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/-
Copyright (c) 2014 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Leonardo de Moura, Simon Hudon, Mario Carneiro
-/
import Aesop
import Mathlib.Algebra.Group.Defs
import Mathlib.Data.Nat.Init
import Mathlib.Data.Int.Init
import Mathlib.Logic.Function.Iterate
import Mathlib.Tactic.SimpRw
import Mathlib.Tactic.SplitIfs
/-!
# Basic lemmas about semigroups, monoids, and groups
This file lists various basic lemmas about semigroups, monoids, and groups. Most proofs are
one-liners from the corresponding axioms. For the definitions of semigroups, monoids and groups, see
`Algebra/Group/Defs.lean`.
-/
assert_not_exists MonoidWithZero DenselyOrdered
open Function
variable {α β G M : Type*}
section ite
variable [Pow α β]
@[to_additive (attr := simp) dite_smul]
lemma pow_dite (p : Prop) [Decidable p] (a : α) (b : p → β) (c : ¬ p → β) :
a ^ (if h : p then b h else c h) = if h : p then a ^ b h else a ^ c h := by split_ifs <;> rfl
@[to_additive (attr := simp) smul_dite]
lemma dite_pow (p : Prop) [Decidable p] (a : p → α) (b : ¬ p → α) (c : β) :
(if h : p then a h else b h) ^ c = if h : p then a h ^ c else b h ^ c := by split_ifs <;> rfl
@[to_additive (attr := simp) ite_smul]
lemma pow_ite (p : Prop) [Decidable p] (a : α) (b c : β) :
a ^ (if p then b else c) = if p then a ^ b else a ^ c := pow_dite _ _ _ _
@[to_additive (attr := simp) smul_ite]
lemma ite_pow (p : Prop) [Decidable p] (a b : α) (c : β) :
(if p then a else b) ^ c = if p then a ^ c else b ^ c := dite_pow _ _ _ _
set_option linter.existingAttributeWarning false in
attribute [to_additive (attr := simp)] dite_smul smul_dite ite_smul smul_ite
end ite
section Semigroup
variable [Semigroup α]
@[to_additive]
instance Semigroup.to_isAssociative : Std.Associative (α := α) (· * ·) := ⟨mul_assoc⟩
/-- Composing two multiplications on the left by `y` then `x`
is equal to a multiplication on the left by `x * y`.
-/
@[to_additive (attr := simp) "Composing two additions on the left by `y` then `x`
is equal to an addition on the left by `x + y`."]
theorem comp_mul_left (x y : α) : (x * ·) ∘ (y * ·) = (x * y * ·) := by
ext z
simp [mul_assoc]
/-- Composing two multiplications on the right by `y` and `x`
is equal to a multiplication on the right by `y * x`.
-/
@[to_additive (attr := simp) "Composing two additions on the right by `y` and `x`
is equal to an addition on the right by `y + x`."]
theorem comp_mul_right (x y : α) : (· * x) ∘ (· * y) = (· * (y * x)) := by
ext z
simp [mul_assoc]
end Semigroup
@[to_additive]
instance CommMagma.to_isCommutative [CommMagma G] : Std.Commutative (α := G) (· * ·) := ⟨mul_comm⟩
section MulOneClass
variable [MulOneClass M]
@[to_additive]
theorem ite_mul_one {P : Prop} [Decidable P] {a b : M} :
ite P (a * b) 1 = ite P a 1 * ite P b 1 := by
by_cases h : P <;> simp [h]
@[to_additive]
theorem ite_one_mul {P : Prop} [Decidable P] {a b : M} :
ite P 1 (a * b) = ite P 1 a * ite P 1 b := by
by_cases h : P <;> simp [h]
@[to_additive]
theorem eq_one_iff_eq_one_of_mul_eq_one {a b : M} (h : a * b = 1) : a = 1 ↔ b = 1 := by
constructor <;> (rintro rfl; simpa using h)
@[to_additive]
theorem one_mul_eq_id : ((1 : M) * ·) = id :=
funext one_mul
@[to_additive]
theorem mul_one_eq_id : (· * (1 : M)) = id :=
funext mul_one
end MulOneClass
section CommSemigroup
variable [CommSemigroup G]
@[to_additive]
theorem mul_left_comm (a b c : G) : a * (b * c) = b * (a * c) := by
rw [← mul_assoc, mul_comm a, mul_assoc]
@[to_additive]
theorem mul_right_comm (a b c : G) : a * b * c = a * c * b := by
rw [mul_assoc, mul_comm b, mul_assoc]
@[to_additive]
theorem mul_mul_mul_comm (a b c d : G) : a * b * (c * d) = a * c * (b * d) := by
simp only [mul_left_comm, mul_assoc]
@[to_additive]
theorem mul_rotate (a b c : G) : a * b * c = b * c * a := by
simp only [mul_left_comm, mul_comm]
@[to_additive]
theorem mul_rotate' (a b c : G) : a * (b * c) = b * (c * a) := by
simp only [mul_left_comm, mul_comm]
end CommSemigroup
attribute [local simp] mul_assoc sub_eq_add_neg
section Monoid
variable [Monoid M] {a b : M} {m n : ℕ}
@[to_additive boole_nsmul]
lemma pow_boole (P : Prop) [Decidable P] (a : M) :
(a ^ if P then 1 else 0) = if P then a else 1 := by simp only [pow_ite, pow_one, pow_zero]
@[to_additive nsmul_add_sub_nsmul]
lemma pow_mul_pow_sub (a : M) (h : m ≤ n) : a ^ m * a ^ (n - m) = a ^ n := by
rw [← pow_add, Nat.add_comm, Nat.sub_add_cancel h]
@[to_additive sub_nsmul_nsmul_add]
lemma pow_sub_mul_pow (a : M) (h : m ≤ n) : a ^ (n - m) * a ^ m = a ^ n := by
rw [← pow_add, Nat.sub_add_cancel h]
@[to_additive sub_one_nsmul_add]
lemma mul_pow_sub_one (hn : n ≠ 0) (a : M) : a * a ^ (n - 1) = a ^ n := by
rw [← pow_succ', Nat.sub_add_cancel <| Nat.one_le_iff_ne_zero.2 hn]
@[to_additive add_sub_one_nsmul]
lemma pow_sub_one_mul (hn : n ≠ 0) (a : M) : a ^ (n - 1) * a = a ^ n := by
rw [← pow_succ, Nat.sub_add_cancel <| Nat.one_le_iff_ne_zero.2 hn]
/-- If `x ^ n = 1`, then `x ^ m` is the same as `x ^ (m % n)` -/
@[to_additive nsmul_eq_mod_nsmul "If `n • x = 0`, then `m • x` is the same as `(m % n) • x`"]
lemma pow_eq_pow_mod (m : ℕ) (ha : a ^ n = 1) : a ^ m = a ^ (m % n) := by
calc
a ^ m = a ^ (m % n + n * (m / n)) := by rw [Nat.mod_add_div]
_ = a ^ (m % n) := by simp [pow_add, pow_mul, ha]
@[to_additive] lemma pow_mul_pow_eq_one : ∀ n, a * b = 1 → a ^ n * b ^ n = 1
| 0, _ => by simp
| n + 1, h =>
calc
a ^ n.succ * b ^ n.succ = a ^ n * a * (b * b ^ n) := by rw [pow_succ, pow_succ']
_ = a ^ n * (a * b) * b ^ n := by simp only [mul_assoc]
_ = 1 := by simp [h, pow_mul_pow_eq_one]
@[to_additive (attr := simp)]
lemma mul_left_iterate (a : M) : ∀ n : ℕ, (a * ·)^[n] = (a ^ n * ·)
| 0 => by ext; simp
| n + 1 => by ext; simp [pow_succ, mul_left_iterate]
@[to_additive (attr := simp)]
lemma mul_right_iterate (a : M) : ∀ n : ℕ, (· * a)^[n] = (· * a ^ n)
| 0 => by ext; simp
| n + 1 => by ext; simp [pow_succ', mul_right_iterate]
@[to_additive]
lemma mul_left_iterate_apply_one (a : M) : (a * ·)^[n] 1 = a ^ n := by simp [mul_right_iterate]
@[to_additive]
lemma mul_right_iterate_apply_one (a : M) : (· * a)^[n] 1 = a ^ n := by simp [mul_right_iterate]
@[to_additive (attr := simp)]
lemma pow_iterate (k : ℕ) : ∀ n : ℕ, (fun x : M ↦ x ^ k)^[n] = (· ^ k ^ n)
| 0 => by ext; simp
| n + 1 => by ext; simp [pow_iterate, Nat.pow_succ', pow_mul]
end Monoid
section CommMonoid
variable [CommMonoid M] {x y z : M}
@[to_additive]
theorem inv_unique (hy : x * y = 1) (hz : x * z = 1) : y = z :=
left_inv_eq_right_inv (Trans.trans (mul_comm _ _) hy) hz
@[to_additive nsmul_add] lemma mul_pow (a b : M) : ∀ n, (a * b) ^ n = a ^ n * b ^ n
| 0 => by rw [pow_zero, pow_zero, pow_zero, one_mul]
| n + 1 => by rw [pow_succ', pow_succ', pow_succ', mul_pow, mul_mul_mul_comm]
end CommMonoid
section LeftCancelMonoid
variable [Monoid M] [IsLeftCancelMul M] {a b : M}
@[to_additive (attr := simp)]
theorem mul_eq_left : a * b = a ↔ b = 1 := calc
a * b = a ↔ a * b = a * 1 := by rw [mul_one]
_ ↔ b = 1 := mul_left_cancel_iff
@[deprecated (since := "2025-03-05")] alias mul_right_eq_self := mul_eq_left
@[deprecated (since := "2025-03-05")] alias add_right_eq_self := add_eq_left
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] mul_right_eq_self
@[to_additive (attr := simp)]
theorem left_eq_mul : a = a * b ↔ b = 1 :=
eq_comm.trans mul_eq_left
@[deprecated (since := "2025-03-05")] alias self_eq_mul_right := left_eq_mul
@[deprecated (since := "2025-03-05")] alias self_eq_add_right := left_eq_add
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] self_eq_mul_right
@[to_additive]
theorem mul_ne_left : a * b ≠ a ↔ b ≠ 1 := mul_eq_left.not
@[deprecated (since := "2025-03-05")] alias mul_right_ne_self := mul_ne_left
@[deprecated (since := "2025-03-05")] alias add_right_ne_self := add_ne_left
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] mul_right_ne_self
@[to_additive]
theorem left_ne_mul : a ≠ a * b ↔ b ≠ 1 := left_eq_mul.not
@[deprecated (since := "2025-03-05")] alias self_ne_mul_right := left_ne_mul
@[deprecated (since := "2025-03-05")] alias self_ne_add_right := left_ne_add
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] self_ne_mul_right
end LeftCancelMonoid
section RightCancelMonoid
variable [RightCancelMonoid M] {a b : M}
@[to_additive (attr := simp)]
theorem mul_eq_right : a * b = b ↔ a = 1 := calc
a * b = b ↔ a * b = 1 * b := by rw [one_mul]
_ ↔ a = 1 := mul_right_cancel_iff
@[deprecated (since := "2025-03-05")] alias mul_left_eq_self := mul_eq_right
@[deprecated (since := "2025-03-05")] alias add_left_eq_self := add_eq_right
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] mul_left_eq_self
@[to_additive (attr := simp)]
theorem right_eq_mul : b = a * b ↔ a = 1 :=
eq_comm.trans mul_eq_right
@[deprecated (since := "2025-03-05")] alias self_eq_mul_left := right_eq_mul
@[deprecated (since := "2025-03-05")] alias self_eq_add_left := right_eq_add
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] self_eq_mul_left
@[to_additive]
theorem mul_ne_right : a * b ≠ b ↔ a ≠ 1 := mul_eq_right.not
@[deprecated (since := "2025-03-05")] alias mul_left_ne_self := mul_ne_right
@[deprecated (since := "2025-03-05")] alias add_left_ne_self := add_ne_right
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] mul_left_ne_self
@[to_additive]
theorem right_ne_mul : b ≠ a * b ↔ a ≠ 1 := right_eq_mul.not
@[deprecated (since := "2025-03-05")] alias self_ne_mul_left := right_ne_mul
@[deprecated (since := "2025-03-05")] alias self_ne_add_left := right_ne_add
set_option linter.existingAttributeWarning false in
attribute [to_additive existing] self_ne_mul_left
end RightCancelMonoid
section CancelCommMonoid
variable [CancelCommMonoid α] {a b c d : α}
@[to_additive] lemma eq_iff_eq_of_mul_eq_mul (h : a * b = c * d) : a = c ↔ b = d := by aesop
@[to_additive] lemma ne_iff_ne_of_mul_eq_mul (h : a * b = c * d) : a ≠ c ↔ b ≠ d := by aesop
end CancelCommMonoid
section InvolutiveInv
variable [InvolutiveInv G] {a b : G}
@[to_additive (attr := simp)]
theorem inv_involutive : Function.Involutive (Inv.inv : G → G) :=
inv_inv
@[to_additive (attr := simp)]
theorem inv_surjective : Function.Surjective (Inv.inv : G → G) :=
inv_involutive.surjective
@[to_additive]
theorem inv_injective : Function.Injective (Inv.inv : G → G) :=
inv_involutive.injective
@[to_additive (attr := simp)]
theorem inv_inj : a⁻¹ = b⁻¹ ↔ a = b :=
inv_injective.eq_iff
@[to_additive]
theorem inv_eq_iff_eq_inv : a⁻¹ = b ↔ a = b⁻¹ :=
⟨fun h => h ▸ (inv_inv a).symm, fun h => h.symm ▸ inv_inv b⟩
variable (G)
@[to_additive]
theorem inv_comp_inv : Inv.inv ∘ Inv.inv = @id G :=
inv_involutive.comp_self
@[to_additive]
theorem leftInverse_inv : LeftInverse (fun a : G ↦ a⁻¹) fun a ↦ a⁻¹ :=
inv_inv
@[to_additive]
theorem rightInverse_inv : RightInverse (fun a : G ↦ a⁻¹) fun a ↦ a⁻¹ :=
inv_inv
end InvolutiveInv
section DivInvMonoid
variable [DivInvMonoid G]
@[to_additive]
theorem mul_one_div (x y : G) : x * (1 / y) = x / y := by
rw [div_eq_mul_inv, one_mul, div_eq_mul_inv]
@[to_additive, field_simps] -- The attributes are out of order on purpose
theorem mul_div_assoc' (a b c : G) : a * (b / c) = a * b / c :=
(mul_div_assoc _ _ _).symm
@[to_additive]
theorem mul_div (a b c : G) : a * (b / c) = a * b / c := by simp only [mul_assoc, div_eq_mul_inv]
@[to_additive]
theorem div_eq_mul_one_div (a b : G) : a / b = a * (1 / b) := by rw [div_eq_mul_inv, one_div]
end DivInvMonoid
section DivInvOneMonoid
variable [DivInvOneMonoid G]
@[to_additive (attr := simp)]
theorem div_one (a : G) : a / 1 = a := by simp [div_eq_mul_inv]
@[to_additive]
theorem one_div_one : (1 : G) / 1 = 1 :=
div_one _
end DivInvOneMonoid
section DivisionMonoid
variable [DivisionMonoid α] {a b c d : α}
attribute [local simp] mul_assoc div_eq_mul_inv
@[to_additive]
theorem eq_inv_of_mul_eq_one_right (h : a * b = 1) : b = a⁻¹ :=
(inv_eq_of_mul_eq_one_right h).symm
@[to_additive]
theorem eq_one_div_of_mul_eq_one_left (h : b * a = 1) : b = 1 / a := by
rw [eq_inv_of_mul_eq_one_left h, one_div]
@[to_additive]
theorem eq_one_div_of_mul_eq_one_right (h : a * b = 1) : b = 1 / a := by
rw [eq_inv_of_mul_eq_one_right h, one_div]
@[to_additive]
theorem eq_of_div_eq_one (h : a / b = 1) : a = b :=
inv_injective <| inv_eq_of_mul_eq_one_right <| by rwa [← div_eq_mul_inv]
@[to_additive]
lemma eq_of_inv_mul_eq_one (h : a⁻¹ * b = 1) : a = b := by simpa using eq_inv_of_mul_eq_one_left h
@[to_additive]
lemma eq_of_mul_inv_eq_one (h : a * b⁻¹ = 1) : a = b := by simpa using eq_inv_of_mul_eq_one_left h
@[to_additive]
theorem div_ne_one_of_ne : a ≠ b → a / b ≠ 1 :=
mt eq_of_div_eq_one
variable (a b c)
@[to_additive]
theorem one_div_mul_one_div_rev : 1 / a * (1 / b) = 1 / (b * a) := by simp
@[to_additive]
theorem inv_div_left : a⁻¹ / b = (b * a)⁻¹ := by simp
@[to_additive (attr := simp)]
theorem inv_div : (a / b)⁻¹ = b / a := by simp
@[to_additive]
theorem one_div_div : 1 / (a / b) = b / a := by simp
@[to_additive]
theorem one_div_one_div : 1 / (1 / a) = a := by simp
@[to_additive]
theorem div_eq_div_iff_comm : a / b = c / d ↔ b / a = d / c :=
inv_inj.symm.trans <| by simp only [inv_div]
@[to_additive]
instance (priority := 100) DivisionMonoid.toDivInvOneMonoid : DivInvOneMonoid α :=
{ DivisionMonoid.toDivInvMonoid with
inv_one := by simpa only [one_div, inv_inv] using (inv_div (1 : α) 1).symm }
@[to_additive (attr := simp)]
lemma inv_pow (a : α) : ∀ n : ℕ, a⁻¹ ^ n = (a ^ n)⁻¹
| 0 => by rw [pow_zero, pow_zero, inv_one]
| n + 1 => by rw [pow_succ', pow_succ, inv_pow _ n, mul_inv_rev]
-- the attributes are intentionally out of order. `smul_zero` proves `zsmul_zero`.
@[to_additive zsmul_zero, simp]
lemma one_zpow : ∀ n : ℤ, (1 : α) ^ n = 1
| (n : ℕ) => by rw [zpow_natCast, one_pow]
| .negSucc n => by rw [zpow_negSucc, one_pow, inv_one]
@[to_additive (attr := simp) neg_zsmul]
lemma zpow_neg (a : α) : ∀ n : ℤ, a ^ (-n) = (a ^ n)⁻¹
| (_ + 1 : ℕ) => DivInvMonoid.zpow_neg' _ _
| 0 => by simp
| Int.negSucc n => by
rw [zpow_negSucc, inv_inv, ← zpow_natCast]
rfl
@[to_additive neg_one_zsmul_add]
lemma mul_zpow_neg_one (a b : α) : (a * b) ^ (-1 : ℤ) = b ^ (-1 : ℤ) * a ^ (-1 : ℤ) := by
simp only [zpow_neg, zpow_one, mul_inv_rev]
@[to_additive zsmul_neg]
lemma inv_zpow (a : α) : ∀ n : ℤ, a⁻¹ ^ n = (a ^ n)⁻¹
| (n : ℕ) => by rw [zpow_natCast, zpow_natCast, inv_pow]
| .negSucc n => by rw [zpow_negSucc, zpow_negSucc, inv_pow]
@[to_additive (attr := simp) zsmul_neg']
lemma inv_zpow' (a : α) (n : ℤ) : a⁻¹ ^ n = a ^ (-n) := by rw [inv_zpow, zpow_neg]
@[to_additive nsmul_zero_sub]
lemma one_div_pow (a : α) (n : ℕ) : (1 / a) ^ n = 1 / a ^ n := by simp only [one_div, inv_pow]
@[to_additive zsmul_zero_sub]
lemma one_div_zpow (a : α) (n : ℤ) : (1 / a) ^ n = 1 / a ^ n := by simp only [one_div, inv_zpow]
variable {a b c}
@[to_additive (attr := simp)]
theorem inv_eq_one : a⁻¹ = 1 ↔ a = 1 :=
inv_injective.eq_iff' inv_one
@[to_additive (attr := simp)]
theorem one_eq_inv : 1 = a⁻¹ ↔ a = 1 :=
eq_comm.trans inv_eq_one
@[to_additive]
theorem inv_ne_one : a⁻¹ ≠ 1 ↔ a ≠ 1 :=
inv_eq_one.not
@[to_additive]
theorem eq_of_one_div_eq_one_div (h : 1 / a = 1 / b) : a = b := by
rw [← one_div_one_div a, h, one_div_one_div]
-- Note that `mul_zsmul` and `zpow_mul` have the primes swapped
-- when additivised since their argument order,
-- and therefore the more "natural" choice of lemma, is reversed.
@[to_additive mul_zsmul'] lemma zpow_mul (a : α) : ∀ m n : ℤ, a ^ (m * n) = (a ^ m) ^ n
| (m : ℕ), (n : ℕ) => by
rw [zpow_natCast, zpow_natCast, ← pow_mul, ← zpow_natCast]
rfl
| (m : ℕ), .negSucc n => by
rw [zpow_natCast, zpow_negSucc, ← pow_mul, Int.ofNat_mul_negSucc, zpow_neg, inv_inj,
← zpow_natCast]
| .negSucc m, (n : ℕ) => by
rw [zpow_natCast, zpow_negSucc, ← inv_pow, ← pow_mul, Int.negSucc_mul_ofNat, zpow_neg, inv_pow,
inv_inj, ← zpow_natCast]
| .negSucc m, .negSucc n => by
rw [zpow_negSucc, zpow_negSucc, Int.negSucc_mul_negSucc, inv_pow, inv_inv, ← pow_mul, ←
zpow_natCast]
rfl
@[to_additive mul_zsmul]
lemma zpow_mul' (a : α) (m n : ℤ) : a ^ (m * n) = (a ^ n) ^ m := by rw [Int.mul_comm, zpow_mul]
@[to_additive]
theorem zpow_comm (a : α) (m n : ℤ) : (a ^ m) ^ n = (a ^ n) ^ m := by rw [← zpow_mul, zpow_mul']
variable (a b c)
@[to_additive, field_simps] -- The attributes are out of order on purpose
theorem div_div_eq_mul_div : a / (b / c) = a * c / b := by simp
@[to_additive (attr := simp)]
theorem div_inv_eq_mul : a / b⁻¹ = a * b := by simp
@[to_additive]
theorem div_mul_eq_div_div_swap : a / (b * c) = a / c / b := by
simp only [mul_assoc, mul_inv_rev, div_eq_mul_inv]
end DivisionMonoid
section DivisionCommMonoid
variable [DivisionCommMonoid α] (a b c d : α)
attribute [local simp] mul_assoc mul_comm mul_left_comm div_eq_mul_inv
@[to_additive neg_add]
theorem mul_inv : (a * b)⁻¹ = a⁻¹ * b⁻¹ := by simp
@[to_additive]
theorem inv_div' : (a / b)⁻¹ = a⁻¹ / b⁻¹ := by simp
@[to_additive]
theorem div_eq_inv_mul : a / b = b⁻¹ * a := by simp
@[to_additive]
theorem inv_mul_eq_div : a⁻¹ * b = b / a := by simp
@[to_additive] lemma inv_div_comm (a b : α) : a⁻¹ / b = b⁻¹ / a := by simp
@[to_additive]
theorem inv_mul' : (a * b)⁻¹ = a⁻¹ / b := by simp
@[to_additive]
theorem inv_div_inv : a⁻¹ / b⁻¹ = b / a := by simp
@[to_additive]
theorem inv_inv_div_inv : (a⁻¹ / b⁻¹)⁻¹ = a / b := by simp
@[to_additive]
theorem one_div_mul_one_div : 1 / a * (1 / b) = 1 / (a * b) := by simp
@[to_additive]
theorem div_right_comm : a / b / c = a / c / b := by simp
@[to_additive, field_simps]
theorem div_div : a / b / c = a / (b * c) := by simp
@[to_additive]
theorem div_mul : a / b * c = a / (b / c) := by simp
@[to_additive]
theorem mul_div_left_comm : a * (b / c) = b * (a / c) := by simp
@[to_additive]
theorem mul_div_right_comm : a * b / c = a / c * b := by simp
@[to_additive]
theorem div_mul_eq_div_div : a / (b * c) = a / b / c := by simp
@[to_additive, field_simps]
theorem div_mul_eq_mul_div : a / b * c = a * c / b := by simp
@[to_additive]
theorem one_div_mul_eq_div : 1 / a * b = b / a := by simp
@[to_additive]
theorem mul_comm_div : a / b * c = a * (c / b) := by simp
@[to_additive]
theorem div_mul_comm : a / b * c = c / b * a := by simp
@[to_additive]
theorem div_mul_eq_div_mul_one_div : a / (b * c) = a / b * (1 / c) := by simp
@[to_additive]
theorem div_div_div_eq : a / b / (c / d) = a * d / (b * c) := by simp
@[to_additive]
theorem div_div_div_comm : a / b / (c / d) = a / c / (b / d) := by simp
@[to_additive]
theorem div_mul_div_comm : a / b * (c / d) = a * c / (b * d) := by simp
@[to_additive]
theorem mul_div_mul_comm : a * b / (c * d) = a / c * (b / d) := by simp
@[to_additive zsmul_add] lemma mul_zpow : ∀ n : ℤ, (a * b) ^ n = a ^ n * b ^ n
| (n : ℕ) => by simp_rw [zpow_natCast, mul_pow]
| .negSucc n => by simp_rw [zpow_negSucc, ← inv_pow, mul_inv, mul_pow]
@[to_additive nsmul_sub]
lemma div_pow (a b : α) (n : ℕ) : (a / b) ^ n = a ^ n / b ^ n := by
simp only [div_eq_mul_inv, mul_pow, inv_pow]
@[to_additive zsmul_sub]
lemma div_zpow (a b : α) (n : ℤ) : (a / b) ^ n = a ^ n / b ^ n := by
simp only [div_eq_mul_inv, mul_zpow, inv_zpow]
attribute [field_simps] div_pow div_zpow
end DivisionCommMonoid
section Group
variable [Group G] {a b c d : G} {n : ℤ}
@[to_additive (attr := simp)]
theorem div_eq_inv_self : a / b = b⁻¹ ↔ a = 1 := by rw [div_eq_mul_inv, mul_eq_right]
@[to_additive]
theorem mul_left_surjective (a : G) : Surjective (a * ·) :=
fun x ↦ ⟨a⁻¹ * x, mul_inv_cancel_left a x⟩
@[to_additive]
theorem mul_right_surjective (a : G) : Function.Surjective fun x ↦ x * a := fun x ↦
⟨x * a⁻¹, inv_mul_cancel_right x a⟩
@[to_additive]
theorem eq_mul_inv_of_mul_eq (h : a * c = b) : a = b * c⁻¹ := by simp [h.symm]
@[to_additive]
theorem eq_inv_mul_of_mul_eq (h : b * a = c) : a = b⁻¹ * c := by simp [h.symm]
@[to_additive]
theorem inv_mul_eq_of_eq_mul (h : b = a * c) : a⁻¹ * b = c := by simp [h]
@[to_additive]
theorem mul_inv_eq_of_eq_mul (h : a = c * b) : a * b⁻¹ = c := by simp [h]
@[to_additive]
theorem eq_mul_of_mul_inv_eq (h : a * c⁻¹ = b) : a = b * c := by simp [h.symm]
@[to_additive]
theorem eq_mul_of_inv_mul_eq (h : b⁻¹ * a = c) : a = b * c := by simp [h.symm, mul_inv_cancel_left]
@[to_additive]
theorem mul_eq_of_eq_inv_mul (h : b = a⁻¹ * c) : a * b = c := by rw [h, mul_inv_cancel_left]
@[to_additive]
theorem mul_eq_of_eq_mul_inv (h : a = c * b⁻¹) : a * b = c := by simp [h]
@[to_additive]
theorem mul_eq_one_iff_eq_inv : a * b = 1 ↔ a = b⁻¹ :=
⟨eq_inv_of_mul_eq_one_left, fun h ↦ by rw [h, inv_mul_cancel]⟩
@[to_additive]
theorem mul_eq_one_iff_inv_eq : a * b = 1 ↔ a⁻¹ = b := by
rw [mul_eq_one_iff_eq_inv, inv_eq_iff_eq_inv]
/-- Variant of `mul_eq_one_iff_eq_inv` with swapped equality. -/
@[to_additive]
theorem mul_eq_one_iff_eq_inv' : a * b = 1 ↔ b = a⁻¹ := by
rw [mul_eq_one_iff_inv_eq, eq_comm]
/-- Variant of `mul_eq_one_iff_inv_eq` with swapped equality. -/
@[to_additive]
theorem mul_eq_one_iff_inv_eq' : a * b = 1 ↔ b⁻¹ = a := by
rw [mul_eq_one_iff_eq_inv, eq_comm]
@[to_additive]
theorem eq_inv_iff_mul_eq_one : a = b⁻¹ ↔ a * b = 1 :=
mul_eq_one_iff_eq_inv.symm
@[to_additive]
theorem inv_eq_iff_mul_eq_one : a⁻¹ = b ↔ a * b = 1 :=
mul_eq_one_iff_inv_eq.symm
@[to_additive]
theorem eq_mul_inv_iff_mul_eq : a = b * c⁻¹ ↔ a * c = b :=
⟨fun h ↦ by rw [h, inv_mul_cancel_right], fun h ↦ by rw [← h, mul_inv_cancel_right]⟩
@[to_additive]
theorem eq_inv_mul_iff_mul_eq : a = b⁻¹ * c ↔ b * a = c :=
⟨fun h ↦ by rw [h, mul_inv_cancel_left], fun h ↦ by rw [← h, inv_mul_cancel_left]⟩
@[to_additive]
theorem inv_mul_eq_iff_eq_mul : a⁻¹ * b = c ↔ b = a * c :=
⟨fun h ↦ by rw [← h, mul_inv_cancel_left], fun h ↦ by rw [h, inv_mul_cancel_left]⟩
@[to_additive]
theorem mul_inv_eq_iff_eq_mul : a * b⁻¹ = c ↔ a = c * b :=
⟨fun h ↦ by rw [← h, inv_mul_cancel_right], fun h ↦ by rw [h, mul_inv_cancel_right]⟩
@[to_additive]
theorem mul_inv_eq_one : a * b⁻¹ = 1 ↔ a = b := by rw [mul_eq_one_iff_eq_inv, inv_inv]
@[to_additive]
theorem inv_mul_eq_one : a⁻¹ * b = 1 ↔ a = b := by rw [mul_eq_one_iff_eq_inv, inv_inj]
@[to_additive (attr := simp)]
theorem conj_eq_one_iff : a * b * a⁻¹ = 1 ↔ b = 1 := by
rw [mul_inv_eq_one, mul_eq_left]
@[to_additive]
theorem div_left_injective : Function.Injective fun a ↦ a / b := by
-- FIXME this could be by `simpa`, but it fails. This is probably a bug in `simpa`.
simp only [div_eq_mul_inv]
exact fun a a' h ↦ mul_left_injective b⁻¹ h
@[to_additive]
theorem div_right_injective : Function.Injective fun a ↦ b / a := by
-- FIXME see above
simp only [div_eq_mul_inv]
exact fun a a' h ↦ inv_injective (mul_right_injective b h)
@[to_additive (attr := simp)]
lemma div_mul_cancel_right (a b : G) : a / (b * a) = b⁻¹ := by rw [← inv_div, mul_div_cancel_right]
@[to_additive (attr := simp)]
theorem mul_div_mul_right_eq_div (a b c : G) : a * c / (b * c) = a / b := by
rw [div_mul_eq_div_div_swap]; simp only [mul_left_inj, eq_self_iff_true, mul_div_cancel_right]
@[to_additive eq_sub_of_add_eq]
theorem eq_div_of_mul_eq' (h : a * c = b) : a = b / c := by simp [← h]
@[to_additive sub_eq_of_eq_add]
theorem div_eq_of_eq_mul'' (h : a = c * b) : a / b = c := by simp [h]
@[to_additive]
theorem eq_mul_of_div_eq (h : a / c = b) : a = b * c := by simp [← h]
@[to_additive]
theorem mul_eq_of_eq_div (h : a = c / b) : a * b = c := by simp [h]
@[to_additive (attr := simp)]
theorem div_right_inj : a / b = a / c ↔ b = c :=
div_right_injective.eq_iff
@[to_additive (attr := simp)]
theorem div_left_inj : b / a = c / a ↔ b = c := by
rw [div_eq_mul_inv, div_eq_mul_inv]
exact mul_left_inj _
@[to_additive (attr := simp)]
theorem div_mul_div_cancel (a b c : G) : a / b * (b / c) = a / c := by
rw [← mul_div_assoc, div_mul_cancel]
@[to_additive (attr := simp)]
theorem div_div_div_cancel_right (a b c : G) : a / c / (b / c) = a / b := by
rw [← inv_div c b, div_inv_eq_mul, div_mul_div_cancel]
@[to_additive]
theorem div_eq_one : a / b = 1 ↔ a = b :=
⟨eq_of_div_eq_one, fun h ↦ by rw [h, div_self']⟩
alias ⟨_, div_eq_one_of_eq⟩ := div_eq_one
alias ⟨_, sub_eq_zero_of_eq⟩ := sub_eq_zero
@[to_additive]
theorem div_ne_one : a / b ≠ 1 ↔ a ≠ b :=
not_congr div_eq_one
@[to_additive (attr := simp)]
theorem div_eq_self : a / b = a ↔ b = 1 := by rw [div_eq_mul_inv, mul_eq_left, inv_eq_one]
@[to_additive eq_sub_iff_add_eq]
theorem eq_div_iff_mul_eq' : a = b / c ↔ a * c = b := by rw [div_eq_mul_inv, eq_mul_inv_iff_mul_eq]
@[to_additive]
theorem div_eq_iff_eq_mul : a / b = c ↔ a = c * b := by rw [div_eq_mul_inv, mul_inv_eq_iff_eq_mul]
@[to_additive]
theorem eq_iff_eq_of_div_eq_div (H : a / b = c / d) : a = b ↔ c = d := by
rw [← div_eq_one, H, div_eq_one]
@[to_additive]
theorem leftInverse_div_mul_left (c : G) : Function.LeftInverse (fun x ↦ x / c) fun x ↦ x * c :=
fun x ↦ mul_div_cancel_right x c
@[to_additive]
theorem leftInverse_mul_left_div (c : G) : Function.LeftInverse (fun x ↦ x * c) fun x ↦ x / c :=
fun x ↦ div_mul_cancel x c
@[to_additive]
theorem leftInverse_mul_right_inv_mul (c : G) :
Function.LeftInverse (fun x ↦ c * x) fun x ↦ c⁻¹ * x :=
fun x ↦ mul_inv_cancel_left c x
@[to_additive]
theorem leftInverse_inv_mul_mul_right (c : G) :
Function.LeftInverse (fun x ↦ c⁻¹ * x) fun x ↦ c * x :=
fun x ↦ inv_mul_cancel_left c x
@[to_additive (attr := simp) natAbs_nsmul_eq_zero]
lemma pow_natAbs_eq_one : a ^ n.natAbs = 1 ↔ a ^ n = 1 := by cases n <;> simp
@[to_additive sub_nsmul]
lemma pow_sub (a : G) {m n : ℕ} (h : n ≤ m) : a ^ (m - n) = a ^ m * (a ^ n)⁻¹ :=
eq_mul_inv_of_mul_eq <| by rw [← pow_add, Nat.sub_add_cancel h]
@[to_additive sub_nsmul_neg]
theorem inv_pow_sub (a : G) {m n : ℕ} (h : n ≤ m) : a⁻¹ ^ (m - n) = (a ^ m)⁻¹ * a ^ n := by
rw [pow_sub a⁻¹ h, inv_pow, inv_pow, inv_inv]
@[to_additive add_one_zsmul]
lemma zpow_add_one (a : G) : ∀ n : ℤ, a ^ (n + 1) = a ^ n * a
| (n : ℕ) => by simp only [← Int.natCast_succ, zpow_natCast, pow_succ]
| -1 => by simp [Int.add_left_neg]
| .negSucc (n + 1) => by
rw [zpow_negSucc, pow_succ', mul_inv_rev, inv_mul_cancel_right]
rw [Int.negSucc_eq, Int.neg_add, Int.neg_add_cancel_right]
exact zpow_negSucc _ _
@[to_additive sub_one_zsmul]
lemma zpow_sub_one (a : G) (n : ℤ) : a ^ (n - 1) = a ^ n * a⁻¹ :=
calc
a ^ (n - 1) = a ^ (n - 1) * a * a⁻¹ := (mul_inv_cancel_right _ _).symm
_ = a ^ n * a⁻¹ := by rw [← zpow_add_one, Int.sub_add_cancel]
@[to_additive add_zsmul]
lemma zpow_add (a : G) (m n : ℤ) : a ^ (m + n) = a ^ m * a ^ n := by
induction n with
| hz => simp
| hp n ihn => simp only [← Int.add_assoc, zpow_add_one, ihn, mul_assoc]
| hn n ihn => rw [zpow_sub_one, ← mul_assoc, ← ihn, ← zpow_sub_one, Int.add_sub_assoc]
@[to_additive one_add_zsmul]
lemma zpow_one_add (a : G) (n : ℤ) : a ^ (1 + n) = a * a ^ n := by rw [zpow_add, zpow_one]
@[to_additive add_zsmul_self]
lemma mul_self_zpow (a : G) (n : ℤ) : a * a ^ n = a ^ (n + 1) := by
rw [Int.add_comm, zpow_add, zpow_one]
@[to_additive add_self_zsmul]
lemma mul_zpow_self (a : G) (n : ℤ) : a ^ n * a = a ^ (n + 1) := (zpow_add_one ..).symm
@[to_additive sub_zsmul] lemma zpow_sub (a : G) (m n : ℤ) : a ^ (m - n) = a ^ m * (a ^ n)⁻¹ := by
rw [Int.sub_eq_add_neg, zpow_add, zpow_neg]
@[to_additive natCast_sub_natCast_zsmul]
lemma zpow_natCast_sub_natCast (a : G) (m n : ℕ) : a ^ (m - n : ℤ) = a ^ m / a ^ n := by
simpa [div_eq_mul_inv] using zpow_sub a m n
@[to_additive natCast_sub_one_zsmul]
lemma zpow_natCast_sub_one (a : G) (n : ℕ) : a ^ (n - 1 : ℤ) = a ^ n / a := by
simpa [div_eq_mul_inv] using zpow_sub a n 1
@[to_additive one_sub_natCast_zsmul]
lemma zpow_one_sub_natCast (a : G) (n : ℕ) : a ^ (1 - n : ℤ) = a / a ^ n := by
simpa [div_eq_mul_inv] using zpow_sub a 1 n
@[to_additive] lemma zpow_mul_comm (a : G) (m n : ℤ) : a ^ m * a ^ n = a ^ n * a ^ m := by
rw [← zpow_add, Int.add_comm, zpow_add]
theorem zpow_eq_zpow_emod {x : G} (m : ℤ) {n : ℤ} (h : x ^ n = 1) :
x ^ m = x ^ (m % n) :=
calc
x ^ m = x ^ (m % n + n * (m / n)) := by rw [Int.emod_add_ediv]
_ = x ^ (m % n) := by simp [zpow_add, zpow_mul, h]
theorem zpow_eq_zpow_emod' {x : G} (m : ℤ) {n : ℕ} (h : x ^ n = 1) :
x ^ m = x ^ (m % (n : ℤ)) := zpow_eq_zpow_emod m (by simpa)
@[to_additive (attr := simp)]
lemma zpow_iterate (k : ℤ) : ∀ n : ℕ, (fun x : G ↦ x ^ k)^[n] = (· ^ k ^ n)
| 0 => by ext; simp [Int.pow_zero]
| n + 1 => by ext; simp [zpow_iterate, Int.pow_succ', zpow_mul]
/-- To show a property of all powers of `g` it suffices to show it is closed under multiplication
by `g` and `g⁻¹` on the left. For subgroups generated by more than one element, see
`Subgroup.closure_induction_left`. -/
@[to_additive "To show a property of all multiples of `g` it suffices to show it is closed under
addition by `g` and `-g` on the left. For additive subgroups generated by more than one element, see
`AddSubgroup.closure_induction_left`."]
lemma zpow_induction_left {g : G} {P : G → Prop} (h_one : P (1 : G))
(h_mul : ∀ a, P a → P (g * a)) (h_inv : ∀ a, P a → P (g⁻¹ * a)) (n : ℤ) : P (g ^ n) := by
induction n with
| hz => rwa [zpow_zero]
| hp n ih =>
rw [Int.add_comm, zpow_add, zpow_one]
exact h_mul _ ih
| hn n ih =>
rw [Int.sub_eq_add_neg, Int.add_comm, zpow_add, zpow_neg_one]
exact h_inv _ ih
/-- To show a property of all powers of `g` it suffices to show it is closed under multiplication
by `g` and `g⁻¹` on the right. For subgroups generated by more than one element, see
`Subgroup.closure_induction_right`. -/
@[to_additive "To show a property of all multiples of `g` it suffices to show it is closed under
addition by `g` and `-g` on the right. For additive subgroups generated by more than one element,
see `AddSubgroup.closure_induction_right`."]
lemma zpow_induction_right {g : G} {P : G → Prop} (h_one : P (1 : G))
(h_mul : ∀ a, P a → P (a * g)) (h_inv : ∀ a, P a → P (a * g⁻¹)) (n : ℤ) : P (g ^ n) := by
induction n with
| hz => rwa [zpow_zero]
| hp n ih =>
rw [zpow_add_one]
exact h_mul _ ih
| hn n ih =>
rw [zpow_sub_one]
exact h_inv _ ih
end Group
section CommGroup
variable [CommGroup G] {a b c d : G}
attribute [local simp] mul_assoc mul_comm mul_left_comm div_eq_mul_inv
@[to_additive]
theorem div_eq_of_eq_mul' {a b c : G} (h : a = b * c) : a / b = c := by
rw [h, div_eq_mul_inv, mul_comm, inv_mul_cancel_left]
@[to_additive (attr := simp)]
theorem mul_div_mul_left_eq_div (a b c : G) : c * a / (c * b) = a / b := by
rw [div_eq_mul_inv, mul_inv_rev, mul_comm b⁻¹ c⁻¹, mul_comm c a, mul_assoc, ← mul_assoc c,
mul_inv_cancel, one_mul, div_eq_mul_inv]
@[to_additive eq_sub_of_add_eq']
theorem eq_div_of_mul_eq'' (h : c * a = b) : a = b / c := by simp [h.symm]
@[to_additive]
theorem eq_mul_of_div_eq' (h : a / b = c) : a = b * c := by simp [h.symm]
@[to_additive]
theorem mul_eq_of_eq_div' (h : b = c / a) : a * b = c := by
rw [h, div_eq_mul_inv, mul_comm c, mul_inv_cancel_left]
@[to_additive sub_sub_self]
theorem div_div_self' (a b : G) : a / (a / b) = b := by simp
@[to_additive]
theorem div_eq_div_mul_div (a b c : G) : a / b = c / b * (a / c) := by simp [mul_left_comm c]
@[to_additive (attr := simp)]
theorem div_div_cancel (a b : G) : a / (a / b) = b :=
div_div_self' a b
@[to_additive (attr := simp)]
theorem div_div_cancel_left (a b : G) : a / b / a = b⁻¹ := by simp
@[to_additive eq_sub_iff_add_eq']
theorem eq_div_iff_mul_eq'' : a = b / c ↔ c * a = b := by rw [eq_div_iff_mul_eq', mul_comm]
@[to_additive]
theorem div_eq_iff_eq_mul' : a / b = c ↔ a = b * c := by rw [div_eq_iff_eq_mul, mul_comm]
@[to_additive (attr := simp)]
theorem mul_div_cancel_left (a b : G) : a * b / a = b := by rw [div_eq_inv_mul, inv_mul_cancel_left]
@[to_additive (attr := simp)]
theorem mul_div_cancel (a b : G) : a * (b / a) = b := by
rw [← mul_div_assoc, mul_div_cancel_left]
@[to_additive (attr := simp)]
theorem div_mul_cancel_left (a b : G) : a / (a * b) = b⁻¹ := by rw [← inv_div, mul_div_cancel_left]
-- This lemma is in the `simp` set under the name `mul_inv_cancel_comm_assoc`,
-- along with the additive version `add_neg_cancel_comm_assoc`,
-- defined in `Algebra.Group.Commute`
@[to_additive]
theorem mul_mul_inv_cancel'_right (a b : G) : a * (b * a⁻¹) = b := by
rw [← div_eq_mul_inv, mul_div_cancel a b]
@[to_additive (attr := simp)]
theorem mul_mul_div_cancel (a b c : G) : a * c * (b / c) = a * b := by
rw [mul_assoc, mul_div_cancel]
@[to_additive (attr := simp)]
theorem div_mul_mul_cancel (a b c : G) : a / c * (b * c) = a * b := by
rw [mul_left_comm, div_mul_cancel, mul_comm]
@[to_additive (attr := simp)]
theorem div_mul_div_cancel' (a b c : G) : a / b * (c / a) = c / b := by
rw [mul_comm]; apply div_mul_div_cancel
@[to_additive (attr := simp)]
theorem mul_div_div_cancel (a b c : G) : a * b / (a / c) = b * c := by
rw [← div_mul, mul_div_cancel_left]
@[to_additive (attr := simp)]
theorem div_div_div_cancel_left (a b c : G) : c / a / (c / b) = b / a := by
rw [← inv_div b c, div_inv_eq_mul, mul_comm, div_mul_div_cancel]
@[to_additive]
theorem div_eq_div_iff_mul_eq_mul : a / b = c / d ↔ a * d = c * b := by
rw [div_eq_iff_eq_mul, div_mul_eq_mul_div, eq_comm, div_eq_iff_eq_mul']
simp only [mul_comm, eq_comm]
@[to_additive]
theorem div_eq_div_iff_div_eq_div : a / b = c / d ↔ a / c = b / d := by
rw [div_eq_iff_eq_mul, div_mul_eq_mul_div, div_eq_iff_eq_mul', mul_div_assoc]
end CommGroup
section multiplicative
variable [Monoid β] (p r : α → α → Prop) [IsTotal α r] (f : α → α → β)
@[to_additive additive_of_symmetric_of_isTotal]
lemma multiplicative_of_symmetric_of_isTotal
(hsymm : Symmetric p) (hf_swap : ∀ {a b}, p a b → f a b * f b a = 1)
(hmul : ∀ {a b c}, r a b → r b c → p a b → p b c → p a c → f a c = f a b * f b c)
{a b c : α} (pab : p a b) (pbc : p b c) (pac : p a c) : f a c = f a b * f b c := by
have hmul' : ∀ {b c}, r b c → p a b → p b c → p a c → f a c = f a b * f b c := by
intros b c rbc pab pbc pac
obtain rab | rba := total_of r a b
· exact hmul rab rbc pab pbc pac
rw [← one_mul (f a c), ← hf_swap pab, mul_assoc]
obtain rac | rca := total_of r a c
· rw [hmul rba rac (hsymm pab) pac pbc]
· rw [hmul rbc rca pbc (hsymm pac) (hsymm pab), mul_assoc, hf_swap (hsymm pac), mul_one]
obtain rbc | rcb := total_of r b c
· exact hmul' rbc pab pbc pac
· rw [hmul' rcb pac (hsymm pbc) pab, mul_assoc, hf_swap (hsymm pbc), mul_one]
/-- If a binary function from a type equipped with a total relation `r` to a monoid is
anti-symmetric (i.e. satisfies `f a b * f b a = 1`), in order to show it is multiplicative
(i.e. satisfies `f a c = f a b * f b c`), we may assume `r a b` and `r b c` are satisfied.
We allow restricting to a subset specified by a predicate `p`. -/
@[to_additive additive_of_isTotal "If a binary function from a type equipped with a total relation
`r` to an additive monoid is anti-symmetric (i.e. satisfies `f a b + f b a = 0`), in order to show
it is additive (i.e. satisfies `f a c = f a b + f b c`), we may assume `r a b` and `r b c` are
satisfied. We allow restricting to a subset specified by a predicate `p`."]
theorem multiplicative_of_isTotal (p : α → Prop) (hswap : ∀ {a b}, p a → p b → f a b * f b a = 1)
(hmul : ∀ {a b c}, r a b → r b c → p a → p b → p c → f a c = f a b * f b c) {a b c : α}
(pa : p a) (pb : p b) (pc : p c) : f a c = f a b * f b c := by
apply multiplicative_of_symmetric_of_isTotal (fun a b => p a ∧ p b) r f fun _ _ => And.symm
· simp_rw [and_imp]; exact @hswap
· exact fun rab rbc pab _pbc pac => hmul rab rbc pab.1 pab.2 pac.2
exacts [⟨pa, pb⟩, ⟨pb, pc⟩, ⟨pa, pc⟩]
end multiplicative
/-- An auxiliary lemma that can be used to prove `⇑(f ^ n) = ⇑f^[n]`. -/
@[to_additive]
lemma hom_coe_pow {F : Type*} [Monoid F] (c : F → M → M) (h1 : c 1 = id)
(hmul : ∀ f g, c (f * g) = c f ∘ c g) (f : F) : ∀ n, c (f ^ n) = (c f)^[n]
| 0 => by
rw [pow_zero, h1]
rfl
| n + 1 => by rw [pow_succ, iterate_succ, hmul, hom_coe_pow c h1 hmul f n]
| Mathlib/Algebra/Group/Basic.lean | 1,240 | 1,253 | |
/-
Copyright (c) 2024 Judith Ludwig, Christian Merten. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Judith Ludwig, Christian Merten
-/
import Mathlib.RingTheory.AdicCompletion.Basic
import Mathlib.RingTheory.AdicCompletion.Algebra
import Mathlib.Algebra.DirectSum.Basic
/-!
# Functoriality of adic completions
In this file we establish functorial properties of the adic completion.
## Main definitions
- `AdicCauchySequence.map I f`: the linear map on `I`-adic cauchy sequences induced by `f`
- `AdicCompletion.map I f`: the linear map on `I`-adic completions induced by `f`
## Main results
- `sumEquivOfFintype`: adic completion commutes with finite sums
- `piEquivOfFintype`: adic completion commutes with finite products
-/
suppress_compilation
variable {R : Type*} [CommRing R] (I : Ideal R)
variable {M : Type*} [AddCommGroup M] [Module R M]
variable {N : Type*} [AddCommGroup N] [Module R N]
variable {P : Type*} [AddCommGroup P] [Module R P]
variable {T : Type*} [AddCommGroup T] [Module (AdicCompletion I R) T]
namespace LinearMap
/-- `R`-linear version of `reduceModIdeal`. -/
private def reduceModIdealAux (f : M →ₗ[R] N) :
M ⧸ (I • ⊤ : Submodule R M) →ₗ[R] N ⧸ (I • ⊤ : Submodule R N) :=
Submodule.mapQ (I • ⊤ : Submodule R M) (I • ⊤ : Submodule R N) f
(fun x hx ↦ by
refine Submodule.smul_induction_on hx (fun r hr x _ ↦ ?_) (fun x y hx hy ↦ ?_)
· simp [Submodule.smul_mem_smul hr Submodule.mem_top]
· simp [Submodule.add_mem _ hx hy])
@[local simp]
private theorem reduceModIdealAux_apply (f : M →ₗ[R] N) (x : M) :
(f.reduceModIdealAux I) (Submodule.Quotient.mk (p := (I • ⊤ : Submodule R M)) x) =
Submodule.Quotient.mk (p := (I • ⊤ : Submodule R N)) (f x) :=
rfl
/-- The induced linear map on the quotients mod `I • ⊤`. -/
def reduceModIdeal (f : M →ₗ[R] N) :
M ⧸ (I • ⊤ : Submodule R M) →ₗ[R ⧸ I] N ⧸ (I • ⊤ : Submodule R N) where
toFun := f.reduceModIdealAux I
map_add' := by simp
map_smul' r x := by
refine Quotient.inductionOn' r (fun r ↦ ?_)
refine Quotient.inductionOn' x (fun x ↦ ?_)
simp only [Submodule.Quotient.mk''_eq_mk, Ideal.Quotient.mk_eq_mk, Module.Quotient.mk_smul_mk,
Submodule.Quotient.mk_smul, LinearMapClass.map_smul, reduceModIdealAux_apply,
RingHomCompTriple.comp_apply]
@[simp]
theorem reduceModIdeal_apply (f : M →ₗ[R] N) (x : M) :
(f.reduceModIdeal I) (Submodule.Quotient.mk (p := (I • ⊤ : Submodule R M)) x) =
Submodule.Quotient.mk (p := (I • ⊤ : Submodule R N)) (f x) :=
rfl
end LinearMap
namespace AdicCompletion
open LinearMap
theorem transitionMap_comp_reduceModIdeal (f : M →ₗ[R] N) {m n : ℕ}
(hmn : m ≤ n) : transitionMap I N hmn ∘ₗ f.reduceModIdeal (I ^ n) =
(f.reduceModIdeal (I ^ m) : _ →ₗ[R] _) ∘ₗ transitionMap I M hmn := by
ext x
simp
namespace AdicCauchySequence
/-- A linear map induces a linear map on adic cauchy sequences. -/
@[simps]
def map (f : M →ₗ[R] N) : AdicCauchySequence I M →ₗ[R] AdicCauchySequence I N where
toFun a := ⟨fun n ↦ f (a n), fun {m n} hmn ↦ by
have hm : Submodule.map f (I ^ m • ⊤ : Submodule R M) ≤ (I ^ m • ⊤ : Submodule R N) := by
rw [Submodule.map_smul'']
exact smul_mono_right _ le_top
apply SModEq.mono hm
apply SModEq.map (a.property hmn) f⟩
map_add' a b := by ext n; simp
map_smul' r a := by ext n; simp
variable (M) in
@[simp]
theorem map_id : map I (LinearMap.id (M := M)) = LinearMap.id :=
rfl
theorem map_comp (f : M →ₗ[R] N) (g : N →ₗ[R] P) :
map I g ∘ₗ map I f = map I (g ∘ₗ f) :=
rfl
theorem map_comp_apply (f : M →ₗ[R] N) (g : N →ₗ[R] P) (a : AdicCauchySequence I M) :
map I g (map I f a) = map I (g ∘ₗ f) a :=
rfl
@[simp]
theorem map_zero : map I (0 : M →ₗ[R] N) = 0 :=
rfl
end AdicCauchySequence
/-- `R`-linear version of `adicCompletion`. -/
private def adicCompletionAux (f : M →ₗ[R] N) :
AdicCompletion I M →ₗ[R] AdicCompletion I N :=
AdicCompletion.lift I (fun n ↦ reduceModIdeal (I ^ n) f ∘ₗ AdicCompletion.eval I M n)
(fun {m n} hmn ↦ by rw [← comp_assoc, AdicCompletion.transitionMap_comp_reduceModIdeal,
comp_assoc, transitionMap_comp_eval])
@[local simp]
private theorem adicCompletionAux_val_apply (f : M →ₗ[R] N) {n : ℕ} (x : AdicCompletion I M) :
(adicCompletionAux I f x).val n = f.reduceModIdeal (I ^ n) (x.val n) :=
rfl
/-- A linear map induces a map on adic completions. -/
def map (f : M →ₗ[R] N) :
AdicCompletion I M →ₗ[AdicCompletion I R] AdicCompletion I N where
toFun := adicCompletionAux I f
map_add' := by simp
map_smul' r x := by
ext n
simp only [adicCompletionAux_val_apply, smul_eval, smul_eq_mul, RingHom.id_apply]
rw [val_smul_eq_evalₐ_smul, val_smul_eq_evalₐ_smul, map_smul]
@[simp]
theorem map_val_apply (f : M →ₗ[R] N) {n : ℕ} (x : AdicCompletion I M) :
(map I f x).val n = f.reduceModIdeal (I ^ n) (x.val n) :=
rfl
/-- Equality of maps out of an adic completion can be checked on Cauchy sequences. -/
theorem map_ext {N} {f g : AdicCompletion I M → N}
(h : ∀ (a : AdicCauchySequence I M),
f (AdicCompletion.mk I M a) = g (AdicCompletion.mk I M a)) :
f = g := by
ext x
apply induction_on I M x h
/-- Equality of linear maps out of an adic completion can be checked on Cauchy sequences. -/
@[ext]
theorem map_ext' {f g : AdicCompletion I M →ₗ[AdicCompletion I R] T}
(h : ∀ (a : AdicCauchySequence I M),
f (AdicCompletion.mk I M a) = g (AdicCompletion.mk I M a)) :
f = g := by
ext x
apply induction_on I M x h
/-- Equality of linear maps out of an adic completion can be checked on Cauchy sequences. -/
@[ext]
theorem map_ext'' {f g : AdicCompletion I M →ₗ[R] N}
(h : f.comp (AdicCompletion.mk I M) = g.comp (AdicCompletion.mk I M)) :
f = g := by
ext x
apply induction_on I M x (fun a ↦ LinearMap.ext_iff.mp h a)
variable (M) in
@[simp]
theorem map_id :
map I (LinearMap.id (M := M)) =
LinearMap.id (R := AdicCompletion I R) (M := AdicCompletion I M) := by
ext a n
simp
theorem map_comp (f : M →ₗ[R] N) (g : N →ₗ[R] P) :
map I g ∘ₗ map I f = map I (g ∘ₗ f) := by
ext
simp
theorem map_comp_apply (f : M →ₗ[R] N) (g : N →ₗ[R] P) (x : AdicCompletion I M) :
map I g (map I f x) = map I (g ∘ₗ f) x := by
show (map I g ∘ₗ map I f) x = map I (g ∘ₗ f) x
rw [map_comp]
@[simp]
theorem map_mk (f : M →ₗ[R] N) (a : AdicCauchySequence I M) :
map I f (AdicCompletion.mk I M a) =
AdicCompletion.mk I N (AdicCauchySequence.map I f a) :=
rfl
@[simp]
theorem map_zero : map I (0 : M →ₗ[R] N) = 0 := by
ext
simp
|
/-- A linear equiv induces a linear equiv on adic completions. -/
def congr (f : M ≃ₗ[R] N) :
AdicCompletion I M ≃ₗ[AdicCompletion I R] AdicCompletion I N :=
| Mathlib/RingTheory/AdicCompletion/Functoriality.lean | 195 | 198 |
/-
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.Option.Basic
import Batteries.Tactic.Congr
import Mathlib.Data.Set.Basic
import Mathlib.Tactic.Contrapose
/-!
# Partial Equivalences
In this file, we define partial equivalences `PEquiv`, which are a bijection between a subset of `α`
and a subset of `β`. Notationally, a `PEquiv` is denoted by "`≃.`" (note that the full stop is part
of the notation). The way we store these internally is with two functions `f : α → Option β` and
the reverse function `g : β → Option α`, with the condition that if `f a` is `some b`,
then `g b` is `some a`.
## Main results
- `PEquiv.ofSet`: creates a `PEquiv` from a set `s`,
which sends an element to itself if it is in `s`.
- `PEquiv.single`: given two elements `a : α` and `b : β`, create a `PEquiv` that sends them to
each other, and ignores all other elements.
- `PEquiv.injective_of_forall_ne_isSome`/`injective_of_forall_isSome`: If the domain of a `PEquiv`
is all of `α` (except possibly one point), its `toFun` is injective.
## Canonical order
`PEquiv` is canonically ordered by inclusion; that is, if a function `f` defined on a subset `s`
is equal to `g` on that subset, but `g` is also defined on a larger set, then `f ≤ g`. We also have
a definition of `⊥`, which is the empty `PEquiv` (sends all to `none`), which in the end gives us a
`SemilatticeInf` with an `OrderBot` instance.
## Tags
pequiv, partial equivalence
-/
assert_not_exists RelIso
universe u v w x
/-- A `PEquiv` is a partial equivalence, a representation of a bijection between a subset
of `α` and a subset of `β`. See also `PartialEquiv` for a version that requires `toFun` and
`invFun` to be globally defined functions and has `source` and `target` sets as extra fields. -/
structure PEquiv (α : Type u) (β : Type v) where
/-- The underlying partial function of a `PEquiv` -/
toFun : α → Option β
/-- The partial inverse of `toFun` -/
invFun : β → Option α
/-- `invFun` is the partial inverse of `toFun` -/
inv : ∀ (a : α) (b : β), a ∈ invFun b ↔ b ∈ toFun a
/-- A `PEquiv` is a partial equivalence, a representation of a bijection between a subset
of `α` and a subset of `β`. See also `PartialEquiv` for a version that requires `toFun` and
`invFun` to be globally defined functions and has `source` and `target` sets as extra fields. -/
infixr:25 " ≃. " => PEquiv
namespace PEquiv
variable {α : Type u} {β : Type v} {γ : Type w} {δ : Type x}
open Function Option
instance : FunLike (α ≃. β) α (Option β) :=
{ coe := toFun
coe_injective' := by
rintro ⟨f₁, f₂, hf⟩ ⟨g₁, g₂, hg⟩ (rfl : f₁ = g₁)
congr with y x
simp only [hf, hg] }
@[simp] theorem coe_mk (f₁ : α → Option β) (f₂ h) : (mk f₁ f₂ h : α → Option β) = f₁ :=
rfl
theorem coe_mk_apply (f₁ : α → Option β) (f₂ : β → Option α) (h) (x : α) :
(PEquiv.mk f₁ f₂ h : α → Option β) x = f₁ x :=
rfl
@[ext] theorem ext {f g : α ≃. β} (h : ∀ x, f x = g x) : f = g :=
DFunLike.ext f g h
/-- The identity map as a partial equivalence. -/
@[refl]
protected def refl (α : Type*) : α ≃. α where
toFun := some
invFun := some
inv _ _ := eq_comm
/-- The inverse partial equivalence. -/
@[symm]
protected def symm (f : α ≃. β) : β ≃. α where
toFun := f.2
invFun := f.1
inv _ _ := (f.inv _ _).symm
theorem mem_iff_mem (f : α ≃. β) : ∀ {a : α} {b : β}, a ∈ f.symm b ↔ b ∈ f a :=
f.3 _ _
theorem eq_some_iff (f : α ≃. β) : ∀ {a : α} {b : β}, f.symm b = some a ↔ f a = some b :=
f.3 _ _
/-- Composition of partial equivalences `f : α ≃. β` and `g : β ≃. γ`. -/
@[trans]
protected def trans (f : α ≃. β) (g : β ≃. γ) :
α ≃. γ where
toFun a := (f a).bind g
invFun a := (g.symm a).bind f.symm
inv a b := by simp_all [and_comm, eq_some_iff f, eq_some_iff g, bind_eq_some_iff]
@[simp]
theorem refl_apply (a : α) : PEquiv.refl α a = some a :=
rfl
@[simp]
theorem symm_refl : (PEquiv.refl α).symm = PEquiv.refl α :=
rfl
@[simp]
theorem symm_symm (f : α ≃. β) : f.symm.symm = f := rfl
theorem symm_bijective : Function.Bijective (PEquiv.symm : (α ≃. β) → β ≃. α) :=
Function.bijective_iff_has_inverse.mpr ⟨_, symm_symm, symm_symm⟩
theorem symm_injective : Function.Injective (@PEquiv.symm α β) :=
symm_bijective.injective
theorem trans_assoc (f : α ≃. β) (g : β ≃. γ) (h : γ ≃. δ) :
(f.trans g).trans h = f.trans (g.trans h) :=
ext fun _ => Option.bind_assoc _ _ _
theorem mem_trans (f : α ≃. β) (g : β ≃. γ) (a : α) (c : γ) :
c ∈ f.trans g a ↔ ∃ b, b ∈ f a ∧ c ∈ g b :=
Option.bind_eq_some'
theorem trans_eq_some (f : α ≃. β) (g : β ≃. γ) (a : α) (c : γ) :
f.trans g a = some c ↔ ∃ b, f a = some b ∧ g b = some c :=
Option.bind_eq_some'
theorem trans_eq_none (f : α ≃. β) (g : β ≃. γ) (a : α) :
f.trans g a = none ↔ ∀ b c, b ∉ f a ∨ c ∉ g b := by
simp only [eq_none_iff_forall_not_mem, mem_trans, imp_iff_not_or.symm]
push_neg
exact forall_swap
@[simp]
theorem refl_trans (f : α ≃. β) : (PEquiv.refl α).trans f = f := by
ext; dsimp [PEquiv.trans]; rfl
@[simp]
theorem trans_refl (f : α ≃. β) : f.trans (PEquiv.refl β) = f := by
ext; dsimp [PEquiv.trans]; simp
protected theorem inj (f : α ≃. β) {a₁ a₂ : α} {b : β} (h₁ : b ∈ f a₁) (h₂ : b ∈ f a₂) :
a₁ = a₂ := by rw [← mem_iff_mem] at *; cases h : f.symm b <;> simp_all
/-- If the domain of a `PEquiv` is `α` except a point, its forward direction is injective. -/
theorem injective_of_forall_ne_isSome (f : α ≃. β) (a₂ : α)
(h : ∀ a₁ : α, a₁ ≠ a₂ → isSome (f a₁)) : Injective f :=
HasLeftInverse.injective
⟨fun b => Option.recOn b a₂ fun b' => Option.recOn (f.symm b') a₂ id, fun x => by
classical
cases hfx : f x
· have : x = a₂ := not_imp_comm.1 (h x) (hfx.symm ▸ by simp)
simp [this]
· dsimp only
rw [(eq_some_iff f).2 hfx]
rfl⟩
/-- If the domain of a `PEquiv` is all of `α`, its forward direction is injective. -/
theorem injective_of_forall_isSome {f : α ≃. β} (h : ∀ a : α, isSome (f a)) : Injective f :=
(Classical.em (Nonempty α)).elim
(fun hn => injective_of_forall_ne_isSome f (Classical.choice hn) fun a _ => h a) fun hn x =>
(hn ⟨x⟩).elim
section OfSet
variable (s : Set α) [DecidablePred (· ∈ s)]
/-- Creates a `PEquiv` that is the identity on `s`, and `none` outside of it. -/
def ofSet (s : Set α) [DecidablePred (· ∈ s)] :
α ≃. α where
toFun a := if a ∈ s then some a else none
invFun a := if a ∈ s then some a else none
inv a b := by
split_ifs with hb ha ha
· simp [eq_comm]
· simp [ne_of_mem_of_not_mem hb ha]
· simp [ne_of_mem_of_not_mem ha hb]
· simp
theorem mem_ofSet_self_iff {s : Set α} [DecidablePred (· ∈ s)] {a : α} : a ∈ ofSet s a ↔ a ∈ s := by
dsimp [ofSet]; split_ifs <;> simp [*]
theorem mem_ofSet_iff {s : Set α} [DecidablePred (· ∈ s)] {a b : α} :
a ∈ ofSet s b ↔ a = b ∧ a ∈ s := by
dsimp [ofSet]
split_ifs with h
· simp only [mem_def, eq_comm, some.injEq, iff_self_and]
rintro rfl
exact h
· simp only [mem_def, false_iff, not_and, reduceCtorEq]
rintro rfl
exact h
@[simp]
theorem ofSet_eq_some_iff {s : Set α} {_ : DecidablePred (· ∈ s)} {a b : α} :
ofSet s b = some a ↔ a = b ∧ a ∈ s :=
mem_ofSet_iff
theorem ofSet_eq_some_self_iff {s : Set α} {_ : DecidablePred (· ∈ s)} {a : α} :
ofSet s a = some a ↔ a ∈ s :=
mem_ofSet_self_iff
@[simp]
theorem ofSet_symm : (ofSet s).symm = ofSet s :=
rfl
@[simp]
theorem ofSet_univ : ofSet Set.univ = PEquiv.refl α :=
rfl
@[simp]
theorem ofSet_eq_refl {s : Set α} [DecidablePred (· ∈ s)] :
ofSet s = PEquiv.refl α ↔ s = Set.univ :=
⟨fun h => by
rw [Set.eq_univ_iff_forall]
intro
rw [← mem_ofSet_self_iff, h]
exact rfl, fun h => by simp only [← ofSet_univ, h]⟩
end OfSet
theorem symm_trans_rev (f : α ≃. β) (g : β ≃. γ) : (f.trans g).symm = g.symm.trans f.symm :=
rfl
theorem self_trans_symm (f : α ≃. β) : f.trans f.symm = ofSet { a | (f a).isSome } := by
ext
dsimp [PEquiv.trans]
simp only [eq_some_iff f, Option.isSome_iff_exists, Option.mem_def, bind_eq_some',
ofSet_eq_some_iff]
constructor
· rintro ⟨b, hb₁, hb₂⟩
exact ⟨PEquiv.inj _ hb₂ hb₁, b, hb₂⟩
· simp +contextual
theorem symm_trans_self (f : α ≃. β) : f.symm.trans f = ofSet { b | (f.symm b).isSome } :=
symm_injective <| by simp [symm_trans_rev, self_trans_symm, -symm_symm]
theorem trans_symm_eq_iff_forall_isSome {f : α ≃. β} :
f.trans f.symm = PEquiv.refl α ↔ ∀ a, isSome (f a) := by
rw [self_trans_symm, ofSet_eq_refl, Set.eq_univ_iff_forall]; rfl
instance instBotPEquiv : Bot (α ≃. β) :=
⟨{ toFun := fun _ => none
invFun := fun _ => none
inv := by simp }⟩
instance : Inhabited (α ≃. β) :=
⟨⊥⟩
@[simp]
theorem bot_apply (a : α) : (⊥ : α ≃. β) a = none :=
rfl
@[simp]
theorem symm_bot : (⊥ : α ≃. β).symm = ⊥ :=
rfl
@[simp]
theorem trans_bot (f : α ≃. β) : f.trans (⊥ : β ≃. γ) = ⊥ := by
ext; dsimp [PEquiv.trans]; simp
@[simp]
theorem bot_trans (f : β ≃. γ) : (⊥ : α ≃. β).trans f = ⊥ := by
ext; dsimp [PEquiv.trans]; simp
theorem isSome_symm_get (f : α ≃. β) {a : α} (h : isSome (f a)) :
isSome (f.symm (Option.get _ h)) :=
isSome_iff_exists.2 ⟨a, by rw [f.eq_some_iff, some_get]⟩
section Single
variable [DecidableEq α] [DecidableEq β] [DecidableEq γ]
/-- Create a `PEquiv` which sends `a` to `b` and `b` to `a`, but is otherwise `none`. -/
def single (a : α) (b : β) :
α ≃. β where
toFun x := if x = a then some b else none
invFun x := if x = b then some a else none
inv x y := by
split_ifs with h1 h2
· simp [*]
· simp only [mem_def, some.injEq, iff_false, reduceCtorEq] at *
exact Ne.symm h2
· simp only [mem_def, some.injEq, false_iff, reduceCtorEq] at *
exact Ne.symm h1
· simp
theorem mem_single (a : α) (b : β) : b ∈ single a b a :=
if_pos rfl
theorem mem_single_iff (a₁ a₂ : α) (b₁ b₂ : β) : b₁ ∈ single a₂ b₂ a₁ ↔ a₁ = a₂ ∧ b₁ = b₂ := by
dsimp [single]; split_ifs <;> simp [*, eq_comm]
@[simp]
theorem symm_single (a : α) (b : β) : (single a b).symm = single b a :=
rfl
@[simp]
theorem single_apply (a : α) (b : β) : single a b a = some b :=
if_pos rfl
theorem single_apply_of_ne {a₁ a₂ : α} (h : a₁ ≠ a₂) (b : β) : single a₁ b a₂ = none :=
if_neg h.symm
theorem single_trans_of_mem (a : α) {b : β} {c : γ} {f : β ≃. γ} (h : c ∈ f b) :
(single a b).trans f = single a c := by
ext
dsimp [single, PEquiv.trans]
split_ifs <;> simp_all
theorem trans_single_of_mem {a : α} {b : β} (c : γ) {f : α ≃. β} (h : b ∈ f a) :
f.trans (single b c) = single a c :=
symm_injective <| single_trans_of_mem _ ((mem_iff_mem f).2 h)
@[simp]
theorem single_trans_single (a : α) (b : β) (c : γ) :
(single a b).trans (single b c) = single a c :=
single_trans_of_mem _ (mem_single _ _)
@[simp]
theorem single_subsingleton_eq_refl [Subsingleton α] (a b : α) : single a b = PEquiv.refl α := by
ext i j
dsimp [single]
rw [if_pos (Subsingleton.elim i a), Subsingleton.elim i j, Subsingleton.elim b j]
theorem trans_single_of_eq_none {b : β} (c : γ) {f : δ ≃. β} (h : f.symm b = none) :
f.trans (single b c) = ⊥ := by
ext
simp only [eq_none_iff_forall_not_mem, Option.mem_def, f.eq_some_iff] at h
dsimp [PEquiv.trans, single]
simp only [mem_def, bind_eq_some_iff, iff_false, not_exists, not_and, reduceCtorEq]
intros
split_ifs <;> simp_all
theorem single_trans_of_eq_none (a : α) {b : β} {f : β ≃. δ} (h : f b = none) :
(single a b).trans f = ⊥ :=
symm_injective <| trans_single_of_eq_none _ h
theorem single_trans_single_of_ne {b₁ b₂ : β} (h : b₁ ≠ b₂) (a : α) (c : γ) :
(single a b₁).trans (single b₂ c) = ⊥ :=
single_trans_of_eq_none _ (single_apply_of_ne h.symm _)
end Single
section Order
instance instPartialOrderPEquiv : PartialOrder (α ≃. β) where
le f g := ∀ (a : α) (b : β), b ∈ f a → b ∈ g a
le_refl _ _ _ := id
le_trans _ _ _ fg gh a b := gh a b ∘ fg a b
le_antisymm f g fg gf :=
ext
(by
| intro a
rcases h : g a with _ | b
· exact eq_none_iff_forall_not_mem.2 fun b hb => Option.not_mem_none b <| h ▸ fg a b hb
· exact gf _ _ h)
| Mathlib/Data/PEquiv.lean | 369 | 373 |
/-
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 | 1,214 | 1,217 | |
/-
Copyright (c) 2020 Devon Tuma. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Devon Tuma
-/
import Mathlib.Probability.ProbabilityMassFunction.Basic
/-!
# Monad Operations for Probability Mass Functions
This file constructs two operations on `PMF` that give it a monad structure.
`pure a` is the distribution where a single value `a` has probability `1`.
`bind pa pb : PMF β` is the distribution given by sampling `a : α` from `pa : PMF α`,
and then sampling from `pb a : PMF β` to get a final result `b : β`.
`bindOnSupport` generalizes `bind` to allow binding to a partial function,
so that the second argument only needs to be defined on the support of the first argument.
-/
noncomputable section
variable {α β γ : Type*}
open NNReal ENNReal
open MeasureTheory
namespace PMF
section Pure
open scoped Classical in
/-- The pure `PMF` is the `PMF` where all the mass lies in one point.
The value of `pure a` is `1` at `a` and `0` elsewhere. -/
def pure (a : α) : PMF α :=
⟨fun a' => if a' = a then 1 else 0, hasSum_ite_eq _ _⟩
variable (a a' : α)
open scoped Classical in
@[simp]
theorem pure_apply : pure a a' = if a' = a then 1 else 0 := rfl
@[simp]
theorem support_pure : (pure a).support = {a} :=
Set.ext fun a' => by simp [mem_support_iff]
theorem mem_support_pure_iff : a' ∈ (pure a).support ↔ a' = a := by simp
theorem pure_apply_self : pure a a = 1 :=
if_pos rfl
theorem pure_apply_of_ne (h : a' ≠ a) : pure a a' = 0 :=
if_neg h
instance [Inhabited α] : Inhabited (PMF α) :=
⟨pure default⟩
section Measure
variable (s : Set α)
open scoped Classical in
@[simp]
theorem toOuterMeasure_pure_apply : (pure a).toOuterMeasure s = if a ∈ s then 1 else 0 := by
refine (toOuterMeasure_apply (pure a) s).trans ?_
split_ifs with ha
· refine (tsum_congr fun b => ?_).trans (tsum_ite_eq a 1)
exact ite_eq_left_iff.2 fun hb =>
symm (ite_eq_right_iff.2 fun h => (hb <| h.symm ▸ ha).elim)
· refine (tsum_congr fun b => ?_).trans tsum_zero
exact ite_eq_right_iff.2 fun hb =>
ite_eq_right_iff.2 fun h => (ha <| h ▸ hb).elim
variable [MeasurableSpace α]
open scoped Classical in
/-- The measure of a set under `pure a` is `1` for sets containing `a` and `0` otherwise. -/
@[simp]
theorem toMeasure_pure_apply (hs : MeasurableSet s) :
(pure a).toMeasure s = if a ∈ s then 1 else 0 :=
(toMeasure_apply_eq_toOuterMeasure_apply (pure a) s hs).trans (toOuterMeasure_pure_apply a s)
theorem toMeasure_pure : (pure a).toMeasure = Measure.dirac a :=
Measure.ext fun s hs => by rw [toMeasure_pure_apply a s hs, Measure.dirac_apply' a hs]; rfl
@[simp]
theorem toPMF_dirac [Countable α] [h : MeasurableSingletonClass α] :
(Measure.dirac a).toPMF = pure a := by
rw [toPMF_eq_iff_toMeasure_eq, toMeasure_pure]
end Measure
end Pure
|
section Bind
| Mathlib/Probability/ProbabilityMassFunction/Monad.lean | 97 | 99 |
/-
Copyright (c) 2022 Joseph Myers. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joseph Myers
-/
import Mathlib.Algebra.ModEq
import Mathlib.Algebra.Order.Archimedean.Basic
import Mathlib.Algebra.Ring.Periodic
import Mathlib.Data.Int.SuccPred
import Mathlib.Order.Circular
/-!
# Reducing to an interval modulo its length
This file defines operations that reduce a number (in an `Archimedean`
`LinearOrderedAddCommGroup`) to a number in a given interval, modulo the length of that
interval.
## Main definitions
* `toIcoDiv hp a b` (where `hp : 0 < p`): The unique integer such that this multiple of `p`,
subtracted from `b`, is in `Ico a (a + p)`.
* `toIcoMod hp a b` (where `hp : 0 < p`): Reduce `b` to the interval `Ico a (a + p)`.
* `toIocDiv hp a b` (where `hp : 0 < p`): The unique integer such that this multiple of `p`,
subtracted from `b`, is in `Ioc a (a + p)`.
* `toIocMod hp a b` (where `hp : 0 < p`): Reduce `b` to the interval `Ioc a (a + p)`.
-/
assert_not_exists TwoSidedIdeal
noncomputable section
section LinearOrderedAddCommGroup
variable {α : Type*} [AddCommGroup α] [LinearOrder α] [IsOrderedAddMonoid α] [hα : Archimedean α]
{p : α} (hp : 0 < p)
{a b c : α} {n : ℤ}
section
include hp
/--
The unique integer such that this multiple of `p`, subtracted from `b`, is in `Ico a (a + p)`. -/
def toIcoDiv (a b : α) : ℤ :=
(existsUnique_sub_zsmul_mem_Ico hp b a).choose
theorem sub_toIcoDiv_zsmul_mem_Ico (a b : α) : b - toIcoDiv hp a b • p ∈ Set.Ico a (a + p) :=
(existsUnique_sub_zsmul_mem_Ico hp b a).choose_spec.1
theorem toIcoDiv_eq_of_sub_zsmul_mem_Ico (h : b - n • p ∈ Set.Ico a (a + p)) :
toIcoDiv hp a b = n :=
((existsUnique_sub_zsmul_mem_Ico hp b a).choose_spec.2 _ h).symm
/--
The unique integer such that this multiple of `p`, subtracted from `b`, is in `Ioc a (a + p)`. -/
def toIocDiv (a b : α) : ℤ :=
(existsUnique_sub_zsmul_mem_Ioc hp b a).choose
theorem sub_toIocDiv_zsmul_mem_Ioc (a b : α) : b - toIocDiv hp a b • p ∈ Set.Ioc a (a + p) :=
(existsUnique_sub_zsmul_mem_Ioc hp b a).choose_spec.1
theorem toIocDiv_eq_of_sub_zsmul_mem_Ioc (h : b - n • p ∈ Set.Ioc a (a + p)) :
toIocDiv hp a b = n :=
((existsUnique_sub_zsmul_mem_Ioc hp b a).choose_spec.2 _ h).symm
/-- Reduce `b` to the interval `Ico a (a + p)`. -/
def toIcoMod (a b : α) : α :=
b - toIcoDiv hp a b • p
/-- Reduce `b` to the interval `Ioc a (a + p)`. -/
def toIocMod (a b : α) : α :=
b - toIocDiv hp a b • p
theorem toIcoMod_mem_Ico (a b : α) : toIcoMod hp a b ∈ Set.Ico a (a + p) :=
sub_toIcoDiv_zsmul_mem_Ico hp a b
theorem toIcoMod_mem_Ico' (b : α) : toIcoMod hp 0 b ∈ Set.Ico 0 p := by
convert toIcoMod_mem_Ico hp 0 b
exact (zero_add p).symm
theorem toIocMod_mem_Ioc (a b : α) : toIocMod hp a b ∈ Set.Ioc a (a + p) :=
sub_toIocDiv_zsmul_mem_Ioc hp a b
theorem left_le_toIcoMod (a b : α) : a ≤ toIcoMod hp a b :=
(Set.mem_Ico.1 (toIcoMod_mem_Ico hp a b)).1
theorem left_lt_toIocMod (a b : α) : a < toIocMod hp a b :=
(Set.mem_Ioc.1 (toIocMod_mem_Ioc hp a b)).1
theorem toIcoMod_lt_right (a b : α) : toIcoMod hp a b < a + p :=
(Set.mem_Ico.1 (toIcoMod_mem_Ico hp a b)).2
theorem toIocMod_le_right (a b : α) : toIocMod hp a b ≤ a + p :=
(Set.mem_Ioc.1 (toIocMod_mem_Ioc hp a b)).2
@[simp]
theorem self_sub_toIcoDiv_zsmul (a b : α) : b - toIcoDiv hp a b • p = toIcoMod hp a b :=
rfl
@[simp]
theorem self_sub_toIocDiv_zsmul (a b : α) : b - toIocDiv hp a b • p = toIocMod hp a b :=
rfl
@[simp]
theorem toIcoDiv_zsmul_sub_self (a b : α) : toIcoDiv hp a b • p - b = -toIcoMod hp a b := by
rw [toIcoMod, neg_sub]
@[simp]
theorem toIocDiv_zsmul_sub_self (a b : α) : toIocDiv hp a b • p - b = -toIocMod hp a b := by
rw [toIocMod, neg_sub]
@[simp]
theorem toIcoMod_sub_self (a b : α) : toIcoMod hp a b - b = -toIcoDiv hp a b • p := by
rw [toIcoMod, sub_sub_cancel_left, neg_smul]
@[simp]
theorem toIocMod_sub_self (a b : α) : toIocMod hp a b - b = -toIocDiv hp a b • p := by
rw [toIocMod, sub_sub_cancel_left, neg_smul]
@[simp]
theorem self_sub_toIcoMod (a b : α) : b - toIcoMod hp a b = toIcoDiv hp a b • p := by
rw [toIcoMod, sub_sub_cancel]
@[simp]
theorem self_sub_toIocMod (a b : α) : b - toIocMod hp a b = toIocDiv hp a b • p := by
rw [toIocMod, sub_sub_cancel]
@[simp]
theorem toIcoMod_add_toIcoDiv_zsmul (a b : α) : toIcoMod hp a b + toIcoDiv hp a b • p = b := by
rw [toIcoMod, sub_add_cancel]
@[simp]
theorem toIocMod_add_toIocDiv_zsmul (a b : α) : toIocMod hp a b + toIocDiv hp a b • p = b := by
rw [toIocMod, sub_add_cancel]
@[simp]
theorem toIcoDiv_zsmul_sub_toIcoMod (a b : α) : toIcoDiv hp a b • p + toIcoMod hp a b = b := by
rw [add_comm, toIcoMod_add_toIcoDiv_zsmul]
@[simp]
theorem toIocDiv_zsmul_sub_toIocMod (a b : α) : toIocDiv hp a b • p + toIocMod hp a b = b := by
rw [add_comm, toIocMod_add_toIocDiv_zsmul]
theorem toIcoMod_eq_iff : toIcoMod hp a b = c ↔ c ∈ Set.Ico a (a + p) ∧ ∃ z : ℤ, b = c + z • p := by
refine
⟨fun h =>
⟨h ▸ toIcoMod_mem_Ico hp a b, toIcoDiv hp a b, h ▸ (toIcoMod_add_toIcoDiv_zsmul _ _ _).symm⟩,
?_⟩
simp_rw [← @sub_eq_iff_eq_add]
rintro ⟨hc, n, rfl⟩
rw [← toIcoDiv_eq_of_sub_zsmul_mem_Ico hp hc, toIcoMod]
theorem toIocMod_eq_iff : toIocMod hp a b = c ↔ c ∈ Set.Ioc a (a + p) ∧ ∃ z : ℤ, b = c + z • p := by
refine
⟨fun h =>
⟨h ▸ toIocMod_mem_Ioc hp a b, toIocDiv hp a b, h ▸ (toIocMod_add_toIocDiv_zsmul hp _ _).symm⟩,
?_⟩
simp_rw [← @sub_eq_iff_eq_add]
rintro ⟨hc, n, rfl⟩
rw [← toIocDiv_eq_of_sub_zsmul_mem_Ioc hp hc, toIocMod]
@[simp]
theorem toIcoDiv_apply_left (a : α) : toIcoDiv hp a a = 0 :=
toIcoDiv_eq_of_sub_zsmul_mem_Ico hp <| by simp [hp]
@[simp]
theorem toIocDiv_apply_left (a : α) : toIocDiv hp a a = -1 :=
toIocDiv_eq_of_sub_zsmul_mem_Ioc hp <| by simp [hp]
@[simp]
theorem toIcoMod_apply_left (a : α) : toIcoMod hp a a = a := by
rw [toIcoMod_eq_iff hp, Set.left_mem_Ico]
exact ⟨lt_add_of_pos_right _ hp, 0, by simp⟩
@[simp]
theorem toIocMod_apply_left (a : α) : toIocMod hp a a = a + p := by
rw [toIocMod_eq_iff hp, Set.right_mem_Ioc]
exact ⟨lt_add_of_pos_right _ hp, -1, by simp⟩
theorem toIcoDiv_apply_right (a : α) : toIcoDiv hp a (a + p) = 1 :=
toIcoDiv_eq_of_sub_zsmul_mem_Ico hp <| by simp [hp]
theorem toIocDiv_apply_right (a : α) : toIocDiv hp a (a + p) = 0 :=
toIocDiv_eq_of_sub_zsmul_mem_Ioc hp <| by simp [hp]
theorem toIcoMod_apply_right (a : α) : toIcoMod hp a (a + p) = a := by
rw [toIcoMod_eq_iff hp, Set.left_mem_Ico]
exact ⟨lt_add_of_pos_right _ hp, 1, by simp⟩
theorem toIocMod_apply_right (a : α) : toIocMod hp a (a + p) = a + p := by
rw [toIocMod_eq_iff hp, Set.right_mem_Ioc]
exact ⟨lt_add_of_pos_right _ hp, 0, by simp⟩
@[simp]
theorem toIcoDiv_add_zsmul (a b : α) (m : ℤ) : toIcoDiv hp a (b + m • p) = toIcoDiv hp a b + m :=
toIcoDiv_eq_of_sub_zsmul_mem_Ico hp <| by
simpa only [add_smul, add_sub_add_right_eq_sub] using sub_toIcoDiv_zsmul_mem_Ico hp a b
@[simp]
theorem toIcoDiv_add_zsmul' (a b : α) (m : ℤ) :
toIcoDiv hp (a + m • p) b = toIcoDiv hp a b - m := by
refine toIcoDiv_eq_of_sub_zsmul_mem_Ico _ ?_
rw [sub_smul, ← sub_add, add_right_comm]
simpa using sub_toIcoDiv_zsmul_mem_Ico hp a b
@[simp]
theorem toIocDiv_add_zsmul (a b : α) (m : ℤ) : toIocDiv hp a (b + m • p) = toIocDiv hp a b + m :=
toIocDiv_eq_of_sub_zsmul_mem_Ioc hp <| by
simpa only [add_smul, add_sub_add_right_eq_sub] using sub_toIocDiv_zsmul_mem_Ioc hp a b
@[simp]
theorem toIocDiv_add_zsmul' (a b : α) (m : ℤ) :
toIocDiv hp (a + m • p) b = toIocDiv hp a b - m := by
refine toIocDiv_eq_of_sub_zsmul_mem_Ioc _ ?_
rw [sub_smul, ← sub_add, add_right_comm]
simpa using sub_toIocDiv_zsmul_mem_Ioc hp a b
@[simp]
theorem toIcoDiv_zsmul_add (a b : α) (m : ℤ) : toIcoDiv hp a (m • p + b) = m + toIcoDiv hp a b := by
rw [add_comm, toIcoDiv_add_zsmul, add_comm]
/-! Note we omit `toIcoDiv_zsmul_add'` as `-m + toIcoDiv hp a b` is not very convenient. -/
@[simp]
theorem toIocDiv_zsmul_add (a b : α) (m : ℤ) : toIocDiv hp a (m • p + b) = m + toIocDiv hp a b := by
rw [add_comm, toIocDiv_add_zsmul, add_comm]
/-! Note we omit `toIocDiv_zsmul_add'` as `-m + toIocDiv hp a b` is not very convenient. -/
@[simp]
theorem toIcoDiv_sub_zsmul (a b : α) (m : ℤ) : toIcoDiv hp a (b - m • p) = toIcoDiv hp a b - m := by
rw [sub_eq_add_neg, ← neg_smul, toIcoDiv_add_zsmul, sub_eq_add_neg]
@[simp]
theorem toIcoDiv_sub_zsmul' (a b : α) (m : ℤ) :
toIcoDiv hp (a - m • p) b = toIcoDiv hp a b + m := by
rw [sub_eq_add_neg, ← neg_smul, toIcoDiv_add_zsmul', sub_neg_eq_add]
@[simp]
theorem toIocDiv_sub_zsmul (a b : α) (m : ℤ) : toIocDiv hp a (b - m • p) = toIocDiv hp a b - m := by
rw [sub_eq_add_neg, ← neg_smul, toIocDiv_add_zsmul, sub_eq_add_neg]
@[simp]
theorem toIocDiv_sub_zsmul' (a b : α) (m : ℤ) :
toIocDiv hp (a - m • p) b = toIocDiv hp a b + m := by
rw [sub_eq_add_neg, ← neg_smul, toIocDiv_add_zsmul', sub_neg_eq_add]
@[simp]
theorem toIcoDiv_add_right (a b : α) : toIcoDiv hp a (b + p) = toIcoDiv hp a b + 1 := by
simpa only [one_zsmul] using toIcoDiv_add_zsmul hp a b 1
@[simp]
theorem toIcoDiv_add_right' (a b : α) : toIcoDiv hp (a + p) b = toIcoDiv hp a b - 1 := by
simpa only [one_zsmul] using toIcoDiv_add_zsmul' hp a b 1
@[simp]
theorem toIocDiv_add_right (a b : α) : toIocDiv hp a (b + p) = toIocDiv hp a b + 1 := by
simpa only [one_zsmul] using toIocDiv_add_zsmul hp a b 1
@[simp]
theorem toIocDiv_add_right' (a b : α) : toIocDiv hp (a + p) b = toIocDiv hp a b - 1 := by
simpa only [one_zsmul] using toIocDiv_add_zsmul' hp a b 1
@[simp]
theorem toIcoDiv_add_left (a b : α) : toIcoDiv hp a (p + b) = toIcoDiv hp a b + 1 := by
rw [add_comm, toIcoDiv_add_right]
@[simp]
theorem toIcoDiv_add_left' (a b : α) : toIcoDiv hp (p + a) b = toIcoDiv hp a b - 1 := by
rw [add_comm, toIcoDiv_add_right']
@[simp]
theorem toIocDiv_add_left (a b : α) : toIocDiv hp a (p + b) = toIocDiv hp a b + 1 := by
rw [add_comm, toIocDiv_add_right]
@[simp]
theorem toIocDiv_add_left' (a b : α) : toIocDiv hp (p + a) b = toIocDiv hp a b - 1 := by
rw [add_comm, toIocDiv_add_right']
@[simp]
theorem toIcoDiv_sub (a b : α) : toIcoDiv hp a (b - p) = toIcoDiv hp a b - 1 := by
simpa only [one_zsmul] using toIcoDiv_sub_zsmul hp a b 1
@[simp]
theorem toIcoDiv_sub' (a b : α) : toIcoDiv hp (a - p) b = toIcoDiv hp a b + 1 := by
simpa only [one_zsmul] using toIcoDiv_sub_zsmul' hp a b 1
@[simp]
theorem toIocDiv_sub (a b : α) : toIocDiv hp a (b - p) = toIocDiv hp a b - 1 := by
simpa only [one_zsmul] using toIocDiv_sub_zsmul hp a b 1
@[simp]
theorem toIocDiv_sub' (a b : α) : toIocDiv hp (a - p) b = toIocDiv hp a b + 1 := by
simpa only [one_zsmul] using toIocDiv_sub_zsmul' hp a b 1
theorem toIcoDiv_sub_eq_toIcoDiv_add (a b c : α) :
toIcoDiv hp a (b - c) = toIcoDiv hp (a + c) b := by
apply toIcoDiv_eq_of_sub_zsmul_mem_Ico
rw [← sub_right_comm, Set.sub_mem_Ico_iff_left, add_right_comm]
exact sub_toIcoDiv_zsmul_mem_Ico hp (a + c) b
theorem toIocDiv_sub_eq_toIocDiv_add (a b c : α) :
toIocDiv hp a (b - c) = toIocDiv hp (a + c) b := by
apply toIocDiv_eq_of_sub_zsmul_mem_Ioc
rw [← sub_right_comm, Set.sub_mem_Ioc_iff_left, add_right_comm]
exact sub_toIocDiv_zsmul_mem_Ioc hp (a + c) b
theorem toIcoDiv_sub_eq_toIcoDiv_add' (a b c : α) :
toIcoDiv hp (a - c) b = toIcoDiv hp a (b + c) := by
rw [← sub_neg_eq_add, toIcoDiv_sub_eq_toIcoDiv_add, sub_eq_add_neg]
theorem toIocDiv_sub_eq_toIocDiv_add' (a b c : α) :
toIocDiv hp (a - c) b = toIocDiv hp a (b + c) := by
rw [← sub_neg_eq_add, toIocDiv_sub_eq_toIocDiv_add, sub_eq_add_neg]
theorem toIcoDiv_neg (a b : α) : toIcoDiv hp a (-b) = -(toIocDiv hp (-a) b + 1) := by
suffices toIcoDiv hp a (-b) = -toIocDiv hp (-(a + p)) b by
rwa [neg_add, ← sub_eq_add_neg, toIocDiv_sub_eq_toIocDiv_add', toIocDiv_add_right] at this
rw [← neg_eq_iff_eq_neg, eq_comm]
apply toIocDiv_eq_of_sub_zsmul_mem_Ioc
obtain ⟨hc, ho⟩ := sub_toIcoDiv_zsmul_mem_Ico hp a (-b)
rw [← neg_lt_neg_iff, neg_sub' (-b), neg_neg, ← neg_smul] at ho
rw [← neg_le_neg_iff, neg_sub' (-b), neg_neg, ← neg_smul] at hc
refine ⟨ho, hc.trans_eq ?_⟩
rw [neg_add, neg_add_cancel_right]
theorem toIcoDiv_neg' (a b : α) : toIcoDiv hp (-a) b = -(toIocDiv hp a (-b) + 1) := by
simpa only [neg_neg] using toIcoDiv_neg hp (-a) (-b)
theorem toIocDiv_neg (a b : α) : toIocDiv hp a (-b) = -(toIcoDiv hp (-a) b + 1) := by
rw [← neg_neg b, toIcoDiv_neg, neg_neg, neg_neg, neg_add', neg_neg, add_sub_cancel_right]
theorem toIocDiv_neg' (a b : α) : toIocDiv hp (-a) b = -(toIcoDiv hp a (-b) + 1) := by
simpa only [neg_neg] using toIocDiv_neg hp (-a) (-b)
@[simp]
theorem toIcoMod_add_zsmul (a b : α) (m : ℤ) : toIcoMod hp a (b + m • p) = toIcoMod hp a b := by
rw [toIcoMod, toIcoDiv_add_zsmul, toIcoMod, add_smul]
abel
@[simp]
theorem toIcoMod_add_zsmul' (a b : α) (m : ℤ) :
toIcoMod hp (a + m • p) b = toIcoMod hp a b + m • p := by
simp only [toIcoMod, toIcoDiv_add_zsmul', sub_smul, sub_add]
@[simp]
theorem toIocMod_add_zsmul (a b : α) (m : ℤ) : toIocMod hp a (b + m • p) = toIocMod hp a b := by
rw [toIocMod, toIocDiv_add_zsmul, toIocMod, add_smul]
abel
@[simp]
theorem toIocMod_add_zsmul' (a b : α) (m : ℤ) :
toIocMod hp (a + m • p) b = toIocMod hp a b + m • p := by
simp only [toIocMod, toIocDiv_add_zsmul', sub_smul, sub_add]
@[simp]
theorem toIcoMod_zsmul_add (a b : α) (m : ℤ) : toIcoMod hp a (m • p + b) = toIcoMod hp a b := by
rw [add_comm, toIcoMod_add_zsmul]
@[simp]
theorem toIcoMod_zsmul_add' (a b : α) (m : ℤ) :
toIcoMod hp (m • p + a) b = m • p + toIcoMod hp a b := by
rw [add_comm, toIcoMod_add_zsmul', add_comm]
@[simp]
theorem toIocMod_zsmul_add (a b : α) (m : ℤ) : toIocMod hp a (m • p + b) = toIocMod hp a b := by
rw [add_comm, toIocMod_add_zsmul]
@[simp]
theorem toIocMod_zsmul_add' (a b : α) (m : ℤ) :
toIocMod hp (m • p + a) b = m • p + toIocMod hp a b := by
rw [add_comm, toIocMod_add_zsmul', add_comm]
@[simp]
| theorem toIcoMod_sub_zsmul (a b : α) (m : ℤ) : toIcoMod hp a (b - m • p) = toIcoMod hp a b := by
rw [sub_eq_add_neg, ← neg_smul, toIcoMod_add_zsmul]
| Mathlib/Algebra/Order/ToIntervalMod.lean | 377 | 379 |
/-
Copyright (c) 2020 Kenji Nakagawa. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kenji Nakagawa, Anne Baanen, Filippo A. E. Nuccio
-/
import Mathlib.Algebra.Algebra.Subalgebra.Pointwise
import Mathlib.Algebra.Polynomial.FieldDivision
import Mathlib.RingTheory.Spectrum.Maximal.Localization
import Mathlib.RingTheory.ChainOfDivisors
import Mathlib.RingTheory.DedekindDomain.Basic
import Mathlib.RingTheory.FractionalIdeal.Operations
import Mathlib.Algebra.Squarefree.Basic
/-!
# Dedekind domains and ideals
In this file, we show a ring is a Dedekind domain iff all fractional ideals are invertible.
Then we prove some results on the unique factorization monoid structure of the ideals.
## Main definitions
- `IsDedekindDomainInv` alternatively defines a Dedekind domain as an integral domain where
every nonzero fractional ideal is invertible.
- `isDedekindDomainInv_iff` shows that this does note depend on the choice of field of
fractions.
- `IsDedekindDomain.HeightOneSpectrum` defines the type of nonzero prime ideals of `R`.
## Main results:
- `isDedekindDomain_iff_isDedekindDomainInv`
- `Ideal.uniqueFactorizationMonoid`
## Implementation notes
The definitions that involve a field of fractions choose a canonical field of fractions,
but are independent of that choice. The `..._iff` lemmas express this independence.
Often, definitions assume that Dedekind domains are not fields. We found it more practical
to add a `(h : ¬ IsField A)` assumption whenever this is explicitly needed.
## References
* [D. Marcus, *Number Fields*][marcus1977number]
* [J.W.S. Cassels, A. Fröhlich, *Algebraic Number Theory*][cassels1967algebraic]
* [J. Neukirch, *Algebraic Number Theory*][Neukirch1992]
## Tags
dedekind domain, dedekind ring
-/
variable (R A K : Type*) [CommRing R] [CommRing A] [Field K]
open scoped nonZeroDivisors Polynomial
section Inverse
namespace FractionalIdeal
variable {R₁ : Type*} [CommRing R₁] [IsDomain R₁] [Algebra R₁ K] [IsFractionRing R₁ K]
variable {I J : FractionalIdeal R₁⁰ K}
noncomputable instance : Inv (FractionalIdeal R₁⁰ K) := ⟨fun I => 1 / I⟩
theorem inv_eq : I⁻¹ = 1 / I := rfl
theorem inv_zero' : (0 : FractionalIdeal R₁⁰ K)⁻¹ = 0 := div_zero
theorem inv_nonzero {J : FractionalIdeal R₁⁰ K} (h : J ≠ 0) :
J⁻¹ = ⟨(1 : FractionalIdeal R₁⁰ K) / J, fractional_div_of_nonzero h⟩ := div_nonzero h
theorem coe_inv_of_nonzero {J : FractionalIdeal R₁⁰ K} (h : J ≠ 0) :
(↑J⁻¹ : Submodule R₁ K) = IsLocalization.coeSubmodule K ⊤ / (J : Submodule R₁ K) := by
simp_rw [inv_nonzero _ h, coe_one, coe_mk, IsLocalization.coeSubmodule_top]
variable {K}
theorem mem_inv_iff (hI : I ≠ 0) {x : K} : x ∈ I⁻¹ ↔ ∀ y ∈ I, x * y ∈ (1 : FractionalIdeal R₁⁰ K) :=
mem_div_iff_of_nonzero hI
theorem inv_anti_mono (hI : I ≠ 0) (hJ : J ≠ 0) (hIJ : I ≤ J) : J⁻¹ ≤ I⁻¹ := by
-- Porting note: in Lean3, introducing `x` would just give `x ∈ J⁻¹ → x ∈ I⁻¹`, but
-- in Lean4, it goes all the way down to the subtypes
intro x
simp only [val_eq_coe, mem_coe, mem_inv_iff hJ, mem_inv_iff hI]
exact fun h y hy => h y (hIJ hy)
theorem le_self_mul_inv {I : FractionalIdeal R₁⁰ K} (hI : I ≤ (1 : FractionalIdeal R₁⁰ K)) :
I ≤ I * I⁻¹ :=
le_self_mul_one_div hI
variable (K)
theorem coe_ideal_le_self_mul_inv (I : Ideal R₁) :
(I : FractionalIdeal R₁⁰ K) ≤ I * (I : FractionalIdeal R₁⁰ K)⁻¹ :=
le_self_mul_inv coeIdeal_le_one
/-- `I⁻¹` is the inverse of `I` if `I` has an inverse. -/
theorem right_inverse_eq (I J : FractionalIdeal R₁⁰ K) (h : I * J = 1) : J = I⁻¹ := by
have hI : I ≠ 0 := ne_zero_of_mul_eq_one I J h
suffices h' : I * (1 / I) = 1 from
congr_arg Units.inv <| @Units.ext _ _ (Units.mkOfMulEqOne _ _ h) (Units.mkOfMulEqOne _ _ h') rfl
apply le_antisymm
· apply mul_le.mpr _
intro x hx y hy
rw [mul_comm]
exact (mem_div_iff_of_nonzero hI).mp hy x hx
rw [← h]
apply mul_left_mono I
apply (le_div_iff_of_nonzero hI).mpr _
intro y hy x hx
rw [mul_comm]
exact mul_mem_mul hy hx
theorem mul_inv_cancel_iff {I : FractionalIdeal R₁⁰ K} : I * I⁻¹ = 1 ↔ ∃ J, I * J = 1 :=
⟨fun h => ⟨I⁻¹, h⟩, fun ⟨J, hJ⟩ => by rwa [← right_inverse_eq K I J hJ]⟩
theorem mul_inv_cancel_iff_isUnit {I : FractionalIdeal R₁⁰ K} : I * I⁻¹ = 1 ↔ IsUnit I :=
(mul_inv_cancel_iff K).trans isUnit_iff_exists_inv.symm
variable {K' : Type*} [Field K'] [Algebra R₁ K'] [IsFractionRing R₁ K']
@[simp]
protected theorem map_inv (I : FractionalIdeal R₁⁰ K) (h : K ≃ₐ[R₁] K') :
I⁻¹.map (h : K →ₐ[R₁] K') = (I.map h)⁻¹ := by
rw [inv_eq, FractionalIdeal.map_div, FractionalIdeal.map_one, inv_eq]
open Submodule Submodule.IsPrincipal
@[simp]
theorem spanSingleton_inv (x : K) : (spanSingleton R₁⁰ x)⁻¹ = spanSingleton _ x⁻¹ :=
one_div_spanSingleton x
theorem spanSingleton_div_spanSingleton (x y : K) :
spanSingleton R₁⁰ x / spanSingleton R₁⁰ y = spanSingleton R₁⁰ (x / y) := by
rw [div_spanSingleton, mul_comm, spanSingleton_mul_spanSingleton, div_eq_mul_inv]
theorem spanSingleton_div_self {x : K} (hx : x ≠ 0) :
spanSingleton R₁⁰ x / spanSingleton R₁⁰ x = 1 := by
rw [spanSingleton_div_spanSingleton, div_self hx, spanSingleton_one]
theorem coe_ideal_span_singleton_div_self {x : R₁} (hx : x ≠ 0) :
(Ideal.span ({x} : Set R₁) : FractionalIdeal R₁⁰ K) / Ideal.span ({x} : Set R₁) = 1 := by
rw [coeIdeal_span_singleton,
spanSingleton_div_self K <|
(map_ne_zero_iff _ <| FaithfulSMul.algebraMap_injective R₁ K).mpr hx]
theorem spanSingleton_mul_inv {x : K} (hx : x ≠ 0) :
spanSingleton R₁⁰ x * (spanSingleton R₁⁰ x)⁻¹ = 1 := by
rw [spanSingleton_inv, spanSingleton_mul_spanSingleton, mul_inv_cancel₀ hx, spanSingleton_one]
theorem coe_ideal_span_singleton_mul_inv {x : R₁} (hx : x ≠ 0) :
(Ideal.span ({x} : Set R₁) : FractionalIdeal R₁⁰ K) *
(Ideal.span ({x} : Set R₁) : FractionalIdeal R₁⁰ K)⁻¹ = 1 := by
rw [coeIdeal_span_singleton,
spanSingleton_mul_inv K <|
(map_ne_zero_iff _ <| FaithfulSMul.algebraMap_injective R₁ K).mpr hx]
theorem spanSingleton_inv_mul {x : K} (hx : x ≠ 0) :
(spanSingleton R₁⁰ x)⁻¹ * spanSingleton R₁⁰ x = 1 := by
rw [mul_comm, spanSingleton_mul_inv K hx]
theorem coe_ideal_span_singleton_inv_mul {x : R₁} (hx : x ≠ 0) :
(Ideal.span ({x} : Set R₁) : FractionalIdeal R₁⁰ K)⁻¹ * Ideal.span ({x} : Set R₁) = 1 := by
rw [mul_comm, coe_ideal_span_singleton_mul_inv K hx]
theorem mul_generator_self_inv {R₁ : Type*} [CommRing R₁] [Algebra R₁ K] [IsLocalization R₁⁰ K]
(I : FractionalIdeal R₁⁰ K) [Submodule.IsPrincipal (I : Submodule R₁ K)] (h : I ≠ 0) :
I * spanSingleton _ (generator (I : Submodule R₁ K))⁻¹ = 1 := by
-- Rewrite only the `I` that appears alone.
conv_lhs => congr; rw [eq_spanSingleton_of_principal I]
rw [spanSingleton_mul_spanSingleton, mul_inv_cancel₀, spanSingleton_one]
intro generator_I_eq_zero
apply h
rw [eq_spanSingleton_of_principal I, generator_I_eq_zero, spanSingleton_zero]
theorem invertible_of_principal (I : FractionalIdeal R₁⁰ K)
[Submodule.IsPrincipal (I : Submodule R₁ K)] (h : I ≠ 0) : I * I⁻¹ = 1 :=
mul_div_self_cancel_iff.mpr
⟨spanSingleton _ (generator (I : Submodule R₁ K))⁻¹, mul_generator_self_inv _ I h⟩
theorem invertible_iff_generator_nonzero (I : FractionalIdeal R₁⁰ K)
[Submodule.IsPrincipal (I : Submodule R₁ K)] :
I * I⁻¹ = 1 ↔ generator (I : Submodule R₁ K) ≠ 0 := by
constructor
· intro hI hg
apply ne_zero_of_mul_eq_one _ _ hI
rw [eq_spanSingleton_of_principal I, hg, spanSingleton_zero]
· intro hg
apply invertible_of_principal
rw [eq_spanSingleton_of_principal I]
intro hI
have := mem_spanSingleton_self R₁⁰ (generator (I : Submodule R₁ K))
rw [hI, mem_zero_iff] at this
contradiction
theorem isPrincipal_inv (I : FractionalIdeal R₁⁰ K) [Submodule.IsPrincipal (I : Submodule R₁ K)]
(h : I ≠ 0) : Submodule.IsPrincipal I⁻¹.1 := by
rw [val_eq_coe, isPrincipal_iff]
use (generator (I : Submodule R₁ K))⁻¹
have hI : I * spanSingleton _ (generator (I : Submodule R₁ K))⁻¹ = 1 :=
mul_generator_self_inv _ I h
exact (right_inverse_eq _ I (spanSingleton _ (generator (I : Submodule R₁ K))⁻¹) hI).symm
variable {K}
lemma den_mem_inv {I : FractionalIdeal R₁⁰ K} (hI : I ≠ ⊥) :
(algebraMap R₁ K) (I.den : R₁) ∈ I⁻¹ := by
rw [mem_inv_iff hI]
intro i hi
rw [← Algebra.smul_def (I.den : R₁) i, ← mem_coe, coe_one]
suffices Submodule.map (Algebra.linearMap R₁ K) I.num ≤ 1 from
this <| (den_mul_self_eq_num I).symm ▸ smul_mem_pointwise_smul i I.den I.coeToSubmodule hi
apply le_trans <| map_mono (show I.num ≤ 1 by simp only [Ideal.one_eq_top, le_top, bot_eq_zero])
rw [Ideal.one_eq_top, Submodule.map_top, one_eq_range]
lemma num_le_mul_inv (I : FractionalIdeal R₁⁰ K) : I.num ≤ I * I⁻¹ := by
by_cases hI : I = 0
· rw [hI, num_zero_eq <| FaithfulSMul.algebraMap_injective R₁ K, zero_mul, zero_eq_bot,
coeIdeal_bot]
· rw [mul_comm, ← den_mul_self_eq_num']
exact mul_right_mono I <| spanSingleton_le_iff_mem.2 (den_mem_inv hI)
lemma bot_lt_mul_inv {I : FractionalIdeal R₁⁰ K} (hI : I ≠ ⊥) : ⊥ < I * I⁻¹ :=
lt_of_lt_of_le (coeIdeal_ne_zero.2 (hI ∘ num_eq_zero_iff.1)).bot_lt I.num_le_mul_inv
noncomputable instance : InvOneClass (FractionalIdeal R₁⁰ K) := { inv_one := div_one }
end FractionalIdeal
section IsDedekindDomainInv
variable [IsDomain A]
/-- A Dedekind domain is an integral domain such that every fractional ideal has an inverse.
This is equivalent to `IsDedekindDomain`.
In particular we provide a `fractional_ideal.comm_group_with_zero` instance,
assuming `IsDedekindDomain A`, which implies `IsDedekindDomainInv`. For **integral** ideals,
`IsDedekindDomain`(`_inv`) implies only `Ideal.cancelCommMonoidWithZero`.
-/
def IsDedekindDomainInv : Prop :=
∀ I ≠ (⊥ : FractionalIdeal A⁰ (FractionRing A)), I * I⁻¹ = 1
open FractionalIdeal
variable {R A K}
theorem isDedekindDomainInv_iff [Algebra A K] [IsFractionRing A K] :
IsDedekindDomainInv A ↔ ∀ I ≠ (⊥ : FractionalIdeal A⁰ K), I * I⁻¹ = 1 := by
let h : FractionalIdeal A⁰ (FractionRing A) ≃+* FractionalIdeal A⁰ K :=
FractionalIdeal.mapEquiv (FractionRing.algEquiv A K)
refine h.toEquiv.forall_congr (fun {x} => ?_)
rw [← h.toEquiv.apply_eq_iff_eq]
simp [h, IsDedekindDomainInv]
theorem FractionalIdeal.adjoinIntegral_eq_one_of_isUnit [Algebra A K] [IsFractionRing A K] (x : K)
(hx : IsIntegral A x) (hI : IsUnit (adjoinIntegral A⁰ x hx)) : adjoinIntegral A⁰ x hx = 1 := by
set I := adjoinIntegral A⁰ x hx
have mul_self : IsIdempotentElem I := by
apply coeToSubmodule_injective
simp only [coe_mul, adjoinIntegral_coe, I]
rw [(Algebra.adjoin A {x}).isIdempotentElem_toSubmodule]
convert congr_arg (· * I⁻¹) mul_self <;>
simp only [(mul_inv_cancel_iff_isUnit K).mpr hI, mul_assoc, mul_one]
namespace IsDedekindDomainInv
variable [Algebra A K] [IsFractionRing A K] (h : IsDedekindDomainInv A)
include h
theorem mul_inv_eq_one {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) : I * I⁻¹ = 1 :=
isDedekindDomainInv_iff.mp h I hI
theorem inv_mul_eq_one {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) : I⁻¹ * I = 1 :=
(mul_comm _ _).trans (h.mul_inv_eq_one hI)
protected theorem isUnit {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) : IsUnit I :=
isUnit_of_mul_eq_one _ _ (h.mul_inv_eq_one hI)
theorem isNoetherianRing : IsNoetherianRing A := by
refine isNoetherianRing_iff.mpr ⟨fun I : Ideal A => ?_⟩
by_cases hI : I = ⊥
· rw [hI]; apply Submodule.fg_bot
have hI : (I : FractionalIdeal A⁰ (FractionRing A)) ≠ 0 := coeIdeal_ne_zero.mpr hI
exact I.fg_of_isUnit (IsFractionRing.injective A (FractionRing A)) (h.isUnit hI)
theorem integrallyClosed : IsIntegrallyClosed A := by
-- It suffices to show that for integral `x`,
-- `A[x]` (which is a fractional ideal) is in fact equal to `A`.
refine (isIntegrallyClosed_iff (FractionRing A)).mpr (fun {x hx} => ?_)
rw [← Set.mem_range, ← Algebra.mem_bot, ← Subalgebra.mem_toSubmodule, Algebra.toSubmodule_bot,
Submodule.one_eq_span, ← coe_spanSingleton A⁰ (1 : FractionRing A), spanSingleton_one, ←
FractionalIdeal.adjoinIntegral_eq_one_of_isUnit x hx (h.isUnit _)]
· exact mem_adjoinIntegral_self A⁰ x hx
· exact fun h => one_ne_zero (eq_zero_iff.mp h 1 (Algebra.adjoin A {x}).one_mem)
open Ring
theorem dimensionLEOne : DimensionLEOne A := ⟨by
-- We're going to show that `P` is maximal because any (maximal) ideal `M`
-- that is strictly larger would be `⊤`.
rintro P P_ne hP
refine Ideal.isMaximal_def.mpr ⟨hP.ne_top, fun M hM => ?_⟩
-- We may assume `P` and `M` (as fractional ideals) are nonzero.
have P'_ne : (P : FractionalIdeal A⁰ (FractionRing A)) ≠ 0 := coeIdeal_ne_zero.mpr P_ne
have M'_ne : (M : FractionalIdeal A⁰ (FractionRing A)) ≠ 0 := coeIdeal_ne_zero.mpr hM.ne_bot
-- In particular, we'll show `M⁻¹ * P ≤ P`
suffices (M⁻¹ : FractionalIdeal A⁰ (FractionRing A)) * P ≤ P by
rw [eq_top_iff, ← coeIdeal_le_coeIdeal (FractionRing A), coeIdeal_top]
calc
(1 : FractionalIdeal A⁰ (FractionRing A)) = _ * _ * _ := ?_
_ ≤ _ * _ := mul_right_mono
((P : FractionalIdeal A⁰ (FractionRing A))⁻¹ * M : FractionalIdeal A⁰ (FractionRing A)) this
_ = M := ?_
· rw [mul_assoc, ← mul_assoc (P : FractionalIdeal A⁰ (FractionRing A)), h.mul_inv_eq_one P'_ne,
one_mul, h.inv_mul_eq_one M'_ne]
· rw [← mul_assoc (P : FractionalIdeal A⁰ (FractionRing A)), h.mul_inv_eq_one P'_ne, one_mul]
-- Suppose we have `x ∈ M⁻¹ * P`, then in fact `x = algebraMap _ _ y` for some `y`.
intro x hx
have le_one : (M⁻¹ : FractionalIdeal A⁰ (FractionRing A)) * P ≤ 1 := by
rw [← h.inv_mul_eq_one M'_ne]
exact mul_left_mono _ ((coeIdeal_le_coeIdeal (FractionRing A)).mpr hM.le)
obtain ⟨y, _hy, rfl⟩ := (mem_coeIdeal _).mp (le_one hx)
-- Since `M` is strictly greater than `P`, let `z ∈ M \ P`.
obtain ⟨z, hzM, hzp⟩ := SetLike.exists_of_lt hM
-- We have `z * y ∈ M * (M⁻¹ * P) = P`.
have zy_mem := mul_mem_mul (mem_coeIdeal_of_mem A⁰ hzM) hx
rw [← RingHom.map_mul, ← mul_assoc, h.mul_inv_eq_one M'_ne, one_mul] at zy_mem
obtain ⟨zy, hzy, zy_eq⟩ := (mem_coeIdeal A⁰).mp zy_mem
rw [IsFractionRing.injective A (FractionRing A) zy_eq] at hzy
-- But `P` is a prime ideal, so `z ∉ P` implies `y ∈ P`, as desired.
exact mem_coeIdeal_of_mem A⁰ (Or.resolve_left (hP.mem_or_mem hzy) hzp)⟩
/-- Showing one side of the equivalence between the definitions
`IsDedekindDomainInv` and `IsDedekindDomain` of Dedekind domains. -/
theorem isDedekindDomain : IsDedekindDomain A :=
{ h.isNoetherianRing, h.dimensionLEOne, h.integrallyClosed with }
end IsDedekindDomainInv
end IsDedekindDomainInv
variable [Algebra A K] [IsFractionRing A K]
variable {A K}
theorem one_mem_inv_coe_ideal [IsDomain A] {I : Ideal A} (hI : I ≠ ⊥) :
(1 : K) ∈ (I : FractionalIdeal A⁰ K)⁻¹ := by
rw [FractionalIdeal.mem_inv_iff (FractionalIdeal.coeIdeal_ne_zero.mpr hI)]
intro y hy
rw [one_mul]
exact FractionalIdeal.coeIdeal_le_one hy
/-- Specialization of `exists_primeSpectrum_prod_le_and_ne_bot_of_domain` to Dedekind domains:
Let `I : Ideal A` be a nonzero ideal, where `A` is a Dedekind domain that is not a field.
Then `exists_primeSpectrum_prod_le_and_ne_bot_of_domain` states we can find a product of prime
ideals that is contained within `I`. This lemma extends that result by making the product minimal:
let `M` be a maximal ideal that contains `I`, then the product including `M` is contained within `I`
and the product excluding `M` is not contained within `I`. -/
theorem exists_multiset_prod_cons_le_and_prod_not_le [IsDedekindDomain A] (hNF : ¬IsField A)
{I M : Ideal A} (hI0 : I ≠ ⊥) (hIM : I ≤ M) [hM : M.IsMaximal] :
∃ Z : Multiset (PrimeSpectrum A),
(M ::ₘ Z.map PrimeSpectrum.asIdeal).prod ≤ I ∧
¬Multiset.prod (Z.map PrimeSpectrum.asIdeal) ≤ I := by
-- Let `Z` be a minimal set of prime ideals such that their product is contained in `J`.
obtain ⟨Z₀, hZ₀⟩ := PrimeSpectrum.exists_primeSpectrum_prod_le_and_ne_bot_of_domain hNF hI0
obtain ⟨Z, ⟨hZI, hprodZ⟩, h_eraseZ⟩ :=
wellFounded_lt.has_min
{Z | (Z.map PrimeSpectrum.asIdeal).prod ≤ I ∧ (Z.map PrimeSpectrum.asIdeal).prod ≠ ⊥}
⟨Z₀, hZ₀.1, hZ₀.2⟩
obtain ⟨_, hPZ', hPM⟩ := hM.isPrime.multiset_prod_le.mp (hZI.trans hIM)
-- Then in fact there is a `P ∈ Z` with `P ≤ M`.
obtain ⟨P, hPZ, rfl⟩ := Multiset.mem_map.mp hPZ'
classical
have := Multiset.map_erase PrimeSpectrum.asIdeal (fun _ _ => PrimeSpectrum.ext) P Z
obtain ⟨hP0, hZP0⟩ : P.asIdeal ≠ ⊥ ∧ ((Z.erase P).map PrimeSpectrum.asIdeal).prod ≠ ⊥ := by
rwa [Ne, ← Multiset.cons_erase hPZ', Multiset.prod_cons, Ideal.mul_eq_bot, not_or, ←
this] at hprodZ
-- By maximality of `P` and `M`, we have that `P ≤ M` implies `P = M`.
have hPM' := (P.isPrime.isMaximal hP0).eq_of_le hM.ne_top hPM
subst hPM'
-- By minimality of `Z`, erasing `P` from `Z` is exactly what we need.
refine ⟨Z.erase P, ?_, ?_⟩
· convert hZI
rw [this, Multiset.cons_erase hPZ']
· refine fun h => h_eraseZ (Z.erase P) ⟨h, ?_⟩ (Multiset.erase_lt.mpr hPZ)
exact hZP0
namespace FractionalIdeal
open Ideal
lemma not_inv_le_one_of_ne_bot [IsDedekindDomain A] {I : Ideal A}
(hI0 : I ≠ ⊥) (hI1 : I ≠ ⊤) : ¬(I⁻¹ : FractionalIdeal A⁰ K) ≤ 1 := by
have hNF : ¬IsField A := fun h ↦ letI := h.toField; (eq_bot_or_eq_top I).elim hI0 hI1
wlog hM : I.IsMaximal generalizing I
· rcases I.exists_le_maximal hI1 with ⟨M, hmax, hIM⟩
have hMbot : M ≠ ⊥ := (M.bot_lt_of_maximal hNF).ne'
refine mt (le_trans <| inv_anti_mono ?_ ?_ ?_) (this hMbot hmax.ne_top hmax) <;>
simpa only [coeIdeal_ne_zero, coeIdeal_le_coeIdeal]
have hI0 : ⊥ < I := I.bot_lt_of_maximal hNF
obtain ⟨⟨a, haI⟩, ha0⟩ := Submodule.nonzero_mem_of_bot_lt hI0
replace ha0 : a ≠ 0 := Subtype.coe_injective.ne ha0
let J : Ideal A := Ideal.span {a}
have hJ0 : J ≠ ⊥ := mt Ideal.span_singleton_eq_bot.mp ha0
have hJI : J ≤ I := I.span_singleton_le_iff_mem.2 haI
-- Then we can find a product of prime (hence maximal) ideals contained in `J`,
-- such that removing element `M` from the product is not contained in `J`.
obtain ⟨Z, hle, hnle⟩ := exists_multiset_prod_cons_le_and_prod_not_le hNF hJ0 hJI
-- Choose an element `b` of the product that is not in `J`.
obtain ⟨b, hbZ, hbJ⟩ := SetLike.not_le_iff_exists.mp hnle
have hnz_fa : algebraMap A K a ≠ 0 :=
mt ((injective_iff_map_eq_zero _).mp (IsFractionRing.injective A K) a) ha0
-- Then `b a⁻¹ : K` is in `M⁻¹` but not in `1`.
refine Set.not_subset.2 ⟨algebraMap A K b * (algebraMap A K a)⁻¹, (mem_inv_iff ?_).mpr ?_, ?_⟩
· exact coeIdeal_ne_zero.mpr hI0.ne'
· rintro y₀ hy₀
obtain ⟨y, h_Iy, rfl⟩ := (mem_coeIdeal _).mp hy₀
rw [mul_comm, ← mul_assoc, ← RingHom.map_mul]
have h_yb : y * b ∈ J := by
apply hle
rw [Multiset.prod_cons]
exact Submodule.smul_mem_smul h_Iy hbZ
rw [Ideal.mem_span_singleton'] at h_yb
rcases h_yb with ⟨c, hc⟩
rw [← hc, RingHom.map_mul, mul_assoc, mul_inv_cancel₀ hnz_fa, mul_one]
apply coe_mem_one
· refine mt (mem_one_iff _).mp ?_
rintro ⟨x', h₂_abs⟩
rw [← div_eq_mul_inv, eq_div_iff_mul_eq hnz_fa, ← RingHom.map_mul] at h₂_abs
have := Ideal.mem_span_singleton'.mpr ⟨x', IsFractionRing.injective A K h₂_abs⟩
contradiction
theorem exists_not_mem_one_of_ne_bot [IsDedekindDomain A] {I : Ideal A} (hI0 : I ≠ ⊥)
(hI1 : I ≠ ⊤) : ∃ x ∈ (I⁻¹ : FractionalIdeal A⁰ K), x ∉ (1 : FractionalIdeal A⁰ K) :=
Set.not_subset.1 <| not_inv_le_one_of_ne_bot hI0 hI1
theorem mul_inv_cancel_of_le_one [h : IsDedekindDomain A] {I : Ideal A} (hI0 : I ≠ ⊥)
(hI : (I * (I : FractionalIdeal A⁰ K)⁻¹)⁻¹ ≤ 1) : I * (I : FractionalIdeal A⁰ K)⁻¹ = 1 := by
-- We'll show a contradiction with `exists_not_mem_one_of_ne_bot`:
-- `J⁻¹ = (I * I⁻¹)⁻¹` cannot have an element `x ∉ 1`, so it must equal `1`.
obtain ⟨J, hJ⟩ : ∃ J : Ideal A, (J : FractionalIdeal A⁰ K) = I * (I : FractionalIdeal A⁰ K)⁻¹ :=
le_one_iff_exists_coeIdeal.mp mul_one_div_le_one
by_cases hJ0 : J = ⊥
· subst hJ0
refine absurd ?_ hI0
rw [eq_bot_iff, ← coeIdeal_le_coeIdeal K, hJ]
exact coe_ideal_le_self_mul_inv K I
by_cases hJ1 : J = ⊤
· rw [← hJ, hJ1, coeIdeal_top]
exact (not_inv_le_one_of_ne_bot (K := K) hJ0 hJ1 (hJ ▸ hI)).elim
/-- Nonzero integral ideals in a Dedekind domain are invertible.
We will use this to show that nonzero fractional ideals are invertible,
and finally conclude that fractional ideals in a Dedekind domain form a group with zero.
-/
theorem coe_ideal_mul_inv [h : IsDedekindDomain A] (I : Ideal A) (hI0 : I ≠ ⊥) :
I * (I : FractionalIdeal A⁰ K)⁻¹ = 1 := by
-- We'll show `1 ≤ J⁻¹ = (I * I⁻¹)⁻¹ ≤ 1`.
apply mul_inv_cancel_of_le_one hI0
by_cases hJ0 : I * (I : FractionalIdeal A⁰ K)⁻¹ = 0
· rw [hJ0, inv_zero']; exact zero_le _
intro x hx
-- In particular, we'll show all `x ∈ J⁻¹` are integral.
suffices x ∈ integralClosure A K by
rwa [IsIntegrallyClosed.integralClosure_eq_bot, Algebra.mem_bot, Set.mem_range,
← mem_one_iff] at this
-- For that, we'll find a subalgebra that is f.g. as a module and contains `x`.
-- `A` is a noetherian ring, so we just need to find a subalgebra between `{x}` and `I⁻¹`.
rw [mem_integralClosure_iff_mem_fg]
have x_mul_mem : ∀ b ∈ (I⁻¹ : FractionalIdeal A⁰ K), x * b ∈ (I⁻¹ : FractionalIdeal A⁰ K) := by
intro b hb
rw [mem_inv_iff (coeIdeal_ne_zero.mpr hI0)]
dsimp only at hx
rw [val_eq_coe, mem_coe, mem_inv_iff hJ0] at hx
simp only [mul_assoc, mul_comm b] at hx ⊢
intro y hy
exact hx _ (mul_mem_mul hy hb)
-- It turns out the subalgebra consisting of all `p(x)` for `p : A[X]` works.
refine ⟨AlgHom.range (Polynomial.aeval x : A[X] →ₐ[A] K),
isNoetherian_submodule.mp (isNoetherian (I : FractionalIdeal A⁰ K)⁻¹) _ fun y hy => ?_,
⟨Polynomial.X, Polynomial.aeval_X x⟩⟩
obtain ⟨p, rfl⟩ := (AlgHom.mem_range _).mp hy
rw [Polynomial.aeval_eq_sum_range]
refine Submodule.sum_mem _ fun i hi => Submodule.smul_mem _ _ ?_
clear hi
induction' i with i ih
· rw [pow_zero]; exact one_mem_inv_coe_ideal hI0
· show x ^ i.succ ∈ (I⁻¹ : FractionalIdeal A⁰ K)
rw [pow_succ']; exact x_mul_mem _ ih
/-- Nonzero fractional ideals in a Dedekind domain are units.
This is also available as `_root_.mul_inv_cancel`, using the
`Semifield` instance defined below.
-/
protected theorem mul_inv_cancel [IsDedekindDomain A] {I : FractionalIdeal A⁰ K} (hne : I ≠ 0) :
I * I⁻¹ = 1 := by
obtain ⟨a, J, ha, hJ⟩ :
∃ (a : A) (aI : Ideal A), a ≠ 0 ∧ I = spanSingleton A⁰ (algebraMap A K a)⁻¹ * aI :=
exists_eq_spanSingleton_mul I
suffices h₂ : I * (spanSingleton A⁰ (algebraMap _ _ a) * (J : FractionalIdeal A⁰ K)⁻¹) = 1 by
rw [mul_inv_cancel_iff]
exact ⟨spanSingleton A⁰ (algebraMap _ _ a) * (J : FractionalIdeal A⁰ K)⁻¹, h₂⟩
subst hJ
rw [mul_assoc, mul_left_comm (J : FractionalIdeal A⁰ K), coe_ideal_mul_inv, mul_one,
spanSingleton_mul_spanSingleton, inv_mul_cancel₀, spanSingleton_one]
· exact mt ((injective_iff_map_eq_zero (algebraMap A K)).mp (IsFractionRing.injective A K) _) ha
· exact coeIdeal_ne_zero.mp (right_ne_zero_of_mul hne)
theorem mul_right_le_iff [IsDedekindDomain A] {J : FractionalIdeal A⁰ K} (hJ : J ≠ 0) :
∀ {I I'}, I * J ≤ I' * J ↔ I ≤ I' := by
intro I I'
constructor
· intro h
convert mul_right_mono J⁻¹ h <;> dsimp only <;>
rw [mul_assoc, FractionalIdeal.mul_inv_cancel hJ, mul_one]
· exact fun h => mul_right_mono J h
theorem mul_left_le_iff [IsDedekindDomain A] {J : FractionalIdeal A⁰ K} (hJ : J ≠ 0) {I I'} :
J * I ≤ J * I' ↔ I ≤ I' := by convert mul_right_le_iff hJ using 1; simp only [mul_comm]
theorem mul_right_strictMono [IsDedekindDomain A] {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) :
StrictMono (· * I) :=
strictMono_of_le_iff_le fun _ _ => (mul_right_le_iff hI).symm
theorem mul_left_strictMono [IsDedekindDomain A] {I : FractionalIdeal A⁰ K} (hI : I ≠ 0) :
StrictMono (I * ·) :=
strictMono_of_le_iff_le fun _ _ => (mul_left_le_iff hI).symm
/-- This is also available as `_root_.div_eq_mul_inv`, using the
`Semifield` instance defined below.
-/
protected theorem div_eq_mul_inv [IsDedekindDomain A] (I J : FractionalIdeal A⁰ K) :
I / J = I * J⁻¹ := by
by_cases hJ : J = 0
· rw [hJ, div_zero, inv_zero', mul_zero]
refine le_antisymm ((mul_right_le_iff hJ).mp ?_) ((le_div_iff_mul_le hJ).mpr ?_)
· rw [mul_assoc, mul_comm J⁻¹, FractionalIdeal.mul_inv_cancel hJ, mul_one, mul_le]
intro x hx y hy
rw [mem_div_iff_of_nonzero hJ] at hx
exact hx y hy
rw [mul_assoc, mul_comm J⁻¹, FractionalIdeal.mul_inv_cancel hJ, mul_one]
end FractionalIdeal
/-- `IsDedekindDomain` and `IsDedekindDomainInv` are equivalent ways
to express that an integral domain is a Dedekind domain. -/
theorem isDedekindDomain_iff_isDedekindDomainInv [IsDomain A] :
IsDedekindDomain A ↔ IsDedekindDomainInv A :=
⟨fun _h _I hI => FractionalIdeal.mul_inv_cancel hI, fun h => h.isDedekindDomain⟩
end Inverse
section IsDedekindDomain
variable {R A}
variable [IsDedekindDomain A] [Algebra A K] [IsFractionRing A K]
open FractionalIdeal
open Ideal
noncomputable instance FractionalIdeal.semifield : Semifield (FractionalIdeal A⁰ K) where
__ := coeIdeal_injective.nontrivial
inv_zero := inv_zero' _
div_eq_mul_inv := FractionalIdeal.div_eq_mul_inv
mul_inv_cancel _ := FractionalIdeal.mul_inv_cancel
nnqsmul := _
nnqsmul_def := fun _ _ => rfl
#adaptation_note /-- 2025-03-29 for lean4#7717 had to add `mul_left_cancel_of_ne_zero` field.
TODO(kmill) There is trouble calculating the type of the `IsLeftCancelMulZero` parent. -/
/-- Fractional ideals have cancellative multiplication in a Dedekind domain.
Although this instance is a direct consequence of the instance
`FractionalIdeal.semifield`, we define this instance to provide
a computable alternative.
-/
instance FractionalIdeal.cancelCommMonoidWithZero :
CancelCommMonoidWithZero (FractionalIdeal A⁰ K) where
__ : CommSemiring (FractionalIdeal A⁰ K) := inferInstance
mul_left_cancel_of_ne_zero := mul_left_cancel₀
instance Ideal.cancelCommMonoidWithZero : CancelCommMonoidWithZero (Ideal A) :=
{ Function.Injective.cancelCommMonoidWithZero (coeIdealHom A⁰ (FractionRing A)) coeIdeal_injective
(RingHom.map_zero _) (RingHom.map_one _) (RingHom.map_mul _) (RingHom.map_pow _) with }
-- Porting note: Lean can infer all it needs by itself
instance Ideal.isDomain : IsDomain (Ideal A) := { }
/-- For ideals in a Dedekind domain, to divide is to contain. -/
theorem Ideal.dvd_iff_le {I J : Ideal A} : I ∣ J ↔ J ≤ I :=
⟨Ideal.le_of_dvd, fun h => by
by_cases hI : I = ⊥
· have hJ : J = ⊥ := by rwa [hI, ← eq_bot_iff] at h
rw [hI, hJ]
have hI' : (I : FractionalIdeal A⁰ (FractionRing A)) ≠ 0 := coeIdeal_ne_zero.mpr hI
have : (I : FractionalIdeal A⁰ (FractionRing A))⁻¹ * J ≤ 1 := by
rw [← inv_mul_cancel₀ hI']
exact mul_left_mono _ ((coeIdeal_le_coeIdeal _).mpr h)
obtain ⟨H, hH⟩ := le_one_iff_exists_coeIdeal.mp this
use H
refine coeIdeal_injective (show (J : FractionalIdeal A⁰ (FractionRing A)) = ↑(I * H) from ?_)
rw [coeIdeal_mul, hH, ← mul_assoc, mul_inv_cancel₀ hI', one_mul]⟩
theorem Ideal.dvdNotUnit_iff_lt {I J : Ideal A} : DvdNotUnit I J ↔ J < I :=
⟨fun ⟨hI, H, hunit, hmul⟩ =>
lt_of_le_of_ne (Ideal.dvd_iff_le.mp ⟨H, hmul⟩)
(mt
(fun h =>
have : H = 1 := mul_left_cancel₀ hI (by rw [← hmul, h, mul_one])
show IsUnit H from this.symm ▸ isUnit_one)
hunit),
fun h =>
dvdNotUnit_of_dvd_of_not_dvd (Ideal.dvd_iff_le.mpr (le_of_lt h))
(mt Ideal.dvd_iff_le.mp (not_le_of_lt h))⟩
instance : WfDvdMonoid (Ideal A) where
wf := by
have : WellFoundedGT (Ideal A) := inferInstance
convert this.wf
ext
rw [Ideal.dvdNotUnit_iff_lt]
instance Ideal.uniqueFactorizationMonoid : UniqueFactorizationMonoid (Ideal A) :=
{ irreducible_iff_prime := by
intro P
exact ⟨fun hirr => ⟨hirr.ne_zero, hirr.not_isUnit, fun I J => by
have : P.IsMaximal := by
refine ⟨⟨mt Ideal.isUnit_iff.mpr hirr.not_isUnit, ?_⟩⟩
intro J hJ
obtain ⟨_J_ne, H, hunit, P_eq⟩ := Ideal.dvdNotUnit_iff_lt.mpr hJ
exact Ideal.isUnit_iff.mp ((hirr.isUnit_or_isUnit P_eq).resolve_right hunit)
rw [Ideal.dvd_iff_le, Ideal.dvd_iff_le, Ideal.dvd_iff_le, SetLike.le_def, SetLike.le_def,
SetLike.le_def]
contrapose!
rintro ⟨⟨x, x_mem, x_not_mem⟩, ⟨y, y_mem, y_not_mem⟩⟩
exact
⟨x * y, Ideal.mul_mem_mul x_mem y_mem,
mt this.isPrime.mem_or_mem (not_or_intro x_not_mem y_not_mem)⟩⟩, Prime.irreducible⟩ }
instance Ideal.normalizationMonoid : NormalizationMonoid (Ideal A) := .ofUniqueUnits
@[simp]
theorem Ideal.dvd_span_singleton {I : Ideal A} {x : A} : I ∣ Ideal.span {x} ↔ x ∈ I :=
Ideal.dvd_iff_le.trans (Ideal.span_le.trans Set.singleton_subset_iff)
theorem Ideal.isPrime_of_prime {P : Ideal A} (h : Prime P) : IsPrime P := by
refine ⟨?_, fun hxy => ?_⟩
· rintro rfl
rw [← Ideal.one_eq_top] at h
exact h.not_unit isUnit_one
· simp only [← Ideal.dvd_span_singleton, ← Ideal.span_singleton_mul_span_singleton] at hxy ⊢
exact h.dvd_or_dvd hxy
theorem Ideal.prime_of_isPrime {P : Ideal A} (hP : P ≠ ⊥) (h : IsPrime P) : Prime P := by
refine ⟨hP, mt Ideal.isUnit_iff.mp h.ne_top, fun I J hIJ => ?_⟩
simpa only [Ideal.dvd_iff_le] using h.mul_le.mp (Ideal.le_of_dvd hIJ)
/-- In a Dedekind domain, the (nonzero) prime elements of the monoid with zero `Ideal A`
are exactly the prime ideals. -/
theorem Ideal.prime_iff_isPrime {P : Ideal A} (hP : P ≠ ⊥) : Prime P ↔ IsPrime P :=
⟨Ideal.isPrime_of_prime, Ideal.prime_of_isPrime hP⟩
/-- In a Dedekind domain, the prime ideals are the zero ideal together with the prime elements
of the monoid with zero `Ideal A`. -/
theorem Ideal.isPrime_iff_bot_or_prime {P : Ideal A} : IsPrime P ↔ P = ⊥ ∨ Prime P :=
⟨fun hp => (eq_or_ne P ⊥).imp_right fun hp0 => Ideal.prime_of_isPrime hp0 hp, fun hp =>
hp.elim (fun h => h.symm ▸ Ideal.bot_prime) Ideal.isPrime_of_prime⟩
@[simp]
theorem Ideal.prime_span_singleton_iff {a : A} : Prime (Ideal.span {a}) ↔ Prime a := by
rcases eq_or_ne a 0 with rfl | ha
· rw [Set.singleton_zero, span_zero, ← Ideal.zero_eq_bot, ← not_iff_not]
simp only [not_prime_zero, not_false_eq_true]
· have ha' : span {a} ≠ ⊥ := by simpa only [ne_eq, span_singleton_eq_bot] using ha
rw [Ideal.prime_iff_isPrime ha', Ideal.span_singleton_prime ha]
open Submodule.IsPrincipal in
theorem Ideal.prime_generator_of_prime {P : Ideal A} (h : Prime P) [P.IsPrincipal] :
Prime (generator P) :=
have : Ideal.IsPrime P := Ideal.isPrime_of_prime h
prime_generator_of_isPrime _ h.ne_zero
open UniqueFactorizationMonoid in
nonrec theorem Ideal.mem_normalizedFactors_iff {p I : Ideal A} (hI : I ≠ ⊥) :
p ∈ normalizedFactors I ↔ p.IsPrime ∧ I ≤ p := by
rw [← Ideal.dvd_iff_le]
by_cases hp : p = 0
· rw [← zero_eq_bot] at hI
simp only [hp, zero_not_mem_normalizedFactors, zero_dvd_iff, hI, false_iff, not_and,
not_false_eq_true, implies_true]
· rwa [mem_normalizedFactors_iff hI, prime_iff_isPrime]
theorem Ideal.pow_right_strictAnti (I : Ideal A) (hI0 : I ≠ ⊥) (hI1 : I ≠ ⊤) :
StrictAnti (I ^ · : ℕ → Ideal A) :=
strictAnti_nat_of_succ_lt fun e =>
Ideal.dvdNotUnit_iff_lt.mp ⟨pow_ne_zero _ hI0, I, mt isUnit_iff.mp hI1, pow_succ I e⟩
theorem Ideal.pow_lt_self (I : Ideal A) (hI0 : I ≠ ⊥) (hI1 : I ≠ ⊤) (e : ℕ) (he : 2 ≤ e) :
I ^ e < I := by
convert I.pow_right_strictAnti hI0 hI1 he
dsimp only
rw [pow_one]
theorem Ideal.exists_mem_pow_not_mem_pow_succ (I : Ideal A) (hI0 : I ≠ ⊥) (hI1 : I ≠ ⊤) (e : ℕ) :
∃ x ∈ I ^ e, x ∉ I ^ (e + 1) :=
SetLike.exists_of_lt (I.pow_right_strictAnti hI0 hI1 e.lt_succ_self)
open UniqueFactorizationMonoid
theorem Ideal.eq_prime_pow_of_succ_lt_of_le {P I : Ideal A} [P_prime : P.IsPrime] (hP : P ≠ ⊥)
{i : ℕ} (hlt : P ^ (i + 1) < I) (hle : I ≤ P ^ i) : I = P ^ i := by
refine le_antisymm hle ?_
have P_prime' := Ideal.prime_of_isPrime hP P_prime
have h1 : I ≠ ⊥ := (lt_of_le_of_lt bot_le hlt).ne'
have := pow_ne_zero i hP
have h3 := pow_ne_zero (i + 1) hP
rw [← Ideal.dvdNotUnit_iff_lt, dvdNotUnit_iff_normalizedFactors_lt_normalizedFactors h1 h3,
normalizedFactors_pow, normalizedFactors_irreducible P_prime'.irreducible,
Multiset.nsmul_singleton, Multiset.lt_replicate_succ] at hlt
rw [← Ideal.dvd_iff_le, dvd_iff_normalizedFactors_le_normalizedFactors, normalizedFactors_pow,
normalizedFactors_irreducible P_prime'.irreducible, Multiset.nsmul_singleton]
all_goals assumption
theorem Ideal.pow_succ_lt_pow {P : Ideal A} [P_prime : P.IsPrime] (hP : P ≠ ⊥) (i : ℕ) :
P ^ (i + 1) < P ^ i :=
lt_of_le_of_ne (Ideal.pow_le_pow_right (Nat.le_succ _))
(mt (pow_inj_of_not_isUnit (mt Ideal.isUnit_iff.mp P_prime.ne_top) hP).mp i.succ_ne_self)
theorem Associates.le_singleton_iff (x : A) (n : ℕ) (I : Ideal A) :
Associates.mk I ^ n ≤ Associates.mk (Ideal.span {x}) ↔ x ∈ I ^ n := by
simp_rw [← Associates.dvd_eq_le, ← Associates.mk_pow, Associates.mk_dvd_mk,
Ideal.dvd_span_singleton]
variable {K}
lemma FractionalIdeal.le_inv_comm {I J : FractionalIdeal A⁰ K} (hI : I ≠ 0) (hJ : J ≠ 0) :
I ≤ J⁻¹ ↔ J ≤ I⁻¹ := by
rw [inv_eq, inv_eq, le_div_iff_mul_le hI, le_div_iff_mul_le hJ, mul_comm]
lemma FractionalIdeal.inv_le_comm {I J : FractionalIdeal A⁰ K} (hI : I ≠ 0) (hJ : J ≠ 0) :
I⁻¹ ≤ J ↔ J⁻¹ ≤ I := by
simpa using le_inv_comm (A := A) (K := K) (inv_ne_zero hI) (inv_ne_zero hJ)
open FractionalIdeal
/-- Strengthening of `IsLocalization.exist_integer_multiples`:
Let `J ≠ ⊤` be an ideal in a Dedekind domain `A`, and `f ≠ 0` a finite collection
of elements of `K = Frac(A)`, then we can multiply the elements of `f` by some `a : K`
to find a collection of elements of `A` that is not completely contained in `J`. -/
theorem Ideal.exist_integer_multiples_not_mem {J : Ideal A} (hJ : J ≠ ⊤) {ι : Type*} (s : Finset ι)
(f : ι → K) {j} (hjs : j ∈ s) (hjf : f j ≠ 0) :
∃ a : K,
(∀ i ∈ s, IsLocalization.IsInteger A (a * f i)) ∧
∃ i ∈ s, a * f i ∉ (J : FractionalIdeal A⁰ K) := by
-- Consider the fractional ideal `I` spanned by the `f`s.
let I : FractionalIdeal A⁰ K := spanFinset A s f
have hI0 : I ≠ 0 := spanFinset_ne_zero.mpr ⟨j, hjs, hjf⟩
-- We claim the multiplier `a` we're looking for is in `I⁻¹ \ (J / I)`.
suffices ↑J / I < I⁻¹ by
obtain ⟨_, a, hI, hpI⟩ := SetLike.lt_iff_le_and_exists.mp this
rw [mem_inv_iff hI0] at hI
refine ⟨a, fun i hi => ?_, ?_⟩
-- By definition, `a ∈ I⁻¹` multiplies elements of `I` into elements of `1`,
-- in other words, `a * f i` is an integer.
· exact (mem_one_iff _).mp (hI (f i) (Submodule.subset_span (Set.mem_image_of_mem f hi)))
· contrapose! hpI
-- And if all `a`-multiples of `I` are an element of `J`,
-- then `a` is actually an element of `J / I`, contradiction.
refine (mem_div_iff_of_nonzero hI0).mpr fun y hy => Submodule.span_induction ?_ ?_ ?_ ?_ hy
· rintro _ ⟨i, hi, rfl⟩; exact hpI i hi
· rw [mul_zero]; exact Submodule.zero_mem _
· intro x y _ _ hx hy; rw [mul_add]; exact Submodule.add_mem _ hx hy
· intro b x _ hx; rw [mul_smul_comm]; exact Submodule.smul_mem _ b hx
-- To show the inclusion of `J / I` into `I⁻¹ = 1 / I`, note that `J < I`.
calc
↑J / I = ↑J * I⁻¹ := div_eq_mul_inv (↑J) I
_ < 1 * I⁻¹ := mul_right_strictMono (inv_ne_zero hI0) ?_
_ = I⁻¹ := one_mul _
rw [← coeIdeal_top]
-- And multiplying by `I⁻¹` is indeed strictly monotone.
exact
strictMono_of_le_iff_le (fun _ _ => (coeIdeal_le_coeIdeal K).symm)
(lt_top_iff_ne_top.mpr hJ)
section Gcd
namespace Ideal
/-! ### GCD and LCM of ideals in a Dedekind domain
We show that the gcd of two ideals in a Dedekind domain is just their supremum,
and the lcm is their infimum, and use this to instantiate `NormalizedGCDMonoid (Ideal A)`.
-/
@[simp]
theorem sup_mul_inf (I J : Ideal A) : (I ⊔ J) * (I ⊓ J) = I * J := by
letI := UniqueFactorizationMonoid.toNormalizedGCDMonoid (Ideal A)
have hgcd : gcd I J = I ⊔ J := by
rw [gcd_eq_normalize _ _, normalize_eq]
· rw [dvd_iff_le, sup_le_iff, ← dvd_iff_le, ← dvd_iff_le]
exact ⟨gcd_dvd_left _ _, gcd_dvd_right _ _⟩
· rw [dvd_gcd_iff, dvd_iff_le, dvd_iff_le]
simp
have hlcm : lcm I J = I ⊓ J := by
rw [lcm_eq_normalize _ _, normalize_eq]
· rw [lcm_dvd_iff, dvd_iff_le, dvd_iff_le]
simp
· rw [dvd_iff_le, le_inf_iff, ← dvd_iff_le, ← dvd_iff_le]
exact ⟨dvd_lcm_left _ _, dvd_lcm_right _ _⟩
rw [← hgcd, ← hlcm, associated_iff_eq.mp (gcd_mul_lcm _ _)]
/-- Ideals in a Dedekind domain have gcd and lcm operators that (trivially) are compatible with
the normalization operator. -/
instance : NormalizedGCDMonoid (Ideal A) :=
{ Ideal.normalizationMonoid with
gcd := (· ⊔ ·)
gcd_dvd_left := fun _ _ => by simpa only [dvd_iff_le] using le_sup_left
gcd_dvd_right := fun _ _ => by simpa only [dvd_iff_le] using le_sup_right
dvd_gcd := by
simp only [dvd_iff_le]
exact fun h1 h2 => @sup_le (Ideal A) _ _ _ _ h1 h2
lcm := (· ⊓ ·)
lcm_zero_left := fun _ => by simp only [zero_eq_bot, bot_inf_eq]
lcm_zero_right := fun _ => by simp only [zero_eq_bot, inf_bot_eq]
gcd_mul_lcm := fun _ _ => by rw [associated_iff_eq, sup_mul_inf]
normalize_gcd := fun _ _ => normalize_eq _
normalize_lcm := fun _ _ => normalize_eq _ }
-- In fact, any lawful gcd and lcm would equal sup and inf respectively.
@[simp]
theorem gcd_eq_sup (I J : Ideal A) : gcd I J = I ⊔ J := rfl
@[simp]
theorem lcm_eq_inf (I J : Ideal A) : lcm I J = I ⊓ J := rfl
theorem isCoprime_iff_gcd {I J : Ideal A} : IsCoprime I J ↔ gcd I J = 1 := by
rw [Ideal.isCoprime_iff_codisjoint, codisjoint_iff, one_eq_top, gcd_eq_sup]
theorem factors_span_eq {p : K[X]} : factors (span {p}) = (factors p).map (fun q ↦ span {q}) := by
rcases eq_or_ne p 0 with rfl | hp; · simpa [Set.singleton_zero] using normalizedFactors_zero
have : ∀ q ∈ (factors p).map (fun q ↦ span {q}), Prime q := fun q hq ↦ by
obtain ⟨r, hr, rfl⟩ := Multiset.mem_map.mp hq
exact prime_span_singleton_iff.mpr <| prime_of_factor r hr
rw [← span_singleton_eq_span_singleton.mpr (factors_prod hp), ← multiset_prod_span_singleton,
factors_eq_normalizedFactors, normalizedFactors_prod_of_prime this]
end Ideal
end Gcd
end IsDedekindDomain
section IsDedekindDomain
variable {T : Type*} [CommRing T] [IsDedekindDomain T] {I J : Ideal T}
open Multiset UniqueFactorizationMonoid Ideal
theorem prod_normalizedFactors_eq_self (hI : I ≠ ⊥) : (normalizedFactors I).prod = I :=
associated_iff_eq.1 (prod_normalizedFactors hI)
theorem count_le_of_ideal_ge [DecidableEq (Ideal T)]
{I J : Ideal T} (h : I ≤ J) (hI : I ≠ ⊥) (K : Ideal T) :
count K (normalizedFactors J) ≤ count K (normalizedFactors I) :=
le_iff_count.1 ((dvd_iff_normalizedFactors_le_normalizedFactors (ne_bot_of_le_ne_bot hI h) hI).1
(dvd_iff_le.2 h))
_
theorem sup_eq_prod_inf_factors [DecidableEq (Ideal T)] (hI : I ≠ ⊥) (hJ : J ≠ ⊥) :
I ⊔ J = (normalizedFactors I ∩ normalizedFactors J).prod := by
have H : normalizedFactors (normalizedFactors I ∩ normalizedFactors J).prod =
normalizedFactors I ∩ normalizedFactors J := by
apply normalizedFactors_prod_of_prime
intro p hp
rw [mem_inter] at hp
exact prime_of_normalized_factor p hp.left
have := Multiset.prod_ne_zero_of_prime (normalizedFactors I ∩ normalizedFactors J) fun _ h =>
prime_of_normalized_factor _ (Multiset.mem_inter.1 h).1
apply le_antisymm
· rw [sup_le_iff, ← dvd_iff_le, ← dvd_iff_le]
constructor
· rw [dvd_iff_normalizedFactors_le_normalizedFactors this hI, H]
exact inf_le_left
· rw [dvd_iff_normalizedFactors_le_normalizedFactors this hJ, H]
exact inf_le_right
· rw [← dvd_iff_le, dvd_iff_normalizedFactors_le_normalizedFactors,
normalizedFactors_prod_of_prime, le_iff_count]
· intro a
rw [Multiset.count_inter]
exact le_min (count_le_of_ideal_ge le_sup_left hI a) (count_le_of_ideal_ge le_sup_right hJ a)
· intro p hp
rw [mem_inter] at hp
exact prime_of_normalized_factor p hp.left
· exact ne_bot_of_le_ne_bot hI le_sup_left
· exact this
theorem irreducible_pow_sup [DecidableEq (Ideal T)] (hI : I ≠ ⊥) (hJ : Irreducible J) (n : ℕ) :
J ^ n ⊔ I = J ^ min ((normalizedFactors I).count J) n := by
rw [sup_eq_prod_inf_factors (pow_ne_zero n hJ.ne_zero) hI, min_comm,
normalizedFactors_of_irreducible_pow hJ, normalize_eq J, replicate_inter, prod_replicate]
theorem irreducible_pow_sup_of_le (hJ : Irreducible J) (n : ℕ) (hn : n ≤ emultiplicity J I) :
J ^ n ⊔ I = J ^ n := by
classical
by_cases hI : I = ⊥
· simp_all
rw [irreducible_pow_sup hI hJ, min_eq_right]
rw [emultiplicity_eq_count_normalizedFactors hJ hI, normalize_eq J] at hn
exact_mod_cast hn
theorem irreducible_pow_sup_of_ge (hI : I ≠ ⊥) (hJ : Irreducible J) (n : ℕ)
(hn : emultiplicity J I ≤ n) : J ^ n ⊔ I = J ^ multiplicity J I := by
classical
rw [irreducible_pow_sup hI hJ, min_eq_left]
· congr
rw [← Nat.cast_inj (R := ℕ∞), ← FiniteMultiplicity.emultiplicity_eq_multiplicity,
emultiplicity_eq_count_normalizedFactors hJ hI, normalize_eq J]
rw [← emultiplicity_lt_top]
apply hn.trans_lt
simp
· rw [emultiplicity_eq_count_normalizedFactors hJ hI, normalize_eq J] at hn
exact_mod_cast hn
theorem Ideal.eq_prime_pow_mul_coprime [DecidableEq (Ideal T)] {I : Ideal T} (hI : I ≠ ⊥)
(P : Ideal T) [hpm : P.IsMaximal] :
∃ Q : Ideal T, P ⊔ Q = ⊤ ∧ I = P ^ (Multiset.count P (normalizedFactors I)) * Q := by
use (filter (¬ P = ·) (normalizedFactors I)).prod
constructor
· refine P.sup_multiset_prod_eq_top (fun p hpi ↦ ?_)
have hp : Prime p := prime_of_normalized_factor p (filter_subset _ (normalizedFactors I) hpi)
exact hpm.coprime_of_ne ((isPrime_of_prime hp).isMaximal hp.ne_zero) (of_mem_filter hpi)
· nth_rw 1 [← prod_normalizedFactors_eq_self hI, ← filter_add_not (P = ·) (normalizedFactors I)]
rw [prod_add, pow_count]
end IsDedekindDomain
/-!
### Height one spectrum of a Dedekind domain
If `R` is a Dedekind domain of Krull dimension 1, the maximal ideals of `R` are exactly its nonzero
prime ideals.
We define `HeightOneSpectrum` and provide lemmas to recover the facts that prime ideals of height
one are prime and irreducible.
-/
namespace IsDedekindDomain
variable [IsDedekindDomain R]
/-- The height one prime spectrum of a Dedekind domain `R` is the type of nonzero prime ideals of
`R`. Note that this equals the maximal spectrum if `R` has Krull dimension 1. -/
@[ext, nolint unusedArguments]
structure HeightOneSpectrum where
asIdeal : Ideal R
isPrime : asIdeal.IsPrime
ne_bot : asIdeal ≠ ⊥
attribute [instance] HeightOneSpectrum.isPrime
variable (v : HeightOneSpectrum R) {R}
namespace HeightOneSpectrum
instance isMaximal : v.asIdeal.IsMaximal := v.isPrime.isMaximal v.ne_bot
theorem prime : Prime v.asIdeal := Ideal.prime_of_isPrime v.ne_bot v.isPrime
theorem irreducible : Irreducible v.asIdeal :=
UniqueFactorizationMonoid.irreducible_iff_prime.mpr v.prime
theorem associates_irreducible : Irreducible <| Associates.mk v.asIdeal :=
Associates.irreducible_mk.mpr v.irreducible
/-- An equivalence between the height one and maximal spectra for rings of Krull dimension 1. -/
def equivMaximalSpectrum (hR : ¬IsField R) : HeightOneSpectrum R ≃ MaximalSpectrum R where
toFun v := ⟨v.asIdeal, v.isPrime.isMaximal v.ne_bot⟩
invFun v :=
⟨v.asIdeal, v.isMaximal.isPrime, Ring.ne_bot_of_isMaximal_of_not_isField v.isMaximal hR⟩
left_inv := fun ⟨_, _, _⟩ => rfl
right_inv := fun ⟨_, _⟩ => rfl
variable (R)
/-- A Dedekind domain is equal to the intersection of its localizations at all its height one
non-zero prime ideals viewed as subalgebras of its field of fractions. -/
theorem iInf_localization_eq_bot [Algebra R K] [hK : IsFractionRing R K] :
(⨅ v : HeightOneSpectrum R,
Localization.subalgebra.ofField K _ v.asIdeal.primeCompl_le_nonZeroDivisors) = ⊥ := by
ext x
rw [Algebra.mem_iInf]
constructor
on_goal 1 => by_cases hR : IsField R
· rcases Function.bijective_iff_has_inverse.mp
(IsField.localization_map_bijective (Rₘ := K) (flip nonZeroDivisors.ne_zero rfl : 0 ∉ R⁰) hR)
with ⟨algebra_map_inv, _, algebra_map_right_inv⟩
exact fun _ => Algebra.mem_bot.mpr ⟨algebra_map_inv x, algebra_map_right_inv x⟩
all_goals rw [← MaximalSpectrum.iInf_localization_eq_bot, Algebra.mem_iInf]
· exact fun hx ⟨v, hv⟩ => hx ((equivMaximalSpectrum hR).symm ⟨v, hv⟩)
· exact fun hx ⟨v, hv, hbot⟩ => hx ⟨v, hv.isMaximal hbot⟩
end HeightOneSpectrum
end IsDedekindDomain
section
open Ideal
variable {R A}
variable [IsDedekindDomain A] {I : Ideal R} {J : Ideal A}
/-- The map from ideals of `R` dividing `I` to the ideals of `A` dividing `J` induced by
a homomorphism `f : R/I →+* A/J` -/
@[simps] -- Porting note: use `Subtype` instead of `Set` to make linter happy
def idealFactorsFunOfQuotHom {f : R ⧸ I →+* A ⧸ J} (hf : Function.Surjective f) :
{p : Ideal R // p ∣ I} →o {p : Ideal A // p ∣ J} where
toFun X := ⟨comap (Ideal.Quotient.mk J) (map f (map (Ideal.Quotient.mk I) X)), by
have : RingHom.ker (Ideal.Quotient.mk J) ≤
comap (Ideal.Quotient.mk J) (map f (map (Ideal.Quotient.mk I) X)) :=
ker_le_comap (Ideal.Quotient.mk J)
rw [mk_ker] at this
exact dvd_iff_le.mpr this⟩
monotone' := by
rintro ⟨X, hX⟩ ⟨Y, hY⟩ h
rw [← Subtype.coe_le_coe, Subtype.coe_mk, Subtype.coe_mk] at h ⊢
rw [Subtype.coe_mk, comap_le_comap_iff_of_surjective (Ideal.Quotient.mk J)
Ideal.Quotient.mk_surjective, map_le_iff_le_comap, Subtype.coe_mk,
comap_map_of_surjective _ hf (map (Ideal.Quotient.mk I) Y)]
suffices map (Ideal.Quotient.mk I) X ≤ map (Ideal.Quotient.mk I) Y by
exact le_sup_of_le_left this
rwa [map_le_iff_le_comap, comap_map_of_surjective (Ideal.Quotient.mk I)
Ideal.Quotient.mk_surjective, ← RingHom.ker_eq_comap_bot, mk_ker,
sup_eq_left.mpr <| le_of_dvd hY]
@[simp]
theorem idealFactorsFunOfQuotHom_id :
idealFactorsFunOfQuotHom (RingHom.id (A ⧸ J)).surjective = OrderHom.id :=
OrderHom.ext _ _
(funext fun X => by
simp only [idealFactorsFunOfQuotHom, map_id, OrderHom.coe_mk, OrderHom.id_coe, id,
comap_map_of_surjective (Ideal.Quotient.mk J) Ideal.Quotient.mk_surjective, ←
RingHom.ker_eq_comap_bot (Ideal.Quotient.mk J), mk_ker,
sup_eq_left.mpr (dvd_iff_le.mp X.prop), Subtype.coe_eta])
variable {B : Type*} [CommRing B] [IsDedekindDomain B] {L : Ideal B}
theorem idealFactorsFunOfQuotHom_comp {f : R ⧸ I →+* A ⧸ J} {g : A ⧸ J →+* B ⧸ L}
(hf : Function.Surjective f) (hg : Function.Surjective g) :
(idealFactorsFunOfQuotHom hg).comp (idealFactorsFunOfQuotHom hf) =
idealFactorsFunOfQuotHom (show Function.Surjective (g.comp f) from hg.comp hf) := by
refine OrderHom.ext _ _ (funext fun x => ?_)
rw [idealFactorsFunOfQuotHom, idealFactorsFunOfQuotHom, OrderHom.comp_coe, OrderHom.coe_mk,
OrderHom.coe_mk, Function.comp_apply, idealFactorsFunOfQuotHom, OrderHom.coe_mk,
Subtype.mk_eq_mk, Subtype.coe_mk, map_comap_of_surjective (Ideal.Quotient.mk J)
Ideal.Quotient.mk_surjective, map_map]
variable [IsDedekindDomain R] (f : R ⧸ I ≃+* A ⧸ J)
/-- The bijection between ideals of `R` dividing `I` and the ideals of `A` dividing `J` induced by
an isomorphism `f : R/I ≅ A/J`. -/
def idealFactorsEquivOfQuotEquiv : { p : Ideal R | p ∣ I } ≃o { p : Ideal A | p ∣ J } := by
have f_surj : Function.Surjective (f : R ⧸ I →+* A ⧸ J) := f.surjective
have fsym_surj : Function.Surjective (f.symm : A ⧸ J →+* R ⧸ I) := f.symm.surjective
refine OrderIso.ofHomInv (idealFactorsFunOfQuotHom f_surj) (idealFactorsFunOfQuotHom fsym_surj)
?_ ?_
· have := idealFactorsFunOfQuotHom_comp fsym_surj f_surj
simp only [RingEquiv.comp_symm, idealFactorsFunOfQuotHom_id] at this
rw [← this, OrderHom.coe_eq, OrderHom.coe_eq]
· have := idealFactorsFunOfQuotHom_comp f_surj fsym_surj
simp only [RingEquiv.symm_comp, idealFactorsFunOfQuotHom_id] at this
rw [← this, OrderHom.coe_eq, OrderHom.coe_eq]
theorem idealFactorsEquivOfQuotEquiv_symm :
(idealFactorsEquivOfQuotEquiv f).symm = idealFactorsEquivOfQuotEquiv f.symm := rfl
theorem idealFactorsEquivOfQuotEquiv_is_dvd_iso {L M : Ideal R} (hL : L ∣ I) (hM : M ∣ I) :
(idealFactorsEquivOfQuotEquiv f ⟨L, hL⟩ : Ideal A) ∣ idealFactorsEquivOfQuotEquiv f ⟨M, hM⟩ ↔
L ∣ M := by
suffices
idealFactorsEquivOfQuotEquiv f ⟨M, hM⟩ ≤ idealFactorsEquivOfQuotEquiv f ⟨L, hL⟩ ↔
(⟨M, hM⟩ : { p : Ideal R | p ∣ I }) ≤ ⟨L, hL⟩
by rw [dvd_iff_le, dvd_iff_le, Subtype.coe_le_coe, this, Subtype.mk_le_mk]
exact (idealFactorsEquivOfQuotEquiv f).le_iff_le
open UniqueFactorizationMonoid
theorem idealFactorsEquivOfQuotEquiv_mem_normalizedFactors_of_mem_normalizedFactors (hJ : J ≠ ⊥)
{L : Ideal R} (hL : L ∈ normalizedFactors I) :
↑(idealFactorsEquivOfQuotEquiv f ⟨L, dvd_of_mem_normalizedFactors hL⟩)
∈ normalizedFactors J := by
have hI : I ≠ ⊥ := by
intro hI
rw [hI, bot_eq_zero, normalizedFactors_zero, ← Multiset.empty_eq_zero] at hL
exact Finset.not_mem_empty _ hL
refine mem_normalizedFactors_factor_dvd_iso_of_mem_normalizedFactors hI hJ hL
(d := (idealFactorsEquivOfQuotEquiv f).toEquiv) ?_
rintro ⟨l, hl⟩ ⟨l', hl'⟩
rw [Subtype.coe_mk, Subtype.coe_mk]
apply idealFactorsEquivOfQuotEquiv_is_dvd_iso f
/-- The bijection between the sets of normalized factors of I and J induced by a ring
isomorphism `f : R/I ≅ A/J`. -/
def normalizedFactorsEquivOfQuotEquiv (hI : I ≠ ⊥) (hJ : J ≠ ⊥) :
{ L : Ideal R | L ∈ normalizedFactors I } ≃ { M : Ideal A | M ∈ normalizedFactors J } where
toFun j :=
⟨idealFactorsEquivOfQuotEquiv f ⟨↑j, dvd_of_mem_normalizedFactors j.prop⟩,
idealFactorsEquivOfQuotEquiv_mem_normalizedFactors_of_mem_normalizedFactors f hJ j.prop⟩
invFun j :=
⟨(idealFactorsEquivOfQuotEquiv f).symm ⟨↑j, dvd_of_mem_normalizedFactors j.prop⟩, by
rw [idealFactorsEquivOfQuotEquiv_symm]
exact
idealFactorsEquivOfQuotEquiv_mem_normalizedFactors_of_mem_normalizedFactors f.symm hI
j.prop⟩
left_inv := fun ⟨j, hj⟩ => by simp
right_inv := fun ⟨j, hj⟩ => by simp [-Set.coe_setOf]
@[simp]
theorem normalizedFactorsEquivOfQuotEquiv_symm (hI : I ≠ ⊥) (hJ : J ≠ ⊥) :
(normalizedFactorsEquivOfQuotEquiv f hI hJ).symm =
normalizedFactorsEquivOfQuotEquiv f.symm hJ hI := rfl
/-- The map `normalizedFactorsEquivOfQuotEquiv` preserves multiplicities. -/
theorem normalizedFactorsEquivOfQuotEquiv_emultiplicity_eq_emultiplicity (hI : I ≠ ⊥) (hJ : J ≠ ⊥)
(L : Ideal R) (hL : L ∈ normalizedFactors I) :
emultiplicity (↑(normalizedFactorsEquivOfQuotEquiv f hI hJ ⟨L, hL⟩)) J = emultiplicity L I := by
rw [normalizedFactorsEquivOfQuotEquiv, Equiv.coe_fn_mk, Subtype.coe_mk]
refine emultiplicity_factor_dvd_iso_eq_emultiplicity_of_mem_normalizedFactors hI hJ hL
(d := (idealFactorsEquivOfQuotEquiv f).toEquiv) ?_
exact fun ⟨l, hl⟩ ⟨l', hl'⟩ => idealFactorsEquivOfQuotEquiv_is_dvd_iso f hl hl'
end
section ChineseRemainder
open Ideal UniqueFactorizationMonoid
variable {R}
theorem Ring.DimensionLeOne.prime_le_prime_iff_eq [Ring.DimensionLEOne R] {P Q : Ideal R}
[hP : P.IsPrime] [hQ : Q.IsPrime] (hP0 : P ≠ ⊥) : P ≤ Q ↔ P = Q :=
⟨(hP.isMaximal hP0).eq_of_le hQ.ne_top, Eq.le⟩
theorem Ideal.coprime_of_no_prime_ge {I J : Ideal R} (h : ∀ P, I ≤ P → J ≤ P → ¬IsPrime P) :
IsCoprime I J := by
rw [isCoprime_iff_sup_eq]
by_contra hIJ
obtain ⟨P, hP, hIJ⟩ := Ideal.exists_le_maximal _ hIJ
exact h P (le_trans le_sup_left hIJ) (le_trans le_sup_right hIJ) hP.isPrime
section DedekindDomain
variable [IsDedekindDomain R]
theorem Ideal.IsPrime.mul_mem_pow (I : Ideal R) [hI : I.IsPrime] {a b : R} {n : ℕ}
(h : a * b ∈ I ^ n) : a ∈ I ∨ b ∈ I ^ n := by
cases n; · simp
by_cases hI0 : I = ⊥; · simpa [pow_succ, hI0] using h
simp only [← Submodule.span_singleton_le_iff_mem, Ideal.submodule_span_eq, ← Ideal.dvd_iff_le, ←
Ideal.span_singleton_mul_span_singleton] at h ⊢
by_cases ha : I ∣ span {a}
· exact Or.inl ha
rw [mul_comm] at h
exact Or.inr (Prime.pow_dvd_of_dvd_mul_right ((Ideal.prime_iff_isPrime hI0).mpr hI) _ ha h)
theorem Ideal.IsPrime.mem_pow_mul (I : Ideal R) [hI : I.IsPrime] {a b : R} {n : ℕ}
(h : a * b ∈ I ^ n) : a ∈ I ^ n ∨ b ∈ I := by
rw [mul_comm] at h
rw [or_comm]
exact Ideal.IsPrime.mul_mem_pow _ h
section
theorem Ideal.count_normalizedFactors_eq {p x : Ideal R} [hp : p.IsPrime] {n : ℕ} (hle : x ≤ p ^ n)
[DecidableEq (Ideal R)] (hlt : ¬x ≤ p ^ (n + 1)) : (normalizedFactors x).count p = n :=
count_normalizedFactors_eq' ((Ideal.isPrime_iff_bot_or_prime.mp hp).imp_right Prime.irreducible)
(normalize_eq _) (Ideal.dvd_iff_le.mpr hle) (mt Ideal.le_of_dvd hlt)
/-- The number of times an ideal `I` occurs as normalized factor of another ideal `J` is stable
when regarding these ideals as associated elements of the monoid of ideals. -/
theorem count_associates_factors_eq [DecidableEq (Ideal R)] [DecidableEq <| Associates (Ideal R)]
[∀ (p : Associates <| Ideal R), Decidable (Irreducible p)]
{I J : Ideal R} (hI : I ≠ 0) (hJ : J.IsPrime) (hJ₀ : J ≠ ⊥) :
(Associates.mk J).count (Associates.mk I).factors = Multiset.count J (normalizedFactors I) := by
replace hI : Associates.mk I ≠ 0 := Associates.mk_ne_zero.mpr hI
have hJ' : Irreducible (Associates.mk J) := by
simpa only [Associates.irreducible_mk] using (Ideal.prime_of_isPrime hJ₀ hJ).irreducible
apply (Ideal.count_normalizedFactors_eq (p := J) (x := I) _ _).symm
all_goals
rw [← Ideal.dvd_iff_le, ← Associates.mk_dvd_mk, Associates.mk_pow]
simp only [Associates.dvd_eq_le]
rw [Associates.prime_pow_dvd_iff_le hI hJ']
omega
end
theorem Ideal.le_mul_of_no_prime_factors {I J K : Ideal R}
(coprime : ∀ P, J ≤ P → K ≤ P → ¬IsPrime P) (hJ : I ≤ J) (hK : I ≤ K) : I ≤ J * K := by
simp only [← Ideal.dvd_iff_le] at coprime hJ hK ⊢
by_cases hJ0 : J = 0
· simpa only [hJ0, zero_mul] using hJ
obtain ⟨I', rfl⟩ := hK
rw [mul_comm]
refine mul_dvd_mul_left K
(UniqueFactorizationMonoid.dvd_of_dvd_mul_right_of_no_prime_factors (b := K) hJ0 ?_ hJ)
exact fun hPJ hPK => mt Ideal.isPrime_of_prime (coprime _ hPJ hPK)
/-- The intersection of distinct prime powers in a Dedekind domain is the product of these
prime powers. -/
theorem IsDedekindDomain.inf_prime_pow_eq_prod {ι : Type*} (s : Finset ι) (f : ι → Ideal R)
(e : ι → ℕ) (prime : ∀ i ∈ s, Prime (f i))
(coprime : ∀ᵉ (i ∈ s) (j ∈ s), i ≠ j → f i ≠ f j) :
(s.inf fun i => f i ^ e i) = ∏ i ∈ s, f i ^ e i := by
letI := Classical.decEq ι
revert prime coprime
refine s.induction ?_ ?_
· simp
intro a s ha ih prime coprime
specialize
ih (fun i hi => prime i (Finset.mem_insert_of_mem hi)) fun i hi j hj =>
coprime i (Finset.mem_insert_of_mem hi) j (Finset.mem_insert_of_mem hj)
rw [Finset.inf_insert, Finset.prod_insert ha, ih]
refine le_antisymm (Ideal.le_mul_of_no_prime_factors ?_ inf_le_left inf_le_right) Ideal.mul_le_inf
intro P hPa hPs hPp
obtain ⟨b, hb, hPb⟩ := hPp.prod_le.mp hPs
haveI := Ideal.isPrime_of_prime (prime a (Finset.mem_insert_self a s))
haveI := Ideal.isPrime_of_prime (prime b (Finset.mem_insert_of_mem hb))
refine coprime a (Finset.mem_insert_self a s) b (Finset.mem_insert_of_mem hb) ?_ ?_
· exact (ne_of_mem_of_not_mem hb ha).symm
· refine ((Ring.DimensionLeOne.prime_le_prime_iff_eq ?_).mp (hPp.le_of_pow_le hPa)).trans
((Ring.DimensionLeOne.prime_le_prime_iff_eq ?_).mp (hPp.le_of_pow_le hPb)).symm
· exact (prime a (Finset.mem_insert_self a s)).ne_zero
· exact (prime b (Finset.mem_insert_of_mem hb)).ne_zero
/-- **Chinese remainder theorem** for a Dedekind domain: if the ideal `I` factors as
`∏ i, P i ^ e i`, then `R ⧸ I` factors as `Π i, R ⧸ (P i ^ e i)`. -/
noncomputable def IsDedekindDomain.quotientEquivPiOfProdEq {ι : Type*} [Fintype ι] (I : Ideal R)
(P : ι → Ideal R) (e : ι → ℕ) (prime : ∀ i, Prime (P i))
(coprime : Pairwise fun i j => P i ≠ P j)
(prod_eq : ∏ i, P i ^ e i = I) : R ⧸ I ≃+* ∀ i, R ⧸ P i ^ e i :=
(Ideal.quotEquivOfEq
(by
simp only [← prod_eq, Finset.inf_eq_iInf, Finset.mem_univ, ciInf_pos,
← IsDedekindDomain.inf_prime_pow_eq_prod _ _ _ (fun i _ => prime i)
(coprime.set_pairwise _)])).trans <|
Ideal.quotientInfRingEquivPiQuotient _ fun i j hij => Ideal.coprime_of_no_prime_ge <| by
intro P hPi hPj hPp
haveI := Ideal.isPrime_of_prime (prime i)
haveI := Ideal.isPrime_of_prime (prime j)
exact coprime hij <| ((Ring.DimensionLeOne.prime_le_prime_iff_eq (prime i).ne_zero).mp
(hPp.le_of_pow_le hPi)).trans <| Eq.symm <|
(Ring.DimensionLeOne.prime_le_prime_iff_eq (prime j).ne_zero).mp (hPp.le_of_pow_le hPj)
open scoped Classical in
/-- **Chinese remainder theorem** for a Dedekind domain: `R ⧸ I` factors as `Π i, R ⧸ (P i ^ e i)`,
where `P i` ranges over the prime factors of `I` and `e i` over the multiplicities. -/
noncomputable def IsDedekindDomain.quotientEquivPiFactors {I : Ideal R} (hI : I ≠ ⊥) :
R ⧸ I ≃+* ∀ P : (factors I).toFinset, R ⧸ (P : Ideal R) ^ (Multiset.count ↑P (factors I)) :=
IsDedekindDomain.quotientEquivPiOfProdEq _ _ _
(fun P : (factors I).toFinset => prime_of_factor _ (Multiset.mem_toFinset.mp P.prop))
(fun _ _ hij => Subtype.coe_injective.ne hij)
(calc
(∏ P : (factors I).toFinset, (P : Ideal R) ^ (factors I).count (P : Ideal R)) =
∏ P ∈ (factors I).toFinset, P ^ (factors I).count P :=
(factors I).toFinset.prod_coe_sort fun P => P ^ (factors I).count P
_ = ((factors I).map fun P => P).prod := (Finset.prod_multiset_map_count (factors I) id).symm
_ = (factors I).prod := by rw [Multiset.map_id']
_ = I := associated_iff_eq.mp (factors_prod hI)
)
@[simp]
theorem IsDedekindDomain.quotientEquivPiFactors_mk {I : Ideal R} (hI : I ≠ ⊥) (x : R) :
IsDedekindDomain.quotientEquivPiFactors hI (Ideal.Quotient.mk I x) = fun _P =>
Ideal.Quotient.mk _ x := rfl
/-- **Chinese remainder theorem** for a Dedekind domain: if the ideal `I` factors as
`∏ i ∈ s, P i ^ e i`, then `R ⧸ I` factors as `Π (i : s), R ⧸ (P i ^ e i)`.
This is a version of `IsDedekindDomain.quotientEquivPiOfProdEq` where we restrict
the product to a finite subset `s` of a potentially infinite indexing type `ι`.
-/
noncomputable def IsDedekindDomain.quotientEquivPiOfFinsetProdEq {ι : Type*} {s : Finset ι}
(I : Ideal R) (P : ι → Ideal R) (e : ι → ℕ) (prime : ∀ i ∈ s, Prime (P i))
(coprime : ∀ᵉ (i ∈ s) (j ∈ s), i ≠ j → P i ≠ P j)
(prod_eq : ∏ i ∈ s, P i ^ e i = I) : R ⧸ I ≃+* ∀ i : s, R ⧸ P i ^ e i :=
IsDedekindDomain.quotientEquivPiOfProdEq I (fun i : s => P i) (fun i : s => e i)
(fun i => prime i i.2) (fun i j h => coprime i i.2 j j.2 (Subtype.coe_injective.ne h))
(_root_.trans (Finset.prod_coe_sort s fun i => P i ^ e i) prod_eq)
/-- Corollary of the Chinese remainder theorem: given elements `x i : R / P i ^ e i`,
we can choose a representative `y : R` such that `y ≡ x i (mod P i ^ e i)`. -/
theorem IsDedekindDomain.exists_representative_mod_finset {ι : Type*} {s : Finset ι}
(P : ι → Ideal R) (e : ι → ℕ) (prime : ∀ i ∈ s, Prime (P i))
(coprime : ∀ᵉ (i ∈ s) (j ∈ s), i ≠ j → P i ≠ P j) (x : ∀ i : s, R ⧸ P i ^ e i) :
∃ y, ∀ (i) (hi : i ∈ s), Ideal.Quotient.mk (P i ^ e i) y = x ⟨i, hi⟩ := by
let f := IsDedekindDomain.quotientEquivPiOfFinsetProdEq _ P e prime coprime rfl
obtain ⟨y, rfl⟩ := f.surjective x
obtain ⟨z, rfl⟩ := Ideal.Quotient.mk_surjective y
exact ⟨z, fun i _hi => rfl⟩
/-- Corollary of the Chinese remainder theorem: given elements `x i : R`,
we can choose a representative `y : R` such that `y - x i ∈ P i ^ e i`. -/
theorem IsDedekindDomain.exists_forall_sub_mem_ideal {ι : Type*} {s : Finset ι} (P : ι → Ideal R)
(e : ι → ℕ) (prime : ∀ i ∈ s, Prime (P i))
(coprime : ∀ᵉ (i ∈ s) (j ∈ s), i ≠ j → P i ≠ P j) (x : s → R) :
∃ y, ∀ (i) (hi : i ∈ s), y - x ⟨i, hi⟩ ∈ P i ^ e i := by
obtain ⟨y, hy⟩ :=
IsDedekindDomain.exists_representative_mod_finset P e prime coprime fun i =>
Ideal.Quotient.mk _ (x i)
exact ⟨y, fun i hi => Ideal.Quotient.eq.mp (hy i hi)⟩
end DedekindDomain
end ChineseRemainder
section PID
open UniqueFactorizationMonoid Ideal
variable {R}
variable [IsDomain R] [IsPrincipalIdealRing R]
theorem span_singleton_dvd_span_singleton_iff_dvd {a b : R} :
Ideal.span {a} ∣ Ideal.span ({b} : Set R) ↔ a ∣ b :=
⟨fun h => mem_span_singleton.mp (dvd_iff_le.mp h (mem_span_singleton.mpr (dvd_refl b))), fun h =>
dvd_iff_le.mpr fun _d hd => mem_span_singleton.mpr (dvd_trans h (mem_span_singleton.mp hd))⟩
@[simp]
theorem Ideal.squarefree_span_singleton {a : R} :
Squarefree (span {a}) ↔ Squarefree a := by
refine ⟨fun h x hx ↦ ?_, fun h I hI ↦ ?_⟩
· rw [← span_singleton_dvd_span_singleton_iff_dvd, ← span_singleton_mul_span_singleton] at hx
simpa using h _ hx
· rw [← span_singleton_generator I, span_singleton_mul_span_singleton,
span_singleton_dvd_span_singleton_iff_dvd] at hI
exact isUnit_iff.mpr <| eq_top_of_isUnit_mem _ (Submodule.IsPrincipal.generator_mem I) (h _ hI)
theorem singleton_span_mem_normalizedFactors_of_mem_normalizedFactors [NormalizationMonoid R]
{a b : R} (ha : a ∈ normalizedFactors b) :
Ideal.span ({a} : Set R) ∈ normalizedFactors (Ideal.span ({b} : Set R)) := by
by_cases hb : b = 0
· rw [Ideal.span_singleton_eq_bot.mpr hb, bot_eq_zero, normalizedFactors_zero]
rw [hb, normalizedFactors_zero] at ha
exact absurd ha (Multiset.not_mem_zero a)
· suffices Prime (Ideal.span ({a} : Set R)) by
obtain ⟨c, hc, hc'⟩ := exists_mem_normalizedFactors_of_dvd ?_ this.irreducible
(dvd_iff_le.mpr (span_singleton_le_span_singleton.mpr (dvd_of_mem_normalizedFactors ha)))
rwa [associated_iff_eq.mp hc']
· by_contra h
exact hb (span_singleton_eq_bot.mp h)
rw [prime_iff_isPrime]
· exact (span_singleton_prime (prime_of_normalized_factor a ha).ne_zero).mpr
(prime_of_normalized_factor a ha)
· by_contra h
exact (prime_of_normalized_factor a ha).ne_zero (span_singleton_eq_bot.mp h)
theorem emultiplicity_eq_emultiplicity_span {a b : R} :
emultiplicity (Ideal.span {a}) (Ideal.span ({b} : Set R)) = emultiplicity a b := by
by_cases h : FiniteMultiplicity a b
· rw [h.emultiplicity_eq_multiplicity]
apply emultiplicity_eq_of_dvd_of_not_dvd <;>
rw [Ideal.span_singleton_pow, span_singleton_dvd_span_singleton_iff_dvd]
· exact pow_multiplicity_dvd a b
· apply h.not_pow_dvd_of_multiplicity_lt
apply lt_add_one
· suffices ¬FiniteMultiplicity (Ideal.span ({a} : Set R)) (Ideal.span ({b} : Set R)) by
rw [emultiplicity_eq_top.2 h, emultiplicity_eq_top.2 this]
exact FiniteMultiplicity.not_iff_forall.mpr fun n => by
rw [Ideal.span_singleton_pow, span_singleton_dvd_span_singleton_iff_dvd]
exact FiniteMultiplicity.not_iff_forall.mp h n
section NormalizationMonoid
variable [NormalizationMonoid R]
/-- The bijection between the (normalized) prime factors of `r` and the (normalized) prime factors
of `span {r}` -/
noncomputable def normalizedFactorsEquivSpanNormalizedFactors {r : R} (hr : r ≠ 0) :
{ d : R | d ∈ normalizedFactors r } ≃
{ I : Ideal R | I ∈ normalizedFactors (Ideal.span ({r} : Set R)) } := by
refine Equiv.ofBijective ?_ ?_
· exact fun d =>
⟨Ideal.span {↑d}, singleton_span_mem_normalizedFactors_of_mem_normalizedFactors d.prop⟩
· refine ⟨?_, ?_⟩
· rintro ⟨a, ha⟩ ⟨b, hb⟩ h
rw [Subtype.mk_eq_mk, Ideal.span_singleton_eq_span_singleton, Subtype.coe_mk,
Subtype.coe_mk] at h
exact Subtype.mk_eq_mk.mpr (mem_normalizedFactors_eq_of_associated ha hb h)
· rintro ⟨i, hi⟩
have : i.IsPrime := isPrime_of_prime (prime_of_normalized_factor i hi)
have := exists_mem_normalizedFactors_of_dvd hr
(Submodule.IsPrincipal.prime_generator_of_isPrime i
(prime_of_normalized_factor i hi).ne_zero).irreducible ?_
· obtain ⟨a, ha, ha'⟩ := this
use ⟨a, ha⟩
simp only [Subtype.coe_mk, Subtype.mk_eq_mk, ← span_singleton_eq_span_singleton.mpr ha',
Ideal.span_singleton_generator]
· exact (Submodule.IsPrincipal.mem_iff_generator_dvd i).mp
((show Ideal.span {r} ≤ i from dvd_iff_le.mp (dvd_of_mem_normalizedFactors hi))
(mem_span_singleton.mpr (dvd_refl r)))
/-- The bijection `normalizedFactorsEquivSpanNormalizedFactors` between the set of prime
factors of `r` and the set of prime factors of the ideal `⟨r⟩` preserves multiplicities. See
`count_normalizedFactorsSpan_eq_count` for the version stated in terms of multisets `count`. -/
theorem emultiplicity_normalizedFactorsEquivSpanNormalizedFactors_eq_emultiplicity {r d : R}
(hr : r ≠ 0) (hd : d ∈ normalizedFactors r) :
emultiplicity d r =
emultiplicity (normalizedFactorsEquivSpanNormalizedFactors hr ⟨d, hd⟩ : Ideal R)
(Ideal.span {r}) := by
simp only [normalizedFactorsEquivSpanNormalizedFactors, emultiplicity_eq_emultiplicity_span,
Subtype.coe_mk, Equiv.ofBijective_apply]
/-- The bijection `normalized_factors_equiv_span_normalized_factors.symm` between the set of prime
factors of the ideal `⟨r⟩` and the set of prime factors of `r` preserves multiplicities. -/
theorem emultiplicity_normalizedFactorsEquivSpanNormalizedFactors_symm_eq_emultiplicity {r : R}
(hr : r ≠ 0) (I : { I : Ideal R | I ∈ normalizedFactors (Ideal.span ({r} : Set R)) }) :
emultiplicity ((normalizedFactorsEquivSpanNormalizedFactors hr).symm I : R) r =
emultiplicity (I : Ideal R) (Ideal.span {r}) := by
obtain ⟨x, hx⟩ := (normalizedFactorsEquivSpanNormalizedFactors hr).surjective I
obtain ⟨a, ha⟩ := x
rw [hx.symm, Equiv.symm_apply_apply, Subtype.coe_mk,
emultiplicity_normalizedFactorsEquivSpanNormalizedFactors_eq_emultiplicity hr ha]
variable [DecidableEq R] [DecidableEq (Ideal R)]
/-- The bijection between the set of prime factors of the ideal `⟨r⟩` and the set of prime factors
of `r` preserves `count` of the corresponding multisets. See
`multiplicity_normalizedFactorsEquivSpanNormalizedFactors_eq_multiplicity` for the version
stated in terms of multiplicity. -/
theorem count_span_normalizedFactors_eq {r X : R} (hr : r ≠ 0) (hX : Prime X) :
Multiset.count (Ideal.span {X} : Ideal R) (normalizedFactors (Ideal.span {r})) =
Multiset.count (normalize X) (normalizedFactors r) := by
have := emultiplicity_eq_emultiplicity_span (R := R) (a := X) (b := r)
rw [emultiplicity_eq_count_normalizedFactors (Prime.irreducible hX) hr,
emultiplicity_eq_count_normalizedFactors (Prime.irreducible ?_), normalize_apply,
normUnit_eq_one, Units.val_one, one_eq_top, mul_top, Nat.cast_inj] at this
· simp only [normalize_apply, this]
· simp only [Submodule.zero_eq_bot, ne_eq, span_singleton_eq_bot, hr, not_false_eq_true]
· simpa only [prime_span_singleton_iff]
theorem count_span_normalizedFactors_eq_of_normUnit {r X : R}
(hr : r ≠ 0) (hX₁ : normUnit X = 1) (hX : Prime X) :
Multiset.count (Ideal.span {X} : Ideal R) (normalizedFactors (Ideal.span {r})) =
Multiset.count X (normalizedFactors r) := by
simpa [hX₁, normalize_apply] using count_span_normalizedFactors_eq hr hX
end NormalizationMonoid
end PID
section primesOverFinset
open UniqueFactorizationMonoid Ideal
open scoped Classical in
/-- The finite set of all prime factors of the pushforward of `p`. -/
noncomputable abbrev primesOverFinset {A : Type*} [CommRing A] (p : Ideal A) (B : Type*)
[CommRing B] [IsDedekindDomain B] [Algebra A B] : Finset (Ideal B) :=
(factors (p.map (algebraMap A B))).toFinset
variable {A : Type*} [CommRing A] {p : Ideal A} (hpb : p ≠ ⊥) [hpm : p.IsMaximal]
(B : Type*) [CommRing B] [IsDedekindDomain B] [Algebra A B] [NoZeroSMulDivisors A B]
include hpb in
theorem coe_primesOverFinset : primesOverFinset p B = primesOver p B := by
classical
ext P
rw [primesOverFinset, factors_eq_normalizedFactors, Finset.mem_coe, Multiset.mem_toFinset]
exact (P.mem_normalizedFactors_iff (map_ne_bot_of_ne_bot hpb)).trans <| Iff.intro
(fun ⟨hPp, h⟩ => ⟨hPp, ⟨hpm.eq_of_le (comap_ne_top _ hPp.ne_top) (le_comap_of_map_le h)⟩⟩)
(fun ⟨hPp, h⟩ => ⟨hPp, map_le_of_le_comap h.1.le⟩)
variable (p) [Algebra.IsIntegral A B]
theorem primesOver_finite : (primesOver p B).Finite := by
by_cases hpb : p = ⊥
· rw [hpb] at hpm ⊢
haveI : IsDomain A := IsDomain.of_bot_isPrime A
rw [primesOver_bot A B]
exact Set.finite_singleton ⊥
· rw [← coe_primesOverFinset hpb B]
exact (primesOverFinset p B).finite_toSet
theorem primesOver_ncard_ne_zero : (primesOver p B).ncard ≠ 0 := by
rcases exists_ideal_liesOver_maximal_of_isIntegral p B with ⟨P, hPm, hp⟩
exact Set.ncard_ne_zero_of_mem ⟨hPm.isPrime, hp⟩ (primesOver_finite p B)
theorem one_le_primesOver_ncard : 1 ≤ (primesOver p B).ncard :=
Nat.one_le_iff_ne_zero.mpr (primesOver_ncard_ne_zero p B)
end primesOverFinset
| Mathlib/RingTheory/DedekindDomain/Ideal.lean | 1,569 | 1,581 | |
/-
Copyright (c) 2015 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura, Mario Carneiro
-/
import Mathlib.Data.Sum.Basic
import Mathlib.Logic.Equiv.Option
import Mathlib.Logic.Equiv.Sum
import Mathlib.Logic.Function.Conjugate
import Mathlib.Tactic.CC
import Mathlib.Tactic.Lift
/-!
# Equivalence between types
In this file we continue the work on equivalences begun in `Mathlib/Logic/Equiv/Defs.lean`, defining
a lot of equivalences between various types and operations on these equivalences.
More definitions of this kind can be found in other files.
E.g., `Mathlib/Algebra/Equiv/TransferInstance.lean` does it for many algebraic type classes like
`Group`, `Module`, etc.
## Tags
equivalence, congruence, bijective map
-/
universe u v w z
open Function
-- Unless required to be `Type*`, all variables in this file are `Sort*`
variable {α α₁ α₂ β β₁ β₂ γ δ : Sort*}
namespace Equiv
/-- The product over `Option α` of `β a` is the binary product of the
product over `α` of `β (some α)` and `β none` -/
@[simps]
def piOptionEquivProd {α} {β : Option α → Type*} :
(∀ a : Option α, β a) ≃ β none × ∀ a : α, β (some a) where
toFun f := (f none, fun a => f (some a))
invFun x a := Option.casesOn a x.fst x.snd
left_inv f := funext fun a => by cases a <;> rfl
right_inv x := by simp
section subtypeCongr
/-- Combines an `Equiv` between two subtypes with an `Equiv` between their complements to form a
permutation. -/
def subtypeCongr {α} {p q : α → Prop} [DecidablePred p] [DecidablePred q]
(e : { x // p x } ≃ { x // q x }) (f : { x // ¬p x } ≃ { x // ¬q x }) : Perm α :=
(sumCompl p).symm.trans ((sumCongr e f).trans (sumCompl q))
variable {ε : Type*} {p : ε → Prop} [DecidablePred p]
variable (ep ep' : Perm { a // p a }) (en en' : Perm { a // ¬p a })
/-- Combining permutations on `ε` that permute only inside or outside the subtype
split induced by `p : ε → Prop` constructs a permutation on `ε`. -/
def Perm.subtypeCongr : Equiv.Perm ε :=
permCongr (sumCompl p) (sumCongr ep en)
theorem Perm.subtypeCongr.apply (a : ε) : ep.subtypeCongr en a =
if h : p a then (ep ⟨a, h⟩ : ε) else en ⟨a, h⟩ := by
by_cases h : p a <;> simp [Perm.subtypeCongr, h]
@[simp]
theorem Perm.subtypeCongr.left_apply {a : ε} (h : p a) : ep.subtypeCongr en a = ep ⟨a, h⟩ := by
simp [Perm.subtypeCongr.apply, h]
@[simp]
theorem Perm.subtypeCongr.left_apply_subtype (a : { a // p a }) : ep.subtypeCongr en a = ep a :=
Perm.subtypeCongr.left_apply ep en a.property
@[simp]
theorem Perm.subtypeCongr.right_apply {a : ε} (h : ¬p a) : ep.subtypeCongr en a = en ⟨a, h⟩ := by
simp [Perm.subtypeCongr.apply, h]
@[simp]
theorem Perm.subtypeCongr.right_apply_subtype (a : { a // ¬p a }) : ep.subtypeCongr en a = en a :=
Perm.subtypeCongr.right_apply ep en a.property
@[simp]
theorem Perm.subtypeCongr.refl :
Perm.subtypeCongr (Equiv.refl { a // p a }) (Equiv.refl { a // ¬p a }) = Equiv.refl ε := by
ext x
by_cases h : p x <;> simp [h]
@[simp]
theorem Perm.subtypeCongr.symm : (ep.subtypeCongr en).symm = Perm.subtypeCongr ep.symm en.symm := by
ext x
by_cases h : p x
· have : p (ep.symm ⟨x, h⟩) := Subtype.property _
simp [Perm.subtypeCongr.apply, h, symm_apply_eq, this]
· have : ¬p (en.symm ⟨x, h⟩) := Subtype.property (en.symm _)
simp [Perm.subtypeCongr.apply, h, symm_apply_eq, this]
@[simp]
theorem Perm.subtypeCongr.trans :
(ep.subtypeCongr en).trans (ep'.subtypeCongr en')
= Perm.subtypeCongr (ep.trans ep') (en.trans en') := by
ext x
by_cases h : p x
· have : p (ep ⟨x, h⟩) := Subtype.property _
simp [Perm.subtypeCongr.apply, h, this]
· have : ¬p (en ⟨x, h⟩) := Subtype.property (en _)
simp [Perm.subtypeCongr.apply, h, symm_apply_eq, this]
end subtypeCongr
section subtypePreimage
variable (p : α → Prop) [DecidablePred p] (x₀ : { a // p a } → β)
/-- For a fixed function `x₀ : {a // p a} → β` defined on a subtype of `α`,
the subtype of functions `x : α → β` that agree with `x₀` on the subtype `{a // p a}`
is naturally equivalent to the type of functions `{a // ¬ p a} → β`. -/
@[simps]
def subtypePreimage : { x : α → β // x ∘ Subtype.val = x₀ } ≃ ({ a // ¬p a } → β) where
toFun (x : { x : α → β // x ∘ Subtype.val = x₀ }) a := (x : α → β) a
invFun x := ⟨fun a => if h : p a then x₀ ⟨a, h⟩ else x ⟨a, h⟩, funext fun ⟨_, h⟩ => dif_pos h⟩
left_inv := fun ⟨x, hx⟩ =>
Subtype.val_injective <|
funext fun a => by
dsimp only
split_ifs
· rw [← hx]; rfl
· rfl
right_inv x :=
funext fun ⟨a, h⟩ =>
show dite (p a) _ _ = _ by
dsimp only
rw [dif_neg h]
theorem subtypePreimage_symm_apply_coe_pos (x : { a // ¬p a } → β) (a : α) (h : p a) :
((subtypePreimage p x₀).symm x : α → β) a = x₀ ⟨a, h⟩ :=
dif_pos h
theorem subtypePreimage_symm_apply_coe_neg (x : { a // ¬p a } → β) (a : α) (h : ¬p a) :
((subtypePreimage p x₀).symm x : α → β) a = x ⟨a, h⟩ :=
dif_neg h
end subtypePreimage
section
/-- A family of equivalences `∀ a, β₁ a ≃ β₂ a` generates an equivalence between `∀ a, β₁ a` and
`∀ a, β₂ a`. -/
@[simps]
def piCongrRight {β₁ β₂ : α → Sort*} (F : ∀ a, β₁ a ≃ β₂ a) : (∀ a, β₁ a) ≃ (∀ a, β₂ a) :=
⟨Pi.map fun a ↦ F a, Pi.map fun a ↦ (F a).symm, fun H => funext <| by simp,
fun H => funext <| by simp⟩
/-- Given `φ : α → β → Sort*`, we have an equivalence between `∀ a b, φ a b` and `∀ b a, φ a b`.
This is `Function.swap` as an `Equiv`. -/
@[simps apply]
def piComm (φ : α → β → Sort*) : (∀ a b, φ a b) ≃ ∀ b a, φ a b :=
⟨swap, swap, fun _ => rfl, fun _ => rfl⟩
@[simp]
theorem piComm_symm {φ : α → β → Sort*} : (piComm φ).symm = (piComm <| swap φ) :=
rfl
/-- Dependent `curry` equivalence: the type of dependent functions on `Σ i, β i` is equivalent
to the type of dependent functions of two arguments (i.e., functions to the space of functions).
This is `Sigma.curry` and `Sigma.uncurry` together as an equiv. -/
def piCurry {α} {β : α → Type*} (γ : ∀ a, β a → Type*) :
(∀ x : Σ i, β i, γ x.1 x.2) ≃ ∀ a b, γ a b where
toFun := Sigma.curry
invFun := Sigma.uncurry
left_inv := Sigma.uncurry_curry
right_inv := Sigma.curry_uncurry
-- `simps` overapplies these but `simps -fullyApplied` under-applies them
@[simp] theorem piCurry_apply {α} {β : α → Type*} (γ : ∀ a, β a → Type*)
(f : ∀ x : Σ i, β i, γ x.1 x.2) :
piCurry γ f = Sigma.curry f :=
rfl
@[simp] theorem piCurry_symm_apply {α} {β : α → Type*} (γ : ∀ a, β a → Type*) (f : ∀ a b, γ a b) :
(piCurry γ).symm f = Sigma.uncurry f :=
rfl
end
section prodCongr
variable {α₁ α₂ β₁ β₂ : Type*} (e : α₁ → β₁ ≃ β₂)
-- See also `Equiv.ofPreimageEquiv`.
/-- A family of equivalences between fibers gives an equivalence between domains. -/
@[simps!]
def ofFiberEquiv {α β γ} {f : α → γ} {g : β → γ}
(e : ∀ c, { a // f a = c } ≃ { b // g b = c }) : α ≃ β :=
(sigmaFiberEquiv f).symm.trans <| (Equiv.sigmaCongrRight e).trans (sigmaFiberEquiv g)
theorem ofFiberEquiv_map {α β γ} {f : α → γ} {g : β → γ}
(e : ∀ c, { a // f a = c } ≃ { b // g b = c }) (a : α) : g (ofFiberEquiv e a) = f a :=
(_ : { b // g b = _ }).property
end prodCongr
section
open Sum
/-- An equivalence that separates out the 0th fiber of `(Σ (n : ℕ), f n)`. -/
def sigmaNatSucc (f : ℕ → Type u) : (Σ n, f n) ≃ f 0 ⊕ Σ n, f (n + 1) :=
⟨fun x =>
@Sigma.casesOn ℕ f (fun _ => f 0 ⊕ Σ n, f (n + 1)) x fun n =>
@Nat.casesOn (fun i => f i → f 0 ⊕ Σ n : ℕ, f (n + 1)) n (fun x : f 0 => Sum.inl x)
fun (n : ℕ) (x : f n.succ) => Sum.inr ⟨n, x⟩,
Sum.elim (Sigma.mk 0) (Sigma.map Nat.succ fun _ => id), by rintro ⟨n | n, x⟩ <;> rfl, by
rintro (x | ⟨n, x⟩) <;> rfl⟩
end
section
open Sum Nat
/-- The set of natural numbers is equivalent to `ℕ ⊕ PUnit`. -/
def natEquivNatSumPUnit : ℕ ≃ ℕ ⊕ PUnit where
toFun n := Nat.casesOn n (inr PUnit.unit) inl
invFun := Sum.elim Nat.succ fun _ => 0
left_inv n := by cases n <;> rfl
right_inv := by rintro (_ | _) <;> rfl
/-- `ℕ ⊕ PUnit` is equivalent to `ℕ`. -/
def natSumPUnitEquivNat : ℕ ⊕ PUnit ≃ ℕ :=
natEquivNatSumPUnit.symm
/-- The type of integer numbers is equivalent to `ℕ ⊕ ℕ`. -/
def intEquivNatSumNat : ℤ ≃ ℕ ⊕ ℕ where
toFun z := Int.casesOn z inl inr
invFun := Sum.elim Int.ofNat Int.negSucc
left_inv := by rintro (m | n) <;> rfl
right_inv := by rintro (m | n) <;> rfl
end
/-- If `α` is equivalent to `β`, then `Unique α` is equivalent to `Unique β`. -/
def uniqueCongr (e : α ≃ β) : Unique α ≃ Unique β where
toFun h := @Equiv.unique _ _ h e.symm
invFun h := @Equiv.unique _ _ h e
left_inv _ := Subsingleton.elim _ _
right_inv _ := Subsingleton.elim _ _
/-- If `α` is equivalent to `β`, then `IsEmpty α` is equivalent to `IsEmpty β`. -/
theorem isEmpty_congr (e : α ≃ β) : IsEmpty α ↔ IsEmpty β :=
⟨fun h => @Function.isEmpty _ _ h e.symm, fun h => @Function.isEmpty _ _ h e⟩
protected theorem isEmpty (e : α ≃ β) [IsEmpty β] : IsEmpty α :=
e.isEmpty_congr.mpr ‹_›
section
open Subtype
/-- If `α` is equivalent to `β` and the predicates `p : α → Prop` and `q : β → Prop` are equivalent
at corresponding points, then `{a // p a}` is equivalent to `{b // q b}`.
For the statement where `α = β`, that is, `e : perm α`, see `Perm.subtypePerm`. -/
@[simps apply]
def subtypeEquiv {p : α → Prop} {q : β → Prop} (e : α ≃ β) (h : ∀ a, p a ↔ q (e a)) :
{ a : α // p a } ≃ { b : β // q b } where
toFun a := ⟨e a, (h _).mp a.property⟩
invFun b := ⟨e.symm b, (h _).mpr ((e.apply_symm_apply b).symm ▸ b.property)⟩
left_inv a := Subtype.ext <| by simp
right_inv b := Subtype.ext <| by simp
lemma coe_subtypeEquiv_eq_map {X Y} {p : X → Prop} {q : Y → Prop} (e : X ≃ Y)
(h : ∀ x, p x ↔ q (e x)) : ⇑(e.subtypeEquiv h) = Subtype.map e (h · |>.mp) :=
rfl
@[simp]
theorem subtypeEquiv_refl {p : α → Prop} (h : ∀ a, p a ↔ p (Equiv.refl _ a) := fun _ => Iff.rfl) :
(Equiv.refl α).subtypeEquiv h = Equiv.refl { a : α // p a } := by
ext
rfl
-- We use `as_aux_lemma` here to avoid creating large proof terms when using `simp`
@[simp]
theorem subtypeEquiv_symm {p : α → Prop} {q : β → Prop} (e : α ≃ β) (h : ∀ a : α, p a ↔ q (e a)) :
(e.subtypeEquiv h).symm =
e.symm.subtypeEquiv (by as_aux_lemma =>
intro a
convert (h <| e.symm a).symm
exact (e.apply_symm_apply a).symm) :=
rfl
@[simp]
theorem subtypeEquiv_trans {p : α → Prop} {q : β → Prop} {r : γ → Prop} (e : α ≃ β) (f : β ≃ γ)
(h : ∀ a : α, p a ↔ q (e a)) (h' : ∀ b : β, q b ↔ r (f b)) :
(e.subtypeEquiv h).trans (f.subtypeEquiv h')
= (e.trans f).subtypeEquiv (by as_aux_lemma => exact fun a => (h a).trans (h' <| e a)) :=
rfl
/-- If two predicates `p` and `q` are pointwise equivalent, then `{x // p x}` is equivalent to
`{x // q x}`. -/
@[simps!]
def subtypeEquivRight {p q : α → Prop} (e : ∀ x, p x ↔ q x) : { x // p x } ≃ { x // q x } :=
subtypeEquiv (Equiv.refl _) e
lemma subtypeEquivRight_apply {p q : α → Prop} (e : ∀ x, p x ↔ q x)
(z : { x // p x }) : subtypeEquivRight e z = ⟨z, (e z.1).mp z.2⟩ := rfl
lemma subtypeEquivRight_symm_apply {p q : α → Prop} (e : ∀ x, p x ↔ q x)
(z : { x // q x }) : (subtypeEquivRight e).symm z = ⟨z, (e z.1).mpr z.2⟩ := rfl
/-- If `α ≃ β`, then for any predicate `p : β → Prop` the subtype `{a // p (e a)}` is equivalent
to the subtype `{b // p b}`. -/
def subtypeEquivOfSubtype {p : β → Prop} (e : α ≃ β) : { a : α // p (e a) } ≃ { b : β // p b } :=
subtypeEquiv e <| by simp
/-- If `α ≃ β`, then for any predicate `p : α → Prop` the subtype `{a // p a}` is equivalent
to the subtype `{b // p (e.symm b)}`. This version is used by `equiv_rw`. -/
def subtypeEquivOfSubtype' {p : α → Prop} (e : α ≃ β) :
{ a : α // p a } ≃ { b : β // p (e.symm b) } :=
e.symm.subtypeEquivOfSubtype.symm
/-- If two predicates are equal, then the corresponding subtypes are equivalent. -/
def subtypeEquivProp {p q : α → Prop} (h : p = q) : Subtype p ≃ Subtype q :=
subtypeEquiv (Equiv.refl α) fun _ => h ▸ Iff.rfl
/-- A subtype of a subtype is equivalent to the subtype of elements satisfying both predicates. This
version allows the “inner” predicate to depend on `h : p a`. -/
@[simps]
def subtypeSubtypeEquivSubtypeExists (p : α → Prop) (q : Subtype p → Prop) :
Subtype q ≃ { a : α // ∃ h : p a, q ⟨a, h⟩ } :=
⟨fun a =>
⟨a.1, a.1.2, by
rcases a with ⟨⟨a, hap⟩, haq⟩
exact haq⟩,
fun a => ⟨⟨a, a.2.fst⟩, a.2.snd⟩, fun ⟨⟨_, _⟩, _⟩ => rfl, fun ⟨_, _, _⟩ => rfl⟩
/-- A subtype of a subtype is equivalent to the subtype of elements satisfying both predicates. -/
@[simps!]
def subtypeSubtypeEquivSubtypeInter {α : Type u} (p q : α → Prop) :
{ x : Subtype p // q x.1 } ≃ Subtype fun x => p x ∧ q x :=
(subtypeSubtypeEquivSubtypeExists p _).trans <|
subtypeEquivRight fun x => @exists_prop (q x) (p x)
/-- If the outer subtype has more restrictive predicate than the inner one,
then we can drop the latter. -/
@[simps!]
def subtypeSubtypeEquivSubtype {α} {p q : α → Prop} (h : ∀ {x}, q x → p x) :
{ x : Subtype p // q x.1 } ≃ Subtype q :=
(subtypeSubtypeEquivSubtypeInter p _).trans <| subtypeEquivRight fun _ => and_iff_right_of_imp h
/-- If a proposition holds for all elements, then the subtype is
equivalent to the original type. -/
@[simps apply symm_apply]
def subtypeUnivEquiv {α} {p : α → Prop} (h : ∀ x, p x) : Subtype p ≃ α :=
⟨fun x => x, fun x => ⟨x, h x⟩, fun _ => Subtype.eq rfl, fun _ => rfl⟩
/-- A subtype of a sigma-type is a sigma-type over a subtype. -/
def subtypeSigmaEquiv {α} (p : α → Type v) (q : α → Prop) : { y : Sigma p // q y.1 } ≃ Σ x :
Subtype q, p x.1 :=
⟨fun x => ⟨⟨x.1.1, x.2⟩, x.1.2⟩, fun x => ⟨⟨x.1.1, x.2⟩, x.1.2⟩, fun _ => rfl,
fun _ => rfl⟩
/-- A sigma type over a subtype is equivalent to the sigma set over the original type,
if the fiber is empty outside of the subset -/
def sigmaSubtypeEquivOfSubset {α} (p : α → Type v) (q : α → Prop) (h : ∀ x, p x → q x) :
(Σ x : Subtype q, p x) ≃ Σ x : α, p x :=
(subtypeSigmaEquiv p q).symm.trans <| subtypeUnivEquiv fun x => h x.1 x.2
/-- If a predicate `p : β → Prop` is true on the range of a map `f : α → β`, then
`Σ y : {y // p y}, {x // f x = y}` is equivalent to `α`. -/
def sigmaSubtypeFiberEquiv {α β : Type*} (f : α → β) (p : β → Prop) (h : ∀ x, p (f x)) :
(Σ y : Subtype p, { x : α // f x = y }) ≃ α :=
calc
_ ≃ Σy : β, { x : α // f x = y } := sigmaSubtypeEquivOfSubset _ p fun _ ⟨x, h'⟩ => h' ▸ h x
_ ≃ α := sigmaFiberEquiv f
/-- If for each `x` we have `p x ↔ q (f x)`, then `Σ y : {y // q y}, f ⁻¹' {y}` is equivalent
to `{x // p x}`. -/
def sigmaSubtypeFiberEquivSubtype {α β : Type*} (f : α → β) {p : α → Prop} {q : β → Prop}
(h : ∀ x, p x ↔ q (f x)) : (Σ y : Subtype q, { x : α // f x = y }) ≃ Subtype p :=
calc
(Σy : Subtype q, { x : α // f x = y }) ≃ Σy :
Subtype q, { x : Subtype p // Subtype.mk (f x) ((h x).1 x.2) = y } := by {
apply sigmaCongrRight
intro y
apply Equiv.symm
refine (subtypeSubtypeEquivSubtypeExists _ _).trans (subtypeEquivRight ?_)
intro x
exact ⟨fun ⟨hp, h'⟩ => congr_arg Subtype.val h', fun h' => ⟨(h x).2 (h'.symm ▸ y.2),
Subtype.eq h'⟩⟩ }
_ ≃ Subtype p := sigmaFiberEquiv fun x : Subtype p => (⟨f x, (h x).1 x.property⟩ : Subtype q)
/-- A sigma type over an `Option` is equivalent to the sigma set over the original type,
if the fiber is empty at none. -/
def sigmaOptionEquivOfSome {α} (p : Option α → Type v) (h : p none → False) :
(Σ x : Option α, p x) ≃ Σ x : α, p (some x) :=
haveI h' : ∀ x, p x → x.isSome := by
intro x
cases x
· intro n
exfalso
exact h n
· intro _
exact rfl
(sigmaSubtypeEquivOfSubset _ _ h').symm.trans (sigmaCongrLeft' (optionIsSomeEquiv α))
/-- The `Pi`-type `∀ i, π i` is equivalent to the type of sections `f : ι → Σ i, π i` of the
`Sigma` type such that for all `i` we have `(f i).fst = i`. -/
def piEquivSubtypeSigma (ι) (π : ι → Type*) :
(∀ i, π i) ≃ { f : ι → Σ i, π i // ∀ i, (f i).1 = i } where
toFun := fun f => ⟨fun i => ⟨i, f i⟩, fun _ => rfl⟩
invFun := fun f i => by rw [← f.2 i]; exact (f.1 i).2
left_inv := fun _ => funext fun _ => rfl
right_inv := fun ⟨f, hf⟩ =>
Subtype.eq <| funext fun i =>
Sigma.eq (hf i).symm <| eq_of_heq <| rec_heq_of_heq _ <| by simp
/-- The type of functions `f : ∀ a, β a` such that for all `a` we have `p a (f a)` is equivalent
to the type of functions `∀ a, {b : β a // p a b}`. -/
def subtypePiEquivPi {β : α → Sort v} {p : ∀ a, β a → Prop} :
{ f : ∀ a, β a // ∀ a, p a (f a) } ≃ ∀ a, { b : β a // p a b } where
toFun := fun f a => ⟨f.1 a, f.2 a⟩
invFun := fun f => ⟨fun a => (f a).1, fun a => (f a).2⟩
left_inv := by
rintro ⟨f, h⟩
rfl
right_inv := by
rintro f
funext a
exact Subtype.ext_val rfl
end
section subtypeEquivCodomain
variable {X Y : Sort*} [DecidableEq X] {x : X}
/-- The type of all functions `X → Y` with prescribed values for all `x' ≠ x`
is equivalent to the codomain `Y`. -/
def subtypeEquivCodomain (f : { x' // x' ≠ x } → Y) :
{ g : X → Y // g ∘ (↑) = f } ≃ Y :=
(subtypePreimage _ f).trans <|
@funUnique { x' // ¬x' ≠ x } _ <|
show Unique { x' // ¬x' ≠ x } from
@Equiv.unique _ _
(show Unique { x' // x' = x } from {
default := ⟨x, rfl⟩, uniq := fun ⟨_, h⟩ => Subtype.val_injective h })
(subtypeEquivRight fun _ => not_not)
@[simp]
theorem coe_subtypeEquivCodomain (f : { x' // x' ≠ x } → Y) :
(subtypeEquivCodomain f : _ → Y) =
fun g : { g : X → Y // g ∘ (↑) = f } => (g : X → Y) x :=
rfl
@[simp]
theorem subtypeEquivCodomain_apply (f : { x' // x' ≠ x } → Y) (g) :
subtypeEquivCodomain f g = (g : X → Y) x :=
rfl
theorem coe_subtypeEquivCodomain_symm (f : { x' // x' ≠ x } → Y) :
((subtypeEquivCodomain f).symm : Y → _) = fun y =>
⟨fun x' => if h : x' ≠ x then f ⟨x', h⟩ else y, by
funext x'
simp only [ne_eq, dite_not, comp_apply, Subtype.coe_eta, dite_eq_ite, ite_eq_right_iff]
intro w
exfalso
exact x'.property w⟩ :=
rfl
@[simp]
theorem subtypeEquivCodomain_symm_apply (f : { x' // x' ≠ x } → Y) (y : Y) (x' : X) :
((subtypeEquivCodomain f).symm y : X → Y) x' = if h : x' ≠ x then f ⟨x', h⟩ else y :=
rfl
theorem subtypeEquivCodomain_symm_apply_eq (f : { x' // x' ≠ x } → Y) (y : Y) :
((subtypeEquivCodomain f).symm y : X → Y) x = y :=
dif_neg (not_not.mpr rfl)
theorem subtypeEquivCodomain_symm_apply_ne
(f : { x' // x' ≠ x } → Y) (y : Y) (x' : X) (h : x' ≠ x) :
((subtypeEquivCodomain f).symm y : X → Y) x' = f ⟨x', h⟩ :=
dif_pos h
end subtypeEquivCodomain
instance : CanLift (α → β) (α ≃ β) (↑) Bijective where prf f hf := ⟨ofBijective f hf, rfl⟩
section
variable {α' β' : Type*} (e : Perm α') {p : β' → Prop} [DecidablePred p] (f : α' ≃ Subtype p)
/-- Extend the domain of `e : Equiv.Perm α` to one that is over `β` via `f : α → Subtype p`,
where `p : β → Prop`, permuting only the `b : β` that satisfy `p b`.
This can be used to extend the domain across a function `f : α → β`,
keeping everything outside of `Set.range f` fixed. For this use-case `Equiv` given by `f` can
be constructed by `Equiv.of_leftInverse'` or `Equiv.of_leftInverse` when there is a known
inverse, or `Equiv.ofInjective` in the general case.
-/
def Perm.extendDomain : Perm β' :=
(permCongr f e).subtypeCongr (Equiv.refl _)
@[simp]
theorem Perm.extendDomain_apply_image (a : α') : e.extendDomain f (f a) = f (e a) := by
simp [Perm.extendDomain]
theorem Perm.extendDomain_apply_subtype {b : β'} (h : p b) :
e.extendDomain f b = f (e (f.symm ⟨b, h⟩)) := by
simp [Perm.extendDomain, h]
theorem Perm.extendDomain_apply_not_subtype {b : β'} (h : ¬p b) : e.extendDomain f b = b := by
simp [Perm.extendDomain, h]
@[simp]
theorem Perm.extendDomain_refl : Perm.extendDomain (Equiv.refl _) f = Equiv.refl _ := by
simp [Perm.extendDomain]
@[simp]
theorem Perm.extendDomain_symm : (e.extendDomain f).symm = Perm.extendDomain e.symm f :=
rfl
theorem Perm.extendDomain_trans (e e' : Perm α') :
(e.extendDomain f).trans (e'.extendDomain f) = Perm.extendDomain (e.trans e') f := by
simp [Perm.extendDomain, permCongr_trans]
end
/-- Subtype of the quotient is equivalent to the quotient of the subtype. Let `α` be a setoid with
equivalence relation `~`. Let `p₂` be a predicate on the quotient type `α/~`, and `p₁` be the lift
of this predicate to `α`: `p₁ a ↔ p₂ ⟦a⟧`. Let `~₂` be the restriction of `~` to `{x // p₁ x}`.
Then `{x // p₂ x}` is equivalent to the quotient of `{x // p₁ x}` by `~₂`. -/
def subtypeQuotientEquivQuotientSubtype (p₁ : α → Prop) {s₁ : Setoid α} {s₂ : Setoid (Subtype p₁)}
(p₂ : Quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧)
(h : ∀ x y : Subtype p₁, s₂.r x y ↔ s₁.r x y) : {x // p₂ x} ≃ Quotient s₂ where
toFun a :=
Quotient.hrecOn a.1 (fun a h => ⟦⟨a, (hp₂ _).2 h⟩⟧)
(fun a b hab => hfunext (by rw [Quotient.sound hab]) fun _ _ _ =>
heq_of_eq (Quotient.sound ((h _ _).2 hab)))
a.2
invFun a :=
Quotient.liftOn a (fun a => (⟨⟦a.1⟧, (hp₂ _).1 a.2⟩ : { x // p₂ x })) fun _ _ hab =>
Subtype.ext_val (Quotient.sound ((h _ _).1 hab))
left_inv := by exact fun ⟨a, ha⟩ => Quotient.inductionOn a (fun b hb => rfl) ha
right_inv a := by exact Quotient.inductionOn a fun ⟨a, ha⟩ => rfl
@[simp]
theorem subtypeQuotientEquivQuotientSubtype_mk (p₁ : α → Prop)
[s₁ : Setoid α] [s₂ : Setoid (Subtype p₁)] (p₂ : Quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧)
(h : ∀ x y : Subtype p₁, s₂ x y ↔ (x : α) ≈ y)
(x hx) : subtypeQuotientEquivQuotientSubtype p₁ p₂ hp₂ h ⟨⟦x⟧, hx⟩ = ⟦⟨x, (hp₂ _).2 hx⟩⟧ :=
rfl
@[simp]
theorem subtypeQuotientEquivQuotientSubtype_symm_mk (p₁ : α → Prop)
[s₁ : Setoid α] [s₂ : Setoid (Subtype p₁)] (p₂ : Quotient s₁ → Prop) (hp₂ : ∀ a, p₁ a ↔ p₂ ⟦a⟧)
(h : ∀ x y : Subtype p₁, s₂ x y ↔ (x : α) ≈ y) (x) :
(subtypeQuotientEquivQuotientSubtype p₁ p₂ hp₂ h).symm ⟦x⟧ = ⟨⟦x⟧, (hp₂ _).1 x.property⟩ :=
rfl
section Swap
variable [DecidableEq α]
/-- A helper function for `Equiv.swap`. -/
def swapCore (a b r : α) : α :=
if r = a then b else if r = b then a else r
theorem swapCore_self (r a : α) : swapCore a a r = r := by
unfold swapCore
split_ifs <;> simp [*]
theorem swapCore_swapCore (r a b : α) : swapCore a b (swapCore a b r) = r := by
unfold swapCore; split_ifs <;> cc
theorem swapCore_comm (r a b : α) : swapCore a b r = swapCore b a r := by
unfold swapCore; split_ifs <;> cc
/-- `swap a b` is the permutation that swaps `a` and `b` and
leaves other values as is. -/
def swap (a b : α) : Perm α :=
⟨swapCore a b, swapCore a b, fun r => swapCore_swapCore r a b,
fun r => swapCore_swapCore r a b⟩
@[simp]
theorem swap_self (a : α) : swap a a = Equiv.refl _ :=
ext fun r => swapCore_self r a
theorem swap_comm (a b : α) : swap a b = swap b a :=
ext fun r => swapCore_comm r _ _
theorem swap_apply_def (a b x : α) : swap a b x = if x = a then b else if x = b then a else x :=
rfl
@[simp]
theorem swap_apply_left (a b : α) : swap a b a = b :=
if_pos rfl
@[simp]
theorem swap_apply_right (a b : α) : swap a b b = a := by
by_cases h : b = a <;> simp [swap_apply_def, h]
theorem swap_apply_of_ne_of_ne {a b x : α} : x ≠ a → x ≠ b → swap a b x = x := by
simp +contextual [swap_apply_def]
theorem eq_or_eq_of_swap_apply_ne_self {a b x : α} (h : swap a b x ≠ x) : x = a ∨ x = b := by
contrapose! h
exact swap_apply_of_ne_of_ne h.1 h.2
@[simp]
theorem swap_swap (a b : α) : (swap a b).trans (swap a b) = Equiv.refl _ :=
ext fun _ => swapCore_swapCore _ _ _
@[simp]
theorem symm_swap (a b : α) : (swap a b).symm = swap a b :=
rfl
@[simp]
theorem swap_eq_refl_iff {x y : α} : swap x y = Equiv.refl _ ↔ x = y := by
refine ⟨fun h => (Equiv.refl _).injective ?_, fun h => h ▸ swap_self _⟩
rw [← h, swap_apply_left, h, refl_apply]
theorem swap_comp_apply {a b x : α} (π : Perm α) :
π.trans (swap a b) x = if π x = a then b else if π x = b then a else π x := by
cases π
rfl
theorem swap_eq_update (i j : α) : (Equiv.swap i j : α → α) = update (update id j i) i j :=
funext fun x => by rw [update_apply _ i j, update_apply _ j i, Equiv.swap_apply_def, id]
theorem comp_swap_eq_update (i j : α) (f : α → β) :
f ∘ Equiv.swap i j = update (update f j (f i)) i (f j) := by
rw [swap_eq_update, comp_update, comp_update, comp_id]
@[simp]
theorem symm_trans_swap_trans [DecidableEq β] (a b : α) (e : α ≃ β) :
(e.symm.trans (swap a b)).trans e = swap (e a) (e b) :=
Equiv.ext fun x => by
have : ∀ a, e.symm x = a ↔ x = e a := fun a => by
rw [@eq_comm _ (e.symm x)]
constructor <;> intros <;> simp_all
simp only [trans_apply, swap_apply_def, this]
split_ifs <;> simp
@[simp]
theorem trans_swap_trans_symm [DecidableEq β] (a b : β) (e : α ≃ β) :
(e.trans (swap a b)).trans e.symm = swap (e.symm a) (e.symm b) :=
symm_trans_swap_trans a b e.symm
@[simp]
theorem swap_apply_self (i j a : α) : swap i j (swap i j a) = a := by
rw [← Equiv.trans_apply, Equiv.swap_swap, Equiv.refl_apply]
/-- A function is invariant to a swap if it is equal at both elements -/
theorem apply_swap_eq_self {v : α → β} {i j : α} (hv : v i = v j) (k : α) :
v (swap i j k) = v k := by
by_cases hi : k = i
· rw [hi, swap_apply_left, hv]
by_cases hj : k = j
· rw [hj, swap_apply_right, hv]
rw [swap_apply_of_ne_of_ne hi hj]
theorem swap_apply_eq_iff {x y z w : α} : swap x y z = w ↔ z = swap x y w := by
rw [apply_eq_iff_eq_symm_apply, symm_swap]
theorem swap_apply_ne_self_iff {a b x : α} : swap a b x ≠ x ↔ a ≠ b ∧ (x = a ∨ x = b) := by
by_cases hab : a = b
· simp [hab]
by_cases hax : x = a
· simp [hax, eq_comm]
by_cases hbx : x = b
· simp [hbx]
simp [hab, hax, hbx, swap_apply_of_ne_of_ne]
namespace Perm
@[simp]
theorem sumCongr_swap_refl {α β : Sort _} [DecidableEq α] [DecidableEq β] (i j : α) :
Equiv.Perm.sumCongr (Equiv.swap i j) (Equiv.refl β) = Equiv.swap (Sum.inl i) (Sum.inl j) := by
ext x
cases x
· simp only [Equiv.sumCongr_apply, Sum.map, coe_refl, comp_id, Sum.elim_inl, comp_apply,
swap_apply_def, Sum.inl.injEq]
split_ifs <;> rfl
· simp [Sum.map, swap_apply_of_ne_of_ne]
@[simp]
theorem sumCongr_refl_swap {α β : Sort _} [DecidableEq α] [DecidableEq β] (i j : β) :
Equiv.Perm.sumCongr (Equiv.refl α) (Equiv.swap i j) = Equiv.swap (Sum.inr i) (Sum.inr j) := by
ext x
cases x
· simp [Sum.map, swap_apply_of_ne_of_ne]
· simp only [Equiv.sumCongr_apply, Sum.map, coe_refl, comp_id, Sum.elim_inr, comp_apply,
swap_apply_def, Sum.inr.injEq]
split_ifs <;> rfl
end Perm
/-- Augment an equivalence with a prescribed mapping `f a = b` -/
def setValue (f : α ≃ β) (a : α) (b : β) : α ≃ β :=
(swap a (f.symm b)).trans f
@[simp]
theorem setValue_eq (f : α ≃ β) (a : α) (b : β) : setValue f a b a = b := by
simp [setValue, swap_apply_left]
end Swap
end Equiv
namespace Function.Involutive
/-- Convert an involutive function `f` to a permutation with `toFun = invFun = f`. -/
def toPerm (f : α → α) (h : Involutive f) : Equiv.Perm α :=
⟨f, f, h.leftInverse, h.rightInverse⟩
@[simp]
theorem coe_toPerm {f : α → α} (h : Involutive f) : (h.toPerm f : α → α) = f :=
rfl
@[simp]
theorem toPerm_symm {f : α → α} (h : Involutive f) : (h.toPerm f).symm = h.toPerm f :=
rfl
theorem toPerm_involutive {f : α → α} (h : Involutive f) : Involutive (h.toPerm f) :=
h
theorem symm_eq_self_of_involutive (f : Equiv.Perm α) (h : Involutive f) : f.symm = f :=
DFunLike.coe_injective (h.leftInverse_iff.mp f.left_inv)
end Function.Involutive
theorem PLift.eq_up_iff_down_eq {x : PLift α} {y : α} : x = PLift.up y ↔ x.down = y :=
Equiv.plift.eq_symm_apply
theorem Function.Injective.map_swap [DecidableEq α] [DecidableEq β] {f : α → β}
(hf : Function.Injective f) (x y z : α) :
f (Equiv.swap x y z) = Equiv.swap (f x) (f y) (f z) := by
conv_rhs => rw [Equiv.swap_apply_def]
split_ifs with h₁ h₂
· rw [hf h₁, Equiv.swap_apply_left]
· rw [hf h₂, Equiv.swap_apply_right]
· rw [Equiv.swap_apply_of_ne_of_ne (mt (congr_arg f) h₁) (mt (congr_arg f) h₂)]
namespace Equiv
section
/-- Transport dependent functions through an equivalence of the base space.
-/
@[simps apply, simps -isSimp symm_apply]
def piCongrLeft' (P : α → Sort*) (e : α ≃ β) : (∀ a, P a) ≃ ∀ b, P (e.symm b) where
toFun f x := f (e.symm x)
invFun f x := (e.symm_apply_apply x).ndrec (f (e x))
left_inv f := funext fun x =>
(by rintro _ rfl; rfl : ∀ {y} (h : y = x), h.ndrec (f y) = f x) (e.symm_apply_apply x)
right_inv f := funext fun x =>
(by rintro _ rfl; rfl : ∀ {y} (h : y = x), (congr_arg e.symm h).ndrec (f y) = f x)
(e.apply_symm_apply x)
/-- Note: the "obvious" statement `(piCongrLeft' P e).symm g a = g (e a)` doesn't typecheck: the
LHS would have type `P a` while the RHS would have type `P (e.symm (e a))`. For that reason,
we have to explicitly substitute along `e.symm (e a) = a` in the statement of this lemma. -/
add_decl_doc Equiv.piCongrLeft'_symm_apply
/-- This lemma is impractical to state in the dependent case. -/
@[simp]
theorem piCongrLeft'_symm (P : Sort*) (e : α ≃ β) :
(piCongrLeft' (fun _ => P) e).symm = piCongrLeft' _ e.symm := by ext; simp [piCongrLeft']
/-- Note: the "obvious" statement `(piCongrLeft' P e).symm g a = g (e a)` doesn't typecheck: the
LHS would have type `P a` while the RHS would have type `P (e.symm (e a))`. This lemma is a way
around it in the case where `a` is of the form `e.symm b`, so we can use `g b` instead of
`g (e (e.symm b))`. -/
@[simp]
lemma piCongrLeft'_symm_apply_apply (P : α → Sort*) (e : α ≃ β) (g : ∀ b, P (e.symm b)) (b : β) :
(piCongrLeft' P e).symm g (e.symm b) = g b := by
rw [piCongrLeft'_symm_apply, ← heq_iff_eq, rec_heq_iff_heq]
exact congr_arg_heq _ (e.apply_symm_apply _)
end
section
variable (P : β → Sort w) (e : α ≃ β)
/-- Transporting dependent functions through an equivalence of the base,
expressed as a "simplification".
-/
def piCongrLeft : (∀ a, P (e a)) ≃ ∀ b, P b :=
(piCongrLeft' P e.symm).symm
/-- Note: the "obvious" statement `(piCongrLeft P e) f b = f (e.symm b)` doesn't typecheck: the
LHS would have type `P b` while the RHS would have type `P (e (e.symm b))`. For that reason,
we have to explicitly substitute along `e (e.symm b) = b` in the statement of this lemma. -/
@[simp]
lemma piCongrLeft_apply (f : ∀ a, P (e a)) (b : β) :
(piCongrLeft P e) f b = e.apply_symm_apply b ▸ f (e.symm b) :=
rfl
@[simp]
lemma piCongrLeft_symm_apply (g : ∀ b, P b) (a : α) :
(piCongrLeft P e).symm g a = g (e a) :=
piCongrLeft'_apply P e.symm g a
/-- Note: the "obvious" statement `(piCongrLeft P e) f b = f (e.symm b)` doesn't typecheck: the
LHS would have type `P b` while the RHS would have type `P (e (e.symm b))`. This lemma is a way
around it in the case where `b` is of the form `e a`, so we can use `f a` instead of
`f (e.symm (e a))`. -/
lemma piCongrLeft_apply_apply (f : ∀ a, P (e a)) (a : α) :
(piCongrLeft P e) f (e a) = f a :=
piCongrLeft'_symm_apply_apply P e.symm f a
open Sum
lemma piCongrLeft_apply_eq_cast {P : β → Sort v} {e : α ≃ β}
(f : (a : α) → P (e a)) (b : β) :
piCongrLeft P e f b = cast (congr_arg P (e.apply_symm_apply b)) (f (e.symm b)) :=
Eq.rec_eq_cast _ _
theorem piCongrLeft_sumInl {ι ι' ι''} (π : ι'' → Type*) (e : ι ⊕ ι' ≃ ι'') (f : ∀ i, π (e (inl i)))
(g : ∀ i, π (e (inr i))) (i : ι) :
piCongrLeft π e (sumPiEquivProdPi (fun x => π (e x)) |>.symm (f, g)) (e (inl i)) = f i := by
simp_rw [piCongrLeft_apply_eq_cast, sumPiEquivProdPi_symm_apply,
sum_rec_congr _ _ _ (e.symm_apply_apply (inl i)), cast_cast, cast_eq]
theorem piCongrLeft_sumInr {ι ι' ι''} (π : ι'' → Type*) (e : ι ⊕ ι' ≃ ι'') (f : ∀ i, π (e (inl i)))
(g : ∀ i, π (e (inr i))) (j : ι') :
piCongrLeft π e (sumPiEquivProdPi (fun x => π (e x)) |>.symm (f, g)) (e (inr j)) = g j := by
simp_rw [piCongrLeft_apply_eq_cast, sumPiEquivProdPi_symm_apply,
sum_rec_congr _ _ _ (e.symm_apply_apply (inr j)), cast_cast, cast_eq]
@[deprecated (since := "2025-02-21")] alias piCongrLeft_sum_inl := piCongrLeft_sumInl
@[deprecated (since := "2025-02-21")] alias piCongrLeft_sum_inr := piCongrLeft_sumInr
end
section
variable {W : α → Sort w} {Z : β → Sort z} (h₁ : α ≃ β) (h₂ : ∀ a : α, W a ≃ Z (h₁ a))
/-- Transport dependent functions through
an equivalence of the base spaces and a family
of equivalences of the matching fibers.
-/
def piCongr : (∀ a, W a) ≃ ∀ b, Z b :=
(Equiv.piCongrRight h₂).trans (Equiv.piCongrLeft _ h₁)
@[simp]
theorem coe_piCongr_symm : ((h₁.piCongr h₂).symm :
(∀ b, Z b) → ∀ a, W a) = fun f a => (h₂ a).symm (f (h₁ a)) :=
rfl
theorem piCongr_symm_apply (f : ∀ b, Z b) :
(h₁.piCongr h₂).symm f = fun a => (h₂ a).symm (f (h₁ a)) :=
rfl
@[simp]
theorem piCongr_apply_apply (f : ∀ a, W a) (a : α) : h₁.piCongr h₂ f (h₁ a) = h₂ a (f a) := by
simp only [piCongr, piCongrRight, trans_apply, coe_fn_mk, piCongrLeft_apply_apply, Pi.map_apply]
end
section
variable {W : α → Sort w} {Z : β → Sort z} (h₁ : α ≃ β) (h₂ : ∀ b : β, W (h₁.symm b) ≃ Z b)
/-- Transport dependent functions through
an equivalence of the base spaces and a family
of equivalences of the matching fibres.
-/
def piCongr' : (∀ a, W a) ≃ ∀ b, Z b :=
(piCongr h₁.symm fun b => (h₂ b).symm).symm
@[simp]
theorem coe_piCongr' :
(h₁.piCongr' h₂ : (∀ a, W a) → ∀ b, Z b) = fun f b => h₂ b <| f <| h₁.symm b :=
rfl
theorem piCongr'_apply (f : ∀ a, W a) : h₁.piCongr' h₂ f = fun b => h₂ b <| f <| h₁.symm b :=
rfl
@[simp]
theorem piCongr'_symm_apply_symm_apply (f : ∀ b, Z b) (b : β) :
(h₁.piCongr' h₂).symm f (h₁.symm b) = (h₂ b).symm (f b) := by
simp [piCongr', piCongr_apply_apply]
end
/-- Transport dependent functions through an equality of sets. -/
@[simps!] def piCongrSet {α} {W : α → Sort w} {s t : Set α} (h : s = t) :
(∀ i : {i // i ∈ s}, W i) ≃ (∀ i : {i // i ∈ t}, W i) where
toFun f i := f ⟨i, h ▸ i.2⟩
invFun f i := f ⟨i, h.symm ▸ i.2⟩
left_inv f := rfl
right_inv f := rfl
section BinaryOp
variable {α₁ β₁ : Type*} (e : α₁ ≃ β₁) (f : α₁ → α₁ → α₁)
theorem semiconj_conj (f : α₁ → α₁) : Semiconj e f (e.conj f) := fun x => by simp
theorem semiconj₂_conj : Semiconj₂ e f (e.arrowCongr e.conj f) := fun x y => by simp [arrowCongr]
instance [Std.Associative f] : Std.Associative (e.arrowCongr (e.arrowCongr e) f) :=
(e.semiconj₂_conj f).isAssociative_right e.surjective
instance [Std.IdempotentOp f] : Std.IdempotentOp (e.arrowCongr (e.arrowCongr e) f) :=
(e.semiconj₂_conj f).isIdempotent_right e.surjective
end BinaryOp
section ULift
@[simp]
theorem ulift_symm_down {α} (x : α) : (Equiv.ulift.{u, v}.symm x).down = x :=
rfl
end ULift
end Equiv
theorem Function.Injective.swap_apply
[DecidableEq α] [DecidableEq β] {f : α → β} (hf : Function.Injective f) (x y z : α) :
Equiv.swap (f x) (f y) (f z) = f (Equiv.swap x y z) := by
by_cases hx : z = x
· simp [hx]
by_cases hy : z = y
· simp [hy]
rw [Equiv.swap_apply_of_ne_of_ne hx hy, Equiv.swap_apply_of_ne_of_ne (hf.ne hx) (hf.ne hy)]
theorem Function.Injective.swap_comp
[DecidableEq α] [DecidableEq β] {f : α → β} (hf : Function.Injective f) (x y : α) :
Equiv.swap (f x) (f y) ∘ f = f ∘ Equiv.swap x y :=
funext fun _ => hf.swap_apply _ _ _
/-- To give an equivalence between two subsingleton types, it is sufficient to give any two
functions between them. -/
def equivOfSubsingletonOfSubsingleton [Subsingleton α] [Subsingleton β] (f : α → β) (g : β → α) :
α ≃ β where
toFun := f
invFun := g
left_inv _ := Subsingleton.elim _ _
right_inv _ := Subsingleton.elim _ _
/-- A nonempty subsingleton type is (noncomputably) equivalent to `PUnit`. -/
noncomputable def Equiv.punitOfNonemptyOfSubsingleton [h : Nonempty α] [Subsingleton α] :
α ≃ PUnit :=
equivOfSubsingletonOfSubsingleton (fun _ => PUnit.unit) fun _ => h.some
/-- `Unique (Unique α)` is equivalent to `Unique α`. -/
def uniqueUniqueEquiv : Unique (Unique α) ≃ Unique α :=
equivOfSubsingletonOfSubsingleton (fun h => h.default) fun h =>
{ default := h, uniq := fun _ => Subsingleton.elim _ _ }
/-- If `Unique β`, then `Unique α` is equivalent to `α ≃ β`. -/
def uniqueEquivEquivUnique (α : Sort u) (β : Sort v) [Unique β] : Unique α ≃ (α ≃ β) :=
equivOfSubsingletonOfSubsingleton (fun _ => Equiv.ofUnique _ _) Equiv.unique
namespace Function
variable {α' : Sort*}
theorem update_comp_equiv [DecidableEq α'] [DecidableEq α] (f : α → β)
(g : α' ≃ α) (a : α) (v : β) :
update f a v ∘ g = update (f ∘ g) (g.symm a) v := by
rw [← update_comp_eq_of_injective _ g.injective, g.apply_symm_apply]
theorem update_apply_equiv_apply [DecidableEq α'] [DecidableEq α] (f : α → β)
(g : α' ≃ α) (a : α) (v : β) (a' : α') : update f a v (g a') = update (f ∘ g) (g.symm a) v a' :=
congr_fun (update_comp_equiv f g a v) a'
theorem piCongrLeft'_update [DecidableEq α] [DecidableEq β] (P : α → Sort*) (e : α ≃ β)
(f : ∀ a, P a) (b : β) (x : P (e.symm b)) :
e.piCongrLeft' P (update f (e.symm b) x) = update (e.piCongrLeft' P f) b x := by
ext b'
rcases eq_or_ne b' b with (rfl | h) <;> simp_all
theorem piCongrLeft'_symm_update [DecidableEq α] [DecidableEq β] (P : α → Sort*) (e : α ≃ β)
(f : ∀ b, P (e.symm b)) (b : β) (x : P (e.symm b)) :
(e.piCongrLeft' P).symm (update f b x) = update ((e.piCongrLeft' P).symm f) (e.symm b) x := by
simp [(e.piCongrLeft' P).symm_apply_eq, piCongrLeft'_update]
end Function
| Mathlib/Logic/Equiv/Basic.lean | 1,647 | 1,648 | |
/-
Copyright (c) 2022 Heather Macbeth. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Heather Macbeth
-/
import Mathlib.Analysis.InnerProductSpace.Projection
import Mathlib.Analysis.Normed.Lp.lpSpace
import Mathlib.Analysis.InnerProductSpace.PiL2
/-!
# Hilbert sum of a family of inner product spaces
Given a family `(G : ι → Type*) [Π i, InnerProductSpace 𝕜 (G i)]` of inner product spaces, this
file equips `lp G 2` with an inner product space structure, where `lp G 2` consists of those
dependent functions `f : Π i, G i` for which `∑' i, ‖f i‖ ^ 2`, the sum of the norms-squared, is
summable. This construction is sometimes called the *Hilbert sum* of the family `G`. By choosing
`G` to be `ι → 𝕜`, the Hilbert space `ℓ²(ι, 𝕜)` may be seen as a special case of this construction.
We also define a *predicate* `IsHilbertSum 𝕜 G V`, where `V : Π i, G i →ₗᵢ[𝕜] E`, expressing that
`V` is an `OrthogonalFamily` and that the associated map `lp G 2 →ₗᵢ[𝕜] E` is surjective.
## Main definitions
* `OrthogonalFamily.linearIsometry`: Given a Hilbert space `E`, a family `G` of inner product
spaces and a family `V : Π i, G i →ₗᵢ[𝕜] E` of isometric embeddings of the `G i` into `E` with
mutually-orthogonal images, there is an induced isometric embedding of the Hilbert sum of `G`
into `E`.
* `IsHilbertSum`: Given a Hilbert space `E`, a family `G` of inner product
spaces and a family `V : Π i, G i →ₗᵢ[𝕜] E` of isometric embeddings of the `G i` into `E`,
`IsHilbertSum 𝕜 G V` means that `V` is an `OrthogonalFamily` and that the above
linear isometry is surjective.
* `IsHilbertSum.linearIsometryEquiv`: If a Hilbert space `E` is a Hilbert sum of the
inner product spaces `G i` with respect to the family `V : Π i, G i →ₗᵢ[𝕜] E`, then the
corresponding `OrthogonalFamily.linearIsometry` can be upgraded to a `LinearIsometryEquiv`.
* `HilbertBasis`: We define a *Hilbert basis* of a Hilbert space `E` to be a structure whose single
field `HilbertBasis.repr` is an isometric isomorphism of `E` with `ℓ²(ι, 𝕜)` (i.e., the Hilbert
sum of `ι` copies of `𝕜`). This parallels the definition of `Basis`, in `LinearAlgebra.Basis`,
as an isomorphism of an `R`-module with `ι →₀ R`.
* `HilbertBasis.instCoeFun`: More conventionally a Hilbert basis is thought of as a family
`ι → E` of vectors in `E` satisfying certain properties (orthonormality, completeness). We obtain
this interpretation of a Hilbert basis `b` by defining `⇑b`, of type `ι → E`, to be the image
under `b.repr` of `lp.single 2 i (1:𝕜)`. This parallels the definition `Basis.coeFun` in
`LinearAlgebra.Basis`.
* `HilbertBasis.mk`: Make a Hilbert basis of `E` from an orthonormal family `v : ι → E` of vectors
in `E` whose span is dense. This parallels the definition `Basis.mk` in `LinearAlgebra.Basis`.
* `HilbertBasis.mkOfOrthogonalEqBot`: Make a Hilbert basis of `E` from an orthonormal family
`v : ι → E` of vectors in `E` whose span has trivial orthogonal complement.
## Main results
* `lp.instInnerProductSpace`: Construction of the inner product space instance on the Hilbert sum
`lp G 2`. Note that from the file `Analysis.Normed.Lp.lpSpace`, the space `lp G 2` already
held a normed space instance (`lp.normedSpace`), and if each `G i` is a Hilbert space (i.e.,
complete), then `lp G 2` was already known to be complete (`lp.completeSpace`). So the work
here is to define the inner product and show it is compatible.
* `OrthogonalFamily.range_linearIsometry`: Given a family `G` of inner product spaces and a family
`V : Π i, G i →ₗᵢ[𝕜] E` of isometric embeddings of the `G i` into `E` with mutually-orthogonal
images, the image of the embedding `OrthogonalFamily.linearIsometry` of the Hilbert sum of `G`
into `E` is the closure of the span of the images of the `G i`.
* `HilbertBasis.repr_apply_apply`: Given a Hilbert basis `b` of `E`, the entry `b.repr x i` of
`x`'s representation in `ℓ²(ι, 𝕜)` is the inner product `⟪b i, x⟫`.
* `HilbertBasis.hasSum_repr`: Given a Hilbert basis `b` of `E`, a vector `x` in `E` can be
expressed as the "infinite linear combination" `∑' i, b.repr x i • b i` of the basis vectors
`b i`, with coefficients given by the entries `b.repr x i` of `x`'s representation in `ℓ²(ι, 𝕜)`.
* `exists_hilbertBasis`: A Hilbert space admits a Hilbert basis.
