α)}
(hA : A ⊆ (chunk hP G ε hU).parts) (hB : B ⊆ (chunk hP G ε hV).parts) :
(∑ ab ∈ A.product B, G.edgeDensity ab.1 ab.2 : ℝ) / (#A * #B) ≤
G.edgeDensity (A.biUnion id) (B.biUnion id) + ε ^ 5 / 49 := by
have : (↑1 + ε ^ 5 / ↑49) * G.edgeDensity (A.biUnion id) (B.biUnion id) ≤
G.edgeDensity (A.biUnion id) (B.biUnion id) + ε ^ 5 / 49 := by
rw [add_mul, one_mul, add_le_add_iff_left]
refine mul_le_of_le_one_right (by sz_positivity) ?_
exact mod_cast G.edgeDensity_le_one _ _
refine le_trans ?_ this
conv_lhs => -- Porting note: LHS and RHS need separate treatment to get the desired form
simp only [SimpleGraph.edgeDensity, edgeDensity, sum_div, Rat.cast_div, div_div]
conv_rhs =>
rw [SimpleGraph.edgeDensity, edgeDensity, ← sup_eq_biUnion, ← sup_eq_biUnion,
Rel.card_interedges_finpartition _ (ofSubset _ hA rfl) (ofSubset _ hB rfl)]
simp only [cast_sum, mul_sum, sum_div, Rat.cast_sum, Rat.cast_div,
mul_div_left_comm ((1 : ℝ) + _)]
push_cast
apply sum_le_sum
simp only [and_imp, Prod.forall, mem_product, show A.product B = A ×ˢ B by rfl]
intro x y hx hy
rw [mul_mul_mul_comm, mul_comm (#x : ℝ), mul_comm (#y : ℝ), div_le_iff₀, mul_assoc]
· refine le_mul_of_one_le_right (cast_nonneg _) ?_
rw [div_mul_eq_mul_div, one_le_div]
· refine le_trans ?_ (mul_le_mul_of_nonneg_right (m_add_one_div_m_le_one_add hPα hPε hε₁) ?_)
· rw [sq, mul_mul_mul_comm, mul_comm (_ / (m : ℝ)), mul_comm (_ / (m : ℝ))]
exact mul_le_mul (sum_card_subset_chunk_parts_le (by sz_positivity) hA hx)
(sum_card_subset_chunk_parts_le (by sz_positivity) hB hy) (by positivity) (by positivity)
· exact mod_cast _root_.zero_le _
rw [← cast_mul, cast_pos]
apply mul_pos <;> rw [Finset.card_pos, sup_eq_biUnion, biUnion_nonempty]
· exact ⟨_, hx, nonempty_of_mem_parts _ (hA hx)⟩
· exact ⟨_, hy, nonempty_of_mem_parts _ (hB hy)⟩
refine mul_pos (mul_pos ?_ ?_) (mul_pos ?_ ?_) <;> rw [cast_pos, Finset.card_pos]
exacts [⟨_, hx⟩, nonempty_of_mem_parts _ (hA hx), ⟨_, hy⟩, nonempty_of_mem_parts _ (hB hy)]
private theorem average_density_near_total_density [Nonempty α]
(hPα : #P.parts * 16 ^ #P.parts ≤ card α) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5)
(hε₁ : ε ≤ 1) {hU : U ∈ P.parts} {hV : V ∈ P.parts} {A B : Finset (Finset α)}
(hA : A ⊆ (chunk hP G ε hU).parts) (hB : B ⊆ (chunk hP G ε hV).parts) :
|(∑ ab ∈ A.product B, G.edgeDensity ab.1 ab.2 : ℝ) / (#A * #B) -
G.edgeDensity (A.biUnion id) (B.biUnion id)| ≤ ε ^ 5 / 49 := by
rw [abs_sub_le_iff]
constructor
· rw [sub_le_iff_le_add']
exact sum_density_div_card_le_density_add_eps hPα hPε hε₁ hA hB
suffices (G.edgeDensity (A.biUnion id) (B.biUnion id) : ℝ) -
(∑ ab ∈ A.product B, (G.edgeDensity ab.1 ab.2 : ℝ)) / (#A * #B) ≤ ε ^ 5 / 50 by
apply this.trans
gcongr <;> [sz_positivity; norm_num]
rw [sub_le_iff_le_add, ← sub_le_iff_le_add']
apply density_sub_eps_le_sum_density_div_card hPα hPε hA hB
private theorem edgeDensity_chunk_aux [Nonempty α] (hP)
(hPα : #P.parts * 16 ^ #P.parts ≤ card α) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5)
(hU : U ∈ P.parts) (hV : V ∈ P.parts) :
(G.edgeDensity U V : ℝ) ^ 2 - ε ^ 5 / ↑25 ≤
((∑ ab ∈ (chunk hP G ε hU).parts.product (chunk hP G ε hV).parts,
(G.edgeDensity ab.1 ab.2 : ℝ)) / ↑16 ^ #P.parts) ^ 2 := by
obtain hGε | hGε := le_total (G.edgeDensity U V : ℝ) (ε ^ 5 / 50)
· refine (sub_nonpos_of_le <| (sq_le ?_ ?_).trans <| hGε.trans ?_).trans (sq_nonneg _)
· exact mod_cast G.edgeDensity_nonneg _ _
· exact mod_cast G.edgeDensity_le_one _ _
· exact div_le_div_of_nonneg_left (by sz_positivity) (by norm_num) (by norm_num)
rw [← sub_nonneg] at hGε
have : 0 ≤ ε := by sz_positivity
calc
_ = G.edgeDensity U V ^ 2 - 1 * ε ^ 5 / 25 + 0 ^ 10 / 2500 := by ring
_ ≤ G.edgeDensity U V ^ 2 - G.edgeDensity U V * ε ^ 5 / 25 + ε ^ 10 / 2500 := by
gcongr; exact mod_cast G.edgeDensity_le_one ..
_ = (G.edgeDensity U V - ε ^ 5 / 50) ^ 2 := by ring
_ ≤ _ := by
gcongr
have rflU := Set.Subset.refl (chunk hP G ε hU).parts.toSet
have rflV := Set.Subset.refl (chunk hP G ε hV).parts.toSet
refine (le_trans ?_ <| density_sub_eps_le_sum_density_div_card hPα hPε rflU rflV).trans ?_
· rw [biUnion_parts, biUnion_parts]
· rw [card_chunk (m_pos hPα).ne', card_chunk (m_pos hPα).ne', ← cast_mul, ← mul_pow, cast_pow]
norm_cast
private theorem abs_density_star_sub_density_le_eps (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5)
(hε₁ : ε ≤ 1) {hU : U ∈ P.parts} {hV : V ∈ P.parts} (hUV' : U ≠ V) (hUV : ¬G.IsUniform ε U V) :
|(G.edgeDensity ((star hP G ε hU V).biUnion id) ((star hP G ε hV U).biUnion id) : ℝ) -
G.edgeDensity (G.nonuniformWitness ε U V) (G.nonuniformWitness ε V U)| ≤ ε / 5 := by
convert abs_edgeDensity_sub_edgeDensity_le_two_mul G.Adj
(biUnion_star_subset_nonuniformWitness hP G ε hU V)
(biUnion_star_subset_nonuniformWitness hP G ε hV U) (by sz_positivity)
(one_sub_eps_mul_card_nonuniformWitness_le_card_star hV hUV' hUV hPε hε₁)
(one_sub_eps_mul_card_nonuniformWitness_le_card_star hU hUV'.symm (fun hVU => hUV hVU.symm)
hPε hε₁) using 1
linarith
private theorem eps_le_card_star_div [Nonempty α] (hPα : #P.parts * 16 ^ #P.parts ≤ card α)
(hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5) (hε₁ : ε ≤ 1) (hU : U ∈ P.parts) (hV : V ∈ P.parts)
(hUV : U ≠ V) (hunif : ¬G.IsUniform ε U V) :
↑4 / ↑5 * ε ≤ #(star hP G ε hU V) / ↑4 ^ #P.parts := by
have hm : (0 : ℝ) ≤ 1 - (↑m)⁻¹ := sub_nonneg_of_le (inv_le_one_of_one_le₀ <| one_le_m_coe hPα)
have hε : 0 ≤ 1 - ε / 10 :=
sub_nonneg_of_le (div_le_one_of_le₀ (hε₁.trans <| by norm_num) <| by norm_num)
have hε₀ : 0 < ε := by sz_positivity
calc
4 / 5 * ε = (1 - 1 / 10) * (1 - 9⁻¹) * ε := by norm_num
_ ≤ (1 - ε / 10) * (1 - (↑m)⁻¹) * (#(G.nonuniformWitness ε U V) / #U) := by
gcongr
exacts [mod_cast (show 9 ≤ 100 by norm_num).trans (hundred_le_m hPα hPε hε₁),
(le_div_iff₀' <| cast_pos.2 (P.nonempty_of_mem_parts hU).card_pos).2 <|
G.le_card_nonuniformWitness hunif]
_ = (1 - ε / 10) * #(G.nonuniformWitness ε U V) * ((1 - (↑m)⁻¹) / #U) := by
rw [mul_assoc, mul_assoc, mul_div_left_comm]
_ ≤ #((star hP G ε hU V).biUnion id) * ((1 - (↑m)⁻¹) / #U) :=
(mul_le_mul_of_nonneg_right
(one_sub_eps_mul_card_nonuniformWitness_le_card_star hV hUV hunif hPε hε₁) (by positivity))
_ ≤ #(star hP G ε hU V) * (m + 1) * ((1 - (↑m)⁻¹) / #U) :=
(mul_le_mul_of_nonneg_right card_biUnion_star_le_m_add_one_card_star_mul (by positivity))
_ ≤ #(star hP G ε hU V) * (m + ↑1) * ((↑1 - (↑m)⁻¹) / (↑4 ^ #P.parts * m)) :=
(mul_le_mul_of_nonneg_left (div_le_div_of_nonneg_left hm (by sz_positivity) <|
pow_mul_m_le_card_part hP hU) (by positivity))
_ ≤ #(star hP G ε hU V) / ↑4 ^ #P.parts := by
rw [mul_assoc, mul_comm ((4 : ℝ) ^ #P.parts), ← div_div, ← mul_div_assoc, ← mul_comm_div]
refine mul_le_of_le_one_right (by positivity) ?_
have hm : (0 : ℝ) < m := by sz_positivity
rw [mul_div_assoc', div_le_one hm, ← one_div, one_sub_div hm.ne', mul_div_assoc',
div_le_iff₀ hm]
linarith
/-!
### Final bounds
Those inequalities are the end result of all this hard work.
-/
/-- Lower bound on the edge densities between non-uniform parts of `SzemerediRegularity.star`. -/
private theorem edgeDensity_star_not_uniform [Nonempty α]
(hPα : #P.parts * 16 ^ #P.parts ≤ card α) (hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5)
(hε₁ : ε ≤ 1) {hU : U ∈ P.parts} {hV : V ∈ P.parts} (hUVne : U ≠ V) (hUV : ¬G.IsUniform ε U V) :
↑3 / ↑4 * ε ≤
|(∑ ab ∈ (star hP G ε hU V).product (star hP G ε hV U), (G.edgeDensity ab.1 ab.2 : ℝ)) /
(#(star hP G ε hU V) * #(star hP G ε hV U)) -
(∑ ab ∈ (chunk hP G ε hU).parts.product (chunk hP G ε hV).parts,
(G.edgeDensity ab.1 ab.2 : ℝ)) / (16 : ℝ) ^ #P.parts| := by
rw [show (16 : ℝ) = ↑4 ^ 2 by norm_num, pow_right_comm, sq ((4 : ℝ) ^ _)]
set p : ℝ :=
(∑ ab ∈ (star hP G ε hU V).product (star hP G ε hV U), (G.edgeDensity ab.1 ab.2 : ℝ)) /
(#(star hP G ε hU V) * #(star hP G ε hV U))
set q : ℝ :=
(∑ ab ∈ (chunk hP G ε hU).parts.product (chunk hP G ε hV).parts,
(G.edgeDensity ab.1 ab.2 : ℝ)) / (↑4 ^ #P.parts * ↑4 ^ #P.parts)
set r : ℝ := ↑(G.edgeDensity ((star hP G ε hU V).biUnion id) ((star hP G ε hV U).biUnion id))
set s : ℝ := ↑(G.edgeDensity (G.nonuniformWitness ε U V) (G.nonuniformWitness ε V U))
set t : ℝ := ↑(G.edgeDensity U V)
have hrs : |r - s| ≤ ε / 5 := abs_density_star_sub_density_le_eps hPε hε₁ hUVne hUV
have hst : ε ≤ |s - t| := by
-- After https://github.com/leanprover/lean4/pull/2734, we need to do the zeta reduction before `mod_cast`.
unfold s t
exact mod_cast G.nonuniformWitness_spec hUVne hUV
have hpr : |p - r| ≤ ε ^ 5 / 49 :=
average_density_near_total_density hPα hPε hε₁ star_subset_chunk star_subset_chunk
have hqt : |q - t| ≤ ε ^ 5 / 49 := by
have := average_density_near_total_density hPα hPε hε₁
(Subset.refl (chunk hP G ε hU).parts) (Subset.refl (chunk hP G ε hV).parts)
simp_rw [← sup_eq_biUnion, sup_parts, card_chunk (m_pos hPα).ne', cast_pow] at this
norm_num at this
exact this
have hε' : ε ^ 5 ≤ ε := by
simpa using pow_le_pow_of_le_one (by sz_positivity) hε₁ (show 1 ≤ 5 by norm_num)
rw [abs_sub_le_iff] at hrs hpr hqt
rw [le_abs] at hst ⊢
cases hst
· left; linarith
· right; linarith
/-- Lower bound on the edge densities between non-uniform parts of `SzemerediRegularity.increment`.
-/
theorem edgeDensity_chunk_not_uniform [Nonempty α] (hPα : #P.parts * 16 ^ #P.parts ≤ card α)
(hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5) (hε₁ : ε ≤ 1) {hU : U ∈ P.parts} {hV : V ∈ P.parts}
(hUVne : U ≠ V) (hUV : ¬G.IsUniform ε U V) :
(G.edgeDensity U V : ℝ) ^ 2 - ε ^ 5 / ↑25 + ε ^ 4 / ↑3 ≤
(∑ ab ∈ (chunk hP G ε hU).parts.product (chunk hP G ε hV).parts,
(G.edgeDensity ab.1 ab.2 : ℝ) ^ 2) / ↑16 ^ #P.parts :=
calc
↑(G.edgeDensity U V) ^ 2 - ε ^ 5 / 25 + ε ^ 4 / ↑3 ≤ ↑(G.edgeDensity U V) ^ 2 - ε ^ 5 / ↑25 +
#(star hP G ε hU V) * #(star hP G ε hV U) / ↑16 ^ #P.parts *
(↑9 / ↑16) * ε ^ 2 := by
apply add_le_add_left
have Ul : 4 / 5 * ε ≤ #(star hP G ε hU V) / _ :=
eps_le_card_star_div hPα hPε hε₁ hU hV hUVne hUV
have Vl : 4 / 5 * ε ≤ #(star hP G ε hV U) / _ :=
eps_le_card_star_div hPα hPε hε₁ hV hU hUVne.symm fun h => hUV h.symm
rw [show (16 : ℝ) = ↑4 ^ 2 by norm_num, pow_right_comm, sq ((4 : ℝ) ^ _), ←
_root_.div_mul_div_comm, mul_assoc]
have : 0 < ε := by sz_positivity
have UVl := mul_le_mul Ul Vl (by positivity) ?_
swap
· -- This seems faster than `exact div_nonneg (by positivity) (by positivity)` and *much*
-- (tens of seconds) faster than `positivity` on its own.
apply div_nonneg <;> positivity
refine le_trans ?_ (mul_le_mul_of_nonneg_right UVl ?_)
· norm_num
nlinarith
· norm_num
positivity
_ ≤ (∑ ab ∈ (chunk hP G ε hU).parts.product (chunk hP G ε hV).parts,
(G.edgeDensity ab.1 ab.2 : ℝ) ^ 2) / ↑16 ^ #P.parts := by
have t : (star hP G ε hU V).product (star hP G ε hV U) ⊆
(chunk hP G ε hU).parts.product (chunk hP G ε hV).parts :=
product_subset_product star_subset_chunk star_subset_chunk
have hε : 0 ≤ ε := by sz_positivity
have sp : ∀ (a b : Finset (Finset α)), a.product b = a ×ˢ b := fun a b => rfl
have := add_div_le_sum_sq_div_card t (fun x => (G.edgeDensity x.1 x.2 : ℝ))
((G.edgeDensity U V : ℝ) ^ 2 - ε ^ 5 / ↑25) (show 0 ≤ 3 / 4 * ε by linarith) ?_ ?_
· simp_rw [sp, card_product, card_chunk (m_pos hPα).ne', ← mul_pow, cast_pow, mul_pow,
div_pow, ← mul_assoc] at this
norm_num at this
exact this
· simp_rw [sp, card_product, card_chunk (m_pos hPα).ne', ← mul_pow]
norm_num
exact edgeDensity_star_not_uniform hPα hPε hε₁ hUVne hUV
· rw [sp, card_product]
apply (edgeDensity_chunk_aux hP hPα hPε hU hV).trans
· rw [card_chunk (m_pos hPα).ne', card_chunk (m_pos hPα).ne', ← mul_pow]
norm_num
/-- Lower bound on the edge densities between parts of `SzemerediRegularity.increment`. This is the
blanket lower bound used the uniform parts. -/
theorem edgeDensity_chunk_uniform [Nonempty α] (hPα : #P.parts * 16 ^ #P.parts ≤ card α)
(hPε : ↑100 ≤ ↑4 ^ #P.parts * ε ^ 5) (hU : U ∈ P.parts) (hV : V ∈ P.parts) :
(G.edgeDensity U V : ℝ) ^ 2 - ε ^ 5 / ↑25 ≤
(∑ ab ∈ (chunk hP G ε hU).parts.product (chunk hP G ε hV).parts,
(G.edgeDensity ab.1 ab.2 : ℝ) ^ 2) / ↑16 ^ #P.parts := by
apply (edgeDensity_chunk_aux (hP := hP) hPα hPε hU hV).trans
have key : (16 : ℝ) ^ #P.parts = #((chunk hP G ε hU).parts ×ˢ (chunk hP G ε hV).parts) := by
rw [card_product, cast_mul, card_chunk (m_pos hPα).ne', card_chunk (m_pos hPα).ne', ←
cast_mul, ← mul_pow]; norm_cast
simp_rw [key]
convert sum_div_card_sq_le_sum_sq_div_card (α := ℝ)
end SzemerediRegularity
| Mathlib/Combinatorics/SimpleGraph/Regularity/Chunk.lean | 526 | 537 | |
/-
Copyright (c) 2016 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad
-/
import Mathlib.Algebra.Group.Int.Defs
import Mathlib.Algebra.Order.Monoid.Defs
/-!
# The integers form a linear ordered group
This file contains the instance necessary to show that the integers are a linear ordered
additive group.
See note [foundational algebra order theory].
-/
-- We should need only a minimal development of sets in order to get here.
assert_not_exists Set.Subsingleton Ring
instance Int.instIsOrderedAddMonoid : IsOrderedAddMonoid ℤ where
add_le_add_left _ _ := Int.add_le_add_left
| Mathlib/Algebra/Order/Group/Int.lean | 102 | 105 | |
/-
Copyright (c) 2021 Bhavik Mehta. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Bhavik Mehta, Alena Gusakov, Yaël Dillies
-/
import Mathlib.Data.Finset.Grade
import Mathlib.Data.Finset.Sups
import Mathlib.Logic.Function.Iterate
/-!
# Shadows
This file defines shadows of a set family. The shadow of a set family is the set family of sets we
get by removing any element from any set of the original family. If one pictures `Finset α` as a big
hypercube (each dimension being membership of a given element), then taking the shadow corresponds
to projecting each finset down once in all available directions.
## Main definitions
* `Finset.shadow`: The shadow of a set family. Everything we can get by removing a new element from
some set.
* `Finset.upShadow`: The upper shadow of a set family. Everything we can get by adding an element
to some set.
## Notation
We define notation in locale `FinsetFamily`:
* `∂ 𝒜`: Shadow of `𝒜`.
* `∂⁺ 𝒜`: Upper shadow of `𝒜`.
We also maintain the convention that `a, b : α` are elements of the ground type, `s, t : Finset α`
are finsets, and `𝒜, ℬ : Finset (Finset α)` are finset families.
## References
* https://github.com/b-mehta/maths-notes/blob/master/iii/mich/combinatorics.pdf
* http://discretemath.imp.fu-berlin.de/DMII-2015-16/kruskal.pdf
## Tags
shadow, set family
-/
open Finset Nat
variable {α : Type*}
namespace Finset
section Shadow
variable [DecidableEq α] {𝒜 ℬ : Finset (Finset α)} {s t : Finset α} {a : α} {k r : ℕ}
/-- The shadow of a set family `𝒜` is all sets we can get by removing one element from any set in
`𝒜`, and the (`k` times) iterated shadow (`shadow^[k]`) is all sets we can get by removing `k`
elements from any set in `𝒜`. -/
def shadow (𝒜 : Finset (Finset α)) : Finset (Finset α) :=
𝒜.sup fun s => s.image (erase s)
@[inherit_doc] scoped[FinsetFamily] notation:max "∂ " => Finset.shadow
open FinsetFamily
/-- The shadow of the empty set is empty. -/
@[simp]
theorem shadow_empty : ∂ (∅ : Finset (Finset α)) = ∅ :=
rfl
@[simp] lemma shadow_iterate_empty (k : ℕ) : ∂^[k] (∅ : Finset (Finset α)) = ∅ := by
induction k <;> simp [*, shadow_empty]
@[simp]
theorem shadow_singleton_empty : ∂ ({∅} : Finset (Finset α)) = ∅ :=
rfl
@[simp]
theorem shadow_singleton (a : α) : ∂ {{a}} = {∅} := by
simp [shadow]
/-- The shadow is monotone. -/
@[mono]
theorem shadow_monotone : Monotone (shadow : Finset (Finset α) → Finset (Finset α)) := fun _ _ =>
sup_mono
@[gcongr] lemma shadow_mono (h𝒜ℬ : 𝒜 ⊆ ℬ) : ∂ 𝒜 ⊆ ∂ ℬ := shadow_monotone h𝒜ℬ
/-- `t` is in the shadow of `𝒜` iff there is a `s ∈ 𝒜` from which we can remove one element to
get `t`. -/
lemma mem_shadow_iff : t ∈ ∂ 𝒜 ↔ ∃ s ∈ 𝒜, ∃ a ∈ s, erase s a = t := by
simp only [shadow, mem_sup, mem_image]
theorem erase_mem_shadow (hs : s ∈ 𝒜) (ha : a ∈ s) : erase s a ∈ ∂ 𝒜 :=
mem_shadow_iff.2 ⟨s, hs, a, ha, rfl⟩
/-- `t ∈ ∂𝒜` iff `t` is exactly one element less than something from `𝒜`.
See also `Finset.mem_shadow_iff_exists_mem_card_add_one`. -/
lemma mem_shadow_iff_exists_sdiff : t ∈ ∂ 𝒜 ↔ ∃ s ∈ 𝒜, t ⊆ s ∧ #(s \ t) = 1 := by
simp_rw [mem_shadow_iff, ← covBy_iff_card_sdiff_eq_one, covBy_iff_exists_erase]
/-- `t` is in the shadow of `𝒜` iff we can add an element to it so that the resulting finset is in
`𝒜`. -/
lemma mem_shadow_iff_insert_mem : t ∈ ∂ 𝒜 ↔ ∃ a ∉ t, insert a t ∈ 𝒜 := by
simp_rw [mem_shadow_iff_exists_sdiff, ← covBy_iff_card_sdiff_eq_one, covBy_iff_exists_insert]
aesop
/-- `s ∈ ∂ 𝒜` iff `s` is exactly one element less than something from `𝒜`.
See also `Finset.mem_shadow_iff_exists_sdiff`. -/
lemma mem_shadow_iff_exists_mem_card_add_one : t ∈ ∂ 𝒜 ↔ ∃ s ∈ 𝒜, t ⊆ s ∧ #s = #t + 1 := by
refine mem_shadow_iff_exists_sdiff.trans <| exists_congr fun t ↦ and_congr_right fun _ ↦
and_congr_right fun hst ↦ ?_
rw [card_sdiff hst, tsub_eq_iff_eq_add_of_le, add_comm]
exact card_mono hst
lemma mem_shadow_iterate_iff_exists_card :
t ∈ ∂^[k] 𝒜 ↔ ∃ u : Finset α, #u = k ∧ Disjoint t u ∧ t ∪ u ∈ 𝒜 := by
induction k generalizing t with
| zero => simp
| succ k ih =>
simp only [mem_shadow_iff_insert_mem, ih, Function.iterate_succ_apply', card_eq_succ]
aesop
/-- `t ∈ ∂^k 𝒜` iff `t` is exactly `k` elements less than something from `𝒜`.