## Keywords
Hilbert space, Hilbert sum, l2, Hilbert basis, unitary equivalence, isometric isomorphism
-/
open RCLike Submodule Filter
open scoped NNReal ENNReal ComplexConjugate Topology
noncomputable section
variable {ι 𝕜 : Type*} [RCLike 𝕜] {E : Type*}
variable [NormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable {G : ι → Type*} [∀ i, NormedAddCommGroup (G i)] [∀ i, InnerProductSpace 𝕜 (G i)]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-- `ℓ²(ι, 𝕜)` is the Hilbert space of square-summable functions `ι → 𝕜`, herein implemented
as `lp (fun i : ι => 𝕜) 2`. -/
notation "ℓ²(" ι ", " 𝕜 ")" => lp (fun i : ι => 𝕜) 2
/-! ### Inner product space structure on `lp G 2` -/
namespace lp
theorem summable_inner (f g : lp G 2) : Summable fun i => ⟪f i, g i⟫ := by
-- Apply the Direct Comparison Test, comparing with ∑' i, ‖f i‖ * ‖g i‖ (summable by Hölder)
refine .of_norm_bounded (fun i => ‖f i‖ * ‖g i‖) (lp.summable_mul ?_ f g) ?_
· rw [Real.holderConjugate_iff]; norm_num
intro i
-- Then apply Cauchy-Schwarz pointwise
exact norm_inner_le_norm (𝕜 := 𝕜) _ _
instance instInnerProductSpace : InnerProductSpace 𝕜 (lp G 2) :=
{ lp.normedAddCommGroup (E := G) (p := 2) with
inner := fun f g => ∑' i, ⟪f i, g i⟫
norm_sq_eq_re_inner := fun f => by
calc
‖f‖ ^ 2 = ‖f‖ ^ (2 : ℝ≥0∞).toReal := by norm_cast
_ = ∑' i, ‖f i‖ ^ (2 : ℝ≥0∞).toReal := lp.norm_rpow_eq_tsum ?_ f
_ = ∑' i, ‖f i‖ ^ (2 : ℕ) := by norm_cast
_ = ∑' i, re ⟪f i, f i⟫ := by simp [norm_sq_eq_re_inner (𝕜 := 𝕜)]
_ = re (∑' i, ⟪f i, f i⟫) := (RCLike.reCLM.map_tsum ?_).symm
· norm_num
· exact summable_inner f f
conj_inner_symm := fun f g => by
calc
conj _ = conj (∑' i, ⟪g i, f i⟫) := by congr
_ = ∑' i, conj ⟪g i, f i⟫ := RCLike.conjCLE.map_tsum
_ = ∑' i, ⟪f i, g i⟫ := by simp only [inner_conj_symm]
_ = _ := by congr
add_left := fun f₁ f₂ g => by
calc
_ = ∑' i, ⟪(f₁ + f₂) i, g i⟫ := ?_
_ = ∑' i, (⟪f₁ i, g i⟫ + ⟪f₂ i, g i⟫) := by
simp only [inner_add_left, Pi.add_apply, coeFn_add]
_ = (∑' i, ⟪f₁ i, g i⟫) + ∑' i, ⟪f₂ i, g i⟫ := Summable.tsum_add ?_ ?_
_ = _ := by congr
· congr
· exact summable_inner f₁ g
· exact summable_inner f₂ g
smul_left := fun f g c => by
calc
_ = ∑' i, ⟪c • f i, g i⟫ := ?_
_ = ∑' i, conj c * ⟪f i, g i⟫ := by simp only [inner_smul_left]
_ = conj c * ∑' i, ⟪f i, g i⟫ := tsum_mul_left
_ = _ := ?_
· simp only [coeFn_smul, Pi.smul_apply]
· congr }
theorem inner_eq_tsum (f g : lp G 2) : ⟪f, g⟫ = ∑' i, ⟪f i, g i⟫ :=
rfl
theorem hasSum_inner (f g : lp G 2) : HasSum (fun i => ⟪f i, g i⟫) ⟪f, g⟫ :=
(summable_inner f g).hasSum
theorem inner_single_left [DecidableEq ι] (i : ι) (a : G i) (f : lp G 2) :
⟪lp.single 2 i a, f⟫ = ⟪a, f i⟫ := by
refine (hasSum_inner (lp.single 2 i a) f).unique ?_
simp_rw [lp.coeFn_single]
convert hasSum_ite_eq i ⟪a, f i⟫ using 1
ext j
split_ifs with h
· subst h; rw [Pi.single_eq_same]
· simp [Pi.single_eq_of_ne h]
theorem inner_single_right [DecidableEq ι] (i : ι) (a : G i) (f : lp G 2) :
⟪f, lp.single 2 i a⟫ = ⟪f i, a⟫ := by
simpa [inner_conj_symm] using congr_arg conj (inner_single_left (𝕜 := 𝕜) i a f)
end lp
/-! ### Identification of a general Hilbert space `E` with a Hilbert sum -/
namespace OrthogonalFamily
variable [CompleteSpace E] {V : ∀ i, G i →ₗᵢ[𝕜] E} (hV : OrthogonalFamily 𝕜 G V)
include hV
protected theorem summable_of_lp (f : lp G 2) :
Summable fun i => V i (f i) := by
rw [hV.summable_iff_norm_sq_summable]
convert (lp.memℓp f).summable _
· norm_cast
· norm_num
/-- A mutually orthogonal family of subspaces of `E` induce a linear isometry from `lp 2` of the
subspaces into `E`. -/
protected def linearIsometry (hV : OrthogonalFamily 𝕜 G V) : lp G 2 →ₗᵢ[𝕜] E where
toFun f := ∑' i, V i (f i)
map_add' f g := by
simp only [(hV.summable_of_lp f).tsum_add (hV.summable_of_lp g), lp.coeFn_add, Pi.add_apply,
LinearIsometry.map_add]
map_smul' c f := by
simpa only [LinearIsometry.map_smul, Pi.smul_apply, lp.coeFn_smul] using
(hV.summable_of_lp f).tsum_const_smul c
norm_map' f := by
classical
-- needed for lattice instance on `Finset ι`, for `Filter.atTop_neBot`
have H : 0 < (2 : ℝ≥0∞).toReal := by norm_num
suffices ‖∑' i : ι, V i (f i)‖ ^ (2 : ℝ≥0∞).toReal = ‖f‖ ^ (2 : ℝ≥0∞).toReal by
exact Real.rpow_left_injOn H.ne' (norm_nonneg _) (norm_nonneg _) this
refine tendsto_nhds_unique ?_ (lp.hasSum_norm H f)
convert (hV.summable_of_lp f).hasSum.norm.rpow_const (Or.inr H.le) using 1
ext s
exact mod_cast (hV.norm_sum f s).symm
protected theorem linearIsometry_apply (f : lp G 2) : hV.linearIsometry f = ∑' i, V i (f i) :=
rfl
protected theorem hasSum_linearIsometry (f : lp G 2) :
HasSum (fun i => V i (f i)) (hV.linearIsometry f) :=
(hV.summable_of_lp f).hasSum
@[simp]
protected theorem linearIsometry_apply_single [DecidableEq ι] {i : ι} (x : G i) :
hV.linearIsometry (lp.single 2 i x) = V i x := by
rw [hV.linearIsometry_apply, ← tsum_ite_eq i (V i x)]
congr
ext j
rw [lp.single_apply]
split_ifs with h
· subst h; simp
· simp [h]
protected theorem linearIsometry_apply_dfinsupp_sum_single [DecidableEq ι] [∀ i, DecidableEq (G i)]
(W₀ : Π₀ i : ι, G i) : hV.linearIsometry (W₀.sum (lp.single 2)) = W₀.sum fun i => V i := by
simp
/-- The canonical linear isometry from the `lp 2` of a mutually orthogonal family of subspaces of
`E` into E, has range the closure of the span of the subspaces. -/
protected theorem range_linearIsometry [∀ i, CompleteSpace (G i)] :
LinearMap.range hV.linearIsometry.toLinearMap =
(⨆ i, LinearMap.range (V i).toLinearMap).topologicalClosure := by
classical
refine le_antisymm ?_ ?_
· rintro x ⟨f, rfl⟩
refine mem_closure_of_tendsto (hV.hasSum_linearIsometry f) (Eventually.of_forall ?_)
intro s
rw [SetLike.mem_coe]
refine sum_mem ?_
intro i _
refine mem_iSup_of_mem i ?_
exact LinearMap.mem_range_self _ (f i)
· apply topologicalClosure_minimal
· refine iSup_le ?_
rintro i x ⟨x, rfl⟩
use lp.single 2 i x
exact hV.linearIsometry_apply_single x
exact hV.linearIsometry.isometry.isUniformInducing.isComplete_range.isClosed
end OrthogonalFamily
section IsHilbertSum
variable (𝕜 G)
variable [CompleteSpace E] (V : ∀ i, G i →ₗᵢ[𝕜] E) (F : ι → Submodule 𝕜 E)
/-- Given a family of Hilbert spaces `G : ι → Type*`, a Hilbert sum of `G` consists of a Hilbert
space `E` and an orthogonal family `V : Π i, G i →ₗᵢ[𝕜] E` such that the induced isometry
`Φ : lp G 2 → E` is surjective.
Keeping in mind that `lp G 2` is "the" external Hilbert sum of `G : ι → Type*`, this is analogous
to `DirectSum.IsInternal`, except that we don't express it in terms of actual submodules. -/
structure IsHilbertSum : Prop where
ofSurjective ::
/-- The orthogonal family constituting the summands in the Hilbert sum. -/
protected OrthogonalFamily : OrthogonalFamily 𝕜 G V
/-- The isometry `lp G 2 → E` induced by the orthogonal family is surjective. -/
protected surjective_isometry : Function.Surjective OrthogonalFamily.linearIsometry
variable {𝕜 G V}
/-- If `V : Π i, G i →ₗᵢ[𝕜] E` is an orthogonal family such that the supremum of the ranges of
`V i` is dense, then `(E, V)` is a Hilbert sum of `G`. -/
theorem IsHilbertSum.mk [∀ i, CompleteSpace <| G i] (hVortho : OrthogonalFamily 𝕜 G V)
(hVtotal : ⊤ ≤ (⨆ i, LinearMap.range (V i).toLinearMap).topologicalClosure) :
IsHilbertSum 𝕜 G V :=
{ OrthogonalFamily := hVortho
surjective_isometry := by
rw [← LinearIsometry.coe_toLinearMap]
exact LinearMap.range_eq_top.mp
(eq_top_iff.mpr <| hVtotal.trans_eq hVortho.range_linearIsometry.symm) }
/-- This is `Orthonormal.isHilbertSum` in the case of actual inclusions from subspaces. -/
theorem IsHilbertSum.mkInternal [∀ i, CompleteSpace <| F i]
(hFortho : OrthogonalFamily 𝕜 (fun i => F i) fun i => (F i).subtypeₗᵢ)
(hFtotal : ⊤ ≤ (⨆ i, F i).topologicalClosure) :
IsHilbertSum 𝕜 (fun i => F i) fun i => (F i).subtypeₗᵢ :=
IsHilbertSum.mk hFortho (by simpa [subtypeₗᵢ_toLinearMap, range_subtype] using hFtotal)
/-- *A* Hilbert sum `(E, V)` of `G` is canonically isomorphic to *the* Hilbert sum of `G`,
i.e `lp G 2`.
Note that this goes in the opposite direction from `OrthogonalFamily.linearIsometry`. -/
noncomputable def IsHilbertSum.linearIsometryEquiv (hV : IsHilbertSum 𝕜 G V) : E ≃ₗᵢ[𝕜] lp G 2 :=
LinearIsometryEquiv.symm <|
LinearIsometryEquiv.ofSurjective hV.OrthogonalFamily.linearIsometry hV.surjective_isometry
/-- In the canonical isometric isomorphism between a Hilbert sum `E` of `G` and `lp G 2`,
a vector `w : lp G 2` is the image of the infinite sum of the associated elements in `E`. -/
protected theorem IsHilbertSum.linearIsometryEquiv_symm_apply (hV : IsHilbertSum 𝕜 G V)
(w : lp G 2) : hV.linearIsometryEquiv.symm w = ∑' i, V i (w i) := by
simp [IsHilbertSum.linearIsometryEquiv, OrthogonalFamily.linearIsometry_apply]
/-- In the canonical isometric isomorphism between a Hilbert sum `E` of `G` and `lp G 2`,
a vector `w : lp G 2` is the image of the infinite sum of the associated elements in `E`, and this
sum indeed converges. -/
protected theorem IsHilbertSum.hasSum_linearIsometryEquiv_symm (hV : IsHilbertSum 𝕜 G V)
(w : lp G 2) : HasSum (fun i => V i (w i)) (hV.linearIsometryEquiv.symm w) := by
simp [IsHilbertSum.linearIsometryEquiv, OrthogonalFamily.hasSum_linearIsometry]
/-- In the canonical isometric isomorphism between a Hilbert sum `E` of `G : ι → Type*` and
`lp G 2`, an "elementary basis vector" in `lp G 2` supported at `i : ι` is the image of the
associated element in `E`. -/
@[simp]
protected theorem IsHilbertSum.linearIsometryEquiv_symm_apply_single
[DecidableEq ι] (hV : IsHilbertSum 𝕜 G V) {i : ι} (x : G i) :
hV.linearIsometryEquiv.symm (lp.single 2 i x) = V i x := by
simp [IsHilbertSum.linearIsometryEquiv, OrthogonalFamily.linearIsometry_apply_single]
| /-- In the canonical isometric isomorphism between a Hilbert sum `E` of `G : ι → Type*` and
`lp G 2`, a finitely-supported vector in `lp G 2` is the image of the associated finite sum of
elements of `E`. -/
| Mathlib/Analysis/InnerProductSpace/l2Space.lean | 319 | 321 |
/-
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, Amelia Livingston, Yury Kudryashov,
Neil Strickland, Aaron Anderson
-/
import Mathlib.Algebra.GroupWithZero.Units.Basic
import Mathlib.Algebra.Divisibility.Units
import Mathlib.Data.Nat.Basic
/-!
# Divisibility in groups with zero.
Lemmas about divisibility in groups and monoids with zero.
-/
assert_not_exists DenselyOrdered
variable {α : Type*}
section SemigroupWithZero
variable [SemigroupWithZero α] {a : α}
theorem eq_zero_of_zero_dvd (h : 0 ∣ a) : a = 0 :=
Dvd.elim h fun c H' => H'.trans (zero_mul c)
/-- Given an element `a` of a commutative semigroup with zero, there exists another element whose
product with zero equals `a` iff `a` equals zero. -/
@[simp]
theorem zero_dvd_iff : 0 ∣ a ↔ a = 0 :=
⟨eq_zero_of_zero_dvd, fun h => by
rw [h]
exact ⟨0, by simp⟩⟩
@[simp]
theorem dvd_zero (a : α) : a ∣ 0 :=
Dvd.intro 0 (by simp)
end SemigroupWithZero
/-- Given two elements `b`, `c` of a `CancelMonoidWithZero` and a nonzero element `a`,
`a*b` divides `a*c` iff `b` divides `c`. -/
theorem mul_dvd_mul_iff_left [CancelMonoidWithZero α] {a b c : α} (ha : a ≠ 0) :
a * b ∣ a * c ↔ b ∣ c :=
exists_congr fun d => by rw [mul_assoc, mul_right_inj' ha]
/-- Given two elements `a`, `b` of a commutative `CancelMonoidWithZero` and a nonzero
element `c`, `a*c` divides `b*c` iff `a` divides `b`. -/
theorem mul_dvd_mul_iff_right [CancelCommMonoidWithZero α] {a b c : α} (hc : c ≠ 0) :
a * c ∣ b * c ↔ a ∣ b :=
exists_congr fun d => by rw [mul_right_comm, mul_left_inj' hc]
section CommMonoidWithZero
variable [CommMonoidWithZero α]
/-- `DvdNotUnit a b` expresses that `a` divides `b` "strictly", i.e. that `b` divided by `a`
is not a unit. -/
def DvdNotUnit (a b : α) : Prop :=
a ≠ 0 ∧ ∃ x, ¬IsUnit x ∧ b = a * x
theorem dvdNotUnit_of_dvd_of_not_dvd {a b : α} (hd : a ∣ b) (hnd : ¬b ∣ a) : DvdNotUnit a b := by
constructor
· rintro rfl
exact hnd (dvd_zero _)
· rcases hd with ⟨c, rfl⟩
refine ⟨c, ?_, rfl⟩
rintro ⟨u, rfl⟩
simp at hnd
variable {x y : α}
theorem isRelPrime_zero_left : IsRelPrime 0 x ↔ IsUnit x :=
⟨(· (dvd_zero _) dvd_rfl), IsUnit.isRelPrime_right⟩
theorem isRelPrime_zero_right : IsRelPrime x 0 ↔ IsUnit x :=
isRelPrime_comm.trans isRelPrime_zero_left
theorem not_isRelPrime_zero_zero [Nontrivial α] : ¬IsRelPrime (0 : α) 0 :=
mt isRelPrime_zero_right.mp not_isUnit_zero
theorem IsRelPrime.ne_zero_or_ne_zero [Nontrivial α] (h : IsRelPrime x y) : x ≠ 0 ∨ y ≠ 0 :=
not_or_of_imp <| by rintro rfl rfl; exact not_isRelPrime_zero_zero h
end CommMonoidWithZero
theorem isRelPrime_of_no_nonunits_factors [MonoidWithZero α] {x y : α} (nonzero : ¬(x = 0 ∧ y = 0))
(H : ∀ z, ¬ IsUnit z → z ≠ 0 → z ∣ x → ¬z ∣ y) : IsRelPrime x y := by
refine fun z hx hy ↦ by_contra fun h ↦ H z h ?_ hx hy
rintro rfl; exact nonzero ⟨zero_dvd_iff.1 hx, zero_dvd_iff.1 hy⟩
theorem dvd_and_not_dvd_iff [CancelCommMonoidWithZero α] {x y : α} :
x ∣ y ∧ ¬y ∣ x ↔ DvdNotUnit x y :=
⟨fun ⟨⟨d, hd⟩, hyx⟩ =>
⟨fun hx0 => by simp [hx0] at hyx,
⟨d, mt isUnit_iff_dvd_one.1 fun ⟨e, he⟩ => hyx ⟨e, by rw [hd, mul_assoc, ← he, mul_one]⟩,
hd⟩⟩,
fun ⟨hx0, d, hdu, hdx⟩ =>
⟨⟨d, hdx⟩, fun ⟨e, he⟩ =>
hdu
(isUnit_of_dvd_one
⟨e, mul_left_cancel₀ hx0 <| by conv =>
lhs
rw [he, hdx]
simp [mul_assoc]⟩)⟩⟩
section MonoidWithZero
variable [MonoidWithZero α]
theorem ne_zero_of_dvd_ne_zero {p q : α} (h₁ : q ≠ 0) (h₂ : p ∣ q) : p ≠ 0 := by
rcases h₂ with ⟨u, rfl⟩
exact left_ne_zero_of_mul h₁
theorem isPrimal_zero : IsPrimal (0 : α) :=
fun a b h ↦ ⟨a, b, dvd_rfl, dvd_rfl, (zero_dvd_iff.mp h).symm⟩
theorem IsPrimal.mul {α} [CancelCommMonoidWithZero α] {m n : α}
(hm : IsPrimal m) (hn : IsPrimal n) : IsPrimal (m * n) := by
obtain rfl | h0 := eq_or_ne m 0; · rwa [zero_mul]
intro b c h
obtain ⟨a₁, a₂, ⟨b, rfl⟩, ⟨c, rfl⟩, rfl⟩ := hm (dvd_of_mul_right_dvd h)
rw [mul_mul_mul_comm, mul_dvd_mul_iff_left h0] at h
obtain ⟨a₁', a₂', h₁, h₂, rfl⟩ := hn h
exact ⟨a₁ * a₁', a₂ * a₂', mul_dvd_mul_left _ h₁, mul_dvd_mul_left _ h₂, mul_mul_mul_comm _ _ _ _⟩
end MonoidWithZero
|
section CancelCommMonoidWithZero
variable [CancelCommMonoidWithZero α] {a b : α} {m n : ℕ}
section Subsingleton
variable [Subsingleton αˣ]
| Mathlib/Algebra/GroupWithZero/Divisibility.lean | 130 | 137 |
/-
Copyright (c) 2021 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Reid Barton, Yury Kudryashov
-/
import Mathlib.Data.Option.Basic
import Mathlib.Topology.Separation.Regular
/-!
# Paracompact topological spaces
A topological space `X` is said to be paracompact if every open covering of `X` admits a locally
finite refinement.
The definition requires that each set of the new covering is a subset of one of the sets of the
initial covering. However, one can ensure that each open covering `s : ι → Set X` admits a *precise*
locally finite refinement, i.e., an open covering `t : ι → Set X` with the same index set such that
`∀ i, t i ⊆ s i`, see lemma `precise_refinement`. We also provide a convenience lemma
`precise_refinement_set` that deals with open coverings of a closed subset of `X` instead of the
whole space.
We also prove the following facts.
* Every compact space is paracompact, see instance `paracompact_of_compact`.
* A locally compact sigma compact Hausdorff space is paracompact, see instance
`paracompact_of_locallyCompact_sigmaCompact`. Moreover, we can choose a locally finite
refinement with sets in a given collection of filter bases of `𝓝 x`, `x : X`, see
`refinement_of_locallyCompact_sigmaCompact_of_nhds_basis`. For example, in a proper metric space
every open covering `⋃ i, s i` admits a refinement `⋃ i, Metric.ball (c i) (r i)`.
* Every paracompact Hausdorff space is normal. This statement is not an instance to avoid loops in
the instance graph.
* Every `EMetricSpace` is a paracompact space, see instance `EMetric.instParacompactSpace` in
`Topology/EMetricSpace/Paracompact`.
## TODO
Prove (some of) [Michael's theorems](https://ncatlab.org/nlab/show/Michael%27s+theorem).
## Tags
compact space, paracompact space, locally finite covering
-/
open Set Filter Function
open Filter Topology
universe u v w
/-- A topological space is called paracompact, if every open covering of this space admits a locally
finite refinement. We use the same universe for all types in the definition to avoid creating a
class like `ParacompactSpace.{u v}`. Due to lemma `precise_refinement` below, every open covering
`s : α → Set X` indexed on `α : Type v` has a *precise* locally finite refinement, i.e., a locally
finite refinement `t : α → Set X` indexed on the same type such that each `∀ i, t i ⊆ s i`. -/
class ParacompactSpace (X : Type v) [TopologicalSpace X] : Prop where
/-- Every open cover of a paracompact space assumes a locally finite refinement. -/
locallyFinite_refinement :
∀ (α : Type v) (s : α → Set X), (∀ a, IsOpen (s a)) → (⋃ a, s a = univ) →
∃ (β : Type v) (t : β → Set X),
(∀ b, IsOpen (t b)) ∧ (⋃ b, t b = univ) ∧ LocallyFinite t ∧ ∀ b, ∃ a, t b ⊆ s a
variable {ι : Type u} {X : Type v} {Y : Type w} [TopologicalSpace X] [TopologicalSpace Y]
/-- Any open cover of a paracompact space has a locally finite *precise* refinement, that is,
one indexed on the same type with each open set contained in the corresponding original one. -/
theorem precise_refinement [ParacompactSpace X] (u : ι → Set X) (uo : ∀ a, IsOpen (u a))
(uc : ⋃ i, u i = univ) : ∃ v : ι → Set X, (∀ a, IsOpen (v a)) ∧ ⋃ i, v i = univ ∧
LocallyFinite v ∧ ∀ a, v a ⊆ u a := by
-- Apply definition to `range u`, then turn existence quantifiers into functions using `choose`
have := ParacompactSpace.locallyFinite_refinement (range u) (fun r ↦ (r : Set X))
(forall_subtype_range_iff.2 uo) (by rwa [← sUnion_range, Subtype.range_coe])
simp only [exists_subtype_range_iff, iUnion_eq_univ_iff] at this
choose α t hto hXt htf ind hind using this
choose t_inv ht_inv using hXt
choose U hxU hU using htf
-- Send each `i` to the union of `t a` over `a ∈ ind ⁻¹' {i}`
refine ⟨fun i ↦ ⋃ (a : α) (_ : ind a = i), t a, ?_, ?_, ?_, ?_⟩
· exact fun a ↦ isOpen_iUnion fun a ↦ isOpen_iUnion fun _ ↦ hto a
· simp only [eq_univ_iff_forall, mem_iUnion]
exact fun x ↦ ⟨ind (t_inv x), _, rfl, ht_inv _⟩
· refine fun x ↦ ⟨U x, hxU x, ((hU x).image ind).subset ?_⟩
simp only [subset_def, mem_iUnion, mem_setOf_eq, Set.Nonempty, mem_inter_iff]
rintro i ⟨y, ⟨a, rfl, hya⟩, hyU⟩
exact mem_image_of_mem _ ⟨y, hya, hyU⟩
· simp only [subset_def, mem_iUnion]
rintro i x ⟨a, rfl, hxa⟩
exact hind _ hxa
/-- In a paracompact space, every open covering of a closed set admits a locally finite refinement
indexed by the same type. -/
theorem precise_refinement_set [ParacompactSpace X] {s : Set X} (hs : IsClosed s) (u : ι → Set X)
(uo : ∀ i, IsOpen (u i)) (us : s ⊆ ⋃ i, u i) :
∃ v : ι → Set X, (∀ i, IsOpen (v i)) ∧ (s ⊆ ⋃ i, v i) ∧ LocallyFinite v ∧ ∀ i, v i ⊆ u i := by
have uc : (iUnion fun i => Option.elim' sᶜ u i) = univ := by
apply Subset.antisymm (subset_univ _)
· simp_rw [← compl_union_self s, Option.elim', iUnion_option]
apply union_subset_union_right sᶜ us
rcases precise_refinement (Option.elim' sᶜ u) (Option.forall.2 ⟨isOpen_compl_iff.2 hs, uo⟩)
uc with
⟨v, vo, vc, vf, vu⟩
refine ⟨v ∘ some, fun i ↦ vo _, ?_, vf.comp_injective (Option.some_injective _), fun i ↦ vu _⟩
· simp only [iUnion_option, ← compl_subset_iff_union] at vc
exact Subset.trans (subset_compl_comm.1 <| vu Option.none) vc
theorem Topology.IsClosedEmbedding.paracompactSpace [ParacompactSpace Y] {e : X → Y}
(he : IsClosedEmbedding e) : ParacompactSpace X where
locallyFinite_refinement α s ho hu := by
choose U hUo hU using fun a ↦ he.isOpen_iff.1 (ho a)
simp only [← hU] at hu ⊢
have heU : range e ⊆ ⋃ i, U i := by
| simpa only [range_subset_iff, mem_iUnion, iUnion_eq_univ_iff] using hu
rcases precise_refinement_set he.isClosed_range U hUo heU with ⟨V, hVo, heV, hVf, hVU⟩
refine ⟨α, fun a ↦ e ⁻¹' (V a), fun a ↦ (hVo a).preimage he.continuous, ?_,
hVf.preimage_continuous he.continuous, fun a ↦ ⟨a, preimage_mono (hVU a)⟩⟩
simpa only [range_subset_iff, mem_iUnion, iUnion_eq_univ_iff] using heV
theorem Homeomorph.paracompactSpace_iff (e : X ≃ₜ Y) : ParacompactSpace X ↔ ParacompactSpace Y :=
⟨fun _ ↦ e.symm.isClosedEmbedding.paracompactSpace, fun _ ↦ e.isClosedEmbedding.paracompactSpace⟩
/-- The product of a compact space and a paracompact space is a paracompact space. The formalization
is based on https://dantopology.wordpress.com/2009/10/24/compact-x-paracompact-is-paracompact/
| Mathlib/Topology/Compactness/Paracompact.lean | 115 | 125 |
/-
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]
| Mathlib/Analysis/Normed/Group/Pointwise.lean | 149 | 150 |
/-
Copyright (c) 2020 Kenny Lau. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kenny Lau, Wrenna Robson
-/
import Mathlib.Algebra.BigOperators.Group.Finset.Pi
import Mathlib.Algebra.Polynomial.FieldDivision
import Mathlib.LinearAlgebra.Vandermonde
import Mathlib.RingTheory.Polynomial.Basic
/-!
# Lagrange interpolation
## Main definitions
* In everything that follows, `s : Finset ι` is a finite set of indexes, with `v : ι → F` an
indexing of the field over some type. We call the image of v on s the interpolation nodes,
though strictly unique nodes are only defined when v is injective on s.
* `Lagrange.basisDivisor x y`, with `x y : F`. These are the normalised irreducible factors of
the Lagrange basis polynomials. They evaluate to `1` at `x` and `0` at `y` when `x` and `y`
are distinct.
* `Lagrange.basis v i` with `i : ι`: the Lagrange basis polynomial that evaluates to `1` at `v i`
and `0` at `v j` for `i ≠ j`.
* `Lagrange.interpolate v r` where `r : ι → F` is a function from the fintype to the field: the
Lagrange interpolant that evaluates to `r i` at `x i` for all `i : ι`. The `r i` are the _values_
associated with the _nodes_`x i`.
-/
open Polynomial
section PolynomialDetermination
namespace Polynomial
variable {R : Type*} [CommRing R] [IsDomain R] {f g : R[X]}
section Finset
open Function Fintype
open scoped Finset
variable (s : Finset R)
theorem eq_zero_of_degree_lt_of_eval_finset_eq_zero (degree_f_lt : f.degree < #s)
(eval_f : ∀ x ∈ s, f.eval x = 0) : f = 0 := by
rw [← mem_degreeLT] at degree_f_lt
simp_rw [eval_eq_sum_degreeLTEquiv degree_f_lt] at eval_f
rw [← degreeLTEquiv_eq_zero_iff_eq_zero degree_f_lt]
exact
Matrix.eq_zero_of_forall_index_sum_mul_pow_eq_zero
(Injective.comp (Embedding.subtype _).inj' (equivFinOfCardEq (card_coe _)).symm.injective)
fun _ => eval_f _ (Finset.coe_mem _)
theorem eq_of_degree_sub_lt_of_eval_finset_eq (degree_fg_lt : (f - g).degree < #s)
| (eval_fg : ∀ x ∈ s, f.eval x = g.eval x) : f = g := by
rw [← sub_eq_zero]
refine eq_zero_of_degree_lt_of_eval_finset_eq_zero _ degree_fg_lt ?_
simp_rw [eval_sub, sub_eq_zero]
exact eval_fg
| Mathlib/LinearAlgebra/Lagrange.lean | 55 | 60 |
/-
Copyright (c) 2017 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Yakov Pechersky, Eric Wieser
-/
import Mathlib.Data.List.Basic
/-!
# Properties of `List.enum`
## Deprecation note
Many lemmas in this file have been replaced by theorems in Lean4,
in terms of `xs[i]?` and `xs[i]` rather than `get` and `get?`.
The deprecated results here are unused in Mathlib.
Any downstream users who can not easily adapt may remove the deprecations as needed.
-/
namespace List
variable {α : Type*}
theorem forall_mem_zipIdx {l : List α} {n : ℕ} {p : α × ℕ → Prop} :
(∀ x ∈ l.zipIdx n, p x) ↔ ∀ (i : ℕ) (_ : i < length l), p (l[i], n + i) := by
simp only [forall_mem_iff_getElem, getElem_zipIdx, length_zipIdx]
/-- Variant of `forall_mem_zipIdx` with the `zipIdx` argument specialized to `0`. -/
theorem forall_mem_zipIdx' {l : List α} {p : α × ℕ → Prop} :
(∀ x ∈ l.zipIdx, p x) ↔ ∀ (i : ℕ) (_ : i < length l), p (l[i], i) :=
forall_mem_zipIdx.trans <| by simp
theorem exists_mem_zipIdx {l : List α} {n : ℕ} {p : α × ℕ → Prop} :
(∃ x ∈ l.zipIdx n, p x) ↔ ∃ (i : ℕ) (_ : i < length l), p (l[i], n + i) := by
simp only [exists_mem_iff_getElem, getElem_zipIdx, length_zipIdx]
/-- Variant of `exists_mem_zipIdx` with the `zipIdx` argument specialized to `0`. -/
theorem exists_mem_zipIdx' {l : List α} {p : α × ℕ → Prop} :
(∃ x ∈ l.zipIdx, p x) ↔ ∃ (i : ℕ) (_ : i < length l), p (l[i], i) :=
exists_mem_zipIdx.trans <| by simp
@[deprecated (since := "2025-01-28")]
alias forall_mem_enumFrom := forall_mem_zipIdx
@[deprecated (since := "2025-01-28")]
alias forall_mem_enum := forall_mem_zipIdx'
@[deprecated (since := "2025-01-28")]
alias exists_mem_enumFrom := exists_mem_zipIdx
@[deprecated (since := "2025-01-28")]
alias exists_mem_enum := exists_mem_zipIdx'
end List
| Mathlib/Data/List/Enum.lean | 71 | 73 | |
/-
Copyright (c) 2019 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Patrick Massot, Casper Putz, Anne Baanen, Wen Yang
-/
import Mathlib.LinearAlgebra.Matrix.Transvection
import Mathlib.LinearAlgebra.Matrix.NonsingularInverse
import Mathlib.Tactic.FinCases
/-!
# Block matrices and their determinant
This file defines a predicate `Matrix.BlockTriangular` saying a matrix
is block triangular, and proves the value of the determinant for various
matrices built out of blocks.
## Main definitions
* `Matrix.BlockTriangular` expresses that an `o` by `o` matrix is block triangular,
if the rows and columns are ordered according to some order `b : o → α`
## Main results
* `Matrix.det_of_blockTriangular`: the determinant of a block triangular matrix
is equal to the product of the determinants of all the blocks
* `Matrix.det_of_upperTriangular` and `Matrix.det_of_lowerTriangular`: the determinant of
a triangular matrix is the product of the entries along the diagonal
## Tags
matrix, diagonal, det, block triangular
-/
open Finset Function OrderDual
open Matrix
universe v
variable {α β m n o : Type*} {m' n' : α → Type*}
variable {R : Type v} {M N : Matrix m m R} {b : m → α}
namespace Matrix
section LT
variable [LT α]
section Zero
variable [Zero R]
/-- Let `b` map rows and columns of a square matrix `M` to blocks indexed by `α`s. Then
`BlockTriangular M n b` says the matrix is block triangular. -/
def BlockTriangular (M : Matrix m m R) (b : m → α) : Prop :=
∀ ⦃i j⦄, b j < b i → M i j = 0
@[simp]
protected theorem BlockTriangular.submatrix {f : n → m} (h : M.BlockTriangular b) :
(M.submatrix f f).BlockTriangular (b ∘ f) := fun _ _ hij => h hij
theorem blockTriangular_reindex_iff {b : n → α} {e : m ≃ n} :
(reindex e e M).BlockTriangular b ↔ M.BlockTriangular (b ∘ e) := by
refine ⟨fun h => ?_, fun h => ?_⟩
· convert h.submatrix
simp only [reindex_apply, submatrix_submatrix, submatrix_id_id, Equiv.symm_comp_self]
· convert h.submatrix
simp only [comp_assoc b e e.symm, Equiv.self_comp_symm, comp_id]
protected theorem BlockTriangular.transpose :
M.BlockTriangular b → Mᵀ.BlockTriangular (toDual ∘ b) :=
swap
@[simp]
protected theorem blockTriangular_transpose_iff {b : m → αᵒᵈ} :
Mᵀ.BlockTriangular b ↔ M.BlockTriangular (ofDual ∘ b) :=
forall_swap
@[simp]
theorem blockTriangular_zero : BlockTriangular (0 : Matrix m m R) b := fun _ _ _ => rfl
end Zero
protected theorem BlockTriangular.neg [NegZeroClass R] {M : Matrix m m R}
(hM : BlockTriangular M b) : BlockTriangular (-M) b :=
fun _ _ h => by rw [neg_apply, hM h, neg_zero]
theorem BlockTriangular.add [AddZeroClass R] (hM : BlockTriangular M b) (hN : BlockTriangular N b) :
BlockTriangular (M + N) b := fun i j h => by simp_rw [Matrix.add_apply, hM h, hN h, zero_add]
theorem BlockTriangular.sub [SubNegZeroMonoid R]
(hM : BlockTriangular M b) (hN : BlockTriangular N b) :
BlockTriangular (M - N) b := fun i j h => by simp_rw [Matrix.sub_apply, hM h, hN h, sub_zero]
lemma BlockTriangular.add_iff_right [AddGroup R] (hM : BlockTriangular M b) :
BlockTriangular (M + N) b ↔ BlockTriangular N b := ⟨(by simpa using hM.neg.add ·), hM.add⟩
lemma BlockTriangular.add_iff_left [AddGroup R] (hN : BlockTriangular N b) :
BlockTriangular (M + N) b ↔ BlockTriangular M b := ⟨(by simpa using ·.sub hN), (·.add hN)⟩
lemma BlockTriangular.sub_iff_right [AddGroup R] (hM : BlockTriangular M b) :
BlockTriangular (M - N) b ↔ BlockTriangular N b := ⟨(by simpa using ·.neg.add hM), hM.sub⟩
lemma BlockTriangular.sub_iff_left [AddGroup R] (hN : BlockTriangular N b) :
BlockTriangular (M - N) b ↔ BlockTriangular M b := ⟨(by simpa using ·.add hN), (·.sub hN)⟩
lemma BlockTriangular.map {S F} [FunLike F R S] [Zero R] [Zero S] [ZeroHomClass F R S] (f : F)
(h : BlockTriangular M b) : BlockTriangular (M.map f) b :=
fun i j lt ↦ by simp [h lt]
lemma BlockTriangular.comp [Zero R] {M : Matrix m m (Matrix n n R)} (h : BlockTriangular M b) :
BlockTriangular (M.comp m m n n R) fun i ↦ b i.1 :=
fun i j lt ↦ by simp [h lt]
end LT
section Preorder
variable [Preorder α]
section Zero
variable [Zero R]
theorem blockTriangular_diagonal [DecidableEq m] (d : m → R) : BlockTriangular (diagonal d) b :=
fun _ _ h => diagonal_apply_ne' d fun h' => ne_of_lt h (congr_arg _ h')
theorem blockTriangular_blockDiagonal' [DecidableEq α] (d : ∀ i : α, Matrix (m' i) (m' i) R) :
BlockTriangular (blockDiagonal' d) Sigma.fst := by
rintro ⟨i, i'⟩ ⟨j, j'⟩ h
apply blockDiagonal'_apply_ne d i' j' fun h' => ne_of_lt h h'.symm
theorem blockTriangular_blockDiagonal [DecidableEq α] (d : α → Matrix m m R) :
BlockTriangular (blockDiagonal d) Prod.snd := by
rintro ⟨i, i'⟩ ⟨j, j'⟩ h
rw [blockDiagonal'_eq_blockDiagonal, blockTriangular_blockDiagonal']
exact h
variable [DecidableEq m]
theorem blockTriangular_one [One R] : BlockTriangular (1 : Matrix m m R) b :=
blockTriangular_diagonal _
theorem blockTriangular_stdBasisMatrix {i j : m} (hij : b i ≤ b j) (c : R) :
BlockTriangular (stdBasisMatrix i j c) b := by
intro r s hrs
apply StdBasisMatrix.apply_of_ne
rintro ⟨rfl, rfl⟩
exact (hij.trans_lt hrs).false
theorem blockTriangular_stdBasisMatrix' {i j : m} (hij : b j ≤ b i) (c : R) :
BlockTriangular (stdBasisMatrix i j c) (toDual ∘ b) :=
blockTriangular_stdBasisMatrix (by exact toDual_le_toDual.mpr hij) _
end Zero
variable [CommRing R] [DecidableEq m]
theorem blockTriangular_transvection {i j : m} (hij : b i ≤ b j) (c : R) :
BlockTriangular (transvection i j c) b :=
blockTriangular_one.add (blockTriangular_stdBasisMatrix hij c)
theorem blockTriangular_transvection' {i j : m} (hij : b j ≤ b i) (c : R) :
BlockTriangular (transvection i j c) (OrderDual.toDual ∘ b) :=
blockTriangular_one.add (blockTriangular_stdBasisMatrix' hij c)
end Preorder
section LinearOrder
variable [LinearOrder α]
theorem BlockTriangular.mul [Fintype m] [NonUnitalNonAssocSemiring R]
{M N : Matrix m m R} (hM : BlockTriangular M b)
(hN : BlockTriangular N b) : BlockTriangular (M * N) b := by
intro i j hij
apply Finset.sum_eq_zero
intro k _
by_cases hki : b k < b i
· simp_rw [hM hki, zero_mul]
· simp_rw [hN (lt_of_lt_of_le hij (le_of_not_lt hki)), mul_zero]
end LinearOrder
theorem upper_two_blockTriangular [Zero R] [Preorder α] (A : Matrix m m R) (B : Matrix m n R)
(D : Matrix n n R) {a b : α} (hab : a < b) :
BlockTriangular (fromBlocks A B 0 D) (Sum.elim (fun _ => a) fun _ => b) := by
rintro (c | c) (d | d) hcd <;> first | simp [hab.not_lt] at hcd ⊢
/-! ### Determinant -/
variable [CommRing R] [DecidableEq m] [Fintype m] [DecidableEq n] [Fintype n]
theorem equiv_block_det (M : Matrix m m R) {p q : m → Prop} [DecidablePred p] [DecidablePred q]
(e : ∀ x, q x ↔ p x) : (toSquareBlockProp M p).det = (toSquareBlockProp M q).det := by
convert Matrix.det_reindex_self (Equiv.subtypeEquivRight e) (toSquareBlockProp M q)
-- Removed `@[simp]` attribute,
-- as the LHS simplifies already to `M.toSquareBlock id i ⟨i, ⋯⟩ ⟨i, ⋯⟩`
theorem det_toSquareBlock_id (M : Matrix m m R) (i : m) : (M.toSquareBlock id i).det = M i i :=
letI : Unique { a // id a = i } := ⟨⟨⟨i, rfl⟩⟩, fun j => Subtype.ext j.property⟩
(det_unique _).trans rfl
theorem det_toBlock (M : Matrix m m R) (p : m → Prop) [DecidablePred p] :
M.det =
(fromBlocks (toBlock M p p) (toBlock M p fun j => ¬p j) (toBlock M (fun j => ¬p j) p) <|
toBlock M (fun j => ¬p j) fun j => ¬p j).det := by
rw [← Matrix.det_reindex_self (Equiv.sumCompl p).symm M]
rw [det_apply', det_apply']
congr; ext σ; congr; ext x
generalize hy : σ x = y
cases x <;> cases y <;>
simp only [Matrix.reindex_apply, toBlock_apply, Equiv.symm_symm, Equiv.sumCompl_apply_inr,
Equiv.sumCompl_apply_inl, fromBlocks_apply₁₁, fromBlocks_apply₁₂, fromBlocks_apply₂₁,
fromBlocks_apply₂₂, Matrix.submatrix_apply]
theorem twoBlockTriangular_det (M : Matrix m m R) (p : m → Prop) [DecidablePred p]
(h : ∀ i, ¬p i → ∀ j, p j → M i j = 0) :
M.det = (toSquareBlockProp M p).det * (toSquareBlockProp M fun i => ¬p i).det := by
rw [det_toBlock M p]
convert det_fromBlocks_zero₂₁ (toBlock M p p) (toBlock M p fun j => ¬p j)
(toBlock M (fun j => ¬p j) fun j => ¬p j)
ext i j
exact h (↑i) i.2 (↑j) j.2
theorem twoBlockTriangular_det' (M : Matrix m m R) (p : m → Prop) [DecidablePred p]
(h : ∀ i, p i → ∀ j, ¬p j → M i j = 0) :
M.det = (toSquareBlockProp M p).det * (toSquareBlockProp M fun i => ¬p i).det := by
rw [M.twoBlockTriangular_det fun i => ¬p i, mul_comm]
· congr 1
exact equiv_block_det _ fun _ => not_not.symm
· simpa only [Classical.not_not] using h
protected theorem BlockTriangular.det [DecidableEq α] [LinearOrder α] (hM : BlockTriangular M b) :
M.det = ∏ a ∈ univ.image b, (M.toSquareBlock b a).det := by
suffices ∀ hs : Finset α, univ.image b = hs → M.det = ∏ a ∈ hs, (M.toSquareBlock b a).det by
exact this _ rfl
intro s hs
induction s using Finset.strongInduction generalizing m with | H s ih =>
subst hs
cases isEmpty_or_nonempty m
· simp
let k := (univ.image b).max' (univ_nonempty.image _)
rw [twoBlockTriangular_det' M fun i => b i = k]
· have : univ.image b = insert k ((univ.image b).erase k) := by
rw [insert_erase]
apply max'_mem
rw [this, prod_insert (not_mem_erase _ _)]
refine congr_arg _ ?_
let b' := fun i : { a // b a ≠ k } => b ↑i
have h' : BlockTriangular (M.toSquareBlockProp fun i => b i ≠ k) b' := hM.submatrix
have hb' : image b' univ = (image b univ).erase k := by
convert image_subtype_ne_univ_eq_image_erase k b
rw [ih _ (erase_ssubset <| max'_mem _ _) h' hb']
refine Finset.prod_congr rfl fun l hl => ?_
let he : { a // b' a = l } ≃ { a // b a = l } :=
haveI hc : ∀ i, b i = l → b i ≠ k := fun i hi => ne_of_eq_of_ne hi (ne_of_mem_erase hl)
Equiv.subtypeSubtypeEquivSubtype @(hc)
simp only [toSquareBlock_def]
erw [← Matrix.det_reindex_self he.symm fun i j : { a // b a = l } => M ↑i ↑j]
rfl
· intro i hi j hj
apply hM
| rw [hi]
apply lt_of_le_of_ne _ hj
exact Finset.le_max' (univ.image b) _ (mem_image_of_mem _ (mem_univ _))
| Mathlib/LinearAlgebra/Matrix/Block.lean | 266 | 269 |
/-
Copyright (c) 2022 Jujian Zhang. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jujian Zhang
-/
import Mathlib.RingTheory.GradedAlgebra.Basic
import Mathlib.Algebra.GradedMulAction
import Mathlib.Algebra.DirectSum.Decomposition
import Mathlib.Algebra.Module.BigOperators
/-!
# Graded Module
Given an `R`-algebra `A` graded by `𝓐`, a graded `A`-module `M` is expressed as
`DirectSum.Decomposition 𝓜` and `SetLike.GradedSMul 𝓐 𝓜`.
Then `⨁ i, 𝓜 i` is an `A`-module and is isomorphic to `M`.
## Tags
graded module
-/
section
open DirectSum
variable {ιA ιB : Type*} (A : ιA → Type*) (M : ιB → Type*)
namespace DirectSum
open GradedMonoid
/-- A graded version of `DistribMulAction`. -/
class GdistribMulAction [AddMonoid ιA] [VAdd ιA ιB] [GMonoid A] [∀ i, AddMonoid (M i)]
extends GMulAction A M where
smul_add {i j} (a : A i) (b c : M j) : smul a (b + c) = smul a b + smul a c
smul_zero {i j} (a : A i) : smul a (0 : M j) = 0
/-- A graded version of `Module`. -/
class Gmodule [AddMonoid ιA] [VAdd ιA ιB] [∀ i, AddMonoid (A i)] [∀ i, AddMonoid (M i)] [GMonoid A]
extends GdistribMulAction A M where
add_smul {i j} (a a' : A i) (b : M j) : smul (a + a') b = smul a b + smul a' b
zero_smul {i j} (b : M j) : smul (0 : A i) b = 0
/-- A graded version of `Semiring.toModule`. -/
instance GSemiring.toGmodule [AddMonoid ιA] [∀ i : ιA, AddCommMonoid (A i)]
[h : GSemiring A] : Gmodule A A :=
{ GMonoid.toGMulAction A with
smul_add := fun _ _ _ => h.mul_add _ _ _
smul_zero := fun _ => h.mul_zero _
add_smul := fun _ _ => h.add_mul _ _
zero_smul := fun _ => h.zero_mul _ }
variable [AddMonoid ιA] [VAdd ιA ιB] [∀ i : ιA, AddCommMonoid (A i)] [∀ i, AddCommMonoid (M i)]
/-- The piecewise multiplication from the `Mul` instance, as a bundled homomorphism. -/
@[simps]
def gsmulHom [GMonoid A] [Gmodule A M] {i j} : A i →+ M j →+ M (i +ᵥ j) where
toFun a :=
{ toFun := fun b => GSMul.smul a b
map_zero' := GdistribMulAction.smul_zero _
map_add' := GdistribMulAction.smul_add _ }
map_zero' := AddMonoidHom.ext fun a => Gmodule.zero_smul a
map_add' _a₁ _a₂ := AddMonoidHom.ext fun _b => Gmodule.add_smul _ _ _
namespace Gmodule
/-- For graded monoid `A` and a graded module `M` over `A`. `Gmodule.smulAddMonoidHom` is the
`⨁ᵢ Aᵢ`-scalar multiplication on `⨁ᵢ Mᵢ` induced by `gsmul_hom`. -/
def smulAddMonoidHom [DecidableEq ιA] [DecidableEq ιB] [GMonoid A] [Gmodule A M] :
(⨁ i, A i) →+ (⨁ i, M i) →+ ⨁ i, M i :=
toAddMonoid fun _i =>
AddMonoidHom.flip <|
toAddMonoid fun _j => AddMonoidHom.flip <| (of M _).compHom.comp <| gsmulHom A M
section
open GradedMonoid DirectSum Gmodule
instance [DecidableEq ιA] [DecidableEq ιB] [GMonoid A] [Gmodule A M] :
SMul (⨁ i, A i) (⨁ i, M i) where
smul x y := smulAddMonoidHom A M x y
@[simp]
theorem smul_def [DecidableEq ιA] [DecidableEq ιB] [GMonoid A] [Gmodule A M]
(x : ⨁ i, A i) (y : ⨁ i, M i) :
x • y = smulAddMonoidHom _ _ x y := rfl
@[simp]
theorem smulAddMonoidHom_apply_of_of [DecidableEq ιA] [DecidableEq ιB] [GMonoid A] [Gmodule A M]
{i j} (x : A i) (y : M j) :
smulAddMonoidHom A M (DirectSum.of A i x) (of M j y) = of M (i +ᵥ j) (GSMul.smul x y) := by
simp [smulAddMonoidHom]
theorem of_smul_of [DecidableEq ιA] [DecidableEq ιB] [GMonoid A] [Gmodule A M]
{i j} (x : A i) (y : M j) :
DirectSum.of A i x • of M j y = of M (i +ᵥ j) (GSMul.smul x y) := by simp
open AddMonoidHom
-- Almost identical to the proof of `direct_sum.one_mul`
private theorem one_smul' [DecidableEq ιA] [DecidableEq ιB] [GMonoid A] [Gmodule A M]
(x : ⨁ i, M i) :
(1 : ⨁ i, A i) • x = x := by
suffices smulAddMonoidHom A M 1 = AddMonoidHom.id (⨁ i, M i) from DFunLike.congr_fun this x
apply DirectSum.addHom_ext; intro i xi
rw [show (1 : DirectSum ιA fun i => A i) = (of A 0) GOne.one by rfl]
rw [smulAddMonoidHom_apply_of_of]
exact DirectSum.of_eq_of_gradedMonoid_eq (one_smul (GradedMonoid A) <| GradedMonoid.mk i xi)
-- Almost identical to the proof of `direct_sum.mul_assoc`
private theorem mul_smul' [DecidableEq ιA] [DecidableEq ιB] [GSemiring A] [Gmodule A M]
(a b : ⨁ i, A i)
(c : ⨁ i, M i) : (a * b) • c = a • b • c := by
suffices
(-- `fun a b c ↦ (a * b) • c` as a bundled hom
smulAddMonoidHom
A M).compHom.comp
(DirectSum.mulHom A) =
(AddMonoidHom.compHom AddMonoidHom.flipHom <|
(smulAddMonoidHom A M).flip.compHom.comp <| smulAddMonoidHom A M).flip
from-- `fun a b c ↦ a • (b • c)` as a bundled hom
DFunLike.congr_fun (DFunLike.congr_fun (DFunLike.congr_fun this a) b) c
ext ai ax bi bx ci cx : 6
dsimp only [coe_comp, Function.comp_apply, compHom_apply_apply, flip_apply, flipHom_apply]
| rw [smulAddMonoidHom_apply_of_of, smulAddMonoidHom_apply_of_of, DirectSum.mulHom_of_of,
smulAddMonoidHom_apply_of_of]
exact
DirectSum.of_eq_of_gradedMonoid_eq
(mul_smul (GradedMonoid.mk ai ax) (GradedMonoid.mk bi bx) (GradedMonoid.mk ci cx))
/-- The `Module` derived from `gmodule A M`. -/
instance module [DecidableEq ιA] [DecidableEq ιB] [GSemiring A] [Gmodule A M] :
Module (⨁ i, A i) (⨁ i, M i) where
smul := (· • ·)
one_smul := one_smul' _ _
mul_smul := mul_smul' _ _
smul_add r := (smulAddMonoidHom A M r).map_add
smul_zero r := (smulAddMonoidHom A M r).map_zero
add_smul r s x := by simp only [smul_def, map_add, AddMonoidHom.add_apply]
zero_smul x := by simp only [smul_def, map_zero, AddMonoidHom.zero_apply]
end
| Mathlib/Algebra/Module/GradedModule.lean | 127 | 145 |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Aaron Anderson, Yakov Pechersky
-/
import Mathlib.Data.Fintype.Card
import Mathlib.Algebra.Group.Commute.Basic
import Mathlib.Algebra.Group.End
import Mathlib.Data.Finset.NoncommProd
/-!
# support of a permutation
## Main definitions
In the following, `f g : Equiv.Perm α`.
* `Equiv.Perm.Disjoint`: two permutations `f` and `g` are `Disjoint` if every element is fixed
either by `f`, or by `g`.
Equivalently, `f` and `g` are `Disjoint` iff their `support` are disjoint.
* `Equiv.Perm.IsSwap`: `f = swap x y` for `x ≠ y`.
* `Equiv.Perm.support`: the elements `x : α` that are not fixed by `f`.
Assume `α` is a Fintype:
* `Equiv.Perm.fixed_point_card_lt_of_ne_one f` says that `f` has
strictly less than `Fintype.card α - 1` fixed points, unless `f = 1`.
(Equivalently, `f.support` has at least 2 elements.)
-/
open Equiv Finset Function
namespace Equiv.Perm
variable {α : Type*}
section Disjoint
/-- Two permutations `f` and `g` are `Disjoint` if their supports are disjoint, i.e.,
every element is fixed either by `f`, or by `g`. -/
def Disjoint (f g : Perm α) :=
∀ x, f x = x ∨ g x = x
variable {f g h : Perm α}
@[symm]
theorem Disjoint.symm : Disjoint f g → Disjoint g f := by simp only [Disjoint, or_comm, imp_self]
theorem Disjoint.symmetric : Symmetric (@Disjoint α) := fun _ _ => Disjoint.symm
instance : IsSymm (Perm α) Disjoint :=
⟨Disjoint.symmetric⟩
theorem disjoint_comm : Disjoint f g ↔ Disjoint g f :=
⟨Disjoint.symm, Disjoint.symm⟩
theorem Disjoint.commute (h : Disjoint f g) : Commute f g :=
Equiv.ext fun x =>
(h x).elim
(fun hf =>
(h (g x)).elim (fun hg => by simp [mul_apply, hf, hg]) fun hg => by
simp [mul_apply, hf, g.injective hg])
fun hg =>
(h (f x)).elim (fun hf => by simp [mul_apply, f.injective hf, hg]) fun hf => by
simp [mul_apply, hf, hg]
@[simp]
theorem disjoint_one_left (f : Perm α) : Disjoint 1 f := fun _ => Or.inl rfl
@[simp]
theorem disjoint_one_right (f : Perm α) : Disjoint f 1 := fun _ => Or.inr rfl
theorem disjoint_iff_eq_or_eq : Disjoint f g ↔ ∀ x : α, f x = x ∨ g x = x :=
Iff.rfl
@[simp]
theorem disjoint_refl_iff : Disjoint f f ↔ f = 1 := by
refine ⟨fun h => ?_, fun h => h.symm ▸ disjoint_one_left 1⟩
ext x
rcases h x with hx | hx <;> simp [hx]
theorem Disjoint.inv_left (h : Disjoint f g) : Disjoint f⁻¹ g := by
intro x
rw [inv_eq_iff_eq, eq_comm]
exact h x
theorem Disjoint.inv_right (h : Disjoint f g) : Disjoint f g⁻¹ :=
h.symm.inv_left.symm
@[simp]
theorem disjoint_inv_left_iff : Disjoint f⁻¹ g ↔ Disjoint f g := by
refine ⟨fun h => ?_, Disjoint.inv_left⟩
convert h.inv_left
@[simp]
theorem disjoint_inv_right_iff : Disjoint f g⁻¹ ↔ Disjoint f g := by
rw [disjoint_comm, disjoint_inv_left_iff, disjoint_comm]
theorem Disjoint.mul_left (H1 : Disjoint f h) (H2 : Disjoint g h) : Disjoint (f * g) h := fun x =>
by cases H1 x <;> cases H2 x <;> simp [*]
theorem Disjoint.mul_right (H1 : Disjoint f g) (H2 : Disjoint f h) : Disjoint f (g * h) := by
rw [disjoint_comm]
exact H1.symm.mul_left H2.symm
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/11215): TODO: make it `@[simp]`
theorem disjoint_conj (h : Perm α) : Disjoint (h * f * h⁻¹) (h * g * h⁻¹) ↔ Disjoint f g :=
(h⁻¹).forall_congr fun {_} ↦ by simp only [mul_apply, eq_inv_iff_eq]
theorem Disjoint.conj (H : Disjoint f g) (h : Perm α) : Disjoint (h * f * h⁻¹) (h * g * h⁻¹) :=
(disjoint_conj h).2 H
theorem disjoint_prod_right (l : List (Perm α)) (h : ∀ g ∈ l, Disjoint f g) :
Disjoint f l.prod := by
induction' l with g l ih
· exact disjoint_one_right _
· rw [List.prod_cons]
exact (h _ List.mem_cons_self).mul_right (ih fun g hg => h g (List.mem_cons_of_mem _ hg))
theorem disjoint_noncommProd_right {ι : Type*} {k : ι → Perm α} {s : Finset ι}
(hs : Set.Pairwise s fun i j ↦ Commute (k i) (k j))
(hg : ∀ i ∈ s, g.Disjoint (k i)) :
Disjoint g (s.noncommProd k (hs)) :=
noncommProd_induction s k hs g.Disjoint (fun _ _ ↦ Disjoint.mul_right) (disjoint_one_right g) hg
open scoped List in
theorem disjoint_prod_perm {l₁ l₂ : List (Perm α)} (hl : l₁.Pairwise Disjoint) (hp : l₁ ~ l₂) :
l₁.prod = l₂.prod :=
hp.prod_eq' <| hl.imp Disjoint.commute
theorem nodup_of_pairwise_disjoint {l : List (Perm α)} (h1 : (1 : Perm α) ∉ l)
(h2 : l.Pairwise Disjoint) : l.Nodup := by
refine List.Pairwise.imp_of_mem ?_ h2
intro τ σ h_mem _ h_disjoint _
subst τ
suffices (σ : Perm α) = 1 by
rw [this] at h_mem
exact h1 h_mem
exact ext fun a => or_self_iff.mp (h_disjoint a)
theorem pow_apply_eq_self_of_apply_eq_self {x : α} (hfx : f x = x) : ∀ n : ℕ, (f ^ n) x = x
| 0 => rfl
| n + 1 => by rw [pow_succ, mul_apply, hfx, pow_apply_eq_self_of_apply_eq_self hfx n]
theorem zpow_apply_eq_self_of_apply_eq_self {x : α} (hfx : f x = x) : ∀ n : ℤ, (f ^ n) x = x
| (n : ℕ) => pow_apply_eq_self_of_apply_eq_self hfx n
| Int.negSucc n => by rw [zpow_negSucc, inv_eq_iff_eq, pow_apply_eq_self_of_apply_eq_self hfx]
theorem pow_apply_eq_of_apply_apply_eq_self {x : α} (hffx : f (f x) = x) :
∀ n : ℕ, (f ^ n) x = x ∨ (f ^ n) x = f x
| 0 => Or.inl rfl
| n + 1 =>
(pow_apply_eq_of_apply_apply_eq_self hffx n).elim
(fun h => Or.inr (by rw [pow_succ', mul_apply, h]))
fun h => Or.inl (by rw [pow_succ', mul_apply, h, hffx])
theorem zpow_apply_eq_of_apply_apply_eq_self {x : α} (hffx : f (f x) = x) :
∀ i : ℤ, (f ^ i) x = x ∨ (f ^ i) x = f x
| (n : ℕ) => pow_apply_eq_of_apply_apply_eq_self hffx n
| Int.negSucc n => by
rw [zpow_negSucc, inv_eq_iff_eq, ← f.injective.eq_iff, ← mul_apply, ← pow_succ', eq_comm,
inv_eq_iff_eq, ← mul_apply, ← pow_succ, @eq_comm _ x, or_comm]
exact pow_apply_eq_of_apply_apply_eq_self hffx _
theorem Disjoint.mul_apply_eq_iff {σ τ : Perm α} (hστ : Disjoint σ τ) {a : α} :
(σ * τ) a = a ↔ σ a = a ∧ τ a = a := by
refine ⟨fun h => ?_, fun h => by rw [mul_apply, h.2, h.1]⟩
rcases hστ a with hσ | hτ
· exact ⟨hσ, σ.injective (h.trans hσ.symm)⟩
· exact ⟨(congr_arg σ hτ).symm.trans h, hτ⟩
theorem Disjoint.mul_eq_one_iff {σ τ : Perm α} (hστ : Disjoint σ τ) :
σ * τ = 1 ↔ σ = 1 ∧ τ = 1 := by
simp_rw [Perm.ext_iff, one_apply, hστ.mul_apply_eq_iff, forall_and]
theorem Disjoint.zpow_disjoint_zpow {σ τ : Perm α} (hστ : Disjoint σ τ) (m n : ℤ) :
Disjoint (σ ^ m) (τ ^ n) := fun x =>
Or.imp (fun h => zpow_apply_eq_self_of_apply_eq_self h m)
(fun h => zpow_apply_eq_self_of_apply_eq_self h n) (hστ x)
theorem Disjoint.pow_disjoint_pow {σ τ : Perm α} (hστ : Disjoint σ τ) (m n : ℕ) :
Disjoint (σ ^ m) (τ ^ n) :=
hστ.zpow_disjoint_zpow m n
end Disjoint
section IsSwap
variable [DecidableEq α]
/-- `f.IsSwap` indicates that the permutation `f` is a transposition of two elements. -/
def IsSwap (f : Perm α) : Prop :=
∃ x y, x ≠ y ∧ f = swap x y
@[simp]
theorem ofSubtype_swap_eq {p : α → Prop} [DecidablePred p] (x y : Subtype p) :
ofSubtype (Equiv.swap x y) = Equiv.swap ↑x ↑y :=
Equiv.ext fun z => by
by_cases hz : p z
· rw [swap_apply_def, ofSubtype_apply_of_mem _ hz]
split_ifs with hzx hzy
· simp_rw [hzx, Subtype.coe_eta, swap_apply_left]
· simp_rw [hzy, Subtype.coe_eta, swap_apply_right]
· rw [swap_apply_of_ne_of_ne] <;>
simp [Subtype.ext_iff, *]
· rw [ofSubtype_apply_of_not_mem _ hz, swap_apply_of_ne_of_ne]
· intro h
apply hz
rw [h]
exact Subtype.prop x
intro h
apply hz
rw [h]
exact Subtype.prop y
theorem IsSwap.of_subtype_isSwap {p : α → Prop} [DecidablePred p] {f : Perm (Subtype p)}
(h : f.IsSwap) : (ofSubtype f).IsSwap :=
let ⟨⟨x, hx⟩, ⟨y, hy⟩, hxy⟩ := h
⟨x, y, by
simp only [Ne, Subtype.ext_iff] at hxy
exact hxy.1, by
rw [hxy.2, ofSubtype_swap_eq]⟩
theorem ne_and_ne_of_swap_mul_apply_ne_self {f : Perm α} {x y : α} (hy : (swap x (f x) * f) y ≠ y) :
f y ≠ y ∧ y ≠ x := by
simp only [swap_apply_def, mul_apply, f.injective.eq_iff] at *
by_cases h : f y = x
· constructor <;> intro <;> simp_all only [if_true, eq_self_iff_true, not_true, Ne]
· split_ifs at hy with h <;> try { simp [*] at * }
end IsSwap
section support
section Set
variable (p q : Perm α)
theorem set_support_inv_eq : { x | p⁻¹ x ≠ x } = { x | p x ≠ x } := by
ext x
simp only [Set.mem_setOf_eq, Ne]
rw [inv_def, symm_apply_eq, eq_comm]
theorem set_support_apply_mem {p : Perm α} {a : α} :
p a ∈ { x | p x ≠ x } ↔ a ∈ { x | p x ≠ x } := by simp
theorem set_support_zpow_subset (n : ℤ) : { x | (p ^ n) x ≠ x } ⊆ { x | p x ≠ x } := by
intro x
simp only [Set.mem_setOf_eq, Ne]
intro hx H
simp [zpow_apply_eq_self_of_apply_eq_self H] at hx
theorem set_support_mul_subset : { x | (p * q) x ≠ x } ⊆ { x | p x ≠ x } ∪ { x | q x ≠ x } := by
intro x
simp only [Perm.coe_mul, Function.comp_apply, Ne, Set.mem_union, Set.mem_setOf_eq]
by_cases hq : q x = x <;> simp [hq]
end Set
@[simp]
theorem apply_pow_apply_eq_iff (f : Perm α) (n : ℕ) {x : α} :
f ((f ^ n) x) = (f ^ n) x ↔ f x = x := by
rw [← mul_apply, Commute.self_pow f, mul_apply, apply_eq_iff_eq]
@[simp]
theorem apply_zpow_apply_eq_iff (f : Perm α) (n : ℤ) {x : α} :
f ((f ^ n) x) = (f ^ n) x ↔ f x = x := by
rw [← mul_apply, Commute.self_zpow f, mul_apply, apply_eq_iff_eq]
variable [DecidableEq α] [Fintype α] {f g : Perm α}
/-- The `Finset` of nonfixed points of a permutation. -/
def support (f : Perm α) : Finset α := {x | f x ≠ x}
@[simp]
theorem mem_support {x : α} : x ∈ f.support ↔ f x ≠ x := by
rw [support, mem_filter, and_iff_right (mem_univ x)]
theorem not_mem_support {x : α} : x ∉ f.support ↔ f x = x := by simp
|
theorem coe_support_eq_set_support (f : Perm α) : (f.support : Set α) = { x | f x ≠ x } := by
ext
simp
| Mathlib/GroupTheory/Perm/Support.lean | 281 | 284 |
/-
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.Bases
import Mathlib.Topology.DenseEmbedding
import Mathlib.Topology.Connected.TotallyDisconnected
/-! # Stone-Čech compactification
Construction of the Stone-Čech compactification using ultrafilters.
For any topological space `α`, we build a compact Hausdorff space `StoneCech α` and a continuous
map `stoneCechUnit : α → StoneCech α` which is minimal in the sense of the following universal
property: for any compact Hausdorff space `β` and every map `f : α → β` such that
`hf : Continuous f`, there is a unique map `stoneCechExtend hf : StoneCech α → β` such that
`stoneCechExtend_extends : stoneCechExtend hf ∘ stoneCechUnit = f`.
Continuity of this extension is asserted by `continuous_stoneCechExtend` and uniqueness by
`stoneCech_hom_ext`.
Beware that the terminology “extend” is slightly misleading since `stoneCechUnit` is not always
injective, so one cannot always think of `α` as being “inside” its compactification `StoneCech α`.
## Implementation notes
Parts of the formalization are based on “Ultrafilters and Topology”
by Marius Stekelenburg, particularly section 5. However the construction in the general
case is different because the equivalence relation on spaces of ultrafilters described
by Stekelenburg causes issues with universes since it involves a condition
on all compact Hausdorff spaces. We replace it by a two steps construction.
The first step called `PreStoneCech` guarantees the expected universal property but
not the Hausdorff condition. We then define `StoneCech α` as `t2Quotient (PreStoneCech α)`.
-/
noncomputable section
open Filter Set
open Topology
universe u v
section Ultrafilter
/- The set of ultrafilters on α carries a natural topology which makes
it the Stone-Čech compactification of α (viewed as a discrete space). -/
/-- Basis for the topology on `Ultrafilter α`. -/
def ultrafilterBasis (α : Type u) : Set (Set (Ultrafilter α)) :=
range fun s : Set α ↦ { u | s ∈ u }
variable {α : Type u}
instance Ultrafilter.topologicalSpace : TopologicalSpace (Ultrafilter α) :=
TopologicalSpace.generateFrom (ultrafilterBasis α)
theorem ultrafilterBasis_is_basis : TopologicalSpace.IsTopologicalBasis (ultrafilterBasis α) :=
⟨by
rintro _ ⟨a, rfl⟩ _ ⟨b, rfl⟩ u ⟨ua, ub⟩
refine ⟨_, ⟨a ∩ b, rfl⟩, inter_mem ua ub, fun v hv ↦ ⟨?_, ?_⟩⟩ <;> apply mem_of_superset hv <;>
simp [inter_subset_right],
eq_univ_of_univ_subset <| subset_sUnion_of_mem <| ⟨univ, eq_univ_of_forall fun _ ↦ univ_mem⟩,
rfl⟩
/-- The basic open sets for the topology on ultrafilters are open. -/
theorem ultrafilter_isOpen_basic (s : Set α) : IsOpen { u : Ultrafilter α | s ∈ u } :=
ultrafilterBasis_is_basis.isOpen ⟨s, rfl⟩
/-- The basic open sets for the topology on ultrafilters are also closed. -/
theorem ultrafilter_isClosed_basic (s : Set α) : IsClosed { u : Ultrafilter α | s ∈ u } := by
rw [← isOpen_compl_iff]
convert ultrafilter_isOpen_basic sᶜ using 1
ext u
exact Ultrafilter.compl_mem_iff_not_mem.symm
/-- Every ultrafilter `u` on `Ultrafilter α` converges to a unique
point of `Ultrafilter α`, namely `joinM u`. -/
theorem ultrafilter_converges_iff {u : Ultrafilter (Ultrafilter α)} {x : Ultrafilter α} :
↑u ≤ 𝓝 x ↔ x = joinM u := by
rw [eq_comm, ← Ultrafilter.coe_le_coe]
change ↑u ≤ 𝓝 x ↔ ∀ s ∈ x, { v : Ultrafilter α | s ∈ v } ∈ u
simp only [TopologicalSpace.nhds_generateFrom, le_iInf_iff, ultrafilterBasis, le_principal_iff,
mem_setOf_eq]
constructor
· intro h a ha
exact h _ ⟨ha, a, rfl⟩
· rintro h a ⟨xi, a, rfl⟩
exact h _ xi
instance ultrafilter_compact : CompactSpace (Ultrafilter α) :=
⟨isCompact_iff_ultrafilter_le_nhds.mpr fun f _ ↦
⟨joinM f, trivial, ultrafilter_converges_iff.mpr rfl⟩⟩
instance Ultrafilter.t2Space : T2Space (Ultrafilter α) :=
t2_iff_ultrafilter.mpr fun {x y} f fx fy ↦
have hx : x = joinM f := ultrafilter_converges_iff.mp fx
have hy : y = joinM f := ultrafilter_converges_iff.mp fy
hx.trans hy.symm
instance : TotallyDisconnectedSpace (Ultrafilter α) := by
rw [totallyDisconnectedSpace_iff_connectedComponent_singleton]
intro A
simp only [Set.eq_singleton_iff_unique_mem, mem_connectedComponent, true_and]
intro B hB
rw [← Ultrafilter.coe_le_coe]
intro s hs
rw [connectedComponent_eq_iInter_isClopen, Set.mem_iInter] at hB
let Z := { F : Ultrafilter α | s ∈ F }
have hZ : IsClopen Z := ⟨ultrafilter_isClosed_basic s, ultrafilter_isOpen_basic s⟩
exact hB ⟨Z, hZ, hs⟩
@[simp] theorem Ultrafilter.tendsto_pure_self (b : Ultrafilter α) : Tendsto pure b (𝓝 b) := by
rw [Tendsto, ← coe_map, ultrafilter_converges_iff]
ext s
change s ∈ b ↔ {t | s ∈ t} ∈ map pure b
simp_rw [mem_map, preimage_setOf_eq, mem_pure, setOf_mem_eq]
theorem ultrafilter_comap_pure_nhds (b : Ultrafilter α) : comap pure (𝓝 b) ≤ b := by
rw [TopologicalSpace.nhds_generateFrom]
simp only [comap_iInf, comap_principal]
intro s hs
rw [← le_principal_iff]
refine iInf_le_of_le { u | s ∈ u } ?_
refine iInf_le_of_le ⟨hs, ⟨s, rfl⟩⟩ ?_
exact principal_mono.2 fun _ ↦ id
section Embedding
theorem ultrafilter_pure_injective : Function.Injective (pure : α → Ultrafilter α) := by
intro x y h
have : {x} ∈ (pure x : Ultrafilter α) := singleton_mem_pure
rw [h] at this
exact (mem_singleton_iff.mp (mem_pure.mp this)).symm
open TopologicalSpace
/-- The range of `pure : α → Ultrafilter α` is dense in `Ultrafilter α`. -/
theorem denseRange_pure : DenseRange (pure : α → Ultrafilter α) :=
fun x ↦ mem_closure_iff_ultrafilter.mpr
⟨x.map pure, range_mem_map, ultrafilter_converges_iff.mpr (bind_pure x).symm⟩
/-- The map `pure : α → Ultrafilter α` induces on `α` the discrete topology. -/
theorem induced_topology_pure :
TopologicalSpace.induced (pure : α → Ultrafilter α) Ultrafilter.topologicalSpace = ⊥ := by
apply eq_bot_of_singletons_open
intro x
use { u : Ultrafilter α | {x} ∈ u }, ultrafilter_isOpen_basic _
simp
/-- `pure : α → Ultrafilter α` defines a dense inducing of `α` in `Ultrafilter α`. -/
theorem isDenseInducing_pure : @IsDenseInducing _ _ ⊥ _ (pure : α → Ultrafilter α) :=
letI : TopologicalSpace α := ⊥
⟨⟨induced_topology_pure.symm⟩, denseRange_pure⟩
-- The following refined version will never be used
/-- `pure : α → Ultrafilter α` defines a dense embedding of `α` in `Ultrafilter α`. -/
theorem isDenseEmbedding_pure : @IsDenseEmbedding _ _ ⊥ _ (pure : α → Ultrafilter α) :=
letI : TopologicalSpace α := ⊥
{ isDenseInducing_pure with injective := ultrafilter_pure_injective }
end Embedding
section Extension
/- Goal: Any function `α → γ` to a compact Hausdorff space `γ` has a
unique extension to a continuous function `Ultrafilter α → γ`. We
already know it must be unique because `α → Ultrafilter α` is a
dense embedding and `γ` is Hausdorff. For existence, we will invoke
`IsDenseInducing.continuous_extend`. -/
variable {γ : Type*} [TopologicalSpace γ]
/-- The extension of a function `α → γ` to a function `Ultrafilter α → γ`.
When `γ` is a compact Hausdorff space it will be continuous. -/
def Ultrafilter.extend (f : α → γ) : Ultrafilter α → γ :=
letI : TopologicalSpace α := ⊥
isDenseInducing_pure.extend f
variable [T2Space γ]
theorem ultrafilter_extend_extends (f : α → γ) : Ultrafilter.extend f ∘ pure = f := by
letI : TopologicalSpace α := ⊥
haveI : DiscreteTopology α := ⟨rfl⟩
exact funext (isDenseInducing_pure.extend_eq continuous_of_discreteTopology)
variable [CompactSpace γ]
theorem continuous_ultrafilter_extend (f : α → γ) : Continuous (Ultrafilter.extend f) := by
have h (b : Ultrafilter α) : ∃ c, Tendsto f (comap pure (𝓝 b)) (𝓝 c) :=
-- b.map f is an ultrafilter on γ, which is compact, so it converges to some c in γ.
let ⟨c, _, h'⟩ :=
isCompact_univ.ultrafilter_le_nhds (b.map f) (by rw [le_principal_iff]; exact univ_mem)
⟨c, le_trans (map_mono (ultrafilter_comap_pure_nhds _)) h'⟩
let _ : TopologicalSpace α := ⊥
exact isDenseInducing_pure.continuous_extend h
/-- The value of `Ultrafilter.extend f` on an ultrafilter `b` is the
unique limit of the ultrafilter `b.map f` in `γ`. -/
theorem ultrafilter_extend_eq_iff {f : α → γ} {b : Ultrafilter α} {c : γ} :
Ultrafilter.extend f b = c ↔ ↑(b.map f) ≤ 𝓝 c :=
⟨fun h ↦ by
-- Write b as an ultrafilter limit of pure ultrafilters, and use
-- the facts that ultrafilter.extend is a continuous extension of f.
let b' : Ultrafilter (Ultrafilter α) := b.map pure
have t : ↑b' ≤ 𝓝 b := ultrafilter_converges_iff.mpr (bind_pure _).symm
rw [← h]
have := (continuous_ultrafilter_extend f).tendsto b
refine le_trans ?_ (le_trans (map_mono t) this)
change _ ≤ map (Ultrafilter.extend f ∘ pure) ↑b
rw [ultrafilter_extend_extends]
exact le_rfl,
fun h ↦
let _ : TopologicalSpace α := ⊥
isDenseInducing_pure.extend_eq_of_tendsto
(le_trans (map_mono (ultrafilter_comap_pure_nhds _)) h)⟩
end Extension
end Ultrafilter
section PreStoneCech
variable (α : Type u) [TopologicalSpace α]
/-- Auxiliary construction towards the Stone-Čech compactification of a topological space.
It should not be used after the Stone-Čech compactification is constructed. -/
def PreStoneCech : Type u :=
Quot fun F G : Ultrafilter α ↦ ∃ x, (F : Filter α) ≤ 𝓝 x ∧ (G : Filter α) ≤ 𝓝 x
variable {α}
instance : TopologicalSpace (PreStoneCech α) :=
inferInstanceAs (TopologicalSpace <| Quot _)
instance : CompactSpace (PreStoneCech α) :=
Quot.compactSpace
instance [Inhabited α] : Inhabited (PreStoneCech α) :=
inferInstanceAs (Inhabited <| Quot _)
/-- The natural map from α to its pre-Stone-Čech compactification. -/
def preStoneCechUnit (x : α) : PreStoneCech α :=
Quot.mk _ (pure x : Ultrafilter α)
theorem continuous_preStoneCechUnit : Continuous (preStoneCechUnit : α → PreStoneCech α) :=
continuous_iff_ultrafilter.mpr fun x g gx ↦ by
have : (g.map pure).toFilter ≤ 𝓝 g := by
rw [ultrafilter_converges_iff, ← bind_pure g]
rfl
have : (map preStoneCechUnit g : Filter (PreStoneCech α)) ≤ 𝓝 (Quot.mk _ g) :=
(map_mono this).trans (continuous_quot_mk.tendsto _)
convert this
exact Quot.sound ⟨x, pure_le_nhds x, gx⟩
theorem denseRange_preStoneCechUnit : DenseRange (preStoneCechUnit : α → PreStoneCech α) :=
Quot.mk_surjective.denseRange.comp denseRange_pure continuous_coinduced_rng
section Extension
variable {β : Type v} [TopologicalSpace β] [T2Space β]
theorem preStoneCech_hom_ext {g₁ g₂ : PreStoneCech α → β} (h₁ : Continuous g₁) (h₂ : Continuous g₂)
(h : g₁ ∘ preStoneCechUnit = g₂ ∘ preStoneCechUnit) : g₁ = g₂ := by
apply Continuous.ext_on denseRange_preStoneCechUnit h₁ h₂
rintro x ⟨x, rfl⟩
apply congr_fun h x
variable [CompactSpace β]
variable {g : α → β} (hg : Continuous g)
include hg
lemma preStoneCechCompat {F G : Ultrafilter α} {x : α} (hF : ↑F ≤ 𝓝 x) (hG : ↑G ≤ 𝓝 x) :
Ultrafilter.extend g F = Ultrafilter.extend g G := by
replace hF := (map_mono hF).trans hg.continuousAt
replace hG := (map_mono hG).trans hg.continuousAt
rwa [show Ultrafilter.extend g G = g x by rwa [ultrafilter_extend_eq_iff, G.coe_map],
ultrafilter_extend_eq_iff, F.coe_map]
/-- The extension of a continuous function from `α` to a compact
Hausdorff space `β` to the pre-Stone-Čech compactification of `α`. -/
def preStoneCechExtend : PreStoneCech α → β :=
Quot.lift (Ultrafilter.extend g) fun _ _ ⟨_, hF, hG⟩ ↦ preStoneCechCompat hg hF hG
theorem preStoneCechExtend_extends : preStoneCechExtend hg ∘ preStoneCechUnit = g :=
ultrafilter_extend_extends g
lemma eq_if_preStoneCechUnit_eq {a b : α} (h : preStoneCechUnit a = preStoneCechUnit b) :
g a = g b := by
have e := ultrafilter_extend_extends g
rw [← congrFun e a, ← congrFun e b, Function.comp_apply, Function.comp_apply]
rw [preStoneCechUnit, preStoneCechUnit, Quot.eq] at h
generalize (pure a : Ultrafilter α) = F at h
generalize (pure b : Ultrafilter α) = G at h
induction h with
| rel x y a => exact let ⟨a, hx, hy⟩ := a; preStoneCechCompat hg hx hy
| refl x => rfl
| symm x y _ h => rw [h]
| trans x y z _ _ h h' => exact h.trans h'
theorem continuous_preStoneCechExtend : Continuous (preStoneCechExtend hg) :=
continuous_quot_lift _ (continuous_ultrafilter_extend g)
end Extension
end PreStoneCech
section StoneCech
variable (α : Type u) [TopologicalSpace α]
/-- The Stone-Čech compactification of a topological space. -/
def StoneCech : Type u :=
t2Quotient (PreStoneCech α)
variable {α}
instance : TopologicalSpace (StoneCech α) :=
inferInstanceAs <| TopologicalSpace <| t2Quotient _
instance : T2Space (StoneCech α) :=
inferInstanceAs <| T2Space <| t2Quotient _
instance : CompactSpace (StoneCech α) :=
Quot.compactSpace
instance [Inhabited α] : Inhabited (StoneCech α) :=
inferInstanceAs <| Inhabited <| Quotient _
/-- The natural map from α to its Stone-Čech compactification. -/
def stoneCechUnit (x : α) : StoneCech α :=
t2Quotient.mk (preStoneCechUnit x)
theorem continuous_stoneCechUnit : Continuous (stoneCechUnit : α → StoneCech α) :=
(t2Quotient.continuous_mk _).comp continuous_preStoneCechUnit
/-- The image of `stoneCechUnit` is dense. (But `stoneCechUnit` need
not be an embedding, for example if the original space is not Hausdorff.) -/
theorem denseRange_stoneCechUnit : DenseRange (stoneCechUnit : α → StoneCech α) := by
unfold stoneCechUnit t2Quotient.mk
have : Function.Surjective (t2Quotient.mk : PreStoneCech α → StoneCech α) := by
exact Quot.mk_surjective
exact this.denseRange.comp denseRange_preStoneCechUnit continuous_coinduced_rng
section Extension
variable {β : Type v} [TopologicalSpace β] [T2Space β]
variable {g : α → β} (hg : Continuous g)
theorem stoneCech_hom_ext {g₁ g₂ : StoneCech α → β} (h₁ : Continuous g₁) (h₂ : Continuous g₂)
(h : g₁ ∘ stoneCechUnit = g₂ ∘ stoneCechUnit) : g₁ = g₂ := by
apply h₁.ext_on denseRange_stoneCechUnit h₂
rintro _ ⟨x, rfl⟩
exact congr_fun h x
variable [CompactSpace β]
/-- The extension of a continuous function from `α` to a compact
Hausdorff space `β` to the Stone-Čech compactification of `α`.
This extension implements the universal property of this compactification. -/
def stoneCechExtend : StoneCech α → β :=
t2Quotient.lift (continuous_preStoneCechExtend hg)
theorem stoneCechExtend_extends : stoneCechExtend hg ∘ stoneCechUnit = g := by
ext x
rw [stoneCechExtend, Function.comp_apply, stoneCechUnit, t2Quotient.lift_mk]
apply congrFun (preStoneCechExtend_extends hg)
theorem continuous_stoneCechExtend : Continuous (stoneCechExtend hg) :=
continuous_coinduced_dom.mpr (continuous_preStoneCechExtend hg)
lemma eq_if_stoneCechUnit_eq {a b : α} {f : α → β} (hcf : Continuous f)
(h : stoneCechUnit a = stoneCechUnit b) : f a = f b := by
rw [← congrFun (stoneCechExtend_extends hcf), ← congrFun (stoneCechExtend_extends hcf)]
exact congrArg (stoneCechExtend hcf) h
end Extension
end StoneCech
| Mathlib/Topology/StoneCech.lean | 385 | 389 | |
/-
Copyright (c) 2022 Jireh Loreaux. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jireh Loreaux
-/
import Mathlib.Algebra.Algebra.Equiv
import Mathlib.Algebra.Algebra.NonUnitalHom
import Mathlib.Algebra.Algebra.Prod
import Mathlib.Algebra.Algebra.Pi
import Mathlib.Algebra.Star.Prod
import Mathlib.Algebra.Star.Pi
import Mathlib.Algebra.Star.StarRingHom
/-!
# Morphisms of star algebras
This file defines morphisms between `R`-algebras (unital or non-unital) `A` and `B` where both
`A` and `B` are equipped with a `star` operation. These morphisms, namely `StarAlgHom` and
`NonUnitalStarAlgHom` are direct extensions of their non-`star`red counterparts with a field
`map_star` which guarantees they preserve the star operation. We keep the type classes as generic
as possible, in keeping with the definition of `NonUnitalAlgHom` in the non-unital case. In this
file, we only assume `Star` unless we want to talk about the zero map as a
`NonUnitalStarAlgHom`, in which case we need `StarAddMonoid`. Note that the scalar ring `R`
is not required to have a star operation, nor do we need `StarRing` or `StarModule` structures on
`A` and `B`.
As with `NonUnitalAlgHom`, in the non-unital case the multiplications are not assumed to be
associative or unital, or even to be compatible with the scalar actions. In a typical application,
the operations will satisfy compatibility conditions making them into algebras (albeit possibly
non-associative and/or non-unital) but such conditions are not required here for the definitions.
The primary impetus for defining these types is that they constitute the morphisms in the categories
of unital C⋆-algebras (with `StarAlgHom`s) and of C⋆-algebras (with `NonUnitalStarAlgHom`s).
## Main definitions
* `NonUnitalStarAlgHom`
* `StarAlgHom`
## Tags
non-unital, algebra, morphism, star
-/
open EquivLike
/-! ### Non-unital star algebra homomorphisms -/
/-- A *non-unital ⋆-algebra homomorphism* is a non-unital algebra homomorphism between
non-unital `R`-algebras `A` and `B` equipped with a `star` operation, and this homomorphism is
also `star`-preserving. -/
structure NonUnitalStarAlgHom (R A B : Type*) [Monoid R] [NonUnitalNonAssocSemiring A]
[DistribMulAction R A] [Star A] [NonUnitalNonAssocSemiring B] [DistribMulAction R B]
[Star B] extends A →ₙₐ[R] B where
/-- By definition, a non-unital ⋆-algebra homomorphism preserves the `star` operation. -/
map_star' : ∀ a : A, toFun (star a) = star (toFun a)
@[inherit_doc NonUnitalStarAlgHom] infixr:25 " →⋆ₙₐ " => NonUnitalStarAlgHom _
@[inherit_doc] notation:25 A " →⋆ₙₐ[" R "] " B => NonUnitalStarAlgHom R A B
/-- Reinterpret a non-unital star algebra homomorphism as a non-unital algebra homomorphism
by forgetting the interaction with the star operation. -/
add_decl_doc NonUnitalStarAlgHom.toNonUnitalAlgHom
namespace NonUnitalStarAlgHomClass
variable {F R A B : Type*} [Monoid R]
variable [NonUnitalNonAssocSemiring A] [DistribMulAction R A] [Star A]
variable [NonUnitalNonAssocSemiring B] [DistribMulAction R B] [Star B]
variable [FunLike F A B] [NonUnitalAlgHomClass F R A B]
/-- Turn an element of a type `F` satisfying `NonUnitalAlgHomClass F R A B` and `StarHomClass F A B`
into an actual `NonUnitalStarAlgHom`. This is declared as the default coercion from `F` to
`A →⋆ₙₐ[R] B`. -/
@[coe]
def toNonUnitalStarAlgHom [StarHomClass F A B] (f : F) : A →⋆ₙₐ[R] B :=
{ (f : A →ₙₐ[R] B) with
map_star' := map_star f }
instance [StarHomClass F A B] : CoeTC F (A →⋆ₙₐ[R] B) :=
⟨toNonUnitalStarAlgHom⟩
instance [StarHomClass F A B] : NonUnitalStarRingHomClass F A B :=
NonUnitalStarRingHomClass.mk
end NonUnitalStarAlgHomClass
namespace NonUnitalStarAlgHom
section Basic
variable {R A B C D : Type*} [Monoid R]
variable [NonUnitalNonAssocSemiring A] [DistribMulAction R A] [Star A]
variable [NonUnitalNonAssocSemiring B] [DistribMulAction R B] [Star B]
variable [NonUnitalNonAssocSemiring C] [DistribMulAction R C] [Star C]
variable [NonUnitalNonAssocSemiring D] [DistribMulAction R D] [Star D]
instance : FunLike (A →⋆ₙₐ[R] B) A B where
coe f := f.toFun
coe_injective' := by rintro ⟨⟨⟨⟨f, _⟩, _⟩, _⟩, _⟩ ⟨⟨⟨⟨g, _⟩, _⟩, _⟩, _⟩ h; congr
instance : NonUnitalAlgHomClass (A →⋆ₙₐ[R] B) R A B where
map_smulₛₗ f := f.map_smul'
map_add f := f.map_add'
map_zero f := f.map_zero'
map_mul f := f.map_mul'
instance : StarHomClass (A →⋆ₙₐ[R] B) A B where
map_star f := f.map_star'
-- Porting note: in mathlib3 we didn't need the `Simps.apply` hint.
/-- See Note [custom simps projection] -/
def Simps.apply (f : A →⋆ₙₐ[R] B) : A → B := f
initialize_simps_projections NonUnitalStarAlgHom
(toFun → apply)
@[simp]
protected theorem coe_coe {F : Type*} [FunLike F A B] [NonUnitalAlgHomClass F R A B]
[StarHomClass F A B] (f : F) :
⇑(f : A →⋆ₙₐ[R] B) = f := rfl
@[simp]
theorem coe_toNonUnitalAlgHom {f : A →⋆ₙₐ[R] B} : (f.toNonUnitalAlgHom : A → B) = f :=
rfl
@[ext]
theorem ext {f g : A →⋆ₙₐ[R] B} (h : ∀ x, f x = g x) : f = g :=
DFunLike.ext _ _ h
/-- Copy of a `NonUnitalStarAlgHom` with a new `toFun` equal to the old one. Useful
to fix definitional equalities. -/
protected def copy (f : A →⋆ₙₐ[R] B) (f' : A → B) (h : f' = f) : A →⋆ₙₐ[R] B where
toFun := f'
map_smul' := h.symm ▸ map_smul f
map_zero' := h.symm ▸ map_zero f
map_add' := h.symm ▸ map_add f
map_mul' := h.symm ▸ map_mul f
map_star' := h.symm ▸ map_star f
@[simp]
theorem coe_copy (f : A →⋆ₙₐ[R] B) (f' : A → B) (h : f' = f) : ⇑(f.copy f' h) = f' :=
rfl
theorem copy_eq (f : A →⋆ₙₐ[R] B) (f' : A → B) (h : f' = f) : f.copy f' h = f :=
DFunLike.ext' h
@[simp]
theorem coe_mk (f : A → B) (h₁ h₂ h₃ h₄ h₅) :
((⟨⟨⟨⟨f, h₁⟩, h₂, h₃⟩, h₄⟩, h₅⟩ : A →⋆ₙₐ[R] B) : A → B) = f :=
rfl
-- this is probably the more useful lemma for Lean 4 and should likely replace `coe_mk` above
@[simp]
theorem coe_mk' (f : A →ₙₐ[R] B) (h) :
((⟨f, h⟩ : A →⋆ₙₐ[R] B) : A → B) = f :=
rfl
@[simp]
theorem mk_coe (f : A →⋆ₙₐ[R] B) (h₁ h₂ h₃ h₄ h₅) :
(⟨⟨⟨⟨f, h₁⟩, h₂, h₃⟩, h₄⟩, h₅⟩ : A →⋆ₙₐ[R] B) = f := by
ext
rfl
section
variable (R A)
/-- The identity as a non-unital ⋆-algebra homomorphism. -/
protected def id : A →⋆ₙₐ[R] A :=
{ (1 : A →ₙₐ[R] A) with map_star' := fun _ => rfl }
@[simp, norm_cast]
theorem coe_id : ⇑(NonUnitalStarAlgHom.id R A) = id :=
rfl
end
/-- The composition of non-unital ⋆-algebra homomorphisms, as a non-unital ⋆-algebra
homomorphism. -/
def comp (f : B →⋆ₙₐ[R] C) (g : A →⋆ₙₐ[R] B) : A →⋆ₙₐ[R] C :=
{ f.toNonUnitalAlgHom.comp g.toNonUnitalAlgHom with
map_star' := by
simp only [map_star, NonUnitalAlgHom.toFun_eq_coe, eq_self_iff_true, NonUnitalAlgHom.coe_comp,
coe_toNonUnitalAlgHom, Function.comp_apply, forall_const] }
@[simp]
theorem coe_comp (f : B →⋆ₙₐ[R] C) (g : A →⋆ₙₐ[R] B) : ⇑(comp f g) = f ∘ g :=
rfl
@[simp]
theorem comp_apply (f : B →⋆ₙₐ[R] C) (g : A →⋆ₙₐ[R] B) (a : A) : comp f g a = f (g a) :=
rfl
@[simp]
theorem comp_assoc (f : C →⋆ₙₐ[R] D) (g : B →⋆ₙₐ[R] C) (h : A →⋆ₙₐ[R] B) :
(f.comp g).comp h = f.comp (g.comp h) :=
rfl
@[simp]
theorem id_comp (f : A →⋆ₙₐ[R] B) : (NonUnitalStarAlgHom.id _ _).comp f = f :=
ext fun _ => rfl
@[simp]
theorem comp_id (f : A →⋆ₙₐ[R] B) : f.comp (NonUnitalStarAlgHom.id _ _) = f :=
ext fun _ => rfl
instance : Monoid (A →⋆ₙₐ[R] A) where
mul := comp
mul_assoc := comp_assoc
one := NonUnitalStarAlgHom.id R A
one_mul := id_comp
mul_one := comp_id
@[simp]
theorem coe_one : ((1 : A →⋆ₙₐ[R] A) : A → A) = id :=
rfl
theorem one_apply (a : A) : (1 : A →⋆ₙₐ[R] A) a = a :=
rfl
end Basic
section Zero
-- the `zero` requires extra type class assumptions because we need `star_zero`
variable {R A B C D : Type*} [Monoid R]
variable [NonUnitalNonAssocSemiring A] [DistribMulAction R A] [StarAddMonoid A]
variable [NonUnitalNonAssocSemiring B] [DistribMulAction R B] [StarAddMonoid B]
instance : Zero (A →⋆ₙₐ[R] B) :=
⟨{ (0 : NonUnitalAlgHom (MonoidHom.id R) A B) with map_star' := by simp }⟩
instance : Inhabited (A →⋆ₙₐ[R] B) :=
⟨0⟩
instance : MonoidWithZero (A →⋆ₙₐ[R] A) :=
{ inferInstanceAs (Monoid (A →⋆ₙₐ[R] A)),
inferInstanceAs (Zero (A →⋆ₙₐ[R] A)) with
zero_mul := fun _ => ext fun _ => rfl
mul_zero := fun f => ext fun _ => map_zero f }
@[simp]
theorem coe_zero : ((0 : A →⋆ₙₐ[R] B) : A → B) = 0 :=
rfl
theorem zero_apply (a : A) : (0 : A →⋆ₙₐ[R] B) a = 0 :=
rfl
end Zero
section RestrictScalars
variable (R : Type*) {S A B : Type*} [Monoid R] [Monoid S] [Star A] [Star B]
[NonUnitalNonAssocSemiring A] [NonUnitalNonAssocSemiring B] [MulAction R S]
[DistribMulAction S A] [DistribMulAction S B] [DistribMulAction R A] [DistribMulAction R B]
[IsScalarTower R S A] [IsScalarTower R S B]
/-- If a monoid `R` acts on another monoid `S`, then a non-unital star algebra homomorphism
over `S` can be viewed as a non-unital star algebra homomorphism over `R`. -/
def restrictScalars (f : A →⋆ₙₐ[S] B) : A →⋆ₙₐ[R] B :=
{ (f : A →ₙₐ[S] B).restrictScalars R with
map_star' := map_star f }
@[simp]
lemma restrictScalars_apply (f : A →⋆ₙₐ[S] B) (x : A) : f.restrictScalars R x = f x := rfl
lemma coe_restrictScalars (f : A →⋆ₙₐ[S] B) : (f.restrictScalars R : A →ₙ+* B) = f := rfl
lemma coe_restrictScalars' (f : A →⋆ₙₐ[S] B) : (f.restrictScalars R : A → B) = f := rfl
theorem restrictScalars_injective :
Function.Injective (restrictScalars R : (A →⋆ₙₐ[S] B) → A →⋆ₙₐ[R] B) :=
fun _ _ h ↦ ext (DFunLike.congr_fun h :)
end RestrictScalars
end NonUnitalStarAlgHom
/-! ### Unital star algebra homomorphisms -/
section Unital
/-- A *⋆-algebra homomorphism* is an algebra homomorphism between `R`-algebras `A` and `B`
equipped with a `star` operation, and this homomorphism is also `star`-preserving. -/
structure StarAlgHom (R A B : Type*) [CommSemiring R] [Semiring A] [Algebra R A] [Star A]
[Semiring B] [Algebra R B] [Star B] extends AlgHom R A B where
/-- By definition, a ⋆-algebra homomorphism preserves the `star` operation. -/
map_star' : ∀ x : A, toFun (star x) = star (toFun x)
@[inherit_doc StarAlgHom] infixr:25 " →⋆ₐ " => StarAlgHom _
@[inherit_doc] notation:25 A " →⋆ₐ[" R "] " B => StarAlgHom R A B
/-- Reinterpret a unital star algebra homomorphism as a unital algebra homomorphism
by forgetting the interaction with the star operation. -/
add_decl_doc StarAlgHom.toAlgHom
namespace StarAlgHomClass
variable {F R A B : Type*}
variable [CommSemiring R] [Semiring A] [Algebra R A] [Star A]
variable [Semiring B] [Algebra R B] [Star B] [FunLike F A B] [AlgHomClass F R A B]
variable [StarHomClass F A B]
/-- Turn an element of a type `F` satisfying `AlgHomClass F R A B` and `StarHomClass F A B` into an
actual `StarAlgHom`. This is declared as the default coercion from `F` to `A →⋆ₐ[R] B`. -/
@[coe]
def toStarAlgHom (f : F) : A →⋆ₐ[R] B :=
{ (f : A →ₐ[R] B) with
map_star' := map_star f }
instance : CoeTC F (A →⋆ₐ[R] B) :=
⟨toStarAlgHom⟩
end StarAlgHomClass
namespace StarAlgHom
variable {F R A B C D : Type*} [CommSemiring R] [Semiring A] [Algebra R A] [Star A] [Semiring B]
[Algebra R B] [Star B] [Semiring C] [Algebra R C] [Star C] [Semiring D] [Algebra R D] [Star D]
instance : FunLike (A →⋆ₐ[R] B) A B where
coe f := f.toFun
coe_injective' := by rintro ⟨⟨⟨⟨⟨f, _⟩, _⟩, _⟩, _⟩, _⟩ ⟨⟨⟨⟨⟨g, _⟩, _⟩, _⟩, _⟩, _⟩ h; congr
instance : AlgHomClass (A →⋆ₐ[R] B) R A B where
map_mul f := f.map_mul'
map_one f := f.map_one'
map_add f := f.map_add'
map_zero f := f.map_zero'
commutes f := f.commutes'
instance : StarHomClass (A →⋆ₐ[R] B) A B where
map_star f := f.map_star'
@[simp]
protected theorem coe_coe {F : Type*} [FunLike F A B] [AlgHomClass F R A B]
[StarHomClass F A B] (f : F) :
⇑(f : A →⋆ₐ[R] B) = f :=
rfl
-- Porting note: in mathlib3 we didn't need the `Simps.apply` hint.
/-- See Note [custom simps projection] -/
def Simps.apply (f : A →⋆ₐ[R] B) : A → B := f
initialize_simps_projections StarAlgHom (toFun → apply)
@[simp]
theorem coe_toAlgHom {f : A →⋆ₐ[R] B} : (f.toAlgHom : A → B) = f :=
rfl
@[ext]
theorem ext {f g : A →⋆ₐ[R] B} (h : ∀ x, f x = g x) : f = g :=
DFunLike.ext _ _ h
/-- Copy of a `StarAlgHom` with a new `toFun` equal to the old one. Useful
to fix definitional equalities. -/
protected def copy (f : A →⋆ₐ[R] B) (f' : A → B) (h : f' = f) : A →⋆ₐ[R] B where
toFun := f'
map_one' := h.symm ▸ map_one f
map_mul' := h.symm ▸ map_mul f
map_zero' := h.symm ▸ map_zero f
map_add' := h.symm ▸ map_add f
commutes' := h.symm ▸ AlgHomClass.commutes f
map_star' := h.symm ▸ map_star f
@[simp]
theorem coe_copy (f : A →⋆ₐ[R] B) (f' : A → B) (h : f' = f) : ⇑(f.copy f' h) = f' :=
rfl
theorem copy_eq (f : A →⋆ₐ[R] B) (f' : A → B) (h : f' = f) : f.copy f' h = f :=
DFunLike.ext' h
@[simp]
theorem coe_mk (f : A → B) (h₁ h₂ h₃ h₄ h₅ h₆) :
((⟨⟨⟨⟨⟨f, h₁⟩, h₂⟩, h₃, h₄⟩, h₅⟩, h₆⟩ : A →⋆ₐ[R] B) : A → B) = f :=
rfl
-- this is probably the more useful lemma for Lean 4 and should likely replace `coe_mk` above
@[simp]
theorem coe_mk' (f : A →ₐ[R] B) (h) :
((⟨f, h⟩ : A →⋆ₐ[R] B) : A → B) = f :=
rfl
@[simp]
theorem mk_coe (f : A →⋆ₐ[R] B) (h₁ h₂ h₃ h₄ h₅ h₆) :
(⟨⟨⟨⟨⟨f, h₁⟩, h₂⟩, h₃, h₄⟩, h₅⟩, h₆⟩ : A →⋆ₐ[R] B) = f := by
ext
rfl
section
variable (R A)
/-- The identity as a `StarAlgHom`. -/
protected def id : A →⋆ₐ[R] A :=
{ AlgHom.id _ _ with map_star' := fun _ => rfl }
@[simp, norm_cast]
theorem coe_id : ⇑(StarAlgHom.id R A) = id :=
rfl
/-- `algebraMap R A` as a `StarAlgHom` when `A` is a star algebra over `R`. -/
@[simps]
def ofId (R A : Type*) [CommSemiring R] [StarRing R] [Semiring A] [StarMul A]
[Algebra R A] [StarModule R A] : R →⋆ₐ[R] A :=
{ Algebra.ofId R A with
toFun := algebraMap R A
map_star' := by simp [Algebra.algebraMap_eq_smul_one] }
end
instance : Inhabited (A →⋆ₐ[R] A) :=
⟨StarAlgHom.id R A⟩
/-- The composition of ⋆-algebra homomorphisms, as a ⋆-algebra homomorphism. -/
def comp (f : B →⋆ₐ[R] C) (g : A →⋆ₐ[R] B) : A →⋆ₐ[R] C :=
{ f.toAlgHom.comp g.toAlgHom with
map_star' := by
simp only [map_star, AlgHom.toFun_eq_coe, AlgHom.coe_comp, coe_toAlgHom,
Function.comp_apply, eq_self_iff_true, forall_const] }
@[simp]
theorem coe_comp (f : B →⋆ₐ[R] C) (g : A →⋆ₐ[R] B) : ⇑(comp f g) = f ∘ g :=
rfl
@[simp]
theorem comp_apply (f : B →⋆ₐ[R] C) (g : A →⋆ₐ[R] B) (a : A) : comp f g a = f (g a) :=
rfl
@[simp]
theorem comp_assoc (f : C →⋆ₐ[R] D) (g : B →⋆ₐ[R] C) (h : A →⋆ₐ[R] B) :
(f.comp g).comp h = f.comp (g.comp h) :=
rfl
@[simp]
theorem id_comp (f : A →⋆ₐ[R] B) : (StarAlgHom.id _ _).comp f = f :=
ext fun _ => rfl
@[simp]
theorem comp_id (f : A →⋆ₐ[R] B) : f.comp (StarAlgHom.id _ _) = f :=
ext fun _ => rfl
instance : Monoid (A →⋆ₐ[R] A) where
mul := comp
mul_assoc := comp_assoc
one := StarAlgHom.id R A
one_mul := id_comp
mul_one := comp_id
/-- A unital morphism of ⋆-algebras is a `NonUnitalStarAlgHom`. -/
def toNonUnitalStarAlgHom (f : A →⋆ₐ[R] B) : A →⋆ₙₐ[R] B :=
{ f with map_smul' := map_smul f }
@[simp]
theorem coe_toNonUnitalStarAlgHom (f : A →⋆ₐ[R] B) : (f.toNonUnitalStarAlgHom : A → B) = f :=
rfl
end StarAlgHom
end Unital
/-! ### Operations on the product type
Note that this is copied from [`Algebra.Hom.NonUnitalAlg`](../Hom/NonUnitalAlg). -/
namespace NonUnitalStarAlgHom
section Prod
variable (R A B C : Type*) [Monoid R] [NonUnitalNonAssocSemiring A] [DistribMulAction R A] [Star A]
[NonUnitalNonAssocSemiring B] [DistribMulAction R B] [Star B] [NonUnitalNonAssocSemiring C]
[DistribMulAction R C] [Star C]
/-- The first projection of a product is a non-unital ⋆-algebra homomorphism. -/
@[simps!]
def fst : A × B →⋆ₙₐ[R] A :=
{ NonUnitalAlgHom.fst R A B with map_star' := fun _ => rfl }
/-- The second projection of a product is a non-unital ⋆-algebra homomorphism. -/
@[simps!]
def snd : A × B →⋆ₙₐ[R] B :=
{ NonUnitalAlgHom.snd R A B with map_star' := fun _ => rfl }
variable {R A B C}
/-- The `Pi.prod` of two morphisms is a morphism. -/
@[simps!]
def prod (f : A →⋆ₙₐ[R] B) (g : A →⋆ₙₐ[R] C) : A →⋆ₙₐ[R] B × C :=
{ f.toNonUnitalAlgHom.prod g.toNonUnitalAlgHom with
map_star' := fun x => by simp [map_star, Prod.star_def] }
theorem coe_prod (f : A →⋆ₙₐ[R] B) (g : A →⋆ₙₐ[R] C) : ⇑(f.prod g) = Pi.prod f g :=
rfl
@[simp]
theorem fst_prod (f : A →⋆ₙₐ[R] B) (g : A →⋆ₙₐ[R] C) : (fst R B C).comp (prod f g) = f := by
ext; rfl
@[simp]
theorem snd_prod (f : A →⋆ₙₐ[R] B) (g : A →⋆ₙₐ[R] C) : (snd R B C).comp (prod f g) = g := by
ext; rfl
@[simp]
theorem prod_fst_snd : prod (fst R A B) (snd R A B) = 1 :=
DFunLike.coe_injective Pi.prod_fst_snd
/-- Taking the product of two maps with the same domain is equivalent to taking the product of
their codomains. -/
@[simps]
def prodEquiv : (A →⋆ₙₐ[R] B) × (A →⋆ₙₐ[R] C) ≃ (A →⋆ₙₐ[R] B × C) where
toFun f := f.1.prod f.2
invFun f := ((fst _ _ _).comp f, (snd _ _ _).comp f)
left_inv f := by ext <;> rfl
right_inv f := by ext <;> rfl
end Prod
section Pi
variable {ι : Type*}
/-- `Function.eval` as a `NonUnitalStarAlgHom`. -/
@[simps]
def _root_.Pi.evalNonUnitalStarAlgHom (R : Type*) (A : ι → Type*) (j : ι) [Monoid R]
[∀ i, NonUnitalNonAssocSemiring (A i)] [∀ i, DistribMulAction R (A i)] [∀ i, Star (A i)] :
(∀ i, A i) →⋆ₙₐ[R] A j:=
{ Pi.evalMulHom A j, Pi.evalAddHom A j with
map_smul' _ _ := rfl
map_zero' := rfl
map_star' _ := rfl }
/-- `Function.eval` as a `StarAlgHom`. -/
@[simps]
def _root_.Pi.evalStarAlgHom (R : Type*) (A : ι → Type*) (j : ι) [CommSemiring R]
[∀ i, Semiring (A i)] [∀ i, Algebra R (A i)] [∀ i, Star (A i)] :
(∀ i, A i) →⋆ₐ[R] A j :=
{ Pi.evalNonUnitalStarAlgHom R A j, Pi.evalRingHom A j with
commutes' _ := rfl }
end Pi
section InlInr
variable (R A B C : Type*) [Monoid R] [NonUnitalNonAssocSemiring A] [DistribMulAction R A]
[StarAddMonoid A] [NonUnitalNonAssocSemiring B] [DistribMulAction R B] [StarAddMonoid B]
[NonUnitalNonAssocSemiring C] [DistribMulAction R C] [StarAddMonoid C]
/-- The left injection into a product is a non-unital algebra homomorphism. -/
def inl : A →⋆ₙₐ[R] A × B :=
prod 1 0
/-- The right injection into a product is a non-unital algebra homomorphism. -/
def inr : B →⋆ₙₐ[R] A × B :=
prod 0 1
variable {R A B}
@[simp]
theorem coe_inl : (inl R A B : A → A × B) = fun x => (x, 0) :=
rfl
theorem inl_apply (x : A) : inl R A B x = (x, 0) :=
rfl
@[simp]
theorem coe_inr : (inr R A B : B → A × B) = Prod.mk 0 :=
rfl
theorem inr_apply (x : B) : inr R A B x = (0, x) :=
rfl
end InlInr
end NonUnitalStarAlgHom
namespace StarAlgHom
variable (R A B C : Type*) [CommSemiring R] [Semiring A] [Algebra R A] [Star A] [Semiring B]
[Algebra R B] [Star B] [Semiring C] [Algebra R C] [Star C]
/-- The first projection of a product is a ⋆-algebra homomorphism. -/
@[simps!]
def fst : A × B →⋆ₐ[R] A :=
{ AlgHom.fst R A B with map_star' := fun _ => rfl }
/-- The second projection of a product is a ⋆-algebra homomorphism. -/
@[simps!]
def snd : A × B →⋆ₐ[R] B :=
{ AlgHom.snd R A B with map_star' := fun _ => rfl }
variable {R A B C}
/-- The `Pi.prod` of two morphisms is a morphism. -/
@[simps!]
def prod (f : A →⋆ₐ[R] B) (g : A →⋆ₐ[R] C) : A →⋆ₐ[R] B × C :=
{ f.toAlgHom.prod g.toAlgHom with map_star' := fun x => by simp [Prod.star_def, map_star] }
theorem coe_prod (f : A →⋆ₐ[R] B) (g : A →⋆ₐ[R] C) : ⇑(f.prod g) = Pi.prod f g :=
rfl
@[simp]
theorem fst_prod (f : A →⋆ₐ[R] B) (g : A →⋆ₐ[R] C) : (fst R B C).comp (prod f g) = f := by
ext; rfl
@[simp]
theorem snd_prod (f : A →⋆ₐ[R] B) (g : A →⋆ₐ[R] C) : (snd R B C).comp (prod f g) = g := by
ext; rfl
@[simp]
theorem prod_fst_snd : prod (fst R A B) (snd R A B) = 1 :=
DFunLike.coe_injective Pi.prod_fst_snd
/-- Taking the product of two maps with the same domain is equivalent to taking the product of
their codomains. -/
@[simps]
def prodEquiv : (A →⋆ₐ[R] B) × (A →⋆ₐ[R] C) ≃ (A →⋆ₐ[R] B × C) where
toFun f := f.1.prod f.2
invFun f := ((fst _ _ _).comp f, (snd _ _ _).comp f)
left_inv f := by ext <;> rfl
right_inv f := by ext <;> rfl
end StarAlgHom
/-! ### Star algebra equivalences -/
-- Porting note: changed order of arguments to work around
-- [https://github.com/leanprover-community/mathlib4/issues/2505]
/-- A *⋆-algebra* equivalence is an equivalence preserving addition, multiplication, scalar
multiplication and the star operation, which allows for considering both unital and non-unital
equivalences with a single structure. Currently, `AlgEquiv` requires unital algebras, which is
why this structure does not extend it. -/
structure StarAlgEquiv (R A B : Type*) [Add A] [Add B] [Mul A] [Mul B] [SMul R A] [SMul R B]
[Star A] [Star B] extends A ≃+* B where
/-- By definition, a ⋆-algebra equivalence preserves the `star` operation. -/
map_star' : ∀ a : A, toFun (star a) = star (toFun a)
/-- By definition, a ⋆-algebra equivalence commutes with the action of scalars. -/
map_smul' : ∀ (r : R) (a : A), toFun (r • a) = r • toFun a
@[inherit_doc StarAlgEquiv] infixr:25 " ≃⋆ₐ " => StarAlgEquiv _
@[inherit_doc] notation:25 A " ≃⋆ₐ[" R "] " B => StarAlgEquiv R A B
/-- Reinterpret a star algebra equivalence as a `RingEquiv` by forgetting the interaction with
the star operation and scalar multiplication. -/
add_decl_doc StarAlgEquiv.toRingEquiv
/-- The class that directly extends `RingEquivClass` and `SMulHomClass`.
Mostly an implementation detail for `StarAlgEquivClass`.
-/
class NonUnitalAlgEquivClass (F : Type*) (R A B : outParam Type*)
[Add A] [Mul A] [SMul R A] [Add B] [Mul B] [SMul R B] [EquivLike F A B] : Prop
extends RingEquivClass F A B, MulActionSemiHomClass F (@id R) A B where
namespace StarAlgEquivClass
-- See note [lower instance priority]
instance (priority := 100) {F R A B : Type*} [Monoid R] [NonUnitalNonAssocSemiring A]
[DistribMulAction R A] [NonUnitalNonAssocSemiring B] [DistribMulAction R B] [EquivLike F A B]
[NonUnitalAlgEquivClass F R A B] :
NonUnitalAlgHomClass F R A B :=
{ }
-- See note [lower instance priority]
instance (priority := 100) instAlgHomClass (F R A B : Type*) [CommSemiring R] [Semiring A]
[Algebra R A] [Semiring B] [Algebra R B] [EquivLike F A B] [NonUnitalAlgEquivClass F R A B] :
AlgEquivClass F R A B :=
{ commutes := fun f r => by simp only [Algebra.algebraMap_eq_smul_one, map_smul, map_one] }
/-- Turn an element of a type `F` satisfying `AlgEquivClass F R A B` and `StarHomClass F A B` into
an actual `StarAlgEquiv`. This is declared as the default coercion from `F` to `A ≃⋆ₐ[R] B`. -/
@[coe]
| def toStarAlgEquiv {F R A B : Type*} [Add A] [Mul A] [SMul R A] [Star A] [Add B] [Mul B] [SMul R B]
[Star B] [EquivLike F A B] [NonUnitalAlgEquivClass F R A B] [StarHomClass F A B]
| Mathlib/Algebra/Star/StarAlgHom.lean | 680 | 681 |
/-
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.Convex.Function
import Mathlib.Analysis.Convex.StrictConvexSpace
import Mathlib.MeasureTheory.Function.AEEqOfIntegral
import Mathlib.MeasureTheory.Integral.Average
/-!
# Jensen's inequality for integrals
In this file we prove several forms of Jensen's inequality for integrals.
- for convex sets: `Convex.average_mem`, `Convex.set_average_mem`, `Convex.integral_mem`;
- for convex functions: `ConvexOn.average_mem_epigraph`, `ConvexOn.map_average_le`,
`ConvexOn.set_average_mem_epigraph`, `ConvexOn.map_set_average_le`, `ConvexOn.map_integral_le`;
- for strictly convex sets: `StrictConvex.ae_eq_const_or_average_mem_interior`;
- for a closed ball in a strictly convex normed space:
`ae_eq_const_or_norm_integral_lt_of_norm_le_const`;
- for strictly convex functions: `StrictConvexOn.ae_eq_const_or_map_average_lt`.
## TODO
- Use a typeclass for strict convexity of a closed ball.
## Tags
convex, integral, center mass, average value, Jensen's inequality
-/
open MeasureTheory MeasureTheory.Measure Metric Set Filter TopologicalSpace Function
open scoped Topology ENNReal Convex
variable {α E : Type*} {m0 : MeasurableSpace α} [NormedAddCommGroup E] [NormedSpace ℝ E]
[CompleteSpace E] {μ : Measure α} {s : Set E} {t : Set α} {f : α → E} {g : E → ℝ} {C : ℝ}
/-!
### Non-strict Jensen's inequality
-/
/-- If `μ` is a probability measure on `α`, `s` is a convex closed set in `E`, and `f` is an
integrable function sending `μ`-a.e. points to `s`, then the expected value of `f` belongs to `s`:
`∫ x, f x ∂μ ∈ s`. See also `Convex.sum_mem` for a finite sum version of this lemma. -/
theorem Convex.integral_mem [IsProbabilityMeasure μ] (hs : Convex ℝ s) (hsc : IsClosed s)
(hf : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ) : (∫ x, f x ∂μ) ∈ s := by
borelize E
rcases hfi.aestronglyMeasurable with ⟨g, hgm, hfg⟩
haveI : SeparableSpace (range g ∩ s : Set E) :=
(hgm.isSeparable_range.mono inter_subset_left).separableSpace
obtain ⟨y₀, h₀⟩ : (range g ∩ s).Nonempty := by
rcases (hf.and hfg).exists with ⟨x₀, h₀⟩
exact ⟨f x₀, by simp only [h₀.2, mem_range_self], h₀.1⟩
rw [integral_congr_ae hfg]; rw [integrable_congr hfg] at hfi
have hg : ∀ᵐ x ∂μ, g x ∈ closure (range g ∩ s) := by
filter_upwards [hfg.rw (fun _ y => y ∈ s) hf] with x hx
apply subset_closure
exact ⟨mem_range_self _, hx⟩
set G : ℕ → SimpleFunc α E := SimpleFunc.approxOn _ hgm.measurable (range g ∩ s) y₀ h₀
have : Tendsto (fun n => (G n).integral μ) atTop (𝓝 <| ∫ x, g x ∂μ) :=
tendsto_integral_approxOn_of_measurable hfi _ hg _ (integrable_const _)
refine hsc.mem_of_tendsto this (Eventually.of_forall fun n => hs.sum_mem ?_ ?_ ?_)
· exact fun _ _ => ENNReal.toReal_nonneg
· simp_rw [measureReal_def]
rw [← ENNReal.toReal_sum, (G n).sum_range_measure_preimage_singleton, measure_univ,
ENNReal.toReal_one]
exact fun _ _ => measure_ne_top _ _
· simp only [SimpleFunc.mem_range, forall_mem_range]
intro x
apply (range g).inter_subset_right
exact SimpleFunc.approxOn_mem hgm.measurable h₀ _ _
/-- If `μ` is a non-zero finite measure on `α`, `s` is a convex closed set in `E`, and `f` is an
integrable function sending `μ`-a.e. points to `s`, then the average value of `f` belongs to `s`:
`⨍ x, f x ∂μ ∈ s`. See also `Convex.centerMass_mem` for a finite sum version of this lemma. -/
theorem Convex.average_mem [IsFiniteMeasure μ] [NeZero μ] (hs : Convex ℝ s) (hsc : IsClosed s)
(hfs : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ) : (⨍ x, f x ∂μ) ∈ s :=
hs.integral_mem hsc (ae_mono' smul_absolutelyContinuous hfs) hfi.to_average
/-- If `μ` is a non-zero finite measure on `α`, `s` is a convex closed set in `E`, and `f` is an
integrable function sending `μ`-a.e. points to `s`, then the average value of `f` belongs to `s`:
`⨍ x, f x ∂μ ∈ s`. See also `Convex.centerMass_mem` for a finite sum version of this lemma. -/
theorem Convex.set_average_mem (hs : Convex ℝ s) (hsc : IsClosed s) (h0 : μ t ≠ 0) (ht : μ t ≠ ∞)
(hfs : ∀ᵐ x ∂μ.restrict t, f x ∈ s) (hfi : IntegrableOn f t μ) : (⨍ x in t, f x ∂μ) ∈ s :=
have := Fact.mk ht.lt_top
have := NeZero.mk h0
hs.average_mem hsc hfs hfi
/-- If `μ` is a non-zero finite measure on `α`, `s` is a convex set in `E`, and `f` is an integrable
function sending `μ`-a.e. points to `s`, then the average value of `f` belongs to `closure s`:
`⨍ x, f x ∂μ ∈ s`. See also `Convex.centerMass_mem` for a finite sum version of this lemma. -/
theorem Convex.set_average_mem_closure (hs : Convex ℝ s) (h0 : μ t ≠ 0) (ht : μ t ≠ ∞)
(hfs : ∀ᵐ x ∂μ.restrict t, f x ∈ s) (hfi : IntegrableOn f t μ) :
(⨍ x in t, f x ∂μ) ∈ closure s :=
hs.closure.set_average_mem isClosed_closure h0 ht (hfs.mono fun _ hx => subset_closure hx) hfi
theorem ConvexOn.average_mem_epigraph [IsFiniteMeasure μ] [NeZero μ] (hg : ConvexOn ℝ s g)
(hgc : ContinuousOn g s) (hsc : IsClosed s) (hfs : ∀ᵐ x ∂μ, f x ∈ s)
(hfi : Integrable f μ) (hgi : Integrable (g ∘ f) μ) :
(⨍ x, f x ∂μ, ⨍ x, g (f x) ∂μ) ∈ {p : E × ℝ | p.1 ∈ s ∧ g p.1 ≤ p.2} := by
have ht_mem : ∀ᵐ x ∂μ, (f x, g (f x)) ∈ {p : E × ℝ | p.1 ∈ s ∧ g p.1 ≤ p.2} :=
hfs.mono fun x hx => ⟨hx, le_rfl⟩
exact average_pair hfi hgi ▸
hg.convex_epigraph.average_mem (hsc.epigraph hgc) ht_mem (hfi.prodMk hgi)
theorem ConcaveOn.average_mem_hypograph [IsFiniteMeasure μ] [NeZero μ] (hg : ConcaveOn ℝ s g)
(hgc : ContinuousOn g s) (hsc : IsClosed s) (hfs : ∀ᵐ x ∂μ, f x ∈ s)
(hfi : Integrable f μ) (hgi : Integrable (g ∘ f) μ) :
(⨍ x, f x ∂μ, ⨍ x, g (f x) ∂μ) ∈ {p : E × ℝ | p.1 ∈ s ∧ p.2 ≤ g p.1} := by
simpa only [mem_setOf_eq, Pi.neg_apply, average_neg, neg_le_neg_iff] using
hg.neg.average_mem_epigraph hgc.neg hsc hfs hfi hgi.neg
/-- **Jensen's inequality**: if a function `g : E → ℝ` is convex and continuous on a convex closed
set `s`, `μ` is a finite non-zero measure on `α`, and `f : α → E` is a function sending
`μ`-a.e. points to `s`, then the value of `g` at the average value of `f` is less than or equal to
the average value of `g ∘ f` provided that both `f` and `g ∘ f` are integrable. See also
`ConvexOn.map_centerMass_le` for a finite sum version of this lemma. -/
theorem ConvexOn.map_average_le [IsFiniteMeasure μ] [NeZero μ]
(hg : ConvexOn ℝ s g) (hgc : ContinuousOn g s) (hsc : IsClosed s)
(hfs : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ) (hgi : Integrable (g ∘ f) μ) :
g (⨍ x, f x ∂μ) ≤ ⨍ x, g (f x) ∂μ :=
(hg.average_mem_epigraph hgc hsc hfs hfi hgi).2
/-- **Jensen's inequality**: if a function `g : E → ℝ` is concave and continuous on a convex closed
set `s`, `μ` is a finite non-zero measure on `α`, and `f : α → E` is a function sending
`μ`-a.e. points to `s`, then the average value of `g ∘ f` is less than or equal to the value of `g`
at the average value of `f` provided that both `f` and `g ∘ f` are integrable. See also
`ConcaveOn.le_map_centerMass` for a finite sum version of this lemma. -/
theorem ConcaveOn.le_map_average [IsFiniteMeasure μ] [NeZero μ]
(hg : ConcaveOn ℝ s g) (hgc : ContinuousOn g s) (hsc : IsClosed s)
(hfs : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ) (hgi : Integrable (g ∘ f) μ) :
(⨍ x, g (f x) ∂μ) ≤ g (⨍ x, f x ∂μ) :=
(hg.average_mem_hypograph hgc hsc hfs hfi hgi).2
/-- **Jensen's inequality**: if a function `g : E → ℝ` is convex and continuous on a convex closed
set `s`, `μ` is a finite non-zero measure on `α`, and `f : α → E` is a function sending
`μ`-a.e. points of a set `t` to `s`, then the value of `g` at the average value of `f` over `t` is
less than or equal to the average value of `g ∘ f` over `t` provided that both `f` and `g ∘ f` are
integrable. -/
theorem ConvexOn.set_average_mem_epigraph (hg : ConvexOn ℝ s g) (hgc : ContinuousOn g s)
(hsc : IsClosed s) (h0 : μ t ≠ 0) (ht : μ t ≠ ∞) (hfs : ∀ᵐ x ∂μ.restrict t, f x ∈ s)
(hfi : IntegrableOn f t μ) (hgi : IntegrableOn (g ∘ f) t μ) :
(⨍ x in t, f x ∂μ, ⨍ x in t, g (f x) ∂μ) ∈ {p : E × ℝ | p.1 ∈ s ∧ g p.1 ≤ p.2} :=
have := Fact.mk ht.lt_top
have := NeZero.mk h0
hg.average_mem_epigraph hgc hsc hfs hfi hgi
/-- **Jensen's inequality**: if a function `g : E → ℝ` is concave and continuous on a convex closed
set `s`, `μ` is a finite non-zero measure on `α`, and `f : α → E` is a function sending
`μ`-a.e. points of a set `t` to `s`, then the average value of `g ∘ f` over `t` is less than or
equal to the value of `g` at the average value of `f` over `t` provided that both `f` and `g ∘ f`
are integrable. -/
theorem ConcaveOn.set_average_mem_hypograph (hg : ConcaveOn ℝ s g) (hgc : ContinuousOn g s)
(hsc : IsClosed s) (h0 : μ t ≠ 0) (ht : μ t ≠ ∞) (hfs : ∀ᵐ x ∂μ.restrict t, f x ∈ s)
(hfi : IntegrableOn f t μ) (hgi : IntegrableOn (g ∘ f) t μ) :
(⨍ x in t, f x ∂μ, ⨍ x in t, g (f x) ∂μ) ∈ {p : E × ℝ | p.1 ∈ s ∧ p.2 ≤ g p.1} := by
simpa only [mem_setOf_eq, Pi.neg_apply, average_neg, neg_le_neg_iff] using
hg.neg.set_average_mem_epigraph hgc.neg hsc h0 ht hfs hfi hgi.neg
/-- **Jensen's inequality**: if a function `g : E → ℝ` is convex and continuous on a convex closed
set `s`, `μ` is a finite non-zero measure on `α`, and `f : α → E` is a function sending
`μ`-a.e. points of a set `t` to `s`, then the value of `g` at the average value of `f` over `t` is
less than or equal to the average value of `g ∘ f` over `t` provided that both `f` and `g ∘ f` are
integrable. -/
theorem ConvexOn.map_set_average_le (hg : ConvexOn ℝ s g) (hgc : ContinuousOn g s)
(hsc : IsClosed s) (h0 : μ t ≠ 0) (ht : μ t ≠ ∞) (hfs : ∀ᵐ x ∂μ.restrict t, f x ∈ s)
(hfi : IntegrableOn f t μ) (hgi : IntegrableOn (g ∘ f) t μ) :
g (⨍ x in t, f x ∂μ) ≤ ⨍ x in t, g (f x) ∂μ :=
(hg.set_average_mem_epigraph hgc hsc h0 ht hfs hfi hgi).2
/-- **Jensen's inequality**: if a function `g : E → ℝ` is concave and continuous on a convex closed
set `s`, `μ` is a finite non-zero measure on `α`, and `f : α → E` is a function sending
`μ`-a.e. points of a set `t` to `s`, then the average value of `g ∘ f` over `t` is less than or
equal to the value of `g` at the average value of `f` over `t` provided that both `f` and `g ∘ f`
are integrable. -/
theorem ConcaveOn.le_map_set_average (hg : ConcaveOn ℝ s g) (hgc : ContinuousOn g s)
(hsc : IsClosed s) (h0 : μ t ≠ 0) (ht : μ t ≠ ∞) (hfs : ∀ᵐ x ∂μ.restrict t, f x ∈ s)
(hfi : IntegrableOn f t μ) (hgi : IntegrableOn (g ∘ f) t μ) :
(⨍ x in t, g (f x) ∂μ) ≤ g (⨍ x in t, f x ∂μ) :=
(hg.set_average_mem_hypograph hgc hsc h0 ht hfs hfi hgi).2
/-- **Jensen's inequality**: if a function `g : E → ℝ` is convex and continuous on a convex closed
set `s`, `μ` is a probability measure on `α`, and `f : α → E` is a function sending `μ`-a.e. points
to `s`, then the value of `g` at the expected value of `f` is less than or equal to the expected
value of `g ∘ f` provided that both `f` and `g ∘ f` are integrable. See also
`ConvexOn.map_centerMass_le` for a finite sum version of this lemma. -/
theorem ConvexOn.map_integral_le [IsProbabilityMeasure μ] (hg : ConvexOn ℝ s g)
(hgc : ContinuousOn g s) (hsc : IsClosed s) (hfs : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ)
(hgi : Integrable (g ∘ f) μ) : g (∫ x, f x ∂μ) ≤ ∫ x, g (f x) ∂μ := by
simpa only [average_eq_integral] using hg.map_average_le hgc hsc hfs hfi hgi
/-- **Jensen's inequality**: if a function `g : E → ℝ` is concave and continuous on a convex closed
set `s`, `μ` is a probability measure on `α`, and `f : α → E` is a function sending `μ`-a.e. points
to `s`, then the expected value of `g ∘ f` is less than or equal to the value of `g` at the expected
value of `f` provided that both `f` and `g ∘ f` are integrable. -/
theorem ConcaveOn.le_map_integral [IsProbabilityMeasure μ] (hg : ConcaveOn ℝ s g)
(hgc : ContinuousOn g s) (hsc : IsClosed s) (hfs : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ)
(hgi : Integrable (g ∘ f) μ) : (∫ x, g (f x) ∂μ) ≤ g (∫ x, f x ∂μ) := by
simpa only [average_eq_integral] using hg.le_map_average hgc hsc hfs hfi hgi
/-!
### Strict Jensen's inequality
-/
/-- If `f : α → E` is an integrable function, then either it is a.e. equal to the constant
`⨍ x, f x ∂μ` or there exists a measurable set such that `μ t ≠ 0`, `μ tᶜ ≠ 0`, and the average
values of `f` over `t` and `tᶜ` are different. -/
theorem ae_eq_const_or_exists_average_ne_compl [IsFiniteMeasure μ] (hfi : Integrable f μ) :
f =ᵐ[μ] const α (⨍ x, f x ∂μ) ∨
∃ t, MeasurableSet t ∧ μ t ≠ 0 ∧ μ tᶜ ≠ 0 ∧ (⨍ x in t, f x ∂μ) ≠ ⨍ x in tᶜ, f x ∂μ := by
refine or_iff_not_imp_right.mpr fun H => ?_; push_neg at H
refine hfi.ae_eq_of_forall_setIntegral_eq _ _ (integrable_const _) fun t ht ht' => ?_; clear ht'
simp only [const_apply, setIntegral_const]
by_cases h₀ : μ t = 0
· rw [restrict_eq_zero.2 h₀, integral_zero_measure, measureReal_def, h₀,
ENNReal.toReal_zero, zero_smul]
by_cases h₀' : μ tᶜ = 0
· rw [← ae_eq_univ] at h₀'
rw [restrict_congr_set h₀', restrict_univ, measureReal_congr h₀', measure_smul_average]
have := average_mem_openSegment_compl_self ht.nullMeasurableSet h₀ h₀' hfi
rw [← H t ht h₀ h₀', openSegment_same, mem_singleton_iff] at this
rw [this, measure_smul_setAverage _ (measure_ne_top μ _)]
/-- If an integrable function `f : α → E` takes values in a convex set `s` and for some set `t` of
positive measure, the average value of `f` over `t` belongs to the interior of `s`, then the average
of `f` over the whole space belongs to the interior of `s`. -/
theorem Convex.average_mem_interior_of_set [IsFiniteMeasure μ] (hs : Convex ℝ s) (h0 : μ t ≠ 0)
(hfs : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ) (ht : (⨍ x in t, f x ∂μ) ∈ interior s) :
(⨍ x, f x ∂μ) ∈ interior s := by
rw [← measure_toMeasurable] at h0; rw [← restrict_toMeasurable (measure_ne_top μ t)] at ht
by_cases h0' : μ (toMeasurable μ t)ᶜ = 0
· rw [← ae_eq_univ] at h0'
rwa [restrict_congr_set h0', restrict_univ] at ht
exact
hs.openSegment_interior_closure_subset_interior ht
(hs.set_average_mem_closure h0' (measure_ne_top _ _) (ae_restrict_of_ae hfs)
hfi.integrableOn)
(average_mem_openSegment_compl_self (measurableSet_toMeasurable μ t).nullMeasurableSet h0
h0' hfi)
/-- If an integrable function `f : α → E` takes values in a strictly convex closed set `s`, then
either it is a.e. equal to its average value, or its average value belongs to the interior of
`s`. -/
theorem StrictConvex.ae_eq_const_or_average_mem_interior [IsFiniteMeasure μ] (hs : StrictConvex ℝ s)
(hsc : IsClosed s) (hfs : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ) :
f =ᵐ[μ] const α (⨍ x, f x ∂μ) ∨ (⨍ x, f x ∂μ) ∈ interior s := by
have : ∀ {t}, μ t ≠ 0 → (⨍ x in t, f x ∂μ) ∈ s := fun ht =>
hs.convex.set_average_mem hsc ht (measure_ne_top _ _) (ae_restrict_of_ae hfs) hfi.integrableOn
refine (ae_eq_const_or_exists_average_ne_compl hfi).imp_right ?_
rintro ⟨t, hm, h₀, h₀', hne⟩
exact
hs.openSegment_subset (this h₀) (this h₀') hne
(average_mem_openSegment_compl_self hm.nullMeasurableSet h₀ h₀' hfi)
/-- **Jensen's inequality**, strict version: if an integrable function `f : α → E` takes values in a
convex closed set `s`, and `g : E → ℝ` is continuous and strictly convex on `s`, then
either `f` is a.e. equal to its average value, or `g (⨍ x, f x ∂μ) < ⨍ x, g (f x) ∂μ`. -/
theorem StrictConvexOn.ae_eq_const_or_map_average_lt [IsFiniteMeasure μ] (hg : StrictConvexOn ℝ s g)
(hgc : ContinuousOn g s) (hsc : IsClosed s) (hfs : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ)
(hgi : Integrable (g ∘ f) μ) :
f =ᵐ[μ] const α (⨍ x, f x ∂μ) ∨ g (⨍ x, f x ∂μ) < ⨍ x, g (f x) ∂μ := by
have : ∀ {t}, μ t ≠ 0 → (⨍ x in t, f x ∂μ) ∈ s ∧ g (⨍ x in t, f x ∂μ) ≤ ⨍ x in t, g (f x) ∂μ :=
fun ht =>
hg.convexOn.set_average_mem_epigraph hgc hsc ht (measure_ne_top _ _) (ae_restrict_of_ae hfs)
hfi.integrableOn hgi.integrableOn
refine (ae_eq_const_or_exists_average_ne_compl hfi).imp_right ?_
rintro ⟨t, hm, h₀, h₀', hne⟩
rcases average_mem_openSegment_compl_self hm.nullMeasurableSet h₀ h₀' (hfi.prodMk hgi) with
⟨a, b, ha, hb, hab, h_avg⟩
rw [average_pair hfi hgi, average_pair hfi.integrableOn hgi.integrableOn,
average_pair hfi.integrableOn hgi.integrableOn, Prod.smul_mk,
Prod.smul_mk, Prod.mk_add_mk, Prod.mk_inj] at h_avg
simp only [Function.comp] at h_avg
rw [← h_avg.1, ← h_avg.2]
calc
g ((a • ⨍ x in t, f x ∂μ) + b • ⨍ x in tᶜ, f x ∂μ) <
a * g (⨍ x in t, f x ∂μ) + b * g (⨍ x in tᶜ, f x ∂μ) :=
hg.2 (this h₀).1 (this h₀').1 hne ha hb hab
_ ≤ (a * ⨍ x in t, g (f x) ∂μ) + b * ⨍ x in tᶜ, g (f x) ∂μ :=
add_le_add (mul_le_mul_of_nonneg_left (this h₀).2 ha.le)
(mul_le_mul_of_nonneg_left (this h₀').2 hb.le)
/-- **Jensen's inequality**, strict version: if an integrable function `f : α → E` takes values in a
convex closed set `s`, and `g : E → ℝ` is continuous and strictly concave on `s`, then
either `f` is a.e. equal to its average value, or `⨍ x, g (f x) ∂μ < g (⨍ x, f x ∂μ)`. -/
theorem StrictConcaveOn.ae_eq_const_or_lt_map_average [IsFiniteMeasure μ]
(hg : StrictConcaveOn ℝ s g) (hgc : ContinuousOn g s) (hsc : IsClosed s)
(hfs : ∀ᵐ x ∂μ, f x ∈ s) (hfi : Integrable f μ) (hgi : Integrable (g ∘ f) μ) :
f =ᵐ[μ] const α (⨍ x, f x ∂μ) ∨ (⨍ x, g (f x) ∂μ) < g (⨍ x, f x ∂μ) := by
simpa only [Pi.neg_apply, average_neg, neg_lt_neg_iff] using
hg.neg.ae_eq_const_or_map_average_lt hgc.neg hsc hfs hfi hgi.neg
/-- If `E` is a strictly convex normed space and `f : α → E` is a function such that `‖f x‖ ≤ C`
a.e., then either this function is a.e. equal to its average value, or the norm of its average value
is strictly less than `C`. -/
theorem ae_eq_const_or_norm_average_lt_of_norm_le_const [StrictConvexSpace ℝ E]
(h_le : ∀ᵐ x ∂μ, ‖f x‖ ≤ C) : f =ᵐ[μ] const α (⨍ x, f x ∂μ) ∨ ‖⨍ x, f x ∂μ‖ < C := by
rcases le_or_lt C 0 with hC0 | hC0
· have : f =ᵐ[μ] 0 := h_le.mono fun x hx => norm_le_zero_iff.1 (hx.trans hC0)
simp only [average_congr this, Pi.zero_apply, average_zero]
exact Or.inl this
by_cases hfi : Integrable f μ; swap
· simp [average_eq, integral_undef hfi, hC0, ENNReal.toReal_pos_iff]
rcases (le_top : μ univ ≤ ∞).eq_or_lt with hμt | hμt
· simp [average_eq, measureReal_def, hμt, hC0]
haveI : IsFiniteMeasure μ := ⟨hμt⟩
replace h_le : ∀ᵐ x ∂μ, f x ∈ closedBall (0 : E) C := by simpa only [mem_closedBall_zero_iff]
simpa only [interior_closedBall _ hC0.ne', mem_ball_zero_iff] using
(strictConvex_closedBall ℝ (0 : E) C).ae_eq_const_or_average_mem_interior isClosed_closedBall
h_le hfi
/-- If `E` is a strictly convex normed space and `f : α → E` is a function such that `‖f x‖ ≤ C`
a.e., then either this function is a.e. equal to its average value, or the norm of its integral is
strictly less than `μ.real univ * C`. -/
theorem ae_eq_const_or_norm_integral_lt_of_norm_le_const [StrictConvexSpace ℝ E] [IsFiniteMeasure μ]
(h_le : ∀ᵐ x ∂μ, ‖f x‖ ≤ C) :
f =ᵐ[μ] const α (⨍ x, f x ∂μ) ∨ ‖∫ x, f x ∂μ‖ < μ.real univ * C := by
rcases eq_or_ne μ 0 with h₀ | h₀; · left; simp [h₀, EventuallyEq]
have hμ : 0 < μ.real univ := by
simp [measureReal_def, ENNReal.toReal_pos_iff, pos_iff_ne_zero, h₀, measure_lt_top]
refine (ae_eq_const_or_norm_average_lt_of_norm_le_const h_le).imp_right fun H => ?_
rwa [average_eq, norm_smul, norm_inv, Real.norm_eq_abs, abs_of_pos hμ, ← div_eq_inv_mul,
div_lt_iff₀' hμ] at H
/-- If `E` is a strictly convex normed space and `f : α → E` is a function such that `‖f x‖ ≤ C`
a.e. on a set `t` of finite measure, then either this function is a.e. equal to its average value on
`t`, or the norm of its integral over `t` is strictly less than `μ.real t * C`. -/
theorem ae_eq_const_or_norm_setIntegral_lt_of_norm_le_const [StrictConvexSpace ℝ E] (ht : μ t ≠ ∞)
(h_le : ∀ᵐ x ∂μ.restrict t, ‖f x‖ ≤ C) :
f =ᵐ[μ.restrict t] const α (⨍ x in t, f x ∂μ) ∨ ‖∫ x in t, f x ∂μ‖ < μ.real t * C := by
haveI := Fact.mk ht.lt_top
rw [← measureReal_restrict_apply_univ]
exact ae_eq_const_or_norm_integral_lt_of_norm_le_const h_le
| Mathlib/Analysis/Convex/Integral.lean | 345 | 353 | |
/-
Copyright (c) 2023 Yaël Dillies, Vladimir Ivanov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies, Vladimir Ivanov
-/
import Mathlib.Algebra.BigOperators.Intervals
import Mathlib.Algebra.BigOperators.Ring.Finset
import Mathlib.Algebra.Order.BigOperators.Group.Finset
import Mathlib.Algebra.Order.Field.Basic
import Mathlib.Data.Finset.Sups
import Mathlib.Tactic.FieldSimp
import Mathlib.Tactic.Ring
import Mathlib.Algebra.BigOperators.Group.Finset.Powerset
/-!
# The Ahlswede-Zhang identity
This file proves the Ahlswede-Zhang identity, which is a nontrivial relation between the size of the
"truncated unions" of a set family. It sharpens the Lubell-Yamamoto-Meshalkin inequality
`Finset.lubell_yamamoto_meshalkin_inequality_sum_card_div_choose`, by making explicit the correction
term.
For a set family `𝒜` over a ground set of size `n`, the Ahlswede-Zhang identity states that the sum
of `|⋂ B ∈ 𝒜, B ⊆ A, B|/(|A| * n.choose |A|)` over all set `A` is exactly `1`. This implies the LYM
inequality since for an antichain `𝒜` and every `A ∈ 𝒜` we have
`|⋂ B ∈ 𝒜, B ⊆ A, B|/(|A| * n.choose |A|) = 1 / n.choose |A|`.
## Main declarations
* `Finset.truncatedSup`: `s.truncatedSup a` is the supremum of all `b ≥ a` in `𝒜` if there are
some, or `⊤` if there are none.
* `Finset.truncatedInf`: `s.truncatedInf a` is the infimum of all `b ≤ a` in `𝒜` if there are
some, or `⊥` if there are none.
* `AhlswedeZhang.infSum`: LHS of the Ahlswede-Zhang identity.
* `AhlswedeZhang.le_infSum`: The sum of `1 / n.choose |A|` over an antichain is less than the RHS of
the Ahlswede-Zhang identity.
* `AhlswedeZhang.infSum_eq_one`: Ahlswede-Zhang identity.
## References
* [R. Ahlswede, Z. Zhang, *An identity in combinatorial extremal theory*](https://doi.org/10.1016/0001-8708(90)90023-G)
* [D. T. Tru, *An AZ-style identity and Bollobás deficiency*](https://doi.org/10.1016/j.jcta.2007.03.005)
-/
section
variable (α : Type*) [Fintype α] [Nonempty α] {m n : ℕ}
open Finset Fintype Nat
private lemma binomial_sum_eq (h : n < m) :
∑ i ∈ range (n + 1), (n.choose i * (m - n) / ((m - i) * m.choose i) : ℚ) = 1 := by
set f : ℕ → ℚ := fun i ↦ n.choose i * (m.choose i : ℚ)⁻¹ with hf
suffices ∀ i ∈ range (n + 1), f i - f (i + 1) = n.choose i * (m - n) / ((m - i) * m.choose i) by
rw [← sum_congr rfl this, sum_range_sub', hf]
simp [choose_self, choose_zero_right, choose_eq_zero_of_lt h]
intro i h₁
rw [mem_range] at h₁
have h₁ := le_of_lt_succ h₁
have h₂ := h₁.trans_lt h
have h₃ := h₂.le
have hi₄ : (i + 1 : ℚ) ≠ 0 := i.cast_add_one_ne_zero
have := congr_arg ((↑) : ℕ → ℚ) (choose_succ_right_eq m i)
push_cast at this
dsimp [f, hf]
rw [(eq_mul_inv_iff_mul_eq₀ hi₄).mpr this]
have := congr_arg ((↑) : ℕ → ℚ) (choose_succ_right_eq n i)
push_cast at this
rw [(eq_mul_inv_iff_mul_eq₀ hi₄).mpr this]
have : (m - i : ℚ) ≠ 0 := sub_ne_zero_of_ne (cast_lt.mpr h₂).ne'
have : (m.choose i : ℚ) ≠ 0 := cast_ne_zero.2 (choose_pos h₂.le).ne'
field_simp
ring
private lemma Fintype.sum_div_mul_card_choose_card :
∑ s : Finset α, (card α / ((card α - #s) * (card α).choose #s) : ℚ) =
card α * ∑ k ∈ range (card α), (↑k)⁻¹ + 1 := by
rw [← powerset_univ, powerset_card_disjiUnion, sum_disjiUnion]
have : ∀ {x : ℕ}, ∀ s ∈ powersetCard x (univ : Finset α),
(card α / ((card α - #s) * (card α).choose #s) : ℚ) =
card α / ((card α - x) * (card α).choose x) := by
intros n s hs
rw [mem_powersetCard_univ.1 hs]
simp_rw [sum_congr rfl this, sum_const, card_powersetCard, card_univ, nsmul_eq_mul, mul_div,
mul_comm, ← mul_div]
rw [← mul_sum, ← mul_inv_cancel₀ (cast_ne_zero.mpr card_ne_zero : (card α : ℚ) ≠ 0), ← mul_add,
add_comm _ ((card α)⁻¹ : ℚ), ← sum_insert (f := fun x : ℕ ↦ (x⁻¹ : ℚ)) not_mem_range_self,
← range_succ]
have (n) (hn : n ∈ range (card α + 1)) :
((card α).choose n / ((card α - n) * (card α).choose n) : ℚ) = (card α - n : ℚ)⁻¹ := by
rw [div_mul_cancel_right₀]
exact cast_ne_zero.2 (choose_pos <| mem_range_succ_iff.1 hn).ne'
simp only [sum_congr rfl this, mul_eq_mul_left_iff, cast_eq_zero]
convert Or.inl <| sum_range_reflect _ _ with a ha
rw [add_tsub_cancel_right, cast_sub (mem_range_succ_iff.mp ha)]
end
open scoped FinsetFamily
namespace Finset
variable {α β : Type*}
/-! ### Truncated supremum, truncated infimum -/
section SemilatticeSup
variable [SemilatticeSup α] [SemilatticeSup β] [BoundedOrder β] {s t : Finset α} {a : α}
private lemma sup_aux [DecidableLE α] : a ∈ lowerClosure s → {b ∈ s | a ≤ b}.Nonempty :=
fun ⟨b, hb, hab⟩ ↦ ⟨b, mem_filter.2 ⟨hb, hab⟩⟩
private lemma lower_aux [DecidableEq α] :
a ∈ lowerClosure ↑(s ∪ t) ↔ a ∈ lowerClosure s ∨ a ∈ lowerClosure t := by
rw [coe_union, lowerClosure_union, LowerSet.mem_sup_iff]
variable [DecidableLE α] [OrderTop α]
/-- The supremum of the elements of `s` less than `a` if there are some, otherwise `⊤`. -/
def truncatedSup (s : Finset α) (a : α) : α :=
if h : a ∈ lowerClosure s then {b ∈ s | a ≤ b}.sup' (sup_aux h) id else ⊤
lemma truncatedSup_of_mem (h : a ∈ lowerClosure s) :
truncatedSup s a = {b ∈ s | a ≤ b}.sup' (sup_aux h) id := dif_pos h
lemma truncatedSup_of_not_mem (h : a ∉ lowerClosure s) : truncatedSup s a = ⊤ := dif_neg h
@[simp] lemma truncatedSup_empty (a : α) : truncatedSup ∅ a = ⊤ := truncatedSup_of_not_mem (by simp)
@[simp] lemma truncatedSup_singleton (b a : α) : truncatedSup {b} a = if a ≤ b then b else ⊤ := by
simp [truncatedSup]; split_ifs <;> simp [Finset.filter_true_of_mem, *]
lemma le_truncatedSup : a ≤ truncatedSup s a := by
rw [truncatedSup]
split_ifs with h
· obtain ⟨ℬ, hb, h⟩ := h
exact h.trans <| le_sup' id <| mem_filter.2 ⟨hb, h⟩
· exact le_top
lemma map_truncatedSup [DecidableLE β] (e : α ≃o β) (s : Finset α) (a : α) :
e (truncatedSup s a) = truncatedSup (s.map e.toEquiv.toEmbedding) (e a) := by
have : e a ∈ lowerClosure (s.map e.toEquiv.toEmbedding : Set β) ↔ a ∈ lowerClosure s := by simp
simp_rw [truncatedSup, apply_dite e, map_finset_sup', map_top, this]
congr with h
simp only [filter_map, Function.comp_def, Equiv.coe_toEmbedding, RelIso.coe_fn_toEquiv,
OrderIso.le_iff_le, id, sup'_map]
lemma truncatedSup_of_isAntichain (hs : IsAntichain (· ≤ ·) (s : Set α)) (ha : a ∈ s) :
truncatedSup s a = a := by
refine le_antisymm ?_ le_truncatedSup
simp_rw [truncatedSup_of_mem (subset_lowerClosure ha), sup'_le_iff, mem_filter]
rintro b ⟨hb, hab⟩
exact (hs.eq ha hb hab).ge
variable [DecidableEq α]
lemma truncatedSup_union (hs : a ∈ lowerClosure s) (ht : a ∈ lowerClosure t) :
truncatedSup (s ∪ t) a = truncatedSup s a ⊔ truncatedSup t a := by
simpa only [truncatedSup_of_mem, hs, ht, lower_aux.2 (Or.inl hs), filter_union] using
sup'_union _ _ _
lemma truncatedSup_union_left (hs : a ∈ lowerClosure s) (ht : a ∉ lowerClosure t) :
truncatedSup (s ∪ t) a = truncatedSup s a := by
simp only [mem_lowerClosure, mem_coe, exists_prop, not_exists, not_and] at ht
simp only [truncatedSup_of_mem, hs, filter_union, filter_false_of_mem ht, union_empty,
lower_aux.2 (Or.inl hs), ht]
lemma truncatedSup_union_right (hs : a ∉ lowerClosure s) (ht : a ∈ lowerClosure t) :
truncatedSup (s ∪ t) a = truncatedSup t a := by rw [union_comm, truncatedSup_union_left ht hs]
lemma truncatedSup_union_of_not_mem (hs : a ∉ lowerClosure s) (ht : a ∉ lowerClosure t) :
truncatedSup (s ∪ t) a = ⊤ := truncatedSup_of_not_mem fun h ↦ (lower_aux.1 h).elim hs ht
end SemilatticeSup
section SemilatticeInf
variable [SemilatticeInf α] [SemilatticeInf β]
[BoundedOrder β] [DecidableLE β] {s t : Finset α} {a : α}
private lemma inf_aux [DecidableLE α] : a ∈ upperClosure s → {b ∈ s | b ≤ a}.Nonempty :=
fun ⟨b, hb, hab⟩ ↦ ⟨b, mem_filter.2 ⟨hb, hab⟩⟩
private lemma upper_aux [DecidableEq α] :
a ∈ upperClosure ↑(s ∪ t) ↔ a ∈ upperClosure s ∨ a ∈ upperClosure t := by
rw [coe_union, upperClosure_union, UpperSet.mem_inf_iff]
variable [DecidableLE α] [BoundedOrder α]
/-- The infimum of the elements of `s` less than `a` if there are some, otherwise `⊥`. -/
def truncatedInf (s : Finset α) (a : α) : α :=
if h : a ∈ upperClosure s then {b ∈ s | b ≤ a}.inf' (inf_aux h) id else ⊥
lemma truncatedInf_of_mem (h : a ∈ upperClosure s) :
truncatedInf s a = {b ∈ s | b ≤ a}.inf' (inf_aux h) id := dif_pos h
lemma truncatedInf_of_not_mem (h : a ∉ upperClosure s) : truncatedInf s a = ⊥ := dif_neg h
lemma truncatedInf_le : truncatedInf s a ≤ a := by
unfold truncatedInf
split_ifs with h
· obtain ⟨b, hb, hba⟩ := h
exact hba.trans' <| inf'_le id <| mem_filter.2 ⟨hb, ‹_›⟩
· exact bot_le
@[simp] lemma truncatedInf_empty (a : α) : truncatedInf ∅ a = ⊥ := truncatedInf_of_not_mem (by simp)
@[simp] lemma truncatedInf_singleton (b a : α) : truncatedInf {b} a = if b ≤ a then b else ⊥ := by
simp only [truncatedInf, coe_singleton, upperClosure_singleton, UpperSet.mem_Ici_iff,
filter_congr_decidable, id_eq]
split_ifs <;> simp [Finset.filter_true_of_mem, *]
lemma map_truncatedInf (e : α ≃o β) (s : Finset α) (a : α) :
e (truncatedInf s a) = truncatedInf (s.map e.toEquiv.toEmbedding) (e a) := by
have : e a ∈ upperClosure (s.map e.toEquiv.toEmbedding) ↔ a ∈ upperClosure s := by simp
simp_rw [truncatedInf, apply_dite e, map_finset_inf', map_bot, this]
congr with h
simp only [filter_map, Function.comp_def, Equiv.coe_toEmbedding, RelIso.coe_fn_toEquiv,
OrderIso.le_iff_le, id, inf'_map]
lemma truncatedInf_of_isAntichain (hs : IsAntichain (· ≤ ·) (s : Set α)) (ha : a ∈ s) :
truncatedInf s a = a := by
refine le_antisymm truncatedInf_le ?_
simp_rw [truncatedInf_of_mem (subset_upperClosure ha), le_inf'_iff, mem_filter]
rintro b ⟨hb, hba⟩
exact (hs.eq hb ha hba).ge
variable [DecidableEq α]
lemma truncatedInf_union (hs : a ∈ upperClosure s) (ht : a ∈ upperClosure t) :
truncatedInf (s ∪ t) a = truncatedInf s a ⊓ truncatedInf t a := by
simpa only [truncatedInf_of_mem, hs, ht, upper_aux.2 (Or.inl hs), filter_union] using
inf'_union _ _ _
lemma truncatedInf_union_left (hs : a ∈ upperClosure s) (ht : a ∉ upperClosure t) :
truncatedInf (s ∪ t) a = truncatedInf s a := by
simp only [mem_upperClosure, mem_coe, exists_prop, not_exists, not_and] at ht
simp only [truncatedInf_of_mem, hs, filter_union, filter_false_of_mem ht, union_empty,
upper_aux.2 (Or.inl hs), ht]
lemma truncatedInf_union_right (hs : a ∉ upperClosure s) (ht : a ∈ upperClosure t) :
truncatedInf (s ∪ t) a = truncatedInf t a := by
rw [union_comm, truncatedInf_union_left ht hs]
lemma truncatedInf_union_of_not_mem (hs : a ∉ upperClosure s) (ht : a ∉ upperClosure t) :
truncatedInf (s ∪ t) a = ⊥ :=
truncatedInf_of_not_mem <| by rw [coe_union, upperClosure_union]; exact fun h ↦ h.elim hs ht
end SemilatticeInf
section DistribLattice
| variable [DistribLattice α] [DecidableEq α] {s t : Finset α} {a : α}
| Mathlib/Combinatorics/SetFamily/AhlswedeZhang.lean | 249 | 250 |
/-
Copyright (c) 2020 Johan Commelin. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johan Commelin, Kevin Buzzard
-/
import Mathlib.Algebra.BigOperators.Field
import Mathlib.RingTheory.PowerSeries.Inverse
import Mathlib.RingTheory.PowerSeries.WellKnown
/-!
# Bernoulli numbers
The Bernoulli numbers are a sequence of rational numbers that frequently show up in
number theory.
## Mathematical overview
The Bernoulli numbers $(B_0, B_1, B_2, \ldots)=(1, -1/2, 1/6, 0, -1/30, \ldots)$ are
a sequence of rational numbers. They show up in the formula for the sums of $k$th
powers. They are related to the Taylor series expansions of $x/\tan(x)$ and
of $\coth(x)$, and also show up in the values that the Riemann Zeta function
takes both at both negative and positive integers (and hence in the
theory of modular forms). For example, if $1 \leq n$ then
$$\zeta(2n)=\sum_{t\geq1}t^{-2n}=(-1)^{n+1}\frac{(2\pi)^{2n}B_{2n}}{2(2n)!}.$$
This result is formalised in Lean: `riemannZeta_two_mul_nat`.
The Bernoulli numbers can be formally defined using the power series
$$\sum B_n\frac{t^n}{n!}=\frac{t}{1-e^{-t}}$$
although that happens to not be the definition in mathlib (this is an *implementation
detail* and need not concern the mathematician).
Note that $B_1=-1/2$, meaning that we are using the $B_n^-$ of
[from Wikipedia](https://en.wikipedia.org/wiki/Bernoulli_number).
## Implementation detail
The Bernoulli numbers are defined using well-founded induction, by the formula
$$B_n=1-\sum_{k\lt n}\frac{\binom{n}{k}}{n-k+1}B_k.$$
This formula is true for all $n$ and in particular $B_0=1$. Note that this is the definition
for positive Bernoulli numbers, which we call `bernoulli'`. The negative Bernoulli numbers are
then defined as `bernoulli := (-1)^n * bernoulli'`.
## Main theorems
`sum_bernoulli : ∑ k ∈ Finset.range n, (n.choose k : ℚ) * bernoulli k = if n = 1 then 1 else 0`
-/
open Nat Finset Finset.Nat PowerSeries
variable (A : Type*) [CommRing A] [Algebra ℚ A]
/-! ### Definitions -/
/-- The Bernoulli numbers:
the $n$-th Bernoulli number $B_n$ is defined recursively via
$$B_n = 1 - \sum_{k < n} \binom{n}{k}\frac{B_k}{n+1-k}$$ -/
def bernoulli' : ℕ → ℚ :=
WellFounded.fix Nat.lt_wfRel.wf fun n bernoulli' =>
1 - ∑ k : Fin n, n.choose k / (n - k + 1) * bernoulli' k k.2
theorem bernoulli'_def' (n : ℕ) :
bernoulli' n = 1 - ∑ k : Fin n, n.choose k / (n - k + 1) * bernoulli' k :=
WellFounded.fix_eq _ _ _
theorem bernoulli'_def (n : ℕ) :
bernoulli' n = 1 - ∑ k ∈ range n, n.choose k / (n - k + 1) * bernoulli' k := by
rw [bernoulli'_def', ← Fin.sum_univ_eq_sum_range]
theorem bernoulli'_spec (n : ℕ) :
(∑ k ∈ range n.succ, (n.choose (n - k) : ℚ) / (n - k + 1) * bernoulli' k) = 1 := by
rw [sum_range_succ_comm, bernoulli'_def n, tsub_self, choose_zero_right, sub_self, zero_add,
div_one, cast_one, one_mul, sub_add, ← sum_sub_distrib, ← sub_eq_zero, sub_sub_cancel_left,
neg_eq_zero]
exact Finset.sum_eq_zero (fun x hx => by rw [choose_symm (le_of_lt (mem_range.1 hx)), sub_self])
theorem bernoulli'_spec' (n : ℕ) :
(∑ k ∈ antidiagonal n, ((k.1 + k.2).choose k.2 : ℚ) / (k.2 + 1) * bernoulli' k.1) = 1 := by
refine ((sum_antidiagonal_eq_sum_range_succ_mk _ n).trans ?_).trans (bernoulli'_spec n)
refine sum_congr rfl fun x hx => ?_
simp only [add_tsub_cancel_of_le, mem_range_succ_iff.mp hx, cast_sub]
/-! ### Examples -/
section Examples
@[simp]
theorem bernoulli'_zero : bernoulli' 0 = 1 := by
rw [bernoulli'_def]
norm_num
@[simp]
theorem bernoulli'_one : bernoulli' 1 = 1 / 2 := by
rw [bernoulli'_def]
norm_num
@[simp]
theorem bernoulli'_two : bernoulli' 2 = 1 / 6 := by
rw [bernoulli'_def]
norm_num [sum_range_succ, sum_range_succ, sum_range_zero]
@[simp]
theorem bernoulli'_three : bernoulli' 3 = 0 := by
rw [bernoulli'_def]
norm_num [sum_range_succ, sum_range_succ, sum_range_zero]
@[simp]
theorem bernoulli'_four : bernoulli' 4 = -1 / 30 := by
have : Nat.choose 4 2 = 6 := by decide -- shrug
rw [bernoulli'_def]
norm_num [sum_range_succ, sum_range_succ, sum_range_zero, this]
end Examples
@[simp]
theorem sum_bernoulli' (n : ℕ) : (∑ k ∈ range n, (n.choose k : ℚ) * bernoulli' k) = n := by
cases n with | zero => simp | succ n =>
suffices
((n + 1 : ℚ) * ∑ k ∈ range n, ↑(n.choose k) / (n - k + 1) * bernoulli' k) =
∑ x ∈ range n, ↑(n.succ.choose x) * bernoulli' x by
rw_mod_cast [sum_range_succ, bernoulli'_def, ← this, choose_succ_self_right]
ring
simp_rw [mul_sum, ← mul_assoc]
refine sum_congr rfl fun k hk => ?_
congr
have : ((n - k : ℕ) : ℚ) + 1 ≠ 0 := by norm_cast
field_simp [← cast_sub (mem_range.1 hk).le, mul_comm]
rw_mod_cast [tsub_add_eq_add_tsub (mem_range.1 hk).le, choose_mul_succ_eq]
/-- The exponential generating function for the Bernoulli numbers `bernoulli' n`. -/
| def bernoulli'PowerSeries :=
mk fun n => algebraMap ℚ A (bernoulli' n / n !)
theorem bernoulli'PowerSeries_mul_exp_sub_one :
bernoulli'PowerSeries A * (exp A - 1) = X * exp A := by
ext n
-- constant coefficient is a special case
cases n with | zero => simp | succ n =>
rw [bernoulli'PowerSeries, coeff_mul, mul_comm X, sum_antidiagonal_succ']
suffices (∑ p ∈ antidiagonal n,
bernoulli' p.1 / p.1! * ((p.2 + 1) * p.2! : ℚ)⁻¹) = (n ! : ℚ)⁻¹ by
simpa [map_sum, Nat.factorial] using congr_arg (algebraMap ℚ A) this
apply eq_inv_of_mul_eq_one_left
rw [sum_mul]
| Mathlib/NumberTheory/Bernoulli.lean | 137 | 150 |
/-
Copyright (c) 2017 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro
-/
import Mathlib.Data.Finset.Image
import Mathlib.Data.Fintype.Defs
import Mathlib.Data.Nat.Notation
import Mathlib.Logic.Function.Basic
/-!
# Inductive type variant of `Fin`
`Fin` is defined as a subtype of `ℕ`. This file defines an equivalent type, `Fin2`, which is
defined inductively. This is useful for its induction principle and different definitional
equalities.
## Main declarations
* `Fin2 n`: Inductive type variant of `Fin n`. `fz` corresponds to `0` and `fs n` corresponds to
`n`.
* `Fin2.toNat`, `Fin2.optOfNat`, `Fin2.ofNat'`: Conversions to and from `ℕ`. `ofNat' m` takes a
proof that `m < n` through the class `Fin2.IsLT`.
* `Fin2.add k`: Takes `i : Fin2 n` to `i + k : Fin2 (n + k)`.
* `Fin2.left`: Embeds `Fin2 n` into `Fin2 (n + k)`.
* `Fin2.insertPerm a`: Permutation of `Fin2 n` which cycles `0, ..., a - 1` and leaves
`a, ..., n - 1` unchanged.
* `Fin2.remapLeft f`: Function `Fin2 (m + k) → Fin2 (n + k)` by applying `f : Fin m → Fin n` to
`0, ..., m - 1` and sending `m + i` to `n + i`.
-/
open Nat
universe u
/-- An alternate definition of `Fin n` defined as an inductive type instead of a subtype of `ℕ`. -/
inductive Fin2 : ℕ → Type
/-- `0` as a member of `Fin (n + 1)` (`Fin 0` is empty) -/
| fz {n} : Fin2 (n + 1)
/-- `n` as a member of `Fin (n + 1)` -/
| fs {n} : Fin2 n → Fin2 (n + 1)
namespace Fin2
/-- Define a dependent function on `Fin2 (succ n)` by giving its value at
zero (`H1`) and by giving a dependent function on the rest (`H2`). -/
@[elab_as_elim]
protected def cases' {n} {C : Fin2 (succ n) → Sort u} (H1 : C fz) (H2 : ∀ n, C (fs n)) :
∀ i : Fin2 (succ n), C i
| fz => H1
| fs n => H2 n
/-- Ex falso. The dependent eliminator for the empty `Fin2 0` type. -/
def elim0 {C : Fin2 0 → Sort u} : ∀ i : Fin2 0, C i := nofun
/-- Converts a `Fin2` into a natural. -/
def toNat : ∀ {n}, Fin2 n → ℕ
| _, @fz _ => 0
| _, @fs _ i => succ (toNat i)
/-- Converts a natural into a `Fin2` if it is in range -/
def optOfNat : ∀ {n}, ℕ → Option (Fin2 n)
| 0, _ => none
| succ _, 0 => some fz
| succ m, succ k => fs <$> @optOfNat m k
/-- `i + k : Fin2 (n + k)` when `i : Fin2 n` and `k : ℕ` -/
def add {n} (i : Fin2 n) : ∀ k, Fin2 (n + k)
| 0 => i
| succ k => fs (add i k)
/-- `left k` is the embedding `Fin2 n → Fin2 (k + n)` -/
def left (k) : ∀ {n}, Fin2 n → Fin2 (k + n)
| _, @fz _ => fz
| _, @fs _ i => fs (left k i)
/-- `insertPerm a` is a permutation of `Fin2 n` with the following properties:
* `insertPerm a i = i+1` if `i < a`
* `insertPerm a a = 0`
* `insertPerm a i = i` if `i > a` -/
def insertPerm : ∀ {n}, Fin2 n → Fin2 n → Fin2 n
| _, @fz _, @fz _ => fz
| _, @fz _, @fs _ j => fs j
| _, @fs (succ _) _, @fz _ => fs fz
| _, @fs (succ _) i, @fs _ j =>
match insertPerm i j with
| fz => fz
| fs k => fs (fs k)
/-- `remapLeft f k : Fin2 (m + k) → Fin2 (n + k)` applies the function
`f : Fin2 m → Fin2 n` to inputs less than `m`, and leaves the right part
on the right (that is, `remapLeft f k (m + i) = n + i`). -/
def remapLeft {m n} (f : Fin2 m → Fin2 n) : ∀ k, Fin2 (m + k) → Fin2 (n + k)
| 0, i => f i
| _k + 1, @fz _ => fz
| _k + 1, @fs _ i => fs (remapLeft f _ i)
/-- This is a simple type class inference prover for proof obligations
of the form `m < n` where `m n : ℕ`. -/
class IsLT (m n : ℕ) : Prop where
/-- The unique field of `Fin2.IsLT`, a proof that `m < n`. -/
h : m < n
instance IsLT.zero (n) : IsLT 0 (succ n) :=
⟨succ_pos _⟩
instance IsLT.succ (m n) [l : IsLT m n] : IsLT (succ m) (succ n) :=
⟨succ_lt_succ l.h⟩
/-- Use type class inference to infer the boundedness proof, so that we can directly convert a
`Nat` into a `Fin2 n`. This supports notation like `&1 : Fin 3`. -/
def ofNat' : ∀ {n} (m) [IsLT m n], Fin2 n
| 0, _, h => absurd h.h (Nat.not_lt_zero _)
| succ _, 0, _ => fz
| succ n, succ m, h => fs (@ofNat' n m ⟨lt_of_succ_lt_succ h.h⟩)
/-- `castSucc i` embeds `i : Fin2 n` in `Fin2 (n+1)`. -/
def castSucc {n} : Fin2 n → Fin2 (n + 1)
| fz => fz
| fs k => fs <| castSucc k
/-- The greatest value of `Fin2 (n+1)`. -/
def last : {n : Nat} → Fin2 (n+1)
| 0 => fz
| n+1 => fs (@last n)
/-- Maps `0` to `n-1`, `1` to `n-2`, ..., `n-1` to `0`. -/
def rev {n : Nat} : Fin2 n → Fin2 n
| .fz => last
| .fs i => i.rev.castSucc
@[simp] lemma rev_last {n} : rev (@last n) = fz := by
induction n <;> simp_all [rev, castSucc, last]
@[simp] lemma rev_castSucc {n} (i : Fin2 n) : rev (castSucc i) = fs (rev i) := by
induction i <;> simp_all [rev, castSucc, last]
@[simp] lemma rev_rev {n} (i : Fin2 n) : i.rev.rev = i := by
induction i <;> simp_all [rev]
theorem rev_involutive {n} : Function.Involutive (@rev n) := rev_rev
@[inherit_doc] local prefix:arg "&" => ofNat'
instance : Inhabited (Fin2 1) :=
⟨fz⟩
| instance instFintype : ∀ n, Fintype (Fin2 n)
| 0 => ⟨∅, Fin2.elim0⟩
| Mathlib/Data/Fin/Fin2.lean | 148 | 149 |
/-
Copyright (c) 2022 Joseph Myers. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joseph Myers
-/
import Mathlib.Algebra.CharP.Invertible
import Mathlib.Algebra.Order.Interval.Set.Group
import Mathlib.Analysis.Convex.Basic
import Mathlib.Analysis.Convex.Segment
import Mathlib.LinearAlgebra.AffineSpace.FiniteDimensional
import Mathlib.Tactic.FieldSimp
/-!
# Betweenness in affine spaces
This file defines notions of a point in an affine space being between two given points.
## Main definitions
* `affineSegment R x y`: The segment of points weakly between `x` and `y`.
* `Wbtw R x y z`: The point `y` is weakly between `x` and `z`.
* `Sbtw R x y z`: The point `y` is strictly between `x` and `z`.
-/
variable (R : Type*) {V V' P P' : Type*}
open AffineEquiv AffineMap
section OrderedRing
/-- The segment of points weakly between `x` and `y`. When convexity is refactored to support
abstract affine combination spaces, this will no longer need to be a separate definition from
`segment`. However, lemmas involving `+ᵥ` or `-ᵥ` will still be relevant after such a
refactoring, as distinct from versions involving `+` or `-` in a module. -/
def affineSegment [Ring R] [PartialOrder R] [AddCommGroup V] [Module R V]
[AddTorsor V P] (x y : P) :=
lineMap x y '' Set.Icc (0 : R) 1
variable [Ring R] [PartialOrder R] [AddCommGroup V] [Module R V] [AddTorsor V P]
variable [AddCommGroup V'] [Module R V'] [AddTorsor V' P']
variable {R} in
@[simp]
theorem affineSegment_image (f : P →ᵃ[R] P') (x y : P) :
f '' affineSegment R x y = affineSegment R (f x) (f y) := by
rw [affineSegment, affineSegment, Set.image_image, ← comp_lineMap]
rfl
@[simp]
theorem affineSegment_const_vadd_image (x y : P) (v : V) :
(v +ᵥ ·) '' affineSegment R x y = affineSegment R (v +ᵥ x) (v +ᵥ y) :=
affineSegment_image (AffineEquiv.constVAdd R P v : P →ᵃ[R] P) x y
@[simp]
theorem affineSegment_vadd_const_image (x y : V) (p : P) :
(· +ᵥ p) '' affineSegment R x y = affineSegment R (x +ᵥ p) (y +ᵥ p) :=
affineSegment_image (AffineEquiv.vaddConst R p : V →ᵃ[R] P) x y
@[simp]
theorem affineSegment_const_vsub_image (x y p : P) :
(p -ᵥ ·) '' affineSegment R x y = affineSegment R (p -ᵥ x) (p -ᵥ y) :=
affineSegment_image (AffineEquiv.constVSub R p : P →ᵃ[R] V) x y
@[simp]
theorem affineSegment_vsub_const_image (x y p : P) :
(· -ᵥ p) '' affineSegment R x y = affineSegment R (x -ᵥ p) (y -ᵥ p) :=
affineSegment_image ((AffineEquiv.vaddConst R p).symm : P →ᵃ[R] V) x y
variable {R}
@[simp]
theorem mem_const_vadd_affineSegment {x y z : P} (v : V) :
v +ᵥ z ∈ affineSegment R (v +ᵥ x) (v +ᵥ y) ↔ z ∈ affineSegment R x y := by
rw [← affineSegment_const_vadd_image, (AddAction.injective v).mem_set_image]
@[simp]
theorem mem_vadd_const_affineSegment {x y z : V} (p : P) :
z +ᵥ p ∈ affineSegment R (x +ᵥ p) (y +ᵥ p) ↔ z ∈ affineSegment R x y := by
rw [← affineSegment_vadd_const_image, (vadd_right_injective p).mem_set_image]
@[simp]
theorem mem_const_vsub_affineSegment {x y z : P} (p : P) :
p -ᵥ z ∈ affineSegment R (p -ᵥ x) (p -ᵥ y) ↔ z ∈ affineSegment R x y := by
rw [← affineSegment_const_vsub_image, (vsub_right_injective p).mem_set_image]
@[simp]
theorem mem_vsub_const_affineSegment {x y z : P} (p : P) :
z -ᵥ p ∈ affineSegment R (x -ᵥ p) (y -ᵥ p) ↔ z ∈ affineSegment R x y := by
rw [← affineSegment_vsub_const_image, (vsub_left_injective p).mem_set_image]
variable (R)
section OrderedRing
variable [IsOrderedRing R]
theorem affineSegment_eq_segment (x y : V) : affineSegment R x y = segment R x y := by
rw [segment_eq_image_lineMap, affineSegment]
theorem affineSegment_comm (x y : P) : affineSegment R x y = affineSegment R y x := by
refine Set.ext fun z => ?_
constructor <;>
· rintro ⟨t, ht, hxy⟩
refine ⟨1 - t, ?_, ?_⟩
· rwa [Set.sub_mem_Icc_iff_right, sub_self, sub_zero]
· rwa [lineMap_apply_one_sub]
theorem left_mem_affineSegment (x y : P) : x ∈ affineSegment R x y :=
⟨0, Set.left_mem_Icc.2 zero_le_one, lineMap_apply_zero _ _⟩
theorem right_mem_affineSegment (x y : P) : y ∈ affineSegment R x y :=
⟨1, Set.right_mem_Icc.2 zero_le_one, lineMap_apply_one _ _⟩
@[simp]
theorem affineSegment_same (x : P) : affineSegment R x x = {x} := by
simp_rw [affineSegment, lineMap_same, AffineMap.coe_const, Function.const,
(Set.nonempty_Icc.mpr zero_le_one).image_const]
end OrderedRing
/-- The point `y` is weakly between `x` and `z`. -/
def Wbtw (x y z : P) : Prop :=
y ∈ affineSegment R x z
/-- The point `y` is strictly between `x` and `z`. -/
def Sbtw (x y z : P) : Prop :=
Wbtw R x y z ∧ y ≠ x ∧ y ≠ z
variable {R}
section OrderedRing
variable [IsOrderedRing R]
lemma mem_segment_iff_wbtw {x y z : V} : y ∈ segment R x z ↔ Wbtw R x y z := by
rw [Wbtw, affineSegment_eq_segment]
alias ⟨_, Wbtw.mem_segment⟩ := mem_segment_iff_wbtw
lemma Convex.mem_of_wbtw {p₀ p₁ p₂ : V} {s : Set V} (hs : Convex R s) (h₀₁₂ : Wbtw R p₀ p₁ p₂)
(h₀ : p₀ ∈ s) (h₂ : p₂ ∈ s) : p₁ ∈ s := hs.segment_subset h₀ h₂ h₀₁₂.mem_segment
theorem wbtw_comm {x y z : P} : Wbtw R x y z ↔ Wbtw R z y x := by
rw [Wbtw, Wbtw, affineSegment_comm]
alias ⟨Wbtw.symm, _⟩ := wbtw_comm
theorem sbtw_comm {x y z : P} : Sbtw R x y z ↔ Sbtw R z y x := by
rw [Sbtw, Sbtw, wbtw_comm, ← and_assoc, ← and_assoc, and_right_comm]
alias ⟨Sbtw.symm, _⟩ := sbtw_comm
end OrderedRing
lemma AffineSubspace.mem_of_wbtw {s : AffineSubspace R P} {x y z : P} (hxyz : Wbtw R x y z)
(hx : x ∈ s) (hz : z ∈ s) : y ∈ s := by obtain ⟨ε, -, rfl⟩ := hxyz; exact lineMap_mem _ hx hz
theorem Wbtw.map {x y z : P} (h : Wbtw R x y z) (f : P →ᵃ[R] P') : Wbtw R (f x) (f y) (f z) := by
rw [Wbtw, ← affineSegment_image]
exact Set.mem_image_of_mem _ h
theorem Function.Injective.wbtw_map_iff {x y z : P} {f : P →ᵃ[R] P'} (hf : Function.Injective f) :
Wbtw R (f x) (f y) (f z) ↔ Wbtw R x y z := by
refine ⟨fun h => ?_, fun h => h.map _⟩
rwa [Wbtw, ← affineSegment_image, hf.mem_set_image] at h
theorem Function.Injective.sbtw_map_iff {x y z : P} {f : P →ᵃ[R] P'} (hf : Function.Injective f) :
Sbtw R (f x) (f y) (f z) ↔ Sbtw R x y z := by
simp_rw [Sbtw, hf.wbtw_map_iff, hf.ne_iff]
@[simp]
theorem AffineEquiv.wbtw_map_iff {x y z : P} (f : P ≃ᵃ[R] P') :
Wbtw R (f x) (f y) (f z) ↔ Wbtw R x y z := by
have : Function.Injective f.toAffineMap := f.injective
-- `refine` or `exact` are very slow, `apply` is fast. Please check before golfing.
apply this.wbtw_map_iff
@[simp]
theorem AffineEquiv.sbtw_map_iff {x y z : P} (f : P ≃ᵃ[R] P') :
Sbtw R (f x) (f y) (f z) ↔ Sbtw R x y z := by
have : Function.Injective f.toAffineMap := f.injective
-- `refine` or `exact` are very slow, `apply` is fast. Please check before golfing.
apply this.sbtw_map_iff
@[simp]
theorem wbtw_const_vadd_iff {x y z : P} (v : V) :
Wbtw R (v +ᵥ x) (v +ᵥ y) (v +ᵥ z) ↔ Wbtw R x y z :=
mem_const_vadd_affineSegment _
@[simp]
theorem wbtw_vadd_const_iff {x y z : V} (p : P) :
Wbtw R (x +ᵥ p) (y +ᵥ p) (z +ᵥ p) ↔ Wbtw R x y z :=
mem_vadd_const_affineSegment _
@[simp]
theorem wbtw_const_vsub_iff {x y z : P} (p : P) :
Wbtw R (p -ᵥ x) (p -ᵥ y) (p -ᵥ z) ↔ Wbtw R x y z :=
mem_const_vsub_affineSegment _
@[simp]
theorem wbtw_vsub_const_iff {x y z : P} (p : P) :
Wbtw R (x -ᵥ p) (y -ᵥ p) (z -ᵥ p) ↔ Wbtw R x y z :=
mem_vsub_const_affineSegment _
@[simp]
theorem sbtw_const_vadd_iff {x y z : P} (v : V) :
Sbtw R (v +ᵥ x) (v +ᵥ y) (v +ᵥ z) ↔ Sbtw R x y z := by
rw [Sbtw, Sbtw, wbtw_const_vadd_iff, (AddAction.injective v).ne_iff,
(AddAction.injective v).ne_iff]
@[simp]
theorem sbtw_vadd_const_iff {x y z : V} (p : P) :
Sbtw R (x +ᵥ p) (y +ᵥ p) (z +ᵥ p) ↔ Sbtw R x y z := by
rw [Sbtw, Sbtw, wbtw_vadd_const_iff, (vadd_right_injective p).ne_iff,
(vadd_right_injective p).ne_iff]
@[simp]
theorem sbtw_const_vsub_iff {x y z : P} (p : P) :
Sbtw R (p -ᵥ x) (p -ᵥ y) (p -ᵥ z) ↔ Sbtw R x y z := by
rw [Sbtw, Sbtw, wbtw_const_vsub_iff, (vsub_right_injective p).ne_iff,
(vsub_right_injective p).ne_iff]
@[simp]
theorem sbtw_vsub_const_iff {x y z : P} (p : P) :
Sbtw R (x -ᵥ p) (y -ᵥ p) (z -ᵥ p) ↔ Sbtw R x y z := by
rw [Sbtw, Sbtw, wbtw_vsub_const_iff, (vsub_left_injective p).ne_iff,
(vsub_left_injective p).ne_iff]
theorem Sbtw.wbtw {x y z : P} (h : Sbtw R x y z) : Wbtw R x y z :=
h.1
theorem Sbtw.ne_left {x y z : P} (h : Sbtw R x y z) : y ≠ x :=
h.2.1
theorem Sbtw.left_ne {x y z : P} (h : Sbtw R x y z) : x ≠ y :=
h.2.1.symm
theorem Sbtw.ne_right {x y z : P} (h : Sbtw R x y z) : y ≠ z :=
h.2.2
theorem Sbtw.right_ne {x y z : P} (h : Sbtw R x y z) : z ≠ y :=
h.2.2.symm
theorem Sbtw.mem_image_Ioo {x y z : P} (h : Sbtw R x y z) :
y ∈ lineMap x z '' Set.Ioo (0 : R) 1 := by
rcases h with ⟨⟨t, ht, rfl⟩, hyx, hyz⟩
rcases Set.eq_endpoints_or_mem_Ioo_of_mem_Icc ht with (rfl | rfl | ho)
· exfalso
exact hyx (lineMap_apply_zero _ _)
· exfalso
exact hyz (lineMap_apply_one _ _)
· exact ⟨t, ho, rfl⟩
theorem Wbtw.mem_affineSpan {x y z : P} (h : Wbtw R x y z) : y ∈ line[R, x, z] := by
rcases h with ⟨r, ⟨-, rfl⟩⟩
exact lineMap_mem_affineSpan_pair _ _ _
variable (R)
section OrderedRing
variable [IsOrderedRing R]
@[simp]
theorem wbtw_self_left (x y : P) : Wbtw R x x y :=
left_mem_affineSegment _ _ _
@[simp]
theorem wbtw_self_right (x y : P) : Wbtw R x y y :=
right_mem_affineSegment _ _ _
@[simp]
theorem wbtw_self_iff {x y : P} : Wbtw R x y x ↔ y = x := by
refine ⟨fun h => ?_, fun h => ?_⟩
· simpa [Wbtw, affineSegment] using h
· rw [h]
exact wbtw_self_left R x x
end OrderedRing
@[simp]
theorem not_sbtw_self_left (x y : P) : ¬Sbtw R x x y :=
fun h => h.ne_left rfl
@[simp]
theorem not_sbtw_self_right (x y : P) : ¬Sbtw R x y y :=
fun h => h.ne_right rfl
variable {R}
variable [IsOrderedRing R]
theorem Wbtw.left_ne_right_of_ne_left {x y z : P} (h : Wbtw R x y z) (hne : y ≠ x) : x ≠ z := by
rintro rfl
rw [wbtw_self_iff] at h
exact hne h
theorem Wbtw.left_ne_right_of_ne_right {x y z : P} (h : Wbtw R x y z) (hne : y ≠ z) : x ≠ z := by
rintro rfl
rw [wbtw_self_iff] at h
exact hne h
theorem Sbtw.left_ne_right {x y z : P} (h : Sbtw R x y z) : x ≠ z :=
h.wbtw.left_ne_right_of_ne_left h.2.1
theorem sbtw_iff_mem_image_Ioo_and_ne [NoZeroSMulDivisors R V] {x y z : P} :
Sbtw R x y z ↔ y ∈ lineMap x z '' Set.Ioo (0 : R) 1 ∧ x ≠ z := by
refine ⟨fun h => ⟨h.mem_image_Ioo, h.left_ne_right⟩, fun h => ?_⟩
rcases h with ⟨⟨t, ht, rfl⟩, hxz⟩
refine ⟨⟨t, Set.mem_Icc_of_Ioo ht, rfl⟩, ?_⟩
rw [lineMap_apply, ← @vsub_ne_zero V, ← @vsub_ne_zero V _ _ _ _ z, vadd_vsub_assoc, vsub_self,
vadd_vsub_assoc, ← neg_vsub_eq_vsub_rev z x, ← @neg_one_smul R, ← add_smul, ← sub_eq_add_neg]
simp [smul_ne_zero, sub_eq_zero, ht.1.ne.symm, ht.2.ne, hxz.symm]
variable (R)
@[simp]
theorem not_sbtw_self (x y : P) : ¬Sbtw R x y x :=
fun h => h.left_ne_right rfl
theorem wbtw_swap_left_iff [NoZeroSMulDivisors R V] {x y : P} (z : P) :
Wbtw R x y z ∧ Wbtw R y x z ↔ x = y := by
constructor
· rintro ⟨hxyz, hyxz⟩
rcases hxyz with ⟨ty, hty, rfl⟩
rcases hyxz with ⟨tx, htx, hx⟩
rw [lineMap_apply, lineMap_apply, ← add_vadd] at hx
rw [← @vsub_eq_zero_iff_eq V, vadd_vsub, vsub_vadd_eq_vsub_sub, smul_sub, smul_smul, ← sub_smul,
← add_smul, smul_eq_zero] at hx
rcases hx with (h | h)
· nth_rw 1 [← mul_one tx] at h
rw [← mul_sub, add_eq_zero_iff_neg_eq] at h
have h' : ty = 0 := by
refine le_antisymm ?_ hty.1
rw [← h, Left.neg_nonpos_iff]
exact mul_nonneg htx.1 (sub_nonneg.2 hty.2)
simp [h']
· rw [vsub_eq_zero_iff_eq] at h
rw [h, lineMap_same_apply]
· rintro rfl
exact ⟨wbtw_self_left _ _ _, wbtw_self_left _ _ _⟩
theorem wbtw_swap_right_iff [NoZeroSMulDivisors R V] (x : P) {y z : P} :
Wbtw R x y z ∧ Wbtw R x z y ↔ y = z := by
rw [wbtw_comm, wbtw_comm (z := y), eq_comm]
exact wbtw_swap_left_iff R x
theorem wbtw_rotate_iff [NoZeroSMulDivisors R V] (x : P) {y z : P} :
Wbtw R x y z ∧ Wbtw R z x y ↔ x = y := by rw [wbtw_comm, wbtw_swap_right_iff, eq_comm]
variable {R}
theorem Wbtw.swap_left_iff [NoZeroSMulDivisors R V] {x y z : P} (h : Wbtw R x y z) :
Wbtw R y x z ↔ x = y := by rw [← wbtw_swap_left_iff R z, and_iff_right h]
theorem Wbtw.swap_right_iff [NoZeroSMulDivisors R V] {x y z : P} (h : Wbtw R x y z) :
Wbtw R x z y ↔ y = z := by rw [← wbtw_swap_right_iff R x, and_iff_right h]
theorem Wbtw.rotate_iff [NoZeroSMulDivisors R V] {x y z : P} (h : Wbtw R x y z) :
Wbtw R z x y ↔ x = y := by rw [← wbtw_rotate_iff R x, and_iff_right h]
theorem Sbtw.not_swap_left [NoZeroSMulDivisors R V] {x y z : P} (h : Sbtw R x y z) :
¬Wbtw R y x z := fun hs => h.left_ne (h.wbtw.swap_left_iff.1 hs)
theorem Sbtw.not_swap_right [NoZeroSMulDivisors R V] {x y z : P} (h : Sbtw R x y z) :
¬Wbtw R x z y := fun hs => h.ne_right (h.wbtw.swap_right_iff.1 hs)
theorem Sbtw.not_rotate [NoZeroSMulDivisors R V] {x y z : P} (h : Sbtw R x y z) : ¬Wbtw R z x y :=
fun hs => h.left_ne (h.wbtw.rotate_iff.1 hs)
@[simp]
theorem wbtw_lineMap_iff [NoZeroSMulDivisors R V] {x y : P} {r : R} :
Wbtw R x (lineMap x y r) y ↔ x = y ∨ r ∈ Set.Icc (0 : R) 1 := by
by_cases hxy : x = y
· rw [hxy, lineMap_same_apply]
simp
rw [or_iff_right hxy, Wbtw, affineSegment, (lineMap_injective R hxy).mem_set_image]
@[simp]
theorem sbtw_lineMap_iff [NoZeroSMulDivisors R V] {x y : P} {r : R} :
Sbtw R x (lineMap x y r) y ↔ x ≠ y ∧ r ∈ Set.Ioo (0 : R) 1 := by
rw [sbtw_iff_mem_image_Ioo_and_ne, and_comm, and_congr_right]
intro hxy
rw [(lineMap_injective R hxy).mem_set_image]
@[simp]
theorem wbtw_mul_sub_add_iff [NoZeroDivisors R] {x y r : R} :
Wbtw R x (r * (y - x) + x) y ↔ x = y ∨ r ∈ Set.Icc (0 : R) 1 :=
wbtw_lineMap_iff
@[simp]
theorem sbtw_mul_sub_add_iff [NoZeroDivisors R] {x y r : R} :
Sbtw R x (r * (y - x) + x) y ↔ x ≠ y ∧ r ∈ Set.Ioo (0 : R) 1 :=
sbtw_lineMap_iff
omit [IsOrderedRing R] in
@[simp]
theorem wbtw_zero_one_iff {x : R} : Wbtw R 0 x 1 ↔ x ∈ Set.Icc (0 : R) 1 := by
rw [Wbtw, affineSegment, Set.mem_image]
simp_rw [lineMap_apply_ring]
simp
@[simp]
theorem wbtw_one_zero_iff {x : R} : Wbtw R 1 x 0 ↔ x ∈ Set.Icc (0 : R) 1 := by
rw [wbtw_comm, wbtw_zero_one_iff]
omit [IsOrderedRing R] in
@[simp]
theorem sbtw_zero_one_iff {x : R} : Sbtw R 0 x 1 ↔ x ∈ Set.Ioo (0 : R) 1 := by
rw [Sbtw, wbtw_zero_one_iff, Set.mem_Icc, Set.mem_Ioo]
exact
⟨fun h => ⟨h.1.1.lt_of_ne (Ne.symm h.2.1), h.1.2.lt_of_ne h.2.2⟩, fun h =>
⟨⟨h.1.le, h.2.le⟩, h.1.ne', h.2.ne⟩⟩
@[simp]
theorem sbtw_one_zero_iff {x : R} : Sbtw R 1 x 0 ↔ x ∈ Set.Ioo (0 : R) 1 := by
rw [sbtw_comm, sbtw_zero_one_iff]
theorem Wbtw.trans_left {w x y z : P} (h₁ : Wbtw R w y z) (h₂ : Wbtw R w x y) : Wbtw R w x z := by
rcases h₁ with ⟨t₁, ht₁, rfl⟩
rcases h₂ with ⟨t₂, ht₂, rfl⟩
refine ⟨t₂ * t₁, ⟨mul_nonneg ht₂.1 ht₁.1, mul_le_one₀ ht₂.2 ht₁.1 ht₁.2⟩, ?_⟩
rw [lineMap_apply, lineMap_apply, lineMap_vsub_left, smul_smul]
theorem Wbtw.trans_right {w x y z : P} (h₁ : Wbtw R w x z) (h₂ : Wbtw R x y z) : Wbtw R w y z := by
rw [wbtw_comm] at *
exact h₁.trans_left h₂
theorem Wbtw.trans_sbtw_left [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w y z)
(h₂ : Sbtw R w x y) : Sbtw R w x z := by
refine ⟨h₁.trans_left h₂.wbtw, h₂.ne_left, ?_⟩
rintro rfl
exact h₂.right_ne ((wbtw_swap_right_iff R w).1 ⟨h₁, h₂.wbtw⟩)
theorem Wbtw.trans_sbtw_right [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w x z)
(h₂ : Sbtw R x y z) : Sbtw R w y z := by
rw [wbtw_comm] at *
rw [sbtw_comm] at *
exact h₁.trans_sbtw_left h₂
theorem Sbtw.trans_left [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w y z)
(h₂ : Sbtw R w x y) : Sbtw R w x z :=
h₁.wbtw.trans_sbtw_left h₂
theorem Sbtw.trans_right [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w x z)
(h₂ : Sbtw R x y z) : Sbtw R w y z :=
h₁.wbtw.trans_sbtw_right h₂
theorem Wbtw.trans_left_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w y z)
(h₂ : Wbtw R w x y) (h : y ≠ z) : x ≠ z := by
rintro rfl
exact h (h₁.swap_right_iff.1 h₂)
theorem Wbtw.trans_right_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Wbtw R w x z)
(h₂ : Wbtw R x y z) (h : w ≠ x) : w ≠ y := by
rintro rfl
exact h (h₁.swap_left_iff.1 h₂)
theorem Sbtw.trans_wbtw_left_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w y z)
(h₂ : Wbtw R w x y) : x ≠ z :=
h₁.wbtw.trans_left_ne h₂ h₁.ne_right
theorem Sbtw.trans_wbtw_right_ne [NoZeroSMulDivisors R V] {w x y z : P} (h₁ : Sbtw R w x z)
(h₂ : Wbtw R x y z) : w ≠ y :=
h₁.wbtw.trans_right_ne h₂ h₁.left_ne
theorem Sbtw.affineCombination_of_mem_affineSpan_pair [NoZeroDivisors R] [NoZeroSMulDivisors R V]
{ι : Type*} {p : ι → P} (ha : AffineIndependent R p) {w w₁ w₂ : ι → R} {s : Finset ι}
(hw : ∑ i ∈ s, w i = 1) (hw₁ : ∑ i ∈ s, w₁ i = 1) (hw₂ : ∑ i ∈ s, w₂ i = 1)
(h : s.affineCombination R p w ∈
line[R, s.affineCombination R p w₁, s.affineCombination R p w₂])
{i : ι} (his : i ∈ s) (hs : Sbtw R (w₁ i) (w i) (w₂ i)) :
Sbtw R (s.affineCombination R p w₁) (s.affineCombination R p w)
(s.affineCombination R p w₂) := by
rw [affineCombination_mem_affineSpan_pair ha hw hw₁ hw₂] at h
rcases h with ⟨r, hr⟩
rw [hr i his, sbtw_mul_sub_add_iff] at hs
change ∀ i ∈ s, w i = (r • (w₂ - w₁) + w₁) i at hr
rw [s.affineCombination_congr hr fun _ _ => rfl]
rw [← s.weightedVSub_vadd_affineCombination, s.weightedVSub_const_smul,
← s.affineCombination_vsub, ← lineMap_apply, sbtw_lineMap_iff, and_iff_left hs.2,
← @vsub_ne_zero V, s.affineCombination_vsub]
intro hz
have hw₁w₂ : (∑ i ∈ s, (w₁ - w₂) i) = 0 := by
simp_rw [Pi.sub_apply, Finset.sum_sub_distrib, hw₁, hw₂, sub_self]
refine hs.1 ?_
have ha' := ha s (w₁ - w₂) hw₁w₂ hz i his
rwa [Pi.sub_apply, sub_eq_zero] at ha'
end OrderedRing
section StrictOrderedCommRing
variable [CommRing R] [PartialOrder R] [IsStrictOrderedRing R]
[AddCommGroup V] [Module R V] [AddTorsor V P]
variable {R}
theorem Wbtw.sameRay_vsub {x y z : P} (h : Wbtw R x y z) : SameRay R (y -ᵥ x) (z -ᵥ y) := by
rcases h with ⟨t, ⟨ht0, ht1⟩, rfl⟩
simp_rw [lineMap_apply]
rcases ht0.lt_or_eq with (ht0' | rfl); swap; · simp
rcases ht1.lt_or_eq with (ht1' | rfl); swap; · simp
refine Or.inr (Or.inr ⟨1 - t, t, sub_pos.2 ht1', ht0', ?_⟩)
simp only [vadd_vsub, smul_smul, vsub_vadd_eq_vsub_sub, smul_sub, ← sub_smul]
ring_nf
theorem Wbtw.sameRay_vsub_left {x y z : P} (h : Wbtw R x y z) : SameRay R (y -ᵥ x) (z -ᵥ x) := by
rcases h with ⟨t, ⟨ht0, _⟩, rfl⟩
simpa [lineMap_apply] using SameRay.sameRay_nonneg_smul_left (z -ᵥ x) ht0
theorem Wbtw.sameRay_vsub_right {x y z : P} (h : Wbtw R x y z) : SameRay R (z -ᵥ x) (z -ᵥ y) := by
rcases h with ⟨t, ⟨_, ht1⟩, rfl⟩
simpa [lineMap_apply, vsub_vadd_eq_vsub_sub, sub_smul] using
SameRay.sameRay_nonneg_smul_right (z -ᵥ x) (sub_nonneg.2 ht1)
end StrictOrderedCommRing
section LinearOrderedRing
| variable [Ring R] [LinearOrder R] [IsStrictOrderedRing R]
[AddCommGroup V] [Module R V] [AddTorsor V P]
variable {R}
/-- Suppose lines from two vertices of a triangle to interior points of the opposite side meet at
`p`. Then `p` lies in the interior of the first (and by symmetry the other) segment from a
vertex to the point on the opposite side. -/
theorem sbtw_of_sbtw_of_sbtw_of_mem_affineSpan_pair [NoZeroSMulDivisors R V]
{t : Affine.Triangle R P} {i₁ i₂ i₃ : Fin 3} (h₁₂ : i₁ ≠ i₂) {p₁ p₂ p : P}
(h₁ : Sbtw R (t.points i₂) p₁ (t.points i₃)) (h₂ : Sbtw R (t.points i₁) p₂ (t.points i₃))
(h₁' : p ∈ line[R, t.points i₁, p₁]) (h₂' : p ∈ line[R, t.points i₂, p₂]) :
Sbtw R (t.points i₁) p p₁ := by
have h₁₃ : i₁ ≠ i₃ := by
rintro rfl
simp at h₂
have h₂₃ : i₂ ≠ i₃ := by
rintro rfl
simp at h₁
have h3 : ∀ i : Fin 3, i = i₁ ∨ i = i₂ ∨ i = i₃ := by omega
have hu : (Finset.univ : Finset (Fin 3)) = {i₁, i₂, i₃} := by
clear h₁ h₂ h₁' h₂'
decide +revert
| Mathlib/Analysis/Convex/Between.lean | 520 | 541 |
/-
Copyright (c) 2019 Zhouhang Zhou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Zhouhang Zhou, Sébastien Gouëzel, Frédéric Dupuis
-/
import Mathlib.Algebra.BigOperators.Field
import Mathlib.Analysis.Complex.Basic
import Mathlib.Analysis.InnerProductSpace.Defs
import Mathlib.GroupTheory.MonoidLocalization.Basic
/-!
# Properties of inner product spaces
This file proves many basic properties of inner product spaces (real or complex).
## Main results
- `inner_mul_inner_self_le`: the Cauchy-Schwartz inequality (one of many variants).
- `norm_inner_eq_norm_iff`: the equality criteion in the Cauchy-Schwartz inequality (also in many
variants).
- `inner_eq_sum_norm_sq_div_four`: the polarization identity.
## Tags
inner product space, Hilbert space, norm
-/
noncomputable section
open RCLike Real Filter Topology ComplexConjugate Finsupp
open LinearMap (BilinForm)
variable {𝕜 E F : Type*} [RCLike 𝕜]
section BasicProperties_Seminormed
open scoped InnerProductSpace
variable [SeminormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [SeminormedAddCommGroup F] [InnerProductSpace ℝ F]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
local postfix:90 "†" => starRingEnd _
export InnerProductSpace (norm_sq_eq_re_inner)
@[simp]
theorem inner_conj_symm (x y : E) : ⟪y, x⟫† = ⟪x, y⟫ :=
InnerProductSpace.conj_inner_symm _ _
theorem real_inner_comm (x y : F) : ⟪y, x⟫_ℝ = ⟪x, y⟫_ℝ :=
@inner_conj_symm ℝ _ _ _ _ x y
theorem inner_eq_zero_symm {x y : E} : ⟪x, y⟫ = 0 ↔ ⟪y, x⟫ = 0 := by
rw [← inner_conj_symm]
exact star_eq_zero
@[simp]
theorem inner_self_im (x : E) : im ⟪x, x⟫ = 0 := by rw [← @ofReal_inj 𝕜, im_eq_conj_sub]; simp
theorem inner_add_left (x y z : E) : ⟪x + y, z⟫ = ⟪x, z⟫ + ⟪y, z⟫ :=
InnerProductSpace.add_left _ _ _
theorem inner_add_right (x y z : E) : ⟪x, y + z⟫ = ⟪x, y⟫ + ⟪x, z⟫ := by
rw [← inner_conj_symm, inner_add_left, RingHom.map_add]
simp only [inner_conj_symm]
theorem inner_re_symm (x y : E) : re ⟪x, y⟫ = re ⟪y, x⟫ := by rw [← inner_conj_symm, conj_re]
theorem inner_im_symm (x y : E) : im ⟪x, y⟫ = -im ⟪y, x⟫ := by rw [← inner_conj_symm, conj_im]
section Algebra
variable {𝕝 : Type*} [CommSemiring 𝕝] [StarRing 𝕝] [Algebra 𝕝 𝕜] [Module 𝕝 E]
[IsScalarTower 𝕝 𝕜 E] [StarModule 𝕝 𝕜]
/-- See `inner_smul_left` for the common special when `𝕜 = 𝕝`. -/
lemma inner_smul_left_eq_star_smul (x y : E) (r : 𝕝) : ⟪r • x, y⟫ = r† • ⟪x, y⟫ := by
rw [← algebraMap_smul 𝕜 r, InnerProductSpace.smul_left, starRingEnd_apply, starRingEnd_apply,
← algebraMap_star_comm, ← smul_eq_mul, algebraMap_smul]
/-- Special case of `inner_smul_left_eq_star_smul` when the acting ring has a trivial star
(eg `ℕ`, `ℤ`, `ℚ≥0`, `ℚ`, `ℝ`). -/
lemma inner_smul_left_eq_smul [TrivialStar 𝕝] (x y : E) (r : 𝕝) : ⟪r • x, y⟫ = r • ⟪x, y⟫ := by
rw [inner_smul_left_eq_star_smul, starRingEnd_apply, star_trivial]
/-- See `inner_smul_right` for the common special when `𝕜 = 𝕝`. -/
lemma inner_smul_right_eq_smul (x y : E) (r : 𝕝) : ⟪x, r • y⟫ = r • ⟪x, y⟫ := by
rw [← inner_conj_symm, inner_smul_left_eq_star_smul, starRingEnd_apply, starRingEnd_apply,
star_smul, star_star, ← starRingEnd_apply, inner_conj_symm]
end Algebra
/-- See `inner_smul_left_eq_star_smul` for the case of a general algebra action. -/
theorem inner_smul_left (x y : E) (r : 𝕜) : ⟪r • x, y⟫ = r† * ⟪x, y⟫ :=
inner_smul_left_eq_star_smul ..
theorem real_inner_smul_left (x y : F) (r : ℝ) : ⟪r • x, y⟫_ℝ = r * ⟪x, y⟫_ℝ :=
inner_smul_left _ _ _
theorem inner_smul_real_left (x y : E) (r : ℝ) : ⟪(r : 𝕜) • x, y⟫ = r • ⟪x, y⟫ := by
rw [inner_smul_left, conj_ofReal, Algebra.smul_def]
/-- See `inner_smul_right_eq_smul` for the case of a general algebra action. -/
theorem inner_smul_right (x y : E) (r : 𝕜) : ⟪x, r • y⟫ = r * ⟪x, y⟫ :=
inner_smul_right_eq_smul ..
theorem real_inner_smul_right (x y : F) (r : ℝ) : ⟪x, r • y⟫_ℝ = r * ⟪x, y⟫_ℝ :=
inner_smul_right _ _ _
theorem inner_smul_real_right (x y : E) (r : ℝ) : ⟪x, (r : 𝕜) • y⟫ = r • ⟪x, y⟫ := by
rw [inner_smul_right, Algebra.smul_def]
/-- The inner product as a sesquilinear form.
Note that in the case `𝕜 = ℝ` this is a bilinear form. -/
@[simps!]
def sesqFormOfInner : E →ₗ[𝕜] E →ₗ⋆[𝕜] 𝕜 :=
LinearMap.mk₂'ₛₗ (RingHom.id 𝕜) (starRingEnd _) (fun x y => ⟪y, x⟫)
(fun _x _y _z => inner_add_right _ _ _) (fun _r _x _y => inner_smul_right _ _ _)
(fun _x _y _z => inner_add_left _ _ _) fun _r _x _y => inner_smul_left _ _ _
/-- The real inner product as a bilinear form.
Note that unlike `sesqFormOfInner`, this does not reverse the order of the arguments. -/
@[simps!]
def bilinFormOfRealInner : BilinForm ℝ F := sesqFormOfInner.flip
/-- An inner product with a sum on the left. -/
theorem sum_inner {ι : Type*} (s : Finset ι) (f : ι → E) (x : E) :
⟪∑ i ∈ s, f i, x⟫ = ∑ i ∈ s, ⟪f i, x⟫ :=
map_sum (sesqFormOfInner (𝕜 := 𝕜) (E := E) x) _ _
/-- An inner product with a sum on the right. -/
theorem inner_sum {ι : Type*} (s : Finset ι) (f : ι → E) (x : E) :
⟪x, ∑ i ∈ s, f i⟫ = ∑ i ∈ s, ⟪x, f i⟫ :=
map_sum (LinearMap.flip sesqFormOfInner x) _ _
/-- An inner product with a sum on the left, `Finsupp` version. -/
protected theorem Finsupp.sum_inner {ι : Type*} (l : ι →₀ 𝕜) (v : ι → E) (x : E) :
⟪l.sum fun (i : ι) (a : 𝕜) => a • v i, x⟫ = l.sum fun (i : ι) (a : 𝕜) => conj a • ⟪v i, x⟫ := by
convert sum_inner (𝕜 := 𝕜) l.support (fun a => l a • v a) x
simp only [inner_smul_left, Finsupp.sum, smul_eq_mul]
/-- An inner product with a sum on the right, `Finsupp` version. -/
protected theorem Finsupp.inner_sum {ι : Type*} (l : ι →₀ 𝕜) (v : ι → E) (x : E) :
⟪x, l.sum fun (i : ι) (a : 𝕜) => a • v i⟫ = l.sum fun (i : ι) (a : 𝕜) => a • ⟪x, v i⟫ := by
convert inner_sum (𝕜 := 𝕜) l.support (fun a => l a • v a) x
simp only [inner_smul_right, Finsupp.sum, smul_eq_mul]
protected theorem DFinsupp.sum_inner {ι : Type*} [DecidableEq ι] {α : ι → Type*}
[∀ i, AddZeroClass (α i)] [∀ (i) (x : α i), Decidable (x ≠ 0)] (f : ∀ i, α i → E)
(l : Π₀ i, α i) (x : E) : ⟪l.sum f, x⟫ = l.sum fun i a => ⟪f i a, x⟫ := by
simp +contextual only [DFinsupp.sum, sum_inner, smul_eq_mul]
protected theorem DFinsupp.inner_sum {ι : Type*} [DecidableEq ι] {α : ι → Type*}
[∀ i, AddZeroClass (α i)] [∀ (i) (x : α i), Decidable (x ≠ 0)] (f : ∀ i, α i → E)
(l : Π₀ i, α i) (x : E) : ⟪x, l.sum f⟫ = l.sum fun i a => ⟪x, f i a⟫ := by
simp +contextual only [DFinsupp.sum, inner_sum, smul_eq_mul]
@[simp]
theorem inner_zero_left (x : E) : ⟪0, x⟫ = 0 := by
rw [← zero_smul 𝕜 (0 : E), inner_smul_left, RingHom.map_zero, zero_mul]
theorem inner_re_zero_left (x : E) : re ⟪0, x⟫ = 0 := by
simp only [inner_zero_left, AddMonoidHom.map_zero]
@[simp]
theorem inner_zero_right (x : E) : ⟪x, 0⟫ = 0 := by
rw [← inner_conj_symm, inner_zero_left, RingHom.map_zero]
theorem inner_re_zero_right (x : E) : re ⟪x, 0⟫ = 0 := by
simp only [inner_zero_right, AddMonoidHom.map_zero]
theorem inner_self_nonneg {x : E} : 0 ≤ re ⟪x, x⟫ :=
PreInnerProductSpace.toCore.re_inner_nonneg x
theorem real_inner_self_nonneg {x : F} : 0 ≤ ⟪x, x⟫_ℝ :=
@inner_self_nonneg ℝ F _ _ _ x
@[simp]
theorem inner_self_ofReal_re (x : E) : (re ⟪x, x⟫ : 𝕜) = ⟪x, x⟫ :=
((RCLike.is_real_TFAE (⟪x, x⟫ : 𝕜)).out 2 3).2 (inner_self_im (𝕜 := 𝕜) x)
theorem inner_self_eq_norm_sq_to_K (x : E) : ⟪x, x⟫ = (‖x‖ : 𝕜) ^ 2 := by
rw [← inner_self_ofReal_re, ← norm_sq_eq_re_inner, ofReal_pow]
theorem inner_self_re_eq_norm (x : E) : re ⟪x, x⟫ = ‖⟪x, x⟫‖ := by
conv_rhs => rw [← inner_self_ofReal_re]
symm
exact norm_of_nonneg inner_self_nonneg
theorem inner_self_ofReal_norm (x : E) : (‖⟪x, x⟫‖ : 𝕜) = ⟪x, x⟫ := by
rw [← inner_self_re_eq_norm]
exact inner_self_ofReal_re _
theorem real_inner_self_abs (x : F) : |⟪x, x⟫_ℝ| = ⟪x, x⟫_ℝ :=
@inner_self_ofReal_norm ℝ F _ _ _ x
theorem norm_inner_symm (x y : E) : ‖⟪x, y⟫‖ = ‖⟪y, x⟫‖ := by rw [← inner_conj_symm, norm_conj]
@[simp]
theorem inner_neg_left (x y : E) : ⟪-x, y⟫ = -⟪x, y⟫ := by
rw [← neg_one_smul 𝕜 x, inner_smul_left]
simp
@[simp]
theorem inner_neg_right (x y : E) : ⟪x, -y⟫ = -⟪x, y⟫ := by
rw [← inner_conj_symm, inner_neg_left]; simp only [RingHom.map_neg, inner_conj_symm]
theorem inner_neg_neg (x y : E) : ⟪-x, -y⟫ = ⟪x, y⟫ := by simp
theorem inner_self_conj (x : E) : ⟪x, x⟫† = ⟪x, x⟫ := inner_conj_symm _ _
theorem inner_sub_left (x y z : E) : ⟪x - y, z⟫ = ⟪x, z⟫ - ⟪y, z⟫ := by
simp [sub_eq_add_neg, inner_add_left]
theorem inner_sub_right (x y z : E) : ⟪x, y - z⟫ = ⟪x, y⟫ - ⟪x, z⟫ := by
simp [sub_eq_add_neg, inner_add_right]
theorem inner_mul_symm_re_eq_norm (x y : E) : re (⟪x, y⟫ * ⟪y, x⟫) = ‖⟪x, y⟫ * ⟪y, x⟫‖ := by
rw [← inner_conj_symm, mul_comm]
exact re_eq_norm_of_mul_conj (inner y x)
/-- Expand `⟪x + y, x + y⟫` -/
theorem inner_add_add_self (x y : E) : ⟪x + y, x + y⟫ = ⟪x, x⟫ + ⟪x, y⟫ + ⟪y, x⟫ + ⟪y, y⟫ := by
simp only [inner_add_left, inner_add_right]; ring
/-- Expand `⟪x + y, x + y⟫_ℝ` -/
theorem real_inner_add_add_self (x y : F) :
⟪x + y, x + y⟫_ℝ = ⟪x, x⟫_ℝ + 2 * ⟪x, y⟫_ℝ + ⟪y, y⟫_ℝ := by
have : ⟪y, x⟫_ℝ = ⟪x, y⟫_ℝ := by rw [← inner_conj_symm]; rfl
simp only [inner_add_add_self, this, add_left_inj]
ring
-- Expand `⟪x - y, x - y⟫`
theorem inner_sub_sub_self (x y : E) : ⟪x - y, x - y⟫ = ⟪x, x⟫ - ⟪x, y⟫ - ⟪y, x⟫ + ⟪y, y⟫ := by
simp only [inner_sub_left, inner_sub_right]; ring
/-- Expand `⟪x - y, x - y⟫_ℝ` -/
theorem real_inner_sub_sub_self (x y : F) :
⟪x - y, x - y⟫_ℝ = ⟪x, x⟫_ℝ - 2 * ⟪x, y⟫_ℝ + ⟪y, y⟫_ℝ := by
have : ⟪y, x⟫_ℝ = ⟪x, y⟫_ℝ := by rw [← inner_conj_symm]; rfl
simp only [inner_sub_sub_self, this, add_left_inj]
ring
/-- Parallelogram law -/
theorem parallelogram_law {x y : E} : ⟪x + y, x + y⟫ + ⟪x - y, x - y⟫ = 2 * (⟪x, x⟫ + ⟪y, y⟫) := by
simp only [inner_add_add_self, inner_sub_sub_self]
ring
/-- **Cauchy–Schwarz inequality**. -/
theorem inner_mul_inner_self_le (x y : E) : ‖⟪x, y⟫‖ * ‖⟪y, x⟫‖ ≤ re ⟪x, x⟫ * re ⟪y, y⟫ :=
letI cd : PreInnerProductSpace.Core 𝕜 E := PreInnerProductSpace.toCore
InnerProductSpace.Core.inner_mul_inner_self_le x y
/-- Cauchy–Schwarz inequality for real inner products. -/
theorem real_inner_mul_inner_self_le (x y : F) : ⟪x, y⟫_ℝ * ⟪x, y⟫_ℝ ≤ ⟪x, x⟫_ℝ * ⟪y, y⟫_ℝ :=
calc
⟪x, y⟫_ℝ * ⟪x, y⟫_ℝ ≤ ‖⟪x, y⟫_ℝ‖ * ‖⟪y, x⟫_ℝ‖ := by
rw [real_inner_comm y, ← norm_mul]
exact le_abs_self _
_ ≤ ⟪x, x⟫_ℝ * ⟪y, y⟫_ℝ := @inner_mul_inner_self_le ℝ _ _ _ _ x y
end BasicProperties_Seminormed
section BasicProperties
variable [NormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [NormedAddCommGroup F] [InnerProductSpace ℝ F]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
export InnerProductSpace (norm_sq_eq_re_inner)
@[simp]
theorem inner_self_eq_zero {x : E} : ⟪x, x⟫ = 0 ↔ x = 0 := by
rw [inner_self_eq_norm_sq_to_K, sq_eq_zero_iff, ofReal_eq_zero, norm_eq_zero]
theorem inner_self_ne_zero {x : E} : ⟪x, x⟫ ≠ 0 ↔ x ≠ 0 :=
inner_self_eq_zero.not
variable (𝕜)
theorem ext_inner_left {x y : E} (h : ∀ v, ⟪v, x⟫ = ⟪v, y⟫) : x = y := by
rw [← sub_eq_zero, ← @inner_self_eq_zero 𝕜, inner_sub_right, sub_eq_zero, h (x - y)]
theorem ext_inner_right {x y : E} (h : ∀ v, ⟪x, v⟫ = ⟪y, v⟫) : x = y := by
rw [← sub_eq_zero, ← @inner_self_eq_zero 𝕜, inner_sub_left, sub_eq_zero, h (x - y)]
variable {𝕜}
@[simp]
theorem re_inner_self_nonpos {x : E} : re ⟪x, x⟫ ≤ 0 ↔ x = 0 := by
rw [← norm_sq_eq_re_inner, (sq_nonneg _).le_iff_eq, sq_eq_zero_iff, norm_eq_zero]
@[simp]
lemma re_inner_self_pos {x : E} : 0 < re ⟪x, x⟫ ↔ x ≠ 0 := by
simpa [-re_inner_self_nonpos] using re_inner_self_nonpos (𝕜 := 𝕜) (x := x).not
@[deprecated (since := "2025-04-22")] alias inner_self_nonpos := re_inner_self_nonpos
@[deprecated (since := "2025-04-22")] alias inner_self_pos := re_inner_self_pos
open scoped InnerProductSpace in
theorem real_inner_self_nonpos {x : F} : ⟪x, x⟫_ℝ ≤ 0 ↔ x = 0 := re_inner_self_nonpos (𝕜 := ℝ)
open scoped InnerProductSpace in
theorem real_inner_self_pos {x : F} : 0 < ⟪x, x⟫_ℝ ↔ x ≠ 0 := re_inner_self_pos (𝕜 := ℝ)
/-- A family of vectors is linearly independent if they are nonzero
and orthogonal. -/
theorem linearIndependent_of_ne_zero_of_inner_eq_zero {ι : Type*} {v : ι → E} (hz : ∀ i, v i ≠ 0)
(ho : Pairwise fun i j => ⟪v i, v j⟫ = 0) : LinearIndependent 𝕜 v := by
rw [linearIndependent_iff']
intro s g hg i hi
have h' : g i * inner (v i) (v i) = inner (v i) (∑ j ∈ s, g j • v j) := by
rw [inner_sum]
symm
convert Finset.sum_eq_single (M := 𝕜) i ?_ ?_
· rw [inner_smul_right]
· intro j _hj hji
rw [inner_smul_right, ho hji.symm, mul_zero]
· exact fun h => False.elim (h hi)
simpa [hg, hz] using h'
end BasicProperties
section Norm_Seminormed
open scoped InnerProductSpace
variable [SeminormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [SeminormedAddCommGroup F] [InnerProductSpace ℝ F]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
local notation "IK" => @RCLike.I 𝕜 _
theorem norm_eq_sqrt_re_inner (x : E) : ‖x‖ = √(re ⟪x, x⟫) :=
calc
‖x‖ = √(‖x‖ ^ 2) := (sqrt_sq (norm_nonneg _)).symm
_ = √(re ⟪x, x⟫) := congr_arg _ (norm_sq_eq_re_inner _)
@[deprecated (since := "2025-04-22")] alias norm_eq_sqrt_inner := norm_eq_sqrt_re_inner
theorem norm_eq_sqrt_real_inner (x : F) : ‖x‖ = √⟪x, x⟫_ℝ :=
@norm_eq_sqrt_re_inner ℝ _ _ _ _ x
theorem inner_self_eq_norm_mul_norm (x : E) : re ⟪x, x⟫ = ‖x‖ * ‖x‖ := by
rw [@norm_eq_sqrt_re_inner 𝕜, ← sqrt_mul inner_self_nonneg (re ⟪x, x⟫),
sqrt_mul_self inner_self_nonneg]
theorem inner_self_eq_norm_sq (x : E) : re ⟪x, x⟫ = ‖x‖ ^ 2 := by
rw [pow_two, inner_self_eq_norm_mul_norm]
theorem real_inner_self_eq_norm_mul_norm (x : F) : ⟪x, x⟫_ℝ = ‖x‖ * ‖x‖ := by
have h := @inner_self_eq_norm_mul_norm ℝ F _ _ _ x
simpa using h
theorem real_inner_self_eq_norm_sq (x : F) : ⟪x, x⟫_ℝ = ‖x‖ ^ 2 := by
rw [pow_two, real_inner_self_eq_norm_mul_norm]
/-- Expand the square -/
theorem norm_add_sq (x y : E) : ‖x + y‖ ^ 2 = ‖x‖ ^ 2 + 2 * re ⟪x, y⟫ + ‖y‖ ^ 2 := by
repeat' rw [sq (M := ℝ), ← @inner_self_eq_norm_mul_norm 𝕜]
rw [inner_add_add_self, two_mul]
simp only [add_assoc, add_left_inj, add_right_inj, AddMonoidHom.map_add]
rw [← inner_conj_symm, conj_re]
alias norm_add_pow_two := norm_add_sq
/-- Expand the square -/
theorem norm_add_sq_real (x y : F) : ‖x + y‖ ^ 2 = ‖x‖ ^ 2 + 2 * ⟪x, y⟫_ℝ + ‖y‖ ^ 2 := by
have h := @norm_add_sq ℝ _ _ _ _ x y
simpa using h
alias norm_add_pow_two_real := norm_add_sq_real
/-- Expand the square -/
theorem norm_add_mul_self (x y : E) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + 2 * re ⟪x, y⟫ + ‖y‖ * ‖y‖ := by
repeat' rw [← sq (M := ℝ)]
exact norm_add_sq _ _
/-- Expand the square -/
theorem norm_add_mul_self_real (x y : F) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + 2 * ⟪x, y⟫_ℝ + ‖y‖ * ‖y‖ := by
have h := @norm_add_mul_self ℝ _ _ _ _ x y
simpa using h
/-- Expand the square -/
theorem norm_sub_sq (x y : E) : ‖x - y‖ ^ 2 = ‖x‖ ^ 2 - 2 * re ⟪x, y⟫ + ‖y‖ ^ 2 := by
rw [sub_eq_add_neg, @norm_add_sq 𝕜 _ _ _ _ x (-y), norm_neg, inner_neg_right, map_neg, mul_neg,
sub_eq_add_neg]
alias norm_sub_pow_two := norm_sub_sq
/-- Expand the square -/
theorem norm_sub_sq_real (x y : F) : ‖x - y‖ ^ 2 = ‖x‖ ^ 2 - 2 * ⟪x, y⟫_ℝ + ‖y‖ ^ 2 :=
@norm_sub_sq ℝ _ _ _ _ _ _
alias norm_sub_pow_two_real := norm_sub_sq_real
/-- Expand the square -/
theorem norm_sub_mul_self (x y : E) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ - 2 * re ⟪x, y⟫ + ‖y‖ * ‖y‖ := by
repeat' rw [← sq (M := ℝ)]
exact norm_sub_sq _ _
/-- Expand the square -/
theorem norm_sub_mul_self_real (x y : F) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ - 2 * ⟪x, y⟫_ℝ + ‖y‖ * ‖y‖ := by
have h := @norm_sub_mul_self ℝ _ _ _ _ x y
simpa using h
/-- Cauchy–Schwarz inequality with norm -/
theorem norm_inner_le_norm (x y : E) : ‖⟪x, y⟫‖ ≤ ‖x‖ * ‖y‖ := by
rw [norm_eq_sqrt_re_inner (𝕜 := 𝕜) x, norm_eq_sqrt_re_inner (𝕜 := 𝕜) y]
letI : PreInnerProductSpace.Core 𝕜 E := PreInnerProductSpace.toCore
exact InnerProductSpace.Core.norm_inner_le_norm x y
theorem nnnorm_inner_le_nnnorm (x y : E) : ‖⟪x, y⟫‖₊ ≤ ‖x‖₊ * ‖y‖₊ :=
norm_inner_le_norm x y
theorem re_inner_le_norm (x y : E) : re ⟪x, y⟫ ≤ ‖x‖ * ‖y‖ :=
le_trans (re_le_norm (inner x y)) (norm_inner_le_norm x y)
/-- Cauchy–Schwarz inequality with norm -/
theorem abs_real_inner_le_norm (x y : F) : |⟪x, y⟫_ℝ| ≤ ‖x‖ * ‖y‖ :=
(Real.norm_eq_abs _).ge.trans (norm_inner_le_norm x y)
/-- Cauchy–Schwarz inequality with norm -/
theorem real_inner_le_norm (x y : F) : ⟪x, y⟫_ℝ ≤ ‖x‖ * ‖y‖ :=
le_trans (le_abs_self _) (abs_real_inner_le_norm _ _)
lemma inner_eq_zero_of_left {x : E} (y : E) (h : ‖x‖ = 0) : ⟪x, y⟫_𝕜 = 0 := by
rw [← norm_eq_zero]
refine le_antisymm ?_ (by positivity)
exact norm_inner_le_norm _ _ |>.trans <| by simp [h]
lemma inner_eq_zero_of_right (x : E) {y : E} (h : ‖y‖ = 0) : ⟪x, y⟫_𝕜 = 0 := by
rw [inner_eq_zero_symm, inner_eq_zero_of_left _ h]
variable (𝕜)
include 𝕜 in
theorem parallelogram_law_with_norm (x y : E) :
‖x + y‖ * ‖x + y‖ + ‖x - y‖ * ‖x - y‖ = 2 * (‖x‖ * ‖x‖ + ‖y‖ * ‖y‖) := by
simp only [← @inner_self_eq_norm_mul_norm 𝕜]
rw [← re.map_add, parallelogram_law, two_mul, two_mul]
simp only [re.map_add]
include 𝕜 in
theorem parallelogram_law_with_nnnorm (x y : E) :
‖x + y‖₊ * ‖x + y‖₊ + ‖x - y‖₊ * ‖x - y‖₊ = 2 * (‖x‖₊ * ‖x‖₊ + ‖y‖₊ * ‖y‖₊) :=
Subtype.ext <| parallelogram_law_with_norm 𝕜 x y
variable {𝕜}
/-- Polarization identity: The real part of the inner product, in terms of the norm. -/
theorem re_inner_eq_norm_add_mul_self_sub_norm_mul_self_sub_norm_mul_self_div_two (x y : E) :
re ⟪x, y⟫ = (‖x + y‖ * ‖x + y‖ - ‖x‖ * ‖x‖ - ‖y‖ * ‖y‖) / 2 := by
rw [@norm_add_mul_self 𝕜]
ring
/-- Polarization identity: The real part of the inner product, in terms of the norm. -/
theorem re_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two (x y : E) :
re ⟪x, y⟫ = (‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ - ‖x - y‖ * ‖x - y‖) / 2 := by
rw [@norm_sub_mul_self 𝕜]
ring
/-- Polarization identity: The real part of the inner product, in terms of the norm. -/
theorem re_inner_eq_norm_add_mul_self_sub_norm_sub_mul_self_div_four (x y : E) :
re ⟪x, y⟫ = (‖x + y‖ * ‖x + y‖ - ‖x - y‖ * ‖x - y‖) / 4 := by
rw [@norm_add_mul_self 𝕜, @norm_sub_mul_self 𝕜]
ring
/-- Polarization identity: The imaginary part of the inner product, in terms of the norm. -/
theorem im_inner_eq_norm_sub_i_smul_mul_self_sub_norm_add_i_smul_mul_self_div_four (x y : E) :
im ⟪x, y⟫ = (‖x - IK • y‖ * ‖x - IK • y‖ - ‖x + IK • y‖ * ‖x + IK • y‖) / 4 := by
simp only [@norm_add_mul_self 𝕜, @norm_sub_mul_self 𝕜, inner_smul_right, I_mul_re]
ring
/-- Polarization identity: The inner product, in terms of the norm. -/
theorem inner_eq_sum_norm_sq_div_four (x y : E) :
⟪x, y⟫ = ((‖x + y‖ : 𝕜) ^ 2 - (‖x - y‖ : 𝕜) ^ 2 +
((‖x - IK • y‖ : 𝕜) ^ 2 - (‖x + IK • y‖ : 𝕜) ^ 2) * IK) / 4 := by
rw [← re_add_im ⟪x, y⟫, re_inner_eq_norm_add_mul_self_sub_norm_sub_mul_self_div_four,
im_inner_eq_norm_sub_i_smul_mul_self_sub_norm_add_i_smul_mul_self_div_four]
push_cast
simp only [sq, ← mul_div_right_comm, ← add_div]
/-- Polarization identity: The real inner product, in terms of the norm. -/
theorem real_inner_eq_norm_add_mul_self_sub_norm_mul_self_sub_norm_mul_self_div_two (x y : F) :
⟪x, y⟫_ℝ = (‖x + y‖ * ‖x + y‖ - ‖x‖ * ‖x‖ - ‖y‖ * ‖y‖) / 2 :=
re_to_real.symm.trans <|
re_inner_eq_norm_add_mul_self_sub_norm_mul_self_sub_norm_mul_self_div_two x y
/-- Polarization identity: The real inner product, in terms of the norm. -/
theorem real_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two (x y : F) :
⟪x, y⟫_ℝ = (‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ - ‖x - y‖ * ‖x - y‖) / 2 :=
re_to_real.symm.trans <|
re_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two x y
/-- Pythagorean theorem, if-and-only-if vector inner product form. -/
theorem norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero (x y : F) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ ↔ ⟪x, y⟫_ℝ = 0 := by
rw [@norm_add_mul_self ℝ, add_right_cancel_iff, add_eq_left, mul_eq_zero]
norm_num
/-- Pythagorean theorem, if-and-if vector inner product form using square roots. -/
theorem norm_add_eq_sqrt_iff_real_inner_eq_zero {x y : F} :
‖x + y‖ = √(‖x‖ * ‖x‖ + ‖y‖ * ‖y‖) ↔ ⟪x, y⟫_ℝ = 0 := by
rw [← norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero, eq_comm, sqrt_eq_iff_mul_self_eq,
eq_comm] <;> positivity
/-- Pythagorean theorem, vector inner product form. -/
theorem norm_add_sq_eq_norm_sq_add_norm_sq_of_inner_eq_zero (x y : E) (h : ⟪x, y⟫ = 0) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ := by
rw [@norm_add_mul_self 𝕜, add_right_cancel_iff, add_eq_left, mul_eq_zero]
apply Or.inr
simp only [h, zero_re']
/-- Pythagorean theorem, vector inner product form. -/
theorem norm_add_sq_eq_norm_sq_add_norm_sq_real {x y : F} (h : ⟪x, y⟫_ℝ = 0) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ :=
(norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero x y).2 h
/-- Pythagorean theorem, subtracting vectors, if-and-only-if vector
inner product form. -/
theorem norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero (x y : F) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ ↔ ⟪x, y⟫_ℝ = 0 := by
rw [@norm_sub_mul_self ℝ, add_right_cancel_iff, sub_eq_add_neg, add_eq_left, neg_eq_zero,
mul_eq_zero]
norm_num
/-- Pythagorean theorem, subtracting vectors, if-and-if vector inner product form using square
roots. -/
theorem norm_sub_eq_sqrt_iff_real_inner_eq_zero {x y : F} :
‖x - y‖ = √(‖x‖ * ‖x‖ + ‖y‖ * ‖y‖) ↔ ⟪x, y⟫_ℝ = 0 := by
rw [← norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero, eq_comm, sqrt_eq_iff_mul_self_eq,
eq_comm] <;> positivity
/-- Pythagorean theorem, subtracting vectors, vector inner product
form. -/
theorem norm_sub_sq_eq_norm_sq_add_norm_sq_real {x y : F} (h : ⟪x, y⟫_ℝ = 0) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ :=
(norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero x y).2 h
/-- The sum and difference of two vectors are orthogonal if and only
if they have the same norm. -/
theorem real_inner_add_sub_eq_zero_iff (x y : F) : ⟪x + y, x - y⟫_ℝ = 0 ↔ ‖x‖ = ‖y‖ := by
conv_rhs => rw [← mul_self_inj_of_nonneg (norm_nonneg _) (norm_nonneg _)]
simp only [← @inner_self_eq_norm_mul_norm ℝ, inner_add_left, inner_sub_right, real_inner_comm y x,
sub_eq_zero, re_to_real]
constructor
· intro h
rw [add_comm] at h
linarith
· intro h
linarith
/-- Given two orthogonal vectors, their sum and difference have equal norms. -/
theorem norm_sub_eq_norm_add {v w : E} (h : ⟪v, w⟫ = 0) : ‖w - v‖ = ‖w + v‖ := by
rw [← mul_self_inj_of_nonneg (norm_nonneg _) (norm_nonneg _)]
simp only [h, ← @inner_self_eq_norm_mul_norm 𝕜, sub_neg_eq_add, sub_zero, map_sub, zero_re',
zero_sub, add_zero, map_add, inner_add_right, inner_sub_left, inner_sub_right, inner_re_symm,
zero_add]
/-- The real inner product of two vectors, divided by the product of their
norms, has absolute value at most 1. -/
theorem abs_real_inner_div_norm_mul_norm_le_one (x y : F) : |⟪x, y⟫_ℝ / (‖x‖ * ‖y‖)| ≤ 1 := by
rw [abs_div, abs_mul, abs_norm, abs_norm]
exact div_le_one_of_le₀ (abs_real_inner_le_norm x y) (by positivity)
/-- The inner product of a vector with a multiple of itself. -/
theorem real_inner_smul_self_left (x : F) (r : ℝ) : ⟪r • x, x⟫_ℝ = r * (‖x‖ * ‖x‖) := by
rw [real_inner_smul_left, ← real_inner_self_eq_norm_mul_norm]
/-- The inner product of a vector with a multiple of itself. -/
theorem real_inner_smul_self_right (x : F) (r : ℝ) : ⟪x, r • x⟫_ℝ = r * (‖x‖ * ‖x‖) := by
rw [inner_smul_right, ← real_inner_self_eq_norm_mul_norm]
/-- The inner product of two weighted sums, where the weights in each
sum add to 0, in terms of the norms of pairwise differences. -/
theorem inner_sum_smul_sum_smul_of_sum_eq_zero {ι₁ : Type*} {s₁ : Finset ι₁} {w₁ : ι₁ → ℝ}
(v₁ : ι₁ → F) (h₁ : ∑ i ∈ s₁, w₁ i = 0) {ι₂ : Type*} {s₂ : Finset ι₂} {w₂ : ι₂ → ℝ}
(v₂ : ι₂ → F) (h₂ : ∑ i ∈ s₂, w₂ i = 0) :
⟪∑ i₁ ∈ s₁, w₁ i₁ • v₁ i₁, ∑ i₂ ∈ s₂, w₂ i₂ • v₂ i₂⟫_ℝ =
(-∑ i₁ ∈ s₁, ∑ i₂ ∈ s₂, w₁ i₁ * w₂ i₂ * (‖v₁ i₁ - v₂ i₂‖ * ‖v₁ i₁ - v₂ i₂‖)) / 2 := by
simp_rw [sum_inner, inner_sum, real_inner_smul_left, real_inner_smul_right,
real_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two, ← div_sub_div_same,
← div_add_div_same, mul_sub_left_distrib, left_distrib, Finset.sum_sub_distrib,
Finset.sum_add_distrib, ← Finset.mul_sum, ← Finset.sum_mul, h₁, h₂, zero_mul,
mul_zero, Finset.sum_const_zero, zero_add, zero_sub, Finset.mul_sum, neg_div,
Finset.sum_div, mul_div_assoc, mul_assoc]
end Norm_Seminormed
section Norm
open scoped InnerProductSpace
variable [NormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [NormedAddCommGroup F] [InnerProductSpace ℝ F]
variable {ι : Type*}
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-- Formula for the distance between the images of two nonzero points under an inversion with center
zero. See also `EuclideanGeometry.dist_inversion_inversion` for inversions around a general
point. -/
theorem dist_div_norm_sq_smul {x y : F} (hx : x ≠ 0) (hy : y ≠ 0) (R : ℝ) :
dist ((R / ‖x‖) ^ 2 • x) ((R / ‖y‖) ^ 2 • y) = R ^ 2 / (‖x‖ * ‖y‖) * dist x y :=
calc
dist ((R / ‖x‖) ^ 2 • x) ((R / ‖y‖) ^ 2 • y) =
√(‖(R / ‖x‖) ^ 2 • x - (R / ‖y‖) ^ 2 • y‖ ^ 2) := by
rw [dist_eq_norm, sqrt_sq (norm_nonneg _)]
_ = √((R ^ 2 / (‖x‖ * ‖y‖)) ^ 2 * ‖x - y‖ ^ 2) :=
congr_arg sqrt <| by
field_simp [sq, norm_sub_mul_self_real, norm_smul, real_inner_smul_left, inner_smul_right,
Real.norm_of_nonneg (mul_self_nonneg _)]
ring
_ = R ^ 2 / (‖x‖ * ‖y‖) * dist x y := by
rw [sqrt_mul, sqrt_sq, sqrt_sq, dist_eq_norm] <;> positivity
/-- The inner product of a nonzero vector with a nonzero multiple of
itself, divided by the product of their norms, has absolute value
1. -/
theorem norm_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul {x : E} {r : 𝕜} (hx : x ≠ 0)
(hr : r ≠ 0) : ‖⟪x, r • x⟫‖ / (‖x‖ * ‖r • x‖) = 1 := by
have hx' : ‖x‖ ≠ 0 := by simp [hx]
have hr' : ‖r‖ ≠ 0 := by simp [hr]
rw [inner_smul_right, norm_mul, ← inner_self_re_eq_norm, inner_self_eq_norm_mul_norm, norm_smul]
rw [← mul_assoc, ← div_div, mul_div_cancel_right₀ _ hx', ← div_div, mul_comm,
mul_div_cancel_right₀ _ hr', div_self hx']
/-- The inner product of a nonzero vector with a nonzero multiple of
itself, divided by the product of their norms, has absolute value
1. -/
theorem abs_real_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul {x : F} {r : ℝ}
(hx : x ≠ 0) (hr : r ≠ 0) : |⟪x, r • x⟫_ℝ| / (‖x‖ * ‖r • x‖) = 1 :=
norm_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul hx hr
/-- The inner product of a nonzero vector with a positive multiple of
itself, divided by the product of their norms, has value 1. -/
theorem real_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_pos_mul {x : F} {r : ℝ} (hx : x ≠ 0)
(hr : 0 < r) : ⟪x, r • x⟫_ℝ / (‖x‖ * ‖r • x‖) = 1 := by
rw [real_inner_smul_self_right, norm_smul, Real.norm_eq_abs, ← mul_assoc ‖x‖, mul_comm _ |r|,
mul_assoc, abs_of_nonneg hr.le, div_self]
exact mul_ne_zero hr.ne' (mul_self_ne_zero.2 (norm_ne_zero_iff.2 hx))
/-- The inner product of a nonzero vector with a negative multiple of
itself, divided by the product of their norms, has value -1. -/
theorem real_inner_div_norm_mul_norm_eq_neg_one_of_ne_zero_of_neg_mul {x : F} {r : ℝ} (hx : x ≠ 0)
(hr : r < 0) : ⟪x, r • x⟫_ℝ / (‖x‖ * ‖r • x‖) = -1 := by
rw [real_inner_smul_self_right, norm_smul, Real.norm_eq_abs, ← mul_assoc ‖x‖, mul_comm _ |r|,
mul_assoc, abs_of_neg hr, neg_mul, div_neg_eq_neg_div, div_self]
exact mul_ne_zero hr.ne (mul_self_ne_zero.2 (norm_ne_zero_iff.2 hx))
theorem norm_inner_eq_norm_tfae (x y : E) :
List.TFAE [‖⟪x, y⟫‖ = ‖x‖ * ‖y‖,
x = 0 ∨ y = (⟪x, y⟫ / ⟪x, x⟫) • x,
x = 0 ∨ ∃ r : 𝕜, y = r • x,
x = 0 ∨ y ∈ 𝕜 ∙ x] := by
tfae_have 1 → 2 := by
refine fun h => or_iff_not_imp_left.2 fun hx₀ => ?_
have : ‖x‖ ^ 2 ≠ 0 := pow_ne_zero _ (norm_ne_zero_iff.2 hx₀)
rw [← sq_eq_sq₀, mul_pow, ← mul_right_inj' this, eq_comm, ← sub_eq_zero, ← mul_sub] at h <;>
try positivity
simp only [@norm_sq_eq_re_inner 𝕜] at h
letI : InnerProductSpace.Core 𝕜 E := InnerProductSpace.toCore
erw [← InnerProductSpace.Core.cauchy_schwarz_aux (𝕜 := 𝕜) (F := E)] at h
rw [InnerProductSpace.Core.normSq_eq_zero, sub_eq_zero] at h
rw [div_eq_inv_mul, mul_smul, h, inv_smul_smul₀]
rwa [inner_self_ne_zero]
tfae_have 2 → 3 := fun h => h.imp_right fun h' => ⟨_, h'⟩
tfae_have 3 → 1 := by
rintro (rfl | ⟨r, rfl⟩) <;>
simp [inner_smul_right, norm_smul, inner_self_eq_norm_sq_to_K, inner_self_eq_norm_mul_norm,
sq, mul_left_comm]
tfae_have 3 ↔ 4 := by simp only [Submodule.mem_span_singleton, eq_comm]
tfae_finish
/-- If the inner product of two vectors is equal to the product of their norms, then the two vectors
are multiples of each other. One form of the equality case for Cauchy-Schwarz.
Compare `inner_eq_norm_mul_iff`, which takes the stronger hypothesis `⟪x, y⟫ = ‖x‖ * ‖y‖`. -/
theorem norm_inner_eq_norm_iff {x y : E} (hx₀ : x ≠ 0) (hy₀ : y ≠ 0) :
‖⟪x, y⟫‖ = ‖x‖ * ‖y‖ ↔ ∃ r : 𝕜, r ≠ 0 ∧ y = r • x :=
calc
‖⟪x, y⟫‖ = ‖x‖ * ‖y‖ ↔ x = 0 ∨ ∃ r : 𝕜, y = r • x :=
(@norm_inner_eq_norm_tfae 𝕜 _ _ _ _ x y).out 0 2
_ ↔ ∃ r : 𝕜, y = r • x := or_iff_right hx₀
_ ↔ ∃ r : 𝕜, r ≠ 0 ∧ y = r • x :=
⟨fun ⟨r, h⟩ => ⟨r, fun hr₀ => hy₀ <| h.symm ▸ smul_eq_zero.2 <| Or.inl hr₀, h⟩,
fun ⟨r, _hr₀, h⟩ => ⟨r, h⟩⟩
/-- The inner product of two vectors, divided by the product of their
norms, has absolute value 1 if and only if they are nonzero and one is
a multiple of the other. One form of equality case for Cauchy-Schwarz. -/
theorem norm_inner_div_norm_mul_norm_eq_one_iff (x y : E) :
‖⟪x, y⟫ / (‖x‖ * ‖y‖)‖ = 1 ↔ x ≠ 0 ∧ ∃ r : 𝕜, r ≠ 0 ∧ y = r • x := by
constructor
· intro h
have hx₀ : x ≠ 0 := fun h₀ => by simp [h₀] at h
have hy₀ : y ≠ 0 := fun h₀ => by simp [h₀] at h
refine ⟨hx₀, (norm_inner_eq_norm_iff hx₀ hy₀).1 <| eq_of_div_eq_one ?_⟩
simpa using h
· rintro ⟨hx, ⟨r, ⟨hr, rfl⟩⟩⟩
simp only [norm_div, norm_mul, norm_ofReal, abs_norm]
exact norm_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul hx hr
/-- The inner product of two vectors, divided by the product of their
norms, has absolute value 1 if and only if they are nonzero and one is
a multiple of the other. One form of equality case for Cauchy-Schwarz. -/
theorem abs_real_inner_div_norm_mul_norm_eq_one_iff (x y : F) :
|⟪x, y⟫_ℝ / (‖x‖ * ‖y‖)| = 1 ↔ x ≠ 0 ∧ ∃ r : ℝ, r ≠ 0 ∧ y = r • x :=
@norm_inner_div_norm_mul_norm_eq_one_iff ℝ F _ _ _ x y
theorem inner_eq_norm_mul_iff_div {x y : E} (h₀ : x ≠ 0) :
⟪x, y⟫ = (‖x‖ : 𝕜) * ‖y‖ ↔ (‖y‖ / ‖x‖ : 𝕜) • x = y := by
have h₀' := h₀
rw [← norm_ne_zero_iff, Ne, ← @ofReal_eq_zero 𝕜] at h₀'
constructor <;> intro h
· have : x = 0 ∨ y = (⟪x, y⟫ / ⟪x, x⟫ : 𝕜) • x :=
((@norm_inner_eq_norm_tfae 𝕜 _ _ _ _ x y).out 0 1).1 (by simp [h])
rw [this.resolve_left h₀, h]
simp [norm_smul, inner_self_ofReal_norm, mul_div_cancel_right₀ _ h₀']
· conv_lhs => rw [← h, inner_smul_right, inner_self_eq_norm_sq_to_K]
field_simp [sq, mul_left_comm]
/-- If the inner product of two vectors is equal to the product of their norms (i.e.,
`⟪x, y⟫ = ‖x‖ * ‖y‖`), then the two vectors are nonnegative real multiples of each other. One form
of the equality case for Cauchy-Schwarz.
Compare `norm_inner_eq_norm_iff`, which takes the weaker hypothesis `abs ⟪x, y⟫ = ‖x‖ * ‖y‖`. -/
theorem inner_eq_norm_mul_iff {x y : E} :
⟪x, y⟫ = (‖x‖ : 𝕜) * ‖y‖ ↔ (‖y‖ : 𝕜) • x = (‖x‖ : 𝕜) • y := by
rcases eq_or_ne x 0 with (rfl | h₀)
· simp
· rw [inner_eq_norm_mul_iff_div h₀, div_eq_inv_mul, mul_smul, inv_smul_eq_iff₀]
rwa [Ne, ofReal_eq_zero, norm_eq_zero]
/-- If the inner product of two vectors is equal to the product of their norms (i.e.,
`⟪x, y⟫ = ‖x‖ * ‖y‖`), then the two vectors are nonnegative real multiples of each other. One form
of the equality case for Cauchy-Schwarz.
Compare `norm_inner_eq_norm_iff`, which takes the weaker hypothesis `abs ⟪x, y⟫ = ‖x‖ * ‖y‖`. -/
theorem inner_eq_norm_mul_iff_real {x y : F} : ⟪x, y⟫_ℝ = ‖x‖ * ‖y‖ ↔ ‖y‖ • x = ‖x‖ • y :=
inner_eq_norm_mul_iff
/-- The inner product of two vectors, divided by the product of their
norms, has value 1 if and only if they are nonzero and one is
a positive multiple of the other. -/
theorem real_inner_div_norm_mul_norm_eq_one_iff (x y : F) :
⟪x, y⟫_ℝ / (‖x‖ * ‖y‖) = 1 ↔ x ≠ 0 ∧ ∃ r : ℝ, 0 < r ∧ y = r • x := by
constructor
· intro h
have hx₀ : x ≠ 0 := fun h₀ => by simp [h₀] at h
have hy₀ : y ≠ 0 := fun h₀ => by simp [h₀] at h
refine ⟨hx₀, ‖y‖ / ‖x‖, div_pos (norm_pos_iff.2 hy₀) (norm_pos_iff.2 hx₀), ?_⟩
exact ((inner_eq_norm_mul_iff_div hx₀).1 (eq_of_div_eq_one h)).symm
· rintro ⟨hx, ⟨r, ⟨hr, rfl⟩⟩⟩
exact real_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_pos_mul hx hr
/-- The inner product of two vectors, divided by the product of their
norms, has value -1 if and only if they are nonzero and one is
a negative multiple of the other. -/
theorem real_inner_div_norm_mul_norm_eq_neg_one_iff (x y : F) :
⟪x, y⟫_ℝ / (‖x‖ * ‖y‖) = -1 ↔ x ≠ 0 ∧ ∃ r : ℝ, r < 0 ∧ y = r • x := by
rw [← neg_eq_iff_eq_neg, ← neg_div, ← inner_neg_right, ← norm_neg y,
real_inner_div_norm_mul_norm_eq_one_iff, (@neg_surjective ℝ _).exists]
refine Iff.rfl.and (exists_congr fun r => ?_)
rw [neg_pos, neg_smul, neg_inj]
/-- If the inner product of two unit vectors is `1`, then the two vectors are equal. One form of
the equality case for Cauchy-Schwarz. -/
theorem inner_eq_one_iff_of_norm_one {x y : E} (hx : ‖x‖ = 1) (hy : ‖y‖ = 1) :
⟪x, y⟫ = 1 ↔ x = y := by
convert inner_eq_norm_mul_iff (𝕜 := 𝕜) (E := E) using 2 <;> simp [hx, hy]
theorem inner_lt_norm_mul_iff_real {x y : F} : ⟪x, y⟫_ℝ < ‖x‖ * ‖y‖ ↔ ‖y‖ • x ≠ ‖x‖ • y :=
calc
⟪x, y⟫_ℝ < ‖x‖ * ‖y‖ ↔ ⟪x, y⟫_ℝ ≠ ‖x‖ * ‖y‖ :=
⟨ne_of_lt, lt_of_le_of_ne (real_inner_le_norm _ _)⟩
_ ↔ ‖y‖ • x ≠ ‖x‖ • y := not_congr inner_eq_norm_mul_iff_real
/-- If the inner product of two unit vectors is strictly less than `1`, then the two vectors are
distinct. One form of the equality case for Cauchy-Schwarz. -/
theorem inner_lt_one_iff_real_of_norm_one {x y : F} (hx : ‖x‖ = 1) (hy : ‖y‖ = 1) :
⟪x, y⟫_ℝ < 1 ↔ x ≠ y := by convert inner_lt_norm_mul_iff_real (F := F) <;> simp [hx, hy]
/-- The sphere of radius `r = ‖y‖` is tangent to the plane `⟪x, y⟫ = ‖y‖ ^ 2` at `x = y`. -/
theorem eq_of_norm_le_re_inner_eq_norm_sq {x y : E} (hle : ‖x‖ ≤ ‖y‖) (h : re ⟪x, y⟫ = ‖y‖ ^ 2) :
x = y := by
suffices H : re ⟪x - y, x - y⟫ ≤ 0 by rwa [re_inner_self_nonpos, sub_eq_zero] at H
have H₁ : ‖x‖ ^ 2 ≤ ‖y‖ ^ 2 := by gcongr
have H₂ : re ⟪y, x⟫ = ‖y‖ ^ 2 := by rwa [← inner_conj_symm, conj_re]
simpa [inner_sub_left, inner_sub_right, ← norm_sq_eq_re_inner, h, H₂] using H₁
end Norm
section RCLike
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-- A field `𝕜` satisfying `RCLike` is itself a `𝕜`-inner product space. -/
instance RCLike.innerProductSpace : InnerProductSpace 𝕜 𝕜 where
inner x y := y * conj x
norm_sq_eq_re_inner x := by simp only [inner, mul_conj, ← ofReal_pow, ofReal_re]
conj_inner_symm x y := by simp only [mul_comm, map_mul, starRingEnd_self_apply]
add_left x y z := by simp only [mul_add, map_add]
smul_left x y z := by simp only [mul_comm (conj z), mul_assoc, smul_eq_mul, map_mul]
@[simp]
theorem RCLike.inner_apply (x y : 𝕜) : ⟪x, y⟫ = y * conj x :=
rfl
/-- A version of `RCLike.inner_apply` that swaps the order of multiplication. -/
theorem RCLike.inner_apply' (x y : 𝕜) : ⟪x, y⟫ = conj x * y := mul_comm _ _
end RCLike
section RCLikeToReal
open scoped InnerProductSpace
variable {G : Type*}
variable (𝕜 E)
variable [SeminormedAddCommGroup E] [InnerProductSpace 𝕜 E]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-- A general inner product implies a real inner product. This is not registered as an instance
| since `𝕜` does not appear in the return type `Inner ℝ E`. -/
def Inner.rclikeToReal : Inner ℝ E where inner x y := re ⟪x, y⟫
/-- A general inner product space structure implies a real inner product structure.
| Mathlib/Analysis/InnerProductSpace/Basic.lean | 836 | 840 |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Abhimanyu Pallavi Sudhir, Jean Lo, Calle Sönne, Benjamin Davidson
-/
import Mathlib.Analysis.SpecialFunctions.Trigonometric.Angle
import Mathlib.Analysis.SpecialFunctions.Trigonometric.Inverse
/-!
# The argument of a complex number.
We define `arg : ℂ → ℝ`, returning a real number in the range (-π, π],
such that for `x ≠ 0`, `sin (arg x) = x.im / x.abs` and `cos (arg x) = x.re / x.abs`,
while `arg 0` defaults to `0`
-/
open Filter Metric Set
open scoped ComplexConjugate Real Topology
namespace Complex
variable {a x z : ℂ}
/-- `arg` returns values in the range (-π, π], such that for `x ≠ 0`,
`sin (arg x) = x.im / x.abs` and `cos (arg x) = x.re / x.abs`,
`arg 0` defaults to `0` -/
noncomputable def arg (x : ℂ) : ℝ :=
if 0 ≤ x.re then Real.arcsin (x.im / ‖x‖)
else if 0 ≤ x.im then Real.arcsin ((-x).im / ‖x‖) + π else Real.arcsin ((-x).im / ‖x‖) - π
theorem sin_arg (x : ℂ) : Real.sin (arg x) = x.im / ‖x‖ := by
unfold arg; split_ifs <;>
simp [sub_eq_add_neg, arg, Real.sin_arcsin (abs_le.1 (abs_im_div_norm_le_one x)).1
(abs_le.1 (abs_im_div_norm_le_one x)).2, Real.sin_add, neg_div, Real.arcsin_neg, Real.sin_neg]
theorem cos_arg {x : ℂ} (hx : x ≠ 0) : Real.cos (arg x) = x.re / ‖x‖ := by
rw [arg]
split_ifs with h₁ h₂
· rw [Real.cos_arcsin]
field_simp [Real.sqrt_sq, (norm_pos_iff.mpr hx).le, *]
· rw [Real.cos_add_pi, Real.cos_arcsin]
field_simp [Real.sqrt_div (sq_nonneg _), Real.sqrt_sq_eq_abs,
_root_.abs_of_neg (not_le.1 h₁), *]
· rw [Real.cos_sub_pi, Real.cos_arcsin]
field_simp [Real.sqrt_div (sq_nonneg _), Real.sqrt_sq_eq_abs,
_root_.abs_of_neg (not_le.1 h₁), *]
@[simp]
theorem norm_mul_exp_arg_mul_I (x : ℂ) : ‖x‖ * exp (arg x * I) = x := by
rcases eq_or_ne x 0 with (rfl | hx)
· simp
· have : ‖x‖ ≠ 0 := norm_ne_zero_iff.mpr hx
apply Complex.ext <;> field_simp [sin_arg, cos_arg hx, this, mul_comm ‖x‖]
@[simp]
theorem norm_mul_cos_add_sin_mul_I (x : ℂ) : (‖x‖ * (cos (arg x) + sin (arg x) * I) : ℂ) = x := by
rw [← exp_mul_I, norm_mul_exp_arg_mul_I]
@[simp]
lemma norm_mul_cos_arg (x : ℂ) : ‖x‖ * Real.cos (arg x) = x.re := by
simpa [-norm_mul_cos_add_sin_mul_I] using congr_arg re (norm_mul_cos_add_sin_mul_I x)
@[simp]
lemma norm_mul_sin_arg (x : ℂ) : ‖x‖ * Real.sin (arg x) = x.im := by
simpa [-norm_mul_cos_add_sin_mul_I] using congr_arg im (norm_mul_cos_add_sin_mul_I x)
theorem norm_eq_one_iff (z : ℂ) : ‖z‖ = 1 ↔ ∃ θ : ℝ, exp (θ * I) = z := by
refine ⟨fun hz => ⟨arg z, ?_⟩, ?_⟩
· calc
exp (arg z * I) = ‖z‖ * exp (arg z * I) := by rw [hz, ofReal_one, one_mul]
_ = z :=norm_mul_exp_arg_mul_I z
· rintro ⟨θ, rfl⟩
exact Complex.norm_exp_ofReal_mul_I θ
@[deprecated (since := "2025-02-16")] alias abs_mul_exp_arg_mul_I := norm_mul_exp_arg_mul_I
@[deprecated (since := "2025-02-16")] alias abs_mul_cos_add_sin_mul_I := norm_mul_cos_add_sin_mul_I
| @[deprecated (since := "2025-02-16")] alias abs_mul_cos_arg := norm_mul_cos_arg
@[deprecated (since := "2025-02-16")] alias abs_mul_sin_arg := norm_mul_sin_arg
@[deprecated (since := "2025-02-16")] alias abs_eq_one_iff := norm_eq_one_iff
@[simp]
theorem range_exp_mul_I : (Set.range fun x : ℝ => exp (x * I)) = Metric.sphere 0 1 := by
ext x
simp only [mem_sphere_zero_iff_norm, norm_eq_one_iff, Set.mem_range]
| Mathlib/Analysis/SpecialFunctions/Complex/Arg.lean | 76 | 83 |
/-
Copyright (c) 2021 Aaron Anderson, Jesse Michael Han, Floris van Doorn. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Aaron Anderson, Jesse Michael Han, Floris van Doorn
-/
import Mathlib.Data.Finset.Basic
import Mathlib.ModelTheory.Syntax
import Mathlib.Data.List.ProdSigma
/-!
# Basics on First-Order Semantics
This file defines the interpretations of first-order terms, formulas, sentences, and theories
in a style inspired by the [Flypitch project](https://flypitch.github.io/).
## Main Definitions
- `FirstOrder.Language.Term.realize` is defined so that `t.realize v` is the term `t` evaluated at
variables `v`.
- `FirstOrder.Language.BoundedFormula.Realize` is defined so that `φ.Realize v xs` is the bounded
formula `φ` evaluated at tuples of variables `v` and `xs`.
- `FirstOrder.Language.Formula.Realize` is defined so that `φ.Realize v` is the formula `φ`
evaluated at variables `v`.
- `FirstOrder.Language.Sentence.Realize` is defined so that `φ.Realize M` is the sentence `φ`
evaluated in the structure `M`. Also denoted `M ⊨ φ`.
- `FirstOrder.Language.Theory.Model` is defined so that `T.Model M` is true if and only if every
sentence of `T` is realized in `M`. Also denoted `T ⊨ φ`.
## Main Results
- Several results in this file show that syntactic constructions such as `relabel`, `castLE`,
`liftAt`, `subst`, and the actions of language maps commute with realization of terms, formulas,
sentences, and theories.
## Implementation Notes
- Formulas use a modified version of de Bruijn variables. Specifically, a `L.BoundedFormula α n`
is a formula with some variables indexed by a type `α`, which cannot be quantified over, and some
indexed by `Fin n`, which can. For any `φ : L.BoundedFormula α (n + 1)`, we define the formula
`∀' φ : L.BoundedFormula α n` by universally quantifying over the variable indexed by
`n : Fin (n + 1)`.
## References
For the Flypitch project:
- [J. Han, F. van Doorn, *A formal proof of the independence of the continuum hypothesis*]
[flypitch_cpp]
- [J. Han, F. van Doorn, *A formalization of forcing and the unprovability of
the continuum hypothesis*][flypitch_itp]
-/
universe u v w u' v'
namespace FirstOrder
namespace Language
variable {L : Language.{u, v}} {L' : Language}
variable {M : Type w} {N P : Type*} [L.Structure M] [L.Structure N] [L.Structure P]
variable {α : Type u'} {β : Type v'} {γ : Type*}
open FirstOrder Cardinal
open Structure Cardinal Fin
namespace Term
/-- A term `t` with variables indexed by `α` can be evaluated by giving a value to each variable. -/
def realize (v : α → M) : ∀ _t : L.Term α, M
| var k => v k
| func f ts => funMap f fun i => (ts i).realize v
@[simp]
theorem realize_var (v : α → M) (k) : realize v (var k : L.Term α) = v k := rfl
@[simp]
theorem realize_func (v : α → M) {n} (f : L.Functions n) (ts) :
realize v (func f ts : L.Term α) = funMap f fun i => (ts i).realize v := rfl
@[simp]
theorem realize_relabel {t : L.Term α} {g : α → β} {v : β → M} :
(t.relabel g).realize v = t.realize (v ∘ g) := by
induction t with
| var => rfl
| func f ts ih => simp [ih]
@[simp]
theorem realize_liftAt {n n' m : ℕ} {t : L.Term (α ⊕ (Fin n))} {v : α ⊕ (Fin (n + n')) → M} :
(t.liftAt n' m).realize v =
t.realize (v ∘ Sum.map id fun i : Fin _ =>
if ↑i < m then Fin.castAdd n' i else Fin.addNat i n') :=
realize_relabel
@[simp]
theorem realize_constants {c : L.Constants} {v : α → M} : c.term.realize v = c :=
funMap_eq_coe_constants
@[simp]
theorem realize_functions_apply₁ {f : L.Functions 1} {t : L.Term α} {v : α → M} :
(f.apply₁ t).realize v = funMap f ![t.realize v] := by
rw [Functions.apply₁, Term.realize]
refine congr rfl (funext fun i => ?_)
simp only [Matrix.cons_val_fin_one]
@[simp]
theorem realize_functions_apply₂ {f : L.Functions 2} {t₁ t₂ : L.Term α} {v : α → M} :
(f.apply₂ t₁ t₂).realize v = funMap f ![t₁.realize v, t₂.realize v] := by
rw [Functions.apply₂, Term.realize]
refine congr rfl (funext (Fin.cases ?_ ?_))
· simp only [Matrix.cons_val_zero]
· simp only [Matrix.cons_val_succ, Matrix.cons_val_fin_one, forall_const]
theorem realize_con {A : Set M} {a : A} {v : α → M} : (L.con a).term.realize v = a :=
rfl
@[simp]
theorem realize_subst {t : L.Term α} {tf : α → L.Term β} {v : β → M} :
(t.subst tf).realize v = t.realize fun a => (tf a).realize v := by
induction t with
| var => rfl
| func _ _ ih => simp [ih]
theorem realize_restrictVar [DecidableEq α] {t : L.Term α} {f : t.varFinset → β}
{v : β → M} (v' : α → M) (hv' : ∀ a, v (f a) = v' a) :
(t.restrictVar f).realize v = t.realize v' := by
induction t with
| var => simp [restrictVar, hv']
| func _ _ ih =>
exact congr rfl (funext fun i => ih i ((by simp [Function.comp_apply, hv'])))
/-- A special case of `realize_restrictVar`, included because we can add the `simp` attribute
to it -/
@[simp]
theorem realize_restrictVar' [DecidableEq α] {t : L.Term α} {s : Set α} (h : ↑t.varFinset ⊆ s)
{v : α → M} : (t.restrictVar (Set.inclusion h)).realize (v ∘ (↑)) = t.realize v :=
realize_restrictVar _ (by simp)
theorem realize_restrictVarLeft [DecidableEq α] {γ : Type*} {t : L.Term (α ⊕ γ)}
{f : t.varFinsetLeft → β}
{xs : β ⊕ γ → M} (xs' : α → M) (hxs' : ∀ a, xs (Sum.inl (f a)) = xs' a) :
(t.restrictVarLeft f).realize xs = t.realize (Sum.elim xs' (xs ∘ Sum.inr)) := by
induction t with
| var a => cases a <;> simp [restrictVarLeft, hxs']
| func _ _ ih =>
exact congr rfl (funext fun i => ih i (by simp [hxs']))
/-- A special case of `realize_restrictVarLeft`, included because we can add the `simp` attribute
to it -/
@[simp]
theorem realize_restrictVarLeft' [DecidableEq α] {γ : Type*} {t : L.Term (α ⊕ γ)} {s : Set α}
(h : ↑t.varFinsetLeft ⊆ s) {v : α → M} {xs : γ → M} :
(t.restrictVarLeft (Set.inclusion h)).realize (Sum.elim (v ∘ (↑)) xs) =
t.realize (Sum.elim v xs) :=
realize_restrictVarLeft _ (by simp)
@[simp]
theorem realize_constantsToVars [L[[α]].Structure M] [(lhomWithConstants L α).IsExpansionOn M]
{t : L[[α]].Term β} {v : β → M} :
t.constantsToVars.realize (Sum.elim (fun a => ↑(L.con a)) v) = t.realize v := by
induction t with
| var => simp
| @func n f ts ih =>
cases n
· cases f
· simp only [realize, ih, constantsOn, constantsOnFunc, constantsToVars]
-- Porting note: below lemma does not work with simp for some reason
rw [withConstants_funMap_sumInl]
· simp only [realize, constantsToVars, Sum.elim_inl, funMap_eq_coe_constants]
rfl
· obtain - | f := f
· simp only [realize, ih, constantsOn, constantsOnFunc, constantsToVars]
-- Porting note: below lemma does not work with simp for some reason
rw [withConstants_funMap_sumInl]
· exact isEmptyElim f
@[simp]
theorem realize_varsToConstants [L[[α]].Structure M] [(lhomWithConstants L α).IsExpansionOn M]
{t : L.Term (α ⊕ β)} {v : β → M} :
t.varsToConstants.realize v = t.realize (Sum.elim (fun a => ↑(L.con a)) v) := by
induction t with
| var ab => rcases ab with a | b <;> simp [Language.con]
| func f ts ih =>
simp only [realize, constantsOn, constantsOnFunc, ih, varsToConstants]
-- Porting note: below lemma does not work with simp for some reason
rw [withConstants_funMap_sumInl]
theorem realize_constantsVarsEquivLeft [L[[α]].Structure M]
[(lhomWithConstants L α).IsExpansionOn M] {n} {t : L[[α]].Term (β ⊕ (Fin n))} {v : β → M}
{xs : Fin n → M} :
(constantsVarsEquivLeft t).realize (Sum.elim (Sum.elim (fun a => ↑(L.con a)) v) xs) =
t.realize (Sum.elim v xs) := by
simp only [constantsVarsEquivLeft, realize_relabel, Equiv.coe_trans, Function.comp_apply,
constantsVarsEquiv_apply, relabelEquiv_symm_apply]
refine _root_.trans ?_ realize_constantsToVars
rcongr x
rcases x with (a | (b | i)) <;> simp
end Term
namespace LHom
@[simp]
theorem realize_onTerm [L'.Structure M] (φ : L →ᴸ L') [φ.IsExpansionOn M] (t : L.Term α)
(v : α → M) : (φ.onTerm t).realize v = t.realize v := by
induction t with
| var => rfl
| func f ts ih => simp only [Term.realize, LHom.onTerm, LHom.map_onFunction, ih]
end LHom
@[simp]
theorem HomClass.realize_term {F : Type*} [FunLike F M N] [HomClass L F M N]
(g : F) {t : L.Term α} {v : α → M} :
t.realize (g ∘ v) = g (t.realize v) := by
induction t
· rfl
· rw [Term.realize, Term.realize, HomClass.map_fun]
refine congr rfl ?_
ext x
simp [*]
variable {n : ℕ}
namespace BoundedFormula
open Term
/-- A bounded formula can be evaluated as true or false by giving values to each free variable. -/
def Realize : ∀ {l} (_f : L.BoundedFormula α l) (_v : α → M) (_xs : Fin l → M), Prop
| _, falsum, _v, _xs => False
| _, equal t₁ t₂, v, xs => t₁.realize (Sum.elim v xs) = t₂.realize (Sum.elim v xs)
| _, rel R ts, v, xs => RelMap R fun i => (ts i).realize (Sum.elim v xs)
| _, imp f₁ f₂, v, xs => Realize f₁ v xs → Realize f₂ v xs
| _, all f, v, xs => ∀ x : M, Realize f v (snoc xs x)
variable {l : ℕ} {φ ψ : L.BoundedFormula α l} {θ : L.BoundedFormula α l.succ}
variable {v : α → M} {xs : Fin l → M}
@[simp]
theorem realize_bot : (⊥ : L.BoundedFormula α l).Realize v xs ↔ False :=
Iff.rfl
@[simp]
theorem realize_not : φ.not.Realize v xs ↔ ¬φ.Realize v xs :=
Iff.rfl
@[simp]
theorem realize_bdEqual (t₁ t₂ : L.Term (α ⊕ (Fin l))) :
(t₁.bdEqual t₂).Realize v xs ↔ t₁.realize (Sum.elim v xs) = t₂.realize (Sum.elim v xs) :=
Iff.rfl
@[simp]
theorem realize_top : (⊤ : L.BoundedFormula α l).Realize v xs ↔ True := by simp [Top.top]
@[simp]
theorem realize_inf : (φ ⊓ ψ).Realize v xs ↔ φ.Realize v xs ∧ ψ.Realize v xs := by
simp [Inf.inf, Realize]
@[simp]
theorem realize_foldr_inf (l : List (L.BoundedFormula α n)) (v : α → M) (xs : Fin n → M) :
(l.foldr (· ⊓ ·) ⊤).Realize v xs ↔ ∀ φ ∈ l, BoundedFormula.Realize φ v xs := by
induction' l with φ l ih
· simp
· simp [ih]
@[simp]
theorem realize_imp : (φ.imp ψ).Realize v xs ↔ φ.Realize v xs → ψ.Realize v xs := by
simp only [Realize]
@[simp]
theorem realize_rel {k : ℕ} {R : L.Relations k} {ts : Fin k → L.Term _} :
(R.boundedFormula ts).Realize v xs ↔ RelMap R fun i => (ts i).realize (Sum.elim v xs) :=
Iff.rfl
@[simp]
theorem realize_rel₁ {R : L.Relations 1} {t : L.Term _} :
(R.boundedFormula₁ t).Realize v xs ↔ RelMap R ![t.realize (Sum.elim v xs)] := by
rw [Relations.boundedFormula₁, realize_rel, iff_eq_eq]
refine congr rfl (funext fun _ => ?_)
simp only [Matrix.cons_val_fin_one]
@[simp]
theorem realize_rel₂ {R : L.Relations 2} {t₁ t₂ : L.Term _} :
(R.boundedFormula₂ t₁ t₂).Realize v xs ↔
RelMap R ![t₁.realize (Sum.elim v xs), t₂.realize (Sum.elim v xs)] := by
rw [Relations.boundedFormula₂, realize_rel, iff_eq_eq]
refine congr rfl (funext (Fin.cases ?_ ?_))
· simp only [Matrix.cons_val_zero]
· simp only [Matrix.cons_val_succ, Matrix.cons_val_fin_one, forall_const]
@[simp]
theorem realize_sup : (φ ⊔ ψ).Realize v xs ↔ φ.Realize v xs ∨ ψ.Realize v xs := by
simp only [realize, max, realize_not, eq_iff_iff]
tauto
@[simp]
theorem realize_foldr_sup (l : List (L.BoundedFormula α n)) (v : α → M) (xs : Fin n → M) :
(l.foldr (· ⊔ ·) ⊥).Realize v xs ↔ ∃ φ ∈ l, BoundedFormula.Realize φ v xs := by
induction' l with φ l ih
· simp
· simp_rw [List.foldr_cons, realize_sup, ih, List.mem_cons, or_and_right, exists_or,
exists_eq_left]
@[simp]
theorem realize_all : (all θ).Realize v xs ↔ ∀ a : M, θ.Realize v (Fin.snoc xs a) :=
Iff.rfl
@[simp]
theorem realize_ex : θ.ex.Realize v xs ↔ ∃ a : M, θ.Realize v (Fin.snoc xs a) := by
rw [BoundedFormula.ex, realize_not, realize_all, not_forall]
simp_rw [realize_not, Classical.not_not]
@[simp]
theorem realize_iff : (φ.iff ψ).Realize v xs ↔ (φ.Realize v xs ↔ ψ.Realize v xs) := by
simp only [BoundedFormula.iff, realize_inf, realize_imp, and_imp, ← iff_def]
theorem realize_castLE_of_eq {m n : ℕ} (h : m = n) {h' : m ≤ n} {φ : L.BoundedFormula α m}
{v : α → M} {xs : Fin n → M} : (φ.castLE h').Realize v xs ↔ φ.Realize v (xs ∘ Fin.cast h) := by
subst h
simp only [castLE_rfl, cast_refl, OrderIso.coe_refl, Function.comp_id]
theorem realize_mapTermRel_id [L'.Structure M]
{ft : ∀ n, L.Term (α ⊕ (Fin n)) → L'.Term (β ⊕ (Fin n))}
{fr : ∀ n, L.Relations n → L'.Relations n} {n} {φ : L.BoundedFormula α n} {v : α → M}
{v' : β → M} {xs : Fin n → M}
(h1 :
∀ (n) (t : L.Term (α ⊕ (Fin n))) (xs : Fin n → M),
(ft n t).realize (Sum.elim v' xs) = t.realize (Sum.elim v xs))
(h2 : ∀ (n) (R : L.Relations n) (x : Fin n → M), RelMap (fr n R) x = RelMap R x) :
(φ.mapTermRel ft fr fun _ => id).Realize v' xs ↔ φ.Realize v xs := by
induction φ with
| falsum => rfl
| equal => simp [mapTermRel, Realize, h1]
| rel => simp [mapTermRel, Realize, h1, h2]
| imp _ _ ih1 ih2 => simp [mapTermRel, Realize, ih1, ih2]
| all _ ih => simp only [mapTermRel, Realize, ih, id]
theorem realize_mapTermRel_add_castLe [L'.Structure M] {k : ℕ}
{ft : ∀ n, L.Term (α ⊕ (Fin n)) → L'.Term (β ⊕ (Fin (k + n)))}
{fr : ∀ n, L.Relations n → L'.Relations n} {n} {φ : L.BoundedFormula α n}
(v : ∀ {n}, (Fin (k + n) → M) → α → M) {v' : β → M} (xs : Fin (k + n) → M)
(h1 :
∀ (n) (t : L.Term (α ⊕ (Fin n))) (xs' : Fin (k + n) → M),
(ft n t).realize (Sum.elim v' xs') = t.realize (Sum.elim (v xs') (xs' ∘ Fin.natAdd _)))
(h2 : ∀ (n) (R : L.Relations n) (x : Fin n → M), RelMap (fr n R) x = RelMap R x)
(hv : ∀ (n) (xs : Fin (k + n) → M) (x : M), @v (n + 1) (snoc xs x : Fin _ → M) = v xs) :
(φ.mapTermRel ft fr fun _ => castLE (add_assoc _ _ _).symm.le).Realize v' xs ↔
φ.Realize (v xs) (xs ∘ Fin.natAdd _) := by
induction φ with
| falsum => rfl
| equal => simp [mapTermRel, Realize, h1]
| rel => simp [mapTermRel, Realize, h1, h2]
| imp _ _ ih1 ih2 => simp [mapTermRel, Realize, ih1, ih2]
| all _ ih => simp [mapTermRel, Realize, ih, hv]
@[simp]
theorem realize_relabel {m n : ℕ} {φ : L.BoundedFormula α n} {g : α → β ⊕ (Fin m)} {v : β → M}
{xs : Fin (m + n) → M} :
(φ.relabel g).Realize v xs ↔
φ.Realize (Sum.elim v (xs ∘ Fin.castAdd n) ∘ g) (xs ∘ Fin.natAdd m) := by
apply realize_mapTermRel_add_castLe <;> simp
theorem realize_liftAt {n n' m : ℕ} {φ : L.BoundedFormula α n} {v : α → M} {xs : Fin (n + n') → M}
(hmn : m + n' ≤ n + 1) :
(φ.liftAt n' m).Realize v xs ↔
φ.Realize v (xs ∘ fun i => if ↑i < m then Fin.castAdd n' i else Fin.addNat i n') := by
rw [liftAt]
induction φ with
| falsum => simp [mapTermRel, Realize]
| equal => simp [mapTermRel, Realize, realize_rel, realize_liftAt, Sum.elim_comp_map]
| rel => simp [mapTermRel, Realize, realize_rel, realize_liftAt, Sum.elim_comp_map]
| imp _ _ ih1 ih2 => simp only [mapTermRel, Realize, ih1 hmn, ih2 hmn]
| @all k _ ih3 =>
have h : k + 1 + n' = k + n' + 1 := by rw [add_assoc, add_comm 1 n', ← add_assoc]
simp only [mapTermRel, Realize, realize_castLE_of_eq h, ih3 (hmn.trans k.succ.le_succ)]
refine forall_congr' fun x => iff_eq_eq.mpr (congr rfl (funext (Fin.lastCases ?_ fun i => ?_)))
· simp only [Function.comp_apply, val_last, snoc_last]
refine (congr rfl (Fin.ext ?_)).trans (snoc_last _ _)
split_ifs <;> dsimp; omega
· simp only [Function.comp_apply, Fin.snoc_castSucc]
refine (congr rfl (Fin.ext ?_)).trans (snoc_castSucc _ _ _)
simp only [coe_castSucc, coe_cast]
split_ifs <;> simp
theorem realize_liftAt_one {n m : ℕ} {φ : L.BoundedFormula α n} {v : α → M} {xs : Fin (n + 1) → M}
(hmn : m ≤ n) :
(φ.liftAt 1 m).Realize v xs ↔
φ.Realize v (xs ∘ fun i => if ↑i < m then castSucc i else i.succ) := by
simp [realize_liftAt (add_le_add_right hmn 1), castSucc]
@[simp]
theorem realize_liftAt_one_self {n : ℕ} {φ : L.BoundedFormula α n} {v : α → M}
{xs : Fin (n + 1) → M} : (φ.liftAt 1 n).Realize v xs ↔ φ.Realize v (xs ∘ castSucc) := by
rw [realize_liftAt_one (refl n), iff_eq_eq]
refine congr rfl (congr rfl (funext fun i => ?_))
rw [if_pos i.is_lt]
@[simp]
theorem realize_subst {φ : L.BoundedFormula α n} {tf : α → L.Term β} {v : β → M} {xs : Fin n → M} :
(φ.subst tf).Realize v xs ↔ φ.Realize (fun a => (tf a).realize v) xs :=
realize_mapTermRel_id
(fun n t x => by
rw [Term.realize_subst]
rcongr a
cases a
· simp only [Sum.elim_inl, Function.comp_apply, Term.realize_relabel, Sum.elim_comp_inl]
· rfl)
(by simp)
theorem realize_restrictFreeVar [DecidableEq α] {n : ℕ} {φ : L.BoundedFormula α n}
{f : φ.freeVarFinset → β} {v : β → M} {xs : Fin n → M}
(v' : α → M) (hv' : ∀ a, v (f a) = v' a) :
(φ.restrictFreeVar f).Realize v xs ↔ φ.Realize v' xs := by
induction φ with
| falsum => rfl
| equal =>
simp only [Realize, restrictFreeVar, freeVarFinset.eq_2]
rw [realize_restrictVarLeft v' (by simp [hv']), realize_restrictVarLeft v' (by simp [hv'])]
simp [Function.comp_apply]
| rel =>
simp only [Realize, freeVarFinset.eq_3, Finset.biUnion_val, restrictFreeVar]
congr!
rw [realize_restrictVarLeft v' (by simp [hv'])]
simp [Function.comp_apply]
| imp _ _ ih1 ih2 =>
simp only [Realize, restrictFreeVar, freeVarFinset.eq_4]
rw [ih1, ih2] <;> simp [hv']
| all _ ih3 =>
simp only [restrictFreeVar, Realize]
refine forall_congr' (fun _ => ?_)
rw [ih3]; simp [hv']
/-- A special case of `realize_restrictFreeVar`, included because we can add the `simp` attribute
to it -/
@[simp]
theorem realize_restrictFreeVar' [DecidableEq α] {n : ℕ} {φ : L.BoundedFormula α n} {s : Set α}
(h : ↑φ.freeVarFinset ⊆ s) {v : α → M} {xs : Fin n → M} :
(φ.restrictFreeVar (Set.inclusion h)).Realize (v ∘ (↑)) xs ↔ φ.Realize v xs :=
realize_restrictFreeVar _ (by simp)
theorem realize_constantsVarsEquiv [L[[α]].Structure M] [(lhomWithConstants L α).IsExpansionOn M]
{n} {φ : L[[α]].BoundedFormula β n} {v : β → M} {xs : Fin n → M} :
(constantsVarsEquiv φ).Realize (Sum.elim (fun a => ↑(L.con a)) v) xs ↔ φ.Realize v xs := by
refine realize_mapTermRel_id (fun n t xs => realize_constantsVarsEquivLeft) fun n R xs => ?_
-- This used to be `rw`, but we need `erw` after https://github.com/leanprover/lean4/pull/2644
erw [← (lhomWithConstants L α).map_onRelation
(Equiv.sumEmpty (L.Relations n) ((constantsOn α).Relations n) R) xs]
| rcongr
obtain - | R := R
· simp
· exact isEmptyElim R
@[simp]
theorem realize_relabelEquiv {g : α ≃ β} {k} {φ : L.BoundedFormula α k} {v : β → M}
{xs : Fin k → M} : (relabelEquiv g φ).Realize v xs ↔ φ.Realize (v ∘ g) xs := by
simp only [relabelEquiv, mapTermRelEquiv_apply, Equiv.coe_refl]
refine realize_mapTermRel_id (fun n t xs => ?_) fun _ _ _ => rfl
| Mathlib/ModelTheory/Semantics.lean | 449 | 458 |
/-
Copyright (c) 2014 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Leonardo de Moura
-/
import Mathlib.Data.Set.Operations
import Mathlib.Order.Basic
import Mathlib.Order.BooleanAlgebra
import Mathlib.Tactic.Tauto
import Mathlib.Tactic.ByContra
import Mathlib.Util.Delaborators
import Mathlib.Tactic.Lift
/-!
# Basic properties of sets
Sets in Lean are homogeneous; all their elements have the same type. Sets whose elements
have type `X` are thus defined as `Set X := X → Prop`. Note that this function need not
be decidable. The definition is in the module `Mathlib.Data.Set.Defs`.
This file provides some basic definitions related to sets and functions not present in the
definitions file, as well as extra lemmas for functions defined in the definitions file and
`Mathlib.Data.Set.Operations` (empty set, univ, union, intersection, insert, singleton,
set-theoretic difference, complement, and powerset).
Note that a set is a term, not a type. There is a coercion from `Set α` to `Type*` sending
`s` to the corresponding subtype `↥s`.
See also the file `SetTheory/ZFC.lean`, which contains an encoding of ZFC set theory in Lean.
## Main definitions
Notation used here:
- `f : α → β` is a function,
- `s : Set α` and `s₁ s₂ : Set α` are subsets of `α`
- `t : Set β` is a subset of `β`.
Definitions in the file:
* `Nonempty s : Prop` : the predicate `s ≠ ∅`. Note that this is the preferred way to express the
fact that `s` has an element (see the Implementation Notes).
* `inclusion s₁ s₂ : ↥s₁ → ↥s₂` : the map `↥s₁ → ↥s₂` induced by an inclusion `s₁ ⊆ s₂`.
## Notation
* `sᶜ` for the complement of `s`
## Implementation notes
* `s.Nonempty` is to be preferred to `s ≠ ∅` or `∃ x, x ∈ s`. It has the advantage that
the `s.Nonempty` dot notation can be used.
* For `s : Set α`, do not use `Subtype s`. Instead use `↥s` or `(s : Type*)` or `s`.
## Tags
set, sets, subset, subsets, union, intersection, insert, singleton, complement, powerset
-/
assert_not_exists RelIso
/-! ### Set coercion to a type -/
open Function
universe u v
namespace Set
variable {α : Type u} {s t : Set α}
instance instBooleanAlgebra : BooleanAlgebra (Set α) :=
{ (inferInstance : BooleanAlgebra (α → Prop)) with
sup := (· ∪ ·),
le := (· ≤ ·),
lt := fun s t => s ⊆ t ∧ ¬t ⊆ s,
inf := (· ∩ ·),
bot := ∅,
compl := (·ᶜ),
top := univ,
sdiff := (· \ ·) }
instance : HasSSubset (Set α) :=
⟨(· < ·)⟩
@[simp]
theorem top_eq_univ : (⊤ : Set α) = univ :=
rfl
@[simp]
theorem bot_eq_empty : (⊥ : Set α) = ∅ :=
rfl
@[simp]
theorem sup_eq_union : ((· ⊔ ·) : Set α → Set α → Set α) = (· ∪ ·) :=
rfl
@[simp]
theorem inf_eq_inter : ((· ⊓ ·) : Set α → Set α → Set α) = (· ∩ ·) :=
rfl
@[simp]
theorem le_eq_subset : ((· ≤ ·) : Set α → Set α → Prop) = (· ⊆ ·) :=
rfl
@[simp]
theorem lt_eq_ssubset : ((· < ·) : Set α → Set α → Prop) = (· ⊂ ·) :=
rfl
theorem le_iff_subset : s ≤ t ↔ s ⊆ t :=
Iff.rfl
theorem lt_iff_ssubset : s < t ↔ s ⊂ t :=
Iff.rfl
alias ⟨_root_.LE.le.subset, _root_.HasSubset.Subset.le⟩ := le_iff_subset
alias ⟨_root_.LT.lt.ssubset, _root_.HasSSubset.SSubset.lt⟩ := lt_iff_ssubset
instance PiSetCoe.canLift (ι : Type u) (α : ι → Type v) [∀ i, Nonempty (α i)] (s : Set ι) :
CanLift (∀ i : s, α i) (∀ i, α i) (fun f i => f i) fun _ => True :=
PiSubtype.canLift ι α s
instance PiSetCoe.canLift' (ι : Type u) (α : Type v) [Nonempty α] (s : Set ι) :
CanLift (s → α) (ι → α) (fun f i => f i) fun _ => True :=
PiSetCoe.canLift ι (fun _ => α) s
end Set
section SetCoe
variable {α : Type u}
instance (s : Set α) : CoeTC s α := ⟨fun x => x.1⟩
theorem Set.coe_eq_subtype (s : Set α) : ↥s = { x // x ∈ s } :=
rfl
@[simp]
theorem Set.coe_setOf (p : α → Prop) : ↥{ x | p x } = { x // p x } :=
rfl
theorem SetCoe.forall {s : Set α} {p : s → Prop} : (∀ x : s, p x) ↔ ∀ (x) (h : x ∈ s), p ⟨x, h⟩ :=
Subtype.forall
theorem SetCoe.exists {s : Set α} {p : s → Prop} :
(∃ x : s, p x) ↔ ∃ (x : _) (h : x ∈ s), p ⟨x, h⟩ :=
Subtype.exists
theorem SetCoe.exists' {s : Set α} {p : ∀ x, x ∈ s → Prop} :
(∃ (x : _) (h : x ∈ s), p x h) ↔ ∃ x : s, p x.1 x.2 :=
(@SetCoe.exists _ _ fun x => p x.1 x.2).symm
theorem SetCoe.forall' {s : Set α} {p : ∀ x, x ∈ s → Prop} :
(∀ (x) (h : x ∈ s), p x h) ↔ ∀ x : s, p x.1 x.2 :=
(@SetCoe.forall _ _ fun x => p x.1 x.2).symm
@[simp]
theorem set_coe_cast :
∀ {s t : Set α} (H' : s = t) (H : ↥s = ↥t) (x : s), cast H x = ⟨x.1, H' ▸ x.2⟩
| _, _, rfl, _, _ => rfl
theorem SetCoe.ext {s : Set α} {a b : s} : (a : α) = b → a = b :=
Subtype.eq
theorem SetCoe.ext_iff {s : Set α} {a b : s} : (↑a : α) = ↑b ↔ a = b :=
Iff.intro SetCoe.ext fun h => h ▸ rfl
end SetCoe
/-- See also `Subtype.prop` -/
theorem Subtype.mem {α : Type*} {s : Set α} (p : s) : (p : α) ∈ s :=
p.prop
/-- Duplicate of `Eq.subset'`, which currently has elaboration problems. -/
theorem Eq.subset {α} {s t : Set α} : s = t → s ⊆ t :=
fun h₁ _ h₂ => by rw [← h₁]; exact h₂
namespace Set
variable {α : Type u} {β : Type v} {a b : α} {s s₁ s₂ t t₁ t₂ u : Set α}
instance : Inhabited (Set α) :=
⟨∅⟩
@[trans]
theorem mem_of_mem_of_subset {x : α} {s t : Set α} (hx : x ∈ s) (h : s ⊆ t) : x ∈ t :=
h hx
theorem forall_in_swap {p : α → β → Prop} : (∀ a ∈ s, ∀ (b), p a b) ↔ ∀ (b), ∀ a ∈ s, p a b := by
tauto
theorem setOf_injective : Function.Injective (@setOf α) := injective_id
theorem setOf_inj {p q : α → Prop} : { x | p x } = { x | q x } ↔ p = q := Iff.rfl
/-! ### Lemmas about `mem` and `setOf` -/
theorem mem_setOf {a : α} {p : α → Prop} : a ∈ { x | p x } ↔ p a :=
Iff.rfl
/-- This lemma is intended for use with `rw` where a membership predicate is needed,
hence the explicit argument and the equality in the reverse direction from normal.
See also `Set.mem_setOf_eq` for the reverse direction applied to an argument. -/
theorem eq_mem_setOf (p : α → Prop) : p = (· ∈ {a | p a}) := rfl
/-- If `h : a ∈ {x | p x}` then `h.out : p x`. These are definitionally equal, but this can
nevertheless be useful for various reasons, e.g. to apply further projection notation or in an
argument to `simp`. -/
theorem _root_.Membership.mem.out {p : α → Prop} {a : α} (h : a ∈ { x | p x }) : p a :=
h
theorem nmem_setOf_iff {a : α} {p : α → Prop} : a ∉ { x | p x } ↔ ¬p a :=
Iff.rfl
@[simp]
theorem setOf_mem_eq {s : Set α} : { x | x ∈ s } = s :=
rfl
theorem setOf_set {s : Set α} : setOf s = s :=
rfl
theorem setOf_app_iff {p : α → Prop} {x : α} : { x | p x } x ↔ p x :=
Iff.rfl
theorem mem_def {a : α} {s : Set α} : a ∈ s ↔ s a :=
Iff.rfl
theorem setOf_bijective : Bijective (setOf : (α → Prop) → Set α) :=
bijective_id
theorem subset_setOf {p : α → Prop} {s : Set α} : s ⊆ setOf p ↔ ∀ x, x ∈ s → p x :=
Iff.rfl
theorem setOf_subset {p : α → Prop} {s : Set α} : setOf p ⊆ s ↔ ∀ x, p x → x ∈ s :=
Iff.rfl
@[simp]
theorem setOf_subset_setOf {p q : α → Prop} : { a | p a } ⊆ { a | q a } ↔ ∀ a, p a → q a :=
Iff.rfl
theorem setOf_and {p q : α → Prop} : { a | p a ∧ q a } = { a | p a } ∩ { a | q a } :=
rfl
theorem setOf_or {p q : α → Prop} : { a | p a ∨ q a } = { a | p a } ∪ { a | q a } :=
rfl
/-! ### Subset and strict subset relations -/
instance : IsRefl (Set α) (· ⊆ ·) :=
show IsRefl (Set α) (· ≤ ·) by infer_instance
instance : IsTrans (Set α) (· ⊆ ·) :=
show IsTrans (Set α) (· ≤ ·) by infer_instance
instance : Trans ((· ⊆ ·) : Set α → Set α → Prop) (· ⊆ ·) (· ⊆ ·) :=
show Trans (· ≤ ·) (· ≤ ·) (· ≤ ·) by infer_instance
instance : IsAntisymm (Set α) (· ⊆ ·) :=
show IsAntisymm (Set α) (· ≤ ·) by infer_instance
instance : IsIrrefl (Set α) (· ⊂ ·) :=
show IsIrrefl (Set α) (· < ·) by infer_instance
instance : IsTrans (Set α) (· ⊂ ·) :=
show IsTrans (Set α) (· < ·) by infer_instance
instance : Trans ((· ⊂ ·) : Set α → Set α → Prop) (· ⊂ ·) (· ⊂ ·) :=
show Trans (· < ·) (· < ·) (· < ·) by infer_instance
instance : Trans ((· ⊂ ·) : Set α → Set α → Prop) (· ⊆ ·) (· ⊂ ·) :=
show Trans (· < ·) (· ≤ ·) (· < ·) by infer_instance
instance : Trans ((· ⊆ ·) : Set α → Set α → Prop) (· ⊂ ·) (· ⊂ ·) :=
show Trans (· ≤ ·) (· < ·) (· < ·) by infer_instance
instance : IsAsymm (Set α) (· ⊂ ·) :=
show IsAsymm (Set α) (· < ·) by infer_instance
instance : IsNonstrictStrictOrder (Set α) (· ⊆ ·) (· ⊂ ·) :=
⟨fun _ _ => Iff.rfl⟩
-- TODO(Jeremy): write a tactic to unfold specific instances of generic notation?
theorem subset_def : (s ⊆ t) = ∀ x, x ∈ s → x ∈ t :=
rfl
theorem ssubset_def : (s ⊂ t) = (s ⊆ t ∧ ¬t ⊆ s) :=
rfl
@[refl]
theorem Subset.refl (a : Set α) : a ⊆ a := fun _ => id
theorem Subset.rfl {s : Set α} : s ⊆ s :=
Subset.refl s
@[trans]
theorem Subset.trans {a b c : Set α} (ab : a ⊆ b) (bc : b ⊆ c) : a ⊆ c := fun _ h => bc <| ab h
@[trans]
theorem mem_of_eq_of_mem {x y : α} {s : Set α} (hx : x = y) (h : y ∈ s) : x ∈ s :=
hx.symm ▸ h
theorem Subset.antisymm {a b : Set α} (h₁ : a ⊆ b) (h₂ : b ⊆ a) : a = b :=
Set.ext fun _ => ⟨@h₁ _, @h₂ _⟩
theorem Subset.antisymm_iff {a b : Set α} : a = b ↔ a ⊆ b ∧ b ⊆ a :=
⟨fun e => ⟨e.subset, e.symm.subset⟩, fun ⟨h₁, h₂⟩ => Subset.antisymm h₁ h₂⟩
-- an alternative name
theorem eq_of_subset_of_subset {a b : Set α} : a ⊆ b → b ⊆ a → a = b :=
Subset.antisymm
theorem mem_of_subset_of_mem {s₁ s₂ : Set α} {a : α} (h : s₁ ⊆ s₂) : a ∈ s₁ → a ∈ s₂ :=
@h _
theorem not_mem_subset (h : s ⊆ t) : a ∉ t → a ∉ s :=
mt <| mem_of_subset_of_mem h
theorem not_subset : ¬s ⊆ t ↔ ∃ a ∈ s, a ∉ t := by
simp only [subset_def, not_forall, exists_prop]
theorem not_top_subset : ¬⊤ ⊆ s ↔ ∃ a, a ∉ s := by
simp [not_subset]
lemma eq_of_forall_subset_iff (h : ∀ u, s ⊆ u ↔ t ⊆ u) : s = t := eq_of_forall_ge_iff h
/-! ### Definition of strict subsets `s ⊂ t` and basic properties. -/
protected theorem eq_or_ssubset_of_subset (h : s ⊆ t) : s = t ∨ s ⊂ t :=
eq_or_lt_of_le h
theorem exists_of_ssubset {s t : Set α} (h : s ⊂ t) : ∃ x ∈ t, x ∉ s :=
not_subset.1 h.2
protected theorem ssubset_iff_subset_ne {s t : Set α} : s ⊂ t ↔ s ⊆ t ∧ s ≠ t :=
@lt_iff_le_and_ne (Set α) _ s t
theorem ssubset_iff_of_subset {s t : Set α} (h : s ⊆ t) : s ⊂ t ↔ ∃ x ∈ t, x ∉ s :=
⟨exists_of_ssubset, fun ⟨_, hxt, hxs⟩ => ⟨h, fun h => hxs <| h hxt⟩⟩
theorem ssubset_iff_exists {s t : Set α} : s ⊂ t ↔ s ⊆ t ∧ ∃ x ∈ t, x ∉ s :=
⟨fun h ↦ ⟨h.le, Set.exists_of_ssubset h⟩, fun ⟨h1, h2⟩ ↦ (Set.ssubset_iff_of_subset h1).mpr h2⟩
protected theorem ssubset_of_ssubset_of_subset {s₁ s₂ s₃ : Set α} (hs₁s₂ : s₁ ⊂ s₂)
(hs₂s₃ : s₂ ⊆ s₃) : s₁ ⊂ s₃ :=
⟨Subset.trans hs₁s₂.1 hs₂s₃, fun hs₃s₁ => hs₁s₂.2 (Subset.trans hs₂s₃ hs₃s₁)⟩
protected theorem ssubset_of_subset_of_ssubset {s₁ s₂ s₃ : Set α} (hs₁s₂ : s₁ ⊆ s₂)
(hs₂s₃ : s₂ ⊂ s₃) : s₁ ⊂ s₃ :=
⟨Subset.trans hs₁s₂ hs₂s₃.1, fun hs₃s₁ => hs₂s₃.2 (Subset.trans hs₃s₁ hs₁s₂)⟩
theorem not_mem_empty (x : α) : ¬x ∈ (∅ : Set α) :=
id
theorem not_not_mem : ¬a ∉ s ↔ a ∈ s :=
not_not
/-! ### Non-empty sets -/
theorem nonempty_coe_sort {s : Set α} : Nonempty ↥s ↔ s.Nonempty :=
nonempty_subtype
alias ⟨_, Nonempty.coe_sort⟩ := nonempty_coe_sort
theorem nonempty_def : s.Nonempty ↔ ∃ x, x ∈ s :=
Iff.rfl
theorem nonempty_of_mem {x} (h : x ∈ s) : s.Nonempty :=
⟨x, h⟩
theorem Nonempty.not_subset_empty : s.Nonempty → ¬s ⊆ ∅
| ⟨_, hx⟩, hs => hs hx
/-- Extract a witness from `s.Nonempty`. This function might be used instead of case analysis
on the argument. Note that it makes a proof depend on the `Classical.choice` axiom. -/
protected noncomputable def Nonempty.some (h : s.Nonempty) : α :=
Classical.choose h
protected theorem Nonempty.some_mem (h : s.Nonempty) : h.some ∈ s :=
Classical.choose_spec h
theorem Nonempty.mono (ht : s ⊆ t) (hs : s.Nonempty) : t.Nonempty :=
hs.imp ht
theorem nonempty_of_not_subset (h : ¬s ⊆ t) : (s \ t).Nonempty :=
let ⟨x, xs, xt⟩ := not_subset.1 h
⟨x, xs, xt⟩
theorem nonempty_of_ssubset (ht : s ⊂ t) : (t \ s).Nonempty :=
nonempty_of_not_subset ht.2
theorem Nonempty.of_diff (h : (s \ t).Nonempty) : s.Nonempty :=
h.imp fun _ => And.left
theorem nonempty_of_ssubset' (ht : s ⊂ t) : t.Nonempty :=
(nonempty_of_ssubset ht).of_diff
theorem Nonempty.inl (hs : s.Nonempty) : (s ∪ t).Nonempty :=
hs.imp fun _ => Or.inl
theorem Nonempty.inr (ht : t.Nonempty) : (s ∪ t).Nonempty :=
ht.imp fun _ => Or.inr
@[simp]
theorem union_nonempty : (s ∪ t).Nonempty ↔ s.Nonempty ∨ t.Nonempty :=
exists_or
theorem Nonempty.left (h : (s ∩ t).Nonempty) : s.Nonempty :=
h.imp fun _ => And.left
theorem Nonempty.right (h : (s ∩ t).Nonempty) : t.Nonempty :=
h.imp fun _ => And.right
theorem inter_nonempty : (s ∩ t).Nonempty ↔ ∃ x, x ∈ s ∧ x ∈ t :=
Iff.rfl
theorem inter_nonempty_iff_exists_left : (s ∩ t).Nonempty ↔ ∃ x ∈ s, x ∈ t := by
simp_rw [inter_nonempty]
theorem inter_nonempty_iff_exists_right : (s ∩ t).Nonempty ↔ ∃ x ∈ t, x ∈ s := by
simp_rw [inter_nonempty, and_comm]
theorem nonempty_iff_univ_nonempty : Nonempty α ↔ (univ : Set α).Nonempty :=
⟨fun ⟨x⟩ => ⟨x, trivial⟩, fun ⟨x, _⟩ => ⟨x⟩⟩
@[simp]
theorem univ_nonempty : ∀ [Nonempty α], (univ : Set α).Nonempty
| ⟨x⟩ => ⟨x, trivial⟩
theorem Nonempty.to_subtype : s.Nonempty → Nonempty (↥s) :=
nonempty_subtype.2
theorem Nonempty.to_type : s.Nonempty → Nonempty α := fun ⟨x, _⟩ => ⟨x⟩
instance univ.nonempty [Nonempty α] : Nonempty (↥(Set.univ : Set α)) :=
Set.univ_nonempty.to_subtype
-- Redeclare for refined keys
-- `Nonempty (@Subtype _ (@Membership.mem _ (Set _) _ (@Top.top (Set _) _)))`
instance instNonemptyTop [Nonempty α] : Nonempty (⊤ : Set α) :=
inferInstanceAs (Nonempty (univ : Set α))
theorem Nonempty.of_subtype [Nonempty (↥s)] : s.Nonempty := nonempty_subtype.mp ‹_›
@[deprecated (since := "2024-11-23")] alias nonempty_of_nonempty_subtype := Nonempty.of_subtype
/-! ### Lemmas about the empty set -/
theorem empty_def : (∅ : Set α) = { _x : α | False } :=
rfl
@[simp]
theorem mem_empty_iff_false (x : α) : x ∈ (∅ : Set α) ↔ False :=
Iff.rfl
@[simp]
theorem setOf_false : { _a : α | False } = ∅ :=
rfl
@[simp] theorem setOf_bot : { _x : α | ⊥ } = ∅ := rfl
@[simp]
theorem empty_subset (s : Set α) : ∅ ⊆ s :=
nofun
@[simp]
theorem subset_empty_iff {s : Set α} : s ⊆ ∅ ↔ s = ∅ :=
(Subset.antisymm_iff.trans <| and_iff_left (empty_subset _)).symm
theorem eq_empty_iff_forall_not_mem {s : Set α} : s = ∅ ↔ ∀ x, x ∉ s :=
subset_empty_iff.symm
theorem eq_empty_of_forall_not_mem (h : ∀ x, x ∉ s) : s = ∅ :=
subset_empty_iff.1 h
theorem eq_empty_of_subset_empty {s : Set α} : s ⊆ ∅ → s = ∅ :=
subset_empty_iff.1
theorem eq_empty_of_isEmpty [IsEmpty α] (s : Set α) : s = ∅ :=
eq_empty_of_subset_empty fun x _ => isEmptyElim x
/-- There is exactly one set of a type that is empty. -/
instance uniqueEmpty [IsEmpty α] : Unique (Set α) where
default := ∅
uniq := eq_empty_of_isEmpty
/-- See also `Set.nonempty_iff_ne_empty`. -/
theorem not_nonempty_iff_eq_empty {s : Set α} : ¬s.Nonempty ↔ s = ∅ := by
simp only [Set.Nonempty, not_exists, eq_empty_iff_forall_not_mem]
/-- See also `Set.not_nonempty_iff_eq_empty`. -/
theorem nonempty_iff_ne_empty : s.Nonempty ↔ s ≠ ∅ :=
not_nonempty_iff_eq_empty.not_right
/-- See also `nonempty_iff_ne_empty'`. -/
theorem not_nonempty_iff_eq_empty' : ¬Nonempty s ↔ s = ∅ := by
rw [nonempty_subtype, not_exists, eq_empty_iff_forall_not_mem]
/-- See also `not_nonempty_iff_eq_empty'`. -/
theorem nonempty_iff_ne_empty' : Nonempty s ↔ s ≠ ∅ :=
not_nonempty_iff_eq_empty'.not_right
alias ⟨Nonempty.ne_empty, _⟩ := nonempty_iff_ne_empty
@[simp]
theorem not_nonempty_empty : ¬(∅ : Set α).Nonempty := fun ⟨_, hx⟩ => hx
@[simp]
theorem isEmpty_coe_sort {s : Set α} : IsEmpty (↥s) ↔ s = ∅ :=
not_iff_not.1 <| by simpa using nonempty_iff_ne_empty
theorem eq_empty_or_nonempty (s : Set α) : s = ∅ ∨ s.Nonempty :=
or_iff_not_imp_left.2 nonempty_iff_ne_empty.2
theorem subset_eq_empty {s t : Set α} (h : t ⊆ s) (e : s = ∅) : t = ∅ :=
subset_empty_iff.1 <| e ▸ h
theorem forall_mem_empty {p : α → Prop} : (∀ x ∈ (∅ : Set α), p x) ↔ True :=
iff_true_intro fun _ => False.elim
instance (α : Type u) : IsEmpty.{u + 1} (↥(∅ : Set α)) :=
⟨fun x => x.2⟩
@[simp]
theorem empty_ssubset : ∅ ⊂ s ↔ s.Nonempty :=
(@bot_lt_iff_ne_bot (Set α) _ _ _).trans nonempty_iff_ne_empty.symm
alias ⟨_, Nonempty.empty_ssubset⟩ := empty_ssubset
/-!
### Universal set.
In Lean `@univ α` (or `univ : Set α`) is the set that contains all elements of type `α`.
Mathematically it is the same as `α` but it has a different type.
-/
@[simp]
theorem setOf_true : { _x : α | True } = univ :=
rfl
@[simp] theorem setOf_top : { _x : α | ⊤ } = univ := rfl
@[simp]
theorem univ_eq_empty_iff : (univ : Set α) = ∅ ↔ IsEmpty α :=
eq_empty_iff_forall_not_mem.trans
⟨fun H => ⟨fun x => H x trivial⟩, fun H x _ => @IsEmpty.false α H x⟩
theorem empty_ne_univ [Nonempty α] : (∅ : Set α) ≠ univ := fun e =>
not_isEmpty_of_nonempty α <| univ_eq_empty_iff.1 e.symm
@[simp]
theorem subset_univ (s : Set α) : s ⊆ univ := fun _ _ => trivial
@[simp]
theorem univ_subset_iff {s : Set α} : univ ⊆ s ↔ s = univ :=
@top_le_iff _ _ _ s
alias ⟨eq_univ_of_univ_subset, _⟩ := univ_subset_iff
theorem eq_univ_iff_forall {s : Set α} : s = univ ↔ ∀ x, x ∈ s :=
univ_subset_iff.symm.trans <| forall_congr' fun _ => imp_iff_right trivial
theorem eq_univ_of_forall {s : Set α} : (∀ x, x ∈ s) → s = univ :=
eq_univ_iff_forall.2
theorem Nonempty.eq_univ [Subsingleton α] : s.Nonempty → s = univ := by
rintro ⟨x, hx⟩
exact eq_univ_of_forall fun y => by rwa [Subsingleton.elim y x]
theorem eq_univ_of_subset {s t : Set α} (h : s ⊆ t) (hs : s = univ) : t = univ :=
eq_univ_of_univ_subset <| (hs ▸ h : univ ⊆ t)
theorem exists_mem_of_nonempty (α) : ∀ [Nonempty α], ∃ x : α, x ∈ (univ : Set α)
| ⟨x⟩ => ⟨x, trivial⟩
theorem ne_univ_iff_exists_not_mem {α : Type*} (s : Set α) : s ≠ univ ↔ ∃ a, a ∉ s := by
rw [← not_forall, ← eq_univ_iff_forall]
theorem not_subset_iff_exists_mem_not_mem {α : Type*} {s t : Set α} :
¬s ⊆ t ↔ ∃ x, x ∈ s ∧ x ∉ t := by simp [subset_def]
theorem univ_unique [Unique α] : @Set.univ α = {default} :=
Set.ext fun x => iff_of_true trivial <| Subsingleton.elim x default
theorem ssubset_univ_iff : s ⊂ univ ↔ s ≠ univ :=
lt_top_iff_ne_top
instance nontrivial_of_nonempty [Nonempty α] : Nontrivial (Set α) :=
⟨⟨∅, univ, empty_ne_univ⟩⟩
/-! ### Lemmas about union -/
theorem union_def {s₁ s₂ : Set α} : s₁ ∪ s₂ = { a | a ∈ s₁ ∨ a ∈ s₂ } :=
rfl
theorem mem_union_left {x : α} {a : Set α} (b : Set α) : x ∈ a → x ∈ a ∪ b :=
Or.inl
theorem mem_union_right {x : α} {b : Set α} (a : Set α) : x ∈ b → x ∈ a ∪ b :=
Or.inr
theorem mem_or_mem_of_mem_union {x : α} {a b : Set α} (H : x ∈ a ∪ b) : x ∈ a ∨ x ∈ b :=
H
theorem MemUnion.elim {x : α} {a b : Set α} {P : Prop} (H₁ : x ∈ a ∪ b) (H₂ : x ∈ a → P)
(H₃ : x ∈ b → P) : P :=
Or.elim H₁ H₂ H₃
@[simp]
theorem mem_union (x : α) (a b : Set α) : x ∈ a ∪ b ↔ x ∈ a ∨ x ∈ b :=
Iff.rfl
@[simp]
theorem union_self (a : Set α) : a ∪ a = a :=
ext fun _ => or_self_iff
@[simp]
theorem union_empty (a : Set α) : a ∪ ∅ = a :=
ext fun _ => iff_of_eq (or_false _)
@[simp]
theorem empty_union (a : Set α) : ∅ ∪ a = a :=
ext fun _ => iff_of_eq (false_or _)
theorem union_comm (a b : Set α) : a ∪ b = b ∪ a :=
ext fun _ => or_comm
theorem union_assoc (a b c : Set α) : a ∪ b ∪ c = a ∪ (b ∪ c) :=
ext fun _ => or_assoc
instance union_isAssoc : Std.Associative (α := Set α) (· ∪ ·) :=
⟨union_assoc⟩
instance union_isComm : Std.Commutative (α := Set α) (· ∪ ·) :=
⟨union_comm⟩
theorem union_left_comm (s₁ s₂ s₃ : Set α) : s₁ ∪ (s₂ ∪ s₃) = s₂ ∪ (s₁ ∪ s₃) :=
ext fun _ => or_left_comm
theorem union_right_comm (s₁ s₂ s₃ : Set α) : s₁ ∪ s₂ ∪ s₃ = s₁ ∪ s₃ ∪ s₂ :=
ext fun _ => or_right_comm
@[simp]
theorem union_eq_left {s t : Set α} : s ∪ t = s ↔ t ⊆ s :=
sup_eq_left
@[simp]
theorem union_eq_right {s t : Set α} : s ∪ t = t ↔ s ⊆ t :=
sup_eq_right
theorem union_eq_self_of_subset_left {s t : Set α} (h : s ⊆ t) : s ∪ t = t :=
union_eq_right.mpr h
theorem union_eq_self_of_subset_right {s t : Set α} (h : t ⊆ s) : s ∪ t = s :=
union_eq_left.mpr h
@[simp]
theorem subset_union_left {s t : Set α} : s ⊆ s ∪ t := fun _ => Or.inl
@[simp]
theorem subset_union_right {s t : Set α} : t ⊆ s ∪ t := fun _ => Or.inr
theorem union_subset {s t r : Set α} (sr : s ⊆ r) (tr : t ⊆ r) : s ∪ t ⊆ r := fun _ =>
Or.rec (@sr _) (@tr _)
@[simp]
theorem union_subset_iff {s t u : Set α} : s ∪ t ⊆ u ↔ s ⊆ u ∧ t ⊆ u :=
(forall_congr' fun _ => or_imp).trans forall_and
@[gcongr]
theorem union_subset_union {s₁ s₂ t₁ t₂ : Set α} (h₁ : s₁ ⊆ s₂) (h₂ : t₁ ⊆ t₂) :
s₁ ∪ t₁ ⊆ s₂ ∪ t₂ := fun _ => Or.imp (@h₁ _) (@h₂ _)
@[gcongr]
theorem union_subset_union_left {s₁ s₂ : Set α} (t) (h : s₁ ⊆ s₂) : s₁ ∪ t ⊆ s₂ ∪ t :=
union_subset_union h Subset.rfl
@[gcongr]
theorem union_subset_union_right (s) {t₁ t₂ : Set α} (h : t₁ ⊆ t₂) : s ∪ t₁ ⊆ s ∪ t₂ :=
union_subset_union Subset.rfl h
theorem subset_union_of_subset_left {s t : Set α} (h : s ⊆ t) (u : Set α) : s ⊆ t ∪ u :=
h.trans subset_union_left
theorem subset_union_of_subset_right {s u : Set α} (h : s ⊆ u) (t : Set α) : s ⊆ t ∪ u :=
h.trans subset_union_right
theorem union_congr_left (ht : t ⊆ s ∪ u) (hu : u ⊆ s ∪ t) : s ∪ t = s ∪ u :=
sup_congr_left ht hu
theorem union_congr_right (hs : s ⊆ t ∪ u) (ht : t ⊆ s ∪ u) : s ∪ u = t ∪ u :=
sup_congr_right hs ht
theorem union_eq_union_iff_left : s ∪ t = s ∪ u ↔ t ⊆ s ∪ u ∧ u ⊆ s ∪ t :=
sup_eq_sup_iff_left
theorem union_eq_union_iff_right : s ∪ u = t ∪ u ↔ s ⊆ t ∪ u ∧ t ⊆ s ∪ u :=
sup_eq_sup_iff_right
@[simp]
theorem union_empty_iff {s t : Set α} : s ∪ t = ∅ ↔ s = ∅ ∧ t = ∅ := by
simp only [← subset_empty_iff]
exact union_subset_iff
@[simp]
theorem union_univ (s : Set α) : s ∪ univ = univ := sup_top_eq _
@[simp]
theorem univ_union (s : Set α) : univ ∪ s = univ := top_sup_eq _
@[simp]
theorem ssubset_union_left_iff : s ⊂ s ∪ t ↔ ¬ t ⊆ s :=
left_lt_sup
@[simp]
theorem ssubset_union_right_iff : t ⊂ s ∪ t ↔ ¬ s ⊆ t :=
right_lt_sup
/-! ### Lemmas about intersection -/
theorem inter_def {s₁ s₂ : Set α} : s₁ ∩ s₂ = { a | a ∈ s₁ ∧ a ∈ s₂ } :=
rfl
@[simp, mfld_simps]
theorem mem_inter_iff (x : α) (a b : Set α) : x ∈ a ∩ b ↔ x ∈ a ∧ x ∈ b :=
Iff.rfl
theorem mem_inter {x : α} {a b : Set α} (ha : x ∈ a) (hb : x ∈ b) : x ∈ a ∩ b :=
⟨ha, hb⟩
theorem mem_of_mem_inter_left {x : α} {a b : Set α} (h : x ∈ a ∩ b) : x ∈ a :=
h.left
theorem mem_of_mem_inter_right {x : α} {a b : Set α} (h : x ∈ a ∩ b) : x ∈ b :=
h.right
@[simp]
theorem inter_self (a : Set α) : a ∩ a = a :=
ext fun _ => and_self_iff
@[simp]
theorem inter_empty (a : Set α) : a ∩ ∅ = ∅ :=
ext fun _ => iff_of_eq (and_false _)
@[simp]
theorem empty_inter (a : Set α) : ∅ ∩ a = ∅ :=
ext fun _ => iff_of_eq (false_and _)
theorem inter_comm (a b : Set α) : a ∩ b = b ∩ a :=
ext fun _ => and_comm
theorem inter_assoc (a b c : Set α) : a ∩ b ∩ c = a ∩ (b ∩ c) :=
ext fun _ => and_assoc
instance inter_isAssoc : Std.Associative (α := Set α) (· ∩ ·) :=
⟨inter_assoc⟩
instance inter_isComm : Std.Commutative (α := Set α) (· ∩ ·) :=
⟨inter_comm⟩
theorem inter_left_comm (s₁ s₂ s₃ : Set α) : s₁ ∩ (s₂ ∩ s₃) = s₂ ∩ (s₁ ∩ s₃) :=
ext fun _ => and_left_comm
theorem inter_right_comm (s₁ s₂ s₃ : Set α) : s₁ ∩ s₂ ∩ s₃ = s₁ ∩ s₃ ∩ s₂ :=
ext fun _ => and_right_comm
@[simp, mfld_simps]
theorem inter_subset_left {s t : Set α} : s ∩ t ⊆ s := fun _ => And.left
@[simp]
theorem inter_subset_right {s t : Set α} : s ∩ t ⊆ t := fun _ => And.right
theorem subset_inter {s t r : Set α} (rs : r ⊆ s) (rt : r ⊆ t) : r ⊆ s ∩ t := fun _ h =>
⟨rs h, rt h⟩
@[simp]
theorem subset_inter_iff {s t r : Set α} : r ⊆ s ∩ t ↔ r ⊆ s ∧ r ⊆ t :=
(forall_congr' fun _ => imp_and).trans forall_and
@[simp] lemma inter_eq_left : s ∩ t = s ↔ s ⊆ t := inf_eq_left
@[simp] lemma inter_eq_right : s ∩ t = t ↔ t ⊆ s := inf_eq_right
@[simp] lemma left_eq_inter : s = s ∩ t ↔ s ⊆ t := left_eq_inf
@[simp] lemma right_eq_inter : t = s ∩ t ↔ t ⊆ s := right_eq_inf
theorem inter_eq_self_of_subset_left {s t : Set α} : s ⊆ t → s ∩ t = s :=
inter_eq_left.mpr
theorem inter_eq_self_of_subset_right {s t : Set α} : t ⊆ s → s ∩ t = t :=
inter_eq_right.mpr
theorem inter_congr_left (ht : s ∩ u ⊆ t) (hu : s ∩ t ⊆ u) : s ∩ t = s ∩ u :=
inf_congr_left ht hu
theorem inter_congr_right (hs : t ∩ u ⊆ s) (ht : s ∩ u ⊆ t) : s ∩ u = t ∩ u :=
inf_congr_right hs ht
theorem inter_eq_inter_iff_left : s ∩ t = s ∩ u ↔ s ∩ u ⊆ t ∧ s ∩ t ⊆ u :=
inf_eq_inf_iff_left
theorem inter_eq_inter_iff_right : s ∩ u = t ∩ u ↔ t ∩ u ⊆ s ∧ s ∩ u ⊆ t :=
inf_eq_inf_iff_right
@[simp, mfld_simps]
theorem inter_univ (a : Set α) : a ∩ univ = a := inf_top_eq _
@[simp, mfld_simps]
theorem univ_inter (a : Set α) : univ ∩ a = a := top_inf_eq _
@[gcongr]
theorem inter_subset_inter {s₁ s₂ t₁ t₂ : Set α} (h₁ : s₁ ⊆ t₁) (h₂ : s₂ ⊆ t₂) :
s₁ ∩ s₂ ⊆ t₁ ∩ t₂ := fun _ => And.imp (@h₁ _) (@h₂ _)
@[gcongr]
theorem inter_subset_inter_left {s t : Set α} (u : Set α) (H : s ⊆ t) : s ∩ u ⊆ t ∩ u :=
inter_subset_inter H Subset.rfl
@[gcongr]
theorem inter_subset_inter_right {s t : Set α} (u : Set α) (H : s ⊆ t) : u ∩ s ⊆ u ∩ t :=
inter_subset_inter Subset.rfl H
theorem union_inter_cancel_left {s t : Set α} : (s ∪ t) ∩ s = s :=
inter_eq_self_of_subset_right subset_union_left
theorem union_inter_cancel_right {s t : Set α} : (s ∪ t) ∩ t = t :=
inter_eq_self_of_subset_right subset_union_right
theorem inter_setOf_eq_sep (s : Set α) (p : α → Prop) : s ∩ {a | p a} = {a ∈ s | p a} :=
rfl
theorem setOf_inter_eq_sep (p : α → Prop) (s : Set α) : {a | p a} ∩ s = {a ∈ s | p a} :=
inter_comm _ _
@[simp]
theorem inter_ssubset_right_iff : s ∩ t ⊂ t ↔ ¬ t ⊆ s :=
inf_lt_right
@[simp]
theorem inter_ssubset_left_iff : s ∩ t ⊂ s ↔ ¬ s ⊆ t :=
inf_lt_left
/-! ### Distributivity laws -/
theorem inter_union_distrib_left (s t u : Set α) : s ∩ (t ∪ u) = s ∩ t ∪ s ∩ u :=
inf_sup_left _ _ _
theorem union_inter_distrib_right (s t u : Set α) : (s ∪ t) ∩ u = s ∩ u ∪ t ∩ u :=
inf_sup_right _ _ _
theorem union_inter_distrib_left (s t u : Set α) : s ∪ t ∩ u = (s ∪ t) ∩ (s ∪ u) :=
sup_inf_left _ _ _
theorem inter_union_distrib_right (s t u : Set α) : s ∩ t ∪ u = (s ∪ u) ∩ (t ∪ u) :=
sup_inf_right _ _ _
theorem union_union_distrib_left (s t u : Set α) : s ∪ (t ∪ u) = s ∪ t ∪ (s ∪ u) :=
sup_sup_distrib_left _ _ _
theorem union_union_distrib_right (s t u : Set α) : s ∪ t ∪ u = s ∪ u ∪ (t ∪ u) :=
sup_sup_distrib_right _ _ _
theorem inter_inter_distrib_left (s t u : Set α) : s ∩ (t ∩ u) = s ∩ t ∩ (s ∩ u) :=
inf_inf_distrib_left _ _ _
theorem inter_inter_distrib_right (s t u : Set α) : s ∩ t ∩ u = s ∩ u ∩ (t ∩ u) :=
inf_inf_distrib_right _ _ _
theorem union_union_union_comm (s t u v : Set α) : s ∪ t ∪ (u ∪ v) = s ∪ u ∪ (t ∪ v) :=
sup_sup_sup_comm _ _ _ _
theorem inter_inter_inter_comm (s t u v : Set α) : s ∩ t ∩ (u ∩ v) = s ∩ u ∩ (t ∩ v) :=
inf_inf_inf_comm _ _ _ _
/-! ### Lemmas about sets defined as `{x ∈ s | p x}`. -/
section Sep
variable {p q : α → Prop} {x : α}
theorem mem_sep (xs : x ∈ s) (px : p x) : x ∈ { x ∈ s | p x } :=
⟨xs, px⟩
@[simp]
theorem sep_mem_eq : { x ∈ s | x ∈ t } = s ∩ t :=
rfl
@[simp]
theorem mem_sep_iff : x ∈ { x ∈ s | p x } ↔ x ∈ s ∧ p x :=
Iff.rfl
theorem sep_ext_iff : { x ∈ s | p x } = { x ∈ s | q x } ↔ ∀ x ∈ s, p x ↔ q x := by
simp_rw [Set.ext_iff, mem_sep_iff, and_congr_right_iff]
theorem sep_eq_of_subset (h : s ⊆ t) : { x ∈ t | x ∈ s } = s :=
inter_eq_self_of_subset_right h
@[simp]
theorem sep_subset (s : Set α) (p : α → Prop) : { x ∈ s | p x } ⊆ s := fun _ => And.left
@[simp]
theorem sep_eq_self_iff_mem_true : { x ∈ s | p x } = s ↔ ∀ x ∈ s, p x := by
simp_rw [Set.ext_iff, mem_sep_iff, and_iff_left_iff_imp]
@[simp]
theorem sep_eq_empty_iff_mem_false : { x ∈ s | p x } = ∅ ↔ ∀ x ∈ s, ¬p x := by
simp_rw [Set.ext_iff, mem_sep_iff, mem_empty_iff_false, iff_false, not_and]
theorem sep_true : { x ∈ s | True } = s :=
inter_univ s
theorem sep_false : { x ∈ s | False } = ∅ :=
inter_empty s
theorem sep_empty (p : α → Prop) : { x ∈ (∅ : Set α) | p x } = ∅ :=
empty_inter {x | p x}
theorem sep_univ : { x ∈ (univ : Set α) | p x } = { x | p x } :=
univ_inter {x | p x}
@[simp]
theorem sep_union : { x | (x ∈ s ∨ x ∈ t) ∧ p x } = { x ∈ s | p x } ∪ { x ∈ t | p x } :=
union_inter_distrib_right { x | x ∈ s } { x | x ∈ t } p
@[simp]
theorem sep_inter : { x | (x ∈ s ∧ x ∈ t) ∧ p x } = { x ∈ s | p x } ∩ { x ∈ t | p x } :=
inter_inter_distrib_right s t {x | p x}
@[simp]
theorem sep_and : { x ∈ s | p x ∧ q x } = { x ∈ s | p x } ∩ { x ∈ s | q x } :=
inter_inter_distrib_left s {x | p x} {x | q x}
@[simp]
theorem sep_or : { x ∈ s | p x ∨ q x } = { x ∈ s | p x } ∪ { x ∈ s | q x } :=
inter_union_distrib_left s p q
@[simp]
theorem sep_setOf : { x ∈ { y | p y } | q x } = { x | p x ∧ q x } :=
rfl
end Sep
/-- See also `Set.sdiff_inter_right_comm`. -/
lemma inter_diff_assoc (a b c : Set α) : (a ∩ b) \ c = a ∩ (b \ c) := inf_sdiff_assoc ..
/-- See also `Set.inter_diff_assoc`. -/
lemma sdiff_inter_right_comm (s t u : Set α) : s \ t ∩ u = (s ∩ u) \ t := sdiff_inf_right_comm ..
lemma inter_sdiff_left_comm (s t u : Set α) : s ∩ (t \ u) = t ∩ (s \ u) := inf_sdiff_left_comm ..
theorem diff_union_diff_cancel (hts : t ⊆ s) (hut : u ⊆ t) : s \ t ∪ t \ u = s \ u :=
sdiff_sup_sdiff_cancel hts hut
/-- A version of `diff_union_diff_cancel` with more general hypotheses. -/
theorem diff_union_diff_cancel' (hi : s ∩ u ⊆ t) (hu : t ⊆ s ∪ u) : (s \ t) ∪ (t \ u) = s \ u :=
sdiff_sup_sdiff_cancel' hi hu
theorem diff_diff_eq_sdiff_union (h : u ⊆ s) : s \ (t \ u) = s \ t ∪ u := sdiff_sdiff_eq_sdiff_sup h
theorem inter_diff_distrib_left (s t u : Set α) : s ∩ (t \ u) = (s ∩ t) \ (s ∩ u) :=
inf_sdiff_distrib_left _ _ _
theorem inter_diff_distrib_right (s t u : Set α) : (s \ t) ∩ u = (s ∩ u) \ (t ∩ u) :=
inf_sdiff_distrib_right _ _ _
theorem diff_inter_distrib_right (s t r : Set α) : (t ∩ r) \ s = (t \ s) ∩ (r \ s) :=
inf_sdiff
/-! ### Lemmas about complement -/
theorem compl_def (s : Set α) : sᶜ = { x | x ∉ s } :=
rfl
theorem mem_compl {s : Set α} {x : α} (h : x ∉ s) : x ∈ sᶜ :=
h
theorem compl_setOf {α} (p : α → Prop) : { a | p a }ᶜ = { a | ¬p a } :=
rfl
theorem not_mem_of_mem_compl {s : Set α} {x : α} (h : x ∈ sᶜ) : x ∉ s :=
h
theorem not_mem_compl_iff {x : α} : x ∉ sᶜ ↔ x ∈ s :=
not_not
@[simp]
theorem inter_compl_self (s : Set α) : s ∩ sᶜ = ∅ :=
inf_compl_eq_bot
@[simp]
theorem compl_inter_self (s : Set α) : sᶜ ∩ s = ∅ :=
compl_inf_eq_bot
@[simp]
theorem compl_empty : (∅ : Set α)ᶜ = univ :=
compl_bot
@[simp]
theorem compl_union (s t : Set α) : (s ∪ t)ᶜ = sᶜ ∩ tᶜ :=
compl_sup
theorem compl_inter (s t : Set α) : (s ∩ t)ᶜ = sᶜ ∪ tᶜ :=
compl_inf
@[simp]
theorem compl_univ : (univ : Set α)ᶜ = ∅ :=
compl_top
@[simp]
theorem compl_empty_iff {s : Set α} : sᶜ = ∅ ↔ s = univ :=
compl_eq_bot
@[simp]
theorem compl_univ_iff {s : Set α} : sᶜ = univ ↔ s = ∅ :=
compl_eq_top
theorem compl_ne_univ : sᶜ ≠ univ ↔ s.Nonempty :=
compl_univ_iff.not.trans nonempty_iff_ne_empty.symm
lemma inl_compl_union_inr_compl {α β : Type*} {s : Set α} {t : Set β} :
Sum.inl '' sᶜ ∪ Sum.inr '' tᶜ = (Sum.inl '' s ∪ Sum.inr '' t)ᶜ := by
rw [compl_union]
aesop
theorem nonempty_compl : sᶜ.Nonempty ↔ s ≠ univ :=
(ne_univ_iff_exists_not_mem s).symm
theorem union_eq_compl_compl_inter_compl (s t : Set α) : s ∪ t = (sᶜ ∩ tᶜ)ᶜ :=
ext fun _ => or_iff_not_and_not
theorem inter_eq_compl_compl_union_compl (s t : Set α) : s ∩ t = (sᶜ ∪ tᶜ)ᶜ :=
ext fun _ => and_iff_not_or_not
@[simp]
theorem union_compl_self (s : Set α) : s ∪ sᶜ = univ :=
eq_univ_iff_forall.2 fun _ => em _
@[simp]
theorem compl_union_self (s : Set α) : sᶜ ∪ s = univ := by rw [union_comm, union_compl_self]
theorem compl_subset_comm : sᶜ ⊆ t ↔ tᶜ ⊆ s :=
@compl_le_iff_compl_le _ s _ _
theorem subset_compl_comm : s ⊆ tᶜ ↔ t ⊆ sᶜ :=
@le_compl_iff_le_compl _ _ _ t
@[simp]
theorem compl_subset_compl : sᶜ ⊆ tᶜ ↔ t ⊆ s :=
@compl_le_compl_iff_le (Set α) _ _ _
@[gcongr] theorem compl_subset_compl_of_subset (h : t ⊆ s) : sᶜ ⊆ tᶜ := compl_subset_compl.2 h
theorem subset_union_compl_iff_inter_subset {s t u : Set α} : s ⊆ t ∪ uᶜ ↔ s ∩ u ⊆ t :=
(@isCompl_compl _ u _).le_sup_right_iff_inf_left_le
theorem compl_subset_iff_union {s t : Set α} : sᶜ ⊆ t ↔ s ∪ t = univ :=
Iff.symm <| eq_univ_iff_forall.trans <| forall_congr' fun _ => or_iff_not_imp_left
theorem inter_subset (a b c : Set α) : a ∩ b ⊆ c ↔ a ⊆ bᶜ ∪ c :=
forall_congr' fun _ => and_imp.trans <| imp_congr_right fun _ => imp_iff_not_or
theorem inter_compl_nonempty_iff {s t : Set α} : (s ∩ tᶜ).Nonempty ↔ ¬s ⊆ t :=
(not_subset.trans <| exists_congr fun x => by simp [mem_compl]).symm
/-! ### Lemmas about set difference -/
theorem not_mem_diff_of_mem {s t : Set α} {x : α} (hx : x ∈ t) : x ∉ s \ t := fun h => h.2 hx
theorem mem_of_mem_diff {s t : Set α} {x : α} (h : x ∈ s \ t) : x ∈ s :=
h.left
theorem not_mem_of_mem_diff {s t : Set α} {x : α} (h : x ∈ s \ t) : x ∉ t :=
h.right
theorem diff_eq_compl_inter {s t : Set α} : s \ t = tᶜ ∩ s := by rw [diff_eq, inter_comm]
theorem diff_nonempty {s t : Set α} : (s \ t).Nonempty ↔ ¬s ⊆ t :=
inter_compl_nonempty_iff
theorem diff_subset {s t : Set α} : s \ t ⊆ s := show s \ t ≤ s from sdiff_le
theorem diff_subset_compl (s t : Set α) : s \ t ⊆ tᶜ :=
diff_eq_compl_inter ▸ inter_subset_left
theorem union_diff_cancel' {s t u : Set α} (h₁ : s ⊆ t) (h₂ : t ⊆ u) : t ∪ u \ s = u :=
sup_sdiff_cancel' h₁ h₂
theorem union_diff_cancel {s t : Set α} (h : s ⊆ t) : s ∪ t \ s = t :=
sup_sdiff_cancel_right h
theorem union_diff_cancel_left {s t : Set α} (h : s ∩ t ⊆ ∅) : (s ∪ t) \ s = t :=
Disjoint.sup_sdiff_cancel_left <| disjoint_iff_inf_le.2 h
theorem union_diff_cancel_right {s t : Set α} (h : s ∩ t ⊆ ∅) : (s ∪ t) \ t = s :=
Disjoint.sup_sdiff_cancel_right <| disjoint_iff_inf_le.2 h
@[simp]
theorem union_diff_left {s t : Set α} : (s ∪ t) \ s = t \ s :=
sup_sdiff_left_self
@[simp]
theorem union_diff_right {s t : Set α} : (s ∪ t) \ t = s \ t :=
sup_sdiff_right_self
theorem union_diff_distrib {s t u : Set α} : (s ∪ t) \ u = s \ u ∪ t \ u :=
sup_sdiff
@[simp]
theorem inter_diff_self (a b : Set α) : a ∩ (b \ a) = ∅ :=
inf_sdiff_self_right
@[simp]
theorem inter_union_diff (s t : Set α) : s ∩ t ∪ s \ t = s :=
sup_inf_sdiff s t
@[simp]
theorem diff_union_inter (s t : Set α) : s \ t ∪ s ∩ t = s := by
rw [union_comm]
exact sup_inf_sdiff _ _
@[simp]
theorem inter_union_compl (s t : Set α) : s ∩ t ∪ s ∩ tᶜ = s :=
inter_union_diff _ _
@[gcongr]
theorem diff_subset_diff {s₁ s₂ t₁ t₂ : Set α} : s₁ ⊆ s₂ → t₂ ⊆ t₁ → s₁ \ t₁ ⊆ s₂ \ t₂ :=
show s₁ ≤ s₂ → t₂ ≤ t₁ → s₁ \ t₁ ≤ s₂ \ t₂ from sdiff_le_sdiff
@[gcongr]
theorem diff_subset_diff_left {s₁ s₂ t : Set α} (h : s₁ ⊆ s₂) : s₁ \ t ⊆ s₂ \ t :=
sdiff_le_sdiff_right ‹s₁ ≤ s₂›
@[gcongr]
theorem diff_subset_diff_right {s t u : Set α} (h : t ⊆ u) : s \ u ⊆ s \ t :=
sdiff_le_sdiff_left ‹t ≤ u›
theorem diff_subset_diff_iff_subset {r : Set α} (hs : s ⊆ r) (ht : t ⊆ r) :
r \ s ⊆ r \ t ↔ t ⊆ s :=
sdiff_le_sdiff_iff_le hs ht
theorem compl_eq_univ_diff (s : Set α) : sᶜ = univ \ s :=
top_sdiff.symm
@[simp]
theorem empty_diff (s : Set α) : (∅ \ s : Set α) = ∅ :=
bot_sdiff
theorem diff_eq_empty {s t : Set α} : s \ t = ∅ ↔ s ⊆ t :=
sdiff_eq_bot_iff
@[simp]
theorem diff_empty {s : Set α} : s \ ∅ = s :=
sdiff_bot
@[simp]
theorem diff_univ (s : Set α) : s \ univ = ∅ :=
diff_eq_empty.2 (subset_univ s)
theorem diff_diff {u : Set α} : (s \ t) \ u = s \ (t ∪ u) :=
sdiff_sdiff_left
-- the following statement contains parentheses to help the reader
theorem diff_diff_comm {s t u : Set α} : (s \ t) \ u = (s \ u) \ t :=
sdiff_sdiff_comm
theorem diff_subset_iff {s t u : Set α} : s \ t ⊆ u ↔ s ⊆ t ∪ u :=
show s \ t ≤ u ↔ s ≤ t ∪ u from sdiff_le_iff
theorem subset_diff_union (s t : Set α) : s ⊆ s \ t ∪ t :=
show s ≤ s \ t ∪ t from le_sdiff_sup
theorem diff_union_of_subset {s t : Set α} (h : t ⊆ s) : s \ t ∪ t = s :=
Subset.antisymm (union_subset diff_subset h) (subset_diff_union _ _)
theorem diff_subset_comm {s t u : Set α} : s \ t ⊆ u ↔ s \ u ⊆ t :=
show s \ t ≤ u ↔ s \ u ≤ t from sdiff_le_comm
theorem diff_inter {s t u : Set α} : s \ (t ∩ u) = s \ t ∪ s \ u :=
sdiff_inf
theorem diff_inter_diff : s \ t ∩ (s \ u) = s \ (t ∪ u) :=
sdiff_sup.symm
theorem diff_compl : s \ tᶜ = s ∩ t :=
sdiff_compl
theorem compl_diff : (t \ s)ᶜ = s ∪ tᶜ :=
Eq.trans compl_sdiff himp_eq
theorem diff_diff_right {s t u : Set α} : s \ (t \ u) = s \ t ∪ s ∩ u :=
sdiff_sdiff_right'
theorem inter_diff_right_comm : (s ∩ t) \ u = s \ u ∩ t := by
rw [diff_eq, diff_eq, inter_right_comm]
theorem diff_inter_right_comm : (s \ u) ∩ t = (s ∩ t) \ u := by
rw [diff_eq, diff_eq, inter_right_comm]
@[simp]
theorem union_diff_self {s t : Set α} : s ∪ t \ s = s ∪ t :=
sup_sdiff_self _ _
@[simp]
theorem diff_union_self {s t : Set α} : s \ t ∪ t = s ∪ t :=
sdiff_sup_self _ _
@[simp]
theorem diff_inter_self {a b : Set α} : b \ a ∩ a = ∅ :=
inf_sdiff_self_left
@[simp]
theorem diff_inter_self_eq_diff {s t : Set α} : s \ (t ∩ s) = s \ t :=
sdiff_inf_self_right _ _
@[simp]
theorem diff_self_inter {s t : Set α} : s \ (s ∩ t) = s \ t :=
sdiff_inf_self_left _ _
theorem diff_self {s : Set α} : s \ s = ∅ :=
sdiff_self
theorem diff_diff_right_self (s t : Set α) : s \ (s \ t) = s ∩ t :=
sdiff_sdiff_right_self
theorem diff_diff_cancel_left {s t : Set α} (h : s ⊆ t) : t \ (t \ s) = s :=
sdiff_sdiff_eq_self h
theorem union_eq_diff_union_diff_union_inter (s t : Set α) : s ∪ t = s \ t ∪ t \ s ∪ s ∩ t :=
sup_eq_sdiff_sup_sdiff_sup_inf
/-! ### Powerset -/
theorem mem_powerset {x s : Set α} (h : x ⊆ s) : x ∈ 𝒫 s := @h
theorem subset_of_mem_powerset {x s : Set α} (h : x ∈ 𝒫 s) : x ⊆ s := @h
@[simp]
theorem mem_powerset_iff (x s : Set α) : x ∈ 𝒫 s ↔ x ⊆ s :=
Iff.rfl
theorem powerset_inter (s t : Set α) : 𝒫(s ∩ t) = 𝒫 s ∩ 𝒫 t :=
ext fun _ => subset_inter_iff
@[simp]
theorem powerset_mono : 𝒫 s ⊆ 𝒫 t ↔ s ⊆ t :=
⟨fun h => @h _ (fun _ h => h), fun h _ hu _ ha => h (hu ha)⟩
theorem monotone_powerset : Monotone (powerset : Set α → Set (Set α)) := fun _ _ => powerset_mono.2
@[simp]
theorem powerset_nonempty : (𝒫 s).Nonempty :=
⟨∅, fun _ h => empty_subset s h⟩
@[simp]
theorem powerset_empty : 𝒫(∅ : Set α) = {∅} :=
ext fun _ => subset_empty_iff
@[simp]
theorem powerset_univ : 𝒫(univ : Set α) = univ :=
eq_univ_of_forall subset_univ
/-! ### Sets defined as an if-then-else -/
@[deprecated _root_.mem_dite (since := "2025-01-30")]
protected theorem mem_dite (p : Prop) [Decidable p] (s : p → Set α) (t : ¬ p → Set α) (x : α) :
(x ∈ if h : p then s h else t h) ↔ (∀ h : p, x ∈ s h) ∧ ∀ h : ¬p, x ∈ t h :=
_root_.mem_dite
theorem mem_dite_univ_right (p : Prop) [Decidable p] (t : p → Set α) (x : α) :
(x ∈ if h : p then t h else univ) ↔ ∀ h : p, x ∈ t h := by
simp [mem_dite]
@[simp]
theorem mem_ite_univ_right (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p t Set.univ ↔ p → x ∈ t :=
mem_dite_univ_right p (fun _ => t) x
theorem mem_dite_univ_left (p : Prop) [Decidable p] (t : ¬p → Set α) (x : α) :
(x ∈ if h : p then univ else t h) ↔ ∀ h : ¬p, x ∈ t h := by
split_ifs <;> simp_all
@[simp]
theorem mem_ite_univ_left (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p Set.univ t ↔ ¬p → x ∈ t :=
mem_dite_univ_left p (fun _ => t) x
theorem mem_dite_empty_right (p : Prop) [Decidable p] (t : p → Set α) (x : α) :
(x ∈ if h : p then t h else ∅) ↔ ∃ h : p, x ∈ t h := by
simp only [mem_dite, mem_empty_iff_false, imp_false, not_not]
exact ⟨fun h => ⟨h.2, h.1 h.2⟩, fun ⟨h₁, h₂⟩ => ⟨fun _ => h₂, h₁⟩⟩
@[simp]
theorem mem_ite_empty_right (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p t ∅ ↔ p ∧ x ∈ t :=
(mem_dite_empty_right p (fun _ => t) x).trans (by simp)
theorem mem_dite_empty_left (p : Prop) [Decidable p] (t : ¬p → Set α) (x : α) :
(x ∈ if h : p then ∅ else t h) ↔ ∃ h : ¬p, x ∈ t h := by
simp only [mem_dite, mem_empty_iff_false, imp_false]
exact ⟨fun h => ⟨h.1, h.2 h.1⟩, fun ⟨h₁, h₂⟩ => ⟨fun h => h₁ h, fun _ => h₂⟩⟩
@[simp]
theorem mem_ite_empty_left (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p ∅ t ↔ ¬p ∧ x ∈ t :=
(mem_dite_empty_left p (fun _ => t) x).trans (by simp)
/-! ### If-then-else for sets -/
/-- `ite` for sets: `Set.ite t s s' ∩ t = s ∩ t`, `Set.ite t s s' ∩ tᶜ = s' ∩ tᶜ`.
Defined as `s ∩ t ∪ s' \ t`. -/
protected def ite (t s s' : Set α) : Set α :=
s ∩ t ∪ s' \ t
@[simp]
theorem ite_inter_self (t s s' : Set α) : t.ite s s' ∩ t = s ∩ t := by
rw [Set.ite, union_inter_distrib_right, diff_inter_self, inter_assoc, inter_self, union_empty]
@[simp]
theorem ite_compl (t s s' : Set α) : tᶜ.ite s s' = t.ite s' s := by
rw [Set.ite, Set.ite, diff_compl, union_comm, diff_eq]
@[simp]
theorem ite_inter_compl_self (t s s' : Set α) : t.ite s s' ∩ tᶜ = s' ∩ tᶜ := by
rw [← ite_compl, ite_inter_self]
@[simp]
theorem ite_diff_self (t s s' : Set α) : t.ite s s' \ t = s' \ t :=
ite_inter_compl_self t s s'
@[simp]
theorem ite_same (t s : Set α) : t.ite s s = s :=
inter_union_diff _ _
@[simp]
theorem ite_left (s t : Set α) : s.ite s t = s ∪ t := by simp [Set.ite]
@[simp]
theorem ite_right (s t : Set α) : s.ite t s = t ∩ s := by simp [Set.ite]
@[simp]
theorem ite_empty (s s' : Set α) : Set.ite ∅ s s' = s' := by simp [Set.ite]
@[simp]
theorem ite_univ (s s' : Set α) : Set.ite univ s s' = s := by simp [Set.ite]
@[simp]
theorem ite_empty_left (t s : Set α) : t.ite ∅ s = s \ t := by simp [Set.ite]
@[simp]
theorem ite_empty_right (t s : Set α) : t.ite s ∅ = s ∩ t := by simp [Set.ite]
theorem ite_mono (t : Set α) {s₁ s₁' s₂ s₂' : Set α} (h : s₁ ⊆ s₂) (h' : s₁' ⊆ s₂') :
t.ite s₁ s₁' ⊆ t.ite s₂ s₂' :=
union_subset_union (inter_subset_inter_left _ h) (inter_subset_inter_left _ h')
theorem ite_subset_union (t s s' : Set α) : t.ite s s' ⊆ s ∪ s' :=
union_subset_union inter_subset_left diff_subset
theorem inter_subset_ite (t s s' : Set α) : s ∩ s' ⊆ t.ite s s' :=
ite_same t (s ∩ s') ▸ ite_mono _ inter_subset_left inter_subset_right
theorem ite_inter_inter (t s₁ s₂ s₁' s₂' : Set α) :
t.ite (s₁ ∩ s₂) (s₁' ∩ s₂') = t.ite s₁ s₁' ∩ t.ite s₂ s₂' := by
ext x
simp only [Set.ite, Set.mem_inter_iff, Set.mem_diff, Set.mem_union]
tauto
theorem ite_inter (t s₁ s₂ s : Set α) : t.ite (s₁ ∩ s) (s₂ ∩ s) = t.ite s₁ s₂ ∩ s := by
rw [ite_inter_inter, ite_same]
theorem ite_inter_of_inter_eq (t : Set α) {s₁ s₂ s : Set α} (h : s₁ ∩ s = s₂ ∩ s) :
t.ite s₁ s₂ ∩ s = s₁ ∩ s := by rw [← ite_inter, ← h, ite_same]
theorem subset_ite {t s s' u : Set α} : u ⊆ t.ite s s' ↔ u ∩ t ⊆ s ∧ u \ t ⊆ s' := by
simp only [subset_def, ← forall_and]
refine forall_congr' fun x => ?_
by_cases hx : x ∈ t <;> simp [*, Set.ite]
theorem ite_eq_of_subset_left (t : Set α) {s₁ s₂ : Set α} (h : s₁ ⊆ s₂) :
t.ite s₁ s₂ = s₁ ∪ (s₂ \ t) := by
ext x
by_cases hx : x ∈ t <;> simp [*, Set.ite, or_iff_right_of_imp (@h x)]
theorem ite_eq_of_subset_right (t : Set α) {s₁ s₂ : Set α} (h : s₂ ⊆ s₁) :
t.ite s₁ s₂ = (s₁ ∩ t) ∪ s₂ := by
ext x
by_cases hx : x ∈ t <;> simp [*, Set.ite, or_iff_left_of_imp (@h x)]
end Set
open Set
namespace Function
variable {α : Type*} {β : Type*}
theorem Injective.nonempty_apply_iff {f : Set α → Set β} (hf : Injective f) (h2 : f ∅ = ∅)
{s : Set α} : (f s).Nonempty ↔ s.Nonempty := by
rw [nonempty_iff_ne_empty, ← h2, nonempty_iff_ne_empty, hf.ne_iff]
end Function
namespace Subsingleton
variable {α : Type*} [Subsingleton α]
theorem eq_univ_of_nonempty {s : Set α} : s.Nonempty → s = univ := fun ⟨x, hx⟩ =>
eq_univ_of_forall fun y => Subsingleton.elim x y ▸ hx
@[elab_as_elim]
theorem set_cases {p : Set α → Prop} (h0 : p ∅) (h1 : p univ) (s) : p s :=
(s.eq_empty_or_nonempty.elim fun h => h.symm ▸ h0) fun h => (eq_univ_of_nonempty h).symm ▸ h1
theorem mem_iff_nonempty {α : Type*} [Subsingleton α] {s : Set α} {x : α} : x ∈ s ↔ s.Nonempty :=
⟨fun hx => ⟨x, hx⟩, fun ⟨y, hy⟩ => Subsingleton.elim y x ▸ hy⟩
end Subsingleton
/-! ### Decidability instances for sets -/
namespace Set
variable {α : Type u} (s t : Set α) (a b : α)
instance decidableSdiff [Decidable (a ∈ s)] [Decidable (a ∈ t)] : Decidable (a ∈ s \ t) :=
inferInstanceAs (Decidable (a ∈ s ∧ a ∉ t))
instance decidableInter [Decidable (a ∈ s)] [Decidable (a ∈ t)] : Decidable (a ∈ s ∩ t) :=
inferInstanceAs (Decidable (a ∈ s ∧ a ∈ t))
instance decidableUnion [Decidable (a ∈ s)] [Decidable (a ∈ t)] : Decidable (a ∈ s ∪ t) :=
inferInstanceAs (Decidable (a ∈ s ∨ a ∈ t))
instance decidableCompl [Decidable (a ∈ s)] : Decidable (a ∈ sᶜ) :=
inferInstanceAs (Decidable (a ∉ s))
instance decidableEmptyset : Decidable (a ∈ (∅ : Set α)) := Decidable.isFalse (by simp)
instance decidableUniv : Decidable (a ∈ univ) := Decidable.isTrue (by simp)
instance decidableInsert [Decidable (a = b)] [Decidable (a ∈ s)] : Decidable (a ∈ insert b s) :=
inferInstanceAs (Decidable (_ ∨ _))
instance decidableSetOf (p : α → Prop) [Decidable (p a)] : Decidable (a ∈ { a | p a }) := by
assumption
end Set
variable {α : Type*} {s t u : Set α}
namespace Equiv
/-- Given a predicate `p : α → Prop`, produces an equivalence between
`Set {a : α // p a}` and `{s : Set α // ∀ a ∈ s, p a}`. -/
protected def setSubtypeComm (p : α → Prop) :
Set {a : α // p a} ≃ {s : Set α // ∀ a ∈ s, p a} where
toFun s := ⟨{a | ∃ h : p a, s ⟨a, h⟩}, fun _ h ↦ h.1⟩
invFun s := {a | a.val ∈ s.val}
left_inv s := by ext a; exact ⟨fun h ↦ h.2, fun h ↦ ⟨a.property, h⟩⟩
right_inv s := by ext; exact ⟨fun h ↦ h.2, fun h ↦ ⟨s.property _ h, h⟩⟩
@[simp]
protected lemma setSubtypeComm_apply (p : α → Prop) (s : Set {a // p a}) :
(Equiv.setSubtypeComm p) s = ⟨{a | ∃ h : p a, ⟨a, h⟩ ∈ s}, fun _ h ↦ h.1⟩ :=
rfl
@[simp]
protected lemma setSubtypeComm_symm_apply (p : α → Prop) (s : {s // ∀ a ∈ s, p a}) :
(Equiv.setSubtypeComm p).symm s = {a | a.val ∈ s.val} :=
rfl
end Equiv
| Mathlib/Data/Set/Basic.lean | 1,942 | 1,951 | |
/-
Copyright (c) 2022 Joseph Hua. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kim Morrison, Bhavik Mehta, Johan Commelin, Reid Barton, Robert Y. Lewis, Joseph Hua
-/
import Mathlib.CategoryTheory.Limits.Shapes.IsTerminal
import Mathlib.CategoryTheory.Functor.EpiMono
/-!
# Algebras of endofunctors
This file defines (co)algebras of an endofunctor, and provides the category instance for them.
It also defines the forgetful functor from the category of (co)algebras. It is shown that the
structure map of the initial algebra of an endofunctor is an isomorphism. Furthermore, it is shown
that for an adjunction `F ⊣ G` the category of algebras over `F` is equivalent to the category of
coalgebras over `G`.
## TODO
* Prove that if the countable infinite product over the powers of the endofunctor exists, then
algebras over the endofunctor coincide with algebras over the free monad on the endofunctor.
-/
universe v u
namespace CategoryTheory
namespace Endofunctor
variable {C : Type u} [Category.{v} C]
/-- An algebra of an endofunctor; `str` stands for "structure morphism" -/
structure Algebra (F : C ⥤ C) where
/-- carrier of the algebra -/
a : C
/-- structure morphism of the algebra -/
str : F.obj a ⟶ a
instance [Inhabited C] : Inhabited (Algebra (𝟭 C)) :=
⟨⟨default, 𝟙 _⟩⟩
namespace Algebra
variable {F : C ⥤ C} (A : Algebra F) {A₀ A₁ A₂ : Algebra F}
/-
```
str
F A₀ -----> A₀
| |
F f | | f
V V
F A₁ -----> A₁
str
```
-/
/-- A morphism between algebras of endofunctor `F` -/
@[ext]
structure Hom (A₀ A₁ : Algebra F) where
/-- underlying morphism between the carriers -/
f : A₀.1 ⟶ A₁.1
/-- compatibility condition -/
h : F.map f ≫ A₁.str = A₀.str ≫ f := by aesop_cat
attribute [reassoc (attr := simp)] Hom.h
namespace Hom
/-- The identity morphism of an algebra of endofunctor `F` -/
def id : Hom A A where f := 𝟙 _
instance : Inhabited (Hom A A) :=
⟨{ f := 𝟙 _ }⟩
/-- The composition of morphisms between algebras of endofunctor `F` -/
def comp (f : Hom A₀ A₁) (g : Hom A₁ A₂) : Hom A₀ A₂ where f := f.1 ≫ g.1
end Hom
instance (F : C ⥤ C) : CategoryStruct (Algebra F) where
Hom := Hom
id := Hom.id
comp := @Hom.comp _ _ _
@[ext]
lemma ext {A B : Algebra F} {f g : A ⟶ B} (w : f.f = g.f := by aesop_cat) : f = g :=
Hom.ext w
@[simp]
theorem id_eq_id : Algebra.Hom.id A = 𝟙 A :=
rfl
@[simp]
theorem id_f : (𝟙 _ : A ⟶ A).1 = 𝟙 A.1 :=
rfl
variable (f : A₀ ⟶ A₁) (g : A₁ ⟶ A₂)
@[simp]
theorem comp_eq_comp : Algebra.Hom.comp f g = f ≫ g :=
rfl
@[simp]
theorem comp_f : (f ≫ g).1 = f.1 ≫ g.1 :=
rfl
/-- Algebras of an endofunctor `F` form a category -/
instance (F : C ⥤ C) : Category (Algebra F) := { }
/-- To construct an isomorphism of algebras, it suffices to give an isomorphism of the As which
commutes with the structure morphisms.
-/
@[simps!]
def isoMk (h : A₀.1 ≅ A₁.1) (w : F.map h.hom ≫ A₁.str = A₀.str ≫ h.hom := by aesop_cat) :
A₀ ≅ A₁ where
hom := { f := h.hom }
inv :=
{ f := h.inv
h := by
rw [h.eq_comp_inv, Category.assoc, ← w, ← Functor.map_comp_assoc]
simp }
/-- The forgetful functor from the category of algebras, forgetting the algebraic structure. -/
@[simps]
def forget (F : C ⥤ C) : Algebra F ⥤ C where
obj A := A.1
map := Hom.f
/-- An algebra morphism with an underlying isomorphism hom in `C` is an algebra isomorphism. -/
theorem iso_of_iso (f : A₀ ⟶ A₁) [IsIso f.1] : IsIso f :=
⟨⟨{ f := inv f.1
h := by
rw [IsIso.eq_comp_inv f.1, Category.assoc, ← f.h]
simp }, by aesop_cat, by aesop_cat⟩⟩
instance forget_reflects_iso : (forget F).ReflectsIsomorphisms where reflects := iso_of_iso
instance forget_faithful : (forget F).Faithful := { }
/-- An algebra morphism with an underlying epimorphism hom in `C` is an algebra epimorphism. -/
theorem epi_of_epi {X Y : Algebra F} (f : X ⟶ Y) [h : Epi f.1] : Epi f :=
(forget F).epi_of_epi_map h
/-- An algebra morphism with an underlying monomorphism hom in `C` is an algebra monomorphism. -/
theorem mono_of_mono {X Y : Algebra F} (f : X ⟶ Y) [h : Mono f.1] : Mono f :=
(forget F).mono_of_mono_map h
/-- From a natural transformation `α : G → F` we get a functor from
algebras of `F` to algebras of `G`.
-/
@[simps]
def functorOfNatTrans {F G : C ⥤ C} (α : G ⟶ F) : Algebra F ⥤ Algebra G where
obj A :=
{ a := A.1
str := α.app _ ≫ A.str }
map f := { f := f.1 }
/-- The identity transformation induces the identity endofunctor on the category of algebras. -/
@[simps!]
def functorOfNatTransId : functorOfNatTrans (𝟙 F) ≅ 𝟭 _ :=
NatIso.ofComponents fun X => isoMk (Iso.refl _)
/-- A composition of natural transformations gives the composition of corresponding functors. -/
@[simps!]
def functorOfNatTransComp {F₀ F₁ F₂ : C ⥤ C} (α : F₀ ⟶ F₁) (β : F₁ ⟶ F₂) :
functorOfNatTrans (α ≫ β) ≅ functorOfNatTrans β ⋙ functorOfNatTrans α :=
NatIso.ofComponents fun X => isoMk (Iso.refl _)
/--
If `α` and `β` are two equal natural transformations, then the functors of algebras induced by them
are isomorphic.
We define it like this as opposed to using `eq_to_iso` so that the components are nicer to prove
lemmas about.
-/
@[simps!]
def functorOfNatTransEq {F G : C ⥤ C} {α β : F ⟶ G} (h : α = β) :
functorOfNatTrans α ≅ functorOfNatTrans β :=
NatIso.ofComponents fun X => isoMk (Iso.refl _)
/-- Naturally isomorphic endofunctors give equivalent categories of algebras.
Furthermore, they are equivalent as categories over `C`, that is,
we have `equiv_of_nat_iso h ⋙ forget = forget`.
-/
@[simps]
def equivOfNatIso {F G : C ⥤ C} (α : F ≅ G) : Algebra F ≌ Algebra G where
functor := functorOfNatTrans α.inv
inverse := functorOfNatTrans α.hom
unitIso := functorOfNatTransId.symm ≪≫ functorOfNatTransEq (by simp) ≪≫ functorOfNatTransComp _ _
counitIso :=
(functorOfNatTransComp _ _).symm ≪≫ functorOfNatTransEq (by simp) ≪≫ functorOfNatTransId
namespace Initial
variable {A : Algebra F} (h : Limits.IsInitial A)
/-- The inverse of the structure map of an initial algebra -/
@[simp]
def strInv : A.1 ⟶ F.obj A.1 :=
(h.to ⟨F.obj A.a, F.map A.str⟩).f
theorem left_inv' :
⟨strInv h ≫ A.str, by rw [← Category.assoc, F.map_comp, strInv, ← Hom.h]⟩ = 𝟙 A :=
Limits.IsInitial.hom_ext h _ (𝟙 A)
theorem left_inv : strInv h ≫ A.str = 𝟙 _ :=
congr_arg Hom.f (left_inv' h)
theorem right_inv : A.str ≫ strInv h = 𝟙 _ := by
rw [strInv, ← (h.to ⟨F.obj A.1, F.map A.str⟩).h, ← F.map_id, ← F.map_comp]
congr
exact left_inv h
/-- The structure map of the initial algebra is an isomorphism,
hence endofunctors preserve their initial algebras
-/
theorem str_isIso (h : Limits.IsInitial A) : IsIso A.str :=
{ out := ⟨strInv h, right_inv _, left_inv _⟩ }
end Initial
end Algebra
/-- A coalgebra of an endofunctor; `str` stands for "structure morphism" -/
structure Coalgebra (F : C ⥤ C) where
/-- carrier of the coalgebra -/
V : C
/-- structure morphism of the coalgebra -/
| str : V ⟶ F.obj V
instance [Inhabited C] : Inhabited (Coalgebra (𝟭 C)) :=
| Mathlib/CategoryTheory/Endofunctor/Algebra.lean | 229 | 231 |
/-
Copyright (c) 2014 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Leonardo de Moura
-/
import Mathlib.Data.Set.Operations
import Mathlib.Order.Basic
import Mathlib.Order.BooleanAlgebra
import Mathlib.Tactic.Tauto
import Mathlib.Tactic.ByContra
import Mathlib.Util.Delaborators
import Mathlib.Tactic.Lift
/-!
# Basic properties of sets
Sets in Lean are homogeneous; all their elements have the same type. Sets whose elements
have type `X` are thus defined as `Set X := X → Prop`. Note that this function need not
be decidable. The definition is in the module `Mathlib.Data.Set.Defs`.
This file provides some basic definitions related to sets and functions not present in the
definitions file, as well as extra lemmas for functions defined in the definitions file and
`Mathlib.Data.Set.Operations` (empty set, univ, union, intersection, insert, singleton,
set-theoretic difference, complement, and powerset).
Note that a set is a term, not a type. There is a coercion from `Set α` to `Type*` sending
`s` to the corresponding subtype `↥s`.
See also the file `SetTheory/ZFC.lean`, which contains an encoding of ZFC set theory in Lean.
## Main definitions
Notation used here:
- `f : α → β` is a function,
- `s : Set α` and `s₁ s₂ : Set α` are subsets of `α`
- `t : Set β` is a subset of `β`.
Definitions in the file:
* `Nonempty s : Prop` : the predicate `s ≠ ∅`. Note that this is the preferred way to express the
fact that `s` has an element (see the Implementation Notes).
* `inclusion s₁ s₂ : ↥s₁ → ↥s₂` : the map `↥s₁ → ↥s₂` induced by an inclusion `s₁ ⊆ s₂`.
## Notation
* `sᶜ` for the complement of `s`
## Implementation notes
* `s.Nonempty` is to be preferred to `s ≠ ∅` or `∃ x, x ∈ s`. It has the advantage that
the `s.Nonempty` dot notation can be used.
* For `s : Set α`, do not use `Subtype s`. Instead use `↥s` or `(s : Type*)` or `s`.
## Tags
set, sets, subset, subsets, union, intersection, insert, singleton, complement, powerset
-/
assert_not_exists RelIso
/-! ### Set coercion to a type -/
open Function
universe u v
namespace Set
variable {α : Type u} {s t : Set α}
instance instBooleanAlgebra : BooleanAlgebra (Set α) :=
{ (inferInstance : BooleanAlgebra (α → Prop)) with
sup := (· ∪ ·),
le := (· ≤ ·),
lt := fun s t => s ⊆ t ∧ ¬t ⊆ s,
inf := (· ∩ ·),
bot := ∅,
compl := (·ᶜ),
top := univ,
sdiff := (· \ ·) }
instance : HasSSubset (Set α) :=
⟨(· < ·)⟩
@[simp]
theorem top_eq_univ : (⊤ : Set α) = univ :=
rfl
@[simp]
theorem bot_eq_empty : (⊥ : Set α) = ∅ :=
rfl
@[simp]
theorem sup_eq_union : ((· ⊔ ·) : Set α → Set α → Set α) = (· ∪ ·) :=
rfl
@[simp]
theorem inf_eq_inter : ((· ⊓ ·) : Set α → Set α → Set α) = (· ∩ ·) :=
rfl
@[simp]
theorem le_eq_subset : ((· ≤ ·) : Set α → Set α → Prop) = (· ⊆ ·) :=
rfl
@[simp]
theorem lt_eq_ssubset : ((· < ·) : Set α → Set α → Prop) = (· ⊂ ·) :=
rfl
theorem le_iff_subset : s ≤ t ↔ s ⊆ t :=
Iff.rfl
theorem lt_iff_ssubset : s < t ↔ s ⊂ t :=
Iff.rfl
alias ⟨_root_.LE.le.subset, _root_.HasSubset.Subset.le⟩ := le_iff_subset
alias ⟨_root_.LT.lt.ssubset, _root_.HasSSubset.SSubset.lt⟩ := lt_iff_ssubset
instance PiSetCoe.canLift (ι : Type u) (α : ι → Type v) [∀ i, Nonempty (α i)] (s : Set ι) :
CanLift (∀ i : s, α i) (∀ i, α i) (fun f i => f i) fun _ => True :=
PiSubtype.canLift ι α s
instance PiSetCoe.canLift' (ι : Type u) (α : Type v) [Nonempty α] (s : Set ι) :
CanLift (s → α) (ι → α) (fun f i => f i) fun _ => True :=
PiSetCoe.canLift ι (fun _ => α) s
end Set
section SetCoe
variable {α : Type u}
instance (s : Set α) : CoeTC s α := ⟨fun x => x.1⟩
theorem Set.coe_eq_subtype (s : Set α) : ↥s = { x // x ∈ s } :=
rfl
@[simp]
theorem Set.coe_setOf (p : α → Prop) : ↥{ x | p x } = { x // p x } :=
rfl
theorem SetCoe.forall {s : Set α} {p : s → Prop} : (∀ x : s, p x) ↔ ∀ (x) (h : x ∈ s), p ⟨x, h⟩ :=
Subtype.forall
theorem SetCoe.exists {s : Set α} {p : s → Prop} :
(∃ x : s, p x) ↔ ∃ (x : _) (h : x ∈ s), p ⟨x, h⟩ :=
Subtype.exists
theorem SetCoe.exists' {s : Set α} {p : ∀ x, x ∈ s → Prop} :
(∃ (x : _) (h : x ∈ s), p x h) ↔ ∃ x : s, p x.1 x.2 :=
(@SetCoe.exists _ _ fun x => p x.1 x.2).symm
theorem SetCoe.forall' {s : Set α} {p : ∀ x, x ∈ s → Prop} :
(∀ (x) (h : x ∈ s), p x h) ↔ ∀ x : s, p x.1 x.2 :=
(@SetCoe.forall _ _ fun x => p x.1 x.2).symm
@[simp]
theorem set_coe_cast :
∀ {s t : Set α} (H' : s = t) (H : ↥s = ↥t) (x : s), cast H x = ⟨x.1, H' ▸ x.2⟩
| _, _, rfl, _, _ => rfl
theorem SetCoe.ext {s : Set α} {a b : s} : (a : α) = b → a = b :=
Subtype.eq
theorem SetCoe.ext_iff {s : Set α} {a b : s} : (↑a : α) = ↑b ↔ a = b :=
Iff.intro SetCoe.ext fun h => h ▸ rfl
end SetCoe
/-- See also `Subtype.prop` -/
theorem Subtype.mem {α : Type*} {s : Set α} (p : s) : (p : α) ∈ s :=
p.prop
/-- Duplicate of `Eq.subset'`, which currently has elaboration problems. -/
theorem Eq.subset {α} {s t : Set α} : s = t → s ⊆ t :=
fun h₁ _ h₂ => by rw [← h₁]; exact h₂
namespace Set
variable {α : Type u} {β : Type v} {a b : α} {s s₁ s₂ t t₁ t₂ u : Set α}
instance : Inhabited (Set α) :=
⟨∅⟩
@[trans]
theorem mem_of_mem_of_subset {x : α} {s t : Set α} (hx : x ∈ s) (h : s ⊆ t) : x ∈ t :=
h hx
theorem forall_in_swap {p : α → β → Prop} : (∀ a ∈ s, ∀ (b), p a b) ↔ ∀ (b), ∀ a ∈ s, p a b := by
tauto
theorem setOf_injective : Function.Injective (@setOf α) := injective_id
theorem setOf_inj {p q : α → Prop} : { x | p x } = { x | q x } ↔ p = q := Iff.rfl
/-! ### Lemmas about `mem` and `setOf` -/
theorem mem_setOf {a : α} {p : α → Prop} : a ∈ { x | p x } ↔ p a :=
Iff.rfl
/-- This lemma is intended for use with `rw` where a membership predicate is needed,
hence the explicit argument and the equality in the reverse direction from normal.
See also `Set.mem_setOf_eq` for the reverse direction applied to an argument. -/
theorem eq_mem_setOf (p : α → Prop) : p = (· ∈ {a | p a}) := rfl
/-- If `h : a ∈ {x | p x}` then `h.out : p x`. These are definitionally equal, but this can
nevertheless be useful for various reasons, e.g. to apply further projection notation or in an
argument to `simp`. -/
theorem _root_.Membership.mem.out {p : α → Prop} {a : α} (h : a ∈ { x | p x }) : p a :=
h
theorem nmem_setOf_iff {a : α} {p : α → Prop} : a ∉ { x | p x } ↔ ¬p a :=
Iff.rfl
@[simp]
theorem setOf_mem_eq {s : Set α} : { x | x ∈ s } = s :=
rfl
theorem setOf_set {s : Set α} : setOf s = s :=
rfl
theorem setOf_app_iff {p : α → Prop} {x : α} : { x | p x } x ↔ p x :=
Iff.rfl
theorem mem_def {a : α} {s : Set α} : a ∈ s ↔ s a :=
Iff.rfl
theorem setOf_bijective : Bijective (setOf : (α → Prop) → Set α) :=
bijective_id
theorem subset_setOf {p : α → Prop} {s : Set α} : s ⊆ setOf p ↔ ∀ x, x ∈ s → p x :=
Iff.rfl
theorem setOf_subset {p : α → Prop} {s : Set α} : setOf p ⊆ s ↔ ∀ x, p x → x ∈ s :=
Iff.rfl
@[simp]
theorem setOf_subset_setOf {p q : α → Prop} : { a | p a } ⊆ { a | q a } ↔ ∀ a, p a → q a :=
Iff.rfl
theorem setOf_and {p q : α → Prop} : { a | p a ∧ q a } = { a | p a } ∩ { a | q a } :=
rfl
theorem setOf_or {p q : α → Prop} : { a | p a ∨ q a } = { a | p a } ∪ { a | q a } :=
rfl
/-! ### Subset and strict subset relations -/
instance : IsRefl (Set α) (· ⊆ ·) :=
show IsRefl (Set α) (· ≤ ·) by infer_instance
instance : IsTrans (Set α) (· ⊆ ·) :=
show IsTrans (Set α) (· ≤ ·) by infer_instance
instance : Trans ((· ⊆ ·) : Set α → Set α → Prop) (· ⊆ ·) (· ⊆ ·) :=
show Trans (· ≤ ·) (· ≤ ·) (· ≤ ·) by infer_instance
instance : IsAntisymm (Set α) (· ⊆ ·) :=
show IsAntisymm (Set α) (· ≤ ·) by infer_instance
instance : IsIrrefl (Set α) (· ⊂ ·) :=
show IsIrrefl (Set α) (· < ·) by infer_instance
instance : IsTrans (Set α) (· ⊂ ·) :=
show IsTrans (Set α) (· < ·) by infer_instance
instance : Trans ((· ⊂ ·) : Set α → Set α → Prop) (· ⊂ ·) (· ⊂ ·) :=
show Trans (· < ·) (· < ·) (· < ·) by infer_instance
instance : Trans ((· ⊂ ·) : Set α → Set α → Prop) (· ⊆ ·) (· ⊂ ·) :=
show Trans (· < ·) (· ≤ ·) (· < ·) by infer_instance
instance : Trans ((· ⊆ ·) : Set α → Set α → Prop) (· ⊂ ·) (· ⊂ ·) :=
show Trans (· ≤ ·) (· < ·) (· < ·) by infer_instance
instance : IsAsymm (Set α) (· ⊂ ·) :=
show IsAsymm (Set α) (· < ·) by infer_instance
instance : IsNonstrictStrictOrder (Set α) (· ⊆ ·) (· ⊂ ·) :=
⟨fun _ _ => Iff.rfl⟩
-- TODO(Jeremy): write a tactic to unfold specific instances of generic notation?
theorem subset_def : (s ⊆ t) = ∀ x, x ∈ s → x ∈ t :=
rfl
theorem ssubset_def : (s ⊂ t) = (s ⊆ t ∧ ¬t ⊆ s) :=
rfl
@[refl]
theorem Subset.refl (a : Set α) : a ⊆ a := fun _ => id
theorem Subset.rfl {s : Set α} : s ⊆ s :=
Subset.refl s
@[trans]
theorem Subset.trans {a b c : Set α} (ab : a ⊆ b) (bc : b ⊆ c) : a ⊆ c := fun _ h => bc <| ab h
@[trans]
theorem mem_of_eq_of_mem {x y : α} {s : Set α} (hx : x = y) (h : y ∈ s) : x ∈ s :=
hx.symm ▸ h
theorem Subset.antisymm {a b : Set α} (h₁ : a ⊆ b) (h₂ : b ⊆ a) : a = b :=
Set.ext fun _ => ⟨@h₁ _, @h₂ _⟩
theorem Subset.antisymm_iff {a b : Set α} : a = b ↔ a ⊆ b ∧ b ⊆ a :=
⟨fun e => ⟨e.subset, e.symm.subset⟩, fun ⟨h₁, h₂⟩ => Subset.antisymm h₁ h₂⟩
-- an alternative name
theorem eq_of_subset_of_subset {a b : Set α} : a ⊆ b → b ⊆ a → a = b :=
Subset.antisymm
theorem mem_of_subset_of_mem {s₁ s₂ : Set α} {a : α} (h : s₁ ⊆ s₂) : a ∈ s₁ → a ∈ s₂ :=
@h _
theorem not_mem_subset (h : s ⊆ t) : a ∉ t → a ∉ s :=
mt <| mem_of_subset_of_mem h
theorem not_subset : ¬s ⊆ t ↔ ∃ a ∈ s, a ∉ t := by
simp only [subset_def, not_forall, exists_prop]
theorem not_top_subset : ¬⊤ ⊆ s ↔ ∃ a, a ∉ s := by
simp [not_subset]
lemma eq_of_forall_subset_iff (h : ∀ u, s ⊆ u ↔ t ⊆ u) : s = t := eq_of_forall_ge_iff h
/-! ### Definition of strict subsets `s ⊂ t` and basic properties. -/
protected theorem eq_or_ssubset_of_subset (h : s ⊆ t) : s = t ∨ s ⊂ t :=
eq_or_lt_of_le h
theorem exists_of_ssubset {s t : Set α} (h : s ⊂ t) : ∃ x ∈ t, x ∉ s :=
not_subset.1 h.2
protected theorem ssubset_iff_subset_ne {s t : Set α} : s ⊂ t ↔ s ⊆ t ∧ s ≠ t :=
@lt_iff_le_and_ne (Set α) _ s t
theorem ssubset_iff_of_subset {s t : Set α} (h : s ⊆ t) : s ⊂ t ↔ ∃ x ∈ t, x ∉ s :=
⟨exists_of_ssubset, fun ⟨_, hxt, hxs⟩ => ⟨h, fun h => hxs <| h hxt⟩⟩
theorem ssubset_iff_exists {s t : Set α} : s ⊂ t ↔ s ⊆ t ∧ ∃ x ∈ t, x ∉ s :=
⟨fun h ↦ ⟨h.le, Set.exists_of_ssubset h⟩, fun ⟨h1, h2⟩ ↦ (Set.ssubset_iff_of_subset h1).mpr h2⟩
protected theorem ssubset_of_ssubset_of_subset {s₁ s₂ s₃ : Set α} (hs₁s₂ : s₁ ⊂ s₂)
(hs₂s₃ : s₂ ⊆ s₃) : s₁ ⊂ s₃ :=
⟨Subset.trans hs₁s₂.1 hs₂s₃, fun hs₃s₁ => hs₁s₂.2 (Subset.trans hs₂s₃ hs₃s₁)⟩
protected theorem ssubset_of_subset_of_ssubset {s₁ s₂ s₃ : Set α} (hs₁s₂ : s₁ ⊆ s₂)
(hs₂s₃ : s₂ ⊂ s₃) : s₁ ⊂ s₃ :=
⟨Subset.trans hs₁s₂ hs₂s₃.1, fun hs₃s₁ => hs₂s₃.2 (Subset.trans hs₃s₁ hs₁s₂)⟩
theorem not_mem_empty (x : α) : ¬x ∈ (∅ : Set α) :=
id
theorem not_not_mem : ¬a ∉ s ↔ a ∈ s :=
not_not
/-! ### Non-empty sets -/
theorem nonempty_coe_sort {s : Set α} : Nonempty ↥s ↔ s.Nonempty :=
nonempty_subtype
alias ⟨_, Nonempty.coe_sort⟩ := nonempty_coe_sort
theorem nonempty_def : s.Nonempty ↔ ∃ x, x ∈ s :=
Iff.rfl
theorem nonempty_of_mem {x} (h : x ∈ s) : s.Nonempty :=
⟨x, h⟩
theorem Nonempty.not_subset_empty : s.Nonempty → ¬s ⊆ ∅
| ⟨_, hx⟩, hs => hs hx
/-- Extract a witness from `s.Nonempty`. This function might be used instead of case analysis
on the argument. Note that it makes a proof depend on the `Classical.choice` axiom. -/
protected noncomputable def Nonempty.some (h : s.Nonempty) : α :=
Classical.choose h
protected theorem Nonempty.some_mem (h : s.Nonempty) : h.some ∈ s :=
Classical.choose_spec h
theorem Nonempty.mono (ht : s ⊆ t) (hs : s.Nonempty) : t.Nonempty :=
hs.imp ht
theorem nonempty_of_not_subset (h : ¬s ⊆ t) : (s \ t).Nonempty :=
let ⟨x, xs, xt⟩ := not_subset.1 h
⟨x, xs, xt⟩
theorem nonempty_of_ssubset (ht : s ⊂ t) : (t \ s).Nonempty :=
nonempty_of_not_subset ht.2
theorem Nonempty.of_diff (h : (s \ t).Nonempty) : s.Nonempty :=
h.imp fun _ => And.left
theorem nonempty_of_ssubset' (ht : s ⊂ t) : t.Nonempty :=
(nonempty_of_ssubset ht).of_diff
theorem Nonempty.inl (hs : s.Nonempty) : (s ∪ t).Nonempty :=
hs.imp fun _ => Or.inl
theorem Nonempty.inr (ht : t.Nonempty) : (s ∪ t).Nonempty :=
ht.imp fun _ => Or.inr
@[simp]
theorem union_nonempty : (s ∪ t).Nonempty ↔ s.Nonempty ∨ t.Nonempty :=
exists_or
theorem Nonempty.left (h : (s ∩ t).Nonempty) : s.Nonempty :=
h.imp fun _ => And.left
theorem Nonempty.right (h : (s ∩ t).Nonempty) : t.Nonempty :=
h.imp fun _ => And.right
theorem inter_nonempty : (s ∩ t).Nonempty ↔ ∃ x, x ∈ s ∧ x ∈ t :=
Iff.rfl
theorem inter_nonempty_iff_exists_left : (s ∩ t).Nonempty ↔ ∃ x ∈ s, x ∈ t := by
simp_rw [inter_nonempty]
theorem inter_nonempty_iff_exists_right : (s ∩ t).Nonempty ↔ ∃ x ∈ t, x ∈ s := by
simp_rw [inter_nonempty, and_comm]
theorem nonempty_iff_univ_nonempty : Nonempty α ↔ (univ : Set α).Nonempty :=
⟨fun ⟨x⟩ => ⟨x, trivial⟩, fun ⟨x, _⟩ => ⟨x⟩⟩
@[simp]
theorem univ_nonempty : ∀ [Nonempty α], (univ : Set α).Nonempty
| ⟨x⟩ => ⟨x, trivial⟩
theorem Nonempty.to_subtype : s.Nonempty → Nonempty (↥s) :=
nonempty_subtype.2
theorem Nonempty.to_type : s.Nonempty → Nonempty α := fun ⟨x, _⟩ => ⟨x⟩
instance univ.nonempty [Nonempty α] : Nonempty (↥(Set.univ : Set α)) :=
Set.univ_nonempty.to_subtype
-- Redeclare for refined keys
-- `Nonempty (@Subtype _ (@Membership.mem _ (Set _) _ (@Top.top (Set _) _)))`
instance instNonemptyTop [Nonempty α] : Nonempty (⊤ : Set α) :=
inferInstanceAs (Nonempty (univ : Set α))
theorem Nonempty.of_subtype [Nonempty (↥s)] : s.Nonempty := nonempty_subtype.mp ‹_›
@[deprecated (since := "2024-11-23")] alias nonempty_of_nonempty_subtype := Nonempty.of_subtype
/-! ### Lemmas about the empty set -/
theorem empty_def : (∅ : Set α) = { _x : α | False } :=
rfl
@[simp]
theorem mem_empty_iff_false (x : α) : x ∈ (∅ : Set α) ↔ False :=
Iff.rfl
@[simp]
theorem setOf_false : { _a : α | False } = ∅ :=
rfl
@[simp] theorem setOf_bot : { _x : α | ⊥ } = ∅ := rfl
@[simp]
theorem empty_subset (s : Set α) : ∅ ⊆ s :=
nofun
@[simp]
theorem subset_empty_iff {s : Set α} : s ⊆ ∅ ↔ s = ∅ :=
(Subset.antisymm_iff.trans <| and_iff_left (empty_subset _)).symm
theorem eq_empty_iff_forall_not_mem {s : Set α} : s = ∅ ↔ ∀ x, x ∉ s :=
subset_empty_iff.symm
theorem eq_empty_of_forall_not_mem (h : ∀ x, x ∉ s) : s = ∅ :=
subset_empty_iff.1 h
theorem eq_empty_of_subset_empty {s : Set α} : s ⊆ ∅ → s = ∅ :=
subset_empty_iff.1
theorem eq_empty_of_isEmpty [IsEmpty α] (s : Set α) : s = ∅ :=
eq_empty_of_subset_empty fun x _ => isEmptyElim x
/-- There is exactly one set of a type that is empty. -/
instance uniqueEmpty [IsEmpty α] : Unique (Set α) where
default := ∅
uniq := eq_empty_of_isEmpty
/-- See also `Set.nonempty_iff_ne_empty`. -/
theorem not_nonempty_iff_eq_empty {s : Set α} : ¬s.Nonempty ↔ s = ∅ := by
simp only [Set.Nonempty, not_exists, eq_empty_iff_forall_not_mem]
/-- See also `Set.not_nonempty_iff_eq_empty`. -/
theorem nonempty_iff_ne_empty : s.Nonempty ↔ s ≠ ∅ :=
not_nonempty_iff_eq_empty.not_right
/-- See also `nonempty_iff_ne_empty'`. -/
theorem not_nonempty_iff_eq_empty' : ¬Nonempty s ↔ s = ∅ := by
rw [nonempty_subtype, not_exists, eq_empty_iff_forall_not_mem]
/-- See also `not_nonempty_iff_eq_empty'`. -/
theorem nonempty_iff_ne_empty' : Nonempty s ↔ s ≠ ∅ :=
not_nonempty_iff_eq_empty'.not_right
alias ⟨Nonempty.ne_empty, _⟩ := nonempty_iff_ne_empty
@[simp]
theorem not_nonempty_empty : ¬(∅ : Set α).Nonempty := fun ⟨_, hx⟩ => hx
@[simp]
theorem isEmpty_coe_sort {s : Set α} : IsEmpty (↥s) ↔ s = ∅ :=
not_iff_not.1 <| by simpa using nonempty_iff_ne_empty
theorem eq_empty_or_nonempty (s : Set α) : s = ∅ ∨ s.Nonempty :=
or_iff_not_imp_left.2 nonempty_iff_ne_empty.2
theorem subset_eq_empty {s t : Set α} (h : t ⊆ s) (e : s = ∅) : t = ∅ :=
subset_empty_iff.1 <| e ▸ h
theorem forall_mem_empty {p : α → Prop} : (∀ x ∈ (∅ : Set α), p x) ↔ True :=
iff_true_intro fun _ => False.elim
instance (α : Type u) : IsEmpty.{u + 1} (↥(∅ : Set α)) :=
⟨fun x => x.2⟩
@[simp]
theorem empty_ssubset : ∅ ⊂ s ↔ s.Nonempty :=
(@bot_lt_iff_ne_bot (Set α) _ _ _).trans nonempty_iff_ne_empty.symm
alias ⟨_, Nonempty.empty_ssubset⟩ := empty_ssubset
/-!
### Universal set.
In Lean `@univ α` (or `univ : Set α`) is the set that contains all elements of type `α`.
Mathematically it is the same as `α` but it has a different type.
-/
@[simp]
theorem setOf_true : { _x : α | True } = univ :=
rfl
@[simp] theorem setOf_top : { _x : α | ⊤ } = univ := rfl
@[simp]
theorem univ_eq_empty_iff : (univ : Set α) = ∅ ↔ IsEmpty α :=
eq_empty_iff_forall_not_mem.trans
⟨fun H => ⟨fun x => H x trivial⟩, fun H x _ => @IsEmpty.false α H x⟩
theorem empty_ne_univ [Nonempty α] : (∅ : Set α) ≠ univ := fun e =>
not_isEmpty_of_nonempty α <| univ_eq_empty_iff.1 e.symm
@[simp]
theorem subset_univ (s : Set α) : s ⊆ univ := fun _ _ => trivial
@[simp]
theorem univ_subset_iff {s : Set α} : univ ⊆ s ↔ s = univ :=
@top_le_iff _ _ _ s
alias ⟨eq_univ_of_univ_subset, _⟩ := univ_subset_iff
theorem eq_univ_iff_forall {s : Set α} : s = univ ↔ ∀ x, x ∈ s :=
univ_subset_iff.symm.trans <| forall_congr' fun _ => imp_iff_right trivial
theorem eq_univ_of_forall {s : Set α} : (∀ x, x ∈ s) → s = univ :=
eq_univ_iff_forall.2
theorem Nonempty.eq_univ [Subsingleton α] : s.Nonempty → s = univ := by
rintro ⟨x, hx⟩
exact eq_univ_of_forall fun y => by rwa [Subsingleton.elim y x]
theorem eq_univ_of_subset {s t : Set α} (h : s ⊆ t) (hs : s = univ) : t = univ :=
eq_univ_of_univ_subset <| (hs ▸ h : univ ⊆ t)
theorem exists_mem_of_nonempty (α) : ∀ [Nonempty α], ∃ x : α, x ∈ (univ : Set α)
| ⟨x⟩ => ⟨x, trivial⟩
theorem ne_univ_iff_exists_not_mem {α : Type*} (s : Set α) : s ≠ univ ↔ ∃ a, a ∉ s := by
rw [← not_forall, ← eq_univ_iff_forall]
theorem not_subset_iff_exists_mem_not_mem {α : Type*} {s t : Set α} :
¬s ⊆ t ↔ ∃ x, x ∈ s ∧ x ∉ t := by simp [subset_def]
theorem univ_unique [Unique α] : @Set.univ α = {default} :=
Set.ext fun x => iff_of_true trivial <| Subsingleton.elim x default
theorem ssubset_univ_iff : s ⊂ univ ↔ s ≠ univ :=
lt_top_iff_ne_top
instance nontrivial_of_nonempty [Nonempty α] : Nontrivial (Set α) :=
⟨⟨∅, univ, empty_ne_univ⟩⟩
/-! ### Lemmas about union -/
theorem union_def {s₁ s₂ : Set α} : s₁ ∪ s₂ = { a | a ∈ s₁ ∨ a ∈ s₂ } :=
rfl
theorem mem_union_left {x : α} {a : Set α} (b : Set α) : x ∈ a → x ∈ a ∪ b :=
Or.inl
theorem mem_union_right {x : α} {b : Set α} (a : Set α) : x ∈ b → x ∈ a ∪ b :=
Or.inr
theorem mem_or_mem_of_mem_union {x : α} {a b : Set α} (H : x ∈ a ∪ b) : x ∈ a ∨ x ∈ b :=
H
theorem MemUnion.elim {x : α} {a b : Set α} {P : Prop} (H₁ : x ∈ a ∪ b) (H₂ : x ∈ a → P)
(H₃ : x ∈ b → P) : P :=
Or.elim H₁ H₂ H₃
@[simp]
theorem mem_union (x : α) (a b : Set α) : x ∈ a ∪ b ↔ x ∈ a ∨ x ∈ b :=
Iff.rfl
@[simp]
theorem union_self (a : Set α) : a ∪ a = a :=
ext fun _ => or_self_iff
@[simp]
theorem union_empty (a : Set α) : a ∪ ∅ = a :=
ext fun _ => iff_of_eq (or_false _)
@[simp]
theorem empty_union (a : Set α) : ∅ ∪ a = a :=
ext fun _ => iff_of_eq (false_or _)
theorem union_comm (a b : Set α) : a ∪ b = b ∪ a :=
ext fun _ => or_comm
theorem union_assoc (a b c : Set α) : a ∪ b ∪ c = a ∪ (b ∪ c) :=
ext fun _ => or_assoc
instance union_isAssoc : Std.Associative (α := Set α) (· ∪ ·) :=
⟨union_assoc⟩
instance union_isComm : Std.Commutative (α := Set α) (· ∪ ·) :=
⟨union_comm⟩
theorem union_left_comm (s₁ s₂ s₃ : Set α) : s₁ ∪ (s₂ ∪ s₃) = s₂ ∪ (s₁ ∪ s₃) :=
ext fun _ => or_left_comm
theorem union_right_comm (s₁ s₂ s₃ : Set α) : s₁ ∪ s₂ ∪ s₃ = s₁ ∪ s₃ ∪ s₂ :=
ext fun _ => or_right_comm
@[simp]
theorem union_eq_left {s t : Set α} : s ∪ t = s ↔ t ⊆ s :=
sup_eq_left
@[simp]
theorem union_eq_right {s t : Set α} : s ∪ t = t ↔ s ⊆ t :=
sup_eq_right
theorem union_eq_self_of_subset_left {s t : Set α} (h : s ⊆ t) : s ∪ t = t :=
union_eq_right.mpr h
theorem union_eq_self_of_subset_right {s t : Set α} (h : t ⊆ s) : s ∪ t = s :=
union_eq_left.mpr h
@[simp]
theorem subset_union_left {s t : Set α} : s ⊆ s ∪ t := fun _ => Or.inl
@[simp]
theorem subset_union_right {s t : Set α} : t ⊆ s ∪ t := fun _ => Or.inr
theorem union_subset {s t r : Set α} (sr : s ⊆ r) (tr : t ⊆ r) : s ∪ t ⊆ r := fun _ =>
Or.rec (@sr _) (@tr _)
@[simp]
theorem union_subset_iff {s t u : Set α} : s ∪ t ⊆ u ↔ s ⊆ u ∧ t ⊆ u :=
(forall_congr' fun _ => or_imp).trans forall_and
@[gcongr]
theorem union_subset_union {s₁ s₂ t₁ t₂ : Set α} (h₁ : s₁ ⊆ s₂) (h₂ : t₁ ⊆ t₂) :
s₁ ∪ t₁ ⊆ s₂ ∪ t₂ := fun _ => Or.imp (@h₁ _) (@h₂ _)
@[gcongr]
theorem union_subset_union_left {s₁ s₂ : Set α} (t) (h : s₁ ⊆ s₂) : s₁ ∪ t ⊆ s₂ ∪ t :=
union_subset_union h Subset.rfl
@[gcongr]
theorem union_subset_union_right (s) {t₁ t₂ : Set α} (h : t₁ ⊆ t₂) : s ∪ t₁ ⊆ s ∪ t₂ :=
union_subset_union Subset.rfl h
theorem subset_union_of_subset_left {s t : Set α} (h : s ⊆ t) (u : Set α) : s ⊆ t ∪ u :=
h.trans subset_union_left
theorem subset_union_of_subset_right {s u : Set α} (h : s ⊆ u) (t : Set α) : s ⊆ t ∪ u :=
h.trans subset_union_right
theorem union_congr_left (ht : t ⊆ s ∪ u) (hu : u ⊆ s ∪ t) : s ∪ t = s ∪ u :=
sup_congr_left ht hu
theorem union_congr_right (hs : s ⊆ t ∪ u) (ht : t ⊆ s ∪ u) : s ∪ u = t ∪ u :=
sup_congr_right hs ht
theorem union_eq_union_iff_left : s ∪ t = s ∪ u ↔ t ⊆ s ∪ u ∧ u ⊆ s ∪ t :=
sup_eq_sup_iff_left
theorem union_eq_union_iff_right : s ∪ u = t ∪ u ↔ s ⊆ t ∪ u ∧ t ⊆ s ∪ u :=
sup_eq_sup_iff_right
@[simp]
theorem union_empty_iff {s t : Set α} : s ∪ t = ∅ ↔ s = ∅ ∧ t = ∅ := by
simp only [← subset_empty_iff]
exact union_subset_iff
@[simp]
theorem union_univ (s : Set α) : s ∪ univ = univ := sup_top_eq _
@[simp]
theorem univ_union (s : Set α) : univ ∪ s = univ := top_sup_eq _
@[simp]
theorem ssubset_union_left_iff : s ⊂ s ∪ t ↔ ¬ t ⊆ s :=
left_lt_sup
@[simp]
theorem ssubset_union_right_iff : t ⊂ s ∪ t ↔ ¬ s ⊆ t :=
right_lt_sup
/-! ### Lemmas about intersection -/
theorem inter_def {s₁ s₂ : Set α} : s₁ ∩ s₂ = { a | a ∈ s₁ ∧ a ∈ s₂ } :=
rfl
@[simp, mfld_simps]
theorem mem_inter_iff (x : α) (a b : Set α) : x ∈ a ∩ b ↔ x ∈ a ∧ x ∈ b :=
Iff.rfl
theorem mem_inter {x : α} {a b : Set α} (ha : x ∈ a) (hb : x ∈ b) : x ∈ a ∩ b :=
⟨ha, hb⟩
theorem mem_of_mem_inter_left {x : α} {a b : Set α} (h : x ∈ a ∩ b) : x ∈ a :=
h.left
theorem mem_of_mem_inter_right {x : α} {a b : Set α} (h : x ∈ a ∩ b) : x ∈ b :=
h.right
@[simp]
theorem inter_self (a : Set α) : a ∩ a = a :=
ext fun _ => and_self_iff
@[simp]
theorem inter_empty (a : Set α) : a ∩ ∅ = ∅ :=
ext fun _ => iff_of_eq (and_false _)
@[simp]
theorem empty_inter (a : Set α) : ∅ ∩ a = ∅ :=
ext fun _ => iff_of_eq (false_and _)
theorem inter_comm (a b : Set α) : a ∩ b = b ∩ a :=
ext fun _ => and_comm
theorem inter_assoc (a b c : Set α) : a ∩ b ∩ c = a ∩ (b ∩ c) :=
ext fun _ => and_assoc
instance inter_isAssoc : Std.Associative (α := Set α) (· ∩ ·) :=
⟨inter_assoc⟩
instance inter_isComm : Std.Commutative (α := Set α) (· ∩ ·) :=
⟨inter_comm⟩
theorem inter_left_comm (s₁ s₂ s₃ : Set α) : s₁ ∩ (s₂ ∩ s₃) = s₂ ∩ (s₁ ∩ s₃) :=
ext fun _ => and_left_comm
theorem inter_right_comm (s₁ s₂ s₃ : Set α) : s₁ ∩ s₂ ∩ s₃ = s₁ ∩ s₃ ∩ s₂ :=
ext fun _ => and_right_comm
@[simp, mfld_simps]
theorem inter_subset_left {s t : Set α} : s ∩ t ⊆ s := fun _ => And.left
@[simp]
theorem inter_subset_right {s t : Set α} : s ∩ t ⊆ t := fun _ => And.right
theorem subset_inter {s t r : Set α} (rs : r ⊆ s) (rt : r ⊆ t) : r ⊆ s ∩ t := fun _ h =>
⟨rs h, rt h⟩
@[simp]
theorem subset_inter_iff {s t r : Set α} : r ⊆ s ∩ t ↔ r ⊆ s ∧ r ⊆ t :=
(forall_congr' fun _ => imp_and).trans forall_and
@[simp] lemma inter_eq_left : s ∩ t = s ↔ s ⊆ t := inf_eq_left
@[simp] lemma inter_eq_right : s ∩ t = t ↔ t ⊆ s := inf_eq_right
@[simp] lemma left_eq_inter : s = s ∩ t ↔ s ⊆ t := left_eq_inf
@[simp] lemma right_eq_inter : t = s ∩ t ↔ t ⊆ s := right_eq_inf
theorem inter_eq_self_of_subset_left {s t : Set α} : s ⊆ t → s ∩ t = s :=
inter_eq_left.mpr
theorem inter_eq_self_of_subset_right {s t : Set α} : t ⊆ s → s ∩ t = t :=
inter_eq_right.mpr
theorem inter_congr_left (ht : s ∩ u ⊆ t) (hu : s ∩ t ⊆ u) : s ∩ t = s ∩ u :=
inf_congr_left ht hu
theorem inter_congr_right (hs : t ∩ u ⊆ s) (ht : s ∩ u ⊆ t) : s ∩ u = t ∩ u :=
inf_congr_right hs ht
theorem inter_eq_inter_iff_left : s ∩ t = s ∩ u ↔ s ∩ u ⊆ t ∧ s ∩ t ⊆ u :=
inf_eq_inf_iff_left
theorem inter_eq_inter_iff_right : s ∩ u = t ∩ u ↔ t ∩ u ⊆ s ∧ s ∩ u ⊆ t :=
inf_eq_inf_iff_right
@[simp, mfld_simps]
theorem inter_univ (a : Set α) : a ∩ univ = a := inf_top_eq _
@[simp, mfld_simps]
theorem univ_inter (a : Set α) : univ ∩ a = a := top_inf_eq _
@[gcongr]
theorem inter_subset_inter {s₁ s₂ t₁ t₂ : Set α} (h₁ : s₁ ⊆ t₁) (h₂ : s₂ ⊆ t₂) :
s₁ ∩ s₂ ⊆ t₁ ∩ t₂ := fun _ => And.imp (@h₁ _) (@h₂ _)
@[gcongr]
theorem inter_subset_inter_left {s t : Set α} (u : Set α) (H : s ⊆ t) : s ∩ u ⊆ t ∩ u :=
inter_subset_inter H Subset.rfl
@[gcongr]
theorem inter_subset_inter_right {s t : Set α} (u : Set α) (H : s ⊆ t) : u ∩ s ⊆ u ∩ t :=
inter_subset_inter Subset.rfl H
theorem union_inter_cancel_left {s t : Set α} : (s ∪ t) ∩ s = s :=
inter_eq_self_of_subset_right subset_union_left
theorem union_inter_cancel_right {s t : Set α} : (s ∪ t) ∩ t = t :=
inter_eq_self_of_subset_right subset_union_right
theorem inter_setOf_eq_sep (s : Set α) (p : α → Prop) : s ∩ {a | p a} = {a ∈ s | p a} :=
rfl
theorem setOf_inter_eq_sep (p : α → Prop) (s : Set α) : {a | p a} ∩ s = {a ∈ s | p a} :=
inter_comm _ _
@[simp]
theorem inter_ssubset_right_iff : s ∩ t ⊂ t ↔ ¬ t ⊆ s :=
inf_lt_right
@[simp]
theorem inter_ssubset_left_iff : s ∩ t ⊂ s ↔ ¬ s ⊆ t :=
inf_lt_left
/-! ### Distributivity laws -/
theorem inter_union_distrib_left (s t u : Set α) : s ∩ (t ∪ u) = s ∩ t ∪ s ∩ u :=
inf_sup_left _ _ _
theorem union_inter_distrib_right (s t u : Set α) : (s ∪ t) ∩ u = s ∩ u ∪ t ∩ u :=
inf_sup_right _ _ _
theorem union_inter_distrib_left (s t u : Set α) : s ∪ t ∩ u = (s ∪ t) ∩ (s ∪ u) :=
sup_inf_left _ _ _
theorem inter_union_distrib_right (s t u : Set α) : s ∩ t ∪ u = (s ∪ u) ∩ (t ∪ u) :=
sup_inf_right _ _ _
theorem union_union_distrib_left (s t u : Set α) : s ∪ (t ∪ u) = s ∪ t ∪ (s ∪ u) :=
sup_sup_distrib_left _ _ _
theorem union_union_distrib_right (s t u : Set α) : s ∪ t ∪ u = s ∪ u ∪ (t ∪ u) :=
sup_sup_distrib_right _ _ _
theorem inter_inter_distrib_left (s t u : Set α) : s ∩ (t ∩ u) = s ∩ t ∩ (s ∩ u) :=
inf_inf_distrib_left _ _ _
theorem inter_inter_distrib_right (s t u : Set α) : s ∩ t ∩ u = s ∩ u ∩ (t ∩ u) :=
inf_inf_distrib_right _ _ _
theorem union_union_union_comm (s t u v : Set α) : s ∪ t ∪ (u ∪ v) = s ∪ u ∪ (t ∪ v) :=
sup_sup_sup_comm _ _ _ _
theorem inter_inter_inter_comm (s t u v : Set α) : s ∩ t ∩ (u ∩ v) = s ∩ u ∩ (t ∩ v) :=
inf_inf_inf_comm _ _ _ _
/-! ### Lemmas about sets defined as `{x ∈ s | p x}`. -/
section Sep
variable {p q : α → Prop} {x : α}
theorem mem_sep (xs : x ∈ s) (px : p x) : x ∈ { x ∈ s | p x } :=
⟨xs, px⟩
@[simp]
theorem sep_mem_eq : { x ∈ s | x ∈ t } = s ∩ t :=
rfl
@[simp]
theorem mem_sep_iff : x ∈ { x ∈ s | p x } ↔ x ∈ s ∧ p x :=
Iff.rfl
theorem sep_ext_iff : { x ∈ s | p x } = { x ∈ s | q x } ↔ ∀ x ∈ s, p x ↔ q x := by
simp_rw [Set.ext_iff, mem_sep_iff, and_congr_right_iff]
theorem sep_eq_of_subset (h : s ⊆ t) : { x ∈ t | x ∈ s } = s :=
inter_eq_self_of_subset_right h
@[simp]
theorem sep_subset (s : Set α) (p : α → Prop) : { x ∈ s | p x } ⊆ s := fun _ => And.left
@[simp]
theorem sep_eq_self_iff_mem_true : { x ∈ s | p x } = s ↔ ∀ x ∈ s, p x := by
simp_rw [Set.ext_iff, mem_sep_iff, and_iff_left_iff_imp]
@[simp]
theorem sep_eq_empty_iff_mem_false : { x ∈ s | p x } = ∅ ↔ ∀ x ∈ s, ¬p x := by
simp_rw [Set.ext_iff, mem_sep_iff, mem_empty_iff_false, iff_false, not_and]
theorem sep_true : { x ∈ s | True } = s :=
inter_univ s
theorem sep_false : { x ∈ s | False } = ∅ :=
inter_empty s
theorem sep_empty (p : α → Prop) : { x ∈ (∅ : Set α) | p x } = ∅ :=
empty_inter {x | p x}
theorem sep_univ : { x ∈ (univ : Set α) | p x } = { x | p x } :=
univ_inter {x | p x}
@[simp]
theorem sep_union : { x | (x ∈ s ∨ x ∈ t) ∧ p x } = { x ∈ s | p x } ∪ { x ∈ t | p x } :=
union_inter_distrib_right { x | x ∈ s } { x | x ∈ t } p
@[simp]
theorem sep_inter : { x | (x ∈ s ∧ x ∈ t) ∧ p x } = { x ∈ s | p x } ∩ { x ∈ t | p x } :=
inter_inter_distrib_right s t {x | p x}
@[simp]
theorem sep_and : { x ∈ s | p x ∧ q x } = { x ∈ s | p x } ∩ { x ∈ s | q x } :=
inter_inter_distrib_left s {x | p x} {x | q x}
@[simp]
theorem sep_or : { x ∈ s | p x ∨ q x } = { x ∈ s | p x } ∪ { x ∈ s | q x } :=
inter_union_distrib_left s p q
@[simp]
theorem sep_setOf : { x ∈ { y | p y } | q x } = { x | p x ∧ q x } :=
rfl
end Sep
/-- See also `Set.sdiff_inter_right_comm`. -/
lemma inter_diff_assoc (a b c : Set α) : (a ∩ b) \ c = a ∩ (b \ c) := inf_sdiff_assoc ..
/-- See also `Set.inter_diff_assoc`. -/
lemma sdiff_inter_right_comm (s t u : Set α) : s \ t ∩ u = (s ∩ u) \ t := sdiff_inf_right_comm ..
lemma inter_sdiff_left_comm (s t u : Set α) : s ∩ (t \ u) = t ∩ (s \ u) := inf_sdiff_left_comm ..
theorem diff_union_diff_cancel (hts : t ⊆ s) (hut : u ⊆ t) : s \ t ∪ t \ u = s \ u :=
sdiff_sup_sdiff_cancel hts hut
/-- A version of `diff_union_diff_cancel` with more general hypotheses. -/
theorem diff_union_diff_cancel' (hi : s ∩ u ⊆ t) (hu : t ⊆ s ∪ u) : (s \ t) ∪ (t \ u) = s \ u :=
sdiff_sup_sdiff_cancel' hi hu
theorem diff_diff_eq_sdiff_union (h : u ⊆ s) : s \ (t \ u) = s \ t ∪ u := sdiff_sdiff_eq_sdiff_sup h
theorem inter_diff_distrib_left (s t u : Set α) : s ∩ (t \ u) = (s ∩ t) \ (s ∩ u) :=
inf_sdiff_distrib_left _ _ _
theorem inter_diff_distrib_right (s t u : Set α) : (s \ t) ∩ u = (s ∩ u) \ (t ∩ u) :=
inf_sdiff_distrib_right _ _ _
theorem diff_inter_distrib_right (s t r : Set α) : (t ∩ r) \ s = (t \ s) ∩ (r \ s) :=
inf_sdiff
/-! ### Lemmas about complement -/
theorem compl_def (s : Set α) : sᶜ = { x | x ∉ s } :=
rfl
theorem mem_compl {s : Set α} {x : α} (h : x ∉ s) : x ∈ sᶜ :=
h
theorem compl_setOf {α} (p : α → Prop) : { a | p a }ᶜ = { a | ¬p a } :=
rfl
theorem not_mem_of_mem_compl {s : Set α} {x : α} (h : x ∈ sᶜ) : x ∉ s :=
h
theorem not_mem_compl_iff {x : α} : x ∉ sᶜ ↔ x ∈ s :=
not_not
@[simp]
theorem inter_compl_self (s : Set α) : s ∩ sᶜ = ∅ :=
inf_compl_eq_bot
@[simp]
theorem compl_inter_self (s : Set α) : sᶜ ∩ s = ∅ :=
compl_inf_eq_bot
@[simp]
theorem compl_empty : (∅ : Set α)ᶜ = univ :=
compl_bot
@[simp]
theorem compl_union (s t : Set α) : (s ∪ t)ᶜ = sᶜ ∩ tᶜ :=
compl_sup
theorem compl_inter (s t : Set α) : (s ∩ t)ᶜ = sᶜ ∪ tᶜ :=
compl_inf
@[simp]
theorem compl_univ : (univ : Set α)ᶜ = ∅ :=
compl_top
@[simp]
theorem compl_empty_iff {s : Set α} : sᶜ = ∅ ↔ s = univ :=
compl_eq_bot
@[simp]
theorem compl_univ_iff {s : Set α} : sᶜ = univ ↔ s = ∅ :=
compl_eq_top
theorem compl_ne_univ : sᶜ ≠ univ ↔ s.Nonempty :=
compl_univ_iff.not.trans nonempty_iff_ne_empty.symm
lemma inl_compl_union_inr_compl {α β : Type*} {s : Set α} {t : Set β} :
Sum.inl '' sᶜ ∪ Sum.inr '' tᶜ = (Sum.inl '' s ∪ Sum.inr '' t)ᶜ := by
rw [compl_union]
aesop
theorem nonempty_compl : sᶜ.Nonempty ↔ s ≠ univ :=
(ne_univ_iff_exists_not_mem s).symm
theorem union_eq_compl_compl_inter_compl (s t : Set α) : s ∪ t = (sᶜ ∩ tᶜ)ᶜ :=
ext fun _ => or_iff_not_and_not
theorem inter_eq_compl_compl_union_compl (s t : Set α) : s ∩ t = (sᶜ ∪ tᶜ)ᶜ :=
ext fun _ => and_iff_not_or_not
@[simp]
theorem union_compl_self (s : Set α) : s ∪ sᶜ = univ :=
eq_univ_iff_forall.2 fun _ => em _
@[simp]
theorem compl_union_self (s : Set α) : sᶜ ∪ s = univ := by rw [union_comm, union_compl_self]
theorem compl_subset_comm : sᶜ ⊆ t ↔ tᶜ ⊆ s :=
@compl_le_iff_compl_le _ s _ _
theorem subset_compl_comm : s ⊆ tᶜ ↔ t ⊆ sᶜ :=
@le_compl_iff_le_compl _ _ _ t
@[simp]
theorem compl_subset_compl : sᶜ ⊆ tᶜ ↔ t ⊆ s :=
@compl_le_compl_iff_le (Set α) _ _ _
@[gcongr] theorem compl_subset_compl_of_subset (h : t ⊆ s) : sᶜ ⊆ tᶜ := compl_subset_compl.2 h
theorem subset_union_compl_iff_inter_subset {s t u : Set α} : s ⊆ t ∪ uᶜ ↔ s ∩ u ⊆ t :=
(@isCompl_compl _ u _).le_sup_right_iff_inf_left_le
theorem compl_subset_iff_union {s t : Set α} : sᶜ ⊆ t ↔ s ∪ t = univ :=
Iff.symm <| eq_univ_iff_forall.trans <| forall_congr' fun _ => or_iff_not_imp_left
theorem inter_subset (a b c : Set α) : a ∩ b ⊆ c ↔ a ⊆ bᶜ ∪ c :=
forall_congr' fun _ => and_imp.trans <| imp_congr_right fun _ => imp_iff_not_or
theorem inter_compl_nonempty_iff {s t : Set α} : (s ∩ tᶜ).Nonempty ↔ ¬s ⊆ t :=
(not_subset.trans <| exists_congr fun x => by simp [mem_compl]).symm
/-! ### Lemmas about set difference -/
theorem not_mem_diff_of_mem {s t : Set α} {x : α} (hx : x ∈ t) : x ∉ s \ t := fun h => h.2 hx
theorem mem_of_mem_diff {s t : Set α} {x : α} (h : x ∈ s \ t) : x ∈ s :=
h.left
theorem not_mem_of_mem_diff {s t : Set α} {x : α} (h : x ∈ s \ t) : x ∉ t :=
h.right
theorem diff_eq_compl_inter {s t : Set α} : s \ t = tᶜ ∩ s := by rw [diff_eq, inter_comm]
theorem diff_nonempty {s t : Set α} : (s \ t).Nonempty ↔ ¬s ⊆ t :=
inter_compl_nonempty_iff
theorem diff_subset {s t : Set α} : s \ t ⊆ s := show s \ t ≤ s from sdiff_le
theorem diff_subset_compl (s t : Set α) : s \ t ⊆ tᶜ :=
diff_eq_compl_inter ▸ inter_subset_left
theorem union_diff_cancel' {s t u : Set α} (h₁ : s ⊆ t) (h₂ : t ⊆ u) : t ∪ u \ s = u :=
sup_sdiff_cancel' h₁ h₂
theorem union_diff_cancel {s t : Set α} (h : s ⊆ t) : s ∪ t \ s = t :=
sup_sdiff_cancel_right h
theorem union_diff_cancel_left {s t : Set α} (h : s ∩ t ⊆ ∅) : (s ∪ t) \ s = t :=
Disjoint.sup_sdiff_cancel_left <| disjoint_iff_inf_le.2 h
theorem union_diff_cancel_right {s t : Set α} (h : s ∩ t ⊆ ∅) : (s ∪ t) \ t = s :=
Disjoint.sup_sdiff_cancel_right <| disjoint_iff_inf_le.2 h
@[simp]
theorem union_diff_left {s t : Set α} : (s ∪ t) \ s = t \ s :=
sup_sdiff_left_self
@[simp]
theorem union_diff_right {s t : Set α} : (s ∪ t) \ t = s \ t :=
sup_sdiff_right_self
theorem union_diff_distrib {s t u : Set α} : (s ∪ t) \ u = s \ u ∪ t \ u :=
sup_sdiff
@[simp]
theorem inter_diff_self (a b : Set α) : a ∩ (b \ a) = ∅ :=
inf_sdiff_self_right
@[simp]
theorem inter_union_diff (s t : Set α) : s ∩ t ∪ s \ t = s :=
sup_inf_sdiff s t
@[simp]
theorem diff_union_inter (s t : Set α) : s \ t ∪ s ∩ t = s := by
rw [union_comm]
exact sup_inf_sdiff _ _
@[simp]
theorem inter_union_compl (s t : Set α) : s ∩ t ∪ s ∩ tᶜ = s :=
inter_union_diff _ _
@[gcongr]
theorem diff_subset_diff {s₁ s₂ t₁ t₂ : Set α} : s₁ ⊆ s₂ → t₂ ⊆ t₁ → s₁ \ t₁ ⊆ s₂ \ t₂ :=
show s₁ ≤ s₂ → t₂ ≤ t₁ → s₁ \ t₁ ≤ s₂ \ t₂ from sdiff_le_sdiff
@[gcongr]
theorem diff_subset_diff_left {s₁ s₂ t : Set α} (h : s₁ ⊆ s₂) : s₁ \ t ⊆ s₂ \ t :=
sdiff_le_sdiff_right ‹s₁ ≤ s₂›
@[gcongr]
theorem diff_subset_diff_right {s t u : Set α} (h : t ⊆ u) : s \ u ⊆ s \ t :=
sdiff_le_sdiff_left ‹t ≤ u›
theorem diff_subset_diff_iff_subset {r : Set α} (hs : s ⊆ r) (ht : t ⊆ r) :
r \ s ⊆ r \ t ↔ t ⊆ s :=
sdiff_le_sdiff_iff_le hs ht
theorem compl_eq_univ_diff (s : Set α) : sᶜ = univ \ s :=
top_sdiff.symm
@[simp]
theorem empty_diff (s : Set α) : (∅ \ s : Set α) = ∅ :=
bot_sdiff
theorem diff_eq_empty {s t : Set α} : s \ t = ∅ ↔ s ⊆ t :=
sdiff_eq_bot_iff
@[simp]
theorem diff_empty {s : Set α} : s \ ∅ = s :=
sdiff_bot
@[simp]
theorem diff_univ (s : Set α) : s \ univ = ∅ :=
diff_eq_empty.2 (subset_univ s)
theorem diff_diff {u : Set α} : (s \ t) \ u = s \ (t ∪ u) :=
sdiff_sdiff_left
-- the following statement contains parentheses to help the reader
theorem diff_diff_comm {s t u : Set α} : (s \ t) \ u = (s \ u) \ t :=
sdiff_sdiff_comm
theorem diff_subset_iff {s t u : Set α} : s \ t ⊆ u ↔ s ⊆ t ∪ u :=
show s \ t ≤ u ↔ s ≤ t ∪ u from sdiff_le_iff
theorem subset_diff_union (s t : Set α) : s ⊆ s \ t ∪ t :=
show s ≤ s \ t ∪ t from le_sdiff_sup
theorem diff_union_of_subset {s t : Set α} (h : t ⊆ s) : s \ t ∪ t = s :=
Subset.antisymm (union_subset diff_subset h) (subset_diff_union _ _)
theorem diff_subset_comm {s t u : Set α} : s \ t ⊆ u ↔ s \ u ⊆ t :=
show s \ t ≤ u ↔ s \ u ≤ t from sdiff_le_comm
theorem diff_inter {s t u : Set α} : s \ (t ∩ u) = s \ t ∪ s \ u :=
sdiff_inf
theorem diff_inter_diff : s \ t ∩ (s \ u) = s \ (t ∪ u) :=
sdiff_sup.symm
theorem diff_compl : s \ tᶜ = s ∩ t :=
sdiff_compl
theorem compl_diff : (t \ s)ᶜ = s ∪ tᶜ :=
Eq.trans compl_sdiff himp_eq
theorem diff_diff_right {s t u : Set α} : s \ (t \ u) = s \ t ∪ s ∩ u :=
sdiff_sdiff_right'
theorem inter_diff_right_comm : (s ∩ t) \ u = s \ u ∩ t := by
rw [diff_eq, diff_eq, inter_right_comm]
theorem diff_inter_right_comm : (s \ u) ∩ t = (s ∩ t) \ u := by
rw [diff_eq, diff_eq, inter_right_comm]
@[simp]
theorem union_diff_self {s t : Set α} : s ∪ t \ s = s ∪ t :=
sup_sdiff_self _ _
@[simp]
theorem diff_union_self {s t : Set α} : s \ t ∪ t = s ∪ t :=
sdiff_sup_self _ _
@[simp]
theorem diff_inter_self {a b : Set α} : b \ a ∩ a = ∅ :=
inf_sdiff_self_left
@[simp]
theorem diff_inter_self_eq_diff {s t : Set α} : s \ (t ∩ s) = s \ t :=
sdiff_inf_self_right _ _
@[simp]
theorem diff_self_inter {s t : Set α} : s \ (s ∩ t) = s \ t :=
sdiff_inf_self_left _ _
theorem diff_self {s : Set α} : s \ s = ∅ :=
sdiff_self
theorem diff_diff_right_self (s t : Set α) : s \ (s \ t) = s ∩ t :=
sdiff_sdiff_right_self
theorem diff_diff_cancel_left {s t : Set α} (h : s ⊆ t) : t \ (t \ s) = s :=
sdiff_sdiff_eq_self h
theorem union_eq_diff_union_diff_union_inter (s t : Set α) : s ∪ t = s \ t ∪ t \ s ∪ s ∩ t :=
sup_eq_sdiff_sup_sdiff_sup_inf
/-! ### Powerset -/
theorem mem_powerset {x s : Set α} (h : x ⊆ s) : x ∈ 𝒫 s := @h
theorem subset_of_mem_powerset {x s : Set α} (h : x ∈ 𝒫 s) : x ⊆ s := @h
@[simp]
theorem mem_powerset_iff (x s : Set α) : x ∈ 𝒫 s ↔ x ⊆ s :=
Iff.rfl
theorem powerset_inter (s t : Set α) : 𝒫(s ∩ t) = 𝒫 s ∩ 𝒫 t :=
ext fun _ => subset_inter_iff
@[simp]
theorem powerset_mono : 𝒫 s ⊆ 𝒫 t ↔ s ⊆ t :=
⟨fun h => @h _ (fun _ h => h), fun h _ hu _ ha => h (hu ha)⟩
theorem monotone_powerset : Monotone (powerset : Set α → Set (Set α)) := fun _ _ => powerset_mono.2
@[simp]
theorem powerset_nonempty : (𝒫 s).Nonempty :=
⟨∅, fun _ h => empty_subset s h⟩
@[simp]
theorem powerset_empty : 𝒫(∅ : Set α) = {∅} :=
ext fun _ => subset_empty_iff
@[simp]
theorem powerset_univ : 𝒫(univ : Set α) = univ :=
eq_univ_of_forall subset_univ
/-! ### Sets defined as an if-then-else -/
@[deprecated _root_.mem_dite (since := "2025-01-30")]
protected theorem mem_dite (p : Prop) [Decidable p] (s : p → Set α) (t : ¬ p → Set α) (x : α) :
(x ∈ if h : p then s h else t h) ↔ (∀ h : p, x ∈ s h) ∧ ∀ h : ¬p, x ∈ t h :=
_root_.mem_dite
theorem mem_dite_univ_right (p : Prop) [Decidable p] (t : p → Set α) (x : α) :
(x ∈ if h : p then t h else univ) ↔ ∀ h : p, x ∈ t h := by
simp [mem_dite]
@[simp]
theorem mem_ite_univ_right (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p t Set.univ ↔ p → x ∈ t :=
mem_dite_univ_right p (fun _ => t) x
theorem mem_dite_univ_left (p : Prop) [Decidable p] (t : ¬p → Set α) (x : α) :
(x ∈ if h : p then univ else t h) ↔ ∀ h : ¬p, x ∈ t h := by
split_ifs <;> simp_all
@[simp]
theorem mem_ite_univ_left (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p Set.univ t ↔ ¬p → x ∈ t :=
mem_dite_univ_left p (fun _ => t) x
theorem mem_dite_empty_right (p : Prop) [Decidable p] (t : p → Set α) (x : α) :
(x ∈ if h : p then t h else ∅) ↔ ∃ h : p, x ∈ t h := by
simp only [mem_dite, mem_empty_iff_false, imp_false, not_not]
exact ⟨fun h => ⟨h.2, h.1 h.2⟩, fun ⟨h₁, h₂⟩ => ⟨fun _ => h₂, h₁⟩⟩
@[simp]
theorem mem_ite_empty_right (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p t ∅ ↔ p ∧ x ∈ t :=
(mem_dite_empty_right p (fun _ => t) x).trans (by simp)
theorem mem_dite_empty_left (p : Prop) [Decidable p] (t : ¬p → Set α) (x : α) :
(x ∈ if h : p then ∅ else t h) ↔ ∃ h : ¬p, x ∈ t h := by
simp only [mem_dite, mem_empty_iff_false, imp_false]
exact ⟨fun h => ⟨h.1, h.2 h.1⟩, fun ⟨h₁, h₂⟩ => ⟨fun h => h₁ h, fun _ => h₂⟩⟩
@[simp]
theorem mem_ite_empty_left (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p ∅ t ↔ ¬p ∧ x ∈ t :=
(mem_dite_empty_left p (fun _ => t) x).trans (by simp)
/-! ### If-then-else for sets -/
/-- `ite` for sets: `Set.ite t s s' ∩ t = s ∩ t`, `Set.ite t s s' ∩ tᶜ = s' ∩ tᶜ`.
Defined as `s ∩ t ∪ s' \ t`. -/
protected def ite (t s s' : Set α) : Set α :=
s ∩ t ∪ s' \ t
@[simp]
theorem ite_inter_self (t s s' : Set α) : t.ite s s' ∩ t = s ∩ t := by
rw [Set.ite, union_inter_distrib_right, diff_inter_self, inter_assoc, inter_self, union_empty]
@[simp]
theorem ite_compl (t s s' : Set α) : tᶜ.ite s s' = t.ite s' s := by
rw [Set.ite, Set.ite, diff_compl, union_comm, diff_eq]
@[simp]
theorem ite_inter_compl_self (t s s' : Set α) : t.ite s s' ∩ tᶜ = s' ∩ tᶜ := by
rw [← ite_compl, ite_inter_self]
@[simp]
theorem ite_diff_self (t s s' : Set α) : t.ite s s' \ t = s' \ t :=
ite_inter_compl_self t s s'
@[simp]
theorem ite_same (t s : Set α) : t.ite s s = s :=
inter_union_diff _ _
@[simp]
theorem ite_left (s t : Set α) : s.ite s t = s ∪ t := by simp [Set.ite]
@[simp]
theorem ite_right (s t : Set α) : s.ite t s = t ∩ s := by simp [Set.ite]
@[simp]
theorem ite_empty (s s' : Set α) : Set.ite ∅ s s' = s' := by simp [Set.ite]
@[simp]
theorem ite_univ (s s' : Set α) : Set.ite univ s s' = s := by simp [Set.ite]
@[simp]
theorem ite_empty_left (t s : Set α) : t.ite ∅ s = s \ t := by simp [Set.ite]
@[simp]
theorem ite_empty_right (t s : Set α) : t.ite s ∅ = s ∩ t := by simp [Set.ite]
theorem ite_mono (t : Set α) {s₁ s₁' s₂ s₂' : Set α} (h : s₁ ⊆ s₂) (h' : s₁' ⊆ s₂') :
t.ite s₁ s₁' ⊆ t.ite s₂ s₂' :=
union_subset_union (inter_subset_inter_left _ h) (inter_subset_inter_left _ h')
theorem ite_subset_union (t s s' : Set α) : t.ite s s' ⊆ s ∪ s' :=
union_subset_union inter_subset_left diff_subset
theorem inter_subset_ite (t s s' : Set α) : s ∩ s' ⊆ t.ite s s' :=
ite_same t (s ∩ s') ▸ ite_mono _ inter_subset_left inter_subset_right
theorem ite_inter_inter (t s₁ s₂ s₁' s₂' : Set α) :
t.ite (s₁ ∩ s₂) (s₁' ∩ s₂') = t.ite s₁ s₁' ∩ t.ite s₂ s₂' := by
ext x
simp only [Set.ite, Set.mem_inter_iff, Set.mem_diff, Set.mem_union]
tauto
theorem ite_inter (t s₁ s₂ s : Set α) : t.ite (s₁ ∩ s) (s₂ ∩ s) = t.ite s₁ s₂ ∩ s := by
rw [ite_inter_inter, ite_same]
theorem ite_inter_of_inter_eq (t : Set α) {s₁ s₂ s : Set α} (h : s₁ ∩ s = s₂ ∩ s) :
t.ite s₁ s₂ ∩ s = s₁ ∩ s := by rw [← ite_inter, ← h, ite_same]
theorem subset_ite {t s s' u : Set α} : u ⊆ t.ite s s' ↔ u ∩ t ⊆ s ∧ u \ t ⊆ s' := by
simp only [subset_def, ← forall_and]
refine forall_congr' fun x => ?_
by_cases hx : x ∈ t <;> simp [*, Set.ite]
theorem ite_eq_of_subset_left (t : Set α) {s₁ s₂ : Set α} (h : s₁ ⊆ s₂) :
t.ite s₁ s₂ = s₁ ∪ (s₂ \ t) := by
ext x
by_cases hx : x ∈ t <;> simp [*, Set.ite, or_iff_right_of_imp (@h x)]
theorem ite_eq_of_subset_right (t : Set α) {s₁ s₂ : Set α} (h : s₂ ⊆ s₁) :
t.ite s₁ s₂ = (s₁ ∩ t) ∪ s₂ := by
ext x
by_cases hx : x ∈ t <;> simp [*, Set.ite, or_iff_left_of_imp (@h x)]
end Set
open Set
namespace Function
variable {α : Type*} {β : Type*}
theorem Injective.nonempty_apply_iff {f : Set α → Set β} (hf : Injective f) (h2 : f ∅ = ∅)
{s : Set α} : (f s).Nonempty ↔ s.Nonempty := by
rw [nonempty_iff_ne_empty, ← h2, nonempty_iff_ne_empty, hf.ne_iff]
end Function
namespace Subsingleton
variable {α : Type*} [Subsingleton α]
theorem eq_univ_of_nonempty {s : Set α} : s.Nonempty → s = univ := fun ⟨x, hx⟩ =>
eq_univ_of_forall fun y => Subsingleton.elim x y ▸ hx
@[elab_as_elim]
theorem set_cases {p : Set α → Prop} (h0 : p ∅) (h1 : p univ) (s) : p s :=
(s.eq_empty_or_nonempty.elim fun h => h.symm ▸ h0) fun h => (eq_univ_of_nonempty h).symm ▸ h1
theorem mem_iff_nonempty {α : Type*} [Subsingleton α] {s : Set α} {x : α} : x ∈ s ↔ s.Nonempty :=
⟨fun hx => ⟨x, hx⟩, fun ⟨y, hy⟩ => Subsingleton.elim y x ▸ hy⟩
end Subsingleton
/-! ### Decidability instances for sets -/
namespace Set
variable {α : Type u} (s t : Set α) (a b : α)
instance decidableSdiff [Decidable (a ∈ s)] [Decidable (a ∈ t)] : Decidable (a ∈ s \ t) :=
inferInstanceAs (Decidable (a ∈ s ∧ a ∉ t))
instance decidableInter [Decidable (a ∈ s)] [Decidable (a ∈ t)] : Decidable (a ∈ s ∩ t) :=
inferInstanceAs (Decidable (a ∈ s ∧ a ∈ t))
instance decidableUnion [Decidable (a ∈ s)] [Decidable (a ∈ t)] : Decidable (a ∈ s ∪ t) :=
inferInstanceAs (Decidable (a ∈ s ∨ a ∈ t))
instance decidableCompl [Decidable (a ∈ s)] : Decidable (a ∈ sᶜ) :=
inferInstanceAs (Decidable (a ∉ s))
|
instance decidableEmptyset : Decidable (a ∈ (∅ : Set α)) := Decidable.isFalse (by simp)
instance decidableUniv : Decidable (a ∈ univ) := Decidable.isTrue (by simp)
| Mathlib/Data/Set/Basic.lean | 1,446 | 1,449 |
/-
Copyright (c) 2019 Zhouhang Zhou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Zhouhang Zhou, Sébastien Gouëzel, Frédéric Dupuis
-/
import Mathlib.Algebra.BigOperators.Field
import Mathlib.Analysis.Complex.Basic
import Mathlib.Analysis.InnerProductSpace.Defs
import Mathlib.GroupTheory.MonoidLocalization.Basic
/-!
# Properties of inner product spaces
This file proves many basic properties of inner product spaces (real or complex).
## Main results
- `inner_mul_inner_self_le`: the Cauchy-Schwartz inequality (one of many variants).
- `norm_inner_eq_norm_iff`: the equality criteion in the Cauchy-Schwartz inequality (also in many
variants).
- `inner_eq_sum_norm_sq_div_four`: the polarization identity.
## Tags
inner product space, Hilbert space, norm
-/
noncomputable section
open RCLike Real Filter Topology ComplexConjugate Finsupp
open LinearMap (BilinForm)
variable {𝕜 E F : Type*} [RCLike 𝕜]
section BasicProperties_Seminormed
open scoped InnerProductSpace
variable [SeminormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [SeminormedAddCommGroup F] [InnerProductSpace ℝ F]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
local postfix:90 "†" => starRingEnd _
export InnerProductSpace (norm_sq_eq_re_inner)
@[simp]
theorem inner_conj_symm (x y : E) : ⟪y, x⟫† = ⟪x, y⟫ :=
InnerProductSpace.conj_inner_symm _ _
theorem real_inner_comm (x y : F) : ⟪y, x⟫_ℝ = ⟪x, y⟫_ℝ :=
@inner_conj_symm ℝ _ _ _ _ x y
theorem inner_eq_zero_symm {x y : E} : ⟪x, y⟫ = 0 ↔ ⟪y, x⟫ = 0 := by
rw [← inner_conj_symm]
exact star_eq_zero
@[simp]
theorem inner_self_im (x : E) : im ⟪x, x⟫ = 0 := by rw [← @ofReal_inj 𝕜, im_eq_conj_sub]; simp
theorem inner_add_left (x y z : E) : ⟪x + y, z⟫ = ⟪x, z⟫ + ⟪y, z⟫ :=
InnerProductSpace.add_left _ _ _
theorem inner_add_right (x y z : E) : ⟪x, y + z⟫ = ⟪x, y⟫ + ⟪x, z⟫ := by
rw [← inner_conj_symm, inner_add_left, RingHom.map_add]
simp only [inner_conj_symm]
theorem inner_re_symm (x y : E) : re ⟪x, y⟫ = re ⟪y, x⟫ := by rw [← inner_conj_symm, conj_re]
theorem inner_im_symm (x y : E) : im ⟪x, y⟫ = -im ⟪y, x⟫ := by rw [← inner_conj_symm, conj_im]
section Algebra
variable {𝕝 : Type*} [CommSemiring 𝕝] [StarRing 𝕝] [Algebra 𝕝 𝕜] [Module 𝕝 E]
[IsScalarTower 𝕝 𝕜 E] [StarModule 𝕝 𝕜]
/-- See `inner_smul_left` for the common special when `𝕜 = 𝕝`. -/
lemma inner_smul_left_eq_star_smul (x y : E) (r : 𝕝) : ⟪r • x, y⟫ = r† • ⟪x, y⟫ := by
rw [← algebraMap_smul 𝕜 r, InnerProductSpace.smul_left, starRingEnd_apply, starRingEnd_apply,
← algebraMap_star_comm, ← smul_eq_mul, algebraMap_smul]
/-- Special case of `inner_smul_left_eq_star_smul` when the acting ring has a trivial star
(eg `ℕ`, `ℤ`, `ℚ≥0`, `ℚ`, `ℝ`). -/
lemma inner_smul_left_eq_smul [TrivialStar 𝕝] (x y : E) (r : 𝕝) : ⟪r • x, y⟫ = r • ⟪x, y⟫ := by
rw [inner_smul_left_eq_star_smul, starRingEnd_apply, star_trivial]
/-- See `inner_smul_right` for the common special when `𝕜 = 𝕝`. -/
lemma inner_smul_right_eq_smul (x y : E) (r : 𝕝) : ⟪x, r • y⟫ = r • ⟪x, y⟫ := by
rw [← inner_conj_symm, inner_smul_left_eq_star_smul, starRingEnd_apply, starRingEnd_apply,
star_smul, star_star, ← starRingEnd_apply, inner_conj_symm]
end Algebra
/-- See `inner_smul_left_eq_star_smul` for the case of a general algebra action. -/
theorem inner_smul_left (x y : E) (r : 𝕜) : ⟪r • x, y⟫ = r† * ⟪x, y⟫ :=
inner_smul_left_eq_star_smul ..
theorem real_inner_smul_left (x y : F) (r : ℝ) : ⟪r • x, y⟫_ℝ = r * ⟪x, y⟫_ℝ :=
inner_smul_left _ _ _
theorem inner_smul_real_left (x y : E) (r : ℝ) : ⟪(r : 𝕜) • x, y⟫ = r • ⟪x, y⟫ := by
rw [inner_smul_left, conj_ofReal, Algebra.smul_def]
/-- See `inner_smul_right_eq_smul` for the case of a general algebra action. -/
theorem inner_smul_right (x y : E) (r : 𝕜) : ⟪x, r • y⟫ = r * ⟪x, y⟫ :=
inner_smul_right_eq_smul ..
theorem real_inner_smul_right (x y : F) (r : ℝ) : ⟪x, r • y⟫_ℝ = r * ⟪x, y⟫_ℝ :=
inner_smul_right _ _ _
theorem inner_smul_real_right (x y : E) (r : ℝ) : ⟪x, (r : 𝕜) • y⟫ = r • ⟪x, y⟫ := by
rw [inner_smul_right, Algebra.smul_def]
/-- The inner product as a sesquilinear form.
Note that in the case `𝕜 = ℝ` this is a bilinear form. -/
@[simps!]
def sesqFormOfInner : E →ₗ[𝕜] E →ₗ⋆[𝕜] 𝕜 :=
LinearMap.mk₂'ₛₗ (RingHom.id 𝕜) (starRingEnd _) (fun x y => ⟪y, x⟫)
(fun _x _y _z => inner_add_right _ _ _) (fun _r _x _y => inner_smul_right _ _ _)
(fun _x _y _z => inner_add_left _ _ _) fun _r _x _y => inner_smul_left _ _ _
/-- The real inner product as a bilinear form.
Note that unlike `sesqFormOfInner`, this does not reverse the order of the arguments. -/
@[simps!]
def bilinFormOfRealInner : BilinForm ℝ F := sesqFormOfInner.flip
/-- An inner product with a sum on the left. -/
theorem sum_inner {ι : Type*} (s : Finset ι) (f : ι → E) (x : E) :
⟪∑ i ∈ s, f i, x⟫ = ∑ i ∈ s, ⟪f i, x⟫ :=
map_sum (sesqFormOfInner (𝕜 := 𝕜) (E := E) x) _ _
/-- An inner product with a sum on the right. -/
theorem inner_sum {ι : Type*} (s : Finset ι) (f : ι → E) (x : E) :
⟪x, ∑ i ∈ s, f i⟫ = ∑ i ∈ s, ⟪x, f i⟫ :=
map_sum (LinearMap.flip sesqFormOfInner x) _ _
/-- An inner product with a sum on the left, `Finsupp` version. -/
protected theorem Finsupp.sum_inner {ι : Type*} (l : ι →₀ 𝕜) (v : ι → E) (x : E) :
⟪l.sum fun (i : ι) (a : 𝕜) => a • v i, x⟫ = l.sum fun (i : ι) (a : 𝕜) => conj a • ⟪v i, x⟫ := by
convert sum_inner (𝕜 := 𝕜) l.support (fun a => l a • v a) x
simp only [inner_smul_left, Finsupp.sum, smul_eq_mul]
/-- An inner product with a sum on the right, `Finsupp` version. -/
protected theorem Finsupp.inner_sum {ι : Type*} (l : ι →₀ 𝕜) (v : ι → E) (x : E) :
⟪x, l.sum fun (i : ι) (a : 𝕜) => a • v i⟫ = l.sum fun (i : ι) (a : 𝕜) => a • ⟪x, v i⟫ := by
convert inner_sum (𝕜 := 𝕜) l.support (fun a => l a • v a) x
simp only [inner_smul_right, Finsupp.sum, smul_eq_mul]
protected theorem DFinsupp.sum_inner {ι : Type*} [DecidableEq ι] {α : ι → Type*}
[∀ i, AddZeroClass (α i)] [∀ (i) (x : α i), Decidable (x ≠ 0)] (f : ∀ i, α i → E)
(l : Π₀ i, α i) (x : E) : ⟪l.sum f, x⟫ = l.sum fun i a => ⟪f i a, x⟫ := by
simp +contextual only [DFinsupp.sum, sum_inner, smul_eq_mul]
protected theorem DFinsupp.inner_sum {ι : Type*} [DecidableEq ι] {α : ι → Type*}
[∀ i, AddZeroClass (α i)] [∀ (i) (x : α i), Decidable (x ≠ 0)] (f : ∀ i, α i → E)
(l : Π₀ i, α i) (x : E) : ⟪x, l.sum f⟫ = l.sum fun i a => ⟪x, f i a⟫ := by
simp +contextual only [DFinsupp.sum, inner_sum, smul_eq_mul]
@[simp]
theorem inner_zero_left (x : E) : ⟪0, x⟫ = 0 := by
rw [← zero_smul 𝕜 (0 : E), inner_smul_left, RingHom.map_zero, zero_mul]
theorem inner_re_zero_left (x : E) : re ⟪0, x⟫ = 0 := by
simp only [inner_zero_left, AddMonoidHom.map_zero]
@[simp]
theorem inner_zero_right (x : E) : ⟪x, 0⟫ = 0 := by
rw [← inner_conj_symm, inner_zero_left, RingHom.map_zero]
theorem inner_re_zero_right (x : E) : re ⟪x, 0⟫ = 0 := by
simp only [inner_zero_right, AddMonoidHom.map_zero]
theorem inner_self_nonneg {x : E} : 0 ≤ re ⟪x, x⟫ :=
PreInnerProductSpace.toCore.re_inner_nonneg x
theorem real_inner_self_nonneg {x : F} : 0 ≤ ⟪x, x⟫_ℝ :=
@inner_self_nonneg ℝ F _ _ _ x
@[simp]
theorem inner_self_ofReal_re (x : E) : (re ⟪x, x⟫ : 𝕜) = ⟪x, x⟫ :=
((RCLike.is_real_TFAE (⟪x, x⟫ : 𝕜)).out 2 3).2 (inner_self_im (𝕜 := 𝕜) x)
theorem inner_self_eq_norm_sq_to_K (x : E) : ⟪x, x⟫ = (‖x‖ : 𝕜) ^ 2 := by
rw [← inner_self_ofReal_re, ← norm_sq_eq_re_inner, ofReal_pow]
theorem inner_self_re_eq_norm (x : E) : re ⟪x, x⟫ = ‖⟪x, x⟫‖ := by
conv_rhs => rw [← inner_self_ofReal_re]
symm
exact norm_of_nonneg inner_self_nonneg
theorem inner_self_ofReal_norm (x : E) : (‖⟪x, x⟫‖ : 𝕜) = ⟪x, x⟫ := by
rw [← inner_self_re_eq_norm]
exact inner_self_ofReal_re _
theorem real_inner_self_abs (x : F) : |⟪x, x⟫_ℝ| = ⟪x, x⟫_ℝ :=
@inner_self_ofReal_norm ℝ F _ _ _ x
theorem norm_inner_symm (x y : E) : ‖⟪x, y⟫‖ = ‖⟪y, x⟫‖ := by rw [← inner_conj_symm, norm_conj]
@[simp]
theorem inner_neg_left (x y : E) : ⟪-x, y⟫ = -⟪x, y⟫ := by
rw [← neg_one_smul 𝕜 x, inner_smul_left]
simp
@[simp]
theorem inner_neg_right (x y : E) : ⟪x, -y⟫ = -⟪x, y⟫ := by
rw [← inner_conj_symm, inner_neg_left]; simp only [RingHom.map_neg, inner_conj_symm]
theorem inner_neg_neg (x y : E) : ⟪-x, -y⟫ = ⟪x, y⟫ := by simp
theorem inner_self_conj (x : E) : ⟪x, x⟫† = ⟪x, x⟫ := inner_conj_symm _ _
theorem inner_sub_left (x y z : E) : ⟪x - y, z⟫ = ⟪x, z⟫ - ⟪y, z⟫ := by
simp [sub_eq_add_neg, inner_add_left]
theorem inner_sub_right (x y z : E) : ⟪x, y - z⟫ = ⟪x, y⟫ - ⟪x, z⟫ := by
simp [sub_eq_add_neg, inner_add_right]
theorem inner_mul_symm_re_eq_norm (x y : E) : re (⟪x, y⟫ * ⟪y, x⟫) = ‖⟪x, y⟫ * ⟪y, x⟫‖ := by
rw [← inner_conj_symm, mul_comm]
exact re_eq_norm_of_mul_conj (inner y x)
/-- Expand `⟪x + y, x + y⟫` -/
theorem inner_add_add_self (x y : E) : ⟪x + y, x + y⟫ = ⟪x, x⟫ + ⟪x, y⟫ + ⟪y, x⟫ + ⟪y, y⟫ := by
simp only [inner_add_left, inner_add_right]; ring
/-- Expand `⟪x + y, x + y⟫_ℝ` -/
theorem real_inner_add_add_self (x y : F) :
⟪x + y, x + y⟫_ℝ = ⟪x, x⟫_ℝ + 2 * ⟪x, y⟫_ℝ + ⟪y, y⟫_ℝ := by
have : ⟪y, x⟫_ℝ = ⟪x, y⟫_ℝ := by rw [← inner_conj_symm]; rfl
simp only [inner_add_add_self, this, add_left_inj]
ring
-- Expand `⟪x - y, x - y⟫`
theorem inner_sub_sub_self (x y : E) : ⟪x - y, x - y⟫ = ⟪x, x⟫ - ⟪x, y⟫ - ⟪y, x⟫ + ⟪y, y⟫ := by
simp only [inner_sub_left, inner_sub_right]; ring
/-- Expand `⟪x - y, x - y⟫_ℝ` -/
theorem real_inner_sub_sub_self (x y : F) :
⟪x - y, x - y⟫_ℝ = ⟪x, x⟫_ℝ - 2 * ⟪x, y⟫_ℝ + ⟪y, y⟫_ℝ := by
have : ⟪y, x⟫_ℝ = ⟪x, y⟫_ℝ := by rw [← inner_conj_symm]; rfl
simp only [inner_sub_sub_self, this, add_left_inj]
ring
/-- Parallelogram law -/
theorem parallelogram_law {x y : E} : ⟪x + y, x + y⟫ + ⟪x - y, x - y⟫ = 2 * (⟪x, x⟫ + ⟪y, y⟫) := by
simp only [inner_add_add_self, inner_sub_sub_self]
ring
/-- **Cauchy–Schwarz inequality**. -/
theorem inner_mul_inner_self_le (x y : E) : ‖⟪x, y⟫‖ * ‖⟪y, x⟫‖ ≤ re ⟪x, x⟫ * re ⟪y, y⟫ :=
letI cd : PreInnerProductSpace.Core 𝕜 E := PreInnerProductSpace.toCore
InnerProductSpace.Core.inner_mul_inner_self_le x y
/-- Cauchy–Schwarz inequality for real inner products. -/
theorem real_inner_mul_inner_self_le (x y : F) : ⟪x, y⟫_ℝ * ⟪x, y⟫_ℝ ≤ ⟪x, x⟫_ℝ * ⟪y, y⟫_ℝ :=
calc
⟪x, y⟫_ℝ * ⟪x, y⟫_ℝ ≤ ‖⟪x, y⟫_ℝ‖ * ‖⟪y, x⟫_ℝ‖ := by
rw [real_inner_comm y, ← norm_mul]
exact le_abs_self _
_ ≤ ⟪x, x⟫_ℝ * ⟪y, y⟫_ℝ := @inner_mul_inner_self_le ℝ _ _ _ _ x y
end BasicProperties_Seminormed
section BasicProperties
variable [NormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [NormedAddCommGroup F] [InnerProductSpace ℝ F]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
export InnerProductSpace (norm_sq_eq_re_inner)
@[simp]
theorem inner_self_eq_zero {x : E} : ⟪x, x⟫ = 0 ↔ x = 0 := by
rw [inner_self_eq_norm_sq_to_K, sq_eq_zero_iff, ofReal_eq_zero, norm_eq_zero]
theorem inner_self_ne_zero {x : E} : ⟪x, x⟫ ≠ 0 ↔ x ≠ 0 :=
inner_self_eq_zero.not
variable (𝕜)
theorem ext_inner_left {x y : E} (h : ∀ v, ⟪v, x⟫ = ⟪v, y⟫) : x = y := by
rw [← sub_eq_zero, ← @inner_self_eq_zero 𝕜, inner_sub_right, sub_eq_zero, h (x - y)]
theorem ext_inner_right {x y : E} (h : ∀ v, ⟪x, v⟫ = ⟪y, v⟫) : x = y := by
rw [← sub_eq_zero, ← @inner_self_eq_zero 𝕜, inner_sub_left, sub_eq_zero, h (x - y)]
variable {𝕜}
@[simp]
theorem re_inner_self_nonpos {x : E} : re ⟪x, x⟫ ≤ 0 ↔ x = 0 := by
rw [← norm_sq_eq_re_inner, (sq_nonneg _).le_iff_eq, sq_eq_zero_iff, norm_eq_zero]
@[simp]
lemma re_inner_self_pos {x : E} : 0 < re ⟪x, x⟫ ↔ x ≠ 0 := by
simpa [-re_inner_self_nonpos] using re_inner_self_nonpos (𝕜 := 𝕜) (x := x).not
@[deprecated (since := "2025-04-22")] alias inner_self_nonpos := re_inner_self_nonpos
@[deprecated (since := "2025-04-22")] alias inner_self_pos := re_inner_self_pos
open scoped InnerProductSpace in
theorem real_inner_self_nonpos {x : F} : ⟪x, x⟫_ℝ ≤ 0 ↔ x = 0 := re_inner_self_nonpos (𝕜 := ℝ)
open scoped InnerProductSpace in
theorem real_inner_self_pos {x : F} : 0 < ⟪x, x⟫_ℝ ↔ x ≠ 0 := re_inner_self_pos (𝕜 := ℝ)
/-- A family of vectors is linearly independent if they are nonzero
and orthogonal. -/
theorem linearIndependent_of_ne_zero_of_inner_eq_zero {ι : Type*} {v : ι → E} (hz : ∀ i, v i ≠ 0)
(ho : Pairwise fun i j => ⟪v i, v j⟫ = 0) : LinearIndependent 𝕜 v := by
rw [linearIndependent_iff']
intro s g hg i hi
have h' : g i * inner (v i) (v i) = inner (v i) (∑ j ∈ s, g j • v j) := by
rw [inner_sum]
symm
convert Finset.sum_eq_single (M := 𝕜) i ?_ ?_
· rw [inner_smul_right]
· intro j _hj hji
rw [inner_smul_right, ho hji.symm, mul_zero]
· exact fun h => False.elim (h hi)
simpa [hg, hz] using h'
end BasicProperties
section Norm_Seminormed
open scoped InnerProductSpace
variable [SeminormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [SeminormedAddCommGroup F] [InnerProductSpace ℝ F]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
local notation "IK" => @RCLike.I 𝕜 _
theorem norm_eq_sqrt_re_inner (x : E) : ‖x‖ = √(re ⟪x, x⟫) :=
calc
‖x‖ = √(‖x‖ ^ 2) := (sqrt_sq (norm_nonneg _)).symm
_ = √(re ⟪x, x⟫) := congr_arg _ (norm_sq_eq_re_inner _)
@[deprecated (since := "2025-04-22")] alias norm_eq_sqrt_inner := norm_eq_sqrt_re_inner
theorem norm_eq_sqrt_real_inner (x : F) : ‖x‖ = √⟪x, x⟫_ℝ :=
@norm_eq_sqrt_re_inner ℝ _ _ _ _ x
theorem inner_self_eq_norm_mul_norm (x : E) : re ⟪x, x⟫ = ‖x‖ * ‖x‖ := by
rw [@norm_eq_sqrt_re_inner 𝕜, ← sqrt_mul inner_self_nonneg (re ⟪x, x⟫),
sqrt_mul_self inner_self_nonneg]
theorem inner_self_eq_norm_sq (x : E) : re ⟪x, x⟫ = ‖x‖ ^ 2 := by
rw [pow_two, inner_self_eq_norm_mul_norm]
theorem real_inner_self_eq_norm_mul_norm (x : F) : ⟪x, x⟫_ℝ = ‖x‖ * ‖x‖ := by
have h := @inner_self_eq_norm_mul_norm ℝ F _ _ _ x
simpa using h
theorem real_inner_self_eq_norm_sq (x : F) : ⟪x, x⟫_ℝ = ‖x‖ ^ 2 := by
rw [pow_two, real_inner_self_eq_norm_mul_norm]
/-- Expand the square -/
theorem norm_add_sq (x y : E) : ‖x + y‖ ^ 2 = ‖x‖ ^ 2 + 2 * re ⟪x, y⟫ + ‖y‖ ^ 2 := by
repeat' rw [sq (M := ℝ), ← @inner_self_eq_norm_mul_norm 𝕜]
rw [inner_add_add_self, two_mul]
simp only [add_assoc, add_left_inj, add_right_inj, AddMonoidHom.map_add]
rw [← inner_conj_symm, conj_re]
alias norm_add_pow_two := norm_add_sq
/-- Expand the square -/
theorem norm_add_sq_real (x y : F) : ‖x + y‖ ^ 2 = ‖x‖ ^ 2 + 2 * ⟪x, y⟫_ℝ + ‖y‖ ^ 2 := by
have h := @norm_add_sq ℝ _ _ _ _ x y
simpa using h
alias norm_add_pow_two_real := norm_add_sq_real
/-- Expand the square -/
theorem norm_add_mul_self (x y : E) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + 2 * re ⟪x, y⟫ + ‖y‖ * ‖y‖ := by
repeat' rw [← sq (M := ℝ)]
exact norm_add_sq _ _
/-- Expand the square -/
theorem norm_add_mul_self_real (x y : F) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + 2 * ⟪x, y⟫_ℝ + ‖y‖ * ‖y‖ := by
have h := @norm_add_mul_self ℝ _ _ _ _ x y
simpa using h
/-- Expand the square -/
theorem norm_sub_sq (x y : E) : ‖x - y‖ ^ 2 = ‖x‖ ^ 2 - 2 * re ⟪x, y⟫ + ‖y‖ ^ 2 := by
rw [sub_eq_add_neg, @norm_add_sq 𝕜 _ _ _ _ x (-y), norm_neg, inner_neg_right, map_neg, mul_neg,
sub_eq_add_neg]
alias norm_sub_pow_two := norm_sub_sq
/-- Expand the square -/
theorem norm_sub_sq_real (x y : F) : ‖x - y‖ ^ 2 = ‖x‖ ^ 2 - 2 * ⟪x, y⟫_ℝ + ‖y‖ ^ 2 :=
@norm_sub_sq ℝ _ _ _ _ _ _
alias norm_sub_pow_two_real := norm_sub_sq_real
/-- Expand the square -/
theorem norm_sub_mul_self (x y : E) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ - 2 * re ⟪x, y⟫ + ‖y‖ * ‖y‖ := by
repeat' rw [← sq (M := ℝ)]
exact norm_sub_sq _ _
/-- Expand the square -/
theorem norm_sub_mul_self_real (x y : F) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ - 2 * ⟪x, y⟫_ℝ + ‖y‖ * ‖y‖ := by
have h := @norm_sub_mul_self ℝ _ _ _ _ x y
simpa using h
/-- Cauchy–Schwarz inequality with norm -/
theorem norm_inner_le_norm (x y : E) : ‖⟪x, y⟫‖ ≤ ‖x‖ * ‖y‖ := by
rw [norm_eq_sqrt_re_inner (𝕜 := 𝕜) x, norm_eq_sqrt_re_inner (𝕜 := 𝕜) y]
letI : PreInnerProductSpace.Core 𝕜 E := PreInnerProductSpace.toCore
exact InnerProductSpace.Core.norm_inner_le_norm x y
theorem nnnorm_inner_le_nnnorm (x y : E) : ‖⟪x, y⟫‖₊ ≤ ‖x‖₊ * ‖y‖₊ :=
norm_inner_le_norm x y
theorem re_inner_le_norm (x y : E) : re ⟪x, y⟫ ≤ ‖x‖ * ‖y‖ :=
le_trans (re_le_norm (inner x y)) (norm_inner_le_norm x y)
/-- Cauchy–Schwarz inequality with norm -/
theorem abs_real_inner_le_norm (x y : F) : |⟪x, y⟫_ℝ| ≤ ‖x‖ * ‖y‖ :=
(Real.norm_eq_abs _).ge.trans (norm_inner_le_norm x y)
/-- Cauchy–Schwarz inequality with norm -/
theorem real_inner_le_norm (x y : F) : ⟪x, y⟫_ℝ ≤ ‖x‖ * ‖y‖ :=
le_trans (le_abs_self _) (abs_real_inner_le_norm _ _)
lemma inner_eq_zero_of_left {x : E} (y : E) (h : ‖x‖ = 0) : ⟪x, y⟫_𝕜 = 0 := by
rw [← norm_eq_zero]
refine le_antisymm ?_ (by positivity)
exact norm_inner_le_norm _ _ |>.trans <| by simp [h]
lemma inner_eq_zero_of_right (x : E) {y : E} (h : ‖y‖ = 0) : ⟪x, y⟫_𝕜 = 0 := by
rw [inner_eq_zero_symm, inner_eq_zero_of_left _ h]
variable (𝕜)
include 𝕜 in
theorem parallelogram_law_with_norm (x y : E) :
‖x + y‖ * ‖x + y‖ + ‖x - y‖ * ‖x - y‖ = 2 * (‖x‖ * ‖x‖ + ‖y‖ * ‖y‖) := by
simp only [← @inner_self_eq_norm_mul_norm 𝕜]
rw [← re.map_add, parallelogram_law, two_mul, two_mul]
simp only [re.map_add]
include 𝕜 in
theorem parallelogram_law_with_nnnorm (x y : E) :
‖x + y‖₊ * ‖x + y‖₊ + ‖x - y‖₊ * ‖x - y‖₊ = 2 * (‖x‖₊ * ‖x‖₊ + ‖y‖₊ * ‖y‖₊) :=
Subtype.ext <| parallelogram_law_with_norm 𝕜 x y
variable {𝕜}
/-- Polarization identity: The real part of the inner product, in terms of the norm. -/
theorem re_inner_eq_norm_add_mul_self_sub_norm_mul_self_sub_norm_mul_self_div_two (x y : E) :
re ⟪x, y⟫ = (‖x + y‖ * ‖x + y‖ - ‖x‖ * ‖x‖ - ‖y‖ * ‖y‖) / 2 := by
rw [@norm_add_mul_self 𝕜]
ring
/-- Polarization identity: The real part of the inner product, in terms of the norm. -/
theorem re_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two (x y : E) :
re ⟪x, y⟫ = (‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ - ‖x - y‖ * ‖x - y‖) / 2 := by
rw [@norm_sub_mul_self 𝕜]
ring
/-- Polarization identity: The real part of the inner product, in terms of the norm. -/
theorem re_inner_eq_norm_add_mul_self_sub_norm_sub_mul_self_div_four (x y : E) :
re ⟪x, y⟫ = (‖x + y‖ * ‖x + y‖ - ‖x - y‖ * ‖x - y‖) / 4 := by
rw [@norm_add_mul_self 𝕜, @norm_sub_mul_self 𝕜]
ring
/-- Polarization identity: The imaginary part of the inner product, in terms of the norm. -/
theorem im_inner_eq_norm_sub_i_smul_mul_self_sub_norm_add_i_smul_mul_self_div_four (x y : E) :
im ⟪x, y⟫ = (‖x - IK • y‖ * ‖x - IK • y‖ - ‖x + IK • y‖ * ‖x + IK • y‖) / 4 := by
simp only [@norm_add_mul_self 𝕜, @norm_sub_mul_self 𝕜, inner_smul_right, I_mul_re]
ring
/-- Polarization identity: The inner product, in terms of the norm. -/
theorem inner_eq_sum_norm_sq_div_four (x y : E) :
⟪x, y⟫ = ((‖x + y‖ : 𝕜) ^ 2 - (‖x - y‖ : 𝕜) ^ 2 +
((‖x - IK • y‖ : 𝕜) ^ 2 - (‖x + IK • y‖ : 𝕜) ^ 2) * IK) / 4 := by
rw [← re_add_im ⟪x, y⟫, re_inner_eq_norm_add_mul_self_sub_norm_sub_mul_self_div_four,
im_inner_eq_norm_sub_i_smul_mul_self_sub_norm_add_i_smul_mul_self_div_four]
push_cast
simp only [sq, ← mul_div_right_comm, ← add_div]
/-- Polarization identity: The real inner product, in terms of the norm. -/
theorem real_inner_eq_norm_add_mul_self_sub_norm_mul_self_sub_norm_mul_self_div_two (x y : F) :
⟪x, y⟫_ℝ = (‖x + y‖ * ‖x + y‖ - ‖x‖ * ‖x‖ - ‖y‖ * ‖y‖) / 2 :=
re_to_real.symm.trans <|
re_inner_eq_norm_add_mul_self_sub_norm_mul_self_sub_norm_mul_self_div_two x y
/-- Polarization identity: The real inner product, in terms of the norm. -/
theorem real_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two (x y : F) :
⟪x, y⟫_ℝ = (‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ - ‖x - y‖ * ‖x - y‖) / 2 :=
re_to_real.symm.trans <|
re_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two x y
/-- Pythagorean theorem, if-and-only-if vector inner product form. -/
theorem norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero (x y : F) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ ↔ ⟪x, y⟫_ℝ = 0 := by
rw [@norm_add_mul_self ℝ, add_right_cancel_iff, add_eq_left, mul_eq_zero]
norm_num
/-- Pythagorean theorem, if-and-if vector inner product form using square roots. -/
theorem norm_add_eq_sqrt_iff_real_inner_eq_zero {x y : F} :
‖x + y‖ = √(‖x‖ * ‖x‖ + ‖y‖ * ‖y‖) ↔ ⟪x, y⟫_ℝ = 0 := by
rw [← norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero, eq_comm, sqrt_eq_iff_mul_self_eq,
eq_comm] <;> positivity
/-- Pythagorean theorem, vector inner product form. -/
theorem norm_add_sq_eq_norm_sq_add_norm_sq_of_inner_eq_zero (x y : E) (h : ⟪x, y⟫ = 0) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ := by
rw [@norm_add_mul_self 𝕜, add_right_cancel_iff, add_eq_left, mul_eq_zero]
apply Or.inr
simp only [h, zero_re']
/-- Pythagorean theorem, vector inner product form. -/
theorem norm_add_sq_eq_norm_sq_add_norm_sq_real {x y : F} (h : ⟪x, y⟫_ℝ = 0) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ :=
(norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero x y).2 h
/-- Pythagorean theorem, subtracting vectors, if-and-only-if vector
inner product form. -/
theorem norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero (x y : F) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ ↔ ⟪x, y⟫_ℝ = 0 := by
rw [@norm_sub_mul_self ℝ, add_right_cancel_iff, sub_eq_add_neg, add_eq_left, neg_eq_zero,
mul_eq_zero]
norm_num
/-- Pythagorean theorem, subtracting vectors, if-and-if vector inner product form using square
roots. -/
theorem norm_sub_eq_sqrt_iff_real_inner_eq_zero {x y : F} :
‖x - y‖ = √(‖x‖ * ‖x‖ + ‖y‖ * ‖y‖) ↔ ⟪x, y⟫_ℝ = 0 := by
rw [← norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero, eq_comm, sqrt_eq_iff_mul_self_eq,
eq_comm] <;> positivity
/-- Pythagorean theorem, subtracting vectors, vector inner product
form. -/
theorem norm_sub_sq_eq_norm_sq_add_norm_sq_real {x y : F} (h : ⟪x, y⟫_ℝ = 0) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ :=
(norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero x y).2 h
/-- The sum and difference of two vectors are orthogonal if and only
if they have the same norm. -/
theorem real_inner_add_sub_eq_zero_iff (x y : F) : ⟪x + y, x - y⟫_ℝ = 0 ↔ ‖x‖ = ‖y‖ := by
conv_rhs => rw [← mul_self_inj_of_nonneg (norm_nonneg _) (norm_nonneg _)]
simp only [← @inner_self_eq_norm_mul_norm ℝ, inner_add_left, inner_sub_right, real_inner_comm y x,
sub_eq_zero, re_to_real]
constructor
· intro h
rw [add_comm] at h
linarith
· intro h
linarith
/-- Given two orthogonal vectors, their sum and difference have equal norms. -/
theorem norm_sub_eq_norm_add {v w : E} (h : ⟪v, w⟫ = 0) : ‖w - v‖ = ‖w + v‖ := by
rw [← mul_self_inj_of_nonneg (norm_nonneg _) (norm_nonneg _)]
simp only [h, ← @inner_self_eq_norm_mul_norm 𝕜, sub_neg_eq_add, sub_zero, map_sub, zero_re',
zero_sub, add_zero, map_add, inner_add_right, inner_sub_left, inner_sub_right, inner_re_symm,
zero_add]
/-- The real inner product of two vectors, divided by the product of their
norms, has absolute value at most 1. -/
theorem abs_real_inner_div_norm_mul_norm_le_one (x y : F) : |⟪x, y⟫_ℝ / (‖x‖ * ‖y‖)| ≤ 1 := by
rw [abs_div, abs_mul, abs_norm, abs_norm]
exact div_le_one_of_le₀ (abs_real_inner_le_norm x y) (by positivity)
/-- The inner product of a vector with a multiple of itself. -/
theorem real_inner_smul_self_left (x : F) (r : ℝ) : ⟪r • x, x⟫_ℝ = r * (‖x‖ * ‖x‖) := by
rw [real_inner_smul_left, ← real_inner_self_eq_norm_mul_norm]
/-- The inner product of a vector with a multiple of itself. -/
theorem real_inner_smul_self_right (x : F) (r : ℝ) : ⟪x, r • x⟫_ℝ = r * (‖x‖ * ‖x‖) := by
rw [inner_smul_right, ← real_inner_self_eq_norm_mul_norm]
/-- The inner product of two weighted sums, where the weights in each
sum add to 0, in terms of the norms of pairwise differences. -/
theorem inner_sum_smul_sum_smul_of_sum_eq_zero {ι₁ : Type*} {s₁ : Finset ι₁} {w₁ : ι₁ → ℝ}
(v₁ : ι₁ → F) (h₁ : ∑ i ∈ s₁, w₁ i = 0) {ι₂ : Type*} {s₂ : Finset ι₂} {w₂ : ι₂ → ℝ}
(v₂ : ι₂ → F) (h₂ : ∑ i ∈ s₂, w₂ i = 0) :
⟪∑ i₁ ∈ s₁, w₁ i₁ • v₁ i₁, ∑ i₂ ∈ s₂, w₂ i₂ • v₂ i₂⟫_ℝ =
(-∑ i₁ ∈ s₁, ∑ i₂ ∈ s₂, w₁ i₁ * w₂ i₂ * (‖v₁ i₁ - v₂ i₂‖ * ‖v₁ i₁ - v₂ i₂‖)) / 2 := by
simp_rw [sum_inner, inner_sum, real_inner_smul_left, real_inner_smul_right,
real_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two, ← div_sub_div_same,
← div_add_div_same, mul_sub_left_distrib, left_distrib, Finset.sum_sub_distrib,
Finset.sum_add_distrib, ← Finset.mul_sum, ← Finset.sum_mul, h₁, h₂, zero_mul,
mul_zero, Finset.sum_const_zero, zero_add, zero_sub, Finset.mul_sum, neg_div,
Finset.sum_div, mul_div_assoc, mul_assoc]
end Norm_Seminormed
section Norm
open scoped InnerProductSpace
variable [NormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [NormedAddCommGroup F] [InnerProductSpace ℝ F]
variable {ι : Type*}
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-- Formula for the distance between the images of two nonzero points under an inversion with center
zero. See also `EuclideanGeometry.dist_inversion_inversion` for inversions around a general
point. -/
theorem dist_div_norm_sq_smul {x y : F} (hx : x ≠ 0) (hy : y ≠ 0) (R : ℝ) :
dist ((R / ‖x‖) ^ 2 • x) ((R / ‖y‖) ^ 2 • y) = R ^ 2 / (‖x‖ * ‖y‖) * dist x y :=
calc
dist ((R / ‖x‖) ^ 2 • x) ((R / ‖y‖) ^ 2 • y) =
√(‖(R / ‖x‖) ^ 2 • x - (R / ‖y‖) ^ 2 • y‖ ^ 2) := by
rw [dist_eq_norm, sqrt_sq (norm_nonneg _)]
_ = √((R ^ 2 / (‖x‖ * ‖y‖)) ^ 2 * ‖x - y‖ ^ 2) :=
congr_arg sqrt <| by
field_simp [sq, norm_sub_mul_self_real, norm_smul, real_inner_smul_left, inner_smul_right,
Real.norm_of_nonneg (mul_self_nonneg _)]
ring
_ = R ^ 2 / (‖x‖ * ‖y‖) * dist x y := by
rw [sqrt_mul, sqrt_sq, sqrt_sq, dist_eq_norm] <;> positivity
/-- The inner product of a nonzero vector with a nonzero multiple of
itself, divided by the product of their norms, has absolute value
1. -/
theorem norm_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul {x : E} {r : 𝕜} (hx : x ≠ 0)
(hr : r ≠ 0) : ‖⟪x, r • x⟫‖ / (‖x‖ * ‖r • x‖) = 1 := by
have hx' : ‖x‖ ≠ 0 := by simp [hx]
have hr' : ‖r‖ ≠ 0 := by simp [hr]
rw [inner_smul_right, norm_mul, ← inner_self_re_eq_norm, inner_self_eq_norm_mul_norm, norm_smul]
rw [← mul_assoc, ← div_div, mul_div_cancel_right₀ _ hx', ← div_div, mul_comm,
mul_div_cancel_right₀ _ hr', div_self hx']
/-- The inner product of a nonzero vector with a nonzero multiple of
itself, divided by the product of their norms, has absolute value
1. -/
theorem abs_real_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul {x : F} {r : ℝ}
(hx : x ≠ 0) (hr : r ≠ 0) : |⟪x, r • x⟫_ℝ| / (‖x‖ * ‖r • x‖) = 1 :=
norm_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul hx hr
/-- The inner product of a nonzero vector with a positive multiple of
itself, divided by the product of their norms, has value 1. -/
theorem real_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_pos_mul {x : F} {r : ℝ} (hx : x ≠ 0)
(hr : 0 < r) : ⟪x, r • x⟫_ℝ / (‖x‖ * ‖r • x‖) = 1 := by
rw [real_inner_smul_self_right, norm_smul, Real.norm_eq_abs, ← mul_assoc ‖x‖, mul_comm _ |r|,
mul_assoc, abs_of_nonneg hr.le, div_self]
exact mul_ne_zero hr.ne' (mul_self_ne_zero.2 (norm_ne_zero_iff.2 hx))
/-- The inner product of a nonzero vector with a negative multiple of
itself, divided by the product of their norms, has value -1. -/
theorem real_inner_div_norm_mul_norm_eq_neg_one_of_ne_zero_of_neg_mul {x : F} {r : ℝ} (hx : x ≠ 0)
(hr : r < 0) : ⟪x, r • x⟫_ℝ / (‖x‖ * ‖r • x‖) = -1 := by
rw [real_inner_smul_self_right, norm_smul, Real.norm_eq_abs, ← mul_assoc ‖x‖, mul_comm _ |r|,
mul_assoc, abs_of_neg hr, neg_mul, div_neg_eq_neg_div, div_self]
exact mul_ne_zero hr.ne (mul_self_ne_zero.2 (norm_ne_zero_iff.2 hx))
theorem norm_inner_eq_norm_tfae (x y : E) :
List.TFAE [‖⟪x, y⟫‖ = ‖x‖ * ‖y‖,
x = 0 ∨ y = (⟪x, y⟫ / ⟪x, x⟫) • x,
x = 0 ∨ ∃ r : 𝕜, y = r • x,
x = 0 ∨ y ∈ 𝕜 ∙ x] := by
tfae_have 1 → 2 := by
refine fun h => or_iff_not_imp_left.2 fun hx₀ => ?_
have : ‖x‖ ^ 2 ≠ 0 := pow_ne_zero _ (norm_ne_zero_iff.2 hx₀)
rw [← sq_eq_sq₀, mul_pow, ← mul_right_inj' this, eq_comm, ← sub_eq_zero, ← mul_sub] at h <;>
try positivity
simp only [@norm_sq_eq_re_inner 𝕜] at h
letI : InnerProductSpace.Core 𝕜 E := InnerProductSpace.toCore
erw [← InnerProductSpace.Core.cauchy_schwarz_aux (𝕜 := 𝕜) (F := E)] at h
rw [InnerProductSpace.Core.normSq_eq_zero, sub_eq_zero] at h
rw [div_eq_inv_mul, mul_smul, h, inv_smul_smul₀]
rwa [inner_self_ne_zero]
tfae_have 2 → 3 := fun h => h.imp_right fun h' => ⟨_, h'⟩
tfae_have 3 → 1 := by
rintro (rfl | ⟨r, rfl⟩) <;>
simp [inner_smul_right, norm_smul, inner_self_eq_norm_sq_to_K, inner_self_eq_norm_mul_norm,
sq, mul_left_comm]
tfae_have 3 ↔ 4 := by simp only [Submodule.mem_span_singleton, eq_comm]
tfae_finish
/-- If the inner product of two vectors is equal to the product of their norms, then the two vectors
are multiples of each other. One form of the equality case for Cauchy-Schwarz.
Compare `inner_eq_norm_mul_iff`, which takes the stronger hypothesis `⟪x, y⟫ = ‖x‖ * ‖y‖`. -/
theorem norm_inner_eq_norm_iff {x y : E} (hx₀ : x ≠ 0) (hy₀ : y ≠ 0) :
‖⟪x, y⟫‖ = ‖x‖ * ‖y‖ ↔ ∃ r : 𝕜, r ≠ 0 ∧ y = r • x :=
calc
‖⟪x, y⟫‖ = ‖x‖ * ‖y‖ ↔ x = 0 ∨ ∃ r : 𝕜, y = r • x :=
(@norm_inner_eq_norm_tfae 𝕜 _ _ _ _ x y).out 0 2
_ ↔ ∃ r : 𝕜, y = r • x := or_iff_right hx₀
_ ↔ ∃ r : 𝕜, r ≠ 0 ∧ y = r • x :=
⟨fun ⟨r, h⟩ => ⟨r, fun hr₀ => hy₀ <| h.symm ▸ smul_eq_zero.2 <| Or.inl hr₀, h⟩,
fun ⟨r, _hr₀, h⟩ => ⟨r, h⟩⟩
/-- The inner product of two vectors, divided by the product of their
norms, has absolute value 1 if and only if they are nonzero and one is
a multiple of the other. One form of equality case for Cauchy-Schwarz. -/
theorem norm_inner_div_norm_mul_norm_eq_one_iff (x y : E) :
‖⟪x, y⟫ / (‖x‖ * ‖y‖)‖ = 1 ↔ x ≠ 0 ∧ ∃ r : 𝕜, r ≠ 0 ∧ y = r • x := by
constructor
· intro h
have hx₀ : x ≠ 0 := fun h₀ => by simp [h₀] at h
have hy₀ : y ≠ 0 := fun h₀ => by simp [h₀] at h
refine ⟨hx₀, (norm_inner_eq_norm_iff hx₀ hy₀).1 <| eq_of_div_eq_one ?_⟩
simpa using h
· rintro ⟨hx, ⟨r, ⟨hr, rfl⟩⟩⟩
simp only [norm_div, norm_mul, norm_ofReal, abs_norm]
exact norm_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul hx hr
/-- The inner product of two vectors, divided by the product of their
norms, has absolute value 1 if and only if they are nonzero and one is
a multiple of the other. One form of equality case for Cauchy-Schwarz. -/
theorem abs_real_inner_div_norm_mul_norm_eq_one_iff (x y : F) :
|⟪x, y⟫_ℝ / (‖x‖ * ‖y‖)| = 1 ↔ x ≠ 0 ∧ ∃ r : ℝ, r ≠ 0 ∧ y = r • x :=
@norm_inner_div_norm_mul_norm_eq_one_iff ℝ F _ _ _ x y
theorem inner_eq_norm_mul_iff_div {x y : E} (h₀ : x ≠ 0) :
⟪x, y⟫ = (‖x‖ : 𝕜) * ‖y‖ ↔ (‖y‖ / ‖x‖ : 𝕜) • x = y := by
have h₀' := h₀
rw [← norm_ne_zero_iff, Ne, ← @ofReal_eq_zero 𝕜] at h₀'
constructor <;> intro h
· have : x = 0 ∨ y = (⟪x, y⟫ / ⟪x, x⟫ : 𝕜) • x :=
((@norm_inner_eq_norm_tfae 𝕜 _ _ _ _ x y).out 0 1).1 (by simp [h])
rw [this.resolve_left h₀, h]
simp [norm_smul, inner_self_ofReal_norm, mul_div_cancel_right₀ _ h₀']
· conv_lhs => rw [← h, inner_smul_right, inner_self_eq_norm_sq_to_K]
field_simp [sq, mul_left_comm]
/-- If the inner product of two vectors is equal to the product of their norms (i.e.,
`⟪x, y⟫ = ‖x‖ * ‖y‖`), then the two vectors are nonnegative real multiples of each other. One form
of the equality case for Cauchy-Schwarz.
Compare `norm_inner_eq_norm_iff`, which takes the weaker hypothesis `abs ⟪x, y⟫ = ‖x‖ * ‖y‖`. -/
theorem inner_eq_norm_mul_iff {x y : E} :
⟪x, y⟫ = (‖x‖ : 𝕜) * ‖y‖ ↔ (‖y‖ : 𝕜) • x = (‖x‖ : 𝕜) • y := by
rcases eq_or_ne x 0 with (rfl | h₀)
· simp
| · rw [inner_eq_norm_mul_iff_div h₀, div_eq_inv_mul, mul_smul, inv_smul_eq_iff₀]
rwa [Ne, ofReal_eq_zero, norm_eq_zero]
/-- If the inner product of two vectors is equal to the product of their norms (i.e.,
`⟪x, y⟫ = ‖x‖ * ‖y‖`), then the two vectors are nonnegative real multiples of each other. One form
of the equality case for Cauchy-Schwarz.
Compare `norm_inner_eq_norm_iff`, which takes the weaker hypothesis `abs ⟪x, y⟫ = ‖x‖ * ‖y‖`. -/
theorem inner_eq_norm_mul_iff_real {x y : F} : ⟪x, y⟫_ℝ = ‖x‖ * ‖y‖ ↔ ‖y‖ • x = ‖x‖ • y :=
inner_eq_norm_mul_iff
/-- The inner product of two vectors, divided by the product of their
norms, has value 1 if and only if they are nonzero and one is
a positive multiple of the other. -/
theorem real_inner_div_norm_mul_norm_eq_one_iff (x y : F) :
⟪x, y⟫_ℝ / (‖x‖ * ‖y‖) = 1 ↔ x ≠ 0 ∧ ∃ r : ℝ, 0 < r ∧ y = r • x := by
constructor
| Mathlib/Analysis/InnerProductSpace/Basic.lean | 743 | 758 |
/-
Copyright (c) 2019 Amelia Livingston. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Amelia Livingston, Bryan Gin-ge Chen, Patrick Massot, Wen Yang, Johan Commelin
-/
import Mathlib.Data.Set.Finite.Range
import Mathlib.Order.Partition.Finpartition
/-!
# Equivalence relations: partitions
This file comprises properties of equivalence relations viewed as partitions.
There are two implementations of partitions here:
* A collection `c : Set (Set α)` of sets is a partition of `α` if `∅ ∉ c` and each element `a : α`
belongs to a unique set `b ∈ c`. This is expressed as `IsPartition c`
* An indexed partition is a map `s : ι → α` whose image is a partition. This is
expressed as `IndexedPartition s`.
Of course both implementations are related to `Quotient` and `Setoid`.
`Setoid.isPartition.partition` and `Finpartition.isPartition_parts` furnish
a link between `Setoid.IsPartition` and `Finpartition`.
## TODO
Could the design of `Finpartition` inform the one of `Setoid.IsPartition`? Maybe bundling it and
changing it from `Set (Set α)` to `Set α` where `[Lattice α] [OrderBot α]` would make it more
usable.
## Tags
setoid, equivalence, iseqv, relation, equivalence relation, partition, equivalence class
-/
namespace Setoid
variable {α : Type*}
/-- If x ∈ α is in 2 elements of a set of sets partitioning α, those 2 sets are equal. -/
theorem eq_of_mem_eqv_class {c : Set (Set α)} (H : ∀ a, ∃! b ∈ c, a ∈ b) {x b b'}
(hc : b ∈ c) (hb : x ∈ b) (hc' : b' ∈ c) (hb' : x ∈ b') : b = b' :=
(H x).unique ⟨hc, hb⟩ ⟨hc', hb'⟩
/-- Makes an equivalence relation from a set of sets partitioning α. -/
def mkClasses (c : Set (Set α)) (H : ∀ a, ∃! b ∈ c, a ∈ b) : Setoid α where
r x y := ∀ s ∈ c, x ∈ s → y ∈ s
iseqv.refl := fun _ _ _ hx => hx
iseqv.symm := fun {x _y} h s hs hy => by
obtain ⟨t, ⟨ht, hx⟩, _⟩ := H x
rwa [eq_of_mem_eqv_class H hs hy ht (h t ht hx)]
iseqv.trans := fun {_x _ _} h1 h2 s hs hx => h2 s hs (h1 s hs hx)
/-- Makes the equivalence classes of an equivalence relation. -/
def classes (r : Setoid α) : Set (Set α) :=
{ s | ∃ y, s = { x | r x y } }
theorem mem_classes (r : Setoid α) (y) : { x | r x y } ∈ r.classes :=
⟨y, rfl⟩
theorem classes_ker_subset_fiber_set {β : Type*} (f : α → β) :
(Setoid.ker f).classes ⊆ Set.range fun y => { x | f x = y } := by
rintro s ⟨x, rfl⟩
rw [Set.mem_range]
exact ⟨f x, rfl⟩
theorem finite_classes_ker {α β : Type*} [Finite β] (f : α → β) : (Setoid.ker f).classes.Finite :=
(Set.finite_range _).subset <| classes_ker_subset_fiber_set f
theorem card_classes_ker_le {α β : Type*} [Fintype β] (f : α → β)
[Fintype (Setoid.ker f).classes] : Fintype.card (Setoid.ker f).classes ≤ Fintype.card β := by
classical exact
le_trans (Set.card_le_card (classes_ker_subset_fiber_set f)) (Fintype.card_range_le _)
/-- Two equivalence relations are equal iff all their equivalence classes are equal. -/
theorem eq_iff_classes_eq {r₁ r₂ : Setoid α} :
r₁ = r₂ ↔ ∀ x, { y | r₁ x y } = { y | r₂ x y } :=
⟨fun h _x => h ▸ rfl, fun h => ext fun x => Set.ext_iff.1 <| h x⟩
theorem rel_iff_exists_classes (r : Setoid α) {x y} : r x y ↔ ∃ c ∈ r.classes, x ∈ c ∧ y ∈ c :=
⟨fun h => ⟨_, r.mem_classes y, h, r.refl' y⟩, fun ⟨c, ⟨z, hz⟩, hx, hy⟩ => by
subst c
exact r.trans' hx (r.symm' hy)⟩
/-- Two equivalence relations are equal iff their equivalence classes are equal. -/
theorem classes_inj {r₁ r₂ : Setoid α} : r₁ = r₂ ↔ r₁.classes = r₂.classes :=
⟨fun h => h ▸ rfl, fun h => ext fun a b => by simp only [rel_iff_exists_classes, exists_prop, h]⟩
/-- The empty set is not an equivalence class. -/
theorem empty_not_mem_classes {r : Setoid α} : ∅ ∉ r.classes := fun ⟨y, hy⟩ =>
Set.not_mem_empty y <| hy.symm ▸ r.refl' y
/-- Equivalence classes partition the type. -/
theorem classes_eqv_classes {r : Setoid α} (a) : ∃! b ∈ r.classes, a ∈ b :=
ExistsUnique.intro { x | r x a } ⟨r.mem_classes a, r.refl' _⟩ <| by
rintro y ⟨⟨_, rfl⟩, ha⟩
ext x
exact ⟨fun hx => r.trans' hx (r.symm' ha), fun hx => r.trans' hx ha⟩
/-- If x ∈ α is in 2 equivalence classes, the equivalence classes are equal. -/
theorem eq_of_mem_classes {r : Setoid α} {x b} (hc : b ∈ r.classes) (hb : x ∈ b) {b'}
(hc' : b' ∈ r.classes) (hb' : x ∈ b') : b = b' :=
eq_of_mem_eqv_class classes_eqv_classes hc hb hc' hb'
/-- The elements of a set of sets partitioning α are the equivalence classes of the
| equivalence relation defined by the set of sets. -/
theorem eq_eqv_class_of_mem {c : Set (Set α)} (H : ∀ a, ∃! b ∈ c, a ∈ b) {s y}
(hs : s ∈ c) (hy : y ∈ s) : s = { x | mkClasses c H x y } := by
ext x
constructor
| Mathlib/Data/Setoid/Partition.lean | 107 | 111 |
/-
Copyright (c) 2024 David Loeffler. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: David Loeffler
-/
import Mathlib.Analysis.SpecialFunctions.Gamma.Beta
/-!
# Deligne's archimedean Gamma-factors
In the theory of L-series one frequently encounters the following functions (of a complex variable
`s`) introduced in Deligne's landmark paper *Valeurs de fonctions L et periodes d'integrales*:
$$ \Gamma_{\mathbb{R}}(s) = \pi ^ {-s / 2} \Gamma (s / 2) $$
and
$$ \Gamma_{\mathbb{C}}(s) = 2 (2 \pi) ^ {-s} \Gamma (s). $$
These are the factors that need to be included in the Dedekind zeta function of a number field
for each real, resp. complex, infinite place.
(Note that these are *not* the same as Mathlib's `Real.Gamma` vs. `Complex.Gamma`; Deligne's
functions both take a complex variable as input.)
This file defines these functions, and proves some elementary properties, including a reflection
formula which is an important input in functional equations of (un-completed) Dirichlet L-functions.
-/
open Filter Topology Asymptotics Real Set MeasureTheory
open Complex hiding abs_of_nonneg
namespace Complex
/-- Deligne's archimedean Gamma factor for a real infinite place.
See "Valeurs de fonctions L et periodes d'integrales" § 5.3. Note that this is not the same as
`Real.Gamma`; in particular it is a function `ℂ → ℂ`. -/
noncomputable def Gammaℝ (s : ℂ) := π ^ (-s / 2) * Gamma (s / 2)
lemma Gammaℝ_def (s : ℂ) : Gammaℝ s = π ^ (-s / 2) * Gamma (s / 2) := rfl
/-- Deligne's archimedean Gamma factor for a complex infinite place.
See "Valeurs de fonctions L et periodes d'integrales" § 5.3. (Some authors omit the factor of 2).
Note that this is not the same as `Complex.Gamma`. -/
noncomputable def Gammaℂ (s : ℂ) := 2 * (2 * π) ^ (-s) * Gamma s
lemma Gammaℂ_def (s : ℂ) : Gammaℂ s = 2 * (2 * π) ^ (-s) * Gamma s := rfl
lemma Gammaℝ_add_two {s : ℂ} (hs : s ≠ 0) : Gammaℝ (s + 2) = Gammaℝ s * s / 2 / π := by
rw [Gammaℝ_def, Gammaℝ_def, neg_div, add_div, neg_add, div_self two_ne_zero,
Gamma_add_one _ (div_ne_zero hs two_ne_zero),
cpow_add _ _ (ofReal_ne_zero.mpr pi_ne_zero), cpow_neg_one]
field_simp [pi_ne_zero]
ring
lemma Gammaℂ_add_one {s : ℂ} (hs : s ≠ 0) : Gammaℂ (s + 1) = Gammaℂ s * s / 2 / π := by
rw [Gammaℂ_def, Gammaℂ_def, Gamma_add_one _ hs, neg_add,
cpow_add _ _ (mul_ne_zero two_ne_zero (ofReal_ne_zero.mpr pi_ne_zero)), cpow_neg_one]
field_simp [pi_ne_zero]
ring
lemma Gammaℝ_ne_zero_of_re_pos {s : ℂ} (hs : 0 < re s) : Gammaℝ s ≠ 0 := by
apply mul_ne_zero
· simp [pi_ne_zero]
· apply Gamma_ne_zero_of_re_pos
rw [div_ofNat_re]
exact div_pos hs two_pos
lemma Gammaℝ_eq_zero_iff {s : ℂ} : Gammaℝ s = 0 ↔ ∃ n : ℕ, s = -(2 * n) := by
simp [Gammaℝ_def, Complex.Gamma_eq_zero_iff, pi_ne_zero, div_eq_iff (two_ne_zero' ℂ), mul_comm]
@[simp]
lemma Gammaℝ_one : Gammaℝ 1 = 1 := by
rw [Gammaℝ_def, Complex.Gamma_one_half_eq]
simp [neg_div, cpow_neg, inv_mul_cancel, pi_ne_zero]
@[simp]
lemma Gammaℂ_one : Gammaℂ 1 = 1 / π := by
rw [Gammaℂ_def, cpow_neg_one, Complex.Gamma_one]
field_simp [pi_ne_zero]
section analyticity
lemma differentiable_Gammaℝ_inv : Differentiable ℂ (fun s ↦ (Gammaℝ s)⁻¹) := by
conv => enter [2, s]; rw [Gammaℝ, mul_inv]
refine Differentiable.mul (fun s ↦ .inv ?_ (by simp [pi_ne_zero])) ?_
· refine ((differentiableAt_id.neg.div_const (2 : ℂ)).const_cpow ?_)
exact Or.inl (ofReal_ne_zero.mpr pi_ne_zero)
· exact differentiable_one_div_Gamma.comp (differentiable_id.div_const _)
lemma Gammaℝ_residue_zero : Tendsto (fun s ↦ s * Gammaℝ s) (𝓝[≠] 0) (𝓝 2) := by
have h : Tendsto (fun z : ℂ ↦ z / 2 * Gamma (z / 2)) (𝓝[≠] 0) (𝓝 1) := by
refine tendsto_self_mul_Gamma_nhds_zero.comp ?_
rw [tendsto_nhdsWithin_iff, (by simp : 𝓝 (0 : ℂ) = 𝓝 (0 / 2))]
exact ⟨(tendsto_id.div_const _).mono_left nhdsWithin_le_nhds,
eventually_of_mem self_mem_nhdsWithin fun x hx ↦ div_ne_zero hx two_ne_zero⟩
have h' : Tendsto (fun s : ℂ ↦ 2 * (π : ℂ) ^ (-s / 2)) (𝓝[≠] 0) (𝓝 2) := by
rw [(by simp : 𝓝 2 = 𝓝 (2 * (π : ℂ) ^ (-(0 : ℂ) / 2)))]
refine Tendsto.mono_left (ContinuousAt.tendsto ?_) nhdsWithin_le_nhds
exact continuousAt_const.mul ((continuousAt_const_cpow (ofReal_ne_zero.mpr pi_ne_zero)).comp
(continuousAt_id.neg.div_const _))
convert mul_one (2 : ℂ) ▸ (h'.mul h) using 2 with z
rw [Gammaℝ]
ring_nf
end analyticity
section reflection
/-- Reformulation of the doubling formula in terms of `Gammaℝ`. -/
lemma Gammaℝ_mul_Gammaℝ_add_one (s : ℂ) : Gammaℝ s * Gammaℝ (s + 1) = Gammaℂ s := by
simp only [Gammaℝ_def, Gammaℂ_def]
calc
_ = (π ^ (-s / 2) * π ^ (-(s + 1) / 2)) * (Gamma (s / 2) * Gamma (s / 2 + 1 / 2)) := by ring_nf
_ = 2 ^ (1 - s) * (π ^ (-1 / 2 - s) * π ^ (1 / 2 : ℂ)) * Gamma s := by
rw [← cpow_add _ _ (ofReal_ne_zero.mpr pi_ne_zero), Complex.Gamma_mul_Gamma_add_half,
sqrt_eq_rpow, ofReal_cpow pi_pos.le, ofReal_div, ofReal_one, ofReal_ofNat]
ring_nf
_ = 2 * ((2 : ℝ) ^ (-s) * π ^ (-s)) * Gamma s := by
rw [sub_eq_add_neg, cpow_add _ _ two_ne_zero, cpow_one,
← cpow_add _ _ (ofReal_ne_zero.mpr pi_ne_zero), ofReal_ofNat]
ring_nf
_ = 2 * (2 * π) ^ (-s) * Gamma s := by
rw [← mul_cpow_ofReal_nonneg two_pos.le pi_pos.le, ofReal_ofNat]
/-- Reformulation of the reflection formula in terms of `Gammaℝ`. -/
lemma Gammaℝ_one_sub_mul_Gammaℝ_one_add (s : ℂ) :
Gammaℝ (1 - s) * Gammaℝ (1 + s) = (cos (π * s / 2))⁻¹ :=
calc Gammaℝ (1 - s) * Gammaℝ (1 + s)
_ = (π ^ ((s - 1) / 2) * π ^ ((-1 - s) / 2)) *
(Gamma ((1 - s) / 2) * Gamma (1 - (1 - s) / 2)) := by
simp only [Gammaℝ_def]
ring_nf
_ = (π ^ ((s - 1) / 2) * π ^ ((-1 - s) / 2) * π ^ (1 : ℂ)) / sin (π / 2 - π * s / 2) := by
rw [Complex.Gamma_mul_Gamma_one_sub, cpow_one]
ring_nf
_ = _ := by
simp_rw [← cpow_add _ _ (ofReal_ne_zero.mpr pi_ne_zero),
Complex.sin_pi_div_two_sub]
ring_nf
rw [cpow_zero, one_mul]
/-- Another formulation of the reflection formula in terms of `Gammaℝ`. -/
| lemma Gammaℝ_div_Gammaℝ_one_sub {s : ℂ} (hs : ∀ (n : ℕ), s ≠ -(2 * n + 1)) :
Gammaℝ s / Gammaℝ (1 - s) = Gammaℂ s * cos (π * s / 2) := by
have : Gammaℝ (s + 1) ≠ 0 := by
simpa only [Ne, Gammaℝ_eq_zero_iff, not_exists, ← eq_sub_iff_add_eq,
sub_eq_add_neg, ← neg_add]
calc Gammaℝ s / Gammaℝ (1 - s)
_ = (Gammaℝ s * Gammaℝ (s + 1)) / (Gammaℝ (1 - s) * Gammaℝ (1 + s)) := by
rw [add_comm 1 s, mul_comm (Gammaℝ (1 - s)) (Gammaℝ (s + 1)), ← div_div,
mul_div_cancel_right₀ _ this]
_ = (2 * (2 * π) ^ (-s) * Gamma s) / ((cos (π * s / 2))⁻¹) := by
rw [Gammaℝ_one_sub_mul_Gammaℝ_one_add, Gammaℝ_mul_Gammaℝ_add_one, Gammaℂ_def]
_ = _ := by rw [Gammaℂ_def, div_eq_mul_inv, inv_inv]
| Mathlib/Analysis/SpecialFunctions/Gamma/Deligne.lean | 147 | 159 |
/-
Copyright (c) 2021 Damiano Testa. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Damiano Testa
-/
import Mathlib.Algebra.Group.Commute.Defs
import Mathlib.Algebra.Group.Units.Defs
import Mathlib.Algebra.GroupWithZero.Defs
import Mathlib.Algebra.Order.Monoid.Unbundled.Basic
import Mathlib.Tactic.NthRewrite
/-!
# Regular elements
We introduce left-regular, right-regular and regular elements, along with their `to_additive`
analogues add-left-regular, add-right-regular and add-regular elements.
By definition, a regular element in a commutative ring is a non-zero divisor.
Lemma `isRegular_of_ne_zero` implies that every non-zero element of an integral domain is regular.
Since it assumes that the ring is a `CancelMonoidWithZero` it applies also, for instance, to `ℕ`.
The lemmas in Section `MulZeroClass` show that the `0` element is (left/right-)regular if and
only if the `MulZeroClass` is trivial. This is useful when figuring out stopping conditions for
regular sequences: if `0` is ever an element of a regular sequence, then we can extend the sequence
by adding one further `0`.
The final goal is to develop part of the API to prove, eventually, results about non-zero-divisors.
-/
variable {R : Type*}
section Mul
variable [Mul R]
/-- A left-regular element is an element `c` such that multiplication on the left by `c`
is injective. -/
@[to_additive "An add-left-regular element is an element `c` such that addition
on the left by `c` is injective."]
def IsLeftRegular (c : R) :=
(c * ·).Injective
/-- A right-regular element is an element `c` such that multiplication on the right by `c`
is injective. -/
@[to_additive "An add-right-regular element is an element `c` such that addition
on the right by `c` is injective."]
def IsRightRegular (c : R) :=
(· * c).Injective
/-- An add-regular element is an element `c` such that addition by `c` both on the left and
on the right is injective. -/
structure IsAddRegular {R : Type*} [Add R] (c : R) : Prop where
/-- An add-regular element `c` is left-regular -/
left : IsAddLeftRegular c -- Porting note: It seems like to_additive is misbehaving
/-- An add-regular element `c` is right-regular -/
right : IsAddRightRegular c
/-- A regular element is an element `c` such that multiplication by `c` both on the left and
on the right is injective. -/
structure IsRegular (c : R) : Prop where
/-- A regular element `c` is left-regular -/
left : IsLeftRegular c
/-- A regular element `c` is right-regular -/
right : IsRightRegular c
attribute [simp] IsRegular.left IsRegular.right
attribute [to_additive] IsRegular
@[to_additive]
theorem isRegular_iff {c : R} : IsRegular c ↔ IsLeftRegular c ∧ IsRightRegular c :=
⟨fun ⟨h1, h2⟩ => ⟨h1, h2⟩, fun ⟨h1, h2⟩ => ⟨h1, h2⟩⟩
@[to_additive]
protected theorem MulLECancellable.isLeftRegular [PartialOrder R] {a : R}
(ha : MulLECancellable a) : IsLeftRegular a :=
ha.Injective
theorem IsLeftRegular.right_of_commute {a : R}
(ca : ∀ b, Commute a b) (h : IsLeftRegular a) : IsRightRegular a :=
fun x y xy => h <| (ca x).trans <| xy.trans <| (ca y).symm
theorem IsRightRegular.left_of_commute {a : R}
(ca : ∀ b, Commute a b) (h : IsRightRegular a) : IsLeftRegular a := by
simp_rw [@Commute.symm_iff R _ a] at ca
exact fun x y xy => h <| (ca x).trans <| xy.trans <| (ca y).symm
theorem Commute.isRightRegular_iff {a : R} (ca : ∀ b, Commute a b) :
IsRightRegular a ↔ IsLeftRegular a :=
⟨IsRightRegular.left_of_commute ca, IsLeftRegular.right_of_commute ca⟩
theorem Commute.isRegular_iff {a : R} (ca : ∀ b, Commute a b) : IsRegular a ↔ IsLeftRegular a :=
⟨fun h => h.left, fun h => ⟨h, h.right_of_commute ca⟩⟩
end Mul
section Semigroup
variable [Semigroup R] {a b : R}
/-- In a semigroup, the product of left-regular elements is left-regular. -/
@[to_additive "In an additive semigroup, the sum of add-left-regular elements is add-left.regular."]
theorem IsLeftRegular.mul (lra : IsLeftRegular a) (lrb : IsLeftRegular b) : IsLeftRegular (a * b) :=
show Function.Injective (((a * b) * ·)) from comp_mul_left a b ▸ lra.comp lrb
/-- In a semigroup, the product of right-regular elements is right-regular. -/
@[to_additive "In an additive semigroup, the sum of add-right-regular elements is
add-right-regular."]
theorem IsRightRegular.mul (rra : IsRightRegular a) (rrb : IsRightRegular b) :
IsRightRegular (a * b) :=
show Function.Injective (· * (a * b)) from comp_mul_right b a ▸ rrb.comp rra
/-- In a semigroup, the product of regular elements is regular. -/
@[to_additive "In an additive semigroup, the sum of add-regular elements is add-regular."]
theorem IsRegular.mul (rra : IsRegular a) (rrb : IsRegular b) :
IsRegular (a * b) :=
⟨rra.left.mul rrb.left, rra.right.mul rrb.right⟩
/-- If an element `b` becomes left-regular after multiplying it on the left by a left-regular
element, then `b` is left-regular. -/
@[to_additive "If an element `b` becomes add-left-regular after adding to it on the left
an add-left-regular element, then `b` is add-left-regular."]
theorem IsLeftRegular.of_mul (ab : IsLeftRegular (a * b)) : IsLeftRegular b :=
Function.Injective.of_comp (f := (a * ·)) (by rwa [comp_mul_left a b])
/-- An element is left-regular if and only if multiplying it on the left by a left-regular element
is left-regular. -/
@[to_additive (attr := simp) "An element is add-left-regular if and only if adding to it on the left
an add-left-regular element is add-left-regular."]
theorem mul_isLeftRegular_iff (b : R) (ha : IsLeftRegular a) :
IsLeftRegular (a * b) ↔ IsLeftRegular b :=
⟨fun ab => IsLeftRegular.of_mul ab, fun ab => IsLeftRegular.mul ha ab⟩
/-- If an element `b` becomes right-regular after multiplying it on the right by a right-regular
element, then `b` is right-regular. -/
@[to_additive "If an element `b` becomes add-right-regular after adding to it on the right
an add-right-regular element, then `b` is add-right-regular."]
theorem IsRightRegular.of_mul (ab : IsRightRegular (b * a)) : IsRightRegular b := by
refine fun x y xy => ab (?_ : x * (b * a) = y * (b * a))
rw [← mul_assoc, ← mul_assoc]
exact congr_arg (· * a) xy
/-- An element is right-regular if and only if multiplying it on the right with a right-regular
element is right-regular. -/
@[to_additive (attr := simp)
"An element is add-right-regular if and only if adding it on the right to
an add-right-regular element is add-right-regular."]
theorem mul_isRightRegular_iff (b : R) (ha : IsRightRegular a) :
IsRightRegular (b * a) ↔ IsRightRegular b :=
⟨fun ab => IsRightRegular.of_mul ab, fun ab => IsRightRegular.mul ab ha⟩
/-- Two elements `a` and `b` are regular if and only if both products `a * b` and `b * a`
are regular. -/
@[to_additive "Two elements `a` and `b` are add-regular if and only if both sums `a + b` and
`b + a` are add-regular."]
theorem isRegular_mul_and_mul_iff :
IsRegular (a * b) ∧ IsRegular (b * a) ↔ IsRegular a ∧ IsRegular b := by
refine ⟨?_, ?_⟩
· rintro ⟨ab, ba⟩
exact
⟨⟨IsLeftRegular.of_mul ba.left, IsRightRegular.of_mul ab.right⟩,
⟨IsLeftRegular.of_mul ab.left, IsRightRegular.of_mul ba.right⟩⟩
· rintro ⟨ha, hb⟩
exact ⟨ha.mul hb, hb.mul ha⟩
/-- The "most used" implication of `mul_and_mul_iff`, with split hypotheses, instead of `∧`. -/
@[to_additive "The \"most used\" implication of `add_and_add_iff`, with split
hypotheses, instead of `∧`."]
theorem IsRegular.and_of_mul_of_mul (ab : IsRegular (a * b)) (ba : IsRegular (b * a)) :
IsRegular a ∧ IsRegular b :=
isRegular_mul_and_mul_iff.mp ⟨ab, ba⟩
end Semigroup
section MulZeroClass
variable [MulZeroClass R] {a b : R}
/-- The element `0` is left-regular if and only if `R` is trivial. -/
theorem IsLeftRegular.subsingleton (h : IsLeftRegular (0 : R)) : Subsingleton R :=
⟨fun a b => h <| Eq.trans (zero_mul a) (zero_mul b).symm⟩
/-- The element `0` is right-regular if and only if `R` is trivial. -/
theorem IsRightRegular.subsingleton (h : IsRightRegular (0 : R)) : Subsingleton R :=
⟨fun a b => h <| Eq.trans (mul_zero a) (mul_zero b).symm⟩
/-- The element `0` is regular if and only if `R` is trivial. -/
theorem IsRegular.subsingleton (h : IsRegular (0 : R)) : Subsingleton R :=
h.left.subsingleton
/-- The element `0` is left-regular if and only if `R` is trivial. -/
theorem isLeftRegular_zero_iff_subsingleton : IsLeftRegular (0 : R) ↔ Subsingleton R :=
⟨fun h => h.subsingleton, fun H a b _ => @Subsingleton.elim _ H a b⟩
/-- In a non-trivial `MulZeroClass`, the `0` element is not left-regular. -/
theorem not_isLeftRegular_zero_iff : ¬IsLeftRegular (0 : R) ↔ Nontrivial R := by
rw [nontrivial_iff, not_iff_comm, isLeftRegular_zero_iff_subsingleton, subsingleton_iff]
push_neg
exact Iff.rfl
/-- The element `0` is right-regular if and only if `R` is trivial. -/
theorem isRightRegular_zero_iff_subsingleton : IsRightRegular (0 : R) ↔ Subsingleton R :=
⟨fun h => h.subsingleton, fun H a b _ => @Subsingleton.elim _ H a b⟩
/-- In a non-trivial `MulZeroClass`, the `0` element is not right-regular. -/
theorem not_isRightRegular_zero_iff : ¬IsRightRegular (0 : R) ↔ Nontrivial R := by
rw [nontrivial_iff, not_iff_comm, isRightRegular_zero_iff_subsingleton, subsingleton_iff]
push_neg
exact Iff.rfl
/-- The element `0` is regular if and only if `R` is trivial. -/
theorem isRegular_iff_subsingleton : IsRegular (0 : R) ↔ Subsingleton R :=
⟨fun h => h.left.subsingleton, fun h =>
⟨isLeftRegular_zero_iff_subsingleton.mpr h, isRightRegular_zero_iff_subsingleton.mpr h⟩⟩
/-- A left-regular element of a `Nontrivial` `MulZeroClass` is non-zero. -/
theorem IsLeftRegular.ne_zero [Nontrivial R] (la : IsLeftRegular a) : a ≠ 0 := by
rintro rfl
rcases exists_pair_ne R with ⟨x, y, xy⟩
refine xy (la (?_ : 0 * x = 0 * y)) -- Porting note: lean4 seems to need the type signature
rw [zero_mul, zero_mul]
/-- A right-regular element of a `Nontrivial` `MulZeroClass` is non-zero. -/
theorem IsRightRegular.ne_zero [Nontrivial R] (ra : IsRightRegular a) : a ≠ 0 := by
rintro rfl
rcases exists_pair_ne R with ⟨x, y, xy⟩
refine xy (ra (?_ : x * 0 = y * 0))
rw [mul_zero, mul_zero]
/-- A regular element of a `Nontrivial` `MulZeroClass` is non-zero. -/
theorem IsRegular.ne_zero [Nontrivial R] (la : IsRegular a) : a ≠ 0 :=
la.left.ne_zero
/-- In a non-trivial ring, the element `0` is not left-regular -- with typeclasses. -/
theorem not_isLeftRegular_zero [nR : Nontrivial R] : ¬IsLeftRegular (0 : R) :=
not_isLeftRegular_zero_iff.mpr nR
/-- In a non-trivial ring, the element `0` is not right-regular -- with typeclasses. -/
theorem not_isRightRegular_zero [nR : Nontrivial R] : ¬IsRightRegular (0 : R) :=
not_isRightRegular_zero_iff.mpr nR
/-- In a non-trivial ring, the element `0` is not regular -- with typeclasses. -/
theorem not_isRegular_zero [Nontrivial R] : ¬IsRegular (0 : R) := fun h => IsRegular.ne_zero h rfl
@[simp] lemma IsLeftRegular.mul_left_eq_zero_iff (hb : IsLeftRegular b) : b * a = 0 ↔ a = 0 := by
nth_rw 1 [← mul_zero b]
exact ⟨fun h ↦ hb h, fun ha ↦ by rw [ha]⟩
@[simp] lemma IsRightRegular.mul_right_eq_zero_iff (hb : IsRightRegular b) : a * b = 0 ↔ a = 0 := by
nth_rw 1 [← zero_mul b]
exact ⟨fun h ↦ hb h, fun ha ↦ by rw [ha]⟩
end MulZeroClass
section MulOneClass
variable [MulOneClass R]
/-- If multiplying by `1` on either side is the identity, `1` is regular. -/
@[to_additive "If adding `0` on either side is the identity, `0` is regular."]
theorem isRegular_one : IsRegular (1 : R) :=
⟨fun a b ab => (one_mul a).symm.trans (Eq.trans ab (one_mul b)), fun a b ab =>
(mul_one a).symm.trans (Eq.trans ab (mul_one b))⟩
end MulOneClass
section CommSemigroup
variable [CommSemigroup R] {a b : R}
/-- A product is regular if and only if the factors are. -/
@[to_additive "A sum is add-regular if and only if the summands are."]
theorem isRegular_mul_iff : IsRegular (a * b) ↔ IsRegular a ∧ IsRegular b := by
refine Iff.trans ?_ isRegular_mul_and_mul_iff
exact ⟨fun ab => ⟨ab, by rwa [mul_comm]⟩, fun rab => rab.1⟩
end CommSemigroup
section Monoid
variable [Monoid R] {a b : R} {n : ℕ}
/-- An element admitting a left inverse is left-regular. -/
@[to_additive "An element admitting a left additive opposite is add-left-regular."]
theorem isLeftRegular_of_mul_eq_one (h : b * a = 1) : IsLeftRegular a :=
IsLeftRegular.of_mul (a := b) (by rw [h]; exact isRegular_one.left)
/-- An element admitting a right inverse is right-regular. -/
@[to_additive "An element admitting a right additive opposite is add-right-regular."]
theorem isRightRegular_of_mul_eq_one (h : a * b = 1) : IsRightRegular a :=
| IsRightRegular.of_mul (a := b) (by rw [h]; exact isRegular_one.right)
/-- If `R` is a monoid, an element in `Rˣ` is regular. -/
| Mathlib/Algebra/Regular/Basic.lean | 292 | 294 |
/-
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.Pi.Basic
import Mathlib.Data.Set.BooleanAlgebra
import Mathlib.Data.Set.Piecewise
import Mathlib.Order.Interval.Set.Basic
import Mathlib.Order.Interval.Set.UnorderedInterval
/-!