See also `Finset.mem_shadow_iff_exists_mem_card_add`. -/
lemma mem_shadow_iterate_iff_exists_sdiff : t ∈ ∂^[k] 𝒜 ↔ ∃ s ∈ 𝒜, t ⊆ s ∧ #(s \ t) = k := by
rw [mem_shadow_iterate_iff_exists_card]
constructor
· rintro ⟨u, rfl, htu, hsuA⟩
| exact ⟨_, hsuA, subset_union_left, by rw [union_sdiff_cancel_left htu]⟩
· rintro ⟨s, hs, hts, rfl⟩
refine ⟨s \ t, rfl, disjoint_sdiff, ?_⟩
rwa [union_sdiff_self_eq_union, union_eq_right.2 hts]
/-- `t ∈ ∂^k 𝒜` iff `t` is exactly `k` elements less than something in `𝒜`.
See also `Finset.mem_shadow_iterate_iff_exists_sdiff`. -/
lemma mem_shadow_iterate_iff_exists_mem_card_add :
t ∈ ∂^[k] 𝒜 ↔ ∃ s ∈ 𝒜, t ⊆ s ∧ #s = #t + k := by
refine mem_shadow_iterate_iff_exists_sdiff.trans <| exists_congr fun t ↦ and_congr_right fun _ ↦
| Mathlib/Combinatorics/SetFamily/Shadow.lean | 132 | 142 |
/-
Copyright (c) 2018 Reid Barton. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Reid Barton, Kim Morrison
-/
import Mathlib.CategoryTheory.Opposites
/-!
# Morphisms from equations between objects.
When working categorically, sometimes one encounters an equation `h : X = Y` between objects.
Your initial aversion to this is natural and appropriate:
you're in for some trouble, and if there is another way to approach the problem that won't
rely on this equality, it may be worth pursuing.
You have two options:
1. Use the equality `h` as one normally would in Lean (e.g. using `rw` and `subst`).
This may immediately cause difficulties, because in category theory everything is dependently
typed, and equations between objects quickly lead to nasty goals with `eq.rec`.
2. Promote `h` to a morphism using `eqToHom h : X ⟶ Y`, or `eqToIso h : X ≅ Y`.
This file introduces various `simp` lemmas which in favourable circumstances
result in the various `eqToHom` morphisms to drop out at the appropriate moment!
-/
universe v₁ v₂ v₃ u₁ u₂ u₃
-- morphism levels before object levels. See note [CategoryTheory universes].
namespace CategoryTheory
open Opposite
variable {C : Type u₁} [Category.{v₁} C]
/-- An equality `X = Y` gives us a morphism `X ⟶ Y`.
It is typically better to use this, rather than rewriting by the equality then using `𝟙 _`
which usually leads to dependent type theory hell.
-/
def eqToHom {X Y : C} (p : X = Y) : X ⟶ Y := by rw [p]; exact 𝟙 _
@[simp]
theorem eqToHom_refl (X : C) (p : X = X) : eqToHom p = 𝟙 X :=
rfl
@[reassoc (attr := simp)]
theorem eqToHom_trans {X Y Z : C} (p : X = Y) (q : Y = Z) :
eqToHom p ≫ eqToHom q = eqToHom (p.trans q) := by
cases p
cases q
simp
/-- `eqToHom h` is heterogeneously equal to the identity of its domain. -/
lemma eqToHom_heq_id_dom (X Y : C) (h : X = Y) : HEq (eqToHom h) (𝟙 X) := by
subst h; rfl
/-- `eqToHom h` is heterogeneously equal to the identity of its codomain. -/
lemma eqToHom_heq_id_cod (X Y : C) (h : X = Y) : HEq (eqToHom h) (𝟙 Y) := by
subst h; rfl
/-- Two morphisms are conjugate via eqToHom if and only if they are heterogeneously equal.
Note this used to be in the Functor namespace, where it doesn't belong. -/
theorem conj_eqToHom_iff_heq {W X Y Z : C} (f : W ⟶ X) (g : Y ⟶ Z) (h : W = Y) (h' : X = Z) :
f = eqToHom h ≫ g ≫ eqToHom h'.symm ↔ HEq f g := by
cases h
cases h'
simp
theorem conj_eqToHom_iff_heq' {C} [Category C] {W X Y Z : C}
(f : W ⟶ X) (g : Y ⟶ Z) (h : W = Y) (h' : Z = X) :
f = eqToHom h ≫ g ≫ eqToHom h' ↔ HEq f g := conj_eqToHom_iff_heq _ _ _ h'.symm
theorem comp_eqToHom_iff {X Y Y' : C} (p : Y = Y') (f : X ⟶ Y) (g : X ⟶ Y') :
f ≫ eqToHom p = g ↔ f = g ≫ eqToHom p.symm :=
{ mp := fun h => h ▸ by simp
mpr := fun h => by simp [eq_whisker h (eqToHom p)] }
theorem eqToHom_comp_iff {X X' Y : C} (p : X = X') (f : X ⟶ Y) (g : X' ⟶ Y) :
eqToHom p ≫ g = f ↔ g = eqToHom p.symm ≫ f :=
{ mp := fun h => h ▸ by simp
mpr := fun h => h ▸ by simp [whisker_eq _ h] }
theorem eqToHom_comp_heq {C} [Category C] {W X Y : C}
(f : Y ⟶ X) (h : W = Y) : HEq (eqToHom h ≫ f) f := by
rw [← conj_eqToHom_iff_heq _ _ h rfl, eqToHom_refl, Category.comp_id]
@[simp] theorem eqToHom_comp_heq_iff {C} [Category C] {W X Y Z Z' : C}
(f : Y ⟶ X) (g : Z ⟶ Z') (h : W = Y) :
HEq (eqToHom h ≫ f) g ↔ HEq f g :=
⟨(eqToHom_comp_heq ..).symm.trans, (eqToHom_comp_heq ..).trans⟩
@[simp] theorem heq_eqToHom_comp_iff {C} [Category C] {W X Y Z Z' : C}
(f : Y ⟶ X) (g : Z ⟶ Z') (h : W = Y) :
HEq g (eqToHom h ≫ f) ↔ HEq g f :=
⟨(·.trans (eqToHom_comp_heq ..)), (·.trans (eqToHom_comp_heq ..).symm)⟩
theorem comp_eqToHom_heq {C} [Category C] {X Y Z : C}
(f : X ⟶ Y) (h : Y = Z) : HEq (f ≫ eqToHom h) f := by
rw [← conj_eqToHom_iff_heq' _ _ rfl h, eqToHom_refl, Category.id_comp]
@[simp] theorem comp_eqToHom_heq_iff {C} [Category C] {W X Y Z Z' : C}
(f : X ⟶ Y) (g : Z ⟶ Z') (h : Y = W) :
HEq (f ≫ eqToHom h) g ↔ HEq f g :=
⟨(comp_eqToHom_heq ..).symm.trans, (comp_eqToHom_heq ..).trans⟩
@[simp] theorem heq_comp_eqToHom_iff {C} [Category C] {W X Y Z Z' : C}
(f : X ⟶ Y) (g : Z ⟶ Z') (h : Y = W) :
HEq g (f ≫ eqToHom h) ↔ HEq g f :=
⟨(·.trans (comp_eqToHom_heq ..)), (·.trans (comp_eqToHom_heq ..).symm)⟩
theorem heq_comp {C} [Category C] {X Y Z X' Y' Z' : C}
{f : X ⟶ Y} {g : Y ⟶ Z} {f' : X' ⟶ Y'} {g' : Y' ⟶ Z'}
(eq1 : X = X') (eq2 : Y = Y') (eq3 : Z = Z')
(H1 : HEq f f') (H2 : HEq g g') :
HEq (f ≫ g) (f' ≫ g') := by
cases eq1; cases eq2; cases eq3; cases H1; cases H2; rfl
variable {β : Sort*}
/-- We can push `eqToHom` to the left through families of morphisms. -/
-- The simpNF linter incorrectly claims that this will never apply.
-- It seems the side condition `w` is not applied by `simpNF`.
-- https://github.com/leanprover-community/mathlib4/issues/5049
@[reassoc (attr := simp, nolint simpNF)]
theorem eqToHom_naturality {f g : β → C} (z : ∀ b, f b ⟶ g b) {j j' : β} (w : j = j') :
z j ≫ eqToHom (by simp [w]) = eqToHom (by simp [w]) ≫ z j' := by
cases w
simp
/-- A variant on `eqToHom_naturality` that helps Lean identify the families `f` and `g`. -/
-- The simpNF linter incorrectly claims that this will never apply.
-- It seems the side condition `w` is not applied by `simpNF`.
-- https://github.com/leanprover-community/mathlib4/issues/5049
@[reassoc (attr := simp, nolint simpNF)]
theorem eqToHom_iso_hom_naturality {f g : β → C} (z : ∀ b, f b ≅ g b) {j j' : β} (w : j = j') :
(z j).hom ≫ eqToHom (by simp [w]) = eqToHom (by simp [w]) ≫ (z j').hom := by
cases w
simp
/-- A variant on `eqToHom_naturality` that helps Lean identify the families `f` and `g`. -/
-- The simpNF linter incorrectly claims that this will never apply.
-- It seems the side condition `w` is not applied by `simpNF`.
-- https://github.com/leanprover-community/mathlib4/issues/5049
@[reassoc (attr := simp, nolint simpNF)]
theorem eqToHom_iso_inv_naturality {f g : β → C} (z : ∀ b, f b ≅ g b) {j j' : β} (w : j = j') :
(z j).inv ≫ eqToHom (by simp [w]) = eqToHom (by simp [w]) ≫ (z j').inv := by
cases w
simp
/-- Reducible form of congrArg_mpr_hom_left -/
@[simp]
theorem congrArg_cast_hom_left {X Y Z : C} (p : X = Y) (q : Y ⟶ Z) :
cast (congrArg (fun W : C => W ⟶ Z) p.symm) q = eqToHom p ≫ q := by
cases p
simp
/-- If we (perhaps unintentionally) perform equational rewriting on
the source object of a morphism,
we can replace the resulting `_.mpr f` term by a composition with an `eqToHom`.
It may be advisable to introduce any necessary `eqToHom` morphisms manually,
rather than relying on this lemma firing.
-/
theorem congrArg_mpr_hom_left {X Y Z : C} (p : X = Y) (q : Y ⟶ Z) :
(congrArg (fun W : C => W ⟶ Z) p).mpr q = eqToHom p ≫ q := by
cases p
simp
/-- Reducible form of `congrArg_mpr_hom_right` -/
@[simp]
theorem congrArg_cast_hom_right {X Y Z : C} (p : X ⟶ Y) (q : Z = Y) :
cast (congrArg (fun W : C => X ⟶ W) q.symm) p = p ≫ eqToHom q.symm := by
| cases q
simp
| Mathlib/CategoryTheory/EqToHom.lean | 174 | 176 |
/-
Copyright (c) 2020 Bhavik Mehta. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Bhavik Mehta
-/
import Mathlib.CategoryTheory.Adjunction.FullyFaithful
import Mathlib.CategoryTheory.Functor.EpiMono
import Mathlib.CategoryTheory.HomCongr
/-!
# Reflective functors
Basic properties of reflective functors, especially those relating to their essential image.
Note properties of reflective functors relating to limits and colimits are included in
`Mathlib.CategoryTheory.Monad.Limits`.
-/
universe v₁ v₂ v₃ u₁ u₂ u₃
noncomputable section
namespace CategoryTheory
open Category Adjunction
variable {C : Type u₁} {D : Type u₂} {E : Type u₃}
variable [Category.{v₁} C] [Category.{v₂} D] [Category.{v₃} E]
/--
A functor is *reflective*, or *a reflective inclusion*, if it is fully faithful and right adjoint.
-/
class Reflective (R : D ⥤ C) extends R.Full, R.Faithful where
/-- a choice of a left adjoint to `R` -/
L : C ⥤ D
/-- `R` is a right adjoint -/
adj : L ⊣ R
variable (i : D ⥤ C)
/-- The reflector `C ⥤ D` when `R : D ⥤ C` is reflective. -/
def reflector [Reflective i] : C ⥤ D := Reflective.L (R := i)
/-- The adjunction `reflector i ⊣ i` when `i` is reflective. -/
def reflectorAdjunction [Reflective i] : reflector i ⊣ i := Reflective.adj
instance [Reflective i] : i.IsRightAdjoint := ⟨_, ⟨reflectorAdjunction i⟩⟩
instance [Reflective i] : (reflector i).IsLeftAdjoint := ⟨_, ⟨reflectorAdjunction i⟩⟩
/-- A reflective functor is fully faithful. -/
def Functor.fullyFaithfulOfReflective [Reflective i] : i.FullyFaithful :=
(reflectorAdjunction i).fullyFaithfulROfIsIsoCounit
-- TODO: This holds more generally for idempotent adjunctions, not just reflective adjunctions.
/-- For a reflective functor `i` (with left adjoint `L`), with unit `η`, we have `η_iL = iL η`.
-/
theorem unit_obj_eq_map_unit [Reflective i] (X : C) :
(reflectorAdjunction i).unit.app (i.obj ((reflector i).obj X)) =
i.map ((reflector i).map ((reflectorAdjunction i).unit.app X)) := by
rw [← cancel_mono (i.map ((reflectorAdjunction i).counit.app ((reflector i).obj X))),
← i.map_comp]
simp
/--
When restricted to objects in `D` given by `i : D ⥤ C`, the unit is an isomorphism. In other words,
`η_iX` is an isomorphism for any `X` in `D`.
More generally this applies to objects essentially in the reflective subcategory, see
`Functor.essImage.unit_isIso`.
-/
example [Reflective i] {B : D} : IsIso ((reflectorAdjunction i).unit.app (i.obj B)) :=
inferInstance
variable {i}
/-- If `A` is essentially in the image of a reflective functor `i`, then `η_A` is an isomorphism.
This gives that the "witness" for `A` being in the essential image can instead be given as the
reflection of `A`, with the isomorphism as `η_A`.
(For any `B` in the reflective subcategory, we automatically have that `ε_B` is an iso.)
-/
theorem Functor.essImage.unit_isIso [Reflective i] {A : C} (h : i.essImage A) :
IsIso ((reflectorAdjunction i).unit.app A) := by
rwa [isIso_unit_app_iff_mem_essImage]
/-- If `η_A` is a split monomorphism, then `A` is in the reflective subcategory. -/
theorem mem_essImage_of_unit_isSplitMono [Reflective i] {A : C}
[IsSplitMono ((reflectorAdjunction i).unit.app A)] : i.essImage A := by
let η : 𝟭 C ⟶ reflector i ⋙ i := (reflectorAdjunction i).unit
haveI : IsIso (η.app (i.obj ((reflector i).obj A))) :=
Functor.essImage.unit_isIso ((i.obj_mem_essImage _))
have : Epi (η.app A) := by
refine @epi_of_epi _ _ _ _ _ (retraction (η.app A)) (η.app A) ?_
rw [show retraction _ ≫ η.app A = _ from η.naturality (retraction (η.app A))]
apply epi_comp (η.app (i.obj ((reflector i).obj A)))
haveI := isIso_of_epi_of_isSplitMono (η.app A)
exact (reflectorAdjunction i).mem_essImage_of_unit_isIso A
/-- Composition of reflective functors. -/
instance Reflective.comp (F : C ⥤ D) (G : D ⥤ E) [Reflective F] [Reflective G] :
Reflective (F ⋙ G) where
L := reflector G ⋙ reflector F
adj := (reflectorAdjunction G).comp (reflectorAdjunction F)
/-- (Implementation) Auxiliary definition for `unitCompPartialBijective`. -/
def unitCompPartialBijectiveAux [Reflective i] (A : C) (B : D) :
(A ⟶ i.obj B) ≃ (i.obj ((reflector i).obj A) ⟶ i.obj B) :=
((reflectorAdjunction i).homEquiv _ _).symm.trans
(Functor.FullyFaithful.ofFullyFaithful i).homEquiv
/-- The description of the inverse of the bijection `unitCompPartialBijectiveAux`. -/
theorem unitCompPartialBijectiveAux_symm_apply [Reflective i] {A : C} {B : D}
(f : i.obj ((reflector i).obj A) ⟶ i.obj B) :
(unitCompPartialBijectiveAux _ _).symm f = (reflectorAdjunction i).unit.app A ≫ f := by
simp [unitCompPartialBijectiveAux, Adjunction.homEquiv_unit]
/-- If `i` has a reflector `L`, then the function `(i.obj (L.obj A) ⟶ B) → (A ⟶ B)` given by
precomposing with `η.app A` is a bijection provided `B` is in the essential image of `i`.
That is, the function `fun (f : i.obj (L.obj A) ⟶ B) ↦ η.app A ≫ f` is bijective,
as long as `B` is in the essential image of `i`.
This definition gives an equivalence: the key property that the inverse can be described
nicely is shown in `unitCompPartialBijective_symm_apply`.
This establishes there is a natural bijection `(A ⟶ B) ≃ (i.obj (L.obj A) ⟶ B)`. In other words,
from the point of view of objects in `D`, `A` and `i.obj (L.obj A)` look the same: specifically
that `η.app A` is an isomorphism.
-/
def unitCompPartialBijective [Reflective i] (A : C) {B : C} (hB : i.essImage B) :
(A ⟶ B) ≃ (i.obj ((reflector i).obj A) ⟶ B) :=
calc
(A ⟶ B) ≃ (A ⟶ i.obj (Functor.essImage.witness hB)) := Iso.homCongr (Iso.refl _) hB.getIso.symm
_ ≃ (i.obj _ ⟶ i.obj (Functor.essImage.witness hB)) := unitCompPartialBijectiveAux _ _
_ ≃ (i.obj ((reflector i).obj A) ⟶ B) :=
Iso.homCongr (Iso.refl _) (Functor.essImage.getIso hB)
@[simp]
theorem unitCompPartialBijective_symm_apply [Reflective i] (A : C) {B : C} (hB : i.essImage B)
(f) : (unitCompPartialBijective A hB).symm f = (reflectorAdjunction i).unit.app A ≫ f := by
simp [unitCompPartialBijective, unitCompPartialBijectiveAux_symm_apply]
theorem unitCompPartialBijective_symm_natural [Reflective i] (A : C) {B B' : C} (h : B ⟶ B')
(hB : i.essImage B) (hB' : i.essImage B') (f : i.obj ((reflector i).obj A) ⟶ B) :
(unitCompPartialBijective A hB').symm (f ≫ h) = (unitCompPartialBijective A hB).symm f ≫ h := by
simp
theorem unitCompPartialBijective_natural [Reflective i] (A : C) {B B' : C} (h : B ⟶ B')
(hB : i.essImage B) (hB' : i.essImage B') (f : A ⟶ B) :
(unitCompPartialBijective A hB') (f ≫ h) = unitCompPartialBijective A hB f ≫ h := by
rw [← Equiv.eq_symm_apply, unitCompPartialBijective_symm_natural A h, Equiv.symm_apply_apply]
instance [Reflective i] (X : Functor.EssImageSubcategory i) :
IsIso (NatTrans.app (reflectorAdjunction i).unit X.obj) :=
Functor.essImage.unit_isIso X.property
-- These attributes are necessary to make automation work in `equivEssImageOfReflective`.
-- Making them global doesn't break anything elsewhere, but this is enough for now.
-- TODO: investigate further.
attribute [local simp 900] ObjectProperty.ι_map in
attribute [local ext] Functor.essImage_ext in
/-- If `i : D ⥤ C` is reflective, the inverse functor of `i ≌ F.essImage` can be explicitly
defined by the reflector. -/
@[simps]
def equivEssImageOfReflective [Reflective i] : D ≌ i.EssImageSubcategory where
functor := i.toEssImage
inverse := i.essImage.ι ⋙ reflector i
unitIso := (asIso <| (reflectorAdjunction i).counit).symm
counitIso := Functor.fullyFaithfulCancelRight i.essImage.ι <|
NatIso.ofComponents (fun X ↦ (asIso ((reflectorAdjunction i).unit.app X.obj)).symm)
/--
A functor is *coreflective*, or *a coreflective inclusion*, if it is fully faithful and left
adjoint.
-/
class Coreflective (L : C ⥤ D) extends L.Full, L.Faithful where
/-- a choice of a right adjoint to `L` -/
R : D ⥤ C
/-- `L` is a left adjoint -/
adj : L ⊣ R
variable (j : C ⥤ D)
/-- The coreflector `D ⥤ C` when `L : C ⥤ D` is coreflective. -/
def coreflector [Coreflective j] : D ⥤ C := Coreflective.R (L := j)
/-- The adjunction `j ⊣ coreflector j` when `j` is coreflective. -/
def coreflectorAdjunction [Coreflective j] : j ⊣ coreflector j := Coreflective.adj
instance [Coreflective j] : j.IsLeftAdjoint := ⟨_, ⟨coreflectorAdjunction j⟩⟩
instance [Coreflective j] : (coreflector j).IsRightAdjoint := ⟨_, ⟨coreflectorAdjunction j⟩⟩
/-- A coreflective functor is fully faithful. -/
def Functor.fullyFaithfulOfCoreflective [Coreflective j] : j.FullyFaithful :=
(coreflectorAdjunction j).fullyFaithfulLOfIsIsoUnit
lemma counit_obj_eq_map_counit [Coreflective j] (X : D) :
(coreflectorAdjunction j).counit.app (j.obj ((coreflector j).obj X)) =
j.map ((coreflector j).map ((coreflectorAdjunction j).counit.app X)) := by
rw [← cancel_epi (j.map ((coreflectorAdjunction j).unit.app ((coreflector j).obj X))),
← j.map_comp]
simp
example [Coreflective j] {B : C} : IsIso ((coreflectorAdjunction j).counit.app (j.obj B)) :=
inferInstance
variable {j}
lemma Functor.essImage.counit_isIso [Coreflective j] {A : D} (h : j.essImage A) :
IsIso ((coreflectorAdjunction j).counit.app A) := by
rwa [isIso_counit_app_iff_mem_essImage]
lemma mem_essImage_of_counit_isSplitEpi [Coreflective j] {A : D}
[IsSplitEpi ((coreflectorAdjunction j).counit.app A)] : j.essImage A := by
let ε : coreflector j ⋙ j ⟶ 𝟭 D := (coreflectorAdjunction j).counit
haveI : IsIso (ε.app (j.obj ((coreflector j).obj A))) :=
Functor.essImage.counit_isIso ((j.obj_mem_essImage _))
have : Mono (ε.app A) := by
refine @mono_of_mono _ _ _ _ _ (ε.app A) (section_ (ε.app A)) ?_
rw [show ε.app A ≫ section_ _ = _ from (ε.naturality (section_ (ε.app A))).symm]
apply mono_comp _ (ε.app (j.obj ((coreflector j).obj A)))
haveI := isIso_of_mono_of_isSplitEpi (ε.app A)
exact (coreflectorAdjunction j).mem_essImage_of_counit_isIso A
instance Coreflective.comp (F : C ⥤ D) (G : D ⥤ E) [Coreflective F] [Coreflective G] :
Coreflective (F ⋙ G) where
R := coreflector G ⋙ coreflector F
adj := (coreflectorAdjunction F).comp (coreflectorAdjunction G)
end CategoryTheory
| Mathlib/CategoryTheory/Adjunction/Reflective.lean | 267 | 277 | |
/-
Copyright (c) 2019 Floris van Doorn. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Floris van Doorn, Yury Kudryashov, Sébastien Gouëzel, Chris Hughes
-/
import Mathlib.Data.Fin.Rev
import Mathlib.Data.Nat.Find
/-!
# Operation on tuples
We interpret maps `∀ i : Fin n, α i` as `n`-tuples of elements of possibly varying type `α i`,
`(α 0, …, α (n-1))`. A particular case is `Fin n → α` of elements with all the same type.
In this case when `α i` is a constant map, then tuples are isomorphic (but not definitionally equal)
to `Vector`s.
## Main declarations
There are three (main) ways to consider `Fin n` as a subtype of `Fin (n + 1)`, hence three (main)
ways to move between tuples of length `n` and of length `n + 1` by adding/removing an entry.
### Adding at the start
* `Fin.succ`: Send `i : Fin n` to `i + 1 : Fin (n + 1)`. This is defined in Core.