# Intervals in `pi`-space
In this we prove various simple lemmas about intervals in `Π i, α i`. Closed intervals (`Ici x`,
`Iic x`, `Icc x y`) are equal to products of their projections to `α i`, while (semi-)open intervals
usually include the corresponding products as proper subsets.
-/
-- Porting note: Added, since dot notation no longer works on `Function.update`
open Function
variable {ι : Type*} {α : ι → Type*}
namespace Set
section PiPreorder
variable [∀ i, Preorder (α i)] (x y : ∀ i, α i)
@[simp]
theorem pi_univ_Ici : (pi univ fun i ↦ Ici (x i)) = Ici x :=
| ext fun y ↦ by simp [Pi.le_def]
| Mathlib/Order/Interval/Set/Pi.lean | 33 | 34 |
/-
Copyright (c) 2019 Zhouhang Zhou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Zhouhang Zhou
-/
import Mathlib.Order.Filter.AtTopBot.Field
import Mathlib.Tactic.FieldSimp
import Mathlib.Tactic.LinearCombination
import Mathlib.Tactic.Linarith.Frontend
/-!
# Quadratic discriminants and roots of a quadratic
This file defines the discriminant of a quadratic and gives the solution to a quadratic equation.
## Main definition
- `discrim a b c`: the discriminant of a quadratic `a * (x * x) + b * x + c` is `b * b - 4 * a * c`.
## Main statements
- `quadratic_eq_zero_iff`: roots of a quadratic can be written as
`(-b + s) / (2 * a)` or `(-b - s) / (2 * a)`, where `s` is a square root of the discriminant.
- `quadratic_ne_zero_of_discrim_ne_sq`: if the discriminant has no square root,
then the corresponding quadratic has no root.
- `discrim_le_zero`: if a quadratic is always non-negative, then its discriminant is non-positive.
- `discrim_le_zero_of_nonpos`, `discrim_lt_zero`, `discrim_lt_zero_of_neg`: versions of this
statement with other inequalities.
## Tags
polynomial, quadratic, discriminant, root
-/
assert_not_exists Finite Finset
open Filter
section Ring
variable {R : Type*}
/-- Discriminant of a quadratic -/
def discrim [Ring R] (a b c : R) : R :=
b ^ 2 - 4 * a * c
@[simp] lemma discrim_neg [Ring R] (a b c : R) : discrim (-a) (-b) (-c) = discrim a b c := by
simp [discrim]
variable [CommRing R] {a b c : R}
lemma discrim_eq_sq_of_quadratic_eq_zero {x : R} (h : a * (x * x) + b * x + c = 0) :
discrim a b c = (2 * a * x + b) ^ 2 := by
rw [discrim]
linear_combination -4 * a * h
/-- A quadratic has roots if and only if its discriminant equals some square.
-/
theorem quadratic_eq_zero_iff_discrim_eq_sq [NeZero (2 : R)] [NoZeroDivisors R]
(ha : a ≠ 0) (x : R) :
a * (x * x) + b * x + c = 0 ↔ discrim a b c = (2 * a * x + b) ^ 2 := by
refine ⟨discrim_eq_sq_of_quadratic_eq_zero, fun h ↦ ?_⟩
rw [discrim] at h
have ha : 2 * 2 * a ≠ 0 := mul_ne_zero (mul_ne_zero (NeZero.ne _) (NeZero.ne _)) ha
apply mul_left_cancel₀ ha
linear_combination -h
/-- A quadratic has no root if its discriminant has no square root. -/
theorem quadratic_ne_zero_of_discrim_ne_sq (h : ∀ s : R, discrim a b c ≠ s^2) (x : R) :
a * (x * x) + b * x + c ≠ 0 :=
mt discrim_eq_sq_of_quadratic_eq_zero (h _)
end Ring
section Field
variable {K : Type*} [Field K] [NeZero (2 : K)] {a b c : K}
/-- Roots of a quadratic equation. -/
theorem quadratic_eq_zero_iff (ha : a ≠ 0) {s : K} (h : discrim a b c = s * s) (x : K) :
a * (x * x) + b * x + c = 0 ↔ x = (-b + s) / (2 * a) ∨ x = (-b - s) / (2 * a) := by
rw [quadratic_eq_zero_iff_discrim_eq_sq ha, h, sq, mul_self_eq_mul_self_iff]
field_simp
apply or_congr
· constructor <;> intro h' <;> linear_combination -h'
| · constructor <;> intro h' <;> linear_combination h'
/-- A quadratic has roots if its discriminant has square roots -/
theorem exists_quadratic_eq_zero (ha : a ≠ 0) (h : ∃ s, discrim a b c = s * s) :
∃ x, a * (x * x) + b * x + c = 0 := by
rcases h with ⟨s, hs⟩
use (-b + s) / (2 * a)
| Mathlib/Algebra/QuadraticDiscriminant.lean | 86 | 92 |
/-
Copyright (c) 2020 Kexing Ying. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kexing Ying
-/
import Mathlib.Algebra.Group.Conj
import Mathlib.Algebra.Group.Pi.Lemmas
import Mathlib.Algebra.Group.Subgroup.Ker
/-!
# Basic results on subgroups
We prove basic results on the definitions of subgroups. The bundled subgroups use bundled monoid
homomorphisms.
Special thanks goes to Amelia Livingston and Yury Kudryashov for their help and inspiration.
## Main definitions
Notation used here:
- `G N` are `Group`s
- `A` is an `AddGroup`
- `H K` are `Subgroup`s of `G` or `AddSubgroup`s of `A`
- `x` is an element of type `G` or type `A`
- `f g : N →* G` are group homomorphisms
- `s k` are sets of elements of type `G`
Definitions in the file:
* `Subgroup.prod H K` : the product of subgroups `H`, `K` of groups `G`, `N` respectively, `H × K`
is a subgroup of `G × N`
## Implementation notes
Subgroup inclusion is denoted `≤` rather than `⊆`, although `∈` is defined as
membership of a subgroup's underlying set.
## Tags
subgroup, subgroups
-/
assert_not_exists OrderedAddCommMonoid Multiset Ring
open Function
open scoped Int
variable {G G' G'' : Type*} [Group G] [Group G'] [Group G'']
variable {A : Type*} [AddGroup A]
section SubgroupClass
variable {M S : Type*} [DivInvMonoid M] [SetLike S M] [hSM : SubgroupClass S M] {H K : S}
variable [SetLike S G] [SubgroupClass S G]
@[to_additive]
theorem div_mem_comm_iff {a b : G} : a / b ∈ H ↔ b / a ∈ H :=
inv_div b a ▸ inv_mem_iff
end SubgroupClass
namespace Subgroup
variable (H K : Subgroup G)
@[to_additive]
protected theorem div_mem_comm_iff {a b : G} : a / b ∈ H ↔ b / a ∈ H :=
div_mem_comm_iff
variable {k : Set G}
open Set
variable {N : Type*} [Group N] {P : Type*} [Group P]
/-- Given `Subgroup`s `H`, `K` of groups `G`, `N` respectively, `H × K` as a subgroup of `G × N`. -/
@[to_additive prod
"Given `AddSubgroup`s `H`, `K` of `AddGroup`s `A`, `B` respectively, `H × K`
as an `AddSubgroup` of `A × B`."]
def prod (H : Subgroup G) (K : Subgroup N) : Subgroup (G × N) :=
{ Submonoid.prod H.toSubmonoid K.toSubmonoid with
inv_mem' := fun hx => ⟨H.inv_mem' hx.1, K.inv_mem' hx.2⟩ }
@[to_additive coe_prod]
theorem coe_prod (H : Subgroup G) (K : Subgroup N) :
(H.prod K : Set (G × N)) = (H : Set G) ×ˢ (K : Set N) :=
rfl
@[to_additive mem_prod]
theorem mem_prod {H : Subgroup G} {K : Subgroup N} {p : G × N} : p ∈ H.prod K ↔ p.1 ∈ H ∧ p.2 ∈ K :=
Iff.rfl
open scoped Relator in
@[to_additive prod_mono]
theorem prod_mono : ((· ≤ ·) ⇒ (· ≤ ·) ⇒ (· ≤ ·)) (@prod G _ N _) (@prod G _ N _) :=
fun _s _s' hs _t _t' ht => Set.prod_mono hs ht
@[to_additive prod_mono_right]
theorem prod_mono_right (K : Subgroup G) : Monotone fun t : Subgroup N => K.prod t :=
prod_mono (le_refl K)
@[to_additive prod_mono_left]
theorem prod_mono_left (H : Subgroup N) : Monotone fun K : Subgroup G => K.prod H := fun _ _ hs =>
prod_mono hs (le_refl H)
@[to_additive prod_top]
theorem prod_top (K : Subgroup G) : K.prod (⊤ : Subgroup N) = K.comap (MonoidHom.fst G N) :=
ext fun x => by simp [mem_prod, MonoidHom.coe_fst]
@[to_additive top_prod]
theorem top_prod (H : Subgroup N) : (⊤ : Subgroup G).prod H = H.comap (MonoidHom.snd G N) :=
ext fun x => by simp [mem_prod, MonoidHom.coe_snd]
@[to_additive (attr := simp) top_prod_top]
theorem top_prod_top : (⊤ : Subgroup G).prod (⊤ : Subgroup N) = ⊤ :=
(top_prod _).trans <| comap_top _
@[to_additive (attr := simp) bot_prod_bot]
theorem bot_prod_bot : (⊥ : Subgroup G).prod (⊥ : Subgroup N) = ⊥ :=
SetLike.coe_injective <| by simp [coe_prod]
@[deprecated (since := "2025-03-11")]
alias _root_.AddSubgroup.bot_sum_bot := AddSubgroup.bot_prod_bot
@[to_additive le_prod_iff]
theorem le_prod_iff {H : Subgroup G} {K : Subgroup N} {J : Subgroup (G × N)} :
J ≤ H.prod K ↔ map (MonoidHom.fst G N) J ≤ H ∧ map (MonoidHom.snd G N) J ≤ K := by
simpa only [← Subgroup.toSubmonoid_le] using Submonoid.le_prod_iff
@[to_additive prod_le_iff]
theorem prod_le_iff {H : Subgroup G} {K : Subgroup N} {J : Subgroup (G × N)} :
H.prod K ≤ J ↔ map (MonoidHom.inl G N) H ≤ J ∧ map (MonoidHom.inr G N) K ≤ J := by
simpa only [← Subgroup.toSubmonoid_le] using Submonoid.prod_le_iff
@[to_additive (attr := simp) prod_eq_bot_iff]
theorem prod_eq_bot_iff {H : Subgroup G} {K : Subgroup N} : H.prod K = ⊥ ↔ H = ⊥ ∧ K = ⊥ := by
simpa only [← Subgroup.toSubmonoid_inj] using Submonoid.prod_eq_bot_iff
@[to_additive closure_prod]
theorem closure_prod {s : Set G} {t : Set N} (hs : 1 ∈ s) (ht : 1 ∈ t) :
closure (s ×ˢ t) = (closure s).prod (closure t) :=
le_antisymm
(closure_le _ |>.2 <| Set.prod_subset_prod_iff.2 <| .inl ⟨subset_closure, subset_closure⟩)
(prod_le_iff.2 ⟨
map_le_iff_le_comap.2 <| closure_le _ |>.2 fun _x hx => subset_closure ⟨hx, ht⟩,
map_le_iff_le_comap.2 <| closure_le _ |>.2 fun _y hy => subset_closure ⟨hs, hy⟩⟩)
/-- Product of subgroups is isomorphic to their product as groups. -/
@[to_additive prodEquiv
"Product of additive subgroups is isomorphic to their product
as additive groups"]
def prodEquiv (H : Subgroup G) (K : Subgroup N) : H.prod K ≃* H × K :=
{ Equiv.Set.prod (H : Set G) (K : Set N) with map_mul' := fun _ _ => rfl }
section Pi
variable {η : Type*} {f : η → Type*}
-- defined here and not in Algebra.Group.Submonoid.Operations to have access to Algebra.Group.Pi
/-- A version of `Set.pi` for submonoids. Given an index set `I` and a family of submodules
`s : Π i, Submonoid f i`, `pi I s` is the submonoid of dependent functions `f : Π i, f i` such that
`f i` belongs to `Pi I s` whenever `i ∈ I`. -/
@[to_additive "A version of `Set.pi` for `AddSubmonoid`s. Given an index set `I` and a family
of submodules `s : Π i, AddSubmonoid f i`, `pi I s` is the `AddSubmonoid` of dependent functions
`f : Π i, f i` such that `f i` belongs to `pi I s` whenever `i ∈ I`."]
def _root_.Submonoid.pi [∀ i, MulOneClass (f i)] (I : Set η) (s : ∀ i, Submonoid (f i)) :
Submonoid (∀ i, f i) where
carrier := I.pi fun i => (s i).carrier
one_mem' i _ := (s i).one_mem
mul_mem' hp hq i hI := (s i).mul_mem (hp i hI) (hq i hI)
variable [∀ i, Group (f i)]
/-- A version of `Set.pi` for subgroups. Given an index set `I` and a family of submodules
`s : Π i, Subgroup f i`, `pi I s` is the subgroup of dependent functions `f : Π i, f i` such that
`f i` belongs to `pi I s` whenever `i ∈ I`. -/
@[to_additive
"A version of `Set.pi` for `AddSubgroup`s. Given an index set `I` and a family
of submodules `s : Π i, AddSubgroup f i`, `pi I s` is the `AddSubgroup` of dependent functions
`f : Π i, f i` such that `f i` belongs to `pi I s` whenever `i ∈ I`."]
def pi (I : Set η) (H : ∀ i, Subgroup (f i)) : Subgroup (∀ i, f i) :=
{ Submonoid.pi I fun i => (H i).toSubmonoid with
inv_mem' := fun hp i hI => (H i).inv_mem (hp i hI) }
@[to_additive]
theorem coe_pi (I : Set η) (H : ∀ i, Subgroup (f i)) :
(pi I H : Set (∀ i, f i)) = Set.pi I fun i => (H i : Set (f i)) :=
rfl
@[to_additive]
theorem mem_pi (I : Set η) {H : ∀ i, Subgroup (f i)} {p : ∀ i, f i} :
p ∈ pi I H ↔ ∀ i : η, i ∈ I → p i ∈ H i :=
Iff.rfl
@[to_additive]
theorem pi_top (I : Set η) : (pi I fun i => (⊤ : Subgroup (f i))) = ⊤ :=
ext fun x => by simp [mem_pi]
@[to_additive]
theorem pi_empty (H : ∀ i, Subgroup (f i)) : pi ∅ H = ⊤ :=
ext fun x => by simp [mem_pi]
@[to_additive]
theorem pi_bot : (pi Set.univ fun i => (⊥ : Subgroup (f i))) = ⊥ :=
(eq_bot_iff_forall _).mpr fun p hp => by
simp only [mem_pi, mem_bot] at *
ext j
exact hp j trivial
@[to_additive]
theorem le_pi_iff {I : Set η} {H : ∀ i, Subgroup (f i)} {J : Subgroup (∀ i, f i)} :
J ≤ pi I H ↔ ∀ i : η, i ∈ I → map (Pi.evalMonoidHom f i) J ≤ H i := by
constructor
· intro h i hi
rintro _ ⟨x, hx, rfl⟩
exact (h hx) _ hi
· intro h x hx i hi
exact h i hi ⟨_, hx, rfl⟩
@[to_additive (attr := simp)]
theorem mulSingle_mem_pi [DecidableEq η] {I : Set η} {H : ∀ i, Subgroup (f i)} (i : η) (x : f i) :
Pi.mulSingle i x ∈ pi I H ↔ i ∈ I → x ∈ H i := by
constructor
· intro h hi
simpa using h i hi
· intro h j hj
by_cases heq : j = i
· subst heq
simpa using h hj
· simp [heq, one_mem]
@[to_additive]
theorem pi_eq_bot_iff (H : ∀ i, Subgroup (f i)) : pi Set.univ H = ⊥ ↔ ∀ i, H i = ⊥ := by
classical
simp only [eq_bot_iff_forall]
constructor
· intro h i x hx
have : MonoidHom.mulSingle f i x = 1 :=
h (MonoidHom.mulSingle f i x) ((mulSingle_mem_pi i x).mpr fun _ => hx)
simpa using congr_fun this i
· exact fun h x hx => funext fun i => h _ _ (hx i trivial)
end Pi
end Subgroup
namespace Subgroup
variable {H K : Subgroup G}
variable (H)
/-- A subgroup is characteristic if it is fixed by all automorphisms.
Several equivalent conditions are provided by lemmas of the form `Characteristic.iff...` -/
structure Characteristic : Prop where
/-- `H` is fixed by all automorphisms -/
fixed : ∀ ϕ : G ≃* G, H.comap ϕ.toMonoidHom = H
attribute [class] Characteristic
instance (priority := 100) normal_of_characteristic [h : H.Characteristic] : H.Normal :=
⟨fun a ha b => (SetLike.ext_iff.mp (h.fixed (MulAut.conj b)) a).mpr ha⟩
end Subgroup
namespace AddSubgroup
variable (H : AddSubgroup A)
/-- An `AddSubgroup` is characteristic if it is fixed by all automorphisms.
Several equivalent conditions are provided by lemmas of the form `Characteristic.iff...` -/
structure Characteristic : Prop where
/-- `H` is fixed by all automorphisms -/
fixed : ∀ ϕ : A ≃+ A, H.comap ϕ.toAddMonoidHom = H
attribute [to_additive] Subgroup.Characteristic
attribute [class] Characteristic
instance (priority := 100) normal_of_characteristic [h : H.Characteristic] : H.Normal :=
⟨fun a ha b => (SetLike.ext_iff.mp (h.fixed (AddAut.conj b)) a).mpr ha⟩
end AddSubgroup
namespace Subgroup
variable {H K : Subgroup G}
@[to_additive]
theorem characteristic_iff_comap_eq : H.Characteristic ↔ ∀ ϕ : G ≃* G, H.comap ϕ.toMonoidHom = H :=
⟨Characteristic.fixed, Characteristic.mk⟩
@[to_additive]
theorem characteristic_iff_comap_le : H.Characteristic ↔ ∀ ϕ : G ≃* G, H.comap ϕ.toMonoidHom ≤ H :=
characteristic_iff_comap_eq.trans
⟨fun h ϕ => le_of_eq (h ϕ), fun h ϕ =>
le_antisymm (h ϕ) fun g hg => h ϕ.symm ((congr_arg (· ∈ H) (ϕ.symm_apply_apply g)).mpr hg)⟩
@[to_additive]
theorem characteristic_iff_le_comap : H.Characteristic ↔ ∀ ϕ : G ≃* G, H ≤ H.comap ϕ.toMonoidHom :=
characteristic_iff_comap_eq.trans
⟨fun h ϕ => ge_of_eq (h ϕ), fun h ϕ =>
le_antisymm (fun g hg => (congr_arg (· ∈ H) (ϕ.symm_apply_apply g)).mp (h ϕ.symm hg)) (h ϕ)⟩
@[to_additive]
theorem characteristic_iff_map_eq : H.Characteristic ↔ ∀ ϕ : G ≃* G, H.map ϕ.toMonoidHom = H := by
simp_rw [map_equiv_eq_comap_symm']
exact characteristic_iff_comap_eq.trans ⟨fun h ϕ => h ϕ.symm, fun h ϕ => h ϕ.symm⟩
@[to_additive]
theorem characteristic_iff_map_le : H.Characteristic ↔ ∀ ϕ : G ≃* G, H.map ϕ.toMonoidHom ≤ H := by
simp_rw [map_equiv_eq_comap_symm']
exact characteristic_iff_comap_le.trans ⟨fun h ϕ => h ϕ.symm, fun h ϕ => h ϕ.symm⟩
@[to_additive]
theorem characteristic_iff_le_map : H.Characteristic ↔ ∀ ϕ : G ≃* G, H ≤ H.map ϕ.toMonoidHom := by
simp_rw [map_equiv_eq_comap_symm']
exact characteristic_iff_le_comap.trans ⟨fun h ϕ => h ϕ.symm, fun h ϕ => h ϕ.symm⟩
@[to_additive]
instance botCharacteristic : Characteristic (⊥ : Subgroup G) :=
characteristic_iff_le_map.mpr fun _ϕ => bot_le
@[to_additive]
instance topCharacteristic : Characteristic (⊤ : Subgroup G) :=
characteristic_iff_map_le.mpr fun _ϕ => le_top
variable (H)
section Normalizer
variable {H}
@[to_additive]
theorem normalizer_eq_top_iff : H.normalizer = ⊤ ↔ H.Normal :=
eq_top_iff.trans
⟨fun h => ⟨fun a ha b => (h (mem_top b) a).mp ha⟩, fun h a _ha b =>
⟨fun hb => h.conj_mem b hb a, fun hb => by rwa [h.mem_comm_iff, inv_mul_cancel_left] at hb⟩⟩
variable (H) in
@[to_additive]
theorem normalizer_eq_top [h : H.Normal] : H.normalizer = ⊤ :=
normalizer_eq_top_iff.mpr h
variable {N : Type*} [Group N]
/-- The preimage of the normalizer is contained in the normalizer of the preimage. -/
@[to_additive "The preimage of the normalizer is contained in the normalizer of the preimage."]
theorem le_normalizer_comap (f : N →* G) :
H.normalizer.comap f ≤ (H.comap f).normalizer := fun x => by
simp only [mem_normalizer_iff, mem_comap]
intro h n
simp [h (f n)]
/-- The image of the normalizer is contained in the normalizer of the image. -/
@[to_additive "The image of the normalizer is contained in the normalizer of the image."]
theorem le_normalizer_map (f : G →* N) : H.normalizer.map f ≤ (H.map f).normalizer := fun _ => by
simp only [and_imp, exists_prop, mem_map, exists_imp, mem_normalizer_iff]
rintro x hx rfl n
constructor
· rintro ⟨y, hy, rfl⟩
use x * y * x⁻¹, (hx y).1 hy
simp
· rintro ⟨y, hyH, hy⟩
use x⁻¹ * y * x
rw [hx]
simp [hy, hyH, mul_assoc]
@[to_additive]
theorem comap_normalizer_eq_of_le_range {f : N →* G} (h : H ≤ f.range) :
comap f H.normalizer = (comap f H).normalizer := by
apply le_antisymm (le_normalizer_comap f)
rw [← map_le_iff_le_comap]
apply (le_normalizer_map f).trans
rw [map_comap_eq_self h]
@[to_additive]
theorem subgroupOf_normalizer_eq {H N : Subgroup G} (h : H ≤ N) :
H.normalizer.subgroupOf N = (H.subgroupOf N).normalizer :=
comap_normalizer_eq_of_le_range (h.trans_eq N.range_subtype.symm)
@[to_additive]
theorem normal_subgroupOf_iff_le_normalizer (h : H ≤ K) :
(H.subgroupOf K).Normal ↔ K ≤ H.normalizer := by
rw [← subgroupOf_eq_top, subgroupOf_normalizer_eq h, normalizer_eq_top_iff]
@[to_additive]
theorem normal_subgroupOf_iff_le_normalizer_inf :
(H.subgroupOf K).Normal ↔ K ≤ (H ⊓ K).normalizer :=
inf_subgroupOf_right H K ▸ normal_subgroupOf_iff_le_normalizer inf_le_right
@[to_additive]
instance (priority := 100) normal_in_normalizer : (H.subgroupOf H.normalizer).Normal :=
(normal_subgroupOf_iff_le_normalizer H.le_normalizer).mpr le_rfl
@[to_additive]
theorem le_normalizer_of_normal_subgroupOf [hK : (H.subgroupOf K).Normal] (HK : H ≤ K) :
K ≤ H.normalizer :=
(normal_subgroupOf_iff_le_normalizer HK).mp hK
@[to_additive]
theorem subset_normalizer_of_normal {S : Set G} [hH : H.Normal] : S ⊆ H.normalizer :=
(@normalizer_eq_top _ _ H hH) ▸ le_top
@[to_additive]
theorem le_normalizer_of_normal [H.Normal] : K ≤ H.normalizer := subset_normalizer_of_normal
@[to_additive]
theorem inf_normalizer_le_normalizer_inf : H.normalizer ⊓ K.normalizer ≤ (H ⊓ K).normalizer :=
fun _ h g ↦ and_congr (h.1 g) (h.2 g)
variable (G) in
/-- Every proper subgroup `H` of `G` is a proper normal subgroup of the normalizer of `H` in `G`. -/
def _root_.NormalizerCondition :=
∀ H : Subgroup G, H < ⊤ → H < normalizer H
/-- Alternative phrasing of the normalizer condition: Only the full group is self-normalizing.
This may be easier to work with, as it avoids inequalities and negations. -/
theorem _root_.normalizerCondition_iff_only_full_group_self_normalizing :
NormalizerCondition G ↔ ∀ H : Subgroup G, H.normalizer = H → H = ⊤ := by
apply forall_congr'; intro H
simp only [lt_iff_le_and_ne, le_normalizer, le_top, Ne]
tauto
variable (H)
end Normalizer
end Subgroup
namespace Group
variable {s : Set G}
/-- Given a set `s`, `conjugatesOfSet s` is the set of all conjugates of
the elements of `s`. -/
def conjugatesOfSet (s : Set G) : Set G :=
⋃ a ∈ s, conjugatesOf a
theorem mem_conjugatesOfSet_iff {x : G} : x ∈ conjugatesOfSet s ↔ ∃ a ∈ s, IsConj a x := by
rw [conjugatesOfSet, Set.mem_iUnion₂]
simp only [conjugatesOf, isConj_iff, Set.mem_setOf_eq, exists_prop]
theorem subset_conjugatesOfSet : s ⊆ conjugatesOfSet s := fun (x : G) (h : x ∈ s) =>
mem_conjugatesOfSet_iff.2 ⟨x, h, IsConj.refl _⟩
theorem conjugatesOfSet_mono {s t : Set G} (h : s ⊆ t) : conjugatesOfSet s ⊆ conjugatesOfSet t :=
Set.biUnion_subset_biUnion_left h
theorem conjugates_subset_normal {N : Subgroup G} [tn : N.Normal] {a : G} (h : a ∈ N) :
conjugatesOf a ⊆ N := by
rintro a hc
obtain ⟨c, rfl⟩ := isConj_iff.1 hc
exact tn.conj_mem a h c
theorem conjugatesOfSet_subset {s : Set G} {N : Subgroup G} [N.Normal] (h : s ⊆ N) :
conjugatesOfSet s ⊆ N :=
Set.iUnion₂_subset fun _x H => conjugates_subset_normal (h H)
/-- The set of conjugates of `s` is closed under conjugation. -/
theorem conj_mem_conjugatesOfSet {x c : G} :
x ∈ conjugatesOfSet s → c * x * c⁻¹ ∈ conjugatesOfSet s := fun H => by
rcases mem_conjugatesOfSet_iff.1 H with ⟨a, h₁, h₂⟩
exact mem_conjugatesOfSet_iff.2 ⟨a, h₁, h₂.trans (isConj_iff.2 ⟨c, rfl⟩)⟩
end Group
namespace Subgroup
open Group
variable {s : Set G}
/-- The normal closure of a set `s` is the subgroup closure of all the conjugates of
elements of `s`. It is the smallest normal subgroup containing `s`. -/
def normalClosure (s : Set G) : Subgroup G :=
closure (conjugatesOfSet s)
theorem conjugatesOfSet_subset_normalClosure : conjugatesOfSet s ⊆ normalClosure s :=
subset_closure
theorem subset_normalClosure : s ⊆ normalClosure s :=
Set.Subset.trans subset_conjugatesOfSet conjugatesOfSet_subset_normalClosure
theorem le_normalClosure {H : Subgroup G} : H ≤ normalClosure ↑H := fun _ h =>
subset_normalClosure h
/-- The normal closure of `s` is a normal subgroup. -/
instance normalClosure_normal : (normalClosure s).Normal :=
⟨fun n h g => by
refine Subgroup.closure_induction (fun x hx => ?_) ?_ (fun x y _ _ ihx ihy => ?_)
(fun x _ ihx => ?_) h
· exact conjugatesOfSet_subset_normalClosure (conj_mem_conjugatesOfSet hx)
· simpa using (normalClosure s).one_mem
· rw [← conj_mul]
exact mul_mem ihx ihy
· rw [← conj_inv]
exact inv_mem ihx⟩
/-- The normal closure of `s` is the smallest normal subgroup containing `s`. -/
theorem normalClosure_le_normal {N : Subgroup G} [N.Normal] (h : s ⊆ N) : normalClosure s ≤ N := by
intro a w
refine closure_induction (fun x hx => ?_) ?_ (fun x y _ _ ihx ihy => ?_) (fun x _ ihx => ?_) w
· exact conjugatesOfSet_subset h hx
· exact one_mem _
· exact mul_mem ihx ihy
· exact inv_mem ihx
theorem normalClosure_subset_iff {N : Subgroup G} [N.Normal] : s ⊆ N ↔ normalClosure s ≤ N :=
⟨normalClosure_le_normal, Set.Subset.trans subset_normalClosure⟩
@[gcongr]
theorem normalClosure_mono {s t : Set G} (h : s ⊆ t) : normalClosure s ≤ normalClosure t :=
normalClosure_le_normal (Set.Subset.trans h subset_normalClosure)
theorem normalClosure_eq_iInf :
normalClosure s = ⨅ (N : Subgroup G) (_ : Normal N) (_ : s ⊆ N), N :=
le_antisymm (le_iInf fun _ => le_iInf fun _ => le_iInf normalClosure_le_normal)
(iInf_le_of_le (normalClosure s)
(iInf_le_of_le (by infer_instance) (iInf_le_of_le subset_normalClosure le_rfl)))
@[simp]
theorem normalClosure_eq_self (H : Subgroup G) [H.Normal] : normalClosure ↑H = H :=
le_antisymm (normalClosure_le_normal rfl.subset) le_normalClosure
theorem normalClosure_idempotent : normalClosure ↑(normalClosure s) = normalClosure s :=
normalClosure_eq_self _
theorem closure_le_normalClosure {s : Set G} : closure s ≤ normalClosure s := by
simp only [subset_normalClosure, closure_le]
@[simp]
theorem normalClosure_closure_eq_normalClosure {s : Set G} :
normalClosure ↑(closure s) = normalClosure s :=
le_antisymm (normalClosure_le_normal closure_le_normalClosure) (normalClosure_mono subset_closure)
/-- The normal core of a subgroup `H` is the largest normal subgroup of `G` contained in `H`,
as shown by `Subgroup.normalCore_eq_iSup`. -/
def normalCore (H : Subgroup G) : Subgroup G where
carrier := { a : G | ∀ b : G, b * a * b⁻¹ ∈ H }
one_mem' a := by rw [mul_one, mul_inv_cancel]; exact H.one_mem
inv_mem' {_} h b := (congr_arg (· ∈ H) conj_inv).mp (H.inv_mem (h b))
mul_mem' {_ _} ha hb c := (congr_arg (· ∈ H) conj_mul).mp (H.mul_mem (ha c) (hb c))
theorem normalCore_le (H : Subgroup G) : H.normalCore ≤ H := fun a h => by
rw [← mul_one a, ← inv_one, ← one_mul a]
exact h 1
instance normalCore_normal (H : Subgroup G) : H.normalCore.Normal :=
⟨fun a h b c => by
rw [mul_assoc, mul_assoc, ← mul_inv_rev, ← mul_assoc, ← mul_assoc]; exact h (c * b)⟩
theorem normal_le_normalCore {H : Subgroup G} {N : Subgroup G} [hN : N.Normal] :
N ≤ H.normalCore ↔ N ≤ H :=
⟨ge_trans H.normalCore_le, fun h_le n hn g => h_le (hN.conj_mem n hn g)⟩
theorem normalCore_mono {H K : Subgroup G} (h : H ≤ K) : H.normalCore ≤ K.normalCore :=
normal_le_normalCore.mpr (H.normalCore_le.trans h)
theorem normalCore_eq_iSup (H : Subgroup G) :
H.normalCore = ⨆ (N : Subgroup G) (_ : Normal N) (_ : N ≤ H), N :=
le_antisymm
(le_iSup_of_le H.normalCore
(le_iSup_of_le H.normalCore_normal (le_iSup_of_le H.normalCore_le le_rfl)))
(iSup_le fun _ => iSup_le fun _ => iSup_le normal_le_normalCore.mpr)
@[simp]
theorem normalCore_eq_self (H : Subgroup G) [H.Normal] : H.normalCore = H :=
le_antisymm H.normalCore_le (normal_le_normalCore.mpr le_rfl)
theorem normalCore_idempotent (H : Subgroup G) : H.normalCore.normalCore = H.normalCore :=
H.normalCore.normalCore_eq_self
end Subgroup
namespace MonoidHom
variable {N : Type*} {P : Type*} [Group N] [Group P] (K : Subgroup G)
open Subgroup
section Ker
variable {M : Type*} [MulOneClass M]
@[to_additive prodMap_comap_prod]
theorem prodMap_comap_prod {G' : Type*} {N' : Type*} [Group G'] [Group N'] (f : G →* N)
(g : G' →* N') (S : Subgroup N) (S' : Subgroup N') :
(S.prod S').comap (prodMap f g) = (S.comap f).prod (S'.comap g) :=
SetLike.coe_injective <| Set.preimage_prod_map_prod f g _ _
@[deprecated (since := "2025-03-11")]
alias _root_.AddMonoidHom.sumMap_comap_sum := AddMonoidHom.prodMap_comap_prod
@[to_additive ker_prodMap]
theorem ker_prodMap {G' : Type*} {N' : Type*} [Group G'] [Group N'] (f : G →* N) (g : G' →* N') :
(prodMap f g).ker = f.ker.prod g.ker := by
rw [← comap_bot, ← comap_bot, ← comap_bot, ← prodMap_comap_prod, bot_prod_bot]
@[deprecated (since := "2025-03-11")]
alias _root_.AddMonoidHom.ker_sumMap := AddMonoidHom.ker_prodMap
@[to_additive (attr := simp)]
lemma ker_fst : ker (fst G G') = .prod ⊥ ⊤ := SetLike.ext fun _ => (iff_of_eq (and_true _)).symm
@[to_additive (attr := simp)]
lemma ker_snd : ker (snd G G') = .prod ⊤ ⊥ := SetLike.ext fun _ => (iff_of_eq (true_and _)).symm
end Ker
end MonoidHom
namespace Subgroup
variable {N : Type*} [Group N] (H : Subgroup G)
@[to_additive]
theorem Normal.map {H : Subgroup G} (h : H.Normal) (f : G →* N) (hf : Function.Surjective f) :
(H.map f).Normal := by
rw [← normalizer_eq_top_iff, ← top_le_iff, ← f.range_eq_top_of_surjective hf, f.range_eq_map,
← H.normalizer_eq_top]
exact le_normalizer_map _
end Subgroup
namespace Subgroup
open MonoidHom
variable {N : Type*} [Group N] (f : G →* N)
/-- The preimage of the normalizer is equal to the normalizer of the preimage of a surjective
function. -/
@[to_additive
"The preimage of the normalizer is equal to the normalizer of the preimage of
a surjective function."]
theorem comap_normalizer_eq_of_surjective (H : Subgroup G) {f : N →* G}
(hf : Function.Surjective f) : H.normalizer.comap f = (H.comap f).normalizer :=
comap_normalizer_eq_of_le_range fun x _ ↦ hf x
@[deprecated (since := "2025-03-13")]
alias comap_normalizer_eq_of_injective_of_le_range := comap_normalizer_eq_of_le_range
@[deprecated (since := "2025-03-13")]
alias _root_.AddSubgroup.comap_normalizer_eq_of_injective_of_le_range :=
AddSubgroup.comap_normalizer_eq_of_le_range
/-- The image of the normalizer is equal to the normalizer of the image of an isomorphism. -/
@[to_additive
"The image of the normalizer is equal to the normalizer of the image of an
isomorphism."]
theorem map_equiv_normalizer_eq (H : Subgroup G) (f : G ≃* N) :
H.normalizer.map f.toMonoidHom = (H.map f.toMonoidHom).normalizer := by
ext x
simp only [mem_normalizer_iff, mem_map_equiv]
rw [f.toEquiv.forall_congr]
intro
simp
/-- The image of the normalizer is equal to the normalizer of the image of a bijective
function. -/
@[to_additive
"The image of the normalizer is equal to the normalizer of the image of a bijective
function."]
theorem map_normalizer_eq_of_bijective (H : Subgroup G) {f : G →* N} (hf : Function.Bijective f) :
H.normalizer.map f = (H.map f).normalizer :=
map_equiv_normalizer_eq H (MulEquiv.ofBijective f hf)
end Subgroup
namespace MonoidHom
variable {G₁ G₂ G₃ : Type*} [Group G₁] [Group G₂] [Group G₃]
variable (f : G₁ →* G₂) (f_inv : G₂ → G₁)
/-- Auxiliary definition used to define `liftOfRightInverse` -/
@[to_additive "Auxiliary definition used to define `liftOfRightInverse`"]
def liftOfRightInverseAux (hf : Function.RightInverse f_inv f) (g : G₁ →* G₃) (hg : f.ker ≤ g.ker) :
G₂ →* G₃ where
toFun b := g (f_inv b)
map_one' := hg (hf 1)
map_mul' := by
intro x y
rw [← g.map_mul, ← mul_inv_eq_one, ← g.map_inv, ← g.map_mul, ← g.mem_ker]
apply hg
rw [f.mem_ker, f.map_mul, f.map_inv, mul_inv_eq_one, f.map_mul]
simp only [hf _]
@[to_additive (attr := simp)]
theorem liftOfRightInverseAux_comp_apply (hf : Function.RightInverse f_inv f) (g : G₁ →* G₃)
(hg : f.ker ≤ g.ker) (x : G₁) : (f.liftOfRightInverseAux f_inv hf g hg) (f x) = g x := by
dsimp [liftOfRightInverseAux]
rw [← mul_inv_eq_one, ← g.map_inv, ← g.map_mul, ← g.mem_ker]
apply hg
rw [f.mem_ker, f.map_mul, f.map_inv, mul_inv_eq_one]
simp only [hf _]
/-- `liftOfRightInverse f hf g hg` is the unique group homomorphism `φ`
* such that `φ.comp f = g` (`MonoidHom.liftOfRightInverse_comp`),
* where `f : G₁ →+* G₂` has a RightInverse `f_inv` (`hf`),
* and `g : G₂ →+* G₃` satisfies `hg : f.ker ≤ g.ker`.
See `MonoidHom.eq_liftOfRightInverse` for the uniqueness lemma.
```
G₁.
| \
f | \ g
| \
v \⌟
G₂----> G₃
∃!φ
```
-/
@[to_additive
"`liftOfRightInverse f f_inv hf g hg` is the unique additive group homomorphism `φ`
* such that `φ.comp f = g` (`AddMonoidHom.liftOfRightInverse_comp`),
* where `f : G₁ →+ G₂` has a RightInverse `f_inv` (`hf`),
* and `g : G₂ →+ G₃` satisfies `hg : f.ker ≤ g.ker`.
See `AddMonoidHom.eq_liftOfRightInverse` for the uniqueness lemma.
```
G₁.
| \\
f | \\ g
| \\
v \\⌟
G₂----> G₃
∃!φ
```"]
def liftOfRightInverse (hf : Function.RightInverse f_inv f) :
{ g : G₁ →* G₃ // f.ker ≤ g.ker } ≃ (G₂ →* G₃) where
toFun g := f.liftOfRightInverseAux f_inv hf g.1 g.2
invFun φ := ⟨φ.comp f, fun x hx ↦ mem_ker.mpr <| by simp [mem_ker.mp hx]⟩
left_inv g := by
ext
simp only [comp_apply, liftOfRightInverseAux_comp_apply, Subtype.coe_mk]
right_inv φ := by
ext b
simp [liftOfRightInverseAux, hf b]
/-- A non-computable version of `MonoidHom.liftOfRightInverse` for when no computable right
inverse is available, that uses `Function.surjInv`. -/
@[to_additive (attr := simp)
"A non-computable version of `AddMonoidHom.liftOfRightInverse` for when no
computable right inverse is available."]
noncomputable abbrev liftOfSurjective (hf : Function.Surjective f) :
{ g : G₁ →* G₃ // f.ker ≤ g.ker } ≃ (G₂ →* G₃) :=
f.liftOfRightInverse (Function.surjInv hf) (Function.rightInverse_surjInv hf)
@[to_additive (attr := simp)]
theorem liftOfRightInverse_comp_apply (hf : Function.RightInverse f_inv f)
(g : { g : G₁ →* G₃ // f.ker ≤ g.ker }) (x : G₁) :
(f.liftOfRightInverse f_inv hf g) (f x) = g.1 x :=
f.liftOfRightInverseAux_comp_apply f_inv hf g.1 g.2 x
@[to_additive (attr := simp)]
theorem liftOfRightInverse_comp (hf : Function.RightInverse f_inv f)
(g : { g : G₁ →* G₃ // f.ker ≤ g.ker }) : (f.liftOfRightInverse f_inv hf g).comp f = g :=
MonoidHom.ext <| f.liftOfRightInverse_comp_apply f_inv hf g
@[to_additive]
theorem eq_liftOfRightInverse (hf : Function.RightInverse f_inv f) (g : G₁ →* G₃)
(hg : f.ker ≤ g.ker) (h : G₂ →* G₃) (hh : h.comp f = g) :
h = f.liftOfRightInverse f_inv hf ⟨g, hg⟩ := by
simp_rw [← hh]
exact ((f.liftOfRightInverse f_inv hf).apply_symm_apply _).symm
end MonoidHom
variable {N : Type*} [Group N]
namespace Subgroup
-- Here `H.Normal` is an explicit argument so we can use dot notation with `comap`.
@[to_additive]
theorem Normal.comap {H : Subgroup N} (hH : H.Normal) (f : G →* N) : (H.comap f).Normal :=
⟨fun _ => by simp +contextual [Subgroup.mem_comap, hH.conj_mem]⟩
@[to_additive]
instance (priority := 100) normal_comap {H : Subgroup N} [nH : H.Normal] (f : G →* N) :
(H.comap f).Normal :=
nH.comap _
-- Here `H.Normal` is an explicit argument so we can use dot notation with `subgroupOf`.
@[to_additive]
theorem Normal.subgroupOf {H : Subgroup G} (hH : H.Normal) (K : Subgroup G) :
(H.subgroupOf K).Normal :=
hH.comap _
@[to_additive]
instance (priority := 100) normal_subgroupOf {H N : Subgroup G} [N.Normal] :
(N.subgroupOf H).Normal :=
Subgroup.normal_comap _
theorem map_normalClosure (s : Set G) (f : G →* N) (hf : Surjective f) :
(normalClosure s).map f = normalClosure (f '' s) := by
have : Normal (map f (normalClosure s)) := Normal.map inferInstance f hf
apply le_antisymm
· simp [map_le_iff_le_comap, normalClosure_le_normal, coe_comap,
← Set.image_subset_iff, subset_normalClosure]
· exact normalClosure_le_normal (Set.image_subset f subset_normalClosure)
theorem comap_normalClosure (s : Set N) (f : G ≃* N) :
normalClosure (f ⁻¹' s) = (normalClosure s).comap f := by
have := Set.preimage_equiv_eq_image_symm s f.toEquiv
simp_all [comap_equiv_eq_map_symm, map_normalClosure s (f.symm : N →* G) f.symm.surjective]
lemma Normal.of_map_injective {G H : Type*} [Group G] [Group H] {φ : G →* H}
(hφ : Function.Injective φ) {L : Subgroup G} (n : (L.map φ).Normal) : L.Normal :=
L.comap_map_eq_self_of_injective hφ ▸ n.comap φ
theorem Normal.of_map_subtype {K : Subgroup G} {L : Subgroup K}
(n : (Subgroup.map K.subtype L).Normal) : L.Normal :=
n.of_map_injective K.subtype_injective
end Subgroup
namespace Subgroup
section SubgroupNormal
@[to_additive]
theorem normal_subgroupOf_iff {H K : Subgroup G} (hHK : H ≤ K) :
(H.subgroupOf K).Normal ↔ ∀ h k, h ∈ H → k ∈ K → k * h * k⁻¹ ∈ H :=
⟨fun hN h k hH hK => hN.conj_mem ⟨h, hHK hH⟩ hH ⟨k, hK⟩, fun hN =>
{ conj_mem := fun h hm k => hN h.1 k.1 hm k.2 }⟩
@[to_additive prod_addSubgroupOf_prod_normal]
instance prod_subgroupOf_prod_normal {H₁ K₁ : Subgroup G} {H₂ K₂ : Subgroup N}
[h₁ : (H₁.subgroupOf K₁).Normal] [h₂ : (H₂.subgroupOf K₂).Normal] :
((H₁.prod H₂).subgroupOf (K₁.prod K₂)).Normal where
conj_mem n hgHK g :=
⟨h₁.conj_mem ⟨(n : G × N).fst, (mem_prod.mp n.2).1⟩ hgHK.1
⟨(g : G × N).fst, (mem_prod.mp g.2).1⟩,
h₂.conj_mem ⟨(n : G × N).snd, (mem_prod.mp n.2).2⟩ hgHK.2
⟨(g : G × N).snd, (mem_prod.mp g.2).2⟩⟩
@[deprecated (since := "2025-03-11")]
alias _root_.AddSubgroup.sum_addSubgroupOf_sum_normal := AddSubgroup.prod_addSubgroupOf_prod_normal
@[to_additive prod_normal]
instance prod_normal (H : Subgroup G) (K : Subgroup N) [hH : H.Normal] [hK : K.Normal] :
(H.prod K).Normal where
conj_mem n hg g :=
⟨hH.conj_mem n.fst (Subgroup.mem_prod.mp hg).1 g.fst,
hK.conj_mem n.snd (Subgroup.mem_prod.mp hg).2 g.snd⟩
@[deprecated (since := "2025-03-11")]
alias _root_.AddSubgroup.sum_normal := AddSubgroup.prod_normal
@[to_additive]
theorem inf_subgroupOf_inf_normal_of_right (A B' B : Subgroup G)
[hN : (B'.subgroupOf B).Normal] : ((A ⊓ B').subgroupOf (A ⊓ B)).Normal := by
rw [normal_subgroupOf_iff_le_normalizer_inf] at hN ⊢
rw [inf_inf_inf_comm, inf_idem]
exact le_trans (inf_le_inf A.le_normalizer hN) (inf_normalizer_le_normalizer_inf)
@[to_additive]
theorem inf_subgroupOf_inf_normal_of_left {A' A : Subgroup G} (B : Subgroup G)
[hN : (A'.subgroupOf A).Normal] : ((A' ⊓ B).subgroupOf (A ⊓ B)).Normal := by
rw [normal_subgroupOf_iff_le_normalizer_inf] at hN ⊢
rw [inf_inf_inf_comm, inf_idem]
exact le_trans (inf_le_inf hN B.le_normalizer) (inf_normalizer_le_normalizer_inf)
@[to_additive]
instance normal_inf_normal (H K : Subgroup G) [hH : H.Normal] [hK : K.Normal] : (H ⊓ K).Normal :=
⟨fun n hmem g => ⟨hH.conj_mem n hmem.1 g, hK.conj_mem n hmem.2 g⟩⟩
@[to_additive]
theorem normal_iInf_normal {ι : Type*} {a : ι → Subgroup G}
(norm : ∀ i : ι, (a i).Normal) : (iInf a).Normal := by
constructor
intro g g_in_iInf h
rw [Subgroup.mem_iInf] at g_in_iInf ⊢
intro i
exact (norm i).conj_mem g (g_in_iInf i) h
@[to_additive]
theorem SubgroupNormal.mem_comm {H K : Subgroup G} (hK : H ≤ K) [hN : (H.subgroupOf K).Normal]
{a b : G} (hb : b ∈ K) (h : a * b ∈ H) : b * a ∈ H := by
have := (normal_subgroupOf_iff hK).mp hN (a * b) b h hb
rwa [mul_assoc, mul_assoc, mul_inv_cancel, mul_one] at this
/-- Elements of disjoint, normal subgroups commute. -/
@[to_additive "Elements of disjoint, normal subgroups commute."]
theorem commute_of_normal_of_disjoint (H₁ H₂ : Subgroup G) (hH₁ : H₁.Normal) (hH₂ : H₂.Normal)
(hdis : Disjoint H₁ H₂) (x y : G) (hx : x ∈ H₁) (hy : y ∈ H₂) : Commute x y := by
suffices x * y * x⁻¹ * y⁻¹ = 1 by
show x * y = y * x
· rw [mul_assoc, mul_eq_one_iff_eq_inv] at this
simpa
apply hdis.le_bot
constructor
· suffices x * (y * x⁻¹ * y⁻¹) ∈ H₁ by simpa [mul_assoc]
exact H₁.mul_mem hx (hH₁.conj_mem _ (H₁.inv_mem hx) _)
· show x * y * x⁻¹ * y⁻¹ ∈ H₂
apply H₂.mul_mem _ (H₂.inv_mem hy)
apply hH₂.conj_mem _ hy
@[to_additive]
theorem normal_subgroupOf_of_le_normalizer {H N : Subgroup G}
(hLE : H ≤ N.normalizer) : (N.subgroupOf H).Normal := by
rw [normal_subgroupOf_iff_le_normalizer_inf]
exact (le_inf hLE H.le_normalizer).trans inf_normalizer_le_normalizer_inf
@[to_additive]
theorem normal_subgroupOf_sup_of_le_normalizer {H N : Subgroup G}
(hLE : H ≤ N.normalizer) : (N.subgroupOf (H ⊔ N)).Normal := by
rw [normal_subgroupOf_iff_le_normalizer le_sup_right]
exact sup_le hLE le_normalizer
end SubgroupNormal
end Subgroup
namespace IsConj
open Subgroup
theorem normalClosure_eq_top_of {N : Subgroup G} [hn : N.Normal] {g g' : G} {hg : g ∈ N}
{hg' : g' ∈ N} (hc : IsConj g g') (ht : normalClosure ({⟨g, hg⟩} : Set N) = ⊤) :
normalClosure ({⟨g', hg'⟩} : Set N) = ⊤ := by
obtain ⟨c, rfl⟩ := isConj_iff.1 hc
have h : ∀ x : N, (MulAut.conj c) x ∈ N := by
rintro ⟨x, hx⟩
exact hn.conj_mem _ hx c
have hs : Function.Surjective (((MulAut.conj c).toMonoidHom.restrict N).codRestrict _ h) := by
rintro ⟨x, hx⟩
refine ⟨⟨c⁻¹ * x * c, ?_⟩, ?_⟩
· have h := hn.conj_mem _ hx c⁻¹
rwa [inv_inv] at h
simp only [MonoidHom.codRestrict_apply, MulEquiv.coe_toMonoidHom, MulAut.conj_apply, coe_mk,
MonoidHom.restrict_apply, Subtype.mk_eq_mk, ← mul_assoc, mul_inv_cancel, one_mul]
rw [mul_assoc, mul_inv_cancel, mul_one]
rw [eq_top_iff, ← MonoidHom.range_eq_top.2 hs, MonoidHom.range_eq_map]
refine le_trans (map_mono (eq_top_iff.1 ht)) (map_le_iff_le_comap.2 (normalClosure_le_normal ?_))
rw [Set.singleton_subset_iff, SetLike.mem_coe]
simp only [MonoidHom.codRestrict_apply, MulEquiv.coe_toMonoidHom, MulAut.conj_apply, coe_mk,
MonoidHom.restrict_apply, mem_comap]
exact subset_normalClosure (Set.mem_singleton _)
end IsConj
namespace ConjClasses
/-- The conjugacy classes that are not trivial. -/
def noncenter (G : Type*) [Monoid G] : Set (ConjClasses G) :=
{x | x.carrier.Nontrivial}
@[simp] lemma mem_noncenter {G} [Monoid G] (g : ConjClasses G) :
g ∈ noncenter G ↔ g.carrier.Nontrivial := Iff.rfl
end ConjClasses
/-- Suppose `G` acts on `M` and `I` is a subgroup of `M`.
The inertia subgroup of `I` is the subgroup of `G` whose action is trivial mod `I`. -/
def AddSubgroup.inertia {M : Type*} [AddGroup M] (I : AddSubgroup M) (G : Type*)
[Group G] [MulAction G M] : Subgroup G where
carrier := { σ | ∀ x, σ • x - x ∈ I }
mul_mem' {a b} ha hb x := by simpa [mul_smul] using add_mem (ha (b • x)) (hb x)
one_mem' := by simp [zero_mem]
inv_mem' {a} ha x := by simpa using sub_mem_comm_iff.mp (ha (a⁻¹ • x))
@[simp] lemma AddSubgroup.mem_inertia {M : Type*} [AddGroup M] {I : AddSubgroup M} {G : Type*}
[Group G] [MulAction G M] {σ : G} : σ ∈ I.inertia G ↔ ∀ x, σ • x - x ∈ I := .rfl
| Mathlib/Algebra/Group/Subgroup/Basic.lean | 3,587 | 3,593 | |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker
-/
import Mathlib.Algebra.Field.IsField
import Mathlib.Algebra.Polynomial.Inductions
import Mathlib.Algebra.Polynomial.Monic
import Mathlib.Algebra.Ring.Regular
import Mathlib.RingTheory.Multiplicity
import Mathlib.Data.Nat.Lattice
/-!
# Division of univariate polynomials
The main defs are `divByMonic` and `modByMonic`.
The compatibility between these is given by `modByMonic_add_div`.
We also define `rootMultiplicity`.
-/
noncomputable section
open Polynomial
open Finset
namespace Polynomial
universe u v w z
variable {R : Type u} {S : Type v} {T : Type w} {A : Type z} {a b : R} {n : ℕ}
section Semiring
variable [Semiring R]
theorem X_dvd_iff {f : R[X]} : X ∣ f ↔ f.coeff 0 = 0 :=
⟨fun ⟨g, hfg⟩ => by rw [hfg, coeff_X_mul_zero], fun hf =>
⟨f.divX, by rw [← add_zero (X * f.divX), ← C_0, ← hf, X_mul_divX_add]⟩⟩
theorem X_pow_dvd_iff {f : R[X]} {n : ℕ} : X ^ n ∣ f ↔ ∀ d < n, f.coeff d = 0 :=
⟨fun ⟨g, hgf⟩ d hd => by
simp only [hgf, coeff_X_pow_mul', ite_eq_right_iff, not_le_of_lt hd, IsEmpty.forall_iff],
fun hd => by
induction n with
| zero => simp [pow_zero, one_dvd]
| succ n hn =>
obtain ⟨g, hgf⟩ := hn fun d : ℕ => fun H : d < n => hd _ (Nat.lt_succ_of_lt H)
have := coeff_X_pow_mul g n 0
rw [zero_add, ← hgf, hd n (Nat.lt_succ_self n)] at this
obtain ⟨k, hgk⟩ := Polynomial.X_dvd_iff.mpr this.symm
use k
rwa [pow_succ, mul_assoc, ← hgk]⟩
variable {p q : R[X]}
theorem finiteMultiplicity_of_degree_pos_of_monic (hp : (0 : WithBot ℕ) < degree p) (hmp : Monic p)
(hq : q ≠ 0) : FiniteMultiplicity p q :=
have zn0 : (0 : R) ≠ 1 :=
haveI := Nontrivial.of_polynomial_ne hq
zero_ne_one
⟨natDegree q, fun ⟨r, hr⟩ => by
have hp0 : p ≠ 0 := fun hp0 => by simp [hp0] at hp
have hr0 : r ≠ 0 := fun hr0 => by subst hr0; simp [hq] at hr
have hpn1 : leadingCoeff p ^ (natDegree q + 1) = 1 := by simp [show _ = _ from hmp]
have hpn0' : leadingCoeff p ^ (natDegree q + 1) ≠ 0 := hpn1.symm ▸ zn0.symm
have hpnr0 : leadingCoeff (p ^ (natDegree q + 1)) * leadingCoeff r ≠ 0 := by
simp only [leadingCoeff_pow' hpn0', leadingCoeff_eq_zero, hpn1, one_pow, one_mul, Ne,
hr0, not_false_eq_true]
have hnp : 0 < natDegree p := Nat.cast_lt.1 <| by
rw [← degree_eq_natDegree hp0]; exact hp
have := congr_arg natDegree hr
rw [natDegree_mul' hpnr0, natDegree_pow' hpn0', add_mul, add_assoc] at this
exact
ne_of_lt
(lt_add_of_le_of_pos (le_mul_of_one_le_right (Nat.zero_le _) hnp)
(add_pos_of_pos_of_nonneg (by rwa [one_mul]) (Nat.zero_le _)))
this⟩
@[deprecated (since := "2024-11-30")]
alias multiplicity_finite_of_degree_pos_of_monic := finiteMultiplicity_of_degree_pos_of_monic
end Semiring
section Ring
variable [Ring R] {p q : R[X]}
theorem div_wf_lemma (h : degree q ≤ degree p ∧ p ≠ 0) (hq : Monic q) :
degree (p - q * (C (leadingCoeff p) * X ^ (natDegree p - natDegree q))) < degree p :=
have hp : leadingCoeff p ≠ 0 := mt leadingCoeff_eq_zero.1 h.2
have hq0 : q ≠ 0 := hq.ne_zero_of_polynomial_ne h.2
have hlt : natDegree q ≤ natDegree p :=
(Nat.cast_le (α := WithBot ℕ)).1
(by rw [← degree_eq_natDegree h.2, ← degree_eq_natDegree hq0]; exact h.1)
degree_sub_lt
(by
rw [hq.degree_mul_comm, hq.degree_mul, degree_C_mul_X_pow _ hp, degree_eq_natDegree h.2,
degree_eq_natDegree hq0, ← Nat.cast_add, tsub_add_cancel_of_le hlt])
h.2 (by rw [leadingCoeff_monic_mul hq, leadingCoeff_mul_X_pow, leadingCoeff_C])
/-- See `divByMonic`. -/
noncomputable def divModByMonicAux : ∀ (_p : R[X]) {q : R[X]}, Monic q → R[X] × R[X]
| p, q, hq =>
letI := Classical.decEq R
if h : degree q ≤ degree p ∧ p ≠ 0 then
let z := C (leadingCoeff p) * X ^ (natDegree p - natDegree q)
have _wf := div_wf_lemma h hq
let dm := divModByMonicAux (p - q * z) hq
⟨z + dm.1, dm.2⟩
else ⟨0, p⟩
termination_by p => p
/-- `divByMonic`, denoted as `p /ₘ q`, gives the quotient of `p` by a monic polynomial `q`. -/
def divByMonic (p q : R[X]) : R[X] :=
letI := Classical.decEq R
if hq : Monic q then (divModByMonicAux p hq).1 else 0
/-- `modByMonic`, denoted as `p %ₘ q`, gives the remainder of `p` by a monic polynomial `q`. -/
def modByMonic (p q : R[X]) : R[X] :=
letI := Classical.decEq R
if hq : Monic q then (divModByMonicAux p hq).2 else p
@[inherit_doc]
infixl:70 " /ₘ " => divByMonic
@[inherit_doc]
infixl:70 " %ₘ " => modByMonic
theorem degree_modByMonic_lt [Nontrivial R] :
∀ (p : R[X]) {q : R[X]} (_hq : Monic q), degree (p %ₘ q) < degree q
| p, q, hq =>
letI := Classical.decEq R
if h : degree q ≤ degree p ∧ p ≠ 0 then by
have _wf := div_wf_lemma ⟨h.1, h.2⟩ hq
have :=
degree_modByMonic_lt (p - q * (C (leadingCoeff p) * X ^ (natDegree p - natDegree q))) hq
unfold modByMonic at this ⊢
unfold divModByMonicAux
dsimp
rw [dif_pos hq] at this ⊢
rw [if_pos h]
exact this
else
Or.casesOn (not_and_or.1 h)
(by
unfold modByMonic divModByMonicAux
dsimp
rw [dif_pos hq, if_neg h]
exact lt_of_not_ge)
(by
intro hp
unfold modByMonic divModByMonicAux
dsimp
rw [dif_pos hq, if_neg h, Classical.not_not.1 hp]
exact lt_of_le_of_ne bot_le (Ne.symm (mt degree_eq_bot.1 hq.ne_zero)))
termination_by p => p
theorem natDegree_modByMonic_lt (p : R[X]) {q : R[X]} (hmq : Monic q) (hq : q ≠ 1) :
natDegree (p %ₘ q) < q.natDegree := by
by_cases hpq : p %ₘ q = 0
· rw [hpq, natDegree_zero, Nat.pos_iff_ne_zero]
contrapose! hq
exact eq_one_of_monic_natDegree_zero hmq hq
· haveI := Nontrivial.of_polynomial_ne hpq
exact natDegree_lt_natDegree hpq (degree_modByMonic_lt p hmq)
@[simp]
theorem zero_modByMonic (p : R[X]) : 0 %ₘ p = 0 := by
classical
unfold modByMonic divModByMonicAux
dsimp
by_cases hp : Monic p
· rw [dif_pos hp, if_neg (mt And.right (not_not_intro rfl)), Prod.snd_zero]
· rw [dif_neg hp]
@[simp]
theorem zero_divByMonic (p : R[X]) : 0 /ₘ p = 0 := by
classical
unfold divByMonic divModByMonicAux
dsimp
by_cases hp : Monic p
· rw [dif_pos hp, if_neg (mt And.right (not_not_intro rfl)), Prod.fst_zero]
· rw [dif_neg hp]
@[simp]
theorem modByMonic_zero (p : R[X]) : p %ₘ 0 = p :=
letI := Classical.decEq R
if h : Monic (0 : R[X]) then by
haveI := monic_zero_iff_subsingleton.mp h
simp [eq_iff_true_of_subsingleton]
else by unfold modByMonic divModByMonicAux; rw [dif_neg h]
@[simp]
theorem divByMonic_zero (p : R[X]) : p /ₘ 0 = 0 :=
letI := Classical.decEq R
if h : Monic (0 : R[X]) then by
haveI := monic_zero_iff_subsingleton.mp h
simp [eq_iff_true_of_subsingleton]
else by unfold divByMonic divModByMonicAux; rw [dif_neg h]
theorem divByMonic_eq_of_not_monic (p : R[X]) (hq : ¬Monic q) : p /ₘ q = 0 :=
dif_neg hq
theorem modByMonic_eq_of_not_monic (p : R[X]) (hq : ¬Monic q) : p %ₘ q = p :=
dif_neg hq
theorem modByMonic_eq_self_iff [Nontrivial R] (hq : Monic q) : p %ₘ q = p ↔ degree p < degree q :=
⟨fun h => h ▸ degree_modByMonic_lt _ hq, fun h => by
classical
have : ¬degree q ≤ degree p := not_le_of_gt h
unfold modByMonic divModByMonicAux; dsimp; rw [dif_pos hq, if_neg (mt And.left this)]⟩
theorem degree_modByMonic_le (p : R[X]) {q : R[X]} (hq : Monic q) : degree (p %ₘ q) ≤ degree q := by
nontriviality R
exact (degree_modByMonic_lt _ hq).le
theorem degree_modByMonic_le_left : degree (p %ₘ q) ≤ degree p := by
nontriviality R
by_cases hq : q.Monic
· cases lt_or_ge (degree p) (degree q)
· rw [(modByMonic_eq_self_iff hq).mpr ‹_›]
· exact (degree_modByMonic_le p hq).trans ‹_›
· rw [modByMonic_eq_of_not_monic p hq]
theorem natDegree_modByMonic_le (p : Polynomial R) {g : Polynomial R} (hg : g.Monic) :
natDegree (p %ₘ g) ≤ g.natDegree :=
natDegree_le_natDegree (degree_modByMonic_le p hg)
theorem natDegree_modByMonic_le_left : natDegree (p %ₘ q) ≤ natDegree p :=
natDegree_le_natDegree degree_modByMonic_le_left
theorem X_dvd_sub_C : X ∣ p - C (p.coeff 0) := by
simp [X_dvd_iff, coeff_C]
theorem modByMonic_eq_sub_mul_div :
∀ (p : R[X]) {q : R[X]} (_hq : Monic q), p %ₘ q = p - q * (p /ₘ q)
| p, q, hq =>
letI := Classical.decEq R
| if h : degree q ≤ degree p ∧ p ≠ 0 then by
have _wf := div_wf_lemma h hq
have ih := modByMonic_eq_sub_mul_div
(p - q * (C (leadingCoeff p) * X ^ (natDegree p - natDegree q))) hq
unfold modByMonic divByMonic divModByMonicAux
dsimp
rw [dif_pos hq, if_pos h]
rw [modByMonic, dif_pos hq] at ih
refine ih.trans ?_
unfold divByMonic
rw [dif_pos hq, dif_pos hq, if_pos h, mul_add, sub_add_eq_sub_sub]
else by
unfold modByMonic divByMonic divModByMonicAux
dsimp
rw [dif_pos hq, if_neg h, dif_pos hq, if_neg h, mul_zero, sub_zero]
termination_by p => p
theorem modByMonic_add_div (p : R[X]) {q : R[X]} (hq : Monic q) : p %ₘ q + q * (p /ₘ q) = p :=
eq_sub_iff_add_eq.1 (modByMonic_eq_sub_mul_div p hq)
| Mathlib/Algebra/Polynomial/Div.lean | 240 | 259 |
/-
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.Data.Fintype.Option
import Mathlib.GroupTheory.Perm.Sign
/-!
# Permutations of `Option α`
-/
open Equiv
@[simp]
theorem Equiv.optionCongr_one {α : Type*} : (1 : Perm α).optionCongr = 1 :=
Equiv.optionCongr_refl
@[simp]
theorem Equiv.optionCongr_swap {α : Type*} [DecidableEq α] (x y : α) :
optionCongr (swap x y) = swap (some x) (some y) := by
ext (_ | i)
· simp [swap_apply_of_ne_of_ne]
· by_cases hx : i = x
· simp only [hx, optionCongr_apply, Option.map_some', swap_apply_left, Option.mem_def,
Option.some.injEq]
by_cases hy : i = y <;> simp [hx, hy, swap_apply_of_ne_of_ne]
@[simp]
theorem Equiv.optionCongr_sign {α : Type*} [DecidableEq α] [Fintype α] (e : Perm α) :
Perm.sign e.optionCongr = Perm.sign e := by
induction e using Perm.swap_induction_on with
| one => simp [Perm.one_def]
| swap_mul f x y hne h =>
simp [h, hne, Perm.mul_def, ← Equiv.optionCongr_trans]
| @[simp]
theorem map_equiv_removeNone {α : Type*} [DecidableEq α] (σ : Perm (Option α)) :
(removeNone σ).optionCongr = swap none (σ none) * σ := by
ext1 x
have : Option.map (⇑(removeNone σ)) x = (swap none (σ none)) (σ x) := by
obtain - | x := x
| Mathlib/GroupTheory/Perm/Option.lean | 38 | 43 |
/-
Copyright (c) 2015, 2017 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Robert Y. Lewis, Johannes Hölzl, Mario Carneiro, Sébastien Gouëzel
-/
import Mathlib.Algebra.Order.BigOperators.Group.Finset
import Mathlib.Order.Interval.Finset.Nat
import Mathlib.Topology.EMetricSpace.Defs
import Mathlib.Topology.UniformSpace.Compact
import Mathlib.Topology.UniformSpace.LocallyUniformConvergence
import Mathlib.Topology.UniformSpace.UniformEmbedding
/-!
# Extended metric spaces
Further results about extended metric spaces.
-/
open Set Filter
universe u v w
variable {α : Type u} {β : Type v} {X : Type*}
open scoped Uniformity Topology NNReal ENNReal Pointwise
variable [PseudoEMetricSpace α]
/-- The triangle (polygon) inequality for sequences of points; `Finset.Ico` version. -/
theorem edist_le_Ico_sum_edist (f : ℕ → α) {m n} (h : m ≤ n) :
edist (f m) (f n) ≤ ∑ i ∈ Finset.Ico m n, edist (f i) (f (i + 1)) := by
induction n, h using Nat.le_induction with
| base => rw [Finset.Ico_self, Finset.sum_empty, edist_self]
| succ n hle ihn =>
calc
edist (f m) (f (n + 1)) ≤ edist (f m) (f n) + edist (f n) (f (n + 1)) := edist_triangle _ _ _
_ ≤ (∑ i ∈ Finset.Ico m n, _) + _ := add_le_add ihn le_rfl
_ = ∑ i ∈ Finset.Ico m (n + 1), _ := by
{ rw [Nat.Ico_succ_right_eq_insert_Ico hle, Finset.sum_insert, add_comm]; simp }
/-- The triangle (polygon) inequality for sequences of points; `Finset.range` version. -/
theorem edist_le_range_sum_edist (f : ℕ → α) (n : ℕ) :
edist (f 0) (f n) ≤ ∑ i ∈ Finset.range n, edist (f i) (f (i + 1)) :=
Nat.Ico_zero_eq_range ▸ edist_le_Ico_sum_edist f (Nat.zero_le n)
/-- A version of `edist_le_Ico_sum_edist` with each intermediate distance replaced
with an upper estimate. -/
theorem edist_le_Ico_sum_of_edist_le {f : ℕ → α} {m n} (hmn : m ≤ n) {d : ℕ → ℝ≥0∞}
(hd : ∀ {k}, m ≤ k → k < n → edist (f k) (f (k + 1)) ≤ d k) :
edist (f m) (f n) ≤ ∑ i ∈ Finset.Ico m n, d i :=
le_trans (edist_le_Ico_sum_edist f hmn) <|
Finset.sum_le_sum fun _k hk => hd (Finset.mem_Ico.1 hk).1 (Finset.mem_Ico.1 hk).2
/-- A version of `edist_le_range_sum_edist` with each intermediate distance replaced
with an upper estimate. -/
theorem edist_le_range_sum_of_edist_le {f : ℕ → α} (n : ℕ) {d : ℕ → ℝ≥0∞}
(hd : ∀ {k}, k < n → edist (f k) (f (k + 1)) ≤ d k) :
edist (f 0) (f n) ≤ ∑ i ∈ Finset.range n, d i :=
Nat.Ico_zero_eq_range ▸ edist_le_Ico_sum_of_edist_le (zero_le n) fun _ => hd
namespace EMetric
theorem isUniformInducing_iff [PseudoEMetricSpace β] {f : α → β} :
IsUniformInducing f ↔ UniformContinuous f ∧
∀ δ > 0, ∃ ε > 0, ∀ {a b : α}, edist (f a) (f b) < ε → edist a b < δ :=
isUniformInducing_iff'.trans <| Iff.rfl.and <|
((uniformity_basis_edist.comap _).le_basis_iff uniformity_basis_edist).trans <| by
simp only [subset_def, Prod.forall]; rfl
/-- ε-δ characterization of uniform embeddings on pseudoemetric spaces -/
nonrec theorem isUniformEmbedding_iff [PseudoEMetricSpace β] {f : α → β} :
IsUniformEmbedding f ↔ Function.Injective f ∧ UniformContinuous f ∧
∀ δ > 0, ∃ ε > 0, ∀ {a b : α}, edist (f a) (f b) < ε → edist a b < δ :=
(isUniformEmbedding_iff _).trans <| and_comm.trans <| Iff.rfl.and isUniformInducing_iff
/-- If a map between pseudoemetric spaces is a uniform embedding then the edistance between `f x`
and `f y` is controlled in terms of the distance between `x` and `y`.
In fact, this lemma holds for a `IsUniformInducing` map.
TODO: generalize? -/
theorem controlled_of_isUniformEmbedding [PseudoEMetricSpace β] {f : α → β}
(h : IsUniformEmbedding f) :
(∀ ε > 0, ∃ δ > 0, ∀ {a b : α}, edist a b < δ → edist (f a) (f b) < ε) ∧
∀ δ > 0, ∃ ε > 0, ∀ {a b : α}, edist (f a) (f b) < ε → edist a b < δ :=
⟨uniformContinuous_iff.1 h.uniformContinuous, (isUniformEmbedding_iff.1 h).2.2⟩
/-- ε-δ characterization of Cauchy sequences on pseudoemetric spaces -/
protected theorem cauchy_iff {f : Filter α} :
Cauchy f ↔ f ≠ ⊥ ∧ ∀ ε > 0, ∃ t ∈ f, ∀ x, x ∈ t → ∀ y, y ∈ t → edist x y < ε := by
rw [← neBot_iff]; exact uniformity_basis_edist.cauchy_iff
/-- A very useful criterion to show that a space is complete is to show that all sequences
which satisfy a bound of the form `edist (u n) (u m) < B N` for all `n m ≥ N` are
converging. This is often applied for `B N = 2^{-N}`, i.e., with a very fast convergence to
`0`, which makes it possible to use arguments of converging series, while this is impossible
to do in general for arbitrary Cauchy sequences. -/
theorem complete_of_convergent_controlled_sequences (B : ℕ → ℝ≥0∞) (hB : ∀ n, 0 < B n)
(H : ∀ u : ℕ → α, (∀ N n m : ℕ, N ≤ n → N ≤ m → edist (u n) (u m) < B N) →
∃ x, Tendsto u atTop (𝓝 x)) :
CompleteSpace α :=
UniformSpace.complete_of_convergent_controlled_sequences
(fun n => { p : α × α | edist p.1 p.2 < B n }) (fun n => edist_mem_uniformity <| hB n) H
/-- A sequentially complete pseudoemetric space is complete. -/
theorem complete_of_cauchySeq_tendsto :
(∀ u : ℕ → α, CauchySeq u → ∃ a, Tendsto u atTop (𝓝 a)) → CompleteSpace α :=
UniformSpace.complete_of_cauchySeq_tendsto
/-- Expressing locally uniform convergence on a set using `edist`. -/
| theorem tendstoLocallyUniformlyOn_iff {ι : Type*} [TopologicalSpace β] {F : ι → β → α} {f : β → α}
{p : Filter ι} {s : Set β} :
| Mathlib/Topology/EMetricSpace/Basic.lean | 110 | 111 |
/-
Copyright (c) 2019 Zhouhang Zhou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Zhouhang Zhou, Sébastien Gouëzel, Frédéric Dupuis
-/
import Mathlib.Algebra.BigOperators.Field
import Mathlib.Analysis.Complex.Basic
import Mathlib.Analysis.InnerProductSpace.Defs
import Mathlib.GroupTheory.MonoidLocalization.Basic
/-!
# Properties of inner product spaces
This file proves many basic properties of inner product spaces (real or complex).
## Main results
- `inner_mul_inner_self_le`: the Cauchy-Schwartz inequality (one of many variants).
- `norm_inner_eq_norm_iff`: the equality criteion in the Cauchy-Schwartz inequality (also in many
variants).
- `inner_eq_sum_norm_sq_div_four`: the polarization identity.
## Tags
inner product space, Hilbert space, norm
-/
noncomputable section
open RCLike Real Filter Topology ComplexConjugate Finsupp
open LinearMap (BilinForm)
variable {𝕜 E F : Type*} [RCLike 𝕜]
section BasicProperties_Seminormed
open scoped InnerProductSpace
variable [SeminormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [SeminormedAddCommGroup F] [InnerProductSpace ℝ F]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
local postfix:90 "†" => starRingEnd _
export InnerProductSpace (norm_sq_eq_re_inner)
@[simp]
theorem inner_conj_symm (x y : E) : ⟪y, x⟫† = ⟪x, y⟫ :=
InnerProductSpace.conj_inner_symm _ _
theorem real_inner_comm (x y : F) : ⟪y, x⟫_ℝ = ⟪x, y⟫_ℝ :=
@inner_conj_symm ℝ _ _ _ _ x y
theorem inner_eq_zero_symm {x y : E} : ⟪x, y⟫ = 0 ↔ ⟪y, x⟫ = 0 := by
rw [← inner_conj_symm]
exact star_eq_zero
@[simp]
theorem inner_self_im (x : E) : im ⟪x, x⟫ = 0 := by rw [← @ofReal_inj 𝕜, im_eq_conj_sub]; simp
theorem inner_add_left (x y z : E) : ⟪x + y, z⟫ = ⟪x, z⟫ + ⟪y, z⟫ :=
InnerProductSpace.add_left _ _ _
theorem inner_add_right (x y z : E) : ⟪x, y + z⟫ = ⟪x, y⟫ + ⟪x, z⟫ := by
rw [← inner_conj_symm, inner_add_left, RingHom.map_add]
simp only [inner_conj_symm]
theorem inner_re_symm (x y : E) : re ⟪x, y⟫ = re ⟪y, x⟫ := by rw [← inner_conj_symm, conj_re]
theorem inner_im_symm (x y : E) : im ⟪x, y⟫ = -im ⟪y, x⟫ := by rw [← inner_conj_symm, conj_im]
section Algebra
variable {𝕝 : Type*} [CommSemiring 𝕝] [StarRing 𝕝] [Algebra 𝕝 𝕜] [Module 𝕝 E]
[IsScalarTower 𝕝 𝕜 E] [StarModule 𝕝 𝕜]
/-- See `inner_smul_left` for the common special when `𝕜 = 𝕝`. -/
lemma inner_smul_left_eq_star_smul (x y : E) (r : 𝕝) : ⟪r • x, y⟫ = r† • ⟪x, y⟫ := by
rw [← algebraMap_smul 𝕜 r, InnerProductSpace.smul_left, starRingEnd_apply, starRingEnd_apply,
← algebraMap_star_comm, ← smul_eq_mul, algebraMap_smul]
/-- Special case of `inner_smul_left_eq_star_smul` when the acting ring has a trivial star
(eg `ℕ`, `ℤ`, `ℚ≥0`, `ℚ`, `ℝ`). -/
lemma inner_smul_left_eq_smul [TrivialStar 𝕝] (x y : E) (r : 𝕝) : ⟪r • x, y⟫ = r • ⟪x, y⟫ := by
rw [inner_smul_left_eq_star_smul, starRingEnd_apply, star_trivial]
/-- See `inner_smul_right` for the common special when `𝕜 = 𝕝`. -/
lemma inner_smul_right_eq_smul (x y : E) (r : 𝕝) : ⟪x, r • y⟫ = r • ⟪x, y⟫ := by
rw [← inner_conj_symm, inner_smul_left_eq_star_smul, starRingEnd_apply, starRingEnd_apply,
star_smul, star_star, ← starRingEnd_apply, inner_conj_symm]
end Algebra
/-- See `inner_smul_left_eq_star_smul` for the case of a general algebra action. -/
theorem inner_smul_left (x y : E) (r : 𝕜) : ⟪r • x, y⟫ = r† * ⟪x, y⟫ :=
inner_smul_left_eq_star_smul ..
theorem real_inner_smul_left (x y : F) (r : ℝ) : ⟪r • x, y⟫_ℝ = r * ⟪x, y⟫_ℝ :=
inner_smul_left _ _ _
theorem inner_smul_real_left (x y : E) (r : ℝ) : ⟪(r : 𝕜) • x, y⟫ = r • ⟪x, y⟫ := by
rw [inner_smul_left, conj_ofReal, Algebra.smul_def]
/-- See `inner_smul_right_eq_smul` for the case of a general algebra action. -/
theorem inner_smul_right (x y : E) (r : 𝕜) : ⟪x, r • y⟫ = r * ⟪x, y⟫ :=
inner_smul_right_eq_smul ..
theorem real_inner_smul_right (x y : F) (r : ℝ) : ⟪x, r • y⟫_ℝ = r * ⟪x, y⟫_ℝ :=
inner_smul_right _ _ _
theorem inner_smul_real_right (x y : E) (r : ℝ) : ⟪x, (r : 𝕜) • y⟫ = r • ⟪x, y⟫ := by
rw [inner_smul_right, Algebra.smul_def]
/-- The inner product as a sesquilinear form.
Note that in the case `𝕜 = ℝ` this is a bilinear form. -/
@[simps!]
def sesqFormOfInner : E →ₗ[𝕜] E →ₗ⋆[𝕜] 𝕜 :=
LinearMap.mk₂'ₛₗ (RingHom.id 𝕜) (starRingEnd _) (fun x y => ⟪y, x⟫)
(fun _x _y _z => inner_add_right _ _ _) (fun _r _x _y => inner_smul_right _ _ _)
(fun _x _y _z => inner_add_left _ _ _) fun _r _x _y => inner_smul_left _ _ _
/-- The real inner product as a bilinear form.
Note that unlike `sesqFormOfInner`, this does not reverse the order of the arguments. -/
@[simps!]
def bilinFormOfRealInner : BilinForm ℝ F := sesqFormOfInner.flip
/-- An inner product with a sum on the left. -/
theorem sum_inner {ι : Type*} (s : Finset ι) (f : ι → E) (x : E) :
⟪∑ i ∈ s, f i, x⟫ = ∑ i ∈ s, ⟪f i, x⟫ :=
map_sum (sesqFormOfInner (𝕜 := 𝕜) (E := E) x) _ _
/-- An inner product with a sum on the right. -/
theorem inner_sum {ι : Type*} (s : Finset ι) (f : ι → E) (x : E) :
⟪x, ∑ i ∈ s, f i⟫ = ∑ i ∈ s, ⟪x, f i⟫ :=
map_sum (LinearMap.flip sesqFormOfInner x) _ _
/-- An inner product with a sum on the left, `Finsupp` version. -/
protected theorem Finsupp.sum_inner {ι : Type*} (l : ι →₀ 𝕜) (v : ι → E) (x : E) :
⟪l.sum fun (i : ι) (a : 𝕜) => a • v i, x⟫ = l.sum fun (i : ι) (a : 𝕜) => conj a • ⟪v i, x⟫ := by
convert sum_inner (𝕜 := 𝕜) l.support (fun a => l a • v a) x
simp only [inner_smul_left, Finsupp.sum, smul_eq_mul]
/-- An inner product with a sum on the right, `Finsupp` version. -/
protected theorem Finsupp.inner_sum {ι : Type*} (l : ι →₀ 𝕜) (v : ι → E) (x : E) :
⟪x, l.sum fun (i : ι) (a : 𝕜) => a • v i⟫ = l.sum fun (i : ι) (a : 𝕜) => a • ⟪x, v i⟫ := by
convert inner_sum (𝕜 := 𝕜) l.support (fun a => l a • v a) x
simp only [inner_smul_right, Finsupp.sum, smul_eq_mul]
protected theorem DFinsupp.sum_inner {ι : Type*} [DecidableEq ι] {α : ι → Type*}
[∀ i, AddZeroClass (α i)] [∀ (i) (x : α i), Decidable (x ≠ 0)] (f : ∀ i, α i → E)
(l : Π₀ i, α i) (x : E) : ⟪l.sum f, x⟫ = l.sum fun i a => ⟪f i a, x⟫ := by
simp +contextual only [DFinsupp.sum, sum_inner, smul_eq_mul]
protected theorem DFinsupp.inner_sum {ι : Type*} [DecidableEq ι] {α : ι → Type*}
[∀ i, AddZeroClass (α i)] [∀ (i) (x : α i), Decidable (x ≠ 0)] (f : ∀ i, α i → E)
(l : Π₀ i, α i) (x : E) : ⟪x, l.sum f⟫ = l.sum fun i a => ⟪x, f i a⟫ := by
simp +contextual only [DFinsupp.sum, inner_sum, smul_eq_mul]
@[simp]
theorem inner_zero_left (x : E) : ⟪0, x⟫ = 0 := by
rw [← zero_smul 𝕜 (0 : E), inner_smul_left, RingHom.map_zero, zero_mul]
theorem inner_re_zero_left (x : E) : re ⟪0, x⟫ = 0 := by
simp only [inner_zero_left, AddMonoidHom.map_zero]
@[simp]
theorem inner_zero_right (x : E) : ⟪x, 0⟫ = 0 := by
rw [← inner_conj_symm, inner_zero_left, RingHom.map_zero]
theorem inner_re_zero_right (x : E) : re ⟪x, 0⟫ = 0 := by
simp only [inner_zero_right, AddMonoidHom.map_zero]
theorem inner_self_nonneg {x : E} : 0 ≤ re ⟪x, x⟫ :=
PreInnerProductSpace.toCore.re_inner_nonneg x
theorem real_inner_self_nonneg {x : F} : 0 ≤ ⟪x, x⟫_ℝ :=
@inner_self_nonneg ℝ F _ _ _ x
@[simp]
theorem inner_self_ofReal_re (x : E) : (re ⟪x, x⟫ : 𝕜) = ⟪x, x⟫ :=
((RCLike.is_real_TFAE (⟪x, x⟫ : 𝕜)).out 2 3).2 (inner_self_im (𝕜 := 𝕜) x)
theorem inner_self_eq_norm_sq_to_K (x : E) : ⟪x, x⟫ = (‖x‖ : 𝕜) ^ 2 := by
rw [← inner_self_ofReal_re, ← norm_sq_eq_re_inner, ofReal_pow]
theorem inner_self_re_eq_norm (x : E) : re ⟪x, x⟫ = ‖⟪x, x⟫‖ := by
conv_rhs => rw [← inner_self_ofReal_re]
symm
exact norm_of_nonneg inner_self_nonneg
theorem inner_self_ofReal_norm (x : E) : (‖⟪x, x⟫‖ : 𝕜) = ⟪x, x⟫ := by
rw [← inner_self_re_eq_norm]
exact inner_self_ofReal_re _
theorem real_inner_self_abs (x : F) : |⟪x, x⟫_ℝ| = ⟪x, x⟫_ℝ :=
@inner_self_ofReal_norm ℝ F _ _ _ x
theorem norm_inner_symm (x y : E) : ‖⟪x, y⟫‖ = ‖⟪y, x⟫‖ := by rw [← inner_conj_symm, norm_conj]
@[simp]
theorem inner_neg_left (x y : E) : ⟪-x, y⟫ = -⟪x, y⟫ := by
rw [← neg_one_smul 𝕜 x, inner_smul_left]
simp
@[simp]
theorem inner_neg_right (x y : E) : ⟪x, -y⟫ = -⟪x, y⟫ := by
rw [← inner_conj_symm, inner_neg_left]; simp only [RingHom.map_neg, inner_conj_symm]
theorem inner_neg_neg (x y : E) : ⟪-x, -y⟫ = ⟪x, y⟫ := by simp
theorem inner_self_conj (x : E) : ⟪x, x⟫† = ⟪x, x⟫ := inner_conj_symm _ _
theorem inner_sub_left (x y z : E) : ⟪x - y, z⟫ = ⟪x, z⟫ - ⟪y, z⟫ := by
simp [sub_eq_add_neg, inner_add_left]
theorem inner_sub_right (x y z : E) : ⟪x, y - z⟫ = ⟪x, y⟫ - ⟪x, z⟫ := by
simp [sub_eq_add_neg, inner_add_right]
theorem inner_mul_symm_re_eq_norm (x y : E) : re (⟪x, y⟫ * ⟪y, x⟫) = ‖⟪x, y⟫ * ⟪y, x⟫‖ := by
rw [← inner_conj_symm, mul_comm]
exact re_eq_norm_of_mul_conj (inner y x)
/-- Expand `⟪x + y, x + y⟫` -/
theorem inner_add_add_self (x y : E) : ⟪x + y, x + y⟫ = ⟪x, x⟫ + ⟪x, y⟫ + ⟪y, x⟫ + ⟪y, y⟫ := by
simp only [inner_add_left, inner_add_right]; ring
/-- Expand `⟪x + y, x + y⟫_ℝ` -/
theorem real_inner_add_add_self (x y : F) :
⟪x + y, x + y⟫_ℝ = ⟪x, x⟫_ℝ + 2 * ⟪x, y⟫_ℝ + ⟪y, y⟫_ℝ := by
have : ⟪y, x⟫_ℝ = ⟪x, y⟫_ℝ := by rw [← inner_conj_symm]; rfl
simp only [inner_add_add_self, this, add_left_inj]
ring
-- Expand `⟪x - y, x - y⟫`
theorem inner_sub_sub_self (x y : E) : ⟪x - y, x - y⟫ = ⟪x, x⟫ - ⟪x, y⟫ - ⟪y, x⟫ + ⟪y, y⟫ := by
simp only [inner_sub_left, inner_sub_right]; ring
/-- Expand `⟪x - y, x - y⟫_ℝ` -/
theorem real_inner_sub_sub_self (x y : F) :
⟪x - y, x - y⟫_ℝ = ⟪x, x⟫_ℝ - 2 * ⟪x, y⟫_ℝ + ⟪y, y⟫_ℝ := by
have : ⟪y, x⟫_ℝ = ⟪x, y⟫_ℝ := by rw [← inner_conj_symm]; rfl
simp only [inner_sub_sub_self, this, add_left_inj]
ring
/-- Parallelogram law -/
theorem parallelogram_law {x y : E} : ⟪x + y, x + y⟫ + ⟪x - y, x - y⟫ = 2 * (⟪x, x⟫ + ⟪y, y⟫) := by
simp only [inner_add_add_self, inner_sub_sub_self]
ring
/-- **Cauchy–Schwarz inequality**. -/
theorem inner_mul_inner_self_le (x y : E) : ‖⟪x, y⟫‖ * ‖⟪y, x⟫‖ ≤ re ⟪x, x⟫ * re ⟪y, y⟫ :=
letI cd : PreInnerProductSpace.Core 𝕜 E := PreInnerProductSpace.toCore
InnerProductSpace.Core.inner_mul_inner_self_le x y
/-- Cauchy–Schwarz inequality for real inner products. -/
theorem real_inner_mul_inner_self_le (x y : F) : ⟪x, y⟫_ℝ * ⟪x, y⟫_ℝ ≤ ⟪x, x⟫_ℝ * ⟪y, y⟫_ℝ :=
calc
⟪x, y⟫_ℝ * ⟪x, y⟫_ℝ ≤ ‖⟪x, y⟫_ℝ‖ * ‖⟪y, x⟫_ℝ‖ := by
rw [real_inner_comm y, ← norm_mul]
exact le_abs_self _
_ ≤ ⟪x, x⟫_ℝ * ⟪y, y⟫_ℝ := @inner_mul_inner_self_le ℝ _ _ _ _ x y
end BasicProperties_Seminormed
section BasicProperties
variable [NormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [NormedAddCommGroup F] [InnerProductSpace ℝ F]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
export InnerProductSpace (norm_sq_eq_re_inner)
@[simp]
theorem inner_self_eq_zero {x : E} : ⟪x, x⟫ = 0 ↔ x = 0 := by
rw [inner_self_eq_norm_sq_to_K, sq_eq_zero_iff, ofReal_eq_zero, norm_eq_zero]
theorem inner_self_ne_zero {x : E} : ⟪x, x⟫ ≠ 0 ↔ x ≠ 0 :=
inner_self_eq_zero.not
variable (𝕜)
theorem ext_inner_left {x y : E} (h : ∀ v, ⟪v, x⟫ = ⟪v, y⟫) : x = y := by
rw [← sub_eq_zero, ← @inner_self_eq_zero 𝕜, inner_sub_right, sub_eq_zero, h (x - y)]
theorem ext_inner_right {x y : E} (h : ∀ v, ⟪x, v⟫ = ⟪y, v⟫) : x = y := by
rw [← sub_eq_zero, ← @inner_self_eq_zero 𝕜, inner_sub_left, sub_eq_zero, h (x - y)]
variable {𝕜}
@[simp]
theorem re_inner_self_nonpos {x : E} : re ⟪x, x⟫ ≤ 0 ↔ x = 0 := by
rw [← norm_sq_eq_re_inner, (sq_nonneg _).le_iff_eq, sq_eq_zero_iff, norm_eq_zero]
@[simp]
lemma re_inner_self_pos {x : E} : 0 < re ⟪x, x⟫ ↔ x ≠ 0 := by
simpa [-re_inner_self_nonpos] using re_inner_self_nonpos (𝕜 := 𝕜) (x := x).not
@[deprecated (since := "2025-04-22")] alias inner_self_nonpos := re_inner_self_nonpos
@[deprecated (since := "2025-04-22")] alias inner_self_pos := re_inner_self_pos
open scoped InnerProductSpace in
theorem real_inner_self_nonpos {x : F} : ⟪x, x⟫_ℝ ≤ 0 ↔ x = 0 := re_inner_self_nonpos (𝕜 := ℝ)
open scoped InnerProductSpace in
theorem real_inner_self_pos {x : F} : 0 < ⟪x, x⟫_ℝ ↔ x ≠ 0 := re_inner_self_pos (𝕜 := ℝ)
/-- A family of vectors is linearly independent if they are nonzero
and orthogonal. -/
theorem linearIndependent_of_ne_zero_of_inner_eq_zero {ι : Type*} {v : ι → E} (hz : ∀ i, v i ≠ 0)
(ho : Pairwise fun i j => ⟪v i, v j⟫ = 0) : LinearIndependent 𝕜 v := by
rw [linearIndependent_iff']
intro s g hg i hi
have h' : g i * inner (v i) (v i) = inner (v i) (∑ j ∈ s, g j • v j) := by
rw [inner_sum]
symm
convert Finset.sum_eq_single (M := 𝕜) i ?_ ?_
· rw [inner_smul_right]
· intro j _hj hji
rw [inner_smul_right, ho hji.symm, mul_zero]
· exact fun h => False.elim (h hi)
simpa [hg, hz] using h'
end BasicProperties
section Norm_Seminormed
open scoped InnerProductSpace
variable [SeminormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [SeminormedAddCommGroup F] [InnerProductSpace ℝ F]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
local notation "IK" => @RCLike.I 𝕜 _
theorem norm_eq_sqrt_re_inner (x : E) : ‖x‖ = √(re ⟪x, x⟫) :=
calc
‖x‖ = √(‖x‖ ^ 2) := (sqrt_sq (norm_nonneg _)).symm
_ = √(re ⟪x, x⟫) := congr_arg _ (norm_sq_eq_re_inner _)
@[deprecated (since := "2025-04-22")] alias norm_eq_sqrt_inner := norm_eq_sqrt_re_inner
theorem norm_eq_sqrt_real_inner (x : F) : ‖x‖ = √⟪x, x⟫_ℝ :=
@norm_eq_sqrt_re_inner ℝ _ _ _ _ x
theorem inner_self_eq_norm_mul_norm (x : E) : re ⟪x, x⟫ = ‖x‖ * ‖x‖ := by
rw [@norm_eq_sqrt_re_inner 𝕜, ← sqrt_mul inner_self_nonneg (re ⟪x, x⟫),
sqrt_mul_self inner_self_nonneg]
theorem inner_self_eq_norm_sq (x : E) : re ⟪x, x⟫ = ‖x‖ ^ 2 := by
rw [pow_two, inner_self_eq_norm_mul_norm]
theorem real_inner_self_eq_norm_mul_norm (x : F) : ⟪x, x⟫_ℝ = ‖x‖ * ‖x‖ := by
have h := @inner_self_eq_norm_mul_norm ℝ F _ _ _ x
simpa using h
theorem real_inner_self_eq_norm_sq (x : F) : ⟪x, x⟫_ℝ = ‖x‖ ^ 2 := by
rw [pow_two, real_inner_self_eq_norm_mul_norm]
/-- Expand the square -/
theorem norm_add_sq (x y : E) : ‖x + y‖ ^ 2 = ‖x‖ ^ 2 + 2 * re ⟪x, y⟫ + ‖y‖ ^ 2 := by
repeat' rw [sq (M := ℝ), ← @inner_self_eq_norm_mul_norm 𝕜]
rw [inner_add_add_self, two_mul]
simp only [add_assoc, add_left_inj, add_right_inj, AddMonoidHom.map_add]
rw [← inner_conj_symm, conj_re]
alias norm_add_pow_two := norm_add_sq
/-- Expand the square -/
theorem norm_add_sq_real (x y : F) : ‖x + y‖ ^ 2 = ‖x‖ ^ 2 + 2 * ⟪x, y⟫_ℝ + ‖y‖ ^ 2 := by
have h := @norm_add_sq ℝ _ _ _ _ x y
simpa using h
alias norm_add_pow_two_real := norm_add_sq_real
/-- Expand the square -/
theorem norm_add_mul_self (x y : E) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + 2 * re ⟪x, y⟫ + ‖y‖ * ‖y‖ := by
repeat' rw [← sq (M := ℝ)]
exact norm_add_sq _ _
/-- Expand the square -/
theorem norm_add_mul_self_real (x y : F) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + 2 * ⟪x, y⟫_ℝ + ‖y‖ * ‖y‖ := by
have h := @norm_add_mul_self ℝ _ _ _ _ x y
simpa using h
/-- Expand the square -/
theorem norm_sub_sq (x y : E) : ‖x - y‖ ^ 2 = ‖x‖ ^ 2 - 2 * re ⟪x, y⟫ + ‖y‖ ^ 2 := by
rw [sub_eq_add_neg, @norm_add_sq 𝕜 _ _ _ _ x (-y), norm_neg, inner_neg_right, map_neg, mul_neg,
sub_eq_add_neg]
alias norm_sub_pow_two := norm_sub_sq
/-- Expand the square -/
theorem norm_sub_sq_real (x y : F) : ‖x - y‖ ^ 2 = ‖x‖ ^ 2 - 2 * ⟪x, y⟫_ℝ + ‖y‖ ^ 2 :=
@norm_sub_sq ℝ _ _ _ _ _ _
alias norm_sub_pow_two_real := norm_sub_sq_real
/-- Expand the square -/
theorem norm_sub_mul_self (x y : E) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ - 2 * re ⟪x, y⟫ + ‖y‖ * ‖y‖ := by
repeat' rw [← sq (M := ℝ)]
exact norm_sub_sq _ _
/-- Expand the square -/
theorem norm_sub_mul_self_real (x y : F) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ - 2 * ⟪x, y⟫_ℝ + ‖y‖ * ‖y‖ := by
have h := @norm_sub_mul_self ℝ _ _ _ _ x y
simpa using h
/-- Cauchy–Schwarz inequality with norm -/
theorem norm_inner_le_norm (x y : E) : ‖⟪x, y⟫‖ ≤ ‖x‖ * ‖y‖ := by
rw [norm_eq_sqrt_re_inner (𝕜 := 𝕜) x, norm_eq_sqrt_re_inner (𝕜 := 𝕜) y]
letI : PreInnerProductSpace.Core 𝕜 E := PreInnerProductSpace.toCore
exact InnerProductSpace.Core.norm_inner_le_norm x y
theorem nnnorm_inner_le_nnnorm (x y : E) : ‖⟪x, y⟫‖₊ ≤ ‖x‖₊ * ‖y‖₊ :=
norm_inner_le_norm x y
theorem re_inner_le_norm (x y : E) : re ⟪x, y⟫ ≤ ‖x‖ * ‖y‖ :=
le_trans (re_le_norm (inner x y)) (norm_inner_le_norm x y)
/-- Cauchy–Schwarz inequality with norm -/
theorem abs_real_inner_le_norm (x y : F) : |⟪x, y⟫_ℝ| ≤ ‖x‖ * ‖y‖ :=
(Real.norm_eq_abs _).ge.trans (norm_inner_le_norm x y)
/-- Cauchy–Schwarz inequality with norm -/
theorem real_inner_le_norm (x y : F) : ⟪x, y⟫_ℝ ≤ ‖x‖ * ‖y‖ :=
le_trans (le_abs_self _) (abs_real_inner_le_norm _ _)
lemma inner_eq_zero_of_left {x : E} (y : E) (h : ‖x‖ = 0) : ⟪x, y⟫_𝕜 = 0 := by
rw [← norm_eq_zero]
refine le_antisymm ?_ (by positivity)
exact norm_inner_le_norm _ _ |>.trans <| by simp [h]
lemma inner_eq_zero_of_right (x : E) {y : E} (h : ‖y‖ = 0) : ⟪x, y⟫_𝕜 = 0 := by
rw [inner_eq_zero_symm, inner_eq_zero_of_left _ h]
variable (𝕜)
include 𝕜 in
theorem parallelogram_law_with_norm (x y : E) :
‖x + y‖ * ‖x + y‖ + ‖x - y‖ * ‖x - y‖ = 2 * (‖x‖ * ‖x‖ + ‖y‖ * ‖y‖) := by
simp only [← @inner_self_eq_norm_mul_norm 𝕜]
rw [← re.map_add, parallelogram_law, two_mul, two_mul]
simp only [re.map_add]
include 𝕜 in
theorem parallelogram_law_with_nnnorm (x y : E) :
‖x + y‖₊ * ‖x + y‖₊ + ‖x - y‖₊ * ‖x - y‖₊ = 2 * (‖x‖₊ * ‖x‖₊ + ‖y‖₊ * ‖y‖₊) :=
Subtype.ext <| parallelogram_law_with_norm 𝕜 x y
variable {𝕜}
/-- Polarization identity: The real part of the inner product, in terms of the norm. -/
theorem re_inner_eq_norm_add_mul_self_sub_norm_mul_self_sub_norm_mul_self_div_two (x y : E) :
re ⟪x, y⟫ = (‖x + y‖ * ‖x + y‖ - ‖x‖ * ‖x‖ - ‖y‖ * ‖y‖) / 2 := by
rw [@norm_add_mul_self 𝕜]
ring
/-- Polarization identity: The real part of the inner product, in terms of the norm. -/
theorem re_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two (x y : E) :
re ⟪x, y⟫ = (‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ - ‖x - y‖ * ‖x - y‖) / 2 := by
rw [@norm_sub_mul_self 𝕜]
ring
/-- Polarization identity: The real part of the inner product, in terms of the norm. -/
theorem re_inner_eq_norm_add_mul_self_sub_norm_sub_mul_self_div_four (x y : E) :
re ⟪x, y⟫ = (‖x + y‖ * ‖x + y‖ - ‖x - y‖ * ‖x - y‖) / 4 := by
rw [@norm_add_mul_self 𝕜, @norm_sub_mul_self 𝕜]
ring
/-- Polarization identity: The imaginary part of the inner product, in terms of the norm. -/
theorem im_inner_eq_norm_sub_i_smul_mul_self_sub_norm_add_i_smul_mul_self_div_four (x y : E) :
im ⟪x, y⟫ = (‖x - IK • y‖ * ‖x - IK • y‖ - ‖x + IK • y‖ * ‖x + IK • y‖) / 4 := by
simp only [@norm_add_mul_self 𝕜, @norm_sub_mul_self 𝕜, inner_smul_right, I_mul_re]
ring
/-- Polarization identity: The inner product, in terms of the norm. -/
theorem inner_eq_sum_norm_sq_div_four (x y : E) :
⟪x, y⟫ = ((‖x + y‖ : 𝕜) ^ 2 - (‖x - y‖ : 𝕜) ^ 2 +
((‖x - IK • y‖ : 𝕜) ^ 2 - (‖x + IK • y‖ : 𝕜) ^ 2) * IK) / 4 := by
rw [← re_add_im ⟪x, y⟫, re_inner_eq_norm_add_mul_self_sub_norm_sub_mul_self_div_four,
im_inner_eq_norm_sub_i_smul_mul_self_sub_norm_add_i_smul_mul_self_div_four]
push_cast
simp only [sq, ← mul_div_right_comm, ← add_div]
/-- Polarization identity: The real inner product, in terms of the norm. -/
theorem real_inner_eq_norm_add_mul_self_sub_norm_mul_self_sub_norm_mul_self_div_two (x y : F) :
⟪x, y⟫_ℝ = (‖x + y‖ * ‖x + y‖ - ‖x‖ * ‖x‖ - ‖y‖ * ‖y‖) / 2 :=
re_to_real.symm.trans <|
re_inner_eq_norm_add_mul_self_sub_norm_mul_self_sub_norm_mul_self_div_two x y
/-- Polarization identity: The real inner product, in terms of the norm. -/
theorem real_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two (x y : F) :
⟪x, y⟫_ℝ = (‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ - ‖x - y‖ * ‖x - y‖) / 2 :=
re_to_real.symm.trans <|
re_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two x y
/-- Pythagorean theorem, if-and-only-if vector inner product form. -/
theorem norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero (x y : F) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ ↔ ⟪x, y⟫_ℝ = 0 := by
rw [@norm_add_mul_self ℝ, add_right_cancel_iff, add_eq_left, mul_eq_zero]
norm_num
/-- Pythagorean theorem, if-and-if vector inner product form using square roots. -/
theorem norm_add_eq_sqrt_iff_real_inner_eq_zero {x y : F} :
‖x + y‖ = √(‖x‖ * ‖x‖ + ‖y‖ * ‖y‖) ↔ ⟪x, y⟫_ℝ = 0 := by
rw [← norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero, eq_comm, sqrt_eq_iff_mul_self_eq,
eq_comm] <;> positivity
/-- Pythagorean theorem, vector inner product form. -/
theorem norm_add_sq_eq_norm_sq_add_norm_sq_of_inner_eq_zero (x y : E) (h : ⟪x, y⟫ = 0) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ := by
rw [@norm_add_mul_self 𝕜, add_right_cancel_iff, add_eq_left, mul_eq_zero]
apply Or.inr
simp only [h, zero_re']
/-- Pythagorean theorem, vector inner product form. -/
theorem norm_add_sq_eq_norm_sq_add_norm_sq_real {x y : F} (h : ⟪x, y⟫_ℝ = 0) :
‖x + y‖ * ‖x + y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ :=
(norm_add_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero x y).2 h
/-- Pythagorean theorem, subtracting vectors, if-and-only-if vector
inner product form. -/
theorem norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero (x y : F) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ ↔ ⟪x, y⟫_ℝ = 0 := by
rw [@norm_sub_mul_self ℝ, add_right_cancel_iff, sub_eq_add_neg, add_eq_left, neg_eq_zero,
mul_eq_zero]
norm_num
/-- Pythagorean theorem, subtracting vectors, if-and-if vector inner product form using square
roots. -/
theorem norm_sub_eq_sqrt_iff_real_inner_eq_zero {x y : F} :
‖x - y‖ = √(‖x‖ * ‖x‖ + ‖y‖ * ‖y‖) ↔ ⟪x, y⟫_ℝ = 0 := by
rw [← norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero, eq_comm, sqrt_eq_iff_mul_self_eq,
eq_comm] <;> positivity
/-- Pythagorean theorem, subtracting vectors, vector inner product
form. -/
theorem norm_sub_sq_eq_norm_sq_add_norm_sq_real {x y : F} (h : ⟪x, y⟫_ℝ = 0) :
‖x - y‖ * ‖x - y‖ = ‖x‖ * ‖x‖ + ‖y‖ * ‖y‖ :=
(norm_sub_sq_eq_norm_sq_add_norm_sq_iff_real_inner_eq_zero x y).2 h
/-- The sum and difference of two vectors are orthogonal if and only
if they have the same norm. -/
theorem real_inner_add_sub_eq_zero_iff (x y : F) : ⟪x + y, x - y⟫_ℝ = 0 ↔ ‖x‖ = ‖y‖ := by
conv_rhs => rw [← mul_self_inj_of_nonneg (norm_nonneg _) (norm_nonneg _)]
simp only [← @inner_self_eq_norm_mul_norm ℝ, inner_add_left, inner_sub_right, real_inner_comm y x,
sub_eq_zero, re_to_real]
constructor
· intro h
rw [add_comm] at h
linarith
· intro h
linarith
/-- Given two orthogonal vectors, their sum and difference have equal norms. -/
theorem norm_sub_eq_norm_add {v w : E} (h : ⟪v, w⟫ = 0) : ‖w - v‖ = ‖w + v‖ := by
rw [← mul_self_inj_of_nonneg (norm_nonneg _) (norm_nonneg _)]
simp only [h, ← @inner_self_eq_norm_mul_norm 𝕜, sub_neg_eq_add, sub_zero, map_sub, zero_re',
zero_sub, add_zero, map_add, inner_add_right, inner_sub_left, inner_sub_right, inner_re_symm,
zero_add]
/-- The real inner product of two vectors, divided by the product of their
norms, has absolute value at most 1. -/
theorem abs_real_inner_div_norm_mul_norm_le_one (x y : F) : |⟪x, y⟫_ℝ / (‖x‖ * ‖y‖)| ≤ 1 := by
rw [abs_div, abs_mul, abs_norm, abs_norm]
exact div_le_one_of_le₀ (abs_real_inner_le_norm x y) (by positivity)
/-- The inner product of a vector with a multiple of itself. -/
theorem real_inner_smul_self_left (x : F) (r : ℝ) : ⟪r • x, x⟫_ℝ = r * (‖x‖ * ‖x‖) := by
rw [real_inner_smul_left, ← real_inner_self_eq_norm_mul_norm]
/-- The inner product of a vector with a multiple of itself. -/
theorem real_inner_smul_self_right (x : F) (r : ℝ) : ⟪x, r • x⟫_ℝ = r * (‖x‖ * ‖x‖) := by
rw [inner_smul_right, ← real_inner_self_eq_norm_mul_norm]
/-- The inner product of two weighted sums, where the weights in each
sum add to 0, in terms of the norms of pairwise differences. -/
theorem inner_sum_smul_sum_smul_of_sum_eq_zero {ι₁ : Type*} {s₁ : Finset ι₁} {w₁ : ι₁ → ℝ}
(v₁ : ι₁ → F) (h₁ : ∑ i ∈ s₁, w₁ i = 0) {ι₂ : Type*} {s₂ : Finset ι₂} {w₂ : ι₂ → ℝ}
(v₂ : ι₂ → F) (h₂ : ∑ i ∈ s₂, w₂ i = 0) :
⟪∑ i₁ ∈ s₁, w₁ i₁ • v₁ i₁, ∑ i₂ ∈ s₂, w₂ i₂ • v₂ i₂⟫_ℝ =
(-∑ i₁ ∈ s₁, ∑ i₂ ∈ s₂, w₁ i₁ * w₂ i₂ * (‖v₁ i₁ - v₂ i₂‖ * ‖v₁ i₁ - v₂ i₂‖)) / 2 := by
simp_rw [sum_inner, inner_sum, real_inner_smul_left, real_inner_smul_right,
real_inner_eq_norm_mul_self_add_norm_mul_self_sub_norm_sub_mul_self_div_two, ← div_sub_div_same,
← div_add_div_same, mul_sub_left_distrib, left_distrib, Finset.sum_sub_distrib,
Finset.sum_add_distrib, ← Finset.mul_sum, ← Finset.sum_mul, h₁, h₂, zero_mul,
mul_zero, Finset.sum_const_zero, zero_add, zero_sub, Finset.mul_sum, neg_div,
Finset.sum_div, mul_div_assoc, mul_assoc]
end Norm_Seminormed
section Norm
open scoped InnerProductSpace
variable [NormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable [NormedAddCommGroup F] [InnerProductSpace ℝ F]
variable {ι : Type*}
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-- Formula for the distance between the images of two nonzero points under an inversion with center
zero. See also `EuclideanGeometry.dist_inversion_inversion` for inversions around a general
point. -/
theorem dist_div_norm_sq_smul {x y : F} (hx : x ≠ 0) (hy : y ≠ 0) (R : ℝ) :
dist ((R / ‖x‖) ^ 2 • x) ((R / ‖y‖) ^ 2 • y) = R ^ 2 / (‖x‖ * ‖y‖) * dist x y :=
calc
dist ((R / ‖x‖) ^ 2 • x) ((R / ‖y‖) ^ 2 • y) =
√(‖(R / ‖x‖) ^ 2 • x - (R / ‖y‖) ^ 2 • y‖ ^ 2) := by
rw [dist_eq_norm, sqrt_sq (norm_nonneg _)]
_ = √((R ^ 2 / (‖x‖ * ‖y‖)) ^ 2 * ‖x - y‖ ^ 2) :=
congr_arg sqrt <| by
field_simp [sq, norm_sub_mul_self_real, norm_smul, real_inner_smul_left, inner_smul_right,
Real.norm_of_nonneg (mul_self_nonneg _)]
ring
_ = R ^ 2 / (‖x‖ * ‖y‖) * dist x y := by
rw [sqrt_mul, sqrt_sq, sqrt_sq, dist_eq_norm] <;> positivity
/-- The inner product of a nonzero vector with a nonzero multiple of
itself, divided by the product of their norms, has absolute value
1. -/
theorem norm_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul {x : E} {r : 𝕜} (hx : x ≠ 0)
(hr : r ≠ 0) : ‖⟪x, r • x⟫‖ / (‖x‖ * ‖r • x‖) = 1 := by
have hx' : ‖x‖ ≠ 0 := by simp [hx]
have hr' : ‖r‖ ≠ 0 := by simp [hr]
rw [inner_smul_right, norm_mul, ← inner_self_re_eq_norm, inner_self_eq_norm_mul_norm, norm_smul]
rw [← mul_assoc, ← div_div, mul_div_cancel_right₀ _ hx', ← div_div, mul_comm,
mul_div_cancel_right₀ _ hr', div_self hx']
/-- The inner product of a nonzero vector with a nonzero multiple of
itself, divided by the product of their norms, has absolute value
1. -/
theorem abs_real_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul {x : F} {r : ℝ}
(hx : x ≠ 0) (hr : r ≠ 0) : |⟪x, r • x⟫_ℝ| / (‖x‖ * ‖r • x‖) = 1 :=
norm_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul hx hr
/-- The inner product of a nonzero vector with a positive multiple of
itself, divided by the product of their norms, has value 1. -/
theorem real_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_pos_mul {x : F} {r : ℝ} (hx : x ≠ 0)
(hr : 0 < r) : ⟪x, r • x⟫_ℝ / (‖x‖ * ‖r • x‖) = 1 := by
rw [real_inner_smul_self_right, norm_smul, Real.norm_eq_abs, ← mul_assoc ‖x‖, mul_comm _ |r|,
mul_assoc, abs_of_nonneg hr.le, div_self]
exact mul_ne_zero hr.ne' (mul_self_ne_zero.2 (norm_ne_zero_iff.2 hx))
/-- The inner product of a nonzero vector with a negative multiple of
itself, divided by the product of their norms, has value -1. -/
theorem real_inner_div_norm_mul_norm_eq_neg_one_of_ne_zero_of_neg_mul {x : F} {r : ℝ} (hx : x ≠ 0)
(hr : r < 0) : ⟪x, r • x⟫_ℝ / (‖x‖ * ‖r • x‖) = -1 := by
rw [real_inner_smul_self_right, norm_smul, Real.norm_eq_abs, ← mul_assoc ‖x‖, mul_comm _ |r|,
mul_assoc, abs_of_neg hr, neg_mul, div_neg_eq_neg_div, div_self]
exact mul_ne_zero hr.ne (mul_self_ne_zero.2 (norm_ne_zero_iff.2 hx))
theorem norm_inner_eq_norm_tfae (x y : E) :
List.TFAE [‖⟪x, y⟫‖ = ‖x‖ * ‖y‖,
x = 0 ∨ y = (⟪x, y⟫ / ⟪x, x⟫) • x,
x = 0 ∨ ∃ r : 𝕜, y = r • x,
x = 0 ∨ y ∈ 𝕜 ∙ x] := by
tfae_have 1 → 2 := by
refine fun h => or_iff_not_imp_left.2 fun hx₀ => ?_
have : ‖x‖ ^ 2 ≠ 0 := pow_ne_zero _ (norm_ne_zero_iff.2 hx₀)
rw [← sq_eq_sq₀, mul_pow, ← mul_right_inj' this, eq_comm, ← sub_eq_zero, ← mul_sub] at h <;>
try positivity
simp only [@norm_sq_eq_re_inner 𝕜] at h
letI : InnerProductSpace.Core 𝕜 E := InnerProductSpace.toCore
erw [← InnerProductSpace.Core.cauchy_schwarz_aux (𝕜 := 𝕜) (F := E)] at h
rw [InnerProductSpace.Core.normSq_eq_zero, sub_eq_zero] at h
rw [div_eq_inv_mul, mul_smul, h, inv_smul_smul₀]
rwa [inner_self_ne_zero]
tfae_have 2 → 3 := fun h => h.imp_right fun h' => ⟨_, h'⟩
tfae_have 3 → 1 := by
rintro (rfl | ⟨r, rfl⟩) <;>
simp [inner_smul_right, norm_smul, inner_self_eq_norm_sq_to_K, inner_self_eq_norm_mul_norm,
sq, mul_left_comm]
tfae_have 3 ↔ 4 := by simp only [Submodule.mem_span_singleton, eq_comm]
tfae_finish
/-- If the inner product of two vectors is equal to the product of their norms, then the two vectors
are multiples of each other. One form of the equality case for Cauchy-Schwarz.
Compare `inner_eq_norm_mul_iff`, which takes the stronger hypothesis `⟪x, y⟫ = ‖x‖ * ‖y‖`. -/
theorem norm_inner_eq_norm_iff {x y : E} (hx₀ : x ≠ 0) (hy₀ : y ≠ 0) :
‖⟪x, y⟫‖ = ‖x‖ * ‖y‖ ↔ ∃ r : 𝕜, r ≠ 0 ∧ y = r • x :=
calc
‖⟪x, y⟫‖ = ‖x‖ * ‖y‖ ↔ x = 0 ∨ ∃ r : 𝕜, y = r • x :=
(@norm_inner_eq_norm_tfae 𝕜 _ _ _ _ x y).out 0 2
_ ↔ ∃ r : 𝕜, y = r • x := or_iff_right hx₀
_ ↔ ∃ r : 𝕜, r ≠ 0 ∧ y = r • x :=
⟨fun ⟨r, h⟩ => ⟨r, fun hr₀ => hy₀ <| h.symm ▸ smul_eq_zero.2 <| Or.inl hr₀, h⟩,
fun ⟨r, _hr₀, h⟩ => ⟨r, h⟩⟩
/-- The inner product of two vectors, divided by the product of their
norms, has absolute value 1 if and only if they are nonzero and one is
a multiple of the other. One form of equality case for Cauchy-Schwarz. -/
theorem norm_inner_div_norm_mul_norm_eq_one_iff (x y : E) :
‖⟪x, y⟫ / (‖x‖ * ‖y‖)‖ = 1 ↔ x ≠ 0 ∧ ∃ r : 𝕜, r ≠ 0 ∧ y = r • x := by
constructor
· intro h
have hx₀ : x ≠ 0 := fun h₀ => by simp [h₀] at h
have hy₀ : y ≠ 0 := fun h₀ => by simp [h₀] at h
refine ⟨hx₀, (norm_inner_eq_norm_iff hx₀ hy₀).1 <| eq_of_div_eq_one ?_⟩
simpa using h
· rintro ⟨hx, ⟨r, ⟨hr, rfl⟩⟩⟩
simp only [norm_div, norm_mul, norm_ofReal, abs_norm]
exact norm_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_ne_zero_mul hx hr
/-- The inner product of two vectors, divided by the product of their
norms, has absolute value 1 if and only if they are nonzero and one is
a multiple of the other. One form of equality case for Cauchy-Schwarz. -/
theorem abs_real_inner_div_norm_mul_norm_eq_one_iff (x y : F) :
|⟪x, y⟫_ℝ / (‖x‖ * ‖y‖)| = 1 ↔ x ≠ 0 ∧ ∃ r : ℝ, r ≠ 0 ∧ y = r • x :=
@norm_inner_div_norm_mul_norm_eq_one_iff ℝ F _ _ _ x y
theorem inner_eq_norm_mul_iff_div {x y : E} (h₀ : x ≠ 0) :
⟪x, y⟫ = (‖x‖ : 𝕜) * ‖y‖ ↔ (‖y‖ / ‖x‖ : 𝕜) • x = y := by
have h₀' := h₀
rw [← norm_ne_zero_iff, Ne, ← @ofReal_eq_zero 𝕜] at h₀'
constructor <;> intro h
· have : x = 0 ∨ y = (⟪x, y⟫ / ⟪x, x⟫ : 𝕜) • x :=
((@norm_inner_eq_norm_tfae 𝕜 _ _ _ _ x y).out 0 1).1 (by simp [h])
rw [this.resolve_left h₀, h]
simp [norm_smul, inner_self_ofReal_norm, mul_div_cancel_right₀ _ h₀']
· conv_lhs => rw [← h, inner_smul_right, inner_self_eq_norm_sq_to_K]
field_simp [sq, mul_left_comm]
/-- If the inner product of two vectors is equal to the product of their norms (i.e.,
`⟪x, y⟫ = ‖x‖ * ‖y‖`), then the two vectors are nonnegative real multiples of each other. One form
of the equality case for Cauchy-Schwarz.
Compare `norm_inner_eq_norm_iff`, which takes the weaker hypothesis `abs ⟪x, y⟫ = ‖x‖ * ‖y‖`. -/
theorem inner_eq_norm_mul_iff {x y : E} :
⟪x, y⟫ = (‖x‖ : 𝕜) * ‖y‖ ↔ (‖y‖ : 𝕜) • x = (‖x‖ : 𝕜) • y := by
rcases eq_or_ne x 0 with (rfl | h₀)
· simp
· rw [inner_eq_norm_mul_iff_div h₀, div_eq_inv_mul, mul_smul, inv_smul_eq_iff₀]
rwa [Ne, ofReal_eq_zero, norm_eq_zero]
/-- If the inner product of two vectors is equal to the product of their norms (i.e.,
`⟪x, y⟫ = ‖x‖ * ‖y‖`), then the two vectors are nonnegative real multiples of each other. One form
of the equality case for Cauchy-Schwarz.
Compare `norm_inner_eq_norm_iff`, which takes the weaker hypothesis `abs ⟪x, y⟫ = ‖x‖ * ‖y‖`. -/
theorem inner_eq_norm_mul_iff_real {x y : F} : ⟪x, y⟫_ℝ = ‖x‖ * ‖y‖ ↔ ‖y‖ • x = ‖x‖ • y :=
inner_eq_norm_mul_iff
/-- The inner product of two vectors, divided by the product of their
norms, has value 1 if and only if they are nonzero and one is
a positive multiple of the other. -/
theorem real_inner_div_norm_mul_norm_eq_one_iff (x y : F) :
⟪x, y⟫_ℝ / (‖x‖ * ‖y‖) = 1 ↔ x ≠ 0 ∧ ∃ r : ℝ, 0 < r ∧ y = r • x := by
constructor
· intro h
have hx₀ : x ≠ 0 := fun h₀ => by simp [h₀] at h
have hy₀ : y ≠ 0 := fun h₀ => by simp [h₀] at h
refine ⟨hx₀, ‖y‖ / ‖x‖, div_pos (norm_pos_iff.2 hy₀) (norm_pos_iff.2 hx₀), ?_⟩
exact ((inner_eq_norm_mul_iff_div hx₀).1 (eq_of_div_eq_one h)).symm
· rintro ⟨hx, ⟨r, ⟨hr, rfl⟩⟩⟩
exact real_inner_div_norm_mul_norm_eq_one_of_ne_zero_of_pos_mul hx hr
/-- The inner product of two vectors, divided by the product of their
norms, has value -1 if and only if they are nonzero and one is
a negative multiple of the other. -/
theorem real_inner_div_norm_mul_norm_eq_neg_one_iff (x y : F) :
⟪x, y⟫_ℝ / (‖x‖ * ‖y‖) = -1 ↔ x ≠ 0 ∧ ∃ r : ℝ, r < 0 ∧ y = r • x := by
rw [← neg_eq_iff_eq_neg, ← neg_div, ← inner_neg_right, ← norm_neg y,
real_inner_div_norm_mul_norm_eq_one_iff, (@neg_surjective ℝ _).exists]
refine Iff.rfl.and (exists_congr fun r => ?_)
rw [neg_pos, neg_smul, neg_inj]
/-- If the inner product of two unit vectors is `1`, then the two vectors are equal. One form of
the equality case for Cauchy-Schwarz. -/
theorem inner_eq_one_iff_of_norm_one {x y : E} (hx : ‖x‖ = 1) (hy : ‖y‖ = 1) :
⟪x, y⟫ = 1 ↔ x = y := by
convert inner_eq_norm_mul_iff (𝕜 := 𝕜) (E := E) using 2 <;> simp [hx, hy]
theorem inner_lt_norm_mul_iff_real {x y : F} : ⟪x, y⟫_ℝ < ‖x‖ * ‖y‖ ↔ ‖y‖ • x ≠ ‖x‖ • y :=
calc
⟪x, y⟫_ℝ < ‖x‖ * ‖y‖ ↔ ⟪x, y⟫_ℝ ≠ ‖x‖ * ‖y‖ :=
⟨ne_of_lt, lt_of_le_of_ne (real_inner_le_norm _ _)⟩
_ ↔ ‖y‖ • x ≠ ‖x‖ • y := not_congr inner_eq_norm_mul_iff_real
/-- If the inner product of two unit vectors is strictly less than `1`, then the two vectors are
distinct. One form of the equality case for Cauchy-Schwarz. -/
theorem inner_lt_one_iff_real_of_norm_one {x y : F} (hx : ‖x‖ = 1) (hy : ‖y‖ = 1) :
⟪x, y⟫_ℝ < 1 ↔ x ≠ y := by convert inner_lt_norm_mul_iff_real (F := F) <;> simp [hx, hy]
/-- The sphere of radius `r = ‖y‖` is tangent to the plane `⟪x, y⟫ = ‖y‖ ^ 2` at `x = y`. -/
theorem eq_of_norm_le_re_inner_eq_norm_sq {x y : E} (hle : ‖x‖ ≤ ‖y‖) (h : re ⟪x, y⟫ = ‖y‖ ^ 2) :
x = y := by
suffices H : re ⟪x - y, x - y⟫ ≤ 0 by rwa [re_inner_self_nonpos, sub_eq_zero] at H
have H₁ : ‖x‖ ^ 2 ≤ ‖y‖ ^ 2 := by gcongr
have H₂ : re ⟪y, x⟫ = ‖y‖ ^ 2 := by rwa [← inner_conj_symm, conj_re]
simpa [inner_sub_left, inner_sub_right, ← norm_sq_eq_re_inner, h, H₂] using H₁
end Norm
section RCLike
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-- A field `𝕜` satisfying `RCLike` is itself a `𝕜`-inner product space. -/
instance RCLike.innerProductSpace : InnerProductSpace 𝕜 𝕜 where
inner x y := y * conj x
norm_sq_eq_re_inner x := by simp only [inner, mul_conj, ← ofReal_pow, ofReal_re]
conj_inner_symm x y := by simp only [mul_comm, map_mul, starRingEnd_self_apply]
add_left x y z := by simp only [mul_add, map_add]
smul_left x y z := by simp only [mul_comm (conj z), mul_assoc, smul_eq_mul, map_mul]
@[simp]
theorem RCLike.inner_apply (x y : 𝕜) : ⟪x, y⟫ = y * conj x :=
rfl
/-- A version of `RCLike.inner_apply` that swaps the order of multiplication. -/
theorem RCLike.inner_apply' (x y : 𝕜) : ⟪x, y⟫ = conj x * y := mul_comm _ _
end RCLike
section RCLikeToReal
open scoped InnerProductSpace
variable {G : Type*}
variable (𝕜 E)
variable [SeminormedAddCommGroup E] [InnerProductSpace 𝕜 E]
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-- A general inner product implies a real inner product. This is not registered as an instance
since `𝕜` does not appear in the return type `Inner ℝ E`. -/
def Inner.rclikeToReal : Inner ℝ E where inner x y := re ⟪x, y⟫
/-- A general inner product space structure implies a real inner product structure.
This is not registered as an instance since
* `𝕜` does not appear in the return type `InnerProductSpace ℝ E`,
* It is likely to create instance diamonds, as it builds upon the diamond-prone
`NormedSpace.restrictScalars`.
However, it can be used in a proof to obtain a real inner product space structure from a given
`𝕜`-inner product space structure. -/
-- See note [reducible non instances]
abbrev InnerProductSpace.rclikeToReal : InnerProductSpace ℝ E :=
{ Inner.rclikeToReal 𝕜 E,
NormedSpace.restrictScalars ℝ 𝕜
E with
norm_sq_eq_re_inner := norm_sq_eq_re_inner
conj_inner_symm := fun _ _ => inner_re_symm _ _
add_left := fun x y z => by
change re ⟪x + y, z⟫ = re ⟪x, z⟫ + re ⟪y, z⟫
simp only [inner_add_left, map_add]
smul_left := fun x y r => by
change re ⟪(r : 𝕜) • x, y⟫ = r * re ⟪x, y⟫
simp only [inner_smul_left, conj_ofReal, re_ofReal_mul] }
variable {E}
theorem real_inner_eq_re_inner (x y : E) :
@Inner.inner ℝ E (Inner.rclikeToReal 𝕜 E) x y = re ⟪x, y⟫ :=
rfl
theorem real_inner_I_smul_self (x : E) :
@Inner.inner ℝ E (Inner.rclikeToReal 𝕜 E) x ((I : 𝕜) • x) = 0 := by
simp [real_inner_eq_re_inner 𝕜, inner_smul_right]
/-- A complex inner product implies a real inner product. This cannot be an instance since it
creates a diamond with `PiLp.innerProductSpace` because `re (sum i, inner (x i) (y i))` and
`sum i, re (inner (x i) (y i))` are not defeq. -/
def InnerProductSpace.complexToReal [SeminormedAddCommGroup G] [InnerProductSpace ℂ G] :
InnerProductSpace ℝ G :=
InnerProductSpace.rclikeToReal ℂ G
instance : InnerProductSpace ℝ ℂ := InnerProductSpace.complexToReal
@[simp]
protected theorem Complex.inner (w z : ℂ) : ⟪w, z⟫_ℝ = (z * conj w).re :=
rfl
end RCLikeToReal
/-- An `RCLike` field is a real inner product space. -/
noncomputable instance RCLike.toInnerProductSpaceReal : InnerProductSpace ℝ 𝕜 where
__ := Inner.rclikeToReal 𝕜 𝕜
norm_sq_eq_re_inner := norm_sq_eq_re_inner
conj_inner_symm x y := inner_re_symm ..
add_left x y z :=
show re (_ * _) = re (_ * _) + re (_ * _) by simp only [map_add, mul_re, conj_re, conj_im]; ring
smul_left x y r :=
show re (_ * _) = _ * re (_ * _) by
simp only [mul_re, conj_re, conj_im, conj_trivial, smul_re, smul_im]; ring
-- The instance above does not create diamonds for concrete `𝕜`:
example : (innerProductSpace : InnerProductSpace ℝ ℝ) = RCLike.toInnerProductSpaceReal := rfl
example :
(instInnerProductSpaceRealComplex : InnerProductSpace ℝ ℂ) = RCLike.toInnerProductSpaceReal := rfl
| Mathlib/Analysis/InnerProductSpace/Basic.lean | 1,049 | 1,051 | |
/-
Copyright (c) 2018 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Johannes Hölzl
-/
import Mathlib.MeasureTheory.Integral.Lebesgue.Countable
import Mathlib.MeasureTheory.Measure.Decomposition.Exhaustion
import Mathlib.MeasureTheory.Measure.Prod
/-!
# Measure with a given density with respect to another measure
For a measure `μ` on `α` and a function `f : α → ℝ≥0∞`, we define a new measure `μ.withDensity f`.
On a measurable set `s`, that measure has value `∫⁻ a in s, f a ∂μ`.
An important result about `withDensity` is the Radon-Nikodym theorem. It states that, given measures
`μ, ν`, if `HaveLebesgueDecomposition μ ν` then `μ` is absolutely continuous with respect to
`ν` if and only if there exists a measurable function `f : α → ℝ≥0∞` such that
`μ = ν.withDensity f`.
See `MeasureTheory.Measure.absolutelyContinuous_iff_withDensity_rnDeriv_eq`.
-/
open Set hiding restrict restrict_apply
open Filter ENNReal NNReal MeasureTheory.Measure
namespace MeasureTheory
variable {α : Type*} {m0 : MeasurableSpace α} {μ : Measure α}
/-- Given a measure `μ : Measure α` and a function `f : α → ℝ≥0∞`, `μ.withDensity f` is the
measure such that for a measurable set `s` we have `μ.withDensity f s = ∫⁻ a in s, f a ∂μ`. -/
noncomputable
def Measure.withDensity {m : MeasurableSpace α} (μ : Measure α) (f : α → ℝ≥0∞) : Measure α :=
Measure.ofMeasurable (fun s _ => ∫⁻ a in s, f a ∂μ) (by simp) fun _ hs hd =>
lintegral_iUnion hs hd _
@[simp]
theorem withDensity_apply (f : α → ℝ≥0∞) {s : Set α} (hs : MeasurableSet s) :
μ.withDensity f s = ∫⁻ a in s, f a ∂μ :=
Measure.ofMeasurable_apply s hs
theorem withDensity_apply_le (f : α → ℝ≥0∞) (s : Set α) :
∫⁻ a in s, f a ∂μ ≤ μ.withDensity f s := by
let t := toMeasurable (μ.withDensity f) s
calc
∫⁻ a in s, f a ∂μ ≤ ∫⁻ a in t, f a ∂μ :=
lintegral_mono_set (subset_toMeasurable (withDensity μ f) s)
_ = μ.withDensity f t :=
(withDensity_apply f (measurableSet_toMeasurable (withDensity μ f) s)).symm
_ = μ.withDensity f s := measure_toMeasurable s
/-! In the next theorem, the s-finiteness assumption is necessary. Here is a counterexample
without this assumption. Let `α` be an uncountable space, let `x₀` be some fixed point, and consider
the σ-algebra made of those sets which are countable and do not contain `x₀`, and of their
complements. This is the σ-algebra generated by the sets `{x}` for `x ≠ x₀`. Define a measure equal
to `+∞` on nonempty sets. Let `s = {x₀}` and `f` the indicator of `sᶜ`. Then
* `∫⁻ a in s, f a ∂μ = 0`. Indeed, consider a simple function `g ≤ f`. It vanishes on `s`. Then
`∫⁻ a in s, g a ∂μ = 0`. Taking the supremum over `g` gives the claim.
* `μ.withDensity f s = +∞`. Indeed, this is the infimum of `μ.withDensity f t` over measurable sets
`t` containing `s`. As `s` is not measurable, such a set `t` contains a point `x ≠ x₀`. Then
`μ.withDensity f t ≥ μ.withDensity f {x} = ∫⁻ a in {x}, f a ∂μ = μ {x} = +∞`.
One checks that `μ.withDensity f = μ`, while `μ.restrict s` gives zero mass to sets not
containing `x₀`, and infinite mass to those that contain it. -/
theorem withDensity_apply' [SFinite μ] (f : α → ℝ≥0∞) (s : Set α) :
μ.withDensity f s = ∫⁻ a in s, f a ∂μ := by
apply le_antisymm ?_ (withDensity_apply_le f s)
let t := toMeasurable μ s
calc
μ.withDensity f s ≤ μ.withDensity f t := measure_mono (subset_toMeasurable μ s)
_ = ∫⁻ a in t, f a ∂μ := withDensity_apply f (measurableSet_toMeasurable μ s)
_ = ∫⁻ a in s, f a ∂μ := by congr 1; exact restrict_toMeasurable_of_sFinite s
@[simp]
lemma withDensity_zero_left (f : α → ℝ≥0∞) : (0 : Measure α).withDensity f = 0 := by
ext s hs
rw [withDensity_apply _ hs]
simp
theorem withDensity_congr_ae {f g : α → ℝ≥0∞} (h : f =ᵐ[μ] g) :
μ.withDensity f = μ.withDensity g := by
refine Measure.ext fun s hs => ?_
rw [withDensity_apply _ hs, withDensity_apply _ hs]
exact lintegral_congr_ae (ae_restrict_of_ae h)
lemma withDensity_mono {f g : α → ℝ≥0∞} (hfg : f ≤ᵐ[μ] g) :
μ.withDensity f ≤ μ.withDensity g := by
refine le_iff.2 fun s hs ↦ ?_
rw [withDensity_apply _ hs, withDensity_apply _ hs]
refine setLIntegral_mono_ae' hs ?_
filter_upwards [hfg] with x h_le using fun _ ↦ h_le
theorem withDensity_add_left {f : α → ℝ≥0∞} (hf : Measurable f) (g : α → ℝ≥0∞) :
μ.withDensity (f + g) = μ.withDensity f + μ.withDensity g := by
refine Measure.ext fun s hs => ?_
rw [withDensity_apply _ hs, Measure.add_apply, withDensity_apply _ hs, withDensity_apply _ hs,
← lintegral_add_left hf]
simp only [Pi.add_apply]
theorem withDensity_add_right (f : α → ℝ≥0∞) {g : α → ℝ≥0∞} (hg : Measurable g) :
μ.withDensity (f + g) = μ.withDensity f + μ.withDensity g := by
simpa only [add_comm] using withDensity_add_left hg f
theorem withDensity_add_measure {m : MeasurableSpace α} (μ ν : Measure α) (f : α → ℝ≥0∞) :
(μ + ν).withDensity f = μ.withDensity f + ν.withDensity f := by
ext1 s hs
simp only [withDensity_apply f hs, restrict_add, lintegral_add_measure, Measure.add_apply]
theorem withDensity_sum {ι : Type*} {m : MeasurableSpace α} (μ : ι → Measure α) (f : α → ℝ≥0∞) :
(sum μ).withDensity f = sum fun n => (μ n).withDensity f := by
ext1 s hs
simp_rw [sum_apply _ hs, withDensity_apply f hs, restrict_sum μ hs, lintegral_sum_measure]
theorem withDensity_smul (r : ℝ≥0∞) {f : α → ℝ≥0∞} (hf : Measurable f) :
μ.withDensity (r • f) = r • μ.withDensity f := by
refine Measure.ext fun s hs => ?_
rw [withDensity_apply _ hs, Measure.coe_smul, Pi.smul_apply, withDensity_apply _ hs,
smul_eq_mul, ← lintegral_const_mul r hf]
simp only [Pi.smul_apply, smul_eq_mul]
theorem withDensity_smul' (r : ℝ≥0∞) (f : α → ℝ≥0∞) (hr : r ≠ ∞) :
μ.withDensity (r • f) = r • μ.withDensity f := by
refine Measure.ext fun s hs => ?_
rw [withDensity_apply _ hs, Measure.coe_smul, Pi.smul_apply, withDensity_apply _ hs,
smul_eq_mul, ← lintegral_const_mul' r f hr]
simp only [Pi.smul_apply, smul_eq_mul]
theorem withDensity_smul_measure (r : ℝ≥0∞) (f : α → ℝ≥0∞) :
(r • μ).withDensity f = r • μ.withDensity f := by
ext s hs
simp [withDensity_apply, hs]
theorem isFiniteMeasure_withDensity {f : α → ℝ≥0∞} (hf : ∫⁻ a, f a ∂μ ≠ ∞) :
IsFiniteMeasure (μ.withDensity f) :=
{ measure_univ_lt_top := by
rwa [withDensity_apply _ MeasurableSet.univ, Measure.restrict_univ, lt_top_iff_ne_top] }
theorem withDensity_absolutelyContinuous {m : MeasurableSpace α} (μ : Measure α) (f : α → ℝ≥0∞) :
μ.withDensity f ≪ μ := by
refine AbsolutelyContinuous.mk fun s hs₁ hs₂ => ?_
rw [withDensity_apply _ hs₁]
exact setLIntegral_measure_zero _ _ hs₂
@[simp]
theorem withDensity_zero : μ.withDensity 0 = 0 := by
ext1 s hs
simp [withDensity_apply _ hs]
@[simp]
theorem withDensity_one : μ.withDensity 1 = μ := by
ext1 s hs
simp [withDensity_apply _ hs]
@[simp]
theorem withDensity_const (c : ℝ≥0∞) : μ.withDensity (fun _ ↦ c) = c • μ := by
ext1 s hs
simp [withDensity_apply _ hs]
theorem withDensity_tsum {ι : Type*} [Countable ι] {f : ι → α → ℝ≥0∞} (h : ∀ i, Measurable (f i)) :
μ.withDensity (∑' n, f n) = sum fun n => μ.withDensity (f n) := by
ext1 s hs
simp_rw [sum_apply _ hs, withDensity_apply _ hs]
change ∫⁻ x in s, (∑' n, f n) x ∂μ = ∑' i, ∫⁻ x, f i x ∂μ.restrict s
rw [← lintegral_tsum fun i => (h i).aemeasurable]
exact lintegral_congr fun x => tsum_apply (Pi.summable.2 fun _ => ENNReal.summable)
theorem withDensity_indicator {s : Set α} (hs : MeasurableSet s) (f : α → ℝ≥0∞) :
μ.withDensity (s.indicator f) = (μ.restrict s).withDensity f := by
ext1 t ht
rw [withDensity_apply _ ht, lintegral_indicator hs, restrict_comm hs, ←
withDensity_apply _ ht]
theorem withDensity_indicator_one {s : Set α} (hs : MeasurableSet s) :
μ.withDensity (s.indicator 1) = μ.restrict s := by
rw [withDensity_indicator hs, withDensity_one]
theorem withDensity_ofReal_mutuallySingular {f : α → ℝ} (hf : Measurable f) :
(μ.withDensity fun x => ENNReal.ofReal <| f x) ⟂ₘ
μ.withDensity fun x => ENNReal.ofReal <| -f x := by
set S : Set α := { x | f x < 0 }
have hS : MeasurableSet S := measurableSet_lt hf measurable_const
refine ⟨S, hS, ?_, ?_⟩
· rw [withDensity_apply _ hS, lintegral_eq_zero_iff hf.ennreal_ofReal, EventuallyEq]
exact (ae_restrict_mem hS).mono fun x hx => ENNReal.ofReal_eq_zero.2 (le_of_lt hx)
· rw [withDensity_apply _ hS.compl, lintegral_eq_zero_iff hf.neg.ennreal_ofReal, EventuallyEq]
exact
(ae_restrict_mem hS.compl).mono fun x hx =>
ENNReal.ofReal_eq_zero.2 (not_lt.1 <| mt neg_pos.1 hx)
theorem restrict_withDensity {s : Set α} (hs : MeasurableSet s) (f : α → ℝ≥0∞) :
(μ.withDensity f).restrict s = (μ.restrict s).withDensity f := by
ext1 t ht
rw [restrict_apply ht, withDensity_apply _ ht, withDensity_apply _ (ht.inter hs),
restrict_restrict ht]
theorem restrict_withDensity' [SFinite μ] (s : Set α) (f : α → ℝ≥0∞) :
(μ.withDensity f).restrict s = (μ.restrict s).withDensity f := by
ext1 t ht
rw [restrict_apply ht, withDensity_apply _ ht, withDensity_apply' _ (t ∩ s),
restrict_restrict ht]
lemma trim_withDensity {m m0 : MeasurableSpace α} {μ : Measure α}
(hm : m ≤ m0) {f : α → ℝ≥0∞} (hf : Measurable[m] f) :
(μ.withDensity f).trim hm = (μ.trim hm).withDensity f := by
refine @Measure.ext _ m _ _ (fun s hs ↦ ?_)
rw [withDensity_apply _ hs, restrict_trim _ _ hs, lintegral_trim _ hf, trim_measurableSet_eq _ hs,
withDensity_apply _ (hm s hs)]
lemma Measure.MutuallySingular.withDensity {ν : Measure α} {f : α → ℝ≥0∞} (h : μ ⟂ₘ ν) :
μ.withDensity f ⟂ₘ ν :=
MutuallySingular.mono_ac h (withDensity_absolutelyContinuous _ _) AbsolutelyContinuous.rfl
@[simp]
theorem withDensity_eq_zero_iff {f : α → ℝ≥0∞} (hf : AEMeasurable f μ) :
μ.withDensity f = 0 ↔ f =ᵐ[μ] 0 := by
rw [← measure_univ_eq_zero, withDensity_apply _ .univ, restrict_univ, lintegral_eq_zero_iff' hf]
alias ⟨withDensity_eq_zero, _⟩ := withDensity_eq_zero_iff
theorem withDensity_apply_eq_zero' {f : α → ℝ≥0∞} {s : Set α} (hf : AEMeasurable f μ) :
μ.withDensity f s = 0 ↔ μ ({ x | f x ≠ 0 } ∩ s) = 0 := by
constructor
· intro hs
let t := toMeasurable (μ.withDensity f) s
apply measure_mono_null (inter_subset_inter_right _ (subset_toMeasurable (μ.withDensity f) s))
have A : μ.withDensity f t = 0 := by rw [measure_toMeasurable, hs]
rw [withDensity_apply f (measurableSet_toMeasurable _ s),
lintegral_eq_zero_iff' (AEMeasurable.restrict hf),
EventuallyEq, ae_restrict_iff'₀, ae_iff] at A
swap
· simp only [measurableSet_toMeasurable, MeasurableSet.nullMeasurableSet]
simp only [Pi.zero_apply, mem_setOf_eq, Filter.mem_mk] at A
convert A using 2
ext x
simp only [and_comm, exists_prop, mem_inter_iff, mem_setOf_eq,
mem_compl_iff, not_forall]
· intro hs
let t := toMeasurable μ ({ x | f x ≠ 0 } ∩ s)
have A : s ⊆ t ∪ { x | f x = 0 } := by
intro x hx
rcases eq_or_ne (f x) 0 with (fx | fx)
· simp only [fx, mem_union, mem_setOf_eq, eq_self_iff_true, or_true]
· left
apply subset_toMeasurable _ _
exact ⟨fx, hx⟩
apply measure_mono_null A (measure_union_null _ _)
· apply withDensity_absolutelyContinuous
rwa [measure_toMeasurable]
rcases hf with ⟨g, hg, hfg⟩
have t : {x | f x = 0} =ᵐ[μ.withDensity f] {x | g x = 0} := by
apply withDensity_absolutelyContinuous
filter_upwards [hfg] with a ha
rw [eq_iff_iff]
exact ⟨fun h ↦ by rw [h] at ha; exact ha.symm,
fun h ↦ by rw [h] at ha; exact ha⟩
rw [measure_congr t, withDensity_congr_ae hfg]
have M : MeasurableSet { x : α | g x = 0 } := hg (measurableSet_singleton _)
rw [withDensity_apply _ M, lintegral_eq_zero_iff hg]
filter_upwards [ae_restrict_mem M]
simp only [imp_self, Pi.zero_apply, imp_true_iff]
theorem withDensity_apply_eq_zero {f : α → ℝ≥0∞} {s : Set α} (hf : Measurable f) :
μ.withDensity f s = 0 ↔ μ ({ x | f x ≠ 0 } ∩ s) = 0 :=
withDensity_apply_eq_zero' <| hf.aemeasurable
theorem ae_withDensity_iff' {p : α → Prop} {f : α → ℝ≥0∞} (hf : AEMeasurable f μ) :
(∀ᵐ x ∂μ.withDensity f, p x) ↔ ∀ᵐ x ∂μ, f x ≠ 0 → p x := by
rw [ae_iff, ae_iff, withDensity_apply_eq_zero' hf, iff_iff_eq]
congr
ext x
simp only [exists_prop, mem_inter_iff, mem_setOf_eq, not_forall]
theorem ae_withDensity_iff {p : α → Prop} {f : α → ℝ≥0∞} (hf : Measurable f) :
(∀ᵐ x ∂μ.withDensity f, p x) ↔ ∀ᵐ x ∂μ, f x ≠ 0 → p x :=
ae_withDensity_iff' <| hf.aemeasurable
theorem ae_withDensity_iff_ae_restrict' {p : α → Prop} {f : α → ℝ≥0∞}
(hf : AEMeasurable f μ) :
(∀ᵐ x ∂μ.withDensity f, p x) ↔ ∀ᵐ x ∂μ.restrict { x | f x ≠ 0 }, p x := by
rw [ae_withDensity_iff' hf, ae_restrict_iff'₀]
· simp only [mem_setOf]
· rcases hf with ⟨g, hg, hfg⟩
have nonneg_eq_ae : {x | g x ≠ 0} =ᵐ[μ] {x | f x ≠ 0} := by
filter_upwards [hfg] with a ha
simp only [eq_iff_iff]
exact ⟨fun (h : g a ≠ 0) ↦ by rwa [← ha] at h,
fun (h : f a ≠ 0) ↦ by rwa [ha] at h⟩
| exact NullMeasurableSet.congr
(MeasurableSet.nullMeasurableSet
<| hg (measurableSet_singleton _)).compl
nonneg_eq_ae
theorem ae_withDensity_iff_ae_restrict {p : α → Prop} {f : α → ℝ≥0∞} (hf : Measurable f) :
| Mathlib/MeasureTheory/Measure/WithDensity.lean | 291 | 296 |
/-
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.Polynomial.Degree.Support
/-! # Interactions between `R[X]` and `Rᵐᵒᵖ[X]`
This file contains the basic API for "pushing through" the isomorphism
`opRingEquiv : R[X]ᵐᵒᵖ ≃+* Rᵐᵒᵖ[X]`. It allows going back and forth between a polynomial ring
over a semiring and the polynomial ring over the opposite semiring. -/
open Polynomial
open Polynomial MulOpposite
variable {R : Type*} [Semiring R]
noncomputable section
namespace Polynomial
/-- Ring isomorphism between `R[X]ᵐᵒᵖ` and `Rᵐᵒᵖ[X]` sending each coefficient of a polynomial
to the corresponding element of the opposite ring. -/
def opRingEquiv (R : Type*) [Semiring R] : R[X]ᵐᵒᵖ ≃+* Rᵐᵒᵖ[X] :=
((toFinsuppIso R).op.trans AddMonoidAlgebra.opRingEquiv).trans (toFinsuppIso _).symm
/-! Lemmas to get started, using `opRingEquiv R` on the various expressions of
`Finsupp.single`: `monomial`, `C a`, `X`, `C a * X ^ n`. -/
@[simp]
theorem opRingEquiv_op_monomial (n : ℕ) (r : R) :
opRingEquiv R (op (monomial n r : R[X])) = monomial n (op r) := by
simp only [opRingEquiv, RingEquiv.coe_trans, Function.comp_apply,
AddMonoidAlgebra.opRingEquiv_apply, RingEquiv.op_apply_apply, toFinsuppIso_apply, unop_op,
toFinsupp_monomial, Finsupp.mapRange_single, toFinsuppIso_symm_apply, ofFinsupp_single]
@[simp]
theorem opRingEquiv_op_C (a : R) : opRingEquiv R (op (C a)) = C (op a) :=
opRingEquiv_op_monomial 0 a
@[simp]
theorem opRingEquiv_op_X : opRingEquiv R (op (X : R[X])) = X :=
opRingEquiv_op_monomial 1 1
theorem opRingEquiv_op_C_mul_X_pow (r : R) (n : ℕ) :
opRingEquiv R (op (C r * X ^ n : R[X])) = C (op r) * X ^ n := by
simp only [X_pow_mul, op_mul, op_pow, map_mul, map_pow, opRingEquiv_op_X, opRingEquiv_op_C]
/-! Lemmas to get started, using `(opRingEquiv R).symm` on the various expressions of
`Finsupp.single`: `monomial`, `C a`, `X`, `C a * X ^ n`. -/
@[simp]
theorem opRingEquiv_symm_monomial (n : ℕ) (r : Rᵐᵒᵖ) :
(opRingEquiv R).symm (monomial n r) = op (monomial n (unop r)) :=
(opRingEquiv R).injective (by simp)
@[simp]
theorem opRingEquiv_symm_C (a : Rᵐᵒᵖ) : (opRingEquiv R).symm (C a) = op (C (unop a)) :=
opRingEquiv_symm_monomial 0 a
@[simp]
theorem opRingEquiv_symm_X : (opRingEquiv R).symm (X : Rᵐᵒᵖ[X]) = op X :=
opRingEquiv_symm_monomial 1 1
theorem opRingEquiv_symm_C_mul_X_pow (r : Rᵐᵒᵖ) (n : ℕ) :
(opRingEquiv R).symm (C r * X ^ n : Rᵐᵒᵖ[X]) = op (C (unop r) * X ^ n) := by
rw [C_mul_X_pow_eq_monomial, opRingEquiv_symm_monomial, C_mul_X_pow_eq_monomial]
/-! Lemmas about more global properties of polynomials and opposites. -/
@[simp]
theorem coeff_opRingEquiv (p : R[X]ᵐᵒᵖ) (n : ℕ) :
(opRingEquiv R p).coeff n = op ((unop p).coeff n) := by
induction' p with p
cases p
rfl
@[simp]
theorem support_opRingEquiv (p : R[X]ᵐᵒᵖ) : (opRingEquiv R p).support = (unop p).support := by
induction' p with p
cases p
exact Finsupp.support_mapRange_of_injective (map_zero _) _ op_injective
@[simp]
theorem natDegree_opRingEquiv (p : R[X]ᵐᵒᵖ) : (opRingEquiv R p).natDegree = (unop p).natDegree := by
by_cases p0 : p = 0
· simp only [p0, map_zero, natDegree_zero, unop_zero]
· simp only [p0, natDegree_eq_support_max', Ne, EmbeddingLike.map_eq_zero_iff, not_false_iff,
support_opRingEquiv, unop_eq_zero_iff]
@[simp]
theorem leadingCoeff_opRingEquiv (p : R[X]ᵐᵒᵖ) :
(opRingEquiv R p).leadingCoeff = op (unop p).leadingCoeff := by
rw [leadingCoeff, coeff_opRingEquiv, natDegree_opRingEquiv, leadingCoeff]
end Polynomial
| Mathlib/RingTheory/Polynomial/Opposites.lean | 110 | 114 | |
/-
Copyright (c) 2021 Yakov Pechersky. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yakov Pechersky
-/
import Mathlib.Data.Finset.Powerset
import Mathlib.Data.Fintype.Defs
import Mathlib.Data.List.Permutation
/-!
# Fintype instance for nodup lists
The subtype of `{l : List α // l.Nodup}` over a `[Fintype α]`
admits a `Fintype` instance.
## Implementation details
To construct the `Fintype` instance, a function lifting a `Multiset α`
to the `Multiset (List α)` is provided.
This function is applied to the `Finset.powerset` of `Finset.univ`.
-/
variable {α : Type*}
open List
namespace Multiset
/-- Given a `m : Multiset α`, we form the `Multiset` of `l : List α` with the property `⟦l⟧ = m`. -/
def lists : Multiset α → Multiset (List α) := fun s =>
Quotient.liftOn s (fun l => l.permutations) fun l l' (h : l ~ l') => by
simp only [mem_permutations, List.mem_toFinset]
refine coe_eq_coe.mpr ?_
exact Perm.permutations h
@[simp]
theorem lists_coe (l : List α) : lists (l : Multiset α) = l.permutations :=
rfl
@[simp]
theorem lists_nodup_finset (l : Finset α) : (lists (l.val)).Nodup := by
have h_nodup : l.val.Nodup := l.nodup
rw [← Finset.coe_toList l, Multiset.coe_nodup] at h_nodup
rw [← Finset.coe_toList l]
exact nodup_permutations l.val.toList (h_nodup)
@[simp]
theorem mem_lists_iff (s : Multiset α) (l : List α) : l ∈ lists s ↔ s = ⟦l⟧ := by
induction s using Quotient.inductionOn
| simpa using perm_comm
end Multiset
| Mathlib/Data/Fintype/List.lean | 51 | 53 |
/-
Copyright (c) 2020 Anne Baanen. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Anne Baanen
-/
import Mathlib.Data.Matrix.PEquiv
import Mathlib.Data.Set.Card
import Mathlib.LinearAlgebra.Matrix.Determinant.Basic
import Mathlib.LinearAlgebra.Matrix.Trace
/-!
# Permutation matrices
This file defines the matrix associated with a permutation
## Main definitions
- `Equiv.Perm.permMatrix`: the permutation matrix associated with an `Equiv.Perm`
## Main results
- `Matrix.det_permutation`: the determinant is the sign of the permutation
- `Matrix.trace_permutation`: the trace is the number of fixed points of the permutation
-/
open Equiv
variable {n R : Type*} [DecidableEq n] (σ : Perm n)
variable (R) in
/-- the permutation matrix associated with an `Equiv.Perm` -/
abbrev Equiv.Perm.permMatrix [Zero R] [One R] : Matrix n n R :=
σ.toPEquiv.toMatrix
namespace Matrix
@[simp]
lemma transpose_permMatrix [Zero R] [One R] : (σ.permMatrix R).transpose = (σ⁻¹).permMatrix R := by
rw [← PEquiv.toMatrix_symm, ← Equiv.toPEquiv_symm, ← Equiv.Perm.inv_def]
@[simp]
lemma conjTranspose_permMatrix [NonAssocSemiring R] [StarRing R] :
(σ.permMatrix R).conjTranspose = (σ⁻¹).permMatrix R := by
simp only [conjTranspose, transpose_permMatrix, map]
| aesop
variable [Fintype n]
| Mathlib/LinearAlgebra/Matrix/Permutation.lean | 47 | 50 |
/-
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.Primrec
import Mathlib.Data.Nat.PSub
import Mathlib.Data.PFun
/-!
# The partial recursive functions
The partial recursive functions are defined similarly to the primitive
recursive functions, but now all functions are partial, implemented
using the `Part` monad, and there is an additional operation, called
μ-recursion, which performs unbounded minimization: `μ f` returns the
least natural number `n` for which `f n = 0`, or diverges if such `n` doesn't exist.
## Main definitions
- `Nat.Partrec f`: `f` is partial recursive, for functions `f : ℕ →. ℕ`
- `Partrec f`: `f` is partial recursive, for partial functions between `Primcodable` types
- `Computable f`: `f` is partial recursive, for total functions between `Primcodable` types
## References
* [Mario Carneiro, *Formalizing computability theory via partial recursive functions*][carneiro2019]
-/
open List (Vector)
open Encodable Denumerable Part
attribute [-simp] not_forall
namespace Nat
section Rfind
variable (p : ℕ →. Bool)
private def lbp (m n : ℕ) : Prop :=
m = n + 1 ∧ ∀ k ≤ n, false ∈ p k
private def wf_lbp (H : ∃ n, true ∈ p n ∧ ∀ k < n, (p k).Dom) : WellFounded (lbp p) :=
⟨by
let ⟨n, pn⟩ := H
suffices ∀ m k, n ≤ k + m → Acc (lbp p) k by exact fun a => this _ _ (Nat.le_add_left _ _)
intro m k kn
induction' m with m IH generalizing k <;> refine ⟨_, fun y r => ?_⟩ <;> rcases r with ⟨rfl, a⟩
· injection mem_unique pn.1 (a _ kn)
· exact IH _ (by rw [Nat.add_right_comm]; exact kn)⟩
variable (H : ∃ n, true ∈ p n ∧ ∀ k < n, (p k).Dom)
/-- Find the smallest `n` satisfying `p n`, where all `p k` for `k < n` are defined as false.
Returns a subtype. -/
def rfindX : { n // true ∈ p n ∧ ∀ m < n, false ∈ p m } :=
suffices ∀ k, (∀ n < k, false ∈ p n) → { n // true ∈ p n ∧ ∀ m < n, false ∈ p m } from
this 0 fun _ => (Nat.not_lt_zero _).elim
@WellFounded.fix _ _ (lbp p) (wf_lbp p H)
(by
intro m IH al
have pm : (p m).Dom := by
rcases H with ⟨n, h₁, h₂⟩
rcases lt_trichotomy m n with (h₃ | h₃ | h₃)
· exact h₂ _ h₃
· rw [h₃]
exact h₁.fst
· injection mem_unique h₁ (al _ h₃)
cases e : (p m).get pm
· suffices ∀ᵉ k ≤ m, false ∈ p k from IH _ ⟨rfl, this⟩ fun n h => this _ (le_of_lt_succ h)
intro n h
rcases h.lt_or_eq_dec with h | h
· exact al _ h
· rw [h]
exact ⟨_, e⟩
· exact ⟨m, ⟨_, e⟩, al⟩)
end Rfind
/-- Find the smallest `n` satisfying `p n`, where all `p k` for `k < n` are defined as false.
Returns a `Part`. -/
def rfind (p : ℕ →. Bool) : Part ℕ :=
⟨_, fun h => (rfindX p h).1⟩
theorem rfind_spec {p : ℕ →. Bool} {n : ℕ} (h : n ∈ rfind p) : true ∈ p n :=
h.snd ▸ (rfindX p h.fst).2.1
theorem rfind_min {p : ℕ →. Bool} {n : ℕ} (h : n ∈ rfind p) : ∀ {m : ℕ}, m < n → false ∈ p m :=
@(h.snd ▸ @((rfindX p h.fst).2.2))
@[simp]
theorem rfind_dom {p : ℕ →. Bool} :
(rfind p).Dom ↔ ∃ n, true ∈ p n ∧ ∀ {m : ℕ}, m < n → (p m).Dom :=
Iff.rfl
theorem rfind_dom' {p : ℕ →. Bool} :
(rfind p).Dom ↔ ∃ n, true ∈ p n ∧ ∀ {m : ℕ}, m ≤ n → (p m).Dom :=
exists_congr fun _ =>
and_congr_right fun pn =>
⟨fun H _ h => (Decidable.eq_or_lt_of_le h).elim (fun e => e.symm ▸ pn.fst) (H _), fun H _ h =>
H (le_of_lt h)⟩
@[simp]
theorem mem_rfind {p : ℕ →. Bool} {n : ℕ} :
n ∈ rfind p ↔ true ∈ p n ∧ ∀ {m : ℕ}, m < n → false ∈ p m :=
⟨fun h => ⟨rfind_spec h, @rfind_min _ _ h⟩, fun ⟨h₁, h₂⟩ => by
let ⟨m, hm⟩ := dom_iff_mem.1 <| (@rfind_dom p).2 ⟨_, h₁, fun {m} mn => (h₂ mn).fst⟩
rcases lt_trichotomy m n with (h | h | h)
· injection mem_unique (h₂ h) (rfind_spec hm)
· rwa [← h]
· injection mem_unique h₁ (rfind_min hm h)⟩
theorem rfind_min' {p : ℕ → Bool} {m : ℕ} (pm : p m) : ∃ n ∈ rfind p, n ≤ m :=
have : true ∈ (p : ℕ →. Bool) m := ⟨trivial, pm⟩
let ⟨n, hn⟩ := dom_iff_mem.1 <| (@rfind_dom p).2 ⟨m, this, fun {_} _ => ⟨⟩⟩
⟨n, hn, not_lt.1 fun h => by injection mem_unique this (rfind_min hn h)⟩
theorem rfind_zero_none (p : ℕ →. Bool) (p0 : p 0 = Part.none) : rfind p = Part.none :=
eq_none_iff.2 fun _ h =>
let ⟨_, _, h₂⟩ := rfind_dom'.1 h.fst
(p0 ▸ h₂ (zero_le _) : (@Part.none Bool).Dom)
/-- Find the smallest `n` satisfying `f n`, where all `f k` for `k < n` are defined as false.
Returns a `Part`. -/
def rfindOpt {α} (f : ℕ → Option α) : Part α :=
(rfind fun n => (f n).isSome).bind fun n => f n
theorem rfindOpt_spec {α} {f : ℕ → Option α} {a} (h : a ∈ rfindOpt f) : ∃ n, a ∈ f n :=
let ⟨n, _, h₂⟩ := mem_bind_iff.1 h
⟨n, mem_coe.1 h₂⟩
theorem rfindOpt_dom {α} {f : ℕ → Option α} : (rfindOpt f).Dom ↔ ∃ n a, a ∈ f n :=
⟨fun h => (rfindOpt_spec ⟨h, rfl⟩).imp fun _ h => ⟨_, h⟩, fun h => by
have h' : ∃ n, (f n).isSome := h.imp fun n => Option.isSome_iff_exists.2
have s := Nat.find_spec h'
have fd : (rfind fun n => (f n).isSome).Dom :=
⟨Nat.find h', by simpa using s.symm, fun _ _ => trivial⟩
refine ⟨fd, ?_⟩
have := rfind_spec (get_mem fd)
simpa using this⟩
theorem rfindOpt_mono {α} {f : ℕ → Option α} (H : ∀ {a m n}, m ≤ n → a ∈ f m → a ∈ f n) {a} :
a ∈ rfindOpt f ↔ ∃ n, a ∈ f n :=
⟨rfindOpt_spec, fun ⟨n, h⟩ => by
have h' := rfindOpt_dom.2 ⟨_, _, h⟩
obtain ⟨k, hk⟩ := rfindOpt_spec ⟨h', rfl⟩
have := (H (le_max_left _ _) h).symm.trans (H (le_max_right _ _) hk)
simp at this; simp [this, get_mem]⟩
/-- `Partrec f` means that the partial function `f : ℕ → ℕ` is partially recursive. -/
inductive Partrec : (ℕ →. ℕ) → Prop
| zero : Partrec (pure 0)
| succ : Partrec succ
| left : Partrec ↑fun n : ℕ => n.unpair.1
| right : Partrec ↑fun n : ℕ => n.unpair.2
| pair {f g} : Partrec f → Partrec g → Partrec fun n => pair <$> f n <*> g n
| comp {f g} : Partrec f → Partrec g → Partrec fun n => g n >>= f
| prec {f g} : Partrec f → Partrec g → Partrec (unpaired fun a n =>
n.rec (f a) fun y IH => do let i ← IH; g (pair a (pair y i)))
| rfind {f} : Partrec f → Partrec fun a => rfind fun n => (fun m => m = 0) <$> f (pair a n)
namespace Partrec
theorem of_eq {f g : ℕ →. ℕ} (hf : Partrec f) (H : ∀ n, f n = g n) : Partrec g :=
(funext H : f = g) ▸ hf
theorem of_eq_tot {f : ℕ →. ℕ} {g : ℕ → ℕ} (hf : Partrec f) (H : ∀ n, g n ∈ f n) : Partrec g :=
hf.of_eq fun n => eq_some_iff.2 (H n)
theorem of_primrec {f : ℕ → ℕ} (hf : Nat.Primrec f) : Partrec f := by
induction hf with
| zero => exact zero
| succ => exact succ
| left => exact left
| right => exact right
| pair _ _ pf pg =>
refine (pf.pair pg).of_eq_tot fun n => ?_
simp [Seq.seq]
| comp _ _ pf pg =>
refine (pf.comp pg).of_eq_tot fun n => (by simp)
| prec _ _ pf pg =>
refine (pf.prec pg).of_eq_tot fun n => ?_
simp only [unpaired, PFun.coe_val, bind_eq_bind]
induction n.unpair.2 with
| zero => simp
| succ m IH =>
simp only [mem_bind_iff, mem_some_iff]
exact ⟨_, IH, rfl⟩
protected theorem some : Partrec some :=
of_primrec Primrec.id
theorem none : Partrec fun _ => none :=
(of_primrec (Nat.Primrec.const 1)).rfind.of_eq fun _ =>
eq_none_iff.2 fun _ ⟨h, _⟩ => by simp at h
theorem prec' {f g h} (hf : Partrec f) (hg : Partrec g) (hh : Partrec h) :
Partrec fun a => (f a).bind fun n => n.rec (g a)
fun y IH => do {let i ← IH; h (Nat.pair a (Nat.pair y i))} :=
((prec hg hh).comp (pair Partrec.some hf)).of_eq fun a =>
ext fun s => by simp [Seq.seq]
theorem ppred : Partrec fun n => ppred n :=
have : Primrec₂ fun n m => if n = Nat.succ m then 0 else 1 :=
(Primrec.ite
(@PrimrecRel.comp _ _ _ _ _ _ _ _ _ _
Primrec.eq Primrec.fst (_root_.Primrec.succ.comp Primrec.snd))
(_root_.Primrec.const 0) (_root_.Primrec.const 1)).to₂
(of_primrec (Primrec₂.unpaired'.2 this)).rfind.of_eq fun n => by
cases n <;> simp
· exact
eq_none_iff.2 fun a ⟨⟨m, h, _⟩, _⟩ => by
simp [show 0 ≠ m.succ by intro h; injection h] at h
· refine eq_some_iff.2 ?_
simp only [mem_rfind, not_true, IsEmpty.forall_iff, decide_true, mem_some_iff,
false_eq_decide_iff, true_and]
intro m h
simp [ne_of_gt h]
end Partrec
end Nat
/-- Partially recursive partial functions `α → σ` between `Primcodable` types -/
def Partrec {α σ} [Primcodable α] [Primcodable σ] (f : α →. σ) :=
Nat.Partrec fun n => Part.bind (decode (α := α) n) fun a => (f a).map encode
/-- Partially recursive partial functions `α → β → σ` between `Primcodable` types -/
def Partrec₂ {α β σ} [Primcodable α] [Primcodable β] [Primcodable σ] (f : α → β →. σ) :=
Partrec fun p : α × β => f p.1 p.2
/-- Computable functions `α → σ` between `Primcodable` types:
a function is computable if and only if it is partially recursive (as a partial function) -/
def Computable {α σ} [Primcodable α] [Primcodable σ] (f : α → σ) :=
Partrec (f : α →. σ)
/-- Computable functions `α → β → σ` between `Primcodable` types -/
def Computable₂ {α β σ} [Primcodable α] [Primcodable β] [Primcodable σ] (f : α → β → σ) :=
Computable fun p : α × β => f p.1 p.2
theorem Primrec.to_comp {α σ} [Primcodable α] [Primcodable σ] {f : α → σ} (hf : Primrec f) :
Computable f :=
(Nat.Partrec.ppred.comp (Nat.Partrec.of_primrec hf)).of_eq fun n => by
simp; cases decode (α := α) n <;> simp
nonrec theorem Primrec₂.to_comp {α β σ} [Primcodable α] [Primcodable β] [Primcodable σ]
{f : α → β → σ} (hf : Primrec₂ f) : Computable₂ f :=
hf.to_comp
protected theorem Computable.partrec {α σ} [Primcodable α] [Primcodable σ] {f : α → σ}
(hf : Computable f) : Partrec (f : α →. σ) :=
hf
protected theorem Computable₂.partrec₂ {α β σ} [Primcodable α] [Primcodable β] [Primcodable σ]
{f : α → β → σ} (hf : Computable₂ f) : Partrec₂ fun a => (f a : β →. σ) :=
hf
namespace Computable
variable {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variable [Primcodable α] [Primcodable β] [Primcodable γ] [Primcodable σ]
theorem of_eq {f g : α → σ} (hf : Computable f) (H : ∀ n, f n = g n) : Computable g :=
(funext H : f = g) ▸ hf
theorem const (s : σ) : Computable fun _ : α => s :=
(Primrec.const _).to_comp
theorem ofOption {f : α → Option β} (hf : Computable f) : Partrec fun a => (f a : Part β) :=
(Nat.Partrec.ppred.comp hf).of_eq fun n => by
rcases decode (α := α) n with - | a <;> simp
rcases f a with - | b <;> simp
theorem to₂ {f : α × β → σ} (hf : Computable f) : Computable₂ fun a b => f (a, b) :=
hf.of_eq fun ⟨_, _⟩ => rfl
protected theorem id : Computable (@id α) :=
Primrec.id.to_comp
theorem fst : Computable (@Prod.fst α β) :=
Primrec.fst.to_comp
theorem snd : Computable (@Prod.snd α β) :=
Primrec.snd.to_comp
nonrec theorem pair {f : α → β} {g : α → γ} (hf : Computable f) (hg : Computable g) :
Computable fun a => (f a, g a) :=
(hf.pair hg).of_eq fun n => by cases decode (α := α) n <;> simp [Seq.seq]
theorem unpair : Computable Nat.unpair :=
Primrec.unpair.to_comp
theorem succ : Computable Nat.succ :=
Primrec.succ.to_comp
theorem pred : Computable Nat.pred :=
Primrec.pred.to_comp
theorem nat_bodd : Computable Nat.bodd :=
Primrec.nat_bodd.to_comp
theorem nat_div2 : Computable Nat.div2 :=
Primrec.nat_div2.to_comp
theorem sumInl : Computable (@Sum.inl α β) :=
Primrec.sumInl.to_comp
theorem sumInr : Computable (@Sum.inr α β) :=
Primrec.sumInr.to_comp
@[deprecated (since := "2025-02-21")] alias sum_inl := Computable.sumInl
@[deprecated (since := "2025-02-21")] alias sum_inr := Computable.sumInr
theorem list_cons : Computable₂ (@List.cons α) :=
Primrec.list_cons.to_comp
theorem list_reverse : Computable (@List.reverse α) :=
Primrec.list_reverse.to_comp
theorem list_getElem? : Computable₂ ((·[·]? : List α → ℕ → Option α)) :=
Primrec.list_getElem?.to_comp
@[deprecated (since := "2025-02-14")] alias list_get? := list_getElem?
theorem list_append : Computable₂ ((· ++ ·) : List α → List α → List α) :=
Primrec.list_append.to_comp
theorem list_concat : Computable₂ fun l (a : α) => l ++ [a] :=
Primrec.list_concat.to_comp
theorem list_length : Computable (@List.length α) :=
Primrec.list_length.to_comp
theorem vector_cons {n} : Computable₂ (@List.Vector.cons α n) :=
Primrec.vector_cons.to_comp
theorem vector_toList {n} : Computable (@List.Vector.toList α n) :=
Primrec.vector_toList.to_comp
theorem vector_length {n} : Computable (@List.Vector.length α n) :=
Primrec.vector_length.to_comp
theorem vector_head {n} : Computable (@List.Vector.head α n) :=
Primrec.vector_head.to_comp
theorem vector_tail {n} : Computable (@List.Vector.tail α n) :=
Primrec.vector_tail.to_comp
theorem vector_get {n} : Computable₂ (@List.Vector.get α n) :=
Primrec.vector_get.to_comp
theorem vector_ofFn' {n} : Computable (@List.Vector.ofFn α n) :=
Primrec.vector_ofFn'.to_comp
theorem fin_app {n} : Computable₂ (@id (Fin n → σ)) :=
Primrec.fin_app.to_comp
protected theorem encode : Computable (@encode α _) :=
Primrec.encode.to_comp
protected theorem decode : Computable (decode (α := α)) :=
Primrec.decode.to_comp
protected theorem ofNat (α) [Denumerable α] : Computable (ofNat α) :=
(Primrec.ofNat _).to_comp
theorem encode_iff {f : α → σ} : (Computable fun a => encode (f a)) ↔ Computable f :=
Iff.rfl
theorem option_some : Computable (@Option.some α) :=
Primrec.option_some.to_comp
end Computable
namespace Partrec
variable {α : Type*} {β : Type*} {σ : Type*} [Primcodable α] [Primcodable β] [Primcodable σ]
open Computable
theorem of_eq {f g : α →. σ} (hf : Partrec f) (H : ∀ n, f n = g n) : Partrec g :=
(funext H : f = g) ▸ hf
theorem of_eq_tot {f : α →. σ} {g : α → σ} (hf : Partrec f) (H : ∀ n, g n ∈ f n) : Computable g :=
hf.of_eq fun a => eq_some_iff.2 (H a)
theorem none : Partrec fun _ : α => @Part.none σ :=
Nat.Partrec.none.of_eq fun n => by cases decode (α := α) n <;> simp
protected theorem some : Partrec (@Part.some α) :=
Computable.id
theorem _root_.Decidable.Partrec.const' (s : Part σ) [Decidable s.Dom] : Partrec fun _ : α => s :=
(Computable.ofOption (const (toOption s))).of_eq fun _ => of_toOption s
theorem const' (s : Part σ) : Partrec fun _ : α => s :=
haveI := Classical.dec s.Dom
Decidable.Partrec.const' s
protected theorem bind {f : α →. β} {g : α → β →. σ} (hf : Partrec f) (hg : Partrec₂ g) :
Partrec fun a => (f a).bind (g a) :=
(hg.comp (Nat.Partrec.some.pair hf)).of_eq fun n => by
simp [Seq.seq]; rcases e : decode (α := α) n with - | a <;> simp [e, encodek]
theorem map {f : α →. β} {g : α → β → σ} (hf : Partrec f) (hg : Computable₂ g) :
Partrec fun a => (f a).map (g a) := by
simpa [bind_some_eq_map] using Partrec.bind (g := fun a x => some (g a x)) hf hg
theorem to₂ {f : α × β →. σ} (hf : Partrec f) : Partrec₂ fun a b => f (a, b) :=
hf.of_eq fun ⟨_, _⟩ => rfl
theorem nat_rec {f : α → ℕ} {g : α →. σ} {h : α → ℕ × σ →. σ} (hf : Computable f) (hg : Partrec g)
(hh : Partrec₂ h) : Partrec fun a => (f a).rec (g a) fun y IH => IH.bind fun i => h a (y, i) :=
(Nat.Partrec.prec' hf hg hh).of_eq fun n => by
rcases e : decode (α := α) n with - | a <;> simp [e]
induction' f a with m IH <;> simp
rw [IH, Part.bind_map]
congr; funext s
simp [encodek]
nonrec theorem comp {f : β →. σ} {g : α → β} (hf : Partrec f) (hg : Computable g) :
Partrec fun a => f (g a) :=
(hf.comp hg).of_eq fun n => by simp; rcases e : decode (α := α) n with - | a <;> simp [e, encodek]
theorem nat_iff {f : ℕ →. ℕ} : Partrec f ↔ Nat.Partrec f := by simp [Partrec, map_id']
theorem map_encode_iff {f : α →. σ} : (Partrec fun a => (f a).map encode) ↔ Partrec f :=
Iff.rfl
end Partrec
namespace Partrec₂
variable {α : Type*} {β : Type*} {γ : Type*} {δ : Type*} {σ : Type*}
variable [Primcodable α] [Primcodable β] [Primcodable γ] [Primcodable δ] [Primcodable σ]
theorem unpaired {f : ℕ → ℕ →. α} : Partrec (Nat.unpaired f) ↔ Partrec₂ f :=
⟨fun h => by simpa using Partrec.comp (g := fun p : ℕ × ℕ => (p.1, p.2)) h Primrec₂.pair.to_comp,
fun h => h.comp Primrec.unpair.to_comp⟩
theorem unpaired' {f : ℕ → ℕ →. ℕ} : Nat.Partrec (Nat.unpaired f) ↔ Partrec₂ f :=
Partrec.nat_iff.symm.trans unpaired
nonrec theorem comp {f : β → γ →. σ} {g : α → β} {h : α → γ} (hf : Partrec₂ f) (hg : Computable g)
(hh : Computable h) : Partrec fun a => f (g a) (h a) :=
hf.comp (hg.pair hh)
theorem comp₂ {f : γ → δ →. σ} {g : α → β → γ} {h : α → β → δ} (hf : Partrec₂ f)
(hg : Computable₂ g) (hh : Computable₂ h) : Partrec₂ fun a b => f (g a b) (h a b) :=
hf.comp hg hh
end Partrec₂
namespace Computable
variable {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variable [Primcodable α] [Primcodable β] [Primcodable γ] [Primcodable σ]
nonrec theorem comp {f : β → σ} {g : α → β} (hf : Computable f) (hg : Computable g) :
Computable fun a => f (g a) :=
hf.comp hg
theorem comp₂ {f : γ → σ} {g : α → β → γ} (hf : Computable f) (hg : Computable₂ g) :
Computable₂ fun a b => f (g a b) :=
hf.comp hg
end Computable
namespace Computable₂
variable {α : Type*} {β : Type*} {γ : Type*} {δ : Type*} {σ : Type*}
variable [Primcodable α] [Primcodable β] [Primcodable γ] [Primcodable δ] [Primcodable σ]
theorem mk {f : α → β → σ} (hf : Computable fun p : α × β => f p.1 p.2) : Computable₂ f := hf
nonrec theorem comp {f : β → γ → σ} {g : α → β} {h : α → γ} (hf : Computable₂ f)
(hg : Computable g) (hh : Computable h) : Computable fun a => f (g a) (h a) :=
hf.comp (hg.pair hh)
theorem comp₂ {f : γ → δ → σ} {g : α → β → γ} {h : α → β → δ} (hf : Computable₂ f)
(hg : Computable₂ g) (hh : Computable₂ h) : Computable₂ fun a b => f (g a b) (h a b) :=
hf.comp hg hh
end Computable₂
namespace Partrec
variable {α : Type*} {σ : Type*} [Primcodable α] [Primcodable σ]
open Computable
theorem rfind {p : α → ℕ →. Bool} (hp : Partrec₂ p) : Partrec fun a => Nat.rfind (p a) :=
(Nat.Partrec.rfind <|
hp.map ((Primrec.dom_bool fun b => cond b 0 1).comp Primrec.snd).to₂.to_comp).of_eq
fun n => by
rcases e : decode (α := α) n with - | a <;> simp [e, Nat.rfind_zero_none, map_id']
congr; funext n
simp only [map_map, Function.comp]
refine map_id' (fun b => ?_) _
cases b <;> rfl
theorem rfindOpt {f : α → ℕ → Option σ} (hf : Computable₂ f) :
Partrec fun a => Nat.rfindOpt (f a) :=
(rfind (Primrec.option_isSome.to_comp.comp hf).partrec.to₂).bind (ofOption hf)
theorem nat_casesOn_right {f : α → ℕ} {g : α → σ} {h : α → ℕ →. σ} (hf : Computable f)
(hg : Computable g) (hh : Partrec₂ h) : Partrec fun a => (f a).casesOn (some (g a)) (h a) :=
(nat_rec hf hg (hh.comp fst (pred.comp <| hf.comp fst)).to₂).of_eq fun a => by
simp only [PFun.coe_val, Nat.pred_eq_sub_one]; rcases f a with - | n <;> simp
refine ext fun b => ⟨fun H => ?_, fun H => ?_⟩
· rcases mem_bind_iff.1 H with ⟨c, _, h₂⟩
exact h₂
· have : ∀ m, (Nat.rec (motive := fun _ => Part σ)
(Part.some (g a)) (fun y IH => IH.bind fun _ => h a n) m).Dom := by
intro m
induction m <;> simp [*, H.fst]
exact ⟨⟨this n, H.fst⟩, H.snd⟩
theorem bind_decode₂_iff {f : α →. σ} :
Partrec f ↔ Nat.Partrec fun n => Part.bind (decode₂ α n) fun a => (f a).map encode :=
⟨fun hf =>
nat_iff.1 <|
(Computable.ofOption Primrec.decode₂.to_comp).bind <|
(map hf (Computable.encode.comp snd).to₂).comp snd,
fun h =>
map_encode_iff.1 <| by simpa [encodek₂] using (nat_iff.2 h).comp (@Computable.encode α _)⟩
theorem vector_mOfFn :
∀ {n} {f : Fin n → α →. σ},
(∀ i, Partrec (f i)) → Partrec fun a : α => Vector.mOfFn fun i => f i a
| 0, _, _ => const _
| n + 1, f, hf => by
simp only [Vector.mOfFn, Nat.add_eq, Nat.add_zero, pure_eq_some, bind_eq_bind]
exact
(hf 0).bind
(Partrec.bind ((vector_mOfFn fun i => hf i.succ).comp fst)
(Primrec.vector_cons.to_comp.comp (snd.comp fst) snd))
end Partrec
@[simp]
theorem Vector.mOfFn_part_some {α n} :
∀ f : Fin n → α,
(List.Vector.mOfFn fun i => Part.some (f i)) = Part.some (List.Vector.ofFn f) :=
Vector.mOfFn_pure
namespace Computable
variable {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variable [Primcodable α] [Primcodable β] [Primcodable γ] [Primcodable σ]
theorem option_some_iff {f : α → σ} : (Computable fun a => Option.some (f a)) ↔ Computable f :=
⟨fun h => encode_iff.1 <| Primrec.pred.to_comp.comp <| encode_iff.2 h, option_some.comp⟩
theorem bind_decode_iff {f : α → β → Option σ} :
(Computable₂ fun a n => (decode (α := β) n).bind (f a)) ↔ Computable₂ f :=
⟨fun hf =>
Nat.Partrec.of_eq
(((Partrec.nat_iff.2
(Nat.Partrec.ppred.comp <| Nat.Partrec.of_primrec <| Primcodable.prim (α := β))).comp
snd).bind
(Computable.comp hf fst).to₂.partrec₂)
fun n => by
simp only [decode_prod_val, decode_nat, Option.map_some', PFun.coe_val, bind_eq_bind,
bind_some, Part.map_bind, map_some]
cases decode (α := α) n.unpair.1 <;> simp
cases decode (α := β) n.unpair.2 <;> simp,
fun hf => by
have :
Partrec fun a : α × ℕ =>
(encode (decode (α := β) a.2)).casesOn (some Option.none)
fun n => Part.map (f a.1) (decode (α := β) n) :=
Partrec.nat_casesOn_right
(h := fun (a : α × ℕ) (n : ℕ) ↦ map (fun b ↦ f a.1 b) (Part.ofOption (decode n)))
(Primrec.encdec.to_comp.comp snd) (const Option.none)
((ofOption (Computable.decode.comp snd)).map (hf.comp (fst.comp <| fst.comp fst) snd).to₂)
refine this.of_eq fun a => ?_
simp; cases decode (α := β) a.2 <;> simp [encodek]⟩
theorem map_decode_iff {f : α → β → σ} :
(Computable₂ fun a n => (decode (α := β) n).map (f a)) ↔ Computable₂ f := by
convert (bind_decode_iff (f := fun a => Option.some ∘ f a)).trans option_some_iff
apply Option.map_eq_bind
theorem nat_rec {f : α → ℕ} {g : α → σ} {h : α → ℕ × σ → σ} (hf : Computable f) (hg : Computable g)
(hh : Computable₂ h) :
Computable fun a => Nat.rec (motive := fun _ => σ) (g a) (fun y IH => h a (y, IH)) (f a) :=
(Partrec.nat_rec hf hg hh.partrec₂).of_eq fun a => by simp; induction f a <;> simp [*]
theorem nat_casesOn {f : α → ℕ} {g : α → σ} {h : α → ℕ → σ} (hf : Computable f) (hg : Computable g)
(hh : Computable₂ h) :
Computable fun a => Nat.casesOn (motive := fun _ => σ) (f a) (g a) (h a) :=
nat_rec hf hg (hh.comp fst <| fst.comp snd).to₂
theorem cond {c : α → Bool} {f : α → σ} {g : α → σ} (hc : Computable c) (hf : Computable f)
(hg : Computable g) : Computable fun a => cond (c a) (f a) (g a) :=
(nat_casesOn (encode_iff.2 hc) hg (hf.comp fst).to₂).of_eq fun a => by cases c a <;> rfl
theorem option_casesOn {o : α → Option β} {f : α → σ} {g : α → β → σ} (ho : Computable o)
(hf : Computable f) (hg : Computable₂ g) :
@Computable _ σ _ _ fun a => Option.casesOn (o a) (f a) (g a) :=
option_some_iff.1 <|
(nat_casesOn (encode_iff.2 ho) (option_some_iff.2 hf) (map_decode_iff.2 hg)).of_eq fun a => by
cases o a <;> simp [encodek]
theorem option_bind {f : α → Option β} {g : α → β → Option σ} (hf : Computable f)
(hg : Computable₂ g) : Computable fun a => (f a).bind (g a) :=
(option_casesOn hf (const Option.none) hg).of_eq fun a => by cases f a <;> rfl
theorem option_map {f : α → Option β} {g : α → β → σ} (hf : Computable f) (hg : Computable₂ g) :
Computable fun a => (f a).map (g a) := by
convert option_bind hf (option_some.comp₂ hg)
apply Option.map_eq_bind
theorem option_getD {f : α → Option β} {g : α → β} (hf : Computable f) (hg : Computable g) :
Computable fun a => (f a).getD (g a) :=
(Computable.option_casesOn hf hg (show Computable₂ fun _ b => b from Computable.snd)).of_eq
fun a => by cases f a <;> rfl
theorem subtype_mk {f : α → β} {p : β → Prop} [DecidablePred p] {h : ∀ a, p (f a)}
(hp : PrimrecPred p) (hf : Computable f) :
@Computable _ _ _ (Primcodable.subtype hp) fun a => (⟨f a, h a⟩ : Subtype p) :=
hf
theorem sumCasesOn {f : α → β ⊕ γ} {g : α → β → σ} {h : α → γ → σ} (hf : Computable f)
(hg : Computable₂ g) (hh : Computable₂ h) :
@Computable _ σ _ _ fun a => Sum.casesOn (f a) (g a) (h a) :=
option_some_iff.1 <|
(cond (nat_bodd.comp <| encode_iff.2 hf)
(option_map (Computable.decode.comp <| nat_div2.comp <| encode_iff.2 hf) hh)
(option_map (Computable.decode.comp <| nat_div2.comp <| encode_iff.2 hf) hg)).of_eq
fun a => by
rcases f a with b | c <;> simp [Nat.div2_val]
@[deprecated (since := "2025-02-21")] alias sum_casesOn := sumCasesOn
theorem nat_strong_rec (f : α → ℕ → σ) {g : α → List σ → Option σ} (hg : Computable₂ g)
(H : ∀ a n, g a ((List.range n).map (f a)) = Option.some (f a n)) : Computable₂ f :=
suffices Computable₂ fun a n => (List.range n).map (f a) from
option_some_iff.1 <|
(list_getElem?.comp (this.comp fst (succ.comp snd)) snd).to₂.of_eq fun a => by
simp [List.getElem?_range (Nat.lt_succ_self a.2)]
option_some_iff.1 <|
(nat_rec snd (const (Option.some []))
(to₂ <|
option_bind (snd.comp snd) <|
to₂ <|
option_map (hg.comp (fst.comp <| fst.comp fst) snd)
(to₂ <| list_concat.comp (snd.comp fst) snd))).of_eq
fun a => by
induction' a.2 with n IH; · rfl
simp [IH, H, List.range_succ]
theorem list_ofFn :
∀ {n} {f : Fin n → α → σ},
(∀ i, Computable (f i)) → Computable fun a => List.ofFn fun i => f i a
| 0, _, _ => by
simp only [List.ofFn_zero]
exact const []
| n + 1, f, hf => by
simp only [List.ofFn_succ]
exact list_cons.comp (hf 0) (list_ofFn fun i => hf i.succ)
theorem vector_ofFn {n} {f : Fin n → α → σ} (hf : ∀ i, Computable (f i)) :
Computable fun a => List.Vector.ofFn fun i => f i a :=
(Partrec.vector_mOfFn hf).of_eq fun a => by simp
end Computable
namespace Partrec
variable {α : Type*} {β : Type*} {γ : Type*} {σ : Type*}
variable [Primcodable α] [Primcodable β] [Primcodable γ] [Primcodable σ]
open Computable
theorem option_some_iff {f : α →. σ} : (Partrec fun a => (f a).map Option.some) ↔ Partrec f :=
⟨fun h => (Nat.Partrec.ppred.comp h).of_eq fun n => by simp [Part.bind_assoc, bind_some_eq_map],
fun hf => hf.map (option_some.comp snd).to₂⟩
theorem optionCasesOn_right {o : α → Option β} {f : α → σ} {g : α → β →. σ} (ho : Computable o)
(hf : Computable f) (hg : Partrec₂ g) :
@Partrec _ σ _ _ fun a => Option.casesOn (o a) (Part.some (f a)) (g a) :=
have :
Partrec fun a : α =>
Nat.casesOn (encode (o a)) (Part.some (f a)) (fun n => Part.bind (decode (α := β) n) (g a)) :=
nat_casesOn_right (h := fun a n ↦ Part.bind (ofOption (decode n)) fun b ↦ g a b)
(encode_iff.2 ho) hf.partrec <|
((@Computable.decode β _).comp snd).ofOption.bind (hg.comp (fst.comp fst) snd).to₂
this.of_eq fun a => by rcases o a with - | b <;> simp [encodek]
@[deprecated (since := "2025-02-21")] alias option_casesOn_right := optionCasesOn_right
|
theorem sumCasesOn_right {f : α → β ⊕ γ} {g : α → β → σ} {h : α → γ →. σ} (hf : Computable f)
(hg : Computable₂ g) (hh : Partrec₂ h) :
@Partrec _ σ _ _ fun a => Sum.casesOn (f a) (fun b => Part.some (g a b)) (h a) :=
| Mathlib/Computability/Partrec.lean | 694 | 697 |
/-
Copyright (c) 2021 Bryan Gin-ge Chen. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Adam Topaz, Bryan Gin-ge Chen, Yaël Dillies
-/
import Mathlib.Order.BooleanAlgebra
import Mathlib.Logic.Equiv.Basic
/-!
# Symmetric difference and bi-implication
This file defines the symmetric difference and bi-implication operators in (co-)Heyting algebras.
## Examples
Some examples are
* The symmetric difference of two sets is the set of elements that are in either but not both.
* The symmetric difference on propositions is `Xor'`.
* The symmetric difference on `Bool` is `Bool.xor`.
* The equivalence of propositions. Two propositions are equivalent if they imply each other.
* The symmetric difference translates to addition when considering a Boolean algebra as a Boolean
ring.
## Main declarations
* `symmDiff`: The symmetric difference operator, defined as `(a \ b) ⊔ (b \ a)`
* `bihimp`: The bi-implication operator, defined as `(b ⇨ a) ⊓ (a ⇨ b)`
In generalized Boolean algebras, the symmetric difference operator is:
* `symmDiff_comm`: commutative, and
* `symmDiff_assoc`: associative.
## Notations
* `a ∆ b`: `symmDiff a b`
* `a ⇔ b`: `bihimp a b`
## References
The proof of associativity follows the note "Associativity of the Symmetric Difference of Sets: A
Proof from the Book" by John McCuan:
* <https://people.math.gatech.edu/~mccuan/courses/4317/symmetricdifference.pdf>
## Tags
boolean ring, generalized boolean algebra, boolean algebra, symmetric difference, bi-implication,
Heyting
-/
assert_not_exists RelIso
open Function OrderDual
variable {ι α β : Type*} {π : ι → Type*}
/-- The symmetric difference operator on a type with `⊔` and `\` is `(A \ B) ⊔ (B \ A)`. -/
def symmDiff [Max α] [SDiff α] (a b : α) : α :=
a \ b ⊔ b \ a
/-- The Heyting bi-implication is `(b ⇨ a) ⊓ (a ⇨ b)`. This generalizes equivalence of
propositions. -/
def bihimp [Min α] [HImp α] (a b : α) : α :=
(b ⇨ a) ⊓ (a ⇨ b)
/-- Notation for symmDiff -/
scoped[symmDiff] infixl:100 " ∆ " => symmDiff
/-- Notation for bihimp -/
scoped[symmDiff] infixl:100 " ⇔ " => bihimp
open scoped symmDiff
theorem symmDiff_def [Max α] [SDiff α] (a b : α) : a ∆ b = a \ b ⊔ b \ a :=
rfl
theorem bihimp_def [Min α] [HImp α] (a b : α) : a ⇔ b = (b ⇨ a) ⊓ (a ⇨ b) :=
rfl
theorem symmDiff_eq_Xor' (p q : Prop) : p ∆ q = Xor' p q :=
rfl
@[simp]
theorem bihimp_iff_iff {p q : Prop} : p ⇔ q ↔ (p ↔ q) :=
iff_iff_implies_and_implies.symm.trans Iff.comm
@[simp]
theorem Bool.symmDiff_eq_xor : ∀ p q : Bool, p ∆ q = xor p q := by decide
section GeneralizedCoheytingAlgebra
variable [GeneralizedCoheytingAlgebra α] (a b c : α)
@[simp]
theorem toDual_symmDiff : toDual (a ∆ b) = toDual a ⇔ toDual b :=
rfl
@[simp]
theorem ofDual_bihimp (a b : αᵒᵈ) : ofDual (a ⇔ b) = ofDual a ∆ ofDual b :=
rfl
theorem symmDiff_comm : a ∆ b = b ∆ a := by simp only [symmDiff, sup_comm]
instance symmDiff_isCommutative : Std.Commutative (α := α) (· ∆ ·) :=
⟨symmDiff_comm⟩
@[simp]
theorem symmDiff_self : a ∆ a = ⊥ := by rw [symmDiff, sup_idem, sdiff_self]
@[simp]
theorem symmDiff_bot : a ∆ ⊥ = a := by rw [symmDiff, sdiff_bot, bot_sdiff, sup_bot_eq]
@[simp]
theorem bot_symmDiff : ⊥ ∆ a = a := by rw [symmDiff_comm, symmDiff_bot]
@[simp]
theorem symmDiff_eq_bot {a b : α} : a ∆ b = ⊥ ↔ a = b := by
simp_rw [symmDiff, sup_eq_bot_iff, sdiff_eq_bot_iff, le_antisymm_iff]
theorem symmDiff_of_le {a b : α} (h : a ≤ b) : a ∆ b = b \ a := by
rw [symmDiff, sdiff_eq_bot_iff.2 h, bot_sup_eq]
theorem symmDiff_of_ge {a b : α} (h : b ≤ a) : a ∆ b = a \ b := by
rw [symmDiff, sdiff_eq_bot_iff.2 h, sup_bot_eq]
theorem symmDiff_le {a b c : α} (ha : a ≤ b ⊔ c) (hb : b ≤ a ⊔ c) : a ∆ b ≤ c :=
sup_le (sdiff_le_iff.2 ha) <| sdiff_le_iff.2 hb
theorem symmDiff_le_iff {a b c : α} : a ∆ b ≤ c ↔ a ≤ b ⊔ c ∧ b ≤ a ⊔ c := by
simp_rw [symmDiff, sup_le_iff, sdiff_le_iff]
@[simp]
theorem symmDiff_le_sup {a b : α} : a ∆ b ≤ a ⊔ b :=
sup_le_sup sdiff_le sdiff_le
theorem symmDiff_eq_sup_sdiff_inf : a ∆ b = (a ⊔ b) \ (a ⊓ b) := by simp [sup_sdiff, symmDiff]
theorem Disjoint.symmDiff_eq_sup {a b : α} (h : Disjoint a b) : a ∆ b = a ⊔ b := by
rw [symmDiff, h.sdiff_eq_left, h.sdiff_eq_right]
theorem symmDiff_sdiff : a ∆ b \ c = a \ (b ⊔ c) ⊔ b \ (a ⊔ c) := by
rw [symmDiff, sup_sdiff_distrib, sdiff_sdiff_left, sdiff_sdiff_left]
@[simp]
theorem symmDiff_sdiff_inf : a ∆ b \ (a ⊓ b) = a ∆ b := by
rw [symmDiff_sdiff]
simp [symmDiff]
@[simp]
theorem symmDiff_sdiff_eq_sup : a ∆ (b \ a) = a ⊔ b := by
rw [symmDiff, sdiff_idem]
exact
le_antisymm (sup_le_sup sdiff_le sdiff_le)
(sup_le le_sdiff_sup <| le_sdiff_sup.trans <| sup_le le_sup_right le_sdiff_sup)
@[simp]
| theorem sdiff_symmDiff_eq_sup : (a \ b) ∆ b = a ⊔ b := by
| Mathlib/Order/SymmDiff.lean | 158 | 158 |
/-
Copyright (c) 2021 Kalle Kytölä. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kalle Kytölä
-/
import Mathlib.MeasureTheory.Integral.Bochner.ContinuousLinearMap
import Mathlib.MeasureTheory.Measure.HasOuterApproxClosed
import Mathlib.MeasureTheory.Measure.Prod
import Mathlib.Topology.Algebra.Module.WeakDual
/-!
# Finite measures
This file defines the type of finite measures on a given measurable space. When the underlying
space has a topology and the measurable space structure (sigma algebra) is finer than the Borel
sigma algebra, then the type of finite measures is equipped with the topology of weak convergence
of measures. The topology of weak convergence is the coarsest topology w.r.t. which
for every bounded continuous `ℝ≥0`-valued function `f`, the integration of `f` against the
measure is continuous.
## Main definitions
The main definitions are
* `MeasureTheory.FiniteMeasure Ω`: The type of finite measures on `Ω` with the topology of weak
convergence of measures.
* `MeasureTheory.FiniteMeasure.toWeakDualBCNN : FiniteMeasure Ω → (WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0))`:
Interpret a finite measure as a continuous linear functional on the space of
bounded continuous nonnegative functions on `Ω`. This is used for the definition of the
topology of weak convergence.
* `MeasureTheory.FiniteMeasure.map`: The push-forward `f* μ` of a finite measure `μ` on `Ω`
along a measurable function `f : Ω → Ω'`.
* `MeasureTheory.FiniteMeasure.mapCLM`: The push-forward along a given continuous `f : Ω → Ω'`
as a continuous linear map `f* : FiniteMeasure Ω →L[ℝ≥0] FiniteMeasure Ω'`.
## Main results
* Finite measures `μ` on `Ω` give rise to continuous linear functionals on the space of
bounded continuous nonnegative functions on `Ω` via integration:
`MeasureTheory.FiniteMeasure.toWeakDualBCNN : FiniteMeasure Ω → (WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0))`
* `MeasureTheory.FiniteMeasure.tendsto_iff_forall_integral_tendsto`: Convergence of finite
measures is characterized by the convergence of integrals of all bounded continuous functions.
This shows that the chosen definition of topology coincides with the common textbook definition
of weak convergence of measures. A similar characterization by the convergence of integrals (in
the `MeasureTheory.lintegral` sense) of all bounded continuous nonnegative functions is
`MeasureTheory.FiniteMeasure.tendsto_iff_forall_lintegral_tendsto`.
* `MeasureTheory.FiniteMeasure.continuous_map`: For a continuous function `f : Ω → Ω'`, the
push-forward of finite measures `f* : FiniteMeasure Ω → FiniteMeasure Ω'` is continuous.
* `MeasureTheory.FiniteMeasure.t2Space`: The topology of weak convergence of finite Borel measures
is Hausdorff on spaces where indicators of closed sets have continuous decreasing approximating
sequences (in particular on any pseudo-metrizable spaces).
## Implementation notes
The topology of weak convergence of finite Borel measures is defined using a mapping from
`MeasureTheory.FiniteMeasure Ω` to `WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0)`, inheriting the topology from the
latter.
The implementation of `MeasureTheory.FiniteMeasure Ω` and is directly as a subtype of
`MeasureTheory.Measure Ω`, and the coercion to a function is the composition `ENNReal.toNNReal`
and the coercion to function of `MeasureTheory.Measure Ω`. Another alternative would have been to
use a bijection with `MeasureTheory.VectorMeasure Ω ℝ≥0` as an intermediate step. Some
considerations:
* Potential advantages of using the `NNReal`-valued vector measure alternative:
* The coercion to function would avoid need to compose with `ENNReal.toNNReal`, the
`NNReal`-valued API could be more directly available.
* Potential drawbacks of the vector measure alternative:
* The coercion to function would lose monotonicity, as non-measurable sets would be defined to
have measure 0.
* No integration theory directly. E.g., the topology definition requires
`MeasureTheory.lintegral` w.r.t. a coercion to `MeasureTheory.Measure Ω` in any case.
## References
* [Billingsley, *Convergence of probability measures*][billingsley1999]
## Tags
weak convergence of measures, finite measure
-/
noncomputable section
open BoundedContinuousFunction Filter MeasureTheory Set Topology
open scoped ENNReal NNReal
namespace MeasureTheory
namespace FiniteMeasure
section FiniteMeasure
/-! ### Finite measures
In this section we define the `Type` of `MeasureTheory.FiniteMeasure Ω`, when `Ω` is a measurable
space. Finite measures on `Ω` are a module over `ℝ≥0`.
If `Ω` is moreover a topological space and the sigma algebra on `Ω` is finer than the Borel sigma
algebra (i.e. `[OpensMeasurableSpace Ω]`), then `MeasureTheory.FiniteMeasure Ω` is equipped with
the topology of weak convergence of measures. This is implemented by defining a pairing of finite
measures `μ` on `Ω` with continuous bounded nonnegative functions `f : Ω →ᵇ ℝ≥0` via integration,
and using the associated weak topology (essentially the weak-star topology on the dual of
`Ω →ᵇ ℝ≥0`).
-/
variable {Ω : Type*} [MeasurableSpace Ω]
/-- Finite measures are defined as the subtype of measures that have the property of being finite
measures (i.e., their total mass is finite). -/
def _root_.MeasureTheory.FiniteMeasure (Ω : Type*) [MeasurableSpace Ω] : Type _ :=
{ μ : Measure Ω // IsFiniteMeasure μ }
/-- Coercion from `MeasureTheory.FiniteMeasure Ω` to `MeasureTheory.Measure Ω`. -/
@[coe]
def toMeasure : FiniteMeasure Ω → Measure Ω := Subtype.val
/-- A finite measure can be interpreted as a measure. -/
instance instCoe : Coe (FiniteMeasure Ω) (MeasureTheory.Measure Ω) := { coe := toMeasure }
instance isFiniteMeasure (μ : FiniteMeasure Ω) : IsFiniteMeasure (μ : Measure Ω) := μ.prop
@[simp]
theorem val_eq_toMeasure (ν : FiniteMeasure Ω) : ν.val = (ν : Measure Ω) := rfl
theorem toMeasure_injective : Function.Injective ((↑) : FiniteMeasure Ω → Measure Ω) :=
Subtype.coe_injective
instance instFunLike : FunLike (FiniteMeasure Ω) (Set Ω) ℝ≥0 where
coe μ s := ((μ : Measure Ω) s).toNNReal
coe_injective' μ ν h := toMeasure_injective <| Measure.ext fun s _ ↦ by
simpa [ENNReal.toNNReal_eq_toNNReal_iff, measure_ne_top] using congr_fun h s
lemma coeFn_def (μ : FiniteMeasure Ω) : μ = fun s ↦ ((μ : Measure Ω) s).toNNReal := rfl
lemma coeFn_mk (μ : Measure Ω) (hμ) :
DFunLike.coe (F := FiniteMeasure Ω) ⟨μ, hμ⟩ = fun s ↦ (μ s).toNNReal := rfl
@[simp, norm_cast]
lemma mk_apply (μ : Measure Ω) (hμ) (s : Set Ω) :
DFunLike.coe (F := FiniteMeasure Ω) ⟨μ, hμ⟩ s = (μ s).toNNReal := rfl
@[simp]
theorem ennreal_coeFn_eq_coeFn_toMeasure (ν : FiniteMeasure Ω) (s : Set Ω) :
(ν s : ℝ≥0∞) = (ν : Measure Ω) s :=
ENNReal.coe_toNNReal (measure_lt_top (↑ν) s).ne
@[simp]
theorem null_iff_toMeasure_null (ν : FiniteMeasure Ω) (s : Set Ω) :
ν s = 0 ↔ (ν : Measure Ω) s = 0 :=
⟨fun h ↦ by rw [← ennreal_coeFn_eq_coeFn_toMeasure, h, ENNReal.coe_zero],
fun h ↦ congrArg ENNReal.toNNReal h⟩
theorem apply_mono (μ : FiniteMeasure Ω) {s₁ s₂ : Set Ω} (h : s₁ ⊆ s₂) : μ s₁ ≤ μ s₂ :=
ENNReal.toNNReal_mono (measure_ne_top _ s₂) ((μ : Measure Ω).mono h)
/-- Continuity from below: the measure of the union of a sequence of (not necessarily measurable)
sets is the limit of the measures of the partial unions. -/
protected lemma tendsto_measure_iUnion_accumulate {ι : Type*} [Preorder ι]
[IsCountablyGenerated (atTop : Filter ι)] {μ : FiniteMeasure Ω} {f : ι → Set Ω} :
Tendsto (fun i ↦ μ (Accumulate f i)) atTop (𝓝 (μ (⋃ i, f i))) := by
simpa [← ennreal_coeFn_eq_coeFn_toMeasure]
using tendsto_measure_iUnion_accumulate (μ := μ.toMeasure) (ι := ι)
/-- The (total) mass of a finite measure `μ` is `μ univ`, i.e., the cast to `NNReal` of
`(μ : measure Ω) univ`. -/
def mass (μ : FiniteMeasure Ω) : ℝ≥0 := μ univ
@[simp] theorem apply_le_mass (μ : FiniteMeasure Ω) (s : Set Ω) : μ s ≤ μ.mass := by
simpa using apply_mono μ (subset_univ s)
@[simp]
theorem ennreal_mass {μ : FiniteMeasure Ω} : (μ.mass : ℝ≥0∞) = (μ : Measure Ω) univ :=
ennreal_coeFn_eq_coeFn_toMeasure μ Set.univ
instance instZero : Zero (FiniteMeasure Ω) where zero := ⟨0, MeasureTheory.isFiniteMeasureZero⟩
@[simp, norm_cast] lemma coeFn_zero : ⇑(0 : FiniteMeasure Ω) = 0 := rfl
@[simp]
theorem zero_mass : (0 : FiniteMeasure Ω).mass = 0 := rfl
@[simp]
theorem mass_zero_iff (μ : FiniteMeasure Ω) : μ.mass = 0 ↔ μ = 0 := by
refine ⟨fun μ_mass => ?_, fun hμ => by simp only [hμ, zero_mass]⟩
apply toMeasure_injective
apply Measure.measure_univ_eq_zero.mp
rwa [← ennreal_mass, ENNReal.coe_eq_zero]
theorem mass_nonzero_iff (μ : FiniteMeasure Ω) : μ.mass ≠ 0 ↔ μ ≠ 0 :=
not_iff_not.mpr <| FiniteMeasure.mass_zero_iff μ
@[ext]
theorem eq_of_forall_toMeasure_apply_eq (μ ν : FiniteMeasure Ω)
(h : ∀ s : Set Ω, MeasurableSet s → (μ : Measure Ω) s = (ν : Measure Ω) s) : μ = ν := by
apply Subtype.ext
ext1 s s_mble
exact h s s_mble
theorem eq_of_forall_apply_eq (μ ν : FiniteMeasure Ω)
(h : ∀ s : Set Ω, MeasurableSet s → μ s = ν s) : μ = ν := by
ext1 s s_mble
simpa [ennreal_coeFn_eq_coeFn_toMeasure] using congr_arg ((↑) : ℝ≥0 → ℝ≥0∞) (h s s_mble)
instance instInhabited : Inhabited (FiniteMeasure Ω) := ⟨0⟩
instance instAdd : Add (FiniteMeasure Ω) where add μ ν := ⟨μ + ν, MeasureTheory.isFiniteMeasureAdd⟩
variable {R : Type*} [SMul R ℝ≥0] [SMul R ℝ≥0∞] [IsScalarTower R ℝ≥0 ℝ≥0∞]
[IsScalarTower R ℝ≥0∞ ℝ≥0∞]
instance instSMul : SMul R (FiniteMeasure Ω) where
smul (c : R) μ := ⟨c • (μ : Measure Ω), MeasureTheory.isFiniteMeasureSMulOfNNRealTower⟩
@[simp, norm_cast]
theorem toMeasure_zero : ((↑) : FiniteMeasure Ω → Measure Ω) 0 = 0 := rfl
@[norm_cast]
theorem toMeasure_add (μ ν : FiniteMeasure Ω) : ↑(μ + ν) = (↑μ + ↑ν : Measure Ω) := rfl
@[simp, norm_cast]
theorem toMeasure_smul (c : R) (μ : FiniteMeasure Ω) : ↑(c • μ) = c • (μ : Measure Ω) :=
rfl
@[simp, norm_cast]
theorem coeFn_add (μ ν : FiniteMeasure Ω) : (⇑(μ + ν) : Set Ω → ℝ≥0) = (⇑μ + ⇑ν : Set Ω → ℝ≥0) := by
funext
simp only [Pi.add_apply, ← ENNReal.coe_inj, ne_eq, ennreal_coeFn_eq_coeFn_toMeasure,
ENNReal.coe_add]
norm_cast
@[simp, norm_cast]
theorem coeFn_smul [IsScalarTower R ℝ≥0 ℝ≥0] (c : R) (μ : FiniteMeasure Ω) :
(⇑(c • μ) : Set Ω → ℝ≥0) = c • (⇑μ : Set Ω → ℝ≥0) := by
funext; simp [← ENNReal.coe_inj, ENNReal.coe_smul]
instance instAddCommMonoid : AddCommMonoid (FiniteMeasure Ω) :=
toMeasure_injective.addCommMonoid _ toMeasure_zero toMeasure_add fun _ _ ↦ toMeasure_smul _ _
/-- Coercion is an `AddMonoidHom`. -/
@[simps]
def toMeasureAddMonoidHom : FiniteMeasure Ω →+ Measure Ω where
toFun := (↑)
map_zero' := toMeasure_zero
map_add' := toMeasure_add
instance {Ω : Type*} [MeasurableSpace Ω] : Module ℝ≥0 (FiniteMeasure Ω) :=
Function.Injective.module _ toMeasureAddMonoidHom toMeasure_injective toMeasure_smul
@[simp]
theorem smul_apply [IsScalarTower R ℝ≥0 ℝ≥0] (c : R) (μ : FiniteMeasure Ω) (s : Set Ω) :
(c • μ) s = c • μ s := by
rw [coeFn_smul, Pi.smul_apply]
/-- Restrict a finite measure μ to a set A. -/
def restrict (μ : FiniteMeasure Ω) (A : Set Ω) : FiniteMeasure Ω where
val := (μ : Measure Ω).restrict A
property := MeasureTheory.isFiniteMeasureRestrict (μ : Measure Ω) A
theorem restrict_measure_eq (μ : FiniteMeasure Ω) (A : Set Ω) :
(μ.restrict A : Measure Ω) = (μ : Measure Ω).restrict A := rfl
theorem restrict_apply_measure (μ : FiniteMeasure Ω) (A : Set Ω) {s : Set Ω}
(s_mble : MeasurableSet s) : (μ.restrict A : Measure Ω) s = (μ : Measure Ω) (s ∩ A) :=
Measure.restrict_apply s_mble
theorem restrict_apply (μ : FiniteMeasure Ω) (A : Set Ω) {s : Set Ω} (s_mble : MeasurableSet s) :
(μ.restrict A) s = μ (s ∩ A) := by
apply congr_arg ENNReal.toNNReal
exact Measure.restrict_apply s_mble
theorem restrict_mass (μ : FiniteMeasure Ω) (A : Set Ω) : (μ.restrict A).mass = μ A := by
simp only [mass, restrict_apply μ A MeasurableSet.univ, univ_inter]
theorem restrict_eq_zero_iff (μ : FiniteMeasure Ω) (A : Set Ω) : μ.restrict A = 0 ↔ μ A = 0 := by
rw [← mass_zero_iff, restrict_mass]
theorem restrict_nonzero_iff (μ : FiniteMeasure Ω) (A : Set Ω) : μ.restrict A ≠ 0 ↔ μ A ≠ 0 := by
rw [← mass_nonzero_iff, restrict_mass]
/-- The type of finite measures is a measurable space when equipped with the Giry monad. -/
instance : MeasurableSpace (FiniteMeasure Ω) := Subtype.instMeasurableSpace
/-- The set of all finite measures is a measurable set in the Giry monad. -/
lemma measurableSet_isFiniteMeasure : MeasurableSet { μ : Measure Ω | IsFiniteMeasure μ } := by
suffices { μ : Measure Ω | IsFiniteMeasure μ } = (fun μ => μ univ) ⁻¹' (Set.Ico 0 ∞) by
rw [this]
exact Measure.measurable_coe MeasurableSet.univ measurableSet_Ico
ext μ
simp only [mem_setOf_eq, mem_iUnion, mem_preimage, mem_Ico, zero_le, true_and, exists_const]
exact isFiniteMeasure_iff μ
/-- The monoidal product is a measurabule function from the product of finite measures over
`α` and `β` into the type of finite measures over `α × β`. -/
theorem measurable_prod {α β : Type*} [MeasurableSpace α] [MeasurableSpace β] :
Measurable (fun (μ : FiniteMeasure α × FiniteMeasure β)
↦ μ.1.toMeasure.prod μ.2.toMeasure) := by
have Heval {u v} (Hu : MeasurableSet u) (Hv : MeasurableSet v):
Measurable fun a : (FiniteMeasure α × FiniteMeasure β) ↦
a.1.toMeasure u * a.2.toMeasure v :=
Measurable.mul
((Measure.measurable_coe Hu).comp (measurable_subtype_coe.comp measurable_fst))
((Measure.measurable_coe Hv).comp (measurable_subtype_coe.comp measurable_snd))
apply Measurable.measure_of_isPiSystem generateFrom_prod.symm isPiSystem_prod _
· simp_rw [← Set.univ_prod_univ, Measure.prod_prod, Heval MeasurableSet.univ MeasurableSet.univ]
simp only [mem_image2, mem_setOf_eq, forall_exists_index, and_imp]
intros _ _ Hu _ Hv Heq
simp_rw [← Heq, Measure.prod_prod, Heval Hu Hv]
variable [TopologicalSpace Ω]
/-- Two finite Borel measures are equal if the integrals of all non-negative bounded continuous
functions with respect to both agree. -/
theorem ext_of_forall_lintegral_eq [HasOuterApproxClosed Ω] [BorelSpace Ω]
{μ ν : FiniteMeasure Ω} (h : ∀ (f : Ω →ᵇ ℝ≥0), ∫⁻ x, f x ∂μ = ∫⁻ x, f x ∂ν) :
μ = ν := by
apply Subtype.ext
change (μ : Measure Ω) = (ν : Measure Ω)
exact ext_of_forall_lintegral_eq_of_IsFiniteMeasure h
/-- Two finite Borel measures are equal if the integrals of all bounded continuous functions with
respect to both agree. -/
theorem ext_of_forall_integral_eq [HasOuterApproxClosed Ω] [BorelSpace Ω]
{μ ν : FiniteMeasure Ω} (h : ∀ (f : Ω →ᵇ ℝ), ∫ x, f x ∂μ = ∫ x, f x ∂ν) :
μ = ν := by
apply ext_of_forall_lintegral_eq
intro f
apply (ENNReal.toReal_eq_toReal_iff' (lintegral_lt_top_of_nnreal μ f).ne
(lintegral_lt_top_of_nnreal ν f).ne).mp
rw [toReal_lintegral_coe_eq_integral f μ, toReal_lintegral_coe_eq_integral f ν]
exact h ⟨⟨fun x => (f x).toReal, Continuous.comp' NNReal.continuous_coe f.continuous⟩,
f.map_bounded'⟩
/-- The pairing of a finite (Borel) measure `μ` with a nonnegative bounded continuous
function is obtained by (Lebesgue) integrating the (test) function against the measure.
This is `MeasureTheory.FiniteMeasure.testAgainstNN`. -/
def testAgainstNN (μ : FiniteMeasure Ω) (f : Ω →ᵇ ℝ≥0) : ℝ≥0 :=
(∫⁻ ω, f ω ∂(μ : Measure Ω)).toNNReal
@[simp]
theorem testAgainstNN_coe_eq {μ : FiniteMeasure Ω} {f : Ω →ᵇ ℝ≥0} :
(μ.testAgainstNN f : ℝ≥0∞) = ∫⁻ ω, f ω ∂(μ : Measure Ω) :=
ENNReal.coe_toNNReal (f.lintegral_lt_top_of_nnreal _).ne
theorem testAgainstNN_const (μ : FiniteMeasure Ω) (c : ℝ≥0) :
μ.testAgainstNN (BoundedContinuousFunction.const Ω c) = c * μ.mass := by
simp [← ENNReal.coe_inj]
theorem testAgainstNN_mono (μ : FiniteMeasure Ω) {f g : Ω →ᵇ ℝ≥0} (f_le_g : (f : Ω → ℝ≥0) ≤ g) :
μ.testAgainstNN f ≤ μ.testAgainstNN g := by
simp only [← ENNReal.coe_le_coe, testAgainstNN_coe_eq]
gcongr
apply f_le_g
@[simp]
theorem testAgainstNN_zero (μ : FiniteMeasure Ω) : μ.testAgainstNN 0 = 0 := by
simpa only [zero_mul] using μ.testAgainstNN_const 0
@[simp]
theorem testAgainstNN_one (μ : FiniteMeasure Ω) : μ.testAgainstNN 1 = μ.mass := by
simp only [testAgainstNN, coe_one, Pi.one_apply, ENNReal.coe_one, lintegral_one]
rfl
@[simp]
theorem zero_testAgainstNN_apply (f : Ω →ᵇ ℝ≥0) : (0 : FiniteMeasure Ω).testAgainstNN f = 0 := by
simp only [testAgainstNN, toMeasure_zero, lintegral_zero_measure, ENNReal.toNNReal_zero]
theorem zero_testAgainstNN : (0 : FiniteMeasure Ω).testAgainstNN = 0 := by
funext
simp only [zero_testAgainstNN_apply, Pi.zero_apply]
@[simp]
theorem smul_testAgainstNN_apply (c : ℝ≥0) (μ : FiniteMeasure Ω) (f : Ω →ᵇ ℝ≥0) :
(c • μ).testAgainstNN f = c • μ.testAgainstNN f := by
simp only [testAgainstNN, toMeasure_smul, smul_eq_mul, ← ENNReal.smul_toNNReal, ENNReal.smul_def,
lintegral_smul_measure]
section weak_convergence
variable [OpensMeasurableSpace Ω]
theorem testAgainstNN_add (μ : FiniteMeasure Ω) (f₁ f₂ : Ω →ᵇ ℝ≥0) :
μ.testAgainstNN (f₁ + f₂) = μ.testAgainstNN f₁ + μ.testAgainstNN f₂ := by
simp only [← ENNReal.coe_inj, BoundedContinuousFunction.coe_add, ENNReal.coe_add, Pi.add_apply,
testAgainstNN_coe_eq]
exact lintegral_add_left (BoundedContinuousFunction.measurable_coe_ennreal_comp _) _
theorem testAgainstNN_smul [IsScalarTower R ℝ≥0 ℝ≥0] [PseudoMetricSpace R] [Zero R]
[IsBoundedSMul R ℝ≥0] (μ : FiniteMeasure Ω) (c : R) (f : Ω →ᵇ ℝ≥0) :
μ.testAgainstNN (c • f) = c • μ.testAgainstNN f := by
simp only [← ENNReal.coe_inj, BoundedContinuousFunction.coe_smul, testAgainstNN_coe_eq,
ENNReal.coe_smul]
simp_rw [← smul_one_smul ℝ≥0∞ c (f _ : ℝ≥0∞), ← smul_one_smul ℝ≥0∞ c (lintegral _ _ : ℝ≥0∞),
smul_eq_mul]
exact lintegral_const_mul (c • (1 : ℝ≥0∞)) f.measurable_coe_ennreal_comp
theorem testAgainstNN_lipschitz_estimate (μ : FiniteMeasure Ω) (f g : Ω →ᵇ ℝ≥0) :
μ.testAgainstNN f ≤ μ.testAgainstNN g + nndist f g * μ.mass := by
simp only [← μ.testAgainstNN_const (nndist f g), ← testAgainstNN_add, ← ENNReal.coe_le_coe,
BoundedContinuousFunction.coe_add, const_apply, ENNReal.coe_add, Pi.add_apply,
coe_nnreal_ennreal_nndist, testAgainstNN_coe_eq]
apply lintegral_mono
have le_dist : ∀ ω, dist (f ω) (g ω) ≤ nndist f g := BoundedContinuousFunction.dist_coe_le_dist
intro ω
have le' : f ω ≤ g ω + nndist f g := by
calc f ω
_ ≤ g ω + nndist (f ω) (g ω) := NNReal.le_add_nndist (f ω) (g ω)
_ ≤ g ω + nndist f g := (add_le_add_iff_left (g ω)).mpr (le_dist ω)
have le : (f ω : ℝ≥0∞) ≤ (g ω : ℝ≥0∞) + nndist f g := by
simpa only [← ENNReal.coe_add] using (by exact_mod_cast le')
rwa [coe_nnreal_ennreal_nndist] at le
theorem testAgainstNN_lipschitz (μ : FiniteMeasure Ω) :
LipschitzWith μ.mass fun f : Ω →ᵇ ℝ≥0 ↦ μ.testAgainstNN f := by
rw [lipschitzWith_iff_dist_le_mul]
intro f₁ f₂
suffices abs (μ.testAgainstNN f₁ - μ.testAgainstNN f₂ : ℝ) ≤ μ.mass * dist f₁ f₂ by
rwa [NNReal.dist_eq]
apply abs_le.mpr
constructor
· have key := μ.testAgainstNN_lipschitz_estimate f₂ f₁
rw [mul_comm] at key
suffices ↑(μ.testAgainstNN f₂) ≤ ↑(μ.testAgainstNN f₁) + ↑μ.mass * dist f₁ f₂ by linarith
simpa [nndist_comm] using NNReal.coe_mono key
· have key := μ.testAgainstNN_lipschitz_estimate f₁ f₂
rw [mul_comm] at key
suffices ↑(μ.testAgainstNN f₁) ≤ ↑(μ.testAgainstNN f₂) + ↑μ.mass * dist f₁ f₂ by linarith
simpa using NNReal.coe_mono key
/-- Finite measures yield elements of the `WeakDual` of bounded continuous nonnegative
functions via `MeasureTheory.FiniteMeasure.testAgainstNN`, i.e., integration. -/
def toWeakDualBCNN (μ : FiniteMeasure Ω) : WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0) where
toFun f := μ.testAgainstNN f
map_add' := testAgainstNN_add μ
map_smul' := testAgainstNN_smul μ
cont := μ.testAgainstNN_lipschitz.continuous
@[simp]
theorem coe_toWeakDualBCNN (μ : FiniteMeasure Ω) : ⇑μ.toWeakDualBCNN = μ.testAgainstNN :=
rfl
@[simp]
theorem toWeakDualBCNN_apply (μ : FiniteMeasure Ω) (f : Ω →ᵇ ℝ≥0) :
μ.toWeakDualBCNN f = (∫⁻ x, f x ∂(μ : Measure Ω)).toNNReal := rfl
/-- The topology of weak convergence on `MeasureTheory.FiniteMeasure Ω` is inherited (induced)
from the weak-* topology on `WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0)` via the function
`MeasureTheory.FiniteMeasure.toWeakDualBCNN`. -/
instance instTopologicalSpace : TopologicalSpace (FiniteMeasure Ω) :=
TopologicalSpace.induced toWeakDualBCNN inferInstance
theorem toWeakDualBCNN_continuous : Continuous (@toWeakDualBCNN Ω _ _ _) :=
continuous_induced_dom
/-- Integration of (nonnegative bounded continuous) test functions against finite Borel measures
depends continuously on the measure. -/
theorem continuous_testAgainstNN_eval (f : Ω →ᵇ ℝ≥0) :
Continuous fun μ : FiniteMeasure Ω ↦ μ.testAgainstNN f := by
show Continuous ((fun φ : WeakDual ℝ≥0 (Ω →ᵇ ℝ≥0) ↦ φ f) ∘ toWeakDualBCNN)
refine Continuous.comp ?_ (toWeakDualBCNN_continuous (Ω := Ω))
exact WeakBilin.eval_continuous _ _
/-- The total mass of a finite measure depends continuously on the measure. -/
theorem continuous_mass : Continuous fun μ : FiniteMeasure Ω ↦ μ.mass := by
simp_rw [← testAgainstNN_one]; exact continuous_testAgainstNN_eval 1
/-- Convergence of finite measures implies the convergence of their total masses. -/
theorem _root_.Filter.Tendsto.mass {γ : Type*} {F : Filter γ} {μs : γ → FiniteMeasure Ω}
{μ : FiniteMeasure Ω} (h : Tendsto μs F (𝓝 μ)) : Tendsto (fun i ↦ (μs i).mass) F (𝓝 μ.mass) :=
(continuous_mass.tendsto μ).comp h
theorem tendsto_iff_weakDual_tendsto {γ : Type*} {F : Filter γ} {μs : γ → FiniteMeasure Ω}
{μ : FiniteMeasure Ω} :
Tendsto μs F (𝓝 μ) ↔ Tendsto (fun i ↦ (μs i).toWeakDualBCNN) F (𝓝 μ.toWeakDualBCNN) :=
IsInducing.tendsto_nhds_iff ⟨rfl⟩
|
theorem tendsto_iff_forall_toWeakDualBCNN_tendsto {γ : Type*} {F : Filter γ}
{μs : γ → FiniteMeasure Ω} {μ : FiniteMeasure Ω} :
Tendsto μs F (𝓝 μ) ↔
∀ f : Ω →ᵇ ℝ≥0, Tendsto (fun i ↦ (μs i).toWeakDualBCNN f) F (𝓝 (μ.toWeakDualBCNN f)) := by
| Mathlib/MeasureTheory/Measure/FiniteMeasure.lean | 477 | 481 |
/-
Copyright (c) 2023 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov, Yaël Dillies
-/
import Mathlib.Analysis.Convex.Topology
import Mathlib.Analysis.Complex.ReImTopology
/-!
# Theorems about convexity on the complex plane
We show that the open and closed half-spaces in ℂ given by an inequality on either the real or
imaginary part are all convex over ℝ. We also prove some results on star-convexity for the
slit plane.
-/
open Set
| open scoped ComplexOrder
namespace Complex
/-- A version of `convexHull_prod` for `Set.reProdIm`. -/
lemma convexHull_reProdIm (s t : Set ℝ) :
convexHull ℝ (s ×ℂ t) = convexHull ℝ s ×ℂ convexHull ℝ t :=
calc
| Mathlib/Analysis/Complex/Convex.lean | 18 | 25 |
/-
Copyright (c) 2021 Rémy Degenne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Rémy Degenne
-/
import Mathlib.Probability.Independence.Basic
import Mathlib.Probability.Independence.Conditional
/-!
# Kolmogorov's 0-1 law
Let `s : ι → MeasurableSpace Ω` be an independent sequence of sub-σ-algebras. Then any set which
is measurable with respect to the tail σ-algebra `limsup s atTop` has probability 0 or 1.
## Main statements
* `measure_zero_or_one_of_measurableSet_limsup_atTop`: Kolmogorov's 0-1 law. Any set which is
measurable with respect to the tail σ-algebra `limsup s atTop` of an independent sequence of
σ-algebras `s` has probability 0 or 1.
-/
open MeasureTheory MeasurableSpace
open scoped MeasureTheory ENNReal
namespace ProbabilityTheory
variable {α Ω ι : Type*} {_mα : MeasurableSpace α} {s : ι → MeasurableSpace Ω}
{m m0 : MeasurableSpace Ω} {κ : Kernel α Ω} {μα : Measure α} {μ : Measure Ω}
theorem Kernel.measure_eq_zero_or_one_or_top_of_indepSet_self {t : Set Ω}
(h_indep : Kernel.IndepSet t t κ μα) :
| ∀ᵐ a ∂μα, κ a t = 0 ∨ κ a t = 1 ∨ κ a t = ∞ := by
specialize h_indep t t (measurableSet_generateFrom (Set.mem_singleton t))
(measurableSet_generateFrom (Set.mem_singleton t))
filter_upwards [h_indep] with a ha
by_cases h0 : κ a t = 0
· exact Or.inl h0
by_cases h_top : κ a t = ∞
· exact Or.inr (Or.inr h_top)
rw [← one_mul (κ a (t ∩ t)), Set.inter_self, ENNReal.mul_left_inj h0 h_top] at ha
exact Or.inr (Or.inl ha.symm)
theorem measure_eq_zero_or_one_or_top_of_indepSet_self {t : Set Ω}
| Mathlib/Probability/Independence/ZeroOne.lean | 33 | 44 |
/-
Copyright (c) 2021 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel
-/
import Mathlib.MeasureTheory.Measure.Trim
import Mathlib.MeasureTheory.MeasurableSpace.CountablyGenerated
/-!
# Almost everywhere measurable functions
A function is almost everywhere measurable if it coincides almost everywhere with a measurable
function. This property, called `AEMeasurable f μ`, is defined in the file `MeasureSpaceDef`.
We discuss several of its properties that are analogous to properties of measurable functions.
-/
open MeasureTheory MeasureTheory.Measure Filter Set Function ENNReal
variable {ι α β γ δ R : Type*} {m0 : MeasurableSpace α} [MeasurableSpace β] [MeasurableSpace γ]
[MeasurableSpace δ] {f g : α → β} {μ ν : Measure α}
section
@[nontriviality, measurability]
theorem Subsingleton.aemeasurable [Subsingleton α] : AEMeasurable f μ :=
Subsingleton.measurable.aemeasurable
@[nontriviality, measurability]
theorem aemeasurable_of_subsingleton_codomain [Subsingleton β] : AEMeasurable f μ :=
(measurable_of_subsingleton_codomain f).aemeasurable
@[simp, measurability]
theorem aemeasurable_zero_measure : AEMeasurable f (0 : Measure α) := by
nontriviality α; inhabit α
exact ⟨fun _ => f default, measurable_const, rfl⟩
@[fun_prop]
theorem aemeasurable_id'' (μ : Measure α) {m : MeasurableSpace α} (hm : m ≤ m0) :
@AEMeasurable α α m m0 id μ :=
@Measurable.aemeasurable α α m0 m id μ (measurable_id'' hm)
lemma aemeasurable_of_map_neZero {μ : Measure α}
{f : α → β} (h : NeZero (μ.map f)) :
AEMeasurable f μ := by
by_contra h'
simp [h'] at h
namespace AEMeasurable
lemma mono_ac (hf : AEMeasurable f ν) (hμν : μ ≪ ν) : AEMeasurable f μ :=
⟨hf.mk f, hf.measurable_mk, hμν.ae_le hf.ae_eq_mk⟩
theorem mono_measure (h : AEMeasurable f μ) (h' : ν ≤ μ) : AEMeasurable f ν :=
mono_ac h h'.absolutelyContinuous
theorem mono_set {s t} (h : s ⊆ t) (ht : AEMeasurable f (μ.restrict t)) :
AEMeasurable f (μ.restrict s) :=
ht.mono_measure (restrict_mono h le_rfl)
@[fun_prop]
protected theorem mono' (h : AEMeasurable f μ) (h' : ν ≪ μ) : AEMeasurable f ν :=
⟨h.mk f, h.measurable_mk, h' h.ae_eq_mk⟩
theorem ae_mem_imp_eq_mk {s} (h : AEMeasurable f (μ.restrict s)) :
∀ᵐ x ∂μ, x ∈ s → f x = h.mk f x :=
ae_imp_of_ae_restrict h.ae_eq_mk
theorem ae_inf_principal_eq_mk {s} (h : AEMeasurable f (μ.restrict s)) : f =ᶠ[ae μ ⊓ 𝓟 s] h.mk f :=
le_ae_restrict h.ae_eq_mk
@[measurability]
theorem sum_measure [Countable ι] {μ : ι → Measure α} (h : ∀ i, AEMeasurable f (μ i)) :
AEMeasurable f (sum μ) := by
classical
nontriviality β
inhabit β
set s : ι → Set α := fun i => toMeasurable (μ i) { x | f x ≠ (h i).mk f x }
have hsμ : ∀ i, μ i (s i) = 0 := by
intro i
rw [measure_toMeasurable]
exact (h i).ae_eq_mk
have hsm : MeasurableSet (⋂ i, s i) :=
MeasurableSet.iInter fun i => measurableSet_toMeasurable _ _
have hs : ∀ i x, x ∉ s i → f x = (h i).mk f x := by
intro i x hx
contrapose! hx
exact subset_toMeasurable _ _ hx
set g : α → β := (⋂ i, s i).piecewise (const α default) f
refine ⟨g, measurable_of_restrict_of_restrict_compl hsm ?_ ?_, ae_sum_iff.mpr fun i => ?_⟩
· rw [restrict_piecewise]
simp only [s, Set.restrict, const]
exact measurable_const
· rw [restrict_piecewise_compl, compl_iInter]
intro t ht
refine ⟨⋃ i, (h i).mk f ⁻¹' t ∩ (s i)ᶜ, MeasurableSet.iUnion fun i ↦
(measurable_mk _ ht).inter (measurableSet_toMeasurable _ _).compl, ?_⟩
ext ⟨x, hx⟩
simp only [mem_preimage, mem_iUnion, Subtype.coe_mk, Set.restrict, mem_inter_iff,
mem_compl_iff] at hx ⊢
constructor
· rintro ⟨i, hxt, hxs⟩
rwa [hs _ _ hxs]
· rcases hx with ⟨i, hi⟩
rw [hs _ _ hi]
exact fun h => ⟨i, h, hi⟩
· refine measure_mono_null (fun x (hx : f x ≠ g x) => ?_) (hsμ i)
contrapose! hx
refine (piecewise_eq_of_not_mem _ _ _ ?_).symm
exact fun h => hx (mem_iInter.1 h i)
@[simp]
theorem _root_.aemeasurable_sum_measure_iff [Countable ι] {μ : ι → Measure α} :
AEMeasurable f (sum μ) ↔ ∀ i, AEMeasurable f (μ i) :=
⟨fun h _ => h.mono_measure (le_sum _ _), sum_measure⟩
@[simp]
theorem _root_.aemeasurable_add_measure_iff :
AEMeasurable f (μ + ν) ↔ AEMeasurable f μ ∧ AEMeasurable f ν := by
rw [← sum_cond, aemeasurable_sum_measure_iff, Bool.forall_bool, and_comm]
rfl
@[measurability]
theorem add_measure {f : α → β} (hμ : AEMeasurable f μ) (hν : AEMeasurable f ν) :
AEMeasurable f (μ + ν) :=
aemeasurable_add_measure_iff.2 ⟨hμ, hν⟩
@[measurability]
protected theorem iUnion [Countable ι] {s : ι → Set α}
(h : ∀ i, AEMeasurable f (μ.restrict (s i))) : AEMeasurable f (μ.restrict (⋃ i, s i)) :=
(sum_measure h).mono_measure <| restrict_iUnion_le
@[simp]
theorem _root_.aemeasurable_iUnion_iff [Countable ι] {s : ι → Set α} :
AEMeasurable f (μ.restrict (⋃ i, s i)) ↔ ∀ i, AEMeasurable f (μ.restrict (s i)) :=
⟨fun h _ => h.mono_measure <| restrict_mono (subset_iUnion _ _) le_rfl, AEMeasurable.iUnion⟩
@[simp]
theorem _root_.aemeasurable_union_iff {s t : Set α} :
AEMeasurable f (μ.restrict (s ∪ t)) ↔
AEMeasurable f (μ.restrict s) ∧ AEMeasurable f (μ.restrict t) := by
simp only [union_eq_iUnion, aemeasurable_iUnion_iff, Bool.forall_bool, cond, and_comm]
@[measurability]
theorem smul_measure [SMul R ℝ≥0∞] [IsScalarTower R ℝ≥0∞ ℝ≥0∞]
(h : AEMeasurable f μ) (c : R) : AEMeasurable f (c • μ) :=
⟨h.mk f, h.measurable_mk, ae_smul_measure h.ae_eq_mk c⟩
theorem comp_aemeasurable {f : α → δ} {g : δ → β} (hg : AEMeasurable g (μ.map f))
(hf : AEMeasurable f μ) : AEMeasurable (g ∘ f) μ :=
⟨hg.mk g ∘ hf.mk f, hg.measurable_mk.comp hf.measurable_mk,
(ae_eq_comp hf hg.ae_eq_mk).trans (hf.ae_eq_mk.fun_comp (mk g hg))⟩
@[fun_prop]
theorem comp_aemeasurable' {f : α → δ} {g : δ → β} (hg : AEMeasurable g (μ.map f))
| (hf : AEMeasurable f μ) : AEMeasurable (fun x ↦ g (f x)) μ := comp_aemeasurable hg hf
theorem comp_measurable {f : α → δ} {g : δ → β} (hg : AEMeasurable g (μ.map f))
(hf : Measurable f) : AEMeasurable (g ∘ f) μ :=
| Mathlib/MeasureTheory/Measure/AEMeasurable.lean | 155 | 158 |
/-
Copyright (c) 2017 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Tim Baumann, Stephen Morgan, Kim Morrison, Floris van Doorn
-/
import Mathlib.Tactic.CategoryTheory.Reassoc
/-!
# Isomorphisms
This file defines isomorphisms between objects of a category.
## Main definitions
- `structure Iso` : a bundled isomorphism between two objects of a category;
- `class IsIso` : an unbundled version of `iso`;
note that `IsIso f` is a `Prop`, and only asserts the existence of an inverse.
Of course, this inverse is unique, so it doesn't cost us much to use choice to retrieve it.
- `inv f`, for the inverse of a morphism with `[IsIso f]`
- `asIso` : convert from `IsIso` to `Iso` (noncomputable);
- `of_iso` : convert from `Iso` to `IsIso`;
- standard operations on isomorphisms (composition, inverse etc)
## Notations
- `X ≅ Y` : same as `Iso X Y`;
- `α ≪≫ β` : composition of two isomorphisms; it is called `Iso.trans`
## Tags
category, category theory, isomorphism
-/
universe v u
-- morphism levels before object levels. See note [CategoryTheory universes].
namespace CategoryTheory
open Category
/-- An isomorphism (a.k.a. an invertible morphism) between two objects of a category.
The inverse morphism is bundled.
See also `CategoryTheory.Core` for the category with the same objects and isomorphisms playing
the role of morphisms. -/
@[stacks 0017]
structure Iso {C : Type u} [Category.{v} C] (X Y : C) where
/-- The forward direction of an isomorphism. -/
hom : X ⟶ Y
/-- The backwards direction of an isomorphism. -/
inv : Y ⟶ X
/-- Composition of the two directions of an isomorphism is the identity on the source. -/
hom_inv_id : hom ≫ inv = 𝟙 X := by aesop_cat
/-- Composition of the two directions of an isomorphism in reverse order
is the identity on the target. -/
inv_hom_id : inv ≫ hom = 𝟙 Y := by aesop_cat
attribute [reassoc (attr := simp)] Iso.hom_inv_id Iso.inv_hom_id
/-- Notation for an isomorphism in a category. -/
infixr:10 " ≅ " => Iso -- type as \cong or \iso
variable {C : Type u} [Category.{v} C] {X Y Z : C}
namespace Iso
@[ext]
theorem ext ⦃α β : X ≅ Y⦄ (w : α.hom = β.hom) : α = β :=
suffices α.inv = β.inv by
cases α
cases β
cases w
cases this
rfl
calc
α.inv = α.inv ≫ β.hom ≫ β.inv := by rw [Iso.hom_inv_id, Category.comp_id]
_ = (α.inv ≫ α.hom) ≫ β.inv := by rw [Category.assoc, ← w]
_ = β.inv := by rw [Iso.inv_hom_id, Category.id_comp]
/-- Inverse isomorphism. -/
@[symm]
def symm (I : X ≅ Y) : Y ≅ X where
hom := I.inv
inv := I.hom
@[simp]
theorem symm_hom (α : X ≅ Y) : α.symm.hom = α.inv :=
rfl
@[simp]
theorem symm_inv (α : X ≅ Y) : α.symm.inv = α.hom :=
rfl
@[simp]
theorem symm_mk {X Y : C} (hom : X ⟶ Y) (inv : Y ⟶ X) (hom_inv_id) (inv_hom_id) :
Iso.symm { hom, inv, hom_inv_id := hom_inv_id, inv_hom_id := inv_hom_id } =
{ hom := inv, inv := hom, hom_inv_id := inv_hom_id, inv_hom_id := hom_inv_id } :=
rfl
@[simp]
theorem symm_symm_eq {X Y : C} (α : X ≅ Y) : α.symm.symm = α := rfl
theorem symm_bijective {X Y : C} : Function.Bijective (symm : (X ≅ Y) → _) :=
Function.bijective_iff_has_inverse.mpr ⟨_, symm_symm_eq, symm_symm_eq⟩
@[simp]
theorem symm_eq_iff {X Y : C} {α β : X ≅ Y} : α.symm = β.symm ↔ α = β :=
symm_bijective.injective.eq_iff
theorem nonempty_iso_symm (X Y : C) : Nonempty (X ≅ Y) ↔ Nonempty (Y ≅ X) :=
⟨fun h => ⟨h.some.symm⟩, fun h => ⟨h.some.symm⟩⟩
/-- Identity isomorphism. -/
@[refl, simps]
def refl (X : C) : X ≅ X where
hom := 𝟙 X
inv := 𝟙 X
instance : Inhabited (X ≅ X) := ⟨Iso.refl X⟩
theorem nonempty_iso_refl (X : C) : Nonempty (X ≅ X) := ⟨default⟩
@[simp]
theorem refl_symm (X : C) : (Iso.refl X).symm = Iso.refl X := rfl
/-- Composition of two isomorphisms -/
@[simps]
def trans (α : X ≅ Y) (β : Y ≅ Z) : X ≅ Z where
hom := α.hom ≫ β.hom
inv := β.inv ≫ α.inv
@[simps]
instance instTransIso : Trans (α := C) (· ≅ ·) (· ≅ ·) (· ≅ ·) where
trans := trans
/-- Notation for composition of isomorphisms. -/
infixr:80 " ≪≫ " => Iso.trans -- type as `\ll \gg`.