* `Fin.cases`: Induction/recursion principle for `Fin`: To prove a property/define a function for
all `Fin (n + 1)`, it is enough to prove/define it for `0` and for `i.succ` for all `i : Fin n`.
This is defined in Core.
* `Fin.cons`: Turn a tuple `f : Fin n → α` and an entry `a : α` into a tuple
`Fin.cons a f : Fin (n + 1) → α` by adding `a` at the start. In general, tuples can be dependent
functions, in which case `f : ∀ i : Fin n, α i.succ` and `a : α 0`. This is a special case of
`Fin.cases`.
* `Fin.tail`: Turn a tuple `f : Fin (n + 1) → α` into a tuple `Fin.tail f : Fin n → α` by forgetting
the start. In general, tuples can be dependent functions,
in which case `Fin.tail f : ∀ i : Fin n, α i.succ`.
### Adding at the end
* `Fin.castSucc`: Send `i : Fin n` to `i : Fin (n + 1)`. This is defined in Core.
* `Fin.lastCases`: Induction/recursion principle for `Fin`: To prove a property/define a function
for all `Fin (n + 1)`, it is enough to prove/define it for `last n` and for `i.castSucc` for all
`i : Fin n`. This is defined in Core.
* `Fin.snoc`: Turn a tuple `f : Fin n → α` and an entry `a : α` into a tuple
`Fin.snoc f a : Fin (n + 1) → α` by adding `a` at the end. In general, tuples can be dependent
functions, in which case `f : ∀ i : Fin n, α i.castSucc` and `a : α (last n)`. This is a
special case of `Fin.lastCases`.
* `Fin.init`: Turn a tuple `f : Fin (n + 1) → α` into a tuple `Fin.init f : Fin n → α` by forgetting
the start. In general, tuples can be dependent functions,
in which case `Fin.init f : ∀ i : Fin n, α i.castSucc`.
### Adding in the middle
For a **pivot** `p : Fin (n + 1)`,
* `Fin.succAbove`: Send `i : Fin n` to
* `i : Fin (n + 1)` if `i < p`,
* `i + 1 : Fin (n + 1)` if `p ≤ i`.
* `Fin.succAboveCases`: Induction/recursion principle for `Fin`: To prove a property/define a
function for all `Fin (n + 1)`, it is enough to prove/define it for `p` and for `p.succAbove i`
for all `i : Fin n`.
* `Fin.insertNth`: Turn a tuple `f : Fin n → α` and an entry `a : α` into a tuple
`Fin.insertNth f a : Fin (n + 1) → α` by adding `a` in position `p`. In general, tuples can be
dependent functions, in which case `f : ∀ i : Fin n, α (p.succAbove i)` and `a : α p`. This is a
special case of `Fin.succAboveCases`.
* `Fin.removeNth`: Turn a tuple `f : Fin (n + 1) → α` into a tuple `Fin.removeNth p f : Fin n → α`
by forgetting the `p`-th value. In general, tuples can be dependent functions,
in which case `Fin.removeNth f : ∀ i : Fin n, α (succAbove p i)`.
`p = 0` means we add at the start. `p = last n` means we add at the end.
### Miscellaneous
* `Fin.find p` : returns the first index `n` where `p n` is satisfied, and `none` if it is never
satisfied.
* `Fin.append a b` : append two tuples.
* `Fin.repeat n a` : repeat a tuple `n` times.
-/
assert_not_exists Monoid
universe u v
namespace Fin
variable {m n : ℕ}
open Function
section Tuple
/-- There is exactly one tuple of size zero. -/
example (α : Fin 0 → Sort u) : Unique (∀ i : Fin 0, α i) := by infer_instance
theorem tuple0_le {α : Fin 0 → Type*} [∀ i, Preorder (α i)] (f g : ∀ i, α i) : f ≤ g :=
finZeroElim
variable {α : Fin (n + 1) → Sort u} (x : α 0) (q : ∀ i, α i) (p : ∀ i : Fin n, α i.succ) (i : Fin n)
(y : α i.succ) (z : α 0)
/-- The tail of an `n+1` tuple, i.e., its last `n` entries. -/
def tail (q : ∀ i, α i) : ∀ i : Fin n, α i.succ := fun i ↦ q i.succ
theorem tail_def {n : ℕ} {α : Fin (n + 1) → Sort*} {q : ∀ i, α i} :
(tail fun k : Fin (n + 1) ↦ q k) = fun k : Fin n ↦ q k.succ :=
rfl
/-- Adding an element at the beginning of an `n`-tuple, to get an `n+1`-tuple. -/
def cons (x : α 0) (p : ∀ i : Fin n, α i.succ) : ∀ i, α i := fun j ↦ Fin.cases x p j
@[simp]
theorem tail_cons : tail (cons x p) = p := by
simp +unfoldPartialApp [tail, cons]
@[simp]
theorem cons_succ : cons x p i.succ = p i := by simp [cons]
@[simp]
theorem cons_zero : cons x p 0 = x := by simp [cons]
@[simp]
theorem cons_one {α : Fin (n + 2) → Sort*} (x : α 0) (p : ∀ i : Fin n.succ, α i.succ) :
cons x p 1 = p 0 := by
rw [← cons_succ x p]; rfl
/-- Updating a tuple and adding an element at the beginning commute. -/
@[simp]
theorem cons_update : cons x (update p i y) = update (cons x p) i.succ y := by
ext j
by_cases h : j = 0
· rw [h]
simp [Ne.symm (succ_ne_zero i)]
· let j' := pred j h
have : j'.succ = j := succ_pred j h
rw [← this, cons_succ]
by_cases h' : j' = i
· rw [h']
simp
· have : j'.succ ≠ i.succ := by rwa [Ne, succ_inj]
rw [update_of_ne h', update_of_ne this, cons_succ]
/-- As a binary function, `Fin.cons` is injective. -/
theorem cons_injective2 : Function.Injective2 (@cons n α) := fun x₀ y₀ x y h ↦
⟨congr_fun h 0, funext fun i ↦ by simpa using congr_fun h (Fin.succ i)⟩
@[simp]
theorem cons_inj {x₀ y₀ : α 0} {x y : ∀ i : Fin n, α i.succ} :
cons x₀ x = cons y₀ y ↔ x₀ = y₀ ∧ x = y :=
cons_injective2.eq_iff
theorem cons_left_injective (x : ∀ i : Fin n, α i.succ) : Function.Injective fun x₀ ↦ cons x₀ x :=
cons_injective2.left _
theorem cons_right_injective (x₀ : α 0) : Function.Injective (cons x₀) :=
cons_injective2.right _
/-- Adding an element at the beginning of a tuple and then updating it amounts to adding it
directly. -/
theorem update_cons_zero : update (cons x p) 0 z = cons z p := by
ext j
by_cases h : j = 0
· rw [h]
simp
· simp only [h, update_of_ne, Ne, not_false_iff]
let j' := pred j h
have : j'.succ = j := succ_pred j h
rw [← this, cons_succ, cons_succ]
/-- Concatenating the first element of a tuple with its tail gives back the original tuple -/
@[simp]
theorem cons_self_tail : cons (q 0) (tail q) = q := by
ext j
by_cases h : j = 0
· rw [h]
simp
· let j' := pred j h
have : j'.succ = j := succ_pred j h
rw [← this]
unfold tail
rw [cons_succ]
/-- Equivalence between tuples of length `n + 1` and pairs of an element and a tuple of length `n`
given by separating out the first element of the tuple.
This is `Fin.cons` as an `Equiv`. -/
@[simps]
def consEquiv (α : Fin (n + 1) → Type*) : α 0 × (∀ i, α (succ i)) ≃ ∀ i, α i where
toFun f := cons f.1 f.2
invFun f := (f 0, tail f)
left_inv f := by simp
right_inv f := by simp
/-- Recurse on an `n+1`-tuple by splitting it into a single element and an `n`-tuple. -/
@[elab_as_elim]
def consCases {P : (∀ i : Fin n.succ, α i) → Sort v} (h : ∀ x₀ x, P (Fin.cons x₀ x))
(x : ∀ i : Fin n.succ, α i) : P x :=
_root_.cast (by rw [cons_self_tail]) <| h (x 0) (tail x)
@[simp]
theorem consCases_cons {P : (∀ i : Fin n.succ, α i) → Sort v} (h : ∀ x₀ x, P (Fin.cons x₀ x))
(x₀ : α 0) (x : ∀ i : Fin n, α i.succ) : @consCases _ _ _ h (cons x₀ x) = h x₀ x := by
rw [consCases, cast_eq]
congr
/-- Recurse on a tuple by splitting into `Fin.elim0` and `Fin.cons`. -/
@[elab_as_elim]
def consInduction {α : Sort*} {P : ∀ {n : ℕ}, (Fin n → α) → Sort v} (h0 : P Fin.elim0)
(h : ∀ {n} (x₀) (x : Fin n → α), P x → P (Fin.cons x₀ x)) : ∀ {n : ℕ} (x : Fin n → α), P x
| 0, x => by convert h0
| _ + 1, x => consCases (fun _ _ ↦ h _ _ <| consInduction h0 h _) x
theorem cons_injective_of_injective {α} {x₀ : α} {x : Fin n → α} (hx₀ : x₀ ∉ Set.range x)
(hx : Function.Injective x) : Function.Injective (cons x₀ x : Fin n.succ → α) := by
refine Fin.cases ?_ ?_
· refine Fin.cases ?_ ?_
· intro
rfl
· intro j h
rw [cons_zero, cons_succ] at h
exact hx₀.elim ⟨_, h.symm⟩
· intro i
refine Fin.cases ?_ ?_
· intro h
rw [cons_zero, cons_succ] at h
exact hx₀.elim ⟨_, h⟩
· intro j h
rw [cons_succ, cons_succ] at h
exact congr_arg _ (hx h)
theorem cons_injective_iff {α} {x₀ : α} {x : Fin n → α} :
Function.Injective (cons x₀ x : Fin n.succ → α) ↔ x₀ ∉ Set.range x ∧ Function.Injective x := by
refine ⟨fun h ↦ ⟨?_, ?_⟩, fun h ↦ cons_injective_of_injective h.1 h.2⟩
· rintro ⟨i, hi⟩
replace h := @h i.succ 0
simp [hi] at h
· simpa [Function.comp] using h.comp (Fin.succ_injective _)
@[simp]
theorem forall_fin_zero_pi {α : Fin 0 → Sort*} {P : (∀ i, α i) → Prop} :
(∀ x, P x) ↔ P finZeroElim :=
⟨fun h ↦ h _, fun h x ↦ Subsingleton.elim finZeroElim x ▸ h⟩
@[simp]
theorem exists_fin_zero_pi {α : Fin 0 → Sort*} {P : (∀ i, α i) → Prop} :
(∃ x, P x) ↔ P finZeroElim :=
⟨fun ⟨x, h⟩ ↦ Subsingleton.elim x finZeroElim ▸ h, fun h ↦ ⟨_, h⟩⟩
theorem forall_fin_succ_pi {P : (∀ i, α i) → Prop} : (∀ x, P x) ↔ ∀ a v, P (Fin.cons a v) :=
⟨fun h a v ↦ h (Fin.cons a v), consCases⟩
theorem exists_fin_succ_pi {P : (∀ i, α i) → Prop} : (∃ x, P x) ↔ ∃ a v, P (Fin.cons a v) :=
⟨fun ⟨x, h⟩ ↦ ⟨x 0, tail x, (cons_self_tail x).symm ▸ h⟩, fun ⟨_, _, h⟩ ↦ ⟨_, h⟩⟩
/-- Updating the first element of a tuple does not change the tail. -/
@[simp]
theorem tail_update_zero : tail (update q 0 z) = tail q := by
ext j
simp [tail]
/-- Updating a nonzero element and taking the tail commute. -/
@[simp]
theorem tail_update_succ : tail (update q i.succ y) = update (tail q) i y := by
ext j
by_cases h : j = i
· rw [h]
simp [tail]
· simp [tail, (Fin.succ_injective n).ne h, h]
theorem comp_cons {α : Sort*} {β : Sort*} (g : α → β) (y : α) (q : Fin n → α) :
g ∘ cons y q = cons (g y) (g ∘ q) := by
ext j
by_cases h : j = 0
· rw [h]
rfl
· let j' := pred j h
have : j'.succ = j := succ_pred j h
rw [← this, cons_succ, comp_apply, comp_apply, cons_succ]
theorem comp_tail {α : Sort*} {β : Sort*} (g : α → β) (q : Fin n.succ → α) :
g ∘ tail q = tail (g ∘ q) := by
ext j
simp [tail]
section Preorder
variable {α : Fin (n + 1) → Type*}
theorem le_cons [∀ i, Preorder (α i)] {x : α 0} {q : ∀ i, α i} {p : ∀ i : Fin n, α i.succ} :
q ≤ cons x p ↔ q 0 ≤ x ∧ tail q ≤ p :=
forall_fin_succ.trans <| and_congr Iff.rfl <| forall_congr' fun j ↦ by simp [tail]
theorem cons_le [∀ i, Preorder (α i)] {x : α 0} {q : ∀ i, α i} {p : ∀ i : Fin n, α i.succ} :
cons x p ≤ q ↔ x ≤ q 0 ∧ p ≤ tail q :=
@le_cons _ (fun i ↦ (α i)ᵒᵈ) _ x q p
theorem cons_le_cons [∀ i, Preorder (α i)] {x₀ y₀ : α 0} {x y : ∀ i : Fin n, α i.succ} :
cons x₀ x ≤ cons y₀ y ↔ x₀ ≤ y₀ ∧ x ≤ y :=
forall_fin_succ.trans <| and_congr_right' <| by simp only [cons_succ, Pi.le_def]
end Preorder
theorem range_fin_succ {α} (f : Fin (n + 1) → α) :
Set.range f = insert (f 0) (Set.range (Fin.tail f)) :=
Set.ext fun _ ↦ exists_fin_succ.trans <| eq_comm.or Iff.rfl
@[simp]
theorem range_cons {α} {n : ℕ} (x : α) (b : Fin n → α) :
Set.range (Fin.cons x b : Fin n.succ → α) = insert x (Set.range b) := by
rw [range_fin_succ, cons_zero, tail_cons]
section Append
variable {α : Sort*}
/-- Append a tuple of length `m` to a tuple of length `n` to get a tuple of length `m + n`.
This is a non-dependent version of `Fin.add_cases`. -/
def append (a : Fin m → α) (b : Fin n → α) : Fin (m + n) → α :=
@Fin.addCases _ _ (fun _ => α) a b
@[simp]
theorem append_left (u : Fin m → α) (v : Fin n → α) (i : Fin m) :
append u v (Fin.castAdd n i) = u i :=
addCases_left _
@[simp]
theorem append_right (u : Fin m → α) (v : Fin n → α) (i : Fin n) :
append u v (natAdd m i) = v i :=
addCases_right _
theorem append_right_nil (u : Fin m → α) (v : Fin n → α) (hv : n = 0) :
append u v = u ∘ Fin.cast (by rw [hv, Nat.add_zero]) := by
refine funext (Fin.addCases (fun l => ?_) fun r => ?_)
· rw [append_left, Function.comp_apply]
refine congr_arg u (Fin.ext ?_)
simp
· exact (Fin.cast hv r).elim0
@[simp]
theorem append_elim0 (u : Fin m → α) :
append u Fin.elim0 = u ∘ Fin.cast (Nat.add_zero _) :=
append_right_nil _ _ rfl
theorem append_left_nil (u : Fin m → α) (v : Fin n → α) (hu : m = 0) :
append u v = v ∘ Fin.cast (by rw [hu, Nat.zero_add]) := by
refine funext (Fin.addCases (fun l => ?_) fun r => ?_)
· exact (Fin.cast hu l).elim0
· rw [append_right, Function.comp_apply]
refine congr_arg v (Fin.ext ?_)
simp [hu]
@[simp]
theorem elim0_append (v : Fin n → α) :
append Fin.elim0 v = v ∘ Fin.cast (Nat.zero_add _) :=
append_left_nil _ _ rfl
theorem append_assoc {p : ℕ} (a : Fin m → α) (b : Fin n → α) (c : Fin p → α) :
append (append a b) c = append a (append b c) ∘ Fin.cast (Nat.add_assoc ..) := by
ext i
rw [Function.comp_apply]
refine Fin.addCases (fun l => ?_) (fun r => ?_) i
· rw [append_left]
refine Fin.addCases (fun ll => ?_) (fun lr => ?_) l
· rw [append_left]
simp [castAdd_castAdd]
· rw [append_right]
simp [castAdd_natAdd]
· rw [append_right]
simp [← natAdd_natAdd]
/-- Appending a one-tuple to the left is the same as `Fin.cons`. -/
theorem append_left_eq_cons {n : ℕ} (x₀ : Fin 1 → α) (x : Fin n → α) :
Fin.append x₀ x = Fin.cons (x₀ 0) x ∘ Fin.cast (Nat.add_comm ..) := by
ext i
refine Fin.addCases ?_ ?_ i <;> clear i
· intro i
rw [Subsingleton.elim i 0, Fin.append_left, Function.comp_apply, eq_comm]
exact Fin.cons_zero _ _
· intro i
rw [Fin.append_right, Function.comp_apply, Fin.cast_natAdd, eq_comm, Fin.addNat_one]
exact Fin.cons_succ _ _ _
/-- `Fin.cons` is the same as appending a one-tuple to the left. -/
theorem cons_eq_append (x : α) (xs : Fin n → α) :
cons x xs = append (cons x Fin.elim0) xs ∘ Fin.cast (Nat.add_comm ..) := by
funext i; simp [append_left_eq_cons]
@[simp] lemma append_cast_left {n m} (xs : Fin n → α) (ys : Fin m → α) (n' : ℕ)
(h : n' = n) :
Fin.append (xs ∘ Fin.cast h) ys = Fin.append xs ys ∘ (Fin.cast <| by rw [h]) := by
subst h; simp
@[simp] lemma append_cast_right {n m} (xs : Fin n → α) (ys : Fin m → α) (m' : ℕ)
(h : m' = m) :
Fin.append xs (ys ∘ Fin.cast h) = Fin.append xs ys ∘ (Fin.cast <| by rw [h]) := by
subst h; simp
lemma append_rev {m n} (xs : Fin m → α) (ys : Fin n → α) (i : Fin (m + n)) :
append xs ys (rev i) = append (ys ∘ rev) (xs ∘ rev) (i.cast (Nat.add_comm ..)) := by
rcases rev_surjective i with ⟨i, rfl⟩
rw [rev_rev]
induction i using Fin.addCases
· simp [rev_castAdd]
· simp [cast_rev, rev_addNat]
lemma append_comp_rev {m n} (xs : Fin m → α) (ys : Fin n → α) :
append xs ys ∘ rev = append (ys ∘ rev) (xs ∘ rev) ∘ Fin.cast (Nat.add_comm ..) :=
funext <| append_rev xs ys
theorem append_castAdd_natAdd {f : Fin (m + n) → α} :
append (fun i ↦ f (castAdd n i)) (fun i ↦ f (natAdd m i)) = f := by
unfold append addCases
simp
end Append
section Repeat
variable {α : Sort*}
/-- Repeat `a` `m` times. For example `Fin.repeat 2 ![0, 3, 7] = ![0, 3, 7, 0, 3, 7]`. -/
def «repeat» (m : ℕ) (a : Fin n → α) : Fin (m * n) → α
| i => a i.modNat
@[simp]
theorem repeat_apply (a : Fin n → α) (i : Fin (m * n)) :
Fin.repeat m a i = a i.modNat :=
rfl
@[simp]
theorem repeat_zero (a : Fin n → α) :
Fin.repeat 0 a = Fin.elim0 ∘ Fin.cast (Nat.zero_mul _) :=
funext fun x => (x.cast (Nat.zero_mul _)).elim0
@[simp]
theorem repeat_one (a : Fin n → α) : Fin.repeat 1 a = a ∘ Fin.cast (Nat.one_mul _) := by
generalize_proofs h
apply funext
rw [(Fin.rightInverse_cast h.symm).surjective.forall]
intro i
simp [modNat, Nat.mod_eq_of_lt i.is_lt]
theorem repeat_succ (a : Fin n → α) (m : ℕ) :
Fin.repeat m.succ a =
append a (Fin.repeat m a) ∘ Fin.cast ((Nat.succ_mul _ _).trans (Nat.add_comm ..)) := by
generalize_proofs h
apply funext
rw [(Fin.rightInverse_cast h.symm).surjective.forall]
refine Fin.addCases (fun l => ?_) fun r => ?_
· simp [modNat, Nat.mod_eq_of_lt l.is_lt]
· simp [modNat]
@[simp]
theorem repeat_add (a : Fin n → α) (m₁ m₂ : ℕ) : Fin.repeat (m₁ + m₂) a =
append (Fin.repeat m₁ a) (Fin.repeat m₂ a) ∘ Fin.cast (Nat.add_mul ..) := by
generalize_proofs h
apply funext
rw [(Fin.rightInverse_cast h.symm).surjective.forall]
refine Fin.addCases (fun l => ?_) fun r => ?_
· simp [modNat, Nat.mod_eq_of_lt l.is_lt]
· simp [modNat, Nat.add_mod]
theorem repeat_rev (a : Fin n → α) (k : Fin (m * n)) :
Fin.repeat m a k.rev = Fin.repeat m (a ∘ Fin.rev) k :=
congr_arg a k.modNat_rev
theorem repeat_comp_rev (a : Fin n → α) :
Fin.repeat m a ∘ Fin.rev = Fin.repeat m (a ∘ Fin.rev) :=
funext <| repeat_rev a
end Repeat
end Tuple
section TupleRight
/-! In the previous section, we have discussed inserting or removing elements on the left of a
tuple. In this section, we do the same on the right. A difference is that `Fin (n+1)` is constructed
inductively from `Fin n` starting from the left, not from the right. This implies that Lean needs
more help to realize that elements belong to the right types, i.e., we need to insert casts at
several places. -/
variable {α : Fin (n + 1) → Sort*} (x : α (last n)) (q : ∀ i, α i)
(p : ∀ i : Fin n, α i.castSucc) (i : Fin n) (y : α i.castSucc) (z : α (last n))
/-- The beginning of an `n+1` tuple, i.e., its first `n` entries -/
def init (q : ∀ i, α i) (i : Fin n) : α i.castSucc :=
q i.castSucc
theorem init_def {q : ∀ i, α i} :
(init fun k : Fin (n + 1) ↦ q k) = fun k : Fin n ↦ q k.castSucc :=
rfl
/-- Adding an element at the end of an `n`-tuple, to get an `n+1`-tuple. The name `snoc` comes from
`cons` (i.e., adding an element to the left of a tuple) read in reverse order. -/
def snoc (p : ∀ i : Fin n, α i.castSucc) (x : α (last n)) (i : Fin (n + 1)) : α i :=
if h : i.val < n then _root_.cast (by rw [Fin.castSucc_castLT i h]) (p (castLT i h))
else _root_.cast (by rw [eq_last_of_not_lt h]) x
@[simp]
theorem init_snoc : init (snoc p x) = p := by
ext i
simp only [init, snoc, coe_castSucc, is_lt, cast_eq, dite_true]
convert cast_eq rfl (p i)
@[simp]
theorem snoc_castSucc : snoc p x i.castSucc = p i := by
simp only [snoc, coe_castSucc, is_lt, cast_eq, dite_true]
convert cast_eq rfl (p i)
@[simp]
theorem snoc_comp_castSucc {α : Sort*} {a : α} {f : Fin n → α} :
(snoc f a : Fin (n + 1) → α) ∘ castSucc = f :=
funext fun i ↦ by rw [Function.comp_apply, snoc_castSucc]
@[simp]
theorem snoc_last : snoc p x (last n) = x := by simp [snoc]
lemma snoc_zero {α : Sort*} (p : Fin 0 → α) (x : α) :
Fin.snoc p x = fun _ ↦ x := by
ext y
have : Subsingleton (Fin (0 + 1)) := Fin.subsingleton_one