@[simp]
theorem trans_mk {X Y Z : C} (hom : X ⟶ Y) (inv : Y ⟶ X) (hom_inv_id) (inv_hom_id)
(hom' : Y ⟶ Z) (inv' : Z ⟶ Y) (hom_inv_id') (inv_hom_id') (hom_inv_id'') (inv_hom_id'') :
Iso.trans ⟨hom, inv, hom_inv_id, inv_hom_id⟩ ⟨hom', inv', hom_inv_id', inv_hom_id'⟩ =
⟨hom ≫ hom', inv' ≫ inv, hom_inv_id'', inv_hom_id''⟩ :=
rfl
@[simp]
theorem trans_symm (α : X ≅ Y) (β : Y ≅ Z) : (α ≪≫ β).symm = β.symm ≪≫ α.symm :=
rfl
@[simp]
theorem trans_assoc {Z' : C} (α : X ≅ Y) (β : Y ≅ Z) (γ : Z ≅ Z') :
(α ≪≫ β) ≪≫ γ = α ≪≫ β ≪≫ γ := by
ext; simp only [trans_hom, Category.assoc]
@[simp]
theorem refl_trans (α : X ≅ Y) : Iso.refl X ≪≫ α = α := by ext; apply Category.id_comp
@[simp]
theorem trans_refl (α : X ≅ Y) : α ≪≫ Iso.refl Y = α := by ext; apply Category.comp_id
@[simp]
theorem symm_self_id (α : X ≅ Y) : α.symm ≪≫ α = Iso.refl Y :=
ext α.inv_hom_id
@[simp]
theorem self_symm_id (α : X ≅ Y) : α ≪≫ α.symm = Iso.refl X :=
ext α.hom_inv_id
@[simp]
theorem symm_self_id_assoc (α : X ≅ Y) (β : Y ≅ Z) : α.symm ≪≫ α ≪≫ β = β := by
rw [← trans_assoc, symm_self_id, refl_trans]
@[simp]
theorem self_symm_id_assoc (α : X ≅ Y) (β : X ≅ Z) : α ≪≫ α.symm ≪≫ β = β := by
rw [← trans_assoc, self_symm_id, refl_trans]
theorem inv_comp_eq (α : X ≅ Y) {f : X ⟶ Z} {g : Y ⟶ Z} : α.inv ≫ f = g ↔ f = α.hom ≫ g :=
⟨fun H => by simp [H.symm], fun H => by simp [H]⟩
theorem eq_inv_comp (α : X ≅ Y) {f : X ⟶ Z} {g : Y ⟶ Z} : g = α.inv ≫ f ↔ α.hom ≫ g = f :=
(inv_comp_eq α.symm).symm
theorem comp_inv_eq (α : X ≅ Y) {f : Z ⟶ Y} {g : Z ⟶ X} : f ≫ α.inv = g ↔ f = g ≫ α.hom :=
⟨fun H => by simp [H.symm], fun H => by simp [H]⟩
theorem eq_comp_inv (α : X ≅ Y) {f : Z ⟶ Y} {g : Z ⟶ X} : g = f ≫ α.inv ↔ g ≫ α.hom = f :=
(comp_inv_eq α.symm).symm
theorem inv_eq_inv (f g : X ≅ Y) : f.inv = g.inv ↔ f.hom = g.hom :=
have : ∀ {X Y : C} (f g : X ≅ Y), f.hom = g.hom → f.inv = g.inv := fun f g h => by rw [ext h]
⟨this f.symm g.symm, this f g⟩
theorem hom_comp_eq_id (α : X ≅ Y) {f : Y ⟶ X} : α.hom ≫ f = 𝟙 X ↔ f = α.inv := by
rw [← eq_inv_comp, comp_id]
theorem comp_hom_eq_id (α : X ≅ Y) {f : Y ⟶ X} : f ≫ α.hom = 𝟙 Y ↔ f = α.inv := by
rw [← eq_comp_inv, id_comp]
theorem inv_comp_eq_id (α : X ≅ Y) {f : X ⟶ Y} : α.inv ≫ f = 𝟙 Y ↔ f = α.hom :=
hom_comp_eq_id α.symm
theorem comp_inv_eq_id (α : X ≅ Y) {f : X ⟶ Y} : f ≫ α.inv = 𝟙 X ↔ f = α.hom :=
comp_hom_eq_id α.symm
theorem hom_eq_inv (α : X ≅ Y) (β : Y ≅ X) : α.hom = β.inv ↔ β.hom = α.inv := by
rw [← symm_inv, inv_eq_inv α.symm β, eq_comm]
rfl
/-- The bijection `(Z ⟶ X) ≃ (Z ⟶ Y)` induced by `α : X ≅ Y`. -/
@[simps]
def homToEquiv (α : X ≅ Y) {Z : C} : (Z ⟶ X) ≃ (Z ⟶ Y) where
toFun f := f ≫ α.hom
invFun g := g ≫ α.inv
left_inv := by aesop_cat
right_inv := by aesop_cat
/-- The bijection `(X ⟶ Z) ≃ (Y ⟶ Z)` induced by `α : X ≅ Y`. -/
@[simps]
def homFromEquiv (α : X ≅ Y) {Z : C} : (X ⟶ Z) ≃ (Y ⟶ Z) where
toFun f := α.inv ≫ f
invFun g := α.hom ≫ g
left_inv := by aesop_cat
right_inv := by aesop_cat
end Iso
| /-- `IsIso` typeclass expressing that a morphism is invertible. -/
class IsIso (f : X ⟶ Y) : Prop where
/-- The existence of an inverse morphism. -/
| Mathlib/CategoryTheory/Iso.lean | 227 | 229 |
/-
Copyright (c) 2022 Antoine Labelle, Rémi Bottinelli. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Antoine Labelle, Rémi Bottinelli
-/
import Mathlib.Combinatorics.Quiver.Basic
import Mathlib.Combinatorics.Quiver.Path
/-!
# Rewriting arrows and paths along vertex equalities
This files defines `Hom.cast` and `Path.cast` (and associated lemmas) in order to allow
rewriting arrows and paths along equalities of their endpoints.
-/
universe v v₁ v₂ u u₁ u₂
variable {U : Type*} [Quiver.{u + 1} U]
namespace Quiver
/-!
### Rewriting arrows along equalities of vertices
-/
/-- Change the endpoints of an arrow using equalities. -/
def Hom.cast {u v u' v' : U} (hu : u = u') (hv : v = v') (e : u ⟶ v) : u' ⟶ v' :=
Eq.ndrec (motive := (· ⟶ v')) (Eq.ndrec e hv) hu
theorem Hom.cast_eq_cast {u v u' v' : U} (hu : u = u') (hv : v = v') (e : u ⟶ v) :
e.cast hu hv = _root_.cast (by {rw [hu, hv]}) e := by
subst_vars
rfl
@[simp]
theorem Hom.cast_rfl_rfl {u v : U} (e : u ⟶ v) : e.cast rfl rfl = e :=
rfl
@[simp]
theorem Hom.cast_cast {u v u' v' u'' v'' : U} (e : u ⟶ v) (hu : u = u') (hv : v = v')
(hu' : u' = u'') (hv' : v' = v'') :
(e.cast hu hv).cast hu' hv' = e.cast (hu.trans hu') (hv.trans hv') := by
subst_vars
rfl
theorem Hom.cast_heq {u v u' v' : U} (hu : u = u') (hv : v = v') (e : u ⟶ v) :
HEq (e.cast hu hv) e := by
subst_vars
rfl
theorem Hom.cast_eq_iff_heq {u v u' v' : U} (hu : u = u') (hv : v = v') (e : u ⟶ v) (e' : u' ⟶ v') :
e.cast hu hv = e' ↔ HEq e e' := by
rw [Hom.cast_eq_cast]
exact _root_.cast_eq_iff_heq
theorem Hom.eq_cast_iff_heq {u v u' v' : U} (hu : u = u') (hv : v = v') (e : u ⟶ v) (e' : u' ⟶ v') :
e' = e.cast hu hv ↔ HEq e' e := by
rw [eq_comm, Hom.cast_eq_iff_heq]
exact ⟨HEq.symm, HEq.symm⟩
/-!
### Rewriting paths along equalities of vertices
-/
open Path
/-- Change the endpoints of a path using equalities. -/
def Path.cast {u v u' v' : U} (hu : u = u') (hv : v = v') (p : Path u v) : Path u' v' :=
Eq.ndrec (motive := (Path · v')) (Eq.ndrec p hv) hu
theorem Path.cast_eq_cast {u v u' v' : U} (hu : u = u') (hv : v = v') (p : Path u v) :
p.cast hu hv = _root_.cast (by rw [hu, hv]) p := by
subst_vars
rfl
@[simp]
theorem Path.cast_rfl_rfl {u v : U} (p : Path u v) : p.cast rfl rfl = p :=
rfl
@[simp]
theorem Path.cast_cast {u v u' v' u'' v'' : U} (p : Path u v) (hu : u = u') (hv : v = v')
(hu' : u' = u'') (hv' : v' = v'') :
(p.cast hu hv).cast hu' hv' = p.cast (hu.trans hu') (hv.trans hv') := by
subst_vars
rfl
@[simp]
theorem Path.cast_nil {u u' : U} (hu : u = u') : (Path.nil : Path u u).cast hu hu = Path.nil := by
subst_vars
rfl
theorem Path.cast_heq {u v u' v' : U} (hu : u = u') (hv : v = v') (p : Path u v) :
HEq (p.cast hu hv) p := by
rw [Path.cast_eq_cast]
exact _root_.cast_heq _ _
theorem Path.cast_eq_iff_heq {u v u' v' : U} (hu : u = u') (hv : v = v') (p : Path u v)
(p' : Path u' v') : p.cast hu hv = p' ↔ HEq p p' := by
rw [Path.cast_eq_cast]
exact _root_.cast_eq_iff_heq
theorem Path.eq_cast_iff_heq {u v u' v' : U} (hu : u = u') (hv : v = v') (p : Path u v)
(p' : Path u' v') : p' = p.cast hu hv ↔ HEq p' p :=
⟨fun h => ((p.cast_eq_iff_heq hu hv p').1 h.symm).symm, fun h =>
((p.cast_eq_iff_heq hu hv p').2 h.symm).symm⟩
theorem Path.cast_cons {u v w u' w' : U} (p : Path u v) (e : v ⟶ w) (hu : u = u') (hw : w = w') :
(p.cons e).cast hu hw = (p.cast hu rfl).cons (e.cast rfl hw) := by
subst_vars
rfl
| theorem cast_eq_of_cons_eq_cons {u v v' w : U} {p : Path u v} {p' : Path u v'} {e : v ⟶ w}
{e' : v' ⟶ w} (h : p.cons e = p'.cons e') : p.cast rfl (obj_eq_of_cons_eq_cons h) = p' := by
rw [Path.cast_eq_iff_heq]
exact heq_of_cons_eq_cons h
| Mathlib/Combinatorics/Quiver/Cast.lean | 118 | 121 |
/-
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.Module.Basic
import Mathlib.LinearAlgebra.AffineSpace.AffineEquiv
/-!
# Midpoint of a segment
## Main definitions
* `midpoint R x y`: midpoint of the segment `[x, y]`. We define it for `x` and `y`
in a module over a ring `R` with invertible `2`.
* `AddMonoidHom.ofMapMidpoint`: construct an `AddMonoidHom` given a map `f` such that
`f` sends zero to zero and midpoints to midpoints.
## Main theorems
* `midpoint_eq_iff`: `z` is the midpoint of `[x, y]` if and only if `x + y = z + z`,
* `midpoint_unique`: `midpoint R x y` does not depend on `R`;
* `midpoint x y` is linear both in `x` and `y`;
* `pointReflection_midpoint_left`, `pointReflection_midpoint_right`:
`Equiv.pointReflection (midpoint R x y)` swaps `x` and `y`.
We do not mark most lemmas as `@[simp]` because it is hard to tell which side is simpler.
## Tags
midpoint, AddMonoidHom
-/
open AffineMap AffineEquiv
section
variable (R : Type*) {V V' P P' : Type*} [Ring R] [Invertible (2 : R)] [AddCommGroup V]
[Module R V] [AddTorsor V P] [AddCommGroup V'] [Module R V'] [AddTorsor V' P']
/-- `midpoint x y` is the midpoint of the segment `[x, y]`. -/
def midpoint (x y : P) : P :=
lineMap x y (⅟ 2 : R)
variable {R} {x y z : P}
@[simp]
theorem AffineMap.map_midpoint (f : P →ᵃ[R] P') (a b : P) :
f (midpoint R a b) = midpoint R (f a) (f b) :=
f.apply_lineMap a b _
@[simp]
theorem AffineEquiv.map_midpoint (f : P ≃ᵃ[R] P') (a b : P) :
f (midpoint R a b) = midpoint R (f a) (f b) :=
f.apply_lineMap a b _
theorem AffineEquiv.pointReflection_midpoint_left (x y : P) :
pointReflection R (midpoint R x y) x = y := by
rw [midpoint, pointReflection_apply, lineMap_apply, vadd_vsub, vadd_vadd, ← add_smul, ← two_mul,
mul_invOf_self, one_smul, vsub_vadd]
@[simp]
theorem Equiv.pointReflection_midpoint_left (x y : P) :
(Equiv.pointReflection (midpoint R x y)) x = y := by
rw [midpoint, pointReflection_apply, lineMap_apply, vadd_vsub, vadd_vadd, ← add_smul, ← two_mul,
mul_invOf_self, one_smul, vsub_vadd]
theorem midpoint_comm (x y : P) : midpoint R x y = midpoint R y x := by
rw [midpoint, ← lineMap_apply_one_sub, one_sub_invOf_two, midpoint]
theorem AffineEquiv.pointReflection_midpoint_right (x y : P) :
pointReflection R (midpoint R x y) y = x := by
rw [midpoint_comm, AffineEquiv.pointReflection_midpoint_left]
@[simp]
theorem Equiv.pointReflection_midpoint_right (x y : P) :
(Equiv.pointReflection (midpoint R x y)) y = x := by
rw [midpoint_comm, Equiv.pointReflection_midpoint_left]
theorem midpoint_vsub_midpoint (p₁ p₂ p₃ p₄ : P) :
midpoint R p₁ p₂ -ᵥ midpoint R p₃ p₄ = midpoint R (p₁ -ᵥ p₃) (p₂ -ᵥ p₄) :=
lineMap_vsub_lineMap _ _ _ _ _
theorem midpoint_vadd_midpoint (v v' : V) (p p' : P) :
midpoint R v v' +ᵥ midpoint R p p' = midpoint R (v +ᵥ p) (v' +ᵥ p') :=
lineMap_vadd_lineMap _ _ _ _ _
theorem midpoint_eq_iff {x y z : P} : midpoint R x y = z ↔ pointReflection R z x = y :=
eq_comm.trans
((injective_pointReflection_left_of_module R x).eq_iff'
(AffineEquiv.pointReflection_midpoint_left x y)).symm
@[simp]
theorem midpoint_pointReflection_left (x y : P) :
midpoint R (Equiv.pointReflection x y) y = x :=
midpoint_eq_iff.2 <| Equiv.pointReflection_involutive _ _
@[simp]
theorem midpoint_pointReflection_right (x y : P) :
midpoint R y (Equiv.pointReflection x y) = x :=
midpoint_eq_iff.2 rfl
nonrec lemma AffineEquiv.midpoint_pointReflection_left (x y : P) :
midpoint R (pointReflection R x y) y = x :=
midpoint_pointReflection_left x y
nonrec lemma AffineEquiv.midpoint_pointReflection_right (x y : P) :
midpoint R y (pointReflection R x y) = x :=
midpoint_pointReflection_right x y
@[simp]
theorem midpoint_vsub_left (p₁ p₂ : P) : midpoint R p₁ p₂ -ᵥ p₁ = (⅟ 2 : R) • (p₂ -ᵥ p₁) :=
lineMap_vsub_left _ _ _
@[simp]
theorem midpoint_vsub_right (p₁ p₂ : P) : midpoint R p₁ p₂ -ᵥ p₂ = (⅟ 2 : R) • (p₁ -ᵥ p₂) := by
rw [midpoint_comm, midpoint_vsub_left]
@[simp]
theorem left_vsub_midpoint (p₁ p₂ : P) : p₁ -ᵥ midpoint R p₁ p₂ = (⅟ 2 : R) • (p₁ -ᵥ p₂) :=
left_vsub_lineMap _ _ _
@[simp]
theorem right_vsub_midpoint (p₁ p₂ : P) : p₂ -ᵥ midpoint R p₁ p₂ = (⅟ 2 : R) • (p₂ -ᵥ p₁) := by
rw [midpoint_comm, left_vsub_midpoint]
theorem midpoint_vsub (p₁ p₂ p : P) :
midpoint R p₁ p₂ -ᵥ p = (⅟ 2 : R) • (p₁ -ᵥ p) + (⅟ 2 : R) • (p₂ -ᵥ p) := by
rw [← vsub_sub_vsub_cancel_right p₁ p p₂, smul_sub, sub_eq_add_neg, ← smul_neg,
neg_vsub_eq_vsub_rev, add_assoc, invOf_two_smul_add_invOf_two_smul, ← vadd_vsub_assoc,
midpoint_comm, midpoint, lineMap_apply]
theorem vsub_midpoint (p₁ p₂ p : P) :
p -ᵥ midpoint R p₁ p₂ = (⅟ 2 : R) • (p -ᵥ p₁) + (⅟ 2 : R) • (p -ᵥ p₂) := by
rw [← neg_vsub_eq_vsub_rev, midpoint_vsub, neg_add, ← smul_neg, ← smul_neg, neg_vsub_eq_vsub_rev,
neg_vsub_eq_vsub_rev]
@[simp]
theorem midpoint_sub_left (v₁ v₂ : V) : midpoint R v₁ v₂ - v₁ = (⅟ 2 : R) • (v₂ - v₁) :=
midpoint_vsub_left v₁ v₂
@[simp]
theorem midpoint_sub_right (v₁ v₂ : V) : midpoint R v₁ v₂ - v₂ = (⅟ 2 : R) • (v₁ - v₂) :=
midpoint_vsub_right v₁ v₂
@[simp]
theorem left_sub_midpoint (v₁ v₂ : V) : v₁ - midpoint R v₁ v₂ = (⅟ 2 : R) • (v₁ - v₂) :=
left_vsub_midpoint v₁ v₂
@[simp]
theorem right_sub_midpoint (v₁ v₂ : V) : v₂ - midpoint R v₁ v₂ = (⅟ 2 : R) • (v₂ - v₁) :=
right_vsub_midpoint v₁ v₂
variable (R)
@[simp]
theorem midpoint_eq_left_iff {x y : P} : midpoint R x y = x ↔ x = y := by
rw [midpoint_eq_iff, pointReflection_self]
@[simp]
theorem left_eq_midpoint_iff {x y : P} : x = midpoint R x y ↔ x = y := by
rw [eq_comm, midpoint_eq_left_iff]
@[simp]
theorem midpoint_eq_right_iff {x y : P} : midpoint R x y = y ↔ x = y := by
rw [midpoint_comm, midpoint_eq_left_iff, eq_comm]
@[simp]
theorem right_eq_midpoint_iff {x y : P} : y = midpoint R x y ↔ x = y := by
rw [eq_comm, midpoint_eq_right_iff]
theorem midpoint_eq_midpoint_iff_vsub_eq_vsub {x x' y y' : P} :
midpoint R x y = midpoint R x' y' ↔ x -ᵥ x' = y' -ᵥ y := by
rw [← @vsub_eq_zero_iff_eq V, midpoint_vsub_midpoint, midpoint_eq_iff, pointReflection_apply,
vsub_eq_sub, zero_sub, vadd_eq_add, add_zero, neg_eq_iff_eq_neg, neg_vsub_eq_vsub_rev]
theorem midpoint_eq_iff' {x y z : P} : midpoint R x y = z ↔ Equiv.pointReflection z x = y :=
midpoint_eq_iff
|
/-- `midpoint` does not depend on the ring `R`. -/
| Mathlib/LinearAlgebra/AffineSpace/Midpoint.lean | 179 | 180 |
/-
Copyright (c) 2022 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel
-/
import Mathlib.MeasureTheory.Function.Jacobian
import Mathlib.MeasureTheory.Measure.Lebesgue.Complex
import Mathlib.Analysis.SpecialFunctions.Trigonometric.Deriv
/-!
# Polar coordinates
We define polar coordinates, as a partial homeomorphism in `ℝ^2` between `ℝ^2 - (-∞, 0]` and
`(0, +∞) × (-π, π)`. Its inverse is given by `(r, θ) ↦ (r cos θ, r sin θ)`.
It satisfies the following change of variables formula (see `integral_comp_polarCoord_symm`):
`∫ p in polarCoord.target, p.1 • f (polarCoord.symm p) = ∫ p, f p`
-/
noncomputable section Real
open Real Set MeasureTheory
open scoped ENNReal Real Topology
/-- The polar coordinates partial homeomorphism in `ℝ^2`, mapping `(r cos θ, r sin θ)` to `(r, θ)`.
It is a homeomorphism between `ℝ^2 - (-∞, 0]` and `(0, +∞) × (-π, π)`. -/
@[simps]
def polarCoord : PartialHomeomorph (ℝ × ℝ) (ℝ × ℝ) where
toFun q := (√(q.1 ^ 2 + q.2 ^ 2), Complex.arg (Complex.equivRealProd.symm q))
invFun p := (p.1 * cos p.2, p.1 * sin p.2)
source := {q | 0 < q.1} ∪ {q | q.2 ≠ 0}
target := Ioi (0 : ℝ) ×ˢ Ioo (-π) π
map_target' := by
rintro ⟨r, θ⟩ ⟨hr, hθ⟩
dsimp at hr hθ
rcases eq_or_ne θ 0 with (rfl | h'θ)
· simpa using hr
· right
simp at hr
simpa only [ne_of_gt hr, Ne, mem_setOf_eq, mul_eq_zero, false_or,
sin_eq_zero_iff_of_lt_of_lt hθ.1 hθ.2] using h'θ
map_source' := by
rintro ⟨x, y⟩ hxy
simp only [prodMk_mem_set_prod_eq, mem_Ioi, sqrt_pos, mem_Ioo, Complex.neg_pi_lt_arg,
true_and, Complex.arg_lt_pi_iff]
constructor
· rcases hxy with hxy | hxy
· dsimp at hxy; linarith [sq_pos_of_ne_zero hxy.ne', sq_nonneg y]
· linarith [sq_nonneg x, sq_pos_of_ne_zero hxy]
· rcases hxy with hxy | hxy
· exact Or.inl (le_of_lt hxy)
· exact Or.inr hxy
right_inv' := by
rintro ⟨r, θ⟩ ⟨hr, hθ⟩
ext <;> dsimp at hr hθ ⊢
· conv_rhs => rw [← sqrt_sq (le_of_lt hr), ← one_mul (r ^ 2), ← sin_sq_add_cos_sq θ]
congr 1
ring
· convert Complex.arg_mul_cos_add_sin_mul_I hr ⟨hθ.1, hθ.2.le⟩
simp only [Complex.equivRealProd_symm_apply, Complex.ofReal_mul, Complex.ofReal_cos,
Complex.ofReal_sin]
ring
left_inv' := by
rintro ⟨x, y⟩ _
have A : √(x ^ 2 + y ^ 2) = ‖x + y * Complex.I‖ := by
rw [Complex.norm_def, Complex.normSq_add_mul_I]
have Z := Complex.norm_mul_cos_add_sin_mul_I (x + y * Complex.I)
simp only [← Complex.ofReal_cos, ← Complex.ofReal_sin, mul_add, ← Complex.ofReal_mul, ←
mul_assoc] at Z
simp [A]
open_target := isOpen_Ioi.prod isOpen_Ioo
open_source :=
(isOpen_lt continuous_const continuous_fst).union
(isOpen_ne_fun continuous_snd continuous_const)
continuousOn_invFun := by fun_prop
continuousOn_toFun := by
refine .prodMk (by fun_prop) ?_
have A : MapsTo Complex.equivRealProd.symm ({q : ℝ × ℝ | 0 < q.1} ∪ {q : ℝ × ℝ | q.2 ≠ 0})
Complex.slitPlane := by
rintro ⟨x, y⟩ hxy; simpa only using hxy
refine ContinuousOn.comp (f := Complex.equivRealProd.symm)
(g := Complex.arg) (fun z hz => ?_) ?_ A
· exact (Complex.continuousAt_arg hz).continuousWithinAt
· exact Complex.equivRealProdCLM.symm.continuous.continuousOn
@[fun_prop]
theorem continuous_polarCoord_symm :
Continuous polarCoord.symm :=
.prodMk (by fun_prop) (by fun_prop)
/-- The derivative of `polarCoord.symm`, see `hasFDerivAt_polarCoord_symm`. -/
def fderivPolarCoordSymm (p : ℝ × ℝ) : ℝ × ℝ →L[ℝ] ℝ × ℝ :=
LinearMap.toContinuousLinearMap (Matrix.toLin (Basis.finTwoProd ℝ)
(Basis.finTwoProd ℝ) !![cos p.2, -p.1 * sin p.2; sin p.2, p.1 * cos p.2])
theorem hasFDerivAt_polarCoord_symm (p : ℝ × ℝ) :
HasFDerivAt polarCoord.symm (fderivPolarCoordSymm p) p := by
unfold fderivPolarCoordSymm
rw [Matrix.toLin_finTwoProd_toContinuousLinearMap]
convert HasFDerivAt.prodMk (𝕜 := ℝ)
(hasFDerivAt_fst.mul ((hasDerivAt_cos p.2).comp_hasFDerivAt p hasFDerivAt_snd))
(hasFDerivAt_fst.mul ((hasDerivAt_sin p.2).comp_hasFDerivAt p hasFDerivAt_snd)) using 2 <;>
simp [smul_smul, add_comm, neg_mul, smul_neg, neg_smul _ (ContinuousLinearMap.snd ℝ ℝ ℝ)]
theorem det_fderivPolarCoordSymm (p : ℝ × ℝ) :
(fderivPolarCoordSymm p).det = p.1 := by
conv_rhs => rw [← one_mul p.1, ← cos_sq_add_sin_sq p.2]
unfold fderivPolarCoordSymm
simp only [neg_mul, LinearMap.det_toContinuousLinearMap, LinearMap.det_toLin,
Matrix.det_fin_two_of, sub_neg_eq_add]
ring
-- Porting note: this instance is needed but not automatically synthesised
instance : Measure.IsAddHaarMeasure volume (G := ℝ × ℝ) :=
Measure.prod.instIsAddHaarMeasure _ _
theorem polarCoord_source_ae_eq_univ : polarCoord.source =ᵐ[volume] univ := by
have A : polarCoord.sourceᶜ ⊆ LinearMap.ker (LinearMap.snd ℝ ℝ ℝ) := by
intro x hx
simp only [polarCoord_source, compl_union, mem_inter_iff, mem_compl_iff, mem_setOf_eq, not_lt,
Classical.not_not] at hx
exact hx.2
have B : volume (LinearMap.ker (LinearMap.snd ℝ ℝ ℝ) : Set (ℝ × ℝ)) = 0 := by
apply Measure.addHaar_submodule
rw [Ne, LinearMap.ker_eq_top]
intro h
have : (LinearMap.snd ℝ ℝ ℝ) (0, 1) = (0 : ℝ × ℝ →ₗ[ℝ] ℝ) (0, 1) := by rw [h]
simp at this
simp only [ae_eq_univ]
exact le_antisymm ((measure_mono A).trans (le_of_eq B)) bot_le
theorem integral_comp_polarCoord_symm {E : Type*} [NormedAddCommGroup E] [NormedSpace ℝ E]
(f : ℝ × ℝ → E) :
(∫ p in polarCoord.target, p.1 • f (polarCoord.symm p)) = ∫ p, f p := by
symm
calc
∫ p, f p = ∫ p in polarCoord.source, f p := by
rw [← setIntegral_univ]
apply setIntegral_congr_set
exact polarCoord_source_ae_eq_univ.symm
_ = ∫ p in polarCoord.target, |p.1| • f (polarCoord.symm p) := by
rw [← PartialHomeomorph.symm_target, integral_target_eq_integral_abs_det_fderiv_smul volume
(fun p _ ↦ hasFDerivAt_polarCoord_symm p), PartialHomeomorph.symm_source]
simp_rw [det_fderivPolarCoordSymm]
_ = ∫ p in polarCoord.target, p.1 • f (polarCoord.symm p) := by
apply setIntegral_congr_fun polarCoord.open_target.measurableSet fun x hx => ?_
rw [abs_of_pos hx.1]
theorem lintegral_comp_polarCoord_symm (f : ℝ × ℝ → ℝ≥0∞) :
∫⁻ (p : ℝ × ℝ) in polarCoord.target, ENNReal.ofReal p.1 • f (polarCoord.symm p) =
∫⁻ (p : ℝ × ℝ), f p := by
symm
calc
_ = ∫⁻ p in polarCoord.symm '' polarCoord.target, f p := by
rw [← setLIntegral_univ, setLIntegral_congr polarCoord_source_ae_eq_univ.symm,
polarCoord.symm_image_target_eq_source ]
_ = ∫⁻ (p : ℝ × ℝ) in polarCoord.target, ENNReal.ofReal |p.1| • f (polarCoord.symm p) := by
rw [lintegral_image_eq_lintegral_abs_det_fderiv_mul volume _
(fun p _ ↦ (hasFDerivAt_polarCoord_symm p).hasFDerivWithinAt)]
· simp_rw [det_fderivPolarCoordSymm]; rfl
exacts [polarCoord.symm.injOn, measurableSet_Ioi.prod measurableSet_Ioo]
_ = ∫⁻ (p : ℝ × ℝ) in polarCoord.target, ENNReal.ofReal p.1 • f (polarCoord.symm p) := by
refine setLIntegral_congr_fun polarCoord.open_target.measurableSet ?_
filter_upwards with _ hx using by rw [abs_of_pos hx.1]
|
end Real
noncomputable section Complex
| Mathlib/Analysis/SpecialFunctions/PolarCoord.lean | 167 | 170 |
/-
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.Nat.Fib.Basic
/-!
# Zeckendorf's Theorem
This file proves Zeckendorf's theorem: Every natural number can be written uniquely as a sum of
distinct non-consecutive Fibonacci numbers.
## Main declarations
* `List.IsZeckendorfRep`: Predicate for a list to be an increasing sequence of non-consecutive
natural numbers greater than or equal to `2`, namely a Zeckendorf representation.
* `Nat.greatestFib`: Greatest index of a Fibonacci number less than or equal to some natural.
* `Nat.zeckendorf`: Send a natural number to its Zeckendorf representation.
* `Nat.zeckendorfEquiv`: Zeckendorf's theorem, in the form of an equivalence between natural numbers
and Zeckendorf representations.
## TODO
We could prove that the order induced by `zeckendorfEquiv` on Zeckendorf representations is exactly
the lexicographic order.
## Tags
fibonacci, zeckendorf, digit
-/
open List Nat
-- TODO: The `local` attribute makes this not considered as an instance by linters
@[nolint defLemma docBlame]
local instance : IsTrans ℕ fun a b ↦ b + 2 ≤ a where
trans _a _b _c hba hcb := hcb.trans <| le_self_add.trans hba
namespace List
/-- A list of natural numbers is a Zeckendorf representation (of a natural number) if it is an
increasing sequence of non-consecutive numbers greater than or equal to `2`.
This is relevant for Zeckendorf's theorem, since if we write a natural `n` as a sum of Fibonacci
numbers `(l.map fib).sum`, `IsZeckendorfRep l` exactly means that we can't simplify any expression
of the form `fib n + fib (n + 1) = fib (n + 2)`, `fib 1 = fib 2` or `fib 0 = 0` in the sum. -/
def IsZeckendorfRep (l : List ℕ) : Prop := (l ++ [0]).Chain' (fun a b ↦ b + 2 ≤ a)
@[simp]
lemma IsZeckendorfRep_nil : IsZeckendorfRep [] := by simp [IsZeckendorfRep]
lemma IsZeckendorfRep.sum_fib_lt : ∀ {n l}, IsZeckendorfRep l → (∀ a ∈ (l ++ [0]).head?, a < n) →
(l.map fib).sum < fib n
| _, [], _, hn => fib_pos.2 <| hn _ rfl
| n, a :: l, hl, hn => by
simp only [IsZeckendorfRep, cons_append, chain'_iff_pairwise, pairwise_cons] at hl
have : ∀ b, b ∈ head? (l ++ [0]) → b < a - 1 :=
fun b hb ↦ lt_tsub_iff_right.2 <| hl.1 _ <| mem_of_mem_head? hb
simp only [mem_append, mem_singleton, ← chain'_iff_pairwise, or_imp, forall_and, forall_eq,
zero_add] at hl
simp only [map, List.sum_cons]
refine (add_lt_add_left (sum_fib_lt hl.2 this) _).trans_le ?_
rw [add_comm, ← fib_add_one (hl.1.2.trans_lt' zero_lt_two).ne']
exact fib_mono (hn _ rfl)
end List
namespace Nat
variable {m n : ℕ}
/-- The greatest index of a Fibonacci number less than or equal to `n`. -/
def greatestFib (n : ℕ) : ℕ := (n + 1).findGreatest (fun k ↦ fib k ≤ n)
lemma fib_greatestFib_le (n : ℕ) : fib (greatestFib n) ≤ n :=
findGreatest_spec (P := (fun k ↦ fib k ≤ n)) (zero_le _) <| zero_le _
lemma greatestFib_mono : Monotone greatestFib :=
fun _a _b hab ↦ findGreatest_mono (fun _k ↦ hab.trans') <| add_le_add_right hab _
@[simp] lemma le_greatestFib : m ≤ greatestFib n ↔ fib m ≤ n :=
⟨fun h ↦ (fib_mono h).trans <| fib_greatestFib_le _,
fun h ↦ le_findGreatest (m.le_fib_add_one.trans <| add_le_add_right h _) h⟩
@[simp] lemma greatestFib_lt : greatestFib m < n ↔ m < fib n :=
lt_iff_lt_of_le_iff_le le_greatestFib
lemma lt_fib_greatestFib_add_one (n : ℕ) : n < fib (greatestFib n + 1) :=
greatestFib_lt.1 <| lt_succ_self _
@[simp] lemma greatestFib_fib : ∀ {n}, n ≠ 1 → greatestFib (fib n) = n
| 0, _ => rfl
| _n + 2, _ => findGreatest_eq_iff.2
⟨le_fib_add_one _, fun _ ↦ le_rfl, fun _m hnm _ ↦ ((fib_lt_fib le_add_self).2 hnm).not_le⟩
@[simp] lemma greatestFib_eq_zero : greatestFib n = 0 ↔ n = 0 :=
⟨fun h ↦ by simpa using findGreatest_eq_zero_iff.1 h zero_lt_one le_add_self, by rintro rfl; rfl⟩
lemma greatestFib_ne_zero : greatestFib n ≠ 0 ↔ n ≠ 0 := greatestFib_eq_zero.not
@[simp] lemma greatestFib_pos : 0 < greatestFib n ↔ 0 < n := by simp [pos_iff_ne_zero]
lemma greatestFib_sub_fib_greatestFib_le_greatestFib (hn : n ≠ 0) :
greatestFib (n - fib (greatestFib n)) ≤ greatestFib n - 2 := by
rw [← Nat.lt_succ_iff, greatestFib_lt, tsub_lt_iff_right n.fib_greatestFib_le, Nat.sub_succ,
succ_pred, ← fib_add_one]
· exact n.lt_fib_greatestFib_add_one
· simpa
· simpa [← succ_le_iff, tsub_eq_zero_iff_le] using hn.bot_lt
private lemma zeckendorf_aux (hm : 0 < m) : m - fib (greatestFib m) < m :=
tsub_lt_self hm <| fib_pos.2 <| findGreatest_pos.2 ⟨1, zero_lt_one, le_add_self, hm⟩
/-- The Zeckendorf representation of a natural number.
Note: For unfolding, you should use the equational lemmas `Nat.zeckendorf_zero` and
`Nat.zeckendorf_of_pos` instead of the autogenerated one. -/
def zeckendorf : ℕ → List ℕ
| 0 => []
| m@(_ + 1) =>
letI a := greatestFib m
a :: zeckendorf (m - fib a)
decreasing_by simp_wf; subst_vars; apply zeckendorf_aux (zero_lt_succ _)
@[simp] lemma zeckendorf_zero : zeckendorf 0 = [] := zeckendorf.eq_1 ..
@[simp] lemma zeckendorf_succ (n : ℕ) :
zeckendorf (n + 1) = greatestFib (n + 1) :: zeckendorf (n + 1 - fib (greatestFib (n + 1))) :=
zeckendorf.eq_2 ..
@[simp] lemma zeckendorf_of_pos : ∀ {n}, 0 < n →
zeckendorf n = greatestFib n :: zeckendorf (n - fib (greatestFib n))
| _n + 1, _ => zeckendorf_succ _
lemma isZeckendorfRep_zeckendorf : ∀ n, (zeckendorf n).IsZeckendorfRep
| 0 => by simp only [zeckendorf_zero, IsZeckendorfRep_nil]
| n + 1 => by
rw [zeckendorf_succ, IsZeckendorfRep, List.cons_append]
refine (isZeckendorfRep_zeckendorf _).cons' (fun a ha ↦ ?_)
obtain h | h := eq_zero_or_pos (n + 1 - fib (greatestFib (n + 1)))
· simp only [h, zeckendorf_zero, nil_append, head?_cons, Option.mem_some_iff] at ha
subst ha
exact le_greatestFib.2 le_add_self
rw [zeckendorf_of_pos h, cons_append, head?_cons, Option.mem_some_iff] at ha
subst a
exact add_le_of_le_tsub_right_of_le (le_greatestFib.2 le_add_self)
(greatestFib_sub_fib_greatestFib_le_greatestFib n.succ_ne_zero)
| lemma zeckendorf_sum_fib : ∀ {l}, IsZeckendorfRep l → zeckendorf (l.map fib).sum = l
| [], _ => by simp only [map_nil, List.sum_nil, zeckendorf_zero]
| a :: l, hl => by
have hl' := hl
simp only [IsZeckendorfRep, cons_append, chain'_iff_pairwise, pairwise_cons, mem_append,
mem_singleton, or_imp, forall_and, forall_eq, zero_add] at hl
rw [← chain'_iff_pairwise] at hl
have ha : 0 < a := hl.1.2.trans_lt' zero_lt_two
suffices h : greatestFib (fib a + sum (map fib l)) = a by
simp only [map, List.sum_cons, add_pos_iff, fib_pos.2 ha, true_or, zeckendorf_of_pos, h,
add_tsub_cancel_left, zeckendorf_sum_fib hl.2]
simp only [add_comm, add_assoc, greatestFib, findGreatest_eq_iff, ne_eq, ha.ne',
not_false_eq_true, le_add_iff_nonneg_left, _root_.zero_le, forall_true_left, not_le, true_and]
refine ⟨le_add_of_le_right <| le_fib_add_one _, fun n hn _ ↦ ?_⟩
rw [add_comm, ← List.sum_cons, ← map_cons]
exact hl'.sum_fib_lt (by simpa)
| Mathlib/Data/Nat/Fib/Zeckendorf.lean | 150 | 165 |
/-
Copyright (c) 2022 Anatole Dedecker. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Anatole Dedecker
-/
import Mathlib.Topology.UniformSpace.UniformConvergenceTopology
/-!
# Equicontinuity of a family of functions
Let `X` be a topological space and `α` a `UniformSpace`. A family of functions `F : ι → X → α`
is said to be *equicontinuous at a point `x₀ : X`* when, for any entourage `U` in `α`, there is a
neighborhood `V` of `x₀` such that, for all `x ∈ V`, and *for all `i`*, `F i x` is `U`-close to
`F i x₀`. In other words, one has `∀ U ∈ 𝓤 α, ∀ᶠ x in 𝓝 x₀, ∀ i, (F i x₀, F i x) ∈ U`.
For maps between metric spaces, this corresponds to
`∀ ε > 0, ∃ δ > 0, ∀ x, ∀ i, dist x₀ x < δ → dist (F i x₀) (F i x) < ε`.
`F` is said to be *equicontinuous* if it is equicontinuous at each point.
A closely related concept is that of ***uniform*** *equicontinuity* of a family of functions
`F : ι → β → α` between uniform spaces, which means that, for any entourage `U` in `α`, there is an
entourage `V` in `β` such that, if `x` and `y` are `V`-close, then *for all `i`*, `F i x` and
`F i y` are `U`-close. In other words, one has
`∀ U ∈ 𝓤 α, ∀ᶠ xy in 𝓤 β, ∀ i, (F i xy.1, F i xy.2) ∈ U`.
For maps between metric spaces, this corresponds to
`∀ ε > 0, ∃ δ > 0, ∀ x y, ∀ i, dist x y < δ → dist (F i x₀) (F i x) < ε`.
## Main definitions
* `EquicontinuousAt`: equicontinuity of a family of functions at a point
* `Equicontinuous`: equicontinuity of a family of functions on the whole domain
* `UniformEquicontinuous`: uniform equicontinuity of a family of functions on the whole domain
We also introduce relative versions, namely `EquicontinuousWithinAt`, `EquicontinuousOn` and
`UniformEquicontinuousOn`, akin to `ContinuousWithinAt`, `ContinuousOn` and `UniformContinuousOn`
respectively.
## Main statements
* `equicontinuous_iff_continuous`: equicontinuity can be expressed as a simple continuity
condition between well-chosen function spaces. This is really useful for building up the theory.
* `Equicontinuous.closure`: if a set of functions is equicontinuous, its closure
*for the topology of pointwise convergence* is also equicontinuous.
## Notations
Throughout this file, we use :
- `ι`, `κ` for indexing types
- `X`, `Y`, `Z` for topological spaces
- `α`, `β`, `γ` for uniform spaces
## Implementation details
We choose to express equicontinuity as a properties of indexed families of functions rather
than sets of functions for the following reasons:
- it is really easy to express equicontinuity of `H : Set (X → α)` using our setup: it is just
equicontinuity of the family `(↑) : ↥H → (X → α)`. On the other hand, going the other way around
would require working with the range of the family, which is always annoying because it
introduces useless existentials.
- in most applications, one doesn't work with bare functions but with a more specific hom type
`hom`. Equicontinuity of a set `H : Set hom` would then have to be expressed as equicontinuity
of `coe_fn '' H`, which is super annoying to work with. This is much simpler with families,
because equicontinuity of a family `𝓕 : ι → hom` would simply be expressed as equicontinuity
of `coe_fn ∘ 𝓕`, which doesn't introduce any nasty existentials.
To simplify statements, we do provide abbreviations `Set.EquicontinuousAt`, `Set.Equicontinuous`
and `Set.UniformEquicontinuous` asserting the corresponding fact about the family
`(↑) : ↥H → (X → α)` where `H : Set (X → α)`. Note however that these won't work for sets of hom
types, and in that case one should go back to the family definition rather than using `Set.image`.
## References
* [N. Bourbaki, *General Topology, Chapter X*][bourbaki1966]
## Tags
equicontinuity, uniform convergence, ascoli
-/
section
open UniformSpace Filter Set Uniformity Topology UniformConvergence Function
variable {ι κ X X' Y α α' β β' γ : Type*} [tX : TopologicalSpace X] [tY : TopologicalSpace Y]
[uα : UniformSpace α] [uβ : UniformSpace β] [uγ : UniformSpace γ]
/-- A family `F : ι → X → α` of functions from a topological space to a uniform space is
*equicontinuous at `x₀ : X`* if, for all entourages `U ∈ 𝓤 α`, there is a neighborhood `V` of `x₀`
such that, for all `x ∈ V` and for all `i : ι`, `F i x` is `U`-close to `F i x₀`. -/
def EquicontinuousAt (F : ι → X → α) (x₀ : X) : Prop :=
∀ U ∈ 𝓤 α, ∀ᶠ x in 𝓝 x₀, ∀ i, (F i x₀, F i x) ∈ U
/-- We say that a set `H : Set (X → α)` of functions is equicontinuous at a point if the family
`(↑) : ↥H → (X → α)` is equicontinuous at that point. -/
protected abbrev Set.EquicontinuousAt (H : Set <| X → α) (x₀ : X) : Prop :=
EquicontinuousAt ((↑) : H → X → α) x₀
/-- A family `F : ι → X → α` of functions from a topological space to a uniform space is
*equicontinuous at `x₀ : X` within `S : Set X`* if, for all entourages `U ∈ 𝓤 α`, there is a
neighborhood `V` of `x₀` within `S` such that, for all `x ∈ V` and for all `i : ι`, `F i x` is
`U`-close to `F i x₀`. -/
def EquicontinuousWithinAt (F : ι → X → α) (S : Set X) (x₀ : X) : Prop :=
∀ U ∈ 𝓤 α, ∀ᶠ x in 𝓝[S] x₀, ∀ i, (F i x₀, F i x) ∈ U
/-- We say that a set `H : Set (X → α)` of functions is equicontinuous at a point within a subset
if the family `(↑) : ↥H → (X → α)` is equicontinuous at that point within that same subset. -/
protected abbrev Set.EquicontinuousWithinAt (H : Set <| X → α) (S : Set X) (x₀ : X) : Prop :=
EquicontinuousWithinAt ((↑) : H → X → α) S x₀
/-- A family `F : ι → X → α` of functions from a topological space to a uniform space is
*equicontinuous* on all of `X` if it is equicontinuous at each point of `X`. -/
def Equicontinuous (F : ι → X → α) : Prop :=
∀ x₀, EquicontinuousAt F x₀
/-- We say that a set `H : Set (X → α)` of functions is equicontinuous if the family
`(↑) : ↥H → (X → α)` is equicontinuous. -/
protected abbrev Set.Equicontinuous (H : Set <| X → α) : Prop :=
Equicontinuous ((↑) : H → X → α)
/-- A family `F : ι → X → α` of functions from a topological space to a uniform space is
*equicontinuous on `S : Set X`* if it is equicontinuous *within `S`* at each point of `S`. -/
def EquicontinuousOn (F : ι → X → α) (S : Set X) : Prop :=
∀ x₀ ∈ S, EquicontinuousWithinAt F S x₀
/-- We say that a set `H : Set (X → α)` of functions is equicontinuous on a subset if the family
`(↑) : ↥H → (X → α)` is equicontinuous on that subset. -/
protected abbrev Set.EquicontinuousOn (H : Set <| X → α) (S : Set X) : Prop :=
EquicontinuousOn ((↑) : H → X → α) S
/-- A family `F : ι → β → α` of functions between uniform spaces is *uniformly equicontinuous* if,
for all entourages `U ∈ 𝓤 α`, there is an entourage `V ∈ 𝓤 β` such that, whenever `x` and `y` are
`V`-close, we have that, *for all `i : ι`*, `F i x` is `U`-close to `F i y`. -/
def UniformEquicontinuous (F : ι → β → α) : Prop :=
∀ U ∈ 𝓤 α, ∀ᶠ xy : β × β in 𝓤 β, ∀ i, (F i xy.1, F i xy.2) ∈ U
/-- We say that a set `H : Set (X → α)` of functions is uniformly equicontinuous if the family
`(↑) : ↥H → (X → α)` is uniformly equicontinuous. -/
protected abbrev Set.UniformEquicontinuous (H : Set <| β → α) : Prop :=
UniformEquicontinuous ((↑) : H → β → α)
/-- A family `F : ι → β → α` of functions between uniform spaces is
*uniformly equicontinuous on `S : Set β`* if, for all entourages `U ∈ 𝓤 α`, there is a relative
entourage `V ∈ 𝓤 β ⊓ 𝓟 (S ×ˢ S)` such that, whenever `x` and `y` are `V`-close, we have that,
*for all `i : ι`*, `F i x` is `U`-close to `F i y`. -/
def UniformEquicontinuousOn (F : ι → β → α) (S : Set β) : Prop :=
∀ U ∈ 𝓤 α, ∀ᶠ xy : β × β in 𝓤 β ⊓ 𝓟 (S ×ˢ S), ∀ i, (F i xy.1, F i xy.2) ∈ U
/-- We say that a set `H : Set (X → α)` of functions is uniformly equicontinuous on a subset if the
family `(↑) : ↥H → (X → α)` is uniformly equicontinuous on that subset. -/
protected abbrev Set.UniformEquicontinuousOn (H : Set <| β → α) (S : Set β) : Prop :=
UniformEquicontinuousOn ((↑) : H → β → α) S
lemma EquicontinuousAt.equicontinuousWithinAt {F : ι → X → α} {x₀ : X} (H : EquicontinuousAt F x₀)
(S : Set X) : EquicontinuousWithinAt F S x₀ :=
fun U hU ↦ (H U hU).filter_mono inf_le_left
lemma EquicontinuousWithinAt.mono {F : ι → X → α} {x₀ : X} {S T : Set X}
(H : EquicontinuousWithinAt F T x₀) (hST : S ⊆ T) : EquicontinuousWithinAt F S x₀ :=
fun U hU ↦ (H U hU).filter_mono <| nhdsWithin_mono x₀ hST
@[simp] lemma equicontinuousWithinAt_univ (F : ι → X → α) (x₀ : X) :
EquicontinuousWithinAt F univ x₀ ↔ EquicontinuousAt F x₀ := by
rw [EquicontinuousWithinAt, EquicontinuousAt, nhdsWithin_univ]
lemma equicontinuousAt_restrict_iff (F : ι → X → α) {S : Set X} (x₀ : S) :
EquicontinuousAt (S.restrict ∘ F) x₀ ↔ EquicontinuousWithinAt F S x₀ := by
simp [EquicontinuousWithinAt, EquicontinuousAt,
← eventually_nhds_subtype_iff]
lemma Equicontinuous.equicontinuousOn {F : ι → X → α} (H : Equicontinuous F)
(S : Set X) : EquicontinuousOn F S :=
fun x _ ↦ (H x).equicontinuousWithinAt S
lemma EquicontinuousOn.mono {F : ι → X → α} {S T : Set X}
(H : EquicontinuousOn F T) (hST : S ⊆ T) : EquicontinuousOn F S :=
fun x hx ↦ (H x (hST hx)).mono hST
lemma equicontinuousOn_univ (F : ι → X → α) :
EquicontinuousOn F univ ↔ Equicontinuous F := by
simp [EquicontinuousOn, Equicontinuous]
lemma equicontinuous_restrict_iff (F : ι → X → α) {S : Set X} :
Equicontinuous (S.restrict ∘ F) ↔ EquicontinuousOn F S := by
simp [Equicontinuous, EquicontinuousOn, equicontinuousAt_restrict_iff]
lemma UniformEquicontinuous.uniformEquicontinuousOn {F : ι → β → α} (H : UniformEquicontinuous F)
(S : Set β) : UniformEquicontinuousOn F S :=
fun U hU ↦ (H U hU).filter_mono inf_le_left
lemma UniformEquicontinuousOn.mono {F : ι → β → α} {S T : Set β}
(H : UniformEquicontinuousOn F T) (hST : S ⊆ T) : UniformEquicontinuousOn F S :=
fun U hU ↦ (H U hU).filter_mono <| by gcongr
lemma uniformEquicontinuousOn_univ (F : ι → β → α) :
UniformEquicontinuousOn F univ ↔ UniformEquicontinuous F := by
simp [UniformEquicontinuousOn, UniformEquicontinuous]
lemma uniformEquicontinuous_restrict_iff (F : ι → β → α) {S : Set β} :
UniformEquicontinuous (S.restrict ∘ F) ↔ UniformEquicontinuousOn F S := by
rw [UniformEquicontinuous, UniformEquicontinuousOn]
conv in _ ⊓ _ => rw [← Subtype.range_val (s := S), ← range_prodMap, ← map_comap]
rfl
/-!
### Empty index type
-/
@[simp]
lemma equicontinuousAt_empty [h : IsEmpty ι] (F : ι → X → α) (x₀ : X) :
EquicontinuousAt F x₀ :=
fun _ _ ↦ Eventually.of_forall (fun _ ↦ h.elim)
@[simp]
lemma equicontinuousWithinAt_empty [h : IsEmpty ι] (F : ι → X → α) (S : Set X) (x₀ : X) :
EquicontinuousWithinAt F S x₀ :=
fun _ _ ↦ Eventually.of_forall (fun _ ↦ h.elim)
@[simp]
lemma equicontinuous_empty [IsEmpty ι] (F : ι → X → α) :
Equicontinuous F :=
equicontinuousAt_empty F
@[simp]
lemma equicontinuousOn_empty [IsEmpty ι] (F : ι → X → α) (S : Set X) :
EquicontinuousOn F S :=
fun x₀ _ ↦ equicontinuousWithinAt_empty F S x₀
@[simp]
lemma uniformEquicontinuous_empty [h : IsEmpty ι] (F : ι → β → α) :
UniformEquicontinuous F :=
fun _ _ ↦ Eventually.of_forall (fun _ ↦ h.elim)
@[simp]
lemma uniformEquicontinuousOn_empty [h : IsEmpty ι] (F : ι → β → α) (S : Set β) :
UniformEquicontinuousOn F S :=
fun _ _ ↦ Eventually.of_forall (fun _ ↦ h.elim)
/-!
### Finite index type
-/
theorem equicontinuousAt_finite [Finite ι] {F : ι → X → α} {x₀ : X} :
EquicontinuousAt F x₀ ↔ ∀ i, ContinuousAt (F i) x₀ := by
simp [EquicontinuousAt, ContinuousAt, (nhds_basis_uniformity' (𝓤 α).basis_sets).tendsto_right_iff,
UniformSpace.ball, @forall_swap _ ι]
theorem equicontinuousWithinAt_finite [Finite ι] {F : ι → X → α} {S : Set X} {x₀ : X} :
EquicontinuousWithinAt F S x₀ ↔ ∀ i, ContinuousWithinAt (F i) S x₀ := by
simp [EquicontinuousWithinAt, ContinuousWithinAt,
(nhds_basis_uniformity' (𝓤 α).basis_sets).tendsto_right_iff, UniformSpace.ball,
@forall_swap _ ι]
theorem equicontinuous_finite [Finite ι] {F : ι → X → α} :
Equicontinuous F ↔ ∀ i, Continuous (F i) := by
simp only [Equicontinuous, equicontinuousAt_finite, continuous_iff_continuousAt, @forall_swap ι]
theorem equicontinuousOn_finite [Finite ι] {F : ι → X → α} {S : Set X} :
EquicontinuousOn F S ↔ ∀ i, ContinuousOn (F i) S := by
simp only [EquicontinuousOn, equicontinuousWithinAt_finite, ContinuousOn, @forall_swap ι]
theorem uniformEquicontinuous_finite [Finite ι] {F : ι → β → α} :
UniformEquicontinuous F ↔ ∀ i, UniformContinuous (F i) := by
simp only [UniformEquicontinuous, eventually_all, @forall_swap _ ι]; rfl
theorem uniformEquicontinuousOn_finite [Finite ι] {F : ι → β → α} {S : Set β} :
UniformEquicontinuousOn F S ↔ ∀ i, UniformContinuousOn (F i) S := by
simp only [UniformEquicontinuousOn, eventually_all, @forall_swap _ ι]; rfl
/-!
### Index type with a unique element
-/
theorem equicontinuousAt_unique [Unique ι] {F : ι → X → α} {x : X} :
EquicontinuousAt F x ↔ ContinuousAt (F default) x :=
equicontinuousAt_finite.trans Unique.forall_iff
theorem equicontinuousWithinAt_unique [Unique ι] {F : ι → X → α} {S : Set X} {x : X} :
EquicontinuousWithinAt F S x ↔ ContinuousWithinAt (F default) S x :=
equicontinuousWithinAt_finite.trans Unique.forall_iff
theorem equicontinuous_unique [Unique ι] {F : ι → X → α} :
Equicontinuous F ↔ Continuous (F default) :=
equicontinuous_finite.trans Unique.forall_iff
theorem equicontinuousOn_unique [Unique ι] {F : ι → X → α} {S : Set X} :
EquicontinuousOn F S ↔ ContinuousOn (F default) S :=
equicontinuousOn_finite.trans Unique.forall_iff
theorem uniformEquicontinuous_unique [Unique ι] {F : ι → β → α} :
UniformEquicontinuous F ↔ UniformContinuous (F default) :=
uniformEquicontinuous_finite.trans Unique.forall_iff
theorem uniformEquicontinuousOn_unique [Unique ι] {F : ι → β → α} {S : Set β} :
UniformEquicontinuousOn F S ↔ UniformContinuousOn (F default) S :=
uniformEquicontinuousOn_finite.trans Unique.forall_iff
/-- Reformulation of equicontinuity at `x₀` within a set `S`, comparing two variables near `x₀`
instead of comparing only one with `x₀`. -/
theorem equicontinuousWithinAt_iff_pair {F : ι → X → α} {S : Set X} {x₀ : X} (hx₀ : x₀ ∈ S) :
EquicontinuousWithinAt F S x₀ ↔
∀ U ∈ 𝓤 α, ∃ V ∈ 𝓝[S] x₀, ∀ x ∈ V, ∀ y ∈ V, ∀ i, (F i x, F i y) ∈ U := by
constructor <;> intro H U hU
· rcases comp_symm_mem_uniformity_sets hU with ⟨V, hV, hVsymm, hVU⟩
refine ⟨_, H V hV, fun x hx y hy i => hVU (prodMk_mem_compRel ?_ (hy i))⟩
exact hVsymm.mk_mem_comm.mp (hx i)
· rcases H U hU with ⟨V, hV, hVU⟩
filter_upwards [hV] using fun x hx i => hVU x₀ (mem_of_mem_nhdsWithin hx₀ hV) x hx i
/-- Reformulation of equicontinuity at `x₀` comparing two variables near `x₀` instead of comparing
only one with `x₀`. -/
theorem equicontinuousAt_iff_pair {F : ι → X → α} {x₀ : X} :
EquicontinuousAt F x₀ ↔
∀ U ∈ 𝓤 α, ∃ V ∈ 𝓝 x₀, ∀ x ∈ V, ∀ y ∈ V, ∀ i, (F i x, F i y) ∈ U := by
simp_rw [← equicontinuousWithinAt_univ, equicontinuousWithinAt_iff_pair (mem_univ x₀),
nhdsWithin_univ]
/-- Uniform equicontinuity implies equicontinuity. -/
theorem UniformEquicontinuous.equicontinuous {F : ι → β → α} (h : UniformEquicontinuous F) :
Equicontinuous F := fun x₀ U hU ↦
mem_of_superset (ball_mem_nhds x₀ (h U hU)) fun _ hx i ↦ hx i
/-- Uniform equicontinuity on a subset implies equicontinuity on that subset. -/
theorem UniformEquicontinuousOn.equicontinuousOn {F : ι → β → α} {S : Set β}
(h : UniformEquicontinuousOn F S) :
EquicontinuousOn F S := fun _ hx₀ U hU ↦
mem_of_superset (ball_mem_nhdsWithin hx₀ (h U hU)) fun _ hx i ↦ hx i
/-- Each function of a family equicontinuous at `x₀` is continuous at `x₀`. -/
theorem EquicontinuousAt.continuousAt {F : ι → X → α} {x₀ : X} (h : EquicontinuousAt F x₀) (i : ι) :
ContinuousAt (F i) x₀ :=
(UniformSpace.hasBasis_nhds _).tendsto_right_iff.2 fun U ⟨hU, _⟩ ↦ (h U hU).mono fun _x hx ↦ hx i
/-- Each function of a family equicontinuous at `x₀` within `S` is continuous at `x₀` within `S`. -/
theorem EquicontinuousWithinAt.continuousWithinAt {F : ι → X → α} {S : Set X} {x₀ : X}
(h : EquicontinuousWithinAt F S x₀) (i : ι) :
ContinuousWithinAt (F i) S x₀ :=
(UniformSpace.hasBasis_nhds _).tendsto_right_iff.2 fun U ⟨hU, _⟩ ↦ (h U hU).mono fun _x hx ↦ hx i
protected theorem Set.EquicontinuousAt.continuousAt_of_mem {H : Set <| X → α} {x₀ : X}
(h : H.EquicontinuousAt x₀) {f : X → α} (hf : f ∈ H) : ContinuousAt f x₀ :=
h.continuousAt ⟨f, hf⟩
protected theorem Set.EquicontinuousWithinAt.continuousWithinAt_of_mem {H : Set <| X → α}
{S : Set X} {x₀ : X} (h : H.EquicontinuousWithinAt S x₀) {f : X → α} (hf : f ∈ H) :
ContinuousWithinAt f S x₀ :=
h.continuousWithinAt ⟨f, hf⟩
/-- Each function of an equicontinuous family is continuous. -/
theorem Equicontinuous.continuous {F : ι → X → α} (h : Equicontinuous F) (i : ι) :
Continuous (F i) :=
continuous_iff_continuousAt.mpr fun x => (h x).continuousAt i
/-- Each function of a family equicontinuous on `S` is continuous on `S`. -/
theorem EquicontinuousOn.continuousOn {F : ι → X → α} {S : Set X} (h : EquicontinuousOn F S)
(i : ι) : ContinuousOn (F i) S :=
fun x hx ↦ (h x hx).continuousWithinAt i
protected theorem Set.Equicontinuous.continuous_of_mem {H : Set <| X → α} (h : H.Equicontinuous)
{f : X → α} (hf : f ∈ H) : Continuous f :=
h.continuous ⟨f, hf⟩
protected theorem Set.EquicontinuousOn.continuousOn_of_mem {H : Set <| X → α} {S : Set X}
(h : H.EquicontinuousOn S) {f : X → α} (hf : f ∈ H) : ContinuousOn f S :=
h.continuousOn ⟨f, hf⟩
/-- Each function of a uniformly equicontinuous family is uniformly continuous. -/
theorem UniformEquicontinuous.uniformContinuous {F : ι → β → α} (h : UniformEquicontinuous F)
(i : ι) : UniformContinuous (F i) := fun U hU =>
mem_map.mpr (mem_of_superset (h U hU) fun _ hxy => hxy i)
/-- Each function of a family uniformly equicontinuous on `S` is uniformly continuous on `S`. -/
theorem UniformEquicontinuousOn.uniformContinuousOn {F : ι → β → α} {S : Set β}
(h : UniformEquicontinuousOn F S) (i : ι) :
UniformContinuousOn (F i) S := fun U hU =>
mem_map.mpr (mem_of_superset (h U hU) fun _ hxy => hxy i)
protected theorem Set.UniformEquicontinuous.uniformContinuous_of_mem {H : Set <| β → α}
(h : H.UniformEquicontinuous) {f : β → α} (hf : f ∈ H) : UniformContinuous f :=
h.uniformContinuous ⟨f, hf⟩
protected theorem Set.UniformEquicontinuousOn.uniformContinuousOn_of_mem {H : Set <| β → α}
{S : Set β} (h : H.UniformEquicontinuousOn S) {f : β → α} (hf : f ∈ H) :
UniformContinuousOn f S :=
h.uniformContinuousOn ⟨f, hf⟩
/-- Taking sub-families preserves equicontinuity at a point. -/
theorem EquicontinuousAt.comp {F : ι → X → α} {x₀ : X} (h : EquicontinuousAt F x₀) (u : κ → ι) :
EquicontinuousAt (F ∘ u) x₀ := fun U hU => (h U hU).mono fun _ H k => H (u k)
/-- Taking sub-families preserves equicontinuity at a point within a subset. -/
theorem EquicontinuousWithinAt.comp {F : ι → X → α} {S : Set X} {x₀ : X}
(h : EquicontinuousWithinAt F S x₀) (u : κ → ι) :
EquicontinuousWithinAt (F ∘ u) S x₀ :=
fun U hU ↦ (h U hU).mono fun _ H k => H (u k)
protected theorem Set.EquicontinuousAt.mono {H H' : Set <| X → α} {x₀ : X}
(h : H.EquicontinuousAt x₀) (hH : H' ⊆ H) : H'.EquicontinuousAt x₀ :=
h.comp (inclusion hH)
protected theorem Set.EquicontinuousWithinAt.mono {H H' : Set <| X → α} {S : Set X} {x₀ : X}
(h : H.EquicontinuousWithinAt S x₀) (hH : H' ⊆ H) : H'.EquicontinuousWithinAt S x₀ :=
h.comp (inclusion hH)
/-- Taking sub-families preserves equicontinuity. -/
theorem Equicontinuous.comp {F : ι → X → α} (h : Equicontinuous F) (u : κ → ι) :
Equicontinuous (F ∘ u) := fun x => (h x).comp u
/-- Taking sub-families preserves equicontinuity on a subset. -/
theorem EquicontinuousOn.comp {F : ι → X → α} {S : Set X} (h : EquicontinuousOn F S) (u : κ → ι) :
EquicontinuousOn (F ∘ u) S := fun x hx ↦ (h x hx).comp u
protected theorem Set.Equicontinuous.mono {H H' : Set <| X → α} (h : H.Equicontinuous)
(hH : H' ⊆ H) : H'.Equicontinuous :=
h.comp (inclusion hH)
protected theorem Set.EquicontinuousOn.mono {H H' : Set <| X → α} {S : Set X}
(h : H.EquicontinuousOn S) (hH : H' ⊆ H) : H'.EquicontinuousOn S :=
h.comp (inclusion hH)
/-- Taking sub-families preserves uniform equicontinuity. -/
theorem UniformEquicontinuous.comp {F : ι → β → α} (h : UniformEquicontinuous F) (u : κ → ι) :
UniformEquicontinuous (F ∘ u) := fun U hU => (h U hU).mono fun _ H k => H (u k)
/-- Taking sub-families preserves uniform equicontinuity on a subset. -/
theorem UniformEquicontinuousOn.comp {F : ι → β → α} {S : Set β} (h : UniformEquicontinuousOn F S)
(u : κ → ι) : UniformEquicontinuousOn (F ∘ u) S :=
fun U hU ↦ (h U hU).mono fun _ H k => H (u k)
protected theorem Set.UniformEquicontinuous.mono {H H' : Set <| β → α} (h : H.UniformEquicontinuous)
(hH : H' ⊆ H) : H'.UniformEquicontinuous :=
h.comp (inclusion hH)
protected theorem Set.UniformEquicontinuousOn.mono {H H' : Set <| β → α} {S : Set β}
(h : H.UniformEquicontinuousOn S) (hH : H' ⊆ H) : H'.UniformEquicontinuousOn S :=
h.comp (inclusion hH)
/-- A family `𝓕 : ι → X → α` is equicontinuous at `x₀` iff `range 𝓕` is equicontinuous at `x₀`,
i.e the family `(↑) : range F → X → α` is equicontinuous at `x₀`. -/
theorem equicontinuousAt_iff_range {F : ι → X → α} {x₀ : X} :
EquicontinuousAt F x₀ ↔ EquicontinuousAt ((↑) : range F → X → α) x₀ := by
simp only [EquicontinuousAt, forall_subtype_range_iff]
/-- A family `𝓕 : ι → X → α` is equicontinuous at `x₀` within `S` iff `range 𝓕` is equicontinuous
at `x₀` within `S`, i.e the family `(↑) : range F → X → α` is equicontinuous at `x₀` within `S`. -/
theorem equicontinuousWithinAt_iff_range {F : ι → X → α} {S : Set X} {x₀ : X} :
EquicontinuousWithinAt F S x₀ ↔ EquicontinuousWithinAt ((↑) : range F → X → α) S x₀ := by
simp only [EquicontinuousWithinAt, forall_subtype_range_iff]
/-- A family `𝓕 : ι → X → α` is equicontinuous iff `range 𝓕` is equicontinuous,
i.e the family `(↑) : range F → X → α` is equicontinuous. -/
theorem equicontinuous_iff_range {F : ι → X → α} :
Equicontinuous F ↔ Equicontinuous ((↑) : range F → X → α) :=
forall_congr' fun _ => equicontinuousAt_iff_range
/-- A family `𝓕 : ι → X → α` is equicontinuous on `S` iff `range 𝓕` is equicontinuous on `S`,
i.e the family `(↑) : range F → X → α` is equicontinuous on `S`. -/
theorem equicontinuousOn_iff_range {F : ι → X → α} {S : Set X} :
EquicontinuousOn F S ↔ EquicontinuousOn ((↑) : range F → X → α) S :=
forall_congr' fun _ ↦ forall_congr' fun _ ↦ equicontinuousWithinAt_iff_range
/-- A family `𝓕 : ι → β → α` is uniformly equicontinuous iff `range 𝓕` is uniformly equicontinuous,
i.e the family `(↑) : range F → β → α` is uniformly equicontinuous. -/
theorem uniformEquicontinuous_iff_range {F : ι → β → α} :
UniformEquicontinuous F ↔ UniformEquicontinuous ((↑) : range F → β → α) :=
⟨fun h => by rw [← comp_rangeSplitting F]; exact h.comp _, fun h =>
h.comp (rangeFactorization F)⟩
/-- A family `𝓕 : ι → β → α` is uniformly equicontinuous on `S` iff `range 𝓕` is uniformly
equicontinuous on `S`, i.e the family `(↑) : range F → β → α` is uniformly equicontinuous on `S`. -/
theorem uniformEquicontinuousOn_iff_range {F : ι → β → α} {S : Set β} :
UniformEquicontinuousOn F S ↔ UniformEquicontinuousOn ((↑) : range F → β → α) S :=
⟨fun h => by rw [← comp_rangeSplitting F]; exact h.comp _, fun h =>
h.comp (rangeFactorization F)⟩
section
open UniformFun
/-- A family `𝓕 : ι → X → α` is equicontinuous at `x₀` iff the function `swap 𝓕 : X → ι → α` is
continuous at `x₀` *when `ι → α` is equipped with the topology of uniform convergence*. This is
very useful for developing the equicontinuity API, but it should not be used directly for other
purposes. -/
theorem equicontinuousAt_iff_continuousAt {F : ι → X → α} {x₀ : X} :
EquicontinuousAt F x₀ ↔ ContinuousAt (ofFun ∘ Function.swap F : X → ι →ᵤ α) x₀ := by
rw [ContinuousAt, (UniformFun.hasBasis_nhds ι α _).tendsto_right_iff]
rfl
/-- A family `𝓕 : ι → X → α` is equicontinuous at `x₀` within `S` iff the function
`swap 𝓕 : X → ι → α` is continuous at `x₀` within `S`
*when `ι → α` is equipped with the topology of uniform convergence*. This is very useful for
developing the equicontinuity API, but it should not be used directly for other purposes. -/
theorem equicontinuousWithinAt_iff_continuousWithinAt {F : ι → X → α} {S : Set X} {x₀ : X} :
EquicontinuousWithinAt F S x₀ ↔
ContinuousWithinAt (ofFun ∘ Function.swap F : X → ι →ᵤ α) S x₀ := by
rw [ContinuousWithinAt, (UniformFun.hasBasis_nhds ι α _).tendsto_right_iff]
rfl
/-- A family `𝓕 : ι → X → α` is equicontinuous iff the function `swap 𝓕 : X → ι → α` is
continuous *when `ι → α` is equipped with the topology of uniform convergence*. This is
very useful for developing the equicontinuity API, but it should not be used directly for other
purposes. -/
theorem equicontinuous_iff_continuous {F : ι → X → α} :
Equicontinuous F ↔ Continuous (ofFun ∘ Function.swap F : X → ι →ᵤ α) := by
simp_rw [Equicontinuous, continuous_iff_continuousAt, equicontinuousAt_iff_continuousAt]
/-- A family `𝓕 : ι → X → α` is equicontinuous on `S` iff the function `swap 𝓕 : X → ι → α` is
continuous on `S` *when `ι → α` is equipped with the topology of uniform convergence*. This is
very useful for developing the equicontinuity API, but it should not be used directly for other
purposes. -/
theorem equicontinuousOn_iff_continuousOn {F : ι → X → α} {S : Set X} :
EquicontinuousOn F S ↔ ContinuousOn (ofFun ∘ Function.swap F : X → ι →ᵤ α) S := by
simp_rw [EquicontinuousOn, ContinuousOn, equicontinuousWithinAt_iff_continuousWithinAt]
/-- A family `𝓕 : ι → β → α` is uniformly equicontinuous iff the function `swap 𝓕 : β → ι → α` is
uniformly continuous *when `ι → α` is equipped with the uniform structure of uniform convergence*.
This is very useful for developing the equicontinuity API, but it should not be used directly
for other purposes. -/
theorem uniformEquicontinuous_iff_uniformContinuous {F : ι → β → α} :
UniformEquicontinuous F ↔ UniformContinuous (ofFun ∘ Function.swap F : β → ι →ᵤ α) := by
rw [UniformContinuous, (UniformFun.hasBasis_uniformity ι α).tendsto_right_iff]
rfl
/-- A family `𝓕 : ι → β → α` is uniformly equicontinuous on `S` iff the function
`swap 𝓕 : β → ι → α` is uniformly continuous on `S`
*when `ι → α` is equipped with the uniform structure of uniform convergence*. This is very useful
for developing the equicontinuity API, but it should not be used directly for other purposes. -/
theorem uniformEquicontinuousOn_iff_uniformContinuousOn {F : ι → β → α} {S : Set β} :
UniformEquicontinuousOn F S ↔ UniformContinuousOn (ofFun ∘ Function.swap F : β → ι →ᵤ α) S := by
rw [UniformContinuousOn, (UniformFun.hasBasis_uniformity ι α).tendsto_right_iff]
rfl
theorem equicontinuousWithinAt_iInf_rng {u : κ → UniformSpace α'} {F : ι → X → α'}
{S : Set X} {x₀ : X} : EquicontinuousWithinAt (uα := ⨅ k, u k) F S x₀ ↔
∀ k, EquicontinuousWithinAt (uα := u k) F S x₀ := by
simp only [equicontinuousWithinAt_iff_continuousWithinAt (uα := _), topologicalSpace]
unfold ContinuousWithinAt
rw [UniformFun.iInf_eq, toTopologicalSpace_iInf, nhds_iInf, tendsto_iInf]
theorem equicontinuousAt_iInf_rng {u : κ → UniformSpace α'} {F : ι → X → α'}
{x₀ : X} :
EquicontinuousAt (uα := ⨅ k, u k) F x₀ ↔ ∀ k, EquicontinuousAt (uα := u k) F x₀ := by
simp only [← equicontinuousWithinAt_univ (uα := _), equicontinuousWithinAt_iInf_rng]
theorem equicontinuous_iInf_rng {u : κ → UniformSpace α'} {F : ι → X → α'} :
Equicontinuous (uα := ⨅ k, u k) F ↔ ∀ k, Equicontinuous (uα := u k) F := by
simp_rw [equicontinuous_iff_continuous (uα := _), UniformFun.topologicalSpace]
rw [UniformFun.iInf_eq, toTopologicalSpace_iInf, continuous_iInf_rng]
theorem equicontinuousOn_iInf_rng {u : κ → UniformSpace α'} {F : ι → X → α'}
{S : Set X} :
EquicontinuousOn (uα := ⨅ k, u k) F S ↔ ∀ k, EquicontinuousOn (uα := u k) F S := by
simp_rw [EquicontinuousOn, equicontinuousWithinAt_iInf_rng, @forall_swap _ κ]
theorem uniformEquicontinuous_iInf_rng {u : κ → UniformSpace α'} {F : ι → β → α'} :
| UniformEquicontinuous (uα := ⨅ k, u k) F ↔ ∀ k, UniformEquicontinuous (uα := u k) F := by
simp_rw [uniformEquicontinuous_iff_uniformContinuous (uα := _)]
rw [UniformFun.iInf_eq, uniformContinuous_iInf_rng]
| Mathlib/Topology/UniformSpace/Equicontinuity.lean | 556 | 559 |
/-
Copyright (c) 2020 Anne Baanen. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Anne Baanen, Filippo A. E. Nuccio
-/
import Mathlib.RingTheory.Localization.Integer
import Mathlib.RingTheory.Localization.Submodule
/-!
# Fractional ideals
This file defines fractional ideals of an integral domain and proves basic facts about them.
## Main definitions
Let `S` be a submonoid of an integral domain `R` and `P` the localization of `R` at `S`.
* `IsFractional` defines which `R`-submodules of `P` are fractional ideals
* `FractionalIdeal S P` is the type of fractional ideals in `P`
* a coercion `coeIdeal : Ideal R → FractionalIdeal S P`
* `CommSemiring (FractionalIdeal S P)` instance:
the typical ideal operations generalized to fractional ideals
* `Lattice (FractionalIdeal S P)` instance
## Main statements
* `mul_left_mono` and `mul_right_mono` state that ideal multiplication is monotone
* `mul_div_self_cancel_iff` states that `1 / I` is the inverse of `I` if one exists
## Implementation notes
Fractional ideals are considered equal when they contain the same elements,
independent of the denominator `a : R` such that `a I ⊆ R`.
Thus, we define `FractionalIdeal` to be the subtype of the predicate `IsFractional`,
instead of having `FractionalIdeal` be a structure of which `a` is a field.
Most definitions in this file specialize operations from submodules to fractional ideals,
proving that the result of this operation is fractional if the input is fractional.
Exceptions to this rule are defining `(+) := (⊔)` and `⊥ := 0`,
in order to re-use their respective proof terms.
We can still use `simp` to show `↑I + ↑J = ↑(I + J)` and `↑⊥ = ↑0`.
Many results in fact do not need that `P` is a localization, only that `P` is an
`R`-algebra. We omit the `IsLocalization` parameter whenever this is practical.
Similarly, we don't assume that the localization is a field until we need it to
define ideal quotients. When this assumption is needed, we replace `S` with `R⁰`,
making the localization a field.
## References
* https://en.wikipedia.org/wiki/Fractional_ideal
## Tags
fractional ideal, fractional ideals, invertible ideal
-/
open IsLocalization Pointwise nonZeroDivisors
section Defs
variable {R : Type*} [CommRing R] {S : Submonoid R} {P : Type*} [CommRing P]
variable [Algebra R P]
variable (S)
/-- A submodule `I` is a fractional ideal if `a I ⊆ R` for some `a ≠ 0`. -/
def IsFractional (I : Submodule R P) :=
∃ a ∈ S, ∀ b ∈ I, IsInteger R (a • b)
variable (P)
/-- The fractional ideals of a domain `R` are ideals of `R` divided by some `a ∈ R`.
More precisely, let `P` be a localization of `R` at some submonoid `S`,
then a fractional ideal `I ⊆ P` is an `R`-submodule of `P`,
such that there is a nonzero `a : R` with `a I ⊆ R`.
-/
def FractionalIdeal :=
{ I : Submodule R P // IsFractional S I }
end Defs
namespace FractionalIdeal
open Set Submodule
variable {R : Type*} [CommRing R] {S : Submonoid R} {P : Type*} [CommRing P]
variable [Algebra R P]
/-- Map a fractional ideal `I` to a submodule by forgetting that `∃ a, a I ⊆ R`.
This implements the coercion `FractionalIdeal S P → Submodule R P`.
-/
@[coe]
def coeToSubmodule (I : FractionalIdeal S P) : Submodule R P :=
I.val
/-- Map a fractional ideal `I` to a submodule by forgetting that `∃ a, a I ⊆ R`.
This coercion is typically called `coeToSubmodule` in lemma names
(or `coe` when the coercion is clear from the context),
not to be confused with `IsLocalization.coeSubmodule : Ideal R → Submodule R P`
(which we use to define `coe : Ideal R → FractionalIdeal S P`).
-/
instance : CoeOut (FractionalIdeal S P) (Submodule R P) :=
⟨coeToSubmodule⟩
protected theorem isFractional (I : FractionalIdeal S P) : IsFractional S (I : Submodule R P) :=
I.prop
/-- An element of `S` such that `I.den • I = I.num`, see `FractionalIdeal.num` and
`FractionalIdeal.den_mul_self_eq_num`. -/
noncomputable def den (I : FractionalIdeal S P) : S :=
⟨I.2.choose, I.2.choose_spec.1⟩
/-- An ideal of `R` such that `I.den • I = I.num`, see `FractionalIdeal.den` and
`FractionalIdeal.den_mul_self_eq_num`. -/
noncomputable def num (I : FractionalIdeal S P) : Ideal R :=
(I.den • (I : Submodule R P)).comap (Algebra.linearMap R P)
theorem den_mul_self_eq_num (I : FractionalIdeal S P) :
I.den • (I : Submodule R P) = Submodule.map (Algebra.linearMap R P) I.num := by
rw [den, num, Submodule.map_comap_eq]
refine (inf_of_le_right ?_).symm
rintro _ ⟨a, ha, rfl⟩
exact I.2.choose_spec.2 a ha
/-- The linear equivalence between the fractional ideal `I` and the integral ideal `I.num`
defined by mapping `x` to `den I • x`. -/
noncomputable def equivNum [Nontrivial P] [NoZeroSMulDivisors R P]
{I : FractionalIdeal S P} (h_nz : (I.den : R) ≠ 0) : I ≃ₗ[R] I.num := by
refine LinearEquiv.trans
(LinearEquiv.ofBijective ((DistribMulAction.toLinearMap R P I.den).restrict fun _ hx ↦ ?_)
⟨fun _ _ hxy ↦ ?_, fun ⟨y, hy⟩ ↦ ?_⟩)
(Submodule.equivMapOfInjective (Algebra.linearMap R P)
(FaithfulSMul.algebraMap_injective R P) (num I)).symm
· rw [← den_mul_self_eq_num]
exact Submodule.smul_mem_pointwise_smul _ _ _ hx
· simp_rw [LinearMap.restrict_apply, DistribMulAction.toLinearMap_apply, Subtype.mk.injEq] at hxy
rwa [Submonoid.smul_def, Submonoid.smul_def, smul_right_inj h_nz, SetCoe.ext_iff] at hxy
· rw [← den_mul_self_eq_num] at hy
obtain ⟨x, hx, hxy⟩ := hy
exact ⟨⟨x, hx⟩, by simp_rw [LinearMap.restrict_apply, Subtype.ext_iff, ← hxy]; rfl⟩
section SetLike
instance : SetLike (FractionalIdeal S P) P where
coe I := ↑(I : Submodule R P)
coe_injective' := SetLike.coe_injective.comp Subtype.coe_injective
@[simp]
theorem mem_coe {I : FractionalIdeal S P} {x : P} : x ∈ (I : Submodule R P) ↔ x ∈ I :=
Iff.rfl
@[ext]
theorem ext {I J : FractionalIdeal S P} : (∀ x, x ∈ I ↔ x ∈ J) → I = J :=
SetLike.ext
@[simp]
theorem equivNum_apply [Nontrivial P] [NoZeroSMulDivisors R P] {I : FractionalIdeal S P}
(h_nz : (I.den : R) ≠ 0) (x : I) :
algebraMap R P (equivNum h_nz x) = I.den • x := by
change Algebra.linearMap R P _ = _
rw [equivNum, LinearEquiv.trans_apply, LinearEquiv.ofBijective_apply, LinearMap.restrict_apply,
Submodule.map_equivMapOfInjective_symm_apply, Subtype.coe_mk,
DistribMulAction.toLinearMap_apply]
/-- Copy of a `FractionalIdeal` with a new underlying set equal to the old one.
Useful to fix definitional equalities. -/
protected def copy (p : FractionalIdeal S P) (s : Set P) (hs : s = ↑p) : FractionalIdeal S P :=
⟨Submodule.copy p s hs, by
convert p.isFractional
ext
simp only [hs]
rfl⟩
@[simp]
theorem coe_copy (p : FractionalIdeal S P) (s : Set P) (hs : s = ↑p) : ↑(p.copy s hs) = s :=
rfl
theorem coe_eq (p : FractionalIdeal S P) (s : Set P) (hs : s = ↑p) : p.copy s hs = p :=
SetLike.coe_injective hs
end SetLike
lemma zero_mem (I : FractionalIdeal S P) : 0 ∈ I := I.coeToSubmodule.zero_mem
-- Porting note: this seems to be needed a lot more than in Lean 3
@[simp]
theorem val_eq_coe (I : FractionalIdeal S P) : I.val = I :=
rfl
-- Porting note: had to rephrase this to make it clear to `simp` what was going on.
@[simp, norm_cast]
theorem coe_mk (I : Submodule R P) (hI : IsFractional S I) :
coeToSubmodule ⟨I, hI⟩ = I :=
rfl
theorem coeToSet_coeToSubmodule (I : FractionalIdeal S P) :
((I : Submodule R P) : Set P) = I :=
rfl
/-! Transfer instances from `Submodule R P` to `FractionalIdeal S P`. -/
instance (I : FractionalIdeal S P) : Module R I :=
Submodule.module (I : Submodule R P)
theorem coeToSubmodule_injective :
Function.Injective (fun (I : FractionalIdeal S P) ↦ (I : Submodule R P)) :=
Subtype.coe_injective
theorem coeToSubmodule_inj {I J : FractionalIdeal S P} : (I : Submodule R P) = J ↔ I = J :=
coeToSubmodule_injective.eq_iff
theorem isFractional_of_le_one (I : Submodule R P) (h : I ≤ 1) : IsFractional S I := by
use 1, S.one_mem
intro b hb
rw [one_smul]
obtain ⟨b', b'_mem, rfl⟩ := mem_one.mp (h hb)
exact Set.mem_range_self b'
theorem isFractional_of_le {I : Submodule R P} {J : FractionalIdeal S P} (hIJ : I ≤ J) :
IsFractional S I := by
obtain ⟨a, a_mem, ha⟩ := J.isFractional
use a, a_mem
intro b b_mem
exact ha b (hIJ b_mem)
/-- Map an ideal `I` to a fractional ideal by forgetting `I` is integral.
This is the function that implements the coercion `Ideal R → FractionalIdeal S P`. -/
@[coe]
def coeIdeal (I : Ideal R) : FractionalIdeal S P :=
⟨coeSubmodule P I,
isFractional_of_le_one _ <| by simpa using coeSubmodule_mono P (le_top : I ≤ ⊤)⟩
| -- Is a `CoeTC` rather than `Coe` to speed up failing inference, see library note [use has_coe_t]
/-- Map an ideal `I` to a fractional ideal by forgetting `I` is integral.
This is a bundled version of `IsLocalization.coeSubmodule : Ideal R → Submodule R P`,
which is not to be confused with the `coe : FractionalIdeal S P → Submodule R P`,
also called `coeToSubmodule` in theorem names.
| Mathlib/RingTheory/FractionalIdeal/Basic.lean | 236 | 241 |
/-
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.Additive
import Mathlib.Algebra.Homology.ShortComplex.Exact
import Mathlib.Algebra.Homology.ShortComplex.Preadditive
import Mathlib.Tactic.Linarith
/-!
# The short complexes attached to homological complexes
In this file, we define a functor
`shortComplexFunctor C c i : HomologicalComplex C c ⥤ ShortComplex C`.
By definition, the image of a homological complex `K` by this functor
is the short complex `K.X (c.prev i) ⟶ K.X i ⟶ K.X (c.next i)`.
The homology `K.homology i` of a homological complex `K` in degree `i` is defined as
the homology of the short complex `(shortComplexFunctor C c i).obj K`, which can be
abbreviated as `K.sc i`.
-/
open CategoryTheory Category Limits
namespace HomologicalComplex
variable (C : Type*) [Category C] [HasZeroMorphisms C] {ι : Type*} (c : ComplexShape ι)
/-- The functor `HomologicalComplex C c ⥤ ShortComplex C` which sends a homological
complex `K` to the short complex `K.X i ⟶ K.X j ⟶ K.X k` for arbitrary indices `i`, `j` and `k`. -/
@[simps]
def shortComplexFunctor' (i j k : ι) : HomologicalComplex C c ⥤ ShortComplex C where
obj K := ShortComplex.mk (K.d i j) (K.d j k) (K.d_comp_d i j k)
map f :=
{ τ₁ := f.f i
τ₂ := f.f j
τ₃ := f.f k }
/-- The functor `HomologicalComplex C c ⥤ ShortComplex C` which sends a homological
complex `K` to the short complex `K.X (c.prev i) ⟶ K.X i ⟶ K.X (c.next i)`. -/
@[simps!]
noncomputable def shortComplexFunctor (i : ι) :=
shortComplexFunctor' C c (c.prev i) i (c.next i)
/-- The natural isomorphism `shortComplexFunctor C c j ≅ shortComplexFunctor' C c i j k`
when `c.prev j = i` and `c.next j = k`. -/
@[simps!]
noncomputable def natIsoSc' (i j k : ι) (hi : c.prev j = i) (hk : c.next j = k) :
shortComplexFunctor C c j ≅ shortComplexFunctor' C c i j k :=
NatIso.ofComponents (fun K => ShortComplex.isoMk (K.XIsoOfEq hi) (Iso.refl _) (K.XIsoOfEq hk)
(by simp) (by simp)) (by aesop_cat)
variable {C c}
variable (K L M : HomologicalComplex C c) (φ : K ⟶ L) (ψ : L ⟶ M) (i j k : ι)
/-- The short complex `K.X i ⟶ K.X j ⟶ K.X k` for arbitrary indices `i`, `j` and `k`. -/
abbrev sc' := (shortComplexFunctor' C c i j k).obj K
/-- The short complex `K.X (c.prev i) ⟶ K.X i ⟶ K.X (c.next i)`. -/
noncomputable abbrev sc := (shortComplexFunctor C c i).obj K
/-- The canonical isomorphism `K.sc j ≅ K.sc' i j k` when `c.prev j = i` and `c.next j = k`. -/
noncomputable abbrev isoSc' (hi : c.prev j = i) (hk : c.next j = k) :
K.sc j ≅ K.sc' i j k := (natIsoSc' C c i j k hi hk).app K
/-- A homological complex `K` has homology in degree `i` if the associated
short complex `K.sc i` has. -/
abbrev HasHomology := (K.sc i).HasHomology
section
variable [K.HasHomology i]
/-- The homology in degree `i` of a homological complex. -/
noncomputable def homology := (K.sc i).homology
/-- The cycles in degree `i` of a homological complex. -/
noncomputable def cycles := (K.sc i).cycles
/-- The inclusion of the cycles of a homological complex. -/
noncomputable def iCycles : K.cycles i ⟶ K.X i := (K.sc i).iCycles
/-- The homology class map from cycles to the homology of a homological complex. -/
noncomputable def homologyπ : K.cycles i ⟶ K.homology i := (K.sc i).homologyπ
variable {i}
/-- The morphism to `K.cycles i` that is induced by a "cycle", i.e. a morphism
to `K.X i` whose postcomposition with the differential is zero. -/
noncomputable def liftCycles {A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.next i = j)
(hk : k ≫ K.d i j = 0) : A ⟶ K.cycles i :=
(K.sc i).liftCycles k (by subst hj; exact hk)
/-- The morphism to `K.cycles i` that is induced by a "cycle", i.e. a morphism
to `K.X i` whose postcomposition with the differential is zero. -/
noncomputable abbrev liftCycles' {A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.Rel i j)
(hk : k ≫ K.d i j = 0) : A ⟶ K.cycles i :=
K.liftCycles k j (c.next_eq' hj) hk
@[reassoc (attr := simp)]
lemma liftCycles_i {A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.next i = j)
(hk : k ≫ K.d i j = 0) : K.liftCycles k j hj hk ≫ K.iCycles i = k := by
dsimp [liftCycles, iCycles]
simp
variable (i)
/-- The map `K.X i ⟶ K.cycles j` induced by the differential `K.d i j`. -/
noncomputable def toCycles [K.HasHomology j] :
K.X i ⟶ K.cycles j :=
K.liftCycles (K.d i j) (c.next j) rfl (K.d_comp_d _ _ _)
@[reassoc (attr := simp)]
lemma iCycles_d : K.iCycles i ≫ K.d i j = 0 := by
by_cases hij : c.Rel i j
· obtain rfl := c.next_eq' hij
exact (K.sc i).iCycles_g
· rw [K.shape _ _ hij, comp_zero]
/-- `K.cycles i` is the kernel of `K.d i j` when `c.next i = j`. -/
noncomputable def cyclesIsKernel (hj : c.next i = j) :
IsLimit (KernelFork.ofι (K.iCycles i) (K.iCycles_d i j)) := by
obtain rfl := hj
exact (K.sc i).cyclesIsKernel
end
@[reassoc (attr := simp)]
lemma toCycles_i [K.HasHomology j] :
K.toCycles i j ≫ K.iCycles j = K.d i j :=
liftCycles_i _ _ _ _ _
section
variable [K.HasHomology i]
instance : Mono (K.iCycles i) := by
dsimp only [iCycles]
infer_instance
instance : Epi (K.homologyπ i) := by
dsimp only [homologyπ]
infer_instance
end
@[reassoc (attr := simp)]
lemma d_toCycles [K.HasHomology k] :
K.d i j ≫ K.toCycles j k = 0 := by
simp only [← cancel_mono (K.iCycles k), assoc, toCycles_i, d_comp_d, zero_comp]
variable {i j} in
lemma toCycles_eq_zero [K.HasHomology j] (hij : ¬ c.Rel i j) :
K.toCycles i j = 0 := by
rw [← cancel_mono (K.iCycles j), toCycles_i, zero_comp, K.shape _ _ hij]
variable {i}
section
variable [K.HasHomology i]
@[reassoc]
lemma comp_liftCycles {A' A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.next i = j)
(hk : k ≫ K.d i j = 0) (α : A' ⟶ A) :
α ≫ K.liftCycles k j hj hk = K.liftCycles (α ≫ k) j hj (by rw [assoc, hk, comp_zero]) := by
simp only [← cancel_mono (K.iCycles i), assoc, liftCycles_i]
@[reassoc]
lemma liftCycles_homologyπ_eq_zero_of_boundary {A : C} (k : A ⟶ K.X i) (j : ι)
(hj : c.next i = j) {i' : ι} (x : A ⟶ K.X i') (hx : k = x ≫ K.d i' i) :
K.liftCycles k j hj (by rw [hx, assoc, K.d_comp_d, comp_zero]) ≫ K.homologyπ i = 0 := by
by_cases h : c.Rel i' i
· obtain rfl := c.prev_eq' h
exact (K.sc i).liftCycles_homologyπ_eq_zero_of_boundary _ x hx
· have : liftCycles K k j hj (by rw [hx, assoc, K.d_comp_d, comp_zero]) = 0 := by
rw [K.shape _ _ h, comp_zero] at hx
rw [← cancel_mono (K.iCycles i), zero_comp, liftCycles_i, hx]
rw [this, zero_comp]
end
variable (i)
@[reassoc (attr := simp)]
lemma toCycles_comp_homologyπ [K.HasHomology j] :
K.toCycles i j ≫ K.homologyπ j = 0 :=
K.liftCycles_homologyπ_eq_zero_of_boundary (K.d i j) (c.next j) rfl (𝟙 _) (by simp)
/-- `K.homology j` is the cokernel of `K.toCycles i j : K.X i ⟶ K.cycles j`
when `c.prev j = i`. -/
noncomputable def homologyIsCokernel (hi : c.prev j = i) [K.HasHomology j] :
IsColimit (CokernelCofork.ofπ (K.homologyπ j) (K.toCycles_comp_homologyπ i j)) := by
subst hi
exact (K.sc j).homologyIsCokernel
section
variable [K.HasHomology i]
/-- The opcycles in degree `i` of a homological complex. -/
noncomputable def opcycles := (K.sc i).opcycles
/-- The projection to the opcycles of a homological complex. -/
noncomputable def pOpcycles : K.X i ⟶ K.opcycles i := (K.sc i).pOpcycles
/-- The inclusion map of the homology of a homological complex into its opcycles. -/
noncomputable def homologyι : K.homology i ⟶ K.opcycles i := (K.sc i).homologyι
variable {i}
/-- The morphism from `K.opcycles i` that is induced by an "opcycle", i.e. a morphism
from `K.X i` whose precomposition with the differential is zero. -/
noncomputable def descOpcycles {A : C} (k : K.X i ⟶ A) (j : ι) (hj : c.prev i = j)
(hk : K.d j i ≫ k = 0) : K.opcycles i ⟶ A :=
(K.sc i).descOpcycles k (by subst hj; exact hk)
/-- The morphism from `K.opcycles i` that is induced by an "opcycle", i.e. a morphism
from `K.X i` whose precomposition with the differential is zero. -/
noncomputable abbrev descOpcycles' {A : C} (k : K.X i ⟶ A) (j : ι) (hj : c.Rel j i)
(hk : K.d j i ≫ k = 0) : K.opcycles i ⟶ A :=
K.descOpcycles k j (c.prev_eq' hj) hk
@[reassoc (attr := simp)]
lemma p_descOpcycles {A : C} (k : K.X i ⟶ A) (j : ι) (hj : c.prev i = j)
(hk : K.d j i ≫ k = 0) : K.pOpcycles i ≫ K.descOpcycles k j hj hk = k := by
dsimp [descOpcycles, pOpcycles]
simp
variable (i)
/-- The map `K.opcycles i ⟶ K.X j` induced by the differential `K.d i j`. -/
noncomputable def fromOpcycles :
K.opcycles i ⟶ K.X j :=
K.descOpcycles (K.d i j) (c.prev i) rfl (K.d_comp_d _ _ _)
@[reassoc (attr := simp)]
lemma d_pOpcycles [K.HasHomology j] : K.d i j ≫ K.pOpcycles j = 0 := by
by_cases hij : c.Rel i j
· obtain rfl := c.prev_eq' hij
exact (K.sc j).f_pOpcycles
· rw [K.shape _ _ hij, zero_comp]
/-- `K.opcycles j` is the cokernel of `K.d i j` when `c.prev j = i`. -/
noncomputable def opcyclesIsCokernel (hi : c.prev j = i) [K.HasHomology j] :
IsColimit (CokernelCofork.ofπ (K.pOpcycles j) (K.d_pOpcycles i j)) := by
obtain rfl := hi
exact (K.sc j).opcyclesIsCokernel
@[reassoc (attr := simp)]
lemma p_fromOpcycles :
K.pOpcycles i ≫ K.fromOpcycles i j = K.d i j :=
p_descOpcycles _ _ _ _ _
instance : Epi (K.pOpcycles i) := by
dsimp only [pOpcycles]
infer_instance
instance : Mono (K.homologyι i) := by
dsimp only [homologyι]
infer_instance
@[reassoc (attr := simp)]
lemma fromOpcycles_d :
K.fromOpcycles i j ≫ K.d j k = 0 := by
simp only [← cancel_epi (K.pOpcycles i), p_fromOpcycles_assoc, d_comp_d, comp_zero]
variable {i j} in
lemma fromOpcycles_eq_zero (hij : ¬ c.Rel i j) :
K.fromOpcycles i j = 0 := by
rw [← cancel_epi (K.pOpcycles i), p_fromOpcycles, comp_zero, K.shape _ _ hij]
variable {i}
@[reassoc]
lemma descOpcycles_comp {A A' : C} (k : K.X i ⟶ A) (j : ι) (hj : c.prev i = j)
(hk : K.d j i ≫ k = 0) (α : A ⟶ A') :
K.descOpcycles k j hj hk ≫ α = K.descOpcycles (k ≫ α) j hj
(by rw [reassoc_of% hk, zero_comp]) := by
simp only [← cancel_epi (K.pOpcycles i), p_descOpcycles_assoc, p_descOpcycles]
@[reassoc]
lemma homologyι_descOpcycles_eq_zero_of_boundary {A : C} (k : K.X i ⟶ A) (j : ι)
(hj : c.prev i = j) {i' : ι} (x : K.X i' ⟶ A) (hx : k = K.d i i' ≫ x) :
K.homologyι i ≫ K.descOpcycles k j hj (by rw [hx, K.d_comp_d_assoc, zero_comp]) = 0 := by
by_cases h : c.Rel i i'
· obtain rfl := c.next_eq' h
exact (K.sc i).homologyι_descOpcycles_eq_zero_of_boundary _ x hx
· have : K.descOpcycles k j hj (by rw [hx, K.d_comp_d_assoc, zero_comp]) = 0 := by
rw [K.shape _ _ h, zero_comp] at hx
rw [← cancel_epi (K.pOpcycles i), comp_zero, p_descOpcycles, hx]
rw [this, comp_zero]
variable (i)
@[reassoc (attr := simp)]
lemma homologyι_comp_fromOpcycles :
K.homologyι i ≫ K.fromOpcycles i j = 0 :=
K.homologyι_descOpcycles_eq_zero_of_boundary (K.d i j) _ rfl (𝟙 _) (by simp)
/-- `K.homology i` is the kernel of `K.fromOpcycles i j : K.opcycles i ⟶ K.X j`
when `c.next i = j`. -/
noncomputable def homologyIsKernel (hi : c.next i = j) :
IsLimit (KernelFork.ofι (K.homologyι i) (K.homologyι_comp_fromOpcycles i j)) := by
subst hi
exact (K.sc i).homologyIsKernel
variable {K L M}
variable [L.HasHomology i] [M.HasHomology i]
/-- The map `K.homology i ⟶ L.homology i` induced by a morphism in `HomologicalComplex`. -/
noncomputable def homologyMap : K.homology i ⟶ L.homology i :=
ShortComplex.homologyMap ((shortComplexFunctor C c i).map φ)
/-- The map `K.cycles i ⟶ L.cycles i` induced by a morphism in `HomologicalComplex`. -/
noncomputable def cyclesMap : K.cycles i ⟶ L.cycles i :=
ShortComplex.cyclesMap ((shortComplexFunctor C c i).map φ)
/-- The map `K.opcycles i ⟶ L.opcycles i` induced by a morphism in `HomologicalComplex`. -/
noncomputable def opcyclesMap : K.opcycles i ⟶ L.opcycles i :=
ShortComplex.opcyclesMap ((shortComplexFunctor C c i).map φ)
@[reassoc (attr := simp)]
lemma cyclesMap_i : cyclesMap φ i ≫ L.iCycles i = K.iCycles i ≫ φ.f i :=
ShortComplex.cyclesMap_i _
@[reassoc (attr := simp)]
lemma p_opcyclesMap : K.pOpcycles i ≫ opcyclesMap φ i = φ.f i ≫ L.pOpcycles i :=
ShortComplex.p_opcyclesMap _
instance [Mono (φ.f i)] : Mono (cyclesMap φ i) := mono_of_mono_fac (cyclesMap_i φ i)
instance [Epi (φ.f i)] : Epi (opcyclesMap φ i) := epi_of_epi_fac (p_opcyclesMap φ i)
variable (K)
@[simp]
lemma homologyMap_id : homologyMap (𝟙 K) i = 𝟙 _ :=
ShortComplex.homologyMap_id _
@[simp]
lemma cyclesMap_id : cyclesMap (𝟙 K) i = 𝟙 _ :=
ShortComplex.cyclesMap_id _
@[simp]
lemma opcyclesMap_id : opcyclesMap (𝟙 K) i = 𝟙 _ :=
ShortComplex.opcyclesMap_id _
variable {K}
@[reassoc]
lemma homologyMap_comp : homologyMap (φ ≫ ψ) i = homologyMap φ i ≫ homologyMap ψ i := by
dsimp [homologyMap]
rw [Functor.map_comp, ShortComplex.homologyMap_comp]
@[reassoc]
lemma cyclesMap_comp : cyclesMap (φ ≫ ψ) i = cyclesMap φ i ≫ cyclesMap ψ i := by
dsimp [cyclesMap]
rw [Functor.map_comp, ShortComplex.cyclesMap_comp]
@[reassoc]
lemma opcyclesMap_comp : opcyclesMap (φ ≫ ψ) i = opcyclesMap φ i ≫ opcyclesMap ψ i := by
dsimp [opcyclesMap]
rw [Functor.map_comp, ShortComplex.opcyclesMap_comp]
variable (K L)
@[simp]
lemma homologyMap_zero : homologyMap (0 : K ⟶ L) i = 0 :=
ShortComplex.homologyMap_zero _ _
@[simp]
lemma cyclesMap_zero : cyclesMap (0 : K ⟶ L) i = 0 :=
ShortComplex.cyclesMap_zero _ _
@[simp]
lemma opcyclesMap_zero : opcyclesMap (0 : K ⟶ L) i = 0 :=
ShortComplex.opcyclesMap_zero _ _
variable {K L}
@[reassoc (attr := simp)]
lemma homologyπ_naturality :
K.homologyπ i ≫ homologyMap φ i = cyclesMap φ i ≫ L.homologyπ i :=
ShortComplex.homologyπ_naturality _
@[reassoc (attr := simp)]
lemma homologyι_naturality :
homologyMap φ i ≫ L.homologyι i = K.homologyι i ≫ opcyclesMap φ i :=
ShortComplex.homologyι_naturality _
@[reassoc (attr := simp)]
lemma homology_π_ι :
K.homologyπ i ≫ K.homologyι i = K.iCycles i ≫ K.pOpcycles i :=
(K.sc i).homology_π_ι
variable {i}
@[reassoc (attr := simp)]
lemma opcyclesMap_comp_descOpcycles {A : C} (k : L.X i ⟶ A) (j : ι) (hj : c.prev i = j)
(hk : L.d j i ≫ k = 0) (φ : K ⟶ L) :
opcyclesMap φ i ≫ L.descOpcycles k j hj hk = K.descOpcycles (φ.f i ≫ k) j hj
(by rw [← φ.comm_assoc, hk, comp_zero]) := by
simp only [← cancel_epi (K.pOpcycles i), p_opcyclesMap_assoc, p_descOpcycles]
@[reassoc (attr := simp)]
lemma liftCycles_comp_cyclesMap {A : C} (k : A ⟶ K.X i) (j : ι) (hj : c.next i = j)
(hk : k ≫ K.d i j = 0) (φ : K ⟶ L) :
K.liftCycles k j hj hk ≫ cyclesMap φ i = L.liftCycles (k ≫ φ.f i) j hj
(by rw [assoc, φ.comm, reassoc_of% hk, zero_comp]) := by
simp only [← cancel_mono (L.iCycles i), assoc, cyclesMap_i, liftCycles_i_assoc, liftCycles_i]
section
variable (C c i)
attribute [local simp] homologyMap_comp cyclesMap_comp opcyclesMap_comp
/-- The `i`th homology functor `HomologicalComplex C c ⥤ C`. -/
@[simps]
noncomputable def homologyFunctor [CategoryWithHomology C] : HomologicalComplex C c ⥤ C where
obj K := K.homology i
map f := homologyMap f i
/-- The homology functor to graded objects. -/
@[simps]
noncomputable def gradedHomologyFunctor [CategoryWithHomology C] :
HomologicalComplex C c ⥤ GradedObject ι C where
obj K i := K.homology i
map f i := homologyMap f i
/-- The `i`th cycles functor `HomologicalComplex C c ⥤ C`. -/
@[simps]
noncomputable def cyclesFunctor [CategoryWithHomology C] : HomologicalComplex C c ⥤ C where
obj K := K.cycles i
map f := cyclesMap f i
/-- The `i`th opcycles functor `HomologicalComplex C c ⥤ C`. -/
@[simps]
noncomputable def opcyclesFunctor [CategoryWithHomology C] : HomologicalComplex C c ⥤ C where
obj K := K.opcycles i
map f := opcyclesMap f i
/-- The natural transformation `K.homologyπ i : K.cycles i ⟶ K.homology i`
for all `K : HomologicalComplex C c`. -/
@[simps]
noncomputable def natTransHomologyπ [CategoryWithHomology C] :
cyclesFunctor C c i ⟶ homologyFunctor C c i where
app K := K.homologyπ i
/-- The natural transformation `K.homologyι i : K.homology i ⟶ K.opcycles i`
for all `K : HomologicalComplex C c`. -/
@[simps]
noncomputable def natTransHomologyι [CategoryWithHomology C] :
homologyFunctor C c i ⟶ opcyclesFunctor C c i where
app K := K.homologyι i
/-- The natural isomorphism `K.homology i ≅ (K.sc i).homology`
for all homological complexes `K`. -/
@[simps!]
noncomputable def homologyFunctorIso [CategoryWithHomology C] :
homologyFunctor C c i ≅
shortComplexFunctor C c i ⋙ ShortComplex.homologyFunctor C :=
Iso.refl _
/-- The natural isomorphism `K.homology j ≅ (K.sc' i j k).homology`
for all homological complexes `K` when `c.prev j = i` and `c.next j = k`. -/
noncomputable def homologyFunctorIso' [CategoryWithHomology C]
(hi : c.prev j = i) (hk : c.next j = k) :
homologyFunctor C c j ≅
shortComplexFunctor' C c i j k ⋙ ShortComplex.homologyFunctor C :=
homologyFunctorIso C c j ≪≫ isoWhiskerRight (natIsoSc' C c i j k hi hk) _
instance [CategoryWithHomology C] : (homologyFunctor C c i).PreservesZeroMorphisms where
instance [CategoryWithHomology C] : (opcyclesFunctor C c i).PreservesZeroMorphisms where
instance [CategoryWithHomology C] : (cyclesFunctor C c i).PreservesZeroMorphisms where
end
end
section
variable (hj : c.next i = j) (h : K.d i j = 0) [K.HasHomology i]
include hj h
lemma isIso_iCycles : IsIso (K.iCycles i) := by
subst hj
exact ShortComplex.isIso_iCycles _ h
/-- The canonical isomorphism `K.cycles i ≅ K.X i` when the differential from `i` is zero. -/
@[simps! hom]
noncomputable def iCyclesIso : K.cycles i ≅ K.X i :=
have := K.isIso_iCycles i j hj h
asIso (K.iCycles i)
@[reassoc (attr := simp)]
lemma iCyclesIso_hom_inv_id :
K.iCycles i ≫ (K.iCyclesIso i j hj h).inv = 𝟙 _ :=
(K.iCyclesIso i j hj h).hom_inv_id
@[reassoc (attr := simp)]
lemma iCyclesIso_inv_hom_id :
(K.iCyclesIso i j hj h).inv ≫ K.iCycles i = 𝟙 _ :=
(K.iCyclesIso i j hj h).inv_hom_id
lemma isIso_homologyι : IsIso (K.homologyι i) :=
ShortComplex.isIso_homologyι _ (by aesop_cat)
/-- The canonical isomorphism `K.homology i ≅ K.opcycles i`
when the differential from `i` is zero. -/
@[simps! hom]
noncomputable def isoHomologyι : K.homology i ≅ K.opcycles i :=
have := K.isIso_homologyι i j hj h
asIso (K.homologyι i)
@[reassoc (attr := simp)]
lemma isoHomologyι_hom_inv_id :
K.homologyι i ≫ (K.isoHomologyι i j hj h).inv = 𝟙 _ :=
(K.isoHomologyι i j hj h).hom_inv_id
@[reassoc (attr := simp)]
lemma isoHomologyι_inv_hom_id :
(K.isoHomologyι i j hj h).inv ≫ K.homologyι i = 𝟙 _ :=
(K.isoHomologyι i j hj h).inv_hom_id
end
section
variable (hi : c.prev j = i) (h : K.d i j = 0) [K.HasHomology j]
include hi h
lemma isIso_pOpcycles : IsIso (K.pOpcycles j) := by
obtain rfl := hi
exact ShortComplex.isIso_pOpcycles _ h
/-- The canonical isomorphism `K.X j ≅ K.opCycles j` when the differential to `j` is zero. -/
@[simps! hom]
noncomputable def pOpcyclesIso : K.X j ≅ K.opcycles j :=
have := K.isIso_pOpcycles i j hi h
asIso (K.pOpcycles j)
@[reassoc (attr := simp)]
lemma pOpcyclesIso_hom_inv_id :
K.pOpcycles j ≫ (K.pOpcyclesIso i j hi h).inv = 𝟙 _ :=
(K.pOpcyclesIso i j hi h).hom_inv_id
@[reassoc (attr := simp)]
lemma pOpcyclesIso_inv_hom_id :
(K.pOpcyclesIso i j hi h).inv ≫ K.pOpcycles j = 𝟙 _ :=
(K.pOpcyclesIso i j hi h).inv_hom_id
lemma isIso_homologyπ : IsIso (K.homologyπ j) :=
ShortComplex.isIso_homologyπ _ (by aesop_cat)
/-- The canonical isomorphism `K.cycles j ≅ K.homology j`
when the differential to `j` is zero. -/
@[simps! hom]
noncomputable def isoHomologyπ : K.cycles j ≅ K.homology j :=
have := K.isIso_homologyπ i j hi h
asIso (K.homologyπ j)
@[reassoc (attr := simp)]
lemma isoHomologyπ_hom_inv_id :
K.homologyπ j ≫ (K.isoHomologyπ i j hi h).inv = 𝟙 _ :=
(K.isoHomologyπ i j hi h).hom_inv_id
@[reassoc (attr := simp)]
lemma isoHomologyπ_inv_hom_id :
(K.isoHomologyπ i j hi h).inv ≫ K.homologyπ j = 𝟙 _ :=
(K.isoHomologyπ i j hi h).inv_hom_id
end
section
variable {K L}
lemma epi_homologyMap_of_epi_of_not_rel (φ : K ⟶ L) (i : ι)
[K.HasHomology i] [L.HasHomology i] [Epi (φ.f i)] (hi : ∀ j, ¬ c.Rel i j) :
Epi (homologyMap φ i) :=
((MorphismProperty.epimorphisms C).arrow_mk_iso_iff
(Arrow.isoMk (K.isoHomologyι i _ rfl (shape _ _ _ (by tauto)))
(L.isoHomologyι i _ rfl (shape _ _ _ (by tauto))))).2
(MorphismProperty.epimorphisms.infer_property (opcyclesMap φ i))
lemma mono_homologyMap_of_mono_of_not_rel (φ : K ⟶ L) (j : ι)
[K.HasHomology j] [L.HasHomology j] [Mono (φ.f j)] (hj : ∀ i, ¬ c.Rel i j) :
Mono (homologyMap φ j) :=
((MorphismProperty.monomorphisms C).arrow_mk_iso_iff
(Arrow.isoMk (K.isoHomologyπ _ j rfl (shape _ _ _ (by tauto)))
(L.isoHomologyπ _ j rfl (shape _ _ _ (by tauto))))).1
(MorphismProperty.monomorphisms.infer_property (cyclesMap φ j))
end
/-- A homological complex `K` is exact at `i` if the short complex `K.sc i` is exact. -/
def ExactAt := (K.sc i).Exact
lemma exactAt_iff :
K.ExactAt i ↔ (K.sc i).Exact := by rfl
variable {K i} in
lemma ExactAt.of_iso (hK : K.ExactAt i) {L : HomologicalComplex C c} (e : K ≅ L) :
L.ExactAt i := by
rw [exactAt_iff] at hK ⊢
exact ShortComplex.exact_of_iso ((shortComplexFunctor C c i).mapIso e) hK
lemma exactAt_iff' (hi : c.prev j = i) (hk : c.next j = k) :
K.ExactAt j ↔ (K.sc' i j k).Exact :=
ShortComplex.exact_iff_of_iso (K.isoSc' i j k hi hk)
lemma exactAt_iff_isZero_homology [K.HasHomology i] :
K.ExactAt i ↔ IsZero (K.homology i) := by
dsimp [homology]
rw [exactAt_iff, ShortComplex.exact_iff_isZero_homology]
variable {K i} in
lemma ExactAt.isZero_homology [K.HasHomology i] (h : K.ExactAt i) :
IsZero (K.homology i) := by
rwa [← exactAt_iff_isZero_homology]
/-- A homological complex `K` is acyclic if it is exact at `i` for any `i`. -/
def Acyclic := ∀ i, K.ExactAt i
lemma acyclic_iff :
K.Acyclic ↔ ∀ i, K.ExactAt i := by rfl
lemma acyclic_of_isZero (hK : IsZero K) :
K.Acyclic := by
rw [acyclic_iff]
intro i
apply ShortComplex.exact_of_isZero_X₂
exact (eval _ _ i).map_isZero hK
end HomologicalComplex
namespace ChainComplex
variable {C : Type*} [Category C] [HasZeroMorphisms C]
(K L : ChainComplex C ℕ) (φ : K ⟶ L) [K.HasHomology 0]
instance isIso_homologyι₀ :
IsIso (K.homologyι 0) :=
K.isIso_homologyι 0 _ rfl (by simp)
/-- The canonical isomorphism `K.homology 0 ≅ K.opcycles 0` for a chain complex `K`
indexed by `ℕ`. -/
noncomputable abbrev isoHomologyι₀ :
K.homology 0 ≅ K.opcycles 0 := K.isoHomologyι 0 _ rfl (by simp)
variable {K L}
@[reassoc (attr := simp)]
lemma isoHomologyι₀_inv_naturality [L.HasHomology 0] :
K.isoHomologyι₀.inv ≫ HomologicalComplex.homologyMap φ 0 =
HomologicalComplex.opcyclesMap φ 0 ≫ L.isoHomologyι₀.inv := by
simp only [assoc, ← cancel_mono (L.homologyι 0),
HomologicalComplex.homologyι_naturality, HomologicalComplex.isoHomologyι_inv_hom_id_assoc,
HomologicalComplex.isoHomologyι_inv_hom_id, comp_id]
| end ChainComplex
namespace CochainComplex
variable {C : Type*} [Category C] [HasZeroMorphisms C]
| Mathlib/Algebra/Homology/ShortComplex/HomologicalComplex.lean | 663 | 667 |
/-
Copyright (c) 2022 Joseph Myers. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joseph Myers, Heather Macbeth
-/
import Mathlib.Analysis.InnerProductSpace.TwoDim
import Mathlib.Geometry.Euclidean.Angle.Unoriented.Basic
/-!
# Oriented angles.
This file defines oriented angles in real inner product spaces.
## Main definitions
* `Orientation.oangle` is the oriented angle between two vectors with respect to an orientation.
## Implementation notes
The definitions here use the `Real.angle` type, angles modulo `2 * π`. For some purposes,
angles modulo `π` are more convenient, because results are true for such angles with less
configuration dependence. Results that are only equalities modulo `π` can be represented
modulo `2 * π` as equalities of `(2 : ℤ) • θ`.
## References
* Evan Chen, Euclidean Geometry in Mathematical Olympiads.
-/
noncomputable section
open Module Complex
open scoped Real RealInnerProductSpace ComplexConjugate
namespace Orientation
attribute [local instance] Complex.finrank_real_complex_fact
variable {V V' : Type*}
variable [NormedAddCommGroup V] [NormedAddCommGroup V']
variable [InnerProductSpace ℝ V] [InnerProductSpace ℝ V']
variable [Fact (finrank ℝ V = 2)] [Fact (finrank ℝ V' = 2)] (o : Orientation ℝ V (Fin 2))
local notation "ω" => o.areaForm
/-- The oriented angle from `x` to `y`, modulo `2 * π`. If either vector is 0, this is 0.
See `InnerProductGeometry.angle` for the corresponding unoriented angle definition. -/
def oangle (x y : V) : Real.Angle :=
Complex.arg (o.kahler x y)
/-- Oriented angles are continuous when the vectors involved are nonzero. -/
@[fun_prop]
theorem continuousAt_oangle {x : V × V} (hx1 : x.1 ≠ 0) (hx2 : x.2 ≠ 0) :
ContinuousAt (fun y : V × V => o.oangle y.1 y.2) x := by
refine (Complex.continuousAt_arg_coe_angle ?_).comp ?_
· exact o.kahler_ne_zero hx1 hx2
exact ((continuous_ofReal.comp continuous_inner).add
((continuous_ofReal.comp o.areaForm'.continuous₂).mul continuous_const)).continuousAt
/-- If the first vector passed to `oangle` is 0, the result is 0. -/
@[simp]
theorem oangle_zero_left (x : V) : o.oangle 0 x = 0 := by simp [oangle]
/-- If the second vector passed to `oangle` is 0, the result is 0. -/
@[simp]
theorem oangle_zero_right (x : V) : o.oangle x 0 = 0 := by simp [oangle]
/-- If the two vectors passed to `oangle` are the same, the result is 0. -/
@[simp]
theorem oangle_self (x : V) : o.oangle x x = 0 := by
rw [oangle, kahler_apply_self, ← ofReal_pow]
convert QuotientAddGroup.mk_zero (AddSubgroup.zmultiples (2 * π))
apply arg_ofReal_of_nonneg
positivity
/-- If the angle between two vectors is nonzero, the first vector is nonzero. -/
theorem left_ne_zero_of_oangle_ne_zero {x y : V} (h : o.oangle x y ≠ 0) : x ≠ 0 := by
rintro rfl; simp at h
/-- If the angle between two vectors is nonzero, the second vector is nonzero. -/
theorem right_ne_zero_of_oangle_ne_zero {x y : V} (h : o.oangle x y ≠ 0) : y ≠ 0 := by
rintro rfl; simp at h
/-- If the angle between two vectors is nonzero, the vectors are not equal. -/
theorem ne_of_oangle_ne_zero {x y : V} (h : o.oangle x y ≠ 0) : x ≠ y := by
rintro rfl; simp at h
/-- If the angle between two vectors is `π`, the first vector is nonzero. -/
theorem left_ne_zero_of_oangle_eq_pi {x y : V} (h : o.oangle x y = π) : x ≠ 0 :=
o.left_ne_zero_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_ne_zero : o.oangle x y ≠ 0)
/-- If the angle between two vectors is `π`, the second vector is nonzero. -/
theorem right_ne_zero_of_oangle_eq_pi {x y : V} (h : o.oangle x y = π) : y ≠ 0 :=
o.right_ne_zero_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_ne_zero : o.oangle x y ≠ 0)
/-- If the angle between two vectors is `π`, the vectors are not equal. -/
theorem ne_of_oangle_eq_pi {x y : V} (h : o.oangle x y = π) : x ≠ y :=
o.ne_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_ne_zero : o.oangle x y ≠ 0)
/-- If the angle between two vectors is `π / 2`, the first vector is nonzero. -/
theorem left_ne_zero_of_oangle_eq_pi_div_two {x y : V} (h : o.oangle x y = (π / 2 : ℝ)) : x ≠ 0 :=
o.left_ne_zero_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_div_two_ne_zero : o.oangle x y ≠ 0)
/-- If the angle between two vectors is `π / 2`, the second vector is nonzero. -/
theorem right_ne_zero_of_oangle_eq_pi_div_two {x y : V} (h : o.oangle x y = (π / 2 : ℝ)) : y ≠ 0 :=
o.right_ne_zero_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_div_two_ne_zero : o.oangle x y ≠ 0)
/-- If the angle between two vectors is `π / 2`, the vectors are not equal. -/
theorem ne_of_oangle_eq_pi_div_two {x y : V} (h : o.oangle x y = (π / 2 : ℝ)) : x ≠ y :=
o.ne_of_oangle_ne_zero (h.symm ▸ Real.Angle.pi_div_two_ne_zero : o.oangle x y ≠ 0)
/-- If the angle between two vectors is `-π / 2`, the first vector is nonzero. -/
theorem left_ne_zero_of_oangle_eq_neg_pi_div_two {x y : V} (h : o.oangle x y = (-π / 2 : ℝ)) :
x ≠ 0 :=
o.left_ne_zero_of_oangle_ne_zero (h.symm ▸ Real.Angle.neg_pi_div_two_ne_zero : o.oangle x y ≠ 0)
/-- If the angle between two vectors is `-π / 2`, the second vector is nonzero. -/
theorem right_ne_zero_of_oangle_eq_neg_pi_div_two {x y : V} (h : o.oangle x y = (-π / 2 : ℝ)) :
y ≠ 0 :=
o.right_ne_zero_of_oangle_ne_zero (h.symm ▸ Real.Angle.neg_pi_div_two_ne_zero : o.oangle x y ≠ 0)
/-- If the angle between two vectors is `-π / 2`, the vectors are not equal. -/
theorem ne_of_oangle_eq_neg_pi_div_two {x y : V} (h : o.oangle x y = (-π / 2 : ℝ)) : x ≠ y :=
o.ne_of_oangle_ne_zero (h.symm ▸ Real.Angle.neg_pi_div_two_ne_zero : o.oangle x y ≠ 0)
/-- If the sign of the angle between two vectors is nonzero, the first vector is nonzero. -/
theorem left_ne_zero_of_oangle_sign_ne_zero {x y : V} (h : (o.oangle x y).sign ≠ 0) : x ≠ 0 :=
o.left_ne_zero_of_oangle_ne_zero (Real.Angle.sign_ne_zero_iff.1 h).1
/-- If the sign of the angle between two vectors is nonzero, the second vector is nonzero. -/
theorem right_ne_zero_of_oangle_sign_ne_zero {x y : V} (h : (o.oangle x y).sign ≠ 0) : y ≠ 0 :=
o.right_ne_zero_of_oangle_ne_zero (Real.Angle.sign_ne_zero_iff.1 h).1
/-- If the sign of the angle between two vectors is nonzero, the vectors are not equal. -/
theorem ne_of_oangle_sign_ne_zero {x y : V} (h : (o.oangle x y).sign ≠ 0) : x ≠ y :=
o.ne_of_oangle_ne_zero (Real.Angle.sign_ne_zero_iff.1 h).1
/-- If the sign of the angle between two vectors is positive, the first vector is nonzero. -/
theorem left_ne_zero_of_oangle_sign_eq_one {x y : V} (h : (o.oangle x y).sign = 1) : x ≠ 0 :=
o.left_ne_zero_of_oangle_sign_ne_zero (h.symm ▸ by decide : (o.oangle x y).sign ≠ 0)
/-- If the sign of the angle between two vectors is positive, the second vector is nonzero. -/
theorem right_ne_zero_of_oangle_sign_eq_one {x y : V} (h : (o.oangle x y).sign = 1) : y ≠ 0 :=
o.right_ne_zero_of_oangle_sign_ne_zero (h.symm ▸ by decide : (o.oangle x y).sign ≠ 0)
/-- If the sign of the angle between two vectors is positive, the vectors are not equal. -/
theorem ne_of_oangle_sign_eq_one {x y : V} (h : (o.oangle x y).sign = 1) : x ≠ y :=
o.ne_of_oangle_sign_ne_zero (h.symm ▸ by decide : (o.oangle x y).sign ≠ 0)
/-- If the sign of the angle between two vectors is negative, the first vector is nonzero. -/
theorem left_ne_zero_of_oangle_sign_eq_neg_one {x y : V} (h : (o.oangle x y).sign = -1) : x ≠ 0 :=
o.left_ne_zero_of_oangle_sign_ne_zero (h.symm ▸ by decide : (o.oangle x y).sign ≠ 0)
/-- If the sign of the angle between two vectors is negative, the second vector is nonzero. -/
theorem right_ne_zero_of_oangle_sign_eq_neg_one {x y : V} (h : (o.oangle x y).sign = -1) : y ≠ 0 :=
o.right_ne_zero_of_oangle_sign_ne_zero (h.symm ▸ by decide : (o.oangle x y).sign ≠ 0)
/-- If the sign of the angle between two vectors is negative, the vectors are not equal. -/
theorem ne_of_oangle_sign_eq_neg_one {x y : V} (h : (o.oangle x y).sign = -1) : x ≠ y :=
o.ne_of_oangle_sign_ne_zero (h.symm ▸ by decide : (o.oangle x y).sign ≠ 0)
/-- Swapping the two vectors passed to `oangle` negates the angle. -/
theorem oangle_rev (x y : V) : o.oangle y x = -o.oangle x y := by
simp only [oangle, o.kahler_swap y x, Complex.arg_conj_coe_angle]
/-- Adding the angles between two vectors in each order results in 0. -/
@[simp]
theorem oangle_add_oangle_rev (x y : V) : o.oangle x y + o.oangle y x = 0 := by
simp [o.oangle_rev y x]
/-- Negating the first vector passed to `oangle` adds `π` to the angle. -/
theorem oangle_neg_left {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) :
o.oangle (-x) y = o.oangle x y + π := by
simp only [oangle, map_neg]
convert Complex.arg_neg_coe_angle _
exact o.kahler_ne_zero hx hy
/-- Negating the second vector passed to `oangle` adds `π` to the angle. -/
theorem oangle_neg_right {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) :
o.oangle x (-y) = o.oangle x y + π := by
simp only [oangle, map_neg]
convert Complex.arg_neg_coe_angle _
exact o.kahler_ne_zero hx hy
/-- Negating the first vector passed to `oangle` does not change twice the angle. -/
@[simp]
theorem two_zsmul_oangle_neg_left (x y : V) :
(2 : ℤ) • o.oangle (-x) y = (2 : ℤ) • o.oangle x y := by
by_cases hx : x = 0
· simp [hx]
· by_cases hy : y = 0
· simp [hy]
· simp [o.oangle_neg_left hx hy]
/-- Negating the second vector passed to `oangle` does not change twice the angle. -/
@[simp]
theorem two_zsmul_oangle_neg_right (x y : V) :
(2 : ℤ) • o.oangle x (-y) = (2 : ℤ) • o.oangle x y := by
by_cases hx : x = 0
· simp [hx]
· by_cases hy : y = 0
· simp [hy]
· simp [o.oangle_neg_right hx hy]
/-- Negating both vectors passed to `oangle` does not change the angle. -/
@[simp]
theorem oangle_neg_neg (x y : V) : o.oangle (-x) (-y) = o.oangle x y := by simp [oangle]
/-- Negating the first vector produces the same angle as negating the second vector. -/
theorem oangle_neg_left_eq_neg_right (x y : V) : o.oangle (-x) y = o.oangle x (-y) := by
rw [← neg_neg y, oangle_neg_neg, neg_neg]
/-- The angle between the negation of a nonzero vector and that vector is `π`. -/
@[simp]
theorem oangle_neg_self_left {x : V} (hx : x ≠ 0) : o.oangle (-x) x = π := by
simp [oangle_neg_left, hx]
/-- The angle between a nonzero vector and its negation is `π`. -/
@[simp]
theorem oangle_neg_self_right {x : V} (hx : x ≠ 0) : o.oangle x (-x) = π := by
simp [oangle_neg_right, hx]
/-- Twice the angle between the negation of a vector and that vector is 0. -/
theorem two_zsmul_oangle_neg_self_left (x : V) : (2 : ℤ) • o.oangle (-x) x = 0 := by
by_cases hx : x = 0 <;> simp [hx]
/-- Twice the angle between a vector and its negation is 0. -/
theorem two_zsmul_oangle_neg_self_right (x : V) : (2 : ℤ) • o.oangle x (-x) = 0 := by
by_cases hx : x = 0 <;> simp [hx]
/-- Adding the angles between two vectors in each order, with the first vector in each angle
negated, results in 0. -/
@[simp]
theorem oangle_add_oangle_rev_neg_left (x y : V) : o.oangle (-x) y + o.oangle (-y) x = 0 := by
rw [oangle_neg_left_eq_neg_right, oangle_rev, neg_add_cancel]
/-- Adding the angles between two vectors in each order, with the second vector in each angle
negated, results in 0. -/
@[simp]
theorem oangle_add_oangle_rev_neg_right (x y : V) : o.oangle x (-y) + o.oangle y (-x) = 0 := by
rw [o.oangle_rev (-x), oangle_neg_left_eq_neg_right, add_neg_cancel]
/-- Multiplying the first vector passed to `oangle` by a positive real does not change the
angle. -/
@[simp]
theorem oangle_smul_left_of_pos (x y : V) {r : ℝ} (hr : 0 < r) :
o.oangle (r • x) y = o.oangle x y := by simp [oangle, Complex.arg_real_mul _ hr]
/-- Multiplying the second vector passed to `oangle` by a positive real does not change the
angle. -/
@[simp]
theorem oangle_smul_right_of_pos (x y : V) {r : ℝ} (hr : 0 < r) :
o.oangle x (r • y) = o.oangle x y := by simp [oangle, Complex.arg_real_mul _ hr]
/-- Multiplying the first vector passed to `oangle` by a negative real produces the same angle
as negating that vector. -/
@[simp]
theorem oangle_smul_left_of_neg (x y : V) {r : ℝ} (hr : r < 0) :
o.oangle (r • x) y = o.oangle (-x) y := by
rw [← neg_neg r, neg_smul, ← smul_neg, o.oangle_smul_left_of_pos _ _ (neg_pos_of_neg hr)]
/-- Multiplying the second vector passed to `oangle` by a negative real produces the same angle
as negating that vector. -/
@[simp]
theorem oangle_smul_right_of_neg (x y : V) {r : ℝ} (hr : r < 0) :
o.oangle x (r • y) = o.oangle x (-y) := by
rw [← neg_neg r, neg_smul, ← smul_neg, o.oangle_smul_right_of_pos _ _ (neg_pos_of_neg hr)]
/-- The angle between a nonnegative multiple of a vector and that vector is 0. -/
@[simp]
theorem oangle_smul_left_self_of_nonneg (x : V) {r : ℝ} (hr : 0 ≤ r) : o.oangle (r • x) x = 0 := by
rcases hr.lt_or_eq with (h | h)
· simp [h]
· simp [h.symm]
/-- The angle between a vector and a nonnegative multiple of that vector is 0. -/
@[simp]
theorem oangle_smul_right_self_of_nonneg (x : V) {r : ℝ} (hr : 0 ≤ r) : o.oangle x (r • x) = 0 := by
rcases hr.lt_or_eq with (h | h)
· simp [h]
· simp [h.symm]
/-- The angle between two nonnegative multiples of the same vector is 0. -/
@[simp]
theorem oangle_smul_smul_self_of_nonneg (x : V) {r₁ r₂ : ℝ} (hr₁ : 0 ≤ r₁) (hr₂ : 0 ≤ r₂) :
o.oangle (r₁ • x) (r₂ • x) = 0 := by
rcases hr₁.lt_or_eq with (h | h)
· simp [h, hr₂]
· simp [h.symm]
/-- Multiplying the first vector passed to `oangle` by a nonzero real does not change twice the
angle. -/
@[simp]
theorem two_zsmul_oangle_smul_left_of_ne_zero (x y : V) {r : ℝ} (hr : r ≠ 0) :
(2 : ℤ) • o.oangle (r • x) y = (2 : ℤ) • o.oangle x y := by
rcases hr.lt_or_lt with (h | h) <;> simp [h]
/-- Multiplying the second vector passed to `oangle` by a nonzero real does not change twice the
angle. -/
@[simp]
theorem two_zsmul_oangle_smul_right_of_ne_zero (x y : V) {r : ℝ} (hr : r ≠ 0) :
(2 : ℤ) • o.oangle x (r • y) = (2 : ℤ) • o.oangle x y := by
rcases hr.lt_or_lt with (h | h) <;> simp [h]
/-- Twice the angle between a multiple of a vector and that vector is 0. -/
@[simp]
theorem two_zsmul_oangle_smul_left_self (x : V) {r : ℝ} : (2 : ℤ) • o.oangle (r • x) x = 0 := by
rcases lt_or_le r 0 with (h | h) <;> simp [h]
/-- Twice the angle between a vector and a multiple of that vector is 0. -/
@[simp]
theorem two_zsmul_oangle_smul_right_self (x : V) {r : ℝ} : (2 : ℤ) • o.oangle x (r • x) = 0 := by
rcases lt_or_le r 0 with (h | h) <;> simp [h]
/-- Twice the angle between two multiples of a vector is 0. -/
@[simp]
theorem two_zsmul_oangle_smul_smul_self (x : V) {r₁ r₂ : ℝ} :
(2 : ℤ) • o.oangle (r₁ • x) (r₂ • x) = 0 := by by_cases h : r₁ = 0 <;> simp [h]
/-- If the spans of two vectors are equal, twice angles with those vectors on the left are
equal. -/
theorem two_zsmul_oangle_left_of_span_eq {x y : V} (z : V) (h : (ℝ ∙ x) = ℝ ∙ y) :
(2 : ℤ) • o.oangle x z = (2 : ℤ) • o.oangle y z := by
rw [Submodule.span_singleton_eq_span_singleton] at h
rcases h with ⟨r, rfl⟩
exact (o.two_zsmul_oangle_smul_left_of_ne_zero _ _ (Units.ne_zero _)).symm
/-- If the spans of two vectors are equal, twice angles with those vectors on the right are
equal. -/
theorem two_zsmul_oangle_right_of_span_eq (x : V) {y z : V} (h : (ℝ ∙ y) = ℝ ∙ z) :
(2 : ℤ) • o.oangle x y = (2 : ℤ) • o.oangle x z := by
rw [Submodule.span_singleton_eq_span_singleton] at h
rcases h with ⟨r, rfl⟩
exact (o.two_zsmul_oangle_smul_right_of_ne_zero _ _ (Units.ne_zero _)).symm
/-- If the spans of two pairs of vectors are equal, twice angles between those vectors are
equal. -/
theorem two_zsmul_oangle_of_span_eq_of_span_eq {w x y z : V} (hwx : (ℝ ∙ w) = ℝ ∙ x)
(hyz : (ℝ ∙ y) = ℝ ∙ z) : (2 : ℤ) • o.oangle w y = (2 : ℤ) • o.oangle x z := by
rw [o.two_zsmul_oangle_left_of_span_eq y hwx, o.two_zsmul_oangle_right_of_span_eq x hyz]
/-- The oriented angle between two vectors is zero if and only if the angle with the vectors
swapped is zero. -/
theorem oangle_eq_zero_iff_oangle_rev_eq_zero {x y : V} : o.oangle x y = 0 ↔ o.oangle y x = 0 := by
rw [oangle_rev, neg_eq_zero]
/-- The oriented angle between two vectors is zero if and only if they are on the same ray. -/
theorem oangle_eq_zero_iff_sameRay {x y : V} : o.oangle x y = 0 ↔ SameRay ℝ x y := by
rw [oangle, kahler_apply_apply, Complex.arg_coe_angle_eq_iff_eq_toReal, Real.Angle.toReal_zero,
Complex.arg_eq_zero_iff]
simpa using o.nonneg_inner_and_areaForm_eq_zero_iff_sameRay x y
/-- The oriented angle between two vectors is `π` if and only if the angle with the vectors
swapped is `π`. -/
theorem oangle_eq_pi_iff_oangle_rev_eq_pi {x y : V} : o.oangle x y = π ↔ o.oangle y x = π := by
rw [oangle_rev, neg_eq_iff_eq_neg, Real.Angle.neg_coe_pi]
/-- The oriented angle between two vectors is `π` if and only they are nonzero and the first is
on the same ray as the negation of the second. -/
theorem oangle_eq_pi_iff_sameRay_neg {x y : V} :
o.oangle x y = π ↔ x ≠ 0 ∧ y ≠ 0 ∧ SameRay ℝ x (-y) := by
rw [← o.oangle_eq_zero_iff_sameRay]
constructor
· intro h
by_cases hx : x = 0; · simp [hx, Real.Angle.pi_ne_zero.symm] at h
by_cases hy : y = 0; · simp [hy, Real.Angle.pi_ne_zero.symm] at h
refine ⟨hx, hy, ?_⟩
rw [o.oangle_neg_right hx hy, h, Real.Angle.coe_pi_add_coe_pi]
· rintro ⟨hx, hy, h⟩
rwa [o.oangle_neg_right hx hy, ← Real.Angle.sub_coe_pi_eq_add_coe_pi, sub_eq_zero] at h
/-- The oriented angle between two vectors is zero or `π` if and only if those two vectors are
not linearly independent. -/
theorem oangle_eq_zero_or_eq_pi_iff_not_linearIndependent {x y : V} :
o.oangle x y = 0 ∨ o.oangle x y = π ↔ ¬LinearIndependent ℝ ![x, y] := by
rw [oangle_eq_zero_iff_sameRay, oangle_eq_pi_iff_sameRay_neg,
sameRay_or_ne_zero_and_sameRay_neg_iff_not_linearIndependent]
/-- The oriented angle between two vectors is zero or `π` if and only if the first vector is zero
or the second is a multiple of the first. -/
theorem oangle_eq_zero_or_eq_pi_iff_right_eq_smul {x y : V} :
o.oangle x y = 0 ∨ o.oangle x y = π ↔ x = 0 ∨ ∃ r : ℝ, y = r • x := by
rw [oangle_eq_zero_iff_sameRay, oangle_eq_pi_iff_sameRay_neg]
refine ⟨fun h => ?_, fun h => ?_⟩
· rcases h with (h | ⟨-, -, h⟩)
· by_cases hx : x = 0; · simp [hx]
obtain ⟨r, -, rfl⟩ := h.exists_nonneg_left hx
exact Or.inr ⟨r, rfl⟩
· by_cases hx : x = 0; · simp [hx]
obtain ⟨r, -, hy⟩ := h.exists_nonneg_left hx
refine Or.inr ⟨-r, ?_⟩
simp [hy]
· rcases h with (rfl | ⟨r, rfl⟩); · simp
by_cases hx : x = 0; · simp [hx]
rcases lt_trichotomy r 0 with (hr | hr | hr)
· rw [← neg_smul]
exact Or.inr ⟨hx, smul_ne_zero hr.ne hx,
SameRay.sameRay_pos_smul_right x (Left.neg_pos_iff.2 hr)⟩
· simp [hr]
· exact Or.inl (SameRay.sameRay_pos_smul_right x hr)
/-- The oriented angle between two vectors is not zero or `π` if and only if those two vectors
are linearly independent. -/
theorem oangle_ne_zero_and_ne_pi_iff_linearIndependent {x y : V} :
o.oangle x y ≠ 0 ∧ o.oangle x y ≠ π ↔ LinearIndependent ℝ ![x, y] := by
rw [← not_or, ← not_iff_not, Classical.not_not,
oangle_eq_zero_or_eq_pi_iff_not_linearIndependent]
/-- Two vectors are equal if and only if they have equal norms and zero angle between them. -/
theorem eq_iff_norm_eq_and_oangle_eq_zero (x y : V) : x = y ↔ ‖x‖ = ‖y‖ ∧ o.oangle x y = 0 := by
rw [oangle_eq_zero_iff_sameRay]
constructor
· rintro rfl
simp; rfl
· rcases eq_or_ne y 0 with (rfl | hy)
· simp
rintro ⟨h₁, h₂⟩
obtain ⟨r, hr, rfl⟩ := h₂.exists_nonneg_right hy
have : ‖y‖ ≠ 0 := by simpa using hy
obtain rfl : r = 1 := by
apply mul_right_cancel₀ this
simpa [norm_smul, abs_of_nonneg hr] using h₁
simp
/-- Two vectors with equal norms are equal if and only if they have zero angle between them. -/
theorem eq_iff_oangle_eq_zero_of_norm_eq {x y : V} (h : ‖x‖ = ‖y‖) : x = y ↔ o.oangle x y = 0 :=
⟨fun he => ((o.eq_iff_norm_eq_and_oangle_eq_zero x y).1 he).2, fun ha =>
(o.eq_iff_norm_eq_and_oangle_eq_zero x y).2 ⟨h, ha⟩⟩
/-- Two vectors with zero angle between them are equal if and only if they have equal norms. -/
theorem eq_iff_norm_eq_of_oangle_eq_zero {x y : V} (h : o.oangle x y = 0) : x = y ↔ ‖x‖ = ‖y‖ :=
⟨fun he => ((o.eq_iff_norm_eq_and_oangle_eq_zero x y).1 he).1, fun hn =>
(o.eq_iff_norm_eq_and_oangle_eq_zero x y).2 ⟨hn, h⟩⟩
/-- Given three nonzero vectors, the angle between the first and the second plus the angle
between the second and the third equals the angle between the first and the third. -/
@[simp]
theorem oangle_add {x y z : V} (hx : x ≠ 0) (hy : y ≠ 0) (hz : z ≠ 0) :
o.oangle x y + o.oangle y z = o.oangle x z := by
simp_rw [oangle]
rw [← Complex.arg_mul_coe_angle, o.kahler_mul y x z]
· congr 1
exact mod_cast Complex.arg_real_mul _ (by positivity : 0 < ‖y‖ ^ 2)
· exact o.kahler_ne_zero hx hy
· exact o.kahler_ne_zero hy hz
/-- Given three nonzero vectors, the angle between the second and the third plus the angle
between the first and the second equals the angle between the first and the third. -/
@[simp]
theorem oangle_add_swap {x y z : V} (hx : x ≠ 0) (hy : y ≠ 0) (hz : z ≠ 0) :
o.oangle y z + o.oangle x y = o.oangle x z := by rw [add_comm, o.oangle_add hx hy hz]
/-- Given three nonzero vectors, the angle between the first and the third minus the angle
between the first and the second equals the angle between the second and the third. -/
@[simp]
theorem oangle_sub_left {x y z : V} (hx : x ≠ 0) (hy : y ≠ 0) (hz : z ≠ 0) :
o.oangle x z - o.oangle x y = o.oangle y z := by
rw [sub_eq_iff_eq_add, o.oangle_add_swap hx hy hz]
/-- Given three nonzero vectors, the angle between the first and the third minus the angle
between the second and the third equals the angle between the first and the second. -/
@[simp]
theorem oangle_sub_right {x y z : V} (hx : x ≠ 0) (hy : y ≠ 0) (hz : z ≠ 0) :
o.oangle x z - o.oangle y z = o.oangle x y := by rw [sub_eq_iff_eq_add, o.oangle_add hx hy hz]
/-- Given three nonzero vectors, adding the angles between them in cyclic order results in 0. -/
@[simp]
theorem oangle_add_cyc3 {x y z : V} (hx : x ≠ 0) (hy : y ≠ 0) (hz : z ≠ 0) :
o.oangle x y + o.oangle y z + o.oangle z x = 0 := by simp [hx, hy, hz]
/-- Given three nonzero vectors, adding the angles between them in cyclic order, with the first
vector in each angle negated, results in π. If the vectors add to 0, this is a version of the
sum of the angles of a triangle. -/
@[simp]
theorem oangle_add_cyc3_neg_left {x y z : V} (hx : x ≠ 0) (hy : y ≠ 0) (hz : z ≠ 0) :
o.oangle (-x) y + o.oangle (-y) z + o.oangle (-z) x = π := by
rw [o.oangle_neg_left hx hy, o.oangle_neg_left hy hz, o.oangle_neg_left hz hx,
show o.oangle x y + π + (o.oangle y z + π) + (o.oangle z x + π) =
o.oangle x y + o.oangle y z + o.oangle z x + (π + π + π : Real.Angle) by abel,
o.oangle_add_cyc3 hx hy hz, Real.Angle.coe_pi_add_coe_pi, zero_add, zero_add]
/-- Given three nonzero vectors, adding the angles between them in cyclic order, with the second
vector in each angle negated, results in π. If the vectors add to 0, this is a version of the
sum of the angles of a triangle. -/
@[simp]
theorem oangle_add_cyc3_neg_right {x y z : V} (hx : x ≠ 0) (hy : y ≠ 0) (hz : z ≠ 0) :
o.oangle x (-y) + o.oangle y (-z) + o.oangle z (-x) = π := by
simp_rw [← oangle_neg_left_eq_neg_right, o.oangle_add_cyc3_neg_left hx hy hz]
/-- Pons asinorum, oriented vector angle form. -/
theorem oangle_sub_eq_oangle_sub_rev_of_norm_eq {x y : V} (h : ‖x‖ = ‖y‖) :
o.oangle x (x - y) = o.oangle (y - x) y := by simp [oangle, h]
/-- The angle at the apex of an isosceles triangle is `π` minus twice a base angle, oriented
vector angle form. -/
theorem oangle_eq_pi_sub_two_zsmul_oangle_sub_of_norm_eq {x y : V} (hn : x ≠ y) (h : ‖x‖ = ‖y‖) :
o.oangle y x = π - (2 : ℤ) • o.oangle (y - x) y := by
rw [two_zsmul]
nth_rw 1 [← o.oangle_sub_eq_oangle_sub_rev_of_norm_eq h]
rw [eq_sub_iff_add_eq, ← oangle_neg_neg, ← add_assoc]
have hy : y ≠ 0 := by
rintro rfl
rw [norm_zero, norm_eq_zero] at h
exact hn h
have hx : x ≠ 0 := norm_ne_zero_iff.1 (h.symm ▸ norm_ne_zero_iff.2 hy)
convert o.oangle_add_cyc3_neg_right (neg_ne_zero.2 hy) hx (sub_ne_zero_of_ne hn.symm) using 1
simp
/-- The angle between two vectors, with respect to an orientation given by `Orientation.map`
with a linear isometric equivalence, equals the angle between those two vectors, transformed by
the inverse of that equivalence, with respect to the original orientation. -/
@[simp]
theorem oangle_map (x y : V') (f : V ≃ₗᵢ[ℝ] V') :
(Orientation.map (Fin 2) f.toLinearEquiv o).oangle x y = o.oangle (f.symm x) (f.symm y) := by
simp [oangle, o.kahler_map]
@[simp]
protected theorem _root_.Complex.oangle (w z : ℂ) :
Complex.orientation.oangle w z = Complex.arg (conj w * z) := by
simp [oangle, mul_comm z]
/-- The oriented angle on an oriented real inner product space of dimension 2 can be evaluated in
terms of a complex-number representation of the space. -/
theorem oangle_map_complex (f : V ≃ₗᵢ[ℝ] ℂ)
(hf : Orientation.map (Fin 2) f.toLinearEquiv o = Complex.orientation) (x y : V) :
o.oangle x y = Complex.arg (conj (f x) * f y) := by
rw [← Complex.oangle, ← hf, o.oangle_map]
iterate 2 rw [LinearIsometryEquiv.symm_apply_apply]
/-- Negating the orientation negates the value of `oangle`. -/
theorem oangle_neg_orientation_eq_neg (x y : V) : (-o).oangle x y = -o.oangle x y := by
simp [oangle]
/-- The inner product of two vectors is the product of the norms and the cosine of the oriented
angle between the vectors. -/
theorem inner_eq_norm_mul_norm_mul_cos_oangle (x y : V) :
⟪x, y⟫ = ‖x‖ * ‖y‖ * Real.Angle.cos (o.oangle x y) := by
by_cases hx : x = 0; · simp [hx]
by_cases hy : y = 0; · simp [hy]
rw [oangle, Real.Angle.cos_coe, Complex.cos_arg, o.norm_kahler]
· simp only [kahler_apply_apply, real_smul, add_re, ofReal_re, mul_re, I_re, ofReal_im]
field_simp
· exact o.kahler_ne_zero hx hy
/-- The cosine of the oriented angle between two nonzero vectors is the inner product divided by
the product of the norms. -/
theorem cos_oangle_eq_inner_div_norm_mul_norm {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) :
Real.Angle.cos (o.oangle x y) = ⟪x, y⟫ / (‖x‖ * ‖y‖) := by
rw [o.inner_eq_norm_mul_norm_mul_cos_oangle]
field_simp [norm_ne_zero_iff.2 hx, norm_ne_zero_iff.2 hy]
/-- The cosine of the oriented angle between two nonzero vectors equals that of the unoriented
angle. -/
theorem cos_oangle_eq_cos_angle {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) :
Real.Angle.cos (o.oangle x y) = Real.cos (InnerProductGeometry.angle x y) := by
rw [o.cos_oangle_eq_inner_div_norm_mul_norm hx hy, InnerProductGeometry.cos_angle]
/-- The oriented angle between two nonzero vectors is plus or minus the unoriented angle. -/
theorem oangle_eq_angle_or_eq_neg_angle {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) :
o.oangle x y = InnerProductGeometry.angle x y ∨
o.oangle x y = -InnerProductGeometry.angle x y :=
Real.Angle.cos_eq_real_cos_iff_eq_or_eq_neg.1 <| o.cos_oangle_eq_cos_angle hx hy
/-- The unoriented angle between two nonzero vectors is the absolute value of the oriented angle,
converted to a real. -/
theorem angle_eq_abs_oangle_toReal {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) :
InnerProductGeometry.angle x y = |(o.oangle x y).toReal| := by
have h0 := InnerProductGeometry.angle_nonneg x y
have hpi := InnerProductGeometry.angle_le_pi x y
rcases o.oangle_eq_angle_or_eq_neg_angle hx hy with (h | h)
· rw [h, eq_comm, Real.Angle.abs_toReal_coe_eq_self_iff]
exact ⟨h0, hpi⟩
· rw [h, eq_comm, Real.Angle.abs_toReal_neg_coe_eq_self_iff]
exact ⟨h0, hpi⟩
/-- If the sign of the oriented angle between two vectors is zero, either one of the vectors is
zero or the unoriented angle is 0 or π. -/
theorem eq_zero_or_angle_eq_zero_or_pi_of_sign_oangle_eq_zero {x y : V}
(h : (o.oangle x y).sign = 0) :
x = 0 ∨ y = 0 ∨ InnerProductGeometry.angle x y = 0 ∨ InnerProductGeometry.angle x y = π := by
by_cases hx : x = 0; · simp [hx]
by_cases hy : y = 0; · simp [hy]
rw [o.angle_eq_abs_oangle_toReal hx hy]
rw [Real.Angle.sign_eq_zero_iff] at h
rcases h with (h | h) <;> simp [h, Real.pi_pos.le]
/-- If two unoriented angles are equal, and the signs of the corresponding oriented angles are
equal, then the oriented angles are equal (even in degenerate cases). -/
theorem oangle_eq_of_angle_eq_of_sign_eq {w x y z : V}
(h : InnerProductGeometry.angle w x = InnerProductGeometry.angle y z)
(hs : (o.oangle w x).sign = (o.oangle y z).sign) : o.oangle w x = o.oangle y z := by
by_cases h0 : (w = 0 ∨ x = 0) ∨ y = 0 ∨ z = 0
· have hs' : (o.oangle w x).sign = 0 ∧ (o.oangle y z).sign = 0 := by
rcases h0 with ((rfl | rfl) | rfl | rfl)
· simpa using hs.symm
· simpa using hs.symm
· simpa using hs
· simpa using hs
rcases hs' with ⟨hswx, hsyz⟩
have h' : InnerProductGeometry.angle w x = π / 2 ∧ InnerProductGeometry.angle y z = π / 2 := by
rcases h0 with ((rfl | rfl) | rfl | rfl)
· simpa using h.symm
· simpa using h.symm
· simpa using h
· simpa using h
rcases h' with ⟨hwx, hyz⟩
have hpi : π / 2 ≠ π := by
intro hpi
rw [div_eq_iff, eq_comm, ← sub_eq_zero, mul_two, add_sub_cancel_right] at hpi
· exact Real.pi_pos.ne.symm hpi
· exact two_ne_zero
have h0wx : w = 0 ∨ x = 0 := by
have h0' := o.eq_zero_or_angle_eq_zero_or_pi_of_sign_oangle_eq_zero hswx
simpa [hwx, Real.pi_pos.ne.symm, hpi] using h0'
have h0yz : y = 0 ∨ z = 0 := by
have h0' := o.eq_zero_or_angle_eq_zero_or_pi_of_sign_oangle_eq_zero hsyz
simpa [hyz, Real.pi_pos.ne.symm, hpi] using h0'
rcases h0wx with (h0wx | h0wx) <;> rcases h0yz with (h0yz | h0yz) <;> simp [h0wx, h0yz]
· push_neg at h0
rw [Real.Angle.eq_iff_abs_toReal_eq_of_sign_eq hs]
rwa [o.angle_eq_abs_oangle_toReal h0.1.1 h0.1.2,
o.angle_eq_abs_oangle_toReal h0.2.1 h0.2.2] at h
/-- If the signs of two oriented angles between nonzero vectors are equal, the oriented angles are
equal if and only if the unoriented angles are equal. -/
theorem angle_eq_iff_oangle_eq_of_sign_eq {w x y z : V} (hw : w ≠ 0) (hx : x ≠ 0) (hy : y ≠ 0)
(hz : z ≠ 0) (hs : (o.oangle w x).sign = (o.oangle y z).sign) :
InnerProductGeometry.angle w x = InnerProductGeometry.angle y z ↔
o.oangle w x = o.oangle y z := by
refine ⟨fun h => o.oangle_eq_of_angle_eq_of_sign_eq h hs, fun h => ?_⟩
rw [o.angle_eq_abs_oangle_toReal hw hx, o.angle_eq_abs_oangle_toReal hy hz, h]
/-- The oriented angle between two vectors equals the unoriented angle if the sign is positive. -/
theorem oangle_eq_angle_of_sign_eq_one {x y : V} (h : (o.oangle x y).sign = 1) :
o.oangle x y = InnerProductGeometry.angle x y := by
by_cases hx : x = 0; · exfalso; simp [hx] at h
by_cases hy : y = 0; · exfalso; simp [hy] at h
refine (o.oangle_eq_angle_or_eq_neg_angle hx hy).resolve_right ?_
intro hxy
rw [hxy, Real.Angle.sign_neg, neg_eq_iff_eq_neg, ← SignType.neg_iff, ← not_le] at h
exact h (Real.Angle.sign_coe_nonneg_of_nonneg_of_le_pi (InnerProductGeometry.angle_nonneg _ _)
(InnerProductGeometry.angle_le_pi _ _))
/-- The oriented angle between two vectors equals minus the unoriented angle if the sign is
negative. -/
theorem oangle_eq_neg_angle_of_sign_eq_neg_one {x y : V} (h : (o.oangle x y).sign = -1) :
o.oangle x y = -InnerProductGeometry.angle x y := by
by_cases hx : x = 0; · exfalso; simp [hx] at h
by_cases hy : y = 0; · exfalso; simp [hy] at h
refine (o.oangle_eq_angle_or_eq_neg_angle hx hy).resolve_left ?_
intro hxy
rw [hxy, ← SignType.neg_iff, ← not_le] at h
exact h (Real.Angle.sign_coe_nonneg_of_nonneg_of_le_pi (InnerProductGeometry.angle_nonneg _ _)
(InnerProductGeometry.angle_le_pi _ _))
/-- The oriented angle between two nonzero vectors is zero if and only if the unoriented angle
is zero. -/
theorem oangle_eq_zero_iff_angle_eq_zero {x y : V} (hx : x ≠ 0) (hy : y ≠ 0) :
o.oangle x y = 0 ↔ InnerProductGeometry.angle x y = 0 := by
refine ⟨fun h => ?_, fun h => ?_⟩
· simpa [o.angle_eq_abs_oangle_toReal hx hy]
· have ha := o.oangle_eq_angle_or_eq_neg_angle hx hy
rw [h] at ha
simpa using ha
/-- The oriented angle between two vectors is `π` if and only if the unoriented angle is `π`. -/
theorem oangle_eq_pi_iff_angle_eq_pi {x y : V} :
o.oangle x y = π ↔ InnerProductGeometry.angle x y = π := by
by_cases hx : x = 0
· simp [hx, Real.Angle.pi_ne_zero.symm, div_eq_mul_inv, mul_right_eq_self₀, not_or,
Real.pi_ne_zero]
by_cases hy : y = 0
· simp [hy, Real.Angle.pi_ne_zero.symm, div_eq_mul_inv, mul_right_eq_self₀, not_or,
Real.pi_ne_zero]
refine ⟨fun h => ?_, fun h => ?_⟩
· rw [o.angle_eq_abs_oangle_toReal hx hy, h]
simp [Real.pi_pos.le]
· have ha := o.oangle_eq_angle_or_eq_neg_angle hx hy
rw [h] at ha
simpa using ha
/-- One of two vectors is zero or the oriented angle between them is plus or minus `π / 2` if
and only if the inner product of those vectors is zero. -/
theorem eq_zero_or_oangle_eq_iff_inner_eq_zero {x y : V} :
x = 0 ∨ y = 0 ∨ o.oangle x y = (π / 2 : ℝ) ∨ o.oangle x y = (-π / 2 : ℝ) ↔ ⟪x, y⟫ = 0 := by
by_cases hx : x = 0; · simp [hx]
by_cases hy : y = 0; · simp [hy]
rw [InnerProductGeometry.inner_eq_zero_iff_angle_eq_pi_div_two, or_iff_right hx, or_iff_right hy]
refine ⟨fun h => ?_, fun h => ?_⟩
· rwa [o.angle_eq_abs_oangle_toReal hx hy, Real.Angle.abs_toReal_eq_pi_div_two_iff]
· convert o.oangle_eq_angle_or_eq_neg_angle hx hy using 2 <;> rw [h]
simp only [neg_div, Real.Angle.coe_neg]
/-- If the oriented angle between two vectors is `π / 2`, the inner product of those vectors
is zero. -/
theorem inner_eq_zero_of_oangle_eq_pi_div_two {x y : V} (h : o.oangle x y = (π / 2 : ℝ)) :
⟪x, y⟫ = 0 :=
o.eq_zero_or_oangle_eq_iff_inner_eq_zero.1 <| Or.inr <| Or.inr <| Or.inl h
/-- If the oriented angle between two vectors is `π / 2`, the inner product of those vectors
(reversed) is zero. -/
theorem inner_rev_eq_zero_of_oangle_eq_pi_div_two {x y : V} (h : o.oangle x y = (π / 2 : ℝ)) :
⟪y, x⟫ = 0 := by rw [real_inner_comm, o.inner_eq_zero_of_oangle_eq_pi_div_two h]
/-- If the oriented angle between two vectors is `-π / 2`, the inner product of those vectors
is zero. -/
theorem inner_eq_zero_of_oangle_eq_neg_pi_div_two {x y : V} (h : o.oangle x y = (-π / 2 : ℝ)) :
⟪x, y⟫ = 0 :=
o.eq_zero_or_oangle_eq_iff_inner_eq_zero.1 <| Or.inr <| Or.inr <| Or.inr h
/-- If the oriented angle between two vectors is `-π / 2`, the inner product of those vectors
(reversed) is zero. -/
theorem inner_rev_eq_zero_of_oangle_eq_neg_pi_div_two {x y : V} (h : o.oangle x y = (-π / 2 : ℝ)) :
⟪y, x⟫ = 0 := by rw [real_inner_comm, o.inner_eq_zero_of_oangle_eq_neg_pi_div_two h]
/-- Negating the first vector passed to `oangle` negates the sign of the angle. -/
@[simp]
theorem oangle_sign_neg_left (x y : V) : (o.oangle (-x) y).sign = -(o.oangle x y).sign := by
by_cases hx : x = 0; · simp [hx]
by_cases hy : y = 0; · simp [hy]
rw [o.oangle_neg_left hx hy, Real.Angle.sign_add_pi]
/-- Negating the second vector passed to `oangle` negates the sign of the angle. -/
@[simp]
theorem oangle_sign_neg_right (x y : V) : (o.oangle x (-y)).sign = -(o.oangle x y).sign := by
by_cases hx : x = 0; · simp [hx]
by_cases hy : y = 0; · simp [hy]
rw [o.oangle_neg_right hx hy, Real.Angle.sign_add_pi]
/-- Multiplying the first vector passed to `oangle` by a real multiplies the sign of the angle by
the sign of the real. -/
@[simp]
theorem oangle_sign_smul_left (x y : V) (r : ℝ) :
(o.oangle (r • x) y).sign = SignType.sign r * (o.oangle x y).sign := by
rcases lt_trichotomy r 0 with (h | h | h) <;> simp [h]
/-- Multiplying the second vector passed to `oangle` by a real multiplies the sign of the angle by
the sign of the real. -/
@[simp]
theorem oangle_sign_smul_right (x y : V) (r : ℝ) :
(o.oangle x (r • y)).sign = SignType.sign r * (o.oangle x y).sign := by
rcases lt_trichotomy r 0 with (h | h | h) <;> simp [h]
/-- Auxiliary lemma for the proof of `oangle_sign_smul_add_right`; not intended to be used
outside of that proof. -/
theorem oangle_smul_add_right_eq_zero_or_eq_pi_iff {x y : V} (r : ℝ) :
o.oangle x (r • x + y) = 0 ∨ o.oangle x (r • x + y) = π ↔
o.oangle x y = 0 ∨ o.oangle x y = π := by
simp_rw [oangle_eq_zero_or_eq_pi_iff_not_linearIndependent, Fintype.not_linearIndependent_iff,
Fin.sum_univ_two, Fin.exists_fin_two]
refine ⟨fun h => ?_, fun h => ?_⟩
· rcases h with ⟨m, h, hm⟩
change m 0 • x + m 1 • (r • x + y) = 0 at h
refine ⟨![m 0 + m 1 * r, m 1], ?_⟩
change (m 0 + m 1 * r) • x + m 1 • y = 0 ∧ (m 0 + m 1 * r ≠ 0 ∨ m 1 ≠ 0)
rw [smul_add, smul_smul, ← add_assoc, ← add_smul] at h
refine ⟨h, not_and_or.1 fun h0 => ?_⟩
obtain ⟨h0, h1⟩ := h0
rw [h1] at h0 hm
rw [zero_mul, add_zero] at h0
simp [h0] at hm
· rcases h with ⟨m, h, hm⟩
change m 0 • x + m 1 • y = 0 at h
refine ⟨![m 0 - m 1 * r, m 1], ?_⟩
change (m 0 - m 1 * r) • x + m 1 • (r • x + y) = 0 ∧ (m 0 - m 1 * r ≠ 0 ∨ m 1 ≠ 0)
rw [sub_smul, smul_add, smul_smul, ← add_assoc, sub_add_cancel]
refine ⟨h, not_and_or.1 fun h0 => ?_⟩
obtain ⟨h0, h1⟩ := h0
rw [h1] at h0 hm
rw [zero_mul, sub_zero] at h0
simp [h0] at hm
/-- Adding a multiple of the first vector passed to `oangle` to the second vector does not change
the sign of the angle. -/
@[simp]
theorem oangle_sign_smul_add_right (x y : V) (r : ℝ) :
(o.oangle x (r • x + y)).sign = (o.oangle x y).sign := by
by_cases h : o.oangle x y = 0 ∨ o.oangle x y = π
· rwa [Real.Angle.sign_eq_zero_iff.2 h, Real.Angle.sign_eq_zero_iff,
oangle_smul_add_right_eq_zero_or_eq_pi_iff]
have h' : ∀ r' : ℝ, o.oangle x (r' • x + y) ≠ 0 ∧ o.oangle x (r' • x + y) ≠ π := by
intro r'
rwa [← o.oangle_smul_add_right_eq_zero_or_eq_pi_iff r', not_or] at h
let s : Set (V × V) := (fun r' : ℝ => (x, r' • x + y)) '' Set.univ
have hc : IsConnected s := isConnected_univ.image _ (by fun_prop)
have hf : ContinuousOn (fun z : V × V => o.oangle z.1 z.2) s := by
refine continuousOn_of_forall_continuousAt fun z hz => o.continuousAt_oangle ?_ ?_
all_goals
simp_rw [s, Set.mem_image] at hz
obtain ⟨r', -, rfl⟩ := hz
simp only [Prod.fst, Prod.snd]
intro hz
· simpa [hz] using (h' 0).1
· simpa [hz] using (h' r').1
have hs : ∀ z : V × V, z ∈ s → o.oangle z.1 z.2 ≠ 0 ∧ o.oangle z.1 z.2 ≠ π := by
intro z hz
simp_rw [s, Set.mem_image] at hz
obtain ⟨r', -, rfl⟩ := hz
exact h' r'
have hx : (x, y) ∈ s := by
convert Set.mem_image_of_mem (fun r' : ℝ => (x, r' • x + y)) (Set.mem_univ 0)
simp
have hy : (x, r • x + y) ∈ s := Set.mem_image_of_mem _ (Set.mem_univ _)
convert Real.Angle.sign_eq_of_continuousOn hc hf hs hx hy
/-- Adding a multiple of the second vector passed to `oangle` to the first vector does not change
the sign of the angle. -/
@[simp]
theorem oangle_sign_add_smul_left (x y : V) (r : ℝ) :
(o.oangle (x + r • y) y).sign = (o.oangle x y).sign := by
simp_rw [o.oangle_rev y, Real.Angle.sign_neg, add_comm x, oangle_sign_smul_add_right]
/-- Subtracting a multiple of the first vector passed to `oangle` from the second vector does
not change the sign of the angle. -/
@[simp]
theorem oangle_sign_sub_smul_right (x y : V) (r : ℝ) :
(o.oangle x (y - r • x)).sign = (o.oangle x y).sign := by
rw [sub_eq_add_neg, ← neg_smul, add_comm, oangle_sign_smul_add_right]
| /-- Subtracting a multiple of the second vector passed to `oangle` from the first vector does
not change the sign of the angle. -/
@[simp]
theorem oangle_sign_sub_smul_left (x y : V) (r : ℝ) :
| Mathlib/Geometry/Euclidean/Angle/Oriented/Basic.lean | 823 | 826 |
/-
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.Algebra.Group.Pointwise.Set.Card
import Mathlib.MeasureTheory.Group.Action
import Mathlib.MeasureTheory.Measure.Prod
import Mathlib.Topology.Algebra.Module.Equiv
import Mathlib.Topology.ContinuousMap.CocompactMap
import Mathlib.Topology.Algebra.ContinuousMonoidHom
/-!
# Measures on Groups
We develop some properties of measures on (topological) groups
* We define properties on measures: measures that are left or right invariant w.r.t. multiplication.
* We define the measure `μ.inv : A ↦ μ(A⁻¹)` and show that it is right invariant iff
`μ` is left invariant.
* We define a class `IsHaarMeasure μ`, requiring that the measure `μ` is left-invariant, finite
on compact sets, and positive on open sets.
We also give analogues of all these notions in the additive world.
-/
noncomputable section
open scoped NNReal ENNReal Pointwise Topology
open Inv Set Function MeasureTheory.Measure Filter
variable {G H : Type*} [MeasurableSpace G] [MeasurableSpace H]
namespace MeasureTheory
section Mul
variable [Mul G] {μ : Measure G}
@[to_additive]
theorem map_mul_left_eq_self (μ : Measure G) [IsMulLeftInvariant μ] (g : G) :
map (g * ·) μ = μ :=
IsMulLeftInvariant.map_mul_left_eq_self g
@[to_additive]
theorem map_mul_right_eq_self (μ : Measure G) [IsMulRightInvariant μ] (g : G) : map (· * g) μ = μ :=
IsMulRightInvariant.map_mul_right_eq_self g
@[to_additive MeasureTheory.isAddLeftInvariant_smul]
instance isMulLeftInvariant_smul [IsMulLeftInvariant μ] (c : ℝ≥0∞) : IsMulLeftInvariant (c • μ) :=
⟨fun g => by rw [Measure.map_smul, map_mul_left_eq_self]⟩
@[to_additive MeasureTheory.isAddRightInvariant_smul]
instance isMulRightInvariant_smul [IsMulRightInvariant μ] (c : ℝ≥0∞) :
IsMulRightInvariant (c • μ) :=
⟨fun g => by rw [Measure.map_smul, map_mul_right_eq_self]⟩
@[to_additive MeasureTheory.isAddLeftInvariant_smul_nnreal]
instance isMulLeftInvariant_smul_nnreal [IsMulLeftInvariant μ] (c : ℝ≥0) :
IsMulLeftInvariant (c • μ) :=
MeasureTheory.isMulLeftInvariant_smul (c : ℝ≥0∞)
@[to_additive MeasureTheory.isAddRightInvariant_smul_nnreal]
instance isMulRightInvariant_smul_nnreal [IsMulRightInvariant μ] (c : ℝ≥0) :
IsMulRightInvariant (c • μ) :=
MeasureTheory.isMulRightInvariant_smul (c : ℝ≥0∞)
section MeasurableMul
variable [MeasurableMul G]
@[to_additive]
theorem measurePreserving_mul_left (μ : Measure G) [IsMulLeftInvariant μ] (g : G) :
MeasurePreserving (g * ·) μ μ :=
⟨measurable_const_mul g, map_mul_left_eq_self μ g⟩
@[to_additive]
theorem MeasurePreserving.mul_left (μ : Measure G) [IsMulLeftInvariant μ] (g : G) {X : Type*}
[MeasurableSpace X] {μ' : Measure X} {f : X → G} (hf : MeasurePreserving f μ' μ) :
MeasurePreserving (fun x => g * f x) μ' μ :=
(measurePreserving_mul_left μ g).comp hf
@[to_additive]
theorem measurePreserving_mul_right (μ : Measure G) [IsMulRightInvariant μ] (g : G) :
MeasurePreserving (· * g) μ μ :=
⟨measurable_mul_const g, map_mul_right_eq_self μ g⟩
@[to_additive]
theorem MeasurePreserving.mul_right (μ : Measure G) [IsMulRightInvariant μ] (g : G) {X : Type*}
[MeasurableSpace X] {μ' : Measure X} {f : X → G} (hf : MeasurePreserving f μ' μ) :
MeasurePreserving (fun x => f x * g) μ' μ :=
(measurePreserving_mul_right μ g).comp hf
@[to_additive]
instance Subgroup.smulInvariantMeasure {G α : Type*} [Group G] [MulAction G α] [MeasurableSpace α]
{μ : Measure α} [SMulInvariantMeasure G α μ] (H : Subgroup G) : SMulInvariantMeasure H α μ :=
⟨fun y s hs => by convert SMulInvariantMeasure.measure_preimage_smul (μ := μ) (y : G) hs⟩
/-- An alternative way to prove that `μ` is left invariant under multiplication. -/
@[to_additive "An alternative way to prove that `μ` is left invariant under addition."]
theorem forall_measure_preimage_mul_iff (μ : Measure G) :
(∀ (g : G) (A : Set G), MeasurableSet A → μ ((fun h => g * h) ⁻¹' A) = μ A) ↔
IsMulLeftInvariant μ := by
trans ∀ g, map (g * ·) μ = μ
· simp_rw [Measure.ext_iff]
refine forall_congr' fun g => forall_congr' fun A => forall_congr' fun hA => ?_
rw [map_apply (measurable_const_mul g) hA]
exact ⟨fun h => ⟨h⟩, fun h => h.1⟩
/-- An alternative way to prove that `μ` is right invariant under multiplication. -/
@[to_additive "An alternative way to prove that `μ` is right invariant under addition."]
theorem forall_measure_preimage_mul_right_iff (μ : Measure G) :
(∀ (g : G) (A : Set G), MeasurableSet A → μ ((fun h => h * g) ⁻¹' A) = μ A) ↔
IsMulRightInvariant μ := by
trans ∀ g, map (· * g) μ = μ
· simp_rw [Measure.ext_iff]
refine forall_congr' fun g => forall_congr' fun A => forall_congr' fun hA => ?_
rw [map_apply (measurable_mul_const g) hA]
exact ⟨fun h => ⟨h⟩, fun h => h.1⟩
@[to_additive]
instance Measure.prod.instIsMulLeftInvariant [IsMulLeftInvariant μ] [SFinite μ] {H : Type*}
[Mul H] {mH : MeasurableSpace H} {ν : Measure H} [MeasurableMul H] [IsMulLeftInvariant ν]
[SFinite ν] : IsMulLeftInvariant (μ.prod ν) := by
constructor
rintro ⟨g, h⟩
change map (Prod.map (g * ·) (h * ·)) (μ.prod ν) = μ.prod ν
rw [← map_prod_map _ _ (measurable_const_mul g) (measurable_const_mul h),
map_mul_left_eq_self μ g, map_mul_left_eq_self ν h]
@[to_additive]
instance Measure.prod.instIsMulRightInvariant [IsMulRightInvariant μ] [SFinite μ] {H : Type*}
[Mul H] {mH : MeasurableSpace H} {ν : Measure H} [MeasurableMul H] [IsMulRightInvariant ν]
[SFinite ν] : IsMulRightInvariant (μ.prod ν) := by
constructor
rintro ⟨g, h⟩
change map (Prod.map (· * g) (· * h)) (μ.prod ν) = μ.prod ν
rw [← map_prod_map _ _ (measurable_mul_const g) (measurable_mul_const h),
map_mul_right_eq_self μ g, map_mul_right_eq_self ν h]
@[to_additive]
theorem isMulLeftInvariant_map {H : Type*} [MeasurableSpace H] [Mul H] [MeasurableMul H]
[IsMulLeftInvariant μ] (f : G →ₙ* H) (hf : Measurable f) (h_surj : Surjective f) :
IsMulLeftInvariant (Measure.map f μ) := by
refine ⟨fun h => ?_⟩
rw [map_map (measurable_const_mul _) hf]
obtain ⟨g, rfl⟩ := h_surj h
conv_rhs => rw [← map_mul_left_eq_self μ g]
rw [map_map hf (measurable_const_mul _)]
congr 2
ext y
simp only [comp_apply, map_mul]
end MeasurableMul
end Mul
section Semigroup
variable [Semigroup G] [MeasurableMul G] {μ : Measure G}
/-- The image of a left invariant measure under a left action is left invariant, assuming that
the action preserves multiplication. -/
@[to_additive "The image of a left invariant measure under a left additive action is left invariant,
assuming that the action preserves addition."]
theorem isMulLeftInvariant_map_smul
{α} [SMul α G] [SMulCommClass α G G] [MeasurableSpace α] [MeasurableSMul α G]
[IsMulLeftInvariant μ] (a : α) :
IsMulLeftInvariant (map (a • · : G → G) μ) :=
(forall_measure_preimage_mul_iff _).1 fun x _ hs =>
(smulInvariantMeasure_map_smul μ a).measure_preimage_smul x hs
/-- The image of a right invariant measure under a left action is right invariant, assuming that
the action preserves multiplication. -/
@[to_additive "The image of a right invariant measure under a left additive action is right
invariant, assuming that the action preserves addition."]
theorem isMulRightInvariant_map_smul
{α} [SMul α G] [SMulCommClass α Gᵐᵒᵖ G] [MeasurableSpace α] [MeasurableSMul α G]
[IsMulRightInvariant μ] (a : α) :
IsMulRightInvariant (map (a • · : G → G) μ) :=
(forall_measure_preimage_mul_right_iff _).1 fun x _ hs =>
(smulInvariantMeasure_map_smul μ a).measure_preimage_smul (MulOpposite.op x) hs
/-- The image of a left invariant measure under right multiplication is left invariant. -/
@[to_additive isMulLeftInvariant_map_add_right
"The image of a left invariant measure under right addition is left invariant."]
instance isMulLeftInvariant_map_mul_right [IsMulLeftInvariant μ] (g : G) :
IsMulLeftInvariant (map (· * g) μ) :=
isMulLeftInvariant_map_smul (MulOpposite.op g)
/-- The image of a right invariant measure under left multiplication is right invariant. -/
@[to_additive isMulRightInvariant_map_add_left
"The image of a right invariant measure under left addition is right invariant."]
instance isMulRightInvariant_map_mul_left [IsMulRightInvariant μ] (g : G) :
IsMulRightInvariant (map (g * ·) μ) :=
isMulRightInvariant_map_smul g
end Semigroup
section DivInvMonoid
variable [DivInvMonoid G]
@[to_additive]
theorem map_div_right_eq_self (μ : Measure G) [IsMulRightInvariant μ] (g : G) :
map (· / g) μ = μ := by simp_rw [div_eq_mul_inv, map_mul_right_eq_self μ g⁻¹]
end DivInvMonoid
section Group
variable [Group G] [MeasurableMul G]
@[to_additive]
theorem measurePreserving_div_right (μ : Measure G) [IsMulRightInvariant μ] (g : G) :
MeasurePreserving (· / g) μ μ := by simp_rw [div_eq_mul_inv, measurePreserving_mul_right μ g⁻¹]
/-- We shorten this from `measure_preimage_mul_left`, since left invariant is the preferred option
for measures in this formalization. -/
@[to_additive (attr := simp)
"We shorten this from `measure_preimage_add_left`, since left invariant is the preferred option for
measures in this formalization."]
theorem measure_preimage_mul (μ : Measure G) [IsMulLeftInvariant μ] (g : G) (A : Set G) :
μ ((fun h => g * h) ⁻¹' A) = μ A :=
calc
μ ((fun h => g * h) ⁻¹' A) = map (fun h => g * h) μ A :=
((MeasurableEquiv.mulLeft g).map_apply A).symm
_ = μ A := by rw [map_mul_left_eq_self μ g]
@[to_additive (attr := simp)]
theorem measure_preimage_mul_right (μ : Measure G) [IsMulRightInvariant μ] (g : G) (A : Set G) :
μ ((fun h => h * g) ⁻¹' A) = μ A :=
calc
μ ((fun h => h * g) ⁻¹' A) = map (fun h => h * g) μ A :=
((MeasurableEquiv.mulRight g).map_apply A).symm
_ = μ A := by rw [map_mul_right_eq_self μ g]
@[to_additive]
theorem map_mul_left_ae (μ : Measure G) [IsMulLeftInvariant μ] (x : G) :
Filter.map (fun h => x * h) (ae μ) = ae μ :=
((MeasurableEquiv.mulLeft x).map_ae μ).trans <| congr_arg ae <| map_mul_left_eq_self μ x
@[to_additive]
theorem map_mul_right_ae (μ : Measure G) [IsMulRightInvariant μ] (x : G) :
Filter.map (fun h => h * x) (ae μ) = ae μ :=
((MeasurableEquiv.mulRight x).map_ae μ).trans <| congr_arg ae <| map_mul_right_eq_self μ x
@[to_additive]
theorem map_div_right_ae (μ : Measure G) [IsMulRightInvariant μ] (x : G) :
Filter.map (fun t => t / x) (ae μ) = ae μ :=
((MeasurableEquiv.divRight x).map_ae μ).trans <| congr_arg ae <| map_div_right_eq_self μ x
@[to_additive]
theorem eventually_mul_left_iff (μ : Measure G) [IsMulLeftInvariant μ] (t : G) {p : G → Prop} :
(∀ᵐ x ∂μ, p (t * x)) ↔ ∀ᵐ x ∂μ, p x := by
conv_rhs => rw [Filter.Eventually, ← map_mul_left_ae μ t]
rfl
@[to_additive]
theorem eventually_mul_right_iff (μ : Measure G) [IsMulRightInvariant μ] (t : G) {p : G → Prop} :
(∀ᵐ x ∂μ, p (x * t)) ↔ ∀ᵐ x ∂μ, p x := by
conv_rhs => rw [Filter.Eventually, ← map_mul_right_ae μ t]
rfl
@[to_additive]
theorem eventually_div_right_iff (μ : Measure G) [IsMulRightInvariant μ] (t : G) {p : G → Prop} :
(∀ᵐ x ∂μ, p (x / t)) ↔ ∀ᵐ x ∂μ, p x := by
conv_rhs => rw [Filter.Eventually, ← map_div_right_ae μ t]
rfl
end Group
namespace Measure
-- TODO: noncomputable has to be specified explicitly. https://github.com/leanprover-community/mathlib4/issues/1074 (item 8)
/-- The measure `A ↦ μ (A⁻¹)`, where `A⁻¹` is the pointwise inverse of `A`. -/
@[to_additive "The measure `A ↦ μ (- A)`, where `- A` is the pointwise negation of `A`."]
protected noncomputable def inv [Inv G] (μ : Measure G) : Measure G :=
Measure.map inv μ
/-- A measure is invariant under negation if `- μ = μ`. Equivalently, this means that for all
measurable `A` we have `μ (- A) = μ A`, where `- A` is the pointwise negation of `A`. -/
class IsNegInvariant [Neg G] (μ : Measure G) : Prop where
neg_eq_self : μ.neg = μ
/-- A measure is invariant under inversion if `μ⁻¹ = μ`. Equivalently, this means that for all
measurable `A` we have `μ (A⁻¹) = μ A`, where `A⁻¹` is the pointwise inverse of `A`. -/
@[to_additive existing]
class IsInvInvariant [Inv G] (μ : Measure G) : Prop where
inv_eq_self : μ.inv = μ
section Inv
variable [Inv G]
@[to_additive]
theorem inv_def (μ : Measure G) : μ.inv = Measure.map inv μ := rfl
@[to_additive (attr := simp)]
theorem inv_eq_self (μ : Measure G) [IsInvInvariant μ] : μ.inv = μ :=
IsInvInvariant.inv_eq_self
@[to_additive (attr := simp)]
theorem map_inv_eq_self (μ : Measure G) [IsInvInvariant μ] : map Inv.inv μ = μ :=
IsInvInvariant.inv_eq_self
variable [MeasurableInv G]
@[to_additive]
theorem measurePreserving_inv (μ : Measure G) [IsInvInvariant μ] : MeasurePreserving Inv.inv μ μ :=
⟨measurable_inv, map_inv_eq_self μ⟩
@[to_additive]
instance inv.instSFinite (μ : Measure G) [SFinite μ] : SFinite μ.inv := by
rw [Measure.inv]; infer_instance
end Inv
section InvolutiveInv
variable [InvolutiveInv G] [MeasurableInv G]
@[to_additive (attr := simp)]
theorem inv_apply (μ : Measure G) (s : Set G) : μ.inv s = μ s⁻¹ :=
(MeasurableEquiv.inv G).map_apply s
@[to_additive (attr := simp)]
protected theorem inv_inv (μ : Measure G) : μ.inv.inv = μ :=
(MeasurableEquiv.inv G).map_symm_map
@[to_additive (attr := simp)]
theorem measure_inv (μ : Measure G) [IsInvInvariant μ] (A : Set G) : μ A⁻¹ = μ A := by
rw [← inv_apply, inv_eq_self]
@[to_additive]
theorem measure_preimage_inv (μ : Measure G) [IsInvInvariant μ] (A : Set G) :
μ (Inv.inv ⁻¹' A) = μ A :=
μ.measure_inv A
@[to_additive]
instance inv.instSigmaFinite (μ : Measure G) [SigmaFinite μ] : SigmaFinite μ.inv :=
(MeasurableEquiv.inv G).sigmaFinite_map
end InvolutiveInv
section DivisionMonoid
variable [DivisionMonoid G] [MeasurableMul G] [MeasurableInv G] {μ : Measure G}
@[to_additive]
instance inv.instIsMulRightInvariant [IsMulLeftInvariant μ] : IsMulRightInvariant μ.inv := by
constructor
intro g
conv_rhs => rw [← map_mul_left_eq_self μ g⁻¹]
simp_rw [Measure.inv, map_map (measurable_mul_const g) measurable_inv,
map_map measurable_inv (measurable_const_mul g⁻¹), Function.comp_def, mul_inv_rev, inv_inv]
@[to_additive]
instance inv.instIsMulLeftInvariant [IsMulRightInvariant μ] : IsMulLeftInvariant μ.inv := by
constructor
intro g
conv_rhs => rw [← map_mul_right_eq_self μ g⁻¹]
simp_rw [Measure.inv, map_map (measurable_const_mul g) measurable_inv,
map_map measurable_inv (measurable_mul_const g⁻¹), Function.comp_def, mul_inv_rev, inv_inv]
@[to_additive]
theorem measurePreserving_div_left (μ : Measure G) [IsInvInvariant μ] [IsMulLeftInvariant μ]
(g : G) : MeasurePreserving (fun t => g / t) μ μ := by
simp_rw [div_eq_mul_inv]
exact (measurePreserving_mul_left μ g).comp (measurePreserving_inv μ)
@[to_additive]
theorem map_div_left_eq_self (μ : Measure G) [IsInvInvariant μ] [IsMulLeftInvariant μ] (g : G) :
map (fun t => g / t) μ = μ :=
(measurePreserving_div_left μ g).map_eq
@[to_additive]
theorem measurePreserving_mul_right_inv (μ : Measure G) [IsInvInvariant μ] [IsMulLeftInvariant μ]
(g : G) : MeasurePreserving (fun t => (g * t)⁻¹) μ μ :=
(measurePreserving_inv μ).comp <| measurePreserving_mul_left μ g
@[to_additive]
theorem map_mul_right_inv_eq_self (μ : Measure G) [IsInvInvariant μ] [IsMulLeftInvariant μ]
(g : G) : map (fun t => (g * t)⁻¹) μ = μ :=
(measurePreserving_mul_right_inv μ g).map_eq
end DivisionMonoid
section Group
variable [Group G] {μ : Measure G}
section MeasurableMul
variable [MeasurableMul G]
@[to_additive]
instance : (count : Measure G).IsMulLeftInvariant where
map_mul_left_eq_self g := by
ext s hs
rw [count_apply hs, map_apply (measurable_const_mul _) hs,
count_apply (measurable_const_mul _ hs),
encard_preimage_of_bijective (Group.mulLeft_bijective _)]
@[to_additive]
instance : (count : Measure G).IsMulRightInvariant where
map_mul_right_eq_self g := by
ext s hs
rw [count_apply hs, map_apply (measurable_mul_const _) hs,
count_apply (measurable_mul_const _ hs),
encard_preimage_of_bijective (Group.mulRight_bijective _)]
end MeasurableMul
variable [MeasurableInv G]
@[to_additive]
instance : (count : Measure G).IsInvInvariant where
inv_eq_self := by ext s hs; rw [count_apply hs, inv_apply, count_apply hs.inv, encard_inv]
variable [MeasurableMul G]
@[to_additive]
theorem map_div_left_ae (μ : Measure G) [IsMulLeftInvariant μ] [IsInvInvariant μ] (x : G) :
Filter.map (fun t => x / t) (ae μ) = ae μ :=
((MeasurableEquiv.divLeft x).map_ae μ).trans <| congr_arg ae <| map_div_left_eq_self μ x
end Group
end Measure
section IsTopologicalGroup
variable [TopologicalSpace G] [BorelSpace G] {μ : Measure G} [Group G]
@[to_additive]
instance Measure.IsFiniteMeasureOnCompacts.inv [ContinuousInv G] [IsFiniteMeasureOnCompacts μ] :
IsFiniteMeasureOnCompacts μ.inv :=
IsFiniteMeasureOnCompacts.map μ (Homeomorph.inv G)
@[to_additive]
instance Measure.IsOpenPosMeasure.inv [ContinuousInv G] [IsOpenPosMeasure μ] :
IsOpenPosMeasure μ.inv :=
(Homeomorph.inv G).continuous.isOpenPosMeasure_map (Homeomorph.inv G).surjective
@[to_additive]
instance Measure.Regular.inv [ContinuousInv G] [Regular μ] : Regular μ.inv :=
Regular.map (Homeomorph.inv G)
@[to_additive]
instance Measure.InnerRegular.inv [ContinuousInv G] [InnerRegular μ] : InnerRegular μ.inv :=
InnerRegular.map (Homeomorph.inv G)
/-- The image of an inner regular measure under map of a left action is again inner regular. -/
@[to_additive
"The image of a inner regular measure under map of a left additive action is again
inner regular"]
instance innerRegular_map_smul {α} [Monoid α] [MulAction α G] [ContinuousConstSMul α G]
[InnerRegular μ] (a : α) : InnerRegular (Measure.map (a • · : G → G) μ) :=
InnerRegular.map_of_continuous (continuous_const_smul a)
/-- The image of an inner regular measure under left multiplication is again inner regular. -/
@[to_additive "The image of an inner regular measure under left addition is again inner regular."]
instance innerRegular_map_mul_left [IsTopologicalGroup G] [InnerRegular μ] (g : G) :
InnerRegular (Measure.map (g * ·) μ) := InnerRegular.map_of_continuous (continuous_mul_left g)
/-- The image of an inner regular measure under right multiplication is again inner regular. -/
@[to_additive "The image of an inner regular measure under right addition is again inner regular."]
instance innerRegular_map_mul_right [IsTopologicalGroup G] [InnerRegular μ] (g : G) :
InnerRegular (Measure.map (· * g) μ) := InnerRegular.map_of_continuous (continuous_mul_right g)
variable [IsTopologicalGroup G]
@[to_additive]
theorem regular_inv_iff : μ.inv.Regular ↔ μ.Regular :=
Regular.map_iff (Homeomorph.inv G)
@[to_additive]
theorem innerRegular_inv_iff : μ.inv.InnerRegular ↔ μ.InnerRegular :=
InnerRegular.map_iff (Homeomorph.inv G)
/-- Continuity of the measure of translates of a compact set: Given a compact set `k` in a
topological group, for `g` close enough to the origin, `μ (g • k \ k)` is arbitrarily small. -/
@[to_additive]
lemma eventually_nhds_one_measure_smul_diff_lt [LocallyCompactSpace G]
[IsFiniteMeasureOnCompacts μ] [InnerRegularCompactLTTop μ] {k : Set G}
(hk : IsCompact k) (h'k : IsClosed k) {ε : ℝ≥0∞} (hε : ε ≠ 0) :
∀ᶠ g in 𝓝 (1 : G), μ (g • k \ k) < ε := by
obtain ⟨U, hUk, hU, hμUk⟩ : ∃ (U : Set G), k ⊆ U ∧ IsOpen U ∧ μ U < μ k + ε :=
hk.exists_isOpen_lt_add hε
obtain ⟨V, hV1, hVkU⟩ : ∃ V ∈ 𝓝 (1 : G), V * k ⊆ U := compact_open_separated_mul_left hk hU hUk
filter_upwards [hV1] with g hg
calc
μ (g • k \ k) ≤ μ (U \ k) := by
gcongr
exact (smul_set_subset_smul hg).trans hVkU
_ < ε := measure_diff_lt_of_lt_add h'k.nullMeasurableSet hUk hk.measure_lt_top.ne hμUk
/-- Continuity of the measure of translates of a compact set:
Given a closed compact set `k` in a topological group,
the measure of `g • k \ k` tends to zero as `g` tends to `1`. -/
@[to_additive]
lemma tendsto_measure_smul_diff_isCompact_isClosed [LocallyCompactSpace G]
[IsFiniteMeasureOnCompacts μ] [InnerRegularCompactLTTop μ] {k : Set G}
(hk : IsCompact k) (h'k : IsClosed k) :
Tendsto (fun g : G ↦ μ (g • k \ k)) (𝓝 1) (𝓝 0) :=
ENNReal.nhds_zero_basis.tendsto_right_iff.mpr <| fun _ h ↦
eventually_nhds_one_measure_smul_diff_lt hk h'k h.ne'
section IsMulLeftInvariant
variable [IsMulLeftInvariant μ]
/-- If a left-invariant measure gives positive mass to a compact set, then it gives positive mass to
any open set. -/
@[to_additive
"If a left-invariant measure gives positive mass to a compact set, then it gives positive mass to
any open set."]
theorem isOpenPosMeasure_of_mulLeftInvariant_of_compact (K : Set G) (hK : IsCompact K)
(h : μ K ≠ 0) : IsOpenPosMeasure μ := by
refine ⟨fun U hU hne => ?_⟩
contrapose! h
rw [← nonpos_iff_eq_zero]
rw [← hU.interior_eq] at hne
obtain ⟨t, hKt⟩ : ∃ t : Finset G, K ⊆ ⋃ (g : G) (_ : g ∈ t), (fun h : G => g * h) ⁻¹' U :=
compact_covered_by_mul_left_translates hK hne
calc
μ K ≤ μ (⋃ (g : G) (_ : g ∈ t), (fun h : G => g * h) ⁻¹' U) := measure_mono hKt
_ ≤ ∑ g ∈ t, μ ((fun h : G => g * h) ⁻¹' U) := measure_biUnion_finset_le _ _
_ = 0 := by simp [measure_preimage_mul, h]
/-- A nonzero left-invariant regular measure gives positive mass to any open set. -/
@[to_additive "A nonzero left-invariant regular measure gives positive mass to any open set."]
instance (priority := 80) isOpenPosMeasure_of_mulLeftInvariant_of_regular [Regular μ] [NeZero μ] :
IsOpenPosMeasure μ :=
let ⟨K, hK, h2K⟩ := Regular.exists_isCompact_not_null.mpr (NeZero.ne μ)
isOpenPosMeasure_of_mulLeftInvariant_of_compact K hK h2K
/-- A nonzero left-invariant inner regular measure gives positive mass to any open set. -/
@[to_additive "A nonzero left-invariant inner regular measure gives positive mass to any open set."]
instance (priority := 80) isOpenPosMeasure_of_mulLeftInvariant_of_innerRegular
[InnerRegular μ] [NeZero μ] :
IsOpenPosMeasure μ :=
let ⟨K, hK, h2K⟩ := InnerRegular.exists_isCompact_not_null.mpr (NeZero.ne μ)
isOpenPosMeasure_of_mulLeftInvariant_of_compact K hK h2K
@[to_additive]
theorem null_iff_of_isMulLeftInvariant [Regular μ] {s : Set G} (hs : IsOpen s) :
μ s = 0 ↔ s = ∅ ∨ μ = 0 := by
rcases eq_zero_or_neZero μ with rfl|hμ
· simp
· simp only [or_false, hs.measure_eq_zero_iff μ, NeZero.ne μ]
@[to_additive]
theorem measure_ne_zero_iff_nonempty_of_isMulLeftInvariant [Regular μ] (hμ : μ ≠ 0) {s : Set G}
(hs : IsOpen s) : μ s ≠ 0 ↔ s.Nonempty := by
simpa [null_iff_of_isMulLeftInvariant (μ := μ) hs, hμ] using nonempty_iff_ne_empty.symm
@[to_additive]
theorem measure_pos_iff_nonempty_of_isMulLeftInvariant [Regular μ] (h3μ : μ ≠ 0) {s : Set G}
(hs : IsOpen s) : 0 < μ s ↔ s.Nonempty :=
pos_iff_ne_zero.trans <| measure_ne_zero_iff_nonempty_of_isMulLeftInvariant h3μ hs
/-- If a left-invariant measure gives finite mass to a nonempty open set, then it gives finite mass
to any compact set. -/
@[to_additive
"If a left-invariant measure gives finite mass to a nonempty open set, then it gives finite mass to
any compact set."]
theorem measure_lt_top_of_isCompact_of_isMulLeftInvariant (U : Set G) (hU : IsOpen U)
(h'U : U.Nonempty) (h : μ U ≠ ∞) {K : Set G} (hK : IsCompact K) : μ K < ∞ := by
rw [← hU.interior_eq] at h'U
obtain ⟨t, hKt⟩ : ∃ t : Finset G, K ⊆ ⋃ g ∈ t, (fun h : G => g * h) ⁻¹' U :=
compact_covered_by_mul_left_translates hK h'U
exact (measure_mono hKt).trans_lt <| measure_biUnion_lt_top t.finite_toSet <| by simp [h.lt_top]
/-- If a left-invariant measure gives finite mass to a set with nonempty interior, then
it gives finite mass to any compact set. -/
@[to_additive
"If a left-invariant measure gives finite mass to a set with nonempty interior, then it gives finite
mass to any compact set."]
theorem measure_lt_top_of_isCompact_of_isMulLeftInvariant' {U : Set G}
(hU : (interior U).Nonempty) (h : μ U ≠ ∞) {K : Set G} (hK : IsCompact K) : μ K < ∞ :=
measure_lt_top_of_isCompact_of_isMulLeftInvariant (interior U) isOpen_interior hU
((measure_mono interior_subset).trans_lt (lt_top_iff_ne_top.2 h)).ne hK
/-- In a noncompact locally compact group, a left-invariant measure which is positive
on open sets has infinite mass. -/
@[to_additive (attr := simp)
"In a noncompact locally compact additive group, a left-invariant measure which is positive on open
sets has infinite mass."]
theorem measure_univ_of_isMulLeftInvariant [WeaklyLocallyCompactSpace G] [NoncompactSpace G]
(μ : Measure G) [IsOpenPosMeasure μ] [μ.IsMulLeftInvariant] : μ univ = ∞ := by
/- Consider a closed compact set `K` with nonempty interior. For any compact set `L`, one may
find `g = g (L)` such that `L` is disjoint from `g • K`. Iterating this, one finds
infinitely many translates of `K` which are disjoint from each other. As they all have the
same positive mass, it follows that the space has infinite measure. -/
obtain ⟨K, K1, hK, Kclosed⟩ : ∃ K ∈ 𝓝 (1 : G), IsCompact K ∧ IsClosed K :=
exists_mem_nhds_isCompact_isClosed 1
have K_pos : 0 < μ K := measure_pos_of_mem_nhds μ K1
have A : ∀ L : Set G, IsCompact L → ∃ g : G, Disjoint L (g • K) := fun L hL =>
exists_disjoint_smul_of_isCompact hL hK
choose! g hg using A
set L : ℕ → Set G := fun n => (fun T => T ∪ g T • K)^[n] K
have Lcompact : ∀ n, IsCompact (L n) := by
intro n
induction' n with n IH
· exact hK
· simp_rw [L, iterate_succ']
apply IsCompact.union IH (hK.smul (g (L n)))
have Lclosed : ∀ n, IsClosed (L n) := by
intro n
induction' n with n IH
· exact Kclosed
· simp_rw [L, iterate_succ']
apply IsClosed.union IH (Kclosed.smul (g (L n)))
have M : ∀ n, μ (L n) = (n + 1 : ℕ) * μ K := by
intro n
induction' n with n IH
· simp only [L, one_mul, Nat.cast_one, iterate_zero, id, Nat.zero_add]
· calc
μ (L (n + 1)) = μ (L n) + μ (g (L n) • K) := by
simp_rw [L, iterate_succ']
exact measure_union' (hg _ (Lcompact _)) (Lclosed _).measurableSet
_ = (n + 1 + 1 : ℕ) * μ K := by
simp only [IH, measure_smul, add_mul, Nat.cast_add, Nat.cast_one, one_mul]
have N : Tendsto (fun n => μ (L n)) atTop (𝓝 (∞ * μ K)) := by
simp_rw [M]
apply ENNReal.Tendsto.mul_const _ (Or.inl ENNReal.top_ne_zero)
exact ENNReal.tendsto_nat_nhds_top.comp (tendsto_add_atTop_nat _)
simp only [ENNReal.top_mul', K_pos.ne', if_false] at N
apply top_le_iff.1
exact le_of_tendsto' N fun n => measure_mono (subset_univ _)
@[to_additive]
lemma _root_.MeasurableSet.mul_closure_one_eq {s : Set G} (hs : MeasurableSet s) :
s * (closure {1} : Set G) = s := by
induction s, hs using MeasurableSet.induction_on_open with
| isOpen U hU => exact hU.mul_closure_one_eq
| compl t _ iht => exact compl_mul_closure_one_eq_iff.2 iht
| iUnion f _ _ ihf => simp_rw [iUnion_mul f, ihf]
@[to_additive (attr := simp)]
lemma measure_mul_closure_one (s : Set G) (μ : Measure G) :
μ (s * (closure {1} : Set G)) = μ s := by
apply le_antisymm ?_ (measure_mono (subset_mul_closure_one s))
conv_rhs => rw [measure_eq_iInf]
simp only [le_iInf_iff]
intro t kt t_meas
apply measure_mono
rw [← t_meas.mul_closure_one_eq]
exact smul_subset_smul_right kt
end IsMulLeftInvariant
@[to_additive]
lemma innerRegularWRT_isCompact_isClosed_measure_ne_top_of_group [h : InnerRegularCompactLTTop μ] :
InnerRegularWRT μ (fun s ↦ IsCompact s ∧ IsClosed s) (fun s ↦ MeasurableSet s ∧ μ s ≠ ∞) := by
intro s ⟨s_meas, μs⟩ r hr
rcases h.innerRegular ⟨s_meas, μs⟩ r hr with ⟨K, Ks, K_comp, hK⟩
refine ⟨closure K, ?_, ⟨K_comp.closure, isClosed_closure⟩, ?_⟩
· exact IsCompact.closure_subset_measurableSet K_comp s_meas Ks
· rwa [K_comp.measure_closure]
end IsTopologicalGroup
section CommSemigroup
variable [CommSemigroup G]
/-- In an abelian group every left invariant measure is also right-invariant.
We don't declare the converse as an instance, since that would loop type-class inference, and
we use `IsMulLeftInvariant` as the default hypothesis in abelian groups. -/
@[to_additive IsAddLeftInvariant.isAddRightInvariant
"In an abelian additive group every left invariant measure is also right-invariant. We don't declare
the converse as an instance, since that would loop type-class inference, and we use
`IsAddLeftInvariant` as the default hypothesis in abelian groups."]
instance (priority := 100) IsMulLeftInvariant.isMulRightInvariant {μ : Measure G}
[IsMulLeftInvariant μ] : IsMulRightInvariant μ :=
| ⟨fun g => by simp_rw [mul_comm, map_mul_left_eq_self]⟩
end CommSemigroup
| Mathlib/MeasureTheory/Group/Measure.lean | 681 | 683 |
/-
Copyright (c) 2024 Rémy Degenne. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Rémy Degenne
-/
import Mathlib.MeasureTheory.Measure.GiryMonad
import Mathlib.MeasureTheory.Measure.Stieltjes
import Mathlib.Analysis.Normed.Order.Lattice
import Mathlib.MeasureTheory.Function.StronglyMeasurable.Basic
/-!
# Measurable parametric Stieltjes functions
We provide tools to build a measurable function `α → StieltjesFunction` with limits 0 at -∞ and 1 at
+∞ for all `a : α` from a measurable function `f : α → ℚ → ℝ`. These measurable parametric Stieltjes
functions are cumulative distribution functions (CDF) of transition kernels.
The reason for going through `ℚ` instead of defining directly a Stieltjes function is that since
`ℚ` is countable, building a measurable function is easier and we can obtain properties of the
form `∀ᵐ (a : α) ∂μ, ∀ (q : ℚ), ...` (for some measure `μ` on `α`) by proving the weaker
`∀ (q : ℚ), ∀ᵐ (a : α) ∂μ, ...`.
This construction will be possible if `f a : ℚ → ℝ` satisfies a package of properties for all `a`:
monotonicity, limits at +-∞ and a continuity property. We define `IsRatStieltjesPoint f a` to state
that this is the case at `a` and define the property `IsMeasurableRatCDF f` that `f` is measurable
and `IsRatStieltjesPoint f a` for all `a`.
The function `α → StieltjesFunction` obtained by extending `f` by continuity from the right is then
called `IsMeasurableRatCDF.stieltjesFunction`.
In applications, we will often only have `IsRatStieltjesPoint f a` almost surely with respect to
some measure. In order to turn that almost everywhere property into an everywhere property we define
`toRatCDF (f : α → ℚ → ℝ) := fun a q ↦ if IsRatStieltjesPoint f a then f a q else defaultRatCDF q`,
which satisfies the property `IsMeasurableRatCDF (toRatCDF f)`.
Finally, we define `stieltjesOfMeasurableRat`, composition of `toRatCDF` and
`IsMeasurableRatCDF.stieltjesFunction`.
## Main definitions
* `stieltjesOfMeasurableRat`: turn a measurable function `f : α → ℚ → ℝ` into a measurable
function `α → StieltjesFunction`.
-/
open MeasureTheory Set Filter TopologicalSpace
open scoped NNReal ENNReal MeasureTheory Topology
/-- A measurable function `α → StieltjesFunction` with limits 0 at -∞ and 1 at +∞ gives a measurable
function `α → Measure ℝ` by taking `StieltjesFunction.measure` at each point. -/
lemma StieltjesFunction.measurable_measure {α : Type*} {_ : MeasurableSpace α}
{f : α → StieltjesFunction} (hf : ∀ q, Measurable fun a ↦ f a q)
(hf_bot : ∀ a, Tendsto (f a) atBot (𝓝 0))
(hf_top : ∀ a, Tendsto (f a) atTop (𝓝 1)) :
Measurable fun a ↦ (f a).measure :=
have : ∀ a, IsProbabilityMeasure (f a).measure :=
fun a ↦ (f a).isProbabilityMeasure (hf_bot a) (hf_top a)
.measure_of_isPiSystem_of_isProbabilityMeasure (borel_eq_generateFrom_Iic ℝ) isPiSystem_Iic <| by
simp_rw [forall_mem_range, StieltjesFunction.measure_Iic (f _) (hf_bot _), sub_zero]
exact fun _ ↦ (hf _).ennreal_ofReal
namespace ProbabilityTheory
variable {α : Type*}
section IsMeasurableRatCDF
variable {f : α → ℚ → ℝ}
/-- `a : α` is a Stieltjes point for `f : α → ℚ → ℝ` if `f a` is monotone with limit 0 at -∞
and 1 at +∞ and satisfies a continuity property. -/
structure IsRatStieltjesPoint (f : α → ℚ → ℝ) (a : α) : Prop where
mono : Monotone (f a)
tendsto_atTop_one : Tendsto (f a) atTop (𝓝 1)
tendsto_atBot_zero : Tendsto (f a) atBot (𝓝 0)
iInf_rat_gt_eq : ∀ t : ℚ, ⨅ r : Ioi t, f a r = f a t
lemma isRatStieltjesPoint_unit_prod_iff (f : α → ℚ → ℝ) (a : α) :
IsRatStieltjesPoint (fun p : Unit × α ↦ f p.2) ((), a)
↔ IsRatStieltjesPoint f a := by
constructor <;>
exact fun h ↦ ⟨h.mono, h.tendsto_atTop_one, h.tendsto_atBot_zero, h.iInf_rat_gt_eq⟩
lemma measurableSet_isRatStieltjesPoint [MeasurableSpace α] (hf : Measurable f) :
MeasurableSet {a | IsRatStieltjesPoint f a} := by
have h1 : MeasurableSet {a | Monotone (f a)} := by
change MeasurableSet {a | ∀ q r (_ : q ≤ r), f a q ≤ f a r}
simp_rw [Set.setOf_forall]
refine MeasurableSet.iInter (fun q ↦ ?_)
refine MeasurableSet.iInter (fun r ↦ ?_)
refine MeasurableSet.iInter (fun _ ↦ ?_)
exact measurableSet_le hf.eval hf.eval
have h2 : MeasurableSet {a | Tendsto (f a) atTop (𝓝 1)} :=
measurableSet_tendsto _ (fun q ↦ hf.eval)
have h3 : MeasurableSet {a | Tendsto (f a) atBot (𝓝 0)} :=
measurableSet_tendsto _ (fun q ↦ hf.eval)
have h4 : MeasurableSet {a | ∀ t : ℚ, ⨅ r : Ioi t, f a r = f a t} := by
rw [Set.setOf_forall]
refine MeasurableSet.iInter (fun q ↦ ?_)
exact measurableSet_eq_fun (.iInf fun _ ↦ hf.eval) hf.eval
suffices {a | IsRatStieltjesPoint f a}
= ({a | Monotone (f a)} ∩ {a | Tendsto (f a) atTop (𝓝 1)} ∩ {a | Tendsto (f a) atBot (𝓝 0)}
∩ {a | ∀ t : ℚ, ⨅ r : Ioi t, f a r = f a t}) by
rw [this]
exact (((h1.inter h2).inter h3).inter h4)
ext a
simp only [mem_setOf_eq, mem_inter_iff]
refine ⟨fun h ↦ ?_, fun h ↦ ?_⟩
· exact ⟨⟨⟨h.mono, h.tendsto_atTop_one⟩, h.tendsto_atBot_zero⟩, h.iInf_rat_gt_eq⟩
· exact ⟨h.1.1.1, h.1.1.2, h.1.2, h.2⟩
lemma IsRatStieltjesPoint.ite {f g : α → ℚ → ℝ} {a : α} (p : α → Prop) [DecidablePred p]
(hf : p a → IsRatStieltjesPoint f a) (hg : ¬ p a → IsRatStieltjesPoint g a) :
IsRatStieltjesPoint (fun a ↦ if p a then f a else g a) a where
mono := by split_ifs with h; exacts [(hf h).mono, (hg h).mono]
tendsto_atTop_one := by
split_ifs with h; exacts [(hf h).tendsto_atTop_one, (hg h).tendsto_atTop_one]
tendsto_atBot_zero := by
split_ifs with h; exacts [(hf h).tendsto_atBot_zero, (hg h).tendsto_atBot_zero]
iInf_rat_gt_eq := by split_ifs with h; exacts [(hf h).iInf_rat_gt_eq, (hg h).iInf_rat_gt_eq]
variable [MeasurableSpace α]
/-- A function `f : α → ℚ → ℝ` is a (kernel) rational cumulative distribution function if it is
measurable in the first argument and if `f a` satisfies a list of properties for all `a : α`:
monotonicity between 0 at -∞ and 1 at +∞ and a form of continuity.
A function with these properties can be extended to a measurable function `α → StieltjesFunction`.
See `ProbabilityTheory.IsMeasurableRatCDF.stieltjesFunction`.
-/
structure IsMeasurableRatCDF (f : α → ℚ → ℝ) : Prop where
isRatStieltjesPoint : ∀ a, IsRatStieltjesPoint f a
measurable : Measurable f
lemma IsMeasurableRatCDF.nonneg {f : α → ℚ → ℝ} (hf : IsMeasurableRatCDF f) (a : α) (q : ℚ) :
0 ≤ f a q :=
Monotone.le_of_tendsto (hf.isRatStieltjesPoint a).mono
(hf.isRatStieltjesPoint a).tendsto_atBot_zero q
lemma IsMeasurableRatCDF.le_one {f : α → ℚ → ℝ} (hf : IsMeasurableRatCDF f) (a : α) (q : ℚ) :
f a q ≤ 1 :=
Monotone.ge_of_tendsto (hf.isRatStieltjesPoint a).mono
(hf.isRatStieltjesPoint a).tendsto_atTop_one q
lemma IsMeasurableRatCDF.tendsto_atTop_one {f : α → ℚ → ℝ} (hf : IsMeasurableRatCDF f) (a : α) :
Tendsto (f a) atTop (𝓝 1) := (hf.isRatStieltjesPoint a).tendsto_atTop_one
lemma IsMeasurableRatCDF.tendsto_atBot_zero {f : α → ℚ → ℝ} (hf : IsMeasurableRatCDF f) (a : α) :
Tendsto (f a) atBot (𝓝 0) := (hf.isRatStieltjesPoint a).tendsto_atBot_zero
lemma IsMeasurableRatCDF.iInf_rat_gt_eq {f : α → ℚ → ℝ} (hf : IsMeasurableRatCDF f) (a : α)
(q : ℚ) :
⨅ r : Ioi q, f a r = f a q := (hf.isRatStieltjesPoint a).iInf_rat_gt_eq q
end IsMeasurableRatCDF
section DefaultRatCDF
/-- A function with the property `IsMeasurableRatCDF`.
Used in a piecewise construction to convert a function which only satisfies the properties
defining `IsMeasurableRatCDF` on some set into a true `IsMeasurableRatCDF`. -/
def defaultRatCDF (q : ℚ) := if q < 0 then (0 : ℝ) else 1
lemma monotone_defaultRatCDF : Monotone defaultRatCDF := by
unfold defaultRatCDF
intro x y hxy
dsimp only
split_ifs with h_1 h_2 h_2
exacts [le_rfl, zero_le_one, absurd (hxy.trans_lt h_2) h_1, le_rfl]
lemma defaultRatCDF_nonneg (q : ℚ) : 0 ≤ defaultRatCDF q := by
unfold defaultRatCDF
split_ifs
exacts [le_rfl, zero_le_one]
lemma defaultRatCDF_le_one (q : ℚ) : defaultRatCDF q ≤ 1 := by
unfold defaultRatCDF
split_ifs <;> simp
lemma tendsto_defaultRatCDF_atTop : Tendsto defaultRatCDF atTop (𝓝 1) := by
refine (tendsto_congr' ?_).mp tendsto_const_nhds
rw [EventuallyEq, eventually_atTop]
exact ⟨0, fun q hq => (if_neg (not_lt.mpr hq)).symm⟩
lemma tendsto_defaultRatCDF_atBot : Tendsto defaultRatCDF atBot (𝓝 0) := by
refine (tendsto_congr' ?_).mp tendsto_const_nhds
rw [EventuallyEq, eventually_atBot]
refine ⟨-1, fun q hq => (if_pos (hq.trans_lt ?_)).symm⟩
linarith
lemma iInf_rat_gt_defaultRatCDF (t : ℚ) :
⨅ r : Ioi t, defaultRatCDF r = defaultRatCDF t := by
simp only [defaultRatCDF]
have h_bdd : BddBelow (range fun r : ↥(Ioi t) ↦ ite ((r : ℚ) < 0) (0 : ℝ) 1) := by
refine ⟨0, fun x hx ↦ ?_⟩
obtain ⟨y, rfl⟩ := mem_range.mpr hx
dsimp only
split_ifs
exacts [le_rfl, zero_le_one]
split_ifs with h
· refine le_antisymm ?_ (le_ciInf fun x ↦ ?_)
· obtain ⟨q, htq, hq_neg⟩ : ∃ q, t < q ∧ q < 0 := ⟨t / 2, by linarith, by linarith⟩
refine (ciInf_le h_bdd ⟨q, htq⟩).trans ?_
rw [if_pos]
rwa [Subtype.coe_mk]
· split_ifs
exacts [le_rfl, zero_le_one]
· refine le_antisymm ?_ ?_
· refine (ciInf_le h_bdd ⟨t + 1, lt_add_one t⟩).trans ?_
split_ifs
exacts [zero_le_one, le_rfl]
· refine le_ciInf fun x ↦ ?_
rw [if_neg]
rw [not_lt] at h ⊢
exact h.trans (mem_Ioi.mp x.prop).le
lemma isRatStieltjesPoint_defaultRatCDF (a : α) :
IsRatStieltjesPoint (fun (_ : α) ↦ defaultRatCDF) a where
mono := monotone_defaultRatCDF
tendsto_atTop_one := tendsto_defaultRatCDF_atTop
tendsto_atBot_zero := tendsto_defaultRatCDF_atBot
iInf_rat_gt_eq := iInf_rat_gt_defaultRatCDF
lemma IsMeasurableRatCDF_defaultRatCDF (α : Type*) [MeasurableSpace α] :
IsMeasurableRatCDF (fun (_ : α) (q : ℚ) ↦ defaultRatCDF q) where
isRatStieltjesPoint := isRatStieltjesPoint_defaultRatCDF
measurable := measurable_const
end DefaultRatCDF
section ToRatCDF
variable {f : α → ℚ → ℝ}
open scoped Classical in
/-- Turn a function `f : α → ℚ → ℝ` into another with the property `IsRatStieltjesPoint f a`
everywhere. At `a` that does not satisfy that property, `f a` is replaced by an arbitrary suitable
function.
Mainly useful when `f` satisfies the property `IsRatStieltjesPoint f a` almost everywhere with
respect to some measure. -/
noncomputable
def toRatCDF (f : α → ℚ → ℝ) : α → ℚ → ℝ := fun a ↦
if IsRatStieltjesPoint f a then f a else defaultRatCDF
lemma toRatCDF_of_isRatStieltjesPoint {a : α} (h : IsRatStieltjesPoint f a) (q : ℚ) :
toRatCDF f a q = f a q := by
rw [toRatCDF, if_pos h]
lemma toRatCDF_unit_prod (a : α) :
toRatCDF (fun (p : Unit × α) ↦ f p.2) ((), a) = toRatCDF f a := by
unfold toRatCDF
rw [isRatStieltjesPoint_unit_prod_iff]
variable [MeasurableSpace α]
lemma measurable_toRatCDF (hf : Measurable f) : Measurable (toRatCDF f) :=
Measurable.ite (measurableSet_isRatStieltjesPoint hf) hf measurable_const
lemma isMeasurableRatCDF_toRatCDF (hf : Measurable f) :
IsMeasurableRatCDF (toRatCDF f) where
isRatStieltjesPoint a := by
classical
exact IsRatStieltjesPoint.ite (IsRatStieltjesPoint f) id
(fun _ ↦ isRatStieltjesPoint_defaultRatCDF a)
measurable := measurable_toRatCDF hf
end ToRatCDF
section IsMeasurableRatCDF.stieltjesFunction
/-- Auxiliary definition for `IsMeasurableRatCDF.stieltjesFunction`: turn `f : α → ℚ → ℝ` into
a function `α → ℝ → ℝ` by assigning to `f a x` the infimum of `f a q` over `q : ℚ` with `x < q`. -/
noncomputable irreducible_def IsMeasurableRatCDF.stieltjesFunctionAux (f : α → ℚ → ℝ) :
α → ℝ → ℝ :=
fun a x ↦ ⨅ q : { q' : ℚ // x < q' }, f a q
lemma IsMeasurableRatCDF.stieltjesFunctionAux_def' (f : α → ℚ → ℝ) (a : α) :
IsMeasurableRatCDF.stieltjesFunctionAux f a
= fun (t : ℝ) ↦ ⨅ r : { r' : ℚ // t < r' }, f a r := by
ext t; exact IsMeasurableRatCDF.stieltjesFunctionAux_def f a t
lemma IsMeasurableRatCDF.stieltjesFunctionAux_unit_prod {f : α → ℚ → ℝ} (a : α) :
IsMeasurableRatCDF.stieltjesFunctionAux (fun (p : Unit × α) ↦ f p.2) ((), a)
= IsMeasurableRatCDF.stieltjesFunctionAux f a := by
simp_rw [IsMeasurableRatCDF.stieltjesFunctionAux_def']
variable {f : α → ℚ → ℝ} [MeasurableSpace α] (hf : IsMeasurableRatCDF f)
include hf
lemma IsMeasurableRatCDF.stieltjesFunctionAux_eq (a : α) (r : ℚ) :
IsMeasurableRatCDF.stieltjesFunctionAux f a r = f a r := by
rw [← hf.iInf_rat_gt_eq a r, IsMeasurableRatCDF.stieltjesFunctionAux]
refine Equiv.iInf_congr ?_ ?_
· exact
{ toFun := fun t ↦ ⟨t.1, mod_cast t.2⟩
invFun := fun t ↦ ⟨t.1, mod_cast t.2⟩
left_inv := fun t ↦ by simp only [Subtype.coe_eta]
right_inv := fun t ↦ by simp only [Subtype.coe_eta] }
· intro t
simp only [Equiv.coe_fn_mk, Subtype.coe_mk]
lemma IsMeasurableRatCDF.stieltjesFunctionAux_nonneg (a : α) (r : ℝ) :
0 ≤ IsMeasurableRatCDF.stieltjesFunctionAux f a r := by
have : Nonempty { r' : ℚ // r < ↑r' } := by
obtain ⟨r, hrx⟩ := exists_rat_gt r
exact ⟨⟨r, hrx⟩⟩
rw [IsMeasurableRatCDF.stieltjesFunctionAux_def]
exact le_ciInf fun r' ↦ hf.nonneg a _
lemma IsMeasurableRatCDF.monotone_stieltjesFunctionAux (a : α) :
Monotone (IsMeasurableRatCDF.stieltjesFunctionAux f a) := by
intro x y hxy
have : Nonempty { r' : ℚ // y < ↑r' } := by
obtain ⟨r, hrx⟩ := exists_rat_gt y
exact ⟨⟨r, hrx⟩⟩
simp_rw [IsMeasurableRatCDF.stieltjesFunctionAux_def]
refine le_ciInf fun r ↦ (ciInf_le ?_ ?_).trans_eq ?_
· refine ⟨0, fun z ↦ ?_⟩; rintro ⟨u, rfl⟩; exact hf.nonneg a _
· exact ⟨r.1, hxy.trans_lt r.prop⟩
· rfl
lemma IsMeasurableRatCDF.continuousWithinAt_stieltjesFunctionAux_Ici (a : α) (x : ℝ) :
ContinuousWithinAt (IsMeasurableRatCDF.stieltjesFunctionAux f a) (Ici x) x := by
rw [← continuousWithinAt_Ioi_iff_Ici]
convert Monotone.tendsto_nhdsGT (monotone_stieltjesFunctionAux hf a) x
rw [sInf_image']
have h' : ⨅ r : Ioi x, stieltjesFunctionAux f a r
= ⨅ r : { r' : ℚ // x < r' }, stieltjesFunctionAux f a r := by
refine Real.iInf_Ioi_eq_iInf_rat_gt x ?_ (monotone_stieltjesFunctionAux hf a)
refine ⟨0, fun z ↦ ?_⟩
rintro ⟨u, -, rfl⟩
exact stieltjesFunctionAux_nonneg hf a u
have h'' :
⨅ r : { r' : ℚ // x < r' }, stieltjesFunctionAux f a r =
⨅ r : { r' : ℚ // x < r' }, f a r := by
congr with r
exact stieltjesFunctionAux_eq hf a r
rw [h', h'', ContinuousWithinAt]
congr!
rw [stieltjesFunctionAux_def]
/-- Extend a function `f : α → ℚ → ℝ` with property `IsMeasurableRatCDF` from `ℚ` to `ℝ`,
to a function `α → StieltjesFunction`. -/
noncomputable def IsMeasurableRatCDF.stieltjesFunction (a : α) : StieltjesFunction where
toFun := stieltjesFunctionAux f a
mono' := monotone_stieltjesFunctionAux hf a
right_continuous' x := continuousWithinAt_stieltjesFunctionAux_Ici hf a x
| lemma IsMeasurableRatCDF.stieltjesFunction_eq (a : α) (r : ℚ) : hf.stieltjesFunction a r = f a r :=
stieltjesFunctionAux_eq hf a r
lemma IsMeasurableRatCDF.stieltjesFunction_nonneg (a : α) (r : ℝ) : 0 ≤ hf.stieltjesFunction a r :=
stieltjesFunctionAux_nonneg hf a r
lemma IsMeasurableRatCDF.stieltjesFunction_le_one (a : α) (x : ℝ) :
hf.stieltjesFunction a x ≤ 1 := by
obtain ⟨r, hrx⟩ := exists_rat_gt x
rw [← StieltjesFunction.iInf_rat_gt_eq]
simp_rw [IsMeasurableRatCDF.stieltjesFunction_eq]
refine ciInf_le_of_le ?_ ?_ (hf.le_one _ _)
· refine ⟨0, fun z ↦ ?_⟩; rintro ⟨u, rfl⟩; exact hf.nonneg a _
· exact ⟨r, hrx⟩
| Mathlib/Probability/Kernel/Disintegration/MeasurableStieltjes.lean | 348 | 362 |
/-
Copyright (c) 2022 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kim Morrison, Oleksandr Manzyuk
-/
import Mathlib.CategoryTheory.Bicategory.Basic
import Mathlib.CategoryTheory.Monoidal.Mon_
import Mathlib.CategoryTheory.Limits.Preserves.Shapes.Equalizers
/-!
# The category of bimodule objects over a pair of monoid objects.
-/
universe v₁ v₂ u₁ u₂
open CategoryTheory
open CategoryTheory.MonoidalCategory
variable {C : Type u₁} [Category.{v₁} C] [MonoidalCategory.{v₁} C]
section
open CategoryTheory.Limits
variable [HasCoequalizers C]
section
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorLeft X)]
theorem id_tensor_π_preserves_coequalizer_inv_desc {W X Y Z : C} (f g : X ⟶ Y) (h : Z ⊗ Y ⟶ W)
(wh : (Z ◁ f) ≫ h = (Z ◁ g) ≫ h) :
(Z ◁ coequalizer.π f g) ≫
(PreservesCoequalizer.iso (tensorLeft Z) f g).inv ≫ coequalizer.desc h wh =
h :=
map_π_preserves_coequalizer_inv_desc (tensorLeft Z) f g h wh
theorem id_tensor_π_preserves_coequalizer_inv_colimMap_desc {X Y Z X' Y' Z' : C} (f g : X ⟶ Y)
(f' g' : X' ⟶ Y') (p : Z ⊗ X ⟶ X') (q : Z ⊗ Y ⟶ Y') (wf : (Z ◁ f) ≫ q = p ≫ f')
(wg : (Z ◁ g) ≫ q = p ≫ g') (h : Y' ⟶ Z') (wh : f' ≫ h = g' ≫ h) :
(Z ◁ coequalizer.π f g) ≫
(PreservesCoequalizer.iso (tensorLeft Z) f g).inv ≫
colimMap (parallelPairHom (Z ◁ f) (Z ◁ g) f' g' p q wf wg) ≫ coequalizer.desc h wh =
q ≫ h :=
map_π_preserves_coequalizer_inv_colimMap_desc (tensorLeft Z) f g f' g' p q wf wg h wh
end
section
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorRight X)]
theorem π_tensor_id_preserves_coequalizer_inv_desc {W X Y Z : C} (f g : X ⟶ Y) (h : Y ⊗ Z ⟶ W)
(wh : (f ▷ Z) ≫ h = (g ▷ Z) ≫ h) :
(coequalizer.π f g ▷ Z) ≫
(PreservesCoequalizer.iso (tensorRight Z) f g).inv ≫ coequalizer.desc h wh =
h :=
map_π_preserves_coequalizer_inv_desc (tensorRight Z) f g h wh
theorem π_tensor_id_preserves_coequalizer_inv_colimMap_desc {X Y Z X' Y' Z' : C} (f g : X ⟶ Y)
(f' g' : X' ⟶ Y') (p : X ⊗ Z ⟶ X') (q : Y ⊗ Z ⟶ Y') (wf : (f ▷ Z) ≫ q = p ≫ f')
(wg : (g ▷ Z) ≫ q = p ≫ g') (h : Y' ⟶ Z') (wh : f' ≫ h = g' ≫ h) :
(coequalizer.π f g ▷ Z) ≫
(PreservesCoequalizer.iso (tensorRight Z) f g).inv ≫
colimMap (parallelPairHom (f ▷ Z) (g ▷ Z) f' g' p q wf wg) ≫ coequalizer.desc h wh =
q ≫ h :=
map_π_preserves_coequalizer_inv_colimMap_desc (tensorRight Z) f g f' g' p q wf wg h wh
end
end
/-- A bimodule object for a pair of monoid objects, all internal to some monoidal category. -/
structure Bimod (A B : Mon_ C) where
/-- The underlying monoidal category -/
X : C
/-- The left action of this bimodule object -/
actLeft : A.X ⊗ X ⟶ X
one_actLeft : (A.one ▷ X) ≫ actLeft = (λ_ X).hom := by aesop_cat
left_assoc :
(A.mul ▷ X) ≫ actLeft = (α_ A.X A.X X).hom ≫ (A.X ◁ actLeft) ≫ actLeft := by aesop_cat
/-- The right action of this bimodule object -/
actRight : X ⊗ B.X ⟶ X
actRight_one : (X ◁ B.one) ≫ actRight = (ρ_ X).hom := by aesop_cat
right_assoc :
(X ◁ B.mul) ≫ actRight = (α_ X B.X B.X).inv ≫ (actRight ▷ B.X) ≫ actRight := by
aesop_cat
middle_assoc :
(actLeft ▷ B.X) ≫ actRight = (α_ A.X X B.X).hom ≫ (A.X ◁ actRight) ≫ actLeft := by
aesop_cat
attribute [reassoc (attr := simp)] Bimod.one_actLeft Bimod.actRight_one Bimod.left_assoc
Bimod.right_assoc Bimod.middle_assoc
namespace Bimod
variable {A B : Mon_ C} (M : Bimod A B)
/-- A morphism of bimodule objects. -/
@[ext]
structure Hom (M N : Bimod A B) where
/-- The morphism between `M`'s monoidal category and `N`'s monoidal category -/
hom : M.X ⟶ N.X
left_act_hom : M.actLeft ≫ hom = (A.X ◁ hom) ≫ N.actLeft := by aesop_cat
right_act_hom : M.actRight ≫ hom = (hom ▷ B.X) ≫ N.actRight := by aesop_cat
attribute [reassoc (attr := simp)] Hom.left_act_hom Hom.right_act_hom
/-- The identity morphism on a bimodule object. -/
@[simps]
def id' (M : Bimod A B) : Hom M M where hom := 𝟙 M.X
instance homInhabited (M : Bimod A B) : Inhabited (Hom M M) :=
⟨id' M⟩
/-- Composition of bimodule object morphisms. -/
@[simps]
def comp {M N O : Bimod A B} (f : Hom M N) (g : Hom N O) : Hom M O where hom := f.hom ≫ g.hom
instance : Category (Bimod A B) where
Hom M N := Hom M N
id := id'
comp f g := comp f g
@[ext]
lemma hom_ext {M N : Bimod A B} (f g : M ⟶ N) (h : f.hom = g.hom) : f = g :=
Hom.ext h
@[simp]
theorem id_hom' (M : Bimod A B) : (𝟙 M : Hom M M).hom = 𝟙 M.X :=
rfl
@[simp]
theorem comp_hom' {M N K : Bimod A B} (f : M ⟶ N) (g : N ⟶ K) :
(f ≫ g : Hom M K).hom = f.hom ≫ g.hom :=
rfl
/-- Construct an isomorphism of bimodules by giving an isomorphism between the underlying objects
and checking compatibility with left and right actions only in the forward direction.
-/
@[simps]
def isoOfIso {X Y : Mon_ C} {P Q : Bimod X Y} (f : P.X ≅ Q.X)
(f_left_act_hom : P.actLeft ≫ f.hom = (X.X ◁ f.hom) ≫ Q.actLeft)
(f_right_act_hom : P.actRight ≫ f.hom = (f.hom ▷ Y.X) ≫ Q.actRight) : P ≅ Q where
hom :=
{ hom := f.hom }
inv :=
{ hom := f.inv
left_act_hom := by
rw [← cancel_mono f.hom, Category.assoc, Category.assoc, Iso.inv_hom_id, Category.comp_id,
f_left_act_hom, ← Category.assoc, ← MonoidalCategory.whiskerLeft_comp, Iso.inv_hom_id,
MonoidalCategory.whiskerLeft_id, Category.id_comp]
right_act_hom := by
rw [← cancel_mono f.hom, Category.assoc, Category.assoc, Iso.inv_hom_id, Category.comp_id,
f_right_act_hom, ← Category.assoc, ← comp_whiskerRight, Iso.inv_hom_id,
MonoidalCategory.id_whiskerRight, Category.id_comp] }
hom_inv_id := by ext; dsimp; rw [Iso.hom_inv_id]
inv_hom_id := by ext; dsimp; rw [Iso.inv_hom_id]
variable (A)
/-- A monoid object as a bimodule over itself. -/
@[simps]
def regular : Bimod A A where
X := A.X
actLeft := A.mul
actRight := A.mul
instance : Inhabited (Bimod A A) :=
⟨regular A⟩
/-- The forgetful functor from bimodule objects to the ambient category. -/
def forget : Bimod A B ⥤ C where
obj A := A.X
map f := f.hom
open CategoryTheory.Limits
variable [HasCoequalizers C]
namespace TensorBimod
variable {R S T : Mon_ C} (P : Bimod R S) (Q : Bimod S T)
/-- The underlying object of the tensor product of two bimodules. -/
noncomputable def X : C :=
coequalizer (P.actRight ▷ Q.X) ((α_ _ _ _).hom ≫ (P.X ◁ Q.actLeft))
section
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorLeft X)]
/-- Left action for the tensor product of two bimodules. -/
noncomputable def actLeft : R.X ⊗ X P Q ⟶ X P Q :=
(PreservesCoequalizer.iso (tensorLeft R.X) _ _).inv ≫
colimMap
(parallelPairHom _ _ _ _
((α_ _ _ _).inv ≫ ((α_ _ _ _).inv ▷ _) ≫ (P.actLeft ▷ S.X ▷ Q.X))
((α_ _ _ _).inv ≫ (P.actLeft ▷ Q.X))
(by
dsimp
simp only [Category.assoc]
slice_lhs 1 2 => rw [associator_inv_naturality_middle]
slice_rhs 3 4 => rw [← comp_whiskerRight, middle_assoc, comp_whiskerRight]
monoidal)
(by
dsimp
slice_lhs 1 1 => rw [MonoidalCategory.whiskerLeft_comp]
slice_lhs 2 3 => rw [associator_inv_naturality_right]
slice_lhs 3 4 => rw [whisker_exchange]
monoidal))
theorem whiskerLeft_π_actLeft :
(R.X ◁ coequalizer.π _ _) ≫ actLeft P Q =
(α_ _ _ _).inv ≫ (P.actLeft ▷ Q.X) ≫ coequalizer.π _ _ := by
erw [map_π_preserves_coequalizer_inv_colimMap (tensorLeft _)]
simp only [Category.assoc]
theorem one_act_left' : (R.one ▷ _) ≫ actLeft P Q = (λ_ _).hom := by
refine (cancel_epi ((tensorLeft _).map (coequalizer.π _ _))).1 ?_
dsimp [X]
-- Porting note: had to replace `rw` by `erw`
slice_lhs 1 2 => erw [whisker_exchange]
slice_lhs 2 3 => rw [whiskerLeft_π_actLeft]
slice_lhs 1 2 => rw [associator_inv_naturality_left]
slice_lhs 2 3 => rw [← comp_whiskerRight, one_actLeft]
slice_rhs 1 2 => rw [leftUnitor_naturality]
monoidal
theorem left_assoc' :
(R.mul ▷ _) ≫ actLeft P Q = (α_ R.X R.X _).hom ≫ (R.X ◁ actLeft P Q) ≫ actLeft P Q := by
refine (cancel_epi ((tensorLeft _).map (coequalizer.π _ _))).1 ?_
dsimp [X]
slice_lhs 1 2 => rw [whisker_exchange]
slice_lhs 2 3 => rw [whiskerLeft_π_actLeft]
slice_lhs 1 2 => rw [associator_inv_naturality_left]
slice_lhs 2 3 => rw [← comp_whiskerRight, left_assoc, comp_whiskerRight, comp_whiskerRight]
slice_rhs 1 2 => rw [associator_naturality_right]
slice_rhs 2 3 =>
rw [← MonoidalCategory.whiskerLeft_comp, whiskerLeft_π_actLeft,
MonoidalCategory.whiskerLeft_comp, MonoidalCategory.whiskerLeft_comp]
slice_rhs 4 5 => rw [whiskerLeft_π_actLeft]
slice_rhs 3 4 => rw [associator_inv_naturality_middle]
monoidal
end
section
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorRight X)]
/-- Right action for the tensor product of two bimodules. -/
noncomputable def actRight : X P Q ⊗ T.X ⟶ X P Q :=
(PreservesCoequalizer.iso (tensorRight T.X) _ _).inv ≫
colimMap
(parallelPairHom _ _ _ _
((α_ _ _ _).hom ≫ (α_ _ _ _).hom ≫ (P.X ◁ S.X ◁ Q.actRight) ≫ (α_ _ _ _).inv)
((α_ _ _ _).hom ≫ (P.X ◁ Q.actRight))
(by
dsimp
slice_lhs 1 2 => rw [associator_naturality_left]
slice_lhs 2 3 => rw [← whisker_exchange]
simp)
(by
dsimp
simp only [comp_whiskerRight, whisker_assoc, Category.assoc, Iso.inv_hom_id_assoc]
slice_lhs 3 4 =>
rw [← MonoidalCategory.whiskerLeft_comp, middle_assoc,
MonoidalCategory.whiskerLeft_comp]
simp))
theorem π_tensor_id_actRight :
(coequalizer.π _ _ ▷ T.X) ≫ actRight P Q =
(α_ _ _ _).hom ≫ (P.X ◁ Q.actRight) ≫ coequalizer.π _ _ := by
erw [map_π_preserves_coequalizer_inv_colimMap (tensorRight _)]
simp only [Category.assoc]
theorem actRight_one' : (_ ◁ T.one) ≫ actRight P Q = (ρ_ _).hom := by
refine (cancel_epi ((tensorRight _).map (coequalizer.π _ _))).1 ?_
dsimp [X]
-- Porting note: had to replace `rw` by `erw`
slice_lhs 1 2 =>erw [← whisker_exchange]
slice_lhs 2 3 => rw [π_tensor_id_actRight]
slice_lhs 1 2 => rw [associator_naturality_right]
slice_lhs 2 3 => rw [← MonoidalCategory.whiskerLeft_comp, actRight_one]
simp
theorem right_assoc' :
(_ ◁ T.mul) ≫ actRight P Q =
(α_ _ T.X T.X).inv ≫ (actRight P Q ▷ T.X) ≫ actRight P Q := by
refine (cancel_epi ((tensorRight _).map (coequalizer.π _ _))).1 ?_
dsimp [X]
-- Porting note: had to replace some `rw` by `erw`
slice_lhs 1 2 => rw [← whisker_exchange]
slice_lhs 2 3 => rw [π_tensor_id_actRight]
slice_lhs 1 2 => rw [associator_naturality_right]
slice_lhs 2 3 => rw [← MonoidalCategory.whiskerLeft_comp, right_assoc,
MonoidalCategory.whiskerLeft_comp, MonoidalCategory.whiskerLeft_comp]
slice_rhs 1 2 => rw [associator_inv_naturality_left]
slice_rhs 2 3 => rw [← comp_whiskerRight, π_tensor_id_actRight, comp_whiskerRight,
comp_whiskerRight]
slice_rhs 4 5 => rw [π_tensor_id_actRight]
simp
end
section
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorLeft X)]
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorRight X)]
theorem middle_assoc' :
(actLeft P Q ▷ T.X) ≫ actRight P Q =
(α_ R.X _ T.X).hom ≫ (R.X ◁ actRight P Q) ≫ actLeft P Q := by
refine (cancel_epi ((tensorLeft _ ⋙ tensorRight _).map (coequalizer.π _ _))).1 ?_
dsimp [X]
slice_lhs 1 2 => rw [← comp_whiskerRight, whiskerLeft_π_actLeft, comp_whiskerRight,
comp_whiskerRight]
slice_lhs 3 4 => rw [π_tensor_id_actRight]
slice_lhs 2 3 => rw [associator_naturality_left]
-- Porting note: had to replace `rw` by `erw`
slice_rhs 1 2 => rw [associator_naturality_middle]
slice_rhs 2 3 => rw [← MonoidalCategory.whiskerLeft_comp, π_tensor_id_actRight,
MonoidalCategory.whiskerLeft_comp, MonoidalCategory.whiskerLeft_comp]
slice_rhs 4 5 => rw [whiskerLeft_π_actLeft]
slice_rhs 3 4 => rw [associator_inv_naturality_right]
slice_rhs 4 5 => rw [whisker_exchange]
simp
end
end TensorBimod
section
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorLeft X)]
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorRight X)]
/-- Tensor product of two bimodule objects as a bimodule object. -/
@[simps]
noncomputable def tensorBimod {X Y Z : Mon_ C} (M : Bimod X Y) (N : Bimod Y Z) : Bimod X Z where
X := TensorBimod.X M N
actLeft := TensorBimod.actLeft M N
actRight := TensorBimod.actRight M N
one_actLeft := TensorBimod.one_act_left' M N
actRight_one := TensorBimod.actRight_one' M N
left_assoc := TensorBimod.left_assoc' M N
right_assoc := TensorBimod.right_assoc' M N
middle_assoc := TensorBimod.middle_assoc' M N
/-- Left whiskering for morphisms of bimodule objects. -/
@[simps]
noncomputable def whiskerLeft {X Y Z : Mon_ C} (M : Bimod X Y) {N₁ N₂ : Bimod Y Z} (f : N₁ ⟶ N₂) :
M.tensorBimod N₁ ⟶ M.tensorBimod N₂ where
hom :=
colimMap
(parallelPairHom _ _ _ _ (_ ◁ f.hom) (_ ◁ f.hom)
(by rw [whisker_exchange])
(by
simp only [Category.assoc, tensor_whiskerLeft, Iso.inv_hom_id_assoc,
Iso.cancel_iso_hom_left]
slice_lhs 1 2 => rw [← MonoidalCategory.whiskerLeft_comp, Hom.left_act_hom]
simp))
left_act_hom := by
refine (cancel_epi ((tensorLeft _).map (coequalizer.π _ _))).1 ?_
dsimp
slice_lhs 1 2 => rw [TensorBimod.whiskerLeft_π_actLeft]
slice_lhs 3 4 => rw [ι_colimMap, parallelPairHom_app_one]
slice_rhs 1 2 => rw [← MonoidalCategory.whiskerLeft_comp, ι_colimMap, parallelPairHom_app_one,
MonoidalCategory.whiskerLeft_comp]
slice_rhs 2 3 => rw [TensorBimod.whiskerLeft_π_actLeft]
slice_rhs 1 2 => rw [associator_inv_naturality_right]
slice_rhs 2 3 => rw [whisker_exchange]
simp
right_act_hom := by
refine (cancel_epi ((tensorRight _).map (coequalizer.π _ _))).1 ?_
dsimp
slice_lhs 1 2 => rw [TensorBimod.π_tensor_id_actRight]
slice_lhs 3 4 => rw [ι_colimMap, parallelPairHom_app_one]
slice_lhs 2 3 => rw [← MonoidalCategory.whiskerLeft_comp, Hom.right_act_hom]
slice_rhs 1 2 =>
rw [← comp_whiskerRight, ι_colimMap, parallelPairHom_app_one, comp_whiskerRight]
slice_rhs 2 3 => rw [TensorBimod.π_tensor_id_actRight]
simp
/-- Right whiskering for morphisms of bimodule objects. -/
@[simps]
noncomputable def whiskerRight {X Y Z : Mon_ C} {M₁ M₂ : Bimod X Y} (f : M₁ ⟶ M₂) (N : Bimod Y Z) :
M₁.tensorBimod N ⟶ M₂.tensorBimod N where
hom :=
colimMap
(parallelPairHom _ _ _ _ (f.hom ▷ _ ▷ _) (f.hom ▷ _)
(by rw [← comp_whiskerRight, Hom.right_act_hom, comp_whiskerRight])
(by
slice_lhs 2 3 => rw [whisker_exchange]
simp))
left_act_hom := by
refine (cancel_epi ((tensorLeft _).map (coequalizer.π _ _))).1 ?_
dsimp
slice_lhs 1 2 => rw [TensorBimod.whiskerLeft_π_actLeft]
slice_lhs 3 4 => rw [ι_colimMap, parallelPairHom_app_one]
slice_lhs 2 3 => rw [← comp_whiskerRight, Hom.left_act_hom]
slice_rhs 1 2 => rw [← MonoidalCategory.whiskerLeft_comp, ι_colimMap, parallelPairHom_app_one,
MonoidalCategory.whiskerLeft_comp]
slice_rhs 2 3 => rw [TensorBimod.whiskerLeft_π_actLeft]
slice_rhs 1 2 => rw [associator_inv_naturality_middle]
simp
right_act_hom := by
refine (cancel_epi ((tensorRight _).map (coequalizer.π _ _))).1 ?_
dsimp
slice_lhs 1 2 => rw [TensorBimod.π_tensor_id_actRight]
slice_lhs 3 4 => rw [ι_colimMap, parallelPairHom_app_one]
slice_lhs 2 3 => rw [whisker_exchange]
slice_rhs 1 2 => rw [← comp_whiskerRight, ι_colimMap, parallelPairHom_app_one,
comp_whiskerRight]
slice_rhs 2 3 => rw [TensorBimod.π_tensor_id_actRight]
simp
end
namespace AssociatorBimod
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorLeft X)]
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorRight X)]
variable {R S T U : Mon_ C} (P : Bimod R S) (Q : Bimod S T) (L : Bimod T U)
/-- An auxiliary morphism for the definition of the underlying morphism of the forward component of
the associator isomorphism. -/
noncomputable def homAux : (P.tensorBimod Q).X ⊗ L.X ⟶ (P.tensorBimod (Q.tensorBimod L)).X :=
(PreservesCoequalizer.iso (tensorRight L.X) _ _).inv ≫
coequalizer.desc ((α_ _ _ _).hom ≫ (P.X ◁ coequalizer.π _ _) ≫ coequalizer.π _ _)
(by
dsimp; dsimp [TensorBimod.X]
slice_lhs 1 2 => rw [associator_naturality_left]
slice_lhs 2 3 => rw [← whisker_exchange]
slice_lhs 3 4 => rw [coequalizer.condition]
slice_lhs 2 3 => rw [associator_naturality_right]
slice_lhs 3 4 =>
rw [← MonoidalCategory.whiskerLeft_comp,
TensorBimod.whiskerLeft_π_actLeft, MonoidalCategory.whiskerLeft_comp]
simp)
/-- The underlying morphism of the forward component of the associator isomorphism. -/
noncomputable def hom :
((P.tensorBimod Q).tensorBimod L).X ⟶ (P.tensorBimod (Q.tensorBimod L)).X :=
coequalizer.desc (homAux P Q L)
(by
dsimp [homAux]
refine (cancel_epi ((tensorRight _ ⋙ tensorRight _).map (coequalizer.π _ _))).1 ?_
dsimp [TensorBimod.X]
slice_lhs 1 2 => rw [← comp_whiskerRight, TensorBimod.π_tensor_id_actRight,
comp_whiskerRight, comp_whiskerRight]
slice_lhs 3 5 => rw [π_tensor_id_preserves_coequalizer_inv_desc]
slice_lhs 2 3 => rw [associator_naturality_middle]
slice_lhs 3 4 =>
rw [← MonoidalCategory.whiskerLeft_comp, coequalizer.condition,
MonoidalCategory.whiskerLeft_comp, MonoidalCategory.whiskerLeft_comp]
slice_rhs 1 2 => rw [associator_naturality_left]
slice_rhs 2 3 => rw [← whisker_exchange]
slice_rhs 3 5 => rw [π_tensor_id_preserves_coequalizer_inv_desc]
simp)
theorem hom_left_act_hom' :
((P.tensorBimod Q).tensorBimod L).actLeft ≫ hom P Q L =
(R.X ◁ hom P Q L) ≫ (P.tensorBimod (Q.tensorBimod L)).actLeft := by
dsimp; dsimp [hom, homAux]
refine (cancel_epi ((tensorLeft _).map (coequalizer.π _ _))).1 ?_
rw [tensorLeft_map]
slice_lhs 1 2 => rw [TensorBimod.whiskerLeft_π_actLeft]
slice_lhs 3 4 => rw [coequalizer.π_desc]
slice_rhs 1 2 => rw [← MonoidalCategory.whiskerLeft_comp, coequalizer.π_desc,
MonoidalCategory.whiskerLeft_comp]
refine (cancel_epi ((tensorRight _ ⋙ tensorLeft _).map (coequalizer.π _ _))).1 ?_
dsimp; dsimp [TensorBimod.X]
slice_lhs 1 2 => rw [associator_inv_naturality_middle]
slice_lhs 2 3 =>
rw [← comp_whiskerRight, TensorBimod.whiskerLeft_π_actLeft,
comp_whiskerRight, comp_whiskerRight]
slice_lhs 4 6 => rw [π_tensor_id_preserves_coequalizer_inv_desc]
slice_lhs 3 4 => rw [associator_naturality_left]
slice_rhs 1 3 =>
rw [← MonoidalCategory.whiskerLeft_comp, ← MonoidalCategory.whiskerLeft_comp,
π_tensor_id_preserves_coequalizer_inv_desc, MonoidalCategory.whiskerLeft_comp,
MonoidalCategory.whiskerLeft_comp]
slice_rhs 3 4 => erw [TensorBimod.whiskerLeft_π_actLeft P (Q.tensorBimod L)]
slice_rhs 2 3 => erw [associator_inv_naturality_right]
slice_rhs 3 4 => erw [whisker_exchange]
monoidal
theorem hom_right_act_hom' :
((P.tensorBimod Q).tensorBimod L).actRight ≫ hom P Q L =
(hom P Q L ▷ U.X) ≫ (P.tensorBimod (Q.tensorBimod L)).actRight := by
dsimp; dsimp [hom, homAux]
refine (cancel_epi ((tensorRight _).map (coequalizer.π _ _))).1 ?_
rw [tensorRight_map]
slice_lhs 1 2 => rw [TensorBimod.π_tensor_id_actRight]
slice_lhs 3 4 => rw [coequalizer.π_desc]
slice_rhs 1 2 => rw [← comp_whiskerRight, coequalizer.π_desc, comp_whiskerRight]
refine (cancel_epi ((tensorRight _ ⋙ tensorRight _).map (coequalizer.π _ _))).1 ?_
dsimp; dsimp [TensorBimod.X]
slice_lhs 1 2 => rw [associator_naturality_left]
slice_lhs 2 3 => rw [← whisker_exchange]
slice_lhs 3 5 => rw [π_tensor_id_preserves_coequalizer_inv_desc]
slice_lhs 2 3 => rw [associator_naturality_right]
slice_rhs 1 3 =>
rw [← comp_whiskerRight, ← comp_whiskerRight, π_tensor_id_preserves_coequalizer_inv_desc,
comp_whiskerRight, comp_whiskerRight]
slice_rhs 3 4 => erw [TensorBimod.π_tensor_id_actRight P (Q.tensorBimod L)]
slice_rhs 2 3 => erw [associator_naturality_middle]
dsimp
slice_rhs 3 4 =>
rw [← MonoidalCategory.whiskerLeft_comp, TensorBimod.π_tensor_id_actRight,
MonoidalCategory.whiskerLeft_comp, MonoidalCategory.whiskerLeft_comp]
monoidal
/-- An auxiliary morphism for the definition of the underlying morphism of the inverse component of
the associator isomorphism. -/
noncomputable def invAux : P.X ⊗ (Q.tensorBimod L).X ⟶ ((P.tensorBimod Q).tensorBimod L).X :=
(PreservesCoequalizer.iso (tensorLeft P.X) _ _).inv ≫
coequalizer.desc ((α_ _ _ _).inv ≫ (coequalizer.π _ _ ▷ L.X) ≫ coequalizer.π _ _)
(by
dsimp; dsimp [TensorBimod.X]
slice_lhs 1 2 => rw [associator_inv_naturality_middle]
rw [← Iso.inv_hom_id_assoc (α_ _ _ _) (P.X ◁ Q.actRight), comp_whiskerRight]
slice_lhs 3 4 =>
rw [← comp_whiskerRight, Category.assoc, ← TensorBimod.π_tensor_id_actRight,
comp_whiskerRight]
slice_lhs 4 5 => rw [coequalizer.condition]
slice_lhs 3 4 => rw [associator_naturality_left]
slice_rhs 1 2 => rw [MonoidalCategory.whiskerLeft_comp]
slice_rhs 2 3 => rw [associator_inv_naturality_right]
slice_rhs 3 4 => rw [whisker_exchange]
monoidal)
/-- The underlying morphism of the inverse component of the associator isomorphism. -/
noncomputable def inv :
(P.tensorBimod (Q.tensorBimod L)).X ⟶ ((P.tensorBimod Q).tensorBimod L).X :=
coequalizer.desc (invAux P Q L)
(by
dsimp [invAux]
refine (cancel_epi ((tensorLeft _).map (coequalizer.π _ _))).1 ?_
dsimp [TensorBimod.X]
slice_lhs 1 2 => rw [whisker_exchange]
slice_lhs 2 4 => rw [id_tensor_π_preserves_coequalizer_inv_desc]
slice_lhs 1 2 => rw [associator_inv_naturality_left]
slice_lhs 2 3 =>
rw [← comp_whiskerRight, coequalizer.condition, comp_whiskerRight, comp_whiskerRight]
slice_rhs 1 2 => rw [associator_naturality_right]
slice_rhs 2 3 =>
rw [← MonoidalCategory.whiskerLeft_comp, TensorBimod.whiskerLeft_π_actLeft,
MonoidalCategory.whiskerLeft_comp, MonoidalCategory.whiskerLeft_comp]
slice_rhs 4 6 => rw [id_tensor_π_preserves_coequalizer_inv_desc]
slice_rhs 3 4 => rw [associator_inv_naturality_middle]
monoidal)
theorem hom_inv_id : hom P Q L ≫ inv P Q L = 𝟙 _ := by
dsimp [hom, homAux, inv, invAux]
apply coequalizer.hom_ext
slice_lhs 1 2 => rw [coequalizer.π_desc]
refine (cancel_epi ((tensorRight _).map (coequalizer.π _ _))).1 ?_
rw [tensorRight_map]
slice_lhs 1 3 => rw [π_tensor_id_preserves_coequalizer_inv_desc]
slice_lhs 3 4 => rw [coequalizer.π_desc]
slice_lhs 2 4 => rw [id_tensor_π_preserves_coequalizer_inv_desc]
slice_lhs 1 3 => rw [Iso.hom_inv_id_assoc]
dsimp only [TensorBimod.X]
slice_rhs 2 3 => rw [Category.comp_id]
rfl
theorem inv_hom_id : inv P Q L ≫ hom P Q L = 𝟙 _ := by
dsimp [hom, homAux, inv, invAux]
apply coequalizer.hom_ext
slice_lhs 1 2 => rw [coequalizer.π_desc]
refine (cancel_epi ((tensorLeft _).map (coequalizer.π _ _))).1 ?_
rw [tensorLeft_map]
slice_lhs 1 3 => rw [id_tensor_π_preserves_coequalizer_inv_desc]
slice_lhs 3 4 => rw [coequalizer.π_desc]
slice_lhs 2 4 => rw [π_tensor_id_preserves_coequalizer_inv_desc]
slice_lhs 1 3 => rw [Iso.inv_hom_id_assoc]
dsimp only [TensorBimod.X]
slice_rhs 2 3 => rw [Category.comp_id]
rfl
end AssociatorBimod
namespace LeftUnitorBimod
variable {R S : Mon_ C} (P : Bimod R S)
/-- The underlying morphism of the forward component of the left unitor isomorphism. -/
noncomputable def hom : TensorBimod.X (regular R) P ⟶ P.X :=
coequalizer.desc P.actLeft (by dsimp; rw [Category.assoc, left_assoc])
/-- The underlying morphism of the inverse component of the left unitor isomorphism. -/
noncomputable def inv : P.X ⟶ TensorBimod.X (regular R) P :=
(λ_ P.X).inv ≫ (R.one ▷ _) ≫ coequalizer.π _ _
theorem hom_inv_id : hom P ≫ inv P = 𝟙 _ := by
dsimp only [hom, inv, TensorBimod.X]
ext; dsimp
slice_lhs 1 2 => rw [coequalizer.π_desc]
slice_lhs 1 2 => rw [leftUnitor_inv_naturality]
slice_lhs 2 3 => rw [whisker_exchange]
slice_lhs 3 3 => rw [← Iso.inv_hom_id_assoc (α_ R.X R.X P.X) (R.X ◁ P.actLeft)]
slice_lhs 4 6 => rw [← Category.assoc, ← coequalizer.condition]
slice_lhs 2 3 => rw [associator_inv_naturality_left]
slice_lhs 3 4 => rw [← comp_whiskerRight, Mon_.one_mul]
slice_rhs 1 2 => rw [Category.comp_id]
monoidal
theorem inv_hom_id : inv P ≫ hom P = 𝟙 _ := by
dsimp [hom, inv]
slice_lhs 3 4 => rw [coequalizer.π_desc]
rw [one_actLeft, Iso.inv_hom_id]
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorLeft X)]
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorRight X)]
theorem hom_left_act_hom' :
((regular R).tensorBimod P).actLeft ≫ hom P = (R.X ◁ hom P) ≫ P.actLeft := by
dsimp; dsimp [hom, TensorBimod.actLeft, regular]
refine (cancel_epi ((tensorLeft _).map (coequalizer.π _ _))).1 ?_
dsimp
slice_lhs 1 4 => rw [id_tensor_π_preserves_coequalizer_inv_colimMap_desc]
slice_lhs 2 3 => rw [left_assoc]
slice_rhs 1 2 => rw [← MonoidalCategory.whiskerLeft_comp, coequalizer.π_desc]
rw [Iso.inv_hom_id_assoc]
theorem hom_right_act_hom' :
((regular R).tensorBimod P).actRight ≫ hom P = (hom P ▷ S.X) ≫ P.actRight := by
dsimp; dsimp [hom, TensorBimod.actRight, regular]
refine (cancel_epi ((tensorRight _).map (coequalizer.π _ _))).1 ?_
dsimp
slice_lhs 1 4 => rw [π_tensor_id_preserves_coequalizer_inv_colimMap_desc]
slice_rhs 1 2 => rw [← comp_whiskerRight, coequalizer.π_desc]
slice_rhs 1 2 => rw [middle_assoc]
simp only [Category.assoc]
end LeftUnitorBimod
namespace RightUnitorBimod
variable {R S : Mon_ C} (P : Bimod R S)
/-- The underlying morphism of the forward component of the right unitor isomorphism. -/
noncomputable def hom : TensorBimod.X P (regular S) ⟶ P.X :=
coequalizer.desc P.actRight (by dsimp; rw [Category.assoc, right_assoc, Iso.hom_inv_id_assoc])
/-- The underlying morphism of the inverse component of the right unitor isomorphism. -/
noncomputable def inv : P.X ⟶ TensorBimod.X P (regular S) :=
(ρ_ P.X).inv ≫ (_ ◁ S.one) ≫ coequalizer.π _ _
theorem hom_inv_id : hom P ≫ inv P = 𝟙 _ := by
dsimp only [hom, inv, TensorBimod.X]
ext; dsimp
slice_lhs 1 2 => rw [coequalizer.π_desc]
slice_lhs 1 2 => rw [rightUnitor_inv_naturality]
slice_lhs 2 3 => rw [← whisker_exchange]
slice_lhs 3 4 => rw [coequalizer.condition]
slice_lhs 2 3 => rw [associator_naturality_right]
slice_lhs 3 4 => rw [← MonoidalCategory.whiskerLeft_comp, Mon_.mul_one]
slice_rhs 1 2 => rw [Category.comp_id]
monoidal
theorem inv_hom_id : inv P ≫ hom P = 𝟙 _ := by
dsimp [hom, inv]
slice_lhs 3 4 => rw [coequalizer.π_desc]
rw [actRight_one, Iso.inv_hom_id]
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorLeft X)]
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorRight X)]
theorem hom_left_act_hom' :
(P.tensorBimod (regular S)).actLeft ≫ hom P = (R.X ◁ hom P) ≫ P.actLeft := by
dsimp; dsimp [hom, TensorBimod.actLeft, regular]
refine (cancel_epi ((tensorLeft _).map (coequalizer.π _ _))).1 ?_
dsimp
slice_lhs 1 4 => rw [id_tensor_π_preserves_coequalizer_inv_colimMap_desc]
slice_lhs 2 3 => rw [middle_assoc]
slice_rhs 1 2 => rw [← MonoidalCategory.whiskerLeft_comp, coequalizer.π_desc]
rw [Iso.inv_hom_id_assoc]
theorem hom_right_act_hom' :
(P.tensorBimod (regular S)).actRight ≫ hom P = (hom P ▷ S.X) ≫ P.actRight := by
dsimp; dsimp [hom, TensorBimod.actRight, regular]
refine (cancel_epi ((tensorRight _).map (coequalizer.π _ _))).1 ?_
dsimp
slice_lhs 1 4 => rw [π_tensor_id_preserves_coequalizer_inv_colimMap_desc]
slice_lhs 2 3 => rw [right_assoc]
slice_rhs 1 2 => rw [← comp_whiskerRight, coequalizer.π_desc]
rw [Iso.hom_inv_id_assoc]
end RightUnitorBimod
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorLeft X)]
variable [∀ X : C, PreservesColimitsOfSize.{0, 0} (tensorRight X)]
/-- The associator as a bimodule isomorphism. -/
noncomputable def associatorBimod {W X Y Z : Mon_ C} (L : Bimod W X) (M : Bimod X Y)
(N : Bimod Y Z) : (L.tensorBimod M).tensorBimod N ≅ L.tensorBimod (M.tensorBimod N) :=
isoOfIso
{ hom := AssociatorBimod.hom L M N
inv := AssociatorBimod.inv L M N
hom_inv_id := AssociatorBimod.hom_inv_id L M N
inv_hom_id := AssociatorBimod.inv_hom_id L M N } (AssociatorBimod.hom_left_act_hom' L M N)
(AssociatorBimod.hom_right_act_hom' L M N)
/-- The left unitor as a bimodule isomorphism. -/
noncomputable def leftUnitorBimod {X Y : Mon_ C} (M : Bimod X Y) : (regular X).tensorBimod M ≅ M :=
isoOfIso
{ hom := LeftUnitorBimod.hom M
inv := LeftUnitorBimod.inv M
hom_inv_id := LeftUnitorBimod.hom_inv_id M
inv_hom_id := LeftUnitorBimod.inv_hom_id M } (LeftUnitorBimod.hom_left_act_hom' M)
(LeftUnitorBimod.hom_right_act_hom' M)
/-- The right unitor as a bimodule isomorphism. -/
noncomputable def rightUnitorBimod {X Y : Mon_ C} (M : Bimod X Y) : M.tensorBimod (regular Y) ≅ M :=
isoOfIso
{ hom := RightUnitorBimod.hom M
inv := RightUnitorBimod.inv M
hom_inv_id := RightUnitorBimod.hom_inv_id M
inv_hom_id := RightUnitorBimod.inv_hom_id M } (RightUnitorBimod.hom_left_act_hom' M)
(RightUnitorBimod.hom_right_act_hom' M)
theorem whiskerLeft_id_bimod {X Y Z : Mon_ C} {M : Bimod X Y} {N : Bimod Y Z} :
whiskerLeft M (𝟙 N) = 𝟙 (M.tensorBimod N) := by
ext
apply Limits.coequalizer.hom_ext
dsimp only [tensorBimod_X, whiskerLeft_hom, id_hom']
simp only [MonoidalCategory.whiskerLeft_id, ι_colimMap, parallelPair_obj_one,
parallelPairHom_app_one, Category.id_comp]
erw [Category.comp_id]
theorem id_whiskerRight_bimod {X Y Z : Mon_ C} {M : Bimod X Y} {N : Bimod Y Z} :
whiskerRight (𝟙 M) N = 𝟙 (M.tensorBimod N) := by
ext
apply Limits.coequalizer.hom_ext
dsimp only [tensorBimod_X, whiskerRight_hom, id_hom']
simp only [MonoidalCategory.id_whiskerRight, ι_colimMap, parallelPair_obj_one,
parallelPairHom_app_one, Category.id_comp]
erw [Category.comp_id]
theorem whiskerLeft_comp_bimod {X Y Z : Mon_ C} (M : Bimod X Y) {N P Q : Bimod Y Z} (f : N ⟶ P)
(g : P ⟶ Q) : whiskerLeft M (f ≫ g) = whiskerLeft M f ≫ whiskerLeft M g := by
ext
apply Limits.coequalizer.hom_ext
simp
theorem id_whiskerLeft_bimod {X Y : Mon_ C} {M N : Bimod X Y} (f : M ⟶ N) :
whiskerLeft (regular X) f = (leftUnitorBimod M).hom ≫ f ≫ (leftUnitorBimod N).inv := by
dsimp [tensorHom, regular, leftUnitorBimod]
ext
apply coequalizer.hom_ext
dsimp
slice_lhs 1 2 => rw [ι_colimMap, parallelPairHom_app_one]
dsimp [LeftUnitorBimod.hom]
slice_rhs 1 2 => rw [coequalizer.π_desc]
dsimp [LeftUnitorBimod.inv]
slice_rhs 1 2 => rw [Hom.left_act_hom]
slice_rhs 2 3 => rw [leftUnitor_inv_naturality]
slice_rhs 3 4 => rw [whisker_exchange]
slice_rhs 4 4 => rw [← Iso.inv_hom_id_assoc (α_ X.X X.X N.X) (X.X ◁ N.actLeft)]
slice_rhs 5 7 => rw [← Category.assoc, ← coequalizer.condition]
slice_rhs 3 4 => rw [associator_inv_naturality_left]
| slice_rhs 4 5 => rw [← comp_whiskerRight, Mon_.one_mul]
have : (λ_ (X.X ⊗ N.X)).inv ≫ (α_ (𝟙_ C) X.X N.X).inv ≫ ((λ_ X.X).hom ▷ N.X) = 𝟙 _ := by
monoidal
slice_rhs 2 4 => rw [this]
slice_rhs 1 2 => rw [Category.comp_id]
theorem comp_whiskerLeft_bimod {W X Y Z : Mon_ C} (M : Bimod W X) (N : Bimod X Y)
{P P' : Bimod Y Z} (f : P ⟶ P') :
whiskerLeft (M.tensorBimod N) f =
| Mathlib/CategoryTheory/Monoidal/Bimod.lean | 768 | 776 |
/-
Copyright (c) 2019 Alexander Bentkamp. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Alexander Bentkamp, Yury Kudryashov, Yaël Dillies
-/
import Mathlib.Algebra.Order.BigOperators.Ring.Finset
import Mathlib.Algebra.Order.Module.OrderedSMul
import Mathlib.Algebra.Order.Module.Synonym
import Mathlib.Algebra.Ring.Action.Pointwise.Set
import Mathlib.Analysis.Convex.Star
import Mathlib.Tactic.FieldSimp
import Mathlib.Tactic.NoncommRing
import Mathlib.LinearAlgebra.AffineSpace.AffineSubspace.Defs
/-!
# Convex sets and functions in vector spaces
In a 𝕜-vector space, we define the following objects and properties.
* `Convex 𝕜 s`: A set `s` is convex if for any two points `x y ∈ s` it includes `segment 𝕜 x y`.
* `stdSimplex 𝕜 ι`: The standard simplex in `ι → 𝕜` (currently requires `Fintype ι`). It is the
intersection of the positive quadrant with the hyperplane `s.sum = 1`.
We also provide various equivalent versions of the definitions above, prove that some specific sets
are convex.
## TODO
Generalize all this file to affine spaces.
-/
variable {𝕜 E F β : Type*}
open LinearMap Set
open scoped Convex Pointwise
/-! ### Convexity of sets -/
section OrderedSemiring
variable [Semiring 𝕜] [PartialOrder 𝕜]
section AddCommMonoid
variable [AddCommMonoid E] [AddCommMonoid F]
section SMul
variable (𝕜) [SMul 𝕜 E] [SMul 𝕜 F] (s : Set E) {x : E}
/-- Convexity of sets. -/
def Convex : Prop :=
∀ ⦃x : E⦄, x ∈ s → StarConvex 𝕜 x s
variable {𝕜 s}
theorem Convex.starConvex (hs : Convex 𝕜 s) (hx : x ∈ s) : StarConvex 𝕜 x s :=
hs hx
theorem convex_iff_segment_subset : Convex 𝕜 s ↔ ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → [x -[𝕜] y] ⊆ s :=
forall₂_congr fun _ _ => starConvex_iff_segment_subset
theorem Convex.segment_subset (h : Convex 𝕜 s) {x y : E} (hx : x ∈ s) (hy : y ∈ s) :
[x -[𝕜] y] ⊆ s :=
convex_iff_segment_subset.1 h hx hy
theorem Convex.openSegment_subset (h : Convex 𝕜 s) {x y : E} (hx : x ∈ s) (hy : y ∈ s) :
openSegment 𝕜 x y ⊆ s :=
(openSegment_subset_segment 𝕜 x y).trans (h.segment_subset hx hy)
/-- Alternative definition of set convexity, in terms of pointwise set operations. -/
theorem convex_iff_pointwise_add_subset :
Convex 𝕜 s ↔ ∀ ⦃a b : 𝕜⦄, 0 ≤ a → 0 ≤ b → a + b = 1 → a • s + b • s ⊆ s :=
Iff.intro
(by
rintro hA a b ha hb hab w ⟨au, ⟨u, hu, rfl⟩, bv, ⟨v, hv, rfl⟩, rfl⟩
exact hA hu hv ha hb hab)
fun h _ hx _ hy _ _ ha hb hab => (h ha hb hab) (Set.add_mem_add ⟨_, hx, rfl⟩ ⟨_, hy, rfl⟩)
alias ⟨Convex.set_combo_subset, _⟩ := convex_iff_pointwise_add_subset
theorem convex_empty : Convex 𝕜 (∅ : Set E) := fun _ => False.elim
theorem convex_univ : Convex 𝕜 (Set.univ : Set E) := fun _ _ => starConvex_univ _
theorem Convex.inter {t : Set E} (hs : Convex 𝕜 s) (ht : Convex 𝕜 t) : Convex 𝕜 (s ∩ t) :=
fun _ hx => (hs hx.1).inter (ht hx.2)
theorem convex_sInter {S : Set (Set E)} (h : ∀ s ∈ S, Convex 𝕜 s) : Convex 𝕜 (⋂₀ S) := fun _ hx =>
starConvex_sInter fun _ hs => h _ hs <| hx _ hs
theorem convex_iInter {ι : Sort*} {s : ι → Set E} (h : ∀ i, Convex 𝕜 (s i)) :
Convex 𝕜 (⋂ i, s i) :=
sInter_range s ▸ convex_sInter <| forall_mem_range.2 h
theorem convex_iInter₂ {ι : Sort*} {κ : ι → Sort*} {s : (i : ι) → κ i → Set E}
(h : ∀ i j, Convex 𝕜 (s i j)) : Convex 𝕜 (⋂ (i) (j), s i j) :=
convex_iInter fun i => convex_iInter <| h i
theorem Convex.prod {s : Set E} {t : Set F} (hs : Convex 𝕜 s) (ht : Convex 𝕜 t) :
Convex 𝕜 (s ×ˢ t) := fun _ hx => (hs hx.1).prod (ht hx.2)
theorem convex_pi {ι : Type*} {E : ι → Type*} [∀ i, AddCommMonoid (E i)] [∀ i, SMul 𝕜 (E i)]
{s : Set ι} {t : ∀ i, Set (E i)} (ht : ∀ ⦃i⦄, i ∈ s → Convex 𝕜 (t i)) : Convex 𝕜 (s.pi t) :=
fun _ hx => starConvex_pi fun _ hi => ht hi <| hx _ hi
theorem Directed.convex_iUnion {ι : Sort*} {s : ι → Set E} (hdir : Directed (· ⊆ ·) s)
(hc : ∀ ⦃i : ι⦄, Convex 𝕜 (s i)) : Convex 𝕜 (⋃ i, s i) := by
rintro x hx y hy a b ha hb hab
rw [mem_iUnion] at hx hy ⊢
obtain ⟨i, hx⟩ := hx
obtain ⟨j, hy⟩ := hy
obtain ⟨k, hik, hjk⟩ := hdir i j
exact ⟨k, hc (hik hx) (hjk hy) ha hb hab⟩
theorem DirectedOn.convex_sUnion {c : Set (Set E)} (hdir : DirectedOn (· ⊆ ·) c)
(hc : ∀ ⦃A : Set E⦄, A ∈ c → Convex 𝕜 A) : Convex 𝕜 (⋃₀ c) := by
rw [sUnion_eq_iUnion]
exact (directedOn_iff_directed.1 hdir).convex_iUnion fun A => hc A.2
end SMul
section Module
variable [Module 𝕜 E] [Module 𝕜 F] {s : Set E} {x : E}
theorem convex_iff_openSegment_subset [ZeroLEOneClass 𝕜] :
Convex 𝕜 s ↔ ∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → openSegment 𝕜 x y ⊆ s :=
forall₂_congr fun _ => starConvex_iff_openSegment_subset
theorem convex_iff_forall_pos :
Convex 𝕜 s ↔
∀ ⦃x⦄, x ∈ s → ∀ ⦃y⦄, y ∈ s → ∀ ⦃a b : 𝕜⦄, 0 < a → 0 < b → a + b = 1 → a • x + b • y ∈ s :=
forall₂_congr fun _ => starConvex_iff_forall_pos
theorem convex_iff_pairwise_pos : Convex 𝕜 s ↔
s.Pairwise fun x y => ∀ ⦃a b : 𝕜⦄, 0 < a → 0 < b → a + b = 1 → a • x + b • y ∈ s := by
refine convex_iff_forall_pos.trans ⟨fun h x hx y hy _ => h hx hy, ?_⟩
intro h x hx y hy a b ha hb hab
obtain rfl | hxy := eq_or_ne x y
· rwa [Convex.combo_self hab]
· exact h hx hy hxy ha hb hab
theorem Convex.starConvex_iff [ZeroLEOneClass 𝕜] (hs : Convex 𝕜 s) (h : s.Nonempty) :
StarConvex 𝕜 x s ↔ x ∈ s :=
⟨fun hxs => hxs.mem h, hs.starConvex⟩
protected theorem Set.Subsingleton.convex {s : Set E} (h : s.Subsingleton) : Convex 𝕜 s :=
convex_iff_pairwise_pos.mpr (h.pairwise _)
@[simp] theorem convex_singleton (c : E) : Convex 𝕜 ({c} : Set E) :=
subsingleton_singleton.convex
theorem convex_zero : Convex 𝕜 (0 : Set E) :=
convex_singleton _
theorem convex_segment [IsOrderedRing 𝕜] (x y : E) : Convex 𝕜 [x -[𝕜] y] := by
rintro p ⟨ap, bp, hap, hbp, habp, rfl⟩ q ⟨aq, bq, haq, hbq, habq, rfl⟩ a b ha hb hab
refine
⟨a * ap + b * aq, a * bp + b * bq, add_nonneg (mul_nonneg ha hap) (mul_nonneg hb haq),
add_nonneg (mul_nonneg ha hbp) (mul_nonneg hb hbq), ?_, ?_⟩
· rw [add_add_add_comm, ← mul_add, ← mul_add, habp, habq, mul_one, mul_one, hab]
· match_scalars <;> noncomm_ring
theorem Convex.linear_image (hs : Convex 𝕜 s) (f : E →ₗ[𝕜] F) : Convex 𝕜 (f '' s) := by
rintro _ ⟨x, hx, rfl⟩ _ ⟨y, hy, rfl⟩ a b ha hb hab
exact ⟨a • x + b • y, hs hx hy ha hb hab, by rw [f.map_add, f.map_smul, f.map_smul]⟩
theorem Convex.is_linear_image (hs : Convex 𝕜 s) {f : E → F} (hf : IsLinearMap 𝕜 f) :
Convex 𝕜 (f '' s) :=
hs.linear_image <| hf.mk' f
theorem Convex.linear_preimage {𝕜₁ : Type*} [Semiring 𝕜₁] [Module 𝕜₁ E] [Module 𝕜₁ F] {s : Set F}
[SMul 𝕜 𝕜₁] [IsScalarTower 𝕜 𝕜₁ E] [IsScalarTower 𝕜 𝕜₁ F] (hs : Convex 𝕜 s) (f : E →ₗ[𝕜₁] F) :
Convex 𝕜 (f ⁻¹' s) := fun x hx y hy a b ha hb hab => by
rw [mem_preimage, f.map_add, LinearMap.map_smul_of_tower, LinearMap.map_smul_of_tower]
exact hs hx hy ha hb hab
theorem Convex.is_linear_preimage {𝕜₁ : Type*} [Semiring 𝕜₁] [Module 𝕜₁ E] [Module 𝕜₁ F] {s : Set F}
[SMul 𝕜 𝕜₁] [IsScalarTower 𝕜 𝕜₁ E] [IsScalarTower 𝕜 𝕜₁ F] (hs : Convex 𝕜 s) {f : E → F}
(hf : IsLinearMap 𝕜₁ f) :
Convex 𝕜 (f ⁻¹' s) :=
hs.linear_preimage <| hf.mk' f
theorem Convex.add {t : Set E} (hs : Convex 𝕜 s) (ht : Convex 𝕜 t) : Convex 𝕜 (s + t) := by
rw [← add_image_prod]
exact (hs.prod ht).is_linear_image IsLinearMap.isLinearMap_add
variable (𝕜 E)
/-- The convex sets form an additive submonoid under pointwise addition. -/
def convexAddSubmonoid : AddSubmonoid (Set E) where
carrier := {s : Set E | Convex 𝕜 s}
zero_mem' := convex_zero
add_mem' := Convex.add
@[simp, norm_cast]
theorem coe_convexAddSubmonoid : ↑(convexAddSubmonoid 𝕜 E) = {s : Set E | Convex 𝕜 s} :=
rfl
variable {𝕜 E}
@[simp]
theorem mem_convexAddSubmonoid {s : Set E} : s ∈ convexAddSubmonoid 𝕜 E ↔ Convex 𝕜 s :=
Iff.rfl
theorem convex_list_sum {l : List (Set E)} (h : ∀ i ∈ l, Convex 𝕜 i) : Convex 𝕜 l.sum :=
(convexAddSubmonoid 𝕜 E).list_sum_mem h
theorem convex_multiset_sum {s : Multiset (Set E)} (h : ∀ i ∈ s, Convex 𝕜 i) : Convex 𝕜 s.sum :=
(convexAddSubmonoid 𝕜 E).multiset_sum_mem _ h
theorem convex_sum {ι} {s : Finset ι} (t : ι → Set E) (h : ∀ i ∈ s, Convex 𝕜 (t i)) :
Convex 𝕜 (∑ i ∈ s, t i) :=
(convexAddSubmonoid 𝕜 E).sum_mem h
theorem Convex.vadd (hs : Convex 𝕜 s) (z : E) : Convex 𝕜 (z +ᵥ s) := by
simp_rw [← image_vadd, vadd_eq_add, ← singleton_add]
exact (convex_singleton _).add hs
theorem Convex.translate (hs : Convex 𝕜 s) (z : E) : Convex 𝕜 ((fun x => z + x) '' s) :=
hs.vadd _
/-- The translation of a convex set is also convex. -/
theorem Convex.translate_preimage_right (hs : Convex 𝕜 s) (z : E) :
Convex 𝕜 ((fun x => z + x) ⁻¹' s) := by
intro x hx y hy a b ha hb hab
have h := hs hx hy ha hb hab
rwa [smul_add, smul_add, add_add_add_comm, ← add_smul, hab, one_smul] at h
/-- The translation of a convex set is also convex. -/
theorem Convex.translate_preimage_left (hs : Convex 𝕜 s) (z : E) :
Convex 𝕜 ((fun x => x + z) ⁻¹' s) := by
simpa only [add_comm] using hs.translate_preimage_right z
section OrderedAddCommMonoid
variable [AddCommMonoid β] [PartialOrder β] [IsOrderedAddMonoid β] [Module 𝕜 β] [OrderedSMul 𝕜 β]
theorem convex_Iic (r : β) : Convex 𝕜 (Iic r) := fun x hx y hy a b ha hb hab =>
calc
a • x + b • y ≤ a • r + b • r :=
add_le_add (smul_le_smul_of_nonneg_left hx ha) (smul_le_smul_of_nonneg_left hy hb)
_ = r := Convex.combo_self hab _
theorem convex_Ici (r : β) : Convex 𝕜 (Ici r) :=
convex_Iic (β := βᵒᵈ) r
theorem convex_Icc (r s : β) : Convex 𝕜 (Icc r s) :=
Ici_inter_Iic.subst ((convex_Ici r).inter <| convex_Iic s)
theorem convex_halfSpace_le {f : E → β} (h : IsLinearMap 𝕜 f) (r : β) : Convex 𝕜 { w | f w ≤ r } :=
(convex_Iic r).is_linear_preimage h
@[deprecated (since := "2024-11-12")] alias convex_halfspace_le := convex_halfSpace_le
theorem convex_halfSpace_ge {f : E → β} (h : IsLinearMap 𝕜 f) (r : β) : Convex 𝕜 { w | r ≤ f w } :=
(convex_Ici r).is_linear_preimage h
@[deprecated (since := "2024-11-12")] alias convex_halfspace_ge := convex_halfSpace_ge
theorem convex_hyperplane {f : E → β} (h : IsLinearMap 𝕜 f) (r : β) : Convex 𝕜 { w | f w = r } := by
simp_rw [le_antisymm_iff]
exact (convex_halfSpace_le h r).inter (convex_halfSpace_ge h r)
end OrderedAddCommMonoid
section OrderedCancelAddCommMonoid
variable [AddCommMonoid β] [PartialOrder β] [IsOrderedCancelAddMonoid β]
[Module 𝕜 β] [OrderedSMul 𝕜 β]
theorem convex_Iio (r : β) : Convex 𝕜 (Iio r) := by
intro x hx y hy a b ha hb hab
obtain rfl | ha' := ha.eq_or_lt
· rw [zero_add] at hab
rwa [zero_smul, zero_add, hab, one_smul]
rw [mem_Iio] at hx hy
calc
a • x + b • y < a • r + b • r := add_lt_add_of_lt_of_le
(smul_lt_smul_of_pos_left hx ha') (smul_le_smul_of_nonneg_left hy.le hb)
_ = r := Convex.combo_self hab _
theorem convex_Ioi (r : β) : Convex 𝕜 (Ioi r) :=
convex_Iio (β := βᵒᵈ) r
theorem convex_Ioo (r s : β) : Convex 𝕜 (Ioo r s) :=
Ioi_inter_Iio.subst ((convex_Ioi r).inter <| convex_Iio s)
theorem convex_Ico (r s : β) : Convex 𝕜 (Ico r s) :=
Ici_inter_Iio.subst ((convex_Ici r).inter <| convex_Iio s)
theorem convex_Ioc (r s : β) : Convex 𝕜 (Ioc r s) :=
Ioi_inter_Iic.subst ((convex_Ioi r).inter <| convex_Iic s)
theorem convex_halfSpace_lt {f : E → β} (h : IsLinearMap 𝕜 f) (r : β) : Convex 𝕜 { w | f w < r } :=
(convex_Iio r).is_linear_preimage h
@[deprecated (since := "2024-11-12")] alias convex_halfspace_lt := convex_halfSpace_lt
theorem convex_halfSpace_gt {f : E → β} (h : IsLinearMap 𝕜 f) (r : β) : Convex 𝕜 { w | r < f w } :=
(convex_Ioi r).is_linear_preimage h
@[deprecated (since := "2024-11-12")] alias convex_halfspace_gt := convex_halfSpace_gt
end OrderedCancelAddCommMonoid
section LinearOrderedAddCommMonoid
variable [AddCommMonoid β] [LinearOrder β] [IsOrderedAddMonoid β] [Module 𝕜 β] [OrderedSMul 𝕜 β]
theorem convex_uIcc (r s : β) : Convex 𝕜 (uIcc r s) :=
convex_Icc _ _
end LinearOrderedAddCommMonoid
end Module
end AddCommMonoid
section LinearOrderedAddCommMonoid
variable [AddCommMonoid E] [LinearOrder E] [IsOrderedAddMonoid E]
[PartialOrder β] [Module 𝕜 E] [OrderedSMul 𝕜 E]
{s : Set E} {f : E → β}
theorem MonotoneOn.convex_le (hf : MonotoneOn f s) (hs : Convex 𝕜 s) (r : β) :
Convex 𝕜 ({ x ∈ s | f x ≤ r }) := fun x hx y hy _ _ ha hb hab =>
⟨hs hx.1 hy.1 ha hb hab,
(hf (hs hx.1 hy.1 ha hb hab) (max_rec' s hx.1 hy.1) (Convex.combo_le_max x y ha hb hab)).trans
(max_rec' { x | f x ≤ r } hx.2 hy.2)⟩
theorem MonotoneOn.convex_lt (hf : MonotoneOn f s) (hs : Convex 𝕜 s) (r : β) :
Convex 𝕜 ({ x ∈ s | f x < r }) := fun x hx y hy _ _ ha hb hab =>
⟨hs hx.1 hy.1 ha hb hab,
(hf (hs hx.1 hy.1 ha hb hab) (max_rec' s hx.1 hy.1)
(Convex.combo_le_max x y ha hb hab)).trans_lt
(max_rec' { x | f x < r } hx.2 hy.2)⟩
theorem MonotoneOn.convex_ge (hf : MonotoneOn f s) (hs : Convex 𝕜 s) (r : β) :
Convex 𝕜 ({ x ∈ s | r ≤ f x }) :=
MonotoneOn.convex_le (E := Eᵒᵈ) (β := βᵒᵈ) hf.dual hs r
theorem MonotoneOn.convex_gt (hf : MonotoneOn f s) (hs : Convex 𝕜 s) (r : β) :
Convex 𝕜 ({ x ∈ s | r < f x }) :=
MonotoneOn.convex_lt (E := Eᵒᵈ) (β := βᵒᵈ) hf.dual hs r
theorem AntitoneOn.convex_le (hf : AntitoneOn f s) (hs : Convex 𝕜 s) (r : β) :
Convex 𝕜 ({ x ∈ s | f x ≤ r }) :=
MonotoneOn.convex_ge (β := βᵒᵈ) hf hs r
theorem AntitoneOn.convex_lt (hf : AntitoneOn f s) (hs : Convex 𝕜 s) (r : β) :
Convex 𝕜 ({ x ∈ s | f x < r }) :=
MonotoneOn.convex_gt (β := βᵒᵈ) hf hs r
theorem AntitoneOn.convex_ge (hf : AntitoneOn f s) (hs : Convex 𝕜 s) (r : β) :
Convex 𝕜 ({ x ∈ s | r ≤ f x }) :=
MonotoneOn.convex_le (β := βᵒᵈ) hf hs r
theorem AntitoneOn.convex_gt (hf : AntitoneOn f s) (hs : Convex 𝕜 s) (r : β) :
Convex 𝕜 ({ x ∈ s | r < f x }) :=
MonotoneOn.convex_lt (β := βᵒᵈ) hf hs r
theorem Monotone.convex_le (hf : Monotone f) (r : β) : Convex 𝕜 { x | f x ≤ r } :=
Set.sep_univ.subst ((hf.monotoneOn univ).convex_le convex_univ r)
theorem Monotone.convex_lt (hf : Monotone f) (r : β) : Convex 𝕜 { x | f x ≤ r } :=
Set.sep_univ.subst ((hf.monotoneOn univ).convex_le convex_univ r)
theorem Monotone.convex_ge (hf : Monotone f) (r : β) : Convex 𝕜 { x | r ≤ f x } :=
Set.sep_univ.subst ((hf.monotoneOn univ).convex_ge convex_univ r)
theorem Monotone.convex_gt (hf : Monotone f) (r : β) : Convex 𝕜 { x | f x ≤ r } :=
Set.sep_univ.subst ((hf.monotoneOn univ).convex_le convex_univ r)
theorem Antitone.convex_le (hf : Antitone f) (r : β) : Convex 𝕜 { x | f x ≤ r } :=
Set.sep_univ.subst ((hf.antitoneOn univ).convex_le convex_univ r)
theorem Antitone.convex_lt (hf : Antitone f) (r : β) : Convex 𝕜 { x | f x < r } :=
Set.sep_univ.subst ((hf.antitoneOn univ).convex_lt convex_univ r)
theorem Antitone.convex_ge (hf : Antitone f) (r : β) : Convex 𝕜 { x | r ≤ f x } :=
Set.sep_univ.subst ((hf.antitoneOn univ).convex_ge convex_univ r)
theorem Antitone.convex_gt (hf : Antitone f) (r : β) : Convex 𝕜 { x | r < f x } :=
Set.sep_univ.subst ((hf.antitoneOn univ).convex_gt convex_univ r)
end LinearOrderedAddCommMonoid
end OrderedSemiring
section OrderedCommSemiring
variable [CommSemiring 𝕜] [PartialOrder 𝕜]
section AddCommMonoid
variable [AddCommMonoid E] [AddCommMonoid F] [Module 𝕜 E] [Module 𝕜 F] {s : Set E}
theorem Convex.smul (hs : Convex 𝕜 s) (c : 𝕜) : Convex 𝕜 (c • s) :=
hs.linear_image (LinearMap.lsmul _ _ c)
theorem Convex.smul_preimage (hs : Convex 𝕜 s) (c : 𝕜) : Convex 𝕜 ((fun z => c • z) ⁻¹' s) :=
hs.linear_preimage (LinearMap.lsmul _ _ c)
theorem Convex.affinity (hs : Convex 𝕜 s) (z : E) (c : 𝕜) :
Convex 𝕜 ((fun x => z + c • x) '' s) := by
simpa only [← image_smul, ← image_vadd, image_image] using (hs.smul c).vadd z
end AddCommMonoid
end OrderedCommSemiring
section StrictOrderedCommSemiring
variable [CommSemiring 𝕜] [PartialOrder 𝕜] [IsStrictOrderedRing 𝕜] [AddCommGroup E] [Module 𝕜 E]
theorem convex_openSegment (a b : E) : Convex 𝕜 (openSegment 𝕜 a b) := by
rw [convex_iff_openSegment_subset]
rintro p ⟨ap, bp, hap, hbp, habp, rfl⟩ q ⟨aq, bq, haq, hbq, habq, rfl⟩ z ⟨a, b, ha, hb, hab, rfl⟩
refine ⟨a * ap + b * aq, a * bp + b * bq, by positivity, by positivity, ?_, ?_⟩
· linear_combination (norm := noncomm_ring) a * habp + b * habq + hab
· module
end StrictOrderedCommSemiring
section OrderedRing
variable [Ring 𝕜] [PartialOrder 𝕜]
section AddCommGroup
variable [AddCommGroup E] [AddCommGroup F] [Module 𝕜 E] [Module 𝕜 F] {s t : Set E}
@[simp]
theorem convex_vadd (a : E) : Convex 𝕜 (a +ᵥ s) ↔ Convex 𝕜 s :=
⟨fun h ↦ by simpa using h.vadd (-a), fun h ↦ h.vadd _⟩
/-- Affine subspaces are convex. -/
theorem AffineSubspace.convex (Q : AffineSubspace 𝕜 E) : Convex 𝕜 (Q : Set E) :=
fun x hx y hy a b _ _ hab ↦ by simpa [Convex.combo_eq_smul_sub_add hab] using Q.2 _ hy hx hx
/-- The preimage of a convex set under an affine map is convex. -/
theorem Convex.affine_preimage (f : E →ᵃ[𝕜] F) {s : Set F} (hs : Convex 𝕜 s) : Convex 𝕜 (f ⁻¹' s) :=
fun _ hx => (hs hx).affine_preimage _
/-- The image of a convex set under an affine map is convex. -/
theorem Convex.affine_image (f : E →ᵃ[𝕜] F) (hs : Convex 𝕜 s) : Convex 𝕜 (f '' s) := by
rintro _ ⟨x, hx, rfl⟩
exact (hs hx).affine_image _
theorem Convex.neg (hs : Convex 𝕜 s) : Convex 𝕜 (-s) :=
hs.is_linear_preimage IsLinearMap.isLinearMap_neg (𝕜₁ := 𝕜)
theorem Convex.sub (hs : Convex 𝕜 s) (ht : Convex 𝕜 t) : Convex 𝕜 (s - t) := by
rw [sub_eq_add_neg]
exact hs.add ht.neg
variable [AddRightMono 𝕜]
theorem Convex.add_smul_mem (hs : Convex 𝕜 s) {x y : E} (hx : x ∈ s) (hy : x + y ∈ s) {t : 𝕜}
(ht : t ∈ Icc (0 : 𝕜) 1) : x + t • y ∈ s := by
have h : x + t • y = (1 - t) • x + t • (x + y) := by match_scalars <;> noncomm_ring
rw [h]
exact hs hx hy (sub_nonneg_of_le ht.2) ht.1 (sub_add_cancel _ _)
theorem Convex.smul_mem_of_zero_mem (hs : Convex 𝕜 s) {x : E} (zero_mem : (0 : E) ∈ s) (hx : x ∈ s)
{t : 𝕜} (ht : t ∈ Icc (0 : 𝕜) 1) : t • x ∈ s := by
simpa using hs.add_smul_mem zero_mem (by simpa using hx) ht
theorem Convex.mapsTo_lineMap (h : Convex 𝕜 s) {x y : E} (hx : x ∈ s) (hy : y ∈ s) :
MapsTo (AffineMap.lineMap x y) (Icc (0 : 𝕜) 1) s := by
simpa only [mapsTo', segment_eq_image_lineMap] using h.segment_subset hx hy
theorem Convex.lineMap_mem (h : Convex 𝕜 s) {x y : E} (hx : x ∈ s) (hy : y ∈ s) {t : 𝕜}
(ht : t ∈ Icc 0 1) : AffineMap.lineMap x y t ∈ s :=
h.mapsTo_lineMap hx hy ht
theorem Convex.add_smul_sub_mem (h : Convex 𝕜 s) {x y : E} (hx : x ∈ s) (hy : y ∈ s) {t : 𝕜}
(ht : t ∈ Icc (0 : 𝕜) 1) : x + t • (y - x) ∈ s := by
rw [add_comm]
exact h.lineMap_mem hx hy ht
end AddCommGroup
end OrderedRing
section LinearOrderedSemiring
variable [Semiring 𝕜] [LinearOrder 𝕜] [IsOrderedRing 𝕜] [AddCommMonoid E]
theorem Convex_subadditive_le [SMul 𝕜 E] {f : E → 𝕜} (hf1 : ∀ x y, f (x + y) ≤ (f x) + (f y))
(hf2 : ∀ ⦃c⦄ x, 0 ≤ c → f (c • x) ≤ c * f x) (B : 𝕜) :
Convex 𝕜 { x | f x ≤ B } := by
rw [convex_iff_segment_subset]
rintro x hx y hy z ⟨a, b, ha, hb, hs, rfl⟩
calc
_ ≤ a • (f x) + b • (f y) := le_trans (hf1 _ _) (add_le_add (hf2 x ha) (hf2 y hb))
| _ ≤ a • B + b • B := by gcongr <;> assumption
_ ≤ B := by rw [← add_smul, hs, one_smul]
| Mathlib/Analysis/Convex/Basic.lean | 497 | 498 |
/-
Copyright (c) 2020 Kenny Lau. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kenny Lau, Ken Lee, Chris Hughes
-/
import Mathlib.Algebra.Group.Action.Units
import Mathlib.Algebra.Group.Nat.Units
import Mathlib.Algebra.GroupWithZero.Divisibility
import Mathlib.Algebra.Ring.Divisibility.Basic
import Mathlib.Algebra.Ring.Hom.Defs
import Mathlib.Logic.Basic
import Mathlib.Tactic.Ring
/-!
# Coprime elements of a ring or monoid
## Main definition
* `IsCoprime x y`: that `x` and `y` are coprime, defined to be the existence of `a` and `b` such
that `a * x + b * y = 1`. Note that elements with no common divisors (`IsRelPrime`) are not
necessarily coprime, e.g., the multivariate polynomials `x₁` and `x₂` are not coprime.
The two notions are equivalent in Bézout rings, see `isRelPrime_iff_isCoprime`.
This file also contains lemmas about `IsRelPrime` parallel to `IsCoprime`.
See also `RingTheory.Coprime.Lemmas` for further development of coprime elements.
-/
universe u v
section CommSemiring
variable {R : Type u} [CommSemiring R] (x y z : R)
/-- The proposition that `x` and `y` are coprime, defined to be the existence of `a` and `b` such
that `a * x + b * y = 1`. Note that elements with no common divisors are not necessarily coprime,
e.g., the multivariate polynomials `x₁` and `x₂` are not coprime. -/
def IsCoprime : Prop :=
∃ a b, a * x + b * y = 1
variable {x y z}
@[symm]
theorem IsCoprime.symm (H : IsCoprime x y) : IsCoprime y x :=
let ⟨a, b, H⟩ := H
⟨b, a, by rw [add_comm, H]⟩
theorem isCoprime_comm : IsCoprime x y ↔ IsCoprime y x :=
⟨IsCoprime.symm, IsCoprime.symm⟩
theorem isCoprime_self : IsCoprime x x ↔ IsUnit x :=
⟨fun ⟨a, b, h⟩ => isUnit_of_mul_eq_one x (a + b) <| by rwa [mul_comm, add_mul], fun h =>
let ⟨b, hb⟩ := isUnit_iff_exists_inv'.1 h
⟨b, 0, by rwa [zero_mul, add_zero]⟩⟩
theorem isCoprime_zero_left : IsCoprime 0 x ↔ IsUnit x :=
⟨fun ⟨a, b, H⟩ => isUnit_of_mul_eq_one x b <| by rwa [mul_zero, zero_add, mul_comm] at H, fun H =>
let ⟨b, hb⟩ := isUnit_iff_exists_inv'.1 H
⟨1, b, by rwa [one_mul, zero_add]⟩⟩
theorem isCoprime_zero_right : IsCoprime x 0 ↔ IsUnit x :=
isCoprime_comm.trans isCoprime_zero_left
theorem not_isCoprime_zero_zero [Nontrivial R] : ¬IsCoprime (0 : R) 0 :=
mt isCoprime_zero_right.mp not_isUnit_zero
lemma IsCoprime.intCast {R : Type*} [CommRing R] {a b : ℤ} (h : IsCoprime a b) :
IsCoprime (a : R) (b : R) := by
rcases h with ⟨u, v, H⟩
use u, v
rw_mod_cast [H]
exact Int.cast_one
/-- If a 2-vector `p` satisfies `IsCoprime (p 0) (p 1)`, then `p ≠ 0`. -/
theorem IsCoprime.ne_zero [Nontrivial R] {p : Fin 2 → R} (h : IsCoprime (p 0) (p 1)) : p ≠ 0 := by
rintro rfl
exact not_isCoprime_zero_zero h
theorem IsCoprime.ne_zero_or_ne_zero [Nontrivial R] (h : IsCoprime x y) : x ≠ 0 ∨ y ≠ 0 := by
apply not_or_of_imp
rintro rfl rfl
exact not_isCoprime_zero_zero h
theorem isCoprime_one_left : IsCoprime 1 x :=
⟨1, 0, by rw [one_mul, zero_mul, add_zero]⟩
theorem isCoprime_one_right : IsCoprime x 1 :=
⟨0, 1, by rw [one_mul, zero_mul, zero_add]⟩
theorem IsCoprime.dvd_of_dvd_mul_right (H1 : IsCoprime x z) (H2 : x ∣ y * z) : x ∣ y := by
let ⟨a, b, H⟩ := H1
rw [← mul_one y, ← H, mul_add, ← mul_assoc, mul_left_comm]
exact dvd_add (dvd_mul_left _ _) (H2.mul_left _)
theorem IsCoprime.dvd_of_dvd_mul_left (H1 : IsCoprime x y) (H2 : x ∣ y * z) : x ∣ z := by
let ⟨a, b, H⟩ := H1
rw [← one_mul z, ← H, add_mul, mul_right_comm, mul_assoc b]
exact dvd_add (dvd_mul_left _ _) (H2.mul_left _)
theorem IsCoprime.mul_left (H1 : IsCoprime x z) (H2 : IsCoprime y z) : IsCoprime (x * y) z :=
let ⟨a, b, h1⟩ := H1
let ⟨c, d, h2⟩ := H2
⟨a * c, a * x * d + b * c * y + b * d * z,
calc a * c * (x * y) + (a * x * d + b * c * y + b * d * z) * z
_ = (a * x + b * z) * (c * y + d * z) := by ring
_ = 1 := by rw [h1, h2, mul_one]
⟩
theorem IsCoprime.mul_right (H1 : IsCoprime x y) (H2 : IsCoprime x z) : IsCoprime x (y * z) := by
rw [isCoprime_comm] at H1 H2 ⊢
exact H1.mul_left H2
theorem IsCoprime.mul_dvd (H : IsCoprime x y) (H1 : x ∣ z) (H2 : y ∣ z) : x * y ∣ z := by
obtain ⟨a, b, h⟩ := H
rw [← mul_one z, ← h, mul_add]
apply dvd_add
· rw [mul_comm z, mul_assoc]
exact (mul_dvd_mul_left _ H2).mul_left _
· rw [mul_comm b, ← mul_assoc]
exact (mul_dvd_mul_right H1 _).mul_right _
theorem IsCoprime.of_mul_left_left (H : IsCoprime (x * y) z) : IsCoprime x z :=
let ⟨a, b, h⟩ := H
⟨a * y, b, by rwa [mul_right_comm, mul_assoc]⟩
theorem IsCoprime.of_mul_left_right (H : IsCoprime (x * y) z) : IsCoprime y z := by
rw [mul_comm] at H
exact H.of_mul_left_left
theorem IsCoprime.of_mul_right_left (H : IsCoprime x (y * z)) : IsCoprime x y := by
rw [isCoprime_comm] at H ⊢
exact H.of_mul_left_left
theorem IsCoprime.of_mul_right_right (H : IsCoprime x (y * z)) : IsCoprime x z := by
rw [mul_comm] at H
exact H.of_mul_right_left
theorem IsCoprime.mul_left_iff : IsCoprime (x * y) z ↔ IsCoprime x z ∧ IsCoprime y z :=
⟨fun H => ⟨H.of_mul_left_left, H.of_mul_left_right⟩, fun ⟨H1, H2⟩ => H1.mul_left H2⟩
theorem IsCoprime.mul_right_iff : IsCoprime x (y * z) ↔ IsCoprime x y ∧ IsCoprime x z := by
rw [isCoprime_comm, IsCoprime.mul_left_iff, isCoprime_comm, @isCoprime_comm _ _ z]
theorem IsCoprime.of_isCoprime_of_dvd_left (h : IsCoprime y z) (hdvd : x ∣ y) : IsCoprime x z := by
obtain ⟨d, rfl⟩ := hdvd
exact IsCoprime.of_mul_left_left h
theorem IsCoprime.of_isCoprime_of_dvd_right (h : IsCoprime z y) (hdvd : x ∣ y) : IsCoprime z x :=
(h.symm.of_isCoprime_of_dvd_left hdvd).symm
theorem IsCoprime.isUnit_of_dvd (H : IsCoprime x y) (d : x ∣ y) : IsUnit x :=
let ⟨k, hk⟩ := d
isCoprime_self.1 <| IsCoprime.of_mul_right_left <| show IsCoprime x (x * k) from hk ▸ H
theorem IsCoprime.isUnit_of_dvd' {a b x : R} (h : IsCoprime a b) (ha : x ∣ a) (hb : x ∣ b) :
IsUnit x :=
(h.of_isCoprime_of_dvd_left ha).isUnit_of_dvd hb
theorem IsCoprime.isRelPrime {a b : R} (h : IsCoprime a b) : IsRelPrime a b :=
fun _ ↦ h.isUnit_of_dvd'
theorem IsCoprime.map (H : IsCoprime x y) {S : Type v} [CommSemiring S] (f : R →+* S) :
IsCoprime (f x) (f y) :=
let ⟨a, b, h⟩ := H
⟨f a, f b, by rw [← f.map_mul, ← f.map_mul, ← f.map_add, h, f.map_one]⟩
theorem IsCoprime.of_add_mul_left_left (h : IsCoprime (x + y * z) y) : IsCoprime x y :=
let ⟨a, b, H⟩ := h
⟨a, a * z + b, by
simpa only [add_mul, mul_add, add_assoc, add_comm, add_left_comm, mul_assoc, mul_comm,
mul_left_comm] using H⟩
theorem IsCoprime.of_add_mul_right_left (h : IsCoprime (x + z * y) y) : IsCoprime x y := by
rw [mul_comm] at h
exact h.of_add_mul_left_left
theorem IsCoprime.of_add_mul_left_right (h : IsCoprime x (y + x * z)) : IsCoprime x y := by
rw [isCoprime_comm] at h ⊢
exact h.of_add_mul_left_left
theorem IsCoprime.of_add_mul_right_right (h : IsCoprime x (y + z * x)) : IsCoprime x y := by
rw [mul_comm] at h
exact h.of_add_mul_left_right
theorem IsCoprime.of_mul_add_left_left (h : IsCoprime (y * z + x) y) : IsCoprime x y := by
rw [add_comm] at h
exact h.of_add_mul_left_left
theorem IsCoprime.of_mul_add_right_left (h : IsCoprime (z * y + x) y) : IsCoprime x y := by
rw [add_comm] at h
exact h.of_add_mul_right_left
theorem IsCoprime.of_mul_add_left_right (h : IsCoprime x (x * z + y)) : IsCoprime x y := by
rw [add_comm] at h
exact h.of_add_mul_left_right
theorem IsCoprime.of_mul_add_right_right (h : IsCoprime x (z * x + y)) : IsCoprime x y := by
rw [add_comm] at h
exact h.of_add_mul_right_right
| theorem IsRelPrime.of_add_mul_left_left (h : IsRelPrime (x + y * z) y) : IsRelPrime x y :=
fun _ hx hy ↦ h (dvd_add hx <| dvd_mul_of_dvd_left hy z) hy
| Mathlib/RingTheory/Coprime/Basic.lean | 202 | 204 |
/-
Copyright (c) 2023 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes
-/
import Mathlib.Algebra.Ring.CharZero
import Mathlib.Algebra.Ring.Int.Units
import Mathlib.GroupTheory.Coprod.Basic
import Mathlib.GroupTheory.Complement
/-!
## HNN Extensions of Groups
This file defines the HNN extension of a group `G`, `HNNExtension G A B φ`. Given a group `G`,
subgroups `A` and `B` and an isomorphism `φ` of `A` and `B`, we adjoin a letter `t` to `G`, such
that for any `a ∈ A`, the conjugate of `of a` by `t` is `of (φ a)`, where `of` is the canonical map
from `G` into the `HNNExtension`. This construction is named after Graham Higman, Bernhard Neumann
and Hanna Neumann.
## Main definitions
- `HNNExtension G A B φ` : The HNN Extension of a group `G`, where `A` and `B` are subgroups and `φ`
is an isomorphism between `A` and `B`.
- `HNNExtension.of` : The canonical embedding of `G` into `HNNExtension G A B φ`.
- `HNNExtension.t` : The stable letter of the HNN extension.
- `HNNExtension.lift` : Define a function `HNNExtension G A B φ →* H`, by defining it on `G` and `t`
- `HNNExtension.of_injective` : The canonical embedding `G →* HNNExtension G A B φ` is injective.
- `HNNExtension.ReducedWord.toList_eq_nil_of_mem_of_range` : Britton's Lemma. If an element of
`G` is represented by a reduced word, then this reduced word does not contain `t`.
-/
assert_not_exists Field
open Monoid Coprod Multiplicative Subgroup Function
/-- The relation we quotient the coproduct by to form an `HNNExtension`. -/
def HNNExtension.con (G : Type*) [Group G] (A B : Subgroup G) (φ : A ≃* B) :
Con (G ∗ Multiplicative ℤ) :=
conGen (fun x y => ∃ (a : A),
x = inr (ofAdd 1) * inl (a : G) ∧
y = inl (φ a : G) * inr (ofAdd 1))
/-- The HNN Extension of a group `G`, `HNNExtension G A B φ`. Given a group `G`, subgroups `A` and
`B` and an isomorphism `φ` of `A` and `B`, we adjoin a letter `t` to `G`, such that for
any `a ∈ A`, the conjugate of `of a` by `t` is `of (φ a)`, where `of` is the canonical
map from `G` into the `HNNExtension`. -/
def HNNExtension (G : Type*) [Group G] (A B : Subgroup G) (φ : A ≃* B) : Type _ :=
(HNNExtension.con G A B φ).Quotient
variable {G : Type*} [Group G] {A B : Subgroup G} {φ : A ≃* B} {H : Type*}
[Group H] {M : Type*} [Monoid M]
instance : Group (HNNExtension G A B φ) := by
delta HNNExtension; infer_instance
namespace HNNExtension
/-- The canonical embedding `G →* HNNExtension G A B φ` -/
def of : G →* HNNExtension G A B φ :=
(HNNExtension.con G A B φ).mk'.comp inl
/-- The stable letter of the `HNNExtension` -/
def t : HNNExtension G A B φ :=
(HNNExtension.con G A B φ).mk'.comp inr (ofAdd 1)
theorem t_mul_of (a : A) :
t * (of (a : G) : HNNExtension G A B φ) = of (φ a : G) * t :=
(Con.eq _).2 <| ConGen.Rel.of _ _ <| ⟨a, by simp⟩
theorem of_mul_t (b : B) :
(of (b : G) : HNNExtension G A B φ) * t = t * of (φ.symm b : G) := by
rw [t_mul_of]; simp
theorem equiv_eq_conj (a : A) :
(of (φ a : G) : HNNExtension G A B φ) = t * of (a : G) * t⁻¹ := by
rw [t_mul_of]; simp
theorem equiv_symm_eq_conj (b : B) :
(of (φ.symm b : G) : HNNExtension G A B φ) = t⁻¹ * of (b : G) * t := by
rw [mul_assoc, of_mul_t]; simp
theorem inv_t_mul_of (b : B) :
t⁻¹ * (of (b : G) : HNNExtension G A B φ) = of (φ.symm b : G) * t⁻¹ := by
rw [equiv_symm_eq_conj]; simp
theorem of_mul_inv_t (a : A) :
(of (a : G) : HNNExtension G A B φ) * t⁻¹ = t⁻¹ * of (φ a : G) := by
rw [equiv_eq_conj]; simp [mul_assoc]
/-- Define a function `HNNExtension G A B φ →* H`, by defining it on `G` and `t` -/
def lift (f : G →* H) (x : H) (hx : ∀ a : A, x * f ↑a = f (φ a : G) * x) :
HNNExtension G A B φ →* H :=
Con.lift _ (Coprod.lift f (zpowersHom H x)) (Con.conGen_le <| by
rintro _ _ ⟨a, rfl, rfl⟩
simp [hx])
@[simp]
theorem lift_t (f : G →* H) (x : H) (hx : ∀ a : A, x * f ↑a = f (φ a : G) * x) :
lift f x hx t = x := by
delta HNNExtension; simp [lift, t]
@[simp]
theorem lift_of (f : G →* H) (x : H) (hx : ∀ a : A, x * f ↑a = f (φ a : G) * x) (g : G) :
lift f x hx (of g) = f g := by
delta HNNExtension; simp [lift, of]
@[ext high]
theorem hom_ext {f g : HNNExtension G A B φ →* M}
(hg : f.comp of = g.comp of) (ht : f t = g t) : f = g :=
(MonoidHom.cancel_right Con.mk'_surjective).mp <|
Coprod.hom_ext hg (MonoidHom.ext_mint ht)
@[elab_as_elim]
theorem induction_on {motive : HNNExtension G A B φ → Prop}
(x : HNNExtension G A B φ) (of : ∀ g, motive (of g))
(t : motive t) (mul : ∀ x y, motive x → motive y → motive (x * y))
(inv : ∀ x, motive x → motive x⁻¹) : motive x := by
let S : Subgroup (HNNExtension G A B φ) :=
{ carrier := setOf motive
one_mem' := by simpa using of 1
mul_mem' := mul _ _
inv_mem' := inv _ }
let f : HNNExtension G A B φ →* S :=
lift (HNNExtension.of.codRestrict S of)
⟨HNNExtension.t, t⟩ (by intro a; ext; simp [equiv_eq_conj, mul_assoc])
have hf : S.subtype.comp f = MonoidHom.id _ :=
hom_ext (by ext; simp [f]) (by simp [f])
show motive (MonoidHom.id _ x)
rw [← hf]
exact (f x).2
variable (A B φ)
/-- To avoid duplicating code, we define `toSubgroup A B u` and `toSubgroupEquiv u`
where `u : ℤˣ` is `1` or `-1`. `toSubgroup A B u` is `A` when `u = 1` and `B` when `u = -1`,
and `toSubgroupEquiv` is `φ` when `u = 1` and `φ⁻¹` when `u = -1`. `toSubgroup u` is the subgroup
such that for any `a ∈ toSubgroup u`, `t ^ (u : ℤ) * a = toSubgroupEquiv a * t ^ (u : ℤ)`. -/
def toSubgroup (u : ℤˣ) : Subgroup G :=
if u = 1 then A else B
@[simp]
theorem toSubgroup_one : toSubgroup A B 1 = A := rfl
@[simp]
theorem toSubgroup_neg_one : toSubgroup A B (-1) = B := rfl
variable {A B}
/-- To avoid duplicating code, we define `toSubgroup A B u` and `toSubgroupEquiv u`
where `u : ℤˣ` is `1` or `-1`. `toSubgroup A B u` is `A` when `u = 1` and `B` when `u = -1`,
and `toSubgroupEquiv` is the group ismorphism from `toSubgroup A B u` to `toSubgroup A B (-u)`.
It is defined to be `φ` when `u = 1` and `φ⁻¹` when `u = -1`. -/
def toSubgroupEquiv (u : ℤˣ) : toSubgroup A B u ≃* toSubgroup A B (-u) :=
if hu : u = 1 then hu ▸ φ else by
convert φ.symm <;>
cases Int.units_eq_one_or u <;> simp_all
@[simp]
theorem toSubgroupEquiv_one : toSubgroupEquiv φ 1 = φ := rfl
@[simp]
theorem toSubgroupEquiv_neg_one : toSubgroupEquiv φ (-1) = φ.symm := rfl
@[simp]
theorem toSubgroupEquiv_neg_apply (u : ℤˣ) (a : toSubgroup A B u) :
(toSubgroupEquiv φ (-u) (toSubgroupEquiv φ u a) : G) = a := by
rcases Int.units_eq_one_or u with rfl | rfl
· simp [toSubgroup]
· simp only [toSubgroup_neg_one, toSubgroupEquiv_neg_one, SetLike.coe_eq_coe]
exact φ.apply_symm_apply a
namespace NormalWord
variable (G A B)
/-- To put word in the HNN Extension into a normal form, we must choose an element of each right
coset of both `A` and `B`, such that the chosen element of the subgroup itself is `1`. -/
structure TransversalPair : Type _ where
/-- The transversal of each subgroup -/
set : ℤˣ → Set G
/-- We have exactly one element of each coset of the subgroup -/
compl : ∀ u, IsComplement (toSubgroup A B u : Subgroup G) (set u)
instance TransversalPair.nonempty : Nonempty (TransversalPair G A B) := by
choose t ht using fun u ↦ (toSubgroup A B u).exists_isComplement_right 1
exact ⟨⟨t, fun i ↦ (ht i).1⟩⟩
/-- A reduced word is a `head`, which is an element of `G`, followed by the product list of pairs.
There should also be no sequences of the form `t^u * g * t^-u`, where `g` is in
`toSubgroup A B u` This is a less strict condition than required for `NormalWord`. -/
structure ReducedWord : Type _ where
/-- Every `ReducedWord` is the product of an element of the group and a word made up
of letters each of which is in the transversal. `head` is that element of the base group. -/
head : G
/-- The list of pairs `(ℤˣ × G)`, where each pair `(u, g)` represents the element `t^u * g` of
`HNNExtension G A B φ` -/
toList : List (ℤˣ × G)
/-- There are no sequences of the form `t^u * g * t^-u` where `g ∈ toSubgroup A B u` -/
chain : toList.Chain' (fun a b => a.2 ∈ toSubgroup A B a.1 → a.1 = b.1)
/-- The empty reduced word. -/
@[simps]
def ReducedWord.empty : ReducedWord G A B :=
{ head := 1
toList := []
chain := List.chain'_nil }
variable {G A B}
/-- The product of a `ReducedWord` as an element of the `HNNExtension` -/
def ReducedWord.prod : ReducedWord G A B → HNNExtension G A B φ :=
fun w => of w.head * (w.toList.map (fun x => t ^ (x.1 : ℤ) * of x.2)).prod
/-- Given a `TransversalPair`, we can make a normal form for words in the `HNNExtension G A B φ`.
The normal form is a `head`, which is an element of `G`, followed by the product list of pairs,
`t ^ u * g`, where `u` is `1` or `-1` and `g` is the chosen element of its right coset of
`toSubgroup A B u`. There should also be no sequences of the form `t^u * g * t^-u`
where `g ∈ toSubgroup A B u` -/
structure _root_.HNNExtension.NormalWord (d : TransversalPair G A B) : Type _
extends ReducedWord G A B where
/-- Every element `g : G` in the list is the chosen element of its coset -/
mem_set : ∀ (u : ℤˣ) (g : G), (u, g) ∈ toList → g ∈ d.set u
variable {d : TransversalPair G A B}
@[ext]
theorem ext {w w' : NormalWord d}
(h1 : w.head = w'.head) (h2 : w.toList = w'.toList) : w = w' := by
rcases w with ⟨⟨⟩, _⟩; cases w'; simp_all
/-- The empty word -/
@[simps]
def empty : NormalWord d :=
{ head := 1
toList := []
mem_set := by simp
chain := List.chain'_nil }
/-- The `NormalWord` representing an element `g` of the group `G`, which is just the element `g`
itself. -/
@[simps]
def ofGroup (g : G) : NormalWord d :=
{ head := g
toList := []
mem_set := by simp
chain := List.chain'_nil }
instance : Inhabited (NormalWord d) := ⟨empty⟩
instance : MulAction G (NormalWord d) :=
{ smul := fun g w => { w with head := g * w.head }
one_smul := by simp [instHSMul]
mul_smul := by simp [instHSMul, mul_assoc] }
theorem group_smul_def (g : G) (w : NormalWord d) :
g • w = { w with head := g * w.head } := rfl
@[simp]
theorem group_smul_head (g : G) (w : NormalWord d) : (g • w).head = g * w.head := rfl
@[simp]
theorem group_smul_toList (g : G) (w : NormalWord d) : (g • w).toList = w.toList := rfl
instance : FaithfulSMul G (NormalWord d) := ⟨by simp [group_smul_def]⟩
/-- A constructor to append an element `g` of `G` and `u : ℤˣ` to a word `w` with sufficient
hypotheses that no normalization or cancellation need take place for the result to be in normal form
-/
@[simps]
def cons (g : G) (u : ℤˣ) (w : NormalWord d) (h1 : w.head ∈ d.set u)
(h2 : ∀ u' ∈ Option.map Prod.fst w.toList.head?, w.head ∈ toSubgroup A B u → u = u') :
NormalWord d :=
{ head := g,
toList := (u, w.head) :: w.toList,
mem_set := by
intro u' g' h'
simp only [List.mem_cons, Prod.mk.injEq] at h'
rcases h' with ⟨rfl, rfl⟩ | h'
· exact h1
· exact w.mem_set _ _ h'
chain := by
refine List.chain'_cons'.2 ⟨?_, w.chain⟩
rintro ⟨u', g'⟩ hu' hw1
exact h2 _ (by simp_all) hw1 }
/-- A recursor to induct on a `NormalWord`, by proving the property is preserved under `cons` -/
@[elab_as_elim]
def consRecOn {motive : NormalWord d → Sort*} (w : NormalWord d)
(ofGroup : ∀ g, motive (ofGroup g))
(cons : ∀ (g : G) (u : ℤˣ) (w : NormalWord d) (h1 : w.head ∈ d.set u)
(h2 : ∀ u' ∈ Option.map Prod.fst w.toList.head?,
w.head ∈ toSubgroup A B u → u = u'),
motive w → motive (cons g u w h1 h2)) : motive w := by
rcases w with ⟨⟨g, l, chain⟩, mem_set⟩
induction l generalizing g with
| nil => exact ofGroup _
| cons a l ih =>
exact cons g a.1
{ head := a.2
toList := l
mem_set := fun _ _ h => mem_set _ _ (List.mem_cons_of_mem _ h),
chain := (List.chain'_cons'.1 chain).2 }
(mem_set a.1 a.2 List.mem_cons_self)
(by simpa using (List.chain'_cons'.1 chain).1)
(ih _ _ _)
@[simp]
theorem consRecOn_ofGroup {motive : NormalWord d → Sort*}
(g : G) (ofGroup : ∀ g, motive (ofGroup g))
(cons : ∀ (g : G) (u : ℤˣ) (w : NormalWord d) (h1 : w.head ∈ d.set u)
(h2 : ∀ u' ∈ Option.map Prod.fst w.toList.head?, w.head
∈ toSubgroup A B u → u = u'),
motive w → motive (cons g u w h1 h2)) :
consRecOn (.ofGroup g) ofGroup cons = ofGroup g := rfl
@[simp]
theorem consRecOn_cons {motive : NormalWord d → Sort*}
(g : G) (u : ℤˣ) (w : NormalWord d) (h1 : w.head ∈ d.set u)
(h2 : ∀ u' ∈ Option.map Prod.fst w.toList.head?, w.head ∈ toSubgroup A B u → u = u')
(ofGroup : ∀ g, motive (ofGroup g))
(cons : ∀ (g : G) (u : ℤˣ) (w : NormalWord d) (h1 : w.head ∈ d.set u)
(h2 : ∀ u' ∈ Option.map Prod.fst w.toList.head?,
w.head ∈ toSubgroup A B u → u = u'),
motive w → motive (cons g u w h1 h2)) :
consRecOn (.cons g u w h1 h2) ofGroup cons = cons g u w h1 h2
(consRecOn w ofGroup cons) := rfl
@[simp]
theorem smul_cons (g₁ g₂ : G) (u : ℤˣ) (w : NormalWord d) (h1 : w.head ∈ d.set u)
(h2 : ∀ u' ∈ Option.map Prod.fst w.toList.head?, w.head ∈ toSubgroup A B u → u = u') :
g₁ • cons g₂ u w h1 h2 = cons (g₁ * g₂) u w h1 h2 :=
rfl
@[simp]
theorem smul_ofGroup (g₁ g₂ : G) :
g₁ • (ofGroup g₂ : NormalWord d) = ofGroup (g₁ * g₂) := rfl
variable (d)
/-- The action of `t^u` on `ofGroup g`. The normal form will be
`a * t^u * g'` where `a ∈ toSubgroup A B (-u)` -/
noncomputable def unitsSMulGroup (u : ℤˣ) (g : G) :
(toSubgroup A B (-u)) × d.set u :=
let g' := (d.compl u).equiv g
(toSubgroupEquiv φ u g'.1, g'.2)
theorem unitsSMulGroup_snd (u : ℤˣ) (g : G) :
(unitsSMulGroup φ d u g).2 = ((d.compl u).equiv g).2 := by
rcases Int.units_eq_one_or u with rfl | rfl <;> rfl
variable {d}
/-- `Cancels u w` is a predicate expressing whether `t^u` cancels with some occurrence
of `t^-u` when we multiply `t^u` by `w`. -/
def Cancels (u : ℤˣ) (w : NormalWord d) : Prop :=
(w.head ∈ (toSubgroup A B u : Subgroup G)) ∧ w.toList.head?.map Prod.fst = some (-u)
/-- Multiplying `t^u` by `w` in the special case where cancellation happens -/
def unitsSMulWithCancel (u : ℤˣ) (w : NormalWord d) : Cancels u w → NormalWord d :=
consRecOn w
(by simp [Cancels, ofGroup]; tauto)
(fun g _ w _ _ _ can =>
(toSubgroupEquiv φ u ⟨g, can.1⟩ : G) • w)
/-- Multiplying `t^u` by a `NormalWord`, `w` and putting the result in normal form. -/
noncomputable def unitsSMul (u : ℤˣ) (w : NormalWord d) : NormalWord d :=
letI := Classical.dec
if h : Cancels u w
then unitsSMulWithCancel φ u w h
else let g' := unitsSMulGroup φ d u w.head
cons g'.1 u ((g'.2 * w.head⁻¹ : G) • w)
(by simp)
(by
simp only [g', group_smul_toList, Option.mem_def, Option.map_eq_some_iff, Prod.exists,
exists_and_right, exists_eq_right, group_smul_head, inv_mul_cancel_right,
forall_exists_index, unitsSMulGroup]
simp only [Cancels, Option.map_eq_some_iff, Prod.exists, exists_and_right, exists_eq_right,
not_and, not_exists] at h
intro u' x hx hmem
have : w.head ∈ toSubgroup A B u := by
have := (d.compl u).rightCosetEquivalence_equiv_snd w.head
rw [RightCosetEquivalence, rightCoset_eq_iff, mul_mem_cancel_left hmem] at this
simp_all
have := h this x
simp_all [Int.units_ne_iff_eq_neg])
/-- A condition for not cancelling whose hypothese are the same as those of the `cons` function. -/
theorem not_cancels_of_cons_hyp (u : ℤˣ) (w : NormalWord d)
(h2 : ∀ u' ∈ Option.map Prod.fst w.toList.head?,
w.head ∈ toSubgroup A B u → u = u') :
¬ Cancels u w := by
simp only [Cancels, Option.map_eq_some_iff, Prod.exists,
exists_and_right, exists_eq_right, not_and, not_exists]
intro hw x hx
rw [hx] at h2
simpa using h2 (-u) rfl hw
theorem unitsSMul_cancels_iff (u : ℤˣ) (w : NormalWord d) :
Cancels (-u) (unitsSMul φ u w) ↔ ¬ Cancels u w := by
by_cases h : Cancels u w
· simp only [unitsSMul, h, dite_true, not_true_eq_false, iff_false]
induction w using consRecOn with
| ofGroup => simp [Cancels, unitsSMulWithCancel]
| cons g u' w h1 h2 _ =>
intro hc
apply not_cancels_of_cons_hyp _ _ h2
simp only [Cancels, cons_head, cons_toList, List.head?_cons,
Option.map_some', Option.some.injEq] at h
cases h.2
simpa [Cancels, unitsSMulWithCancel,
Subgroup.mul_mem_cancel_left] using hc
· simp only [unitsSMul, dif_neg h]
| simpa [Cancels] using h
theorem unitsSMul_neg (u : ℤˣ) (w : NormalWord d) :
unitsSMul φ (-u) (unitsSMul φ u w) = w := by
rw [unitsSMul]
split_ifs with hcan
· have hncan : ¬ Cancels u w := (unitsSMul_cancels_iff _ _ _).1 hcan
unfold unitsSMul
simp only [dif_neg hncan]
simp [unitsSMulWithCancel, unitsSMulGroup, (d.compl u).equiv_snd_eq_inv_mul,
-SetLike.coe_sort_coe]
· have hcan2 : Cancels u w := not_not.1 (mt (unitsSMul_cancels_iff _ _ _).2 hcan)
unfold unitsSMul at hcan ⊢
simp only [dif_pos hcan2] at hcan ⊢
cases w using consRecOn with
| ofGroup => simp [Cancels] at hcan2
| cons g u' w h1 h2 ih =>
clear ih
simp only [unitsSMulGroup, SetLike.coe_sort_coe, unitsSMulWithCancel, id_eq, consRecOn_cons,
group_smul_head, IsComplement.equiv_mul_left, map_mul, Submonoid.coe_mul, coe_toSubmonoid,
toSubgroupEquiv_neg_apply, mul_inv_rev]
cases hcan2.2
have : ((d.compl (-u)).equiv w.head).1 = 1 :=
(d.compl (-u)).equiv_fst_eq_one_of_mem_of_one_mem _ h1
apply NormalWord.ext
· -- This used to `simp [this]` before https://github.com/leanprover/lean4/pull/2644
dsimp
conv_lhs => erw [IsComplement.equiv_mul_left]
rw [map_mul, Submonoid.coe_mul, toSubgroupEquiv_neg_apply, this]
simp
· -- The next two lines were not needed before https://github.com/leanprover/lean4/pull/2644
dsimp
conv_lhs => erw [IsComplement.equiv_mul_left]
simp [mul_assoc, Units.ext_iff, (d.compl (-u)).equiv_snd_eq_inv_mul, this,
-SetLike.coe_sort_coe]
/-- the equivalence given by multiplication on the left by `t` -/
| Mathlib/GroupTheory/HNNExtension.lean | 412 | 448 |
/-
Copyright (c) 2022 David Loeffler. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: David Loeffler
-/
import Mathlib.NumberTheory.BernoulliPolynomials
import Mathlib.MeasureTheory.Integral.IntervalIntegral.Basic
import Mathlib.Analysis.Calculus.Deriv.Polynomial
import Mathlib.Analysis.Fourier.AddCircle
import Mathlib.Analysis.PSeries
/-!
# Critical values of the Riemann zeta function
In this file we prove formulae for the critical values of `ζ(s)`, and more generally of Hurwitz
zeta functions, in terms of Bernoulli polynomials.
## Main results:
* `hasSum_zeta_nat`: the final formula for zeta values,
$$\zeta(2k) = \frac{(-1)^{(k + 1)} 2 ^ {2k - 1} \pi^{2k} B_{2 k}}{(2 k)!}.$$
* `hasSum_zeta_two` and `hasSum_zeta_four`: special cases given explicitly.
* `hasSum_one_div_nat_pow_mul_cos`: a formula for the sum `∑ (n : ℕ), cos (2 π i n x) / n ^ k` as
an explicit multiple of `Bₖ(x)`, for any `x ∈ [0, 1]` and `k ≥ 2` even.
* `hasSum_one_div_nat_pow_mul_sin`: a formula for the sum `∑ (n : ℕ), sin (2 π i n x) / n ^ k` as
an explicit multiple of `Bₖ(x)`, for any `x ∈ [0, 1]` and `k ≥ 3` odd.
-/
noncomputable section
open scoped Nat Real Interval
open Complex MeasureTheory Set intervalIntegral
local notation "𝕌" => UnitAddCircle
section BernoulliFunProps
/-! Simple properties of the Bernoulli polynomial, as a function `ℝ → ℝ`. -/
/-- The function `x ↦ Bₖ(x) : ℝ → ℝ`. -/
def bernoulliFun (k : ℕ) (x : ℝ) : ℝ :=
(Polynomial.map (algebraMap ℚ ℝ) (Polynomial.bernoulli k)).eval x
theorem bernoulliFun_eval_zero (k : ℕ) : bernoulliFun k 0 = bernoulli k := by
rw [bernoulliFun, Polynomial.eval_zero_map, Polynomial.bernoulli_eval_zero, eq_ratCast]
theorem bernoulliFun_endpoints_eq_of_ne_one {k : ℕ} (hk : k ≠ 1) :
bernoulliFun k 1 = bernoulliFun k 0 := by
rw [bernoulliFun_eval_zero, bernoulliFun, Polynomial.eval_one_map, Polynomial.bernoulli_eval_one,
bernoulli_eq_bernoulli'_of_ne_one hk, eq_ratCast]
theorem bernoulliFun_eval_one (k : ℕ) : bernoulliFun k 1 = bernoulliFun k 0 + ite (k = 1) 1 0 := by
rw [bernoulliFun, bernoulliFun_eval_zero, Polynomial.eval_one_map, Polynomial.bernoulli_eval_one]
split_ifs with h
· rw [h, bernoulli_one, bernoulli'_one, eq_ratCast]
push_cast; ring
· rw [bernoulli_eq_bernoulli'_of_ne_one h, add_zero, eq_ratCast]
theorem hasDerivAt_bernoulliFun (k : ℕ) (x : ℝ) :
HasDerivAt (bernoulliFun k) (k * bernoulliFun (k - 1) x) x := by
convert ((Polynomial.bernoulli k).map <| algebraMap ℚ ℝ).hasDerivAt x using 1
simp only [bernoulliFun, Polynomial.derivative_map, Polynomial.derivative_bernoulli k,
Polynomial.map_mul, Polynomial.map_natCast, Polynomial.eval_mul, Polynomial.eval_natCast]
theorem antideriv_bernoulliFun (k : ℕ) (x : ℝ) :
HasDerivAt (fun x => bernoulliFun (k + 1) x / (k + 1)) (bernoulliFun k x) x := by
convert (hasDerivAt_bernoulliFun (k + 1) x).div_const _ using 1
field_simp [Nat.cast_add_one_ne_zero k]
theorem integral_bernoulliFun_eq_zero {k : ℕ} (hk : k ≠ 0) :
∫ x : ℝ in (0)..1, bernoulliFun k x = 0 := by
rw [integral_eq_sub_of_hasDerivAt (fun x _ => antideriv_bernoulliFun k x)
((Polynomial.continuous _).intervalIntegrable _ _)]
rw [bernoulliFun_eval_one]
split_ifs with h
· exfalso; exact hk (Nat.succ_inj.mp h)
· simp
end BernoulliFunProps
section BernoulliFourierCoeffs
/-! Compute the Fourier coefficients of the Bernoulli functions via integration by parts. -/
/-- The `n`-th Fourier coefficient of the `k`-th Bernoulli function on the interval `[0, 1]`. -/
def bernoulliFourierCoeff (k : ℕ) (n : ℤ) : ℂ :=
fourierCoeffOn zero_lt_one (fun x => bernoulliFun k x) n
/-- Recurrence relation (in `k`) for the `n`-th Fourier coefficient of `Bₖ`. -/
theorem bernoulliFourierCoeff_recurrence (k : ℕ) {n : ℤ} (hn : n ≠ 0) :
bernoulliFourierCoeff k n =
1 / (-2 * π * I * n) * (ite (k = 1) 1 0 - k * bernoulliFourierCoeff (k - 1) n) := by
unfold bernoulliFourierCoeff
rw [fourierCoeffOn_of_hasDerivAt zero_lt_one hn
(fun x _ => (hasDerivAt_bernoulliFun k x).ofReal_comp)
((continuous_ofReal.comp <|
continuous_const.mul <| Polynomial.continuous _).intervalIntegrable
_ _)]
simp_rw [ofReal_one, ofReal_zero, sub_zero, one_mul]
rw [QuotientAddGroup.mk_zero, fourier_eval_zero, one_mul, ← ofReal_sub, bernoulliFun_eval_one,
add_sub_cancel_left]
congr 2
· split_ifs <;> simp only [ofReal_one, ofReal_zero, one_mul]
· simp_rw [ofReal_mul, ofReal_natCast, fourierCoeffOn.const_mul]
/-- The Fourier coefficients of `B₀(x) = 1`. -/
theorem bernoulli_zero_fourier_coeff {n : ℤ} (hn : n ≠ 0) : bernoulliFourierCoeff 0 n = 0 := by
simpa using bernoulliFourierCoeff_recurrence 0 hn
/-- The `0`-th Fourier coefficient of `Bₖ(x)`. -/
theorem bernoulliFourierCoeff_zero {k : ℕ} (hk : k ≠ 0) : bernoulliFourierCoeff k 0 = 0 := by
simp_rw [bernoulliFourierCoeff, fourierCoeffOn_eq_integral, neg_zero, fourier_zero, sub_zero,
div_one, one_smul, intervalIntegral.integral_ofReal, integral_bernoulliFun_eq_zero hk,
ofReal_zero]
theorem bernoulliFourierCoeff_eq {k : ℕ} (hk : k ≠ 0) (n : ℤ) :
bernoulliFourierCoeff k n = -k ! / (2 * π * I * n) ^ k := by
rcases eq_or_ne n 0 with (rfl | hn)
· rw [bernoulliFourierCoeff_zero hk, Int.cast_zero, mul_zero, zero_pow hk,
div_zero]
refine Nat.le_induction ?_ (fun k hk h'k => ?_) k (Nat.one_le_iff_ne_zero.mpr hk)
· rw [bernoulliFourierCoeff_recurrence 1 hn]
simp only [Nat.cast_one, tsub_self, neg_mul, one_mul, eq_self_iff_true, if_true,
Nat.factorial_one, pow_one, inv_I, mul_neg]
rw [bernoulli_zero_fourier_coeff hn, sub_zero, mul_one, div_neg, neg_div]
· rw [bernoulliFourierCoeff_recurrence (k + 1) hn, Nat.add_sub_cancel k 1]
split_ifs with h
· exfalso; exact (ne_of_gt (Nat.lt_succ_iff.mpr hk)) h
· rw [h'k, Nat.factorial_succ, zero_sub, Nat.cast_mul, pow_add, pow_one, neg_div, mul_neg,
mul_neg, mul_neg, neg_neg, neg_mul, neg_mul, neg_mul, div_neg]
field_simp [Int.cast_ne_zero.mpr hn, I_ne_zero]
ring_nf
end BernoulliFourierCoeffs
section BernoulliPeriodized
/-! In this section we use the above evaluations of the Fourier coefficients of Bernoulli
polynomials, together with the theorem `has_pointwise_sum_fourier_series_of_summable` from Fourier
theory, to obtain an explicit formula for `∑ (n:ℤ), 1 / n ^ k * fourier n x`. -/
/-- The Bernoulli polynomial, extended from `[0, 1)` to the unit circle. -/
def periodizedBernoulli (k : ℕ) : 𝕌 → ℝ :=
AddCircle.liftIco 1 0 (bernoulliFun k)
theorem periodizedBernoulli.continuous {k : ℕ} (hk : k ≠ 1) : Continuous (periodizedBernoulli k) :=
AddCircle.liftIco_zero_continuous
(mod_cast (bernoulliFun_endpoints_eq_of_ne_one hk).symm)
(Polynomial.continuous _).continuousOn
theorem fourierCoeff_bernoulli_eq {k : ℕ} (hk : k ≠ 0) (n : ℤ) :
fourierCoeff ((↑) ∘ periodizedBernoulli k : 𝕌 → ℂ) n = -k ! / (2 * π * I * n) ^ k := by
have : ((↑) ∘ periodizedBernoulli k : 𝕌 → ℂ) = AddCircle.liftIco 1 0 ((↑) ∘ bernoulliFun k) := by
ext1 x; rfl
rw [this, fourierCoeff_liftIco_eq]
simpa only [zero_add] using bernoulliFourierCoeff_eq hk n
theorem summable_bernoulli_fourier {k : ℕ} (hk : 2 ≤ k) :
Summable (fun n => -k ! / (2 * π * I * n) ^ k : ℤ → ℂ) := by
have :
∀ n : ℤ, -(k ! : ℂ) / (2 * π * I * n) ^ k = -k ! / (2 * π * I) ^ k * (1 / (n : ℂ) ^ k) := by
intro n; rw [mul_one_div, div_div, ← mul_pow]
simp_rw [this]
refine Summable.mul_left _ <| .of_norm ?_
have : (fun x : ℤ => ‖1 / (x : ℂ) ^ k‖) = fun x : ℤ => |1 / (x : ℝ) ^ k| := by
ext1 x
simp only [one_div, norm_inv, norm_pow, norm_intCast, pow_abs, abs_inv]
simp_rw [this]
rwa [summable_abs_iff, Real.summable_one_div_int_pow]
theorem hasSum_one_div_pow_mul_fourier_mul_bernoulliFun {k : ℕ} (hk : 2 ≤ k) {x : ℝ}
(hx : x ∈ Icc (0 : ℝ) 1) :
HasSum (fun n : ℤ => 1 / (n : ℂ) ^ k * fourier n (x : 𝕌))
(-(2 * π * I) ^ k / k ! * bernoulliFun k x) := by
-- first show it suffices to prove result for `Ico 0 1`
suffices ∀ {y : ℝ}, y ∈ Ico (0 : ℝ) 1 →
HasSum (fun (n : ℤ) ↦ 1 / (n : ℂ) ^ k * fourier n y)
(-(2 * (π : ℂ) * I) ^ k / k ! * bernoulliFun k y) by
rw [← Ico_insert_right (zero_le_one' ℝ), mem_insert_iff, or_comm] at hx
rcases hx with (hx | rfl)
· exact this hx
· convert this (left_mem_Ico.mpr zero_lt_one) using 1
· rw [AddCircle.coe_period, QuotientAddGroup.mk_zero]
· rw [bernoulliFun_endpoints_eq_of_ne_one (by omega : k ≠ 1)]
intro y hy
let B : C(𝕌, ℂ) :=
ContinuousMap.mk ((↑) ∘ periodizedBernoulli k)
(continuous_ofReal.comp (periodizedBernoulli.continuous (by omega)))
have step1 : ∀ n : ℤ, fourierCoeff B n = -k ! / (2 * π * I * n) ^ k := by
rw [ContinuousMap.coe_mk]; exact fourierCoeff_bernoulli_eq (by omega : k ≠ 0)
have step2 :=
has_pointwise_sum_fourier_series_of_summable
((summable_bernoulli_fourier hk).congr fun n => (step1 n).symm) y
simp_rw [step1] at step2
convert step2.mul_left (-(2 * ↑π * I) ^ k / (k ! : ℂ)) using 2 with n
· rw [smul_eq_mul, ← mul_assoc, mul_div, mul_neg, div_mul_cancel₀, neg_neg, mul_pow _ (n : ℂ),
← div_div, div_self]
· rw [Ne, pow_eq_zero_iff', not_and_or]
exact Or.inl two_pi_I_ne_zero
· exact Nat.cast_ne_zero.mpr (Nat.factorial_ne_zero _)
· rw [ContinuousMap.coe_mk, Function.comp_apply, ofReal_inj, periodizedBernoulli,
AddCircle.liftIco_coe_apply (show y ∈ Ico 0 (0 + 1) by rwa [zero_add])]
end BernoulliPeriodized
section Cleanup
-- This section is just reformulating the results in a nicer form.
theorem hasSum_one_div_nat_pow_mul_fourier {k : ℕ} (hk : 2 ≤ k) {x : ℝ} (hx : x ∈ Icc (0 : ℝ) 1) :
HasSum
(fun n : ℕ =>
(1 : ℂ) / (n : ℂ) ^ k * (fourier n (x : 𝕌) + (-1 : ℂ) ^ k * fourier (-n) (x : 𝕌)))
(-(2 * π * I) ^ k / k ! * bernoulliFun k x) := by
convert (hasSum_one_div_pow_mul_fourier_mul_bernoulliFun hk hx).nat_add_neg using 1
· ext1 n
rw [Int.cast_neg, mul_add, ← mul_assoc]
conv_rhs => rw [neg_eq_neg_one_mul, mul_pow, ← div_div]
congr 2
rw [div_mul_eq_mul_div₀, one_mul]
congr 1
rw [eq_div_iff, ← mul_pow, ← neg_eq_neg_one_mul, neg_neg, one_pow]
apply pow_ne_zero; rw [neg_ne_zero]; exact one_ne_zero
· rw [Int.cast_zero, zero_pow (by positivity : k ≠ 0), div_zero, zero_mul, add_zero]
theorem hasSum_one_div_nat_pow_mul_cos {k : ℕ} (hk : k ≠ 0) {x : ℝ} (hx : x ∈ Icc (0 : ℝ) 1) :
HasSum (fun n : ℕ => 1 / (n : ℝ) ^ (2 * k) * Real.cos (2 * π * n * x))
((-1 : ℝ) ^ (k + 1) * (2 * π) ^ (2 * k) / 2 / (2 * k)! *
(Polynomial.map (algebraMap ℚ ℝ) (Polynomial.bernoulli (2 * k))).eval x) := by
have :
HasSum (fun n : ℕ => 1 / (n : ℂ) ^ (2 * k) * (fourier n (x : 𝕌) + fourier (-n) (x : 𝕌)))
((-1 : ℂ) ^ (k + 1) * (2 * (π : ℂ)) ^ (2 * k) / (2 * k)! * bernoulliFun (2 * k) x) := by
convert
hasSum_one_div_nat_pow_mul_fourier (by omega : 2 ≤ 2 * k)
hx using 3
· rw [pow_mul (-1 : ℂ), neg_one_sq, one_pow, one_mul]
· rw [pow_add, pow_one]
conv_rhs =>
rw [mul_pow]
congr
congr
· skip
· rw [pow_mul, I_sq]
ring
have ofReal_two : ((2 : ℝ) : ℂ) = 2 := by norm_cast
convert ((hasSum_iff _ _).mp (this.div_const 2)).1 with n
· convert (ofReal_re _).symm
rw [ofReal_mul]; rw [← mul_div]; congr
· rw [ofReal_div, ofReal_one, ofReal_pow]; rfl
· rw [ofReal_cos, ofReal_mul, fourier_coe_apply, fourier_coe_apply, cos, ofReal_one, div_one,
div_one, ofReal_mul, ofReal_mul, ofReal_two, Int.cast_neg, Int.cast_natCast,
ofReal_natCast]
congr 3
· ring
· ring
· convert (ofReal_re _).symm
rw [ofReal_mul, ofReal_div, ofReal_div, ofReal_mul, ofReal_pow, ofReal_pow, ofReal_neg,
ofReal_natCast, ofReal_mul, ofReal_two, ofReal_one]
rw [bernoulliFun]
ring
theorem hasSum_one_div_nat_pow_mul_sin {k : ℕ} (hk : k ≠ 0) {x : ℝ} (hx : x ∈ Icc (0 : ℝ) 1) :
HasSum (fun n : ℕ => 1 / (n : ℝ) ^ (2 * k + 1) * Real.sin (2 * π * n * x))
((-1 : ℝ) ^ (k + 1) * (2 * π) ^ (2 * k + 1) / 2 / (2 * k + 1)! *
(Polynomial.map (algebraMap ℚ ℝ) (Polynomial.bernoulli (2 * k + 1))).eval x) := by
have :
HasSum (fun n : ℕ => 1 / (n : ℂ) ^ (2 * k + 1) * (fourier n (x : 𝕌) - fourier (-n) (x : 𝕌)))
((-1 : ℂ) ^ (k + 1) * I * (2 * π : ℂ) ^ (2 * k + 1) / (2 * k + 1)! *
bernoulliFun (2 * k + 1) x) := by
convert
hasSum_one_div_nat_pow_mul_fourier
(by omega : 2 ≤ 2 * k + 1) hx using 1
· ext1 n
rw [pow_add (-1 : ℂ), pow_mul (-1 : ℂ), neg_one_sq, one_pow, one_mul, pow_one, ←
neg_eq_neg_one_mul, ← sub_eq_add_neg]
· congr
rw [pow_add, pow_one]
conv_rhs =>
rw [mul_pow]
congr
congr
· skip
· rw [pow_add, pow_one, pow_mul, I_sq]
ring
have ofReal_two : ((2 : ℝ) : ℂ) = 2 := by norm_cast
convert ((hasSum_iff _ _).mp (this.div_const (2 * I))).1
· convert (ofReal_re _).symm
rw [ofReal_mul]; rw [← mul_div]; congr
· rw [ofReal_div, ofReal_one, ofReal_pow]; rfl
· rw [ofReal_sin, ofReal_mul, fourier_coe_apply, fourier_coe_apply, sin, ofReal_one, div_one,
div_one, ofReal_mul, ofReal_mul, ofReal_two, Int.cast_neg, Int.cast_natCast,
ofReal_natCast, ← div_div, div_I, div_mul_eq_mul_div₀, ← neg_div, ← neg_mul, neg_sub]
congr 4
· ring
· ring
· convert (ofReal_re _).symm
rw [ofReal_mul, ofReal_div, ofReal_div, ofReal_mul, ofReal_pow, ofReal_pow, ofReal_neg,
ofReal_natCast, ofReal_mul, ofReal_two, ofReal_one, ← div_div, div_I,
div_mul_eq_mul_div₀]
have : ∀ α β γ δ : ℂ, α * I * β / γ * δ * I = I ^ 2 * α * β / γ * δ := by intros; ring
rw [this, I_sq]
rw [bernoulliFun]
ring
theorem hasSum_zeta_nat {k : ℕ} (hk : k ≠ 0) :
HasSum (fun n : ℕ => 1 / (n : ℝ) ^ (2 * k))
((-1 : ℝ) ^ (k + 1) * (2 : ℝ) ^ (2 * k - 1) * π ^ (2 * k) *
bernoulli (2 * k) / (2 * k)!) := by
convert hasSum_one_div_nat_pow_mul_cos hk (left_mem_Icc.mpr zero_le_one) using 1
· ext1 n; rw [mul_zero, Real.cos_zero, mul_one]
rw [Polynomial.eval_zero_map, Polynomial.bernoulli_eval_zero, eq_ratCast]
have : (2 : ℝ) ^ (2 * k - 1) = (2 : ℝ) ^ (2 * k) / 2 := by
rw [eq_div_iff (two_ne_zero' ℝ)]
conv_lhs =>
congr
· skip
· rw [← pow_one (2 : ℝ)]
rw [← pow_add, Nat.sub_add_cancel]
omega
rw [this, mul_pow]
ring
end Cleanup
section Examples
theorem hasSum_zeta_two : HasSum (fun n : ℕ => (1 : ℝ) / (n : ℝ) ^ 2) (π ^ 2 / 6) := by
convert hasSum_zeta_nat one_ne_zero using 1; rw [mul_one]
rw [bernoulli_eq_bernoulli'_of_ne_one (by decide : 2 ≠ 1), bernoulli'_two]
norm_num [Nat.factorial]; field_simp; ring
theorem hasSum_zeta_four : HasSum (fun n : ℕ => (1 : ℝ) / (n : ℝ) ^ 4) (π ^ 4 / 90) := by
convert hasSum_zeta_nat two_ne_zero using 1; norm_num
rw [bernoulli_eq_bernoulli'_of_ne_one, bernoulli'_four]
· norm_num [Nat.factorial]; field_simp; ring
· decide
theorem Polynomial.bernoulli_three_eval_one_quarter :
(Polynomial.bernoulli 3).eval (1 / 4) = 3 / 64 := by
simp_rw [Polynomial.bernoulli, Finset.sum_range_succ, Polynomial.eval_add,
Polynomial.eval_monomial]
rw [Finset.sum_range_zero, Polynomial.eval_zero, zero_add, bernoulli_one]
rw [bernoulli_eq_bernoulli'_of_ne_one zero_ne_one, bernoulli'_zero,
bernoulli_eq_bernoulli'_of_ne_one (by decide : 2 ≠ 1), bernoulli'_two,
bernoulli_eq_bernoulli'_of_ne_one (by decide : 3 ≠ 1), bernoulli'_three]
norm_num
/-- Explicit formula for `L(χ, 3)`, where `χ` is the unique nontrivial Dirichlet character modulo 4.
-/
theorem hasSum_L_function_mod_four_eval_three :
HasSum (fun n : ℕ => (1 : ℝ) / (n : ℝ) ^ 3 * Real.sin (π * n / 2)) (π ^ 3 / 32) := by
apply (congr_arg₂ HasSum ?_ ?_).to_iff.mp <|
hasSum_one_div_nat_pow_mul_sin one_ne_zero (?_ : 1 / 4 ∈ Icc (0 : ℝ) 1)
· ext1 n
norm_num
left
congr 1
| ring
· have : (1 / 4 : ℝ) = (algebraMap ℚ ℝ) (1 / 4 : ℚ) := by norm_num
rw [this, mul_pow, Polynomial.eval_map, Polynomial.eval₂_at_apply, (by decide : 2 * 1 + 1 = 3),
Polynomial.bernoulli_three_eval_one_quarter]
norm_num [Nat.factorial]; field_simp; ring
| Mathlib/NumberTheory/ZetaValues.lean | 361 | 365 |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker
-/
import Mathlib.Algebra.Group.Submonoid.Operations
import Mathlib.Algebra.MonoidAlgebra.Defs
import Mathlib.Algebra.Order.Monoid.Unbundled.WithTop
import Mathlib.Algebra.Ring.Action.Rat
import Mathlib.Data.Finset.Sort
import Mathlib.Tactic.FastInstance
/-!
# Theory of univariate polynomials
This file defines `Polynomial R`, the type of univariate polynomials over the semiring `R`, builds
a semiring structure on it, and gives basic definitions that are expanded in other files in this
directory.
## Main definitions
* `monomial n a` is the polynomial `a X^n`. Note that `monomial n` is defined as an `R`-linear map.
* `C a` is the constant polynomial `a`. Note that `C` is defined as a ring homomorphism.
* `X` is the polynomial `X`, i.e., `monomial 1 1`.
* `p.sum f` is `∑ n ∈ p.support, f n (p.coeff n)`, i.e., one sums the values of functions applied
to coefficients of the polynomial `p`.
* `p.erase n` is the polynomial `p` in which one removes the `c X^n` term.
There are often two natural variants of lemmas involving sums, depending on whether one acts on the
polynomials, or on the function. The naming convention is that one adds `index` when acting on
the polynomials. For instance,
* `sum_add_index` states that `(p + q).sum f = p.sum f + q.sum f`;
* `sum_add` states that `p.sum (fun n x ↦ f n x + g n x) = p.sum f + p.sum g`.
* Notation to refer to `Polynomial R`, as `R[X]` or `R[t]`.
## Implementation
Polynomials are defined using `R[ℕ]`, where `R` is a semiring.
The variable `X` commutes with every polynomial `p`: lemma `X_mul` proves the identity
`X * p = p * X`. The relationship to `R[ℕ]` is through a structure
to make polynomials irreducible from the point of view of the kernel. Most operations
are irreducible since Lean can not compute anyway with `AddMonoidAlgebra`. There are two
exceptions that we make semireducible:
* The zero polynomial, so that its coefficients are definitionally equal to `0`.
* The scalar action, to permit typeclass search to unfold it to resolve potential instance
diamonds.
The raw implementation of the equivalence between `R[X]` and `R[ℕ]` is
done through `ofFinsupp` and `toFinsupp` (or, equivalently, `rcases p` when `p` is a polynomial
gives an element `q` of `R[ℕ]`, and conversely `⟨q⟩` gives back `p`). The
equivalence is also registered as a ring equiv in `Polynomial.toFinsuppIso`. These should
in general not be used once the basic API for polynomials is constructed.
-/
noncomputable section
/-- `Polynomial R` is the type of univariate polynomials over `R`,
denoted as `R[X]` within the `Polynomial` namespace.
Polynomials should be seen as (semi-)rings with the additional constructor `X`.
The embedding from `R` is called `C`. -/
structure Polynomial (R : Type*) [Semiring R] where ofFinsupp ::
toFinsupp : AddMonoidAlgebra R ℕ
@[inherit_doc] scoped[Polynomial] notation:9000 R "[X]" => Polynomial R
open AddMonoidAlgebra Finset
open Finsupp hiding single
open Function hiding Commute
namespace Polynomial
universe u
variable {R : Type u} {a b : R} {m n : ℕ}
section Semiring
variable [Semiring R] {p q : R[X]}
theorem forall_iff_forall_finsupp (P : R[X] → Prop) :
(∀ p, P p) ↔ ∀ q : R[ℕ], P ⟨q⟩ :=
⟨fun h q => h ⟨q⟩, fun h ⟨p⟩ => h p⟩
theorem exists_iff_exists_finsupp (P : R[X] → Prop) :
(∃ p, P p) ↔ ∃ q : R[ℕ], P ⟨q⟩ :=
⟨fun ⟨⟨p⟩, hp⟩ => ⟨p, hp⟩, fun ⟨q, hq⟩ => ⟨⟨q⟩, hq⟩⟩
@[simp]
theorem eta (f : R[X]) : Polynomial.ofFinsupp f.toFinsupp = f := by cases f; rfl
/-! ### Conversions to and from `AddMonoidAlgebra`
Since `R[X]` is not defeq to `R[ℕ]`, but instead is a structure wrapping
it, we have to copy across all the arithmetic operators manually, along with the lemmas about how
they unfold around `Polynomial.ofFinsupp` and `Polynomial.toFinsupp`.
-/
section AddMonoidAlgebra
private irreducible_def add : R[X] → R[X] → R[X]
| ⟨a⟩, ⟨b⟩ => ⟨a + b⟩
private irreducible_def neg {R : Type u} [Ring R] : R[X] → R[X]
| ⟨a⟩ => ⟨-a⟩
private irreducible_def mul : R[X] → R[X] → R[X]
| ⟨a⟩, ⟨b⟩ => ⟨a * b⟩
instance zero : Zero R[X] :=
⟨⟨0⟩⟩
instance one : One R[X] :=
⟨⟨1⟩⟩
instance add' : Add R[X] :=
⟨add⟩
instance neg' {R : Type u} [Ring R] : Neg R[X] :=
⟨neg⟩
instance sub {R : Type u} [Ring R] : Sub R[X] :=
⟨fun a b => a + -b⟩
instance mul' : Mul R[X] :=
⟨mul⟩
-- If the private definitions are accidentally exposed, simplify them away.
@[simp] theorem add_eq_add : add p q = p + q := rfl
@[simp] theorem mul_eq_mul : mul p q = p * q := rfl
instance instNSMul : SMul ℕ R[X] where
smul r p := ⟨r • p.toFinsupp⟩
instance smulZeroClass {S : Type*} [SMulZeroClass S R] : SMulZeroClass S R[X] where
smul r p := ⟨r • p.toFinsupp⟩
smul_zero a := congr_arg ofFinsupp (smul_zero a)
instance {S : Type*} [Zero S] [SMulZeroClass S R] [NoZeroSMulDivisors S R] :
NoZeroSMulDivisors S R[X] where
eq_zero_or_eq_zero_of_smul_eq_zero eq :=
(eq_zero_or_eq_zero_of_smul_eq_zero <| congr_arg toFinsupp eq).imp id (congr_arg ofFinsupp)
-- to avoid a bug in the `ring` tactic
instance (priority := 1) pow : Pow R[X] ℕ where pow p n := npowRec n p
@[simp]
theorem ofFinsupp_zero : (⟨0⟩ : R[X]) = 0 :=
rfl
@[simp]
theorem ofFinsupp_one : (⟨1⟩ : R[X]) = 1 :=
rfl
@[simp]
theorem ofFinsupp_add {a b} : (⟨a + b⟩ : R[X]) = ⟨a⟩ + ⟨b⟩ :=
show _ = add _ _ by rw [add_def]
@[simp]
theorem ofFinsupp_neg {R : Type u} [Ring R] {a} : (⟨-a⟩ : R[X]) = -⟨a⟩ :=
show _ = neg _ by rw [neg_def]
@[simp]
theorem ofFinsupp_sub {R : Type u} [Ring R] {a b} : (⟨a - b⟩ : R[X]) = ⟨a⟩ - ⟨b⟩ := by
rw [sub_eq_add_neg, ofFinsupp_add, ofFinsupp_neg]
rfl
@[simp]
theorem ofFinsupp_mul (a b) : (⟨a * b⟩ : R[X]) = ⟨a⟩ * ⟨b⟩ :=
show _ = mul _ _ by rw [mul_def]
@[simp]
theorem ofFinsupp_nsmul (a : ℕ) (b) :
(⟨a • b⟩ : R[X]) = (a • ⟨b⟩ : R[X]) :=
rfl
@[simp]
theorem ofFinsupp_smul {S : Type*} [SMulZeroClass S R] (a : S) (b) :
(⟨a • b⟩ : R[X]) = (a • ⟨b⟩ : R[X]) :=
rfl
@[simp]
theorem ofFinsupp_pow (a) (n : ℕ) : (⟨a ^ n⟩ : R[X]) = ⟨a⟩ ^ n := by
change _ = npowRec n _
induction n with
| zero => simp [npowRec]
| succ n n_ih => simp [npowRec, n_ih, pow_succ]
@[simp]
theorem toFinsupp_zero : (0 : R[X]).toFinsupp = 0 :=
rfl
@[simp]
theorem toFinsupp_one : (1 : R[X]).toFinsupp = 1 :=
rfl
@[simp]
theorem toFinsupp_add (a b : R[X]) : (a + b).toFinsupp = a.toFinsupp + b.toFinsupp := by
cases a
cases b
rw [← ofFinsupp_add]
@[simp]
theorem toFinsupp_neg {R : Type u} [Ring R] (a : R[X]) : (-a).toFinsupp = -a.toFinsupp := by
cases a
rw [← ofFinsupp_neg]
@[simp]
theorem toFinsupp_sub {R : Type u} [Ring R] (a b : R[X]) :
(a - b).toFinsupp = a.toFinsupp - b.toFinsupp := by
rw [sub_eq_add_neg, ← toFinsupp_neg, ← toFinsupp_add]
rfl
@[simp]
theorem toFinsupp_mul (a b : R[X]) : (a * b).toFinsupp = a.toFinsupp * b.toFinsupp := by
cases a
cases b
rw [← ofFinsupp_mul]
@[simp]
theorem toFinsupp_nsmul (a : ℕ) (b : R[X]) :
(a • b).toFinsupp = a • b.toFinsupp :=
rfl
@[simp]
theorem toFinsupp_smul {S : Type*} [SMulZeroClass S R] (a : S) (b : R[X]) :
(a • b).toFinsupp = a • b.toFinsupp :=
rfl
@[simp]
theorem toFinsupp_pow (a : R[X]) (n : ℕ) : (a ^ n).toFinsupp = a.toFinsupp ^ n := by
cases a
rw [← ofFinsupp_pow]
theorem _root_.IsSMulRegular.polynomial {S : Type*} [SMulZeroClass S R] {a : S}
(ha : IsSMulRegular R a) : IsSMulRegular R[X] a
| ⟨_x⟩, ⟨_y⟩, h => congr_arg _ <| ha.finsupp (Polynomial.ofFinsupp.inj h)
theorem toFinsupp_injective : Function.Injective (toFinsupp : R[X] → AddMonoidAlgebra _ _) :=
fun ⟨_x⟩ ⟨_y⟩ => congr_arg _
@[simp]
theorem toFinsupp_inj {a b : R[X]} : a.toFinsupp = b.toFinsupp ↔ a = b :=
toFinsupp_injective.eq_iff
@[simp]
theorem toFinsupp_eq_zero {a : R[X]} : a.toFinsupp = 0 ↔ a = 0 := by
rw [← toFinsupp_zero, toFinsupp_inj]
@[simp]
theorem toFinsupp_eq_one {a : R[X]} : a.toFinsupp = 1 ↔ a = 1 := by
rw [← toFinsupp_one, toFinsupp_inj]
/-- A more convenient spelling of `Polynomial.ofFinsupp.injEq` in terms of `Iff`. -/
theorem ofFinsupp_inj {a b} : (⟨a⟩ : R[X]) = ⟨b⟩ ↔ a = b :=
iff_of_eq (ofFinsupp.injEq _ _)
@[simp]
theorem ofFinsupp_eq_zero {a} : (⟨a⟩ : R[X]) = 0 ↔ a = 0 := by
rw [← ofFinsupp_zero, ofFinsupp_inj]
@[simp]
theorem ofFinsupp_eq_one {a} : (⟨a⟩ : R[X]) = 1 ↔ a = 1 := by rw [← ofFinsupp_one, ofFinsupp_inj]
instance inhabited : Inhabited R[X] :=
⟨0⟩
instance instNatCast : NatCast R[X] where natCast n := ofFinsupp n
@[simp]
theorem ofFinsupp_natCast (n : ℕ) : (⟨n⟩ : R[X]) = n := rfl
@[simp]
theorem toFinsupp_natCast (n : ℕ) : (n : R[X]).toFinsupp = n := rfl
@[simp]
theorem ofFinsupp_ofNat (n : ℕ) [n.AtLeastTwo] : (⟨ofNat(n)⟩ : R[X]) = ofNat(n) := rfl
@[simp]
theorem toFinsupp_ofNat (n : ℕ) [n.AtLeastTwo] : (ofNat(n) : R[X]).toFinsupp = ofNat(n) := rfl
instance semiring : Semiring R[X] :=
fast_instance% Function.Injective.semiring toFinsupp toFinsupp_injective toFinsupp_zero
toFinsupp_one toFinsupp_add toFinsupp_mul (fun _ _ => toFinsupp_nsmul _ _) toFinsupp_pow
fun _ => rfl
instance distribSMul {S} [DistribSMul S R] : DistribSMul S R[X] :=
fast_instance% Function.Injective.distribSMul ⟨⟨toFinsupp, toFinsupp_zero⟩, toFinsupp_add⟩
toFinsupp_injective toFinsupp_smul
instance distribMulAction {S} [Monoid S] [DistribMulAction S R] : DistribMulAction S R[X] :=
fast_instance% Function.Injective.distribMulAction
⟨⟨toFinsupp, toFinsupp_zero (R := R)⟩, toFinsupp_add⟩ toFinsupp_injective toFinsupp_smul
instance faithfulSMul {S} [SMulZeroClass S R] [FaithfulSMul S R] : FaithfulSMul S R[X] where
eq_of_smul_eq_smul {_s₁ _s₂} h :=
eq_of_smul_eq_smul fun a : ℕ →₀ R => congr_arg toFinsupp (h ⟨a⟩)
instance module {S} [Semiring S] [Module S R] : Module S R[X] :=
fast_instance% Function.Injective.module _ ⟨⟨toFinsupp, toFinsupp_zero⟩, toFinsupp_add⟩
toFinsupp_injective toFinsupp_smul
instance smulCommClass {S₁ S₂} [SMulZeroClass S₁ R] [SMulZeroClass S₂ R] [SMulCommClass S₁ S₂ R] :
SMulCommClass S₁ S₂ R[X] :=
⟨by
rintro m n ⟨f⟩
simp_rw [← ofFinsupp_smul, smul_comm m n f]⟩
instance isScalarTower {S₁ S₂} [SMul S₁ S₂] [SMulZeroClass S₁ R] [SMulZeroClass S₂ R]
[IsScalarTower S₁ S₂ R] : IsScalarTower S₁ S₂ R[X] :=
⟨by
rintro _ _ ⟨⟩
simp_rw [← ofFinsupp_smul, smul_assoc]⟩
instance isScalarTower_right {α K : Type*} [Semiring K] [DistribSMul α K] [IsScalarTower α K K] :
IsScalarTower α K[X] K[X] :=
⟨by
rintro _ ⟨⟩ ⟨⟩
simp_rw [smul_eq_mul, ← ofFinsupp_smul, ← ofFinsupp_mul, ← ofFinsupp_smul, smul_mul_assoc]⟩
instance isCentralScalar {S} [SMulZeroClass S R] [SMulZeroClass Sᵐᵒᵖ R] [IsCentralScalar S R] :
IsCentralScalar S R[X] :=
⟨by
rintro _ ⟨⟩
simp_rw [← ofFinsupp_smul, op_smul_eq_smul]⟩
instance unique [Subsingleton R] : Unique R[X] :=
{ Polynomial.inhabited with
uniq := by
rintro ⟨x⟩
apply congr_arg ofFinsupp
simp [eq_iff_true_of_subsingleton] }
variable (R)
/-- Ring isomorphism between `R[X]` and `R[ℕ]`. This is just an
implementation detail, but it can be useful to transfer results from `Finsupp` to polynomials. -/
@[simps apply symm_apply]
def toFinsuppIso : R[X] ≃+* R[ℕ] where
toFun := toFinsupp
invFun := ofFinsupp
left_inv := fun ⟨_p⟩ => rfl
right_inv _p := rfl
map_mul' := toFinsupp_mul
map_add' := toFinsupp_add
instance [DecidableEq R] : DecidableEq R[X] :=
@Equiv.decidableEq R[X] _ (toFinsuppIso R).toEquiv (Finsupp.instDecidableEq)
/-- Linear isomorphism between `R[X]` and `R[ℕ]`. This is just an
implementation detail, but it can be useful to transfer results from `Finsupp` to polynomials. -/
@[simps!]
def toFinsuppIsoLinear : R[X] ≃ₗ[R] R[ℕ] where
__ := toFinsuppIso R
map_smul' _ _ := rfl
end AddMonoidAlgebra
theorem ofFinsupp_sum {ι : Type*} (s : Finset ι) (f : ι → R[ℕ]) :
(⟨∑ i ∈ s, f i⟩ : R[X]) = ∑ i ∈ s, ⟨f i⟩ :=
map_sum (toFinsuppIso R).symm f s
theorem toFinsupp_sum {ι : Type*} (s : Finset ι) (f : ι → R[X]) :
(∑ i ∈ s, f i : R[X]).toFinsupp = ∑ i ∈ s, (f i).toFinsupp :=
map_sum (toFinsuppIso R) f s
/-- The set of all `n` such that `X^n` has a non-zero coefficient. -/
def support : R[X] → Finset ℕ
| ⟨p⟩ => p.support
@[simp]
theorem support_ofFinsupp (p) : support (⟨p⟩ : R[X]) = p.support := by rw [support]
theorem support_toFinsupp (p : R[X]) : p.toFinsupp.support = p.support := by rw [support]
@[simp]
theorem support_zero : (0 : R[X]).support = ∅ :=
rfl
@[simp]
theorem support_eq_empty : p.support = ∅ ↔ p = 0 := by
rcases p with ⟨⟩
simp [support]
@[simp] lemma support_nonempty : p.support.Nonempty ↔ p ≠ 0 :=
Finset.nonempty_iff_ne_empty.trans support_eq_empty.not
theorem card_support_eq_zero : #p.support = 0 ↔ p = 0 := by simp
/-- `monomial s a` is the monomial `a * X^s` -/
def monomial (n : ℕ) : R →ₗ[R] R[X] where
toFun t := ⟨Finsupp.single n t⟩
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/10745): was `simp`.
map_add' x y := by simp; rw [ofFinsupp_add]
-- Porting note (https://github.com/leanprover-community/mathlib4/issues/10745): was `simp [← ofFinsupp_smul]`.
map_smul' r x := by simp; rw [← ofFinsupp_smul, smul_single']
@[simp]
theorem toFinsupp_monomial (n : ℕ) (r : R) : (monomial n r).toFinsupp = Finsupp.single n r := by
simp [monomial]
@[simp]
theorem ofFinsupp_single (n : ℕ) (r : R) : (⟨Finsupp.single n r⟩ : R[X]) = monomial n r := by
simp [monomial]
@[simp]
theorem monomial_zero_right (n : ℕ) : monomial n (0 : R) = 0 :=
(monomial n).map_zero
-- This is not a `simp` lemma as `monomial_zero_left` is more general.
theorem monomial_zero_one : monomial 0 (1 : R) = 1 :=
rfl
-- TODO: can't we just delete this one?
theorem monomial_add (n : ℕ) (r s : R) : monomial n (r + s) = monomial n r + monomial n s :=
(monomial n).map_add _ _
theorem monomial_mul_monomial (n m : ℕ) (r s : R) :
monomial n r * monomial m s = monomial (n + m) (r * s) :=
toFinsupp_injective <| by
simp only [toFinsupp_monomial, toFinsupp_mul, AddMonoidAlgebra.single_mul_single]
@[simp]
theorem monomial_pow (n : ℕ) (r : R) (k : ℕ) : monomial n r ^ k = monomial (n * k) (r ^ k) := by
induction k with
| zero => simp [pow_zero, monomial_zero_one]
| succ k ih => simp [pow_succ, ih, monomial_mul_monomial, mul_add, add_comm]
theorem smul_monomial {S} [SMulZeroClass S R] (a : S) (n : ℕ) (b : R) :
a • monomial n b = monomial n (a • b) :=
toFinsupp_injective <| AddMonoidAlgebra.smul_single _ _ _
theorem monomial_injective (n : ℕ) : Function.Injective (monomial n : R → R[X]) :=
(toFinsuppIso R).symm.injective.comp (single_injective n)
@[simp]
theorem monomial_eq_zero_iff (t : R) (n : ℕ) : monomial n t = 0 ↔ t = 0 :=
LinearMap.map_eq_zero_iff _ (Polynomial.monomial_injective n)
theorem monomial_eq_monomial_iff {m n : ℕ} {a b : R} :
monomial m a = monomial n b ↔ m = n ∧ a = b ∨ a = 0 ∧ b = 0 := by
rw [← toFinsupp_inj, toFinsupp_monomial, toFinsupp_monomial, Finsupp.single_eq_single_iff]
theorem support_add : (p + q).support ⊆ p.support ∪ q.support := by
simpa [support] using Finsupp.support_add
/-- `C a` is the constant polynomial `a`.
`C` is provided as a ring homomorphism.
-/
def C : R →+* R[X] :=
{ monomial 0 with
map_one' := by simp [monomial_zero_one]
map_mul' := by simp [monomial_mul_monomial]
map_zero' := by simp }
@[simp]
theorem monomial_zero_left (a : R) : monomial 0 a = C a :=
rfl
@[simp]
theorem toFinsupp_C (a : R) : (C a).toFinsupp = single 0 a :=
rfl
theorem C_0 : C (0 : R) = 0 := by simp
theorem C_1 : C (1 : R) = 1 :=
rfl
theorem C_mul : C (a * b) = C a * C b :=
C.map_mul a b
theorem C_add : C (a + b) = C a + C b :=
C.map_add a b
@[simp]
theorem smul_C {S} [SMulZeroClass S R] (s : S) (r : R) : s • C r = C (s • r) :=
smul_monomial _ _ r
theorem C_pow : C (a ^ n) = C a ^ n :=
C.map_pow a n
theorem C_eq_natCast (n : ℕ) : C (n : R) = (n : R[X]) :=
map_natCast C n
@[simp]
theorem C_mul_monomial : C a * monomial n b = monomial n (a * b) := by
simp only [← monomial_zero_left, monomial_mul_monomial, zero_add]
@[simp]
theorem monomial_mul_C : monomial n a * C b = monomial n (a * b) := by
simp only [← monomial_zero_left, monomial_mul_monomial, add_zero]
/-- `X` is the polynomial variable (aka indeterminate). -/
def X : R[X] :=
monomial 1 1
theorem monomial_one_one_eq_X : monomial 1 (1 : R) = X :=
rfl
theorem monomial_one_right_eq_X_pow (n : ℕ) : monomial n (1 : R) = X ^ n := by
induction n with
| zero => simp [monomial_zero_one]
| succ n ih => rw [pow_succ, ← ih, ← monomial_one_one_eq_X, monomial_mul_monomial, mul_one]
@[simp]
theorem toFinsupp_X : X.toFinsupp = Finsupp.single 1 (1 : R) :=
rfl
theorem X_ne_C [Nontrivial R] (a : R) : X ≠ C a := by
intro he
simpa using monomial_eq_monomial_iff.1 he
/-- `X` commutes with everything, even when the coefficients are noncommutative. -/
theorem X_mul : X * p = p * X := by
rcases p with ⟨⟩
simp only [X, ← ofFinsupp_single, ← ofFinsupp_mul, LinearMap.coe_mk, ofFinsupp.injEq]
ext
simp [AddMonoidAlgebra.mul_apply, AddMonoidAlgebra.sum_single_index, add_comm]
theorem X_pow_mul {n : ℕ} : X ^ n * p = p * X ^ n := by
induction n with
| zero => simp
| succ n ih =>
conv_lhs => rw [pow_succ]
rw [mul_assoc, X_mul, ← mul_assoc, ih, mul_assoc, ← pow_succ]
/-- Prefer putting constants to the left of `X`.
This lemma is the loop-avoiding `simp` version of `Polynomial.X_mul`. -/
@[simp]
theorem X_mul_C (r : R) : X * C r = C r * X :=
X_mul
/-- Prefer putting constants to the left of `X ^ n`.
This lemma is the loop-avoiding `simp` version of `X_pow_mul`. -/
@[simp]
theorem X_pow_mul_C (r : R) (n : ℕ) : X ^ n * C r = C r * X ^ n :=
X_pow_mul
theorem X_pow_mul_assoc {n : ℕ} : p * X ^ n * q = p * q * X ^ n := by
rw [mul_assoc, X_pow_mul, ← mul_assoc]
/-- Prefer putting constants to the left of `X ^ n`.
This lemma is the loop-avoiding `simp` version of `X_pow_mul_assoc`. -/
@[simp]
theorem X_pow_mul_assoc_C {n : ℕ} (r : R) : p * X ^ n * C r = p * C r * X ^ n :=
X_pow_mul_assoc
theorem commute_X (p : R[X]) : Commute X p :=
X_mul
theorem commute_X_pow (p : R[X]) (n : ℕ) : Commute (X ^ n) p :=
X_pow_mul
@[simp]
theorem monomial_mul_X (n : ℕ) (r : R) : monomial n r * X = monomial (n + 1) r := by
rw [X, monomial_mul_monomial, mul_one]
@[simp]
theorem monomial_mul_X_pow (n : ℕ) (r : R) (k : ℕ) :
monomial n r * X ^ k = monomial (n + k) r := by
induction k with
| zero => simp
| succ k ih => simp [ih, pow_succ, ← mul_assoc, add_assoc]
@[simp]
theorem X_mul_monomial (n : ℕ) (r : R) : X * monomial n r = monomial (n + 1) r := by
rw [X_mul, monomial_mul_X]
@[simp]
theorem X_pow_mul_monomial (k n : ℕ) (r : R) : X ^ k * monomial n r = monomial (n + k) r := by
rw [X_pow_mul, monomial_mul_X_pow]
/-- `coeff p n` (often denoted `p.coeff n`) is the coefficient of `X^n` in `p`. -/
def coeff : R[X] → ℕ → R
| ⟨p⟩ => p
@[simp]
theorem coeff_ofFinsupp (p) : coeff (⟨p⟩ : R[X]) = p := by rw [coeff]
theorem coeff_injective : Injective (coeff : R[X] → ℕ → R) := by
rintro ⟨p⟩ ⟨q⟩
simp only [coeff, DFunLike.coe_fn_eq, imp_self, ofFinsupp.injEq]
@[simp]
theorem coeff_inj : p.coeff = q.coeff ↔ p = q :=
coeff_injective.eq_iff
theorem toFinsupp_apply (f : R[X]) (i) : f.toFinsupp i = f.coeff i := by cases f; rfl
theorem coeff_monomial : coeff (monomial n a) m = if n = m then a else 0 := by
simp [coeff, Finsupp.single_apply]
@[simp]
theorem coeff_monomial_same (n : ℕ) (c : R) : (monomial n c).coeff n = c :=
Finsupp.single_eq_same
theorem coeff_monomial_of_ne {m n : ℕ} (c : R) (h : n ≠ m) : (monomial n c).coeff m = 0 :=
Finsupp.single_eq_of_ne h
@[simp]
theorem coeff_zero (n : ℕ) : coeff (0 : R[X]) n = 0 :=
rfl
theorem coeff_one {n : ℕ} : coeff (1 : R[X]) n = if n = 0 then 1 else 0 := by
simp_rw [eq_comm (a := n) (b := 0)]
exact coeff_monomial
@[simp]
theorem coeff_one_zero : coeff (1 : R[X]) 0 = 1 := by
simp [coeff_one]
@[simp]
theorem coeff_X_one : coeff (X : R[X]) 1 = 1 :=
coeff_monomial
@[simp]
theorem coeff_X_zero : coeff (X : R[X]) 0 = 0 :=
coeff_monomial
@[simp]
theorem coeff_monomial_succ : coeff (monomial (n + 1) a) 0 = 0 := by simp [coeff_monomial]
theorem coeff_X : coeff (X : R[X]) n = if 1 = n then 1 else 0 :=
coeff_monomial
theorem coeff_X_of_ne_one {n : ℕ} (hn : n ≠ 1) : coeff (X : R[X]) n = 0 := by
rw [coeff_X, if_neg hn.symm]
@[simp]
theorem mem_support_iff : n ∈ p.support ↔ p.coeff n ≠ 0 := by
rcases p with ⟨⟩
simp
theorem not_mem_support_iff : n ∉ p.support ↔ p.coeff n = 0 := by simp
theorem coeff_C : coeff (C a) n = ite (n = 0) a 0 := by
convert coeff_monomial (a := a) (m := n) (n := 0) using 2
| simp [eq_comm]
@[simp]
theorem coeff_C_zero : coeff (C a) 0 = a :=
coeff_monomial
| Mathlib/Algebra/Polynomial/Basic.lean | 642 | 646 |
/-
Copyright (c) 2023 Yaël Dillies. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies
-/
import Mathlib.Algebra.BigOperators.Group.Finset.Piecewise
import Mathlib.Algebra.Order.BigOperators.Group.Finset
import Mathlib.Algebra.Order.Pi
import Mathlib.Algebra.Order.Ring.Nat
import Mathlib.Data.Finset.Sups
import Mathlib.Order.Birkhoff
import Mathlib.Order.Booleanisation
import Mathlib.Order.Sublattice
import Mathlib.Tactic.Positivity.Basic
import Mathlib.Tactic.Ring
/-!
# The four functions theorem and corollaries
This file proves the four functions theorem. The statement is that if
`f₁ a * f₂ b ≤ f₃ (a ⊓ b) * f₄ (a ⊔ b)` for all `a`, `b` in a finite distributive lattice, then
`(∑ x ∈ s, f₁ x) * (∑ x ∈ t, f₂ x) ≤ (∑ x ∈ s ⊼ t, f₃ x) * (∑ x ∈ s ⊻ t, f₄ x)` where
`s ⊼ t = {a ⊓ b | a ∈ s, b ∈ t}`, `s ⊻ t = {a ⊔ b | a ∈ s, b ∈ t}`.
The proof uses Birkhoff's representation theorem to restrict to the case where the finite
distributive lattice is in fact a finite powerset algebra, namely `Finset α` for some finite `α`.
Then it proves this new statement by induction on the size of `α`.
## Main declarations
The two versions of the four functions theorem are
* `Finset.four_functions_theorem` for finite powerset algebras.
* `four_functions_theorem` for any finite distributive lattices.
We deduce a number of corollaries:
* `Finset.le_card_infs_mul_card_sups`: Daykin inequality. `|s| |t| ≤ |s ⊼ t| |s ⊻ t|`
* `holley`: Holley inequality.
* `fkg`: Fortuin-Kastelyn-Ginibre inequality.
* `Finset.card_le_card_diffs`: Marica-Schönheim inequality. `|s| ≤ |{a \ b | a, b ∈ s}|`
## TODO
Prove that lattices in which `Finset.le_card_infs_mul_card_sups` holds are distributive. See
Daykin, *A lattice is distributive iff |A| |B| <= |A ∨ B| |A ∧ B|*
Prove the Fishburn-Shepp inequality.
Is `collapse` a construct generally useful for set family inductions? If so, we should move it to an
earlier file and give it a proper API.
## References
[*Applications of the FKG Inequality and Its Relatives*, Graham][Graham1983]
-/
open Finset Fintype Function
open scoped FinsetFamily
variable {α β : Type*}
section Finset
variable [DecidableEq α] [CommSemiring β] [LinearOrder β] [IsStrictOrderedRing β]
{𝒜 : Finset (Finset α)} {a : α} {f f₁ f₂ f₃ f₄ : Finset α → β} {s t u : Finset α}
/-- The `n = 1` case of the Ahlswede-Daykin inequality. Note that we can't just expand everything
out and bound termwise since `c₀ * d₁` appears twice on the RHS of the assumptions while `c₁ * d₀`
does not appear. -/
private lemma ineq [ExistsAddOfLE β] {a₀ a₁ b₀ b₁ c₀ c₁ d₀ d₁ : β}
(ha₀ : 0 ≤ a₀) (ha₁ : 0 ≤ a₁) (hb₀ : 0 ≤ b₀) (hb₁ : 0 ≤ b₁)
(hc₀ : 0 ≤ c₀) (hc₁ : 0 ≤ c₁) (hd₀ : 0 ≤ d₀) (hd₁ : 0 ≤ d₁)
(h₀₀ : a₀ * b₀ ≤ c₀ * d₀) (h₁₀ : a₁ * b₀ ≤ c₀ * d₁)
(h₀₁ : a₀ * b₁ ≤ c₀ * d₁) (h₁₁ : a₁ * b₁ ≤ c₁ * d₁) :
(a₀ + a₁) * (b₀ + b₁) ≤ (c₀ + c₁) * (d₀ + d₁) := by
calc
_ = a₀ * b₀ + (a₀ * b₁ + a₁ * b₀) + a₁ * b₁ := by ring
_ ≤ c₀ * d₀ + (c₀ * d₁ + c₁ * d₀) + c₁ * d₁ := add_le_add_three h₀₀ ?_ h₁₁
_ = (c₀ + c₁) * (d₀ + d₁) := by ring
obtain hcd | hcd := (mul_nonneg hc₀ hd₁).eq_or_gt
· rw [hcd] at h₀₁ h₁₀
rw [h₀₁.antisymm, h₁₀.antisymm, add_zero] <;> positivity
refine le_of_mul_le_mul_right ?_ hcd
calc (a₀ * b₁ + a₁ * b₀) * (c₀ * d₁)
= a₀ * b₁ * (c₀ * d₁) + c₀ * d₁ * (a₁ * b₀) := by ring
_ ≤ a₀ * b₁ * (a₁ * b₀) + c₀ * d₁ * (c₀ * d₁) := mul_add_mul_le_mul_add_mul h₀₁ h₁₀
_ = a₀ * b₀ * (a₁ * b₁) + c₀ * d₁ * (c₀ * d₁) := by ring
_ ≤ c₀ * d₀ * (c₁ * d₁) + c₀ * d₁ * (c₀ * d₁) :=
add_le_add_right (mul_le_mul h₀₀ h₁₁ (by positivity) <| by positivity) _
_ = (c₀ * d₁ + c₁ * d₀) * (c₀ * d₁) := by ring
private def collapse (𝒜 : Finset (Finset α)) (a : α) (f : Finset α → β) (s : Finset α) : β :=
∑ t ∈ 𝒜 with t.erase a = s, f t
private lemma erase_eq_iff (hs : a ∉ s) : t.erase a = s ↔ t = s ∨ t = insert a s := by
by_cases ht : a ∈ t <;>
· simp [ne_of_mem_of_not_mem', erase_eq_iff_eq_insert, *]
aesop
| private lemma filter_collapse_eq (ha : a ∉ s) (𝒜 : Finset (Finset α)) :
{t ∈ 𝒜 | t.erase a = s} =
if s ∈ 𝒜 then
(if insert a s ∈ 𝒜 then {s, insert a s} else {s})
else
(if insert a s ∈ 𝒜 then {insert a s} else ∅) := by
ext t; split_ifs <;> simp [erase_eq_iff ha] <;> aesop
| Mathlib/Combinatorics/SetFamily/FourFunctions.lean | 98 | 104 |
/-
Copyright (c) 2018 Chris Hughes. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Chris Hughes, Johannes Hölzl, Kim Morrison, Jens Wagemaker
-/
import Mathlib.Algebra.MonoidAlgebra.Degree
import Mathlib.Algebra.Order.Ring.WithTop
import Mathlib.Algebra.Polynomial.Basic
import Mathlib.Data.Nat.Cast.WithTop
import Mathlib.Data.Nat.SuccPred
import Mathlib.Order.SuccPred.WithBot
/-!
# Degree of univariate polynomials
## Main definitions
* `Polynomial.degree`: the degree of a polynomial, where `0` has degree `⊥`
* `Polynomial.natDegree`: the degree of a polynomial, where `0` has degree `0`
* `Polynomial.leadingCoeff`: the leading coefficient of a polynomial
* `Polynomial.Monic`: a polynomial is monic if its leading coefficient is 0
* `Polynomial.nextCoeff`: the next coefficient after the leading coefficient
## Main results
* `Polynomial.degree_eq_natDegree`: the degree and natDegree coincide for nonzero polynomials
-/
noncomputable section
open Finsupp Finset
open Polynomial
namespace Polynomial
universe u v
variable {R : Type u} {S : Type v} {a b c d : R} {n m : ℕ}
section Semiring
variable [Semiring R] {p q r : R[X]}
/-- `degree p` is the degree of the polynomial `p`, i.e. the largest `X`-exponent in `p`.
`degree p = some n` when `p ≠ 0` and `n` is the highest power of `X` that appears in `p`, otherwise
`degree 0 = ⊥`. -/
def degree (p : R[X]) : WithBot ℕ :=
p.support.max
/-- `natDegree p` forces `degree p` to ℕ, by defining `natDegree 0 = 0`. -/
def natDegree (p : R[X]) : ℕ :=
(degree p).unbotD 0
/-- `leadingCoeff p` gives the coefficient of the highest power of `X` in `p`. -/
def leadingCoeff (p : R[X]) : R :=
coeff p (natDegree p)
/-- a polynomial is `Monic` if its leading coefficient is 1 -/
def Monic (p : R[X]) :=
leadingCoeff p = (1 : R)
theorem Monic.def : Monic p ↔ leadingCoeff p = 1 :=
Iff.rfl
instance Monic.decidable [DecidableEq R] : Decidable (Monic p) := by unfold Monic; infer_instance
@[simp]
theorem Monic.leadingCoeff {p : R[X]} (hp : p.Monic) : leadingCoeff p = 1 :=
hp
theorem Monic.coeff_natDegree {p : R[X]} (hp : p.Monic) : p.coeff p.natDegree = 1 :=
hp
@[simp]
theorem degree_zero : degree (0 : R[X]) = ⊥ :=
rfl
@[simp]
theorem natDegree_zero : natDegree (0 : R[X]) = 0 :=
rfl
@[simp]
theorem coeff_natDegree : coeff p (natDegree p) = leadingCoeff p :=
rfl
@[simp]
theorem degree_eq_bot : degree p = ⊥ ↔ p = 0 :=
⟨fun h => support_eq_empty.1 (Finset.max_eq_bot.1 h), fun h => h.symm ▸ rfl⟩
theorem degree_ne_bot : degree p ≠ ⊥ ↔ p ≠ 0 := degree_eq_bot.not
theorem degree_eq_natDegree (hp : p ≠ 0) : degree p = (natDegree p : WithBot ℕ) := by
let ⟨n, hn⟩ := not_forall.1 (mt Option.eq_none_iff_forall_not_mem.2 (mt degree_eq_bot.1 hp))
have hn : degree p = some n := Classical.not_not.1 hn
rw [natDegree, hn]; rfl
theorem degree_eq_iff_natDegree_eq {p : R[X]} {n : ℕ} (hp : p ≠ 0) :
p.degree = n ↔ p.natDegree = n := by rw [degree_eq_natDegree hp]; exact WithBot.coe_eq_coe
theorem degree_eq_iff_natDegree_eq_of_pos {p : R[X]} {n : ℕ} (hn : 0 < n) :
p.degree = n ↔ p.natDegree = n := by
obtain rfl|h := eq_or_ne p 0
· simp [hn.ne]
· exact degree_eq_iff_natDegree_eq h
theorem natDegree_eq_of_degree_eq_some {p : R[X]} {n : ℕ} (h : degree p = n) : natDegree p = n := by
rw [natDegree, h, Nat.cast_withBot, WithBot.unbotD_coe]
theorem degree_ne_of_natDegree_ne {n : ℕ} : p.natDegree ≠ n → degree p ≠ n :=
mt natDegree_eq_of_degree_eq_some
@[simp]
theorem degree_le_natDegree : degree p ≤ natDegree p :=
WithBot.giUnbotDBot.gc.le_u_l _
theorem natDegree_eq_of_degree_eq [Semiring S] {q : S[X]} (h : degree p = degree q) :
natDegree p = natDegree q := by unfold natDegree; rw [h]
theorem le_degree_of_ne_zero (h : coeff p n ≠ 0) : (n : WithBot ℕ) ≤ degree p := by
rw [Nat.cast_withBot]
exact Finset.le_sup (mem_support_iff.2 h)
theorem degree_mono [Semiring S] {f : R[X]} {g : S[X]} (h : f.support ⊆ g.support) :
f.degree ≤ g.degree :=
Finset.sup_mono h
theorem degree_le_degree (h : coeff q (natDegree p) ≠ 0) : degree p ≤ degree q := by
by_cases hp : p = 0
· rw [hp, degree_zero]
exact bot_le
· rw [degree_eq_natDegree hp]
exact le_degree_of_ne_zero h
theorem natDegree_le_iff_degree_le {n : ℕ} : natDegree p ≤ n ↔ degree p ≤ n :=
WithBot.unbotD_le_iff (fun _ ↦ bot_le)
theorem natDegree_lt_iff_degree_lt (hp : p ≠ 0) : p.natDegree < n ↔ p.degree < ↑n :=
WithBot.unbotD_lt_iff (absurd · (degree_eq_bot.not.mpr hp))
alias ⟨degree_le_of_natDegree_le, natDegree_le_of_degree_le⟩ := natDegree_le_iff_degree_le
theorem natDegree_le_natDegree [Semiring S] {q : S[X]} (hpq : p.degree ≤ q.degree) :
p.natDegree ≤ q.natDegree :=
WithBot.giUnbotDBot.gc.monotone_l hpq
@[simp]
theorem degree_C (ha : a ≠ 0) : degree (C a) = (0 : WithBot ℕ) := by
rw [degree, ← monomial_zero_left, support_monomial 0 ha, max_eq_sup_coe, sup_singleton,
WithBot.coe_zero]
theorem degree_C_le : degree (C a) ≤ 0 := by
by_cases h : a = 0
· rw [h, C_0]
exact bot_le
· rw [degree_C h]
theorem degree_C_lt : degree (C a) < 1 :=
degree_C_le.trans_lt <| WithBot.coe_lt_coe.mpr zero_lt_one
theorem degree_one_le : degree (1 : R[X]) ≤ (0 : WithBot ℕ) := by rw [← C_1]; exact degree_C_le
@[simp]
theorem natDegree_C (a : R) : natDegree (C a) = 0 := by
by_cases ha : a = 0
· have : C a = 0 := by rw [ha, C_0]
rw [natDegree, degree_eq_bot.2 this, WithBot.unbotD_bot]
· rw [natDegree, degree_C ha, WithBot.unbotD_zero]
@[simp]
theorem natDegree_one : natDegree (1 : R[X]) = 0 :=
natDegree_C 1
@[simp]
theorem natDegree_natCast (n : ℕ) : natDegree (n : R[X]) = 0 := by
simp only [← C_eq_natCast, natDegree_C]
@[simp]
theorem natDegree_ofNat (n : ℕ) [Nat.AtLeastTwo n] :
natDegree (ofNat(n) : R[X]) = 0 :=
natDegree_natCast _
theorem degree_natCast_le (n : ℕ) : degree (n : R[X]) ≤ 0 := degree_le_of_natDegree_le (by simp)
@[simp]
theorem degree_monomial (n : ℕ) (ha : a ≠ 0) : degree (monomial n a) = n := by
rw [degree, support_monomial n ha, max_singleton, Nat.cast_withBot]
@[simp]
theorem degree_C_mul_X_pow (n : ℕ) (ha : a ≠ 0) : degree (C a * X ^ n) = n := by
rw [C_mul_X_pow_eq_monomial, degree_monomial n ha]
theorem degree_C_mul_X (ha : a ≠ 0) : degree (C a * X) = 1 := by
simpa only [pow_one] using degree_C_mul_X_pow 1 ha
theorem degree_monomial_le (n : ℕ) (a : R) : degree (monomial n a) ≤ n :=
letI := Classical.decEq R
if h : a = 0 then by rw [h, (monomial n).map_zero, degree_zero]; exact bot_le
else le_of_eq (degree_monomial n h)
theorem degree_C_mul_X_pow_le (n : ℕ) (a : R) : degree (C a * X ^ n) ≤ n := by
rw [C_mul_X_pow_eq_monomial]
apply degree_monomial_le
theorem degree_C_mul_X_le (a : R) : degree (C a * X) ≤ 1 := by
simpa only [pow_one] using degree_C_mul_X_pow_le 1 a
@[simp]
theorem natDegree_C_mul_X_pow (n : ℕ) (a : R) (ha : a ≠ 0) : natDegree (C a * X ^ n) = n :=
natDegree_eq_of_degree_eq_some (degree_C_mul_X_pow n ha)
@[simp]
theorem natDegree_C_mul_X (a : R) (ha : a ≠ 0) : natDegree (C a * X) = 1 := by
simpa only [pow_one] using natDegree_C_mul_X_pow 1 a ha
@[simp]
theorem natDegree_monomial [DecidableEq R] (i : ℕ) (r : R) :
natDegree (monomial i r) = if r = 0 then 0 else i := by
split_ifs with hr
· simp [hr]
· rw [← C_mul_X_pow_eq_monomial, natDegree_C_mul_X_pow i r hr]
theorem natDegree_monomial_le (a : R) {m : ℕ} : (monomial m a).natDegree ≤ m := by
classical
rw [Polynomial.natDegree_monomial]
split_ifs
exacts [Nat.zero_le _, le_rfl]
theorem natDegree_monomial_eq (i : ℕ) {r : R} (r0 : r ≠ 0) : (monomial i r).natDegree = i :=
letI := Classical.decEq R
Eq.trans (natDegree_monomial _ _) (if_neg r0)
theorem coeff_ne_zero_of_eq_degree (hn : degree p = n) : coeff p n ≠ 0 := fun h =>
mem_support_iff.mp (mem_of_max hn) h
theorem degree_X_pow_le (n : ℕ) : degree (X ^ n : R[X]) ≤ n := by
simpa only [C_1, one_mul] using degree_C_mul_X_pow_le n (1 : R)
|
theorem degree_X_le : degree (X : R[X]) ≤ 1 :=
degree_monomial_le _ _
theorem natDegree_X_le : (X : R[X]).natDegree ≤ 1 :=
| Mathlib/Algebra/Polynomial/Degree/Definitions.lean | 238 | 242 |
/-
Copyright (c) 2023 Johan Commelin. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johan Commelin
-/
import Mathlib.Algebra.Divisibility.Basic
import Mathlib.Algebra.Group.Prod
import Mathlib.Tactic.Common
/-!
# Lemmas about the divisibility relation in product (semi)groups
-/
variable {ι G₁ G₂ : Type*} {G : ι → Type*} [Semigroup G₁] [Semigroup G₂] [∀ i, Semigroup (G i)]
theorem prod_dvd_iff {x y : G₁ × G₂} :
x ∣ y ↔ x.1 ∣ y.1 ∧ x.2 ∣ y.2 := by
cases x; cases y
simp only [dvd_def, Prod.exists, Prod.mk_mul_mk, Prod.mk.injEq,
exists_and_left, exists_and_right, and_self, true_and]
@[simp]
theorem Prod.mk_dvd_mk {x₁ y₁ : G₁} {x₂ y₂ : G₂} :
(x₁, x₂) ∣ (y₁, y₂) ↔ x₁ ∣ y₁ ∧ x₂ ∣ y₂ :=
prod_dvd_iff
instance [DecompositionMonoid G₁] [DecompositionMonoid G₂] : DecompositionMonoid (G₁ × G₂) where
primal a b c h := by
simp_rw [prod_dvd_iff] at h ⊢
obtain ⟨a₁, a₁', h₁, h₁', eq₁⟩ := DecompositionMonoid.primal a.1 h.1
obtain ⟨a₂, a₂', h₂, h₂', eq₂⟩ := DecompositionMonoid.primal a.2 h.2
-- aesop works here
exact ⟨(a₁, a₂), (a₁', a₂'), ⟨h₁, h₂⟩, ⟨h₁', h₂'⟩, Prod.ext eq₁ eq₂⟩
| theorem pi_dvd_iff {x y : ∀ i, G i} : x ∣ y ↔ ∀ i, x i ∣ y i := by
simp_rw [dvd_def, funext_iff, Classical.skolem]; rfl
| Mathlib/Algebra/Divisibility/Prod.lean | 35 | 36 |
/-
Copyright (c) 2020 Joseph Myers. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joseph Myers, Sébastien Gouëzel, Heather Macbeth
-/
import Mathlib.Analysis.InnerProductSpace.Projection
import Mathlib.Analysis.Normed.Lp.PiLp
import Mathlib.LinearAlgebra.FiniteDimensional.Lemmas
import Mathlib.LinearAlgebra.UnitaryGroup
import Mathlib.Util.Superscript
/-!
# `L²` inner product space structure on finite products of inner product spaces
The `L²` norm on a finite product of inner product spaces is compatible with an inner product
$$
\langle x, y\rangle = \sum \langle x_i, y_i \rangle.
$$
This is recorded in this file as an inner product space instance on `PiLp 2`.
This file develops the notion of a finite dimensional Hilbert space over `𝕜 = ℂ, ℝ`, referred to as
`E`. We define an `OrthonormalBasis 𝕜 ι E` as a linear isometric equivalence
between `E` and `EuclideanSpace 𝕜 ι`. Then `stdOrthonormalBasis` shows that such an equivalence
always exists if `E` is finite dimensional. We provide language for converting between a basis
that is orthonormal and an orthonormal basis (e.g. `Basis.toOrthonormalBasis`). We show that
orthonormal bases for each summand in a direct sum of spaces can be combined into an orthonormal
basis for the whole sum in `DirectSum.IsInternal.subordinateOrthonormalBasis`. In
the last section, various properties of matrices are explored.
## Main definitions
- `EuclideanSpace 𝕜 n`: defined to be `PiLp 2 (n → 𝕜)` for any `Fintype n`, i.e., the space
from functions to `n` to `𝕜` with the `L²` norm. We register several instances on it (notably
that it is a finite-dimensional inner product space), and provide a `!ₚ[]` notation (for numeric
subscripts like `₂`) for the case when the indexing type is `Fin n`.
- `OrthonormalBasis 𝕜 ι`: defined to be an isometry to Euclidean space from a given
finite-dimensional inner product space, `E ≃ₗᵢ[𝕜] EuclideanSpace 𝕜 ι`.
- `Basis.toOrthonormalBasis`: constructs an `OrthonormalBasis` for a finite-dimensional
Euclidean space from a `Basis` which is `Orthonormal`.
- `Orthonormal.exists_orthonormalBasis_extension`: provides an existential result of an
`OrthonormalBasis` extending a given orthonormal set
- `exists_orthonormalBasis`: provides an orthonormal basis on a finite dimensional vector space
- `stdOrthonormalBasis`: provides an arbitrarily-chosen `OrthonormalBasis` of a given finite
dimensional inner product space
For consequences in infinite dimension (Hilbert bases, etc.), see the file
`Analysis.InnerProductSpace.L2Space`.
-/
open Real Set Filter RCLike Submodule Function Uniformity Topology NNReal ENNReal
ComplexConjugate DirectSum
noncomputable section
variable {ι ι' 𝕜 : Type*} [RCLike 𝕜]
variable {E : Type*} [NormedAddCommGroup E] [InnerProductSpace 𝕜 E]
variable {F : Type*} [NormedAddCommGroup F] [InnerProductSpace ℝ F]
variable {F' : Type*} [NormedAddCommGroup F'] [InnerProductSpace ℝ F']
local notation "⟪" x ", " y "⟫" => @inner 𝕜 _ _ x y
/-
If `ι` is a finite type and each space `f i`, `i : ι`, is an inner product space,
then `Π i, f i` is an inner product space as well. Since `Π i, f i` is endowed with the sup norm,
we use instead `PiLp 2 f` for the product space, which is endowed with the `L^2` norm.
-/
instance PiLp.innerProductSpace {ι : Type*} [Fintype ι] (f : ι → Type*)
[∀ i, NormedAddCommGroup (f i)] [∀ i, InnerProductSpace 𝕜 (f i)] :
InnerProductSpace 𝕜 (PiLp 2 f) where
inner x y := ∑ i, inner (x i) (y i)
norm_sq_eq_re_inner x := by
simp only [PiLp.norm_sq_eq_of_L2, map_sum, ← norm_sq_eq_re_inner, one_div]
conj_inner_symm := by
intro x y
unfold inner
rw [map_sum]
apply Finset.sum_congr rfl
rintro z -
apply inner_conj_symm
add_left x y z :=
show (∑ i, inner (x i + y i) (z i)) = (∑ i, inner (x i) (z i)) + ∑ i, inner (y i) (z i) by
simp only [inner_add_left, Finset.sum_add_distrib]
smul_left x y r :=
show (∑ i : ι, inner (r • x i) (y i)) = conj r * ∑ i, inner (x i) (y i) by
simp only [Finset.mul_sum, inner_smul_left]
@[simp]
theorem PiLp.inner_apply {ι : Type*} [Fintype ι] {f : ι → Type*} [∀ i, NormedAddCommGroup (f i)]
[∀ i, InnerProductSpace 𝕜 (f i)] (x y : PiLp 2 f) : ⟪x, y⟫ = ∑ i, ⟪x i, y i⟫ :=
rfl
/-- The standard real/complex Euclidean space, functions on a finite type. For an `n`-dimensional
space use `EuclideanSpace 𝕜 (Fin n)`.
For the case when `n = Fin _`, there is `!₂[x, y, ...]` notation for building elements of this type,
analogous to `![x, y, ...]` notation. -/
abbrev EuclideanSpace (𝕜 : Type*) (n : Type*) : Type _ :=
PiLp 2 fun _ : n => 𝕜
section Notation
open Lean Meta Elab Term Macro TSyntax PrettyPrinter.Delaborator SubExpr
open Mathlib.Tactic (subscriptTerm)
/-- Notation for vectors in Lp space. `!₂[x, y, ...]` is a shorthand for
`(WithLp.equiv 2 _ _).symm ![x, y, ...]`, of type `EuclideanSpace _ (Fin _)`.
This also works for other subscripts. -/
syntax (name := PiLp.vecNotation) "!" noWs subscriptTerm noWs "[" term,* "]" : term
macro_rules | `(!$p:subscript[$e:term,*]) => do
-- override the `Fin n.succ` to a literal
let n := e.getElems.size
`((WithLp.equiv $p <| ∀ _ : Fin $(quote n), _).symm ![$e,*])
/-- Unexpander for the `!₂[x, y, ...]` notation. -/
@[app_delab DFunLike.coe]
def EuclideanSpace.delabVecNotation : Delab :=
whenNotPPOption getPPExplicit <| whenPPOption getPPNotation <| withOverApp 6 do
-- check that the `(WithLp.equiv _ _).symm` is present
let p : Term ← withAppFn <| withAppArg do
let_expr Equiv.symm _ _ e := ← getExpr | failure
let_expr WithLp.equiv _ _ := e | failure
withNaryArg 2 <| withNaryArg 0 <| delab
-- to be conservative, only allow subscripts which are numerals
guard <| p matches `($_:num)
let `(![$elems,*]) := ← withAppArg delab | failure
`(!$p[$elems,*])
end Notation
theorem EuclideanSpace.nnnorm_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x : EuclideanSpace 𝕜 n) : ‖x‖₊ = NNReal.sqrt (∑ i, ‖x i‖₊ ^ 2) :=
PiLp.nnnorm_eq_of_L2 x
theorem EuclideanSpace.norm_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x : EuclideanSpace 𝕜 n) : ‖x‖ = √(∑ i, ‖x i‖ ^ 2) := by
simpa only [Real.coe_sqrt, NNReal.coe_sum] using congr_arg ((↑) : ℝ≥0 → ℝ) x.nnnorm_eq
theorem EuclideanSpace.dist_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x y : EuclideanSpace 𝕜 n) : dist x y = √(∑ i, dist (x i) (y i) ^ 2) :=
PiLp.dist_eq_of_L2 x y
theorem EuclideanSpace.nndist_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x y : EuclideanSpace 𝕜 n) : nndist x y = NNReal.sqrt (∑ i, nndist (x i) (y i) ^ 2) :=
PiLp.nndist_eq_of_L2 x y
theorem EuclideanSpace.edist_eq {𝕜 : Type*} [RCLike 𝕜] {n : Type*} [Fintype n]
(x y : EuclideanSpace 𝕜 n) : edist x y = (∑ i, edist (x i) (y i) ^ 2) ^ (1 / 2 : ℝ) :=
PiLp.edist_eq_of_L2 x y
theorem EuclideanSpace.ball_zero_eq {n : Type*} [Fintype n] (r : ℝ) (hr : 0 ≤ r) :
Metric.ball (0 : EuclideanSpace ℝ n) r = {x | ∑ i, x i ^ 2 < r ^ 2} := by
ext x
have : (0 : ℝ) ≤ ∑ i, x i ^ 2 := Finset.sum_nonneg fun _ _ => sq_nonneg _
| simp_rw [mem_setOf, mem_ball_zero_iff, norm_eq, norm_eq_abs, sq_abs, sqrt_lt this hr]
theorem EuclideanSpace.closedBall_zero_eq {n : Type*} [Fintype n] (r : ℝ) (hr : 0 ≤ r) :
| Mathlib/Analysis/InnerProductSpace/PiL2.lean | 161 | 163 |
/-
Copyright (c) 2017 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro
-/
import Mathlib.Data.Ordmap.Invariants
/-!
# Verification of `Ordnode`
This file uses the invariants defined in `Mathlib.Data.Ordmap.Invariants` to construct `Ordset α`,
a wrapper around `Ordnode α` which includes the correctness invariant of the type. It exposes
parallel operations like `insert` as functions on `Ordset` that do the same thing but bundle the
correctness proofs.
The advantage is that it is possible to, for example, prove that the result of `find` on `insert`
will actually find the element, while `Ordnode` cannot guarantee this if the input tree did not
satisfy the type invariants.
## Main definitions
* `Ordnode.Valid`: The validity predicate for an `Ordnode` subtree.
* `Ordset α`: A well formed set of values of type `α`.
## Implementation notes
Because the `Ordnode` file was ported from Haskell, the correctness invariants of some
of the functions have not been spelled out, and some theorems like
`Ordnode.Valid'.balanceL_aux` show very intricate assumptions on the sizes,
which may need to be revised if it turns out some operations violate these assumptions,
because there is a decent amount of slop in the actual data structure invariants, so the
theorem will go through with multiple choices of assumption.
-/
variable {α : Type*}
namespace Ordnode
section Valid
variable [Preorder α]
/-- The validity predicate for an `Ordnode` subtree. This asserts that the `size` fields are
correct, the tree is balanced, and the elements of the tree are organized according to the
ordering. This version of `Valid` also puts all elements in the tree in the interval `(lo, hi)`. -/
structure Valid' (lo : WithBot α) (t : Ordnode α) (hi : WithTop α) : Prop where
ord : t.Bounded lo hi
sz : t.Sized
bal : t.Balanced
/-- The validity predicate for an `Ordnode` subtree. This asserts that the `size` fields are
correct, the tree is balanced, and the elements of the tree are organized according to the
ordering. -/
def Valid (t : Ordnode α) : Prop :=
Valid' ⊥ t ⊤
theorem Valid'.mono_left {x y : α} (xy : x ≤ y) {t : Ordnode α} {o} (h : Valid' y t o) :
Valid' x t o :=
⟨h.1.mono_left xy, h.2, h.3⟩
theorem Valid'.mono_right {x y : α} (xy : x ≤ y) {t : Ordnode α} {o} (h : Valid' o t x) :
Valid' o t y :=
⟨h.1.mono_right xy, h.2, h.3⟩
theorem Valid'.trans_left {t₁ t₂ : Ordnode α} {x : α} {o₁ o₂} (h : Bounded t₁ o₁ x)
(H : Valid' x t₂ o₂) : Valid' o₁ t₂ o₂ :=
⟨h.trans_left H.1, H.2, H.3⟩
theorem Valid'.trans_right {t₁ t₂ : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t₁ x)
(h : Bounded t₂ x o₂) : Valid' o₁ t₁ o₂ :=
⟨H.1.trans_right h, H.2, H.3⟩
theorem Valid'.of_lt {t : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t o₂) (h₁ : Bounded nil o₁ x)
(h₂ : All (· < x) t) : Valid' o₁ t x :=
⟨H.1.of_lt h₁ h₂, H.2, H.3⟩
theorem Valid'.of_gt {t : Ordnode α} {x : α} {o₁ o₂} (H : Valid' o₁ t o₂) (h₁ : Bounded nil x o₂)
(h₂ : All (· > x) t) : Valid' x t o₂ :=
⟨H.1.of_gt h₁ h₂, H.2, H.3⟩
theorem Valid'.valid {t o₁ o₂} (h : @Valid' α _ o₁ t o₂) : Valid t :=
⟨h.1.weak, h.2, h.3⟩
theorem valid'_nil {o₁ o₂} (h : Bounded nil o₁ o₂) : Valid' o₁ (@nil α) o₂ :=
⟨h, ⟨⟩, ⟨⟩⟩
theorem valid_nil : Valid (@nil α) :=
valid'_nil ⟨⟩
theorem Valid'.node {s l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H : BalancedSz (size l) (size r)) (hs : s = size l + size r + 1) :
Valid' o₁ (@node α s l x r) o₂ :=
⟨⟨hl.1, hr.1⟩, ⟨hs, hl.2, hr.2⟩, ⟨H, hl.3, hr.3⟩⟩
theorem Valid'.dual : ∀ {t : Ordnode α} {o₁ o₂}, Valid' o₁ t o₂ → @Valid' αᵒᵈ _ o₂ (dual t) o₁
| .nil, _, _, h => valid'_nil h.1.dual
| .node _ l _ r, _, _, ⟨⟨ol, Or⟩, ⟨rfl, sl, sr⟩, ⟨b, bl, br⟩⟩ =>
let ⟨ol', sl', bl'⟩ := Valid'.dual ⟨ol, sl, bl⟩
let ⟨or', sr', br'⟩ := Valid'.dual ⟨Or, sr, br⟩
⟨⟨or', ol'⟩, ⟨by simp [size_dual, add_comm], sr', sl'⟩,
⟨by rw [size_dual, size_dual]; exact b.symm, br', bl'⟩⟩
theorem Valid'.dual_iff {t : Ordnode α} {o₁ o₂} : Valid' o₁ t o₂ ↔ @Valid' αᵒᵈ _ o₂ (.dual t) o₁ :=
⟨Valid'.dual, fun h => by
have := Valid'.dual h; rwa [dual_dual, OrderDual.Preorder.dual_dual] at this⟩
theorem Valid.dual {t : Ordnode α} : Valid t → @Valid αᵒᵈ _ (.dual t) :=
Valid'.dual
theorem Valid.dual_iff {t : Ordnode α} : Valid t ↔ @Valid αᵒᵈ _ (.dual t) :=
Valid'.dual_iff
theorem Valid'.left {s l x r o₁ o₂} (H : Valid' o₁ (@Ordnode.node α s l x r) o₂) : Valid' o₁ l x :=
⟨H.1.1, H.2.2.1, H.3.2.1⟩
theorem Valid'.right {s l x r o₁ o₂} (H : Valid' o₁ (@Ordnode.node α s l x r) o₂) : Valid' x r o₂ :=
⟨H.1.2, H.2.2.2, H.3.2.2⟩
nonrec theorem Valid.left {s l x r} (H : Valid (@node α s l x r)) : Valid l :=
H.left.valid
nonrec theorem Valid.right {s l x r} (H : Valid (@node α s l x r)) : Valid r :=
H.right.valid
theorem Valid.size_eq {s l x r} (H : Valid (@node α s l x r)) :
size (@node α s l x r) = size l + size r + 1 :=
H.2.1
theorem Valid'.node' {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H : BalancedSz (size l) (size r)) : Valid' o₁ (@node' α l x r) o₂ :=
hl.node hr H rfl
theorem valid'_singleton {x : α} {o₁ o₂} (h₁ : Bounded nil o₁ x) (h₂ : Bounded nil x o₂) :
Valid' o₁ (singleton x : Ordnode α) o₂ :=
(valid'_nil h₁).node (valid'_nil h₂) (Or.inl zero_le_one) rfl
theorem valid_singleton {x : α} : Valid (singleton x : Ordnode α) :=
valid'_singleton ⟨⟩ ⟨⟩
theorem Valid'.node3L {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y)
(hr : Valid' y r o₂) (H1 : BalancedSz (size l) (size m))
(H2 : BalancedSz (size l + size m + 1) (size r)) : Valid' o₁ (@node3L α l x m y r) o₂ :=
(hl.node' hm H1).node' hr H2
theorem Valid'.node3R {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y)
(hr : Valid' y r o₂) (H1 : BalancedSz (size l) (size m + size r + 1))
(H2 : BalancedSz (size m) (size r)) : Valid' o₁ (@node3R α l x m y r) o₂ :=
hl.node' (hm.node' hr H2) H1
theorem Valid'.node4L_lemma₁ {a b c d : ℕ} (lr₂ : 3 * (b + c + 1 + d) ≤ 16 * a + 9)
(mr₂ : b + c + 1 ≤ 3 * d) (mm₁ : b ≤ 3 * c) : b < 3 * a + 1 := by omega
theorem Valid'.node4L_lemma₂ {b c d : ℕ} (mr₂ : b + c + 1 ≤ 3 * d) : c ≤ 3 * d := by omega
theorem Valid'.node4L_lemma₃ {b c d : ℕ} (mr₁ : 2 * d ≤ b + c + 1) (mm₁ : b ≤ 3 * c) :
d ≤ 3 * c := by omega
theorem Valid'.node4L_lemma₄ {a b c d : ℕ} (lr₁ : 3 * a ≤ b + c + 1 + d) (mr₂ : b + c + 1 ≤ 3 * d)
(mm₁ : b ≤ 3 * c) : a + b + 1 ≤ 3 * (c + d + 1) := by omega
theorem Valid'.node4L_lemma₅ {a b c d : ℕ} (lr₂ : 3 * (b + c + 1 + d) ≤ 16 * a + 9)
(mr₁ : 2 * d ≤ b + c + 1) (mm₂ : c ≤ 3 * b) : c + d + 1 ≤ 3 * (a + b + 1) := by omega
theorem Valid'.node4L {l} {x : α} {m} {y : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hm : Valid' x m y)
(hr : Valid' (↑y) r o₂) (Hm : 0 < size m)
(H : size l = 0 ∧ size m = 1 ∧ size r ≤ 1 ∨
0 < size l ∧
ratio * size r ≤ size m ∧
delta * size l ≤ size m + size r ∧
3 * (size m + size r) ≤ 16 * size l + 9 ∧ size m ≤ delta * size r) :
Valid' o₁ (@node4L α l x m y r) o₂ := by
obtain - | ⟨s, ml, z, mr⟩ := m; · cases Hm
suffices
BalancedSz (size l) (size ml) ∧
BalancedSz (size mr) (size r) ∧ BalancedSz (size l + size ml + 1) (size mr + size r + 1) from
Valid'.node' (hl.node' hm.left this.1) (hm.right.node' hr this.2.1) this.2.2
rcases H with (⟨l0, m1, r0⟩ | ⟨l0, mr₁, lr₁, lr₂, mr₂⟩)
· rw [hm.2.size_eq, Nat.succ_inj, add_eq_zero] at m1
rw [l0, m1.1, m1.2]; revert r0; rcases size r with (_ | _ | _) <;>
[decide; decide; (intro r0; unfold BalancedSz delta; omega)]
· rcases Nat.eq_zero_or_pos (size r) with r0 | r0
· rw [r0] at mr₂; cases not_le_of_lt Hm mr₂
rw [hm.2.size_eq] at lr₁ lr₂ mr₁ mr₂
by_cases mm : size ml + size mr ≤ 1
· have r1 :=
le_antisymm
((mul_le_mul_left (by decide)).1 (le_trans mr₁ (Nat.succ_le_succ mm) : _ ≤ ratio * 1)) r0
rw [r1, add_assoc] at lr₁
have l1 :=
le_antisymm
((mul_le_mul_left (by decide)).1 (le_trans lr₁ (add_le_add_right mm 2) : _ ≤ delta * 1))
l0
rw [l1, r1]
revert mm; cases size ml <;> cases size mr <;> intro mm
· decide
· rw [zero_add] at mm; rcases mm with (_ | ⟨⟨⟩⟩)
decide
· rcases mm with (_ | ⟨⟨⟩⟩); decide
· rw [Nat.succ_add] at mm; rcases mm with (_ | ⟨⟨⟩⟩)
rcases hm.3.1.resolve_left mm with ⟨mm₁, mm₂⟩
rcases Nat.eq_zero_or_pos (size ml) with ml0 | ml0
· rw [ml0, mul_zero, Nat.le_zero] at mm₂
rw [ml0, mm₂] at mm; cases mm (by decide)
have : 2 * size l ≤ size ml + size mr + 1 := by
have := Nat.mul_le_mul_left ratio lr₁
rw [mul_left_comm, mul_add] at this
have := le_trans this (add_le_add_left mr₁ _)
rw [← Nat.succ_mul] at this
exact (mul_le_mul_left (by decide)).1 this
refine ⟨Or.inr ⟨?_, ?_⟩, Or.inr ⟨?_, ?_⟩, Or.inr ⟨?_, ?_⟩⟩
· refine (mul_le_mul_left (by decide)).1 (le_trans this ?_)
rw [two_mul, Nat.succ_le_iff]
refine add_lt_add_of_lt_of_le ?_ mm₂
simpa using (mul_lt_mul_right ml0).2 (by decide : 1 < 3)
· exact Nat.le_of_lt_succ (Valid'.node4L_lemma₁ lr₂ mr₂ mm₁)
· exact Valid'.node4L_lemma₂ mr₂
· exact Valid'.node4L_lemma₃ mr₁ mm₁
· exact Valid'.node4L_lemma₄ lr₁ mr₂ mm₁
· exact Valid'.node4L_lemma₅ lr₂ mr₁ mm₂
theorem Valid'.rotateL_lemma₁ {a b c : ℕ} (H2 : 3 * a ≤ b + c) (hb₂ : c ≤ 3 * b) : a ≤ 3 * b := by
omega
theorem Valid'.rotateL_lemma₂ {a b c : ℕ} (H3 : 2 * (b + c) ≤ 9 * a + 3) (h : b < 2 * c) :
b < 3 * a + 1 := by omega
theorem Valid'.rotateL_lemma₃ {a b c : ℕ} (H2 : 3 * a ≤ b + c) (h : b < 2 * c) : a + b < 3 * c := by
omega
theorem Valid'.rotateL_lemma₄ {a b : ℕ} (H3 : 2 * b ≤ 9 * a + 3) : 3 * b ≤ 16 * a + 9 := by
omega
theorem Valid'.rotateL {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H1 : ¬size l + size r ≤ 1) (H2 : delta * size l < size r)
(H3 : 2 * size r ≤ 9 * size l + 5 ∨ size r ≤ 3) : Valid' o₁ (@rotateL α l x r) o₂ := by
obtain - | ⟨rs, rl, rx, rr⟩ := r; · cases H2
rw [hr.2.size_eq, Nat.lt_succ_iff] at H2
rw [hr.2.size_eq] at H3
replace H3 : 2 * (size rl + size rr) ≤ 9 * size l + 3 ∨ size rl + size rr ≤ 2 :=
H3.imp (@Nat.le_of_add_le_add_right _ 2 _) Nat.le_of_succ_le_succ
have H3_0 : size l = 0 → size rl + size rr ≤ 2 := by
intro l0; rw [l0] at H3
exact
(or_iff_right_of_imp fun h => (mul_le_mul_left (by decide)).1 (le_trans h (by decide))).1 H3
have H3p : size l > 0 → 2 * (size rl + size rr) ≤ 9 * size l + 3 := fun l0 : 1 ≤ size l =>
(or_iff_left_of_imp <| by omega).1 H3
have ablem : ∀ {a b : ℕ}, 1 ≤ a → a + b ≤ 2 → b ≤ 1 := by omega
have hlp : size l > 0 → ¬size rl + size rr ≤ 1 := fun l0 hb =>
absurd (le_trans (le_trans (Nat.mul_le_mul_left _ l0) H2) hb) (by decide)
rw [Ordnode.rotateL_node]; split_ifs with h
· have rr0 : size rr > 0 :=
(mul_lt_mul_left (by decide)).1 (lt_of_le_of_lt (Nat.zero_le _) h : ratio * 0 < _)
suffices BalancedSz (size l) (size rl) ∧ BalancedSz (size l + size rl + 1) (size rr) by
exact hl.node3L hr.left hr.right this.1 this.2
rcases Nat.eq_zero_or_pos (size l) with l0 | l0
· rw [l0]; replace H3 := H3_0 l0
have := hr.3.1
rcases Nat.eq_zero_or_pos (size rl) with rl0 | rl0
· rw [rl0] at this ⊢
rw [le_antisymm (balancedSz_zero.1 this.symm) rr0]
decide
have rr1 : size rr = 1 := le_antisymm (ablem rl0 H3) rr0
rw [add_comm] at H3
rw [rr1, show size rl = 1 from le_antisymm (ablem rr0 H3) rl0]
decide
replace H3 := H3p l0
rcases hr.3.1.resolve_left (hlp l0) with ⟨_, hb₂⟩
refine ⟨Or.inr ⟨?_, ?_⟩, Or.inr ⟨?_, ?_⟩⟩
· exact Valid'.rotateL_lemma₁ H2 hb₂
· exact Nat.le_of_lt_succ (Valid'.rotateL_lemma₂ H3 h)
· exact Valid'.rotateL_lemma₃ H2 h
· exact
le_trans hb₂
(Nat.mul_le_mul_left _ <| le_trans (Nat.le_add_left _ _) (Nat.le_add_right _ _))
· rcases Nat.eq_zero_or_pos (size rl) with rl0 | rl0
· rw [rl0, not_lt, Nat.le_zero, Nat.mul_eq_zero] at h
replace h := h.resolve_left (by decide)
rw [rl0, h, Nat.le_zero, Nat.mul_eq_zero] at H2
rw [hr.2.size_eq, rl0, h, H2.resolve_left (by decide)] at H1
cases H1 (by decide)
refine hl.node4L hr.left hr.right rl0 ?_
rcases Nat.eq_zero_or_pos (size l) with l0 | l0
· replace H3 := H3_0 l0
rcases Nat.eq_zero_or_pos (size rr) with rr0 | rr0
· have := hr.3.1
rw [rr0] at this
exact Or.inl ⟨l0, le_antisymm (balancedSz_zero.1 this) rl0, rr0.symm ▸ zero_le_one⟩
exact Or.inl ⟨l0, le_antisymm (ablem rr0 <| by rwa [add_comm]) rl0, ablem rl0 H3⟩
exact
Or.inr ⟨l0, not_lt.1 h, H2, Valid'.rotateL_lemma₄ (H3p l0), (hr.3.1.resolve_left (hlp l0)).1⟩
theorem Valid'.rotateR {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H1 : ¬size l + size r ≤ 1) (H2 : delta * size r < size l)
(H3 : 2 * size l ≤ 9 * size r + 5 ∨ size l ≤ 3) : Valid' o₁ (@rotateR α l x r) o₂ := by
refine Valid'.dual_iff.2 ?_
rw [dual_rotateR]
refine hr.dual.rotateL hl.dual ?_ ?_ ?_
· rwa [size_dual, size_dual, add_comm]
· rwa [size_dual, size_dual]
· rwa [size_dual, size_dual]
theorem Valid'.balance'_aux {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H₁ : 2 * @size α r ≤ 9 * size l + 5 ∨ size r ≤ 3)
(H₂ : 2 * @size α l ≤ 9 * size r + 5 ∨ size l ≤ 3) : Valid' o₁ (@balance' α l x r) o₂ := by
rw [balance']; split_ifs with h h_1 h_2
· exact hl.node' hr (Or.inl h)
· exact hl.rotateL hr h h_1 H₁
· exact hl.rotateR hr h h_2 H₂
· exact hl.node' hr (Or.inr ⟨not_lt.1 h_2, not_lt.1 h_1⟩)
theorem Valid'.balance'_lemma {α l l' r r'} (H1 : BalancedSz l' r')
(H2 : Nat.dist (@size α l) l' ≤ 1 ∧ size r = r' ∨ Nat.dist (size r) r' ≤ 1 ∧ size l = l') :
2 * @size α r ≤ 9 * size l + 5 ∨ size r ≤ 3 := by
suffices @size α r ≤ 3 * (size l + 1) by omega
rcases H2 with (⟨hl, rfl⟩ | ⟨hr, rfl⟩) <;> rcases H1 with (h | ⟨_, h₂⟩)
· exact le_trans (Nat.le_add_left _ _) (le_trans h (Nat.le_add_left _ _))
· exact
le_trans h₂
(Nat.mul_le_mul_left _ <| le_trans (Nat.dist_tri_right _ _) (Nat.add_le_add_left hl _))
· exact
le_trans (Nat.dist_tri_left' _ _)
(le_trans (add_le_add hr (le_trans (Nat.le_add_left _ _) h)) (by omega))
· rw [Nat.mul_succ]
exact le_trans (Nat.dist_tri_right' _ _) (add_le_add h₂ (le_trans hr (by decide)))
theorem Valid'.balance' {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H : ∃ l' r', BalancedSz l' r' ∧
(Nat.dist (size l) l' ≤ 1 ∧ size r = r' ∨ Nat.dist (size r) r' ≤ 1 ∧ size l = l')) :
Valid' o₁ (@balance' α l x r) o₂ :=
let ⟨_, _, H1, H2⟩ := H
Valid'.balance'_aux hl hr (Valid'.balance'_lemma H1 H2) (Valid'.balance'_lemma H1.symm H2.symm)
theorem Valid'.balance {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H : ∃ l' r', BalancedSz l' r' ∧
(Nat.dist (size l) l' ≤ 1 ∧ size r = r' ∨ Nat.dist (size r) r' ≤ 1 ∧ size l = l')) :
Valid' o₁ (@balance α l x r) o₂ := by
rw [balance_eq_balance' hl.3 hr.3 hl.2 hr.2]; exact hl.balance' hr H
theorem Valid'.balanceL_aux {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H₁ : size l = 0 → size r ≤ 1) (H₂ : 1 ≤ size l → 1 ≤ size r → size r ≤ delta * size l)
(H₃ : 2 * @size α l ≤ 9 * size r + 5 ∨ size l ≤ 3) : Valid' o₁ (@balanceL α l x r) o₂ := by
rw [balanceL_eq_balance hl.2 hr.2 H₁ H₂, balance_eq_balance' hl.3 hr.3 hl.2 hr.2]
refine hl.balance'_aux hr (Or.inl ?_) H₃
rcases Nat.eq_zero_or_pos (size r) with r0 | r0
· rw [r0]; exact Nat.zero_le _
rcases Nat.eq_zero_or_pos (size l) with l0 | l0
· rw [l0]; exact le_trans (Nat.mul_le_mul_left _ (H₁ l0)) (by decide)
replace H₂ : _ ≤ 3 * _ := H₂ l0 r0; omega
theorem Valid'.balanceL {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H : (∃ l', Raised l' (size l) ∧ BalancedSz l' (size r)) ∨
∃ r', Raised (size r) r' ∧ BalancedSz (size l) r') :
Valid' o₁ (@balanceL α l x r) o₂ := by
rw [balanceL_eq_balance' hl.3 hr.3 hl.2 hr.2 H]
refine hl.balance' hr ?_
rcases H with (⟨l', e, H⟩ | ⟨r', e, H⟩)
· exact ⟨_, _, H, Or.inl ⟨e.dist_le', rfl⟩⟩
· exact ⟨_, _, H, Or.inr ⟨e.dist_le, rfl⟩⟩
theorem Valid'.balanceR_aux {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H₁ : size r = 0 → size l ≤ 1) (H₂ : 1 ≤ size r → 1 ≤ size l → size l ≤ delta * size r)
(H₃ : 2 * @size α r ≤ 9 * size l + 5 ∨ size r ≤ 3) : Valid' o₁ (@balanceR α l x r) o₂ := by
rw [Valid'.dual_iff, dual_balanceR]
have := hr.dual.balanceL_aux hl.dual
rw [size_dual, size_dual] at this
exact this H₁ H₂ H₃
theorem Valid'.balanceR {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂)
(H : (∃ l', Raised (size l) l' ∧ BalancedSz l' (size r)) ∨
∃ r', Raised r' (size r) ∧ BalancedSz (size l) r') :
Valid' o₁ (@balanceR α l x r) o₂ := by
rw [Valid'.dual_iff, dual_balanceR]; exact hr.dual.balanceL hl.dual (balance_sz_dual H)
theorem Valid'.eraseMax_aux {s l x r o₁ o₂} (H : Valid' o₁ (.node s l x r) o₂) :
Valid' o₁ (@eraseMax α (.node' l x r)) ↑(findMax' x r) ∧
size (.node' l x r) = size (eraseMax (.node' l x r)) + 1 := by
have := H.2.eq_node'; rw [this] at H; clear this
induction r generalizing l x o₁ with
| nil => exact ⟨H.left, rfl⟩
| node rs rl rx rr _ IHrr =>
have := H.2.2.2.eq_node'; rw [this] at H ⊢
rcases IHrr H.right with ⟨h, e⟩
refine ⟨Valid'.balanceL H.left h (Or.inr ⟨_, Or.inr e, H.3.1⟩), ?_⟩
rw [eraseMax, size_balanceL H.3.2.1 h.3 H.2.2.1 h.2 (Or.inr ⟨_, Or.inr e, H.3.1⟩)]
rw [size_node, e]; rfl
theorem Valid'.eraseMin_aux {s l} {x : α} {r o₁ o₂} (H : Valid' o₁ (.node s l x r) o₂) :
Valid' ↑(findMin' l x) (@eraseMin α (.node' l x r)) o₂ ∧
size (.node' l x r) = size (eraseMin (.node' l x r)) + 1 := by
have := H.dual.eraseMax_aux
rwa [← dual_node', size_dual, ← dual_eraseMin, size_dual, ← Valid'.dual_iff, findMax'_dual]
at this
theorem eraseMin.valid : ∀ {t}, @Valid α _ t → Valid (eraseMin t)
| nil, _ => valid_nil
| node _ l x r, h => by rw [h.2.eq_node']; exact h.eraseMin_aux.1.valid
theorem eraseMax.valid {t} (h : @Valid α _ t) : Valid (eraseMax t) := by
rw [Valid.dual_iff, dual_eraseMax]; exact eraseMin.valid h.dual
theorem Valid'.glue_aux {l r o₁ o₂} (hl : Valid' o₁ l o₂) (hr : Valid' o₁ r o₂)
(sep : l.All fun x => r.All fun y => x < y) (bal : BalancedSz (size l) (size r)) :
Valid' o₁ (@glue α l r) o₂ ∧ size (glue l r) = size l + size r := by
obtain - | ⟨ls, ll, lx, lr⟩ := l; · exact ⟨hr, (zero_add _).symm⟩
obtain - | ⟨rs, rl, rx, rr⟩ := r; · exact ⟨hl, rfl⟩
dsimp [glue]; split_ifs
· rw [splitMax_eq]
· obtain ⟨v, e⟩ := Valid'.eraseMax_aux hl
suffices H : _ by
refine ⟨Valid'.balanceR v (hr.of_gt ?_ ?_) H, ?_⟩
· refine findMax'_all (P := fun a : α => Bounded nil (a : WithTop α) o₂)
lx lr hl.1.2.to_nil (sep.2.2.imp ?_)
exact fun x h => hr.1.2.to_nil.mono_left (le_of_lt h.2.1)
· exact @findMax'_all _ (fun a => All (· > a) (.node rs rl rx rr)) lx lr sep.2.1 sep.2.2
· rw [size_balanceR v.3 hr.3 v.2 hr.2 H, add_right_comm, ← e, hl.2.1]; rfl
refine Or.inl ⟨_, Or.inr e, ?_⟩
rwa [hl.2.eq_node'] at bal
· rw [splitMin_eq]
· obtain ⟨v, e⟩ := Valid'.eraseMin_aux hr
suffices H : _ by
refine ⟨Valid'.balanceL (hl.of_lt ?_ ?_) v H, ?_⟩
· refine @findMin'_all (P := fun a : α => Bounded nil o₁ (a : WithBot α))
_ rl rx (sep.2.1.1.imp ?_) hr.1.1.to_nil
exact fun y h => hl.1.1.to_nil.mono_right (le_of_lt h)
· exact
@findMin'_all _ (fun a => All (· < a) (.node ls ll lx lr)) rl rx
(all_iff_forall.2 fun x hx => sep.imp fun y hy => all_iff_forall.1 hy.1 _ hx)
(sep.imp fun y hy => hy.2.1)
· rw [size_balanceL hl.3 v.3 hl.2 v.2 H, add_assoc, ← e, hr.2.1]; rfl
refine Or.inr ⟨_, Or.inr e, ?_⟩
rwa [hr.2.eq_node'] at bal
theorem Valid'.glue {l} {x : α} {r o₁ o₂} (hl : Valid' o₁ l x) (hr : Valid' x r o₂) :
BalancedSz (size l) (size r) →
Valid' o₁ (@glue α l r) o₂ ∧ size (@glue α l r) = size l + size r :=
Valid'.glue_aux (hl.trans_right hr.1) (hr.trans_left hl.1) (hl.1.to_sep hr.1)
theorem Valid'.merge_lemma {a b c : ℕ} (h₁ : 3 * a < b + c + 1) (h₂ : b ≤ 3 * c) :
2 * (a + b) ≤ 9 * c + 5 := by omega
theorem Valid'.merge_aux₁ {o₁ o₂ ls ll lx lr rs rl rx rr t}
(hl : Valid' o₁ (@Ordnode.node α ls ll lx lr) o₂) (hr : Valid' o₁ (.node rs rl rx rr) o₂)
(h : delta * ls < rs) (v : Valid' o₁ t rx) (e : size t = ls + size rl) :
Valid' o₁ (.balanceL t rx rr) o₂ ∧ size (.balanceL t rx rr) = ls + rs := by
rw [hl.2.1] at e
rw [hl.2.1, hr.2.1, delta] at h
rcases hr.3.1 with (H | ⟨hr₁, hr₂⟩); · omega
suffices H₂ : _ by
suffices H₁ : _ by
refine ⟨Valid'.balanceL_aux v hr.right H₁ H₂ ?_, ?_⟩
· rw [e]; exact Or.inl (Valid'.merge_lemma h hr₁)
· rw [balanceL_eq_balance v.2 hr.2.2.2 H₁ H₂, balance_eq_balance' v.3 hr.3.2.2 v.2 hr.2.2.2,
size_balance' v.2 hr.2.2.2, e, hl.2.1, hr.2.1]
abel
· rw [e, add_right_comm]; rintro ⟨⟩
intro _ _; rw [e]; unfold delta at hr₂ ⊢; omega
theorem Valid'.merge_aux {l r o₁ o₂} (hl : Valid' o₁ l o₂) (hr : Valid' o₁ r o₂)
(sep : l.All fun x => r.All fun y => x < y) :
Valid' o₁ (@merge α l r) o₂ ∧ size (merge l r) = size l + size r := by
induction l generalizing o₁ o₂ r with
| nil => exact ⟨hr, (zero_add _).symm⟩
| node ls ll lx lr _ IHlr => ?_
induction r generalizing o₁ o₂ with
| nil => exact ⟨hl, rfl⟩
| node rs rl rx rr IHrl _ => ?_
rw [merge_node]; split_ifs with h h_1
· obtain ⟨v, e⟩ := IHrl (hl.of_lt hr.1.1.to_nil <| sep.imp fun x h => h.2.1) hr.left
(sep.imp fun x h => h.1)
exact Valid'.merge_aux₁ hl hr h v e
· obtain ⟨v, e⟩ := IHlr hl.right (hr.of_gt hl.1.2.to_nil sep.2.1) sep.2.2
have := Valid'.merge_aux₁ hr.dual hl.dual h_1 v.dual
rw [size_dual, add_comm, size_dual, ← dual_balanceR, ← Valid'.dual_iff, size_dual,
add_comm rs] at this
exact this e
· refine Valid'.glue_aux hl hr sep (Or.inr ⟨not_lt.1 h_1, not_lt.1 h⟩)
theorem Valid.merge {l r} (hl : Valid l) (hr : Valid r)
(sep : l.All fun x => r.All fun y => x < y) : Valid (@merge α l r) :=
(Valid'.merge_aux hl hr sep).1
theorem insertWith.valid_aux [IsTotal α (· ≤ ·)] [DecidableLE α] (f : α → α) (x : α)
(hf : ∀ y, x ≤ y ∧ y ≤ x → x ≤ f y ∧ f y ≤ x) :
∀ {t o₁ o₂},
Valid' o₁ t o₂ →
Bounded nil o₁ x →
Bounded nil x o₂ →
Valid' o₁ (insertWith f x t) o₂ ∧ Raised (size t) (size (insertWith f x t))
| nil, _, _, _, bl, br => ⟨valid'_singleton bl br, Or.inr rfl⟩
| node sz l y r, o₁, o₂, h, bl, br => by
rw [insertWith, cmpLE]
split_ifs with h_1 h_2 <;> dsimp only
· rcases h with ⟨⟨lx, xr⟩, hs, hb⟩
rcases hf _ ⟨h_1, h_2⟩ with ⟨xf, fx⟩
refine
⟨⟨⟨lx.mono_right (le_trans h_2 xf), xr.mono_left (le_trans fx h_1)⟩, hs, hb⟩, Or.inl rfl⟩
· rcases insertWith.valid_aux f x hf h.left bl (lt_of_le_not_le h_1 h_2) with ⟨vl, e⟩
suffices H : _ by
refine ⟨vl.balanceL h.right H, ?_⟩
rw [size_balanceL vl.3 h.3.2.2 vl.2 h.2.2.2 H, h.2.size_eq]
exact (e.add_right _).add_right _
exact Or.inl ⟨_, e, h.3.1⟩
· have : y < x := lt_of_le_not_le ((total_of (· ≤ ·) _ _).resolve_left h_1) h_1
rcases insertWith.valid_aux f x hf h.right this br with ⟨vr, e⟩
suffices H : _ by
refine ⟨h.left.balanceR vr H, ?_⟩
| rw [size_balanceR h.3.2.1 vr.3 h.2.2.1 vr.2 H, h.2.size_eq]
exact (e.add_left _).add_right _
exact Or.inr ⟨_, e, h.3.1⟩
| Mathlib/Data/Ordmap/Ordset.lean | 508 | 510 |
/-
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.Algebra.Group.Pointwise.Set.Card
import Mathlib.MeasureTheory.Group.Action
import Mathlib.MeasureTheory.Measure.Prod
import Mathlib.Topology.Algebra.Module.Equiv
import Mathlib.Topology.ContinuousMap.CocompactMap
import Mathlib.Topology.Algebra.ContinuousMonoidHom
/-!
# Measures on Groups
We develop some properties of measures on (topological) groups
* We define properties on measures: measures that are left or right invariant w.r.t. multiplication.
* We define the measure `μ.inv : A ↦ μ(A⁻¹)` and show that it is right invariant iff
`μ` is left invariant.
* We define a class `IsHaarMeasure μ`, requiring that the measure `μ` is left-invariant, finite
on compact sets, and positive on open sets.
We also give analogues of all these notions in the additive world.
-/
noncomputable section
open scoped NNReal ENNReal Pointwise Topology
open Inv Set Function MeasureTheory.Measure Filter
variable {G H : Type*} [MeasurableSpace G] [MeasurableSpace H]
namespace MeasureTheory
section Mul
variable [Mul G] {μ : Measure G}
@[to_additive]
theorem map_mul_left_eq_self (μ : Measure G) [IsMulLeftInvariant μ] (g : G) :
map (g * ·) μ = μ :=
IsMulLeftInvariant.map_mul_left_eq_self g
@[to_additive]
theorem map_mul_right_eq_self (μ : Measure G) [IsMulRightInvariant μ] (g : G) : map (· * g) μ = μ :=
IsMulRightInvariant.map_mul_right_eq_self g
@[to_additive MeasureTheory.isAddLeftInvariant_smul]
instance isMulLeftInvariant_smul [IsMulLeftInvariant μ] (c : ℝ≥0∞) : IsMulLeftInvariant (c • μ) :=
⟨fun g => by rw [Measure.map_smul, map_mul_left_eq_self]⟩
@[to_additive MeasureTheory.isAddRightInvariant_smul]
instance isMulRightInvariant_smul [IsMulRightInvariant μ] (c : ℝ≥0∞) :
IsMulRightInvariant (c • μ) :=
⟨fun g => by rw [Measure.map_smul, map_mul_right_eq_self]⟩
@[to_additive MeasureTheory.isAddLeftInvariant_smul_nnreal]
instance isMulLeftInvariant_smul_nnreal [IsMulLeftInvariant μ] (c : ℝ≥0) :
IsMulLeftInvariant (c • μ) :=
MeasureTheory.isMulLeftInvariant_smul (c : ℝ≥0∞)
@[to_additive MeasureTheory.isAddRightInvariant_smul_nnreal]
instance isMulRightInvariant_smul_nnreal [IsMulRightInvariant μ] (c : ℝ≥0) :
IsMulRightInvariant (c • μ) :=
MeasureTheory.isMulRightInvariant_smul (c : ℝ≥0∞)
section MeasurableMul
variable [MeasurableMul G]
@[to_additive]
theorem measurePreserving_mul_left (μ : Measure G) [IsMulLeftInvariant μ] (g : G) :
MeasurePreserving (g * ·) μ μ :=
⟨measurable_const_mul g, map_mul_left_eq_self μ g⟩
@[to_additive]
theorem MeasurePreserving.mul_left (μ : Measure G) [IsMulLeftInvariant μ] (g : G) {X : Type*}
[MeasurableSpace X] {μ' : Measure X} {f : X → G} (hf : MeasurePreserving f μ' μ) :
MeasurePreserving (fun x => g * f x) μ' μ :=
(measurePreserving_mul_left μ g).comp hf
@[to_additive]
theorem measurePreserving_mul_right (μ : Measure G) [IsMulRightInvariant μ] (g : G) :
MeasurePreserving (· * g) μ μ :=
⟨measurable_mul_const g, map_mul_right_eq_self μ g⟩
@[to_additive]
theorem MeasurePreserving.mul_right (μ : Measure G) [IsMulRightInvariant μ] (g : G) {X : Type*}
[MeasurableSpace X] {μ' : Measure X} {f : X → G} (hf : MeasurePreserving f μ' μ) :
MeasurePreserving (fun x => f x * g) μ' μ :=
(measurePreserving_mul_right μ g).comp hf
@[to_additive]
instance Subgroup.smulInvariantMeasure {G α : Type*} [Group G] [MulAction G α] [MeasurableSpace α]
{μ : Measure α} [SMulInvariantMeasure G α μ] (H : Subgroup G) : SMulInvariantMeasure H α μ :=
⟨fun y s hs => by convert SMulInvariantMeasure.measure_preimage_smul (μ := μ) (y : G) hs⟩
/-- An alternative way to prove that `μ` is left invariant under multiplication. -/
@[to_additive "An alternative way to prove that `μ` is left invariant under addition."]
theorem forall_measure_preimage_mul_iff (μ : Measure G) :
(∀ (g : G) (A : Set G), MeasurableSet A → μ ((fun h => g * h) ⁻¹' A) = μ A) ↔
IsMulLeftInvariant μ := by
trans ∀ g, map (g * ·) μ = μ
· simp_rw [Measure.ext_iff]
refine forall_congr' fun g => forall_congr' fun A => forall_congr' fun hA => ?_
rw [map_apply (measurable_const_mul g) hA]
exact ⟨fun h => ⟨h⟩, fun h => h.1⟩
/-- An alternative way to prove that `μ` is right invariant under multiplication. -/
@[to_additive "An alternative way to prove that `μ` is right invariant under addition."]
theorem forall_measure_preimage_mul_right_iff (μ : Measure G) :
(∀ (g : G) (A : Set G), MeasurableSet A → μ ((fun h => h * g) ⁻¹' A) = μ A) ↔
IsMulRightInvariant μ := by
trans ∀ g, map (· * g) μ = μ
· simp_rw [Measure.ext_iff]
refine forall_congr' fun g => forall_congr' fun A => forall_congr' fun hA => ?_
rw [map_apply (measurable_mul_const g) hA]
exact ⟨fun h => ⟨h⟩, fun h => h.1⟩
@[to_additive]
instance Measure.prod.instIsMulLeftInvariant [IsMulLeftInvariant μ] [SFinite μ] {H : Type*}
[Mul H] {mH : MeasurableSpace H} {ν : Measure H} [MeasurableMul H] [IsMulLeftInvariant ν]
[SFinite ν] : IsMulLeftInvariant (μ.prod ν) := by
constructor
rintro ⟨g, h⟩
change map (Prod.map (g * ·) (h * ·)) (μ.prod ν) = μ.prod ν
rw [← map_prod_map _ _ (measurable_const_mul g) (measurable_const_mul h),
map_mul_left_eq_self μ g, map_mul_left_eq_self ν h]
@[to_additive]
instance Measure.prod.instIsMulRightInvariant [IsMulRightInvariant μ] [SFinite μ] {H : Type*}
[Mul H] {mH : MeasurableSpace H} {ν : Measure H} [MeasurableMul H] [IsMulRightInvariant ν]
[SFinite ν] : IsMulRightInvariant (μ.prod ν) := by
constructor
rintro ⟨g, h⟩
change map (Prod.map (· * g) (· * h)) (μ.prod ν) = μ.prod ν
rw [← map_prod_map _ _ (measurable_mul_const g) (measurable_mul_const h),
map_mul_right_eq_self μ g, map_mul_right_eq_self ν h]
@[to_additive]
theorem isMulLeftInvariant_map {H : Type*} [MeasurableSpace H] [Mul H] [MeasurableMul H]
[IsMulLeftInvariant μ] (f : G →ₙ* H) (hf : Measurable f) (h_surj : Surjective f) :
IsMulLeftInvariant (Measure.map f μ) := by
refine ⟨fun h => ?_⟩
rw [map_map (measurable_const_mul _) hf]
obtain ⟨g, rfl⟩ := h_surj h
conv_rhs => rw [← map_mul_left_eq_self μ g]
rw [map_map hf (measurable_const_mul _)]
congr 2
ext y
simp only [comp_apply, map_mul]
end MeasurableMul
end Mul
section Semigroup
variable [Semigroup G] [MeasurableMul G] {μ : Measure G}
/-- The image of a left invariant measure under a left action is left invariant, assuming that
the action preserves multiplication. -/
@[to_additive "The image of a left invariant measure under a left additive action is left invariant,
assuming that the action preserves addition."]
theorem isMulLeftInvariant_map_smul
{α} [SMul α G] [SMulCommClass α G G] [MeasurableSpace α] [MeasurableSMul α G]
[IsMulLeftInvariant μ] (a : α) :
IsMulLeftInvariant (map (a • · : G → G) μ) :=
(forall_measure_preimage_mul_iff _).1 fun x _ hs =>
(smulInvariantMeasure_map_smul μ a).measure_preimage_smul x hs
/-- The image of a right invariant measure under a left action is right invariant, assuming that
the action preserves multiplication. -/
@[to_additive "The image of a right invariant measure under a left additive action is right
invariant, assuming that the action preserves addition."]
theorem isMulRightInvariant_map_smul
{α} [SMul α G] [SMulCommClass α Gᵐᵒᵖ G] [MeasurableSpace α] [MeasurableSMul α G]
[IsMulRightInvariant μ] (a : α) :
IsMulRightInvariant (map (a • · : G → G) μ) :=
(forall_measure_preimage_mul_right_iff _).1 fun x _ hs =>
(smulInvariantMeasure_map_smul μ a).measure_preimage_smul (MulOpposite.op x) hs
/-- The image of a left invariant measure under right multiplication is left invariant. -/
@[to_additive isMulLeftInvariant_map_add_right
"The image of a left invariant measure under right addition is left invariant."]
instance isMulLeftInvariant_map_mul_right [IsMulLeftInvariant μ] (g : G) :
IsMulLeftInvariant (map (· * g) μ) :=
isMulLeftInvariant_map_smul (MulOpposite.op g)
/-- The image of a right invariant measure under left multiplication is right invariant. -/
@[to_additive isMulRightInvariant_map_add_left
"The image of a right invariant measure under left addition is right invariant."]
instance isMulRightInvariant_map_mul_left [IsMulRightInvariant μ] (g : G) :
IsMulRightInvariant (map (g * ·) μ) :=
isMulRightInvariant_map_smul g
end Semigroup
section DivInvMonoid
variable [DivInvMonoid G]
@[to_additive]
theorem map_div_right_eq_self (μ : Measure G) [IsMulRightInvariant μ] (g : G) :
map (· / g) μ = μ := by simp_rw [div_eq_mul_inv, map_mul_right_eq_self μ g⁻¹]
end DivInvMonoid
section Group
variable [Group G] [MeasurableMul G]
@[to_additive]
theorem measurePreserving_div_right (μ : Measure G) [IsMulRightInvariant μ] (g : G) :
MeasurePreserving (· / g) μ μ := by simp_rw [div_eq_mul_inv, measurePreserving_mul_right μ g⁻¹]
/-- We shorten this from `measure_preimage_mul_left`, since left invariant is the preferred option
for measures in this formalization. -/
@[to_additive (attr := simp)
"We shorten this from `measure_preimage_add_left`, since left invariant is the preferred option for
measures in this formalization."]
theorem measure_preimage_mul (μ : Measure G) [IsMulLeftInvariant μ] (g : G) (A : Set G) :
μ ((fun h => g * h) ⁻¹' A) = μ A :=
calc
μ ((fun h => g * h) ⁻¹' A) = map (fun h => g * h) μ A :=
((MeasurableEquiv.mulLeft g).map_apply A).symm
_ = μ A := by rw [map_mul_left_eq_self μ g]
@[to_additive (attr := simp)]
theorem measure_preimage_mul_right (μ : Measure G) [IsMulRightInvariant μ] (g : G) (A : Set G) :
μ ((fun h => h * g) ⁻¹' A) = μ A :=
calc
μ ((fun h => h * g) ⁻¹' A) = map (fun h => h * g) μ A :=
((MeasurableEquiv.mulRight g).map_apply A).symm
_ = μ A := by rw [map_mul_right_eq_self μ g]
@[to_additive]
theorem map_mul_left_ae (μ : Measure G) [IsMulLeftInvariant μ] (x : G) :
Filter.map (fun h => x * h) (ae μ) = ae μ :=
((MeasurableEquiv.mulLeft x).map_ae μ).trans <| congr_arg ae <| map_mul_left_eq_self μ x
@[to_additive]
theorem map_mul_right_ae (μ : Measure G) [IsMulRightInvariant μ] (x : G) :
Filter.map (fun h => h * x) (ae μ) = ae μ :=
((MeasurableEquiv.mulRight x).map_ae μ).trans <| congr_arg ae <| map_mul_right_eq_self μ x
@[to_additive]
theorem map_div_right_ae (μ : Measure G) [IsMulRightInvariant μ] (x : G) :
Filter.map (fun t => t / x) (ae μ) = ae μ :=
((MeasurableEquiv.divRight x).map_ae μ).trans <| congr_arg ae <| map_div_right_eq_self μ x
@[to_additive]
theorem eventually_mul_left_iff (μ : Measure G) [IsMulLeftInvariant μ] (t : G) {p : G → Prop} :
(∀ᵐ x ∂μ, p (t * x)) ↔ ∀ᵐ x ∂μ, p x := by
conv_rhs => rw [Filter.Eventually, ← map_mul_left_ae μ t]
rfl
@[to_additive]
theorem eventually_mul_right_iff (μ : Measure G) [IsMulRightInvariant μ] (t : G) {p : G → Prop} :
(∀ᵐ x ∂μ, p (x * t)) ↔ ∀ᵐ x ∂μ, p x := by
conv_rhs => rw [Filter.Eventually, ← map_mul_right_ae μ t]
rfl
@[to_additive]
theorem eventually_div_right_iff (μ : Measure G) [IsMulRightInvariant μ] (t : G) {p : G → Prop} :
(∀ᵐ x ∂μ, p (x / t)) ↔ ∀ᵐ x ∂μ, p x := by
conv_rhs => rw [Filter.Eventually, ← map_div_right_ae μ t]
rfl
end Group
namespace Measure
-- TODO: noncomputable has to be specified explicitly. https://github.com/leanprover-community/mathlib4/issues/1074 (item 8)
/-- The measure `A ↦ μ (A⁻¹)`, where `A⁻¹` is the pointwise inverse of `A`. -/
@[to_additive "The measure `A ↦ μ (- A)`, where `- A` is the pointwise negation of `A`."]
protected noncomputable def inv [Inv G] (μ : Measure G) : Measure G :=
Measure.map inv μ
/-- A measure is invariant under negation if `- μ = μ`. Equivalently, this means that for all
measurable `A` we have `μ (- A) = μ A`, where `- A` is the pointwise negation of `A`. -/
class IsNegInvariant [Neg G] (μ : Measure G) : Prop where
neg_eq_self : μ.neg = μ
/-- A measure is invariant under inversion if `μ⁻¹ = μ`. Equivalently, this means that for all
measurable `A` we have `μ (A⁻¹) = μ A`, where `A⁻¹` is the pointwise inverse of `A`. -/
@[to_additive existing]
class IsInvInvariant [Inv G] (μ : Measure G) : Prop where
inv_eq_self : μ.inv = μ
section Inv
variable [Inv G]
@[to_additive]
theorem inv_def (μ : Measure G) : μ.inv = Measure.map inv μ := rfl
@[to_additive (attr := simp)]
theorem inv_eq_self (μ : Measure G) [IsInvInvariant μ] : μ.inv = μ :=
IsInvInvariant.inv_eq_self
@[to_additive (attr := simp)]
theorem map_inv_eq_self (μ : Measure G) [IsInvInvariant μ] : map Inv.inv μ = μ :=
IsInvInvariant.inv_eq_self
variable [MeasurableInv G]
@[to_additive]
theorem measurePreserving_inv (μ : Measure G) [IsInvInvariant μ] : MeasurePreserving Inv.inv μ μ :=
⟨measurable_inv, map_inv_eq_self μ⟩
| @[to_additive]
instance inv.instSFinite (μ : Measure G) [SFinite μ] : SFinite μ.inv := by
rw [Measure.inv]; infer_instance
end Inv
| Mathlib/MeasureTheory/Group/Measure.lean | 316 | 321 |
/-
Copyright (c) 2017 Johannes Hölzl. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Johannes Hölzl, Kim Morrison
-/
import Mathlib.Algebra.Group.Indicator
import Mathlib.Algebra.Group.InjSurj
import Mathlib.Data.Set.Finite.Basic
import Mathlib.Tactic.FastInstance
import Mathlib.Algebra.Group.Equiv.Defs
/-!
# Type of functions with finite support
For any type `α` and any type `M` with zero, we define the type `Finsupp α M` (notation: `α →₀ M`)
of finitely supported functions from `α` to `M`, i.e. the functions which are zero everywhere
on `α` except on a finite set.
Functions with finite support are used (at least) in the following parts of the library:
* `MonoidAlgebra R M` and `AddMonoidAlgebra R M` are defined as `M →₀ R`;
* polynomials and multivariate polynomials are defined as `AddMonoidAlgebra`s, hence they use
`Finsupp` under the hood;
* the linear combination of a family of vectors `v i` with coefficients `f i` (as used, e.g., to
define linearly independent family `LinearIndependent`) is defined as a map
`Finsupp.linearCombination : (ι → M) → (ι →₀ R) →ₗ[R] M`.
Some other constructions are naturally equivalent to `α →₀ M` with some `α` and `M` but are defined
in a different way in the library:
* `Multiset α ≃+ α →₀ ℕ`;
* `FreeAbelianGroup α ≃+ α →₀ ℤ`.
Most of the theory assumes that the range is a commutative additive monoid. This gives us the big
sum operator as a powerful way to construct `Finsupp` elements, which is defined in
`Mathlib.Algebra.BigOperators.Finsupp.Basic`.
Many constructions based on `α →₀ M` are `def`s rather than `abbrev`s to avoid reusing unwanted type
class instances. E.g., `MonoidAlgebra`, `AddMonoidAlgebra`, and types based on these two have
non-pointwise multiplication.
## Main declarations
* `Finsupp`: The type of finitely supported functions from `α` to `β`.
* `Finsupp.onFinset`: The restriction of a function to a `Finset` as a `Finsupp`.
* `Finsupp.mapRange`: Composition of a `ZeroHom` with a `Finsupp`.
* `Finsupp.embDomain`: Maps the domain of a `Finsupp` by an embedding.
* `Finsupp.zipWith`: Postcomposition of two `Finsupp`s with a function `f` such that `f 0 0 = 0`.
## Notations
This file adds `α →₀ M` as a global notation for `Finsupp α M`.
We also use the following convention for `Type*` variables in this file
* `α`, `β`, `γ`: types with no additional structure that appear as the first argument to `Finsupp`
somewhere in the statement;
* `ι` : an auxiliary index type;
* `M`, `M'`, `N`, `P`: types with `Zero` or `(Add)(Comm)Monoid` structure; `M` is also used
for a (semi)module over a (semi)ring.
* `G`, `H`: groups (commutative or not, multiplicative or additive);
* `R`, `S`: (semi)rings.
## Implementation notes
This file is a `noncomputable theory` and uses classical logic throughout.
## TODO
* Expand the list of definitions and important lemmas to the module docstring.
-/
assert_not_exists CompleteLattice Submonoid
noncomputable section
open Finset Function
variable {α β γ ι M M' N P G H R S : Type*}
/-- `Finsupp α M`, denoted `α →₀ M`, is the type of functions `f : α → M` such that
`f x = 0` for all but finitely many `x`. -/
structure Finsupp (α : Type*) (M : Type*) [Zero M] where
/-- The support of a finitely supported function (aka `Finsupp`). -/
support : Finset α
/-- The underlying function of a bundled finitely supported function (aka `Finsupp`). -/
toFun : α → M
/-- The witness that the support of a `Finsupp` is indeed the exact locus where its
underlying function is nonzero. -/
mem_support_toFun : ∀ a, a ∈ support ↔ toFun a ≠ 0
@[inherit_doc]
infixr:25 " →₀ " => Finsupp
namespace Finsupp
/-! ### Basic declarations about `Finsupp` -/
section Basic
variable [Zero M]
instance instFunLike : FunLike (α →₀ M) α M :=
⟨toFun, by
rintro ⟨s, f, hf⟩ ⟨t, g, hg⟩ (rfl : f = g)
congr
ext a
exact (hf _).trans (hg _).symm⟩
@[ext]
theorem ext {f g : α →₀ M} (h : ∀ a, f a = g a) : f = g :=
DFunLike.ext _ _ h
lemma ne_iff {f g : α →₀ M} : f ≠ g ↔ ∃ a, f a ≠ g a := DFunLike.ne_iff
@[simp, norm_cast]
theorem coe_mk (f : α → M) (s : Finset α) (h : ∀ a, a ∈ s ↔ f a ≠ 0) : ⇑(⟨s, f, h⟩ : α →₀ M) = f :=
rfl
instance instZero : Zero (α →₀ M) :=
⟨⟨∅, 0, fun _ => ⟨fun h ↦ (not_mem_empty _ h).elim, fun H => (H rfl).elim⟩⟩⟩
@[simp, norm_cast] lemma coe_zero : ⇑(0 : α →₀ M) = 0 := rfl
theorem zero_apply {a : α} : (0 : α →₀ M) a = 0 :=
rfl
@[simp]
theorem support_zero : (0 : α →₀ M).support = ∅ :=
rfl
instance instInhabited : Inhabited (α →₀ M) :=
⟨0⟩
@[simp]
theorem mem_support_iff {f : α →₀ M} : ∀ {a : α}, a ∈ f.support ↔ f a ≠ 0 :=
@(f.mem_support_toFun)
@[simp, norm_cast]
theorem fun_support_eq (f : α →₀ M) : Function.support f = f.support :=
Set.ext fun _x => mem_support_iff.symm
theorem not_mem_support_iff {f : α →₀ M} {a} : a ∉ f.support ↔ f a = 0 :=
not_iff_comm.1 mem_support_iff.symm
@[simp, norm_cast]
theorem coe_eq_zero {f : α →₀ M} : (f : α → M) = 0 ↔ f = 0 := by rw [← coe_zero, DFunLike.coe_fn_eq]
theorem ext_iff' {f g : α →₀ M} : f = g ↔ f.support = g.support ∧ ∀ x ∈ f.support, f x = g x :=
⟨fun h => h ▸ ⟨rfl, fun _ _ => rfl⟩, fun ⟨h₁, h₂⟩ =>
ext fun a => by
classical
exact if h : a ∈ f.support then h₂ a h else by
have hf : f a = 0 := not_mem_support_iff.1 h
have hg : g a = 0 := by rwa [h₁, not_mem_support_iff] at h
rw [hf, hg]⟩
@[simp]
theorem support_eq_empty {f : α →₀ M} : f.support = ∅ ↔ f = 0 :=
mod_cast @Function.support_eq_empty_iff _ _ _ f
theorem support_nonempty_iff {f : α →₀ M} : f.support.Nonempty ↔ f ≠ 0 := by
simp only [Finsupp.support_eq_empty, Finset.nonempty_iff_ne_empty, Ne]
theorem card_support_eq_zero {f : α →₀ M} : #f.support = 0 ↔ f = 0 := by simp
instance instDecidableEq [DecidableEq α] [DecidableEq M] : DecidableEq (α →₀ M) := fun f g =>
decidable_of_iff (f.support = g.support ∧ ∀ a ∈ f.support, f a = g a) ext_iff'.symm
theorem finite_support (f : α →₀ M) : Set.Finite (Function.support f) :=
f.fun_support_eq.symm ▸ f.support.finite_toSet
theorem support_subset_iff {s : Set α} {f : α →₀ M} :
↑f.support ⊆ s ↔ ∀ a ∉ s, f a = 0 := by
simp only [Set.subset_def, mem_coe, mem_support_iff]; exact forall_congr' fun a => not_imp_comm
/-- Given `Finite α`, `equivFunOnFinite` is the `Equiv` between `α →₀ β` and `α → β`.
(All functions on a finite type are finitely supported.) -/
@[simps]
def equivFunOnFinite [Finite α] : (α →₀ M) ≃ (α → M) where
toFun := (⇑)
invFun f := mk (Function.support f).toFinite.toFinset f fun _a => Set.Finite.mem_toFinset _
left_inv _f := ext fun _x => rfl
right_inv _f := rfl
@[simp]
theorem equivFunOnFinite_symm_coe {α} [Finite α] (f : α →₀ M) : equivFunOnFinite.symm f = f :=
equivFunOnFinite.symm_apply_apply f
@[simp]
lemma coe_equivFunOnFinite_symm {α} [Finite α] (f : α → M) : ⇑(equivFunOnFinite.symm f) = f := rfl
/--
If `α` has a unique term, the type of finitely supported functions `α →₀ β` is equivalent to `β`.
-/
@[simps!]
noncomputable def _root_.Equiv.finsuppUnique {ι : Type*} [Unique ι] : (ι →₀ M) ≃ M :=
Finsupp.equivFunOnFinite.trans (Equiv.funUnique ι M)
@[ext]
theorem unique_ext [Unique α] {f g : α →₀ M} (h : f default = g default) : f = g :=
ext fun a => by rwa [Unique.eq_default a]
end Basic
/-! ### Declarations about `onFinset` -/
section OnFinset
variable [Zero M]
/-- `Finsupp.onFinset s f hf` is the finsupp function representing `f` restricted to the finset `s`.
The function must be `0` outside of `s`. Use this when the set needs to be filtered anyways,
otherwise a better set representation is often available. -/
def onFinset (s : Finset α) (f : α → M) (hf : ∀ a, f a ≠ 0 → a ∈ s) : α →₀ M where
support :=
haveI := Classical.decEq M
{a ∈ s | f a ≠ 0}
toFun := f
mem_support_toFun := by classical simpa
@[simp, norm_cast] lemma coe_onFinset (s : Finset α) (f : α → M) (hf) : onFinset s f hf = f := rfl
@[simp]
theorem onFinset_apply {s : Finset α} {f : α → M} {hf a} : (onFinset s f hf : α →₀ M) a = f a :=
rfl
@[simp]
theorem support_onFinset_subset {s : Finset α} {f : α → M} {hf} :
(onFinset s f hf).support ⊆ s := by
classical convert filter_subset (f · ≠ 0) s
theorem mem_support_onFinset {s : Finset α} {f : α → M} (hf : ∀ a : α, f a ≠ 0 → a ∈ s) {a : α} :
a ∈ (Finsupp.onFinset s f hf).support ↔ f a ≠ 0 := by
rw [Finsupp.mem_support_iff, Finsupp.onFinset_apply]
theorem support_onFinset [DecidableEq M] {s : Finset α} {f : α → M}
(hf : ∀ a : α, f a ≠ 0 → a ∈ s) :
(Finsupp.onFinset s f hf).support = {a ∈ s | f a ≠ 0} := by
dsimp [onFinset]; congr
end OnFinset
section OfSupportFinite
variable [Zero M]
/-- The natural `Finsupp` induced by the function `f` given that it has finite support. -/
noncomputable def ofSupportFinite (f : α → M) (hf : (Function.support f).Finite) : α →₀ M where
support := hf.toFinset
toFun := f
mem_support_toFun _ := hf.mem_toFinset
theorem ofSupportFinite_coe {f : α → M} {hf : (Function.support f).Finite} :
(ofSupportFinite f hf : α → M) = f :=
rfl
instance instCanLift : CanLift (α → M) (α →₀ M) (⇑) fun f => (Function.support f).Finite where
prf f hf := ⟨ofSupportFinite f hf, rfl⟩
end OfSupportFinite
/-! ### Declarations about `mapRange` -/
section MapRange
variable [Zero M] [Zero N] [Zero P]
/-- The composition of `f : M → N` and `g : α →₀ M` is `mapRange f hf g : α →₀ N`,
which is well-defined when `f 0 = 0`.
This preserves the structure on `f`, and exists in various bundled forms for when `f` is itself
bundled (defined in `Mathlib/Data/Finsupp/Basic.lean`):
* `Finsupp.mapRange.equiv`
* `Finsupp.mapRange.zeroHom`
* `Finsupp.mapRange.addMonoidHom`
* `Finsupp.mapRange.addEquiv`
* `Finsupp.mapRange.linearMap`
* `Finsupp.mapRange.linearEquiv`
-/
def mapRange (f : M → N) (hf : f 0 = 0) (g : α →₀ M) : α →₀ N :=
onFinset g.support (f ∘ g) fun a => by
rw [mem_support_iff, not_imp_not]; exact fun H => (congr_arg f H).trans hf
@[simp]
theorem mapRange_apply {f : M → N} {hf : f 0 = 0} {g : α →₀ M} {a : α} :
mapRange f hf g a = f (g a) :=
rfl
@[simp]
theorem mapRange_zero {f : M → N} {hf : f 0 = 0} : mapRange f hf (0 : α →₀ M) = 0 :=
ext fun _ => by simp only [hf, zero_apply, mapRange_apply]
@[simp]
theorem mapRange_id (g : α →₀ M) : mapRange id rfl g = g :=
ext fun _ => rfl
theorem mapRange_comp (f : N → P) (hf : f 0 = 0) (f₂ : M → N) (hf₂ : f₂ 0 = 0) (h : (f ∘ f₂) 0 = 0)
(g : α →₀ M) : mapRange (f ∘ f₂) h g = mapRange f hf (mapRange f₂ hf₂ g) :=
ext fun _ => rfl
@[simp]
lemma mapRange_mapRange (e₁ : N → P) (e₂ : M → N) (he₁ he₂) (f : α →₀ M) :
mapRange e₁ he₁ (mapRange e₂ he₂ f) = mapRange (e₁ ∘ e₂) (by simp [*]) f := ext fun _ ↦ rfl
theorem support_mapRange {f : M → N} {hf : f 0 = 0} {g : α →₀ M} :
(mapRange f hf g).support ⊆ g.support :=
support_onFinset_subset
theorem support_mapRange_of_injective {e : M → N} (he0 : e 0 = 0) (f : ι →₀ M)
(he : Function.Injective e) : (Finsupp.mapRange e he0 f).support = f.support := by
ext
simp only [Finsupp.mem_support_iff, Ne, Finsupp.mapRange_apply]
exact he.ne_iff' he0
lemma range_mapRange (e : M → N) (he₀ : e 0 = 0) :
Set.range (Finsupp.mapRange (α := α) e he₀) = {g | ∀ i, g i ∈ Set.range e} := by
ext g
simp only [Set.mem_range, Set.mem_setOf]
constructor
· rintro ⟨g, rfl⟩ i
simp
· intro h
classical
choose f h using h
use onFinset g.support (Set.indicator g.support f) (by aesop)
ext i
simp only [mapRange_apply, onFinset_apply, Set.indicator_apply]
split_ifs <;> simp_all
/-- `Finsupp.mapRange` of a injective function is injective. -/
lemma mapRange_injective (e : M → N) (he₀ : e 0 = 0) (he : Injective e) :
Injective (Finsupp.mapRange (α := α) e he₀) := by
intro a b h
rw [Finsupp.ext_iff] at h ⊢
simpa only [mapRange_apply, he.eq_iff] using h
/-- `Finsupp.mapRange` of a surjective function is surjective. -/
lemma mapRange_surjective (e : M → N) (he₀ : e 0 = 0) (he : Surjective e) :
Surjective (Finsupp.mapRange (α := α) e he₀) := by
rw [← Set.range_eq_univ, range_mapRange, he.range_eq]
simp
end MapRange
/-! ### Declarations about `embDomain` -/
section EmbDomain
variable [Zero M] [Zero N]
/-- Given `f : α ↪ β` and `v : α →₀ M`, `Finsupp.embDomain f v : β →₀ M`
is the finitely supported function whose value at `f a : β` is `v a`.
For a `b : β` outside the range of `f`, it is zero. -/
def embDomain (f : α ↪ β) (v : α →₀ M) : β →₀ M where
support := v.support.map f
toFun a₂ :=
haveI := Classical.decEq β
if h : a₂ ∈ v.support.map f then
v
(v.support.choose (fun a₁ => f a₁ = a₂)
(by
rcases Finset.mem_map.1 h with ⟨a, ha, rfl⟩
exact ExistsUnique.intro a ⟨ha, rfl⟩ fun b ⟨_, hb⟩ => f.injective hb))
else 0
mem_support_toFun a₂ := by
dsimp
split_ifs with h
· simp only [h, true_iff, Ne]
rw [← not_mem_support_iff, not_not]
classical apply Finset.choose_mem
· simp only [h, Ne, ne_self_iff_false, not_true_eq_false]
@[simp]
theorem support_embDomain (f : α ↪ β) (v : α →₀ M) : (embDomain f v).support = v.support.map f :=
rfl
@[simp]
theorem embDomain_zero (f : α ↪ β) : (embDomain f 0 : β →₀ M) = 0 :=
rfl
@[simp]
theorem embDomain_apply (f : α ↪ β) (v : α →₀ M) (a : α) : embDomain f v (f a) = v a := by
classical
simp_rw [embDomain, coe_mk, mem_map']
split_ifs with h
· refine congr_arg (v : α → M) (f.inj' ?_)
exact Finset.choose_property (fun a₁ => f a₁ = f a) _ _
· exact (not_mem_support_iff.1 h).symm
theorem embDomain_notin_range (f : α ↪ β) (v : α →₀ M) (a : β) (h : a ∉ Set.range f) :
embDomain f v a = 0 := by
classical
refine dif_neg (mt (fun h => ?_) h)
rcases Finset.mem_map.1 h with ⟨a, _h, rfl⟩
exact Set.mem_range_self a
theorem embDomain_injective (f : α ↪ β) : Function.Injective (embDomain f : (α →₀ M) → β →₀ M) :=
fun l₁ l₂ h => ext fun a => by simpa only [embDomain_apply] using DFunLike.ext_iff.1 h (f a)
@[simp]
theorem embDomain_inj {f : α ↪ β} {l₁ l₂ : α →₀ M} : embDomain f l₁ = embDomain f l₂ ↔ l₁ = l₂ :=
(embDomain_injective f).eq_iff
@[simp]
theorem embDomain_eq_zero {f : α ↪ β} {l : α →₀ M} : embDomain f l = 0 ↔ l = 0 :=
(embDomain_injective f).eq_iff' <| embDomain_zero f
theorem embDomain_mapRange (f : α ↪ β) (g : M → N) (p : α →₀ M) (hg : g 0 = 0) :
embDomain f (mapRange g hg p) = mapRange g hg (embDomain f p) := by
ext a
by_cases h : a ∈ Set.range f
· rcases h with ⟨a', rfl⟩
rw [mapRange_apply, embDomain_apply, embDomain_apply, mapRange_apply]
· rw [mapRange_apply, embDomain_notin_range, embDomain_notin_range, ← hg] <;> assumption
end EmbDomain
/-! ### Declarations about `zipWith` -/
section ZipWith
variable [Zero M] [Zero N] [Zero P]
/-- Given finitely supported functions `g₁ : α →₀ M` and `g₂ : α →₀ N` and function `f : M → N → P`,
`Finsupp.zipWith f hf g₁ g₂` is the finitely supported function `α →₀ P` satisfying
`zipWith f hf g₁ g₂ a = f (g₁ a) (g₂ a)`, which is well-defined when `f 0 0 = 0`. -/
def zipWith (f : M → N → P) (hf : f 0 0 = 0) (g₁ : α →₀ M) (g₂ : α →₀ N) : α →₀ P :=
onFinset
(haveI := Classical.decEq α; g₁.support ∪ g₂.support)
(fun a => f (g₁ a) (g₂ a))
fun a (H : f _ _ ≠ 0) => by
classical
rw [mem_union, mem_support_iff, mem_support_iff, ← not_and_or]
rintro ⟨h₁, h₂⟩; rw [h₁, h₂] at H; exact H hf
@[simp]
theorem zipWith_apply {f : M → N → P} {hf : f 0 0 = 0} {g₁ : α →₀ M} {g₂ : α →₀ N} {a : α} :
zipWith f hf g₁ g₂ a = f (g₁ a) (g₂ a) :=
rfl
theorem support_zipWith [D : DecidableEq α] {f : M → N → P} {hf : f 0 0 = 0} {g₁ : α →₀ M}
{g₂ : α →₀ N} : (zipWith f hf g₁ g₂).support ⊆ g₁.support ∪ g₂.support := by
convert support_onFinset_subset
end ZipWith
/-! ### Additive monoid structure on `α →₀ M` -/
section AddZeroClass
variable [AddZeroClass M]
instance instAdd : Add (α →₀ M) :=
⟨zipWith (· + ·) (add_zero 0)⟩
@[simp, norm_cast] lemma coe_add (f g : α →₀ M) : ⇑(f + g) = f + g := rfl
theorem add_apply (g₁ g₂ : α →₀ M) (a : α) : (g₁ + g₂) a = g₁ a + g₂ a :=
rfl
theorem support_add [DecidableEq α] {g₁ g₂ : α →₀ M} :
(g₁ + g₂).support ⊆ g₁.support ∪ g₂.support :=
support_zipWith
theorem support_add_eq [DecidableEq α] {g₁ g₂ : α →₀ M} (h : Disjoint g₁.support g₂.support) :
(g₁ + g₂).support = g₁.support ∪ g₂.support :=
le_antisymm support_zipWith fun a ha =>
(Finset.mem_union.1 ha).elim
(fun ha => by
have : a ∉ g₂.support := disjoint_left.1 h ha
simp only [mem_support_iff, not_not] at *; simpa only [add_apply, this, add_zero] )
fun ha => by
have : a ∉ g₁.support := disjoint_right.1 h ha
simp only [mem_support_iff, not_not] at *; simpa only [add_apply, this, zero_add]
instance instAddZeroClass : AddZeroClass (α →₀ M) :=
fast_instance% DFunLike.coe_injective.addZeroClass _ coe_zero coe_add
instance instIsLeftCancelAdd [IsLeftCancelAdd M] : IsLeftCancelAdd (α →₀ M) where
add_left_cancel _ _ _ h := ext fun x => add_left_cancel <| DFunLike.congr_fun h x
/-- When ι is finite and M is an AddMonoid,
then Finsupp.equivFunOnFinite gives an AddEquiv -/
noncomputable def addEquivFunOnFinite {ι : Type*} [Finite ι] :
(ι →₀ M) ≃+ (ι → M) where
__ := Finsupp.equivFunOnFinite
map_add' _ _ := rfl
/-- AddEquiv between (ι →₀ M) and M, when ι has a unique element -/
noncomputable def _root_.AddEquiv.finsuppUnique {ι : Type*} [Unique ι] :
(ι →₀ M) ≃+ M where
__ := Equiv.finsuppUnique
map_add' _ _ := rfl
instance instIsRightCancelAdd [IsRightCancelAdd M] : IsRightCancelAdd (α →₀ M) where
add_right_cancel _ _ _ h := ext fun x => add_right_cancel <| DFunLike.congr_fun h x
instance instIsCancelAdd [IsCancelAdd M] : IsCancelAdd (α →₀ M) where
/-- Evaluation of a function `f : α →₀ M` at a point as an additive monoid homomorphism.
See `Finsupp.lapply` in `Mathlib/LinearAlgebra/Finsupp/Defs.lean` for the stronger version as a
linear map. -/
@[simps apply]
def applyAddHom (a : α) : (α →₀ M) →+ M where
toFun g := g a
map_zero' := zero_apply
map_add' _ _ := add_apply _ _ _
/-- Coercion from a `Finsupp` to a function type is an `AddMonoidHom`. -/
@[simps]
noncomputable def coeFnAddHom : (α →₀ M) →+ α → M where
toFun := (⇑)
map_zero' := coe_zero
map_add' := coe_add
theorem mapRange_add [AddZeroClass N] {f : M → N} {hf : f 0 = 0}
(hf' : ∀ x y, f (x + y) = f x + f y) (v₁ v₂ : α →₀ M) :
mapRange f hf (v₁ + v₂) = mapRange f hf v₁ + mapRange f hf v₂ :=
ext fun _ => by simp only [hf', add_apply, mapRange_apply]
theorem mapRange_add' [AddZeroClass N] [FunLike β M N] [AddMonoidHomClass β M N]
{f : β} (v₁ v₂ : α →₀ M) :
mapRange f (map_zero f) (v₁ + v₂) = mapRange f (map_zero f) v₁ + mapRange f (map_zero f) v₂ :=
mapRange_add (map_add f) v₁ v₂
/-- Bundle `Finsupp.embDomain f` as an additive map from `α →₀ M` to `β →₀ M`. -/
@[simps]
def embDomain.addMonoidHom (f : α ↪ β) : (α →₀ M) →+ β →₀ M where
toFun v := embDomain f v
map_zero' := by simp
map_add' v w := by
ext b
by_cases h : b ∈ Set.range f
· rcases h with ⟨a, rfl⟩
simp
· simp only [Set.mem_range, not_exists, coe_add, Pi.add_apply,
embDomain_notin_range _ _ _ h, add_zero]
@[simp]
theorem embDomain_add (f : α ↪ β) (v w : α →₀ M) :
embDomain f (v + w) = embDomain f v + embDomain f w :=
(embDomain.addMonoidHom f).map_add v w
end AddZeroClass
section AddMonoid
variable [AddMonoid M]
/-- Note the general `SMul` instance for `Finsupp` doesn't apply as `ℕ` is not distributive
unless `β i`'s addition is commutative. -/
instance instNatSMul : SMul ℕ (α →₀ M) :=
⟨fun n v => v.mapRange (n • ·) (nsmul_zero _)⟩
instance instAddMonoid : AddMonoid (α →₀ M) :=
fast_instance% DFunLike.coe_injective.addMonoid _ coe_zero coe_add fun _ _ => rfl
end AddMonoid
instance instAddCommMonoid [AddCommMonoid M] : AddCommMonoid (α →₀ M) :=
fast_instance% DFunLike.coe_injective.addCommMonoid
DFunLike.coe coe_zero coe_add (fun _ _ => rfl)
instance instNeg [NegZeroClass G] : Neg (α →₀ G) :=
⟨mapRange Neg.neg neg_zero⟩
@[simp, norm_cast] lemma coe_neg [NegZeroClass G] (g : α →₀ G) : ⇑(-g) = -g := rfl
theorem neg_apply [NegZeroClass G] (g : α →₀ G) (a : α) : (-g) a = -g a :=
rfl
theorem mapRange_neg [NegZeroClass G] [NegZeroClass H] {f : G → H} {hf : f 0 = 0}
(hf' : ∀ x, f (-x) = -f x) (v : α →₀ G) : mapRange f hf (-v) = -mapRange f hf v :=
ext fun _ => by simp only [hf', neg_apply, mapRange_apply]
theorem mapRange_neg' [AddGroup G] [SubtractionMonoid H] [FunLike β G H] [AddMonoidHomClass β G H]
{f : β} (v : α →₀ G) :
mapRange f (map_zero f) (-v) = -mapRange f (map_zero f) v :=
mapRange_neg (map_neg f) v
instance instSub [SubNegZeroMonoid G] : Sub (α →₀ G) :=
⟨zipWith Sub.sub (sub_zero _)⟩
@[simp, norm_cast] lemma coe_sub [SubNegZeroMonoid G] (g₁ g₂ : α →₀ G) : ⇑(g₁ - g₂) = g₁ - g₂ := rfl
theorem sub_apply [SubNegZeroMonoid G] (g₁ g₂ : α →₀ G) (a : α) : (g₁ - g₂) a = g₁ a - g₂ a :=
rfl
theorem mapRange_sub [SubNegZeroMonoid G] [SubNegZeroMonoid H] {f : G → H} {hf : f 0 = 0}
(hf' : ∀ x y, f (x - y) = f x - f y) (v₁ v₂ : α →₀ G) :
mapRange f hf (v₁ - v₂) = mapRange f hf v₁ - mapRange f hf v₂ :=
ext fun _ => by simp only [hf', sub_apply, mapRange_apply]
theorem mapRange_sub' [AddGroup G] [SubtractionMonoid H] [FunLike β G H] [AddMonoidHomClass β G H]
{f : β} (v₁ v₂ : α →₀ G) :
mapRange f (map_zero f) (v₁ - v₂) = mapRange f (map_zero f) v₁ - mapRange f (map_zero f) v₂ :=
mapRange_sub (map_sub f) v₁ v₂
/-- Note the general `SMul` instance for `Finsupp` doesn't apply as `ℤ` is not distributive
unless `β i`'s addition is commutative. -/
instance instIntSMul [AddGroup G] : SMul ℤ (α →₀ G) :=
⟨fun n v => v.mapRange (n • ·) (zsmul_zero _)⟩
instance instAddGroup [AddGroup G] : AddGroup (α →₀ G) :=
fast_instance% DFunLike.coe_injective.addGroup DFunLike.coe coe_zero coe_add coe_neg coe_sub
(fun _ _ => rfl) fun _ _ => rfl
instance instAddCommGroup [AddCommGroup G] : AddCommGroup (α →₀ G) :=
fast_instance% DFunLike.coe_injective.addCommGroup DFunLike.coe coe_zero coe_add coe_neg coe_sub
(fun _ _ => rfl) fun _ _ => rfl
@[simp]
theorem support_neg [AddGroup G] (f : α →₀ G) : support (-f) = support f :=
Finset.Subset.antisymm support_mapRange
(calc
support f = support (- -f) := congr_arg support (neg_neg _).symm
_ ⊆ support (-f) := support_mapRange
)
theorem support_sub [DecidableEq α] [AddGroup G] {f g : α →₀ G} :
support (f - g) ⊆ support f ∪ support g := by
rw [sub_eq_add_neg, ← support_neg g]
exact support_add
end Finsupp
| Mathlib/Data/Finsupp/Defs.lean | 914 | 920 | |
/-
Copyright (c) 2023 Jason Yuen. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jason Yuen
-/
import Mathlib.Data.Real.ConjExponents
import Mathlib.Data.Real.Irrational
/-!
# Rayleigh's theorem on Beatty sequences
This file proves Rayleigh's theorem on Beatty sequences. We start by proving `compl_beattySeq`,
which is a generalization of Rayleigh's theorem, and eventually prove
`Irrational.beattySeq_symmDiff_beattySeq_pos`, which is Rayleigh's theorem.
## Main definitions
* `beattySeq`: In the Beatty sequence for real number `r`, the `k`th term is `⌊k * r⌋`.
* `beattySeq'`: In this variant of the Beatty sequence for `r`, the `k`th term is `⌈k * r⌉ - 1`.
## Main statements
Define the following Beatty sets, where `r` denotes a real number:
* `B_r := {⌊k * r⌋ | k ∈ ℤ}`
* `B'_r := {⌈k * r⌉ - 1 | k ∈ ℤ}`
* `B⁺_r := {⌊r⌋, ⌊2r⌋, ⌊3r⌋, ...}`
* `B⁺'_r := {⌈r⌉-1, ⌈2r⌉-1, ⌈3r⌉-1, ...}`
The main statements are:
* `compl_beattySeq`: Let `r` be a real number greater than 1, and `1/r + 1/s = 1`.
Then the complement of `B_r` is `B'_s`.
* `beattySeq_symmDiff_beattySeq'_pos`: Let `r` be a real number greater than 1, and `1/r + 1/s = 1`.
Then `B⁺_r` and `B⁺'_s` partition the positive integers.
* `Irrational.beattySeq_symmDiff_beattySeq_pos`: Let `r` be an irrational number greater than 1, and
`1/r + 1/s = 1`. Then `B⁺_r` and `B⁺_s` partition the positive integers.
## References
* [Wikipedia, *Beatty sequence*](https://en.wikipedia.org/wiki/Beatty_sequence)
## Tags
beatty, sequence, rayleigh, irrational, floor, positive
-/
/-- In the Beatty sequence for real number `r`, the `k`th term is `⌊k * r⌋`. -/
noncomputable def beattySeq (r : ℝ) : ℤ → ℤ :=
fun k ↦ ⌊k * r⌋
/-- In this variant of the Beatty sequence for `r`, the `k`th term is `⌈k * r⌉ - 1`. -/
noncomputable def beattySeq' (r : ℝ) : ℤ → ℤ :=
fun k ↦ ⌈k * r⌉ - 1
namespace Beatty
variable {r s : ℝ} {j : ℤ}
/-- Let `r > 1` and `1/r + 1/s = 1`. Then `B_r` and `B'_s` are disjoint (i.e. no collision exists).
-/
private theorem no_collision (hrs : r.HolderConjugate s) :
Disjoint {beattySeq r k | k} {beattySeq' s k | k} := by
rw [Set.disjoint_left]
intro j ⟨k, h₁⟩ ⟨m, h₂⟩
rw [beattySeq, Int.floor_eq_iff, ← div_le_iff₀ hrs.pos, ← lt_div_iff₀ hrs.pos] at h₁
rw [beattySeq', sub_eq_iff_eq_add, Int.ceil_eq_iff, Int.cast_add, Int.cast_one,
add_sub_cancel_right, ← div_lt_iff₀ hrs.symm.pos, ← le_div_iff₀ hrs.symm.pos] at h₂
have h₃ := add_lt_add_of_le_of_lt h₁.1 h₂.1
have h₄ := add_lt_add_of_lt_of_le h₁.2 h₂.2
simp_rw [div_eq_inv_mul, ← right_distrib, hrs.inv_add_inv_eq_one, one_mul] at h₃ h₄
rw [← Int.cast_one] at h₄
simp_rw [← Int.cast_add, Int.cast_lt, Int.lt_add_one_iff] at h₃ h₄
exact h₄.not_lt h₃
/-- Let `r > 1` and `1/r + 1/s = 1`. Suppose there is an integer `j` where `B_r` and `B'_s` both
jump over `j` (i.e. an anti-collision). Then this leads to a contradiction. -/
private theorem no_anticollision (hrs : r.HolderConjugate s) :
¬∃ j k m : ℤ, k < j / r ∧ (j + 1) / r ≤ k + 1 ∧ m ≤ j / s ∧ (j + 1) / s < m + 1 := by
intro ⟨j, k, m, h₁₁, h₁₂, h₂₁, h₂₂⟩
have h₃ := add_lt_add_of_lt_of_le h₁₁ h₂₁
have h₄ := add_lt_add_of_le_of_lt h₁₂ h₂₂
simp_rw [div_eq_inv_mul, ← right_distrib, hrs.inv_add_inv_eq_one, one_mul] at h₃ h₄
rw [← Int.cast_one, ← add_assoc, add_lt_add_iff_right, add_right_comm] at h₄
simp_rw [← Int.cast_add, Int.cast_lt, Int.lt_add_one_iff] at h₃ h₄
exact h₄.not_lt h₃
/-- Let `0 < r ∈ ℝ` and `j ∈ ℤ`. Then either `j ∈ B_r` or `B_r` jumps over `j`. -/
private theorem hit_or_miss (h : r > 0) :
j ∈ {beattySeq r k | k} ∨ ∃ k : ℤ, k < j / r ∧ (j + 1) / r ≤ k + 1 := by
-- for both cases, the candidate is `k = ⌈(j + 1) / r⌉ - 1`
cases lt_or_ge ((⌈(j + 1) / r⌉ - 1) * r) j
· refine Or.inr ⟨⌈(j + 1) / r⌉ - 1, ?_⟩
rw [Int.cast_sub, Int.cast_one, lt_div_iff₀ h, sub_add_cancel]
exact ⟨‹_›, Int.le_ceil _⟩
· refine Or.inl ⟨⌈(j + 1) / r⌉ - 1, ?_⟩
rw [beattySeq, Int.floor_eq_iff, Int.cast_sub, Int.cast_one, ← lt_div_iff₀ h, sub_lt_iff_lt_add]
exact ⟨‹_›, Int.ceil_lt_add_one _⟩
/-- Let `0 < r ∈ ℝ` and `j ∈ ℤ`. Then either `j ∈ B'_r` or `B'_r` jumps over `j`. -/
private theorem hit_or_miss' (h : r > 0) :
j ∈ {beattySeq' r k | k} ∨ ∃ k : ℤ, k ≤ j / r ∧ (j + 1) / r < k + 1 := by
-- for both cases, the candidate is `k = ⌊(j + 1) / r⌋`
cases le_or_gt (⌊(j + 1) / r⌋ * r) j
· exact Or.inr ⟨⌊(j + 1) / r⌋, (le_div_iff₀ h).2 ‹_›, Int.lt_floor_add_one _⟩
· refine Or.inl ⟨⌊(j + 1) / r⌋, ?_⟩
rw [beattySeq', sub_eq_iff_eq_add, Int.ceil_eq_iff, Int.cast_add, Int.cast_one]
constructor
· rwa [add_sub_cancel_right]
exact sub_nonneg.1 (Int.sub_floor_div_mul_nonneg (j + 1 : ℝ) h)
end Beatty
/-- Generalization of Rayleigh's theorem on Beatty sequences. Let `r` be a real number greater
than 1, and `1/r + 1/s = 1`. Then the complement of `B_r` is `B'_s`. -/
theorem compl_beattySeq {r s : ℝ} (hrs : r.HolderConjugate s) :
{beattySeq r k | k}ᶜ = {beattySeq' s k | k} := by
ext j
by_cases h₁ : j ∈ {beattySeq r k | k} <;> by_cases h₂ : j ∈ {beattySeq' s k | k}
· exact (Set.not_disjoint_iff.2 ⟨j, h₁, h₂⟩ (Beatty.no_collision hrs)).elim
· simp only [Set.mem_compl_iff, h₁, h₂, not_true_eq_false]
· simp only [Set.mem_compl_iff, h₁, h₂, not_false_eq_true]
· have ⟨k, h₁₁, h₁₂⟩ := (Beatty.hit_or_miss hrs.pos).resolve_left h₁
have ⟨m, h₂₁, h₂₂⟩ := (Beatty.hit_or_miss' hrs.symm.pos).resolve_left h₂
exact (Beatty.no_anticollision hrs ⟨j, k, m, h₁₁, h₁₂, h₂₁, h₂₂⟩).elim
theorem compl_beattySeq' {r s : ℝ} (hrs : r.HolderConjugate s) :
{beattySeq' r k | k}ᶜ = {beattySeq s k | k} := by
rw [← compl_beattySeq hrs.symm, compl_compl]
open scoped symmDiff
/-- Generalization of Rayleigh's theorem on Beatty sequences. Let `r` be a real number greater
than 1, and `1/r + 1/s = 1`. Then `B⁺_r` and `B⁺'_s` partition the positive integers. -/
theorem beattySeq_symmDiff_beattySeq'_pos {r s : ℝ} (hrs : r.HolderConjugate s) :
{beattySeq r k | k > 0} ∆ {beattySeq' s k | k > 0} = {n | 0 < n} := by
apply Set.eq_of_subset_of_subset
· rintro j (⟨⟨k, hk, hjk⟩, -⟩ | ⟨⟨k, hk, hjk⟩, -⟩)
· rw [Set.mem_setOf_eq, ← hjk, beattySeq, Int.floor_pos]
exact one_le_mul_of_one_le_of_one_le (by norm_cast) hrs.lt.le
· rw [Set.mem_setOf_eq, ← hjk, beattySeq', sub_pos, Int.lt_ceil, Int.cast_one]
exact one_lt_mul_of_le_of_lt (by norm_cast) hrs.symm.lt
intro j (hj : 0 < j)
have hb₁ : ∀ s ≥ 0, j ∈ {beattySeq s k | k > 0} ↔ j ∈ {beattySeq s k | k} := by
intro _ hs
refine ⟨fun ⟨k, _, hk⟩ ↦ ⟨k, hk⟩, fun ⟨k, hk⟩ ↦ ⟨k, ?_, hk⟩⟩
rw [← hk, beattySeq, Int.floor_pos] at hj
exact_mod_cast pos_of_mul_pos_left (zero_lt_one.trans_le hj) hs
have hb₂ : ∀ s ≥ 0, j ∈ {beattySeq' s k | k > 0} ↔ j ∈ {beattySeq' s k | k} := by
intro _ hs
refine ⟨fun ⟨k, _, hk⟩ ↦ ⟨k, hk⟩, fun ⟨k, hk⟩ ↦ ⟨k, ?_, hk⟩⟩
rw [← hk, beattySeq', sub_pos, Int.lt_ceil, Int.cast_one] at hj
exact_mod_cast pos_of_mul_pos_left (zero_lt_one.trans hj) hs
rw [Set.mem_symmDiff, hb₁ _ hrs.nonneg, hb₂ _ hrs.symm.nonneg, ← compl_beattySeq hrs,
Set.not_mem_compl_iff, Set.mem_compl_iff, and_self, and_self]
exact or_not
theorem beattySeq'_symmDiff_beattySeq_pos {r s : ℝ} (hrs : r.HolderConjugate s) :
{beattySeq' r k | k > 0} ∆ {beattySeq s k | k > 0} = {n | 0 < n} := by
rw [symmDiff_comm, beattySeq_symmDiff_beattySeq'_pos hrs.symm]
| /-- Let `r` be an irrational number. Then `B⁺_r` and `B⁺'_r` are equal. -/
theorem Irrational.beattySeq'_pos_eq {r : ℝ} (hr : Irrational r) :
{beattySeq' r k | k > 0} = {beattySeq r k | k > 0} := by
dsimp only [beattySeq, beattySeq']
congr! 4; rename_i k; rw [and_congr_right_iff]; intro hk; congr!
rw [sub_eq_iff_eq_add, Int.ceil_eq_iff, Int.cast_add, Int.cast_one, add_sub_cancel_right]
refine ⟨(Int.floor_le _).lt_of_ne fun h ↦ ?_, (Int.lt_floor_add_one _).le⟩
| Mathlib/NumberTheory/Rayleigh.lean | 162 | 168 |
/-
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]
theorem sign_sum {ι : Type*} {s : Finset ι} {f : ι → α} (hs : s.Nonempty) (t : SignType)
(h : ∀ i ∈ s, sign (f i) = t) : sign (∑ i ∈ s, f i) = t := by
cases t
· simp_rw [zero_eq_zero, sign_eq_zero_iff] at h ⊢
exact Finset.sum_eq_zero h
· simp_rw [neg_eq_neg_one, sign_eq_neg_one_iff] at h ⊢
exact Finset.sum_neg h hs
· simp_rw [pos_eq_one, sign_eq_one_iff] at h ⊢
exact Finset.sum_pos h hs
end LinearOrderedAddCommGroup
namespace Int
theorem sign_eq_sign (n : ℤ) : Int.sign n = SignType.sign n := by
obtain (n | _) | _ := n <;> simp [sign, Int.sign_neg, negSucc_lt_zero]
end Int
open Finset Nat
section exists_signed_sum
/-!
In this section we explicitly handle universe variables,
| because Lean creates a fresh universe variable for the type whose existence is asserted.
But we want the type to live in the same universe as the input type.
-/
private theorem exists_signed_sum_aux [DecidableEq α] (s : Finset α) (f : α → ℤ) :
∃ (β : Type u) (t : Finset β) (sgn : β → SignType) (g : β → α),
(∀ b, g b ∈ s) ∧
| Mathlib/Data/Sign.lean | 479 | 485 |
/-
Copyright (c) 2019 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel
-/
import Mathlib.Analysis.Analytic.Within
import Mathlib.Analysis.Calculus.FDeriv.Analytic
import Mathlib.Analysis.Calculus.ContDiff.FTaylorSeries
/-!