simp only [Subsingleton.elim y (Fin.last 0), snoc_last]
@[simp]
theorem snoc_comp_nat_add {n m : ℕ} {α : Sort*} (f : Fin (m + n) → α) (a : α) :
(snoc f a : Fin _ → α) ∘ (natAdd m : Fin (n + 1) → Fin (m + n + 1)) =
snoc (f ∘ natAdd m) a := by
ext i
refine Fin.lastCases ?_ (fun i ↦ ?_) i
· simp only [Function.comp_apply]
rw [snoc_last, natAdd_last, snoc_last]
· simp only [comp_apply, snoc_castSucc]
rw [natAdd_castSucc, snoc_castSucc]
@[simp]
theorem snoc_cast_add {α : Fin (n + m + 1) → Sort*} (f : ∀ i : Fin (n + m), α i.castSucc)
(a : α (last (n + m))) (i : Fin n) : (snoc f a) (castAdd (m + 1) i) = f (castAdd m i) :=
dif_pos _
@[simp]
theorem snoc_comp_cast_add {n m : ℕ} {α : Sort*} (f : Fin (n + m) → α) (a : α) :
(snoc f a : Fin _ → α) ∘ castAdd (m + 1) = f ∘ castAdd m :=
funext (snoc_cast_add _ _)
/-- Updating a tuple and adding an element at the end commute. -/
@[simp]
theorem snoc_update : snoc (update p i y) x = update (snoc p x) i.castSucc y := by
ext j
cases j using lastCases with
| cast j => rcases eq_or_ne j i with rfl | hne <;> simp [*]
| last => simp [Ne.symm]
/-- Adding an element at the beginning of a tuple and then updating it amounts to adding it
directly. -/
theorem update_snoc_last : update (snoc p x) (last n) z = snoc p z := by
ext j
cases j using lastCases <;> simp
/-- As a binary function, `Fin.snoc` is injective. -/
theorem snoc_injective2 : Function.Injective2 (@snoc n α) := fun x y xₙ yₙ h ↦
⟨funext fun i ↦ by simpa using congr_fun h (castSucc i), by simpa using congr_fun h (last n)⟩
@[simp]
theorem snoc_inj {x y : ∀ i : Fin n, α i.castSucc} {xₙ yₙ : α (last n)} :
snoc x xₙ = snoc y yₙ ↔ x = y ∧ xₙ = yₙ :=
snoc_injective2.eq_iff
theorem snoc_right_injective (x : ∀ i : Fin n, α i.castSucc) :
Function.Injective (snoc x) :=
snoc_injective2.right _
theorem snoc_left_injective (xₙ : α (last n)) : Function.Injective (snoc · xₙ) :=
snoc_injective2.left _
/-- Concatenating the first element of a tuple with its tail gives back the original tuple -/
@[simp]
theorem snoc_init_self : snoc (init q) (q (last n)) = q := by
ext j
by_cases h : j.val < n
· simp only [init, snoc, h, cast_eq, dite_true, castSucc_castLT]
· rw [eq_last_of_not_lt h]
simp
/-- Updating the last element of a tuple does not change the beginning. -/
@[simp]
theorem init_update_last : init (update q (last n) z) = init q := by
ext j
simp [init, Fin.ne_of_lt]
/-- Updating an element and taking the beginning commute. -/
@[simp]
theorem init_update_castSucc : init (update q i.castSucc y) = update (init q) i y := by
ext j
by_cases h : j = i
· rw [h]
simp [init]
· simp [init, h, castSucc_inj]
/-- `tail` and `init` commute. We state this lemma in a non-dependent setting, as otherwise it
would involve a cast to convince Lean that the two types are equal, making it harder to use. -/
theorem tail_init_eq_init_tail {β : Sort*} (q : Fin (n + 2) → β) :
tail (init q) = init (tail q) := by
ext i
simp [tail, init, castSucc_fin_succ]
/-- `cons` and `snoc` commute. We state this lemma in a non-dependent setting, as otherwise it
would involve a cast to convince Lean that the two types are equal, making it harder to use. -/
theorem cons_snoc_eq_snoc_cons {β : Sort*} (a : β) (q : Fin n → β) (b : β) :
@cons n.succ (fun _ ↦ β) a (snoc q b) = snoc (cons a q) b := by
ext i
by_cases h : i = 0
· simp [h, snoc, castLT]
set j := pred i h with ji
have : i = j.succ := by rw [ji, succ_pred]
rw [this, cons_succ]
by_cases h' : j.val < n
· set k := castLT j h' with jk
have : j = castSucc k := by rw [jk, castSucc_castLT]
rw [this, ← castSucc_fin_succ, snoc]
simp [pred, snoc, cons]
rw [eq_last_of_not_lt h', succ_last]
simp
theorem comp_snoc {α : Sort*} {β : Sort*} (g : α → β) (q : Fin n → α) (y : α) :
g ∘ snoc q y = snoc (g ∘ q) (g y) := by
ext j
by_cases h : j.val < n
· simp [h, snoc, castSucc_castLT]
· rw [eq_last_of_not_lt h]
simp
/-- Appending a one-tuple to the right is the same as `Fin.snoc`. -/
theorem append_right_eq_snoc {α : Sort*} {n : ℕ} (x : Fin n → α) (x₀ : Fin 1 → α) :
Fin.append x x₀ = Fin.snoc x (x₀ 0) := by
ext i
refine Fin.addCases ?_ ?_ i <;> clear i
· intro i
rw [Fin.append_left]
exact (@snoc_castSucc _ (fun _ => α) _ _ i).symm
· intro i
rw [Subsingleton.elim i 0, Fin.append_right]
exact (@snoc_last _ (fun _ => α) _ _).symm
/-- `Fin.snoc` is the same as appending a one-tuple -/
theorem snoc_eq_append {α : Sort*} (xs : Fin n → α) (x : α) :
snoc xs x = append xs (cons x Fin.elim0) :=
(append_right_eq_snoc xs (cons x Fin.elim0)).symm
theorem append_left_snoc {n m} {α : Sort*} (xs : Fin n → α) (x : α) (ys : Fin m → α) :
Fin.append (Fin.snoc xs x) ys =
Fin.append xs (Fin.cons x ys) ∘ Fin.cast (Nat.succ_add_eq_add_succ ..) := by
rw [snoc_eq_append, append_assoc, append_left_eq_cons, append_cast_right]; rfl
theorem append_right_cons {n m} {α : Sort*} (xs : Fin n → α) (y : α) (ys : Fin m → α) :
Fin.append xs (Fin.cons y ys) =
Fin.append (Fin.snoc xs y) ys ∘ Fin.cast (Nat.succ_add_eq_add_succ ..).symm := by
rw [append_left_snoc]; rfl
theorem append_cons {α : Sort*} (a : α) (as : Fin n → α) (bs : Fin m → α) :
Fin.append (cons a as) bs
= cons a (Fin.append as bs) ∘ (Fin.cast <| Nat.add_right_comm n 1 m) := by
funext i
rcases i with ⟨i, -⟩
simp only [append, addCases, cons, castLT, cast, comp_apply]
rcases i with - | i
· simp
· split_ifs with h
· have : i < n := Nat.lt_of_succ_lt_succ h
simp [addCases, this]
· have : ¬i < n := Nat.not_le.mpr <| Nat.lt_succ.mp <| Nat.not_le.mp h
simp [addCases, this]
theorem append_snoc {α : Sort*} (as : Fin n → α) (bs : Fin m → α) (b : α) :
Fin.append as (snoc bs b) = snoc (Fin.append as bs) b := by
funext i
rcases i with ⟨i, isLt⟩
simp only [append, addCases, castLT, cast_mk, subNat_mk, natAdd_mk, cast, snoc.eq_1,
cast_eq, eq_rec_constant, Nat.add_eq, Nat.add_zero, castLT_mk]
split_ifs with lt_n lt_add sub_lt nlt_add lt_add <;> (try rfl)
· have := Nat.lt_add_right m lt_n
contradiction
· obtain rfl := Nat.eq_of_le_of_lt_succ (Nat.not_lt.mp nlt_add) isLt
simp [Nat.add_comm n m] at sub_lt
· have := Nat.sub_lt_left_of_lt_add (Nat.not_lt.mp lt_n) lt_add
contradiction
theorem comp_init {α : Sort*} {β : Sort*} (g : α → β) (q : Fin n.succ → α) :
g ∘ init q = init (g ∘ q) := by
ext j
simp [init]
/-- Equivalence between tuples of length `n + 1` and pairs of an element and a tuple of length `n`
given by separating out the last element of the tuple.
This is `Fin.snoc` as an `Equiv`. -/
@[simps]
def snocEquiv (α : Fin (n + 1) → Type*) : α (last n) × (∀ i, α (castSucc i)) ≃ ∀ i, α i where
toFun f _ := Fin.snoc f.2 f.1 _
invFun f := ⟨f _, Fin.init f⟩
left_inv f := by simp
right_inv f := by simp
/-- Recurse on an `n+1`-tuple by splitting it its initial `n`-tuple and its last element. -/
@[elab_as_elim, inline]
def snocCases {P : (∀ i : Fin n.succ, α i) → Sort*}
(h : ∀ xs x, P (Fin.snoc xs x))
(x : ∀ i : Fin n.succ, α i) : P x :=
_root_.cast (by rw [Fin.snoc_init_self]) <| h (Fin.init x) (x <| Fin.last _)
@[simp] lemma snocCases_snoc
{P : (∀ i : Fin (n+1), α i) → Sort*} (h : ∀ x x₀, P (Fin.snoc x x₀))
(x : ∀ i : Fin n, (Fin.init α) i) (x₀ : α (Fin.last _)) :
snocCases h (Fin.snoc x x₀) = h x x₀ := by
rw [snocCases, cast_eq_iff_heq, Fin.init_snoc, Fin.snoc_last]
/-- Recurse on a tuple by splitting into `Fin.elim0` and `Fin.snoc`. -/
@[elab_as_elim]
def snocInduction {α : Sort*}
{P : ∀ {n : ℕ}, (Fin n → α) → Sort*}
(h0 : P Fin.elim0)
(h : ∀ {n} (x : Fin n → α) (x₀), P x → P (Fin.snoc x x₀)) : ∀ {n : ℕ} (x : Fin n → α), P x
| 0, x => by convert h0
| _ + 1, x => snocCases (fun _ _ ↦ h _ _ <| snocInduction h0 h _) x
end TupleRight
section InsertNth
variable {α : Fin (n + 1) → Sort*} {β : Sort*}
/- Porting note: Lean told me `(fun x x_1 ↦ α x)` was an invalid motive, but disabling
automatic insertion and specifying that motive seems to work. -/
/-- Define a function on `Fin (n + 1)` from a value on `i : Fin (n + 1)` and values on each
`Fin.succAbove i j`, `j : Fin n`. This version is elaborated as eliminator and works for
propositions, see also `Fin.insertNth` for a version without an `@[elab_as_elim]`
attribute. -/
@[elab_as_elim]
def succAboveCases {α : Fin (n + 1) → Sort u} (i : Fin (n + 1)) (x : α i)
(p : ∀ j : Fin n, α (i.succAbove j)) (j : Fin (n + 1)) : α j :=
if hj : j = i then Eq.rec x hj.symm
else
if hlt : j < i then @Eq.recOn _ _ (fun x _ ↦ α x) _ (succAbove_castPred_of_lt _ _ hlt) (p _)
else @Eq.recOn _ _ (fun x _ ↦ α x) _ (succAbove_pred_of_lt _ _ <|
(Fin.lt_or_lt_of_ne hj).resolve_left hlt) (p _)
-- This is a duplicate of `Fin.exists_fin_succ` in Core. We should upstream the name change.
alias forall_iff_succ := forall_fin_succ
-- This is a duplicate of `Fin.exists_fin_succ` in Core. We should upstream the name change.
alias exists_iff_succ := exists_fin_succ
lemma forall_iff_castSucc {P : Fin (n + 1) → Prop} :
(∀ i, P i) ↔ P (last n) ∧ ∀ i : Fin n, P i.castSucc :=
⟨fun h ↦ ⟨h _, fun _ ↦ h _⟩, fun h ↦ lastCases h.1 h.2⟩
lemma exists_iff_castSucc {P : Fin (n + 1) → Prop} :
(∃ i, P i) ↔ P (last n) ∨ ∃ i : Fin n, P i.castSucc where
mp := by
rintro ⟨i, hi⟩
induction' i using lastCases
· exact .inl hi
· exact .inr ⟨_, hi⟩
mpr := by rintro (h | ⟨i, hi⟩) <;> exact ⟨_, ‹_›⟩
theorem forall_iff_succAbove {P : Fin (n + 1) → Prop} (p : Fin (n + 1)) :
(∀ i, P i) ↔ P p ∧ ∀ i, P (p.succAbove i) :=
⟨fun h ↦ ⟨h _, fun _ ↦ h _⟩, fun h ↦ succAboveCases p h.1 h.2⟩
lemma exists_iff_succAbove {P : Fin (n + 1) → Prop} (p : Fin (n + 1)) :
(∃ i, P i) ↔ P p ∨ ∃ i, P (p.succAbove i) where
mp := by
rintro ⟨i, hi⟩
induction' i using p.succAboveCases
· exact .inl hi
· exact .inr ⟨_, hi⟩
mpr := by rintro (h | ⟨i, hi⟩) <;> exact ⟨_, ‹_›⟩
/-- Analogue of `Fin.eq_zero_or_eq_succ` for `succAbove`. -/
theorem eq_self_or_eq_succAbove (p i : Fin (n + 1)) : i = p ∨ ∃ j, i = p.succAbove j :=
succAboveCases p (.inl rfl) (fun j => .inr ⟨j, rfl⟩) i
/-- Remove the `p`-th entry of a tuple. -/
def removeNth (p : Fin (n + 1)) (f : ∀ i, α i) : ∀ i, α (p.succAbove i) := fun i ↦ f (p.succAbove i)
/-- Insert an element into a tuple at a given position. For `i = 0` see `Fin.cons`,
for `i = Fin.last n` see `Fin.snoc`. See also `Fin.succAboveCases` for a version elaborated
as an eliminator. -/
def insertNth (i : Fin (n + 1)) (x : α i) (p : ∀ j : Fin n, α (i.succAbove j)) (j : Fin (n + 1)) :
α j :=
succAboveCases i x p j
@[simp]
theorem insertNth_apply_same (i : Fin (n + 1)) (x : α i) (p : ∀ j, α (i.succAbove j)) :
insertNth i x p i = x := by simp [insertNth, succAboveCases]
@[simp]
theorem insertNth_apply_succAbove (i : Fin (n + 1)) (x : α i) (p : ∀ j, α (i.succAbove j))
(j : Fin n) : insertNth i x p (i.succAbove j) = p j := by
simp only [insertNth, succAboveCases, dif_neg (succAbove_ne _ _), succAbove_lt_iff_castSucc_lt]
split_ifs with hlt
· generalize_proofs H₁ H₂; revert H₂
generalize hk : castPred ((succAbove i) j) H₁ = k
rw [castPred_succAbove _ _ hlt] at hk; cases hk
intro; rfl
· generalize_proofs H₀ H₁ H₂; revert H₂
generalize hk : pred (succAbove i j) H₁ = k
rw [pred_succAbove _ _ (Fin.not_lt.1 hlt)] at hk; cases hk
intro; rfl
@[simp]
theorem succAbove_cases_eq_insertNth : @succAboveCases = @insertNth :=
rfl
@[simp] lemma removeNth_insertNth (p : Fin (n + 1)) (a : α p) (f : ∀ i, α (succAbove p i)) :
removeNth p (insertNth p a f) = f := by ext; unfold removeNth; simp
@[simp] lemma removeNth_zero (f : ∀ i, α i) : removeNth 0 f = tail f := by
ext; simp [tail, removeNth]
@[simp] lemma removeNth_last {α : Type*} (f : Fin (n + 1) → α) : removeNth (last n) f = init f := by
ext; simp [init, removeNth]
@[simp]
theorem insertNth_comp_succAbove (i : Fin (n + 1)) (x : β) (p : Fin n → β) :
insertNth i x p ∘ i.succAbove = p :=
funext (insertNth_apply_succAbove i _ _)
theorem insertNth_eq_iff {p : Fin (n + 1)} {a : α p} {f : ∀ i, α (p.succAbove i)} {g : ∀ j, α j} :
insertNth p a f = g ↔ a = g p ∧ f = removeNth p g := by
simp [funext_iff, forall_iff_succAbove p, removeNth]
theorem eq_insertNth_iff {p : Fin (n + 1)} {a : α p} {f : ∀ i, α (p.succAbove i)} {g : ∀ j, α j} :
g = insertNth p a f ↔ g p = a ∧ removeNth p g = f := by
simpa [eq_comm] using insertNth_eq_iff
/-- As a binary function, `Fin.insertNth` is injective. -/
theorem insertNth_injective2 {p : Fin (n + 1)} :
Function.Injective2 (@insertNth n α p) := fun xₚ yₚ x y h ↦
⟨by simpa using congr_fun h p, funext fun i ↦ by simpa using congr_fun h (succAbove p i)⟩
@[simp]
theorem insertNth_inj {p : Fin (n + 1)} {x y : ∀ i, α (succAbove p i)} {xₚ yₚ : α p} :
insertNth p xₚ x = insertNth p yₚ y ↔ xₚ = yₚ ∧ x = y :=
insertNth_injective2.eq_iff
theorem insertNth_left_injective {p : Fin (n + 1)} (x : ∀ i, α (succAbove p i)) :
Function.Injective (insertNth p · x) :=
insertNth_injective2.left _
theorem insertNth_right_injective {p : Fin (n + 1)} (x : α p) :
Function.Injective (insertNth p x) :=
insertNth_injective2.right _
/- Porting note: Once again, Lean told me `(fun x x_1 ↦ α x)` was an invalid motive, but disabling
automatic insertion and specifying that motive seems to work. -/
theorem insertNth_apply_below {i j : Fin (n + 1)} (h : j < i) (x : α i)
(p : ∀ k, α (i.succAbove k)) :
i.insertNth x p j = @Eq.recOn _ _ (fun x _ ↦ α x) _
(succAbove_castPred_of_lt _ _ h) (p <| j.castPred _) := by
rw [insertNth, succAboveCases, dif_neg (Fin.ne_of_lt h), dif_pos h]
/- Porting note: Once again, Lean told me `(fun x x_1 ↦ α x)` was an invalid motive, but disabling
automatic insertion and specifying that motive seems to work. -/
theorem insertNth_apply_above {i j : Fin (n + 1)} (h : i < j) (x : α i)
(p : ∀ k, α (i.succAbove k)) :
i.insertNth x p j = @Eq.recOn _ _ (fun x _ ↦ α x) _
(succAbove_pred_of_lt _ _ h) (p <| j.pred _) := by
rw [insertNth, succAboveCases, dif_neg (Fin.ne_of_gt h), dif_neg (Fin.lt_asymm h)]
theorem insertNth_zero (x : α 0) (p : ∀ j : Fin n, α (succAbove 0 j)) :
insertNth 0 x p =
cons x fun j ↦ _root_.cast (congr_arg α (congr_fun succAbove_zero j)) (p j) := by
refine insertNth_eq_iff.2 ⟨by simp, ?_⟩
ext j
convert (cons_succ x p j).symm
@[simp]
theorem insertNth_zero' (x : β) (p : Fin n → β) : @insertNth _ (fun _ ↦ β) 0 x p = cons x p := by
simp [insertNth_zero]
theorem insertNth_last (x : α (last n)) (p : ∀ j : Fin n, α ((last n).succAbove j)) :
insertNth (last n) x p =
snoc (fun j ↦ _root_.cast (congr_arg α (succAbove_last_apply j)) (p j)) x := by
refine insertNth_eq_iff.2 ⟨by simp, ?_⟩
ext j
apply eq_of_heq
trans snoc (fun j ↦ _root_.cast (congr_arg α (succAbove_last_apply j)) (p j)) x j.castSucc
· rw [snoc_castSucc]
exact (cast_heq _ _).symm
· apply congr_arg_heq
rw [succAbove_last]
@[simp]
theorem insertNth_last' (x : β) (p : Fin n → β) :
@insertNth _ (fun _ ↦ β) (last n) x p = snoc p x := by simp [insertNth_last]
lemma insertNth_rev {α : Sort*} (i : Fin (n + 1)) (a : α) (f : Fin n → α) (j : Fin (n + 1)) :
insertNth (α := fun _ ↦ α) i a f (rev j) = insertNth (α := fun _ ↦ α) i.rev a (f ∘ rev) j := by
induction j using Fin.succAboveCases
· exact rev i
· simp
· simp [rev_succAbove]
theorem insertNth_comp_rev {α} (i : Fin (n + 1)) (x : α) (p : Fin n → α) :
(Fin.insertNth i x p) ∘ Fin.rev = Fin.insertNth (Fin.rev i) x (p ∘ Fin.rev) := by
funext x
apply insertNth_rev
theorem cons_rev {α n} (a : α) (f : Fin n → α) (i : Fin <| n + 1) :
cons (α := fun _ => α) a f i.rev = snoc (α := fun _ => α) (f ∘ Fin.rev : Fin _ → α) a i := by
simpa using insertNth_rev 0 a f i
theorem cons_comp_rev {α n} (a : α) (f : Fin n → α) :
Fin.cons a f ∘ Fin.rev = Fin.snoc (f ∘ Fin.rev) a := by
funext i; exact cons_rev ..
theorem snoc_rev {α n} (a : α) (f : Fin n → α) (i : Fin <| n + 1) :
snoc (α := fun _ => α) f a i.rev = cons (α := fun _ => α) a (f ∘ Fin.rev : Fin _ → α) i := by
simpa using insertNth_rev (last n) a f i
theorem snoc_comp_rev {α n} (a : α) (f : Fin n → α) :
Fin.snoc f a ∘ Fin.rev = Fin.cons a (f ∘ Fin.rev) :=
funext <| snoc_rev a f
theorem insertNth_binop (op : ∀ j, α j → α j → α j) (i : Fin (n + 1)) (x y : α i)
(p q : ∀ j, α (i.succAbove j)) :
(i.insertNth (op i x y) fun j ↦ op _ (p j) (q j)) = fun j ↦
op j (i.insertNth x p j) (i.insertNth y q j) :=
insertNth_eq_iff.2 <| by unfold removeNth; simp
section Preorder
variable {α : Fin (n + 1) → Type*} [∀ i, Preorder (α i)]
theorem insertNth_le_iff {i : Fin (n + 1)} {x : α i} {p : ∀ j, α (i.succAbove j)} {q : ∀ j, α j} :
i.insertNth x p ≤ q ↔ x ≤ q i ∧ p ≤ fun j ↦ q (i.succAbove j) := by
simp [Pi.le_def, forall_iff_succAbove i]
theorem le_insertNth_iff {i : Fin (n + 1)} {x : α i} {p : ∀ j, α (i.succAbove j)} {q : ∀ j, α j} :
q ≤ i.insertNth x p ↔ q i ≤ x ∧ (fun j ↦ q (i.succAbove j)) ≤ p := by
simp [Pi.le_def, forall_iff_succAbove i]
end Preorder
open Set
@[simp] lemma removeNth_update (p : Fin (n + 1)) (x) (f : ∀ j, α j) :
removeNth p (update f p x) = removeNth p f := by ext i; simp [removeNth, succAbove_ne]
@[simp] lemma insertNth_removeNth (p : Fin (n + 1)) (x) (f : ∀ j, α j) :
insertNth p x (removeNth p f) = update f p x := by simp [Fin.insertNth_eq_iff]
lemma insertNth_self_removeNth (p : Fin (n + 1)) (f : ∀ j, α j) :
insertNth p (f p) (removeNth p f) = f := by simp
@[simp]
theorem update_insertNth (p : Fin (n + 1)) (x y : α p) (f : ∀ i, α (p.succAbove i)) :
update (p.insertNth x f) p y = p.insertNth y f := by
ext i
cases i using p.succAboveCases <;> simp [succAbove_ne]
/-- Equivalence between tuples of length `n + 1` and pairs of an element and a tuple of length `n`
given by separating out the `p`-th element of the tuple.