# Higher differentiability
A function is `C^1` on a domain if it is differentiable there, and its derivative is continuous.
By induction, it is `C^n` if it is `C^{n-1}` and its (n-1)-th derivative is `C^1` there or,
equivalently, if it is `C^1` and its derivative is `C^{n-1}`.
It is `C^∞` if it is `C^n` for all n.
Finally, it is `C^ω` if it is analytic (as well as all its derivative, which is automatic if the
space is complete).
We formalize these notions with predicates `ContDiffWithinAt`, `ContDiffAt`, `ContDiffOn` and
`ContDiff` saying that the function is `C^n` within a set at a point, at a point, on a set
and on the whole space respectively.
To avoid the issue of choice when choosing a derivative in sets where the derivative is not
necessarily unique, `ContDiffOn` is not defined directly in terms of the
regularity of the specific choice `iteratedFDerivWithin 𝕜 n f s` inside `s`, but in terms of the
existence of a nice sequence of derivatives, expressed with a predicate
`HasFTaylorSeriesUpToOn` defined in the file `FTaylorSeries`.
We prove basic properties of these notions.
## Main definitions and results
Let `f : E → F` be a map between normed vector spaces over a nontrivially normed field `𝕜`.
* `ContDiff 𝕜 n f`: expresses that `f` is `C^n`, i.e., it admits a Taylor series up to
rank `n`.
* `ContDiffOn 𝕜 n f s`: expresses that `f` is `C^n` in `s`.
* `ContDiffAt 𝕜 n f x`: expresses that `f` is `C^n` around `x`.
* `ContDiffWithinAt 𝕜 n f s x`: expresses that `f` is `C^n` around `x` within the set `s`.
In sets of unique differentiability, `ContDiffOn 𝕜 n f s` can be expressed in terms of the
properties of `iteratedFDerivWithin 𝕜 m f s` for `m ≤ n`. In the whole space,
`ContDiff 𝕜 n f` can be expressed in terms of the properties of `iteratedFDeriv 𝕜 m f`
for `m ≤ n`.
## Implementation notes
The definitions in this file are designed to work on any field `𝕜`. They are sometimes slightly more
complicated than the naive definitions one would guess from the intuition over the real or complex
numbers, but they are designed to circumvent the lack of gluing properties and partitions of unity
in general. In the usual situations, they coincide with the usual definitions.
### Definition of `C^n` functions in domains
One could define `C^n` functions in a domain `s` by fixing an arbitrary choice of derivatives (this
is what we do with `iteratedFDerivWithin`) and requiring that all these derivatives up to `n` are
continuous. If the derivative is not unique, this could lead to strange behavior like two `C^n`
functions `f` and `g` on `s` whose sum is not `C^n`. A better definition is thus to say that a
function is `C^n` inside `s` if it admits a sequence of derivatives up to `n` inside `s`.
This definition still has the problem that a function which is locally `C^n` would not need to
be `C^n`, as different choices of sequences of derivatives around different points might possibly
not be glued together to give a globally defined sequence of derivatives. (Note that this issue
can not happen over reals, thanks to partition of unity, but the behavior over a general field is
not so clear, and we want a definition for general fields). Also, there are locality
problems for the order parameter: one could image a function which, for each `n`, has a nice
sequence of derivatives up to order `n`, but they do not coincide for varying `n` and can therefore
not be glued to give rise to an infinite sequence of derivatives. This would give a function
which is `C^n` for all `n`, but not `C^∞`. We solve this issue by putting locality conditions
in space and order in our definition of `ContDiffWithinAt` and `ContDiffOn`.
The resulting definition is slightly more complicated to work with (in fact not so much), but it
gives rise to completely satisfactory theorems.
For instance, with this definition, a real function which is `C^m` (but not better) on `(-1/m, 1/m)`
for each natural `m` is by definition `C^∞` at `0`.
There is another issue with the definition of `ContDiffWithinAt 𝕜 n f s x`. We can
require the existence and good behavior of derivatives up to order `n` on a neighborhood of `x`
within `s`. However, this does not imply continuity or differentiability within `s` of the function
at `x` when `x` does not belong to `s`. Therefore, we require such existence and good behavior on
a neighborhood of `x` within `s ∪ {x}` (which appears as `insert x s` in this file).
## Notations
We use the notation `E [×n]→L[𝕜] F` for the space of continuous multilinear maps on `E^n` with
values in `F`. This is the space in which the `n`-th derivative of a function from `E` to `F` lives.
In this file, we denote `(⊤ : ℕ∞) : WithTop ℕ∞` with `∞`, and `⊤ : WithTop ℕ∞` with `ω`. To
avoid ambiguities with the two tops, the theorems name use either `infty` or `omega`.
These notations are scoped in `ContDiff`.
## Tags
derivative, differentiability, higher derivative, `C^n`, multilinear, Taylor series, formal series
-/
noncomputable section
open Set Fin Filter Function
open scoped NNReal Topology ContDiff
universe u uE uF uG uX
variable {𝕜 : Type u} [NontriviallyNormedField 𝕜] {E : Type uE} [NormedAddCommGroup E]
[NormedSpace 𝕜 E] {F : Type uF} [NormedAddCommGroup F] [NormedSpace 𝕜 F] {G : Type uG}
[NormedAddCommGroup G] [NormedSpace 𝕜 G] {X : Type uX} [NormedAddCommGroup X] [NormedSpace 𝕜 X]
{s s₁ t u : Set E} {f f₁ : E → F} {g : F → G} {x x₀ : E} {c : F} {m n : WithTop ℕ∞}
{p : E → FormalMultilinearSeries 𝕜 E F}
/-! ### Smooth functions within a set around a point -/
variable (𝕜) in
/-- A function is continuously differentiable up to order `n` within a set `s` at a point `x` if
it admits continuous derivatives up to order `n` in a neighborhood of `x` in `s ∪ {x}`.
For `n = ∞`, we only require that this holds up to any finite order (where the neighborhood may
depend on the finite order we consider).
For `n = ω`, we require the function to be analytic within `s` at `x`. The precise definition we
give (all the derivatives should be analytic) is more involved to work around issues when the space
is not complete, but it is equivalent when the space is complete.
For instance, a real function which is `C^m` on `(-1/m, 1/m)` for each natural `m`, but not
better, is `C^∞` at `0` within `univ`.
-/
def ContDiffWithinAt (n : WithTop ℕ∞) (f : E → F) (s : Set E) (x : E) : Prop :=
match n with
| ω => ∃ u ∈ 𝓝[insert x s] x, ∃ p : E → FormalMultilinearSeries 𝕜 E F,
HasFTaylorSeriesUpToOn ω f p u ∧ ∀ i, AnalyticOn 𝕜 (fun x ↦ p x i) u
| (n : ℕ∞) => ∀ m : ℕ, m ≤ n → ∃ u ∈ 𝓝[insert x s] x,
∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn m f p u
lemma HasFTaylorSeriesUpToOn.analyticOn
(hf : HasFTaylorSeriesUpToOn ω f p s) (h : AnalyticOn 𝕜 (fun x ↦ p x 0) s) :
AnalyticOn 𝕜 f s := by
have : AnalyticOn 𝕜 (fun x ↦ (continuousMultilinearCurryFin0 𝕜 E F) (p x 0)) s :=
(LinearIsometryEquiv.analyticOnNhd _ _ ).comp_analyticOn
h (Set.mapsTo_univ _ _)
exact this.congr (fun y hy ↦ (hf.zero_eq _ hy).symm)
lemma ContDiffWithinAt.analyticOn (h : ContDiffWithinAt 𝕜 ω f s x) :
∃ u ∈ 𝓝[insert x s] x, AnalyticOn 𝕜 f u := by
obtain ⟨u, hu, p, hp, h'p⟩ := h
exact ⟨u, hu, hp.analyticOn (h'p 0)⟩
lemma ContDiffWithinAt.analyticWithinAt (h : ContDiffWithinAt 𝕜 ω f s x) :
AnalyticWithinAt 𝕜 f s x := by
obtain ⟨u, hu, hf⟩ := h.analyticOn
have xu : x ∈ u := mem_of_mem_nhdsWithin (by simp) hu
exact (hf x xu).mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert _ _) hu)
theorem contDiffWithinAt_omega_iff_analyticWithinAt [CompleteSpace F] :
ContDiffWithinAt 𝕜 ω f s x ↔ AnalyticWithinAt 𝕜 f s x := by
refine ⟨fun h ↦ h.analyticWithinAt, fun h ↦ ?_⟩
obtain ⟨u, hu, p, hp, h'p⟩ := h.exists_hasFTaylorSeriesUpToOn ω
exact ⟨u, hu, p, hp.of_le le_top, fun i ↦ h'p i⟩
theorem contDiffWithinAt_nat {n : ℕ} :
ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x,
∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn n f p u :=
⟨fun H => H n le_rfl, fun ⟨u, hu, p, hp⟩ _m hm => ⟨u, hu, p, hp.of_le (mod_cast hm)⟩⟩
/-- When `n` is either a natural number or `ω`, one can characterize the property of being `C^n`
as the existence of a neighborhood on which there is a Taylor series up to order `n`,
requiring in addition that its terms are analytic in the `ω` case. -/
lemma contDiffWithinAt_iff_of_ne_infty (hn : n ≠ ∞) :
ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x,
∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn n f p u ∧
(n = ω → ∀ i, AnalyticOn 𝕜 (fun x ↦ p x i) u) := by
match n with
| ω => simp [ContDiffWithinAt]
| ∞ => simp at hn
| (n : ℕ) => simp [contDiffWithinAt_nat]
theorem ContDiffWithinAt.of_le (h : ContDiffWithinAt 𝕜 n f s x) (hmn : m ≤ n) :
ContDiffWithinAt 𝕜 m f s x := by
match n with
| ω => match m with
| ω => exact h
| (m : ℕ∞) =>
intro k _
obtain ⟨u, hu, p, hp, -⟩ := h
exact ⟨u, hu, p, hp.of_le le_top⟩
| (n : ℕ∞) => match m with
| ω => simp at hmn
| (m : ℕ∞) => exact fun k hk ↦ h k (le_trans hk (mod_cast hmn))
/-- In a complete space, a function which is analytic within a set at a point is also `C^ω` there.
Note that the same statement for `AnalyticOn` does not require completeness, see
`AnalyticOn.contDiffOn`. -/
theorem AnalyticWithinAt.contDiffWithinAt [CompleteSpace F] (h : AnalyticWithinAt 𝕜 f s x) :
ContDiffWithinAt 𝕜 n f s x :=
(contDiffWithinAt_omega_iff_analyticWithinAt.2 h).of_le le_top
theorem contDiffWithinAt_iff_forall_nat_le {n : ℕ∞} :
ContDiffWithinAt 𝕜 n f s x ↔ ∀ m : ℕ, ↑m ≤ n → ContDiffWithinAt 𝕜 m f s x :=
⟨fun H _ hm => H.of_le (mod_cast hm), fun H m hm => H m hm _ le_rfl⟩
theorem contDiffWithinAt_infty :
ContDiffWithinAt 𝕜 ∞ f s x ↔ ∀ n : ℕ, ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_iff_forall_nat_le.trans <| by simp only [forall_prop_of_true, le_top]
@[deprecated (since := "2024-11-25")] alias contDiffWithinAt_top := contDiffWithinAt_infty
theorem ContDiffWithinAt.continuousWithinAt (h : ContDiffWithinAt 𝕜 n f s x) :
ContinuousWithinAt f s x := by
have := h.of_le (zero_le _)
simp only [ContDiffWithinAt, nonpos_iff_eq_zero, Nat.cast_eq_zero,
mem_pure, forall_eq, CharP.cast_eq_zero] at this
rcases this with ⟨u, hu, p, H⟩
rw [mem_nhdsWithin_insert] at hu
exact (H.continuousOn.continuousWithinAt hu.1).mono_of_mem_nhdsWithin hu.2
theorem ContDiffWithinAt.congr_of_eventuallyEq (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s x := by
match n with
| ω =>
obtain ⟨u, hu, p, H, H'⟩ := h
exact ⟨{x ∈ u | f₁ x = f x}, Filter.inter_mem hu (mem_nhdsWithin_insert.2 ⟨hx, h₁⟩), p,
(H.mono (sep_subset _ _)).congr fun _ ↦ And.right,
fun i ↦ (H' i).mono (sep_subset _ _)⟩
| (n : ℕ∞) =>
intro m hm
let ⟨u, hu, p, H⟩ := h m hm
exact ⟨{ x ∈ u | f₁ x = f x }, Filter.inter_mem hu (mem_nhdsWithin_insert.2 ⟨hx, h₁⟩), p,
(H.mono (sep_subset _ _)).congr fun _ ↦ And.right⟩
theorem Filter.EventuallyEq.congr_contDiffWithinAt (h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : f₁ x = f x) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun H ↦ H.congr_of_eventuallyEq h₁.symm hx.symm, fun H ↦ H.congr_of_eventuallyEq h₁ hx⟩
theorem ContDiffWithinAt.congr_of_eventuallyEq_insert (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : f₁ =ᶠ[𝓝[insert x s] x] f) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr_of_eventuallyEq (nhdsWithin_mono x (subset_insert x s) h₁)
(mem_of_mem_nhdsWithin (mem_insert x s) h₁ :)
theorem Filter.EventuallyEq.congr_contDiffWithinAt_of_insert (h₁ : f₁ =ᶠ[𝓝[insert x s] x] f) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun H ↦ H.congr_of_eventuallyEq_insert h₁.symm, fun H ↦ H.congr_of_eventuallyEq_insert h₁⟩
theorem ContDiffWithinAt.congr_of_eventuallyEq_of_mem (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : x ∈ s) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr_of_eventuallyEq h₁ <| h₁.self_of_nhdsWithin hx
theorem Filter.EventuallyEq.congr_contDiffWithinAt_of_mem (h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : x ∈ s):
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun H ↦ H.congr_of_eventuallyEq_of_mem h₁.symm hx, fun H ↦ H.congr_of_eventuallyEq_of_mem h₁ hx⟩
theorem ContDiffWithinAt.congr (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : ∀ y ∈ s, f₁ y = f y)
(hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr_of_eventuallyEq (Filter.eventuallyEq_of_mem self_mem_nhdsWithin h₁) hx
theorem contDiffWithinAt_congr (h₁ : ∀ y ∈ s, f₁ y = f y) (hx : f₁ x = f x) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun h' ↦ h'.congr (fun x hx ↦ (h₁ x hx).symm) hx.symm, fun h' ↦ h'.congr h₁ hx⟩
theorem ContDiffWithinAt.congr_of_mem (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : ∀ y ∈ s, f₁ y = f y)
(hx : x ∈ s) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr h₁ (h₁ _ hx)
theorem contDiffWithinAt_congr_of_mem (h₁ : ∀ y ∈ s, f₁ y = f y) (hx : x ∈ s) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_congr h₁ (h₁ x hx)
theorem ContDiffWithinAt.congr_of_insert (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : ∀ y ∈ insert x s, f₁ y = f y) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr (fun y hy ↦ h₁ y (mem_insert_of_mem _ hy)) (h₁ x (mem_insert _ _))
theorem contDiffWithinAt_congr_of_insert (h₁ : ∀ y ∈ insert x s, f₁ y = f y) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_congr (fun y hy ↦ h₁ y (mem_insert_of_mem _ hy)) (h₁ x (mem_insert _ _))
theorem ContDiffWithinAt.mono_of_mem_nhdsWithin (h : ContDiffWithinAt 𝕜 n f s x) {t : Set E}
(hst : s ∈ 𝓝[t] x) : ContDiffWithinAt 𝕜 n f t x := by
match n with
| ω =>
obtain ⟨u, hu, p, H, H'⟩ := h
exact ⟨u, nhdsWithin_le_of_mem (insert_mem_nhdsWithin_insert hst) hu, p, H, H'⟩
| (n : ℕ∞) =>
intro m hm
rcases h m hm with ⟨u, hu, p, H⟩
exact ⟨u, nhdsWithin_le_of_mem (insert_mem_nhdsWithin_insert hst) hu, p, H⟩
@[deprecated (since := "2024-10-30")]
alias ContDiffWithinAt.mono_of_mem := ContDiffWithinAt.mono_of_mem_nhdsWithin
theorem ContDiffWithinAt.mono (h : ContDiffWithinAt 𝕜 n f s x) {t : Set E} (hst : t ⊆ s) :
ContDiffWithinAt 𝕜 n f t x :=
h.mono_of_mem_nhdsWithin <| Filter.mem_of_superset self_mem_nhdsWithin hst
theorem ContDiffWithinAt.congr_mono
(h : ContDiffWithinAt 𝕜 n f s x) (h' : EqOn f₁ f s₁) (h₁ : s₁ ⊆ s) (hx : f₁ x = f x) :
ContDiffWithinAt 𝕜 n f₁ s₁ x :=
(h.mono h₁).congr h' hx
theorem ContDiffWithinAt.congr_set (h : ContDiffWithinAt 𝕜 n f s x) {t : Set E}
(hst : s =ᶠ[𝓝 x] t) : ContDiffWithinAt 𝕜 n f t x := by
rw [← nhdsWithin_eq_iff_eventuallyEq] at hst
apply h.mono_of_mem_nhdsWithin <| hst ▸ self_mem_nhdsWithin
@[deprecated (since := "2024-10-23")]
alias ContDiffWithinAt.congr_nhds := ContDiffWithinAt.congr_set
theorem contDiffWithinAt_congr_set {t : Set E} (hst : s =ᶠ[𝓝 x] t) :
ContDiffWithinAt 𝕜 n f s x ↔ ContDiffWithinAt 𝕜 n f t x :=
⟨fun h => h.congr_set hst, fun h => h.congr_set hst.symm⟩
@[deprecated (since := "2024-10-23")]
alias contDiffWithinAt_congr_nhds := contDiffWithinAt_congr_set
theorem contDiffWithinAt_inter' (h : t ∈ 𝓝[s] x) :
ContDiffWithinAt 𝕜 n f (s ∩ t) x ↔ ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_congr_set (mem_nhdsWithin_iff_eventuallyEq.1 h).symm
theorem contDiffWithinAt_inter (h : t ∈ 𝓝 x) :
ContDiffWithinAt 𝕜 n f (s ∩ t) x ↔ ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_inter' (mem_nhdsWithin_of_mem_nhds h)
theorem contDiffWithinAt_insert_self :
ContDiffWithinAt 𝕜 n f (insert x s) x ↔ ContDiffWithinAt 𝕜 n f s x := by
match n with
| ω => simp [ContDiffWithinAt]
| (n : ℕ∞) => simp_rw [ContDiffWithinAt, insert_idem]
theorem contDiffWithinAt_insert {y : E} :
ContDiffWithinAt 𝕜 n f (insert y s) x ↔ ContDiffWithinAt 𝕜 n f s x := by
rcases eq_or_ne x y with (rfl | hx)
· exact contDiffWithinAt_insert_self
refine ⟨fun h ↦ h.mono (subset_insert _ _), fun h ↦ ?_⟩
apply h.mono_of_mem_nhdsWithin
simp [nhdsWithin_insert_of_ne hx, self_mem_nhdsWithin]
alias ⟨ContDiffWithinAt.of_insert, ContDiffWithinAt.insert'⟩ := contDiffWithinAt_insert
protected theorem ContDiffWithinAt.insert (h : ContDiffWithinAt 𝕜 n f s x) :
ContDiffWithinAt 𝕜 n f (insert x s) x :=
h.insert'
theorem contDiffWithinAt_diff_singleton {y : E} :
ContDiffWithinAt 𝕜 n f (s \ {y}) x ↔ ContDiffWithinAt 𝕜 n f s x := by
rw [← contDiffWithinAt_insert, insert_diff_singleton, contDiffWithinAt_insert]
/-- If a function is `C^n` within a set at a point, with `n ≥ 1`, then it is differentiable
within this set at this point. -/
theorem ContDiffWithinAt.differentiableWithinAt' (h : ContDiffWithinAt 𝕜 n f s x) (hn : 1 ≤ n) :
DifferentiableWithinAt 𝕜 f (insert x s) x := by
rcases contDiffWithinAt_nat.1 (h.of_le hn) with ⟨u, hu, p, H⟩
rcases mem_nhdsWithin.1 hu with ⟨t, t_open, xt, tu⟩
rw [inter_comm] at tu
exact (differentiableWithinAt_inter (IsOpen.mem_nhds t_open xt)).1 <|
((H.mono tu).differentiableOn le_rfl) x ⟨mem_insert x s, xt⟩
theorem ContDiffWithinAt.differentiableWithinAt (h : ContDiffWithinAt 𝕜 n f s x) (hn : 1 ≤ n) :
DifferentiableWithinAt 𝕜 f s x :=
(h.differentiableWithinAt' hn).mono (subset_insert x s)
/-- A function is `C^(n + 1)` on a domain iff locally, it has a derivative which is `C^n`
(and moreover the function is analytic when `n = ω`). -/
theorem contDiffWithinAt_succ_iff_hasFDerivWithinAt (hn : n ≠ ∞) :
ContDiffWithinAt 𝕜 (n + 1) f s x ↔ ∃ u ∈ 𝓝[insert x s] x, (n = ω → AnalyticOn 𝕜 f u) ∧
∃ f' : E → E →L[𝕜] F,
(∀ x ∈ u, HasFDerivWithinAt f (f' x) u x) ∧ ContDiffWithinAt 𝕜 n f' u x := by
have h'n : n + 1 ≠ ∞ := by simpa using hn
constructor
· intro h
rcases (contDiffWithinAt_iff_of_ne_infty h'n).1 h with ⟨u, hu, p, Hp, H'p⟩
refine ⟨u, hu, ?_, fun y => (continuousMultilinearCurryFin1 𝕜 E F) (p y 1),
fun y hy => Hp.hasFDerivWithinAt le_add_self hy, ?_⟩
· rintro rfl
exact Hp.analyticOn (H'p rfl 0)
apply (contDiffWithinAt_iff_of_ne_infty hn).2
refine ⟨u, ?_, fun y : E => (p y).shift, ?_⟩
· convert @self_mem_nhdsWithin _ _ x u
have : x ∈ insert x s := by simp
exact insert_eq_of_mem (mem_of_mem_nhdsWithin this hu)
· rw [hasFTaylorSeriesUpToOn_succ_iff_right] at Hp
refine ⟨Hp.2.2, ?_⟩
rintro rfl i
change AnalyticOn 𝕜
(fun x ↦ (continuousMultilinearCurryRightEquiv' 𝕜 i E F) (p x (i + 1))) u
apply (LinearIsometryEquiv.analyticOnNhd _ _).comp_analyticOn
?_ (Set.mapsTo_univ _ _)
exact H'p rfl _
· rintro ⟨u, hu, hf, f', f'_eq_deriv, Hf'⟩
rw [contDiffWithinAt_iff_of_ne_infty h'n]
rcases (contDiffWithinAt_iff_of_ne_infty hn).1 Hf' with ⟨v, hv, p', Hp', p'_an⟩
refine ⟨v ∩ u, ?_, fun x => (p' x).unshift (f x), ?_, ?_⟩
· apply Filter.inter_mem _ hu
apply nhdsWithin_le_of_mem hu
exact nhdsWithin_mono _ (subset_insert x u) hv
· rw [hasFTaylorSeriesUpToOn_succ_iff_right]
refine ⟨fun y _ => rfl, fun y hy => ?_, ?_⟩
· change
HasFDerivWithinAt (fun z => (continuousMultilinearCurryFin0 𝕜 E F).symm (f z))
(FormalMultilinearSeries.unshift (p' y) (f y) 1).curryLeft (v ∩ u) y
rw [← Function.comp_def _ f, LinearIsometryEquiv.comp_hasFDerivWithinAt_iff']
convert (f'_eq_deriv y hy.2).mono inter_subset_right
rw [← Hp'.zero_eq y hy.1]
ext z
change ((p' y 0) (init (@cons 0 (fun _ => E) z 0))) (@cons 0 (fun _ => E) z 0 (last 0)) =
((p' y 0) 0) z
congr
norm_num [eq_iff_true_of_subsingleton]
· convert (Hp'.mono inter_subset_left).congr fun x hx => Hp'.zero_eq x hx.1 using 1
· ext x y
change p' x 0 (init (@snoc 0 (fun _ : Fin 1 => E) 0 y)) y = p' x 0 0 y
rw [init_snoc]
· ext x k v y
change p' x k (init (@snoc k (fun _ : Fin k.succ => E) v y))
(@snoc k (fun _ : Fin k.succ => E) v y (last k)) = p' x k v y
rw [snoc_last, init_snoc]
· intro h i
simp only [WithTop.add_eq_top, WithTop.one_ne_top, or_false] at h
match i with
| 0 =>
simp only [FormalMultilinearSeries.unshift]
apply AnalyticOnNhd.comp_analyticOn _ ((hf h).mono inter_subset_right)
(Set.mapsTo_univ _ _)
exact LinearIsometryEquiv.analyticOnNhd _ _
| i + 1 =>
simp only [FormalMultilinearSeries.unshift, Nat.succ_eq_add_one]
apply AnalyticOnNhd.comp_analyticOn _ ((p'_an h i).mono inter_subset_left)
(Set.mapsTo_univ _ _)
exact LinearIsometryEquiv.analyticOnNhd _ _
/-- A version of `contDiffWithinAt_succ_iff_hasFDerivWithinAt` where all derivatives
are taken within the same set. -/
theorem contDiffWithinAt_succ_iff_hasFDerivWithinAt' (hn : n ≠ ∞) :
ContDiffWithinAt 𝕜 (n + 1) f s x ↔
∃ u ∈ 𝓝[insert x s] x, u ⊆ insert x s ∧ (n = ω → AnalyticOn 𝕜 f u) ∧
∃ f' : E → E →L[𝕜] F,
(∀ x ∈ u, HasFDerivWithinAt f (f' x) s x) ∧ ContDiffWithinAt 𝕜 n f' s x := by
refine ⟨fun hf => ?_, ?_⟩
· obtain ⟨u, hu, f_an, f', huf', hf'⟩ := (contDiffWithinAt_succ_iff_hasFDerivWithinAt hn).mp hf
obtain ⟨w, hw, hxw, hwu⟩ := mem_nhdsWithin.mp hu
rw [inter_comm] at hwu
refine ⟨insert x s ∩ w, inter_mem_nhdsWithin _ (hw.mem_nhds hxw), inter_subset_left, ?_, f',
fun y hy => ?_, ?_⟩
· intro h
apply (f_an h).mono hwu
· refine ((huf' y <| hwu hy).mono hwu).mono_of_mem_nhdsWithin ?_
refine mem_of_superset ?_ (inter_subset_inter_left _ (subset_insert _ _))
exact inter_mem_nhdsWithin _ (hw.mem_nhds hy.2)
· exact hf'.mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert _ _) hu)
· rw [← contDiffWithinAt_insert, contDiffWithinAt_succ_iff_hasFDerivWithinAt hn,
insert_eq_of_mem (mem_insert _ _)]
rintro ⟨u, hu, hus, f_an, f', huf', hf'⟩
exact ⟨u, hu, f_an, f', fun y hy => (huf' y hy).insert'.mono hus, hf'.insert.mono hus⟩
/-! ### Smooth functions within a set -/
variable (𝕜) in
/-- A function is continuously differentiable up to `n` on `s` if, for any point `x` in `s`, it
admits continuous derivatives up to order `n` on a neighborhood of `x` in `s`.
For `n = ∞`, we only require that this holds up to any finite order (where the neighborhood may
depend on the finite order we consider).
-/
def ContDiffOn (n : WithTop ℕ∞) (f : E → F) (s : Set E) : Prop :=
∀ x ∈ s, ContDiffWithinAt 𝕜 n f s x
theorem HasFTaylorSeriesUpToOn.contDiffOn {n : ℕ∞} {f' : E → FormalMultilinearSeries 𝕜 E F}
(hf : HasFTaylorSeriesUpToOn n f f' s) : ContDiffOn 𝕜 n f s := by
intro x hx m hm
use s
simp only [Set.insert_eq_of_mem hx, self_mem_nhdsWithin, true_and]
exact ⟨f', hf.of_le (mod_cast hm)⟩
theorem ContDiffOn.contDiffWithinAt (h : ContDiffOn 𝕜 n f s) (hx : x ∈ s) :
ContDiffWithinAt 𝕜 n f s x :=
h x hx
theorem ContDiffOn.of_le (h : ContDiffOn 𝕜 n f s) (hmn : m ≤ n) : ContDiffOn 𝕜 m f s := fun x hx =>
(h x hx).of_le hmn
theorem ContDiffWithinAt.contDiffOn' (hm : m ≤ n) (h' : m = ∞ → n = ω)
(h : ContDiffWithinAt 𝕜 n f s x) :
∃ u, IsOpen u ∧ x ∈ u ∧ ContDiffOn 𝕜 m f (insert x s ∩ u) := by
rcases eq_or_ne n ω with rfl | hn
· obtain ⟨t, ht, p, hp, h'p⟩ := h
rcases mem_nhdsWithin.1 ht with ⟨u, huo, hxu, hut⟩
rw [inter_comm] at hut
refine ⟨u, huo, hxu, ?_⟩
suffices ContDiffOn 𝕜 ω f (insert x s ∩ u) from this.of_le le_top
intro y hy
refine ⟨insert x s ∩ u, ?_, p, hp.mono hut, fun i ↦ (h'p i).mono hut⟩
simp only [insert_eq_of_mem, hy, self_mem_nhdsWithin]
· match m with
| ω => simp [hn] at hm
| ∞ => exact (hn (h' rfl)).elim
| (m : ℕ) =>
rcases contDiffWithinAt_nat.1 (h.of_le hm) with ⟨t, ht, p, hp⟩
rcases mem_nhdsWithin.1 ht with ⟨u, huo, hxu, hut⟩
rw [inter_comm] at hut
exact ⟨u, huo, hxu, (hp.mono hut).contDiffOn⟩
theorem ContDiffWithinAt.contDiffOn (hm : m ≤ n) (h' : m = ∞ → n = ω)
(h : ContDiffWithinAt 𝕜 n f s x) :
∃ u ∈ 𝓝[insert x s] x, u ⊆ insert x s ∧ ContDiffOn 𝕜 m f u := by
obtain ⟨_u, uo, xu, h⟩ := h.contDiffOn' hm h'
exact ⟨_, inter_mem_nhdsWithin _ (uo.mem_nhds xu), inter_subset_left, h⟩
theorem ContDiffOn.analyticOn (h : ContDiffOn 𝕜 ω f s) : AnalyticOn 𝕜 f s :=
fun x hx ↦ (h x hx).analyticWithinAt
/-- A function is `C^n` within a set at a point, for `n : ℕ`, if and only if it is `C^n` on
a neighborhood of this point. -/
theorem contDiffWithinAt_iff_contDiffOn_nhds (hn : n ≠ ∞) :
ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x, ContDiffOn 𝕜 n f u := by
refine ⟨fun h ↦ ?_, fun h ↦ ?_⟩
· rcases h.contDiffOn le_rfl (by simp [hn]) with ⟨u, hu, h'u⟩
exact ⟨u, hu, h'u.2⟩
· rcases h with ⟨u, u_mem, hu⟩
have : x ∈ u := mem_of_mem_nhdsWithin (mem_insert x s) u_mem
exact (hu x this).mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert x s) u_mem)
protected theorem ContDiffWithinAt.eventually (h : ContDiffWithinAt 𝕜 n f s x) (hn : n ≠ ∞) :
∀ᶠ y in 𝓝[insert x s] x, ContDiffWithinAt 𝕜 n f s y := by
rcases h.contDiffOn le_rfl (by simp [hn]) with ⟨u, hu, _, hd⟩
have : ∀ᶠ y : E in 𝓝[insert x s] x, u ∈ 𝓝[insert x s] y ∧ y ∈ u :=
(eventually_eventually_nhdsWithin.2 hu).and hu
refine this.mono fun y hy => (hd y hy.2).mono_of_mem_nhdsWithin ?_
exact nhdsWithin_mono y (subset_insert _ _) hy.1
theorem ContDiffOn.of_succ (h : ContDiffOn 𝕜 (n + 1) f s) : ContDiffOn 𝕜 n f s :=
h.of_le le_self_add
theorem ContDiffOn.one_of_succ (h : ContDiffOn 𝕜 (n + 1) f s) : ContDiffOn 𝕜 1 f s :=
h.of_le le_add_self
theorem contDiffOn_iff_forall_nat_le {n : ℕ∞} :
ContDiffOn 𝕜 n f s ↔ ∀ m : ℕ, ↑m ≤ n → ContDiffOn 𝕜 m f s :=
⟨fun H _ hm => H.of_le (mod_cast hm), fun H x hx m hm => H m hm x hx m le_rfl⟩
theorem contDiffOn_infty : ContDiffOn 𝕜 ∞ f s ↔ ∀ n : ℕ, ContDiffOn 𝕜 n f s :=
contDiffOn_iff_forall_nat_le.trans <| by simp only [le_top, forall_prop_of_true]
@[deprecated (since := "2024-11-27")] alias contDiffOn_top := contDiffOn_infty
@[deprecated (since := "2024-11-27")]
alias contDiffOn_infty_iff_contDiffOn_omega := contDiffOn_infty
theorem contDiffOn_all_iff_nat :
(∀ (n : ℕ∞), ContDiffOn 𝕜 n f s) ↔ ∀ n : ℕ, ContDiffOn 𝕜 n f s := by
refine ⟨fun H n => H n, ?_⟩
rintro H (_ | n)
exacts [contDiffOn_infty.2 H, H n]
theorem ContDiffOn.continuousOn (h : ContDiffOn 𝕜 n f s) : ContinuousOn f s := fun x hx =>
(h x hx).continuousWithinAt
theorem ContDiffOn.congr (h : ContDiffOn 𝕜 n f s) (h₁ : ∀ x ∈ s, f₁ x = f x) :
ContDiffOn 𝕜 n f₁ s := fun x hx => (h x hx).congr h₁ (h₁ x hx)
theorem contDiffOn_congr (h₁ : ∀ x ∈ s, f₁ x = f x) : ContDiffOn 𝕜 n f₁ s ↔ ContDiffOn 𝕜 n f s :=
⟨fun H => H.congr fun x hx => (h₁ x hx).symm, fun H => H.congr h₁⟩
theorem ContDiffOn.mono (h : ContDiffOn 𝕜 n f s) {t : Set E} (hst : t ⊆ s) : ContDiffOn 𝕜 n f t :=
fun x hx => (h x (hst hx)).mono hst
theorem ContDiffOn.congr_mono (hf : ContDiffOn 𝕜 n f s) (h₁ : ∀ x ∈ s₁, f₁ x = f x) (hs : s₁ ⊆ s) :
ContDiffOn 𝕜 n f₁ s₁ :=
(hf.mono hs).congr h₁
/-- If a function is `C^n` on a set with `n ≥ 1`, then it is differentiable there. -/
theorem ContDiffOn.differentiableOn (h : ContDiffOn 𝕜 n f s) (hn : 1 ≤ n) :
DifferentiableOn 𝕜 f s := fun x hx => (h x hx).differentiableWithinAt hn
/-- If a function is `C^n` around each point in a set, then it is `C^n` on the set. -/
theorem contDiffOn_of_locally_contDiffOn
(h : ∀ x ∈ s, ∃ u, IsOpen u ∧ x ∈ u ∧ ContDiffOn 𝕜 n f (s ∩ u)) : ContDiffOn 𝕜 n f s := by
intro x xs
rcases h x xs with ⟨u, u_open, xu, hu⟩
apply (contDiffWithinAt_inter _).1 (hu x ⟨xs, xu⟩)
exact IsOpen.mem_nhds u_open xu
/-- A function is `C^(n + 1)` on a domain iff locally, it has a derivative which is `C^n`. -/
theorem contDiffOn_succ_iff_hasFDerivWithinAt (hn : n ≠ ∞) :
ContDiffOn 𝕜 (n + 1) f s ↔
∀ x ∈ s, ∃ u ∈ 𝓝[insert x s] x, (n = ω → AnalyticOn 𝕜 f u) ∧ ∃ f' : E → E →L[𝕜] F,
(∀ x ∈ u, HasFDerivWithinAt f (f' x) u x) ∧ ContDiffOn 𝕜 n f' u := by
constructor
· intro h x hx
rcases (contDiffWithinAt_succ_iff_hasFDerivWithinAt hn).1 (h x hx) with
⟨u, hu, f_an, f', hf', Hf'⟩
rcases Hf'.contDiffOn le_rfl (by simp [hn]) with ⟨v, vu, v'u, hv⟩
rw [insert_eq_of_mem hx] at hu ⊢
have xu : x ∈ u := mem_of_mem_nhdsWithin hx hu
rw [insert_eq_of_mem xu] at vu v'u
exact ⟨v, nhdsWithin_le_of_mem hu vu, fun h ↦ (f_an h).mono v'u, f',
fun y hy ↦ (hf' y (v'u hy)).mono v'u, hv⟩
· intro h x hx
rw [contDiffWithinAt_succ_iff_hasFDerivWithinAt hn]
rcases h x hx with ⟨u, u_nhbd, f_an, f', hu, hf'⟩
have : x ∈ u := mem_of_mem_nhdsWithin (mem_insert _ _) u_nhbd
exact ⟨u, u_nhbd, f_an, f', hu, hf' x this⟩
/-! ### Iterated derivative within a set -/
@[simp]
theorem contDiffOn_zero : ContDiffOn 𝕜 0 f s ↔ ContinuousOn f s := by
refine ⟨fun H => H.continuousOn, fun H => fun x hx m hm ↦ ?_⟩
have : (m : WithTop ℕ∞) = 0 := le_antisymm (mod_cast hm) bot_le
rw [this]
refine ⟨insert x s, self_mem_nhdsWithin, ftaylorSeriesWithin 𝕜 f s, ?_⟩
rw [hasFTaylorSeriesUpToOn_zero_iff]
exact ⟨by rwa [insert_eq_of_mem hx], fun x _ => by simp [ftaylorSeriesWithin]⟩
theorem contDiffWithinAt_zero (hx : x ∈ s) :
ContDiffWithinAt 𝕜 0 f s x ↔ ∃ u ∈ 𝓝[s] x, ContinuousOn f (s ∩ u) := by
constructor
· intro h
obtain ⟨u, H, p, hp⟩ := h 0 le_rfl
refine ⟨u, ?_, ?_⟩
· simpa [hx] using H
· simp only [Nat.cast_zero, hasFTaylorSeriesUpToOn_zero_iff] at hp
exact hp.1.mono inter_subset_right
· rintro ⟨u, H, hu⟩
rw [← contDiffWithinAt_inter' H]
have h' : x ∈ s ∩ u := ⟨hx, mem_of_mem_nhdsWithin hx H⟩
exact (contDiffOn_zero.mpr hu).contDiffWithinAt h'
/-- When a function is `C^n` in a set `s` of unique differentiability, it admits
`ftaylorSeriesWithin 𝕜 f s` as a Taylor series up to order `n` in `s`. -/
protected theorem ContDiffOn.ftaylorSeriesWithin
(h : ContDiffOn 𝕜 n f s) (hs : UniqueDiffOn 𝕜 s) :
HasFTaylorSeriesUpToOn n f (ftaylorSeriesWithin 𝕜 f s) s := by
constructor
· intro x _
simp only [ftaylorSeriesWithin, ContinuousMultilinearMap.curry0_apply,
iteratedFDerivWithin_zero_apply]
· intro m hm x hx
have : (m + 1 : ℕ) ≤ n := ENat.add_one_natCast_le_withTop_of_lt hm
rcases (h x hx).of_le this _ le_rfl with ⟨u, hu, p, Hp⟩
rw [insert_eq_of_mem hx] at hu
rcases mem_nhdsWithin.1 hu with ⟨o, o_open, xo, ho⟩
rw [inter_comm] at ho
have : p x m.succ = ftaylorSeriesWithin 𝕜 f s x m.succ := by
change p x m.succ = iteratedFDerivWithin 𝕜 m.succ f s x
rw [← iteratedFDerivWithin_inter_open o_open xo]
exact (Hp.mono ho).eq_iteratedFDerivWithin_of_uniqueDiffOn le_rfl (hs.inter o_open) ⟨hx, xo⟩
rw [← this, ← hasFDerivWithinAt_inter (IsOpen.mem_nhds o_open xo)]
have A : ∀ y ∈ s ∩ o, p y m = ftaylorSeriesWithin 𝕜 f s y m := by
rintro y ⟨hy, yo⟩
change p y m = iteratedFDerivWithin 𝕜 m f s y
rw [← iteratedFDerivWithin_inter_open o_open yo]
exact
(Hp.mono ho).eq_iteratedFDerivWithin_of_uniqueDiffOn (mod_cast Nat.le_succ m)
(hs.inter o_open) ⟨hy, yo⟩
exact
((Hp.mono ho).fderivWithin m (mod_cast lt_add_one m) x ⟨hx, xo⟩).congr
(fun y hy => (A y hy).symm) (A x ⟨hx, xo⟩).symm
· intro m hm
apply continuousOn_of_locally_continuousOn
intro x hx
rcases (h x hx).of_le hm _ le_rfl with ⟨u, hu, p, Hp⟩
rcases mem_nhdsWithin.1 hu with ⟨o, o_open, xo, ho⟩
rw [insert_eq_of_mem hx] at ho
rw [inter_comm] at ho
refine ⟨o, o_open, xo, ?_⟩
have A : ∀ y ∈ s ∩ o, p y m = ftaylorSeriesWithin 𝕜 f s y m := by
rintro y ⟨hy, yo⟩
change p y m = iteratedFDerivWithin 𝕜 m f s y
rw [← iteratedFDerivWithin_inter_open o_open yo]
exact (Hp.mono ho).eq_iteratedFDerivWithin_of_uniqueDiffOn le_rfl (hs.inter o_open) ⟨hy, yo⟩
exact ((Hp.mono ho).cont m le_rfl).congr fun y hy => (A y hy).symm
theorem iteratedFDerivWithin_subset {n : ℕ} (st : s ⊆ t) (hs : UniqueDiffOn 𝕜 s)
(ht : UniqueDiffOn 𝕜 t) (h : ContDiffOn 𝕜 n f t) (hx : x ∈ s) :
iteratedFDerivWithin 𝕜 n f s x = iteratedFDerivWithin 𝕜 n f t x :=
(((h.ftaylorSeriesWithin ht).mono st).eq_iteratedFDerivWithin_of_uniqueDiffOn le_rfl hs hx).symm
theorem ContDiffWithinAt.eventually_hasFTaylorSeriesUpToOn {f : E → F} {s : Set E} {a : E}
(h : ContDiffWithinAt 𝕜 n f s a) (hs : UniqueDiffOn 𝕜 s) (ha : a ∈ s) {m : ℕ} (hm : m ≤ n) :
∀ᶠ t in (𝓝[s] a).smallSets, HasFTaylorSeriesUpToOn m f (ftaylorSeriesWithin 𝕜 f s) t := by
rcases h.contDiffOn' hm (by simp) with ⟨U, hUo, haU, hfU⟩
have : ∀ᶠ t in (𝓝[s] a).smallSets, t ⊆ s ∩ U := by
rw [eventually_smallSets_subset]
exact inter_mem_nhdsWithin _ <| hUo.mem_nhds haU
refine this.mono fun t ht ↦ .mono ?_ ht
rw [insert_eq_of_mem ha] at hfU
refine (hfU.ftaylorSeriesWithin (hs.inter hUo)).congr_series fun k hk x hx ↦ ?_
exact iteratedFDerivWithin_inter_open hUo hx.2
/-- On a set with unique differentiability, an analytic function is automatically `C^ω`, as its
successive derivatives are also analytic. This does not require completeness of the space. See
also `AnalyticOn.contDiffOn_of_completeSpace`. -/
theorem AnalyticOn.contDiffOn (h : AnalyticOn 𝕜 f s) (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 n f s := by
suffices ContDiffOn 𝕜 ω f s from this.of_le le_top
rcases h.exists_hasFTaylorSeriesUpToOn hs with ⟨p, hp⟩
intro x hx
refine ⟨s, ?_, p, hp⟩
rw [insert_eq_of_mem hx]
exact self_mem_nhdsWithin
/-- On a set with unique differentiability, an analytic function is automatically `C^ω`, as its
successive derivatives are also analytic. This does not require completeness of the space. See
also `AnalyticOnNhd.contDiffOn_of_completeSpace`. -/
theorem AnalyticOnNhd.contDiffOn (h : AnalyticOnNhd 𝕜 f s) (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 n f s := h.analyticOn.contDiffOn hs
/-- An analytic function is automatically `C^ω` in a complete space -/
theorem AnalyticOn.contDiffOn_of_completeSpace [CompleteSpace F] (h : AnalyticOn 𝕜 f s) :
ContDiffOn 𝕜 n f s :=
fun x hx ↦ (h x hx).contDiffWithinAt
/-- An analytic function is automatically `C^ω` in a complete space -/
theorem AnalyticOnNhd.contDiffOn_of_completeSpace [CompleteSpace F] (h : AnalyticOnNhd 𝕜 f s) :
ContDiffOn 𝕜 n f s :=
h.analyticOn.contDiffOn_of_completeSpace
theorem contDiffOn_of_continuousOn_differentiableOn {n : ℕ∞}
(Hcont : ∀ m : ℕ, m ≤ n → ContinuousOn (fun x => iteratedFDerivWithin 𝕜 m f s x) s)
(Hdiff : ∀ m : ℕ, m < n →
DifferentiableOn 𝕜 (fun x => iteratedFDerivWithin 𝕜 m f s x) s) :
ContDiffOn 𝕜 n f s := by
intro x hx m hm
rw [insert_eq_of_mem hx]
refine ⟨s, self_mem_nhdsWithin, ftaylorSeriesWithin 𝕜 f s, ?_⟩
constructor
· intro y _
simp only [ftaylorSeriesWithin, ContinuousMultilinearMap.curry0_apply,
iteratedFDerivWithin_zero_apply]
· intro k hk y hy
convert (Hdiff k (lt_of_lt_of_le (mod_cast hk) (mod_cast hm)) y hy).hasFDerivWithinAt
· intro k hk
exact Hcont k (le_trans (mod_cast hk) (mod_cast hm))
theorem contDiffOn_of_differentiableOn {n : ℕ∞}
(h : ∀ m : ℕ, m ≤ n → DifferentiableOn 𝕜 (iteratedFDerivWithin 𝕜 m f s) s) :
ContDiffOn 𝕜 n f s :=
contDiffOn_of_continuousOn_differentiableOn (fun m hm => (h m hm).continuousOn) fun m hm =>
h m (le_of_lt hm)
theorem contDiffOn_of_analyticOn_iteratedFDerivWithin
(h : ∀ m, AnalyticOn 𝕜 (iteratedFDerivWithin 𝕜 m f s) s) :
ContDiffOn 𝕜 n f s := by
suffices ContDiffOn 𝕜 ω f s from this.of_le le_top
intro x hx
refine ⟨insert x s, self_mem_nhdsWithin, ftaylorSeriesWithin 𝕜 f s, ?_, ?_⟩
· rw [insert_eq_of_mem hx]
constructor
· intro y _
simp only [ftaylorSeriesWithin, ContinuousMultilinearMap.curry0_apply,
iteratedFDerivWithin_zero_apply]
· intro k _ y hy
exact ((h k).differentiableOn y hy).hasFDerivWithinAt
· intro k _
exact (h k).continuousOn
· intro i
rw [insert_eq_of_mem hx]
exact h i
theorem contDiffOn_omega_iff_analyticOn (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 ω f s ↔ AnalyticOn 𝕜 f s :=
⟨fun h m ↦ h.analyticOn m, fun h ↦ h.contDiffOn hs⟩
theorem ContDiffOn.continuousOn_iteratedFDerivWithin {m : ℕ} (h : ContDiffOn 𝕜 n f s)
(hmn : m ≤ n) (hs : UniqueDiffOn 𝕜 s) : ContinuousOn (iteratedFDerivWithin 𝕜 m f s) s :=
((h.of_le hmn).ftaylorSeriesWithin hs).cont m le_rfl
theorem ContDiffOn.differentiableOn_iteratedFDerivWithin {m : ℕ} (h : ContDiffOn 𝕜 n f s)
(hmn : m < n) (hs : UniqueDiffOn 𝕜 s) :
DifferentiableOn 𝕜 (iteratedFDerivWithin 𝕜 m f s) s := by
intro x hx
have : (m + 1 : ℕ) ≤ n := ENat.add_one_natCast_le_withTop_of_lt hmn
apply (((h.of_le this).ftaylorSeriesWithin hs).fderivWithin m ?_ x hx).differentiableWithinAt
exact_mod_cast lt_add_one m
theorem ContDiffWithinAt.differentiableWithinAt_iteratedFDerivWithin {m : ℕ}
(h : ContDiffWithinAt 𝕜 n f s x) (hmn : m < n) (hs : UniqueDiffOn 𝕜 (insert x s)) :
DifferentiableWithinAt 𝕜 (iteratedFDerivWithin 𝕜 m f s) s x := by
have : (m + 1 : WithTop ℕ∞) ≠ ∞ := Ne.symm (ne_of_beq_false rfl)
rcases h.contDiffOn' (ENat.add_one_natCast_le_withTop_of_lt hmn) (by simp [this])
with ⟨u, uo, xu, hu⟩
set t := insert x s ∩ u
have A : t =ᶠ[𝓝[≠] x] s := by
simp only [set_eventuallyEq_iff_inf_principal, ← nhdsWithin_inter']
rw [← inter_assoc, nhdsWithin_inter_of_mem', ← diff_eq_compl_inter, insert_diff_of_mem,
diff_eq_compl_inter]
exacts [rfl, mem_nhdsWithin_of_mem_nhds (uo.mem_nhds xu)]
have B : iteratedFDerivWithin 𝕜 m f s =ᶠ[𝓝 x] iteratedFDerivWithin 𝕜 m f t :=
iteratedFDerivWithin_eventually_congr_set' _ A.symm _
have C : DifferentiableWithinAt 𝕜 (iteratedFDerivWithin 𝕜 m f t) t x :=
hu.differentiableOn_iteratedFDerivWithin (Nat.cast_lt.2 m.lt_succ_self) (hs.inter uo) x
⟨mem_insert _ _, xu⟩
rw [differentiableWithinAt_congr_set' _ A] at C
exact C.congr_of_eventuallyEq (B.filter_mono inf_le_left) B.self_of_nhds
theorem contDiffOn_iff_continuousOn_differentiableOn {n : ℕ∞} (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 n f s ↔
(∀ m : ℕ, m ≤ n → ContinuousOn (fun x => iteratedFDerivWithin 𝕜 m f s x) s) ∧
∀ m : ℕ, m < n → DifferentiableOn 𝕜 (fun x => iteratedFDerivWithin 𝕜 m f s x) s :=
⟨fun h => ⟨fun _m hm => h.continuousOn_iteratedFDerivWithin (mod_cast hm) hs,
fun _m hm => h.differentiableOn_iteratedFDerivWithin (mod_cast hm) hs⟩,
fun h => contDiffOn_of_continuousOn_differentiableOn h.1 h.2⟩
theorem contDiffOn_nat_iff_continuousOn_differentiableOn {n : ℕ} (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 n f s ↔
(∀ m : ℕ, m ≤ n → ContinuousOn (fun x => iteratedFDerivWithin 𝕜 m f s x) s) ∧
∀ m : ℕ, m < n → DifferentiableOn 𝕜 (fun x => iteratedFDerivWithin 𝕜 m f s x) s := by
rw [← WithTop.coe_natCast, contDiffOn_iff_continuousOn_differentiableOn hs]
simp
theorem contDiffOn_succ_of_fderivWithin (hf : DifferentiableOn 𝕜 f s)
(h' : n = ω → AnalyticOn 𝕜 f s)
(h : ContDiffOn 𝕜 n (fun y => fderivWithin 𝕜 f s y) s) : ContDiffOn 𝕜 (n + 1) f s := by
rcases eq_or_ne n ∞ with rfl | hn
· rw [ENat.coe_top_add_one, contDiffOn_infty]
intro m x hx
apply ContDiffWithinAt.of_le _ (show (m : WithTop ℕ∞) ≤ m + 1 from le_self_add)
rw [contDiffWithinAt_succ_iff_hasFDerivWithinAt (by simp),
insert_eq_of_mem hx]
exact ⟨s, self_mem_nhdsWithin, (by simp), fderivWithin 𝕜 f s,
fun y hy => (hf y hy).hasFDerivWithinAt, (h x hx).of_le (mod_cast le_top)⟩
· intro x hx
rw [contDiffWithinAt_succ_iff_hasFDerivWithinAt hn,
insert_eq_of_mem hx]
exact ⟨s, self_mem_nhdsWithin, h', fderivWithin 𝕜 f s,
fun y hy => (hf y hy).hasFDerivWithinAt, h x hx⟩
theorem contDiffOn_of_analyticOn_of_fderivWithin (hf : AnalyticOn 𝕜 f s)
(h : ContDiffOn 𝕜 ω (fun y ↦ fderivWithin 𝕜 f s y) s) : ContDiffOn 𝕜 n f s := by
suffices ContDiffOn 𝕜 (ω + 1) f s from this.of_le le_top
exact contDiffOn_succ_of_fderivWithin hf.differentiableOn (fun _ ↦ hf) h
/-- A function is `C^(n + 1)` on a domain with unique derivatives if and only if it is
differentiable there, and its derivative (expressed with `fderivWithin`) is `C^n`. -/
theorem contDiffOn_succ_iff_fderivWithin (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 (n + 1) f s ↔
DifferentiableOn 𝕜 f s ∧ (n = ω → AnalyticOn 𝕜 f s) ∧
ContDiffOn 𝕜 n (fderivWithin 𝕜 f s) s := by
refine ⟨fun H => ?_, fun h => contDiffOn_succ_of_fderivWithin h.1 h.2.1 h.2.2⟩
refine ⟨H.differentiableOn le_add_self, ?_, fun x hx => ?_⟩
· rintro rfl
exact H.analyticOn
have A (m : ℕ) (hm : m ≤ n) : ContDiffWithinAt 𝕜 m (fun y => fderivWithin 𝕜 f s y) s x := by
rcases (contDiffWithinAt_succ_iff_hasFDerivWithinAt (n := m) (ne_of_beq_false rfl)).1
(H.of_le (add_le_add_right hm 1) x hx) with ⟨u, hu, -, f', hff', hf'⟩
rcases mem_nhdsWithin.1 hu with ⟨o, o_open, xo, ho⟩
rw [inter_comm, insert_eq_of_mem hx] at ho
have := hf'.mono ho
rw [contDiffWithinAt_inter' (mem_nhdsWithin_of_mem_nhds (IsOpen.mem_nhds o_open xo))] at this
apply this.congr_of_eventuallyEq_of_mem _ hx
have : o ∩ s ∈ 𝓝[s] x := mem_nhdsWithin.2 ⟨o, o_open, xo, Subset.refl _⟩
rw [inter_comm] at this
refine Filter.eventuallyEq_of_mem this fun y hy => ?_
have A : fderivWithin 𝕜 f (s ∩ o) y = f' y :=
((hff' y (ho hy)).mono ho).fderivWithin (hs.inter o_open y hy)
rwa [fderivWithin_inter (o_open.mem_nhds hy.2)] at A
match n with
| ω => exact (H.analyticOn.fderivWithin hs).contDiffOn hs (n := ω) x hx
| ∞ => exact contDiffWithinAt_infty.2 (fun m ↦ A m (mod_cast le_top))
| (n : ℕ) => exact A n le_rfl
theorem contDiffOn_succ_iff_hasFDerivWithinAt_of_uniqueDiffOn (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 (n + 1) f s ↔ (n = ω → AnalyticOn 𝕜 f s) ∧
∃ f' : E → E →L[𝕜] F, ContDiffOn 𝕜 n f' s ∧ ∀ x, x ∈ s → HasFDerivWithinAt f (f' x) s x := by
rw [contDiffOn_succ_iff_fderivWithin hs]
refine ⟨fun h => ⟨h.2.1, fderivWithin 𝕜 f s, h.2.2,
fun x hx => (h.1 x hx).hasFDerivWithinAt⟩, fun ⟨f_an, h⟩ => ?_⟩
rcases h with ⟨f', h1, h2⟩
refine ⟨fun x hx => (h2 x hx).differentiableWithinAt, f_an, fun x hx => ?_⟩
exact (h1 x hx).congr_of_mem (fun y hy => (h2 y hy).fderivWithin (hs y hy)) hx
@[deprecated (since := "2024-11-27")]
alias contDiffOn_succ_iff_hasFDerivWithin := contDiffOn_succ_iff_hasFDerivWithinAt_of_uniqueDiffOn
theorem contDiffOn_infty_iff_fderivWithin (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 ∞ f s ↔ DifferentiableOn 𝕜 f s ∧ ContDiffOn 𝕜 ∞ (fderivWithin 𝕜 f s) s := by
rw [← ENat.coe_top_add_one, contDiffOn_succ_iff_fderivWithin hs]
simp
@[deprecated (since := "2024-11-27")]
alias contDiffOn_top_iff_fderivWithin := contDiffOn_infty_iff_fderivWithin
/-- A function is `C^(n + 1)` on an open domain if and only if it is
differentiable there, and its derivative (expressed with `fderiv`) is `C^n`. -/
theorem contDiffOn_succ_iff_fderiv_of_isOpen (hs : IsOpen s) :
ContDiffOn 𝕜 (n + 1) f s ↔
DifferentiableOn 𝕜 f s ∧ (n = ω → AnalyticOn 𝕜 f s) ∧
ContDiffOn 𝕜 n (fderiv 𝕜 f) s := by
rw [contDiffOn_succ_iff_fderivWithin hs.uniqueDiffOn,
contDiffOn_congr fun x hx ↦ fderivWithin_of_isOpen hs hx]
theorem contDiffOn_infty_iff_fderiv_of_isOpen (hs : IsOpen s) :
ContDiffOn 𝕜 ∞ f s ↔ DifferentiableOn 𝕜 f s ∧ ContDiffOn 𝕜 ∞ (fderiv 𝕜 f) s := by
rw [← ENat.coe_top_add_one, contDiffOn_succ_iff_fderiv_of_isOpen hs]
simp
@[deprecated (since := "2024-11-27")]
alias contDiffOn_top_iff_fderiv_of_isOpen := contDiffOn_infty_iff_fderiv_of_isOpen
protected theorem ContDiffOn.fderivWithin (hf : ContDiffOn 𝕜 n f s) (hs : UniqueDiffOn 𝕜 s)
(hmn : m + 1 ≤ n) : ContDiffOn 𝕜 m (fderivWithin 𝕜 f s) s :=
((contDiffOn_succ_iff_fderivWithin hs).1 (hf.of_le hmn)).2.2
theorem ContDiffOn.fderiv_of_isOpen (hf : ContDiffOn 𝕜 n f s) (hs : IsOpen s) (hmn : m + 1 ≤ n) :
ContDiffOn 𝕜 m (fderiv 𝕜 f) s :=
(hf.fderivWithin hs.uniqueDiffOn hmn).congr fun _ hx => (fderivWithin_of_isOpen hs hx).symm
theorem ContDiffOn.continuousOn_fderivWithin (h : ContDiffOn 𝕜 n f s) (hs : UniqueDiffOn 𝕜 s)
(hn : 1 ≤ n) : ContinuousOn (fderivWithin 𝕜 f s) s :=
((contDiffOn_succ_iff_fderivWithin hs).1
(h.of_le (show 0 + (1 : WithTop ℕ∞) ≤ n from hn))).2.2.continuousOn
theorem ContDiffOn.continuousOn_fderiv_of_isOpen (h : ContDiffOn 𝕜 n f s) (hs : IsOpen s)
(hn : 1 ≤ n) : ContinuousOn (fderiv 𝕜 f) s :=
((contDiffOn_succ_iff_fderiv_of_isOpen hs).1
(h.of_le (show 0 + (1 : WithTop ℕ∞) ≤ n from hn))).2.2.continuousOn
/-! ### Smooth functions at a point -/
variable (𝕜) in
/-- A function is continuously differentiable up to `n` at a point `x` if, for any integer `k ≤ n`,
there is a neighborhood of `x` where `f` admits derivatives up to order `n`, which are continuous.
-/
def ContDiffAt (n : WithTop ℕ∞) (f : E → F) (x : E) : Prop :=
ContDiffWithinAt 𝕜 n f univ x
theorem contDiffWithinAt_univ : ContDiffWithinAt 𝕜 n f univ x ↔ ContDiffAt 𝕜 n f x :=
Iff.rfl
theorem contDiffAt_infty : ContDiffAt 𝕜 ∞ f x ↔ ∀ n : ℕ, ContDiffAt 𝕜 n f x := by
simp [← contDiffWithinAt_univ, contDiffWithinAt_infty]
@[deprecated (since := "2024-11-27")] alias contDiffAt_top := contDiffAt_infty
theorem ContDiffAt.contDiffWithinAt (h : ContDiffAt 𝕜 n f x) : ContDiffWithinAt 𝕜 n f s x :=
h.mono (subset_univ _)
theorem ContDiffWithinAt.contDiffAt (h : ContDiffWithinAt 𝕜 n f s x) (hx : s ∈ 𝓝 x) :
ContDiffAt 𝕜 n f x := by rwa [ContDiffAt, ← contDiffWithinAt_inter hx, univ_inter]
theorem contDiffWithinAt_iff_contDiffAt (h : s ∈ 𝓝 x) :
ContDiffWithinAt 𝕜 n f s x ↔ ContDiffAt 𝕜 n f x := by
rw [← univ_inter s, contDiffWithinAt_inter h, contDiffWithinAt_univ]
theorem IsOpen.contDiffOn_iff (hs : IsOpen s) :
ContDiffOn 𝕜 n f s ↔ ∀ ⦃a⦄, a ∈ s → ContDiffAt 𝕜 n f a :=
forall₂_congr fun _ => contDiffWithinAt_iff_contDiffAt ∘ hs.mem_nhds
theorem ContDiffOn.contDiffAt (h : ContDiffOn 𝕜 n f s) (hx : s ∈ 𝓝 x) :
ContDiffAt 𝕜 n f x :=
(h _ (mem_of_mem_nhds hx)).contDiffAt hx
theorem ContDiffAt.congr_of_eventuallyEq (h : ContDiffAt 𝕜 n f x) (hg : f₁ =ᶠ[𝓝 x] f) :
ContDiffAt 𝕜 n f₁ x :=
h.congr_of_eventuallyEq_of_mem (by rwa [nhdsWithin_univ]) (mem_univ x)
theorem ContDiffAt.of_le (h : ContDiffAt 𝕜 n f x) (hmn : m ≤ n) : ContDiffAt 𝕜 m f x :=
ContDiffWithinAt.of_le h hmn
theorem ContDiffAt.continuousAt (h : ContDiffAt 𝕜 n f x) : ContinuousAt f x := by
simpa [continuousWithinAt_univ] using h.continuousWithinAt
theorem ContDiffAt.analyticAt (h : ContDiffAt 𝕜 ω f x) : AnalyticAt 𝕜 f x := by
rw [← contDiffWithinAt_univ] at h
rw [← analyticWithinAt_univ]
exact h.analyticWithinAt
/-- In a complete space, a function which is analytic at a point is also `C^ω` there.
Note that the same statement for `AnalyticOn` does not require completeness, see
`AnalyticOn.contDiffOn`. -/
theorem AnalyticAt.contDiffAt [CompleteSpace F] (h : AnalyticAt 𝕜 f x) :
ContDiffAt 𝕜 n f x := by
rw [← contDiffWithinAt_univ]
rw [← analyticWithinAt_univ] at h
exact h.contDiffWithinAt
@[simp]
theorem contDiffWithinAt_compl_self :
ContDiffWithinAt 𝕜 n f {x}ᶜ x ↔ ContDiffAt 𝕜 n f x := by
rw [compl_eq_univ_diff, contDiffWithinAt_diff_singleton, contDiffWithinAt_univ]
/-- If a function is `C^n` with `n ≥ 1` at a point, then it is differentiable there. -/
theorem ContDiffAt.differentiableAt (h : ContDiffAt 𝕜 n f x) (hn : 1 ≤ n) :
DifferentiableAt 𝕜 f x := by
simpa [hn, differentiableWithinAt_univ] using h.differentiableWithinAt
nonrec lemma ContDiffAt.contDiffOn (h : ContDiffAt 𝕜 n f x) (hm : m ≤ n) (h' : m = ∞ → n = ω):
∃ u ∈ 𝓝 x, ContDiffOn 𝕜 m f u := by
simpa [nhdsWithin_univ] using h.contDiffOn hm h'
/-- A function is `C^(n + 1)` at a point iff locally, it has a derivative which is `C^n`. -/
theorem contDiffAt_succ_iff_hasFDerivAt {n : ℕ} :
ContDiffAt 𝕜 (n + 1) f x ↔ ∃ f' : E → E →L[𝕜] F,
(∃ u ∈ 𝓝 x, ∀ x ∈ u, HasFDerivAt f (f' x) x) ∧ ContDiffAt 𝕜 n f' x := by
rw [← contDiffWithinAt_univ, contDiffWithinAt_succ_iff_hasFDerivWithinAt (by simp)]
simp only [nhdsWithin_univ, exists_prop, mem_univ, insert_eq_of_mem]
constructor
· rintro ⟨u, H, -, f', h_fderiv, h_cont_diff⟩
rcases mem_nhds_iff.mp H with ⟨t, htu, ht, hxt⟩
refine ⟨f', ⟨t, ?_⟩, h_cont_diff.contDiffAt H⟩
refine ⟨mem_nhds_iff.mpr ⟨t, Subset.rfl, ht, hxt⟩, ?_⟩
intro y hyt
refine (h_fderiv y (htu hyt)).hasFDerivAt ?_
exact mem_nhds_iff.mpr ⟨t, htu, ht, hyt⟩
· rintro ⟨f', ⟨u, H, h_fderiv⟩, h_cont_diff⟩
refine ⟨u, H, by simp, f', fun x hxu ↦ ?_, h_cont_diff.contDiffWithinAt⟩
exact (h_fderiv x hxu).hasFDerivWithinAt
protected theorem ContDiffAt.eventually (h : ContDiffAt 𝕜 n f x) (h' : n ≠ ∞) :
∀ᶠ y in 𝓝 x, ContDiffAt 𝕜 n f y := by
simpa [nhdsWithin_univ] using ContDiffWithinAt.eventually h h'
theorem iteratedFDerivWithin_eq_iteratedFDeriv {n : ℕ}
(hs : UniqueDiffOn 𝕜 s) (h : ContDiffAt 𝕜 n f x) (hx : x ∈ s) :
iteratedFDerivWithin 𝕜 n f s x = iteratedFDeriv 𝕜 n f x := by
rw [← iteratedFDerivWithin_univ]
rcases h.contDiffOn' le_rfl (by simp) with ⟨u, u_open, xu, hu⟩
rw [← iteratedFDerivWithin_inter_open u_open xu,
← iteratedFDerivWithin_inter_open u_open xu (s := univ)]
apply iteratedFDerivWithin_subset
· exact inter_subset_inter_left _ (subset_univ _)
· exact hs.inter u_open
· apply uniqueDiffOn_univ.inter u_open
· simpa using hu
· exact ⟨hx, xu⟩
/-! ### Smooth functions -/
variable (𝕜) in
/-- A function is continuously differentiable up to `n` if it admits derivatives up to
order `n`, which are continuous. Contrary to the case of definitions in domains (where derivatives
might not be unique) we do not need to localize the definition in space or time.
-/
def ContDiff (n : WithTop ℕ∞) (f : E → F) : Prop :=
match n with
| ω => ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpTo ⊤ f p
∧ ∀ i, AnalyticOnNhd 𝕜 (fun x ↦ p x i) univ
| (n : ℕ∞) => ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpTo n f p
/-- If `f` has a Taylor series up to `n`, then it is `C^n`. -/
theorem HasFTaylorSeriesUpTo.contDiff {n : ℕ∞} {f' : E → FormalMultilinearSeries 𝕜 E F}
(hf : HasFTaylorSeriesUpTo n f f') : ContDiff 𝕜 n f :=
⟨f', hf⟩
theorem contDiffOn_univ : ContDiffOn 𝕜 n f univ ↔ ContDiff 𝕜 n f := by
match n with
| ω =>
constructor
· intro H
use ftaylorSeriesWithin 𝕜 f univ
rw [← hasFTaylorSeriesUpToOn_univ_iff]
refine ⟨H.ftaylorSeriesWithin uniqueDiffOn_univ, fun i ↦ ?_⟩
rw [← analyticOn_univ]
exact H.analyticOn.iteratedFDerivWithin uniqueDiffOn_univ _
· rintro ⟨p, hp, h'p⟩ x _
exact ⟨univ, Filter.univ_sets _, p, (hp.hasFTaylorSeriesUpToOn univ).of_le le_top,
fun i ↦ (h'p i).analyticOn⟩
| (n : ℕ∞) =>
constructor
· intro H
use ftaylorSeriesWithin 𝕜 f univ
rw [← hasFTaylorSeriesUpToOn_univ_iff]
exact H.ftaylorSeriesWithin uniqueDiffOn_univ
· rintro ⟨p, hp⟩ x _ m hm
exact ⟨univ, Filter.univ_sets _, p,
(hp.hasFTaylorSeriesUpToOn univ).of_le (mod_cast hm)⟩
theorem contDiff_iff_contDiffAt : ContDiff 𝕜 n f ↔ ∀ x, ContDiffAt 𝕜 n f x := by
simp [← contDiffOn_univ, ContDiffOn, ContDiffAt]
theorem ContDiff.contDiffAt (h : ContDiff 𝕜 n f) : ContDiffAt 𝕜 n f x :=
contDiff_iff_contDiffAt.1 h x
theorem ContDiff.contDiffWithinAt (h : ContDiff 𝕜 n f) : ContDiffWithinAt 𝕜 n f s x :=
h.contDiffAt.contDiffWithinAt
theorem contDiff_infty : ContDiff 𝕜 ∞ f ↔ ∀ n : ℕ, ContDiff 𝕜 n f := by
simp [contDiffOn_univ.symm, contDiffOn_infty]
@[deprecated (since := "2024-11-25")] alias contDiff_top := contDiff_infty
@[deprecated (since := "2024-11-25")] alias contDiff_infty_iff_contDiff_omega := contDiff_infty
theorem contDiff_all_iff_nat : (∀ n : ℕ∞, ContDiff 𝕜 n f) ↔ ∀ n : ℕ, ContDiff 𝕜 n f := by
simp only [← contDiffOn_univ, contDiffOn_all_iff_nat]
theorem ContDiff.contDiffOn (h : ContDiff 𝕜 n f) : ContDiffOn 𝕜 n f s :=
(contDiffOn_univ.2 h).mono (subset_univ _)
@[simp]
theorem contDiff_zero : ContDiff 𝕜 0 f ↔ Continuous f := by
rw [← contDiffOn_univ, continuous_iff_continuousOn_univ]
exact contDiffOn_zero
theorem contDiffAt_zero : ContDiffAt 𝕜 0 f x ↔ ∃ u ∈ 𝓝 x, ContinuousOn f u := by
rw [← contDiffWithinAt_univ]; simp [contDiffWithinAt_zero, nhdsWithin_univ]
theorem contDiffAt_one_iff :
ContDiffAt 𝕜 1 f x ↔
∃ f' : E → E →L[𝕜] F, ∃ u ∈ 𝓝 x, ContinuousOn f' u ∧ ∀ x ∈ u, HasFDerivAt f (f' x) x := by
rw [show (1 : WithTop ℕ∞) = (0 : ℕ) + 1 from rfl]
simp_rw [contDiffAt_succ_iff_hasFDerivAt, show ((0 : ℕ) : WithTop ℕ∞) = 0 from rfl,
contDiffAt_zero, exists_mem_and_iff antitone_bforall antitone_continuousOn, and_comm]
theorem ContDiff.of_le (h : ContDiff 𝕜 n f) (hmn : m ≤ n) : ContDiff 𝕜 m f :=
contDiffOn_univ.1 <| (contDiffOn_univ.2 h).of_le hmn
theorem ContDiff.of_succ (h : ContDiff 𝕜 (n + 1) f) : ContDiff 𝕜 n f :=
h.of_le le_self_add
theorem ContDiff.one_of_succ (h : ContDiff 𝕜 (n + 1) f) : ContDiff 𝕜 1 f := by
apply h.of_le le_add_self
theorem ContDiff.continuous (h : ContDiff 𝕜 n f) : Continuous f :=
contDiff_zero.1 (h.of_le bot_le)
/-- If a function is `C^n` with `n ≥ 1`, then it is differentiable. -/
theorem ContDiff.differentiable (h : ContDiff 𝕜 n f) (hn : 1 ≤ n) : Differentiable 𝕜 f :=
differentiableOn_univ.1 <| (contDiffOn_univ.2 h).differentiableOn hn
theorem contDiff_iff_forall_nat_le {n : ℕ∞} :
ContDiff 𝕜 n f ↔ ∀ m : ℕ, ↑m ≤ n → ContDiff 𝕜 m f := by
simp_rw [← contDiffOn_univ]; exact contDiffOn_iff_forall_nat_le
/-- A function is `C^(n+1)` iff it has a `C^n` derivative. -/
theorem contDiff_succ_iff_hasFDerivAt {n : ℕ} :
ContDiff 𝕜 (n + 1) f ↔
∃ f' : E → E →L[𝕜] F, ContDiff 𝕜 n f' ∧ ∀ x, HasFDerivAt f (f' x) x := by
simp only [← contDiffOn_univ, ← hasFDerivWithinAt_univ, Set.mem_univ, forall_true_left,
contDiffOn_succ_iff_hasFDerivWithinAt_of_uniqueDiffOn uniqueDiffOn_univ,
WithTop.natCast_ne_top, analyticOn_univ, false_implies, true_and]
theorem contDiff_one_iff_hasFDerivAt : ContDiff 𝕜 1 f ↔
∃ f' : E → E →L[𝕜] F, Continuous f' ∧ ∀ x, HasFDerivAt f (f' x) x := by
convert contDiff_succ_iff_hasFDerivAt using 4; simp
theorem AnalyticOn.contDiff (hf : AnalyticOn 𝕜 f univ) : ContDiff 𝕜 n f := by
rw [← contDiffOn_univ]
exact hf.contDiffOn (n := n) uniqueDiffOn_univ
theorem AnalyticOnNhd.contDiff (hf : AnalyticOnNhd 𝕜 f univ) : ContDiff 𝕜 n f :=
hf.analyticOn.contDiff
theorem ContDiff.analyticOnNhd (h : ContDiff 𝕜 ω f) : AnalyticOnNhd 𝕜 f s := by
rw [← contDiffOn_univ] at h
have := h.analyticOn
rw [analyticOn_univ] at this
exact this.mono (subset_univ _)
theorem contDiff_omega_iff_analyticOnNhd :
ContDiff 𝕜 ω f ↔ AnalyticOnNhd 𝕜 f univ :=
⟨fun h ↦ h.analyticOnNhd, fun h ↦ h.contDiff⟩
/-! ### Iterated derivative -/
/-- When a function is `C^n`, it admits `ftaylorSeries 𝕜 f` as a Taylor series up
to order `n` in `s`. -/
theorem ContDiff.ftaylorSeries (hf : ContDiff 𝕜 n f) :
HasFTaylorSeriesUpTo n f (ftaylorSeries 𝕜 f) := by
simp only [← contDiffOn_univ, ← hasFTaylorSeriesUpToOn_univ_iff, ← ftaylorSeriesWithin_univ]
at hf ⊢
exact ContDiffOn.ftaylorSeriesWithin hf uniqueDiffOn_univ
/-- For `n : ℕ∞`, a function is `C^n` iff it admits `ftaylorSeries 𝕜 f`
as a Taylor series up to order `n`. -/
| theorem contDiff_iff_ftaylorSeries {n : ℕ∞} :
ContDiff 𝕜 n f ↔ HasFTaylorSeriesUpTo n f (ftaylorSeries 𝕜 f) := by
constructor
· rw [← contDiffOn_univ, ← hasFTaylorSeriesUpToOn_univ_iff, ← ftaylorSeriesWithin_univ]
exact fun h ↦ ContDiffOn.ftaylorSeriesWithin h uniqueDiffOn_univ
· exact fun h ↦ ⟨ftaylorSeries 𝕜 f, h⟩
theorem contDiff_iff_continuous_differentiable {n : ℕ∞} :
ContDiff 𝕜 n f ↔
(∀ m : ℕ, m ≤ n → Continuous fun x => iteratedFDeriv 𝕜 m f x) ∧
∀ m : ℕ, m < n → Differentiable 𝕜 fun x => iteratedFDeriv 𝕜 m f x := by
simp [contDiffOn_univ.symm, continuous_iff_continuousOn_univ, differentiableOn_univ.symm,
iteratedFDerivWithin_univ, contDiffOn_iff_continuousOn_differentiableOn uniqueDiffOn_univ]
theorem contDiff_nat_iff_continuous_differentiable {n : ℕ} :
ContDiff 𝕜 n f ↔
(∀ m : ℕ, m ≤ n → Continuous fun x => iteratedFDeriv 𝕜 m f x) ∧
| Mathlib/Analysis/Calculus/ContDiff/Defs.lean | 1,160 | 1,176 |
/-
Copyright (c) 2017 Mario Carneiro. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Mario Carneiro, Floris van Doorn, Violeta Hernández Palacios
-/
import Mathlib.SetTheory.Cardinal.Arithmetic
import Mathlib.SetTheory.Ordinal.FixedPoint
/-!
# Cofinality
This file contains the definition of cofinality of an order and an ordinal number.
## Main Definitions
* `Order.cof r` is the cofinality of a reflexive order. This is the smallest cardinality of a subset
`s` that is *cofinal*, i.e. `∀ x, ∃ y ∈ s, r x y`.
* `Ordinal.cof o` is the cofinality of the ordinal `o` when viewed as a linear order.
## Main Statements
* `Cardinal.lt_power_cof`: A consequence of König's theorem stating that `c < c ^ c.ord.cof` for
`c ≥ ℵ₀`.
## Implementation Notes
* The cofinality is defined for ordinals.
If `c` is a cardinal number, its cofinality is `c.ord.cof`.
-/
noncomputable section
open Function Cardinal Set Order
open scoped Ordinal
universe u v w
variable {α : Type u} {β : Type v} {r : α → α → Prop} {s : β → β → Prop}
/-! ### Cofinality of orders -/
attribute [local instance] IsRefl.swap
namespace Order
/-- Cofinality of a reflexive order `≼`. This is the smallest cardinality
of a subset `S : Set α` such that `∀ a, ∃ b ∈ S, a ≼ b`. -/
def cof (r : α → α → Prop) : Cardinal :=
sInf { c | ∃ S : Set α, (∀ a, ∃ b ∈ S, r a b) ∧ #S = c }
/-- The set in the definition of `Order.cof` is nonempty. -/
private theorem cof_nonempty (r : α → α → Prop) [IsRefl α r] :
{ c | ∃ S : Set α, (∀ a, ∃ b ∈ S, r a b) ∧ #S = c }.Nonempty :=
⟨_, Set.univ, fun a => ⟨a, ⟨⟩, refl _⟩, rfl⟩
theorem cof_le (r : α → α → Prop) {S : Set α} (h : ∀ a, ∃ b ∈ S, r a b) : cof r ≤ #S :=
csInf_le' ⟨S, h, rfl⟩
theorem le_cof [IsRefl α r] (c : Cardinal) :
c ≤ cof r ↔ ∀ {S : Set α}, (∀ a, ∃ b ∈ S, r a b) → c ≤ #S := by
rw [cof, le_csInf_iff'' (cof_nonempty r)]
use fun H S h => H _ ⟨S, h, rfl⟩
rintro H d ⟨S, h, rfl⟩
exact H h
end Order
namespace RelIso
private theorem cof_le_lift [IsRefl β s] (f : r ≃r s) :
Cardinal.lift.{v} (Order.cof r) ≤ Cardinal.lift.{u} (Order.cof s) := by
rw [Order.cof, Order.cof, lift_sInf, lift_sInf, le_csInf_iff'' ((Order.cof_nonempty s).image _)]
rintro - ⟨-, ⟨u, H, rfl⟩, rfl⟩
apply csInf_le'
refine ⟨_, ⟨f.symm '' u, fun a => ?_, rfl⟩, lift_mk_eq'.2 ⟨(f.symm.toEquiv.image u).symm⟩⟩
rcases H (f a) with ⟨b, hb, hb'⟩
refine ⟨f.symm b, mem_image_of_mem _ hb, f.map_rel_iff.1 ?_⟩
rwa [RelIso.apply_symm_apply]
theorem cof_eq_lift [IsRefl β s] (f : r ≃r s) :
Cardinal.lift.{v} (Order.cof r) = Cardinal.lift.{u} (Order.cof s) :=
have := f.toRelEmbedding.isRefl
(f.cof_le_lift).antisymm (f.symm.cof_le_lift)
theorem cof_eq {α β : Type u} {r : α → α → Prop} {s} [IsRefl β s] (f : r ≃r s) :
Order.cof r = Order.cof s :=
lift_inj.1 (f.cof_eq_lift)
end RelIso
/-! ### Cofinality of ordinals -/
namespace Ordinal
/-- Cofinality of an ordinal. This is the smallest cardinal of a subset `S` of the ordinal which is
unbounded, in the sense `∀ a, ∃ b ∈ S, a ≤ b`.
In particular, `cof 0 = 0` and `cof (succ o) = 1`. -/
def cof (o : Ordinal.{u}) : Cardinal.{u} :=
o.liftOn (fun a ↦ Order.cof (swap a.rᶜ)) fun _ _ ⟨f⟩ ↦ f.compl.swap.cof_eq
theorem cof_type (r : α → α → Prop) [IsWellOrder α r] : (type r).cof = Order.cof (swap rᶜ) :=
rfl
theorem cof_type_lt [LinearOrder α] [IsWellOrder α (· < ·)] :
(@type α (· < ·) _).cof = @Order.cof α (· ≤ ·) := by
rw [cof_type, compl_lt, swap_ge]
theorem cof_eq_cof_toType (o : Ordinal) : o.cof = @Order.cof o.toType (· ≤ ·) := by
conv_lhs => rw [← type_toType o, cof_type_lt]
theorem le_cof_type [IsWellOrder α r] {c} : c ≤ cof (type r) ↔ ∀ S, Unbounded r S → c ≤ #S :=
(le_csInf_iff'' (Order.cof_nonempty _)).trans
⟨fun H S h => H _ ⟨S, h, rfl⟩, by
rintro H d ⟨S, h, rfl⟩
exact H _ h⟩
theorem cof_type_le [IsWellOrder α r] {S : Set α} (h : Unbounded r S) : cof (type r) ≤ #S :=
le_cof_type.1 le_rfl S h
theorem lt_cof_type [IsWellOrder α r] {S : Set α} : #S < cof (type r) → Bounded r S := by
simpa using not_imp_not.2 cof_type_le
theorem cof_eq (r : α → α → Prop) [IsWellOrder α r] : ∃ S, Unbounded r S ∧ #S = cof (type r) :=
csInf_mem (Order.cof_nonempty (swap rᶜ))
theorem ord_cof_eq (r : α → α → Prop) [IsWellOrder α r] :
∃ S, Unbounded r S ∧ type (Subrel r (· ∈ S)) = (cof (type r)).ord := by
let ⟨S, hS, e⟩ := cof_eq r
let ⟨s, _, e'⟩ := Cardinal.ord_eq S
let T : Set α := { a | ∃ aS : a ∈ S, ∀ b : S, s b ⟨_, aS⟩ → r b a }
suffices Unbounded r T by
refine ⟨T, this, le_antisymm ?_ (Cardinal.ord_le.2 <| cof_type_le this)⟩
rw [← e, e']
refine
(RelEmbedding.ofMonotone
(fun a : T =>
(⟨a,
let ⟨aS, _⟩ := a.2
aS⟩ :
S))
fun a b h => ?_).ordinal_type_le
rcases a with ⟨a, aS, ha⟩
rcases b with ⟨b, bS, hb⟩
change s ⟨a, _⟩ ⟨b, _⟩
refine ((trichotomous_of s _ _).resolve_left fun hn => ?_).resolve_left ?_
· exact asymm h (ha _ hn)
· intro e
injection e with e
subst b
exact irrefl _ h
intro a
have : { b : S | ¬r b a }.Nonempty :=
let ⟨b, bS, ba⟩ := hS a
⟨⟨b, bS⟩, ba⟩
let b := (IsWellFounded.wf : WellFounded s).min _ this
have ba : ¬r b a := IsWellFounded.wf.min_mem _ this
refine ⟨b, ⟨b.2, fun c => not_imp_not.1 fun h => ?_⟩, ba⟩
rw [show ∀ b : S, (⟨b, b.2⟩ : S) = b by intro b; cases b; rfl]
exact IsWellFounded.wf.not_lt_min _ this (IsOrderConnected.neg_trans h ba)
/-! ### Cofinality of suprema and least strict upper bounds -/
private theorem card_mem_cof {o} : ∃ (ι : _) (f : ι → Ordinal), lsub.{u, u} f = o ∧ #ι = o.card :=
⟨_, _, lsub_typein o, mk_toType o⟩
/-- The set in the `lsub` characterization of `cof` is nonempty. -/
theorem cof_lsub_def_nonempty (o) :
{ a : Cardinal | ∃ (ι : _) (f : ι → Ordinal), lsub.{u, u} f = o ∧ #ι = a }.Nonempty :=
⟨_, card_mem_cof⟩
theorem cof_eq_sInf_lsub (o : Ordinal.{u}) : cof o =
sInf { a : Cardinal | ∃ (ι : Type u) (f : ι → Ordinal), lsub.{u, u} f = o ∧ #ι = a } := by
refine le_antisymm (le_csInf (cof_lsub_def_nonempty o) ?_) (csInf_le' ?_)
· rintro a ⟨ι, f, hf, rfl⟩
rw [← type_toType o]
refine
(cof_type_le fun a => ?_).trans
(@mk_le_of_injective _ _
(fun s : typein ((· < ·) : o.toType → o.toType → Prop) ⁻¹' Set.range f =>
Classical.choose s.prop)
fun s t hst => by
let H := congr_arg f hst
rwa [Classical.choose_spec s.prop, Classical.choose_spec t.prop, typein_inj,
Subtype.coe_inj] at H)
have := typein_lt_self a
simp_rw [← hf, lt_lsub_iff] at this
obtain ⟨i, hi⟩ := this
refine ⟨enum (α := o.toType) (· < ·) ⟨f i, ?_⟩, ?_, ?_⟩
· rw [type_toType, ← hf]
apply lt_lsub
· rw [mem_preimage, typein_enum]
exact mem_range_self i
· rwa [← typein_le_typein, typein_enum]
· rcases cof_eq (α := o.toType) (· < ·) with ⟨S, hS, hS'⟩
let f : S → Ordinal := fun s => typein LT.lt s.val
refine ⟨S, f, le_antisymm (lsub_le fun i => typein_lt_self (o := o) i)
(le_of_forall_lt fun a ha => ?_), by rwa [type_toType o] at hS'⟩
rw [← type_toType o] at ha
rcases hS (enum (· < ·) ⟨a, ha⟩) with ⟨b, hb, hb'⟩
rw [← typein_le_typein, typein_enum] at hb'
exact hb'.trans_lt (lt_lsub.{u, u} f ⟨b, hb⟩)
@[simp]
theorem lift_cof (o) : Cardinal.lift.{u, v} (cof o) = cof (Ordinal.lift.{u, v} o) := by
refine inductionOn o fun α r _ ↦ ?_
rw [← type_uLift, cof_type, cof_type, ← Cardinal.lift_id'.{v, u} (Order.cof _),
← Cardinal.lift_umax]
apply RelIso.cof_eq_lift ⟨Equiv.ulift.symm, _⟩
simp [swap]
theorem cof_le_card (o) : cof o ≤ card o := by
rw [cof_eq_sInf_lsub]
exact csInf_le' card_mem_cof
theorem cof_ord_le (c : Cardinal) : c.ord.cof ≤ c := by simpa using cof_le_card c.ord
theorem ord_cof_le (o : Ordinal.{u}) : o.cof.ord ≤ o :=
(ord_le_ord.2 (cof_le_card o)).trans (ord_card_le o)
theorem exists_lsub_cof (o : Ordinal) :
∃ (ι : _) (f : ι → Ordinal), lsub.{u, u} f = o ∧ #ι = cof o := by
rw [cof_eq_sInf_lsub]
exact csInf_mem (cof_lsub_def_nonempty o)
theorem cof_lsub_le {ι} (f : ι → Ordinal) : cof (lsub.{u, u} f) ≤ #ι := by
rw [cof_eq_sInf_lsub]
exact csInf_le' ⟨ι, f, rfl, rfl⟩
theorem cof_lsub_le_lift {ι} (f : ι → Ordinal) :
cof (lsub.{u, v} f) ≤ Cardinal.lift.{v, u} #ι := by
rw [← mk_uLift.{u, v}]
convert cof_lsub_le.{max u v} fun i : ULift.{v, u} ι => f i.down
exact
lsub_eq_of_range_eq.{u, max u v, max u v}
(Set.ext fun x => ⟨fun ⟨i, hi⟩ => ⟨ULift.up.{v, u} i, hi⟩, fun ⟨i, hi⟩ => ⟨_, hi⟩⟩)
theorem le_cof_iff_lsub {o : Ordinal} {a : Cardinal} :
a ≤ cof o ↔ ∀ {ι} (f : ι → Ordinal), lsub.{u, u} f = o → a ≤ #ι := by
rw [cof_eq_sInf_lsub]
exact
(le_csInf_iff'' (cof_lsub_def_nonempty o)).trans
⟨fun H ι f hf => H _ ⟨ι, f, hf, rfl⟩, fun H b ⟨ι, f, hf, hb⟩ => by
rw [← hb]
exact H _ hf⟩
theorem lsub_lt_ord_lift {ι} {f : ι → Ordinal} {c : Ordinal}
(hι : Cardinal.lift.{v, u} #ι < c.cof)
(hf : ∀ i, f i < c) : lsub.{u, v} f < c :=
lt_of_le_of_ne (lsub_le hf) fun h => by
subst h
exact (cof_lsub_le_lift.{u, v} f).not_lt hι
theorem lsub_lt_ord {ι} {f : ι → Ordinal} {c : Ordinal} (hι : #ι < c.cof) :
(∀ i, f i < c) → lsub.{u, u} f < c :=
lsub_lt_ord_lift (by rwa [(#ι).lift_id])
theorem cof_iSup_le_lift {ι} {f : ι → Ordinal} (H : ∀ i, f i < iSup f) :
cof (iSup f) ≤ Cardinal.lift.{v, u} #ι := by
rw [← Ordinal.sup] at *
rw [← sup_eq_lsub_iff_lt_sup.{u, v}] at H
rw [H]
exact cof_lsub_le_lift f
theorem cof_iSup_le {ι} {f : ι → Ordinal} (H : ∀ i, f i < iSup f) :
cof (iSup f) ≤ #ι := by
rw [← (#ι).lift_id]
exact cof_iSup_le_lift H
theorem iSup_lt_ord_lift {ι} {f : ι → Ordinal} {c : Ordinal} (hι : Cardinal.lift.{v, u} #ι < c.cof)
(hf : ∀ i, f i < c) : iSup f < c :=
(sup_le_lsub.{u, v} f).trans_lt (lsub_lt_ord_lift hι hf)
theorem iSup_lt_ord {ι} {f : ι → Ordinal} {c : Ordinal} (hι : #ι < c.cof) :
(∀ i, f i < c) → iSup f < c :=
iSup_lt_ord_lift (by rwa [(#ι).lift_id])
theorem iSup_lt_lift {ι} {f : ι → Cardinal} {c : Cardinal}
(hι : Cardinal.lift.{v, u} #ι < c.ord.cof)
(hf : ∀ i, f i < c) : iSup f < c := by
rw [← ord_lt_ord, iSup_ord (Cardinal.bddAbove_range _)]
refine iSup_lt_ord_lift hι fun i => ?_
rw [ord_lt_ord]
apply hf
theorem iSup_lt {ι} {f : ι → Cardinal} {c : Cardinal} (hι : #ι < c.ord.cof) :
(∀ i, f i < c) → iSup f < c :=
iSup_lt_lift (by rwa [(#ι).lift_id])
theorem nfpFamily_lt_ord_lift {ι} {f : ι → Ordinal → Ordinal} {c} (hc : ℵ₀ < cof c)
(hc' : Cardinal.lift.{v, u} #ι < cof c) (hf : ∀ (i), ∀ b < c, f i b < c) {a} (ha : a < c) :
nfpFamily f a < c := by
refine iSup_lt_ord_lift ((Cardinal.lift_le.2 (mk_list_le_max ι)).trans_lt ?_) fun l => ?_
· rw [lift_max]
apply max_lt _ hc'
rwa [Cardinal.lift_aleph0]
· induction' l with i l H
· exact ha
· exact hf _ _ H
theorem nfpFamily_lt_ord {ι} {f : ι → Ordinal → Ordinal} {c} (hc : ℵ₀ < cof c) (hc' : #ι < cof c)
(hf : ∀ (i), ∀ b < c, f i b < c) {a} : a < c → nfpFamily.{u, u} f a < c :=
nfpFamily_lt_ord_lift hc (by rwa [(#ι).lift_id]) hf
theorem nfp_lt_ord {f : Ordinal → Ordinal} {c} (hc : ℵ₀ < cof c) (hf : ∀ i < c, f i < c) {a} :
a < c → nfp f a < c :=
nfpFamily_lt_ord_lift hc (by simpa using Cardinal.one_lt_aleph0.trans hc) fun _ => hf
theorem exists_blsub_cof (o : Ordinal) :
∃ f : ∀ a < (cof o).ord, Ordinal, blsub.{u, u} _ f = o := by
rcases exists_lsub_cof o with ⟨ι, f, hf, hι⟩
rcases Cardinal.ord_eq ι with ⟨r, hr, hι'⟩
rw [← @blsub_eq_lsub' ι r hr] at hf
rw [← hι, hι']
exact ⟨_, hf⟩
theorem le_cof_iff_blsub {b : Ordinal} {a : Cardinal} :
a ≤ cof b ↔ ∀ {o} (f : ∀ a < o, Ordinal), blsub.{u, u} o f = b → a ≤ o.card :=
le_cof_iff_lsub.trans
⟨fun H o f hf => by simpa using H _ hf, fun H ι f hf => by
rcases Cardinal.ord_eq ι with ⟨r, hr, hι'⟩
rw [← @blsub_eq_lsub' ι r hr] at hf
simpa using H _ hf⟩
theorem cof_blsub_le_lift {o} (f : ∀ a < o, Ordinal) :
cof (blsub.{u, v} o f) ≤ Cardinal.lift.{v, u} o.card := by
rw [← mk_toType o]
exact cof_lsub_le_lift _
theorem cof_blsub_le {o} (f : ∀ a < o, Ordinal) : cof (blsub.{u, u} o f) ≤ o.card := by
rw [← o.card.lift_id]
exact cof_blsub_le_lift f
theorem blsub_lt_ord_lift {o : Ordinal.{u}} {f : ∀ a < o, Ordinal} {c : Ordinal}
(ho : Cardinal.lift.{v, u} o.card < c.cof) (hf : ∀ i hi, f i hi < c) : blsub.{u, v} o f < c :=
lt_of_le_of_ne (blsub_le hf) fun h =>
ho.not_le (by simpa [← iSup_ord, hf, h] using cof_blsub_le_lift.{u, v} f)
theorem blsub_lt_ord {o : Ordinal} {f : ∀ a < o, Ordinal} {c : Ordinal} (ho : o.card < c.cof)
(hf : ∀ i hi, f i hi < c) : blsub.{u, u} o f < c :=
blsub_lt_ord_lift (by rwa [o.card.lift_id]) hf
theorem cof_bsup_le_lift {o : Ordinal} {f : ∀ a < o, Ordinal} (H : ∀ i h, f i h < bsup.{u, v} o f) :
cof (bsup.{u, v} o f) ≤ Cardinal.lift.{v, u} o.card := by
rw [← bsup_eq_blsub_iff_lt_bsup.{u, v}] at H
rw [H]
exact cof_blsub_le_lift.{u, v} f
theorem cof_bsup_le {o : Ordinal} {f : ∀ a < o, Ordinal} :
(∀ i h, f i h < bsup.{u, u} o f) → cof (bsup.{u, u} o f) ≤ o.card := by
rw [← o.card.lift_id]
exact cof_bsup_le_lift
theorem bsup_lt_ord_lift {o : Ordinal} {f : ∀ a < o, Ordinal} {c : Ordinal}
(ho : Cardinal.lift.{v, u} o.card < c.cof) (hf : ∀ i hi, f i hi < c) : bsup.{u, v} o f < c :=
(bsup_le_blsub f).trans_lt (blsub_lt_ord_lift ho hf)
theorem bsup_lt_ord {o : Ordinal} {f : ∀ a < o, Ordinal} {c : Ordinal} (ho : o.card < c.cof) :
(∀ i hi, f i hi < c) → bsup.{u, u} o f < c :=
bsup_lt_ord_lift (by rwa [o.card.lift_id])
/-! ### Basic results -/
@[simp]
theorem cof_zero : cof 0 = 0 := by
refine LE.le.antisymm ?_ (Cardinal.zero_le _)
rw [← card_zero]
exact cof_le_card 0
@[simp]
theorem cof_eq_zero {o} : cof o = 0 ↔ o = 0 :=
⟨inductionOn o fun _ r _ z =>
let ⟨_, hl, e⟩ := cof_eq r
type_eq_zero_iff_isEmpty.2 <|
⟨fun a =>
let ⟨_, h, _⟩ := hl a
(mk_eq_zero_iff.1 (e.trans z)).elim' ⟨_, h⟩⟩,
fun e => by simp [e]⟩
theorem cof_ne_zero {o} : cof o ≠ 0 ↔ o ≠ 0 :=
cof_eq_zero.not
@[simp]
theorem cof_succ (o) : cof (succ o) = 1 := by
apply le_antisymm
· refine inductionOn o fun α r _ => ?_
change cof (type _) ≤ _
rw [← (_ : #_ = 1)]
· apply cof_type_le
refine fun a => ⟨Sum.inr PUnit.unit, Set.mem_singleton _, ?_⟩
rcases a with (a | ⟨⟨⟨⟩⟩⟩) <;> simp [EmptyRelation]
· rw [Cardinal.mk_fintype, Set.card_singleton]
simp
· rw [← Cardinal.succ_zero, succ_le_iff]
simpa [lt_iff_le_and_ne, Cardinal.zero_le] using fun h =>
succ_ne_zero o (cof_eq_zero.1 (Eq.symm h))
@[simp]
theorem cof_eq_one_iff_is_succ {o} : cof.{u} o = 1 ↔ ∃ a, o = succ a :=
⟨inductionOn o fun α r _ z => by
rcases cof_eq r with ⟨S, hl, e⟩; rw [z] at e
obtain ⟨a⟩ := mk_ne_zero_iff.1 (by rw [e]; exact one_ne_zero)
refine
⟨typein r a,
Eq.symm <|
Quotient.sound
⟨RelIso.ofSurjective (RelEmbedding.ofMonotone ?_ fun x y => ?_) fun x => ?_⟩⟩
· apply Sum.rec <;> [exact Subtype.val; exact fun _ => a]
· rcases x with (x | ⟨⟨⟨⟩⟩⟩) <;> rcases y with (y | ⟨⟨⟨⟩⟩⟩) <;>
simp [Subrel, Order.Preimage, EmptyRelation]
exact x.2
· suffices r x a ∨ ∃ _ : PUnit.{u}, ↑a = x by
convert this
dsimp [RelEmbedding.ofMonotone]; simp
rcases trichotomous_of r x a with (h | h | h)
· exact Or.inl h
· exact Or.inr ⟨PUnit.unit, h.symm⟩
· rcases hl x with ⟨a', aS, hn⟩
refine absurd h ?_
convert hn
change (a : α) = ↑(⟨a', aS⟩ : S)
have := le_one_iff_subsingleton.1 (le_of_eq e)
congr!,
fun ⟨a, e⟩ => by simp [e]⟩
/-! ### Fundamental sequences -/
-- TODO: move stuff about fundamental sequences to their own file.
/-- A fundamental sequence for `a` is an increasing sequence of length `o = cof a` that converges at
`a`. We provide `o` explicitly in order to avoid type rewrites. -/
def IsFundamentalSequence (a o : Ordinal.{u}) (f : ∀ b < o, Ordinal.{u}) : Prop :=
o ≤ a.cof.ord ∧ (∀ {i j} (hi hj), i < j → f i hi < f j hj) ∧ blsub.{u, u} o f = a
namespace IsFundamentalSequence
variable {a o : Ordinal.{u}} {f : ∀ b < o, Ordinal.{u}}
protected theorem cof_eq (hf : IsFundamentalSequence a o f) : a.cof.ord = o :=
hf.1.antisymm' <| by
rw [← hf.2.2]
exact (ord_le_ord.2 (cof_blsub_le f)).trans (ord_card_le o)
protected theorem strict_mono (hf : IsFundamentalSequence a o f) {i j} :
∀ hi hj, i < j → f i hi < f j hj :=
hf.2.1
theorem blsub_eq (hf : IsFundamentalSequence a o f) : blsub.{u, u} o f = a :=
hf.2.2
theorem ord_cof (hf : IsFundamentalSequence a o f) :
IsFundamentalSequence a a.cof.ord fun i hi => f i (hi.trans_le (by rw [hf.cof_eq])) := by
have H := hf.cof_eq
subst H
exact hf
theorem id_of_le_cof (h : o ≤ o.cof.ord) : IsFundamentalSequence o o fun a _ => a :=
⟨h, @fun _ _ _ _ => id, blsub_id o⟩
protected theorem zero {f : ∀ b < (0 : Ordinal), Ordinal} : IsFundamentalSequence 0 0 f :=
⟨by rw [cof_zero, ord_zero], @fun i _ hi => (Ordinal.not_lt_zero i hi).elim, blsub_zero f⟩
protected theorem succ : IsFundamentalSequence (succ o) 1 fun _ _ => o := by
refine ⟨?_, @fun i j hi hj h => ?_, blsub_const Ordinal.one_ne_zero o⟩
· rw [cof_succ, ord_one]
· rw [lt_one_iff_zero] at hi hj
rw [hi, hj] at h
exact h.false.elim
protected theorem monotone (hf : IsFundamentalSequence a o f) {i j : Ordinal} (hi : i < o)
(hj : j < o) (hij : i ≤ j) : f i hi ≤ f j hj := by
rcases lt_or_eq_of_le hij with (hij | rfl)
· exact (hf.2.1 hi hj hij).le
· rfl
theorem trans {a o o' : Ordinal.{u}} {f : ∀ b < o, Ordinal.{u}} (hf : IsFundamentalSequence a o f)
{g : ∀ b < o', Ordinal.{u}} (hg : IsFundamentalSequence o o' g) :
IsFundamentalSequence a o' fun i hi =>
f (g i hi) (by rw [← hg.2.2]; apply lt_blsub) := by
refine ⟨?_, @fun i j _ _ h => hf.2.1 _ _ (hg.2.1 _ _ h), ?_⟩
· rw [hf.cof_eq]
exact hg.1.trans (ord_cof_le o)
· rw [@blsub_comp.{u, u, u} o _ f (@IsFundamentalSequence.monotone _ _ f hf)]
· exact hf.2.2
· exact hg.2.2
protected theorem lt {a o : Ordinal} {s : Π p < o, Ordinal}
(h : IsFundamentalSequence a o s) {p : Ordinal} (hp : p < o) : s p hp < a :=
h.blsub_eq ▸ lt_blsub s p hp
end IsFundamentalSequence
/-- Every ordinal has a fundamental sequence. -/
theorem exists_fundamental_sequence (a : Ordinal.{u}) :
∃ f, IsFundamentalSequence a a.cof.ord f := by
suffices h : ∃ o f, IsFundamentalSequence a o f by
rcases h with ⟨o, f, hf⟩
exact ⟨_, hf.ord_cof⟩
rcases exists_lsub_cof a with ⟨ι, f, hf, hι⟩
rcases ord_eq ι with ⟨r, wo, hr⟩
haveI := wo
let r' := Subrel r fun i ↦ ∀ j, r j i → f j < f i
let hrr' : r' ↪r r := Subrel.relEmbedding _ _
haveI := hrr'.isWellOrder
refine
⟨_, _, hrr'.ordinal_type_le.trans ?_, @fun i j _ h _ => (enum r' ⟨j, h⟩).prop _ ?_,
le_antisymm (blsub_le fun i hi => lsub_le_iff.1 hf.le _) ?_⟩
· rw [← hι, hr]
· change r (hrr'.1 _) (hrr'.1 _)
rwa [hrr'.2, @enum_lt_enum _ r']
· rw [← hf, lsub_le_iff]
intro i
suffices h : ∃ i' hi', f i ≤ bfamilyOfFamily' r' (fun i => f i) i' hi' by
rcases h with ⟨i', hi', hfg⟩
exact hfg.trans_lt (lt_blsub _ _ _)
by_cases h : ∀ j, r j i → f j < f i
· refine ⟨typein r' ⟨i, h⟩, typein_lt_type _ _, ?_⟩
rw [bfamilyOfFamily'_typein]
· push_neg at h
obtain ⟨hji, hij⟩ := wo.wf.min_mem _ h
refine ⟨typein r' ⟨_, fun k hkj => lt_of_lt_of_le ?_ hij⟩, typein_lt_type _ _, ?_⟩
· by_contra! H
exact (wo.wf.not_lt_min _ h ⟨IsTrans.trans _ _ _ hkj hji, H⟩) hkj
· rwa [bfamilyOfFamily'_typein]
@[simp]
theorem cof_cof (a : Ordinal.{u}) : cof (cof a).ord = cof a := by
obtain ⟨f, hf⟩ := exists_fundamental_sequence a
obtain ⟨g, hg⟩ := exists_fundamental_sequence a.cof.ord
exact ord_injective (hf.trans hg).cof_eq.symm
protected theorem IsNormal.isFundamentalSequence {f : Ordinal.{u} → Ordinal.{u}} (hf : IsNormal f)
{a o} (ha : IsLimit a) {g} (hg : IsFundamentalSequence a o g) :
IsFundamentalSequence (f a) o fun b hb => f (g b hb) := by
refine ⟨?_, @fun i j _ _ h => hf.strictMono (hg.2.1 _ _ h), ?_⟩
· rcases exists_lsub_cof (f a) with ⟨ι, f', hf', hι⟩
rw [← hg.cof_eq, ord_le_ord, ← hι]
suffices (lsub.{u, u} fun i => sInf { b : Ordinal | f' i ≤ f b }) = a by
rw [← this]
apply cof_lsub_le
have H : ∀ i, ∃ b < a, f' i ≤ f b := fun i => by
have := lt_lsub.{u, u} f' i
rw [hf', ← IsNormal.blsub_eq.{u, u} hf ha, lt_blsub_iff] at this
simpa using this
refine (lsub_le fun i => ?_).antisymm (le_of_forall_lt fun b hb => ?_)
· rcases H i with ⟨b, hb, hb'⟩
exact lt_of_le_of_lt (csInf_le' hb') hb
· have := hf.strictMono hb
rw [← hf', lt_lsub_iff] at this
obtain ⟨i, hi⟩ := this
rcases H i with ⟨b, _, hb⟩
exact
((le_csInf_iff'' ⟨b, by exact hb⟩).2 fun c hc =>
hf.strictMono.le_iff_le.1 (hi.trans hc)).trans_lt (lt_lsub _ i)
· rw [@blsub_comp.{u, u, u} a _ (fun b _ => f b) (@fun i j _ _ h => hf.strictMono.monotone h) g
hg.2.2]
exact IsNormal.blsub_eq.{u, u} hf ha
theorem IsNormal.cof_eq {f} (hf : IsNormal f) {a} (ha : IsLimit a) : cof (f a) = cof a :=
let ⟨_, hg⟩ := exists_fundamental_sequence a
ord_injective (hf.isFundamentalSequence ha hg).cof_eq
theorem IsNormal.cof_le {f} (hf : IsNormal f) (a) : cof a ≤ cof (f a) := by
rcases zero_or_succ_or_limit a with (rfl | ⟨b, rfl⟩ | ha)
· rw [cof_zero]
exact zero_le _
· rw [cof_succ, Cardinal.one_le_iff_ne_zero, cof_ne_zero, ← Ordinal.pos_iff_ne_zero]
exact (Ordinal.zero_le (f b)).trans_lt (hf.1 b)
· rw [hf.cof_eq ha]
@[simp]
theorem cof_add (a b : Ordinal) : b ≠ 0 → cof (a + b) = cof b := fun h => by
rcases zero_or_succ_or_limit b with (rfl | ⟨c, rfl⟩ | hb)
· contradiction
· rw [add_succ, cof_succ, cof_succ]
· exact (isNormal_add_right a).cof_eq hb
theorem aleph0_le_cof {o} : ℵ₀ ≤ cof o ↔ IsLimit o := by
rcases zero_or_succ_or_limit o with (rfl | ⟨o, rfl⟩ | l)
· simp [not_zero_isLimit, Cardinal.aleph0_ne_zero]
· simp [not_succ_isLimit, Cardinal.one_lt_aleph0]
· simp only [l, iff_true]
refine le_of_not_lt fun h => ?_
obtain ⟨n, e⟩ := Cardinal.lt_aleph0.1 h
have := cof_cof o
rw [e, ord_nat] at this
cases n
· simp at e
simp [e, not_zero_isLimit] at l
· rw [natCast_succ, cof_succ] at this
rw [← this, cof_eq_one_iff_is_succ] at e
rcases e with ⟨a, rfl⟩
exact not_succ_isLimit _ l
@[simp]
theorem cof_preOmega {o : Ordinal} (ho : IsSuccPrelimit o) : (preOmega o).cof = o.cof := by
by_cases h : IsMin o
· simp [h.eq_bot]
· exact isNormal_preOmega.cof_eq ⟨h, ho⟩
@[simp]
theorem cof_omega {o : Ordinal} (ho : o.IsLimit) : (ω_ o).cof = o.cof :=
isNormal_omega.cof_eq ho
@[simp]
theorem cof_omega0 : cof ω = ℵ₀ :=
(aleph0_le_cof.2 isLimit_omega0).antisymm' <| by
rw [← card_omega0]
apply cof_le_card
theorem cof_eq' (r : α → α → Prop) [IsWellOrder α r] (h : IsLimit (type r)) :
∃ S : Set α, (∀ a, ∃ b ∈ S, r a b) ∧ #S = cof (type r) :=
let ⟨S, H, e⟩ := cof_eq r
⟨S, fun a =>
let a' := enum r ⟨_, h.succ_lt (typein_lt_type r a)⟩
let ⟨b, h, ab⟩ := H a'
⟨b, h,
(IsOrderConnected.conn a b a' <|
(typein_lt_typein r).1
(by
rw [typein_enum]
exact lt_succ (typein _ _))).resolve_right
ab⟩,
e⟩
@[simp]
theorem cof_univ : cof univ.{u, v} = Cardinal.univ.{u, v} :=
le_antisymm (cof_le_card _)
(by
refine le_of_forall_lt fun c h => ?_
rcases lt_univ'.1 h with ⟨c, rfl⟩
rcases @cof_eq Ordinal.{u} (· < ·) _ with ⟨S, H, Se⟩
rw [univ, ← lift_cof, ← Cardinal.lift_lift.{u+1, v, u}, Cardinal.lift_lt, ← Se]
refine lt_of_not_ge fun h => ?_
obtain ⟨a, e⟩ := Cardinal.mem_range_lift_of_le h
refine Quotient.inductionOn a (fun α e => ?_) e
obtain ⟨f⟩ := Quotient.exact e
have f := Equiv.ulift.symm.trans f
let g a := (f a).1
let o := succ (iSup g)
rcases H o with ⟨b, h, l⟩
refine l (lt_succ_iff.2 ?_)
rw [← show g (f.symm ⟨b, h⟩) = b by simp [g]]
apply Ordinal.le_iSup)
end Ordinal
namespace Cardinal
open Ordinal
/-! ### Results on sets -/
theorem mk_bounded_subset {α : Type*} (h : ∀ x < #α, 2 ^ x < #α) {r : α → α → Prop}
[IsWellOrder α r] (hr : (#α).ord = type r) : #{ s : Set α // Bounded r s } = #α := by
rcases eq_or_ne #α 0 with (ha | ha)
· rw [ha]
haveI := mk_eq_zero_iff.1 ha
rw [mk_eq_zero_iff]
constructor
rintro ⟨s, hs⟩
exact (not_unbounded_iff s).2 hs (unbounded_of_isEmpty s)
have h' : IsStrongLimit #α := ⟨ha, @h⟩
have ha := h'.aleph0_le
apply le_antisymm
· have : { s : Set α | Bounded r s } = ⋃ i, 𝒫{ j | r j i } := setOf_exists _
rw [← coe_setOf, this]
refine mk_iUnion_le_sum_mk.trans ((sum_le_iSup (fun i => #(𝒫{ j | r j i }))).trans
((mul_le_max_of_aleph0_le_left ha).trans ?_))
rw [max_eq_left]
apply ciSup_le' _
intro i
rw [mk_powerset]
apply (h'.two_power_lt _).le
rw [coe_setOf, card_typein, ← lt_ord, hr]
apply typein_lt_type
· refine @mk_le_of_injective α _ (fun x => Subtype.mk {x} ?_) ?_
· apply bounded_singleton
rw [← hr]
apply isLimit_ord ha
· intro a b hab
simpa [singleton_eq_singleton_iff] using hab
theorem mk_subset_mk_lt_cof {α : Type*} (h : ∀ x < #α, 2 ^ x < #α) :
#{ s : Set α // #s < cof (#α).ord } = #α := by
rcases eq_or_ne #α 0 with (ha | ha)
· simp [ha]
have h' : IsStrongLimit #α := ⟨ha, @h⟩
rcases ord_eq α with ⟨r, wo, hr⟩
haveI := wo
apply le_antisymm
· conv_rhs => rw [← mk_bounded_subset h hr]
apply mk_le_mk_of_subset
intro s hs
rw [hr] at hs
exact lt_cof_type hs
· refine @mk_le_of_injective α _ (fun x => Subtype.mk {x} ?_) ?_
· rw [mk_singleton]
exact one_lt_aleph0.trans_le (aleph0_le_cof.2 (isLimit_ord h'.aleph0_le))
· intro a b hab
simpa [singleton_eq_singleton_iff] using hab
/-- If the union of s is unbounded and s is smaller than the cofinality,
then s has an unbounded member -/
theorem unbounded_of_unbounded_sUnion (r : α → α → Prop) [wo : IsWellOrder α r] {s : Set (Set α)}
(h₁ : Unbounded r <| ⋃₀ s) (h₂ : #s < Order.cof (swap rᶜ)) : ∃ x ∈ s, Unbounded r x := by
by_contra! h
simp_rw [not_unbounded_iff] at h
let f : s → α := fun x : s => wo.wf.sup x (h x.1 x.2)
refine h₂.not_le (le_trans (csInf_le' ⟨range f, fun x => ?_, rfl⟩) mk_range_le)
rcases h₁ x with ⟨y, ⟨c, hc, hy⟩, hxy⟩
exact ⟨f ⟨c, hc⟩, mem_range_self _, fun hxz => hxy (Trans.trans (wo.wf.lt_sup _ hy) hxz)⟩
/-- If the union of s is unbounded and s is smaller than the cofinality,
then s has an unbounded member -/
theorem unbounded_of_unbounded_iUnion {α β : Type u} (r : α → α → Prop) [wo : IsWellOrder α r]
(s : β → Set α) (h₁ : Unbounded r <| ⋃ x, s x) (h₂ : #β < Order.cof (swap rᶜ)) :
∃ x : β, Unbounded r (s x) := by
rw [← sUnion_range] at h₁
rcases unbounded_of_unbounded_sUnion r h₁ (mk_range_le.trans_lt h₂) with ⟨_, ⟨x, rfl⟩, u⟩
exact ⟨x, u⟩
/-! ### Consequences of König's lemma -/
theorem lt_power_cof {c : Cardinal.{u}} : ℵ₀ ≤ c → c < c ^ c.ord.cof :=
Cardinal.inductionOn c fun α h => by
rcases ord_eq α with ⟨r, wo, re⟩
have := isLimit_ord h
rw [re] at this ⊢
rcases cof_eq' r this with ⟨S, H, Se⟩
have := sum_lt_prod (fun a : S => #{ x // r x a }) (fun _ => #α) fun i => ?_
· simp only [Cardinal.prod_const, Cardinal.lift_id, ← Se, ← mk_sigma, power_def] at this ⊢
refine lt_of_le_of_lt ?_ this
refine ⟨Embedding.ofSurjective ?_ ?_⟩
· exact fun x => x.2.1
· exact fun a =>
let ⟨b, h, ab⟩ := H a
⟨⟨⟨_, h⟩, _, ab⟩, rfl⟩
· have := typein_lt_type r i
rwa [← re, lt_ord] at this
theorem lt_cof_power {a b : Cardinal} (ha : ℵ₀ ≤ a) (b1 : 1 < b) : a < (b ^ a).ord.cof := by
have b0 : b ≠ 0 := (zero_lt_one.trans b1).ne'
apply lt_imp_lt_of_le_imp_le (power_le_power_left <| power_ne_zero a b0)
rw [← power_mul, mul_eq_self ha]
exact lt_power_cof (ha.trans <| (cantor' _ b1).le)
end Cardinal
| Mathlib/SetTheory/Cardinal/Cofinality.lean | 975 | 994 | |
/-
Copyright (c) 2019 Sébastien Gouëzel. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Sébastien Gouëzel
-/
import Mathlib.Analysis.Analytic.Within
import Mathlib.Analysis.Calculus.FDeriv.Analytic
import Mathlib.Analysis.Calculus.ContDiff.FTaylorSeries
/-!
# Higher differentiability
A function is `C^1` on a domain if it is differentiable there, and its derivative is continuous.
By induction, it is `C^n` if it is `C^{n-1}` and its (n-1)-th derivative is `C^1` there or,
equivalently, if it is `C^1` and its derivative is `C^{n-1}`.
It is `C^∞` if it is `C^n` for all n.
Finally, it is `C^ω` if it is analytic (as well as all its derivative, which is automatic if the
space is complete).
We formalize these notions with predicates `ContDiffWithinAt`, `ContDiffAt`, `ContDiffOn` and
`ContDiff` saying that the function is `C^n` within a set at a point, at a point, on a set
and on the whole space respectively.
To avoid the issue of choice when choosing a derivative in sets where the derivative is not
necessarily unique, `ContDiffOn` is not defined directly in terms of the
regularity of the specific choice `iteratedFDerivWithin 𝕜 n f s` inside `s`, but in terms of the
existence of a nice sequence of derivatives, expressed with a predicate
`HasFTaylorSeriesUpToOn` defined in the file `FTaylorSeries`.
We prove basic properties of these notions.
## Main definitions and results
Let `f : E → F` be a map between normed vector spaces over a nontrivially normed field `𝕜`.
* `ContDiff 𝕜 n f`: expresses that `f` is `C^n`, i.e., it admits a Taylor series up to
rank `n`.
* `ContDiffOn 𝕜 n f s`: expresses that `f` is `C^n` in `s`.
* `ContDiffAt 𝕜 n f x`: expresses that `f` is `C^n` around `x`.
* `ContDiffWithinAt 𝕜 n f s x`: expresses that `f` is `C^n` around `x` within the set `s`.
In sets of unique differentiability, `ContDiffOn 𝕜 n f s` can be expressed in terms of the
properties of `iteratedFDerivWithin 𝕜 m f s` for `m ≤ n`. In the whole space,
`ContDiff 𝕜 n f` can be expressed in terms of the properties of `iteratedFDeriv 𝕜 m f`
for `m ≤ n`.
## Implementation notes
The definitions in this file are designed to work on any field `𝕜`. They are sometimes slightly more
complicated than the naive definitions one would guess from the intuition over the real or complex
numbers, but they are designed to circumvent the lack of gluing properties and partitions of unity
in general. In the usual situations, they coincide with the usual definitions.
### Definition of `C^n` functions in domains
One could define `C^n` functions in a domain `s` by fixing an arbitrary choice of derivatives (this
is what we do with `iteratedFDerivWithin`) and requiring that all these derivatives up to `n` are
continuous. If the derivative is not unique, this could lead to strange behavior like two `C^n`
functions `f` and `g` on `s` whose sum is not `C^n`. A better definition is thus to say that a
function is `C^n` inside `s` if it admits a sequence of derivatives up to `n` inside `s`.
This definition still has the problem that a function which is locally `C^n` would not need to
be `C^n`, as different choices of sequences of derivatives around different points might possibly
not be glued together to give a globally defined sequence of derivatives. (Note that this issue
can not happen over reals, thanks to partition of unity, but the behavior over a general field is
not so clear, and we want a definition for general fields). Also, there are locality
problems for the order parameter: one could image a function which, for each `n`, has a nice
sequence of derivatives up to order `n`, but they do not coincide for varying `n` and can therefore
not be glued to give rise to an infinite sequence of derivatives. This would give a function
which is `C^n` for all `n`, but not `C^∞`. We solve this issue by putting locality conditions
in space and order in our definition of `ContDiffWithinAt` and `ContDiffOn`.
The resulting definition is slightly more complicated to work with (in fact not so much), but it
gives rise to completely satisfactory theorems.
For instance, with this definition, a real function which is `C^m` (but not better) on `(-1/m, 1/m)`
for each natural `m` is by definition `C^∞` at `0`.
There is another issue with the definition of `ContDiffWithinAt 𝕜 n f s x`. We can
require the existence and good behavior of derivatives up to order `n` on a neighborhood of `x`
within `s`. However, this does not imply continuity or differentiability within `s` of the function
at `x` when `x` does not belong to `s`. Therefore, we require such existence and good behavior on
a neighborhood of `x` within `s ∪ {x}` (which appears as `insert x s` in this file).
## Notations
We use the notation `E [×n]→L[𝕜] F` for the space of continuous multilinear maps on `E^n` with
values in `F`. This is the space in which the `n`-th derivative of a function from `E` to `F` lives.
In this file, we denote `(⊤ : ℕ∞) : WithTop ℕ∞` with `∞`, and `⊤ : WithTop ℕ∞` with `ω`. To
avoid ambiguities with the two tops, the theorems name use either `infty` or `omega`.
These notations are scoped in `ContDiff`.
## Tags
derivative, differentiability, higher derivative, `C^n`, multilinear, Taylor series, formal series
-/
noncomputable section
open Set Fin Filter Function
open scoped NNReal Topology ContDiff
universe u uE uF uG uX
variable {𝕜 : Type u} [NontriviallyNormedField 𝕜] {E : Type uE} [NormedAddCommGroup E]
[NormedSpace 𝕜 E] {F : Type uF} [NormedAddCommGroup F] [NormedSpace 𝕜 F] {G : Type uG}
[NormedAddCommGroup G] [NormedSpace 𝕜 G] {X : Type uX} [NormedAddCommGroup X] [NormedSpace 𝕜 X]
{s s₁ t u : Set E} {f f₁ : E → F} {g : F → G} {x x₀ : E} {c : F} {m n : WithTop ℕ∞}
{p : E → FormalMultilinearSeries 𝕜 E F}
/-! ### Smooth functions within a set around a point -/
variable (𝕜) in
/-- A function is continuously differentiable up to order `n` within a set `s` at a point `x` if
it admits continuous derivatives up to order `n` in a neighborhood of `x` in `s ∪ {x}`.
For `n = ∞`, we only require that this holds up to any finite order (where the neighborhood may
depend on the finite order we consider).
For `n = ω`, we require the function to be analytic within `s` at `x`. The precise definition we
give (all the derivatives should be analytic) is more involved to work around issues when the space
is not complete, but it is equivalent when the space is complete.
For instance, a real function which is `C^m` on `(-1/m, 1/m)` for each natural `m`, but not
better, is `C^∞` at `0` within `univ`.
-/
def ContDiffWithinAt (n : WithTop ℕ∞) (f : E → F) (s : Set E) (x : E) : Prop :=
match n with
| ω => ∃ u ∈ 𝓝[insert x s] x, ∃ p : E → FormalMultilinearSeries 𝕜 E F,
HasFTaylorSeriesUpToOn ω f p u ∧ ∀ i, AnalyticOn 𝕜 (fun x ↦ p x i) u
| (n : ℕ∞) => ∀ m : ℕ, m ≤ n → ∃ u ∈ 𝓝[insert x s] x,
∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn m f p u
lemma HasFTaylorSeriesUpToOn.analyticOn
(hf : HasFTaylorSeriesUpToOn ω f p s) (h : AnalyticOn 𝕜 (fun x ↦ p x 0) s) :
AnalyticOn 𝕜 f s := by
have : AnalyticOn 𝕜 (fun x ↦ (continuousMultilinearCurryFin0 𝕜 E F) (p x 0)) s :=
(LinearIsometryEquiv.analyticOnNhd _ _ ).comp_analyticOn
h (Set.mapsTo_univ _ _)
exact this.congr (fun y hy ↦ (hf.zero_eq _ hy).symm)
lemma ContDiffWithinAt.analyticOn (h : ContDiffWithinAt 𝕜 ω f s x) :
∃ u ∈ 𝓝[insert x s] x, AnalyticOn 𝕜 f u := by
obtain ⟨u, hu, p, hp, h'p⟩ := h
exact ⟨u, hu, hp.analyticOn (h'p 0)⟩
lemma ContDiffWithinAt.analyticWithinAt (h : ContDiffWithinAt 𝕜 ω f s x) :
AnalyticWithinAt 𝕜 f s x := by
obtain ⟨u, hu, hf⟩ := h.analyticOn
have xu : x ∈ u := mem_of_mem_nhdsWithin (by simp) hu
exact (hf x xu).mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert _ _) hu)
theorem contDiffWithinAt_omega_iff_analyticWithinAt [CompleteSpace F] :
ContDiffWithinAt 𝕜 ω f s x ↔ AnalyticWithinAt 𝕜 f s x := by
refine ⟨fun h ↦ h.analyticWithinAt, fun h ↦ ?_⟩
obtain ⟨u, hu, p, hp, h'p⟩ := h.exists_hasFTaylorSeriesUpToOn ω
exact ⟨u, hu, p, hp.of_le le_top, fun i ↦ h'p i⟩
theorem contDiffWithinAt_nat {n : ℕ} :
ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x,
∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn n f p u :=
⟨fun H => H n le_rfl, fun ⟨u, hu, p, hp⟩ _m hm => ⟨u, hu, p, hp.of_le (mod_cast hm)⟩⟩
/-- When `n` is either a natural number or `ω`, one can characterize the property of being `C^n`
as the existence of a neighborhood on which there is a Taylor series up to order `n`,
requiring in addition that its terms are analytic in the `ω` case. -/
lemma contDiffWithinAt_iff_of_ne_infty (hn : n ≠ ∞) :
ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x,
∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpToOn n f p u ∧
(n = ω → ∀ i, AnalyticOn 𝕜 (fun x ↦ p x i) u) := by
match n with
| ω => simp [ContDiffWithinAt]
| ∞ => simp at hn
| (n : ℕ) => simp [contDiffWithinAt_nat]
theorem ContDiffWithinAt.of_le (h : ContDiffWithinAt 𝕜 n f s x) (hmn : m ≤ n) :
ContDiffWithinAt 𝕜 m f s x := by
match n with
| ω => match m with
| ω => exact h
| (m : ℕ∞) =>
intro k _
obtain ⟨u, hu, p, hp, -⟩ := h
exact ⟨u, hu, p, hp.of_le le_top⟩
| (n : ℕ∞) => match m with
| ω => simp at hmn
| (m : ℕ∞) => exact fun k hk ↦ h k (le_trans hk (mod_cast hmn))
/-- In a complete space, a function which is analytic within a set at a point is also `C^ω` there.
Note that the same statement for `AnalyticOn` does not require completeness, see
`AnalyticOn.contDiffOn`. -/
theorem AnalyticWithinAt.contDiffWithinAt [CompleteSpace F] (h : AnalyticWithinAt 𝕜 f s x) :
ContDiffWithinAt 𝕜 n f s x :=
(contDiffWithinAt_omega_iff_analyticWithinAt.2 h).of_le le_top
theorem contDiffWithinAt_iff_forall_nat_le {n : ℕ∞} :
ContDiffWithinAt 𝕜 n f s x ↔ ∀ m : ℕ, ↑m ≤ n → ContDiffWithinAt 𝕜 m f s x :=
⟨fun H _ hm => H.of_le (mod_cast hm), fun H m hm => H m hm _ le_rfl⟩
theorem contDiffWithinAt_infty :
ContDiffWithinAt 𝕜 ∞ f s x ↔ ∀ n : ℕ, ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_iff_forall_nat_le.trans <| by simp only [forall_prop_of_true, le_top]
@[deprecated (since := "2024-11-25")] alias contDiffWithinAt_top := contDiffWithinAt_infty
theorem ContDiffWithinAt.continuousWithinAt (h : ContDiffWithinAt 𝕜 n f s x) :
ContinuousWithinAt f s x := by
have := h.of_le (zero_le _)
simp only [ContDiffWithinAt, nonpos_iff_eq_zero, Nat.cast_eq_zero,
mem_pure, forall_eq, CharP.cast_eq_zero] at this
rcases this with ⟨u, hu, p, H⟩
rw [mem_nhdsWithin_insert] at hu
exact (H.continuousOn.continuousWithinAt hu.1).mono_of_mem_nhdsWithin hu.2
theorem ContDiffWithinAt.congr_of_eventuallyEq (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s x := by
match n with
| ω =>
obtain ⟨u, hu, p, H, H'⟩ := h
exact ⟨{x ∈ u | f₁ x = f x}, Filter.inter_mem hu (mem_nhdsWithin_insert.2 ⟨hx, h₁⟩), p,
(H.mono (sep_subset _ _)).congr fun _ ↦ And.right,
fun i ↦ (H' i).mono (sep_subset _ _)⟩
| (n : ℕ∞) =>
intro m hm
let ⟨u, hu, p, H⟩ := h m hm
exact ⟨{ x ∈ u | f₁ x = f x }, Filter.inter_mem hu (mem_nhdsWithin_insert.2 ⟨hx, h₁⟩), p,
(H.mono (sep_subset _ _)).congr fun _ ↦ And.right⟩
theorem Filter.EventuallyEq.congr_contDiffWithinAt (h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : f₁ x = f x) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun H ↦ H.congr_of_eventuallyEq h₁.symm hx.symm, fun H ↦ H.congr_of_eventuallyEq h₁ hx⟩
theorem ContDiffWithinAt.congr_of_eventuallyEq_insert (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : f₁ =ᶠ[𝓝[insert x s] x] f) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr_of_eventuallyEq (nhdsWithin_mono x (subset_insert x s) h₁)
(mem_of_mem_nhdsWithin (mem_insert x s) h₁ :)
theorem Filter.EventuallyEq.congr_contDiffWithinAt_of_insert (h₁ : f₁ =ᶠ[𝓝[insert x s] x] f) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun H ↦ H.congr_of_eventuallyEq_insert h₁.symm, fun H ↦ H.congr_of_eventuallyEq_insert h₁⟩
theorem ContDiffWithinAt.congr_of_eventuallyEq_of_mem (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : x ∈ s) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr_of_eventuallyEq h₁ <| h₁.self_of_nhdsWithin hx
theorem Filter.EventuallyEq.congr_contDiffWithinAt_of_mem (h₁ : f₁ =ᶠ[𝓝[s] x] f) (hx : x ∈ s):
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun H ↦ H.congr_of_eventuallyEq_of_mem h₁.symm hx, fun H ↦ H.congr_of_eventuallyEq_of_mem h₁ hx⟩
theorem ContDiffWithinAt.congr (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : ∀ y ∈ s, f₁ y = f y)
(hx : f₁ x = f x) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr_of_eventuallyEq (Filter.eventuallyEq_of_mem self_mem_nhdsWithin h₁) hx
theorem contDiffWithinAt_congr (h₁ : ∀ y ∈ s, f₁ y = f y) (hx : f₁ x = f x) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
⟨fun h' ↦ h'.congr (fun x hx ↦ (h₁ x hx).symm) hx.symm, fun h' ↦ h'.congr h₁ hx⟩
theorem ContDiffWithinAt.congr_of_mem (h : ContDiffWithinAt 𝕜 n f s x) (h₁ : ∀ y ∈ s, f₁ y = f y)
(hx : x ∈ s) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr h₁ (h₁ _ hx)
theorem contDiffWithinAt_congr_of_mem (h₁ : ∀ y ∈ s, f₁ y = f y) (hx : x ∈ s) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_congr h₁ (h₁ x hx)
theorem ContDiffWithinAt.congr_of_insert (h : ContDiffWithinAt 𝕜 n f s x)
(h₁ : ∀ y ∈ insert x s, f₁ y = f y) : ContDiffWithinAt 𝕜 n f₁ s x :=
h.congr (fun y hy ↦ h₁ y (mem_insert_of_mem _ hy)) (h₁ x (mem_insert _ _))
theorem contDiffWithinAt_congr_of_insert (h₁ : ∀ y ∈ insert x s, f₁ y = f y) :
ContDiffWithinAt 𝕜 n f₁ s x ↔ ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_congr (fun y hy ↦ h₁ y (mem_insert_of_mem _ hy)) (h₁ x (mem_insert _ _))
theorem ContDiffWithinAt.mono_of_mem_nhdsWithin (h : ContDiffWithinAt 𝕜 n f s x) {t : Set E}
(hst : s ∈ 𝓝[t] x) : ContDiffWithinAt 𝕜 n f t x := by
match n with
| ω =>
obtain ⟨u, hu, p, H, H'⟩ := h
exact ⟨u, nhdsWithin_le_of_mem (insert_mem_nhdsWithin_insert hst) hu, p, H, H'⟩
| (n : ℕ∞) =>
intro m hm
rcases h m hm with ⟨u, hu, p, H⟩
exact ⟨u, nhdsWithin_le_of_mem (insert_mem_nhdsWithin_insert hst) hu, p, H⟩
@[deprecated (since := "2024-10-30")]
alias ContDiffWithinAt.mono_of_mem := ContDiffWithinAt.mono_of_mem_nhdsWithin
theorem ContDiffWithinAt.mono (h : ContDiffWithinAt 𝕜 n f s x) {t : Set E} (hst : t ⊆ s) :
ContDiffWithinAt 𝕜 n f t x :=
h.mono_of_mem_nhdsWithin <| Filter.mem_of_superset self_mem_nhdsWithin hst
theorem ContDiffWithinAt.congr_mono
(h : ContDiffWithinAt 𝕜 n f s x) (h' : EqOn f₁ f s₁) (h₁ : s₁ ⊆ s) (hx : f₁ x = f x) :
ContDiffWithinAt 𝕜 n f₁ s₁ x :=
(h.mono h₁).congr h' hx
theorem ContDiffWithinAt.congr_set (h : ContDiffWithinAt 𝕜 n f s x) {t : Set E}
(hst : s =ᶠ[𝓝 x] t) : ContDiffWithinAt 𝕜 n f t x := by
rw [← nhdsWithin_eq_iff_eventuallyEq] at hst
apply h.mono_of_mem_nhdsWithin <| hst ▸ self_mem_nhdsWithin
@[deprecated (since := "2024-10-23")]
alias ContDiffWithinAt.congr_nhds := ContDiffWithinAt.congr_set
theorem contDiffWithinAt_congr_set {t : Set E} (hst : s =ᶠ[𝓝 x] t) :
ContDiffWithinAt 𝕜 n f s x ↔ ContDiffWithinAt 𝕜 n f t x :=
⟨fun h => h.congr_set hst, fun h => h.congr_set hst.symm⟩
@[deprecated (since := "2024-10-23")]
alias contDiffWithinAt_congr_nhds := contDiffWithinAt_congr_set
theorem contDiffWithinAt_inter' (h : t ∈ 𝓝[s] x) :
ContDiffWithinAt 𝕜 n f (s ∩ t) x ↔ ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_congr_set (mem_nhdsWithin_iff_eventuallyEq.1 h).symm
theorem contDiffWithinAt_inter (h : t ∈ 𝓝 x) :
ContDiffWithinAt 𝕜 n f (s ∩ t) x ↔ ContDiffWithinAt 𝕜 n f s x :=
contDiffWithinAt_inter' (mem_nhdsWithin_of_mem_nhds h)
theorem contDiffWithinAt_insert_self :
ContDiffWithinAt 𝕜 n f (insert x s) x ↔ ContDiffWithinAt 𝕜 n f s x := by
match n with
| ω => simp [ContDiffWithinAt]
| (n : ℕ∞) => simp_rw [ContDiffWithinAt, insert_idem]
theorem contDiffWithinAt_insert {y : E} :
ContDiffWithinAt 𝕜 n f (insert y s) x ↔ ContDiffWithinAt 𝕜 n f s x := by
rcases eq_or_ne x y with (rfl | hx)
· exact contDiffWithinAt_insert_self
refine ⟨fun h ↦ h.mono (subset_insert _ _), fun h ↦ ?_⟩
apply h.mono_of_mem_nhdsWithin
simp [nhdsWithin_insert_of_ne hx, self_mem_nhdsWithin]
alias ⟨ContDiffWithinAt.of_insert, ContDiffWithinAt.insert'⟩ := contDiffWithinAt_insert
protected theorem ContDiffWithinAt.insert (h : ContDiffWithinAt 𝕜 n f s x) :
ContDiffWithinAt 𝕜 n f (insert x s) x :=
h.insert'
theorem contDiffWithinAt_diff_singleton {y : E} :
ContDiffWithinAt 𝕜 n f (s \ {y}) x ↔ ContDiffWithinAt 𝕜 n f s x := by
rw [← contDiffWithinAt_insert, insert_diff_singleton, contDiffWithinAt_insert]
/-- If a function is `C^n` within a set at a point, with `n ≥ 1`, then it is differentiable
within this set at this point. -/
theorem ContDiffWithinAt.differentiableWithinAt' (h : ContDiffWithinAt 𝕜 n f s x) (hn : 1 ≤ n) :
DifferentiableWithinAt 𝕜 f (insert x s) x := by
rcases contDiffWithinAt_nat.1 (h.of_le hn) with ⟨u, hu, p, H⟩
rcases mem_nhdsWithin.1 hu with ⟨t, t_open, xt, tu⟩
rw [inter_comm] at tu
exact (differentiableWithinAt_inter (IsOpen.mem_nhds t_open xt)).1 <|
((H.mono tu).differentiableOn le_rfl) x ⟨mem_insert x s, xt⟩
theorem ContDiffWithinAt.differentiableWithinAt (h : ContDiffWithinAt 𝕜 n f s x) (hn : 1 ≤ n) :
DifferentiableWithinAt 𝕜 f s x :=
(h.differentiableWithinAt' hn).mono (subset_insert x s)
/-- A function is `C^(n + 1)` on a domain iff locally, it has a derivative which is `C^n`
(and moreover the function is analytic when `n = ω`). -/
theorem contDiffWithinAt_succ_iff_hasFDerivWithinAt (hn : n ≠ ∞) :
ContDiffWithinAt 𝕜 (n + 1) f s x ↔ ∃ u ∈ 𝓝[insert x s] x, (n = ω → AnalyticOn 𝕜 f u) ∧
∃ f' : E → E →L[𝕜] F,
(∀ x ∈ u, HasFDerivWithinAt f (f' x) u x) ∧ ContDiffWithinAt 𝕜 n f' u x := by
have h'n : n + 1 ≠ ∞ := by simpa using hn
constructor
· intro h
rcases (contDiffWithinAt_iff_of_ne_infty h'n).1 h with ⟨u, hu, p, Hp, H'p⟩
refine ⟨u, hu, ?_, fun y => (continuousMultilinearCurryFin1 𝕜 E F) (p y 1),
fun y hy => Hp.hasFDerivWithinAt le_add_self hy, ?_⟩
· rintro rfl
exact Hp.analyticOn (H'p rfl 0)
apply (contDiffWithinAt_iff_of_ne_infty hn).2
refine ⟨u, ?_, fun y : E => (p y).shift, ?_⟩
· convert @self_mem_nhdsWithin _ _ x u
have : x ∈ insert x s := by simp
exact insert_eq_of_mem (mem_of_mem_nhdsWithin this hu)
· rw [hasFTaylorSeriesUpToOn_succ_iff_right] at Hp
refine ⟨Hp.2.2, ?_⟩
rintro rfl i
change AnalyticOn 𝕜
(fun x ↦ (continuousMultilinearCurryRightEquiv' 𝕜 i E F) (p x (i + 1))) u
apply (LinearIsometryEquiv.analyticOnNhd _ _).comp_analyticOn
?_ (Set.mapsTo_univ _ _)
exact H'p rfl _
· rintro ⟨u, hu, hf, f', f'_eq_deriv, Hf'⟩
rw [contDiffWithinAt_iff_of_ne_infty h'n]
rcases (contDiffWithinAt_iff_of_ne_infty hn).1 Hf' with ⟨v, hv, p', Hp', p'_an⟩
refine ⟨v ∩ u, ?_, fun x => (p' x).unshift (f x), ?_, ?_⟩
· apply Filter.inter_mem _ hu
apply nhdsWithin_le_of_mem hu
exact nhdsWithin_mono _ (subset_insert x u) hv
· rw [hasFTaylorSeriesUpToOn_succ_iff_right]
refine ⟨fun y _ => rfl, fun y hy => ?_, ?_⟩
· change
HasFDerivWithinAt (fun z => (continuousMultilinearCurryFin0 𝕜 E F).symm (f z))
(FormalMultilinearSeries.unshift (p' y) (f y) 1).curryLeft (v ∩ u) y
rw [← Function.comp_def _ f, LinearIsometryEquiv.comp_hasFDerivWithinAt_iff']
convert (f'_eq_deriv y hy.2).mono inter_subset_right
rw [← Hp'.zero_eq y hy.1]
ext z
change ((p' y 0) (init (@cons 0 (fun _ => E) z 0))) (@cons 0 (fun _ => E) z 0 (last 0)) =
((p' y 0) 0) z
congr
norm_num [eq_iff_true_of_subsingleton]
· convert (Hp'.mono inter_subset_left).congr fun x hx => Hp'.zero_eq x hx.1 using 1
· ext x y
change p' x 0 (init (@snoc 0 (fun _ : Fin 1 => E) 0 y)) y = p' x 0 0 y
rw [init_snoc]
· ext x k v y
change p' x k (init (@snoc k (fun _ : Fin k.succ => E) v y))
(@snoc k (fun _ : Fin k.succ => E) v y (last k)) = p' x k v y
rw [snoc_last, init_snoc]
· intro h i
simp only [WithTop.add_eq_top, WithTop.one_ne_top, or_false] at h
match i with
| 0 =>
simp only [FormalMultilinearSeries.unshift]
apply AnalyticOnNhd.comp_analyticOn _ ((hf h).mono inter_subset_right)
(Set.mapsTo_univ _ _)
exact LinearIsometryEquiv.analyticOnNhd _ _
| i + 1 =>
simp only [FormalMultilinearSeries.unshift, Nat.succ_eq_add_one]
apply AnalyticOnNhd.comp_analyticOn _ ((p'_an h i).mono inter_subset_left)
(Set.mapsTo_univ _ _)
exact LinearIsometryEquiv.analyticOnNhd _ _
/-- A version of `contDiffWithinAt_succ_iff_hasFDerivWithinAt` where all derivatives
are taken within the same set. -/
theorem contDiffWithinAt_succ_iff_hasFDerivWithinAt' (hn : n ≠ ∞) :
ContDiffWithinAt 𝕜 (n + 1) f s x ↔
∃ u ∈ 𝓝[insert x s] x, u ⊆ insert x s ∧ (n = ω → AnalyticOn 𝕜 f u) ∧
∃ f' : E → E →L[𝕜] F,
(∀ x ∈ u, HasFDerivWithinAt f (f' x) s x) ∧ ContDiffWithinAt 𝕜 n f' s x := by
refine ⟨fun hf => ?_, ?_⟩
· obtain ⟨u, hu, f_an, f', huf', hf'⟩ := (contDiffWithinAt_succ_iff_hasFDerivWithinAt hn).mp hf
obtain ⟨w, hw, hxw, hwu⟩ := mem_nhdsWithin.mp hu
rw [inter_comm] at hwu
refine ⟨insert x s ∩ w, inter_mem_nhdsWithin _ (hw.mem_nhds hxw), inter_subset_left, ?_, f',
fun y hy => ?_, ?_⟩
· intro h
apply (f_an h).mono hwu
· refine ((huf' y <| hwu hy).mono hwu).mono_of_mem_nhdsWithin ?_
refine mem_of_superset ?_ (inter_subset_inter_left _ (subset_insert _ _))
exact inter_mem_nhdsWithin _ (hw.mem_nhds hy.2)
· exact hf'.mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert _ _) hu)
· rw [← contDiffWithinAt_insert, contDiffWithinAt_succ_iff_hasFDerivWithinAt hn,
insert_eq_of_mem (mem_insert _ _)]
rintro ⟨u, hu, hus, f_an, f', huf', hf'⟩
exact ⟨u, hu, f_an, f', fun y hy => (huf' y hy).insert'.mono hus, hf'.insert.mono hus⟩
/-! ### Smooth functions within a set -/
variable (𝕜) in
/-- A function is continuously differentiable up to `n` on `s` if, for any point `x` in `s`, it
admits continuous derivatives up to order `n` on a neighborhood of `x` in `s`.
For `n = ∞`, we only require that this holds up to any finite order (where the neighborhood may
depend on the finite order we consider).
-/
def ContDiffOn (n : WithTop ℕ∞) (f : E → F) (s : Set E) : Prop :=
∀ x ∈ s, ContDiffWithinAt 𝕜 n f s x
theorem HasFTaylorSeriesUpToOn.contDiffOn {n : ℕ∞} {f' : E → FormalMultilinearSeries 𝕜 E F}
(hf : HasFTaylorSeriesUpToOn n f f' s) : ContDiffOn 𝕜 n f s := by
intro x hx m hm
use s
simp only [Set.insert_eq_of_mem hx, self_mem_nhdsWithin, true_and]
exact ⟨f', hf.of_le (mod_cast hm)⟩
theorem ContDiffOn.contDiffWithinAt (h : ContDiffOn 𝕜 n f s) (hx : x ∈ s) :
ContDiffWithinAt 𝕜 n f s x :=
h x hx
theorem ContDiffOn.of_le (h : ContDiffOn 𝕜 n f s) (hmn : m ≤ n) : ContDiffOn 𝕜 m f s := fun x hx =>
(h x hx).of_le hmn
theorem ContDiffWithinAt.contDiffOn' (hm : m ≤ n) (h' : m = ∞ → n = ω)
(h : ContDiffWithinAt 𝕜 n f s x) :
∃ u, IsOpen u ∧ x ∈ u ∧ ContDiffOn 𝕜 m f (insert x s ∩ u) := by
rcases eq_or_ne n ω with rfl | hn
· obtain ⟨t, ht, p, hp, h'p⟩ := h
rcases mem_nhdsWithin.1 ht with ⟨u, huo, hxu, hut⟩
rw [inter_comm] at hut
refine ⟨u, huo, hxu, ?_⟩
suffices ContDiffOn 𝕜 ω f (insert x s ∩ u) from this.of_le le_top
intro y hy
refine ⟨insert x s ∩ u, ?_, p, hp.mono hut, fun i ↦ (h'p i).mono hut⟩
simp only [insert_eq_of_mem, hy, self_mem_nhdsWithin]
· match m with
| ω => simp [hn] at hm
| ∞ => exact (hn (h' rfl)).elim
| (m : ℕ) =>
rcases contDiffWithinAt_nat.1 (h.of_le hm) with ⟨t, ht, p, hp⟩
rcases mem_nhdsWithin.1 ht with ⟨u, huo, hxu, hut⟩
rw [inter_comm] at hut
exact ⟨u, huo, hxu, (hp.mono hut).contDiffOn⟩
theorem ContDiffWithinAt.contDiffOn (hm : m ≤ n) (h' : m = ∞ → n = ω)
(h : ContDiffWithinAt 𝕜 n f s x) :
∃ u ∈ 𝓝[insert x s] x, u ⊆ insert x s ∧ ContDiffOn 𝕜 m f u := by
obtain ⟨_u, uo, xu, h⟩ := h.contDiffOn' hm h'
exact ⟨_, inter_mem_nhdsWithin _ (uo.mem_nhds xu), inter_subset_left, h⟩
theorem ContDiffOn.analyticOn (h : ContDiffOn 𝕜 ω f s) : AnalyticOn 𝕜 f s :=
fun x hx ↦ (h x hx).analyticWithinAt
/-- A function is `C^n` within a set at a point, for `n : ℕ`, if and only if it is `C^n` on
a neighborhood of this point. -/
theorem contDiffWithinAt_iff_contDiffOn_nhds (hn : n ≠ ∞) :
ContDiffWithinAt 𝕜 n f s x ↔ ∃ u ∈ 𝓝[insert x s] x, ContDiffOn 𝕜 n f u := by
refine ⟨fun h ↦ ?_, fun h ↦ ?_⟩
· rcases h.contDiffOn le_rfl (by simp [hn]) with ⟨u, hu, h'u⟩
exact ⟨u, hu, h'u.2⟩
· rcases h with ⟨u, u_mem, hu⟩
have : x ∈ u := mem_of_mem_nhdsWithin (mem_insert x s) u_mem
exact (hu x this).mono_of_mem_nhdsWithin (nhdsWithin_mono _ (subset_insert x s) u_mem)
protected theorem ContDiffWithinAt.eventually (h : ContDiffWithinAt 𝕜 n f s x) (hn : n ≠ ∞) :
∀ᶠ y in 𝓝[insert x s] x, ContDiffWithinAt 𝕜 n f s y := by
rcases h.contDiffOn le_rfl (by simp [hn]) with ⟨u, hu, _, hd⟩
have : ∀ᶠ y : E in 𝓝[insert x s] x, u ∈ 𝓝[insert x s] y ∧ y ∈ u :=
(eventually_eventually_nhdsWithin.2 hu).and hu
refine this.mono fun y hy => (hd y hy.2).mono_of_mem_nhdsWithin ?_
exact nhdsWithin_mono y (subset_insert _ _) hy.1
theorem ContDiffOn.of_succ (h : ContDiffOn 𝕜 (n + 1) f s) : ContDiffOn 𝕜 n f s :=
h.of_le le_self_add
theorem ContDiffOn.one_of_succ (h : ContDiffOn 𝕜 (n + 1) f s) : ContDiffOn 𝕜 1 f s :=
h.of_le le_add_self
theorem contDiffOn_iff_forall_nat_le {n : ℕ∞} :
ContDiffOn 𝕜 n f s ↔ ∀ m : ℕ, ↑m ≤ n → ContDiffOn 𝕜 m f s :=
⟨fun H _ hm => H.of_le (mod_cast hm), fun H x hx m hm => H m hm x hx m le_rfl⟩
theorem contDiffOn_infty : ContDiffOn 𝕜 ∞ f s ↔ ∀ n : ℕ, ContDiffOn 𝕜 n f s :=
contDiffOn_iff_forall_nat_le.trans <| by simp only [le_top, forall_prop_of_true]
@[deprecated (since := "2024-11-27")] alias contDiffOn_top := contDiffOn_infty
@[deprecated (since := "2024-11-27")]
alias contDiffOn_infty_iff_contDiffOn_omega := contDiffOn_infty
theorem contDiffOn_all_iff_nat :
(∀ (n : ℕ∞), ContDiffOn 𝕜 n f s) ↔ ∀ n : ℕ, ContDiffOn 𝕜 n f s := by
refine ⟨fun H n => H n, ?_⟩
rintro H (_ | n)
exacts [contDiffOn_infty.2 H, H n]
theorem ContDiffOn.continuousOn (h : ContDiffOn 𝕜 n f s) : ContinuousOn f s := fun x hx =>
(h x hx).continuousWithinAt
theorem ContDiffOn.congr (h : ContDiffOn 𝕜 n f s) (h₁ : ∀ x ∈ s, f₁ x = f x) :
ContDiffOn 𝕜 n f₁ s := fun x hx => (h x hx).congr h₁ (h₁ x hx)
theorem contDiffOn_congr (h₁ : ∀ x ∈ s, f₁ x = f x) : ContDiffOn 𝕜 n f₁ s ↔ ContDiffOn 𝕜 n f s :=
⟨fun H => H.congr fun x hx => (h₁ x hx).symm, fun H => H.congr h₁⟩
theorem ContDiffOn.mono (h : ContDiffOn 𝕜 n f s) {t : Set E} (hst : t ⊆ s) : ContDiffOn 𝕜 n f t :=
fun x hx => (h x (hst hx)).mono hst
theorem ContDiffOn.congr_mono (hf : ContDiffOn 𝕜 n f s) (h₁ : ∀ x ∈ s₁, f₁ x = f x) (hs : s₁ ⊆ s) :
ContDiffOn 𝕜 n f₁ s₁ :=
(hf.mono hs).congr h₁
/-- If a function is `C^n` on a set with `n ≥ 1`, then it is differentiable there. -/
theorem ContDiffOn.differentiableOn (h : ContDiffOn 𝕜 n f s) (hn : 1 ≤ n) :
DifferentiableOn 𝕜 f s := fun x hx => (h x hx).differentiableWithinAt hn
/-- If a function is `C^n` around each point in a set, then it is `C^n` on the set. -/
theorem contDiffOn_of_locally_contDiffOn
(h : ∀ x ∈ s, ∃ u, IsOpen u ∧ x ∈ u ∧ ContDiffOn 𝕜 n f (s ∩ u)) : ContDiffOn 𝕜 n f s := by
intro x xs
rcases h x xs with ⟨u, u_open, xu, hu⟩
apply (contDiffWithinAt_inter _).1 (hu x ⟨xs, xu⟩)
exact IsOpen.mem_nhds u_open xu
/-- A function is `C^(n + 1)` on a domain iff locally, it has a derivative which is `C^n`. -/
theorem contDiffOn_succ_iff_hasFDerivWithinAt (hn : n ≠ ∞) :
ContDiffOn 𝕜 (n + 1) f s ↔
∀ x ∈ s, ∃ u ∈ 𝓝[insert x s] x, (n = ω → AnalyticOn 𝕜 f u) ∧ ∃ f' : E → E →L[𝕜] F,
(∀ x ∈ u, HasFDerivWithinAt f (f' x) u x) ∧ ContDiffOn 𝕜 n f' u := by
constructor
· intro h x hx
rcases (contDiffWithinAt_succ_iff_hasFDerivWithinAt hn).1 (h x hx) with
⟨u, hu, f_an, f', hf', Hf'⟩
rcases Hf'.contDiffOn le_rfl (by simp [hn]) with ⟨v, vu, v'u, hv⟩
rw [insert_eq_of_mem hx] at hu ⊢
have xu : x ∈ u := mem_of_mem_nhdsWithin hx hu
rw [insert_eq_of_mem xu] at vu v'u
exact ⟨v, nhdsWithin_le_of_mem hu vu, fun h ↦ (f_an h).mono v'u, f',
fun y hy ↦ (hf' y (v'u hy)).mono v'u, hv⟩
· intro h x hx
rw [contDiffWithinAt_succ_iff_hasFDerivWithinAt hn]
rcases h x hx with ⟨u, u_nhbd, f_an, f', hu, hf'⟩
have : x ∈ u := mem_of_mem_nhdsWithin (mem_insert _ _) u_nhbd
exact ⟨u, u_nhbd, f_an, f', hu, hf' x this⟩
/-! ### Iterated derivative within a set -/
@[simp]
theorem contDiffOn_zero : ContDiffOn 𝕜 0 f s ↔ ContinuousOn f s := by
refine ⟨fun H => H.continuousOn, fun H => fun x hx m hm ↦ ?_⟩
have : (m : WithTop ℕ∞) = 0 := le_antisymm (mod_cast hm) bot_le
rw [this]
refine ⟨insert x s, self_mem_nhdsWithin, ftaylorSeriesWithin 𝕜 f s, ?_⟩
rw [hasFTaylorSeriesUpToOn_zero_iff]
exact ⟨by rwa [insert_eq_of_mem hx], fun x _ => by simp [ftaylorSeriesWithin]⟩
theorem contDiffWithinAt_zero (hx : x ∈ s) :
ContDiffWithinAt 𝕜 0 f s x ↔ ∃ u ∈ 𝓝[s] x, ContinuousOn f (s ∩ u) := by
constructor
· intro h
obtain ⟨u, H, p, hp⟩ := h 0 le_rfl
refine ⟨u, ?_, ?_⟩
· simpa [hx] using H
· simp only [Nat.cast_zero, hasFTaylorSeriesUpToOn_zero_iff] at hp
exact hp.1.mono inter_subset_right
· rintro ⟨u, H, hu⟩
rw [← contDiffWithinAt_inter' H]
have h' : x ∈ s ∩ u := ⟨hx, mem_of_mem_nhdsWithin hx H⟩
exact (contDiffOn_zero.mpr hu).contDiffWithinAt h'
/-- When a function is `C^n` in a set `s` of unique differentiability, it admits
`ftaylorSeriesWithin 𝕜 f s` as a Taylor series up to order `n` in `s`. -/
protected theorem ContDiffOn.ftaylorSeriesWithin
(h : ContDiffOn 𝕜 n f s) (hs : UniqueDiffOn 𝕜 s) :
HasFTaylorSeriesUpToOn n f (ftaylorSeriesWithin 𝕜 f s) s := by
constructor
· intro x _
simp only [ftaylorSeriesWithin, ContinuousMultilinearMap.curry0_apply,
iteratedFDerivWithin_zero_apply]
· intro m hm x hx
have : (m + 1 : ℕ) ≤ n := ENat.add_one_natCast_le_withTop_of_lt hm
rcases (h x hx).of_le this _ le_rfl with ⟨u, hu, p, Hp⟩
rw [insert_eq_of_mem hx] at hu
rcases mem_nhdsWithin.1 hu with ⟨o, o_open, xo, ho⟩
rw [inter_comm] at ho
have : p x m.succ = ftaylorSeriesWithin 𝕜 f s x m.succ := by
change p x m.succ = iteratedFDerivWithin 𝕜 m.succ f s x
rw [← iteratedFDerivWithin_inter_open o_open xo]
exact (Hp.mono ho).eq_iteratedFDerivWithin_of_uniqueDiffOn le_rfl (hs.inter o_open) ⟨hx, xo⟩
rw [← this, ← hasFDerivWithinAt_inter (IsOpen.mem_nhds o_open xo)]
have A : ∀ y ∈ s ∩ o, p y m = ftaylorSeriesWithin 𝕜 f s y m := by
rintro y ⟨hy, yo⟩
change p y m = iteratedFDerivWithin 𝕜 m f s y
rw [← iteratedFDerivWithin_inter_open o_open yo]
exact
(Hp.mono ho).eq_iteratedFDerivWithin_of_uniqueDiffOn (mod_cast Nat.le_succ m)
(hs.inter o_open) ⟨hy, yo⟩
exact
((Hp.mono ho).fderivWithin m (mod_cast lt_add_one m) x ⟨hx, xo⟩).congr
(fun y hy => (A y hy).symm) (A x ⟨hx, xo⟩).symm
· intro m hm
apply continuousOn_of_locally_continuousOn
intro x hx
rcases (h x hx).of_le hm _ le_rfl with ⟨u, hu, p, Hp⟩
rcases mem_nhdsWithin.1 hu with ⟨o, o_open, xo, ho⟩
rw [insert_eq_of_mem hx] at ho
rw [inter_comm] at ho
refine ⟨o, o_open, xo, ?_⟩
have A : ∀ y ∈ s ∩ o, p y m = ftaylorSeriesWithin 𝕜 f s y m := by
rintro y ⟨hy, yo⟩
change p y m = iteratedFDerivWithin 𝕜 m f s y
rw [← iteratedFDerivWithin_inter_open o_open yo]
exact (Hp.mono ho).eq_iteratedFDerivWithin_of_uniqueDiffOn le_rfl (hs.inter o_open) ⟨hy, yo⟩
exact ((Hp.mono ho).cont m le_rfl).congr fun y hy => (A y hy).symm
theorem iteratedFDerivWithin_subset {n : ℕ} (st : s ⊆ t) (hs : UniqueDiffOn 𝕜 s)
(ht : UniqueDiffOn 𝕜 t) (h : ContDiffOn 𝕜 n f t) (hx : x ∈ s) :
iteratedFDerivWithin 𝕜 n f s x = iteratedFDerivWithin 𝕜 n f t x :=
(((h.ftaylorSeriesWithin ht).mono st).eq_iteratedFDerivWithin_of_uniqueDiffOn le_rfl hs hx).symm
theorem ContDiffWithinAt.eventually_hasFTaylorSeriesUpToOn {f : E → F} {s : Set E} {a : E}
(h : ContDiffWithinAt 𝕜 n f s a) (hs : UniqueDiffOn 𝕜 s) (ha : a ∈ s) {m : ℕ} (hm : m ≤ n) :
∀ᶠ t in (𝓝[s] a).smallSets, HasFTaylorSeriesUpToOn m f (ftaylorSeriesWithin 𝕜 f s) t := by
rcases h.contDiffOn' hm (by simp) with ⟨U, hUo, haU, hfU⟩
have : ∀ᶠ t in (𝓝[s] a).smallSets, t ⊆ s ∩ U := by
rw [eventually_smallSets_subset]
exact inter_mem_nhdsWithin _ <| hUo.mem_nhds haU
refine this.mono fun t ht ↦ .mono ?_ ht
rw [insert_eq_of_mem ha] at hfU
refine (hfU.ftaylorSeriesWithin (hs.inter hUo)).congr_series fun k hk x hx ↦ ?_
exact iteratedFDerivWithin_inter_open hUo hx.2
/-- On a set with unique differentiability, an analytic function is automatically `C^ω`, as its
successive derivatives are also analytic. This does not require completeness of the space. See
also `AnalyticOn.contDiffOn_of_completeSpace`. -/
theorem AnalyticOn.contDiffOn (h : AnalyticOn 𝕜 f s) (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 n f s := by
suffices ContDiffOn 𝕜 ω f s from this.of_le le_top
rcases h.exists_hasFTaylorSeriesUpToOn hs with ⟨p, hp⟩
intro x hx
refine ⟨s, ?_, p, hp⟩
rw [insert_eq_of_mem hx]
exact self_mem_nhdsWithin
/-- On a set with unique differentiability, an analytic function is automatically `C^ω`, as its
successive derivatives are also analytic. This does not require completeness of the space. See
also `AnalyticOnNhd.contDiffOn_of_completeSpace`. -/
theorem AnalyticOnNhd.contDiffOn (h : AnalyticOnNhd 𝕜 f s) (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 n f s := h.analyticOn.contDiffOn hs
/-- An analytic function is automatically `C^ω` in a complete space -/
theorem AnalyticOn.contDiffOn_of_completeSpace [CompleteSpace F] (h : AnalyticOn 𝕜 f s) :
ContDiffOn 𝕜 n f s :=
fun x hx ↦ (h x hx).contDiffWithinAt
/-- An analytic function is automatically `C^ω` in a complete space -/
theorem AnalyticOnNhd.contDiffOn_of_completeSpace [CompleteSpace F] (h : AnalyticOnNhd 𝕜 f s) :
ContDiffOn 𝕜 n f s :=
h.analyticOn.contDiffOn_of_completeSpace
theorem contDiffOn_of_continuousOn_differentiableOn {n : ℕ∞}
(Hcont : ∀ m : ℕ, m ≤ n → ContinuousOn (fun x => iteratedFDerivWithin 𝕜 m f s x) s)
(Hdiff : ∀ m : ℕ, m < n →
DifferentiableOn 𝕜 (fun x => iteratedFDerivWithin 𝕜 m f s x) s) :
ContDiffOn 𝕜 n f s := by
intro x hx m hm
rw [insert_eq_of_mem hx]
refine ⟨s, self_mem_nhdsWithin, ftaylorSeriesWithin 𝕜 f s, ?_⟩
constructor
· intro y _
simp only [ftaylorSeriesWithin, ContinuousMultilinearMap.curry0_apply,
iteratedFDerivWithin_zero_apply]
· intro k hk y hy
convert (Hdiff k (lt_of_lt_of_le (mod_cast hk) (mod_cast hm)) y hy).hasFDerivWithinAt
· intro k hk
exact Hcont k (le_trans (mod_cast hk) (mod_cast hm))
theorem contDiffOn_of_differentiableOn {n : ℕ∞}
(h : ∀ m : ℕ, m ≤ n → DifferentiableOn 𝕜 (iteratedFDerivWithin 𝕜 m f s) s) :
ContDiffOn 𝕜 n f s :=
contDiffOn_of_continuousOn_differentiableOn (fun m hm => (h m hm).continuousOn) fun m hm =>
h m (le_of_lt hm)
theorem contDiffOn_of_analyticOn_iteratedFDerivWithin
(h : ∀ m, AnalyticOn 𝕜 (iteratedFDerivWithin 𝕜 m f s) s) :
ContDiffOn 𝕜 n f s := by
suffices ContDiffOn 𝕜 ω f s from this.of_le le_top
intro x hx
refine ⟨insert x s, self_mem_nhdsWithin, ftaylorSeriesWithin 𝕜 f s, ?_, ?_⟩
· rw [insert_eq_of_mem hx]
constructor
· intro y _
simp only [ftaylorSeriesWithin, ContinuousMultilinearMap.curry0_apply,
iteratedFDerivWithin_zero_apply]
· intro k _ y hy
exact ((h k).differentiableOn y hy).hasFDerivWithinAt
· intro k _
exact (h k).continuousOn
· intro i
rw [insert_eq_of_mem hx]
exact h i
theorem contDiffOn_omega_iff_analyticOn (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 ω f s ↔ AnalyticOn 𝕜 f s :=
⟨fun h m ↦ h.analyticOn m, fun h ↦ h.contDiffOn hs⟩
theorem ContDiffOn.continuousOn_iteratedFDerivWithin {m : ℕ} (h : ContDiffOn 𝕜 n f s)
(hmn : m ≤ n) (hs : UniqueDiffOn 𝕜 s) : ContinuousOn (iteratedFDerivWithin 𝕜 m f s) s :=
((h.of_le hmn).ftaylorSeriesWithin hs).cont m le_rfl
theorem ContDiffOn.differentiableOn_iteratedFDerivWithin {m : ℕ} (h : ContDiffOn 𝕜 n f s)
(hmn : m < n) (hs : UniqueDiffOn 𝕜 s) :
DifferentiableOn 𝕜 (iteratedFDerivWithin 𝕜 m f s) s := by
intro x hx
have : (m + 1 : ℕ) ≤ n := ENat.add_one_natCast_le_withTop_of_lt hmn
apply (((h.of_le this).ftaylorSeriesWithin hs).fderivWithin m ?_ x hx).differentiableWithinAt
exact_mod_cast lt_add_one m
theorem ContDiffWithinAt.differentiableWithinAt_iteratedFDerivWithin {m : ℕ}
(h : ContDiffWithinAt 𝕜 n f s x) (hmn : m < n) (hs : UniqueDiffOn 𝕜 (insert x s)) :
DifferentiableWithinAt 𝕜 (iteratedFDerivWithin 𝕜 m f s) s x := by
have : (m + 1 : WithTop ℕ∞) ≠ ∞ := Ne.symm (ne_of_beq_false rfl)
rcases h.contDiffOn' (ENat.add_one_natCast_le_withTop_of_lt hmn) (by simp [this])
with ⟨u, uo, xu, hu⟩
set t := insert x s ∩ u
have A : t =ᶠ[𝓝[≠] x] s := by
simp only [set_eventuallyEq_iff_inf_principal, ← nhdsWithin_inter']
rw [← inter_assoc, nhdsWithin_inter_of_mem', ← diff_eq_compl_inter, insert_diff_of_mem,
diff_eq_compl_inter]
exacts [rfl, mem_nhdsWithin_of_mem_nhds (uo.mem_nhds xu)]
have B : iteratedFDerivWithin 𝕜 m f s =ᶠ[𝓝 x] iteratedFDerivWithin 𝕜 m f t :=
iteratedFDerivWithin_eventually_congr_set' _ A.symm _
have C : DifferentiableWithinAt 𝕜 (iteratedFDerivWithin 𝕜 m f t) t x :=
hu.differentiableOn_iteratedFDerivWithin (Nat.cast_lt.2 m.lt_succ_self) (hs.inter uo) x
⟨mem_insert _ _, xu⟩
rw [differentiableWithinAt_congr_set' _ A] at C
exact C.congr_of_eventuallyEq (B.filter_mono inf_le_left) B.self_of_nhds
theorem contDiffOn_iff_continuousOn_differentiableOn {n : ℕ∞} (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 n f s ↔
(∀ m : ℕ, m ≤ n → ContinuousOn (fun x => iteratedFDerivWithin 𝕜 m f s x) s) ∧
∀ m : ℕ, m < n → DifferentiableOn 𝕜 (fun x => iteratedFDerivWithin 𝕜 m f s x) s :=
⟨fun h => ⟨fun _m hm => h.continuousOn_iteratedFDerivWithin (mod_cast hm) hs,
fun _m hm => h.differentiableOn_iteratedFDerivWithin (mod_cast hm) hs⟩,
fun h => contDiffOn_of_continuousOn_differentiableOn h.1 h.2⟩
theorem contDiffOn_nat_iff_continuousOn_differentiableOn {n : ℕ} (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 n f s ↔
(∀ m : ℕ, m ≤ n → ContinuousOn (fun x => iteratedFDerivWithin 𝕜 m f s x) s) ∧
∀ m : ℕ, m < n → DifferentiableOn 𝕜 (fun x => iteratedFDerivWithin 𝕜 m f s x) s := by
rw [← WithTop.coe_natCast, contDiffOn_iff_continuousOn_differentiableOn hs]
simp
theorem contDiffOn_succ_of_fderivWithin (hf : DifferentiableOn 𝕜 f s)
(h' : n = ω → AnalyticOn 𝕜 f s)
(h : ContDiffOn 𝕜 n (fun y => fderivWithin 𝕜 f s y) s) : ContDiffOn 𝕜 (n + 1) f s := by
rcases eq_or_ne n ∞ with rfl | hn
· rw [ENat.coe_top_add_one, contDiffOn_infty]
intro m x hx
apply ContDiffWithinAt.of_le _ (show (m : WithTop ℕ∞) ≤ m + 1 from le_self_add)
rw [contDiffWithinAt_succ_iff_hasFDerivWithinAt (by simp),
insert_eq_of_mem hx]
exact ⟨s, self_mem_nhdsWithin, (by simp), fderivWithin 𝕜 f s,
fun y hy => (hf y hy).hasFDerivWithinAt, (h x hx).of_le (mod_cast le_top)⟩
· intro x hx
rw [contDiffWithinAt_succ_iff_hasFDerivWithinAt hn,
insert_eq_of_mem hx]
exact ⟨s, self_mem_nhdsWithin, h', fderivWithin 𝕜 f s,
fun y hy => (hf y hy).hasFDerivWithinAt, h x hx⟩
theorem contDiffOn_of_analyticOn_of_fderivWithin (hf : AnalyticOn 𝕜 f s)
(h : ContDiffOn 𝕜 ω (fun y ↦ fderivWithin 𝕜 f s y) s) : ContDiffOn 𝕜 n f s := by
suffices ContDiffOn 𝕜 (ω + 1) f s from this.of_le le_top
exact contDiffOn_succ_of_fderivWithin hf.differentiableOn (fun _ ↦ hf) h
/-- A function is `C^(n + 1)` on a domain with unique derivatives if and only if it is
differentiable there, and its derivative (expressed with `fderivWithin`) is `C^n`. -/
theorem contDiffOn_succ_iff_fderivWithin (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 (n + 1) f s ↔
DifferentiableOn 𝕜 f s ∧ (n = ω → AnalyticOn 𝕜 f s) ∧
ContDiffOn 𝕜 n (fderivWithin 𝕜 f s) s := by
refine ⟨fun H => ?_, fun h => contDiffOn_succ_of_fderivWithin h.1 h.2.1 h.2.2⟩
refine ⟨H.differentiableOn le_add_self, ?_, fun x hx => ?_⟩
· rintro rfl
exact H.analyticOn
have A (m : ℕ) (hm : m ≤ n) : ContDiffWithinAt 𝕜 m (fun y => fderivWithin 𝕜 f s y) s x := by
rcases (contDiffWithinAt_succ_iff_hasFDerivWithinAt (n := m) (ne_of_beq_false rfl)).1
(H.of_le (add_le_add_right hm 1) x hx) with ⟨u, hu, -, f', hff', hf'⟩
rcases mem_nhdsWithin.1 hu with ⟨o, o_open, xo, ho⟩
rw [inter_comm, insert_eq_of_mem hx] at ho
have := hf'.mono ho
rw [contDiffWithinAt_inter' (mem_nhdsWithin_of_mem_nhds (IsOpen.mem_nhds o_open xo))] at this
apply this.congr_of_eventuallyEq_of_mem _ hx
have : o ∩ s ∈ 𝓝[s] x := mem_nhdsWithin.2 ⟨o, o_open, xo, Subset.refl _⟩
rw [inter_comm] at this
refine Filter.eventuallyEq_of_mem this fun y hy => ?_
have A : fderivWithin 𝕜 f (s ∩ o) y = f' y :=
((hff' y (ho hy)).mono ho).fderivWithin (hs.inter o_open y hy)
rwa [fderivWithin_inter (o_open.mem_nhds hy.2)] at A
match n with
| ω => exact (H.analyticOn.fderivWithin hs).contDiffOn hs (n := ω) x hx
| ∞ => exact contDiffWithinAt_infty.2 (fun m ↦ A m (mod_cast le_top))
| (n : ℕ) => exact A n le_rfl
theorem contDiffOn_succ_iff_hasFDerivWithinAt_of_uniqueDiffOn (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 (n + 1) f s ↔ (n = ω → AnalyticOn 𝕜 f s) ∧
∃ f' : E → E →L[𝕜] F, ContDiffOn 𝕜 n f' s ∧ ∀ x, x ∈ s → HasFDerivWithinAt f (f' x) s x := by
rw [contDiffOn_succ_iff_fderivWithin hs]
refine ⟨fun h => ⟨h.2.1, fderivWithin 𝕜 f s, h.2.2,
fun x hx => (h.1 x hx).hasFDerivWithinAt⟩, fun ⟨f_an, h⟩ => ?_⟩
rcases h with ⟨f', h1, h2⟩
refine ⟨fun x hx => (h2 x hx).differentiableWithinAt, f_an, fun x hx => ?_⟩
exact (h1 x hx).congr_of_mem (fun y hy => (h2 y hy).fderivWithin (hs y hy)) hx
@[deprecated (since := "2024-11-27")]
alias contDiffOn_succ_iff_hasFDerivWithin := contDiffOn_succ_iff_hasFDerivWithinAt_of_uniqueDiffOn
theorem contDiffOn_infty_iff_fderivWithin (hs : UniqueDiffOn 𝕜 s) :
ContDiffOn 𝕜 ∞ f s ↔ DifferentiableOn 𝕜 f s ∧ ContDiffOn 𝕜 ∞ (fderivWithin 𝕜 f s) s := by
rw [← ENat.coe_top_add_one, contDiffOn_succ_iff_fderivWithin hs]
simp
@[deprecated (since := "2024-11-27")]
alias contDiffOn_top_iff_fderivWithin := contDiffOn_infty_iff_fderivWithin
/-- A function is `C^(n + 1)` on an open domain if and only if it is
differentiable there, and its derivative (expressed with `fderiv`) is `C^n`. -/
theorem contDiffOn_succ_iff_fderiv_of_isOpen (hs : IsOpen s) :
ContDiffOn 𝕜 (n + 1) f s ↔
DifferentiableOn 𝕜 f s ∧ (n = ω → AnalyticOn 𝕜 f s) ∧
ContDiffOn 𝕜 n (fderiv 𝕜 f) s := by
rw [contDiffOn_succ_iff_fderivWithin hs.uniqueDiffOn,
contDiffOn_congr fun x hx ↦ fderivWithin_of_isOpen hs hx]
theorem contDiffOn_infty_iff_fderiv_of_isOpen (hs : IsOpen s) :
ContDiffOn 𝕜 ∞ f s ↔ DifferentiableOn 𝕜 f s ∧ ContDiffOn 𝕜 ∞ (fderiv 𝕜 f) s := by
rw [← ENat.coe_top_add_one, contDiffOn_succ_iff_fderiv_of_isOpen hs]
simp
@[deprecated (since := "2024-11-27")]
alias contDiffOn_top_iff_fderiv_of_isOpen := contDiffOn_infty_iff_fderiv_of_isOpen
protected theorem ContDiffOn.fderivWithin (hf : ContDiffOn 𝕜 n f s) (hs : UniqueDiffOn 𝕜 s)
(hmn : m + 1 ≤ n) : ContDiffOn 𝕜 m (fderivWithin 𝕜 f s) s :=
((contDiffOn_succ_iff_fderivWithin hs).1 (hf.of_le hmn)).2.2
theorem ContDiffOn.fderiv_of_isOpen (hf : ContDiffOn 𝕜 n f s) (hs : IsOpen s) (hmn : m + 1 ≤ n) :
ContDiffOn 𝕜 m (fderiv 𝕜 f) s :=
(hf.fderivWithin hs.uniqueDiffOn hmn).congr fun _ hx => (fderivWithin_of_isOpen hs hx).symm
theorem ContDiffOn.continuousOn_fderivWithin (h : ContDiffOn 𝕜 n f s) (hs : UniqueDiffOn 𝕜 s)
(hn : 1 ≤ n) : ContinuousOn (fderivWithin 𝕜 f s) s :=
((contDiffOn_succ_iff_fderivWithin hs).1
(h.of_le (show 0 + (1 : WithTop ℕ∞) ≤ n from hn))).2.2.continuousOn
theorem ContDiffOn.continuousOn_fderiv_of_isOpen (h : ContDiffOn 𝕜 n f s) (hs : IsOpen s)
(hn : 1 ≤ n) : ContinuousOn (fderiv 𝕜 f) s :=
((contDiffOn_succ_iff_fderiv_of_isOpen hs).1
(h.of_le (show 0 + (1 : WithTop ℕ∞) ≤ n from hn))).2.2.continuousOn
/-! ### Smooth functions at a point -/
variable (𝕜) in
/-- A function is continuously differentiable up to `n` at a point `x` if, for any integer `k ≤ n`,
there is a neighborhood of `x` where `f` admits derivatives up to order `n`, which are continuous.
-/
def ContDiffAt (n : WithTop ℕ∞) (f : E → F) (x : E) : Prop :=
ContDiffWithinAt 𝕜 n f univ x
theorem contDiffWithinAt_univ : ContDiffWithinAt 𝕜 n f univ x ↔ ContDiffAt 𝕜 n f x :=
Iff.rfl
theorem contDiffAt_infty : ContDiffAt 𝕜 ∞ f x ↔ ∀ n : ℕ, ContDiffAt 𝕜 n f x := by
simp [← contDiffWithinAt_univ, contDiffWithinAt_infty]
@[deprecated (since := "2024-11-27")] alias contDiffAt_top := contDiffAt_infty
theorem ContDiffAt.contDiffWithinAt (h : ContDiffAt 𝕜 n f x) : ContDiffWithinAt 𝕜 n f s x :=
h.mono (subset_univ _)
theorem ContDiffWithinAt.contDiffAt (h : ContDiffWithinAt 𝕜 n f s x) (hx : s ∈ 𝓝 x) :
ContDiffAt 𝕜 n f x := by rwa [ContDiffAt, ← contDiffWithinAt_inter hx, univ_inter]
theorem contDiffWithinAt_iff_contDiffAt (h : s ∈ 𝓝 x) :
ContDiffWithinAt 𝕜 n f s x ↔ ContDiffAt 𝕜 n f x := by
rw [← univ_inter s, contDiffWithinAt_inter h, contDiffWithinAt_univ]
theorem IsOpen.contDiffOn_iff (hs : IsOpen s) :
ContDiffOn 𝕜 n f s ↔ ∀ ⦃a⦄, a ∈ s → ContDiffAt 𝕜 n f a :=
forall₂_congr fun _ => contDiffWithinAt_iff_contDiffAt ∘ hs.mem_nhds
theorem ContDiffOn.contDiffAt (h : ContDiffOn 𝕜 n f s) (hx : s ∈ 𝓝 x) :
ContDiffAt 𝕜 n f x :=
(h _ (mem_of_mem_nhds hx)).contDiffAt hx
theorem ContDiffAt.congr_of_eventuallyEq (h : ContDiffAt 𝕜 n f x) (hg : f₁ =ᶠ[𝓝 x] f) :
ContDiffAt 𝕜 n f₁ x :=
h.congr_of_eventuallyEq_of_mem (by rwa [nhdsWithin_univ]) (mem_univ x)
theorem ContDiffAt.of_le (h : ContDiffAt 𝕜 n f x) (hmn : m ≤ n) : ContDiffAt 𝕜 m f x :=
ContDiffWithinAt.of_le h hmn
theorem ContDiffAt.continuousAt (h : ContDiffAt 𝕜 n f x) : ContinuousAt f x := by
simpa [continuousWithinAt_univ] using h.continuousWithinAt
theorem ContDiffAt.analyticAt (h : ContDiffAt 𝕜 ω f x) : AnalyticAt 𝕜 f x := by
rw [← contDiffWithinAt_univ] at h
rw [← analyticWithinAt_univ]
exact h.analyticWithinAt
/-- In a complete space, a function which is analytic at a point is also `C^ω` there.
Note that the same statement for `AnalyticOn` does not require completeness, see
`AnalyticOn.contDiffOn`. -/
theorem AnalyticAt.contDiffAt [CompleteSpace F] (h : AnalyticAt 𝕜 f x) :
ContDiffAt 𝕜 n f x := by
rw [← contDiffWithinAt_univ]
rw [← analyticWithinAt_univ] at h
exact h.contDiffWithinAt
@[simp]
theorem contDiffWithinAt_compl_self :
ContDiffWithinAt 𝕜 n f {x}ᶜ x ↔ ContDiffAt 𝕜 n f x := by
rw [compl_eq_univ_diff, contDiffWithinAt_diff_singleton, contDiffWithinAt_univ]
/-- If a function is `C^n` with `n ≥ 1` at a point, then it is differentiable there. -/
theorem ContDiffAt.differentiableAt (h : ContDiffAt 𝕜 n f x) (hn : 1 ≤ n) :
DifferentiableAt 𝕜 f x := by
simpa [hn, differentiableWithinAt_univ] using h.differentiableWithinAt
nonrec lemma ContDiffAt.contDiffOn (h : ContDiffAt 𝕜 n f x) (hm : m ≤ n) (h' : m = ∞ → n = ω):
∃ u ∈ 𝓝 x, ContDiffOn 𝕜 m f u := by
simpa [nhdsWithin_univ] using h.contDiffOn hm h'
/-- A function is `C^(n + 1)` at a point iff locally, it has a derivative which is `C^n`. -/
theorem contDiffAt_succ_iff_hasFDerivAt {n : ℕ} :
ContDiffAt 𝕜 (n + 1) f x ↔ ∃ f' : E → E →L[𝕜] F,
(∃ u ∈ 𝓝 x, ∀ x ∈ u, HasFDerivAt f (f' x) x) ∧ ContDiffAt 𝕜 n f' x := by
rw [← contDiffWithinAt_univ, contDiffWithinAt_succ_iff_hasFDerivWithinAt (by simp)]
simp only [nhdsWithin_univ, exists_prop, mem_univ, insert_eq_of_mem]
constructor
· rintro ⟨u, H, -, f', h_fderiv, h_cont_diff⟩
rcases mem_nhds_iff.mp H with ⟨t, htu, ht, hxt⟩
refine ⟨f', ⟨t, ?_⟩, h_cont_diff.contDiffAt H⟩
refine ⟨mem_nhds_iff.mpr ⟨t, Subset.rfl, ht, hxt⟩, ?_⟩
intro y hyt
refine (h_fderiv y (htu hyt)).hasFDerivAt ?_
exact mem_nhds_iff.mpr ⟨t, htu, ht, hyt⟩
· rintro ⟨f', ⟨u, H, h_fderiv⟩, h_cont_diff⟩
refine ⟨u, H, by simp, f', fun x hxu ↦ ?_, h_cont_diff.contDiffWithinAt⟩
exact (h_fderiv x hxu).hasFDerivWithinAt
protected theorem ContDiffAt.eventually (h : ContDiffAt 𝕜 n f x) (h' : n ≠ ∞) :
∀ᶠ y in 𝓝 x, ContDiffAt 𝕜 n f y := by
simpa [nhdsWithin_univ] using ContDiffWithinAt.eventually h h'
theorem iteratedFDerivWithin_eq_iteratedFDeriv {n : ℕ}
(hs : UniqueDiffOn 𝕜 s) (h : ContDiffAt 𝕜 n f x) (hx : x ∈ s) :
iteratedFDerivWithin 𝕜 n f s x = iteratedFDeriv 𝕜 n f x := by
rw [← iteratedFDerivWithin_univ]
rcases h.contDiffOn' le_rfl (by simp) with ⟨u, u_open, xu, hu⟩
rw [← iteratedFDerivWithin_inter_open u_open xu,
← iteratedFDerivWithin_inter_open u_open xu (s := univ)]
apply iteratedFDerivWithin_subset
· exact inter_subset_inter_left _ (subset_univ _)
· exact hs.inter u_open
· apply uniqueDiffOn_univ.inter u_open
· simpa using hu
· exact ⟨hx, xu⟩
/-! ### Smooth functions -/
variable (𝕜) in
/-- A function is continuously differentiable up to `n` if it admits derivatives up to
order `n`, which are continuous. Contrary to the case of definitions in domains (where derivatives
might not be unique) we do not need to localize the definition in space or time.
-/
def ContDiff (n : WithTop ℕ∞) (f : E → F) : Prop :=
match n with
| ω => ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpTo ⊤ f p
∧ ∀ i, AnalyticOnNhd 𝕜 (fun x ↦ p x i) univ
| (n : ℕ∞) => ∃ p : E → FormalMultilinearSeries 𝕜 E F, HasFTaylorSeriesUpTo n f p
/-- If `f` has a Taylor series up to `n`, then it is `C^n`. -/
theorem HasFTaylorSeriesUpTo.contDiff {n : ℕ∞} {f' : E → FormalMultilinearSeries 𝕜 E F}
(hf : HasFTaylorSeriesUpTo n f f') : ContDiff 𝕜 n f :=
⟨f', hf⟩
theorem contDiffOn_univ : ContDiffOn 𝕜 n f univ ↔ ContDiff 𝕜 n f := by
match n with
| ω =>
constructor
· intro H
use ftaylorSeriesWithin 𝕜 f univ
rw [← hasFTaylorSeriesUpToOn_univ_iff]
refine ⟨H.ftaylorSeriesWithin uniqueDiffOn_univ, fun i ↦ ?_⟩
rw [← analyticOn_univ]
exact H.analyticOn.iteratedFDerivWithin uniqueDiffOn_univ _
· rintro ⟨p, hp, h'p⟩ x _
exact ⟨univ, Filter.univ_sets _, p, (hp.hasFTaylorSeriesUpToOn univ).of_le le_top,
fun i ↦ (h'p i).analyticOn⟩
| (n : ℕ∞) =>
constructor
· intro H
use ftaylorSeriesWithin 𝕜 f univ
rw [← hasFTaylorSeriesUpToOn_univ_iff]
exact H.ftaylorSeriesWithin uniqueDiffOn_univ
· rintro ⟨p, hp⟩ x _ m hm
exact ⟨univ, Filter.univ_sets _, p,
(hp.hasFTaylorSeriesUpToOn univ).of_le (mod_cast hm)⟩
theorem contDiff_iff_contDiffAt : ContDiff 𝕜 n f ↔ ∀ x, ContDiffAt 𝕜 n f x := by
simp [← contDiffOn_univ, ContDiffOn, ContDiffAt]
theorem ContDiff.contDiffAt (h : ContDiff 𝕜 n f) : ContDiffAt 𝕜 n f x :=
contDiff_iff_contDiffAt.1 h x
theorem ContDiff.contDiffWithinAt (h : ContDiff 𝕜 n f) : ContDiffWithinAt 𝕜 n f s x :=
h.contDiffAt.contDiffWithinAt
theorem contDiff_infty : ContDiff 𝕜 ∞ f ↔ ∀ n : ℕ, ContDiff 𝕜 n f := by
simp [contDiffOn_univ.symm, contDiffOn_infty]
@[deprecated (since := "2024-11-25")] alias contDiff_top := contDiff_infty
@[deprecated (since := "2024-11-25")] alias contDiff_infty_iff_contDiff_omega := contDiff_infty
theorem contDiff_all_iff_nat : (∀ n : ℕ∞, ContDiff 𝕜 n f) ↔ ∀ n : ℕ, ContDiff 𝕜 n f := by
simp only [← contDiffOn_univ, contDiffOn_all_iff_nat]
theorem ContDiff.contDiffOn (h : ContDiff 𝕜 n f) : ContDiffOn 𝕜 n f s :=
(contDiffOn_univ.2 h).mono (subset_univ _)
@[simp]
theorem contDiff_zero : ContDiff 𝕜 0 f ↔ Continuous f := by
rw [← contDiffOn_univ, continuous_iff_continuousOn_univ]
exact contDiffOn_zero
theorem contDiffAt_zero : ContDiffAt 𝕜 0 f x ↔ ∃ u ∈ 𝓝 x, ContinuousOn f u := by
rw [← contDiffWithinAt_univ]; simp [contDiffWithinAt_zero, nhdsWithin_univ]
theorem contDiffAt_one_iff :
ContDiffAt 𝕜 1 f x ↔
∃ f' : E → E →L[𝕜] F, ∃ u ∈ 𝓝 x, ContinuousOn f' u ∧ ∀ x ∈ u, HasFDerivAt f (f' x) x := by
rw [show (1 : WithTop ℕ∞) = (0 : ℕ) + 1 from rfl]
simp_rw [contDiffAt_succ_iff_hasFDerivAt, show ((0 : ℕ) : WithTop ℕ∞) = 0 from rfl,
contDiffAt_zero, exists_mem_and_iff antitone_bforall antitone_continuousOn, and_comm]
theorem ContDiff.of_le (h : ContDiff 𝕜 n f) (hmn : m ≤ n) : ContDiff 𝕜 m f :=
contDiffOn_univ.1 <| (contDiffOn_univ.2 h).of_le hmn
theorem ContDiff.of_succ (h : ContDiff 𝕜 (n + 1) f) : ContDiff 𝕜 n f :=
h.of_le le_self_add
theorem ContDiff.one_of_succ (h : ContDiff 𝕜 (n + 1) f) : ContDiff 𝕜 1 f := by
apply h.of_le le_add_self
theorem ContDiff.continuous (h : ContDiff 𝕜 n f) : Continuous f :=
contDiff_zero.1 (h.of_le bot_le)
/-- If a function is `C^n` with `n ≥ 1`, then it is differentiable. -/
theorem ContDiff.differentiable (h : ContDiff 𝕜 n f) (hn : 1 ≤ n) : Differentiable 𝕜 f :=
differentiableOn_univ.1 <| (contDiffOn_univ.2 h).differentiableOn hn
theorem contDiff_iff_forall_nat_le {n : ℕ∞} :
ContDiff 𝕜 n f ↔ ∀ m : ℕ, ↑m ≤ n → ContDiff 𝕜 m f := by
simp_rw [← contDiffOn_univ]; exact contDiffOn_iff_forall_nat_le
/-- A function is `C^(n+1)` iff it has a `C^n` derivative. -/
theorem contDiff_succ_iff_hasFDerivAt {n : ℕ} :
ContDiff 𝕜 (n + 1) f ↔
∃ f' : E → E →L[𝕜] F, ContDiff 𝕜 n f' ∧ ∀ x, HasFDerivAt f (f' x) x := by
simp only [← contDiffOn_univ, ← hasFDerivWithinAt_univ, Set.mem_univ, forall_true_left,
contDiffOn_succ_iff_hasFDerivWithinAt_of_uniqueDiffOn uniqueDiffOn_univ,
WithTop.natCast_ne_top, analyticOn_univ, false_implies, true_and]
theorem contDiff_one_iff_hasFDerivAt : ContDiff 𝕜 1 f ↔
∃ f' : E → E →L[𝕜] F, Continuous f' ∧ ∀ x, HasFDerivAt f (f' x) x := by
convert contDiff_succ_iff_hasFDerivAt using 4; simp
theorem AnalyticOn.contDiff (hf : AnalyticOn 𝕜 f univ) : ContDiff 𝕜 n f := by
rw [← contDiffOn_univ]
exact hf.contDiffOn (n := n) uniqueDiffOn_univ
theorem AnalyticOnNhd.contDiff (hf : AnalyticOnNhd 𝕜 f univ) : ContDiff 𝕜 n f :=
hf.analyticOn.contDiff
theorem ContDiff.analyticOnNhd (h : ContDiff 𝕜 ω f) : AnalyticOnNhd 𝕜 f s := by
rw [← contDiffOn_univ] at h
have := h.analyticOn
rw [analyticOn_univ] at this
exact this.mono (subset_univ _)
theorem contDiff_omega_iff_analyticOnNhd :
ContDiff 𝕜 ω f ↔ AnalyticOnNhd 𝕜 f univ :=
⟨fun h ↦ h.analyticOnNhd, fun h ↦ h.contDiff⟩
/-! ### Iterated derivative -/
/-- When a function is `C^n`, it admits `ftaylorSeries 𝕜 f` as a Taylor series up
to order `n` in `s`. -/
theorem ContDiff.ftaylorSeries (hf : ContDiff 𝕜 n f) :
HasFTaylorSeriesUpTo n f (ftaylorSeries 𝕜 f) := by
simp only [← contDiffOn_univ, ← hasFTaylorSeriesUpToOn_univ_iff, ← ftaylorSeriesWithin_univ]
at hf ⊢
exact ContDiffOn.ftaylorSeriesWithin hf uniqueDiffOn_univ
/-- For `n : ℕ∞`, a function is `C^n` iff it admits `ftaylorSeries 𝕜 f`
as a Taylor series up to order `n`. -/
theorem contDiff_iff_ftaylorSeries {n : ℕ∞} :
ContDiff 𝕜 n f ↔ HasFTaylorSeriesUpTo n f (ftaylorSeries 𝕜 f) := by
constructor
· rw [← contDiffOn_univ, ← hasFTaylorSeriesUpToOn_univ_iff, ← ftaylorSeriesWithin_univ]
exact fun h ↦ ContDiffOn.ftaylorSeriesWithin h uniqueDiffOn_univ
· exact fun h ↦ ⟨ftaylorSeries 𝕜 f, h⟩
theorem contDiff_iff_continuous_differentiable {n : ℕ∞} :
ContDiff 𝕜 n f ↔
(∀ m : ℕ, m ≤ n → Continuous fun x => iteratedFDeriv 𝕜 m f x) ∧
∀ m : ℕ, m < n → Differentiable 𝕜 fun x => iteratedFDeriv 𝕜 m f x := by
simp [contDiffOn_univ.symm, continuous_iff_continuousOn_univ, differentiableOn_univ.symm,
iteratedFDerivWithin_univ, contDiffOn_iff_continuousOn_differentiableOn uniqueDiffOn_univ]
theorem contDiff_nat_iff_continuous_differentiable {n : ℕ} :
ContDiff 𝕜 n f ↔
(∀ m : ℕ, m ≤ n → Continuous fun x => iteratedFDeriv 𝕜 m f x) ∧
∀ m : ℕ, m < n → Differentiable 𝕜 fun x => iteratedFDeriv 𝕜 m f x := by
rw [← WithTop.coe_natCast, contDiff_iff_continuous_differentiable]
simp
/-- If `f` is `C^n` then its `m`-times iterated derivative is continuous for `m ≤ n`. -/
theorem ContDiff.continuous_iteratedFDeriv {m : ℕ} (hm : m ≤ n) (hf : ContDiff 𝕜 n f) :
Continuous fun x => iteratedFDeriv 𝕜 m f x :=
(contDiff_iff_continuous_differentiable.mp (hf.of_le hm)).1 m le_rfl
/-- If `f` is `C^n` then its `m`-times iterated derivative is differentiable for `m < n`. -/
theorem ContDiff.differentiable_iteratedFDeriv {m : ℕ} (hm : m < n) (hf : ContDiff 𝕜 n f) :
Differentiable 𝕜 fun x => iteratedFDeriv 𝕜 m f x :=
(contDiff_iff_continuous_differentiable.mp
(hf.of_le (ENat.add_one_natCast_le_withTop_of_lt hm))).2 m (mod_cast lt_add_one m)
theorem contDiff_of_differentiable_iteratedFDeriv {n : ℕ∞}
(h : ∀ m : ℕ, m ≤ n → Differentiable 𝕜 (iteratedFDeriv 𝕜 m f)) : ContDiff 𝕜 n f :=
contDiff_iff_continuous_differentiable.2
⟨fun m hm => (h m hm).continuous, fun m hm => h m (le_of_lt hm)⟩
/-- A function is `C^(n + 1)` if and only if it is differentiable,
and its derivative (formulated in terms of `fderiv`) is `C^n`. -/
theorem contDiff_succ_iff_fderiv :
ContDiff 𝕜 (n + 1) f ↔ Differentiable 𝕜 f ∧ (n = ω → AnalyticOnNhd 𝕜 f univ) ∧
ContDiff 𝕜 n (fderiv 𝕜 f) := by
simp only [← contDiffOn_univ, ← differentiableOn_univ, ← fderivWithin_univ,
contDiffOn_succ_iff_fderivWithin uniqueDiffOn_univ, analyticOn_univ]
theorem contDiff_one_iff_fderiv :
ContDiff 𝕜 1 f ↔ Differentiable 𝕜 f ∧ Continuous (fderiv 𝕜 f) := by
rw [← zero_add 1, contDiff_succ_iff_fderiv]
simp
theorem contDiff_infty_iff_fderiv :
ContDiff 𝕜 ∞ f ↔ Differentiable 𝕜 f ∧ ContDiff 𝕜 ∞ (fderiv 𝕜 f) := by
rw [← ENat.coe_top_add_one, contDiff_succ_iff_fderiv]
simp
@[deprecated (since := "2024-11-27")] alias contDiff_top_iff_fderiv := contDiff_infty_iff_fderiv
theorem ContDiff.continuous_fderiv (h : ContDiff 𝕜 n f) (hn : 1 ≤ n) :
Continuous (fderiv 𝕜 f) :=
(contDiff_one_iff_fderiv.1 (h.of_le hn)).2
/-- If a function is at least `C^1`, its bundled derivative (mapping `(x, v)` to `Df(x) v`) is
continuous. -/
theorem ContDiff.continuous_fderiv_apply (h : ContDiff 𝕜 n f) (hn : 1 ≤ n) :
Continuous fun p : E × E => (fderiv 𝕜 f p.1 : E → F) p.2 :=
have A : Continuous fun q : (E →L[𝕜] F) × E => q.1 q.2 := isBoundedBilinearMap_apply.continuous
have B : Continuous fun p : E × E => (fderiv 𝕜 f p.1, p.2) :=
((h.continuous_fderiv hn).comp continuous_fst).prodMk continuous_snd
A.comp B
| Mathlib/Analysis/Calculus/ContDiff/Defs.lean | 1,625 | 1,628 | |
/-
Copyright (c) 2022 Yury Kudryashov. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yury Kudryashov
-/
import Mathlib.Analysis.Complex.CauchyIntegral
import Mathlib.Analysis.InnerProductSpace.Convex
import Mathlib.Analysis.NormedSpace.Extr
import Mathlib.Data.Complex.FiniteDimensional
import Mathlib.Topology.Order.ExtrClosure
/-!
# Maximum modulus principle
In this file we prove several versions of the maximum modulus principle. There are several
statements that can be called "the maximum modulus principle" for maps between normed complex
spaces. They differ by assumptions on the domain (any space, a nontrivial space, a finite
dimensional space), assumptions on the codomain (any space, a strictly convex space), and by
conclusion (either equality of norms or of the values of the function).
## Main results
### Theorems for any codomain
Consider a function `f : E → F` that is complex differentiable on a set `s`, is continuous on its
closure, and `‖f x‖` has a maximum on `s` at `c`. We prove the following theorems.
- `Complex.norm_eqOn_closedBall_of_isMaxOn`: if `s = Metric.ball c r`, then `‖f x‖ = ‖f c‖` for
any `x` from the corresponding closed ball;
- `Complex.norm_eq_norm_of_isMaxOn_of_ball_subset`: if `Metric.ball c (dist w c) ⊆ s`, then
`‖f w‖ = ‖f c‖`;
- `Complex.norm_eqOn_of_isPreconnected_of_isMaxOn`: if `U` is an open (pre)connected set, `f` is
complex differentiable on `U`, and `‖f x‖` has a maximum on `U` at `c ∈ U`, then `‖f x‖ = ‖f c‖`
for all `x ∈ U`;
- `Complex.norm_eqOn_closure_of_isPreconnected_of_isMaxOn`: if `s` is open and (pre)connected
and `c ∈ s`, then `‖f x‖ = ‖f c‖` for all `x ∈ closure s`;
- `Complex.norm_eventually_eq_of_isLocalMax`: if `f` is complex differentiable in a neighborhood
of `c` and `‖f x‖` has a local maximum at `c`, then `‖f x‖` is locally a constant in a
neighborhood of `c`.
### Theorems for a strictly convex codomain
If the codomain `F` is a strictly convex space, then in the lemmas from the previous section we can
prove `f w = f c` instead of `‖f w‖ = ‖f c‖`, see
`Complex.eqOn_of_isPreconnected_of_isMaxOn_norm`,
`Complex.eqOn_closure_of_isPreconnected_of_isMaxOn_norm`,
`Complex.eq_of_isMaxOn_of_ball_subset`, `Complex.eqOn_closedBall_of_isMaxOn_norm`, and
`Complex.eventually_eq_of_isLocalMax_norm`.
### Values on the frontier
Finally, we prove some corollaries that relate the (norm of the) values of a function on a set to
its values on the frontier of the set. All these lemmas assume that `E` is a nontrivial space. In
this section `f g : E → F` are functions that are complex differentiable on a bounded set `s` and
are continuous on its closure. We prove the following theorems.
- `Complex.exists_mem_frontier_isMaxOn_norm`: If `E` is a finite dimensional space and `s` is a
nonempty bounded set, then there exists a point `z ∈ frontier s` such that `(‖f ·‖)` takes it
maximum value on `closure s` at `z`.
- `Complex.norm_le_of_forall_mem_frontier_norm_le`: if `‖f z‖ ≤ C` for all `z ∈ frontier s`, then
`‖f z‖ ≤ C` for all `z ∈ s`; note that this theorem does not require `E` to be a finite
dimensional space.
- `Complex.eqOn_closure_of_eqOn_frontier`: if `f x = g x` on the frontier of `s`, then `f x = g x`
on `closure s`;
- `Complex.eqOn_of_eqOn_frontier`: if `f x = g x` on the frontier of `s`, then `f x = g x`
on `s`.
## Tags
maximum modulus principle, complex analysis
-/
open TopologicalSpace Metric Set Filter Asymptotics Function MeasureTheory AffineMap Bornology
open scoped Topology Filter NNReal Real
universe u v w
variable {E : Type u} [NormedAddCommGroup E] [NormedSpace ℂ E] {F : Type v} [NormedAddCommGroup F]
[NormedSpace ℂ F]
local postfix:100 "̂" => UniformSpace.Completion
namespace Complex
/-!
### Auxiliary lemmas
We split the proof into a series of lemmas. First we prove the principle for a function `f : ℂ → F`
with an additional assumption that `F` is a complete space, then drop unneeded assumptions one by
one.
The lemmas with names `*_auxₙ` are considered to be private and should not be used outside of this
file.
-/
theorem norm_max_aux₁ [CompleteSpace F] {f : ℂ → F} {z w : ℂ}
(hd : DiffContOnCl ℂ f (ball z (dist w z)))
(hz : IsMaxOn (norm ∘ f) (closedBall z (dist w z)) z) : ‖f w‖ = ‖f z‖ := by
-- Consider a circle of radius `r = dist w z`.
set r : ℝ := dist w z
have hw : w ∈ closedBall z r := mem_closedBall.2 le_rfl
-- Assume the converse. Since `‖f w‖ ≤ ‖f z‖`, we have `‖f w‖ < ‖f z‖`.
refine (isMaxOn_iff.1 hz _ hw).antisymm (not_lt.1 ?_)
rintro hw_lt : ‖f w‖ < ‖f z‖
have hr : 0 < r := dist_pos.2 (ne_of_apply_ne (norm ∘ f) hw_lt.ne)
-- Due to Cauchy integral formula, it suffices to prove the following inequality.
suffices ‖∮ ζ in C(z, r), (ζ - z)⁻¹ • f ζ‖ < 2 * π * ‖f z‖ by
refine this.ne ?_
have A : (∮ ζ in C(z, r), (ζ - z)⁻¹ • f ζ) = (2 * π * I : ℂ) • f z :=
hd.circleIntegral_sub_inv_smul (mem_ball_self hr)
simp [A, norm_smul, Real.pi_pos.le]
suffices ‖∮ ζ in C(z, r), (ζ - z)⁻¹ • f ζ‖ < 2 * π * r * (‖f z‖ / r) by
rwa [mul_assoc, mul_div_cancel₀ _ hr.ne'] at this
/- This inequality is true because `‖(ζ - z)⁻¹ • f ζ‖ ≤ ‖f z‖ / r` for all `ζ` on the circle and
this inequality is strict at `ζ = w`. -/
have hsub : sphere z r ⊆ closedBall z r := sphere_subset_closedBall
refine circleIntegral.norm_integral_lt_of_norm_le_const_of_lt hr ?_ ?_ ⟨w, rfl, ?_⟩
· show ContinuousOn (fun ζ : ℂ => (ζ - z)⁻¹ • f ζ) (sphere z r)
refine ((continuousOn_id.sub continuousOn_const).inv₀ ?_).smul (hd.continuousOn_ball.mono hsub)
exact fun ζ hζ => sub_ne_zero.2 (ne_of_mem_sphere hζ hr.ne')
· show ∀ ζ ∈ sphere z r, ‖(ζ - z)⁻¹ • f ζ‖ ≤ ‖f z‖ / r
rintro ζ (hζ : ‖ζ - z‖ = r)
rw [le_div_iff₀ hr, norm_smul, norm_inv, hζ, mul_comm, mul_inv_cancel_left₀ hr.ne']
exact hz (hsub hζ)
show ‖(w - z)⁻¹ • f w‖ < ‖f z‖ / r
rw [norm_smul, norm_inv, ← div_eq_inv_mul]
exact (div_lt_div_iff_of_pos_right hr).2 hw_lt
/-!
Now we drop the assumption `CompleteSpace F` by embedding `F` into its completion.
-/
theorem norm_max_aux₂ {f : ℂ → F} {z w : ℂ} (hd : DiffContOnCl ℂ f (ball z (dist w z)))
(hz : IsMaxOn (norm ∘ f) (closedBall z (dist w z)) z) : ‖f w‖ = ‖f z‖ := by
set e : F →L[ℂ] F̂ := UniformSpace.Completion.toComplL
have he : ∀ x, ‖e x‖ = ‖x‖ := UniformSpace.Completion.norm_coe
replace hz : IsMaxOn (norm ∘ e ∘ f) (closedBall z (dist w z)) z := by
simpa only [IsMaxOn, Function.comp_def, he] using hz
simpa only [he, Function.comp_def]
using norm_max_aux₁ (e.differentiable.comp_diffContOnCl hd) hz
/-!
Then we replace the assumption `IsMaxOn (norm ∘ f) (Metric.closedBall z r) z` with a seemingly
weaker assumption `IsMaxOn (norm ∘ f) (Metric.ball z r) z`.
-/
theorem norm_max_aux₃ {f : ℂ → F} {z w : ℂ} {r : ℝ} (hr : dist w z = r)
(hd : DiffContOnCl ℂ f (ball z r)) (hz : IsMaxOn (norm ∘ f) (ball z r) z) : ‖f w‖ = ‖f z‖ := by
subst r
rcases eq_or_ne w z with (rfl | hne); · rfl
rw [← dist_ne_zero] at hne
exact norm_max_aux₂ hd (closure_ball z hne ▸ hz.closure hd.continuousOn.norm)
/-!
### Maximum modulus principle for any codomain
If we do not assume that the codomain is a strictly convex space, then we can only claim that the
**norm** `‖f x‖` is locally constant.
-/
/-!
Finally, we generalize the theorem from a disk in `ℂ` to a closed ball in any normed space.
-/
/-- **Maximum modulus principle** on a closed ball: if `f : E → F` is continuous on a closed ball,
is complex differentiable on the corresponding open ball, and the norm `‖f w‖` takes its maximum
value on the open ball at its center, then the norm `‖f w‖` is constant on the closed ball. -/
theorem norm_eqOn_closedBall_of_isMaxOn {f : E → F} {z : E} {r : ℝ}
(hd : DiffContOnCl ℂ f (ball z r)) (hz : IsMaxOn (norm ∘ f) (ball z r) z) :
EqOn (norm ∘ f) (const E ‖f z‖) (closedBall z r) := by
intro w hw
rw [mem_closedBall, dist_comm] at hw
rcases eq_or_ne z w with (rfl | hne); · rfl
set e := (lineMap z w : ℂ → E)
have hde : Differentiable ℂ e := (differentiable_id.smul_const (w - z)).add_const z
suffices ‖(f ∘ e) (1 : ℂ)‖ = ‖(f ∘ e) (0 : ℂ)‖ by simpa [e]
have hr : dist (1 : ℂ) 0 = 1 := by simp
have hball : MapsTo e (ball 0 1) (ball z r) := by
refine ((lipschitzWith_lineMap z w).mapsTo_ball (mt nndist_eq_zero.1 hne) 0 1).mono
Subset.rfl ?_
simpa only [lineMap_apply_zero, mul_one, coe_nndist] using ball_subset_ball hw
exact norm_max_aux₃ hr (hd.comp hde.diffContOnCl hball)
(hz.comp_mapsTo hball (lineMap_apply_zero z w))
/-- **Maximum modulus principle**: if `f : E → F` is complex differentiable on a set `s`, the norm
of `f` takes it maximum on `s` at `z`, and `w` is a point such that the closed ball with center `z`
and radius `dist w z` is included in `s`, then `‖f w‖ = ‖f z‖`. -/
theorem norm_eq_norm_of_isMaxOn_of_ball_subset {f : E → F} {s : Set E} {z w : E}
(hd : DiffContOnCl ℂ f s) (hz : IsMaxOn (norm ∘ f) s z) (hsub : ball z (dist w z) ⊆ s) :
‖f w‖ = ‖f z‖ :=
norm_eqOn_closedBall_of_isMaxOn (hd.mono hsub) (hz.on_subset hsub) (mem_closedBall.2 le_rfl)
/-- **Maximum modulus principle**: if `f : E → F` is complex differentiable in a neighborhood of `c`
and the norm `‖f z‖` has a local maximum at `c`, then `‖f z‖` is locally constant in a neighborhood
of `c`. -/
theorem norm_eventually_eq_of_isLocalMax {f : E → F} {c : E}
(hd : ∀ᶠ z in 𝓝 c, DifferentiableAt ℂ f z) (hc : IsLocalMax (norm ∘ f) c) :
∀ᶠ y in 𝓝 c, ‖f y‖ = ‖f c‖ := by
rcases nhds_basis_closedBall.eventually_iff.1 (hd.and hc) with ⟨r, hr₀, hr⟩
exact nhds_basis_closedBall.eventually_iff.2
⟨r, hr₀, norm_eqOn_closedBall_of_isMaxOn (DifferentiableOn.diffContOnCl fun x hx =>
(hr <| closure_ball_subset_closedBall hx).1.differentiableWithinAt) fun x hx =>
(hr <| ball_subset_closedBall hx).2⟩
theorem isOpen_setOf_mem_nhds_and_isMaxOn_norm {f : E → F} {s : Set E}
(hd : DifferentiableOn ℂ f s) : IsOpen {z | s ∈ 𝓝 z ∧ IsMaxOn (norm ∘ f) s z} := by
refine isOpen_iff_mem_nhds.2 fun z hz => (eventually_eventually_nhds.2 hz.1).and ?_
replace hd : ∀ᶠ w in 𝓝 z, DifferentiableAt ℂ f w := hd.eventually_differentiableAt hz.1
exact (norm_eventually_eq_of_isLocalMax hd <| hz.2.isLocalMax hz.1).mono fun x hx y hy =>
le_trans (hz.2 hy).out hx.ge
/-- **Maximum modulus principle** on a connected set. Let `U` be a (pre)connected open set in a
complex normed space. Let `f : E → F` be a function that is complex differentiable on `U`. Suppose
that `‖f x‖` takes its maximum value on `U` at `c ∈ U`. Then `‖f x‖ = ‖f c‖` for all `x ∈ U`. -/
theorem norm_eqOn_of_isPreconnected_of_isMaxOn {f : E → F} {U : Set E} {c : E}
(hc : IsPreconnected U) (ho : IsOpen U) (hd : DifferentiableOn ℂ f U) (hcU : c ∈ U)
(hm : IsMaxOn (norm ∘ f) U c) : EqOn (norm ∘ f) (const E ‖f c‖) U := by
set V := U ∩ {z | IsMaxOn (norm ∘ f) U z}
have hV : ∀ x ∈ V, ‖f x‖ = ‖f c‖ := fun x hx => le_antisymm (hm hx.1) (hx.2 hcU)
suffices U ⊆ V from fun x hx => hV x (this hx)
have hVo : IsOpen V := by
simpa only [ho.mem_nhds_iff, setOf_and, setOf_mem_eq]
using isOpen_setOf_mem_nhds_and_isMaxOn_norm hd
have hVne : (U ∩ V).Nonempty := ⟨c, hcU, hcU, hm⟩
set W := U ∩ {z | ‖f z‖ ≠ ‖f c‖}
have hWo : IsOpen W := hd.continuousOn.norm.isOpen_inter_preimage ho isOpen_ne
have hdVW : Disjoint V W := disjoint_left.mpr fun x hxV hxW => hxW.2 (hV x hxV)
have hUVW : U ⊆ V ∪ W := fun x hx =>
(eq_or_ne ‖f x‖ ‖f c‖).imp (fun h => ⟨hx, fun y hy => (hm hy).out.trans_eq h.symm⟩)
(And.intro hx)
exact hc.subset_left_of_subset_union hVo hWo hdVW hUVW hVne
/-- **Maximum modulus principle** on a connected set. Let `U` be a (pre)connected open set in a
complex normed space. Let `f : E → F` be a function that is complex differentiable on `U` and is
continuous on its closure. Suppose that `‖f x‖` takes its maximum value on `U` at `c ∈ U`. Then
`‖f x‖ = ‖f c‖` for all `x ∈ closure U`. -/
theorem norm_eqOn_closure_of_isPreconnected_of_isMaxOn {f : E → F} {U : Set E} {c : E}
(hc : IsPreconnected U) (ho : IsOpen U) (hd : DiffContOnCl ℂ f U) (hcU : c ∈ U)
(hm : IsMaxOn (norm ∘ f) U c) : EqOn (norm ∘ f) (const E ‖f c‖) (closure U) :=
(norm_eqOn_of_isPreconnected_of_isMaxOn hc ho hd.differentiableOn hcU hm).of_subset_closure
hd.continuousOn.norm continuousOn_const subset_closure Subset.rfl
section StrictConvex
/-!
### The case of a strictly convex codomain
If the codomain `F` is a strictly convex space, then we can claim equalities like `f w = f z`
instead of `‖f w‖ = ‖f z‖`.
Instead of repeating the proof starting with lemmas about integrals, we apply a corresponding lemma
above twice: for `f` and for `(f · + f c)`. Then we have `‖f w‖ = ‖f z‖` and
`‖f w + f z‖ = ‖f z + f z‖`, thus `‖f w + f z‖ = ‖f w‖ + ‖f z‖`. This is only possible if
`f w = f z`, see `eq_of_norm_eq_of_norm_add_eq`.
-/
variable [StrictConvexSpace ℝ F]
/-- **Maximum modulus principle** on a connected set. Let `U` be a (pre)connected open set in a
complex normed space. Let `f : E → F` be a function that is complex differentiable on `U`. Suppose
that `‖f x‖` takes its maximum value on `U` at `c ∈ U`. Then `f x = f c` for all `x ∈ U`.
TODO: change assumption from `IsMaxOn` to `IsLocalMax`. -/
theorem eqOn_of_isPreconnected_of_isMaxOn_norm {f : E → F} {U : Set E} {c : E}
(hc : IsPreconnected U) (ho : IsOpen U) (hd : DifferentiableOn ℂ f U) (hcU : c ∈ U)
(hm : IsMaxOn (norm ∘ f) U c) : EqOn f (const E (f c)) U := fun x hx =>
have H₁ : ‖f x‖ = ‖f c‖ := norm_eqOn_of_isPreconnected_of_isMaxOn hc ho hd hcU hm hx
have H₂ : ‖f x + f c‖ = ‖f c + f c‖ :=
norm_eqOn_of_isPreconnected_of_isMaxOn hc ho (hd.add_const _) hcU hm.norm_add_self hx
eq_of_norm_eq_of_norm_add_eq H₁ <| by simp only [H₂, SameRay.rfl.norm_add, H₁, Function.const]
/-- **Maximum modulus principle** on a connected set. Let `U` be a (pre)connected open set in a
complex normed space. Let `f : E → F` be a function that is complex differentiable on `U` and is
continuous on its closure. Suppose that `‖f x‖` takes its maximum value on `U` at `c ∈ U`. Then
`f x = f c` for all `x ∈ closure U`. -/
theorem eqOn_closure_of_isPreconnected_of_isMaxOn_norm {f : E → F} {U : Set E} {c : E}
(hc : IsPreconnected U) (ho : IsOpen U) (hd : DiffContOnCl ℂ f U) (hcU : c ∈ U)
(hm : IsMaxOn (norm ∘ f) U c) : EqOn f (const E (f c)) (closure U) :=
(eqOn_of_isPreconnected_of_isMaxOn_norm hc ho hd.differentiableOn hcU hm).of_subset_closure
hd.continuousOn continuousOn_const subset_closure Subset.rfl
/-- **Maximum modulus principle**. Let `f : E → F` be a function between complex normed spaces.
Suppose that the codomain `F` is a strictly convex space, `f` is complex differentiable on a set
`s`, `f` is continuous on the closure of `s`, the norm of `f` takes it maximum on `s` at `z`, and
`w` is a point such that the closed ball with center `z` and radius `dist w z` is included in `s`,
then `f w = f z`. -/
theorem eq_of_isMaxOn_of_ball_subset {f : E → F} {s : Set E} {z w : E} (hd : DiffContOnCl ℂ f s)
(hz : IsMaxOn (norm ∘ f) s z) (hsub : ball z (dist w z) ⊆ s) : f w = f z :=
have H₁ : ‖f w‖ = ‖f z‖ := norm_eq_norm_of_isMaxOn_of_ball_subset hd hz hsub
have H₂ : ‖f w + f z‖ = ‖f z + f z‖ :=
norm_eq_norm_of_isMaxOn_of_ball_subset (hd.add_const _) hz.norm_add_self hsub
eq_of_norm_eq_of_norm_add_eq H₁ <| by simp only [H₂, SameRay.rfl.norm_add, H₁]
/-- **Maximum modulus principle** on a closed ball. Suppose that a function `f : E → F` from a
normed complex space to a strictly convex normed complex space has the following properties:
- it is continuous on a closed ball `Metric.closedBall z r`,
- it is complex differentiable on the corresponding open ball;
- the norm `‖f w‖` takes its maximum value on the open ball at its center.
Then `f` is a constant on the closed ball. -/
theorem eqOn_closedBall_of_isMaxOn_norm {f : E → F} {z : E} {r : ℝ}
(hd : DiffContOnCl ℂ f (ball z r)) (hz : IsMaxOn (norm ∘ f) (ball z r) z) :
EqOn f (const E (f z)) (closedBall z r) := fun _x hx =>
eq_of_isMaxOn_of_ball_subset hd hz <| ball_subset_ball hx
/-- If `f` is differentiable on the open unit ball `{z : ℂ | ‖z‖ < 1}`, and `‖f‖` attains a maximum
in this open ball, then `f` is constant. -/
lemma eq_const_of_exists_max {f : E → F} {b : ℝ} (h_an : DifferentiableOn ℂ f (ball 0 b))
{v : E} (hv : v ∈ ball 0 b) (hv_max : IsMaxOn (norm ∘ f) (ball 0 b) v) :
Set.EqOn f (Function.const E (f v)) (ball 0 b) :=
Complex.eqOn_of_isPreconnected_of_isMaxOn_norm (convex_ball 0 b).isPreconnected
isOpen_ball h_an hv hv_max
/-- If `f` is a function differentiable on the open unit ball, and there exists an `r < 1` such that
any value of `‖f‖` on the open ball is bounded above by some value on the closed ball of radius `r`,
then `f` is constant. -/
lemma eq_const_of_exists_le [ProperSpace E] {f : E → F} {r b : ℝ}
(h_an : DifferentiableOn ℂ f (ball 0 b)) (hr_nn : 0 ≤ r) (hr_lt : r < b)
(hr : ∀ z, z ∈ (ball 0 b) → ∃ w, w ∈ closedBall 0 r ∧ ‖f z‖ ≤ ‖f w‖) :
Set.EqOn f (Function.const E (f 0)) (ball 0 b) := by
obtain ⟨x, hx_mem, hx_max⟩ := isCompact_closedBall (0 : E) r |>.exists_isMaxOn
(nonempty_closedBall.mpr hr_nn)
| (h_an.continuousOn.mono <| closedBall_subset_ball hr_lt).norm
suffices Set.EqOn f (Function.const E (f x)) (ball 0 b) by
rwa [this (mem_ball_self (hr_nn.trans_lt hr_lt))]
apply eq_const_of_exists_max h_an (closedBall_subset_ball hr_lt hx_mem) (fun z hz ↦ ?_)
obtain ⟨w, hw, hw'⟩ := hr z hz
exact hw'.trans (hx_max hw)
/-- **Maximum modulus principle**: if `f : E → F` is complex differentiable in a neighborhood of `c`
| Mathlib/Analysis/Complex/AbsMax.lean | 333 | 340 |
/-
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.RightHomology
/-!
# Homology of short complexes
In this file, we shall define the homology of short complexes `S`, i.e. diagrams
`f : X₁ ⟶ X₂` and `g : X₂ ⟶ X₃` such that `f ≫ g = 0`. We shall say that
`[S.HasHomology]` when there exists `h : S.HomologyData`. A homology data
for `S` consists of compatible left/right homology data `left` and `right`. The
left homology data `left` involves an object `left.H` that is a cokernel of the canonical
map `S.X₁ ⟶ K` where `K` is a kernel of `g`. On the other hand, the dual notion `right.H`
is a kernel of the canonical morphism `Q ⟶ S.X₃` when `Q` is a cokernel of `f`.
The compatibility that is required involves an isomorphism `left.H ≅ right.H` which
makes a certain pentagon commute. When such a homology data exists, `S.homology`
shall be defined as `h.left.H` for a chosen `h : S.HomologyData`.
This definition requires very little assumption on the category (only the existence
of zero morphisms). We shall prove that in abelian categories, all short complexes
have homology data.
Note: This definition arose by the end of the Liquid Tensor Experiment which
contained a structure `has_homology` which is quite similar to `S.HomologyData`.
After the category `ShortComplex C` was introduced by J. Riou, A. Topaz suggested
such a structure could be used as a basis for the *definition* of homology.
-/
universe v u
namespace CategoryTheory
open Category Limits
variable {C : Type u} [Category.{v} C] [HasZeroMorphisms C] (S : ShortComplex C)
{S₁ S₂ S₃ S₄ : ShortComplex C}
namespace ShortComplex
/-- A homology data for a short complex consists of two compatible left and
right homology data -/
structure HomologyData where
/-- a left homology data -/
left : S.LeftHomologyData
/-- a right homology data -/
right : S.RightHomologyData
/-- the compatibility isomorphism relating the two dual notions of
`LeftHomologyData` and `RightHomologyData` -/
iso : left.H ≅ right.H
/-- the pentagon relation expressing the compatibility of the left
and right homology data -/
comm : left.π ≫ iso.hom ≫ right.ι = left.i ≫ right.p := by aesop_cat
attribute [reassoc (attr := simp)] HomologyData.comm
variable (φ : S₁ ⟶ S₂) (h₁ : S₁.HomologyData) (h₂ : S₂.HomologyData)
/-- A homology map data for a morphism `φ : S₁ ⟶ S₂` where both `S₁` and `S₂` are
equipped with homology data consists of left and right homology map data. -/
structure HomologyMapData where
/-- a left homology map data -/
left : LeftHomologyMapData φ h₁.left h₂.left
/-- a right homology map data -/
right : RightHomologyMapData φ h₁.right h₂.right
namespace HomologyMapData
variable {φ h₁ h₂}
@[reassoc]
lemma comm (h : HomologyMapData φ h₁ h₂) :
h.left.φH ≫ h₂.iso.hom = h₁.iso.hom ≫ h.right.φH := by
simp only [← cancel_epi h₁.left.π, ← cancel_mono h₂.right.ι, assoc,
LeftHomologyMapData.commπ_assoc, HomologyData.comm, LeftHomologyMapData.commi_assoc,
RightHomologyMapData.commι, HomologyData.comm_assoc, RightHomologyMapData.commp]
instance : Subsingleton (HomologyMapData φ h₁ h₂) := ⟨by
rintro ⟨left₁, right₁⟩ ⟨left₂, right₂⟩
simp only [mk.injEq, eq_iff_true_of_subsingleton, and_self]⟩
instance : Inhabited (HomologyMapData φ h₁ h₂) :=
⟨⟨default, default⟩⟩
instance : Unique (HomologyMapData φ h₁ h₂) := Unique.mk' _
variable (φ h₁ h₂)
/-- A choice of the (unique) homology map data associated with a morphism
`φ : S₁ ⟶ S₂` where both short complexes `S₁` and `S₂` are equipped with
homology data. -/
def homologyMapData : HomologyMapData φ h₁ h₂ := default
variable {φ h₁ h₂}
lemma congr_left_φH {γ₁ γ₂ : HomologyMapData φ h₁ h₂} (eq : γ₁ = γ₂) :
γ₁.left.φH = γ₂.left.φH := by rw [eq]
end HomologyMapData
namespace HomologyData
/-- When the first map `S.f` is zero, this is the homology data on `S` given
by any limit kernel fork of `S.g` -/
@[simps]
def ofIsLimitKernelFork (hf : S.f = 0) (c : KernelFork S.g) (hc : IsLimit c) :
S.HomologyData where
left := LeftHomologyData.ofIsLimitKernelFork S hf c hc
right := RightHomologyData.ofIsLimitKernelFork S hf c hc
iso := Iso.refl _
/-- When the first map `S.f` is zero, this is the homology data on `S` given
by the chosen `kernel S.g` -/
@[simps]
noncomputable def ofHasKernel (hf : S.f = 0) [HasKernel S.g] :
S.HomologyData where
left := LeftHomologyData.ofHasKernel S hf
right := RightHomologyData.ofHasKernel S hf
iso := Iso.refl _
/-- When the second map `S.g` is zero, this is the 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.HomologyData where
left := LeftHomologyData.ofIsColimitCokernelCofork S hg c hc
right := RightHomologyData.ofIsColimitCokernelCofork S hg c hc
iso := Iso.refl _
/-- When the second map `S.g` is zero, this is the homology data on `S` given by
the chosen `cokernel S.f` -/
@[simps]
noncomputable def ofHasCokernel (hg : S.g = 0) [HasCokernel S.f] :
S.HomologyData where
left := LeftHomologyData.ofHasCokernel S hg
right := RightHomologyData.ofHasCokernel S hg
iso := Iso.refl _
/-- When both `S.f` and `S.g` are zero, the middle object `S.X₂` gives a homology data on S -/
@[simps]
noncomputable def ofZeros (hf : S.f = 0) (hg : S.g = 0) :
S.HomologyData where
left := LeftHomologyData.ofZeros S hf hg
right := RightHomologyData.ofZeros S hf hg
iso := Iso.refl _
/-- If `φ : S₁ ⟶ S₂` is a morphism of short complexes such that `φ.τ₁` is epi, `φ.τ₂` is an iso
and `φ.τ₃` is mono, then a homology data for `S₁` induces a homology data for `S₂`.
The inverse construction is `ofEpiOfIsIsoOfMono'`. -/
@[simps]
noncomputable def ofEpiOfIsIsoOfMono (φ : S₁ ⟶ S₂) (h : HomologyData S₁)
[Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] : HomologyData S₂ where
left := LeftHomologyData.ofEpiOfIsIsoOfMono φ h.left
right := RightHomologyData.ofEpiOfIsIsoOfMono φ h.right
iso := h.iso
/-- If `φ : S₁ ⟶ S₂` is a morphism of short complexes such that `φ.τ₁` is epi, `φ.τ₂` is an iso
and `φ.τ₃` is mono, then a homology data for `S₂` induces a homology data for `S₁`.