This is `Fin.insertNth` as an `Equiv`. -/
@[simps]
def insertNthEquiv (α : Fin (n + 1) → Type u) (p : Fin (n + 1)) :
α p × (∀ i, α (p.succAbove i)) ≃ ∀ i, α i where
toFun f := insertNth p f.1 f.2
invFun f := (f p, removeNth p f)
left_inv f := by ext <;> simp
right_inv f := by simp
@[simp] lemma insertNthEquiv_zero (α : Fin (n + 1) → Type*) : insertNthEquiv α 0 = consEquiv α :=
Equiv.symm_bijective.injective <| by ext <;> rfl
/-- Note this lemma can only be written about non-dependent tuples as `insertNth (last n) = snoc` is
not a definitional equality. -/
@[simp] lemma insertNthEquiv_last (n : ℕ) (α : Type*) :
insertNthEquiv (fun _ ↦ α) (last n) = snocEquiv (fun _ ↦ α) := by ext; simp
end InsertNth
section Find
/-- `find p` returns the first index `n` where `p n` is satisfied, and `none` if it is never
satisfied. -/
def find : ∀ {n : ℕ} (p : Fin n → Prop) [DecidablePred p], Option (Fin n)
| 0, _p, _ => none
| n + 1, p, _ => by
exact
Option.casesOn (@find n (fun i ↦ p (i.castLT (Nat.lt_succ_of_lt i.2))) _)
(if _ : p (Fin.last n) then some (Fin.last n) else none) fun i ↦
some (i.castLT (Nat.lt_succ_of_lt i.2))
/-- If `find p = some i`, then `p i` holds -/
theorem find_spec :
∀ {n : ℕ} (p : Fin n → Prop) [DecidablePred p] {i : Fin n} (_ : i ∈ Fin.find p), p i
| 0, _, _, _, hi => Option.noConfusion hi
| n + 1, p, I, i, hi => by
rw [find] at hi
rcases h : find fun i : Fin n ↦ p (i.castLT (Nat.lt_succ_of_lt i.2)) with - | j
· rw [h] at hi
dsimp at hi
split_ifs at hi with hl
· simp only [Option.mem_def, Option.some.injEq] at hi
exact hi ▸ hl
· exact (Option.not_mem_none _ hi).elim
· rw [h] at hi
dsimp at hi
rw [← Option.some_inj.1 hi]
exact @find_spec n (fun i ↦ p (i.castLT (Nat.lt_succ_of_lt i.2))) _ _ h
/-- `find p` does not return `none` if and only if `p i` holds at some index `i`. -/
theorem isSome_find_iff :
∀ {n : ℕ} {p : Fin n → Prop} [DecidablePred p], (find p).isSome ↔ ∃ i, p i
| 0, _, _ => iff_of_false (fun h ↦ Bool.noConfusion h) fun ⟨i, _⟩ ↦ Fin.elim0 i
| n + 1, p, _ =>
⟨fun h ↦ by
rw [Option.isSome_iff_exists] at h
obtain ⟨i, hi⟩ := h
exact ⟨i, find_spec _ hi⟩, fun ⟨⟨i, hin⟩, hi⟩ ↦ by
dsimp [find]
rcases h : find fun i : Fin n ↦ p (i.castLT (Nat.lt_succ_of_lt i.2)) with - | j
· split_ifs with hl
· exact Option.isSome_some
· have := (@isSome_find_iff n (fun x ↦ p (x.castLT (Nat.lt_succ_of_lt x.2))) _).2
⟨⟨i, lt_of_le_of_ne (Nat.le_of_lt_succ hin) fun h ↦ by cases h; exact hl hi⟩, hi⟩
rw [h] at this
exact this
· simp⟩
/-- `find p` returns `none` if and only if `p i` never holds. -/
theorem find_eq_none_iff {n : ℕ} {p : Fin n → Prop} [DecidablePred p] :
find p = none ↔ ∀ i, ¬p i := by rw [← not_exists, ← isSome_find_iff]; cases find p <;> simp
/-- If `find p` returns `some i`, then `p j` does not hold for `j < i`, i.e., `i` is minimal among
the indices where `p` holds. -/
theorem find_min :
∀ {n : ℕ} {p : Fin n → Prop} [DecidablePred p] {i : Fin n} (_ : i ∈ Fin.find p) {j : Fin n}
(_ : j < i), ¬p j
| 0, _, _, _, hi, _, _, _ => Option.noConfusion hi
| n + 1, p, _, i, hi, ⟨j, hjn⟩, hj, hpj => by
rw [find] at hi
rcases h : find fun i : Fin n ↦ p (i.castLT (Nat.lt_succ_of_lt i.2)) with - | k
· simp only [h] at hi
split_ifs at hi with hl
· cases hi
rw [find_eq_none_iff] at h
exact h ⟨j, hj⟩ hpj
· exact Option.not_mem_none _ hi
· rw [h] at hi
dsimp at hi
obtain rfl := Option.some_inj.1 hi
exact find_min h (show (⟨j, lt_trans hj k.2⟩ : Fin n) < k from hj) hpj
theorem find_min' {p : Fin n → Prop} [DecidablePred p] {i : Fin n} (h : i ∈ Fin.find p) {j : Fin n}
(hj : p j) : i ≤ j := Fin.not_lt.1 fun hij ↦ find_min h hij hj
theorem nat_find_mem_find {p : Fin n → Prop} [DecidablePred p]
(h : ∃ i, ∃ hin : i < n, p ⟨i, hin⟩) :
(⟨Nat.find h, (Nat.find_spec h).fst⟩ : Fin n) ∈ find p := by
let ⟨i, hin, hi⟩ := h
rcases hf : find p with - | f
· rw [find_eq_none_iff] at hf
exact (hf ⟨i, hin⟩ hi).elim
· refine Option.some_inj.2 (Fin.le_antisymm ?_ ?_)
· exact find_min' hf (Nat.find_spec h).snd
· exact Nat.find_min' _ ⟨f.2, by convert find_spec p hf⟩
theorem mem_find_iff {p : Fin n → Prop} [DecidablePred p] {i : Fin n} :
i ∈ Fin.find p ↔ p i ∧ ∀ j, p j → i ≤ j :=
⟨fun hi ↦ ⟨find_spec _ hi, fun _ ↦ find_min' hi⟩, by
rintro ⟨hpi, hj⟩
cases hfp : Fin.find p
· rw [find_eq_none_iff] at hfp
exact (hfp _ hpi).elim
· exact Option.some_inj.2 (Fin.le_antisymm (find_min' hfp hpi) (hj _ (find_spec _ hfp)))⟩
theorem find_eq_some_iff {p : Fin n → Prop} [DecidablePred p] {i : Fin n} :
Fin.find p = some i ↔ p i ∧ ∀ j, p j → i ≤ j :=
mem_find_iff
theorem mem_find_of_unique {p : Fin n → Prop} [DecidablePred p] (h : ∀ i j, p i → p j → i = j)
{i : Fin n} (hi : p i) : i ∈ Fin.find p :=
mem_find_iff.2 ⟨hi, fun j hj ↦ Fin.le_of_eq <| h i j hi hj⟩
end Find
section ContractNth
variable {α : Sort*}
/-- Sends `(g₀, ..., gₙ)` to `(g₀, ..., op gⱼ gⱼ₊₁, ..., gₙ)`. -/
def contractNth (j : Fin (n + 1)) (op : α → α → α) (g : Fin (n + 1) → α) (k : Fin n) : α :=
if (k : ℕ) < j then g (Fin.castSucc k)
else if (k : ℕ) = j then op (g (Fin.castSucc k)) (g k.succ) else g k.succ
theorem contractNth_apply_of_lt (j : Fin (n + 1)) (op : α → α → α) (g : Fin (n + 1) → α) (k : Fin n)
(h : (k : ℕ) < j) : contractNth j op g k = g (Fin.castSucc k) :=
if_pos h
theorem contractNth_apply_of_eq (j : Fin (n + 1)) (op : α → α → α) (g : Fin (n + 1) → α) (k : Fin n)
(h : (k : ℕ) = j) : contractNth j op g k = op (g (Fin.castSucc k)) (g k.succ) := by
have : ¬(k : ℕ) < j := not_lt.2 (le_of_eq h.symm)
rw [contractNth, if_neg this, if_pos h]
theorem contractNth_apply_of_gt (j : Fin (n + 1)) (op : α → α → α) (g : Fin (n + 1) → α) (k : Fin n)
(h : (j : ℕ) < k) : contractNth j op g k = g k.succ := by
rw [contractNth, if_neg (not_lt_of_gt h), if_neg (Ne.symm <| ne_of_lt h)]
theorem contractNth_apply_of_ne (j : Fin (n + 1)) (op : α → α → α) (g : Fin (n + 1) → α) (k : Fin n)
(hjk : (j : ℕ) ≠ k) : contractNth j op g k = g (j.succAbove k) := by
rcases lt_trichotomy (k : ℕ) j with (h | h | h)
· rwa [j.succAbove_of_castSucc_lt, contractNth_apply_of_lt]
· rwa [Fin.lt_iff_val_lt_val]
· exact False.elim (hjk h.symm)
· rwa [j.succAbove_of_le_castSucc, contractNth_apply_of_gt]
| · exact Fin.le_iff_val_le_val.2 (le_of_lt h)
lemma comp_contractNth {β : Sort*} (opα : α → α → α) (opβ : β → β → β) {f : α → β}
(hf : ∀ x y, f (opα x y) = opβ (f x) (f y)) (j : Fin (n + 1)) (g : Fin (n + 1) → α) :
f ∘ contractNth j opα g = contractNth j opβ (f ∘ g) := by
ext x
rcases lt_trichotomy (x : ℕ) j with (h|h|h)
· simp only [Function.comp_apply, contractNth_apply_of_lt, h]
· simp only [Function.comp_apply, contractNth_apply_of_eq, h, hf]
· simp only [Function.comp_apply, contractNth_apply_of_gt, h]
| Mathlib/Data/Fin/Tuple/Basic.lean | 1,118 | 1,127 |
/-
Copyright (c) 2020 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kim Morrison, Johan Commelin
-/
import Mathlib.Algebra.Algebra.RestrictScalars
import Mathlib.Algebra.Algebra.Subalgebra.Lattice
import Mathlib.Algebra.Module.Rat
import Mathlib.GroupTheory.MonoidLocalization.Basic
import Mathlib.LinearAlgebra.TensorProduct.Tower
/-!
# The tensor product of R-algebras
This file provides results about the multiplicative structure on `A ⊗[R] B` when `R` is a
commutative (semi)ring and `A` and `B` are both `R`-algebras. On these tensor products,
multiplication is characterized by `(a₁ ⊗ₜ b₁) * (a₂ ⊗ₜ b₂) = (a₁ * a₂) ⊗ₜ (b₁ * b₂)`.
## Main declarations
- `LinearMap.baseChange A f` is the `A`-linear map `A ⊗ f`, for an `R`-linear map `f`.
- `Algebra.TensorProduct.semiring`: the ring structure on `A ⊗[R] B` for two `R`-algebras `A`, `B`.
- `Algebra.TensorProduct.leftAlgebra`: the `S`-algebra structure on `A ⊗[R] B`, for when `A` is
additionally an `S` algebra.
- the structure isomorphisms
* `Algebra.TensorProduct.lid : R ⊗[R] A ≃ₐ[R] A`
* `Algebra.TensorProduct.rid : A ⊗[R] R ≃ₐ[S] A` (usually used with `S = R` or `S = A`)
* `Algebra.TensorProduct.comm : A ⊗[R] B ≃ₐ[R] B ⊗[R] A`
* `Algebra.TensorProduct.assoc : ((A ⊗[R] B) ⊗[R] C) ≃ₐ[R] (A ⊗[R] (B ⊗[R] C))`
- `Algebra.TensorProduct.liftEquiv`: a universal property for the tensor product of algebras.
## References
* [C. Kassel, *Quantum Groups* (§II.4)][Kassel1995]
-/
assert_not_exists Equiv.Perm.cycleType
suppress_compilation
open scoped TensorProduct
open TensorProduct
namespace LinearMap
open TensorProduct
/-!
### The base-change of a linear map of `R`-modules to a linear map of `A`-modules
-/
section Semiring
variable {R A B M N P : Type*} [CommSemiring R]
variable [Semiring A] [Algebra R A] [Semiring B] [Algebra R B]
variable [AddCommMonoid M] [AddCommMonoid N] [AddCommMonoid P]
variable [Module R M] [Module R N] [Module R P]
variable (r : R) (f g : M →ₗ[R] N)
variable (A) in
/-- `baseChange A f` for `f : M →ₗ[R] N` is the `A`-linear map `A ⊗[R] M →ₗ[A] A ⊗[R] N`.
This "base change" operation is also known as "extension of scalars". -/
def baseChange (f : M →ₗ[R] N) : A ⊗[R] M →ₗ[A] A ⊗[R] N :=
AlgebraTensorModule.map (LinearMap.id : A →ₗ[A] A) f
@[simp]
theorem baseChange_tmul (a : A) (x : M) : f.baseChange A (a ⊗ₜ x) = a ⊗ₜ f x :=
rfl
theorem baseChange_eq_ltensor : (f.baseChange A : A ⊗ M → A ⊗ N) = f.lTensor A :=
rfl
@[simp]
theorem baseChange_add : (f + g).baseChange A = f.baseChange A + g.baseChange A := by
ext
-- Porting note: added `-baseChange_tmul`
simp [baseChange_eq_ltensor, -baseChange_tmul]
@[simp]
theorem baseChange_zero : baseChange A (0 : M →ₗ[R] N) = 0 := by
ext
simp [baseChange_eq_ltensor]
@[simp]
theorem baseChange_smul : (r • f).baseChange A = r • f.baseChange A := by
ext
simp [baseChange_tmul]
@[simp]
lemma baseChange_id : (.id : M →ₗ[R] M).baseChange A = .id := by
ext; simp
lemma baseChange_comp (g : N →ₗ[R] P) :
(g ∘ₗ f).baseChange A = g.baseChange A ∘ₗ f.baseChange A := by
ext; simp
variable (R M) in
@[simp]
lemma baseChange_one : (1 : Module.End R M).baseChange A = 1 := baseChange_id
|
lemma baseChange_mul (f g : Module.End R M) :
(f * g).baseChange A = f.baseChange A * g.baseChange A := by
| Mathlib/RingTheory/TensorProduct/Basic.lean | 105 | 107 |
/-
Copyright (c) 2022 Damiano Testa. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Damiano Testa, Yuyang Zhao
-/
import Mathlib.Algebra.Order.GroupWithZero.Unbundled.Basic
import Mathlib.Algebra.Order.GroupWithZero.Unbundled.Defs
import Mathlib.Tactic.Linter.DeprecatedModule
deprecated_module (since := "2025-04-13")
| Mathlib/Algebra/Order/GroupWithZero/Unbundled.lean | 433 | 434 | |
/-
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.Convex.Between
import Mathlib.MeasureTheory.Constructions.BorelSpace.Basic
import Mathlib.MeasureTheory.Measure.Lebesgue.Basic
import Mathlib.Topology.MetricSpace.Holder
import Mathlib.Topology.MetricSpace.MetricSeparated
/-!
# Hausdorff measure and metric (outer) measures
In this file we define the `d`-dimensional Hausdorff measure on an (extended) metric space `X` and
the Hausdorff dimension of a set in an (extended) metric space. Let `μ d δ` be the maximal outer
measure such that `μ d δ s ≤ (EMetric.diam s) ^ d` for every set of diameter less than `δ`. Then
the Hausdorff measure `μH[d] s` of `s` is defined as `⨆ δ > 0, μ d δ s`. By Caratheodory theorem
`MeasureTheory.OuterMeasure.IsMetric.borel_le_caratheodory`, this is a Borel measure on `X`.
The value of `μH[d]`, `d > 0`, on a set `s` (measurable or not) is given by
```
μH[d] s = ⨆ (r : ℝ≥0∞) (hr : 0 < r), ⨅ (t : ℕ → Set X) (hts : s ⊆ ⋃ n, t n)
(ht : ∀ n, EMetric.diam (t n) ≤ r), ∑' n, EMetric.diam (t n) ^ d
```
For every set `s` for any `d < d'` we have either `μH[d] s = ∞` or `μH[d'] s = 0`, see
`MeasureTheory.Measure.hausdorffMeasure_zero_or_top`. In
`Mathlib.Topology.MetricSpace.HausdorffDimension` we use this fact to define the Hausdorff dimension
`dimH` of a set in an (extended) metric space.
We also define two generalizations of the Hausdorff measure. In one generalization (see
`MeasureTheory.Measure.mkMetric`) we take any function `m (diam s)` instead of `(diam s) ^ d`. In
an even more general definition (see `MeasureTheory.Measure.mkMetric'`) we use any function
of `m : Set X → ℝ≥0∞`. Some authors start with a partial function `m` defined only on some sets
`s : Set X` (e.g., only on balls or only on measurable sets). This is equivalent to our definition
applied to `MeasureTheory.extend m`.
We also define a predicate `MeasureTheory.OuterMeasure.IsMetric` which says that an outer measure
is additive on metric separated pairs of sets: `μ (s ∪ t) = μ s + μ t` provided that
`⨅ (x ∈ s) (y ∈ t), edist x y ≠ 0`. This is the property required for the Caratheodory theorem
`MeasureTheory.OuterMeasure.IsMetric.borel_le_caratheodory`, so we prove this theorem for any
metric outer measure, then prove that outer measures constructed using `mkMetric'` are metric outer
measures.
## Main definitions
* `MeasureTheory.OuterMeasure.IsMetric`: an outer measure `μ` is called *metric* if
`μ (s ∪ t) = μ s + μ t` for any two metric separated sets `s` and `t`. A metric outer measure in a
Borel extended metric space is guaranteed to satisfy the Caratheodory condition, see
`MeasureTheory.OuterMeasure.IsMetric.borel_le_caratheodory`.
* `MeasureTheory.OuterMeasure.mkMetric'` and its particular case
`MeasureTheory.OuterMeasure.mkMetric`: a construction of an outer measure that is guaranteed to
be metric. Both constructions are generalizations of the Hausdorff measure. The same measures
interpreted as Borel measures are called `MeasureTheory.Measure.mkMetric'` and
`MeasureTheory.Measure.mkMetric`.
* `MeasureTheory.Measure.hausdorffMeasure` a.k.a. `μH[d]`: the `d`-dimensional Hausdorff measure.
There are many definitions of the Hausdorff measure that differ from each other by a
multiplicative constant. We put
`μH[d] s = ⨆ r > 0, ⨅ (t : ℕ → Set X) (hts : s ⊆ ⋃ n, t n) (ht : ∀ n, EMetric.diam (t n) ≤ r),
∑' n, ⨆ (ht : ¬Set.Subsingleton (t n)), (EMetric.diam (t n)) ^ d`,
see `MeasureTheory.Measure.hausdorffMeasure_apply`. In the most interesting case `0 < d` one
can omit the `⨆ (ht : ¬Set.Subsingleton (t n))` part.
## Main statements
### Basic properties
* `MeasureTheory.OuterMeasure.IsMetric.borel_le_caratheodory`: if `μ` is a metric outer measure
on an extended metric space `X` (that is, it is additive on pairs of metric separated sets), then
every Borel set is Caratheodory measurable (hence, `μ` defines an actual
`MeasureTheory.Measure`). See also `MeasureTheory.Measure.mkMetric`.
* `MeasureTheory.Measure.hausdorffMeasure_mono`: `μH[d] s` is an antitone function
of `d`.
* `MeasureTheory.Measure.hausdorffMeasure_zero_or_top`: if `d₁ < d₂`, then for any `s`, either
`μH[d₂] s = 0` or `μH[d₁] s = ∞`. Together with the previous lemma, this means that `μH[d] s` is
equal to infinity on some ray `(-∞, D)` and is equal to zero on `(D, +∞)`, where `D` is a possibly
infinite number called the *Hausdorff dimension* of `s`; `μH[D] s` can be zero, infinity, or
anything in between.
* `MeasureTheory.Measure.noAtoms_hausdorff`: Hausdorff measure has no atoms.
### Hausdorff measure in `ℝⁿ`
* `MeasureTheory.hausdorffMeasure_pi_real`: for a nonempty `ι`, `μH[card ι]` on `ι → ℝ` equals
Lebesgue measure.
## Notations
We use the following notation localized in `MeasureTheory`.
- `μH[d]` : `MeasureTheory.Measure.hausdorffMeasure d`
## Implementation notes
There are a few similar constructions called the `d`-dimensional Hausdorff measure. E.g., some
sources only allow coverings by balls and use `r ^ d` instead of `(diam s) ^ d`. While these
construction lead to different Hausdorff measures, they lead to the same notion of the Hausdorff
dimension.
## References
* [Herbert Federer, Geometric Measure Theory, Chapter 2.10][Federer1996]
## Tags
Hausdorff measure, measure, metric measure
-/
open scoped NNReal ENNReal Topology
open EMetric Set Function Filter Encodable Module TopologicalSpace
noncomputable section
variable {ι X Y : Type*} [EMetricSpace X] [EMetricSpace Y]
namespace MeasureTheory
namespace OuterMeasure
/-!
### Metric outer measures
In this section we define metric outer measures and prove Caratheodory theorem: a metric outer
measure has the Caratheodory property.
-/
/-- We say that an outer measure `μ` in an (e)metric space is *metric* if `μ (s ∪ t) = μ s + μ t`
for any two metric separated sets `s`, `t`. -/
def IsMetric (μ : OuterMeasure X) : Prop :=
∀ s t : Set X, Metric.AreSeparated s t → μ (s ∪ t) = μ s + μ t
namespace IsMetric
variable {μ : OuterMeasure X}
/-- A metric outer measure is additive on a finite set of pairwise metric separated sets. -/
theorem finset_iUnion_of_pairwise_separated (hm : IsMetric μ) {I : Finset ι} {s : ι → Set X}
(hI : ∀ i ∈ I, ∀ j ∈ I, i ≠ j → Metric.AreSeparated (s i) (s j)) :
μ (⋃ i ∈ I, s i) = ∑ i ∈ I, μ (s i) := by
classical
induction I using Finset.induction_on with
| empty => simp
| insert i I hiI ihI =>
simp only [Finset.mem_insert] at hI
rw [Finset.set_biUnion_insert, hm, ihI, Finset.sum_insert hiI]
exacts [fun i hi j hj hij => hI i (Or.inr hi) j (Or.inr hj) hij,
Metric.AreSeparated.finset_iUnion_right fun j hj =>
hI i (Or.inl rfl) j (Or.inr hj) (ne_of_mem_of_not_mem hj hiI).symm]
/-- Caratheodory theorem. If `m` is a metric outer measure, then every Borel measurable set `t` is
Caratheodory measurable: for any (not necessarily measurable) set `s` we have
`μ (s ∩ t) + μ (s \ t) = μ s`. -/
theorem borel_le_caratheodory (hm : IsMetric μ) : borel X ≤ μ.caratheodory := by
rw [borel_eq_generateFrom_isClosed]
refine MeasurableSpace.generateFrom_le fun t ht => μ.isCaratheodory_iff_le.2 fun s => ?_
set S : ℕ → Set X := fun n => {x ∈ s | (↑n)⁻¹ ≤ infEdist x t}
have Ssep (n) : Metric.AreSeparated (S n) t :=
⟨n⁻¹, ENNReal.inv_ne_zero.2 (ENNReal.natCast_ne_top _),
fun x hx y hy ↦ hx.2.trans <| infEdist_le_edist_of_mem hy⟩
have Ssep' : ∀ n, Metric.AreSeparated (S n) (s ∩ t) := fun n =>
(Ssep n).mono Subset.rfl inter_subset_right
have S_sub : ∀ n, S n ⊆ s \ t := fun n =>
subset_inter inter_subset_left (Ssep n).subset_compl_right
have hSs : ∀ n, μ (s ∩ t) + μ (S n) ≤ μ s := fun n =>
calc
μ (s ∩ t) + μ (S n) = μ (s ∩ t ∪ S n) := Eq.symm <| hm _ _ <| (Ssep' n).symm
_ ≤ μ (s ∩ t ∪ s \ t) := μ.mono <| union_subset_union_right _ <| S_sub n
_ = μ s := by rw [inter_union_diff]
have iUnion_S : ⋃ n, S n = s \ t := by
refine Subset.antisymm (iUnion_subset S_sub) ?_
rintro x ⟨hxs, hxt⟩
rw [mem_iff_infEdist_zero_of_closed ht] at hxt
rcases ENNReal.exists_inv_nat_lt hxt with ⟨n, hn⟩
exact mem_iUnion.2 ⟨n, hxs, hn.le⟩
/- Now we have `∀ n, μ (s ∩ t) + μ (S n) ≤ μ s` and we need to prove
`μ (s ∩ t) + μ (⋃ n, S n) ≤ μ s`. We can't pass to the limit because
`μ` is only an outer measure. -/
by_cases htop : μ (s \ t) = ∞
· rw [htop, add_top, ← htop]
exact μ.mono diff_subset
suffices μ (⋃ n, S n) ≤ ⨆ n, μ (S n) by calc
μ (s ∩ t) + μ (s \ t) = μ (s ∩ t) + μ (⋃ n, S n) := by rw [iUnion_S]
_ ≤ μ (s ∩ t) + ⨆ n, μ (S n) := by gcongr
_ = ⨆ n, μ (s ∩ t) + μ (S n) := ENNReal.add_iSup ..
_ ≤ μ s := iSup_le hSs
/- It suffices to show that `∑' k, μ (S (k + 1) \ S k) ≠ ∞`. Indeed, if we have this,
then for all `N` we have `μ (⋃ n, S n) ≤ μ (S N) + ∑' k, m (S (N + k + 1) \ S (N + k))`
and the second term tends to zero, see `OuterMeasure.iUnion_nat_of_monotone_of_tsum_ne_top`
for details. -/
have : ∀ n, S n ⊆ S (n + 1) := fun n x hx =>
⟨hx.1, le_trans (ENNReal.inv_le_inv.2 <| Nat.cast_le.2 n.le_succ) hx.2⟩
refine (μ.iUnion_nat_of_monotone_of_tsum_ne_top this ?_).le; clear this
/- While the sets `S (k + 1) \ S k` are not pairwise metric separated, the sets in each
subsequence `S (2 * k + 1) \ S (2 * k)` and `S (2 * k + 2) \ S (2 * k)` are metric separated,
so `m` is additive on each of those sequences. -/
rw [← tsum_even_add_odd ENNReal.summable ENNReal.summable, ENNReal.add_ne_top]
suffices ∀ a, (∑' k : ℕ, μ (S (2 * k + 1 + a) \ S (2 * k + a))) ≠ ∞ from
⟨by simpa using this 0, by simpa using this 1⟩
refine fun r => ne_top_of_le_ne_top htop ?_
rw [← iUnion_S, ENNReal.tsum_eq_iSup_nat, iSup_le_iff]
intro n
rw [← hm.finset_iUnion_of_pairwise_separated]
· exact μ.mono (iUnion_subset fun i => iUnion_subset fun _ x hx => mem_iUnion.2 ⟨_, hx.1⟩)
suffices ∀ i j, i < j → Metric.AreSeparated (S (2 * i + 1 + r)) (s \ S (2 * j + r)) from
fun i _ j _ hij => hij.lt_or_lt.elim
(fun h => (this i j h).mono inter_subset_left fun x hx => by exact ⟨hx.1.1, hx.2⟩)
fun h => (this j i h).symm.mono (fun x hx => by exact ⟨hx.1.1, hx.2⟩) inter_subset_left
intro i j hj
have A : ((↑(2 * j + r))⁻¹ : ℝ≥0∞) < (↑(2 * i + 1 + r))⁻¹ := by
rw [ENNReal.inv_lt_inv, Nat.cast_lt]; omega
refine ⟨(↑(2 * i + 1 + r))⁻¹ - (↑(2 * j + r))⁻¹, by simpa [tsub_eq_zero_iff_le] using A,
fun x hx y hy => ?_⟩
have : infEdist y t < (↑(2 * j + r))⁻¹ := not_le.1 fun hle => hy.2 ⟨hy.1, hle⟩
rcases infEdist_lt_iff.mp this with ⟨z, hzt, hyz⟩
have hxz : (↑(2 * i + 1 + r))⁻¹ ≤ edist x z := le_infEdist.1 hx.2 _ hzt
apply ENNReal.le_of_add_le_add_right hyz.ne_top
refine le_trans ?_ (edist_triangle _ _ _)
refine (add_le_add le_rfl hyz.le).trans (Eq.trans_le ?_ hxz)
rw [tsub_add_cancel_of_le A.le]
theorem le_caratheodory [MeasurableSpace X] [BorelSpace X] (hm : IsMetric μ) :
‹MeasurableSpace X› ≤ μ.caratheodory := by
rw [BorelSpace.measurable_eq (α := X)]
exact hm.borel_le_caratheodory
end IsMetric
/-!
### Constructors of metric outer measures
In this section we provide constructors `MeasureTheory.OuterMeasure.mkMetric'` and
`MeasureTheory.OuterMeasure.mkMetric` and prove that these outer measures are metric outer
measures. We also prove basic lemmas about `map`/`comap` of these measures.
-/
/-- Auxiliary definition for `OuterMeasure.mkMetric'`: given a function on sets
`m : Set X → ℝ≥0∞`, returns the maximal outer measure `μ` such that `μ s ≤ m s`
for any set `s` of diameter at most `r`. -/
def mkMetric'.pre (m : Set X → ℝ≥0∞) (r : ℝ≥0∞) : OuterMeasure X :=
boundedBy <| extend fun s (_ : diam s ≤ r) => m s
/-- Given a function `m : Set X → ℝ≥0∞`, `mkMetric' m` is the supremum of `mkMetric'.pre m r`
over `r > 0`. Equivalently, it is the limit of `mkMetric'.pre m r` as `r` tends to zero from
the right. -/
def mkMetric' (m : Set X → ℝ≥0∞) : OuterMeasure X :=
⨆ r > 0, mkMetric'.pre m r
/-- Given a function `m : ℝ≥0∞ → ℝ≥0∞` and `r > 0`, let `μ r` be the maximal outer measure such that
`μ s ≤ m (EMetric.diam s)` whenever `EMetric.diam s < r`. Then `mkMetric m = ⨆ r > 0, μ r`. -/
def mkMetric (m : ℝ≥0∞ → ℝ≥0∞) : OuterMeasure X :=
mkMetric' fun s => m (diam s)
namespace mkMetric'
variable {m : Set X → ℝ≥0∞} {r : ℝ≥0∞} {μ : OuterMeasure X} {s : Set X}
theorem le_pre : μ ≤ pre m r ↔ ∀ s : Set X, diam s ≤ r → μ s ≤ m s := by
simp only [pre, le_boundedBy, extend, le_iInf_iff]
theorem pre_le (hs : diam s ≤ r) : pre m r s ≤ m s :=
(boundedBy_le _).trans <| iInf_le _ hs
theorem mono_pre (m : Set X → ℝ≥0∞) {r r' : ℝ≥0∞} (h : r ≤ r') : pre m r' ≤ pre m r :=
le_pre.2 fun _ hs => pre_le (hs.trans h)
theorem mono_pre_nat (m : Set X → ℝ≥0∞) : Monotone fun k : ℕ => pre m k⁻¹ :=
fun k l h => le_pre.2 fun _ hs => pre_le (hs.trans <| by simpa)
theorem tendsto_pre (m : Set X → ℝ≥0∞) (s : Set X) :
Tendsto (fun r => pre m r s) (𝓝[>] 0) (𝓝 <| mkMetric' m s) := by
rw [← map_coe_Ioi_atBot, tendsto_map'_iff]
simp only [mkMetric', OuterMeasure.iSup_apply, iSup_subtype']
exact tendsto_atBot_iSup fun r r' hr => mono_pre _ hr _
theorem tendsto_pre_nat (m : Set X → ℝ≥0∞) (s : Set X) :
Tendsto (fun n : ℕ => pre m n⁻¹ s) atTop (𝓝 <| mkMetric' m s) := by
refine (tendsto_pre m s).comp (tendsto_inf.2 ⟨ENNReal.tendsto_inv_nat_nhds_zero, ?_⟩)
refine tendsto_principal.2 (Eventually.of_forall fun n => ?_)
simp
theorem eq_iSup_nat (m : Set X → ℝ≥0∞) : mkMetric' m = ⨆ n : ℕ, mkMetric'.pre m n⁻¹ := by
ext1 s
rw [iSup_apply]
refine tendsto_nhds_unique (mkMetric'.tendsto_pre_nat m s)
(tendsto_atTop_iSup fun k l hkl => mkMetric'.mono_pre_nat m hkl s)
/-- `MeasureTheory.OuterMeasure.mkMetric'.pre m r` is a trimmed measure provided that
`m (closure s) = m s` for any set `s`. -/
theorem trim_pre [MeasurableSpace X] [OpensMeasurableSpace X] (m : Set X → ℝ≥0∞)
(hcl : ∀ s, m (closure s) = m s) (r : ℝ≥0∞) : (pre m r).trim = pre m r := by
refine le_antisymm (le_pre.2 fun s hs => ?_) (le_trim _)
rw [trim_eq_iInf]
refine iInf_le_of_le (closure s) <| iInf_le_of_le subset_closure <|
iInf_le_of_le measurableSet_closure ((pre_le ?_).trans_eq (hcl _))
rwa [diam_closure]
end mkMetric'
/-- An outer measure constructed using `OuterMeasure.mkMetric'` is a metric outer measure. -/
theorem mkMetric'_isMetric (m : Set X → ℝ≥0∞) : (mkMetric' m).IsMetric := by
rintro s t ⟨r, r0, hr⟩
refine tendsto_nhds_unique_of_eventuallyEq
(mkMetric'.tendsto_pre _ _) ((mkMetric'.tendsto_pre _ _).add (mkMetric'.tendsto_pre _ _)) ?_
rw [← pos_iff_ne_zero] at r0
filter_upwards [Ioo_mem_nhdsGT r0]
rintro ε ⟨_, εr⟩
refine boundedBy_union_of_top_of_nonempty_inter ?_
rintro u ⟨x, hxs, hxu⟩ ⟨y, hyt, hyu⟩
have : ε < diam u := εr.trans_le ((hr x hxs y hyt).trans <| edist_le_diam_of_mem hxu hyu)
exact iInf_eq_top.2 fun h => (this.not_le h).elim
/-- If `c ∉ {0, ∞}` and `m₁ d ≤ c * m₂ d` for `d < ε` for some `ε > 0`
(we use `≤ᶠ[𝓝[≥] 0]` to state this), then `mkMetric m₁ hm₁ ≤ c • mkMetric m₂ hm₂`. -/
theorem mkMetric_mono_smul {m₁ m₂ : ℝ≥0∞ → ℝ≥0∞} {c : ℝ≥0∞} (hc : c ≠ ∞) (h0 : c ≠ 0)
(hle : m₁ ≤ᶠ[𝓝[≥] 0] c • m₂) : (mkMetric m₁ : OuterMeasure X) ≤ c • mkMetric m₂ := by
classical
rcases (mem_nhdsGE_iff_exists_Ico_subset' zero_lt_one).1 hle with ⟨r, hr0, hr⟩
refine fun s =>
le_of_tendsto_of_tendsto (mkMetric'.tendsto_pre _ s)
(ENNReal.Tendsto.const_mul (mkMetric'.tendsto_pre _ s) (Or.inr hc))
(mem_of_superset (Ioo_mem_nhdsGT hr0) fun r' hr' => ?_)
simp only [mem_setOf_eq, mkMetric'.pre, RingHom.id_apply]
rw [← smul_eq_mul, ← smul_apply, smul_boundedBy hc]
refine le_boundedBy.2 (fun t => (boundedBy_le _).trans ?_) _
simp only [smul_eq_mul, Pi.smul_apply, extend, iInf_eq_if]
split_ifs with ht
· apply hr
exact ⟨zero_le _, ht.trans_lt hr'.2⟩
· simp [h0]
@[simp]
theorem mkMetric_top : (mkMetric (fun _ => ∞ : ℝ≥0∞ → ℝ≥0∞) : OuterMeasure X) = ⊤ := by
simp_rw [mkMetric, mkMetric', mkMetric'.pre, extend_top, boundedBy_top, eq_top_iff]
rw [le_iSup_iff]
intro b hb
simpa using hb ⊤
/-- If `m₁ d ≤ m₂ d` for `d < ε` for some `ε > 0` (we use `≤ᶠ[𝓝[≥] 0]` to state this), then
`mkMetric m₁ hm₁ ≤ mkMetric m₂ hm₂`. -/
theorem mkMetric_mono {m₁ m₂ : ℝ≥0∞ → ℝ≥0∞} (hle : m₁ ≤ᶠ[𝓝[≥] 0] m₂) :
(mkMetric m₁ : OuterMeasure X) ≤ mkMetric m₂ := by
convert @mkMetric_mono_smul X _ _ m₂ _ ENNReal.one_ne_top one_ne_zero _ <;> simp [*]
theorem isometry_comap_mkMetric (m : ℝ≥0∞ → ℝ≥0∞) {f : X → Y} (hf : Isometry f)
(H : Monotone m ∨ Surjective f) : comap f (mkMetric m) = mkMetric m := by
simp only [mkMetric, mkMetric', mkMetric'.pre, inducedOuterMeasure, comap_iSup]
refine surjective_id.iSup_congr id fun ε => surjective_id.iSup_congr id fun hε => ?_
rw [comap_boundedBy _ (H.imp _ id)]
· congr with s : 1
apply extend_congr
· simp [hf.ediam_image]
· intros; simp [hf.injective.subsingleton_image_iff, hf.ediam_image]
· intro h_mono s t hst
simp only [extend, le_iInf_iff]
intro ht
apply le_trans _ (h_mono (diam_mono hst))
simp only [(diam_mono hst).trans ht, le_refl, ciInf_pos]
theorem mkMetric_smul (m : ℝ≥0∞ → ℝ≥0∞) {c : ℝ≥0∞} (hc : c ≠ ∞) (hc' : c ≠ 0) :
(mkMetric (c • m) : OuterMeasure X) = c • mkMetric m := by
simp only [mkMetric, mkMetric', mkMetric'.pre, inducedOuterMeasure, ENNReal.smul_iSup]
simp_rw [smul_iSup, smul_boundedBy hc, smul_extend _ hc', Pi.smul_apply]
theorem mkMetric_nnreal_smul (m : ℝ≥0∞ → ℝ≥0∞) {c : ℝ≥0} (hc : c ≠ 0) :
(mkMetric (c • m) : OuterMeasure X) = c • mkMetric m := by
rw [ENNReal.smul_def, ENNReal.smul_def,
mkMetric_smul m ENNReal.coe_ne_top (ENNReal.coe_ne_zero.mpr hc)]
theorem isometry_map_mkMetric (m : ℝ≥0∞ → ℝ≥0∞) {f : X → Y} (hf : Isometry f)
(H : Monotone m ∨ Surjective f) : map f (mkMetric m) = restrict (range f) (mkMetric m) := by
rw [← isometry_comap_mkMetric _ hf H, map_comap]
theorem isometryEquiv_comap_mkMetric (m : ℝ≥0∞ → ℝ≥0∞) (f : X ≃ᵢ Y) :
comap f (mkMetric m) = mkMetric m :=
isometry_comap_mkMetric _ f.isometry (Or.inr f.surjective)
theorem isometryEquiv_map_mkMetric (m : ℝ≥0∞ → ℝ≥0∞) (f : X ≃ᵢ Y) :
map f (mkMetric m) = mkMetric m := by
rw [← isometryEquiv_comap_mkMetric _ f, map_comap_of_surjective f.surjective]
theorem trim_mkMetric [MeasurableSpace X] [BorelSpace X] (m : ℝ≥0∞ → ℝ≥0∞) :
(mkMetric m : OuterMeasure X).trim = mkMetric m := by
simp only [mkMetric, mkMetric'.eq_iSup_nat, trim_iSup]
congr 1 with n : 1
refine mkMetric'.trim_pre _ (fun s => ?_) _
simp
theorem le_mkMetric (m : ℝ≥0∞ → ℝ≥0∞) (μ : OuterMeasure X) (r : ℝ≥0∞) (h0 : 0 < r)
(hr : ∀ s, diam s ≤ r → μ s ≤ m (diam s)) : μ ≤ mkMetric m :=
le_iSup₂_of_le r h0 <| mkMetric'.le_pre.2 fun _ hs => hr _ hs
end OuterMeasure
/-!
### Metric measures
In this section we use `MeasureTheory.OuterMeasure.toMeasure` and theorems about
`MeasureTheory.OuterMeasure.mkMetric'`/`MeasureTheory.OuterMeasure.mkMetric` to define
`MeasureTheory.Measure.mkMetric'`/`MeasureTheory.Measure.mkMetric`. We also restate some lemmas
about metric outer measures for metric measures.
-/
namespace Measure
variable [MeasurableSpace X] [BorelSpace X]
/-- Given a function `m : Set X → ℝ≥0∞`, `mkMetric' m` is the supremum of `μ r`
over `r > 0`, where `μ r` is the maximal outer measure `μ` such that `μ s ≤ m s`
for all `s`. While each `μ r` is an *outer* measure, the supremum is a measure. -/
def mkMetric' (m : Set X → ℝ≥0∞) : Measure X :=
(OuterMeasure.mkMetric' m).toMeasure (OuterMeasure.mkMetric'_isMetric _).le_caratheodory
/-- Given a function `m : ℝ≥0∞ → ℝ≥0∞`, `mkMetric m` is the supremum of `μ r` over `r > 0`, where
`μ r` is the maximal outer measure `μ` such that `μ s ≤ m s` for all sets `s` that contain at least
two points. While each `mkMetric'.pre` is an *outer* measure, the supremum is a measure. -/
def mkMetric (m : ℝ≥0∞ → ℝ≥0∞) : Measure X :=
(OuterMeasure.mkMetric m).toMeasure (OuterMeasure.mkMetric'_isMetric _).le_caratheodory
@[simp]
theorem mkMetric'_toOuterMeasure (m : Set X → ℝ≥0∞) :
(mkMetric' m).toOuterMeasure = (OuterMeasure.mkMetric' m).trim :=
rfl
@[simp]
theorem mkMetric_toOuterMeasure (m : ℝ≥0∞ → ℝ≥0∞) :
(mkMetric m : Measure X).toOuterMeasure = OuterMeasure.mkMetric m :=
OuterMeasure.trim_mkMetric m
end Measure
theorem OuterMeasure.coe_mkMetric [MeasurableSpace X] [BorelSpace X] (m : ℝ≥0∞ → ℝ≥0∞) :
⇑(OuterMeasure.mkMetric m : OuterMeasure X) = Measure.mkMetric m := by
rw [← Measure.mkMetric_toOuterMeasure, Measure.coe_toOuterMeasure]
namespace Measure
variable [MeasurableSpace X] [BorelSpace X]
/-- If `c ∉ {0, ∞}` and `m₁ d ≤ c * m₂ d` for `d < ε` for some `ε > 0`
(we use `≤ᶠ[𝓝[≥] 0]` to state this), then `mkMetric m₁ hm₁ ≤ c • mkMetric m₂ hm₂`. -/
theorem mkMetric_mono_smul {m₁ m₂ : ℝ≥0∞ → ℝ≥0∞} {c : ℝ≥0∞} (hc : c ≠ ∞) (h0 : c ≠ 0)
(hle : m₁ ≤ᶠ[𝓝[≥] 0] c • m₂) : (mkMetric m₁ : Measure X) ≤ c • mkMetric m₂ := fun s ↦ by
rw [← OuterMeasure.coe_mkMetric, coe_smul, ← OuterMeasure.coe_mkMetric]
exact OuterMeasure.mkMetric_mono_smul hc h0 hle s
@[simp]
theorem mkMetric_top : (mkMetric (fun _ => ∞ : ℝ≥0∞ → ℝ≥0∞) : Measure X) = ⊤ := by
apply toOuterMeasure_injective
rw [mkMetric_toOuterMeasure, OuterMeasure.mkMetric_top, toOuterMeasure_top]
/-- If `m₁ d ≤ m₂ d` for `d < ε` for some `ε > 0` (we use `≤ᶠ[𝓝[≥] 0]` to state this), then
`mkMetric m₁ hm₁ ≤ mkMetric m₂ hm₂`. -/
theorem mkMetric_mono {m₁ m₂ : ℝ≥0∞ → ℝ≥0∞} (hle : m₁ ≤ᶠ[𝓝[≥] 0] m₂) :
(mkMetric m₁ : Measure X) ≤ mkMetric m₂ := by
convert @mkMetric_mono_smul X _ _ _ _ m₂ _ ENNReal.one_ne_top one_ne_zero _ <;> simp [*]
/-- A formula for `MeasureTheory.Measure.mkMetric`. -/
theorem mkMetric_apply (m : ℝ≥0∞ → ℝ≥0∞) (s : Set X) :
mkMetric m s =
⨆ (r : ℝ≥0∞) (_ : 0 < r),
⨅ (t : ℕ → Set X) (_ : s ⊆ iUnion t) (_ : ∀ n, diam (t n) ≤ r),
∑' n, ⨆ _ : (t n).Nonempty, m (diam (t n)) := by
classical
-- We mostly unfold the definitions but we need to switch the order of `∑'` and `⨅`
simp only [← OuterMeasure.coe_mkMetric, OuterMeasure.mkMetric, OuterMeasure.mkMetric',
OuterMeasure.iSup_apply, OuterMeasure.mkMetric'.pre, OuterMeasure.boundedBy_apply, extend]
refine
surjective_id.iSup_congr id fun r =>
iSup_congr_Prop Iff.rfl fun _ =>
surjective_id.iInf_congr _ fun t => iInf_congr_Prop Iff.rfl fun ht => ?_
dsimp
by_cases htr : ∀ n, diam (t n) ≤ r
· rw [iInf_eq_if, if_pos htr]
congr 1 with n : 1
simp only [iInf_eq_if, htr n, id, if_true, iSup_and']
· rw [iInf_eq_if, if_neg htr]
push_neg at htr; rcases htr with ⟨n, hn⟩
refine ENNReal.tsum_eq_top_of_eq_top ⟨n, ?_⟩
rw [iSup_eq_if, if_pos, iInf_eq_if, if_neg]
· exact hn.not_le
rcases diam_pos_iff.1 ((zero_le r).trans_lt hn) with ⟨x, hx, -⟩
exact ⟨x, hx⟩
theorem le_mkMetric (m : ℝ≥0∞ → ℝ≥0∞) (μ : Measure X) (ε : ℝ≥0∞) (h₀ : 0 < ε)
(h : ∀ s : Set X, diam s ≤ ε → μ s ≤ m (diam s)) : μ ≤ mkMetric m := by
rw [← toOuterMeasure_le, mkMetric_toOuterMeasure]
exact OuterMeasure.le_mkMetric m μ.toOuterMeasure ε h₀ h
/-- To bound the Hausdorff measure (or, more generally, for a measure defined using
`MeasureTheory.Measure.mkMetric`) of a set, one may use coverings with maximum diameter tending to
`0`, indexed by any sequence of countable types. -/
theorem mkMetric_le_liminf_tsum {β : Type*} {ι : β → Type*} [∀ n, Countable (ι n)] (s : Set X)
{l : Filter β} (r : β → ℝ≥0∞) (hr : Tendsto r l (𝓝 0)) (t : ∀ n : β, ι n → Set X)
(ht : ∀ᶠ n in l, ∀ i, diam (t n i) ≤ r n) (hst : ∀ᶠ n in l, s ⊆ ⋃ i, t n i) (m : ℝ≥0∞ → ℝ≥0∞) :
mkMetric m s ≤ liminf (fun n => ∑' i, m (diam (t n i))) l := by
haveI : ∀ n, Encodable (ι n) := fun n => Encodable.ofCountable _
simp only [mkMetric_apply]
refine iSup₂_le fun ε hε => ?_
refine le_of_forall_gt_imp_ge_of_dense fun c hc => ?_
rcases ((frequently_lt_of_liminf_lt (by isBoundedDefault) hc).and_eventually
((hr.eventually (gt_mem_nhds hε)).and (ht.and hst))).exists with
⟨n, hn, hrn, htn, hstn⟩
set u : ℕ → Set X := fun j => ⋃ b ∈ decode₂ (ι n) j, t n b
refine iInf₂_le_of_le u (by rwa [iUnion_decode₂]) ?_
refine iInf_le_of_le (fun j => ?_) ?_
· rw [EMetric.diam_iUnion_mem_option]
exact iSup₂_le fun _ _ => (htn _).trans hrn.le
· calc
(∑' j : ℕ, ⨆ _ : (u j).Nonempty, m (diam (u j))) = _ :=
tsum_iUnion_decode₂ (fun t : Set X => ⨆ _ : t.Nonempty, m (diam t)) (by simp) _
_ ≤ ∑' i : ι n, m (diam (t n i)) := ENNReal.tsum_le_tsum fun b => iSup_le fun _ => le_rfl
_ ≤ c := hn.le
/-- To bound the Hausdorff measure (or, more generally, for a measure defined using
`MeasureTheory.Measure.mkMetric`) of a set, one may use coverings with maximum diameter tending to
`0`, indexed by any sequence of finite types. -/
theorem mkMetric_le_liminf_sum {β : Type*} {ι : β → Type*} [hι : ∀ n, Fintype (ι n)] (s : Set X)
{l : Filter β} (r : β → ℝ≥0∞) (hr : Tendsto r l (𝓝 0)) (t : ∀ n : β, ι n → Set X)
(ht : ∀ᶠ n in l, ∀ i, diam (t n i) ≤ r n) (hst : ∀ᶠ n in l, s ⊆ ⋃ i, t n i) (m : ℝ≥0∞ → ℝ≥0∞) :
mkMetric m s ≤ liminf (fun n => ∑ i, m (diam (t n i))) l := by
simpa only [tsum_fintype] using mkMetric_le_liminf_tsum s r hr t ht hst m
/-!
### Hausdorff measure and Hausdorff dimension
-/
/-- Hausdorff measure on an (e)metric space. -/
def hausdorffMeasure (d : ℝ) : Measure X :=
mkMetric fun r => r ^ d
|
@[inherit_doc]
scoped[MeasureTheory] notation "μH[" d "]" => MeasureTheory.Measure.hausdorffMeasure d
theorem le_hausdorffMeasure (d : ℝ) (μ : Measure X) (ε : ℝ≥0∞) (h₀ : 0 < ε)
(h : ∀ s : Set X, diam s ≤ ε → μ s ≤ diam s ^ d) : μ ≤ μH[d] :=
le_mkMetric _ μ ε h₀ h
/-- A formula for `μH[d] s`. -/
theorem hausdorffMeasure_apply (d : ℝ) (s : Set X) :
μH[d] s =
⨆ (r : ℝ≥0∞) (_ : 0 < r),
⨅ (t : ℕ → Set X) (_ : s ⊆ ⋃ n, t n) (_ : ∀ n, diam (t n) ≤ r),
∑' n, ⨆ _ : (t n).Nonempty, diam (t n) ^ d :=
mkMetric_apply _ _
/-- To bound the Hausdorff measure of a set, one may use coverings with maximum diameter tending
to `0`, indexed by any sequence of countable types. -/
theorem hausdorffMeasure_le_liminf_tsum {β : Type*} {ι : β → Type*} [∀ n, Countable (ι n)]
(d : ℝ) (s : Set X) {l : Filter β} (r : β → ℝ≥0∞) (hr : Tendsto r l (𝓝 0))
(t : ∀ n : β, ι n → Set X) (ht : ∀ᶠ n in l, ∀ i, diam (t n i) ≤ r n)
| Mathlib/MeasureTheory/Measure/Hausdorff.lean | 536 | 556 |
/-
Copyright (c) 2021 Oliver Nash. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Oliver Nash
-/
import Mathlib.Algebra.Lie.Solvable
import Mathlib.Algebra.Lie.Quotient
import Mathlib.Algebra.Lie.Normalizer
import Mathlib.Algebra.Order.Archimedean.Basic
import Mathlib.LinearAlgebra.Eigenspace.Basic
import Mathlib.RingTheory.Artinian.Module
import Mathlib.RingTheory.Nilpotent.Lemmas
/-!
# Nilpotent Lie algebras
Like groups, Lie algebras admit a natural concept of nilpotency. More generally, any Lie module
carries a natural concept of nilpotency. We define these here via the lower central series.
## Main definitions
* `LieModule.lowerCentralSeries`
* `LieModule.IsNilpotent`
* `LieModule.maxNilpotentSubmodule`
* `LieAlgebra.maxNilpotentIdeal`
## Tags
lie algebra, lower central series, nilpotent, max nilpotent ideal
-/
universe u v w w₁ w₂
section NilpotentModules
variable {R : Type u} {L : Type v} {M : Type w}
variable [CommRing R] [LieRing L] [LieAlgebra R L] [AddCommGroup M] [Module R M]
variable [LieRingModule L M]
variable (k : ℕ) (N : LieSubmodule R L M)
namespace LieSubmodule
/-- A generalisation of the lower central series. The zeroth term is a specified Lie submodule of
a Lie module. In the case when we specify the top ideal `⊤` of the Lie algebra, regarded as a Lie
module over itself, we get the usual lower central series of a Lie algebra.
It can be more convenient to work with this generalisation when considering the lower central series
of a Lie submodule, regarded as a Lie module in its own right, since it provides a type-theoretic
expression of the fact that the terms of the Lie submodule's lower central series are also Lie
submodules of the enclosing Lie module.
See also `LieSubmodule.lowerCentralSeries_eq_lcs_comap` and
`LieSubmodule.lowerCentralSeries_map_eq_lcs` below, as well as `LieSubmodule.ucs`. -/
def lcs : LieSubmodule R L M → LieSubmodule R L M :=
(fun N => ⁅(⊤ : LieIdeal R L), N⁆)^[k]
@[simp]
theorem lcs_zero (N : LieSubmodule R L M) : N.lcs 0 = N :=
rfl
@[simp]
theorem lcs_succ : N.lcs (k + 1) = ⁅(⊤ : LieIdeal R L), N.lcs k⁆ :=
Function.iterate_succ_apply' (fun N' => ⁅⊤, N'⁆) k N
@[simp]
lemma lcs_sup {N₁ N₂ : LieSubmodule R L M} {k : ℕ} :
(N₁ ⊔ N₂).lcs k = N₁.lcs k ⊔ N₂.lcs k := by
induction k with
| zero => simp
| succ k ih => simp only [LieSubmodule.lcs_succ, ih, LieSubmodule.lie_sup]
end LieSubmodule
namespace LieModule
variable (R L M)
/-- The lower central series of Lie submodules of a Lie module. -/
def lowerCentralSeries : LieSubmodule R L M :=
(⊤ : LieSubmodule R L M).lcs k
@[simp]
theorem lowerCentralSeries_zero : lowerCentralSeries R L M 0 = ⊤ :=
rfl
@[simp]
theorem lowerCentralSeries_succ :
lowerCentralSeries R L M (k + 1) = ⁅(⊤ : LieIdeal R L), lowerCentralSeries R L M k⁆ :=
(⊤ : LieSubmodule R L M).lcs_succ k
private theorem coe_lowerCentralSeries_eq_int_aux (R₁ R₂ L M : Type*)
[CommRing R₁] [CommRing R₂] [AddCommGroup M]
[LieRing L] [LieAlgebra R₁ L] [LieAlgebra R₂ L] [Module R₁ M] [Module R₂ M] [LieRingModule L M]
[LieModule R₁ L M] (k : ℕ) :
let I := lowerCentralSeries R₂ L M k; let S : Set M := {⁅a, b⁆ | (a : L) (b ∈ I)}
(Submodule.span R₁ S : Set M) ≤ (Submodule.span R₂ S : Set M) := by
intro I S x hx
simp only [SetLike.mem_coe] at hx ⊢
induction hx using Submodule.closure_induction with
| zero => exact Submodule.zero_mem _
| add y z hy₁ hz₁ hy₂ hz₂ => exact Submodule.add_mem _ hy₂ hz₂
| smul_mem c y hy =>
obtain ⟨a, b, hb, rfl⟩ := hy
rw [← smul_lie]
exact Submodule.subset_span ⟨c • a, b, hb, rfl⟩
theorem coe_lowerCentralSeries_eq_int [LieModule R L M] (k : ℕ) :
(lowerCentralSeries R L M k : Set M) = (lowerCentralSeries ℤ L M k : Set M) := by
rw [← LieSubmodule.coe_toSubmodule, ← LieSubmodule.coe_toSubmodule]
induction k with
| zero => rfl
| succ k ih =>
rw [lowerCentralSeries_succ, lowerCentralSeries_succ]
rw [LieSubmodule.lieIdeal_oper_eq_linear_span', LieSubmodule.lieIdeal_oper_eq_linear_span']
rw [Set.ext_iff] at ih
simp only [SetLike.mem_coe, LieSubmodule.mem_toSubmodule] at ih
simp only [LieSubmodule.mem_top, ih, true_and]
apply le_antisymm
· exact coe_lowerCentralSeries_eq_int_aux _ _ L M k
· simp only [← ih]
exact coe_lowerCentralSeries_eq_int_aux _ _ L M k
end LieModule
namespace LieSubmodule
open LieModule
theorem lcs_le_self : N.lcs k ≤ N := by
induction k with
| zero => simp
| succ k ih =>
simp only [lcs_succ]
exact (LieSubmodule.mono_lie_right ⊤ ih).trans (N.lie_le_right ⊤)
variable [LieModule R L M]
theorem lowerCentralSeries_eq_lcs_comap : lowerCentralSeries R L N k = (N.lcs k).comap N.incl := by
induction k with
| zero => simp
| succ k ih =>
simp only [lcs_succ, lowerCentralSeries_succ] at ih ⊢
have : N.lcs k ≤ N.incl.range := by
rw [N.range_incl]
apply lcs_le_self
rw [ih, LieSubmodule.comap_bracket_eq _ N.incl _ N.ker_incl this]
theorem lowerCentralSeries_map_eq_lcs : (lowerCentralSeries R L N k).map N.incl = N.lcs k := by
rw [lowerCentralSeries_eq_lcs_comap, LieSubmodule.map_comap_incl, inf_eq_right]
apply lcs_le_self
theorem lowerCentralSeries_eq_bot_iff_lcs_eq_bot:
lowerCentralSeries R L N k = ⊥ ↔ lcs k N = ⊥ := by
refine ⟨fun h ↦ ?_, fun h ↦ ?_⟩
· rw [← N.lowerCentralSeries_map_eq_lcs, ← LieModuleHom.le_ker_iff_map]
simpa
· rw [N.lowerCentralSeries_eq_lcs_comap, comap_incl_eq_bot]
simp [h]
end LieSubmodule
namespace LieModule
variable {M₂ : Type w₁} [AddCommGroup M₂] [Module R M₂] [LieRingModule L M₂] [LieModule R L M₂]
variable (R L M)
theorem antitone_lowerCentralSeries : Antitone <| lowerCentralSeries R L M := by
intro l k
induction k generalizing l with
| zero => exact fun h ↦ (Nat.le_zero.mp h).symm ▸ le_rfl
| succ k ih =>
intro h
rcases Nat.of_le_succ h with (hk | hk)
· rw [lowerCentralSeries_succ]
exact (LieSubmodule.mono_lie_right ⊤ (ih hk)).trans (LieSubmodule.lie_le_right _ _)
· exact hk.symm ▸ le_rfl
theorem eventually_iInf_lowerCentralSeries_eq [IsArtinian R M] :
∀ᶠ l in Filter.atTop, ⨅ k, lowerCentralSeries R L M k = lowerCentralSeries R L M l := by
have h_wf : WellFoundedGT (LieSubmodule R L M)ᵒᵈ :=
LieSubmodule.wellFoundedLT_of_isArtinian R L M
obtain ⟨n, hn : ∀ m, n ≤ m → lowerCentralSeries R L M n = lowerCentralSeries R L M m⟩ :=
h_wf.monotone_chain_condition ⟨_, antitone_lowerCentralSeries R L M⟩
refine Filter.eventually_atTop.mpr ⟨n, fun l hl ↦ le_antisymm (iInf_le _ _) (le_iInf fun m ↦ ?_)⟩
rcases le_or_lt l m with h | h
· rw [← hn _ hl, ← hn _ (hl.trans h)]
· exact antitone_lowerCentralSeries R L M (le_of_lt h)
theorem trivial_iff_lower_central_eq_bot : IsTrivial L M ↔ lowerCentralSeries R L M 1 = ⊥ := by
constructor <;> intro h
· simp
· rw [LieSubmodule.eq_bot_iff] at h; apply IsTrivial.mk; intro x m; apply h
apply LieSubmodule.subset_lieSpan
simp only [LieSubmodule.top_coe, Subtype.exists, LieSubmodule.mem_top, exists_prop, true_and,
Set.mem_setOf]
exact ⟨x, m, rfl⟩
section
variable [LieModule R L M]
theorem iterate_toEnd_mem_lowerCentralSeries (x : L) (m : M) (k : ℕ) :
(toEnd R L M x)^[k] m ∈ lowerCentralSeries R L M k := by
induction k with
| zero => simp only [Function.iterate_zero, lowerCentralSeries_zero, LieSubmodule.mem_top]
| succ k ih =>
simp only [lowerCentralSeries_succ, Function.comp_apply, Function.iterate_succ',
toEnd_apply_apply]
exact LieSubmodule.lie_mem_lie (LieSubmodule.mem_top x) ih
theorem iterate_toEnd_mem_lowerCentralSeries₂ (x y : L) (m : M) (k : ℕ) :
(toEnd R L M x ∘ₗ toEnd R L M y)^[k] m ∈
lowerCentralSeries R L M (2 * k) := by
induction k with
| zero => simp
| succ k ih =>
have hk : 2 * k.succ = (2 * k + 1) + 1 := rfl
simp only [lowerCentralSeries_succ, Function.comp_apply, Function.iterate_succ', hk,
toEnd_apply_apply, LinearMap.coe_comp, toEnd_apply_apply]
refine LieSubmodule.lie_mem_lie (LieSubmodule.mem_top x) ?_
exact LieSubmodule.lie_mem_lie (LieSubmodule.mem_top y) ih
variable {R L M}
theorem map_lowerCentralSeries_le (f : M →ₗ⁅R,L⁆ M₂) :
(lowerCentralSeries R L M k).map f ≤ lowerCentralSeries R L M₂ k := by
induction k with
| zero => simp only [lowerCentralSeries_zero, le_top]
| succ k ih =>
simp only [LieModule.lowerCentralSeries_succ, LieSubmodule.map_bracket_eq]
exact LieSubmodule.mono_lie_right ⊤ ih
lemma map_lowerCentralSeries_eq {f : M →ₗ⁅R,L⁆ M₂} (hf : Function.Surjective f) :
(lowerCentralSeries R L M k).map f = lowerCentralSeries R L M₂ k := by
apply le_antisymm (map_lowerCentralSeries_le k f)
induction k with
| zero =>
rwa [lowerCentralSeries_zero, lowerCentralSeries_zero, top_le_iff, f.map_top,
f.range_eq_top]
| succ =>
simp only [lowerCentralSeries_succ, LieSubmodule.map_bracket_eq]
apply LieSubmodule.mono_lie_right
assumption
end
open LieAlgebra
theorem derivedSeries_le_lowerCentralSeries (k : ℕ) :
derivedSeries R L k ≤ lowerCentralSeries R L L k := by
induction k with
| zero => rw [derivedSeries_def, derivedSeriesOfIdeal_zero, lowerCentralSeries_zero]
| succ k h =>
have h' : derivedSeries R L k ≤ ⊤ := by simp only [le_top]
rw [derivedSeries_def, derivedSeriesOfIdeal_succ, lowerCentralSeries_succ]
exact LieSubmodule.mono_lie h' h
/-- A Lie module is nilpotent if its lower central series reaches 0 (in a finite number of
steps). -/
@[mk_iff isNilpotent_iff_int]
class IsNilpotent : Prop where
mk_int ::
nilpotent_int : ∃ k, lowerCentralSeries ℤ L M k = ⊥
section
variable [LieModule R L M]
/-- See also `LieModule.isNilpotent_iff_exists_ucs_eq_top`. -/
lemma isNilpotent_iff :
IsNilpotent L M ↔ ∃ k, lowerCentralSeries R L M k = ⊥ := by
simp [isNilpotent_iff_int, SetLike.ext'_iff, coe_lowerCentralSeries_eq_int R L M]
lemma IsNilpotent.nilpotent [IsNilpotent L M] : ∃ k, lowerCentralSeries R L M k = ⊥ :=
(isNilpotent_iff R L M).mp ‹_›
variable {R L} in
lemma IsNilpotent.mk {k : ℕ} (h : lowerCentralSeries R L M k = ⊥) : IsNilpotent L M :=
(isNilpotent_iff R L M).mpr ⟨k, h⟩
@[deprecated IsNilpotent.nilpotent (since := "2025-01-07")]
theorem exists_lowerCentralSeries_eq_bot_of_isNilpotent [IsNilpotent L M] :
∃ k, lowerCentralSeries R L M k = ⊥ :=
IsNilpotent.nilpotent R L M
@[simp] lemma iInf_lowerCentralSeries_eq_bot_of_isNilpotent [IsNilpotent L M] :
⨅ k, lowerCentralSeries R L M k = ⊥ := by
obtain ⟨k, hk⟩ := IsNilpotent.nilpotent R L M
rw [eq_bot_iff, ← hk]
exact iInf_le _ _
end
section
variable {R L M}
variable [LieModule R L M]
theorem _root_.LieSubmodule.isNilpotent_iff_exists_lcs_eq_bot (N : LieSubmodule R L M) :
LieModule.IsNilpotent L N ↔ ∃ k, N.lcs k = ⊥ := by
rw [isNilpotent_iff R L N]
refine exists_congr fun k => ?_
rw [N.lowerCentralSeries_eq_lcs_comap k, LieSubmodule.comap_incl_eq_bot,
inf_eq_right.mpr (N.lcs_le_self k)]
variable (R L M)
instance (priority := 100) trivialIsNilpotent [IsTrivial L M] : IsNilpotent L M :=
⟨by use 1; simp⟩
instance instIsNilpotentSup (M₁ M₂ : LieSubmodule R L M) [IsNilpotent L M₁] [IsNilpotent L M₂] :
IsNilpotent L (M₁ ⊔ M₂ : LieSubmodule R L M) := by
obtain ⟨k, hk⟩ := IsNilpotent.nilpotent R L M₁
obtain ⟨l, hl⟩ := IsNilpotent.nilpotent R L M₂
let lcs_eq_bot {m n} (N : LieSubmodule R L M) (le : m ≤ n) (hn : lowerCentralSeries R L N m = ⊥) :
lowerCentralSeries R L N n = ⊥ := by
simpa [hn] using antitone_lowerCentralSeries R L N le
have h₁ : lowerCentralSeries R L M₁ (k ⊔ l) = ⊥ := lcs_eq_bot M₁ (Nat.le_max_left k l) hk
have h₂ : lowerCentralSeries R L M₂ (k ⊔ l) = ⊥ := lcs_eq_bot M₂ (Nat.le_max_right k l) hl
refine (isNilpotent_iff R L (M₁ + M₂)).mpr ⟨k ⊔ l, ?_⟩
simp [LieSubmodule.add_eq_sup, (M₁ ⊔ M₂).lowerCentralSeries_eq_lcs_comap, LieSubmodule.lcs_sup,
(M₁.lowerCentralSeries_eq_bot_iff_lcs_eq_bot (k ⊔ l)).1 h₁,
(M₂.lowerCentralSeries_eq_bot_iff_lcs_eq_bot (k ⊔ l)).1 h₂, LieSubmodule.comap_incl_eq_bot]
theorem exists_forall_pow_toEnd_eq_zero [IsNilpotent L M] :
∃ k : ℕ, ∀ x : L, toEnd R L M x ^ k = 0 := by
obtain ⟨k, hM⟩ := IsNilpotent.nilpotent R L M
use k
intro x; ext m
rw [Module.End.pow_apply, LinearMap.zero_apply, ← @LieSubmodule.mem_bot R L M, ← hM]
exact iterate_toEnd_mem_lowerCentralSeries R L M x m k
theorem isNilpotent_toEnd_of_isNilpotent [IsNilpotent L M] (x : L) :
_root_.IsNilpotent (toEnd R L M x) := by
change ∃ k, toEnd R L M x ^ k = 0
have := exists_forall_pow_toEnd_eq_zero R L M
tauto
theorem isNilpotent_toEnd_of_isNilpotent₂ [IsNilpotent L M] (x y : L) :
_root_.IsNilpotent (toEnd R L M x ∘ₗ toEnd R L M y) := by
obtain ⟨k, hM⟩ := IsNilpotent.nilpotent R L M
replace hM : lowerCentralSeries R L M (2 * k) = ⊥ := by
rw [eq_bot_iff, ← hM]; exact antitone_lowerCentralSeries R L M (by omega)
use k
ext m
rw [Module.End.pow_apply, LinearMap.zero_apply, ← LieSubmodule.mem_bot (R := R) (L := L), ← hM]
exact iterate_toEnd_mem_lowerCentralSeries₂ R L M x y m k
@[simp] lemma maxGenEigenSpace_toEnd_eq_top [IsNilpotent L M] (x : L) :
((toEnd R L M x).maxGenEigenspace 0) = ⊤ := by
ext m
simp only [Module.End.mem_maxGenEigenspace, zero_smul, sub_zero, Submodule.mem_top,
iff_true]
obtain ⟨k, hk⟩ := exists_forall_pow_toEnd_eq_zero R L M
exact ⟨k, by simp [hk x]⟩
/-- If the quotient of a Lie module `M` by a Lie submodule on which the Lie algebra acts trivially
is nilpotent then `M` is nilpotent.
This is essentially the Lie module equivalent of the fact that a central
extension of nilpotent Lie algebras is nilpotent. See `LieAlgebra.nilpotent_of_nilpotent_quotient`
below for the corresponding result for Lie algebras. -/
theorem nilpotentOfNilpotentQuotient {N : LieSubmodule R L M} (h₁ : N ≤ maxTrivSubmodule R L M)
(h₂ : IsNilpotent L (M ⧸ N)) : IsNilpotent L M := by
rw [isNilpotent_iff R L] at h₂ ⊢
obtain ⟨k, hk⟩ := h₂
use k + 1
simp only [lowerCentralSeries_succ]
suffices lowerCentralSeries R L M k ≤ N by
replace this := LieSubmodule.mono_lie_right ⊤ (le_trans this h₁)
rwa [ideal_oper_maxTrivSubmodule_eq_bot, le_bot_iff] at this
rw [← LieSubmodule.Quotient.map_mk'_eq_bot_le, ← le_bot_iff, ← hk]
exact map_lowerCentralSeries_le k (LieSubmodule.Quotient.mk' N)
theorem isNilpotent_quotient_iff :
IsNilpotent L (M ⧸ N) ↔ ∃ k, lowerCentralSeries R L M k ≤ N := by
rw [isNilpotent_iff R L]
refine exists_congr fun k ↦ ?_
rw [← LieSubmodule.Quotient.map_mk'_eq_bot_le, map_lowerCentralSeries_eq k
(LieSubmodule.Quotient.surjective_mk' N)]
theorem iInf_lcs_le_of_isNilpotent_quot (h : IsNilpotent L (M ⧸ N)) :
⨅ k, lowerCentralSeries R L M k ≤ N := by
obtain ⟨k, hk⟩ := (isNilpotent_quotient_iff R L M N).mp h
exact iInf_le_of_le k hk
end
/-- Given a nilpotent Lie module `M` with lower central series `M = C₀ ≥ C₁ ≥ ⋯ ≥ Cₖ = ⊥`, this is
the natural number `k` (the number of inclusions).
For a non-nilpotent module, we use the junk value 0. -/
noncomputable def nilpotencyLength : ℕ :=
sInf {k | lowerCentralSeries ℤ L M k = ⊥}
@[simp]
theorem nilpotencyLength_eq_zero_iff [IsNilpotent L M] :
nilpotencyLength L M = 0 ↔ Subsingleton M := by
let s := {k | lowerCentralSeries ℤ L M k = ⊥}
have hs : s.Nonempty := by
obtain ⟨k, hk⟩ := IsNilpotent.nilpotent ℤ L M
exact ⟨k, hk⟩
change sInf s = 0 ↔ _
rw [← LieSubmodule.subsingleton_iff ℤ L M, ← subsingleton_iff_bot_eq_top, ←
lowerCentralSeries_zero, @eq_comm (LieSubmodule ℤ L M)]
refine ⟨fun h => h ▸ Nat.sInf_mem hs, fun h => ?_⟩
rw [Nat.sInf_eq_zero]
exact Or.inl h
section
variable [LieModule R L M]
theorem nilpotencyLength_eq_succ_iff (k : ℕ) :
nilpotencyLength L M = k + 1 ↔
lowerCentralSeries R L M (k + 1) = ⊥ ∧ lowerCentralSeries R L M k ≠ ⊥ := by
have aux (k : ℕ) : lowerCentralSeries R L M k = ⊥ ↔ lowerCentralSeries ℤ L M k = ⊥ := by
simp [SetLike.ext'_iff, coe_lowerCentralSeries_eq_int R L M]
let s := {k | lowerCentralSeries ℤ L M k = ⊥}
rw [aux, ne_eq, aux]
change sInf s = k + 1 ↔ k + 1 ∈ s ∧ k ∉ s
have hs : ∀ k₁ k₂, k₁ ≤ k₂ → k₁ ∈ s → k₂ ∈ s := by
rintro k₁ k₂ h₁₂ (h₁ : lowerCentralSeries ℤ L M k₁ = ⊥)
exact eq_bot_iff.mpr (h₁ ▸ antitone_lowerCentralSeries ℤ L M h₁₂)
exact Nat.sInf_upward_closed_eq_succ_iff hs k
@[simp]
theorem nilpotencyLength_eq_one_iff [Nontrivial M] :
nilpotencyLength L M = 1 ↔ IsTrivial L M := by
rw [nilpotencyLength_eq_succ_iff ℤ, ← trivial_iff_lower_central_eq_bot]
simp
theorem isTrivial_of_nilpotencyLength_le_one [IsNilpotent L M] (h : nilpotencyLength L M ≤ 1) :
IsTrivial L M := by
nontriviality M
rcases Nat.le_one_iff_eq_zero_or_eq_one.mp h with h | h
· rw [nilpotencyLength_eq_zero_iff] at h; infer_instance
· rwa [nilpotencyLength_eq_one_iff] at h
end
/-- Given a non-trivial nilpotent Lie module `M` with lower central series
`M = C₀ ≥ C₁ ≥ ⋯ ≥ Cₖ = ⊥`, this is the `k-1`th term in the lower central series (the last
non-trivial term).
For a trivial or non-nilpotent module, this is the bottom submodule, `⊥`. -/
noncomputable def lowerCentralSeriesLast : LieSubmodule R L M :=
match nilpotencyLength L M with
| 0 => ⊥
| k + 1 => lowerCentralSeries R L M k
theorem lowerCentralSeriesLast_le_max_triv [LieModule R L M] :
lowerCentralSeriesLast R L M ≤ maxTrivSubmodule R L M := by
rw [lowerCentralSeriesLast]
rcases h : nilpotencyLength L M with - | k
· exact bot_le
· rw [le_max_triv_iff_bracket_eq_bot]
rw [nilpotencyLength_eq_succ_iff R, lowerCentralSeries_succ] at h
exact h.1
theorem nontrivial_lowerCentralSeriesLast [LieModule R L M] [Nontrivial M] [IsNilpotent L M] :
Nontrivial (lowerCentralSeriesLast R L M) := by
rw [LieSubmodule.nontrivial_iff_ne_bot, lowerCentralSeriesLast]
cases h : nilpotencyLength L M
· rw [nilpotencyLength_eq_zero_iff, ← not_nontrivial_iff_subsingleton] at h
contradiction
· rw [nilpotencyLength_eq_succ_iff R] at h
exact h.2
theorem lowerCentralSeriesLast_le_of_not_isTrivial [IsNilpotent L M] (h : ¬ IsTrivial L M) :
lowerCentralSeriesLast R L M ≤ lowerCentralSeries R L M 1 := by
rw [lowerCentralSeriesLast]
replace h : 1 < nilpotencyLength L M := by
by_contra contra
have := isTrivial_of_nilpotencyLength_le_one L M (not_lt.mp contra)
contradiction
rcases hk : nilpotencyLength L M with - | k <;> rw [hk] at h
· contradiction
· exact antitone_lowerCentralSeries _ _ _ (Nat.lt_succ.mp h)
variable [LieModule R L M]
/-- For a nilpotent Lie module `M` of a Lie algebra `L`, the first term in the lower central series
of `M` contains a non-zero element on which `L` acts trivially unless the entire action is trivial.
Taking `M = L`, this provides a useful characterisation of Abelian-ness for nilpotent Lie
algebras. -/
lemma disjoint_lowerCentralSeries_maxTrivSubmodule_iff [IsNilpotent L M] :
Disjoint (lowerCentralSeries R L M 1) (maxTrivSubmodule R L M) ↔ IsTrivial L M := by
refine ⟨fun h ↦ ?_, fun h ↦ by simp⟩
nontriviality M
by_contra contra
have : lowerCentralSeriesLast R L M ≤ lowerCentralSeries R L M 1 ⊓ maxTrivSubmodule R L M :=
le_inf_iff.mpr ⟨lowerCentralSeriesLast_le_of_not_isTrivial R L M contra,
lowerCentralSeriesLast_le_max_triv R L M⟩
suffices ¬ Nontrivial (lowerCentralSeriesLast R L M) by
exact this (nontrivial_lowerCentralSeriesLast R L M)
rw [h.eq_bot, le_bot_iff] at this
exact this ▸ not_nontrivial _
theorem nontrivial_max_triv_of_isNilpotent [Nontrivial M] [IsNilpotent L M] :
Nontrivial (maxTrivSubmodule R L M) :=
Set.nontrivial_mono (lowerCentralSeriesLast_le_max_triv R L M)
(nontrivial_lowerCentralSeriesLast R L M)
@[simp]
theorem coe_lcs_range_toEnd_eq (k : ℕ) :
(lowerCentralSeries R (toEnd R L M).range M k : Submodule R M) =
lowerCentralSeries R L M k := by
induction k with
| zero => simp
| succ k ih =>
simp only [lowerCentralSeries_succ, LieSubmodule.lieIdeal_oper_eq_linear_span', ←
(lowerCentralSeries R (toEnd R L M).range M k).mem_toSubmodule, ih]
congr
ext m
constructor
· rintro ⟨⟨-, ⟨y, rfl⟩⟩, -, n, hn, rfl⟩
exact ⟨y, LieSubmodule.mem_top _, n, hn, rfl⟩
· rintro ⟨x, -, n, hn, rfl⟩
exact
⟨⟨toEnd R L M x, LieHom.mem_range_self _ x⟩, LieSubmodule.mem_top _, n, hn, rfl⟩
@[simp]
theorem isNilpotent_range_toEnd_iff :
IsNilpotent (toEnd R L M).range M ↔ IsNilpotent L M := by
simp only [isNilpotent_iff R _ M]
constructor <;> rintro ⟨k, hk⟩ <;> use k <;>
rw [← LieSubmodule.toSubmodule_inj] at hk ⊢ <;>
simpa using hk
end LieModule
namespace LieSubmodule
variable {N₁ N₂ : LieSubmodule R L M}
variable [LieModule R L M]
/-- The upper (aka ascending) central series.
See also `LieSubmodule.lcs`. -/
def ucs (k : ℕ) : LieSubmodule R L M → LieSubmodule R L M :=
normalizer^[k]
@[simp]
theorem ucs_zero : N.ucs 0 = N :=
rfl
@[simp]
theorem ucs_succ (k : ℕ) : N.ucs (k + 1) = (N.ucs k).normalizer :=
Function.iterate_succ_apply' normalizer k N
theorem ucs_add (k l : ℕ) : N.ucs (k + l) = (N.ucs l).ucs k :=
Function.iterate_add_apply normalizer k l N
@[gcongr, mono]
theorem ucs_mono (k : ℕ) (h : N₁ ≤ N₂) : N₁.ucs k ≤ N₂.ucs k := by
induction k with
| zero => simpa
| succ k ih =>
simp only [ucs_succ]
gcongr
theorem ucs_eq_self_of_normalizer_eq_self (h : N₁.normalizer = N₁) (k : ℕ) : N₁.ucs k = N₁ := by
induction k with
| zero => simp
| succ k ih => rwa [ucs_succ, ih]
/-- If a Lie module `M` contains a self-normalizing Lie submodule `N`, then all terms of the upper
central series of `M` are contained in `N`.
An important instance of this situation arises from a Cartan subalgebra `H ⊆ L` with the roles of
`L`, `M`, `N` played by `H`, `L`, `H`, respectively. -/
theorem ucs_le_of_normalizer_eq_self (h : N₁.normalizer = N₁) (k : ℕ) :
(⊥ : LieSubmodule R L M).ucs k ≤ N₁ := by
rw [← ucs_eq_self_of_normalizer_eq_self h k]
gcongr
simp
theorem lcs_add_le_iff (l k : ℕ) : N₁.lcs (l + k) ≤ N₂ ↔ N₁.lcs l ≤ N₂.ucs k := by
induction k generalizing l with
| zero => simp
| succ k ih =>
rw [(by abel : l + (k + 1) = l + 1 + k), ih, ucs_succ, lcs_succ, top_lie_le_iff_le_normalizer]
theorem lcs_le_iff (k : ℕ) : N₁.lcs k ≤ N₂ ↔ N₁ ≤ N₂.ucs k := by
convert lcs_add_le_iff (R := R) (L := L) (M := M) 0 k
rw [zero_add]
theorem gc_lcs_ucs (k : ℕ) :
GaloisConnection (fun N : LieSubmodule R L M => N.lcs k) fun N : LieSubmodule R L M =>
N.ucs k :=
fun _ _ => lcs_le_iff k
theorem ucs_eq_top_iff (k : ℕ) : N.ucs k = ⊤ ↔ LieModule.lowerCentralSeries R L M k ≤ N := by
rw [eq_top_iff, ← lcs_le_iff]; rfl
variable (R) in
theorem _root_.LieModule.isNilpotent_iff_exists_ucs_eq_top :
LieModule.IsNilpotent L M ↔ ∃ k, (⊥ : LieSubmodule R L M).ucs k = ⊤ := by
rw [LieModule.isNilpotent_iff R]; exact exists_congr fun k => by simp [ucs_eq_top_iff]
theorem ucs_comap_incl (k : ℕ) :
((⊥ : LieSubmodule R L M).ucs k).comap N.incl = (⊥ : LieSubmodule R L N).ucs k := by
induction k with
| zero => exact N.ker_incl
| succ k ih => simp [← ih]
theorem isNilpotent_iff_exists_self_le_ucs :
LieModule.IsNilpotent L N ↔ ∃ k, N ≤ (⊥ : LieSubmodule R L M).ucs k := by
simp_rw [LieModule.isNilpotent_iff_exists_ucs_eq_top R, ← ucs_comap_incl, comap_incl_eq_top]
theorem ucs_bot_one : (⊥ : LieSubmodule R L M).ucs 1 = LieModule.maxTrivSubmodule R L M := by
simp [LieSubmodule.normalizer_bot_eq_maxTrivSubmodule]
end LieSubmodule
section Morphisms
open LieModule Function
variable [LieModule R L M]
variable {L₂ M₂ : Type*} [LieRing L₂] [LieAlgebra R L₂]
variable [AddCommGroup M₂] [Module R M₂] [LieRingModule L₂ M₂]
variable {f : L →ₗ⁅R⁆ L₂} {g : M →ₗ[R] M₂}
variable (hfg : ∀ x m, ⁅f x, g m⁆ = g ⁅x, m⁆)
include hfg in
theorem lieModule_lcs_map_le (k : ℕ) :
(lowerCentralSeries R L M k : Submodule R M).map g ≤ lowerCentralSeries R L₂ M₂ k := by
induction k with
| zero =>
simp [LinearMap.range_eq_top, Submodule.map_top]
| succ k ih =>
rw [lowerCentralSeries_succ, LieSubmodule.lieIdeal_oper_eq_linear_span', Submodule.map_span,
Submodule.span_le]
rintro m₂ ⟨m, ⟨x, n, m_n, ⟨h₁, h₂⟩⟩, rfl⟩
simp only [lowerCentralSeries_succ, SetLike.mem_coe, LieSubmodule.mem_toSubmodule]
have : ∃ y : L₂, ∃ n : lowerCentralSeries R L₂ M₂ k, ⁅y, n⁆ = g m := by
use f x, ⟨g m_n, ih (Submodule.mem_map_of_mem h₁)⟩
simp [hfg x m_n, h₂]
obtain ⟨y, n, hn⟩ := this
rw [← hn]
apply LieSubmodule.lie_mem_lie
· simp
· exact SetLike.coe_mem n
variable [LieModule R L₂ M₂] (hg_inj : Injective g)
include hg_inj hfg in
theorem Function.Injective.lieModuleIsNilpotent [IsNilpotent L₂ M₂] : IsNilpotent L M := by
obtain ⟨k, hk⟩ := IsNilpotent.nilpotent R L₂ M₂
rw [isNilpotent_iff R]
use k
rw [← LieSubmodule.toSubmodule_inj] at hk ⊢
apply Submodule.map_injective_of_injective hg_inj
simpa [hk] using lieModule_lcs_map_le hfg k
variable (hf_surj : Surjective f) (hg_surj : Surjective g)
include hf_surj hg_surj hfg in
theorem Function.Surjective.lieModule_lcs_map_eq (k : ℕ) :
(lowerCentralSeries R L M k : Submodule R M).map g = lowerCentralSeries R L₂ M₂ k := by
refine le_antisymm (lieModule_lcs_map_le hfg k) ?_
induction k with
| zero => simpa [LinearMap.range_eq_top]
| succ k ih =>
suffices
{m | ∃ (x : L₂) (n : _), n ∈ lowerCentralSeries R L M k ∧ ⁅x, g n⁆ = m} ⊆
g '' {m | ∃ (x : L) (n : _), n ∈ lowerCentralSeries R L M k ∧ ⁅x, n⁆ = m} by
simp only [← LieSubmodule.mem_toSubmodule] at this
simp_rw [lowerCentralSeries_succ, LieSubmodule.lieIdeal_oper_eq_linear_span',
Submodule.map_span, LieSubmodule.mem_top, true_and, ← LieSubmodule.mem_toSubmodule]
refine Submodule.span_mono (Set.Subset.trans ?_ this)
rintro m₁ ⟨x, n, hn, rfl⟩
obtain ⟨n', hn', rfl⟩ := ih hn
exact ⟨x, n', hn', rfl⟩
rintro m₂ ⟨x, n, hn, rfl⟩
obtain ⟨y, rfl⟩ := hf_surj x
exact ⟨⁅y, n⁆, ⟨y, n, hn, rfl⟩, (hfg y n).symm⟩
include hf_surj hg_surj hfg in
theorem Function.Surjective.lieModuleIsNilpotent [IsNilpotent L M] : IsNilpotent L₂ M₂ := by
obtain ⟨k, hk⟩ := IsNilpotent.nilpotent R L M
rw [isNilpotent_iff R]
use k
rw [← LieSubmodule.toSubmodule_inj] at hk ⊢
simp [← hf_surj.lieModule_lcs_map_eq hfg hg_surj k, hk]
theorem Equiv.lieModule_isNilpotent_iff (f : L ≃ₗ⁅R⁆ L₂) (g : M ≃ₗ[R] M₂)
(hfg : ∀ x m, ⁅f x, g m⁆ = g ⁅x, m⁆) : IsNilpotent L M ↔ IsNilpotent L₂ M₂ := by
constructor <;> intro h
· have hg : Surjective (g : M →ₗ[R] M₂) := g.surjective
exact f.surjective.lieModuleIsNilpotent hfg hg
· have hg : Surjective (g.symm : M₂ →ₗ[R] M) := g.symm.surjective
refine f.symm.surjective.lieModuleIsNilpotent (fun x m => ?_) hg
rw [LinearEquiv.coe_coe, LieEquiv.coe_toLieHom, ← g.symm_apply_apply ⁅f.symm x, g.symm m⁆, ←
hfg, f.apply_symm_apply, g.apply_symm_apply]
@[simp]
theorem LieModule.isNilpotent_of_top_iff :
IsNilpotent (⊤ : LieSubalgebra R L) M ↔ IsNilpotent L M :=
Equiv.lieModule_isNilpotent_iff LieSubalgebra.topEquiv (1 : M ≃ₗ[R] M) fun _ _ => rfl
@[simp] lemma LieModule.isNilpotent_of_top_iff' :
IsNilpotent L {x // x ∈ (⊤ : LieSubmodule R L M)} ↔ IsNilpotent L M :=
Equiv.lieModule_isNilpotent_iff 1 (LinearEquiv.ofTop ⊤ rfl) fun _ _ ↦ rfl
end Morphisms
namespace LieModule
variable (R L M)
variable [LieModule R L M]
theorem isNilpotent_of_le (M₁ M₂ : LieSubmodule R L M) (h₁ : M₁ ≤ M₂) [IsNilpotent L M₂] :
IsNilpotent L M₁ := by
let f : L →ₗ⁅R⁆ L := LieHom.id
let g : M₁ →ₗ[R] M₂ := Submodule.inclusion h₁
have hfg : ∀ x m, ⁅f x, g m⁆ = g ⁅x, m⁆ := by aesop
exact (Submodule.inclusion_injective h₁).lieModuleIsNilpotent hfg
/-- The max nilpotent submodule is the `sSup` of all nilpotent submodules. -/
def maxNilpotentSubmodule :=
sSup { N : LieSubmodule R L M | IsNilpotent L N }
instance instMaxNilpotentSubmoduleIsNilpotent [IsNoetherian R M] :
IsNilpotent L (maxNilpotentSubmodule R L M) := by
have hwf := CompleteLattice.WellFoundedGT.isSupClosedCompact (LieSubmodule R L M) inferInstance
refine hwf { N : LieSubmodule R L M | IsNilpotent L N } ⟨⊥, ?_⟩ fun N₁ h₁ N₂ h₂ => ?_ <;>
simp_all <;> infer_instance
theorem isNilpotent_iff_le_maxNilpotentSubmodule [IsNoetherian R M] (N : LieSubmodule R L M) :
IsNilpotent L N ↔ N ≤ maxNilpotentSubmodule R L M :=
⟨fun h ↦ le_sSup h, fun h ↦ isNilpotent_of_le R L M N (maxNilpotentSubmodule R L M) h⟩
@[simp] lemma maxNilpotentSubmodule_eq_top_of_isNilpotent [LieModule.IsNilpotent L M] :
maxNilpotentSubmodule R L M = ⊤ := by
rw [eq_top_iff]
apply le_sSup
| simpa
end LieModule
end NilpotentModules
| Mathlib/Algebra/Lie/Nilpotent.lean | 739 | 743 |
/-
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.Basic
import Mathlib.CategoryTheory.Limits.Shapes.Kernels
/-!
# Left Homology of short complexes
Given a short complex `S : ShortComplex C`, which consists of two composable
maps `f : X₁ ⟶ X₂` and `g : X₂ ⟶ X₃` such that `f ≫ g = 0`, we shall define
here the "left homology" `S.leftHomology` of `S`. For this, we introduce the
notion of "left homology data". Such an `h : S.LeftHomologyData` consists of the
data of morphisms `i : K ⟶ X₂` and `π : K ⟶ H` such that `i` identifies
`K` with the kernel of `g : X₂ ⟶ X₃`, and that `π` identifies `H` with the cokernel
of the induced map `f' : X₁ ⟶ K`.
When such a `S.LeftHomologyData` exists, we shall say that `[S.HasLeftHomology]`
and we define `S.leftHomology` to be the `H` field of a chosen left homology data.
Similarly, we define `S.cycles` to be the `K` field.
The dual notion is defined in `RightHomologyData.lean`. In `Homology.lean`,
when `S` has two compatible left and right homology data (i.e. they give
the same `H` up to a canonical isomorphism), we shall define `[S.HasHomology]`
and `S.homology`.
-/
namespace CategoryTheory
open Category Limits
namespace ShortComplex
variable {C : Type*} [Category C] [HasZeroMorphisms C] (S : ShortComplex C)
{S₁ S₂ S₃ : ShortComplex C}
/-- A left homology data for a short complex `S` consists of morphisms `i : K ⟶ S.X₂` and
`π : K ⟶ H` such that `i` identifies `K` to the kernel of `g : S.X₂ ⟶ S.X₃`,
and that `π` identifies `H` to the cokernel of the induced map `f' : S.X₁ ⟶ K` -/
structure LeftHomologyData where
/-- a choice of kernel of `S.g : S.X₂ ⟶ S.X₃` -/
K : C
/-- a choice of cokernel of the induced morphism `S.f' : S.X₁ ⟶ K` -/
H : C
/-- the inclusion of cycles in `S.X₂` -/
i : K ⟶ S.X₂
/-- the projection from cycles to the (left) homology -/
π : K ⟶ H
/-- the kernel condition for `i` -/
wi : i ≫ S.g = 0
/-- `i : K ⟶ S.X₂` is a kernel of `g : S.X₂ ⟶ S.X₃` -/
hi : IsLimit (KernelFork.ofι i wi)
/-- the cokernel condition for `π` -/
wπ : hi.lift (KernelFork.ofι _ S.zero) ≫ π = 0
/-- `π : K ⟶ H` is a cokernel of the induced morphism `S.f' : S.X₁ ⟶ K` -/
hπ : IsColimit (CokernelCofork.ofπ π wπ)
initialize_simps_projections LeftHomologyData (-hi, -hπ)
namespace LeftHomologyData
/-- The chosen kernels and cokernels of the limits API give a `LeftHomologyData` -/
@[simps]
noncomputable def ofHasKernelOfHasCokernel
[HasKernel S.g] [HasCokernel (kernel.lift S.g S.f S.zero)] :
S.LeftHomologyData where
K := kernel S.g
H := cokernel (kernel.lift S.g S.f S.zero)
i := kernel.ι _
π := cokernel.π _
wi := kernel.condition _
hi := kernelIsKernel _
wπ := cokernel.condition _
hπ := cokernelIsCokernel _
attribute [reassoc (attr := simp)] wi wπ
variable {S}
variable (h : S.LeftHomologyData) {A : C}
instance : Mono h.i := ⟨fun _ _ => Fork.IsLimit.hom_ext h.hi⟩
instance : Epi h.π := ⟨fun _ _ => Cofork.IsColimit.hom_ext h.hπ⟩
/-- Any morphism `k : A ⟶ S.X₂` that is a cycle (i.e. `k ≫ S.g = 0`) lifts
to a morphism `A ⟶ K` -/
def liftK (k : A ⟶ S.X₂) (hk : k ≫ S.g = 0) : A ⟶ h.K := h.hi.lift (KernelFork.ofι k hk)
@[reassoc (attr := simp)]
lemma liftK_i (k : A ⟶ S.X₂) (hk : k ≫ S.g = 0) : h.liftK k hk ≫ h.i = k :=
h.hi.fac _ WalkingParallelPair.zero
/-- The (left) homology class `A ⟶ H` attached to a cycle `k : A ⟶ S.X₂` -/
@[simp]
def liftH (k : A ⟶ S.X₂) (hk : k ≫ S.g = 0) : A ⟶ h.H := h.liftK k hk ≫ h.π
/-- Given `h : LeftHomologyData S`, this is morphism `S.X₁ ⟶ h.K` induced
by `S.f : S.X₁ ⟶ S.X₂` and the fact that `h.K` is a kernel of `S.g : S.X₂ ⟶ S.X₃`. -/
def f' : S.X₁ ⟶ h.K := h.liftK S.f S.zero
@[reassoc (attr := simp)] lemma f'_i : h.f' ≫ h.i = S.f := liftK_i _ _ _
@[reassoc (attr := simp)] lemma f'_π : h.f' ≫ h.π = 0 := h.wπ
@[reassoc]
lemma liftK_π_eq_zero_of_boundary (k : A ⟶ S.X₂) (x : A ⟶ S.X₁) (hx : k = x ≫ S.f) :
h.liftK k (by rw [hx, assoc, S.zero, comp_zero]) ≫ h.π = 0 := by
rw [show 0 = (x ≫ h.f') ≫ h.π by simp]
congr 1
simp only [← cancel_mono h.i, hx, liftK_i, assoc, f'_i]
/-- For `h : S.LeftHomologyData`, this is a restatement of `h.hπ`, saying that
`π : h.K ⟶ h.H` is a cokernel of `h.f' : S.X₁ ⟶ h.K`. -/
def hπ' : IsColimit (CokernelCofork.ofπ h.π h.f'_π) := h.hπ
/-- The morphism `H ⟶ A` induced by a morphism `k : K ⟶ A` such that `f' ≫ k = 0` -/
def descH (k : h.K ⟶ A) (hk : h.f' ≫ k = 0) : h.H ⟶ A :=
h.hπ.desc (CokernelCofork.ofπ k hk)
@[reassoc (attr := simp)]
lemma π_descH (k : h.K ⟶ A) (hk : h.f' ≫ k = 0) : h.π ≫ h.descH k hk = k :=
h.hπ.fac (CokernelCofork.ofπ k hk) WalkingParallelPair.one
lemma isIso_i (hg : S.g = 0) : IsIso h.i :=
⟨h.liftK (𝟙 S.X₂) (by rw [hg, id_comp]),
by simp only [← cancel_mono h.i, id_comp, assoc, liftK_i, comp_id], liftK_i _ _ _⟩
lemma isIso_π (hf : S.f = 0) : IsIso h.π := by
have ⟨φ, hφ⟩ := CokernelCofork.IsColimit.desc' h.hπ' (𝟙 _)
(by rw [← cancel_mono h.i, comp_id, f'_i, zero_comp, hf])
dsimp at hφ
exact ⟨φ, hφ, by rw [← cancel_epi h.π, reassoc_of% hφ, comp_id]⟩
variable (S)
/-- When the second map `S.g` is zero, this is the left homology data on `S` given
by any colimit cokernel cofork of `S.f` -/
@[simps]
def ofIsColimitCokernelCofork (hg : S.g = 0) (c : CokernelCofork S.f) (hc : IsColimit c) :
S.LeftHomologyData where
K := S.X₂
H := c.pt
i := 𝟙 _
π := c.π
wi := by rw [id_comp, hg]
hi := KernelFork.IsLimit.ofId _ hg
wπ := CokernelCofork.condition _
hπ := IsColimit.ofIsoColimit hc (Cofork.ext (Iso.refl _))
| @[simp] lemma ofIsColimitCokernelCofork_f' (hg : S.g = 0) (c : CokernelCofork S.f)
(hc : IsColimit c) : (ofIsColimitCokernelCofork S hg c hc).f' = S.f := by
rw [← cancel_mono (ofIsColimitCokernelCofork S hg c hc).i, f'_i,
ofIsColimitCokernelCofork_i]
dsimp
rw [comp_id]
| Mathlib/Algebra/Homology/ShortComplex/LeftHomology.lean | 154 | 159 |
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