The inverse construction is `ofEpiOfIsIsoOfMono`. -/
@[simps]
noncomputable def ofEpiOfIsIsoOfMono' (φ : S₁ ⟶ S₂) (h : HomologyData S₂)
[Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] : HomologyData S₁ where
left := LeftHomologyData.ofEpiOfIsIsoOfMono' φ h.left
right := RightHomologyData.ofEpiOfIsIsoOfMono' φ h.right
iso := h.iso
/-- If `e : S₁ ≅ S₂` is an isomorphism of short complexes and `h₁ : HomologyData S₁`,
this is the homology data for `S₂` deduced from the isomorphism. -/
@[simps!]
noncomputable def ofIso (e : S₁ ≅ S₂) (h : HomologyData S₁) :=
h.ofEpiOfIsIsoOfMono e.hom
variable {S}
/-- A homology data for a short complex `S` induces a homology data for `S.op`. -/
@[simps]
def op (h : S.HomologyData) : S.op.HomologyData where
left := h.right.op
right := h.left.op
iso := h.iso.op
comm := Quiver.Hom.unop_inj (by simp)
/-- A homology data for a short complex `S` in the opposite category
induces a homology data for `S.unop`. -/
@[simps]
def unop {S : ShortComplex Cᵒᵖ} (h : S.HomologyData) : S.unop.HomologyData where
left := h.right.unop
right := h.left.unop
iso := h.iso.unop
comm := Quiver.Hom.op_inj (by simp)
end HomologyData
/-- A short complex `S` has homology when there exists a `S.HomologyData` -/
class HasHomology : Prop where
/-- the condition that there exists a homology data -/
condition : Nonempty S.HomologyData
/-- A chosen `S.HomologyData` for a short complex `S` that has homology -/
noncomputable def homologyData [HasHomology S] :
S.HomologyData := HasHomology.condition.some
variable {S}
lemma HasHomology.mk' (h : S.HomologyData) : HasHomology S :=
⟨Nonempty.intro h⟩
instance [HasHomology S] : HasHomology S.op :=
HasHomology.mk' S.homologyData.op
instance (S : ShortComplex Cᵒᵖ) [HasHomology S] : HasHomology S.unop :=
HasHomology.mk' S.homologyData.unop
instance hasLeftHomology_of_hasHomology [S.HasHomology] : S.HasLeftHomology :=
HasLeftHomology.mk' S.homologyData.left
instance hasRightHomology_of_hasHomology [S.HasHomology] : S.HasRightHomology :=
HasRightHomology.mk' S.homologyData.right
instance hasHomology_of_hasCokernel {X Y : C} (f : X ⟶ Y) (Z : C) [HasCokernel f] :
(ShortComplex.mk f (0 : Y ⟶ Z) comp_zero).HasHomology :=
HasHomology.mk' (HomologyData.ofHasCokernel _ rfl)
instance hasHomology_of_hasKernel {Y Z : C} (g : Y ⟶ Z) (X : C) [HasKernel g] :
(ShortComplex.mk (0 : X ⟶ Y) g zero_comp).HasHomology :=
HasHomology.mk' (HomologyData.ofHasKernel _ rfl)
instance hasHomology_of_zeros (X Y Z : C) :
(ShortComplex.mk (0 : X ⟶ Y) (0 : Y ⟶ Z) zero_comp).HasHomology :=
HasHomology.mk' (HomologyData.ofZeros _ rfl rfl)
lemma hasHomology_of_epi_of_isIso_of_mono (φ : S₁ ⟶ S₂) [HasHomology S₁]
[Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] : HasHomology S₂ :=
HasHomology.mk' (HomologyData.ofEpiOfIsIsoOfMono φ S₁.homologyData)
lemma hasHomology_of_epi_of_isIso_of_mono' (φ : S₁ ⟶ S₂) [HasHomology S₂]
[Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] : HasHomology S₁ :=
HasHomology.mk' (HomologyData.ofEpiOfIsIsoOfMono' φ S₂.homologyData)
lemma hasHomology_of_iso (e : S₁ ≅ S₂) [HasHomology S₁] : HasHomology S₂ :=
HasHomology.mk' (HomologyData.ofIso e S₁.homologyData)
namespace HomologyMapData
/-- The homology map data associated to the identity morphism of a short complex. -/
@[simps]
def id (h : S.HomologyData) : HomologyMapData (𝟙 S) h h where
left := LeftHomologyMapData.id h.left
right := RightHomologyMapData.id h.right
/-- The homology map data associated to the zero morphism between two short complexes. -/
@[simps]
def zero (h₁ : S₁.HomologyData) (h₂ : S₂.HomologyData) :
HomologyMapData 0 h₁ h₂ where
left := LeftHomologyMapData.zero h₁.left h₂.left
right := RightHomologyMapData.zero h₁.right h₂.right
/-- The composition of homology map data. -/
@[simps]
def comp {φ : S₁ ⟶ S₂} {φ' : S₂ ⟶ S₃} {h₁ : S₁.HomologyData}
{h₂ : S₂.HomologyData} {h₃ : S₃.HomologyData}
(ψ : HomologyMapData φ h₁ h₂) (ψ' : HomologyMapData φ' h₂ h₃) :
HomologyMapData (φ ≫ φ') h₁ h₃ where
left := ψ.left.comp ψ'.left
right := ψ.right.comp ψ'.right
/-- A homology map data for a morphism of short complexes induces
a homology map data in the opposite category. -/
@[simps]
def op {φ : S₁ ⟶ S₂} {h₁ : S₁.HomologyData} {h₂ : S₂.HomologyData}
(ψ : HomologyMapData φ h₁ h₂) :
HomologyMapData (opMap φ) h₂.op h₁.op where
left := ψ.right.op
right := ψ.left.op
/-- A homology map data for a morphism of short complexes in the opposite category
induces a homology map data in the original category. -/
@[simps]
def unop {S₁ S₂ : ShortComplex Cᵒᵖ} {φ : S₁ ⟶ S₂}
{h₁ : S₁.HomologyData} {h₂ : S₂.HomologyData}
(ψ : HomologyMapData φ h₁ h₂) :
HomologyMapData (unopMap φ) h₂.unop h₁.unop where
left := ψ.right.unop
right := ψ.left.unop
/-- When `S₁.f`, `S₁.g`, `S₂.f` and `S₂.g` are all zero, the action on homology of a
morphism `φ : S₁ ⟶ S₂` is given by the action `φ.τ₂` on the middle objects. -/
@[simps]
def ofZeros (φ : S₁ ⟶ S₂) (hf₁ : S₁.f = 0) (hg₁ : S₁.g = 0) (hf₂ : S₂.f = 0) (hg₂ : S₂.g = 0) :
HomologyMapData φ (HomologyData.ofZeros S₁ hf₁ hg₁) (HomologyData.ofZeros S₂ hf₂ hg₂) where
left := LeftHomologyMapData.ofZeros φ hf₁ hg₁ hf₂ hg₂
right := RightHomologyMapData.ofZeros φ hf₁ hg₁ hf₂ hg₂
/-- When `S₁.g` and `S₂.g` are zero and we have chosen colimit cokernel coforks `c₁` and `c₂`
for `S₁.f` and `S₂.f` respectively, the action on homology of a morphism `φ : S₁ ⟶ S₂` of
short complexes is given by the unique morphism `f : c₁.pt ⟶ c₂.pt` such that
`φ.τ₂ ≫ c₂.π = c₁.π ≫ f`. -/
@[simps]
def ofIsColimitCokernelCofork (φ : S₁ ⟶ S₂)
(hg₁ : S₁.g = 0) (c₁ : CokernelCofork S₁.f) (hc₁ : IsColimit c₁)
(hg₂ : S₂.g = 0) (c₂ : CokernelCofork S₂.f) (hc₂ : IsColimit c₂) (f : c₁.pt ⟶ c₂.pt)
(comm : φ.τ₂ ≫ c₂.π = c₁.π ≫ f) :
HomologyMapData φ (HomologyData.ofIsColimitCokernelCofork S₁ hg₁ c₁ hc₁)
(HomologyData.ofIsColimitCokernelCofork S₂ hg₂ c₂ hc₂) where
left := LeftHomologyMapData.ofIsColimitCokernelCofork φ hg₁ c₁ hc₁ hg₂ c₂ hc₂ f comm
right := RightHomologyMapData.ofIsColimitCokernelCofork φ hg₁ c₁ hc₁ hg₂ c₂ hc₂ f comm
/-- When `S₁.f` and `S₂.f` are zero and we have chosen limit kernel forks `c₁` and `c₂`
for `S₁.g` and `S₂.g` respectively, the action on homology of a morphism `φ : S₁ ⟶ S₂` of
short complexes is given by the unique morphism `f : c₁.pt ⟶ c₂.pt` such that
`c₁.ι ≫ φ.τ₂ = f ≫ c₂.ι`. -/
@[simps]
def ofIsLimitKernelFork (φ : S₁ ⟶ S₂)
(hf₁ : S₁.f = 0) (c₁ : KernelFork S₁.g) (hc₁ : IsLimit c₁)
(hf₂ : S₂.f = 0) (c₂ : KernelFork S₂.g) (hc₂ : IsLimit c₂) (f : c₁.pt ⟶ c₂.pt)
(comm : c₁.ι ≫ φ.τ₂ = f ≫ c₂.ι) :
HomologyMapData φ (HomologyData.ofIsLimitKernelFork S₁ hf₁ c₁ hc₁)
(HomologyData.ofIsLimitKernelFork S₂ hf₂ c₂ hc₂) where
left := LeftHomologyMapData.ofIsLimitKernelFork φ hf₁ c₁ hc₁ hf₂ c₂ hc₂ f comm
right := RightHomologyMapData.ofIsLimitKernelFork φ hf₁ c₁ hc₁ hf₂ c₂ hc₂ f comm
/-- When both maps `S.f` and `S.g` of a short complex `S` are zero, this is the homology map
data (for the identity of `S`) which relates the homology data `ofZeros` and
`ofIsColimitCokernelCofork`. -/
def compatibilityOfZerosOfIsColimitCokernelCofork (hf : S.f = 0) (hg : S.g = 0)
(c : CokernelCofork S.f) (hc : IsColimit c) :
HomologyMapData (𝟙 S) (HomologyData.ofZeros S hf hg)
(HomologyData.ofIsColimitCokernelCofork S hg c hc) where
left := LeftHomologyMapData.compatibilityOfZerosOfIsColimitCokernelCofork S hf hg c hc
right := RightHomologyMapData.compatibilityOfZerosOfIsColimitCokernelCofork S hf hg c hc
/-- When both maps `S.f` and `S.g` of a short complex `S` are zero, this is the homology map
data (for the identity of `S`) which relates the homology data
`HomologyData.ofIsLimitKernelFork` and `ofZeros` . -/
@[simps]
def compatibilityOfZerosOfIsLimitKernelFork (hf : S.f = 0) (hg : S.g = 0)
(c : KernelFork S.g) (hc : IsLimit c) :
HomologyMapData (𝟙 S)
(HomologyData.ofIsLimitKernelFork S hf c hc)
(HomologyData.ofZeros S hf hg) where
left := LeftHomologyMapData.compatibilityOfZerosOfIsLimitKernelFork S hf hg c hc
right := RightHomologyMapData.compatibilityOfZerosOfIsLimitKernelFork S hf hg c hc
/-- This homology map data expresses compatibilities of the homology data
constructed by `HomologyData.ofEpiOfIsIsoOfMono` -/
noncomputable def ofEpiOfIsIsoOfMono (φ : S₁ ⟶ S₂) (h : HomologyData S₁)
[Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] :
HomologyMapData φ h (HomologyData.ofEpiOfIsIsoOfMono φ h) where
left := LeftHomologyMapData.ofEpiOfIsIsoOfMono φ h.left
right := RightHomologyMapData.ofEpiOfIsIsoOfMono φ h.right
/-- This homology map data expresses compatibilities of the homology data
constructed by `HomologyData.ofEpiOfIsIsoOfMono'` -/
noncomputable def ofEpiOfIsIsoOfMono' (φ : S₁ ⟶ S₂) (h : HomologyData S₂)
[Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] :
HomologyMapData φ (HomologyData.ofEpiOfIsIsoOfMono' φ h) h where
left := LeftHomologyMapData.ofEpiOfIsIsoOfMono' φ h.left
right := RightHomologyMapData.ofEpiOfIsIsoOfMono' φ h.right
end HomologyMapData
variable (S)
/-- The homology of a short complex is the `left.H` field of a chosen homology data. -/
noncomputable def homology [HasHomology S] : C := S.homologyData.left.H
/-- When a short complex has homology, this is the canonical isomorphism
`S.leftHomology ≅ S.homology`. -/
noncomputable def leftHomologyIso [S.HasHomology] : S.leftHomology ≅ S.homology :=
leftHomologyMapIso' (Iso.refl _) _ _
/-- When a short complex has homology, this is the canonical isomorphism
`S.rightHomology ≅ S.homology`. -/
noncomputable def rightHomologyIso [S.HasHomology] : S.rightHomology ≅ S.homology :=
rightHomologyMapIso' (Iso.refl _) _ _ ≪≫ S.homologyData.iso.symm
variable {S}
/-- When a short complex has homology, its homology can be computed using
any left homology data. -/
noncomputable def LeftHomologyData.homologyIso (h : S.LeftHomologyData) [S.HasHomology] :
S.homology ≅ h.H := S.leftHomologyIso.symm ≪≫ h.leftHomologyIso
/-- When a short complex has homology, its homology can be computed using
any right homology data. -/
noncomputable def RightHomologyData.homologyIso (h : S.RightHomologyData) [S.HasHomology] :
S.homology ≅ h.H := S.rightHomologyIso.symm ≪≫ h.rightHomologyIso
variable (S)
@[simp]
lemma LeftHomologyData.homologyIso_leftHomologyData [S.HasHomology] :
S.leftHomologyData.homologyIso = S.leftHomologyIso.symm := by
ext
dsimp [homologyIso, leftHomologyIso, ShortComplex.leftHomologyIso]
rw [← leftHomologyMap'_comp, comp_id]
@[simp]
lemma RightHomologyData.homologyIso_rightHomologyData [S.HasHomology] :
S.rightHomologyData.homologyIso = S.rightHomologyIso.symm := by
ext
simp [homologyIso, rightHomologyIso]
variable {S}
/-- Given a morphism `φ : S₁ ⟶ S₂` of short complexes and homology data `h₁` and `h₂`
for `S₁` and `S₂` respectively, this is the induced homology map `h₁.left.H ⟶ h₁.left.H`. -/
def homologyMap' (φ : S₁ ⟶ S₂) (h₁ : S₁.HomologyData) (h₂ : S₂.HomologyData) :
h₁.left.H ⟶ h₂.left.H := leftHomologyMap' φ _ _
/-- The homology map `S₁.homology ⟶ S₂.homology` induced by a morphism
`S₁ ⟶ S₂` of short complexes. -/
noncomputable def homologyMap (φ : S₁ ⟶ S₂) [HasHomology S₁] [HasHomology S₂] :
S₁.homology ⟶ S₂.homology :=
homologyMap' φ _ _
namespace HomologyMapData
variable {φ : S₁ ⟶ S₂} {h₁ : S₁.HomologyData} {h₂ : S₂.HomologyData}
(γ : HomologyMapData φ h₁ h₂)
lemma homologyMap'_eq : homologyMap' φ h₁ h₂ = γ.left.φH :=
LeftHomologyMapData.congr_φH (Subsingleton.elim _ _)
lemma cyclesMap'_eq : cyclesMap' φ h₁.left h₂.left = γ.left.φK :=
LeftHomologyMapData.congr_φK (Subsingleton.elim _ _)
lemma opcyclesMap'_eq : opcyclesMap' φ h₁.right h₂.right = γ.right.φQ :=
RightHomologyMapData.congr_φQ (Subsingleton.elim _ _)
end HomologyMapData
namespace LeftHomologyMapData
variable {h₁ : S₁.LeftHomologyData} {h₂ : S₂.LeftHomologyData}
(γ : LeftHomologyMapData φ h₁ h₂) [S₁.HasHomology] [S₂.HasHomology]
lemma homologyMap_eq :
homologyMap φ = h₁.homologyIso.hom ≫ γ.φH ≫ h₂.homologyIso.inv := by
dsimp [homologyMap, LeftHomologyData.homologyIso, leftHomologyIso,
LeftHomologyData.leftHomologyIso, homologyMap']
simp only [← γ.leftHomologyMap'_eq, ← leftHomologyMap'_comp, id_comp, comp_id]
lemma homologyMap_comm :
homologyMap φ ≫ h₂.homologyIso.hom = h₁.homologyIso.hom ≫ γ.φH := by
simp only [γ.homologyMap_eq, assoc, Iso.inv_hom_id, comp_id]
end LeftHomologyMapData
namespace RightHomologyMapData
variable {h₁ : S₁.RightHomologyData} {h₂ : S₂.RightHomologyData}
(γ : RightHomologyMapData φ h₁ h₂) [S₁.HasHomology] [S₂.HasHomology]
lemma homologyMap_eq :
homologyMap φ = h₁.homologyIso.hom ≫ γ.φH ≫ h₂.homologyIso.inv := by
dsimp [homologyMap, homologyMap', RightHomologyData.homologyIso,
rightHomologyIso, RightHomologyData.rightHomologyIso]
have γ' : HomologyMapData φ S₁.homologyData S₂.homologyData := default
simp only [← γ.rightHomologyMap'_eq, assoc, ← rightHomologyMap'_comp_assoc,
id_comp, comp_id, γ'.left.leftHomologyMap'_eq, γ'.right.rightHomologyMap'_eq, ← γ'.comm_assoc,
Iso.hom_inv_id]
lemma homologyMap_comm :
homologyMap φ ≫ h₂.homologyIso.hom = h₁.homologyIso.hom ≫ γ.φH := by
simp only [γ.homologyMap_eq, assoc, Iso.inv_hom_id, comp_id]
end RightHomologyMapData
@[simp]
lemma homologyMap'_id (h : S.HomologyData) :
homologyMap' (𝟙 S) h h = 𝟙 _ :=
(HomologyMapData.id h).homologyMap'_eq
variable (S)
@[simp]
lemma homologyMap_id [HasHomology S] :
homologyMap (𝟙 S) = 𝟙 _ :=
homologyMap'_id _
@[simp]
lemma homologyMap'_zero (h₁ : S₁.HomologyData) (h₂ : S₂.HomologyData) :
homologyMap' 0 h₁ h₂ = 0 :=
(HomologyMapData.zero h₁ h₂).homologyMap'_eq
variable (S₁ S₂)
@[simp]
lemma homologyMap_zero [S₁.HasHomology] [S₂.HasHomology] :
homologyMap (0 : S₁ ⟶ S₂) = 0 :=
homologyMap'_zero _ _
variable {S₁ S₂}
lemma homologyMap'_comp (φ₁ : S₁ ⟶ S₂) (φ₂ : S₂ ⟶ S₃)
(h₁ : S₁.HomologyData) (h₂ : S₂.HomologyData) (h₃ : S₃.HomologyData) :
homologyMap' (φ₁ ≫ φ₂) h₁ h₃ = homologyMap' φ₁ h₁ h₂ ≫
homologyMap' φ₂ h₂ h₃ :=
leftHomologyMap'_comp _ _ _ _ _
@[simp]
lemma homologyMap_comp [HasHomology S₁] [HasHomology S₂] [HasHomology S₃]
(φ₁ : S₁ ⟶ S₂) (φ₂ : S₂ ⟶ S₃) :
homologyMap (φ₁ ≫ φ₂) = homologyMap φ₁ ≫ homologyMap φ₂ :=
homologyMap'_comp _ _ _ _ _
/-- Given an isomorphism `S₁ ≅ S₂` of short complexes and homology data `h₁` and `h₂`
for `S₁` and `S₂` respectively, this is the induced homology isomorphism `h₁.left.H ≅ h₁.left.H`. -/
@[simps]
def homologyMapIso' (e : S₁ ≅ S₂) (h₁ : S₁.HomologyData)
(h₂ : S₂.HomologyData) : h₁.left.H ≅ h₂.left.H where
hom := homologyMap' e.hom h₁ h₂
inv := homologyMap' e.inv h₂ h₁
hom_inv_id := by rw [← homologyMap'_comp, e.hom_inv_id, homologyMap'_id]
inv_hom_id := by rw [← homologyMap'_comp, e.inv_hom_id, homologyMap'_id]
instance isIso_homologyMap'_of_isIso (φ : S₁ ⟶ S₂) [IsIso φ]
(h₁ : S₁.HomologyData) (h₂ : S₂.HomologyData) :
IsIso (homologyMap' φ h₁ h₂) :=
(inferInstance : IsIso (homologyMapIso' (asIso φ) h₁ h₂).hom)
/-- The homology isomorphism `S₁.homology ⟶ S₂.homology` induced by an isomorphism
`S₁ ≅ S₂` of short complexes. -/
@[simps]
noncomputable def homologyMapIso (e : S₁ ≅ S₂) [S₁.HasHomology]
[S₂.HasHomology] : S₁.homology ≅ S₂.homology where
hom := homologyMap e.hom
inv := homologyMap e.inv
hom_inv_id := by rw [← homologyMap_comp, e.hom_inv_id, homologyMap_id]
inv_hom_id := by rw [← homologyMap_comp, e.inv_hom_id, homologyMap_id]
instance isIso_homologyMap_of_iso (φ : S₁ ⟶ S₂) [IsIso φ] [S₁.HasHomology]
[S₂.HasHomology] :
IsIso (homologyMap φ) :=
(inferInstance : IsIso (homologyMapIso (asIso φ)).hom)
variable {S}
section
variable (h₁ : S.LeftHomologyData) (h₂ : S.RightHomologyData)
/-- If a short complex `S` has both a left homology data `h₁` and a right homology data `h₂`,
this is the canonical morphism `h₁.H ⟶ h₂.H`. -/
def leftRightHomologyComparison' : h₁.H ⟶ h₂.H :=
h₂.liftH (h₁.descH (h₁.i ≫ h₂.p) (by simp))
(by rw [← cancel_epi h₁.π, LeftHomologyData.π_descH_assoc, assoc,
RightHomologyData.p_g', LeftHomologyData.wi, comp_zero])
lemma leftRightHomologyComparison'_eq_liftH :
leftRightHomologyComparison' h₁ h₂ =
h₂.liftH (h₁.descH (h₁.i ≫ h₂.p) (by simp))
(by rw [← cancel_epi h₁.π, LeftHomologyData.π_descH_assoc, assoc,
RightHomologyData.p_g', LeftHomologyData.wi, comp_zero]) := rfl
@[reassoc (attr := simp)]
lemma π_leftRightHomologyComparison'_ι :
h₁.π ≫ leftRightHomologyComparison' h₁ h₂ ≫ h₂.ι = h₁.i ≫ h₂.p := by
simp only [leftRightHomologyComparison'_eq_liftH,
RightHomologyData.liftH_ι, LeftHomologyData.π_descH]
lemma leftRightHomologyComparison'_eq_descH :
leftRightHomologyComparison' h₁ h₂ =
h₁.descH (h₂.liftH (h₁.i ≫ h₂.p) (by simp))
(by rw [← cancel_mono h₂.ι, assoc, RightHomologyData.liftH_ι,
LeftHomologyData.f'_i_assoc, RightHomologyData.wp, zero_comp]) := by
simp only [← cancel_mono h₂.ι, ← cancel_epi h₁.π, π_leftRightHomologyComparison'_ι,
LeftHomologyData.π_descH_assoc, RightHomologyData.liftH_ι]
end
variable (S)
/-- If a short complex `S` has both a left and right homology,
this is the canonical morphism `S.leftHomology ⟶ S.rightHomology`. -/
noncomputable def leftRightHomologyComparison [S.HasLeftHomology] [S.HasRightHomology] :
S.leftHomology ⟶ S.rightHomology :=
leftRightHomologyComparison' _ _
@[reassoc (attr := simp)]
lemma π_leftRightHomologyComparison_ι [S.HasLeftHomology] [S.HasRightHomology] :
S.leftHomologyπ ≫ S.leftRightHomologyComparison ≫ S.rightHomologyι =
S.iCycles ≫ S.pOpcycles :=
π_leftRightHomologyComparison'_ι _ _
@[reassoc]
lemma leftRightHomologyComparison'_naturality (φ : S₁ ⟶ S₂) (h₁ : S₁.LeftHomologyData)
(h₂ : S₁.RightHomologyData) (h₁' : S₂.LeftHomologyData) (h₂' : S₂.RightHomologyData) :
leftHomologyMap' φ h₁ h₁' ≫ leftRightHomologyComparison' h₁' h₂' =
leftRightHomologyComparison' h₁ h₂ ≫ rightHomologyMap' φ h₂ h₂' := by
simp only [← cancel_epi h₁.π, ← cancel_mono h₂'.ι, assoc,
leftHomologyπ_naturality'_assoc, rightHomologyι_naturality',
π_leftRightHomologyComparison'_ι, π_leftRightHomologyComparison'_ι_assoc,
cyclesMap'_i_assoc, p_opcyclesMap']
variable {S}
lemma leftRightHomologyComparison'_compatibility (h₁ h₁' : S.LeftHomologyData)
(h₂ h₂' : S.RightHomologyData) :
leftRightHomologyComparison' h₁ h₂ = leftHomologyMap' (𝟙 S) h₁ h₁' ≫
leftRightHomologyComparison' h₁' h₂' ≫ rightHomologyMap' (𝟙 S) _ _ := by
rw [leftRightHomologyComparison'_naturality_assoc (𝟙 S) h₁ h₂ h₁' h₂',
← rightHomologyMap'_comp, comp_id, rightHomologyMap'_id, comp_id]
lemma leftRightHomologyComparison_eq [S.HasLeftHomology] [S.HasRightHomology]
(h₁ : S.LeftHomologyData) (h₂ : S.RightHomologyData) :
S.leftRightHomologyComparison = h₁.leftHomologyIso.hom ≫
leftRightHomologyComparison' h₁ h₂ ≫ h₂.rightHomologyIso.inv :=
leftRightHomologyComparison'_compatibility _ _ _ _
@[simp]
lemma HomologyData.leftRightHomologyComparison'_eq (h : S.HomologyData) :
leftRightHomologyComparison' h.left h.right = h.iso.hom := by
simp only [← cancel_epi h.left.π, ← cancel_mono h.right.ι, assoc,
π_leftRightHomologyComparison'_ι, comm]
instance isIso_leftRightHomologyComparison'_of_homologyData (h : S.HomologyData) :
IsIso (leftRightHomologyComparison' h.left h.right) := by
rw [h.leftRightHomologyComparison'_eq]
infer_instance
instance isIso_leftRightHomologyComparison' [S.HasHomology]
(h₁ : S.LeftHomologyData) (h₂ : S.RightHomologyData) :
IsIso (leftRightHomologyComparison' h₁ h₂) := by
rw [leftRightHomologyComparison'_compatibility h₁ S.homologyData.left h₂
S.homologyData.right]
infer_instance
instance isIso_leftRightHomologyComparison [S.HasHomology] :
IsIso S.leftRightHomologyComparison := by
dsimp only [leftRightHomologyComparison]
infer_instance
namespace HomologyData
/-- This is the homology data for a short complex `S` that is obtained
from a left homology data `h₁` and a right homology data `h₂` when the comparison
morphism `leftRightHomologyComparison' h₁ h₂ : h₁.H ⟶ h₂.H` is an isomorphism. -/
@[simps]
noncomputable def ofIsIsoLeftRightHomologyComparison'
(h₁ : S.LeftHomologyData) (h₂ : S.RightHomologyData)
[IsIso (leftRightHomologyComparison' h₁ h₂)] :
S.HomologyData where
left := h₁
right := h₂
iso := asIso (leftRightHomologyComparison' h₁ h₂)
end HomologyData
lemma leftRightHomologyComparison'_eq_leftHomologpMap'_comp_iso_hom_comp_rightHomologyMap'
(h : S.HomologyData) (h₁ : S.LeftHomologyData) (h₂ : S.RightHomologyData) :
leftRightHomologyComparison' h₁ h₂ =
leftHomologyMap' (𝟙 S) h₁ h.left ≫ h.iso.hom ≫ rightHomologyMap' (𝟙 S) h.right h₂ := by
simpa only [h.leftRightHomologyComparison'_eq] using
leftRightHomologyComparison'_compatibility h₁ h.left h₂ h.right
@[reassoc]
lemma leftRightHomologyComparison'_fac (h₁ : S.LeftHomologyData) (h₂ : S.RightHomologyData)
[S.HasHomology] :
leftRightHomologyComparison' h₁ h₂ = h₁.homologyIso.inv ≫ h₂.homologyIso.hom := by
rw [leftRightHomologyComparison'_eq_leftHomologpMap'_comp_iso_hom_comp_rightHomologyMap'
S.homologyData h₁ h₂]
dsimp only [LeftHomologyData.homologyIso, LeftHomologyData.leftHomologyIso,
Iso.symm, Iso.trans, Iso.refl, leftHomologyMapIso', leftHomologyIso,
RightHomologyData.homologyIso, RightHomologyData.rightHomologyIso,
rightHomologyMapIso', rightHomologyIso]
simp only [assoc, ← leftHomologyMap'_comp_assoc, id_comp, ← rightHomologyMap'_comp]
variable (S)
@[reassoc]
lemma leftRightHomologyComparison_fac [S.HasHomology] :
S.leftRightHomologyComparison = S.leftHomologyIso.hom ≫ S.rightHomologyIso.inv := by
simpa only [LeftHomologyData.homologyIso_leftHomologyData, Iso.symm_inv,
RightHomologyData.homologyIso_rightHomologyData, Iso.symm_hom] using
leftRightHomologyComparison'_fac S.leftHomologyData S.rightHomologyData
variable {S}
lemma HomologyData.right_homologyIso_eq_left_homologyIso_trans_iso
(h : S.HomologyData) [S.HasHomology] :
h.right.homologyIso = h.left.homologyIso ≪≫ h.iso := by
suffices h.iso = h.left.homologyIso.symm ≪≫ h.right.homologyIso by
rw [this, Iso.self_symm_id_assoc]
ext
dsimp
rw [← leftRightHomologyComparison'_fac, leftRightHomologyComparison'_eq]
lemma hasHomology_of_isIso_leftRightHomologyComparison'
(h₁ : S.LeftHomologyData) (h₂ : S.RightHomologyData)
[IsIso (leftRightHomologyComparison' h₁ h₂)] :
S.HasHomology :=
HasHomology.mk' (HomologyData.ofIsIsoLeftRightHomologyComparison' h₁ h₂)
lemma hasHomology_of_isIsoLeftRightHomologyComparison [S.HasLeftHomology]
[S.HasRightHomology] [h : IsIso S.leftRightHomologyComparison] :
S.HasHomology := by
haveI : IsIso (leftRightHomologyComparison' S.leftHomologyData S.rightHomologyData) := h
exact hasHomology_of_isIso_leftRightHomologyComparison' S.leftHomologyData S.rightHomologyData
section
variable [S₁.HasHomology] [S₂.HasHomology] (φ : S₁ ⟶ S₂)
@[reassoc]
lemma LeftHomologyData.leftHomologyIso_hom_naturality
(h₁ : S₁.LeftHomologyData) (h₂ : S₂.LeftHomologyData) :
h₁.homologyIso.hom ≫ leftHomologyMap' φ h₁ h₂ =
homologyMap φ ≫ h₂.homologyIso.hom := by
dsimp [homologyIso, ShortComplex.leftHomologyIso, homologyMap, homologyMap', leftHomologyIso]
simp only [← leftHomologyMap'_comp, id_comp, comp_id]
@[reassoc]
lemma LeftHomologyData.leftHomologyIso_inv_naturality
(h₁ : S₁.LeftHomologyData) (h₂ : S₂.LeftHomologyData) :
h₁.homologyIso.inv ≫ homologyMap φ =
leftHomologyMap' φ h₁ h₂ ≫ h₂.homologyIso.inv := by
dsimp [homologyIso, ShortComplex.leftHomologyIso, homologyMap, homologyMap', leftHomologyIso]
simp only [← leftHomologyMap'_comp, id_comp, comp_id]
@[reassoc]
lemma leftHomologyIso_hom_naturality :
S₁.leftHomologyIso.hom ≫ homologyMap φ =
leftHomologyMap φ ≫ S₂.leftHomologyIso.hom := by
simpa only [LeftHomologyData.homologyIso_leftHomologyData, Iso.symm_inv] using
LeftHomologyData.leftHomologyIso_inv_naturality φ S₁.leftHomologyData S₂.leftHomologyData
@[reassoc]
lemma leftHomologyIso_inv_naturality :
S₁.leftHomologyIso.inv ≫ leftHomologyMap φ =
homologyMap φ ≫ S₂.leftHomologyIso.inv := by
simpa only [LeftHomologyData.homologyIso_leftHomologyData, Iso.symm_inv] using
LeftHomologyData.leftHomologyIso_hom_naturality φ S₁.leftHomologyData S₂.leftHomologyData
@[reassoc]
lemma RightHomologyData.rightHomologyIso_hom_naturality
(h₁ : S₁.RightHomologyData) (h₂ : S₂.RightHomologyData) :
h₁.homologyIso.hom ≫ rightHomologyMap' φ h₁ h₂ =
homologyMap φ ≫ h₂.homologyIso.hom := by
rw [← cancel_epi h₁.homologyIso.inv, Iso.inv_hom_id_assoc,
← cancel_epi (leftRightHomologyComparison' S₁.leftHomologyData h₁),
← leftRightHomologyComparison'_naturality φ S₁.leftHomologyData h₁ S₂.leftHomologyData h₂,
← cancel_epi (S₁.leftHomologyData.homologyIso.hom),
LeftHomologyData.leftHomologyIso_hom_naturality_assoc,
leftRightHomologyComparison'_fac, leftRightHomologyComparison'_fac, assoc,
Iso.hom_inv_id_assoc, Iso.hom_inv_id_assoc, Iso.hom_inv_id_assoc]
@[reassoc]
lemma RightHomologyData.rightHomologyIso_inv_naturality
(h₁ : S₁.RightHomologyData) (h₂ : S₂.RightHomologyData) :
h₁.homologyIso.inv ≫ homologyMap φ =
rightHomologyMap' φ h₁ h₂ ≫ h₂.homologyIso.inv := by
simp only [← cancel_mono h₂.homologyIso.hom, assoc, Iso.inv_hom_id_assoc, comp_id,
← RightHomologyData.rightHomologyIso_hom_naturality φ h₁ h₂, Iso.inv_hom_id]
@[reassoc]
lemma rightHomologyIso_hom_naturality :
S₁.rightHomologyIso.hom ≫ homologyMap φ =
rightHomologyMap φ ≫ S₂.rightHomologyIso.hom := by
simpa only [RightHomologyData.homologyIso_rightHomologyData, Iso.symm_inv] using
RightHomologyData.rightHomologyIso_inv_naturality φ S₁.rightHomologyData S₂.rightHomologyData
@[reassoc]
lemma rightHomologyIso_inv_naturality :
S₁.rightHomologyIso.inv ≫ rightHomologyMap φ =
homologyMap φ ≫ S₂.rightHomologyIso.inv := by
simpa only [RightHomologyData.homologyIso_rightHomologyData, Iso.symm_inv] using
RightHomologyData.rightHomologyIso_hom_naturality φ S₁.rightHomologyData S₂.rightHomologyData
end
variable (C)
/-- We shall say that a category `C` is a category with homology when all short complexes
have homology. -/
class _root_.CategoryTheory.CategoryWithHomology : Prop where
hasHomology : ∀ (S : ShortComplex C), S.HasHomology
attribute [instance] CategoryWithHomology.hasHomology
instance [CategoryWithHomology C] : CategoryWithHomology Cᵒᵖ :=
⟨fun S => HasHomology.mk' S.unop.homologyData.op⟩
/-- The homology functor `ShortComplex C ⥤ C` for a category `C` with homology. -/
@[simps]
noncomputable def homologyFunctor [CategoryWithHomology C] :
ShortComplex C ⥤ C where
obj S := S.homology
map f := homologyMap f
variable {C}
instance isIso_homologyMap'_of_epi_of_isIso_of_mono (φ : S₁ ⟶ S₂)
(h₁ : S₁.HomologyData) (h₂ : S₂.HomologyData) [Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] :
IsIso (homologyMap' φ h₁ h₂) := by
dsimp only [homologyMap']
infer_instance
lemma isIso_homologyMap_of_epi_of_isIso_of_mono' (φ : S₁ ⟶ S₂) [S₁.HasHomology] [S₂.HasHomology]
(h₁ : Epi φ.τ₁) (h₂ : IsIso φ.τ₂) (h₃ : Mono φ.τ₃) :
IsIso (homologyMap φ) := by
dsimp only [homologyMap]
infer_instance
instance isIso_homologyMap_of_epi_of_isIso_of_mono (φ : S₁ ⟶ S₂) [S₁.HasHomology] [S₂.HasHomology]
[Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] :
IsIso (homologyMap φ) :=
isIso_homologyMap_of_epi_of_isIso_of_mono' φ inferInstance inferInstance inferInstance
instance isIso_homologyFunctor_map_of_epi_of_isIso_of_mono (φ : S₁ ⟶ S₂) [CategoryWithHomology C]
[Epi φ.τ₁] [IsIso φ.τ₂] [Mono φ.τ₃] :
IsIso ((homologyFunctor C).map φ) :=
(inferInstance : IsIso (homologyMap φ))
instance isIso_homologyMap_of_isIso (φ : S₁ ⟶ S₂) [S₁.HasHomology] [S₂.HasHomology] [IsIso φ] :
IsIso (homologyMap φ) := by
dsimp only [homologyMap, homologyMap']
infer_instance
section
variable (S) {A : C}
variable [HasHomology S]
/-- The canonical morphism `S.cycles ⟶ S.homology` for a short complex `S` that has homology. -/
noncomputable def homologyπ : S.cycles ⟶ S.homology :=
S.leftHomologyπ ≫ S.leftHomologyIso.hom
/-- The canonical morphism `S.homology ⟶ S.opcycles` for a short complex `S` that has homology. -/
noncomputable def homologyι : S.homology ⟶ S.opcycles :=
S.rightHomologyIso.inv ≫ S.rightHomologyι
@[reassoc (attr := simp)]
lemma homologyπ_comp_leftHomologyIso_inv :
S.homologyπ ≫ S.leftHomologyIso.inv = S.leftHomologyπ := by
dsimp only [homologyπ]
simp only [assoc, Iso.hom_inv_id, comp_id]
@[reassoc (attr := simp)]
lemma rightHomologyIso_hom_comp_homologyι :
S.rightHomologyIso.hom ≫ S.homologyι = S.rightHomologyι := by
dsimp only [homologyι]
simp only [Iso.hom_inv_id_assoc]
@[reassoc (attr := simp)]
lemma toCycles_comp_homologyπ :
S.toCycles ≫ S.homologyπ = 0 := by
dsimp only [homologyπ]
simp only [toCycles_comp_leftHomologyπ_assoc, zero_comp]
@[reassoc (attr := simp)]
lemma homologyι_comp_fromOpcycles :
S.homologyι ≫ S.fromOpcycles = 0 := by
dsimp only [homologyι]
simp only [assoc, rightHomologyι_comp_fromOpcycles, comp_zero]
/-- The homology `S.homology` of a short complex is
the cokernel of the morphism `S.toCycles : S.X₁ ⟶ S.cycles`. -/
noncomputable def homologyIsCokernel :
IsColimit (CokernelCofork.ofπ S.homologyπ S.toCycles_comp_homologyπ) :=
IsColimit.ofIsoColimit S.leftHomologyIsCokernel
(Cofork.ext S.leftHomologyIso rfl)
/-- The homology `S.homology` of a short complex is
the kernel of the morphism `S.fromOpcycles : S.opcycles ⟶ S.X₃`. -/
noncomputable def homologyIsKernel :
IsLimit (KernelFork.ofι S.homologyι S.homologyι_comp_fromOpcycles) :=
IsLimit.ofIsoLimit S.rightHomologyIsKernel
(Fork.ext S.rightHomologyIso (by simp))
instance : Epi S.homologyπ :=
Limits.epi_of_isColimit_cofork (S.homologyIsCokernel)
instance : Mono S.homologyι :=
Limits.mono_of_isLimit_fork (S.homologyIsKernel)
/-- Given a morphism `k : S.cycles ⟶ A` such that `S.toCycles ≫ k = 0`, this is the
induced morphism `S.homology ⟶ A`. -/
noncomputable def descHomology (k : S.cycles ⟶ A) (hk : S.toCycles ≫ k = 0) :
S.homology ⟶ A :=
S.homologyIsCokernel.desc (CokernelCofork.ofπ k hk)
/-- Given a morphism `k : A ⟶ S.opcycles` such that `k ≫ S.fromOpcycles = 0`, this is the
induced morphism `A ⟶ S.homology`. -/
noncomputable def liftHomology (k : A ⟶ S.opcycles) (hk : k ≫ S.fromOpcycles = 0) :
A ⟶ S.homology :=
S.homologyIsKernel.lift (KernelFork.ofι k hk)
@[reassoc (attr := simp)]
lemma π_descHomology (k : S.cycles ⟶ A) (hk : S.toCycles ≫ k = 0) :
S.homologyπ ≫ S.descHomology k hk = k :=
Cofork.IsColimit.π_desc S.homologyIsCokernel
@[reassoc (attr := simp)]
lemma liftHomology_ι (k : A ⟶ S.opcycles) (hk : k ≫ S.fromOpcycles = 0) :
S.liftHomology k hk ≫ S.homologyι = k :=
Fork.IsLimit.lift_ι S.homologyIsKernel
@[reassoc (attr := simp)]
lemma homologyπ_naturality (φ : S₁ ⟶ S₂) [S₁.HasHomology] [S₂.HasHomology] :
S₁.homologyπ ≫ homologyMap φ = cyclesMap φ ≫ S₂.homologyπ := by
simp only [← cancel_mono S₂.leftHomologyIso.inv, assoc, ← leftHomologyIso_inv_naturality φ,
homologyπ_comp_leftHomologyIso_inv]
simp only [homologyπ, assoc, Iso.hom_inv_id_assoc, leftHomologyπ_naturality]
@[reassoc (attr := simp)]
lemma homologyι_naturality (φ : S₁ ⟶ S₂) [S₁.HasHomology] [S₂.HasHomology] :
homologyMap φ ≫ S₂.homologyι = S₁.homologyι ≫ S₁.opcyclesMap φ := by
simp only [← cancel_epi S₁.rightHomologyIso.hom, rightHomologyIso_hom_naturality_assoc φ,
rightHomologyIso_hom_comp_homologyι, rightHomologyι_naturality]
simp only [homologyι, assoc, Iso.hom_inv_id_assoc]
@[reassoc (attr := simp)]
lemma homology_π_ι :
S.homologyπ ≫ S.homologyι = S.iCycles ≫ S.pOpcycles := by
dsimp only [homologyπ, homologyι]
simpa only [assoc, S.leftRightHomologyComparison_fac] using S.π_leftRightHomologyComparison_ι
/-- The homology of a short complex `S` identifies to the kernel of the induced morphism
`cokernel S.f ⟶ S.X₃`. -/
noncomputable def homologyIsoKernelDesc [HasCokernel S.f]
[HasKernel (cokernel.desc S.f S.g S.zero)] :
S.homology ≅ kernel (cokernel.desc S.f S.g S.zero) :=
S.rightHomologyIso.symm ≪≫ S.rightHomologyIsoKernelDesc
/-- The homology of a short complex `S` identifies to the cokernel of the induced morphism
`S.X₁ ⟶ kernel S.g`. -/
noncomputable def homologyIsoCokernelLift [HasKernel S.g]
[HasCokernel (kernel.lift S.g S.f S.zero)] :
S.homology ≅ cokernel (kernel.lift S.g S.f S.zero) :=
S.leftHomologyIso.symm ≪≫ S.leftHomologyIsoCokernelLift
@[reassoc (attr := simp)]
lemma LeftHomologyData.homologyπ_comp_homologyIso_hom (h : S.LeftHomologyData) :
S.homologyπ ≫ h.homologyIso.hom = h.cyclesIso.hom ≫ h.π := by
dsimp only [homologyπ, homologyIso]
simp only [Iso.trans_hom, Iso.symm_hom, assoc, Iso.hom_inv_id_assoc,
leftHomologyπ_comp_leftHomologyIso_hom]
@[reassoc (attr := simp)]
lemma LeftHomologyData.π_comp_homologyIso_inv (h : S.LeftHomologyData) :
h.π ≫ h.homologyIso.inv = h.cyclesIso.inv ≫ S.homologyπ := by
dsimp only [homologyπ, homologyIso]
simp only [Iso.trans_inv, Iso.symm_inv, π_comp_leftHomologyIso_inv_assoc]
@[reassoc (attr := simp)]
lemma RightHomologyData.homologyIso_inv_comp_homologyι (h : S.RightHomologyData) :
h.homologyIso.inv ≫ S.homologyι = h.ι ≫ h.opcyclesIso.inv := by
dsimp only [homologyι, homologyIso]
simp only [Iso.trans_inv, Iso.symm_inv, assoc, Iso.hom_inv_id_assoc,
rightHomologyIso_inv_comp_rightHomologyι]
@[reassoc (attr := simp)]
lemma RightHomologyData.homologyIso_hom_comp_ι (h : S.RightHomologyData) :
h.homologyIso.hom ≫ h.ι = S.homologyι ≫ h.opcyclesIso.hom := by
dsimp only [homologyι, homologyIso]
simp only [Iso.trans_hom, Iso.symm_hom, assoc, rightHomologyIso_hom_comp_ι]
@[reassoc (attr := simp)]
lemma LeftHomologyData.homologyIso_hom_comp_leftHomologyIso_inv (h : S.LeftHomologyData) :
h.homologyIso.hom ≫ h.leftHomologyIso.inv = S.leftHomologyIso.inv := by
dsimp only [homologyIso]
simp only [Iso.trans_hom, Iso.symm_hom, assoc, Iso.hom_inv_id, comp_id]
@[reassoc (attr := simp)]
lemma LeftHomologyData.leftHomologyIso_hom_comp_homologyIso_inv (h : S.LeftHomologyData) :
h.leftHomologyIso.hom ≫ h.homologyIso.inv = S.leftHomologyIso.hom := by
dsimp only [homologyIso]
simp only [Iso.trans_inv, Iso.symm_inv, Iso.hom_inv_id_assoc]
@[reassoc (attr := simp)]
lemma RightHomologyData.homologyIso_hom_comp_rightHomologyIso_inv (h : S.RightHomologyData) :
h.homologyIso.hom ≫ h.rightHomologyIso.inv = S.rightHomologyIso.inv := by
dsimp only [homologyIso]
simp only [Iso.trans_hom, Iso.symm_hom, assoc, Iso.hom_inv_id, comp_id]
@[reassoc (attr := simp)]
lemma RightHomologyData.rightHomologyIso_hom_comp_homologyIso_inv (h : S.RightHomologyData) :
h.rightHomologyIso.hom ≫ h.homologyIso.inv = S.rightHomologyIso.hom := by
dsimp only [homologyIso]
simp only [Iso.trans_inv, Iso.symm_inv, Iso.hom_inv_id_assoc]
@[reassoc]
lemma comp_homologyMap_comp [S₁.HasHomology] [S₂.HasHomology] (φ : S₁ ⟶ S₂)
(h₁ : S₁.LeftHomologyData) (h₂ : S₂.RightHomologyData) :
h₁.π ≫ h₁.homologyIso.inv ≫ homologyMap φ ≫ h₂.homologyIso.hom ≫ h₂.ι =
h₁.i ≫ φ.τ₂ ≫ h₂.p := by
dsimp only [LeftHomologyData.homologyIso, RightHomologyData.homologyIso,
Iso.symm, Iso.trans, Iso.refl, leftHomologyIso, rightHomologyIso,
leftHomologyMapIso', rightHomologyMapIso',
LeftHomologyData.cyclesIso, RightHomologyData.opcyclesIso,
LeftHomologyData.leftHomologyIso, RightHomologyData.rightHomologyIso,
homologyMap, homologyMap']
simp only [assoc, rightHomologyι_naturality', rightHomologyι_naturality'_assoc,
leftHomologyπ_naturality'_assoc, HomologyData.comm_assoc, p_opcyclesMap'_assoc,
id_τ₂, p_opcyclesMap', id_comp, cyclesMap'_i_assoc]
@[reassoc]
lemma π_homologyMap_ι [S₁.HasHomology] [S₂.HasHomology] (φ : S₁ ⟶ S₂) :
S₁.homologyπ ≫ homologyMap φ ≫ S₂.homologyι = S₁.iCycles ≫ φ.τ₂ ≫ S₂.pOpcycles := by
simp only [homologyι_naturality, homology_π_ι_assoc, p_opcyclesMap]
end
variable (S)
/-- The canonical isomorphism `S.op.homology ≅ Opposite.op S.homology` when a short
complex `S` has homology. -/
noncomputable def homologyOpIso [S.HasHomology] :
S.op.homology ≅ Opposite.op S.homology :=
S.op.leftHomologyIso.symm ≪≫ S.leftHomologyOpIso ≪≫ S.rightHomologyIso.symm.op
lemma homologyMap'_op : (homologyMap' φ h₁ h₂).op =
h₂.iso.inv.op ≫ homologyMap' (opMap φ) h₂.op h₁.op ≫ h₁.iso.hom.op :=
Quiver.Hom.unop_inj (by
dsimp
have γ : HomologyMapData φ h₁ h₂ := default
simp only [γ.homologyMap'_eq, γ.op.homologyMap'_eq, HomologyData.op_left,
HomologyMapData.op_left, RightHomologyMapData.op_φH, Quiver.Hom.unop_op, assoc,
← γ.comm_assoc, Iso.hom_inv_id, comp_id])
lemma homologyMap_op [HasHomology S₁] [HasHomology S₂] :
(homologyMap φ).op =
(S₂.homologyOpIso).inv ≫ homologyMap (opMap φ) ≫ (S₁.homologyOpIso).hom := by
dsimp only [homologyMap, homologyOpIso]
rw [homologyMap'_op]
dsimp only [Iso.symm, Iso.trans, Iso.op, Iso.refl, rightHomologyIso, leftHomologyIso,
leftHomologyOpIso, leftHomologyMapIso', rightHomologyMapIso',
LeftHomologyData.leftHomologyIso, homologyMap']
simp only [assoc, rightHomologyMap'_op, op_comp, ← leftHomologyMap'_comp_assoc, id_comp,
| opMap_id, comp_id, HomologyData.op_left]
@[reassoc]
lemma homologyOpIso_hom_naturality [S₁.HasHomology] [S₂.HasHomology] :
homologyMap (opMap φ) ≫ (S₁.homologyOpIso).hom =
S₂.homologyOpIso.hom ≫ (homologyMap φ).op := by
simp [homologyMap_op]
@[reassoc]
lemma homologyOpIso_inv_naturality [S₁.HasHomology] [S₂.HasHomology] :
| Mathlib/Algebra/Homology/ShortComplex/Homology.lean | 1,036 | 1,045 |
/-
Copyright (c) 2022 Oliver Nash. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Oliver Nash
-/
import Mathlib.Algebra.Lie.Nilpotent
import Mathlib.Algebra.Lie.Normalizer
/-!
# Engel's theorem
This file contains a proof of Engel's theorem providing necessary and sufficient conditions for Lie
algebras and Lie modules to be nilpotent.
The key result `LieModule.isNilpotent_iff_forall` says that if `M` is a Lie module of a
Noetherian Lie algebra `L`, then `M` is nilpotent iff the image of `L → End(M)` consists of
nilpotent elements. In the special case that we have the adjoint representation `M = L`, this says
that a Lie algebra is nilpotent iff `ad x : End(L)` is nilpotent for all `x : L`.
Engel's theorem is true for any coefficients (i.e., it is really a theorem about Lie rings) and so
we work with coefficients in any commutative ring `R` throughout.
On the other hand, Engel's theorem is not true for infinite-dimensional Lie algebras and so a
finite-dimensionality assumption is required. We prove the theorem subject to the assumption
that the Lie algebra is Noetherian as an `R`-module, though actually we only need the slightly
weaker property that the relation `>` is well-founded on the complete lattice of Lie subalgebras.
## Remarks about the proof
Engel's theorem is usually proved in the special case that the coefficients are a field, and uses
an inductive argument on the dimension of the Lie algebra. One begins by choosing either a maximal
proper Lie subalgebra (in some proofs) or a maximal nilpotent Lie subalgebra (in other proofs, at
the cost of obtaining a weaker end result).
Since we work with general coefficients, we cannot induct on dimension and an alternate approach
must be taken. The key ingredient is the concept of nilpotency, not just for Lie algebras, but for
Lie modules. Using this concept, we define an _Engelian Lie algebra_ `LieAlgebra.IsEngelian` to
be one for which a Lie module is nilpotent whenever the action consists of nilpotent endomorphisms.
The argument then proceeds by selecting a maximal Engelian Lie subalgebra and showing that it cannot
be proper.
The first part of the traditional statement of Engel's theorem consists of the statement that if `M`
is a non-trivial `R`-module and `L ⊆ End(M)` is a finite-dimensional Lie subalgebra of nilpotent
elements, then there exists a non-zero element `m : M` that is annihilated by every element of `L`.
This follows trivially from the result established here `LieModule.isNilpotent_iff_forall`, that
`M` is a nilpotent Lie module over `L`, since the last non-zero term in the lower central series
will consist of such elements `m` (see: `LieModule.nontrivial_max_triv_of_isNilpotent`). It seems
that this result has not previously been established at this level of generality.
The second part of the traditional statement of Engel's theorem concerns nilpotency of the Lie
algebra and a proof of this for general coefficients appeared in the literature as long ago
[as 1937](zorn1937). This also follows trivially from `LieModule.isNilpotent_iff_forall` simply by
taking `M = L`.
It is pleasing that the two parts of the traditional statements of Engel's theorem are thus unified
into a single statement about nilpotency of Lie modules. This is not usually emphasised.
## Main definitions
* `LieAlgebra.IsEngelian`
* `LieAlgebra.isEngelian_of_isNoetherian`
* `LieModule.isNilpotent_iff_forall`
* `LieAlgebra.isNilpotent_iff_forall`
-/
universe u₁ u₂ u₃ u₄
variable {R : Type u₁} {L : Type u₂} {L₂ : Type u₃} {M : Type u₄}
variable [CommRing R] [LieRing L] [LieAlgebra R L] [LieRing L₂] [LieAlgebra R L₂]
variable [AddCommGroup M] [Module R M] [LieRingModule L M] [LieModule R L M]
namespace LieSubmodule
open LieModule
variable {I : LieIdeal R L} {x : L} (hxI : (R ∙ x) ⊔ I = ⊤)
include hxI
theorem exists_smul_add_of_span_sup_eq_top (y : L) : ∃ t : R, ∃ z ∈ I, y = t • x + z := by
have hy : y ∈ (⊤ : Submodule R L) := Submodule.mem_top
simp only [← hxI, Submodule.mem_sup, Submodule.mem_span_singleton] at hy
obtain ⟨-, ⟨t, rfl⟩, z, hz, rfl⟩ := hy
exact ⟨t, z, hz, rfl⟩
theorem lie_top_eq_of_span_sup_eq_top (N : LieSubmodule R L M) :
(↑⁅(⊤ : LieIdeal R L), N⁆ : Submodule R M) =
(N : Submodule R M).map (toEnd R L M x) ⊔ (↑⁅I, N⁆ : Submodule R M) := by
simp only [lieIdeal_oper_eq_linear_span', Submodule.sup_span, mem_top, exists_prop,
true_and, Submodule.map_coe, toEnd_apply_apply]
refine le_antisymm (Submodule.span_le.mpr ?_) (Submodule.span_mono fun z hz => ?_)
· rintro z ⟨y, n, hn : n ∈ N, rfl⟩
obtain ⟨t, z, hz, rfl⟩ := exists_smul_add_of_span_sup_eq_top hxI y
simp only [SetLike.mem_coe, Submodule.span_union, Submodule.mem_sup]
exact
⟨t • ⁅x, n⁆, Submodule.subset_span ⟨t • n, N.smul_mem' t hn, lie_smul t x n⟩, ⁅z, n⁆,
Submodule.subset_span ⟨z, hz, n, hn, rfl⟩, by simp⟩
· rcases hz with (⟨m, hm, rfl⟩ | ⟨y, -, m, hm, rfl⟩)
exacts [⟨x, m, hm, rfl⟩, ⟨y, m, hm, rfl⟩]
theorem lcs_le_lcs_of_is_nilpotent_span_sup_eq_top {n i j : ℕ}
(hxn : toEnd R L M x ^ n = 0) (hIM : lowerCentralSeries R L M i ≤ I.lcs M j) :
lowerCentralSeries R L M (i + n) ≤ I.lcs M (j + 1) := by
suffices
∀ l,
((⊤ : LieIdeal R L).lcs M (i + l) : Submodule R M) ≤
(I.lcs M j : Submodule R M).map (toEnd R L M x ^ l) ⊔
(I.lcs M (j + 1) : Submodule R M)
by simpa only [bot_sup_eq, LieIdeal.incl_coe, Submodule.map_zero, hxn] using this n
intro l
induction l with
| zero =>
simp only [add_zero, LieIdeal.lcs_succ, pow_zero, Module.End.one_eq_id,
Submodule.map_id]
exact le_sup_of_le_left hIM
| succ l ih =>
simp only [LieIdeal.lcs_succ, i.add_succ l, lie_top_eq_of_span_sup_eq_top hxI, sup_le_iff]
refine ⟨(Submodule.map_mono ih).trans ?_, le_sup_of_le_right ?_⟩
· rw [Submodule.map_sup, ← Submodule.map_comp, ← Module.End.mul_eq_comp, ← pow_succ', ←
I.lcs_succ]
exact sup_le_sup_left coe_map_toEnd_le _
· refine le_trans (mono_lie_right I ?_) (mono_lie_right I hIM)
exact antitone_lowerCentralSeries R L M le_self_add
theorem isNilpotentOfIsNilpotentSpanSupEqTop (hnp : IsNilpotent <| toEnd R L M x)
(hIM : IsNilpotent I M) : IsNilpotent L M := by
obtain ⟨n, hn⟩ := hnp
obtain ⟨k, hk⟩ := IsNilpotent.nilpotent R I M
have hk' : I.lcs M k = ⊥ := by
simp only [← toSubmodule_inj, I.coe_lcs_eq, hk, bot_toSubmodule]
suffices ∀ l, lowerCentralSeries R L M (l * n) ≤ I.lcs M l by
rw [isNilpotent_iff R]
use k * n
simpa [hk'] using this k
intro l
induction l with
| zero => simp
| succ l ih => exact (l.succ_mul n).symm ▸ lcs_le_lcs_of_is_nilpotent_span_sup_eq_top hxI hn ih
end LieSubmodule
section LieAlgebra
-- Porting note: somehow this doesn't hide `LieModule.IsNilpotent`, so `_root_.IsNilpotent` is used
-- a number of times below.
open LieModule hiding IsNilpotent
variable (R L)
/-- A Lie algebra `L` is said to be Engelian if a sufficient condition for any `L`-Lie module `M` to
be nilpotent is that the image of the map `L → End(M)` consists of nilpotent elements.
Engel's theorem `LieAlgebra.isEngelian_of_isNoetherian` states that any Noetherian Lie algebra is
Engelian. -/
def LieAlgebra.IsEngelian : Prop :=
∀ (M : Type u₄) [AddCommGroup M] [Module R M] [LieRingModule L M] [LieModule R L M],
(∀ x : L, _root_.IsNilpotent (toEnd R L M x)) → LieModule.IsNilpotent L M
variable {R L}
theorem LieAlgebra.isEngelian_of_subsingleton [Subsingleton L] : LieAlgebra.IsEngelian R L := by
intro M _i1 _i2 _i3 _i4 _h
use 1
simp
theorem Function.Surjective.isEngelian {f : L →ₗ⁅R⁆ L₂} (hf : Function.Surjective f)
(h : LieAlgebra.IsEngelian.{u₁, u₂, u₄} R L) : LieAlgebra.IsEngelian.{u₁, u₃, u₄} R L₂ := by
intro M _i1 _i2 _i3 _i4 h'
letI : LieRingModule L M := LieRingModule.compLieHom M f
letI : LieModule R L M := compLieHom M f
have hnp : ∀ x, IsNilpotent (toEnd R L M x) := fun x => h' (f x)
have surj_id : Function.Surjective (LinearMap.id : M →ₗ[R] M) := Function.surjective_id
haveI : LieModule.IsNilpotent L M := h M hnp
apply hf.lieModuleIsNilpotent _ surj_id
aesop
theorem LieEquiv.isEngelian_iff (e : L ≃ₗ⁅R⁆ L₂) :
LieAlgebra.IsEngelian.{u₁, u₂, u₄} R L ↔ LieAlgebra.IsEngelian.{u₁, u₃, u₄} R L₂ :=
⟨e.surjective.isEngelian, e.symm.surjective.isEngelian⟩
theorem LieAlgebra.exists_engelian_lieSubalgebra_of_lt_normalizer {K : LieSubalgebra R L}
(hK₁ : LieAlgebra.IsEngelian.{u₁, u₂, u₄} R K) (hK₂ : K < K.normalizer) :
∃ (K' : LieSubalgebra R L), LieAlgebra.IsEngelian.{u₁, u₂, u₄} R K' ∧ K < K' := by
obtain ⟨x, hx₁, hx₂⟩ := SetLike.exists_of_lt hK₂
let K' : LieSubalgebra R L :=
{ (R ∙ x) ⊔ (K : Submodule R L) with
lie_mem' := fun {y z} => LieSubalgebra.lie_mem_sup_of_mem_normalizer hx₁ }
have hxK' : x ∈ K' := Submodule.mem_sup_left (Submodule.subset_span (Set.mem_singleton _))
have hKK' : K ≤ K' := (LieSubalgebra.toSubmodule_le_toSubmodule K K').mp le_sup_right
have hK' : K' ≤ K.normalizer := by
rw [← LieSubalgebra.toSubmodule_le_toSubmodule]
exact sup_le ((Submodule.span_singleton_le_iff_mem _ _).mpr hx₁) hK₂.le
refine ⟨K', ?_, lt_iff_le_and_ne.mpr ⟨hKK', fun contra => hx₂ (contra.symm ▸ hxK')⟩⟩
intro M _i1 _i2 _i3 _i4 h
obtain ⟨I, hI₁ : (I : LieSubalgebra R K') = LieSubalgebra.ofLe hKK'⟩ :=
LieSubalgebra.exists_nested_lieIdeal_ofLe_normalizer hKK' hK'
have hI₂ : (R ∙ (⟨x, hxK'⟩ : K')) ⊔ (LieSubmodule.toSubmodule I) = ⊤ := by
rw [← LieIdeal.toLieSubalgebra_toSubmodule R K' I, hI₁]
apply Submodule.map_injective_of_injective (K' : Submodule R L).injective_subtype
simp only [LieSubalgebra.coe_ofLe, Submodule.map_sup, Submodule.map_subtype_range_inclusion,
Submodule.map_top, Submodule.range_subtype]
rw [Submodule.map_subtype_span_singleton]
have e : K ≃ₗ⁅R⁆ I :=
(LieSubalgebra.equivOfLe hKK').trans
(LieEquiv.ofEq _ _ ((LieSubalgebra.coe_set_eq _ _).mpr hI₁.symm))
have hI₃ : LieAlgebra.IsEngelian R I := e.isEngelian_iff.mp hK₁
exact LieSubmodule.isNilpotentOfIsNilpotentSpanSupEqTop hI₂ (h _) (hI₃ _ fun x => h x)
attribute [local instance] LieSubalgebra.subsingleton_bot
/-- *Engel's theorem*.
Note that this implies all traditional forms of Engel's theorem via
`LieModule.nontrivial_max_triv_of_isNilpotent`, `LieModule.isNilpotent_iff_forall`,
`LieAlgebra.isNilpotent_iff_forall`. -/
theorem LieAlgebra.isEngelian_of_isNoetherian [IsNoetherian R L] : LieAlgebra.IsEngelian R L := by
intro M _i1 _i2 _i3 _i4 h
rw [← isNilpotent_range_toEnd_iff R]
let L' := (toEnd R L M).range
replace h : ∀ y : L', _root_.IsNilpotent (y : Module.End R M) := by
rintro ⟨-, ⟨y, rfl⟩⟩
simp [h]
change LieModule.IsNilpotent L' M
let s := {K : LieSubalgebra R L' | LieAlgebra.IsEngelian R K}
| have hs : s.Nonempty := ⟨⊥, LieAlgebra.isEngelian_of_subsingleton⟩
suffices ⊤ ∈ s by
rw [← isNilpotent_of_top_iff (R := R)]
apply this M
simp [LieSubalgebra.toEnd_eq, h]
have : ∀ K ∈ s, K ≠ ⊤ → ∃ K' ∈ s, K < K' := by
rintro K (hK₁ : LieAlgebra.IsEngelian R K) hK₂
apply LieAlgebra.exists_engelian_lieSubalgebra_of_lt_normalizer hK₁
apply lt_of_le_of_ne K.le_normalizer
rw [Ne, eq_comm, K.normalizer_eq_self_iff, ← Ne, ←
LieSubmodule.nontrivial_iff_ne_bot R K]
have : Nontrivial (L' ⧸ K.toLieSubmodule) := by
replace hK₂ : K.toLieSubmodule ≠ ⊤ := by
rwa [Ne, ← LieSubmodule.toSubmodule_inj, K.coe_toLieSubmodule,
LieSubmodule.top_toSubmodule, ← LieSubalgebra.top_toSubmodule,
K.toSubmodule_inj]
exact Submodule.Quotient.nontrivial_of_lt_top _ hK₂.lt_top
have : LieModule.IsNilpotent K (L' ⧸ K.toLieSubmodule) := by
refine hK₁ _ fun x => ?_
have hx := LieAlgebra.isNilpotent_ad_of_isNilpotent (h x)
apply Module.End.IsNilpotent.mapQ ?_ hx
intro X HX
simp only [LieSubalgebra.coe_toLieSubmodule, LieSubalgebra.mem_toSubmodule] at HX
simp only [LieSubalgebra.coe_toLieSubmodule, Submodule.mem_comap, ad_apply,
LieSubalgebra.mem_toSubmodule]
exact LieSubalgebra.lie_mem K x.prop HX
exact nontrivial_max_triv_of_isNilpotent R K (L' ⧸ K.toLieSubmodule)
haveI _i5 : IsNoetherian R L' := by
refine isNoetherian_of_surjective L (LieHom.rangeRestrict (toEnd R L M)) ?_
simp only [LieHom.range_toSubmodule, LieHom.coe_toLinearMap,
LinearMap.range_eq_top]
exact LieHom.surjective_rangeRestrict (toEnd R L M)
obtain ⟨K, hK₁, hK₂⟩ := (LieSubalgebra.wellFoundedGT_of_noetherian R L').wf.has_min s hs
have hK₃ : K = ⊤ := by
by_contra contra
obtain ⟨K', hK'₁, hK'₂⟩ := this K hK₁ contra
exact hK₂ K' hK'₁ hK'₂
exact hK₃ ▸ hK₁
/-- Engel's theorem.
See also `LieModule.isNilpotent_iff_forall'` which assumes that `M` is Noetherian instead of `L`. -/
theorem LieModule.isNilpotent_iff_forall [IsNoetherian R L] :
LieModule.IsNilpotent L M ↔ ∀ x, _root_.IsNilpotent <| toEnd R L M x :=
⟨fun _ ↦ isNilpotent_toEnd_of_isNilpotent R L M,
fun h => LieAlgebra.isEngelian_of_isNoetherian M h⟩
/-- Engel's theorem. -/
theorem LieModule.isNilpotent_iff_forall' [IsNoetherian R M] :
LieModule.IsNilpotent L M ↔ ∀ x, _root_.IsNilpotent <| toEnd R L M x := by
rw [← isNilpotent_range_toEnd_iff (R := R), LieModule.isNilpotent_iff_forall (R := R)]; simp
| Mathlib/Algebra/Lie/Engel.lean | 226 | 277 |
/-
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]
| Mathlib/MeasureTheory/Integral/Average.lean | 122 | 123 |
/-
Copyright (c) 2014 Jeremy Avigad. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Jeremy Avigad, Leonardo de Moura
-/
import Mathlib.Data.Set.Operations
import Mathlib.Order.Basic
import Mathlib.Order.BooleanAlgebra
import Mathlib.Tactic.Tauto
import Mathlib.Tactic.ByContra
import Mathlib.Util.Delaborators
import Mathlib.Tactic.Lift
/-!
# Basic properties of sets
Sets in Lean are homogeneous; all their elements have the same type. Sets whose elements
have type `X` are thus defined as `Set X := X → Prop`. Note that this function need not
be decidable. The definition is in the module `Mathlib.Data.Set.Defs`.
This file provides some basic definitions related to sets and functions not present in the
definitions file, as well as extra lemmas for functions defined in the definitions file and
`Mathlib.Data.Set.Operations` (empty set, univ, union, intersection, insert, singleton,
set-theoretic difference, complement, and powerset).
Note that a set is a term, not a type. There is a coercion from `Set α` to `Type*` sending
`s` to the corresponding subtype `↥s`.
See also the file `SetTheory/ZFC.lean`, which contains an encoding of ZFC set theory in Lean.
## Main definitions
Notation used here:
- `f : α → β` is a function,
- `s : Set α` and `s₁ s₂ : Set α` are subsets of `α`
- `t : Set β` is a subset of `β`.
Definitions in the file:
* `Nonempty s : Prop` : the predicate `s ≠ ∅`. Note that this is the preferred way to express the
fact that `s` has an element (see the Implementation Notes).
* `inclusion s₁ s₂ : ↥s₁ → ↥s₂` : the map `↥s₁ → ↥s₂` induced by an inclusion `s₁ ⊆ s₂`.
## Notation
* `sᶜ` for the complement of `s`
## Implementation notes
* `s.Nonempty` is to be preferred to `s ≠ ∅` or `∃ x, x ∈ s`. It has the advantage that
the `s.Nonempty` dot notation can be used.
* For `s : Set α`, do not use `Subtype s`. Instead use `↥s` or `(s : Type*)` or `s`.
## Tags
set, sets, subset, subsets, union, intersection, insert, singleton, complement, powerset
-/
assert_not_exists RelIso
/-! ### Set coercion to a type -/
open Function
universe u v
namespace Set
variable {α : Type u} {s t : Set α}
instance instBooleanAlgebra : BooleanAlgebra (Set α) :=
{ (inferInstance : BooleanAlgebra (α → Prop)) with
sup := (· ∪ ·),
le := (· ≤ ·),
lt := fun s t => s ⊆ t ∧ ¬t ⊆ s,
inf := (· ∩ ·),
bot := ∅,
compl := (·ᶜ),
top := univ,
sdiff := (· \ ·) }
instance : HasSSubset (Set α) :=
⟨(· < ·)⟩
@[simp]
theorem top_eq_univ : (⊤ : Set α) = univ :=
rfl
@[simp]
theorem bot_eq_empty : (⊥ : Set α) = ∅ :=
rfl
@[simp]
theorem sup_eq_union : ((· ⊔ ·) : Set α → Set α → Set α) = (· ∪ ·) :=
rfl
@[simp]
theorem inf_eq_inter : ((· ⊓ ·) : Set α → Set α → Set α) = (· ∩ ·) :=
rfl
@[simp]
theorem le_eq_subset : ((· ≤ ·) : Set α → Set α → Prop) = (· ⊆ ·) :=
rfl
@[simp]
theorem lt_eq_ssubset : ((· < ·) : Set α → Set α → Prop) = (· ⊂ ·) :=
rfl
theorem le_iff_subset : s ≤ t ↔ s ⊆ t :=
Iff.rfl
theorem lt_iff_ssubset : s < t ↔ s ⊂ t :=
Iff.rfl
alias ⟨_root_.LE.le.subset, _root_.HasSubset.Subset.le⟩ := le_iff_subset
alias ⟨_root_.LT.lt.ssubset, _root_.HasSSubset.SSubset.lt⟩ := lt_iff_ssubset
instance PiSetCoe.canLift (ι : Type u) (α : ι → Type v) [∀ i, Nonempty (α i)] (s : Set ι) :
CanLift (∀ i : s, α i) (∀ i, α i) (fun f i => f i) fun _ => True :=
PiSubtype.canLift ι α s
instance PiSetCoe.canLift' (ι : Type u) (α : Type v) [Nonempty α] (s : Set ι) :
CanLift (s → α) (ι → α) (fun f i => f i) fun _ => True :=
PiSetCoe.canLift ι (fun _ => α) s
end Set
section SetCoe
variable {α : Type u}
instance (s : Set α) : CoeTC s α := ⟨fun x => x.1⟩
theorem Set.coe_eq_subtype (s : Set α) : ↥s = { x // x ∈ s } :=
rfl
@[simp]
theorem Set.coe_setOf (p : α → Prop) : ↥{ x | p x } = { x // p x } :=
rfl
theorem SetCoe.forall {s : Set α} {p : s → Prop} : (∀ x : s, p x) ↔ ∀ (x) (h : x ∈ s), p ⟨x, h⟩ :=
Subtype.forall
theorem SetCoe.exists {s : Set α} {p : s → Prop} :
(∃ x : s, p x) ↔ ∃ (x : _) (h : x ∈ s), p ⟨x, h⟩ :=
Subtype.exists
theorem SetCoe.exists' {s : Set α} {p : ∀ x, x ∈ s → Prop} :
(∃ (x : _) (h : x ∈ s), p x h) ↔ ∃ x : s, p x.1 x.2 :=
(@SetCoe.exists _ _ fun x => p x.1 x.2).symm
theorem SetCoe.forall' {s : Set α} {p : ∀ x, x ∈ s → Prop} :
(∀ (x) (h : x ∈ s), p x h) ↔ ∀ x : s, p x.1 x.2 :=
(@SetCoe.forall _ _ fun x => p x.1 x.2).symm
@[simp]
theorem set_coe_cast :
∀ {s t : Set α} (H' : s = t) (H : ↥s = ↥t) (x : s), cast H x = ⟨x.1, H' ▸ x.2⟩
| _, _, rfl, _, _ => rfl
theorem SetCoe.ext {s : Set α} {a b : s} : (a : α) = b → a = b :=
Subtype.eq
theorem SetCoe.ext_iff {s : Set α} {a b : s} : (↑a : α) = ↑b ↔ a = b :=
Iff.intro SetCoe.ext fun h => h ▸ rfl
end SetCoe
/-- See also `Subtype.prop` -/
theorem Subtype.mem {α : Type*} {s : Set α} (p : s) : (p : α) ∈ s :=
p.prop
/-- Duplicate of `Eq.subset'`, which currently has elaboration problems. -/
theorem Eq.subset {α} {s t : Set α} : s = t → s ⊆ t :=
fun h₁ _ h₂ => by rw [← h₁]; exact h₂
namespace Set
variable {α : Type u} {β : Type v} {a b : α} {s s₁ s₂ t t₁ t₂ u : Set α}
instance : Inhabited (Set α) :=
⟨∅⟩
@[trans]
theorem mem_of_mem_of_subset {x : α} {s t : Set α} (hx : x ∈ s) (h : s ⊆ t) : x ∈ t :=
h hx
theorem forall_in_swap {p : α → β → Prop} : (∀ a ∈ s, ∀ (b), p a b) ↔ ∀ (b), ∀ a ∈ s, p a b := by
tauto
theorem setOf_injective : Function.Injective (@setOf α) := injective_id
theorem setOf_inj {p q : α → Prop} : { x | p x } = { x | q x } ↔ p = q := Iff.rfl
/-! ### Lemmas about `mem` and `setOf` -/
theorem mem_setOf {a : α} {p : α → Prop} : a ∈ { x | p x } ↔ p a :=
Iff.rfl
/-- This lemma is intended for use with `rw` where a membership predicate is needed,
hence the explicit argument and the equality in the reverse direction from normal.
See also `Set.mem_setOf_eq` for the reverse direction applied to an argument. -/
theorem eq_mem_setOf (p : α → Prop) : p = (· ∈ {a | p a}) := rfl
/-- If `h : a ∈ {x | p x}` then `h.out : p x`. These are definitionally equal, but this can
nevertheless be useful for various reasons, e.g. to apply further projection notation or in an
argument to `simp`. -/
theorem _root_.Membership.mem.out {p : α → Prop} {a : α} (h : a ∈ { x | p x }) : p a :=
h
theorem nmem_setOf_iff {a : α} {p : α → Prop} : a ∉ { x | p x } ↔ ¬p a :=
Iff.rfl
@[simp]
theorem setOf_mem_eq {s : Set α} : { x | x ∈ s } = s :=
rfl
theorem setOf_set {s : Set α} : setOf s = s :=
rfl
theorem setOf_app_iff {p : α → Prop} {x : α} : { x | p x } x ↔ p x :=
Iff.rfl
theorem mem_def {a : α} {s : Set α} : a ∈ s ↔ s a :=
Iff.rfl
theorem setOf_bijective : Bijective (setOf : (α → Prop) → Set α) :=
bijective_id
theorem subset_setOf {p : α → Prop} {s : Set α} : s ⊆ setOf p ↔ ∀ x, x ∈ s → p x :=
Iff.rfl
theorem setOf_subset {p : α → Prop} {s : Set α} : setOf p ⊆ s ↔ ∀ x, p x → x ∈ s :=
Iff.rfl
@[simp]
theorem setOf_subset_setOf {p q : α → Prop} : { a | p a } ⊆ { a | q a } ↔ ∀ a, p a → q a :=
Iff.rfl
theorem setOf_and {p q : α → Prop} : { a | p a ∧ q a } = { a | p a } ∩ { a | q a } :=
rfl
theorem setOf_or {p q : α → Prop} : { a | p a ∨ q a } = { a | p a } ∪ { a | q a } :=
rfl
/-! ### Subset and strict subset relations -/
instance : IsRefl (Set α) (· ⊆ ·) :=
show IsRefl (Set α) (· ≤ ·) by infer_instance
instance : IsTrans (Set α) (· ⊆ ·) :=
show IsTrans (Set α) (· ≤ ·) by infer_instance
instance : Trans ((· ⊆ ·) : Set α → Set α → Prop) (· ⊆ ·) (· ⊆ ·) :=
show Trans (· ≤ ·) (· ≤ ·) (· ≤ ·) by infer_instance
instance : IsAntisymm (Set α) (· ⊆ ·) :=
show IsAntisymm (Set α) (· ≤ ·) by infer_instance
instance : IsIrrefl (Set α) (· ⊂ ·) :=
show IsIrrefl (Set α) (· < ·) by infer_instance
instance : IsTrans (Set α) (· ⊂ ·) :=
show IsTrans (Set α) (· < ·) by infer_instance
instance : Trans ((· ⊂ ·) : Set α → Set α → Prop) (· ⊂ ·) (· ⊂ ·) :=
show Trans (· < ·) (· < ·) (· < ·) by infer_instance
instance : Trans ((· ⊂ ·) : Set α → Set α → Prop) (· ⊆ ·) (· ⊂ ·) :=
show Trans (· < ·) (· ≤ ·) (· < ·) by infer_instance
instance : Trans ((· ⊆ ·) : Set α → Set α → Prop) (· ⊂ ·) (· ⊂ ·) :=
show Trans (· ≤ ·) (· < ·) (· < ·) by infer_instance
instance : IsAsymm (Set α) (· ⊂ ·) :=
show IsAsymm (Set α) (· < ·) by infer_instance
instance : IsNonstrictStrictOrder (Set α) (· ⊆ ·) (· ⊂ ·) :=
⟨fun _ _ => Iff.rfl⟩
-- TODO(Jeremy): write a tactic to unfold specific instances of generic notation?
theorem subset_def : (s ⊆ t) = ∀ x, x ∈ s → x ∈ t :=
rfl
theorem ssubset_def : (s ⊂ t) = (s ⊆ t ∧ ¬t ⊆ s) :=
rfl
@[refl]
theorem Subset.refl (a : Set α) : a ⊆ a := fun _ => id
theorem Subset.rfl {s : Set α} : s ⊆ s :=
Subset.refl s
@[trans]
theorem Subset.trans {a b c : Set α} (ab : a ⊆ b) (bc : b ⊆ c) : a ⊆ c := fun _ h => bc <| ab h
@[trans]
theorem mem_of_eq_of_mem {x y : α} {s : Set α} (hx : x = y) (h : y ∈ s) : x ∈ s :=
hx.symm ▸ h
theorem Subset.antisymm {a b : Set α} (h₁ : a ⊆ b) (h₂ : b ⊆ a) : a = b :=
Set.ext fun _ => ⟨@h₁ _, @h₂ _⟩
theorem Subset.antisymm_iff {a b : Set α} : a = b ↔ a ⊆ b ∧ b ⊆ a :=
⟨fun e => ⟨e.subset, e.symm.subset⟩, fun ⟨h₁, h₂⟩ => Subset.antisymm h₁ h₂⟩
-- an alternative name
theorem eq_of_subset_of_subset {a b : Set α} : a ⊆ b → b ⊆ a → a = b :=
Subset.antisymm
theorem mem_of_subset_of_mem {s₁ s₂ : Set α} {a : α} (h : s₁ ⊆ s₂) : a ∈ s₁ → a ∈ s₂ :=
@h _
theorem not_mem_subset (h : s ⊆ t) : a ∉ t → a ∉ s :=
mt <| mem_of_subset_of_mem h
theorem not_subset : ¬s ⊆ t ↔ ∃ a ∈ s, a ∉ t := by
simp only [subset_def, not_forall, exists_prop]
theorem not_top_subset : ¬⊤ ⊆ s ↔ ∃ a, a ∉ s := by
simp [not_subset]
lemma eq_of_forall_subset_iff (h : ∀ u, s ⊆ u ↔ t ⊆ u) : s = t := eq_of_forall_ge_iff h
/-! ### Definition of strict subsets `s ⊂ t` and basic properties. -/
protected theorem eq_or_ssubset_of_subset (h : s ⊆ t) : s = t ∨ s ⊂ t :=
eq_or_lt_of_le h
theorem exists_of_ssubset {s t : Set α} (h : s ⊂ t) : ∃ x ∈ t, x ∉ s :=
not_subset.1 h.2
protected theorem ssubset_iff_subset_ne {s t : Set α} : s ⊂ t ↔ s ⊆ t ∧ s ≠ t :=
@lt_iff_le_and_ne (Set α) _ s t
theorem ssubset_iff_of_subset {s t : Set α} (h : s ⊆ t) : s ⊂ t ↔ ∃ x ∈ t, x ∉ s :=
⟨exists_of_ssubset, fun ⟨_, hxt, hxs⟩ => ⟨h, fun h => hxs <| h hxt⟩⟩
theorem ssubset_iff_exists {s t : Set α} : s ⊂ t ↔ s ⊆ t ∧ ∃ x ∈ t, x ∉ s :=
⟨fun h ↦ ⟨h.le, Set.exists_of_ssubset h⟩, fun ⟨h1, h2⟩ ↦ (Set.ssubset_iff_of_subset h1).mpr h2⟩
protected theorem ssubset_of_ssubset_of_subset {s₁ s₂ s₃ : Set α} (hs₁s₂ : s₁ ⊂ s₂)
(hs₂s₃ : s₂ ⊆ s₃) : s₁ ⊂ s₃ :=
⟨Subset.trans hs₁s₂.1 hs₂s₃, fun hs₃s₁ => hs₁s₂.2 (Subset.trans hs₂s₃ hs₃s₁)⟩
protected theorem ssubset_of_subset_of_ssubset {s₁ s₂ s₃ : Set α} (hs₁s₂ : s₁ ⊆ s₂)
(hs₂s₃ : s₂ ⊂ s₃) : s₁ ⊂ s₃ :=
⟨Subset.trans hs₁s₂ hs₂s₃.1, fun hs₃s₁ => hs₂s₃.2 (Subset.trans hs₃s₁ hs₁s₂)⟩
theorem not_mem_empty (x : α) : ¬x ∈ (∅ : Set α) :=
id
theorem not_not_mem : ¬a ∉ s ↔ a ∈ s :=
not_not
/-! ### Non-empty sets -/
theorem nonempty_coe_sort {s : Set α} : Nonempty ↥s ↔ s.Nonempty :=
nonempty_subtype
alias ⟨_, Nonempty.coe_sort⟩ := nonempty_coe_sort
theorem nonempty_def : s.Nonempty ↔ ∃ x, x ∈ s :=
Iff.rfl
theorem nonempty_of_mem {x} (h : x ∈ s) : s.Nonempty :=
⟨x, h⟩
theorem Nonempty.not_subset_empty : s.Nonempty → ¬s ⊆ ∅
| ⟨_, hx⟩, hs => hs hx
/-- Extract a witness from `s.Nonempty`. This function might be used instead of case analysis
on the argument. Note that it makes a proof depend on the `Classical.choice` axiom. -/
protected noncomputable def Nonempty.some (h : s.Nonempty) : α :=
Classical.choose h
protected theorem Nonempty.some_mem (h : s.Nonempty) : h.some ∈ s :=
Classical.choose_spec h
theorem Nonempty.mono (ht : s ⊆ t) (hs : s.Nonempty) : t.Nonempty :=
hs.imp ht
theorem nonempty_of_not_subset (h : ¬s ⊆ t) : (s \ t).Nonempty :=
let ⟨x, xs, xt⟩ := not_subset.1 h
⟨x, xs, xt⟩
theorem nonempty_of_ssubset (ht : s ⊂ t) : (t \ s).Nonempty :=
nonempty_of_not_subset ht.2
theorem Nonempty.of_diff (h : (s \ t).Nonempty) : s.Nonempty :=
h.imp fun _ => And.left
theorem nonempty_of_ssubset' (ht : s ⊂ t) : t.Nonempty :=
(nonempty_of_ssubset ht).of_diff
theorem Nonempty.inl (hs : s.Nonempty) : (s ∪ t).Nonempty :=
hs.imp fun _ => Or.inl
theorem Nonempty.inr (ht : t.Nonempty) : (s ∪ t).Nonempty :=
ht.imp fun _ => Or.inr
@[simp]
theorem union_nonempty : (s ∪ t).Nonempty ↔ s.Nonempty ∨ t.Nonempty :=
exists_or
theorem Nonempty.left (h : (s ∩ t).Nonempty) : s.Nonempty :=
h.imp fun _ => And.left
theorem Nonempty.right (h : (s ∩ t).Nonempty) : t.Nonempty :=
h.imp fun _ => And.right
theorem inter_nonempty : (s ∩ t).Nonempty ↔ ∃ x, x ∈ s ∧ x ∈ t :=
Iff.rfl
theorem inter_nonempty_iff_exists_left : (s ∩ t).Nonempty ↔ ∃ x ∈ s, x ∈ t := by
simp_rw [inter_nonempty]
theorem inter_nonempty_iff_exists_right : (s ∩ t).Nonempty ↔ ∃ x ∈ t, x ∈ s := by
simp_rw [inter_nonempty, and_comm]
theorem nonempty_iff_univ_nonempty : Nonempty α ↔ (univ : Set α).Nonempty :=
⟨fun ⟨x⟩ => ⟨x, trivial⟩, fun ⟨x, _⟩ => ⟨x⟩⟩
@[simp]
theorem univ_nonempty : ∀ [Nonempty α], (univ : Set α).Nonempty
| ⟨x⟩ => ⟨x, trivial⟩
theorem Nonempty.to_subtype : s.Nonempty → Nonempty (↥s) :=
nonempty_subtype.2
theorem Nonempty.to_type : s.Nonempty → Nonempty α := fun ⟨x, _⟩ => ⟨x⟩
instance univ.nonempty [Nonempty α] : Nonempty (↥(Set.univ : Set α)) :=
Set.univ_nonempty.to_subtype
-- Redeclare for refined keys
-- `Nonempty (@Subtype _ (@Membership.mem _ (Set _) _ (@Top.top (Set _) _)))`
instance instNonemptyTop [Nonempty α] : Nonempty (⊤ : Set α) :=
inferInstanceAs (Nonempty (univ : Set α))
theorem Nonempty.of_subtype [Nonempty (↥s)] : s.Nonempty := nonempty_subtype.mp ‹_›
@[deprecated (since := "2024-11-23")] alias nonempty_of_nonempty_subtype := Nonempty.of_subtype
/-! ### Lemmas about the empty set -/
theorem empty_def : (∅ : Set α) = { _x : α | False } :=
rfl
@[simp]
theorem mem_empty_iff_false (x : α) : x ∈ (∅ : Set α) ↔ False :=
Iff.rfl
@[simp]
theorem setOf_false : { _a : α | False } = ∅ :=
rfl
@[simp] theorem setOf_bot : { _x : α | ⊥ } = ∅ := rfl
@[simp]
theorem empty_subset (s : Set α) : ∅ ⊆ s :=
nofun
@[simp]
theorem subset_empty_iff {s : Set α} : s ⊆ ∅ ↔ s = ∅ :=
(Subset.antisymm_iff.trans <| and_iff_left (empty_subset _)).symm
theorem eq_empty_iff_forall_not_mem {s : Set α} : s = ∅ ↔ ∀ x, x ∉ s :=
subset_empty_iff.symm
theorem eq_empty_of_forall_not_mem (h : ∀ x, x ∉ s) : s = ∅ :=
subset_empty_iff.1 h
theorem eq_empty_of_subset_empty {s : Set α} : s ⊆ ∅ → s = ∅ :=
subset_empty_iff.1
theorem eq_empty_of_isEmpty [IsEmpty α] (s : Set α) : s = ∅ :=
eq_empty_of_subset_empty fun x _ => isEmptyElim x
/-- There is exactly one set of a type that is empty. -/
instance uniqueEmpty [IsEmpty α] : Unique (Set α) where
default := ∅
uniq := eq_empty_of_isEmpty
/-- See also `Set.nonempty_iff_ne_empty`. -/
theorem not_nonempty_iff_eq_empty {s : Set α} : ¬s.Nonempty ↔ s = ∅ := by
simp only [Set.Nonempty, not_exists, eq_empty_iff_forall_not_mem]
/-- See also `Set.not_nonempty_iff_eq_empty`. -/
theorem nonempty_iff_ne_empty : s.Nonempty ↔ s ≠ ∅ :=
not_nonempty_iff_eq_empty.not_right
/-- See also `nonempty_iff_ne_empty'`. -/
theorem not_nonempty_iff_eq_empty' : ¬Nonempty s ↔ s = ∅ := by
rw [nonempty_subtype, not_exists, eq_empty_iff_forall_not_mem]
/-- See also `not_nonempty_iff_eq_empty'`. -/
theorem nonempty_iff_ne_empty' : Nonempty s ↔ s ≠ ∅ :=
not_nonempty_iff_eq_empty'.not_right
alias ⟨Nonempty.ne_empty, _⟩ := nonempty_iff_ne_empty
@[simp]
theorem not_nonempty_empty : ¬(∅ : Set α).Nonempty := fun ⟨_, hx⟩ => hx
@[simp]
theorem isEmpty_coe_sort {s : Set α} : IsEmpty (↥s) ↔ s = ∅ :=
not_iff_not.1 <| by simpa using nonempty_iff_ne_empty
theorem eq_empty_or_nonempty (s : Set α) : s = ∅ ∨ s.Nonempty :=
or_iff_not_imp_left.2 nonempty_iff_ne_empty.2
theorem subset_eq_empty {s t : Set α} (h : t ⊆ s) (e : s = ∅) : t = ∅ :=
subset_empty_iff.1 <| e ▸ h
theorem forall_mem_empty {p : α → Prop} : (∀ x ∈ (∅ : Set α), p x) ↔ True :=
iff_true_intro fun _ => False.elim
instance (α : Type u) : IsEmpty.{u + 1} (↥(∅ : Set α)) :=
⟨fun x => x.2⟩
@[simp]
theorem empty_ssubset : ∅ ⊂ s ↔ s.Nonempty :=
(@bot_lt_iff_ne_bot (Set α) _ _ _).trans nonempty_iff_ne_empty.symm
alias ⟨_, Nonempty.empty_ssubset⟩ := empty_ssubset
/-!
### Universal set.
In Lean `@univ α` (or `univ : Set α`) is the set that contains all elements of type `α`.
Mathematically it is the same as `α` but it has a different type.
-/
@[simp]
theorem setOf_true : { _x : α | True } = univ :=
rfl
@[simp] theorem setOf_top : { _x : α | ⊤ } = univ := rfl
@[simp]
theorem univ_eq_empty_iff : (univ : Set α) = ∅ ↔ IsEmpty α :=
eq_empty_iff_forall_not_mem.trans
⟨fun H => ⟨fun x => H x trivial⟩, fun H x _ => @IsEmpty.false α H x⟩
theorem empty_ne_univ [Nonempty α] : (∅ : Set α) ≠ univ := fun e =>
not_isEmpty_of_nonempty α <| univ_eq_empty_iff.1 e.symm
@[simp]
theorem subset_univ (s : Set α) : s ⊆ univ := fun _ _ => trivial
@[simp]
theorem univ_subset_iff {s : Set α} : univ ⊆ s ↔ s = univ :=
@top_le_iff _ _ _ s
alias ⟨eq_univ_of_univ_subset, _⟩ := univ_subset_iff
theorem eq_univ_iff_forall {s : Set α} : s = univ ↔ ∀ x, x ∈ s :=
univ_subset_iff.symm.trans <| forall_congr' fun _ => imp_iff_right trivial
theorem eq_univ_of_forall {s : Set α} : (∀ x, x ∈ s) → s = univ :=
eq_univ_iff_forall.2
theorem Nonempty.eq_univ [Subsingleton α] : s.Nonempty → s = univ := by
rintro ⟨x, hx⟩
exact eq_univ_of_forall fun y => by rwa [Subsingleton.elim y x]
theorem eq_univ_of_subset {s t : Set α} (h : s ⊆ t) (hs : s = univ) : t = univ :=
eq_univ_of_univ_subset <| (hs ▸ h : univ ⊆ t)
theorem exists_mem_of_nonempty (α) : ∀ [Nonempty α], ∃ x : α, x ∈ (univ : Set α)
| ⟨x⟩ => ⟨x, trivial⟩
theorem ne_univ_iff_exists_not_mem {α : Type*} (s : Set α) : s ≠ univ ↔ ∃ a, a ∉ s := by
rw [← not_forall, ← eq_univ_iff_forall]
theorem not_subset_iff_exists_mem_not_mem {α : Type*} {s t : Set α} :
¬s ⊆ t ↔ ∃ x, x ∈ s ∧ x ∉ t := by simp [subset_def]
theorem univ_unique [Unique α] : @Set.univ α = {default} :=
Set.ext fun x => iff_of_true trivial <| Subsingleton.elim x default
theorem ssubset_univ_iff : s ⊂ univ ↔ s ≠ univ :=
lt_top_iff_ne_top
instance nontrivial_of_nonempty [Nonempty α] : Nontrivial (Set α) :=
⟨⟨∅, univ, empty_ne_univ⟩⟩
/-! ### Lemmas about union -/
theorem union_def {s₁ s₂ : Set α} : s₁ ∪ s₂ = { a | a ∈ s₁ ∨ a ∈ s₂ } :=
rfl
theorem mem_union_left {x : α} {a : Set α} (b : Set α) : x ∈ a → x ∈ a ∪ b :=
Or.inl
theorem mem_union_right {x : α} {b : Set α} (a : Set α) : x ∈ b → x ∈ a ∪ b :=
Or.inr
theorem mem_or_mem_of_mem_union {x : α} {a b : Set α} (H : x ∈ a ∪ b) : x ∈ a ∨ x ∈ b :=
H
theorem MemUnion.elim {x : α} {a b : Set α} {P : Prop} (H₁ : x ∈ a ∪ b) (H₂ : x ∈ a → P)
(H₃ : x ∈ b → P) : P :=
Or.elim H₁ H₂ H₃
@[simp]
theorem mem_union (x : α) (a b : Set α) : x ∈ a ∪ b ↔ x ∈ a ∨ x ∈ b :=
Iff.rfl
@[simp]
theorem union_self (a : Set α) : a ∪ a = a :=
ext fun _ => or_self_iff
@[simp]
theorem union_empty (a : Set α) : a ∪ ∅ = a :=
ext fun _ => iff_of_eq (or_false _)
@[simp]
theorem empty_union (a : Set α) : ∅ ∪ a = a :=
ext fun _ => iff_of_eq (false_or _)
theorem union_comm (a b : Set α) : a ∪ b = b ∪ a :=
ext fun _ => or_comm
theorem union_assoc (a b c : Set α) : a ∪ b ∪ c = a ∪ (b ∪ c) :=
ext fun _ => or_assoc
instance union_isAssoc : Std.Associative (α := Set α) (· ∪ ·) :=
⟨union_assoc⟩
instance union_isComm : Std.Commutative (α := Set α) (· ∪ ·) :=
⟨union_comm⟩
theorem union_left_comm (s₁ s₂ s₃ : Set α) : s₁ ∪ (s₂ ∪ s₃) = s₂ ∪ (s₁ ∪ s₃) :=
ext fun _ => or_left_comm
theorem union_right_comm (s₁ s₂ s₃ : Set α) : s₁ ∪ s₂ ∪ s₃ = s₁ ∪ s₃ ∪ s₂ :=
ext fun _ => or_right_comm
@[simp]
theorem union_eq_left {s t : Set α} : s ∪ t = s ↔ t ⊆ s :=
sup_eq_left
@[simp]
theorem union_eq_right {s t : Set α} : s ∪ t = t ↔ s ⊆ t :=
sup_eq_right
theorem union_eq_self_of_subset_left {s t : Set α} (h : s ⊆ t) : s ∪ t = t :=
union_eq_right.mpr h
theorem union_eq_self_of_subset_right {s t : Set α} (h : t ⊆ s) : s ∪ t = s :=
union_eq_left.mpr h
@[simp]
theorem subset_union_left {s t : Set α} : s ⊆ s ∪ t := fun _ => Or.inl
@[simp]
theorem subset_union_right {s t : Set α} : t ⊆ s ∪ t := fun _ => Or.inr
theorem union_subset {s t r : Set α} (sr : s ⊆ r) (tr : t ⊆ r) : s ∪ t ⊆ r := fun _ =>
Or.rec (@sr _) (@tr _)
@[simp]
theorem union_subset_iff {s t u : Set α} : s ∪ t ⊆ u ↔ s ⊆ u ∧ t ⊆ u :=
(forall_congr' fun _ => or_imp).trans forall_and
@[gcongr]
theorem union_subset_union {s₁ s₂ t₁ t₂ : Set α} (h₁ : s₁ ⊆ s₂) (h₂ : t₁ ⊆ t₂) :
s₁ ∪ t₁ ⊆ s₂ ∪ t₂ := fun _ => Or.imp (@h₁ _) (@h₂ _)
@[gcongr]
theorem union_subset_union_left {s₁ s₂ : Set α} (t) (h : s₁ ⊆ s₂) : s₁ ∪ t ⊆ s₂ ∪ t :=
union_subset_union h Subset.rfl
@[gcongr]
theorem union_subset_union_right (s) {t₁ t₂ : Set α} (h : t₁ ⊆ t₂) : s ∪ t₁ ⊆ s ∪ t₂ :=
union_subset_union Subset.rfl h
theorem subset_union_of_subset_left {s t : Set α} (h : s ⊆ t) (u : Set α) : s ⊆ t ∪ u :=
h.trans subset_union_left
theorem subset_union_of_subset_right {s u : Set α} (h : s ⊆ u) (t : Set α) : s ⊆ t ∪ u :=
h.trans subset_union_right
theorem union_congr_left (ht : t ⊆ s ∪ u) (hu : u ⊆ s ∪ t) : s ∪ t = s ∪ u :=
sup_congr_left ht hu
theorem union_congr_right (hs : s ⊆ t ∪ u) (ht : t ⊆ s ∪ u) : s ∪ u = t ∪ u :=
sup_congr_right hs ht
theorem union_eq_union_iff_left : s ∪ t = s ∪ u ↔ t ⊆ s ∪ u ∧ u ⊆ s ∪ t :=
sup_eq_sup_iff_left
theorem union_eq_union_iff_right : s ∪ u = t ∪ u ↔ s ⊆ t ∪ u ∧ t ⊆ s ∪ u :=
sup_eq_sup_iff_right
@[simp]
theorem union_empty_iff {s t : Set α} : s ∪ t = ∅ ↔ s = ∅ ∧ t = ∅ := by
simp only [← subset_empty_iff]
exact union_subset_iff
@[simp]
theorem union_univ (s : Set α) : s ∪ univ = univ := sup_top_eq _
@[simp]
theorem univ_union (s : Set α) : univ ∪ s = univ := top_sup_eq _
@[simp]
theorem ssubset_union_left_iff : s ⊂ s ∪ t ↔ ¬ t ⊆ s :=
left_lt_sup
@[simp]
theorem ssubset_union_right_iff : t ⊂ s ∪ t ↔ ¬ s ⊆ t :=
right_lt_sup
/-! ### Lemmas about intersection -/
theorem inter_def {s₁ s₂ : Set α} : s₁ ∩ s₂ = { a | a ∈ s₁ ∧ a ∈ s₂ } :=
rfl
@[simp, mfld_simps]
theorem mem_inter_iff (x : α) (a b : Set α) : x ∈ a ∩ b ↔ x ∈ a ∧ x ∈ b :=
Iff.rfl
theorem mem_inter {x : α} {a b : Set α} (ha : x ∈ a) (hb : x ∈ b) : x ∈ a ∩ b :=
⟨ha, hb⟩
theorem mem_of_mem_inter_left {x : α} {a b : Set α} (h : x ∈ a ∩ b) : x ∈ a :=
h.left
theorem mem_of_mem_inter_right {x : α} {a b : Set α} (h : x ∈ a ∩ b) : x ∈ b :=
h.right
@[simp]
theorem inter_self (a : Set α) : a ∩ a = a :=
ext fun _ => and_self_iff
@[simp]
theorem inter_empty (a : Set α) : a ∩ ∅ = ∅ :=
ext fun _ => iff_of_eq (and_false _)
@[simp]
theorem empty_inter (a : Set α) : ∅ ∩ a = ∅ :=
ext fun _ => iff_of_eq (false_and _)
theorem inter_comm (a b : Set α) : a ∩ b = b ∩ a :=
ext fun _ => and_comm
theorem inter_assoc (a b c : Set α) : a ∩ b ∩ c = a ∩ (b ∩ c) :=
ext fun _ => and_assoc
instance inter_isAssoc : Std.Associative (α := Set α) (· ∩ ·) :=
⟨inter_assoc⟩
instance inter_isComm : Std.Commutative (α := Set α) (· ∩ ·) :=
⟨inter_comm⟩
theorem inter_left_comm (s₁ s₂ s₃ : Set α) : s₁ ∩ (s₂ ∩ s₃) = s₂ ∩ (s₁ ∩ s₃) :=
ext fun _ => and_left_comm
theorem inter_right_comm (s₁ s₂ s₃ : Set α) : s₁ ∩ s₂ ∩ s₃ = s₁ ∩ s₃ ∩ s₂ :=
ext fun _ => and_right_comm
@[simp, mfld_simps]
theorem inter_subset_left {s t : Set α} : s ∩ t ⊆ s := fun _ => And.left
@[simp]
theorem inter_subset_right {s t : Set α} : s ∩ t ⊆ t := fun _ => And.right
theorem subset_inter {s t r : Set α} (rs : r ⊆ s) (rt : r ⊆ t) : r ⊆ s ∩ t := fun _ h =>
⟨rs h, rt h⟩
@[simp]
theorem subset_inter_iff {s t r : Set α} : r ⊆ s ∩ t ↔ r ⊆ s ∧ r ⊆ t :=
(forall_congr' fun _ => imp_and).trans forall_and
@[simp] lemma inter_eq_left : s ∩ t = s ↔ s ⊆ t := inf_eq_left
@[simp] lemma inter_eq_right : s ∩ t = t ↔ t ⊆ s := inf_eq_right
@[simp] lemma left_eq_inter : s = s ∩ t ↔ s ⊆ t := left_eq_inf
@[simp] lemma right_eq_inter : t = s ∩ t ↔ t ⊆ s := right_eq_inf
theorem inter_eq_self_of_subset_left {s t : Set α} : s ⊆ t → s ∩ t = s :=
inter_eq_left.mpr
theorem inter_eq_self_of_subset_right {s t : Set α} : t ⊆ s → s ∩ t = t :=
inter_eq_right.mpr
theorem inter_congr_left (ht : s ∩ u ⊆ t) (hu : s ∩ t ⊆ u) : s ∩ t = s ∩ u :=
inf_congr_left ht hu
theorem inter_congr_right (hs : t ∩ u ⊆ s) (ht : s ∩ u ⊆ t) : s ∩ u = t ∩ u :=
inf_congr_right hs ht
theorem inter_eq_inter_iff_left : s ∩ t = s ∩ u ↔ s ∩ u ⊆ t ∧ s ∩ t ⊆ u :=
inf_eq_inf_iff_left
theorem inter_eq_inter_iff_right : s ∩ u = t ∩ u ↔ t ∩ u ⊆ s ∧ s ∩ u ⊆ t :=
inf_eq_inf_iff_right
@[simp, mfld_simps]
theorem inter_univ (a : Set α) : a ∩ univ = a := inf_top_eq _
@[simp, mfld_simps]
theorem univ_inter (a : Set α) : univ ∩ a = a := top_inf_eq _
@[gcongr]
theorem inter_subset_inter {s₁ s₂ t₁ t₂ : Set α} (h₁ : s₁ ⊆ t₁) (h₂ : s₂ ⊆ t₂) :
s₁ ∩ s₂ ⊆ t₁ ∩ t₂ := fun _ => And.imp (@h₁ _) (@h₂ _)
@[gcongr]
theorem inter_subset_inter_left {s t : Set α} (u : Set α) (H : s ⊆ t) : s ∩ u ⊆ t ∩ u :=
inter_subset_inter H Subset.rfl
@[gcongr]
theorem inter_subset_inter_right {s t : Set α} (u : Set α) (H : s ⊆ t) : u ∩ s ⊆ u ∩ t :=
inter_subset_inter Subset.rfl H
theorem union_inter_cancel_left {s t : Set α} : (s ∪ t) ∩ s = s :=
inter_eq_self_of_subset_right subset_union_left
theorem union_inter_cancel_right {s t : Set α} : (s ∪ t) ∩ t = t :=
inter_eq_self_of_subset_right subset_union_right
theorem inter_setOf_eq_sep (s : Set α) (p : α → Prop) : s ∩ {a | p a} = {a ∈ s | p a} :=
rfl
theorem setOf_inter_eq_sep (p : α → Prop) (s : Set α) : {a | p a} ∩ s = {a ∈ s | p a} :=
inter_comm _ _
@[simp]
theorem inter_ssubset_right_iff : s ∩ t ⊂ t ↔ ¬ t ⊆ s :=
inf_lt_right
@[simp]
theorem inter_ssubset_left_iff : s ∩ t ⊂ s ↔ ¬ s ⊆ t :=
inf_lt_left
/-! ### Distributivity laws -/
theorem inter_union_distrib_left (s t u : Set α) : s ∩ (t ∪ u) = s ∩ t ∪ s ∩ u :=
inf_sup_left _ _ _
theorem union_inter_distrib_right (s t u : Set α) : (s ∪ t) ∩ u = s ∩ u ∪ t ∩ u :=
inf_sup_right _ _ _
theorem union_inter_distrib_left (s t u : Set α) : s ∪ t ∩ u = (s ∪ t) ∩ (s ∪ u) :=
sup_inf_left _ _ _
theorem inter_union_distrib_right (s t u : Set α) : s ∩ t ∪ u = (s ∪ u) ∩ (t ∪ u) :=
sup_inf_right _ _ _
theorem union_union_distrib_left (s t u : Set α) : s ∪ (t ∪ u) = s ∪ t ∪ (s ∪ u) :=
sup_sup_distrib_left _ _ _
theorem union_union_distrib_right (s t u : Set α) : s ∪ t ∪ u = s ∪ u ∪ (t ∪ u) :=
sup_sup_distrib_right _ _ _
theorem inter_inter_distrib_left (s t u : Set α) : s ∩ (t ∩ u) = s ∩ t ∩ (s ∩ u) :=
inf_inf_distrib_left _ _ _
theorem inter_inter_distrib_right (s t u : Set α) : s ∩ t ∩ u = s ∩ u ∩ (t ∩ u) :=
inf_inf_distrib_right _ _ _
theorem union_union_union_comm (s t u v : Set α) : s ∪ t ∪ (u ∪ v) = s ∪ u ∪ (t ∪ v) :=
sup_sup_sup_comm _ _ _ _
theorem inter_inter_inter_comm (s t u v : Set α) : s ∩ t ∩ (u ∩ v) = s ∩ u ∩ (t ∩ v) :=
inf_inf_inf_comm _ _ _ _
/-! ### Lemmas about sets defined as `{x ∈ s | p x}`. -/
section Sep
variable {p q : α → Prop} {x : α}
theorem mem_sep (xs : x ∈ s) (px : p x) : x ∈ { x ∈ s | p x } :=
⟨xs, px⟩
@[simp]
theorem sep_mem_eq : { x ∈ s | x ∈ t } = s ∩ t :=
rfl
@[simp]
theorem mem_sep_iff : x ∈ { x ∈ s | p x } ↔ x ∈ s ∧ p x :=
Iff.rfl
theorem sep_ext_iff : { x ∈ s | p x } = { x ∈ s | q x } ↔ ∀ x ∈ s, p x ↔ q x := by
simp_rw [Set.ext_iff, mem_sep_iff, and_congr_right_iff]
theorem sep_eq_of_subset (h : s ⊆ t) : { x ∈ t | x ∈ s } = s :=
inter_eq_self_of_subset_right h
@[simp]
theorem sep_subset (s : Set α) (p : α → Prop) : { x ∈ s | p x } ⊆ s := fun _ => And.left
@[simp]
theorem sep_eq_self_iff_mem_true : { x ∈ s | p x } = s ↔ ∀ x ∈ s, p x := by
simp_rw [Set.ext_iff, mem_sep_iff, and_iff_left_iff_imp]
@[simp]
theorem sep_eq_empty_iff_mem_false : { x ∈ s | p x } = ∅ ↔ ∀ x ∈ s, ¬p x := by
simp_rw [Set.ext_iff, mem_sep_iff, mem_empty_iff_false, iff_false, not_and]
theorem sep_true : { x ∈ s | True } = s :=
inter_univ s
theorem sep_false : { x ∈ s | False } = ∅ :=
inter_empty s
theorem sep_empty (p : α → Prop) : { x ∈ (∅ : Set α) | p x } = ∅ :=
empty_inter {x | p x}
theorem sep_univ : { x ∈ (univ : Set α) | p x } = { x | p x } :=
univ_inter {x | p x}
@[simp]
theorem sep_union : { x | (x ∈ s ∨ x ∈ t) ∧ p x } = { x ∈ s | p x } ∪ { x ∈ t | p x } :=
union_inter_distrib_right { x | x ∈ s } { x | x ∈ t } p
@[simp]
theorem sep_inter : { x | (x ∈ s ∧ x ∈ t) ∧ p x } = { x ∈ s | p x } ∩ { x ∈ t | p x } :=
inter_inter_distrib_right s t {x | p x}
@[simp]
theorem sep_and : { x ∈ s | p x ∧ q x } = { x ∈ s | p x } ∩ { x ∈ s | q x } :=
inter_inter_distrib_left s {x | p x} {x | q x}
@[simp]
theorem sep_or : { x ∈ s | p x ∨ q x } = { x ∈ s | p x } ∪ { x ∈ s | q x } :=
inter_union_distrib_left s p q
@[simp]
theorem sep_setOf : { x ∈ { y | p y } | q x } = { x | p x ∧ q x } :=
rfl
end Sep
/-- See also `Set.sdiff_inter_right_comm`. -/
lemma inter_diff_assoc (a b c : Set α) : (a ∩ b) \ c = a ∩ (b \ c) := inf_sdiff_assoc ..
/-- See also `Set.inter_diff_assoc`. -/
lemma sdiff_inter_right_comm (s t u : Set α) : s \ t ∩ u = (s ∩ u) \ t := sdiff_inf_right_comm ..
lemma inter_sdiff_left_comm (s t u : Set α) : s ∩ (t \ u) = t ∩ (s \ u) := inf_sdiff_left_comm ..
theorem diff_union_diff_cancel (hts : t ⊆ s) (hut : u ⊆ t) : s \ t ∪ t \ u = s \ u :=
sdiff_sup_sdiff_cancel hts hut
/-- A version of `diff_union_diff_cancel` with more general hypotheses. -/
theorem diff_union_diff_cancel' (hi : s ∩ u ⊆ t) (hu : t ⊆ s ∪ u) : (s \ t) ∪ (t \ u) = s \ u :=
sdiff_sup_sdiff_cancel' hi hu
theorem diff_diff_eq_sdiff_union (h : u ⊆ s) : s \ (t \ u) = s \ t ∪ u := sdiff_sdiff_eq_sdiff_sup h
theorem inter_diff_distrib_left (s t u : Set α) : s ∩ (t \ u) = (s ∩ t) \ (s ∩ u) :=
inf_sdiff_distrib_left _ _ _
theorem inter_diff_distrib_right (s t u : Set α) : (s \ t) ∩ u = (s ∩ u) \ (t ∩ u) :=
inf_sdiff_distrib_right _ _ _
theorem diff_inter_distrib_right (s t r : Set α) : (t ∩ r) \ s = (t \ s) ∩ (r \ s) :=
inf_sdiff
/-! ### Lemmas about complement -/
theorem compl_def (s : Set α) : sᶜ = { x | x ∉ s } :=
rfl
theorem mem_compl {s : Set α} {x : α} (h : x ∉ s) : x ∈ sᶜ :=
h
theorem compl_setOf {α} (p : α → Prop) : { a | p a }ᶜ = { a | ¬p a } :=
rfl
theorem not_mem_of_mem_compl {s : Set α} {x : α} (h : x ∈ sᶜ) : x ∉ s :=
h
theorem not_mem_compl_iff {x : α} : x ∉ sᶜ ↔ x ∈ s :=
not_not
@[simp]
theorem inter_compl_self (s : Set α) : s ∩ sᶜ = ∅ :=
inf_compl_eq_bot
@[simp]
theorem compl_inter_self (s : Set α) : sᶜ ∩ s = ∅ :=
compl_inf_eq_bot
@[simp]
theorem compl_empty : (∅ : Set α)ᶜ = univ :=
compl_bot
@[simp]
theorem compl_union (s t : Set α) : (s ∪ t)ᶜ = sᶜ ∩ tᶜ :=
compl_sup
theorem compl_inter (s t : Set α) : (s ∩ t)ᶜ = sᶜ ∪ tᶜ :=
compl_inf
@[simp]
theorem compl_univ : (univ : Set α)ᶜ = ∅ :=
compl_top
@[simp]
theorem compl_empty_iff {s : Set α} : sᶜ = ∅ ↔ s = univ :=
compl_eq_bot
@[simp]
theorem compl_univ_iff {s : Set α} : sᶜ = univ ↔ s = ∅ :=
compl_eq_top
theorem compl_ne_univ : sᶜ ≠ univ ↔ s.Nonempty :=
compl_univ_iff.not.trans nonempty_iff_ne_empty.symm
lemma inl_compl_union_inr_compl {α β : Type*} {s : Set α} {t : Set β} :
Sum.inl '' sᶜ ∪ Sum.inr '' tᶜ = (Sum.inl '' s ∪ Sum.inr '' t)ᶜ := by
rw [compl_union]
aesop
theorem nonempty_compl : sᶜ.Nonempty ↔ s ≠ univ :=
(ne_univ_iff_exists_not_mem s).symm
theorem union_eq_compl_compl_inter_compl (s t : Set α) : s ∪ t = (sᶜ ∩ tᶜ)ᶜ :=
ext fun _ => or_iff_not_and_not
theorem inter_eq_compl_compl_union_compl (s t : Set α) : s ∩ t = (sᶜ ∪ tᶜ)ᶜ :=
ext fun _ => and_iff_not_or_not
@[simp]
theorem union_compl_self (s : Set α) : s ∪ sᶜ = univ :=
eq_univ_iff_forall.2 fun _ => em _
@[simp]
theorem compl_union_self (s : Set α) : sᶜ ∪ s = univ := by rw [union_comm, union_compl_self]
theorem compl_subset_comm : sᶜ ⊆ t ↔ tᶜ ⊆ s :=
@compl_le_iff_compl_le _ s _ _
theorem subset_compl_comm : s ⊆ tᶜ ↔ t ⊆ sᶜ :=
@le_compl_iff_le_compl _ _ _ t
@[simp]
theorem compl_subset_compl : sᶜ ⊆ tᶜ ↔ t ⊆ s :=
@compl_le_compl_iff_le (Set α) _ _ _
@[gcongr] theorem compl_subset_compl_of_subset (h : t ⊆ s) : sᶜ ⊆ tᶜ := compl_subset_compl.2 h
theorem subset_union_compl_iff_inter_subset {s t u : Set α} : s ⊆ t ∪ uᶜ ↔ s ∩ u ⊆ t :=
(@isCompl_compl _ u _).le_sup_right_iff_inf_left_le
theorem compl_subset_iff_union {s t : Set α} : sᶜ ⊆ t ↔ s ∪ t = univ :=
Iff.symm <| eq_univ_iff_forall.trans <| forall_congr' fun _ => or_iff_not_imp_left
theorem inter_subset (a b c : Set α) : a ∩ b ⊆ c ↔ a ⊆ bᶜ ∪ c :=
forall_congr' fun _ => and_imp.trans <| imp_congr_right fun _ => imp_iff_not_or
theorem inter_compl_nonempty_iff {s t : Set α} : (s ∩ tᶜ).Nonempty ↔ ¬s ⊆ t :=
(not_subset.trans <| exists_congr fun x => by simp [mem_compl]).symm
/-! ### Lemmas about set difference -/
theorem not_mem_diff_of_mem {s t : Set α} {x : α} (hx : x ∈ t) : x ∉ s \ t := fun h => h.2 hx
theorem mem_of_mem_diff {s t : Set α} {x : α} (h : x ∈ s \ t) : x ∈ s :=
h.left
theorem not_mem_of_mem_diff {s t : Set α} {x : α} (h : x ∈ s \ t) : x ∉ t :=
h.right
theorem diff_eq_compl_inter {s t : Set α} : s \ t = tᶜ ∩ s := by rw [diff_eq, inter_comm]
theorem diff_nonempty {s t : Set α} : (s \ t).Nonempty ↔ ¬s ⊆ t :=
inter_compl_nonempty_iff
theorem diff_subset {s t : Set α} : s \ t ⊆ s := show s \ t ≤ s from sdiff_le
theorem diff_subset_compl (s t : Set α) : s \ t ⊆ tᶜ :=
diff_eq_compl_inter ▸ inter_subset_left
theorem union_diff_cancel' {s t u : Set α} (h₁ : s ⊆ t) (h₂ : t ⊆ u) : t ∪ u \ s = u :=
sup_sdiff_cancel' h₁ h₂
theorem union_diff_cancel {s t : Set α} (h : s ⊆ t) : s ∪ t \ s = t :=
sup_sdiff_cancel_right h
theorem union_diff_cancel_left {s t : Set α} (h : s ∩ t ⊆ ∅) : (s ∪ t) \ s = t :=
Disjoint.sup_sdiff_cancel_left <| disjoint_iff_inf_le.2 h
theorem union_diff_cancel_right {s t : Set α} (h : s ∩ t ⊆ ∅) : (s ∪ t) \ t = s :=
Disjoint.sup_sdiff_cancel_right <| disjoint_iff_inf_le.2 h
@[simp]
theorem union_diff_left {s t : Set α} : (s ∪ t) \ s = t \ s :=
sup_sdiff_left_self
@[simp]
theorem union_diff_right {s t : Set α} : (s ∪ t) \ t = s \ t :=
sup_sdiff_right_self
theorem union_diff_distrib {s t u : Set α} : (s ∪ t) \ u = s \ u ∪ t \ u :=
sup_sdiff
@[simp]
theorem inter_diff_self (a b : Set α) : a ∩ (b \ a) = ∅ :=
inf_sdiff_self_right
@[simp]
theorem inter_union_diff (s t : Set α) : s ∩ t ∪ s \ t = s :=
sup_inf_sdiff s t
@[simp]
theorem diff_union_inter (s t : Set α) : s \ t ∪ s ∩ t = s := by
rw [union_comm]
exact sup_inf_sdiff _ _
@[simp]
theorem inter_union_compl (s t : Set α) : s ∩ t ∪ s ∩ tᶜ = s :=
inter_union_diff _ _
@[gcongr]
theorem diff_subset_diff {s₁ s₂ t₁ t₂ : Set α} : s₁ ⊆ s₂ → t₂ ⊆ t₁ → s₁ \ t₁ ⊆ s₂ \ t₂ :=
show s₁ ≤ s₂ → t₂ ≤ t₁ → s₁ \ t₁ ≤ s₂ \ t₂ from sdiff_le_sdiff
@[gcongr]
theorem diff_subset_diff_left {s₁ s₂ t : Set α} (h : s₁ ⊆ s₂) : s₁ \ t ⊆ s₂ \ t :=
sdiff_le_sdiff_right ‹s₁ ≤ s₂›
@[gcongr]
theorem diff_subset_diff_right {s t u : Set α} (h : t ⊆ u) : s \ u ⊆ s \ t :=
sdiff_le_sdiff_left ‹t ≤ u›
theorem diff_subset_diff_iff_subset {r : Set α} (hs : s ⊆ r) (ht : t ⊆ r) :
r \ s ⊆ r \ t ↔ t ⊆ s :=
sdiff_le_sdiff_iff_le hs ht
theorem compl_eq_univ_diff (s : Set α) : sᶜ = univ \ s :=
top_sdiff.symm
@[simp]
theorem empty_diff (s : Set α) : (∅ \ s : Set α) = ∅ :=
bot_sdiff
theorem diff_eq_empty {s t : Set α} : s \ t = ∅ ↔ s ⊆ t :=
sdiff_eq_bot_iff
@[simp]
theorem diff_empty {s : Set α} : s \ ∅ = s :=
sdiff_bot
@[simp]
theorem diff_univ (s : Set α) : s \ univ = ∅ :=
diff_eq_empty.2 (subset_univ s)
theorem diff_diff {u : Set α} : (s \ t) \ u = s \ (t ∪ u) :=
sdiff_sdiff_left
-- the following statement contains parentheses to help the reader
theorem diff_diff_comm {s t u : Set α} : (s \ t) \ u = (s \ u) \ t :=
sdiff_sdiff_comm
theorem diff_subset_iff {s t u : Set α} : s \ t ⊆ u ↔ s ⊆ t ∪ u :=
show s \ t ≤ u ↔ s ≤ t ∪ u from sdiff_le_iff
theorem subset_diff_union (s t : Set α) : s ⊆ s \ t ∪ t :=
show s ≤ s \ t ∪ t from le_sdiff_sup
theorem diff_union_of_subset {s t : Set α} (h : t ⊆ s) : s \ t ∪ t = s :=
Subset.antisymm (union_subset diff_subset h) (subset_diff_union _ _)
theorem diff_subset_comm {s t u : Set α} : s \ t ⊆ u ↔ s \ u ⊆ t :=
show s \ t ≤ u ↔ s \ u ≤ t from sdiff_le_comm
theorem diff_inter {s t u : Set α} : s \ (t ∩ u) = s \ t ∪ s \ u :=
sdiff_inf
theorem diff_inter_diff : s \ t ∩ (s \ u) = s \ (t ∪ u) :=
sdiff_sup.symm
theorem diff_compl : s \ tᶜ = s ∩ t :=
sdiff_compl
theorem compl_diff : (t \ s)ᶜ = s ∪ tᶜ :=
Eq.trans compl_sdiff himp_eq
theorem diff_diff_right {s t u : Set α} : s \ (t \ u) = s \ t ∪ s ∩ u :=
sdiff_sdiff_right'
theorem inter_diff_right_comm : (s ∩ t) \ u = s \ u ∩ t := by
rw [diff_eq, diff_eq, inter_right_comm]
theorem diff_inter_right_comm : (s \ u) ∩ t = (s ∩ t) \ u := by
rw [diff_eq, diff_eq, inter_right_comm]
@[simp]
theorem union_diff_self {s t : Set α} : s ∪ t \ s = s ∪ t :=
sup_sdiff_self _ _
@[simp]
theorem diff_union_self {s t : Set α} : s \ t ∪ t = s ∪ t :=
sdiff_sup_self _ _
@[simp]
theorem diff_inter_self {a b : Set α} : b \ a ∩ a = ∅ :=
inf_sdiff_self_left
@[simp]
theorem diff_inter_self_eq_diff {s t : Set α} : s \ (t ∩ s) = s \ t :=
sdiff_inf_self_right _ _
@[simp]
theorem diff_self_inter {s t : Set α} : s \ (s ∩ t) = s \ t :=
sdiff_inf_self_left _ _
theorem diff_self {s : Set α} : s \ s = ∅ :=
sdiff_self
theorem diff_diff_right_self (s t : Set α) : s \ (s \ t) = s ∩ t :=
sdiff_sdiff_right_self
theorem diff_diff_cancel_left {s t : Set α} (h : s ⊆ t) : t \ (t \ s) = s :=
sdiff_sdiff_eq_self h
theorem union_eq_diff_union_diff_union_inter (s t : Set α) : s ∪ t = s \ t ∪ t \ s ∪ s ∩ t :=
sup_eq_sdiff_sup_sdiff_sup_inf
/-! ### Powerset -/
theorem mem_powerset {x s : Set α} (h : x ⊆ s) : x ∈ 𝒫 s := @h
theorem subset_of_mem_powerset {x s : Set α} (h : x ∈ 𝒫 s) : x ⊆ s := @h
@[simp]
theorem mem_powerset_iff (x s : Set α) : x ∈ 𝒫 s ↔ x ⊆ s :=
Iff.rfl
theorem powerset_inter (s t : Set α) : 𝒫(s ∩ t) = 𝒫 s ∩ 𝒫 t :=
ext fun _ => subset_inter_iff
@[simp]
theorem powerset_mono : 𝒫 s ⊆ 𝒫 t ↔ s ⊆ t :=
⟨fun h => @h _ (fun _ h => h), fun h _ hu _ ha => h (hu ha)⟩
theorem monotone_powerset : Monotone (powerset : Set α → Set (Set α)) := fun _ _ => powerset_mono.2
@[simp]
theorem powerset_nonempty : (𝒫 s).Nonempty :=
⟨∅, fun _ h => empty_subset s h⟩
@[simp]
theorem powerset_empty : 𝒫(∅ : Set α) = {∅} :=
ext fun _ => subset_empty_iff
@[simp]
theorem powerset_univ : 𝒫(univ : Set α) = univ :=
eq_univ_of_forall subset_univ
/-! ### Sets defined as an if-then-else -/
@[deprecated _root_.mem_dite (since := "2025-01-30")]
protected theorem mem_dite (p : Prop) [Decidable p] (s : p → Set α) (t : ¬ p → Set α) (x : α) :
(x ∈ if h : p then s h else t h) ↔ (∀ h : p, x ∈ s h) ∧ ∀ h : ¬p, x ∈ t h :=
_root_.mem_dite
theorem mem_dite_univ_right (p : Prop) [Decidable p] (t : p → Set α) (x : α) :
(x ∈ if h : p then t h else univ) ↔ ∀ h : p, x ∈ t h := by
simp [mem_dite]
@[simp]
theorem mem_ite_univ_right (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p t Set.univ ↔ p → x ∈ t :=
mem_dite_univ_right p (fun _ => t) x
theorem mem_dite_univ_left (p : Prop) [Decidable p] (t : ¬p → Set α) (x : α) :
(x ∈ if h : p then univ else t h) ↔ ∀ h : ¬p, x ∈ t h := by
split_ifs <;> simp_all
@[simp]
theorem mem_ite_univ_left (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p Set.univ t ↔ ¬p → x ∈ t :=
mem_dite_univ_left p (fun _ => t) x
theorem mem_dite_empty_right (p : Prop) [Decidable p] (t : p → Set α) (x : α) :
(x ∈ if h : p then t h else ∅) ↔ ∃ h : p, x ∈ t h := by
simp only [mem_dite, mem_empty_iff_false, imp_false, not_not]
exact ⟨fun h => ⟨h.2, h.1 h.2⟩, fun ⟨h₁, h₂⟩ => ⟨fun _ => h₂, h₁⟩⟩
@[simp]
theorem mem_ite_empty_right (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p t ∅ ↔ p ∧ x ∈ t :=
(mem_dite_empty_right p (fun _ => t) x).trans (by simp)
theorem mem_dite_empty_left (p : Prop) [Decidable p] (t : ¬p → Set α) (x : α) :
(x ∈ if h : p then ∅ else t h) ↔ ∃ h : ¬p, x ∈ t h := by
simp only [mem_dite, mem_empty_iff_false, imp_false]
exact ⟨fun h => ⟨h.1, h.2 h.1⟩, fun ⟨h₁, h₂⟩ => ⟨fun h => h₁ h, fun _ => h₂⟩⟩
@[simp]
theorem mem_ite_empty_left (p : Prop) [Decidable p] (t : Set α) (x : α) :
x ∈ ite p ∅ t ↔ ¬p ∧ x ∈ t :=
(mem_dite_empty_left p (fun _ => t) x).trans (by simp)
/-! ### If-then-else for sets -/
/-- `ite` for sets: `Set.ite t s s' ∩ t = s ∩ t`, `Set.ite t s s' ∩ tᶜ = s' ∩ tᶜ`.
Defined as `s ∩ t ∪ s' \ t`. -/
protected def ite (t s s' : Set α) : Set α :=
s ∩ t ∪ s' \ t
@[simp]
theorem ite_inter_self (t s s' : Set α) : t.ite s s' ∩ t = s ∩ t := by
rw [Set.ite, union_inter_distrib_right, diff_inter_self, inter_assoc, inter_self, union_empty]
@[simp]
theorem ite_compl (t s s' : Set α) : tᶜ.ite s s' = t.ite s' s := by
rw [Set.ite, Set.ite, diff_compl, union_comm, diff_eq]
@[simp]
theorem ite_inter_compl_self (t s s' : Set α) : t.ite s s' ∩ tᶜ = s' ∩ tᶜ := by
rw [← ite_compl, ite_inter_self]
@[simp]
theorem ite_diff_self (t s s' : Set α) : t.ite s s' \ t = s' \ t :=
ite_inter_compl_self t s s'
@[simp]
theorem ite_same (t s : Set α) : t.ite s s = s :=
inter_union_diff _ _
@[simp]
theorem ite_left (s t : Set α) : s.ite s t = s ∪ t := by simp [Set.ite]
@[simp]
theorem ite_right (s t : Set α) : s.ite t s = t ∩ s := by simp [Set.ite]
@[simp]
theorem ite_empty (s s' : Set α) : Set.ite ∅ s s' = s' := by simp [Set.ite]
@[simp]
theorem ite_univ (s s' : Set α) : Set.ite univ s s' = s := by simp [Set.ite]
@[simp]
theorem ite_empty_left (t s : Set α) : t.ite ∅ s = s \ t := by simp [Set.ite]
@[simp]
theorem ite_empty_right (t s : Set α) : t.ite s ∅ = s ∩ t := by simp [Set.ite]
theorem ite_mono (t : Set α) {s₁ s₁' s₂ s₂' : Set α} (h : s₁ ⊆ s₂) (h' : s₁' ⊆ s₂') :
t.ite s₁ s₁' ⊆ t.ite s₂ s₂' :=
union_subset_union (inter_subset_inter_left _ h) (inter_subset_inter_left _ h')
theorem ite_subset_union (t s s' : Set α) : t.ite s s' ⊆ s ∪ s' :=
union_subset_union inter_subset_left diff_subset
theorem inter_subset_ite (t s s' : Set α) : s ∩ s' ⊆ t.ite s s' :=
ite_same t (s ∩ s') ▸ ite_mono _ inter_subset_left inter_subset_right
theorem ite_inter_inter (t s₁ s₂ s₁' s₂' : Set α) :
t.ite (s₁ ∩ s₂) (s₁' ∩ s₂') = t.ite s₁ s₁' ∩ t.ite s₂ s₂' := by
ext x
simp only [Set.ite, Set.mem_inter_iff, Set.mem_diff, Set.mem_union]
tauto
theorem ite_inter (t s₁ s₂ s : Set α) : t.ite (s₁ ∩ s) (s₂ ∩ s) = t.ite s₁ s₂ ∩ s := by
rw [ite_inter_inter, ite_same]
theorem ite_inter_of_inter_eq (t : Set α) {s₁ s₂ s : Set α} (h : s₁ ∩ s = s₂ ∩ s) :
t.ite s₁ s₂ ∩ s = s₁ ∩ s := by rw [← ite_inter, ← h, ite_same]
theorem subset_ite {t s s' u : Set α} : u ⊆ t.ite s s' ↔ u ∩ t ⊆ s ∧ u \ t ⊆ s' := by
simp only [subset_def, ← forall_and]
refine forall_congr' fun x => ?_
by_cases hx : x ∈ t <;> simp [*, Set.ite]
theorem ite_eq_of_subset_left (t : Set α) {s₁ s₂ : Set α} (h : s₁ ⊆ s₂) :
t.ite s₁ s₂ = s₁ ∪ (s₂ \ t) := by
ext x
by_cases hx : x ∈ t <;> simp [*, Set.ite, or_iff_right_of_imp (@h x)]
theorem ite_eq_of_subset_right (t : Set α) {s₁ s₂ : Set α} (h : s₂ ⊆ s₁) :
t.ite s₁ s₂ = (s₁ ∩ t) ∪ s₂ := by
ext x
by_cases hx : x ∈ t <;> simp [*, Set.ite, or_iff_left_of_imp (@h x)]
end Set
open Set
namespace Function
variable {α : Type*} {β : Type*}
theorem Injective.nonempty_apply_iff {f : Set α → Set β} (hf : Injective f) (h2 : f ∅ = ∅)
{s : Set α} : (f s).Nonempty ↔ s.Nonempty := by
rw [nonempty_iff_ne_empty, ← h2, nonempty_iff_ne_empty, hf.ne_iff]
end Function
namespace Subsingleton
variable {α : Type*} [Subsingleton α]
theorem eq_univ_of_nonempty {s : Set α} : s.Nonempty → s = univ := fun ⟨x, hx⟩ =>
eq_univ_of_forall fun y => Subsingleton.elim x y ▸ hx
@[elab_as_elim]
theorem set_cases {p : Set α → Prop} (h0 : p ∅) (h1 : p univ) (s) : p s :=
(s.eq_empty_or_nonempty.elim fun h => h.symm ▸ h0) fun h => (eq_univ_of_nonempty h).symm ▸ h1
theorem mem_iff_nonempty {α : Type*} [Subsingleton α] {s : Set α} {x : α} : x ∈ s ↔ s.Nonempty :=
⟨fun hx => ⟨x, hx⟩, fun ⟨y, hy⟩ => Subsingleton.elim y x ▸ hy⟩
end Subsingleton
/-! ### Decidability instances for sets -/
namespace Set
variable {α : Type u} (s t : Set α) (a b : α)
instance decidableSdiff [Decidable (a ∈ s)] [Decidable (a ∈ t)] : Decidable (a ∈ s \ t) :=
inferInstanceAs (Decidable (a ∈ s ∧ a ∉ t))
instance decidableInter [Decidable (a ∈ s)] [Decidable (a ∈ t)] : Decidable (a ∈ s ∩ t) :=
inferInstanceAs (Decidable (a ∈ s ∧ a ∈ t))
instance decidableUnion [Decidable (a ∈ s)] [Decidable (a ∈ t)] : Decidable (a ∈ s ∪ t) :=
inferInstanceAs (Decidable (a ∈ s ∨ a ∈ t))
instance decidableCompl [Decidable (a ∈ s)] : Decidable (a ∈ sᶜ) :=
inferInstanceAs (Decidable (a ∉ s))
instance decidableEmptyset : Decidable (a ∈ (∅ : Set α)) := Decidable.isFalse (by simp)
instance decidableUniv : Decidable (a ∈ univ) := Decidable.isTrue (by simp)
instance decidableInsert [Decidable (a = b)] [Decidable (a ∈ s)] : Decidable (a ∈ insert b s) :=
inferInstanceAs (Decidable (_ ∨ _))
instance decidableSetOf (p : α → Prop) [Decidable (p a)] : Decidable (a ∈ { a | p a }) := by
assumption
end Set
variable {α : Type*} {s t u : Set α}
namespace Equiv
/-- Given a predicate `p : α → Prop`, produces an equivalence between
`Set {a : α // p a}` and `{s : Set α // ∀ a ∈ s, p a}`. -/
protected def setSubtypeComm (p : α → Prop) :
Set {a : α // p a} ≃ {s : Set α // ∀ a ∈ s, p a} where
toFun s := ⟨{a | ∃ h : p a, s ⟨a, h⟩}, fun _ h ↦ h.1⟩
invFun s := {a | a.val ∈ s.val}
left_inv s := by ext a; exact ⟨fun h ↦ h.2, fun h ↦ ⟨a.property, h⟩⟩
right_inv s := by ext; exact ⟨fun h ↦ h.2, fun h ↦ ⟨s.property _ h, h⟩⟩
@[simp]
protected lemma setSubtypeComm_apply (p : α → Prop) (s : Set {a // p a}) :
(Equiv.setSubtypeComm p) s = ⟨{a | ∃ h : p a, ⟨a, h⟩ ∈ s}, fun _ h ↦ h.1⟩ :=
rfl
@[simp]
protected lemma setSubtypeComm_symm_apply (p : α → Prop) (s : {s // ∀ a ∈ s, p a}) :
(Equiv.setSubtypeComm p).symm s = {a | a.val ∈ s.val} :=
rfl
end Equiv
| Mathlib/Data/Set/Basic.lean | 2,349 | 2,352 | |
/-
Copyright (c) 2021 Stuart Presnell. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Stuart Presnell
-/
import Mathlib.Data.Nat.PrimeFin
import Mathlib.Data.Nat.Factorization.Defs
import Mathlib.Data.Nat.GCD.BigOperators
import Mathlib.Order.Interval.Finset.Nat
import Mathlib.Tactic.IntervalCases
/-!
# Basic lemmas on prime factorizations
-/
open Finset List Finsupp
namespace Nat
variable {a b m n p : ℕ}
/-! ### Basic facts about factorization -/
/-! ## Lemmas characterising when `n.factorization p = 0` -/
theorem factorization_eq_zero_of_lt {n p : ℕ} (h : n < p) : n.factorization p = 0 :=
Finsupp.not_mem_support_iff.mp (mt le_of_mem_primeFactors (not_le_of_lt h))
@[simp]
theorem factorization_one_right (n : ℕ) : n.factorization 1 = 0 :=
factorization_eq_zero_of_non_prime _ not_prime_one
theorem dvd_of_factorization_pos {n p : ℕ} (hn : n.factorization p ≠ 0) : p ∣ n :=
dvd_of_mem_primeFactorsList <| mem_primeFactors_iff_mem_primeFactorsList.1 <| mem_support_iff.2 hn
theorem factorization_eq_zero_iff_remainder {p r : ℕ} (i : ℕ) (pp : p.Prime) (hr0 : r ≠ 0) :
¬p ∣ r ↔ (p * i + r).factorization p = 0 := by
refine ⟨factorization_eq_zero_of_remainder i, fun h => ?_⟩
rw [factorization_eq_zero_iff] at h
contrapose! h
refine ⟨pp, ?_, ?_⟩
· rwa [← Nat.dvd_add_iff_right (dvd_mul_right p i)]
· contrapose! hr0
exact (add_eq_zero.1 hr0).2
/-- The only numbers with empty prime factorization are `0` and `1` -/
theorem factorization_eq_zero_iff' (n : ℕ) : n.factorization = 0 ↔ n = 0 ∨ n = 1 := by
rw [factorization_eq_primeFactorsList_multiset n]
simp [factorization, AddEquiv.map_eq_zero_iff, Multiset.coe_eq_zero]
/-! ## Lemmas about factorizations of products and powers -/
/-- A product over `n.factorization` can be written as a product over `n.primeFactors`; -/
lemma prod_factorization_eq_prod_primeFactors {β : Type*} [CommMonoid β] (f : ℕ → ℕ → β) :
n.factorization.prod f = ∏ p ∈ n.primeFactors, f p (n.factorization p) := rfl
/-- A product over `n.primeFactors` can be written as a product over `n.factorization`; -/
lemma prod_primeFactors_prod_factorization {β : Type*} [CommMonoid β] (f : ℕ → β) :
∏ p ∈ n.primeFactors, f p = n.factorization.prod (fun p _ ↦ f p) := rfl
/-! ## Lemmas about factorizations of primes and prime powers -/
/-- The multiplicity of prime `p` in `p` is `1` -/
@[simp]
theorem Prime.factorization_self {p : ℕ} (hp : Prime p) : p.factorization p = 1 := by simp [hp]
/-- If the factorization of `n` contains just one number `p` then `n` is a power of `p` -/
theorem eq_pow_of_factorization_eq_single {n p k : ℕ} (hn : n ≠ 0)
(h : n.factorization = Finsupp.single p k) : n = p ^ k := by
rw [← Nat.factorization_prod_pow_eq_self hn, h]
simp
/-- The only prime factor of prime `p` is `p` itself. -/
theorem Prime.eq_of_factorization_pos {p q : ℕ} (hp : Prime p) (h : p.factorization q ≠ 0) :
p = q := by simpa [hp.factorization, single_apply] using h
/-! ### Equivalence between `ℕ+` and `ℕ →₀ ℕ` with support in the primes. -/
theorem eq_factorization_iff {n : ℕ} {f : ℕ →₀ ℕ} (hn : n ≠ 0) (hf : ∀ p ∈ f.support, Prime p) :
f = n.factorization ↔ f.prod (· ^ ·) = n :=
⟨fun h => by rw [h, factorization_prod_pow_eq_self hn], fun h => by
rw [← h, prod_pow_factorization_eq_self hf]⟩
theorem factorizationEquiv_inv_apply {f : ℕ →₀ ℕ} (hf : ∀ p ∈ f.support, Prime p) :
(factorizationEquiv.symm ⟨f, hf⟩).1 = f.prod (· ^ ·) :=
rfl
@[simp]
theorem ordProj_of_not_prime (n p : ℕ) (hp : ¬p.Prime) : ordProj[p] n = 1 := by
simp [factorization_eq_zero_of_non_prime n hp]
@[deprecated (since := "2024-10-24")] alias ord_proj_of_not_prime := ordProj_of_not_prime
@[simp]
theorem ordCompl_of_not_prime (n p : ℕ) (hp : ¬p.Prime) : ordCompl[p] n = n := by
simp [factorization_eq_zero_of_non_prime n hp]
@[deprecated (since := "2024-10-24")] alias ord_compl_of_not_prime := ordCompl_of_not_prime
theorem ordCompl_dvd (n p : ℕ) : ordCompl[p] n ∣ n :=
div_dvd_of_dvd (ordProj_dvd n p)
@[deprecated (since := "2024-10-24")] alias ord_compl_dvd := ordCompl_dvd
theorem ordProj_pos (n p : ℕ) : 0 < ordProj[p] n := by
if pp : p.Prime then simp [pow_pos pp.pos] else simp [pp]
@[deprecated (since := "2024-10-24")] alias ord_proj_pos := ordProj_pos
theorem ordProj_le {n : ℕ} (p : ℕ) (hn : n ≠ 0) : ordProj[p] n ≤ n :=
le_of_dvd hn.bot_lt (Nat.ordProj_dvd n p)
@[deprecated (since := "2024-10-24")] alias ord_proj_le := ordProj_le
theorem ordCompl_pos {n : ℕ} (p : ℕ) (hn : n ≠ 0) : 0 < ordCompl[p] n := by
if pp : p.Prime then
exact Nat.div_pos (ordProj_le p hn) (ordProj_pos n p)
else
simpa [Nat.factorization_eq_zero_of_non_prime n pp] using hn.bot_lt
@[deprecated (since := "2024-10-24")] alias ord_compl_pos := ordCompl_pos
theorem ordCompl_le (n p : ℕ) : ordCompl[p] n ≤ n :=
Nat.div_le_self _ _
@[deprecated (since := "2024-10-24")] alias ord_compl_le := ordCompl_le
theorem ordProj_mul_ordCompl_eq_self (n p : ℕ) : ordProj[p] n * ordCompl[p] n = n :=
Nat.mul_div_cancel' (ordProj_dvd n p)
@[deprecated (since := "2024-10-24")]
alias ord_proj_mul_ord_compl_eq_self := ordProj_mul_ordCompl_eq_self
theorem ordProj_mul {a b : ℕ} (p : ℕ) (ha : a ≠ 0) (hb : b ≠ 0) :
ordProj[p] (a * b) = ordProj[p] a * ordProj[p] b := by
simp [factorization_mul ha hb, pow_add]
@[deprecated (since := "2024-10-24")] alias ord_proj_mul := ordProj_mul
theorem ordCompl_mul (a b p : ℕ) : ordCompl[p] (a * b) = ordCompl[p] a * ordCompl[p] b := by
if ha : a = 0 then simp [ha] else
if hb : b = 0 then simp [hb] else
simp only [ordProj_mul p ha hb]
rw [div_mul_div_comm (ordProj_dvd a p) (ordProj_dvd b p)]
@[deprecated (since := "2024-10-24")] alias ord_compl_mul := ordCompl_mul
/-! ### Factorization and divisibility -/
/-- A crude upper bound on `n.factorization p` -/
theorem factorization_lt {n : ℕ} (p : ℕ) (hn : n ≠ 0) : n.factorization p < n := by
by_cases pp : p.Prime
· exact (Nat.pow_lt_pow_iff_right pp.one_lt).1 <| (ordProj_le p hn).trans_lt <|
Nat.lt_pow_self pp.one_lt
· simpa only [factorization_eq_zero_of_non_prime n pp] using hn.bot_lt
/-- An upper bound on `n.factorization p` -/
theorem factorization_le_of_le_pow {n p b : ℕ} (hb : n ≤ p ^ b) : n.factorization p ≤ b := by
if hn : n = 0 then simp [hn] else
if pp : p.Prime then
exact (Nat.pow_le_pow_iff_right pp.one_lt).1 ((ordProj_le p hn).trans hb)
else
simp [factorization_eq_zero_of_non_prime n pp]
theorem factorization_prime_le_iff_dvd {d n : ℕ} (hd : d ≠ 0) (hn : n ≠ 0) :
(∀ p : ℕ, p.Prime → d.factorization p ≤ n.factorization p) ↔ d ∣ n := by
rw [← factorization_le_iff_dvd hd hn]
refine ⟨fun h p => (em p.Prime).elim (h p) fun hp => ?_, fun h p _ => h p⟩
simp_rw [factorization_eq_zero_of_non_prime _ hp]
rfl
theorem factorization_le_factorization_mul_left {a b : ℕ} (hb : b ≠ 0) :
a.factorization ≤ (a * b).factorization := by
rcases eq_or_ne a 0 with (rfl | ha)
· simp
rw [factorization_le_iff_dvd ha <| mul_ne_zero ha hb]
exact Dvd.intro b rfl
theorem factorization_le_factorization_mul_right {a b : ℕ} (ha : a ≠ 0) :
b.factorization ≤ (a * b).factorization := by
rw [mul_comm]
apply factorization_le_factorization_mul_left ha
theorem Prime.pow_dvd_iff_le_factorization {p k n : ℕ} (pp : Prime p) (hn : n ≠ 0) :
p ^ k ∣ n ↔ k ≤ n.factorization p := by
rw [← factorization_le_iff_dvd (pow_pos pp.pos k).ne' hn, pp.factorization_pow, single_le_iff]
theorem Prime.pow_dvd_iff_dvd_ordProj {p k n : ℕ} (pp : Prime p) (hn : n ≠ 0) :
p ^ k ∣ n ↔ p ^ k ∣ ordProj[p] n := by
rw [pow_dvd_pow_iff_le_right pp.one_lt, pp.pow_dvd_iff_le_factorization hn]
@[deprecated (since := "2024-10-24")]
alias Prime.pow_dvd_iff_dvd_ord_proj := Prime.pow_dvd_iff_dvd_ordProj
theorem Prime.dvd_iff_one_le_factorization {p n : ℕ} (pp : Prime p) (hn : n ≠ 0) :
p ∣ n ↔ 1 ≤ n.factorization p :=
Iff.trans (by simp) (pp.pow_dvd_iff_le_factorization hn)
theorem exists_factorization_lt_of_lt {a b : ℕ} (ha : a ≠ 0) (hab : a < b) :
∃ p : ℕ, a.factorization p < b.factorization p := by
have hb : b ≠ 0 := (ha.bot_lt.trans hab).ne'
contrapose! hab
rw [← Finsupp.le_def, factorization_le_iff_dvd hb ha] at hab
exact le_of_dvd ha.bot_lt hab
@[simp]
theorem factorization_div {d n : ℕ} (h : d ∣ n) :
(n / d).factorization = n.factorization - d.factorization := by
rcases eq_or_ne d 0 with (rfl | hd); · simp [zero_dvd_iff.mp h]
rcases eq_or_ne n 0 with (rfl | hn); · simp [tsub_eq_zero_of_le]
apply add_left_injective d.factorization
simp only
rw [tsub_add_cancel_of_le <| (Nat.factorization_le_iff_dvd hd hn).mpr h, ←
Nat.factorization_mul (Nat.div_pos (Nat.le_of_dvd hn.bot_lt h) hd.bot_lt).ne' hd,
Nat.div_mul_cancel h]
theorem dvd_ordProj_of_dvd {n p : ℕ} (hn : n ≠ 0) (pp : p.Prime) (h : p ∣ n) : p ∣ ordProj[p] n :=
dvd_pow_self p (Prime.factorization_pos_of_dvd pp hn h).ne'
@[deprecated (since := "2024-10-24")] alias dvd_ord_proj_of_dvd := dvd_ordProj_of_dvd
theorem not_dvd_ordCompl {n p : ℕ} (hp : Prime p) (hn : n ≠ 0) : ¬p ∣ ordCompl[p] n := by
rw [Nat.Prime.dvd_iff_one_le_factorization hp (ordCompl_pos p hn).ne']
rw [Nat.factorization_div (Nat.ordProj_dvd n p)]
simp [hp.factorization]
@[deprecated (since := "2024-10-24")] alias not_dvd_ord_compl := not_dvd_ordCompl
theorem coprime_ordCompl {n p : ℕ} (hp : Prime p) (hn : n ≠ 0) : Coprime p (ordCompl[p] n) :=
(or_iff_left (not_dvd_ordCompl hp hn)).mp <| coprime_or_dvd_of_prime hp _
@[deprecated (since := "2024-10-24")] alias coprime_ord_compl := coprime_ordCompl
theorem factorization_ordCompl (n p : ℕ) :
(ordCompl[p] n).factorization = n.factorization.erase p := by
if hn : n = 0 then simp [hn] else
if pp : p.Prime then ?_ else
simp [pp]
ext q
rcases eq_or_ne q p with (rfl | hqp)
· simp only [Finsupp.erase_same, factorization_eq_zero_iff, not_dvd_ordCompl pp hn]
simp
· rw [Finsupp.erase_ne hqp, factorization_div (ordProj_dvd n p)]
simp [pp.factorization, hqp.symm]
@[deprecated (since := "2024-10-24")] alias factorization_ord_compl := factorization_ordCompl
-- `ordCompl[p] n` is the largest divisor of `n` not divisible by `p`.
theorem dvd_ordCompl_of_dvd_not_dvd {p d n : ℕ} (hdn : d ∣ n) (hpd : ¬p ∣ d) :
d ∣ ordCompl[p] n := by
if hn0 : n = 0 then simp [hn0] else
if hd0 : d = 0 then simp [hd0] at hpd else
rw [← factorization_le_iff_dvd hd0 (ordCompl_pos p hn0).ne', factorization_ordCompl]
intro q
if hqp : q = p then
simp [factorization_eq_zero_iff, hqp, hpd]
else
simp [hqp, (factorization_le_iff_dvd hd0 hn0).2 hdn q]
@[deprecated (since := "2024-10-24")]
alias dvd_ord_compl_of_dvd_not_dvd := dvd_ordCompl_of_dvd_not_dvd
/-- If `n` is a nonzero natural number and `p ≠ 1`, then there are natural numbers `e`
and `n'` such that `n'` is not divisible by `p` and `n = p^e * n'`. -/
theorem exists_eq_pow_mul_and_not_dvd {n : ℕ} (hn : n ≠ 0) (p : ℕ) (hp : p ≠ 1) :
∃ e n' : ℕ, ¬p ∣ n' ∧ n = p ^ e * n' :=
let ⟨a', h₁, h₂⟩ :=
(Nat.finiteMultiplicity_iff.mpr ⟨hp, Nat.pos_of_ne_zero hn⟩).exists_eq_pow_mul_and_not_dvd
⟨_, a', h₂, h₁⟩
/-- Any nonzero natural number is the product of an odd part `m` and a power of
two `2 ^ k`. -/
theorem exists_eq_two_pow_mul_odd {n : ℕ} (hn : n ≠ 0) :
∃ k m : ℕ, Odd m ∧ n = 2 ^ k * m :=
let ⟨k, m, hm, hn⟩ := exists_eq_pow_mul_and_not_dvd hn 2 (succ_ne_self 1)
| ⟨k, m, not_even_iff_odd.1 (mt Even.two_dvd hm), hn⟩
theorem dvd_iff_div_factorization_eq_tsub {d n : ℕ} (hd : d ≠ 0) (hdn : d ≤ n) :
d ∣ n ↔ (n / d).factorization = n.factorization - d.factorization := by
refine ⟨factorization_div, ?_⟩
rcases eq_or_lt_of_le hdn with (rfl | hd_lt_n); · simp
have h1 : n / d ≠ 0 := by simp [*]
intro h
rw [dvd_iff_le_div_mul n d]
| Mathlib/Data/Nat/Factorization/Basic.lean | 279 | 287 |
/-
Copyright (c) 2022 Julian Kuelshammer. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Julian Kuelshammer
-/
import Mathlib.Algebra.BigOperators.Fin
import Mathlib.Algebra.BigOperators.NatAntidiagonal
import Mathlib.Data.Nat.Choose.Central
import Mathlib.Tactic.FieldSimp
import Mathlib.Tactic.GCongr
import Mathlib.Tactic.Positivity
/-!
# Catalan numbers
The Catalan numbers (http://oeis.org/A000108) are probably the most ubiquitous sequence of integers
in mathematics. They enumerate several important objects like binary trees, Dyck paths, and
triangulations of convex polygons.
## Main definitions
* `catalan n`: the `n`th Catalan number, defined recursively as
`catalan (n + 1) = ∑ i : Fin n.succ, catalan i * catalan (n - i)`.
## Main results
* `catalan_eq_centralBinom_div`: The explicit formula for the Catalan number using the central
binomial coefficient, `catalan n = Nat.centralBinom n / (n + 1)`.
* `treesOfNumNodesEq_card_eq_catalan`: The number of binary trees with `n` internal nodes
is `catalan n`
## Implementation details
The proof of `catalan_eq_centralBinom_div` follows https://math.stackexchange.com/questions/3304415
## TODO
* Prove that the Catalan numbers enumerate many interesting objects.
* Provide the many variants of Catalan numbers, e.g. associated to complex reflection groups,
Fuss-Catalan, etc.
-/
open Finset
open Finset.antidiagonal (fst_le snd_le)
/-- The recursive definition of the sequence of Catalan numbers:
`catalan (n + 1) = ∑ i : Fin n.succ, catalan i * catalan (n - i)` -/
def catalan : ℕ → ℕ
| 0 => 1
| n + 1 =>
∑ i : Fin n.succ,
catalan i * catalan (n - i)
@[simp]
theorem catalan_zero : catalan 0 = 1 := by rw [catalan]
theorem catalan_succ (n : ℕ) : catalan (n + 1) = ∑ i : Fin n.succ, catalan i * catalan (n - i) := by
rw [catalan]
theorem catalan_succ' (n : ℕ) :
catalan (n + 1) = ∑ ij ∈ antidiagonal n, catalan ij.1 * catalan ij.2 := by
rw [catalan_succ, Nat.sum_antidiagonal_eq_sum_range_succ (fun x y => catalan x * catalan y) n,
sum_range]
@[simp]
theorem catalan_one : catalan 1 = 1 := by simp [catalan_succ]
/-- A helper sequence that can be used to prove the equality of the recursive and the explicit
definition using a telescoping sum argument. -/
private def gosperCatalan (n j : ℕ) : ℚ :=
Nat.centralBinom j * Nat.centralBinom (n - j) * (2 * j - n) / (2 * n * (n + 1))
private theorem gosper_trick {n i : ℕ} (h : i ≤ n) :
gosperCatalan (n + 1) (i + 1) - gosperCatalan (n + 1) i =
Nat.centralBinom i / (i + 1) * Nat.centralBinom (n - i) / (n - i + 1) := by
have l₁ : (i : ℚ) + 1 ≠ 0 := by norm_cast
have l₂ : (n : ℚ) - i + 1 ≠ 0 := by norm_cast
have h₁ := (mul_div_cancel_left₀ (↑(Nat.centralBinom (i + 1))) l₁).symm
have h₂ := (mul_div_cancel_left₀ (↑(Nat.centralBinom (n - i + 1))) l₂).symm
have h₃ : ((i : ℚ) + 1) * (i + 1).centralBinom = 2 * (2 * i + 1) * i.centralBinom :=
mod_cast Nat.succ_mul_centralBinom_succ i
have h₄ :
((n : ℚ) - i + 1) * (n - i + 1).centralBinom = 2 * (2 * (n - i) + 1) * (n - i).centralBinom :=
mod_cast Nat.succ_mul_centralBinom_succ (n - i)
simp only [gosperCatalan]
push_cast
rw [show n + 1 - i = n - i + 1 by rw [Nat.add_comm (n - i) 1, ← (Nat.add_sub_assoc h 1),
add_comm]]
rw [h₁, h₂, h₃, h₄]
field_simp
ring
private theorem gosper_catalan_sub_eq_central_binom_div (n : ℕ) : gosperCatalan (n + 1) (n + 1) -
gosperCatalan (n + 1) 0 = Nat.centralBinom (n + 1) / (n + 2) := by
have : (n : ℚ) + 1 ≠ 0 := by norm_cast
have : (n : ℚ) + 1 + 1 ≠ 0 := by norm_cast
have h : (n : ℚ) + 2 ≠ 0 := by norm_cast
simp only [gosperCatalan, Nat.sub_zero, Nat.centralBinom_zero, Nat.sub_self]
field_simp
ring
theorem catalan_eq_centralBinom_div (n : ℕ) : catalan n = n.centralBinom / (n + 1) := by
suffices (catalan n : ℚ) = Nat.centralBinom n / (n + 1) by
have h := Nat.succ_dvd_centralBinom n
exact mod_cast this
induction n using Nat.caseStrongRecOn with
| zero => simp
| ind d hd =>
simp_rw [catalan_succ, Nat.cast_sum, Nat.cast_mul]
trans (∑ i : Fin d.succ, Nat.centralBinom i / (i + 1) *
(Nat.centralBinom (d - i) / (d - i + 1)) : ℚ)
· congr
ext1 x
have m_le_d : x.val ≤ d := by omega
have d_minus_x_le_d : (d - x.val) ≤ d := tsub_le_self
rw [hd _ m_le_d, hd _ d_minus_x_le_d]
norm_cast
· trans (∑ i : Fin d.succ, (gosperCatalan (d + 1) (i + 1) - gosperCatalan (d + 1) i))
· refine sum_congr rfl fun i _ => ?_
rw [gosper_trick i.is_le, mul_div]
· rw [← sum_range fun i => gosperCatalan (d + 1) (i + 1) - gosperCatalan (d + 1) i,
sum_range_sub, Nat.succ_eq_add_one]
rw [gosper_catalan_sub_eq_central_binom_div d]
norm_cast
theorem succ_mul_catalan_eq_centralBinom (n : ℕ) : (n + 1) * catalan n = n.centralBinom :=
(Nat.eq_mul_of_div_eq_right n.succ_dvd_centralBinom (catalan_eq_centralBinom_div n).symm).symm
theorem catalan_two : catalan 2 = 2 := by
norm_num [catalan_eq_centralBinom_div, Nat.centralBinom, Nat.choose]
theorem catalan_three : catalan 3 = 5 := by
norm_num [catalan_eq_centralBinom_div, Nat.centralBinom, Nat.choose]
namespace Tree
/-- Given two finsets, find all trees that can be formed with
left child in `a` and right child in `b` -/
abbrev pairwiseNode (a b : Finset (Tree Unit)) : Finset (Tree Unit) :=
(a ×ˢ b).map ⟨fun x => x.1 △ x.2, fun ⟨x₁, x₂⟩ ⟨y₁, y₂⟩ => fun h => by simpa using h⟩
/-- A Finset of all trees with `n` nodes. See `mem_treesOfNodesEq` -/
def treesOfNumNodesEq : ℕ → Finset (Tree Unit)
| | 0 => {nil}
| n + 1 =>
| Mathlib/Combinatorics/Enumerative/Catalan.lean | 148 | 149 |
/-
Copyright (c) 2018 Michael Jendrusch. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Michael Jendrusch, Kim Morrison, Bhavik Mehta, Jakob von Raumer
-/
import Mathlib.CategoryTheory.EqToHom
import Mathlib.CategoryTheory.Functor.Trifunctor
import Mathlib.CategoryTheory.Products.Basic
/-!
# Monoidal categories
A monoidal category is a category equipped with a tensor product, unitors, and an associator.
In the definition, we provide the tensor product as a pair of functions
* `tensorObj : C → C → C`
* `tensorHom : (X₁ ⟶ Y₁) → (X₂ ⟶ Y₂) → ((X₁ ⊗ X₂) ⟶ (Y₁ ⊗ Y₂))`
and allow use of the overloaded notation `⊗` for both.
The unitors and associator are provided componentwise.
The tensor product can be expressed as a functor via `tensor : C × C ⥤ C`.
The unitors and associator are gathered together as natural
isomorphisms in `leftUnitor_nat_iso`, `rightUnitor_nat_iso` and `associator_nat_iso`.
Some consequences of the definition are proved in other files after proving the coherence theorem,
e.g. `(λ_ (𝟙_ C)).hom = (ρ_ (𝟙_ C)).hom` in `CategoryTheory.Monoidal.CoherenceLemmas`.
## Implementation notes
In the definition of monoidal categories, we also provide the whiskering operators:
* `whiskerLeft (X : C) {Y₁ Y₂ : C} (f : Y₁ ⟶ Y₂) : X ⊗ Y₁ ⟶ X ⊗ Y₂`, denoted by `X ◁ f`,
* `whiskerRight {X₁ X₂ : C} (f : X₁ ⟶ X₂) (Y : C) : X₁ ⊗ Y ⟶ X₂ ⊗ Y`, denoted by `f ▷ Y`.
These are products of an object and a morphism (the terminology "whiskering"
is borrowed from 2-category theory). The tensor product of morphisms `tensorHom` can be defined
in terms of the whiskerings. There are two possible such definitions, which are related by
the exchange property of the whiskerings. These two definitions are accessed by `tensorHom_def`
and `tensorHom_def'`. By default, `tensorHom` is defined so that `tensorHom_def` holds
definitionally.
If you want to provide `tensorHom` and define `whiskerLeft` and `whiskerRight` in terms of it,
you can use the alternative constructor `CategoryTheory.MonoidalCategory.ofTensorHom`.
The whiskerings are useful when considering simp-normal forms of morphisms in monoidal categories.
### Simp-normal form for morphisms
Rewriting involving associators and unitors could be very complicated. We try to ease this
complexity by putting carefully chosen simp lemmas that rewrite any morphisms into the simp-normal
form defined below. Rewriting into simp-normal form is especially useful in preprocessing
performed by the `coherence` tactic.
The simp-normal form of morphisms is defined to be an expression that has the minimal number of
parentheses. More precisely,
1. it is a composition of morphisms like `f₁ ≫ f₂ ≫ f₃ ≫ f₄ ≫ f₅` such that each `fᵢ` is
either a structural morphisms (morphisms made up only of identities, associators, unitors)
or non-structural morphisms, and
2. each non-structural morphism in the composition is of the form `X₁ ◁ X₂ ◁ X₃ ◁ f ▷ X₄ ▷ X₅`,
where each `Xᵢ` is a object that is not the identity or a tensor and `f` is a non-structural
morphisms that is not the identity or a composite.
Note that `X₁ ◁ X₂ ◁ X₃ ◁ f ▷ X₄ ▷ X₅` is actually `X₁ ◁ (X₂ ◁ (X₃ ◁ ((f ▷ X₄) ▷ X₅)))`.
Currently, the simp lemmas don't rewrite `𝟙 X ⊗ f` and `f ⊗ 𝟙 Y` into `X ◁ f` and `f ▷ Y`,
respectively, since it requires a huge refactoring. We hope to add these simp lemmas soon.
## References
* Tensor categories, Etingof, Gelaki, Nikshych, Ostrik,
http://www-math.mit.edu/~etingof/egnobookfinal.pdf
* <https://stacks.math.columbia.edu/tag/0FFK>.
-/
universe v u
open CategoryTheory.Category
open CategoryTheory.Iso
namespace CategoryTheory
/-- Auxiliary structure to carry only the data fields of (and provide notation for)
`MonoidalCategory`. -/
class MonoidalCategoryStruct (C : Type u) [𝒞 : Category.{v} C] where
/-- curried tensor product of objects -/
tensorObj : C → C → C
/-- left whiskering for morphisms -/
whiskerLeft (X : C) {Y₁ Y₂ : C} (f : Y₁ ⟶ Y₂) : tensorObj X Y₁ ⟶ tensorObj X Y₂
/-- right whiskering for morphisms -/
whiskerRight {X₁ X₂ : C} (f : X₁ ⟶ X₂) (Y : C) : tensorObj X₁ Y ⟶ tensorObj X₂ Y
/-- Tensor product of identity maps is the identity: `(𝟙 X₁ ⊗ 𝟙 X₂) = 𝟙 (X₁ ⊗ X₂)` -/
-- By default, it is defined in terms of whiskerings.
tensorHom {X₁ Y₁ X₂ Y₂ : C} (f : X₁ ⟶ Y₁) (g : X₂ ⟶ Y₂) : (tensorObj X₁ X₂ ⟶ tensorObj Y₁ Y₂) :=
whiskerRight f X₂ ≫ whiskerLeft Y₁ g
/-- The tensor unity in the monoidal structure `𝟙_ C` -/
tensorUnit (C) : C
/-- The associator isomorphism `(X ⊗ Y) ⊗ Z ≃ X ⊗ (Y ⊗ Z)` -/
associator : ∀ X Y Z : C, tensorObj (tensorObj X Y) Z ≅ tensorObj X (tensorObj Y Z)
/-- The left unitor: `𝟙_ C ⊗ X ≃ X` -/
leftUnitor : ∀ X : C, tensorObj tensorUnit X ≅ X
/-- The right unitor: `X ⊗ 𝟙_ C ≃ X` -/
rightUnitor : ∀ X : C, tensorObj X tensorUnit ≅ X
namespace MonoidalCategory
export MonoidalCategoryStruct
(tensorObj whiskerLeft whiskerRight tensorHom tensorUnit associator leftUnitor rightUnitor)
end MonoidalCategory
namespace MonoidalCategory
/-- Notation for `tensorObj`, the tensor product of objects in a monoidal category -/
scoped infixr:70 " ⊗ " => MonoidalCategoryStruct.tensorObj
/-- Notation for the `whiskerLeft` operator of monoidal categories -/
scoped infixr:81 " ◁ " => MonoidalCategoryStruct.whiskerLeft
/-- Notation for the `whiskerRight` operator of monoidal categories -/
scoped infixl:81 " ▷ " => MonoidalCategoryStruct.whiskerRight
/-- Notation for `tensorHom`, the tensor product of morphisms in a monoidal category -/
scoped infixr:70 " ⊗ " => MonoidalCategoryStruct.tensorHom
/-- Notation for `tensorUnit`, the two-sided identity of `⊗` -/
scoped notation "𝟙_ " C:arg => MonoidalCategoryStruct.tensorUnit C
/-- Notation for the monoidal `associator`: `(X ⊗ Y) ⊗ Z ≃ X ⊗ (Y ⊗ Z)` -/
scoped notation "α_" => MonoidalCategoryStruct.associator
/-- Notation for the `leftUnitor`: `𝟙_C ⊗ X ≃ X` -/
scoped notation "λ_" => MonoidalCategoryStruct.leftUnitor
/-- Notation for the `rightUnitor`: `X ⊗ 𝟙_C ≃ X` -/
scoped notation "ρ_" => MonoidalCategoryStruct.rightUnitor
/-- The property that the pentagon relation is satisfied by four objects
in a category equipped with a `MonoidalCategoryStruct`. -/
def Pentagon {C : Type u} [Category.{v} C] [MonoidalCategoryStruct C]
(Y₁ Y₂ Y₃ Y₄ : C) : Prop :=
(α_ Y₁ Y₂ Y₃).hom ▷ Y₄ ≫ (α_ Y₁ (Y₂ ⊗ Y₃) Y₄).hom ≫ Y₁ ◁ (α_ Y₂ Y₃ Y₄).hom =
(α_ (Y₁ ⊗ Y₂) Y₃ Y₄).hom ≫ (α_ Y₁ Y₂ (Y₃ ⊗ Y₄)).hom
end MonoidalCategory
open MonoidalCategory
/--
In a monoidal category, we can take the tensor product of objects, `X ⊗ Y` and of morphisms `f ⊗ g`.
Tensor product does not need to be strictly associative on objects, but there is a
specified associator, `α_ X Y Z : (X ⊗ Y) ⊗ Z ≅ X ⊗ (Y ⊗ Z)`. There is a tensor unit `𝟙_ C`,
with specified left and right unitor isomorphisms `λ_ X : 𝟙_ C ⊗ X ≅ X` and `ρ_ X : X ⊗ 𝟙_ C ≅ X`.
These associators and unitors satisfy the pentagon and triangle equations. -/
@[stacks 0FFK]
-- Porting note: The Mathport did not translate the temporary notation
class MonoidalCategory (C : Type u) [𝒞 : Category.{v} C] extends MonoidalCategoryStruct C where
tensorHom_def {X₁ Y₁ X₂ Y₂ : C} (f : X₁ ⟶ Y₁) (g : X₂ ⟶ Y₂) :
f ⊗ g = (f ▷ X₂) ≫ (Y₁ ◁ g) := by
aesop_cat
/-- Tensor product of identity maps is the identity: `(𝟙 X₁ ⊗ 𝟙 X₂) = 𝟙 (X₁ ⊗ X₂)` -/
tensor_id : ∀ X₁ X₂ : C, 𝟙 X₁ ⊗ 𝟙 X₂ = 𝟙 (X₁ ⊗ X₂) := by aesop_cat
/--
Tensor product of compositions is composition of tensor products:
`(f₁ ≫ g₁) ⊗ (f₂ ≫ g₂) = (f₁ ⊗ f₂) ≫ (g₁ ⊗ g₂)`
-/
tensor_comp :
∀ {X₁ Y₁ Z₁ X₂ Y₂ Z₂ : C} (f₁ : X₁ ⟶ Y₁) (f₂ : X₂ ⟶ Y₂) (g₁ : Y₁ ⟶ Z₁) (g₂ : Y₂ ⟶ Z₂),
(f₁ ≫ g₁) ⊗ (f₂ ≫ g₂) = (f₁ ⊗ f₂) ≫ (g₁ ⊗ g₂) := by
aesop_cat
whiskerLeft_id : ∀ (X Y : C), X ◁ 𝟙 Y = 𝟙 (X ⊗ Y) := by
aesop_cat
id_whiskerRight : ∀ (X Y : C), 𝟙 X ▷ Y = 𝟙 (X ⊗ Y) := by
aesop_cat
/-- Naturality of the associator isomorphism: `(f₁ ⊗ f₂) ⊗ f₃ ≃ f₁ ⊗ (f₂ ⊗ f₃)` -/
associator_naturality :
∀ {X₁ X₂ X₃ Y₁ Y₂ Y₃ : C} (f₁ : X₁ ⟶ Y₁) (f₂ : X₂ ⟶ Y₂) (f₃ : X₃ ⟶ Y₃),
((f₁ ⊗ f₂) ⊗ f₃) ≫ (α_ Y₁ Y₂ Y₃).hom = (α_ X₁ X₂ X₃).hom ≫ (f₁ ⊗ (f₂ ⊗ f₃)) := by
aesop_cat
/--
Naturality of the left unitor, commutativity of `𝟙_ C ⊗ X ⟶ 𝟙_ C ⊗ Y ⟶ Y` and `𝟙_ C ⊗ X ⟶ X ⟶ Y`
-/
leftUnitor_naturality :
∀ {X Y : C} (f : X ⟶ Y), 𝟙_ _ ◁ f ≫ (λ_ Y).hom = (λ_ X).hom ≫ f := by
aesop_cat
/--
Naturality of the right unitor: commutativity of `X ⊗ 𝟙_ C ⟶ Y ⊗ 𝟙_ C ⟶ Y` and `X ⊗ 𝟙_ C ⟶ X ⟶ Y`
-/
rightUnitor_naturality :
∀ {X Y : C} (f : X ⟶ Y), f ▷ 𝟙_ _ ≫ (ρ_ Y).hom = (ρ_ X).hom ≫ f := by
aesop_cat
/--
The pentagon identity relating the isomorphism between `X ⊗ (Y ⊗ (Z ⊗ W))` and `((X ⊗ Y) ⊗ Z) ⊗ W`
-/
pentagon :
∀ W X Y Z : C,
(α_ W X Y).hom ▷ Z ≫ (α_ W (X ⊗ Y) Z).hom ≫ W ◁ (α_ X Y Z).hom =
(α_ (W ⊗ X) Y Z).hom ≫ (α_ W X (Y ⊗ Z)).hom := by
aesop_cat
/--
The identity relating the isomorphisms between `X ⊗ (𝟙_ C ⊗ Y)`, `(X ⊗ 𝟙_ C) ⊗ Y` and `X ⊗ Y`
-/
triangle :
∀ X Y : C, (α_ X (𝟙_ _) Y).hom ≫ X ◁ (λ_ Y).hom = (ρ_ X).hom ▷ Y := by
aesop_cat
attribute [reassoc] MonoidalCategory.tensorHom_def
attribute [reassoc, simp] MonoidalCategory.whiskerLeft_id
attribute [reassoc, simp] MonoidalCategory.id_whiskerRight
attribute [reassoc] MonoidalCategory.tensor_comp
attribute [simp] MonoidalCategory.tensor_comp
attribute [reassoc] MonoidalCategory.associator_naturality
attribute [reassoc] MonoidalCategory.leftUnitor_naturality
attribute [reassoc] MonoidalCategory.rightUnitor_naturality
attribute [reassoc (attr := simp)] MonoidalCategory.pentagon
attribute [reassoc (attr := simp)] MonoidalCategory.triangle
namespace MonoidalCategory
variable {C : Type u} [𝒞 : Category.{v} C] [MonoidalCategory C]
@[simp]
theorem id_tensorHom (X : C) {Y₁ Y₂ : C} (f : Y₁ ⟶ Y₂) :
𝟙 X ⊗ f = X ◁ f := by
simp [tensorHom_def]
@[simp]
theorem tensorHom_id {X₁ X₂ : C} (f : X₁ ⟶ X₂) (Y : C) :
f ⊗ 𝟙 Y = f ▷ Y := by
simp [tensorHom_def]
@[reassoc, simp]
theorem whiskerLeft_comp (W : C) {X Y Z : C} (f : X ⟶ Y) (g : Y ⟶ Z) :
W ◁ (f ≫ g) = W ◁ f ≫ W ◁ g := by
simp only [← id_tensorHom, ← tensor_comp, comp_id]
@[reassoc, simp]
theorem id_whiskerLeft {X Y : C} (f : X ⟶ Y) :
𝟙_ C ◁ f = (λ_ X).hom ≫ f ≫ (λ_ Y).inv := by
rw [← assoc, ← leftUnitor_naturality]; simp [id_tensorHom]
@[reassoc, simp]
theorem tensor_whiskerLeft (X Y : C) {Z Z' : C} (f : Z ⟶ Z') :
(X ⊗ Y) ◁ f = (α_ X Y Z).hom ≫ X ◁ Y ◁ f ≫ (α_ X Y Z').inv := by
simp only [← id_tensorHom, ← tensorHom_id]
rw [← assoc, ← associator_naturality]
simp
@[reassoc, simp]
theorem comp_whiskerRight {W X Y : C} (f : W ⟶ X) (g : X ⟶ Y) (Z : C) :
(f ≫ g) ▷ Z = f ▷ Z ≫ g ▷ Z := by
simp only [← tensorHom_id, ← tensor_comp, id_comp]
@[reassoc, simp]
theorem whiskerRight_id {X Y : C} (f : X ⟶ Y) :
f ▷ 𝟙_ C = (ρ_ X).hom ≫ f ≫ (ρ_ Y).inv := by
rw [← assoc, ← rightUnitor_naturality]; simp [tensorHom_id]
@[reassoc, simp]
theorem whiskerRight_tensor {X X' : C} (f : X ⟶ X') (Y Z : C) :
f ▷ (Y ⊗ Z) = (α_ X Y Z).inv ≫ f ▷ Y ▷ Z ≫ (α_ X' Y Z).hom := by
simp only [← id_tensorHom, ← tensorHom_id]
rw [associator_naturality]
simp [tensor_id]
@[reassoc, simp]
theorem whisker_assoc (X : C) {Y Y' : C} (f : Y ⟶ Y') (Z : C) :
(X ◁ f) ▷ Z = (α_ X Y Z).hom ≫ X ◁ f ▷ Z ≫ (α_ X Y' Z).inv := by
simp only [← id_tensorHom, ← tensorHom_id]
rw [← assoc, ← associator_naturality]
simp
@[reassoc]
theorem whisker_exchange {W X Y Z : C} (f : W ⟶ X) (g : Y ⟶ Z) :
W ◁ g ≫ f ▷ Z = f ▷ Y ≫ X ◁ g := by
simp only [← id_tensorHom, ← tensorHom_id, ← tensor_comp, id_comp, comp_id]
@[reassoc]
theorem tensorHom_def' {X₁ Y₁ X₂ Y₂ : C} (f : X₁ ⟶ Y₁) (g : X₂ ⟶ Y₂) :
f ⊗ g = X₁ ◁ g ≫ f ▷ Y₂ :=
whisker_exchange f g ▸ tensorHom_def f g
@[reassoc (attr := simp)]
theorem whiskerLeft_hom_inv (X : C) {Y Z : C} (f : Y ≅ Z) :
X ◁ f.hom ≫ X ◁ f.inv = 𝟙 (X ⊗ Y) := by
rw [← whiskerLeft_comp, hom_inv_id, whiskerLeft_id]
@[reassoc (attr := simp)]
theorem hom_inv_whiskerRight {X Y : C} (f : X ≅ Y) (Z : C) :
f.hom ▷ Z ≫ f.inv ▷ Z = 𝟙 (X ⊗ Z) := by
rw [← comp_whiskerRight, hom_inv_id, id_whiskerRight]
@[reassoc (attr := simp)]
theorem whiskerLeft_inv_hom (X : C) {Y Z : C} (f : Y ≅ Z) :
X ◁ f.inv ≫ X ◁ f.hom = 𝟙 (X ⊗ Z) := by
rw [← whiskerLeft_comp, inv_hom_id, whiskerLeft_id]
@[reassoc (attr := simp)]
theorem inv_hom_whiskerRight {X Y : C} (f : X ≅ Y) (Z : C) :
f.inv ▷ Z ≫ f.hom ▷ Z = 𝟙 (Y ⊗ Z) := by
rw [← comp_whiskerRight, inv_hom_id, id_whiskerRight]
@[reassoc (attr := simp)]
theorem whiskerLeft_hom_inv' (X : C) {Y Z : C} (f : Y ⟶ Z) [IsIso f] :
X ◁ f ≫ X ◁ inv f = 𝟙 (X ⊗ Y) := by
rw [← whiskerLeft_comp, IsIso.hom_inv_id, whiskerLeft_id]
@[reassoc (attr := simp)]
theorem hom_inv_whiskerRight' {X Y : C} (f : X ⟶ Y) [IsIso f] (Z : C) :
f ▷ Z ≫ inv f ▷ Z = 𝟙 (X ⊗ Z) := by
rw [← comp_whiskerRight, IsIso.hom_inv_id, id_whiskerRight]
@[reassoc (attr := simp)]
theorem whiskerLeft_inv_hom' (X : C) {Y Z : C} (f : Y ⟶ Z) [IsIso f] :
X ◁ inv f ≫ X ◁ f = 𝟙 (X ⊗ Z) := by
rw [← whiskerLeft_comp, IsIso.inv_hom_id, whiskerLeft_id]
@[reassoc (attr := simp)]
theorem inv_hom_whiskerRight' {X Y : C} (f : X ⟶ Y) [IsIso f] (Z : C) :
inv f ▷ Z ≫ f ▷ Z = 𝟙 (Y ⊗ Z) := by
rw [← comp_whiskerRight, IsIso.inv_hom_id, id_whiskerRight]
/-- The left whiskering of an isomorphism is an isomorphism. -/
@[simps]
def whiskerLeftIso (X : C) {Y Z : C} (f : Y ≅ Z) : X ⊗ Y ≅ X ⊗ Z where
hom := X ◁ f.hom
inv := X ◁ f.inv
instance whiskerLeft_isIso (X : C) {Y Z : C} (f : Y ⟶ Z) [IsIso f] : IsIso (X ◁ f) :=
(whiskerLeftIso X (asIso f)).isIso_hom
@[simp]
theorem inv_whiskerLeft (X : C) {Y Z : C} (f : Y ⟶ Z) [IsIso f] :
inv (X ◁ f) = X ◁ inv f := by
aesop_cat
@[simp]
lemma whiskerLeftIso_refl (W X : C) :
whiskerLeftIso W (Iso.refl X) = Iso.refl (W ⊗ X) :=
Iso.ext (whiskerLeft_id W X)
@[simp]
lemma whiskerLeftIso_trans (W : C) {X Y Z : C} (f : X ≅ Y) (g : Y ≅ Z) :
whiskerLeftIso W (f ≪≫ g) = whiskerLeftIso W f ≪≫ whiskerLeftIso W g :=
Iso.ext (whiskerLeft_comp W f.hom g.hom)
@[simp]
lemma whiskerLeftIso_symm (W : C) {X Y : C} (f : X ≅ Y) :
(whiskerLeftIso W f).symm = whiskerLeftIso W f.symm := rfl
/-- The right whiskering of an isomorphism is an isomorphism. -/
@[simps!]
def whiskerRightIso {X Y : C} (f : X ≅ Y) (Z : C) : X ⊗ Z ≅ Y ⊗ Z where
hom := f.hom ▷ Z
inv := f.inv ▷ Z
instance whiskerRight_isIso {X Y : C} (f : X ⟶ Y) (Z : C) [IsIso f] : IsIso (f ▷ Z) :=
(whiskerRightIso (asIso f) Z).isIso_hom
@[simp]
theorem inv_whiskerRight {X Y : C} (f : X ⟶ Y) (Z : C) [IsIso f] :
inv (f ▷ Z) = inv f ▷ Z := by
aesop_cat
@[simp]
lemma whiskerRightIso_refl (X W : C) :
whiskerRightIso (Iso.refl X) W = Iso.refl (X ⊗ W) :=
Iso.ext (id_whiskerRight X W)
@[simp]
lemma whiskerRightIso_trans {X Y Z : C} (f : X ≅ Y) (g : Y ≅ Z) (W : C) :
whiskerRightIso (f ≪≫ g) W = whiskerRightIso f W ≪≫ whiskerRightIso g W :=
Iso.ext (comp_whiskerRight f.hom g.hom W)
@[simp]
lemma whiskerRightIso_symm {X Y : C} (f : X ≅ Y) (W : C) :
(whiskerRightIso f W).symm = whiskerRightIso f.symm W := rfl
/-- The tensor product of two isomorphisms is an isomorphism. -/
@[simps]
def tensorIso {X Y X' Y' : C} (f : X ≅ Y)
(g : X' ≅ Y') : X ⊗ X' ≅ Y ⊗ Y' where
hom := f.hom ⊗ g.hom
inv := f.inv ⊗ g.inv
hom_inv_id := by rw [← tensor_comp, Iso.hom_inv_id, Iso.hom_inv_id, ← tensor_id]
inv_hom_id := by rw [← tensor_comp, Iso.inv_hom_id, Iso.inv_hom_id, ← tensor_id]
/-- Notation for `tensorIso`, the tensor product of isomorphisms -/
scoped infixr:70 " ⊗ " => tensorIso
theorem tensorIso_def {X Y X' Y' : C} (f : X ≅ Y) (g : X' ≅ Y') :
f ⊗ g = whiskerRightIso f X' ≪≫ whiskerLeftIso Y g :=
Iso.ext (tensorHom_def f.hom g.hom)
theorem tensorIso_def' {X Y X' Y' : C} (f : X ≅ Y) (g : X' ≅ Y') :
f ⊗ g = whiskerLeftIso X g ≪≫ whiskerRightIso f Y' :=
Iso.ext (tensorHom_def' f.hom g.hom)
instance tensor_isIso {W X Y Z : C} (f : W ⟶ X) [IsIso f] (g : Y ⟶ Z) [IsIso g] : IsIso (f ⊗ g) :=
(asIso f ⊗ asIso g).isIso_hom
@[simp]
theorem inv_tensor {W X Y Z : C} (f : W ⟶ X) [IsIso f] (g : Y ⟶ Z) [IsIso g] :
inv (f ⊗ g) = inv f ⊗ inv g := by
simp [tensorHom_def ,whisker_exchange]
variable {W X Y Z : C}
theorem whiskerLeft_dite {P : Prop} [Decidable P]
(X : C) {Y Z : C} (f : P → (Y ⟶ Z)) (f' : ¬P → (Y ⟶ Z)) :
X ◁ (if h : P then f h else f' h) = if h : P then X ◁ f h else X ◁ f' h := by
split_ifs <;> rfl
theorem dite_whiskerRight {P : Prop} [Decidable P]
{X Y : C} (f : P → (X ⟶ Y)) (f' : ¬P → (X ⟶ Y)) (Z : C) :
(if h : P then f h else f' h) ▷ Z = if h : P then f h ▷ Z else f' h ▷ Z := by
split_ifs <;> rfl
theorem tensor_dite {P : Prop} [Decidable P] {W X Y Z : C} (f : W ⟶ X) (g : P → (Y ⟶ Z))
(g' : ¬P → (Y ⟶ Z)) : (f ⊗ if h : P then g h else g' h) =
if h : P then f ⊗ g h else f ⊗ g' h := by split_ifs <;> rfl
theorem dite_tensor {P : Prop} [Decidable P] {W X Y Z : C} (f : W ⟶ X) (g : P → (Y ⟶ Z))
(g' : ¬P → (Y ⟶ Z)) : (if h : P then g h else g' h) ⊗ f =
if h : P then g h ⊗ f else g' h ⊗ f := by split_ifs <;> rfl
@[simp]
theorem whiskerLeft_eqToHom (X : C) {Y Z : C} (f : Y = Z) :
X ◁ eqToHom f = eqToHom (congr_arg₂ tensorObj rfl f) := by
cases f
simp only [whiskerLeft_id, eqToHom_refl]
@[simp]
theorem eqToHom_whiskerRight {X Y : C} (f : X = Y) (Z : C) :
eqToHom f ▷ Z = eqToHom (congr_arg₂ tensorObj f rfl) := by
cases f
simp only [id_whiskerRight, eqToHom_refl]
@[reassoc]
theorem associator_naturality_left {X X' : C} (f : X ⟶ X') (Y Z : C) :
f ▷ Y ▷ Z ≫ (α_ X' Y Z).hom = (α_ X Y Z).hom ≫ f ▷ (Y ⊗ Z) := by simp
@[reassoc]
theorem associator_inv_naturality_left {X X' : C} (f : X ⟶ X') (Y Z : C) :
f ▷ (Y ⊗ Z) ≫ (α_ X' Y Z).inv = (α_ X Y Z).inv ≫ f ▷ Y ▷ Z := by simp
@[reassoc]
theorem whiskerRight_tensor_symm {X X' : C} (f : X ⟶ X') (Y Z : C) :
f ▷ Y ▷ Z = (α_ X Y Z).hom ≫ f ▷ (Y ⊗ Z) ≫ (α_ X' Y Z).inv := by simp
@[reassoc]
theorem associator_naturality_middle (X : C) {Y Y' : C} (f : Y ⟶ Y') (Z : C) :
(X ◁ f) ▷ Z ≫ (α_ X Y' Z).hom = (α_ X Y Z).hom ≫ X ◁ f ▷ Z := by simp
@[reassoc]
theorem associator_inv_naturality_middle (X : C) {Y Y' : C} (f : Y ⟶ Y') (Z : C) :
X ◁ f ▷ Z ≫ (α_ X Y' Z).inv = (α_ X Y Z).inv ≫ (X ◁ f) ▷ Z := by simp
@[reassoc]
theorem whisker_assoc_symm (X : C) {Y Y' : C} (f : Y ⟶ Y') (Z : C) :
X ◁ f ▷ Z = (α_ X Y Z).inv ≫ (X ◁ f) ▷ Z ≫ (α_ X Y' Z).hom := by simp
@[reassoc]
theorem associator_naturality_right (X Y : C) {Z Z' : C} (f : Z ⟶ Z') :
(X ⊗ Y) ◁ f ≫ (α_ X Y Z').hom = (α_ X Y Z).hom ≫ X ◁ Y ◁ f := by simp
@[reassoc]
theorem associator_inv_naturality_right (X Y : C) {Z Z' : C} (f : Z ⟶ Z') :
X ◁ Y ◁ f ≫ (α_ X Y Z').inv = (α_ X Y Z).inv ≫ (X ⊗ Y) ◁ f := by simp
@[reassoc]
theorem tensor_whiskerLeft_symm (X Y : C) {Z Z' : C} (f : Z ⟶ Z') :
X ◁ Y ◁ f = (α_ X Y Z).inv ≫ (X ⊗ Y) ◁ f ≫ (α_ X Y Z').hom := by simp
@[reassoc]
theorem leftUnitor_inv_naturality {X Y : C} (f : X ⟶ Y) :
f ≫ (λ_ Y).inv = (λ_ X).inv ≫ _ ◁ f := by simp
@[reassoc]
theorem id_whiskerLeft_symm {X X' : C} (f : X ⟶ X') :
f = (λ_ X).inv ≫ 𝟙_ C ◁ f ≫ (λ_ X').hom := by
simp only [id_whiskerLeft, assoc, inv_hom_id, comp_id, inv_hom_id_assoc]
@[reassoc]
theorem rightUnitor_inv_naturality {X X' : C} (f : X ⟶ X') :
f ≫ (ρ_ X').inv = (ρ_ X).inv ≫ f ▷ _ := by simp
@[reassoc]
theorem whiskerRight_id_symm {X Y : C} (f : X ⟶ Y) :
f = (ρ_ X).inv ≫ f ▷ 𝟙_ C ≫ (ρ_ Y).hom := by
simp
theorem whiskerLeft_iff {X Y : C} (f g : X ⟶ Y) : 𝟙_ C ◁ f = 𝟙_ C ◁ g ↔ f = g := by simp
theorem whiskerRight_iff {X Y : C} (f g : X ⟶ Y) : f ▷ 𝟙_ C = g ▷ 𝟙_ C ↔ f = g := by simp
/-! The lemmas in the next section are true by coherence,
but we prove them directly as they are used in proving the coherence theorem. -/
section
@[reassoc (attr := simp)]
theorem pentagon_inv :
W ◁ (α_ X Y Z).inv ≫ (α_ W (X ⊗ Y) Z).inv ≫ (α_ W X Y).inv ▷ Z =
(α_ W X (Y ⊗ Z)).inv ≫ (α_ (W ⊗ X) Y Z).inv :=
eq_of_inv_eq_inv (by simp)
@[reassoc (attr := simp)]
theorem pentagon_inv_inv_hom_hom_inv :
(α_ W (X ⊗ Y) Z).inv ≫ (α_ W X Y).inv ▷ Z ≫ (α_ (W ⊗ X) Y Z).hom =
W ◁ (α_ X Y Z).hom ≫ (α_ W X (Y ⊗ Z)).inv := by
rw [← cancel_epi (W ◁ (α_ X Y Z).inv), ← cancel_mono (α_ (W ⊗ X) Y Z).inv]
simp
@[reassoc (attr := simp)]
theorem pentagon_inv_hom_hom_hom_inv :
(α_ (W ⊗ X) Y Z).inv ≫ (α_ W X Y).hom ▷ Z ≫ (α_ W (X ⊗ Y) Z).hom =
(α_ W X (Y ⊗ Z)).hom ≫ W ◁ (α_ X Y Z).inv :=
eq_of_inv_eq_inv (by simp)
@[reassoc (attr := simp)]
theorem pentagon_hom_inv_inv_inv_inv :
W ◁ (α_ X Y Z).hom ≫ (α_ W X (Y ⊗ Z)).inv ≫ (α_ (W ⊗ X) Y Z).inv =
(α_ W (X ⊗ Y) Z).inv ≫ (α_ W X Y).inv ▷ Z := by
simp [← cancel_epi (W ◁ (α_ X Y Z).inv)]
@[reassoc (attr := simp)]
theorem pentagon_hom_hom_inv_hom_hom :
(α_ (W ⊗ X) Y Z).hom ≫ (α_ W X (Y ⊗ Z)).hom ≫ W ◁ (α_ X Y Z).inv =
(α_ W X Y).hom ▷ Z ≫ (α_ W (X ⊗ Y) Z).hom :=
eq_of_inv_eq_inv (by simp)
@[reassoc (attr := simp)]
theorem pentagon_hom_inv_inv_inv_hom :
(α_ W X (Y ⊗ Z)).hom ≫ W ◁ (α_ X Y Z).inv ≫ (α_ W (X ⊗ Y) Z).inv =
(α_ (W ⊗ X) Y Z).inv ≫ (α_ W X Y).hom ▷ Z := by
rw [← cancel_epi (α_ W X (Y ⊗ Z)).inv, ← cancel_mono ((α_ W X Y).inv ▷ Z)]
simp
@[reassoc (attr := simp)]
theorem pentagon_hom_hom_inv_inv_hom :
(α_ W (X ⊗ Y) Z).hom ≫ W ◁ (α_ X Y Z).hom ≫ (α_ W X (Y ⊗ Z)).inv =
(α_ W X Y).inv ▷ Z ≫ (α_ (W ⊗ X) Y Z).hom :=
eq_of_inv_eq_inv (by simp)
@[reassoc (attr := simp)]
theorem pentagon_inv_hom_hom_hom_hom :
(α_ W X Y).inv ▷ Z ≫ (α_ (W ⊗ X) Y Z).hom ≫ (α_ W X (Y ⊗ Z)).hom =
(α_ W (X ⊗ Y) Z).hom ≫ W ◁ (α_ X Y Z).hom := by
simp [← cancel_epi ((α_ W X Y).hom ▷ Z)]
@[reassoc (attr := simp)]
theorem pentagon_inv_inv_hom_inv_inv :
(α_ W X (Y ⊗ Z)).inv ≫ (α_ (W ⊗ X) Y Z).inv ≫ (α_ W X Y).hom ▷ Z =
W ◁ (α_ X Y Z).inv ≫ (α_ W (X ⊗ Y) Z).inv :=
eq_of_inv_eq_inv (by simp)
@[reassoc (attr := simp)]
theorem triangle_assoc_comp_right (X Y : C) :
(α_ X (𝟙_ C) Y).inv ≫ ((ρ_ X).hom ▷ Y) = X ◁ (λ_ Y).hom := by
rw [← triangle, Iso.inv_hom_id_assoc]
@[reassoc (attr := simp)]
theorem triangle_assoc_comp_right_inv (X Y : C) :
(ρ_ X).inv ▷ Y ≫ (α_ X (𝟙_ C) Y).hom = X ◁ (λ_ Y).inv := by
simp [← cancel_mono (X ◁ (λ_ Y).hom)]
@[reassoc (attr := simp)]
theorem triangle_assoc_comp_left_inv (X Y : C) :
(X ◁ (λ_ Y).inv) ≫ (α_ X (𝟙_ C) Y).inv = (ρ_ X).inv ▷ Y := by
simp [← cancel_mono ((ρ_ X).hom ▷ Y)]
/-- We state it as a simp lemma, which is regarded as an involved version of
`id_whiskerRight X Y : 𝟙 X ▷ Y = 𝟙 (X ⊗ Y)`.
-/
@[reassoc, simp]
theorem leftUnitor_whiskerRight (X Y : C) :
(λ_ X).hom ▷ Y = (α_ (𝟙_ C) X Y).hom ≫ (λ_ (X ⊗ Y)).hom := by
rw [← whiskerLeft_iff, whiskerLeft_comp, ← cancel_epi (α_ _ _ _).hom, ←
cancel_epi ((α_ _ _ _).hom ▷ _), pentagon_assoc, triangle, ← associator_naturality_middle, ←
comp_whiskerRight_assoc, triangle, associator_naturality_left]
@[reassoc, simp]
theorem leftUnitor_inv_whiskerRight (X Y : C) :
(λ_ X).inv ▷ Y = (λ_ (X ⊗ Y)).inv ≫ (α_ (𝟙_ C) X Y).inv :=
eq_of_inv_eq_inv (by simp)
@[reassoc, simp]
theorem whiskerLeft_rightUnitor (X Y : C) :
X ◁ (ρ_ Y).hom = (α_ X Y (𝟙_ C)).inv ≫ (ρ_ (X ⊗ Y)).hom := by
rw [← whiskerRight_iff, comp_whiskerRight, ← cancel_epi (α_ _ _ _).inv, ←
cancel_epi (X ◁ (α_ _ _ _).inv), pentagon_inv_assoc, triangle_assoc_comp_right, ←
associator_inv_naturality_middle, ← whiskerLeft_comp_assoc, triangle_assoc_comp_right,
associator_inv_naturality_right]
@[reassoc, simp]
theorem whiskerLeft_rightUnitor_inv (X Y : C) :
X ◁ (ρ_ Y).inv = (ρ_ (X ⊗ Y)).inv ≫ (α_ X Y (𝟙_ C)).hom :=
eq_of_inv_eq_inv (by simp)
@[reassoc]
theorem leftUnitor_tensor (X Y : C) :
(λ_ (X ⊗ Y)).hom = (α_ (𝟙_ C) X Y).inv ≫ (λ_ X).hom ▷ Y := by simp
@[reassoc]
theorem leftUnitor_tensor_inv (X Y : C) :
(λ_ (X ⊗ Y)).inv = (λ_ X).inv ▷ Y ≫ (α_ (𝟙_ C) X Y).hom := by simp
@[reassoc]
theorem rightUnitor_tensor (X Y : C) :
(ρ_ (X ⊗ Y)).hom = (α_ X Y (𝟙_ C)).hom ≫ X ◁ (ρ_ Y).hom := by simp
@[reassoc]
theorem rightUnitor_tensor_inv (X Y : C) :
(ρ_ (X ⊗ Y)).inv = X ◁ (ρ_ Y).inv ≫ (α_ X Y (𝟙_ C)).inv := by simp
end
@[reassoc]
theorem associator_inv_naturality {X Y Z X' Y' Z' : C} (f : X ⟶ X') (g : Y ⟶ Y') (h : Z ⟶ Z') :
(f ⊗ g ⊗ h) ≫ (α_ X' Y' Z').inv = (α_ X Y Z).inv ≫ ((f ⊗ g) ⊗ h) := by
simp [tensorHom_def]
@[reassoc, simp]
theorem associator_conjugation {X X' Y Y' Z Z' : C} (f : X ⟶ X') (g : Y ⟶ Y') (h : Z ⟶ Z') :
(f ⊗ g) ⊗ h = (α_ X Y Z).hom ≫ (f ⊗ g ⊗ h) ≫ (α_ X' Y' Z').inv := by
rw [associator_inv_naturality, hom_inv_id_assoc]
@[reassoc]
theorem associator_inv_conjugation {X X' Y Y' Z Z' : C} (f : X ⟶ X') (g : Y ⟶ Y') (h : Z ⟶ Z') :
f ⊗ g ⊗ h = (α_ X Y Z).inv ≫ ((f ⊗ g) ⊗ h) ≫ (α_ X' Y' Z').hom := by
rw [associator_naturality, inv_hom_id_assoc]
-- TODO these next two lemmas aren't so fundamental, and perhaps could be removed
-- (replacing their usages by their proofs).
@[reassoc]
theorem id_tensor_associator_naturality {X Y Z Z' : C} (h : Z ⟶ Z') :
(𝟙 (X ⊗ Y) ⊗ h) ≫ (α_ X Y Z').hom = (α_ X Y Z).hom ≫ (𝟙 X ⊗ 𝟙 Y ⊗ h) := by
rw [← tensor_id, associator_naturality]
@[reassoc]
theorem id_tensor_associator_inv_naturality {X Y Z X' : C} (f : X ⟶ X') :
(f ⊗ 𝟙 (Y ⊗ Z)) ≫ (α_ X' Y Z).inv = (α_ X Y Z).inv ≫ ((f ⊗ 𝟙 Y) ⊗ 𝟙 Z) := by
rw [← tensor_id, associator_inv_naturality]
@[reassoc (attr := simp)]
theorem hom_inv_id_tensor {V W X Y Z : C} (f : V ≅ W) (g : X ⟶ Y) (h : Y ⟶ Z) :
(f.hom ⊗ g) ≫ (f.inv ⊗ h) = (𝟙 V ⊗ g) ≫ (𝟙 V ⊗ h) := by
rw [← tensor_comp, f.hom_inv_id]; simp [id_tensorHom]
@[reassoc (attr := simp)]
theorem inv_hom_id_tensor {V W X Y Z : C} (f : V ≅ W) (g : X ⟶ Y) (h : Y ⟶ Z) :
(f.inv ⊗ g) ≫ (f.hom ⊗ h) = (𝟙 W ⊗ g) ≫ (𝟙 W ⊗ h) := by
rw [← tensor_comp, f.inv_hom_id]; simp [id_tensorHom]
@[reassoc (attr := simp)]
theorem tensor_hom_inv_id {V W X Y Z : C} (f : V ≅ W) (g : X ⟶ Y) (h : Y ⟶ Z) :
(g ⊗ f.hom) ≫ (h ⊗ f.inv) = (g ⊗ 𝟙 V) ≫ (h ⊗ 𝟙 V) := by
rw [← tensor_comp, f.hom_inv_id]; simp [tensorHom_id]
@[reassoc (attr := simp)]
theorem tensor_inv_hom_id {V W X Y Z : C} (f : V ≅ W) (g : X ⟶ Y) (h : Y ⟶ Z) :
(g ⊗ f.inv) ≫ (h ⊗ f.hom) = (g ⊗ 𝟙 W) ≫ (h ⊗ 𝟙 W) := by
rw [← tensor_comp, f.inv_hom_id]; simp [tensorHom_id]
@[reassoc (attr := simp)]
theorem hom_inv_id_tensor' {V W X Y Z : C} (f : V ⟶ W) [IsIso f] (g : X ⟶ Y) (h : Y ⟶ Z) :
(f ⊗ g) ≫ (inv f ⊗ h) = (𝟙 V ⊗ g) ≫ (𝟙 V ⊗ h) := by
rw [← tensor_comp, IsIso.hom_inv_id]; simp [id_tensorHom]
@[reassoc (attr := simp)]
theorem inv_hom_id_tensor' {V W X Y Z : C} (f : V ⟶ W) [IsIso f] (g : X ⟶ Y) (h : Y ⟶ Z) :
(inv f ⊗ g) ≫ (f ⊗ h) = (𝟙 W ⊗ g) ≫ (𝟙 W ⊗ h) := by
rw [← tensor_comp, IsIso.inv_hom_id]; simp [id_tensorHom]
@[reassoc (attr := simp)]
theorem tensor_hom_inv_id' {V W X Y Z : C} (f : V ⟶ W) [IsIso f] (g : X ⟶ Y) (h : Y ⟶ Z) :
(g ⊗ f) ≫ (h ⊗ inv f) = (g ⊗ 𝟙 V) ≫ (h ⊗ 𝟙 V) := by
rw [← tensor_comp, IsIso.hom_inv_id]; simp [tensorHom_id]
@[reassoc (attr := simp)]
theorem tensor_inv_hom_id' {V W X Y Z : C} (f : V ⟶ W) [IsIso f] (g : X ⟶ Y) (h : Y ⟶ Z) :
(g ⊗ inv f) ≫ (h ⊗ f) = (g ⊗ 𝟙 W) ≫ (h ⊗ 𝟙 W) := by
rw [← tensor_comp, IsIso.inv_hom_id]; simp [tensorHom_id]
/--
A constructor for monoidal categories that requires `tensorHom` instead of `whiskerLeft` and
`whiskerRight`.
-/
abbrev ofTensorHom [MonoidalCategoryStruct C]
(tensor_id : ∀ X₁ X₂ : C, tensorHom (𝟙 X₁) (𝟙 X₂) = 𝟙 (tensorObj X₁ X₂) := by
aesop_cat)
(id_tensorHom : ∀ (X : C) {Y₁ Y₂ : C} (f : Y₁ ⟶ Y₂), tensorHom (𝟙 X) f = whiskerLeft X f := by
aesop_cat)
(tensorHom_id : ∀ {X₁ X₂ : C} (f : X₁ ⟶ X₂) (Y : C), tensorHom f (𝟙 Y) = whiskerRight f Y := by
aesop_cat)
(tensor_comp :
∀ {X₁ Y₁ Z₁ X₂ Y₂ Z₂ : C} (f₁ : X₁ ⟶ Y₁) (f₂ : X₂ ⟶ Y₂) (g₁ : Y₁ ⟶ Z₁) (g₂ : Y₂ ⟶ Z₂),
tensorHom (f₁ ≫ g₁) (f₂ ≫ g₂) = tensorHom f₁ f₂ ≫ tensorHom g₁ g₂ := by
| aesop_cat)
(associator_naturality :
∀ {X₁ X₂ X₃ Y₁ Y₂ Y₃ : C} (f₁ : X₁ ⟶ Y₁) (f₂ : X₂ ⟶ Y₂) (f₃ : X₃ ⟶ Y₃),
| Mathlib/CategoryTheory/Monoidal/Category.lean | 696 | 698 |
/-
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.Basic
import Mathlib.Algebra.Module.End
import Mathlib.Algebra.Ring.Prod
import Mathlib.Data.Fintype.Units
import Mathlib.GroupTheory.GroupAction.SubMulAction
import Mathlib.GroupTheory.OrderOfElement
import Mathlib.Tactic.FinCases
/-!
# Integers mod `n`
Definition of the integers mod n, and the field structure on the integers mod p.
## Definitions
* `ZMod n`, which is for integers modulo a nat `n : ℕ`
* `val a` is defined as a natural number:
- for `a : ZMod 0` it is the absolute value of `a`
- for `a : ZMod n` with `0 < n` it is the least natural number in the equivalence class
* A coercion `cast` is defined from `ZMod n` into any ring.
This is a ring hom if the ring has characteristic dividing `n`
-/
assert_not_exists Field Submodule TwoSidedIdeal
open Function ZMod
namespace ZMod
/-- For non-zero `n : ℕ`, the ring `Fin n` is equivalent to `ZMod n`. -/
def finEquiv : ∀ (n : ℕ) [NeZero n], Fin n ≃+* ZMod n
| 0, h => (h.ne _ rfl).elim
| _ + 1, _ => .refl _
instance charZero : CharZero (ZMod 0) := inferInstanceAs (CharZero ℤ)
/-- `val a` is a natural number defined as:
- for `a : ZMod 0` it is the absolute value of `a`
- for `a : ZMod n` with `0 < n` it is the least natural number in the equivalence class
See `ZMod.valMinAbs` for a variant that takes values in the integers.
-/
def val : ∀ {n : ℕ}, ZMod n → ℕ
| 0 => Int.natAbs
| n + 1 => ((↑) : Fin (n + 1) → ℕ)
theorem val_lt {n : ℕ} [NeZero n] (a : ZMod n) : a.val < n := by
cases n
· cases NeZero.ne 0 rfl
exact Fin.is_lt a
theorem val_le {n : ℕ} [NeZero n] (a : ZMod n) : a.val ≤ n :=
a.val_lt.le
@[simp]
theorem val_zero : ∀ {n}, (0 : ZMod n).val = 0
| 0 => rfl
| _ + 1 => rfl
@[simp]
theorem val_one' : (1 : ZMod 0).val = 1 :=
rfl
@[simp]
theorem val_neg' {n : ZMod 0} : (-n).val = n.val :=
Int.natAbs_neg n
@[simp]
theorem val_mul' {m n : ZMod 0} : (m * n).val = m.val * n.val :=
Int.natAbs_mul m n
@[simp]
theorem val_natCast (n a : ℕ) : (a : ZMod n).val = a % n := by
cases n
· rw [Nat.mod_zero]
exact Int.natAbs_natCast a
· apply Fin.val_natCast
lemma val_natCast_of_lt {n a : ℕ} (h : a < n) : (a : ZMod n).val = a := by
rwa [val_natCast, Nat.mod_eq_of_lt]
lemma val_ofNat (n a : ℕ) [a.AtLeastTwo] : (ofNat(a) : ZMod n).val = ofNat(a) % n := val_natCast ..
lemma val_ofNat_of_lt {n a : ℕ} [a.AtLeastTwo] (han : a < n) : (ofNat(a) : ZMod n).val = ofNat(a) :=
val_natCast_of_lt han
theorem val_unit' {n : ZMod 0} : IsUnit n ↔ n.val = 1 := by
simp only [val]
rw [Int.isUnit_iff, Int.natAbs_eq_iff, Nat.cast_one]
lemma eq_one_of_isUnit_natCast {n : ℕ} (h : IsUnit (n : ZMod 0)) : n = 1 := by
rw [← Nat.mod_zero n, ← val_natCast, val_unit'.mp h]
instance charP (n : ℕ) : CharP (ZMod n) n where
cast_eq_zero_iff := by
intro k
rcases n with - | n
· simp [zero_dvd_iff, Int.natCast_eq_zero]
· exact Fin.natCast_eq_zero
@[simp]
theorem addOrderOf_one (n : ℕ) : addOrderOf (1 : ZMod n) = n :=
CharP.eq _ (CharP.addOrderOf_one _) (ZMod.charP n)
/-- This lemma works in the case in which `ZMod n` is not infinite, i.e. `n ≠ 0`. The version
where `a ≠ 0` is `addOrderOf_coe'`. -/
@[simp]
theorem addOrderOf_coe (a : ℕ) {n : ℕ} (n0 : n ≠ 0) : addOrderOf (a : ZMod n) = n / n.gcd a := by
rcases a with - | a
· simp only [Nat.cast_zero, addOrderOf_zero, Nat.gcd_zero_right,
Nat.pos_of_ne_zero n0, Nat.div_self]
rw [← Nat.smul_one_eq_cast, addOrderOf_nsmul' _ a.succ_ne_zero, ZMod.addOrderOf_one]
/-- This lemma works in the case in which `a ≠ 0`. The version where
`ZMod n` is not infinite, i.e. `n ≠ 0`, is `addOrderOf_coe`. -/
@[simp]
theorem addOrderOf_coe' {a : ℕ} (n : ℕ) (a0 : a ≠ 0) : addOrderOf (a : ZMod n) = n / n.gcd a := by
rw [← Nat.smul_one_eq_cast, addOrderOf_nsmul' _ a0, ZMod.addOrderOf_one]
/-- We have that `ringChar (ZMod n) = n`. -/
theorem ringChar_zmod_n (n : ℕ) : ringChar (ZMod n) = n := by
rw [ringChar.eq_iff]
exact ZMod.charP n
theorem natCast_self (n : ℕ) : (n : ZMod n) = 0 :=
CharP.cast_eq_zero (ZMod n) n
@[simp]
theorem natCast_self' (n : ℕ) : (n + 1 : ZMod (n + 1)) = 0 := by
rw [← Nat.cast_add_one, natCast_self (n + 1)]
section UniversalProperty
variable {n : ℕ} {R : Type*}
section
variable [AddGroupWithOne R]
/-- Cast an integer modulo `n` to another semiring.
This function is a morphism if the characteristic of `R` divides `n`.
See `ZMod.castHom` for a bundled version. -/
def cast : ∀ {n : ℕ}, ZMod n → R
| 0 => Int.cast
| _ + 1 => fun i => i.val
@[simp]
theorem cast_zero : (cast (0 : ZMod n) : R) = 0 := by
delta ZMod.cast
cases n
· exact Int.cast_zero
· simp
theorem cast_eq_val [NeZero n] (a : ZMod n) : (cast a : R) = a.val := by
cases n
· cases NeZero.ne 0 rfl
rfl
variable {S : Type*} [AddGroupWithOne S]
@[simp]
theorem _root_.Prod.fst_zmod_cast (a : ZMod n) : (cast a : R × S).fst = cast a := by
cases n
· rfl
· simp [ZMod.cast]
@[simp]
theorem _root_.Prod.snd_zmod_cast (a : ZMod n) : (cast a : R × S).snd = cast a := by
cases n
· rfl
· simp [ZMod.cast]
end
/-- So-named because the coercion is `Nat.cast` into `ZMod`. For `Nat.cast` into an arbitrary ring,
see `ZMod.natCast_val`. -/
theorem natCast_zmod_val {n : ℕ} [NeZero n] (a : ZMod n) : (a.val : ZMod n) = a := by
cases n
· cases NeZero.ne 0 rfl
· apply Fin.cast_val_eq_self
theorem natCast_rightInverse [NeZero n] : Function.RightInverse val ((↑) : ℕ → ZMod n) :=
natCast_zmod_val
theorem natCast_zmod_surjective [NeZero n] : Function.Surjective ((↑) : ℕ → ZMod n) :=
natCast_rightInverse.surjective
/-- So-named because the outer coercion is `Int.cast` into `ZMod`. For `Int.cast` into an arbitrary
ring, see `ZMod.intCast_cast`. -/
@[norm_cast]
theorem intCast_zmod_cast (a : ZMod n) : ((cast a : ℤ) : ZMod n) = a := by
cases n
· simp [ZMod.cast, ZMod]
· dsimp [ZMod.cast]
rw [Int.cast_natCast, natCast_zmod_val]
theorem intCast_rightInverse : Function.RightInverse (cast : ZMod n → ℤ) ((↑) : ℤ → ZMod n) :=
intCast_zmod_cast
theorem intCast_surjective : Function.Surjective ((↑) : ℤ → ZMod n) :=
intCast_rightInverse.surjective
lemma «forall» {P : ZMod n → Prop} : (∀ x, P x) ↔ ∀ x : ℤ, P x := intCast_surjective.forall
lemma «exists» {P : ZMod n → Prop} : (∃ x, P x) ↔ ∃ x : ℤ, P x := intCast_surjective.exists
theorem cast_id : ∀ (n) (i : ZMod n), (ZMod.cast i : ZMod n) = i
| 0, _ => Int.cast_id
| _ + 1, i => natCast_zmod_val i
@[simp]
theorem cast_id' : (ZMod.cast : ZMod n → ZMod n) = id :=
funext (cast_id n)
variable (R) [Ring R]
/-- The coercions are respectively `Nat.cast` and `ZMod.cast`. -/
@[simp]
theorem natCast_comp_val [NeZero n] : ((↑) : ℕ → R) ∘ (val : ZMod n → ℕ) = cast := by
cases n
· cases NeZero.ne 0 rfl
rfl
/-- The coercions are respectively `Int.cast`, `ZMod.cast`, and `ZMod.cast`. -/
@[simp]
theorem intCast_comp_cast : ((↑) : ℤ → R) ∘ (cast : ZMod n → ℤ) = cast := by
cases n
· exact congr_arg (Int.cast ∘ ·) ZMod.cast_id'
· ext
simp [ZMod, ZMod.cast]
variable {R}
@[simp]
theorem natCast_val [NeZero n] (i : ZMod n) : (i.val : R) = cast i :=
congr_fun (natCast_comp_val R) i
@[simp]
theorem intCast_cast (i : ZMod n) : ((cast i : ℤ) : R) = cast i :=
congr_fun (intCast_comp_cast R) i
theorem cast_add_eq_ite {n : ℕ} (a b : ZMod n) :
(cast (a + b) : ℤ) =
if (n : ℤ) ≤ cast a + cast b then (cast a + cast b - n : ℤ) else cast a + cast b := by
rcases n with - | n
· simp; rfl
change Fin (n + 1) at a b
change ((((a + b) : Fin (n + 1)) : ℕ) : ℤ) = if ((n + 1 : ℕ) : ℤ) ≤ (a : ℕ) + b then _ else _
simp only [Fin.val_add_eq_ite, Int.natCast_succ, Int.ofNat_le]
norm_cast
split_ifs with h
· rw [Nat.cast_sub h]
congr
· rfl
section CharDvd
/-! If the characteristic of `R` divides `n`, then `cast` is a homomorphism. -/
variable {m : ℕ} [CharP R m]
@[simp]
theorem cast_one (h : m ∣ n) : (cast (1 : ZMod n) : R) = 1 := by
rcases n with - | n
· exact Int.cast_one
show ((1 % (n + 1) : ℕ) : R) = 1
cases n
· rw [Nat.dvd_one] at h
subst m
subsingleton [CharP.CharOne.subsingleton]
rw [Nat.mod_eq_of_lt]
· exact Nat.cast_one
exact Nat.lt_of_sub_eq_succ rfl
theorem cast_add (h : m ∣ n) (a b : ZMod n) : (cast (a + b : ZMod n) : R) = cast a + cast b := by
cases n
· apply Int.cast_add
symm
dsimp [ZMod, ZMod.cast, ZMod.val]
rw [← Nat.cast_add, Fin.val_add, ← sub_eq_zero, ← Nat.cast_sub (Nat.mod_le _ _),
@CharP.cast_eq_zero_iff R _ m]
exact h.trans (Nat.dvd_sub_mod _)
theorem cast_mul (h : m ∣ n) (a b : ZMod n) : (cast (a * b : ZMod n) : R) = cast a * cast b := by
cases n
· apply Int.cast_mul
symm
dsimp [ZMod, ZMod.cast, ZMod.val]
rw [← Nat.cast_mul, Fin.val_mul, ← sub_eq_zero, ← Nat.cast_sub (Nat.mod_le _ _),
@CharP.cast_eq_zero_iff R _ m]
exact h.trans (Nat.dvd_sub_mod _)
/-- The canonical ring homomorphism from `ZMod n` to a ring of characteristic dividing `n`.
See also `ZMod.lift` for a generalized version working in `AddGroup`s.
-/
def castHom (h : m ∣ n) (R : Type*) [Ring R] [CharP R m] : ZMod n →+* R where
toFun := cast
map_zero' := cast_zero
map_one' := cast_one h
map_add' := cast_add h
map_mul' := cast_mul h
@[simp]
theorem castHom_apply {h : m ∣ n} (i : ZMod n) : castHom h R i = cast i :=
rfl
@[simp]
theorem cast_sub (h : m ∣ n) (a b : ZMod n) : (cast (a - b : ZMod n) : R) = cast a - cast b :=
(castHom h R).map_sub a b
@[simp]
theorem cast_neg (h : m ∣ n) (a : ZMod n) : (cast (-a : ZMod n) : R) = -(cast a) :=
(castHom h R).map_neg a
@[simp]
theorem cast_pow (h : m ∣ n) (a : ZMod n) (k : ℕ) : (cast (a ^ k : ZMod n) : R) = (cast a) ^ k :=
(castHom h R).map_pow a k
@[simp, norm_cast]
theorem cast_natCast (h : m ∣ n) (k : ℕ) : (cast (k : ZMod n) : R) = k :=
map_natCast (castHom h R) k
@[simp, norm_cast]
theorem cast_intCast (h : m ∣ n) (k : ℤ) : (cast (k : ZMod n) : R) = k :=
map_intCast (castHom h R) k
end CharDvd
section CharEq
/-! Some specialised simp lemmas which apply when `R` has characteristic `n`. -/
variable [CharP R n]
@[simp]
theorem cast_one' : (cast (1 : ZMod n) : R) = 1 :=
cast_one dvd_rfl
@[simp]
theorem cast_add' (a b : ZMod n) : (cast (a + b : ZMod n) : R) = cast a + cast b :=
cast_add dvd_rfl a b
@[simp]
theorem cast_mul' (a b : ZMod n) : (cast (a * b : ZMod n) : R) = cast a * cast b :=
cast_mul dvd_rfl a b
@[simp]
theorem cast_sub' (a b : ZMod n) : (cast (a - b : ZMod n) : R) = cast a - cast b :=
cast_sub dvd_rfl a b
@[simp]
theorem cast_pow' (a : ZMod n) (k : ℕ) : (cast (a ^ k : ZMod n) : R) = (cast a : R) ^ k :=
cast_pow dvd_rfl a k
@[simp, norm_cast]
theorem cast_natCast' (k : ℕ) : (cast (k : ZMod n) : R) = k :=
cast_natCast dvd_rfl k
@[simp, norm_cast]
theorem cast_intCast' (k : ℤ) : (cast (k : ZMod n) : R) = k :=
cast_intCast dvd_rfl k
variable (R)
theorem castHom_injective : Function.Injective (ZMod.castHom (dvd_refl n) R) := by
rw [injective_iff_map_eq_zero]
intro x
obtain ⟨k, rfl⟩ := ZMod.intCast_surjective x
rw [map_intCast, CharP.intCast_eq_zero_iff R n, CharP.intCast_eq_zero_iff (ZMod n) n]
exact id
theorem castHom_bijective [Fintype R] (h : Fintype.card R = n) :
Function.Bijective (ZMod.castHom (dvd_refl n) R) := by
haveI : NeZero n :=
⟨by
intro hn
rw [hn] at h
exact (Fintype.card_eq_zero_iff.mp h).elim' 0⟩
rw [Fintype.bijective_iff_injective_and_card, ZMod.card, h, eq_self_iff_true, and_true]
apply ZMod.castHom_injective
/-- The unique ring isomorphism between `ZMod n` and a ring `R`
of characteristic `n` and cardinality `n`. -/
noncomputable def ringEquiv [Fintype R] (h : Fintype.card R = n) : ZMod n ≃+* R :=
RingEquiv.ofBijective _ (ZMod.castHom_bijective R h)
/-- The unique ring isomorphism between `ZMod p` and a ring `R` of cardinality a prime `p`.
If you need any property of this isomorphism, first of all use `ringEquivOfPrime_eq_ringEquiv`
below (after `have : CharP R p := ...`) and deduce it by the results about `ZMod.ringEquiv`. -/
noncomputable def ringEquivOfPrime [Fintype R] {p : ℕ} (hp : p.Prime) (hR : Fintype.card R = p) :
ZMod p ≃+* R :=
have : Nontrivial R := Fintype.one_lt_card_iff_nontrivial.1 (hR ▸ hp.one_lt)
-- The following line exists as `charP_of_card_eq_prime` in `Mathlib.Algebra.CharP.CharAndCard`.
have : CharP R p := (CharP.charP_iff_prime_eq_zero hp).2 (hR ▸ Nat.cast_card_eq_zero R)
ZMod.ringEquiv R hR
@[simp]
lemma ringEquivOfPrime_eq_ringEquiv [Fintype R] {p : ℕ} [CharP R p] (hp : p.Prime)
(hR : Fintype.card R = p) : ringEquivOfPrime R hp hR = ringEquiv R hR := rfl
/-- The identity between `ZMod m` and `ZMod n` when `m = n`, as a ring isomorphism. -/
def ringEquivCongr {m n : ℕ} (h : m = n) : ZMod m ≃+* ZMod n := by
rcases m with - | m <;> rcases n with - | n
· exact RingEquiv.refl _
· exfalso
exact n.succ_ne_zero h.symm
· exfalso
exact m.succ_ne_zero h
· exact
{ finCongr h with
map_mul' := fun a b => by
dsimp [ZMod]
ext
rw [Fin.coe_cast, Fin.coe_mul, Fin.coe_mul, Fin.coe_cast, Fin.coe_cast, ← h]
map_add' := fun a b => by
dsimp [ZMod]
ext
rw [Fin.coe_cast, Fin.val_add, Fin.val_add, Fin.coe_cast, Fin.coe_cast, ← h] }
@[simp] lemma ringEquivCongr_refl (a : ℕ) : ringEquivCongr (rfl : a = a) = .refl _ := by
cases a <;> rfl
lemma ringEquivCongr_refl_apply {a : ℕ} (x : ZMod a) : ringEquivCongr rfl x = x := by
rw [ringEquivCongr_refl]
rfl
lemma ringEquivCongr_symm {a b : ℕ} (hab : a = b) :
(ringEquivCongr hab).symm = ringEquivCongr hab.symm := by
subst hab
cases a <;> rfl
lemma ringEquivCongr_trans {a b c : ℕ} (hab : a = b) (hbc : b = c) :
(ringEquivCongr hab).trans (ringEquivCongr hbc) = ringEquivCongr (hab.trans hbc) := by
subst hab hbc
cases a <;> rfl
lemma ringEquivCongr_ringEquivCongr_apply {a b c : ℕ} (hab : a = b) (hbc : b = c) (x : ZMod a) :
ringEquivCongr hbc (ringEquivCongr hab x) = ringEquivCongr (hab.trans hbc) x := by
rw [← ringEquivCongr_trans hab hbc]
rfl
lemma ringEquivCongr_val {a b : ℕ} (h : a = b) (x : ZMod a) :
ZMod.val ((ZMod.ringEquivCongr h) x) = ZMod.val x := by
subst h
cases a <;> rfl
lemma ringEquivCongr_intCast {a b : ℕ} (h : a = b) (z : ℤ) :
ZMod.ringEquivCongr h z = z := by
subst h
cases a <;> rfl
end CharEq
end UniversalProperty
variable {m n : ℕ}
@[simp]
theorem val_eq_zero : ∀ {n : ℕ} (a : ZMod n), a.val = 0 ↔ a = 0
| 0, _ => Int.natAbs_eq_zero
| n + 1, a => by
rw [Fin.ext_iff]
exact Iff.rfl
theorem intCast_eq_intCast_iff (a b : ℤ) (c : ℕ) : (a : ZMod c) = (b : ZMod c) ↔ a ≡ b [ZMOD c] :=
CharP.intCast_eq_intCast (ZMod c) c
theorem intCast_eq_intCast_iff' (a b : ℤ) (c : ℕ) : (a : ZMod c) = (b : ZMod c) ↔ a % c = b % c :=
ZMod.intCast_eq_intCast_iff a b c
theorem val_intCast {n : ℕ} (a : ℤ) [NeZero n] : ↑(a : ZMod n).val = a % n := by
have hle : (0 : ℤ) ≤ ↑(a : ZMod n).val := Int.natCast_nonneg _
have hlt : ↑(a : ZMod n).val < (n : ℤ) := Int.ofNat_lt.mpr (ZMod.val_lt a)
refine (Int.emod_eq_of_lt hle hlt).symm.trans ?_
rw [← ZMod.intCast_eq_intCast_iff', Int.cast_natCast, ZMod.natCast_val, ZMod.cast_id]
theorem natCast_eq_natCast_iff (a b c : ℕ) : (a : ZMod c) = (b : ZMod c) ↔ a ≡ b [MOD c] := by
simpa [Int.natCast_modEq_iff] using ZMod.intCast_eq_intCast_iff a b c
theorem natCast_eq_natCast_iff' (a b c : ℕ) : (a : ZMod c) = (b : ZMod c) ↔ a % c = b % c :=
ZMod.natCast_eq_natCast_iff a b c
theorem intCast_zmod_eq_zero_iff_dvd (a : ℤ) (b : ℕ) : (a : ZMod b) = 0 ↔ (b : ℤ) ∣ a := by
rw [← Int.cast_zero, ZMod.intCast_eq_intCast_iff, Int.modEq_zero_iff_dvd]
theorem intCast_eq_intCast_iff_dvd_sub (a b : ℤ) (c : ℕ) : (a : ZMod c) = ↑b ↔ ↑c ∣ b - a := by
rw [ZMod.intCast_eq_intCast_iff, Int.modEq_iff_dvd]
theorem natCast_zmod_eq_zero_iff_dvd (a b : ℕ) : (a : ZMod b) = 0 ↔ b ∣ a := by
rw [← Nat.cast_zero, ZMod.natCast_eq_natCast_iff, Nat.modEq_zero_iff_dvd]
theorem coe_intCast (a : ℤ) : cast (a : ZMod n) = a % n := by
cases n
· rw [Int.ofNat_zero, Int.emod_zero, Int.cast_id]; rfl
· rw [← val_intCast, val]; rfl
lemma intCast_cast_add (x y : ZMod n) : (cast (x + y) : ℤ) = (cast x + cast y) % n := by
rw [← ZMod.coe_intCast, Int.cast_add, ZMod.intCast_zmod_cast, ZMod.intCast_zmod_cast]
lemma intCast_cast_mul (x y : ZMod n) : (cast (x * y) : ℤ) = cast x * cast y % n := by
rw [← ZMod.coe_intCast, Int.cast_mul, ZMod.intCast_zmod_cast, ZMod.intCast_zmod_cast]
lemma intCast_cast_sub (x y : ZMod n) : (cast (x - y) : ℤ) = (cast x - cast y) % n := by
rw [← ZMod.coe_intCast, Int.cast_sub, ZMod.intCast_zmod_cast, ZMod.intCast_zmod_cast]
lemma intCast_cast_neg (x : ZMod n) : (cast (-x) : ℤ) = -cast x % n := by
rw [← ZMod.coe_intCast, Int.cast_neg, ZMod.intCast_zmod_cast]
@[simp]
theorem val_neg_one (n : ℕ) : (-1 : ZMod n.succ).val = n := by
dsimp [val, Fin.coe_neg]
cases n
· simp [Nat.mod_one]
· dsimp [ZMod, ZMod.cast]
rw [Fin.coe_neg_one]
/-- `-1 : ZMod n` lifts to `n - 1 : R`. This avoids the characteristic assumption in `cast_neg`. -/
theorem cast_neg_one {R : Type*} [Ring R] (n : ℕ) : cast (-1 : ZMod n) = (n - 1 : R) := by
rcases n with - | n
· dsimp [ZMod, ZMod.cast]; simp
· rw [← natCast_val, val_neg_one, Nat.cast_succ, add_sub_cancel_right]
theorem cast_sub_one {R : Type*} [Ring R] {n : ℕ} (k : ZMod n) :
(cast (k - 1 : ZMod n) : R) = (if k = 0 then (n : R) else cast k) - 1 := by
split_ifs with hk
· rw [hk, zero_sub, ZMod.cast_neg_one]
· cases n
· dsimp [ZMod, ZMod.cast]
rw [Int.cast_sub, Int.cast_one]
· dsimp [ZMod, ZMod.cast, ZMod.val]
rw [Fin.coe_sub_one, if_neg]
· rw [Nat.cast_sub, Nat.cast_one]
rwa [Fin.ext_iff, Fin.val_zero, ← Ne, ← Nat.one_le_iff_ne_zero] at hk
· exact hk
theorem natCast_eq_iff (p : ℕ) (n : ℕ) (z : ZMod p) [NeZero p] :
↑n = z ↔ ∃ k, n = z.val + p * k := by
constructor
· rintro rfl
refine ⟨n / p, ?_⟩
rw [val_natCast, Nat.mod_add_div]
· rintro ⟨k, rfl⟩
rw [Nat.cast_add, natCast_zmod_val, Nat.cast_mul, natCast_self, zero_mul,
add_zero]
theorem intCast_eq_iff (p : ℕ) (n : ℤ) (z : ZMod p) [NeZero p] :
↑n = z ↔ ∃ k, n = z.val + p * k := by
constructor
· rintro rfl
refine ⟨n / p, ?_⟩
rw [val_intCast, Int.emod_add_ediv]
· rintro ⟨k, rfl⟩
rw [Int.cast_add, Int.cast_mul, Int.cast_natCast, Int.cast_natCast, natCast_val,
ZMod.natCast_self, zero_mul, add_zero, cast_id]
@[push_cast, simp]
theorem intCast_mod (a : ℤ) (b : ℕ) : ((a % b : ℤ) : ZMod b) = (a : ZMod b) := by
rw [ZMod.intCast_eq_intCast_iff]
apply Int.mod_modEq
theorem ker_intCastAddHom (n : ℕ) :
(Int.castAddHom (ZMod n)).ker = AddSubgroup.zmultiples (n : ℤ) := by
ext
rw [Int.mem_zmultiples_iff, AddMonoidHom.mem_ker, Int.coe_castAddHom,
intCast_zmod_eq_zero_iff_dvd]
theorem cast_injective_of_le {m n : ℕ} [nzm : NeZero m] (h : m ≤ n) :
Function.Injective (@cast (ZMod n) _ m) := by
cases m with
| zero => cases nzm; simp_all
| succ m =>
rintro ⟨x, hx⟩ ⟨y, hy⟩ f
simp only [cast, val, natCast_eq_natCast_iff',
Nat.mod_eq_of_lt (hx.trans_le h), Nat.mod_eq_of_lt (hy.trans_le h)] at f
apply Fin.ext
exact f
theorem cast_zmod_eq_zero_iff_of_le {m n : ℕ} [NeZero m] (h : m ≤ n) (a : ZMod m) :
(cast a : ZMod n) = 0 ↔ a = 0 := by
rw [← ZMod.cast_zero (n := m)]
exact Injective.eq_iff' (cast_injective_of_le h) rfl
@[simp]
theorem natCast_toNat (p : ℕ) : ∀ {z : ℤ} (_h : 0 ≤ z), (z.toNat : ZMod p) = z
| (n : ℕ), _h => by simp only [Int.cast_natCast, Int.toNat_natCast]
| Int.negSucc n, h => by simp at h
theorem val_injective (n : ℕ) [NeZero n] : Function.Injective (val : ZMod n → ℕ) := by
| cases n
· cases NeZero.ne 0 rfl
| Mathlib/Data/ZMod/Basic.lean | 602 | 603 |
/-
Copyright (c) 2020 Fox Thomson. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Fox Thomson, Martin Dvorak
-/
import Mathlib.Algebra.Order.Kleene
import Mathlib.Algebra.Ring.Hom.Defs
import Mathlib.Data.Set.Lattice
import Mathlib.Tactic.DeriveFintype
/-!
# Languages
This file contains the definition and operations on formal languages over an alphabet.
Note that "strings" are implemented as lists over the alphabet.
Union and concatenation define a [Kleene algebra](https://en.wikipedia.org/wiki/Kleene_algebra)
over the languages.
In addition to that, we define a reversal of a language and prove that it behaves well
with respect to other language operations.
## Notation
* `l + m`: union of languages `l` and `m`
* `l * m`: language of strings `x ++ y` such that `x ∈ l` and `y ∈ m`
* `l ^ n`: language of strings consisting of `n` members of `l` concatenated together
* `1`: language consisting of only the empty string.
This is because it is the unit of the `*` operator.
* `l∗`: Kleene's star – language of strings consisting of arbitrarily many
members of `l` concatenated together
(Note that this is the Unicode asterisk `∗`, and not the more common star `*`)
## Main definitions
* `Language α`: a set of strings over the alphabet `α`
* `l.map f`: transform a language `l` over `α` into a language over `β`
by translating through `f : α → β`
## Main theorems
* `Language.self_eq_mul_add_iff`: Arden's lemma – if a language `l` satisfies the equation
`l = m * l + n`, and `m` doesn't contain the empty string,
then `l` is the language `m∗ * n`
-/
open List Set Computability
universe v
variable {α β γ : Type*}
/-- A language is a set of strings over an alphabet. -/
def Language (α) :=
Set (List α)
namespace Language
instance : Membership (List α) (Language α) := ⟨Set.Mem⟩
instance : Singleton (List α) (Language α) := ⟨Set.singleton⟩
instance : Insert (List α) (Language α) := ⟨Set.insert⟩
instance instCompleteAtomicBooleanAlgebra : CompleteAtomicBooleanAlgebra (Language α) :=
Set.instCompleteAtomicBooleanAlgebra
variable {l m : Language α} {a b x : List α}
/-- Zero language has no elements. -/
instance : Zero (Language α) :=
⟨(∅ : Set _)⟩
/-- `1 : Language α` contains only one element `[]`. -/
instance : One (Language α) :=
⟨{[]}⟩
instance : Inhabited (Language α) := ⟨(∅ : Set _)⟩
/-- The sum of two languages is their union. -/
instance : Add (Language α) :=
⟨((· ∪ ·) : Set (List α) → Set (List α) → Set (List α))⟩
/-- The product of two languages `l` and `m` is the language made of the strings `x ++ y` where
`x ∈ l` and `y ∈ m`. -/
instance : Mul (Language α) :=
⟨image2 (· ++ ·)⟩
theorem zero_def : (0 : Language α) = (∅ : Set _) :=
rfl
theorem one_def : (1 : Language α) = ({[]} : Set (List α)) :=
rfl
theorem add_def (l m : Language α) : l + m = (l ∪ m : Set (List α)) :=
rfl
theorem mul_def (l m : Language α) : l * m = image2 (· ++ ·) l m :=
rfl
/-- The Kleene star of a language `L` is the set of all strings which can be written by
concatenating strings from `L`. -/
instance : KStar (Language α) := ⟨fun l ↦ {x | ∃ L : List (List α), x = L.flatten ∧ ∀ y ∈ L, y ∈ l}⟩
lemma kstar_def (l : Language α) : l∗ = {x | ∃ L : List (List α), x = L.flatten ∧ ∀ y ∈ L, y ∈ l} :=
rfl
@[ext]
theorem ext {l m : Language α} (h : ∀ (x : List α), x ∈ l ↔ x ∈ m) : l = m :=
Set.ext h
@[simp]
theorem not_mem_zero (x : List α) : x ∉ (0 : Language α) :=
id
@[simp]
theorem mem_one (x : List α) : x ∈ (1 : Language α) ↔ x = [] := by rfl
theorem nil_mem_one : [] ∈ (1 : Language α) :=
Set.mem_singleton _
theorem mem_add (l m : Language α) (x : List α) : x ∈ l + m ↔ x ∈ l ∨ x ∈ m :=
Iff.rfl
theorem mem_mul : x ∈ l * m ↔ ∃ a ∈ l, ∃ b ∈ m, a ++ b = x :=
mem_image2
theorem append_mem_mul : a ∈ l → b ∈ m → a ++ b ∈ l * m :=
mem_image2_of_mem
theorem mem_kstar : x ∈ l∗ ↔ ∃ L : List (List α), x = L.flatten ∧ ∀ y ∈ L, y ∈ l :=
Iff.rfl
theorem join_mem_kstar {L : List (List α)} (h : ∀ y ∈ L, y ∈ l) : L.flatten ∈ l∗ :=
⟨L, rfl, h⟩
theorem nil_mem_kstar (l : Language α) : [] ∈ l∗ :=
⟨[], rfl, fun _ h ↦ by contradiction⟩
instance instSemiring : Semiring (Language α) where
add := (· + ·)
add_assoc := union_assoc
zero := 0
zero_add := empty_union
add_zero := union_empty
add_comm := union_comm
mul := (· * ·)
mul_assoc _ _ _ := image2_assoc append_assoc
zero_mul _ := image2_empty_left
mul_zero _ := image2_empty_right
one := 1
one_mul l := by simp [mul_def, one_def]
mul_one l := by simp [mul_def, one_def]
natCast n := if n = 0 then 0 else 1
natCast_zero := rfl
natCast_succ n := by cases n <;> simp [Nat.cast, add_def, zero_def]
left_distrib _ _ _ := image2_union_right
right_distrib _ _ _ := image2_union_left
nsmul := nsmulRec
@[simp]
theorem add_self (l : Language α) : l + l = l :=
sup_idem _
/-- Maps the alphabet of a language. -/
def map (f : α → β) : Language α →+* Language β where
toFun := image (List.map f)
map_zero' := image_empty _
map_one' := image_singleton
map_add' := image_union _
map_mul' _ _ := image_image2_distrib <| fun _ _ => map_append
@[simp]
theorem map_id (l : Language α) : map id l = l := by simp [map]
@[simp]
theorem map_map (g : β → γ) (f : α → β) (l : Language α) : map g (map f l) = map (g ∘ f) l := by
simp [map, image_image]
lemma mem_kstar_iff_exists_nonempty {x : List α} :
x ∈ l∗ ↔ ∃ S : List (List α), x = S.flatten ∧ ∀ y ∈ S, y ∈ l ∧ y ≠ [] := by
constructor
· rintro ⟨S, rfl, h⟩
refine ⟨S.filter fun l ↦ !List.isEmpty l,
by simp [List.flatten_filter_not_isEmpty], fun y hy ↦ ?_⟩
simp only [mem_filter, Bool.not_eq_eq_eq_not, Bool.not_true, isEmpty_eq_false_iff, ne_eq] at hy
exact ⟨h y hy.1, hy.2⟩
· rintro ⟨S, hx, h⟩
exact ⟨S, hx, fun y hy ↦ (h y hy).1⟩
theorem kstar_def_nonempty (l : Language α) :
| l∗ = { x | ∃ S : List (List α), x = S.flatten ∧ ∀ y ∈ S, y ∈ l ∧ y ≠ [] } := by
ext x; apply mem_kstar_iff_exists_nonempty
| Mathlib/Computability/Language.lean | 191 | 193 |
/-
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.Pointwise
import Mathlib.Analysis.NormedSpace.Real
/-!
# Properties of pointwise scalar multiplication of sets in normed spaces.
We explore the relationships between scalar multiplication of sets in vector spaces, and the norm.
Notably, we express arbitrary balls as rescaling of other balls, and we show that the
multiplication of bounded sets remain bounded.
-/
open Metric Set
open Pointwise Topology
variable {𝕜 E : Type*}
section SMulZeroClass
variable [SeminormedAddCommGroup 𝕜] [SeminormedAddCommGroup E]
variable [SMulZeroClass 𝕜 E] [IsBoundedSMul 𝕜 E]
theorem ediam_smul_le (c : 𝕜) (s : Set E) : EMetric.diam (c • s) ≤ ‖c‖₊ • EMetric.diam s :=
(lipschitzWith_smul c).ediam_image_le s
end SMulZeroClass
section DivisionRing
variable [NormedDivisionRing 𝕜] [SeminormedAddCommGroup E]
variable [Module 𝕜 E] [IsBoundedSMul 𝕜 E]
theorem ediam_smul₀ (c : 𝕜) (s : Set E) : EMetric.diam (c • s) = ‖c‖₊ • EMetric.diam s := by
refine le_antisymm (ediam_smul_le c s) ?_
obtain rfl | hc := eq_or_ne c 0
· obtain rfl | hs := s.eq_empty_or_nonempty
· simp
simp [zero_smul_set hs, ← Set.singleton_zero]
· have := (lipschitzWith_smul c⁻¹).ediam_image_le (c • s)
rwa [← smul_eq_mul, ← ENNReal.smul_def, Set.image_smul, inv_smul_smul₀ hc s, nnnorm_inv,
le_inv_smul_iff_of_pos (nnnorm_pos.2 hc)] at this
theorem diam_smul₀ (c : 𝕜) (x : Set E) : diam (c • x) = ‖c‖ * diam x := by
simp_rw [diam, ediam_smul₀, ENNReal.toReal_smul, NNReal.smul_def, coe_nnnorm, smul_eq_mul]
theorem infEdist_smul₀ {c : 𝕜} (hc : c ≠ 0) (s : Set E) (x : E) :
EMetric.infEdist (c • x) (c • s) = ‖c‖₊ • EMetric.infEdist x s := by
simp_rw [EMetric.infEdist]
have : Function.Surjective ((c • ·) : E → E) :=
Function.RightInverse.surjective (smul_inv_smul₀ hc)
trans ⨅ (y) (_ : y ∈ s), ‖c‖₊ • edist x y
· refine (this.iInf_congr _ fun y => ?_).symm
simp_rw [smul_mem_smul_set_iff₀ hc, edist_smul₀]
· have : (‖c‖₊ : ENNReal) ≠ 0 := by simp [hc]
simp_rw [ENNReal.smul_def, smul_eq_mul, ENNReal.mul_iInf_of_ne this ENNReal.coe_ne_top]
theorem infDist_smul₀ {c : 𝕜} (hc : c ≠ 0) (s : Set E) (x : E) :
Metric.infDist (c • x) (c • s) = ‖c‖ * Metric.infDist x s := by
simp_rw [Metric.infDist, infEdist_smul₀ hc s, ENNReal.toReal_smul, NNReal.smul_def, coe_nnnorm,
smul_eq_mul]
end DivisionRing
variable [NormedField 𝕜]
section SeminormedAddCommGroup
variable [SeminormedAddCommGroup E] [NormedSpace 𝕜 E]
theorem smul_ball {c : 𝕜} (hc : c ≠ 0) (x : E) (r : ℝ) : c • ball x r = ball (c • x) (‖c‖ * r) := by
ext y
rw [mem_smul_set_iff_inv_smul_mem₀ hc]
conv_lhs => rw [← inv_smul_smul₀ hc x]
simp [← div_eq_inv_mul, div_lt_iff₀ (norm_pos_iff.2 hc), mul_comm _ r, dist_smul₀]
theorem smul_unitBall {c : 𝕜} (hc : c ≠ 0) : c • ball (0 : E) (1 : ℝ) = ball (0 : E) ‖c‖ := by
rw [_root_.smul_ball hc, smul_zero, mul_one]
theorem smul_sphere' {c : 𝕜} (hc : c ≠ 0) (x : E) (r : ℝ) :
c • sphere x r = sphere (c • x) (‖c‖ * r) := by
ext y
rw [mem_smul_set_iff_inv_smul_mem₀ hc]
conv_lhs => rw [← inv_smul_smul₀ hc x]
simp only [mem_sphere, dist_smul₀, norm_inv, ← div_eq_inv_mul, div_eq_iff (norm_pos_iff.2 hc).ne',
mul_comm r]
theorem smul_closedBall' {c : 𝕜} (hc : c ≠ 0) (x : E) (r : ℝ) :
c • closedBall x r = closedBall (c • x) (‖c‖ * r) := by
simp only [← ball_union_sphere, Set.smul_set_union, _root_.smul_ball hc, smul_sphere' hc]
theorem set_smul_sphere_zero {s : Set 𝕜} (hs : 0 ∉ s) (r : ℝ) :
s • sphere (0 : E) r = (‖·‖) ⁻¹' ((‖·‖ * r) '' s) :=
calc
s • sphere (0 : E) r = ⋃ c ∈ s, c • sphere (0 : E) r := iUnion_smul_left_image.symm
_ = ⋃ c ∈ s, sphere (0 : E) (‖c‖ * r) := iUnion₂_congr fun c hc ↦ by
rw [smul_sphere' (ne_of_mem_of_not_mem hc hs), smul_zero]
_ = (‖·‖) ⁻¹' ((‖·‖ * r) '' s) := by ext; simp [eq_comm]
/-- Image of a bounded set in a normed space under scalar multiplication by a constant is
bounded. See also `Bornology.IsBounded.smul` for a similar lemma about an isometric action. -/
theorem Bornology.IsBounded.smul₀ {s : Set E} (hs : IsBounded s) (c : 𝕜) : IsBounded (c • s) :=
(lipschitzWith_smul c).isBounded_image hs
/-- If `s` is a bounded set, then for small enough `r`, the set `{x} + r • s` is contained in any
fixed neighborhood of `x`. -/
theorem eventually_singleton_add_smul_subset {x : E} {s : Set E} (hs : Bornology.IsBounded s)
{u : Set E} (hu : u ∈ 𝓝 x) : ∀ᶠ r in 𝓝 (0 : 𝕜), {x} + r • s ⊆ u := by
obtain ⟨ε, εpos, hε⟩ : ∃ ε : ℝ, 0 < ε ∧ closedBall x ε ⊆ u := nhds_basis_closedBall.mem_iff.1 hu
obtain ⟨R, Rpos, hR⟩ : ∃ R : ℝ, 0 < R ∧ s ⊆ closedBall 0 R := hs.subset_closedBall_lt 0 0
have : Metric.closedBall (0 : 𝕜) (ε / R) ∈ 𝓝 (0 : 𝕜) := closedBall_mem_nhds _ (div_pos εpos Rpos)
filter_upwards [this] with r hr
simp only [image_add_left, singleton_add]
intro y hy
obtain ⟨z, zs, hz⟩ : ∃ z : E, z ∈ s ∧ r • z = -x + y := by simpa [mem_smul_set] using hy
have I : ‖r • z‖ ≤ ε :=
calc
‖r • z‖ = ‖r‖ * ‖z‖ := norm_smul _ _
_ ≤ ε / R * R :=
(mul_le_mul (mem_closedBall_zero_iff.1 hr) (mem_closedBall_zero_iff.1 (hR zs))
(norm_nonneg _) (div_pos εpos Rpos).le)
_ = ε := by field_simp
have : y = x + r • z := by simp only [hz, add_neg_cancel_left]
apply hε
simpa only [this, dist_eq_norm, add_sub_cancel_left, mem_closedBall] using I
variable [NormedSpace ℝ E] {x y z : E} {δ ε : ℝ}
/-- In a real normed space, the image of the unit ball under scalar multiplication by a positive
constant `r` is the ball of radius `r`. -/
theorem smul_unitBall_of_pos {r : ℝ} (hr : 0 < r) : r • ball (0 : E) 1 = ball (0 : E) r := by
rw [smul_unitBall hr.ne', Real.norm_of_nonneg hr.le]
lemma Ioo_smul_sphere_zero {a b r : ℝ} (ha : 0 ≤ a) (hr : 0 < r) :
Ioo a b • sphere (0 : E) r = ball 0 (b * r) \ closedBall 0 (a * r) := by
have : EqOn (‖·‖) id (Ioo a b) := fun x hx ↦ abs_of_pos (ha.trans_lt hx.1)
rw [set_smul_sphere_zero (by simp [ha.not_lt]), ← image_image (· * r), this.image_eq, image_id,
image_mul_right_Ioo _ _ hr]
ext x; simp [and_comm]
-- This is also true for `ℚ`-normed spaces
theorem exists_dist_eq (x z : E) {a b : ℝ} (ha : 0 ≤ a) (hb : 0 ≤ b) (hab : a + b = 1) :
∃ y, dist x y = b * dist x z ∧ dist y z = a * dist x z := by
use a • x + b • z
nth_rw 1 [← one_smul ℝ x]
nth_rw 4 [← one_smul ℝ z]
simp [dist_eq_norm, ← hab, add_smul, ← smul_sub, norm_smul_of_nonneg, ha, hb]
theorem exists_dist_le_le (hδ : 0 ≤ δ) (hε : 0 ≤ ε) (h : dist x z ≤ ε + δ) :
∃ y, dist x y ≤ δ ∧ dist y z ≤ ε := by
obtain rfl | hε' := hε.eq_or_lt
· exact ⟨z, by rwa [zero_add] at h, (dist_self _).le⟩
have hεδ := add_pos_of_pos_of_nonneg hε' hδ
refine (exists_dist_eq x z (div_nonneg hε <| add_nonneg hε hδ)
(div_nonneg hδ <| add_nonneg hε hδ) <| by
rw [← add_div, div_self hεδ.ne']).imp
fun y hy => ?_
rw [hy.1, hy.2, div_mul_comm, div_mul_comm ε]
rw [← div_le_one hεδ] at h
exact ⟨mul_le_of_le_one_left hδ h, mul_le_of_le_one_left hε h⟩
-- This is also true for `ℚ`-normed spaces
theorem exists_dist_le_lt (hδ : 0 ≤ δ) (hε : 0 < ε) (h : dist x z < ε + δ) :
∃ y, dist x y ≤ δ ∧ dist y z < ε := by
refine (exists_dist_eq x z (div_nonneg hε.le <| add_nonneg hε.le hδ)
(div_nonneg hδ <| add_nonneg hε.le hδ) <| by
rw [← add_div, div_self (add_pos_of_pos_of_nonneg hε hδ).ne']).imp
fun y hy => ?_
rw [hy.1, hy.2, div_mul_comm, div_mul_comm ε]
rw [← div_lt_one (add_pos_of_pos_of_nonneg hε hδ)] at h
exact ⟨mul_le_of_le_one_left hδ h.le, mul_lt_of_lt_one_left hε h⟩
-- This is also true for `ℚ`-normed spaces
theorem exists_dist_lt_le (hδ : 0 < δ) (hε : 0 ≤ ε) (h : dist x z < ε + δ) :
∃ y, dist x y < δ ∧ dist y z ≤ ε := by
obtain ⟨y, yz, xy⟩ :=
exists_dist_le_lt hε hδ (show dist z x < δ + ε by simpa only [dist_comm, add_comm] using h)
exact ⟨y, by simp [dist_comm x y, dist_comm y z, *]⟩
-- This is also true for `ℚ`-normed spaces
theorem exists_dist_lt_lt (hδ : 0 < δ) (hε : 0 < ε) (h : dist x z < ε + δ) :
∃ y, dist x y < δ ∧ dist y z < ε := by
refine (exists_dist_eq x z (div_nonneg hε.le <| add_nonneg hε.le hδ.le)
(div_nonneg hδ.le <| add_nonneg hε.le hδ.le) <| by
rw [← add_div, div_self (add_pos hε hδ).ne']).imp
fun y hy => ?_
rw [hy.1, hy.2, div_mul_comm, div_mul_comm ε]
rw [← div_lt_one (add_pos hε hδ)] at h
exact ⟨mul_lt_of_lt_one_left hδ h, mul_lt_of_lt_one_left hε h⟩
-- This is also true for `ℚ`-normed spaces
theorem disjoint_ball_ball_iff (hδ : 0 < δ) (hε : 0 < ε) :
Disjoint (ball x δ) (ball y ε) ↔ δ + ε ≤ dist x y := by
refine ⟨fun h => le_of_not_lt fun hxy => ?_, ball_disjoint_ball⟩
rw [add_comm] at hxy
obtain ⟨z, hxz, hzy⟩ := exists_dist_lt_lt hδ hε hxy
rw [dist_comm] at hxz
exact h.le_bot ⟨hxz, hzy⟩
-- This is also true for `ℚ`-normed spaces
theorem disjoint_ball_closedBall_iff (hδ : 0 < δ) (hε : 0 ≤ ε) :
Disjoint (ball x δ) (closedBall y ε) ↔ δ + ε ≤ dist x y := by
refine ⟨fun h => le_of_not_lt fun hxy => ?_, ball_disjoint_closedBall⟩
rw [add_comm] at hxy
obtain ⟨z, hxz, hzy⟩ := exists_dist_lt_le hδ hε hxy
rw [dist_comm] at hxz
exact h.le_bot ⟨hxz, hzy⟩
-- This is also true for `ℚ`-normed spaces
theorem disjoint_closedBall_ball_iff (hδ : 0 ≤ δ) (hε : 0 < ε) :
Disjoint (closedBall x δ) (ball y ε) ↔ δ + ε ≤ dist x y := by
rw [disjoint_comm, disjoint_ball_closedBall_iff hε hδ, add_comm, dist_comm]
theorem disjoint_closedBall_closedBall_iff (hδ : 0 ≤ δ) (hε : 0 ≤ ε) :
Disjoint (closedBall x δ) (closedBall y ε) ↔ δ + ε < dist x y := by
refine ⟨fun h => lt_of_not_ge fun hxy => ?_, closedBall_disjoint_closedBall⟩
rw [add_comm] at hxy
obtain ⟨z, hxz, hzy⟩ := exists_dist_le_le hδ hε hxy
rw [dist_comm] at hxz
exact h.le_bot ⟨hxz, hzy⟩
open EMetric ENNReal
@[simp]
theorem infEdist_thickening (hδ : 0 < δ) (s : Set E) (x : E) :
infEdist x (thickening δ s) = infEdist x s - ENNReal.ofReal δ := by
obtain hs | hs := lt_or_le (infEdist x s) (ENNReal.ofReal δ)
· rw [infEdist_zero_of_mem, tsub_eq_zero_of_le hs.le]
exact hs
refine (tsub_le_iff_right.2 infEdist_le_infEdist_thickening_add).antisymm' ?_
refine le_sub_of_add_le_right ofReal_ne_top ?_
refine le_infEdist.2 fun z hz => le_of_forall_lt' fun r h => ?_
cases r with
| top =>
exact add_lt_top.2 ⟨lt_top_iff_ne_top.2 <| infEdist_ne_top ⟨z, self_subset_thickening hδ _ hz⟩,
ofReal_lt_top⟩
| coe r =>
have hr : 0 < ↑r - δ := by
refine sub_pos_of_lt ?_
have := hs.trans_lt ((infEdist_le_edist_of_mem hz).trans_lt h)
rw [ofReal_eq_coe_nnreal hδ.le] at this
exact mod_cast this
rw [edist_lt_coe, ← dist_lt_coe, ← add_sub_cancel δ ↑r] at h
obtain ⟨y, hxy, hyz⟩ := exists_dist_lt_lt hr hδ h
refine (ENNReal.add_lt_add_right ofReal_ne_top <|
infEdist_lt_iff.2 ⟨_, mem_thickening_iff.2 ⟨_, hz, hyz⟩, edist_lt_ofReal.2 hxy⟩).trans_le ?_
rw [← ofReal_add hr.le hδ.le, sub_add_cancel, ofReal_coe_nnreal]
@[simp]
theorem thickening_thickening (hε : 0 < ε) (hδ : 0 < δ) (s : Set E) :
thickening ε (thickening δ s) = thickening (ε + δ) s :=
(thickening_thickening_subset _ _ _).antisymm fun x => by
simp_rw [mem_thickening_iff]
rintro ⟨z, hz, hxz⟩
rw [add_comm] at hxz
obtain ⟨y, hxy, hyz⟩ := exists_dist_lt_lt hε hδ hxz
exact ⟨y, ⟨_, hz, hyz⟩, hxy⟩
@[simp]
theorem cthickening_thickening (hε : 0 ≤ ε) (hδ : 0 < δ) (s : Set E) :
cthickening ε (thickening δ s) = cthickening (ε + δ) s :=
(cthickening_thickening_subset hε _ _).antisymm fun x => by
simp_rw [mem_cthickening_iff, ENNReal.ofReal_add hε hδ.le, infEdist_thickening hδ]
exact tsub_le_iff_right.2
-- Note: `interior (cthickening δ s) ≠ thickening δ s` in general
@[simp]
theorem closure_thickening (hδ : 0 < δ) (s : Set E) :
closure (thickening δ s) = cthickening δ s := by
rw [← cthickening_zero, cthickening_thickening le_rfl hδ, zero_add]
@[simp]
theorem infEdist_cthickening (δ : ℝ) (s : Set E) (x : E) :
infEdist x (cthickening δ s) = infEdist x s - ENNReal.ofReal δ := by
obtain hδ | hδ := le_or_lt δ 0
· rw [cthickening_of_nonpos hδ, infEdist_closure, ofReal_of_nonpos hδ, tsub_zero]
· rw [← closure_thickening hδ, infEdist_closure, infEdist_thickening hδ]
@[simp]
theorem thickening_cthickening (hε : 0 < ε) (hδ : 0 ≤ δ) (s : Set E) :
thickening ε (cthickening δ s) = thickening (ε + δ) s := by
obtain rfl | hδ := hδ.eq_or_lt
· rw [cthickening_zero, thickening_closure, add_zero]
· rw [← closure_thickening hδ, thickening_closure, thickening_thickening hε hδ]
@[simp]
theorem cthickening_cthickening (hε : 0 ≤ ε) (hδ : 0 ≤ δ) (s : Set E) :
cthickening ε (cthickening δ s) = cthickening (ε + δ) s :=
(cthickening_cthickening_subset hε hδ _).antisymm fun x => by
simp_rw [mem_cthickening_iff, ENNReal.ofReal_add hε hδ, infEdist_cthickening]
exact tsub_le_iff_right.2
@[simp]
theorem thickening_ball (hε : 0 < ε) (hδ : 0 < δ) (x : E) :
thickening ε (ball x δ) = ball x (ε + δ) := by
rw [← thickening_singleton, thickening_thickening hε hδ, thickening_singleton]
@[simp]
theorem thickening_closedBall (hε : 0 < ε) (hδ : 0 ≤ δ) (x : E) :
thickening ε (closedBall x δ) = ball x (ε + δ) := by
rw [← cthickening_singleton _ hδ, thickening_cthickening hε hδ, thickening_singleton]
@[simp]
theorem cthickening_ball (hε : 0 ≤ ε) (hδ : 0 < δ) (x : E) :
cthickening ε (ball x δ) = closedBall x (ε + δ) := by
rw [← thickening_singleton, cthickening_thickening hε hδ,
cthickening_singleton _ (add_nonneg hε hδ.le)]
@[simp]
theorem cthickening_closedBall (hε : 0 ≤ ε) (hδ : 0 ≤ δ) (x : E) :
cthickening ε (closedBall x δ) = closedBall x (ε + δ) := by
rw [← cthickening_singleton _ hδ, cthickening_cthickening hε hδ,
cthickening_singleton _ (add_nonneg hε hδ)]
theorem ball_add_ball (hε : 0 < ε) (hδ : 0 < δ) (a b : E) :
ball a ε + ball b δ = ball (a + b) (ε + δ) := by
rw [ball_add, thickening_ball hε hδ b, Metric.vadd_ball, vadd_eq_add]
theorem ball_sub_ball (hε : 0 < ε) (hδ : 0 < δ) (a b : E) :
ball a ε - ball b δ = ball (a - b) (ε + δ) := by
simp_rw [sub_eq_add_neg, neg_ball, ball_add_ball hε hδ]
theorem ball_add_closedBall (hε : 0 < ε) (hδ : 0 ≤ δ) (a b : E) :
ball a ε + closedBall b δ = ball (a + b) (ε + δ) := by
rw [ball_add, thickening_closedBall hε hδ b, Metric.vadd_ball, vadd_eq_add]
theorem ball_sub_closedBall (hε : 0 < ε) (hδ : 0 ≤ δ) (a b : E) :
ball a ε - closedBall b δ = ball (a - b) (ε + δ) := by
simp_rw [sub_eq_add_neg, neg_closedBall, ball_add_closedBall hε hδ]
theorem closedBall_add_ball (hε : 0 ≤ ε) (hδ : 0 < δ) (a b : E) :
closedBall a ε + ball b δ = ball (a + b) (ε + δ) := by
rw [add_comm, ball_add_closedBall hδ hε b, add_comm, add_comm δ]
theorem closedBall_sub_ball (hε : 0 ≤ ε) (hδ : 0 < δ) (a b : E) :
closedBall a ε - ball b δ = ball (a - b) (ε + δ) := by
simp_rw [sub_eq_add_neg, neg_ball, closedBall_add_ball hε hδ]
theorem closedBall_add_closedBall [ProperSpace E] (hε : 0 ≤ ε) (hδ : 0 ≤ δ) (a b : E) :
closedBall a ε + closedBall b δ = closedBall (a + b) (ε + δ) := by
rw [(isCompact_closedBall _ _).add_closedBall hδ b, cthickening_closedBall hδ hε a,
Metric.vadd_closedBall, vadd_eq_add, add_comm, add_comm δ]
theorem closedBall_sub_closedBall [ProperSpace E] (hε : 0 ≤ ε) (hδ : 0 ≤ δ) (a b : E) :
closedBall a ε - closedBall b δ = closedBall (a - b) (ε + δ) := by
rw [sub_eq_add_neg, neg_closedBall, closedBall_add_closedBall hε hδ, sub_eq_add_neg]
end SeminormedAddCommGroup
section NormedAddCommGroup
variable [NormedAddCommGroup E] [NormedSpace 𝕜 E]
theorem smul_closedBall (c : 𝕜) (x : E) {r : ℝ} (hr : 0 ≤ r) :
c • closedBall x r = closedBall (c • x) (‖c‖ * r) := by
rcases eq_or_ne c 0 with (rfl | hc)
· simp [hr, zero_smul_set, Set.singleton_zero, nonempty_closedBall]
· exact smul_closedBall' hc x r
theorem smul_unitClosedBall (c : 𝕜) : c • closedBall (0 : E) (1 : ℝ) = closedBall (0 : E) ‖c‖ := by
rw [_root_.smul_closedBall _ _ zero_le_one, smul_zero, mul_one]
@[deprecated (since := "2024-12-01")] alias smul_closedUnitBall := smul_unitClosedBall
variable [NormedSpace ℝ E]
/-- In a real normed space, the image of the unit closed ball under multiplication by a nonnegative
number `r` is the closed ball of radius `r` with center at the origin. -/
theorem smul_unitClosedBall_of_nonneg {r : ℝ} (hr : 0 ≤ r) :
r • closedBall (0 : E) 1 = closedBall (0 : E) r := by
rw [smul_unitClosedBall, Real.norm_of_nonneg hr]
@[deprecated (since := "2024-12-01")]
alias smul_closedUnitBall_of_nonneg := smul_unitClosedBall_of_nonneg
/-- In a nontrivial real normed space, a sphere is nonempty if and only if its radius is
nonnegative. -/
@[simp]
theorem NormedSpace.sphere_nonempty [Nontrivial E] {x : E} {r : ℝ} :
(sphere x r).Nonempty ↔ 0 ≤ r := by
obtain ⟨y, hy⟩ := exists_ne x
refine ⟨fun h => nonempty_closedBall.1 (h.mono sphere_subset_closedBall), fun hr =>
⟨r • ‖y - x‖⁻¹ • (y - x) + x, ?_⟩⟩
have : ‖y - x‖ ≠ 0 := by simpa [sub_eq_zero]
simp only [mem_sphere_iff_norm, add_sub_cancel_right, norm_smul, Real.norm_eq_abs, norm_inv,
norm_norm, ne_eq, norm_eq_zero]
simp only [abs_norm, ne_eq, norm_eq_zero]
rw [inv_mul_cancel₀ this, mul_one, abs_eq_self.mpr hr]
theorem smul_sphere [Nontrivial E] (c : 𝕜) (x : E) {r : ℝ} (hr : 0 ≤ r) :
c • sphere x r = sphere (c • x) (‖c‖ * r) := by
rcases eq_or_ne c 0 with (rfl | hc)
· simp [zero_smul_set, Set.singleton_zero, hr]
· exact smul_sphere' hc x r
/-- Any ball `Metric.ball x r`, `0 < r` is the image of the unit ball under `fun y ↦ x + r • y`. -/
theorem affinity_unitBall {r : ℝ} (hr : 0 < r) (x : E) : x +ᵥ r • ball (0 : E) 1 = ball x r := by
rw [smul_unitBall_of_pos hr, vadd_ball_zero]
/-- Any closed ball `Metric.closedBall x r`, `0 ≤ r` is the image of the unit closed ball under
`fun y ↦ x + r • y`. -/
theorem affinity_unitClosedBall {r : ℝ} (hr : 0 ≤ r) (x : E) :
x +ᵥ r • closedBall (0 : E) 1 = closedBall x r := by
rw [smul_unitClosedBall, Real.norm_of_nonneg hr, vadd_closedBall_zero]
end NormedAddCommGroup
| Mathlib/Analysis/NormedSpace/Pointwise.lean | 435 | 439 | |
/-
Copyright (c) 2015 Microsoft Corporation. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Leonardo de Moura
-/
import Mathlib.Data.Stream.Defs
import Mathlib.Logic.Function.Basic
import Mathlib.Data.List.Defs
import Mathlib.Data.Nat.Basic
import Mathlib.Tactic.Common
/-!
# Streams a.k.a. infinite lists a.k.a. infinite sequences
-/
open Nat Function Option
namespace Stream'
universe u v w
variable {α : Type u} {β : Type v} {δ : Type w}
variable (m n : ℕ) (x y : List α) (a b : Stream' α)
instance [Inhabited α] : Inhabited (Stream' α) :=
⟨Stream'.const default⟩
@[simp] protected theorem eta (s : Stream' α) : head s :: tail s = s :=
funext fun i => by cases i <;> rfl
/-- Alias for `Stream'.eta` to match `List` API. -/
alias cons_head_tail := Stream'.eta
@[ext]
protected theorem ext {s₁ s₂ : Stream' α} : (∀ n, get s₁ n = get s₂ n) → s₁ = s₂ :=
fun h => funext h
@[simp]
theorem get_zero_cons (a : α) (s : Stream' α) : get (a::s) 0 = a :=
rfl
@[simp]
theorem head_cons (a : α) (s : Stream' α) : head (a::s) = a :=
rfl
@[simp]
theorem tail_cons (a : α) (s : Stream' α) : tail (a::s) = s :=
rfl
@[simp]
theorem get_drop (n m : ℕ) (s : Stream' α) : get (drop m s) n = get s (m + n) := by
rw [Nat.add_comm]
rfl
theorem tail_eq_drop (s : Stream' α) : tail s = drop 1 s :=
rfl
@[simp]
theorem drop_drop (n m : ℕ) (s : Stream' α) : drop n (drop m s) = drop (m + n) s := by
ext; simp [Nat.add_assoc]
@[simp] theorem get_tail {n : ℕ} {s : Stream' α} : s.tail.get n = s.get (n + 1) := rfl
@[simp] theorem tail_drop' {i : ℕ} {s : Stream' α} : tail (drop i s) = s.drop (i + 1) := by
ext; simp [Nat.add_comm, Nat.add_assoc, Nat.add_left_comm]
@[simp] theorem drop_tail' {i : ℕ} {s : Stream' α} : drop i (tail s) = s.drop (i + 1) := rfl
theorem tail_drop (n : ℕ) (s : Stream' α) : tail (drop n s) = drop n (tail s) := by simp
theorem get_succ (n : ℕ) (s : Stream' α) : get s (succ n) = get (tail s) n :=
rfl
@[simp]
theorem get_succ_cons (n : ℕ) (s : Stream' α) (x : α) : get (x :: s) n.succ = get s n :=
rfl
@[simp] lemma get_cons_append_zero {a : α} {x : List α} {s : Stream' α} :
(a :: x ++ₛ s).get 0 = a := rfl
@[simp] lemma append_eq_cons {a : α} {as : Stream' α} : [a] ++ₛ as = a :: as := by rfl
@[simp] theorem drop_zero {s : Stream' α} : s.drop 0 = s := rfl
theorem drop_succ (n : ℕ) (s : Stream' α) : drop (succ n) s = drop n (tail s) :=
rfl
theorem head_drop (a : Stream' α) (n : ℕ) : (a.drop n).head = a.get n := by simp
theorem cons_injective2 : Function.Injective2 (cons : α → Stream' α → Stream' α) := fun x y s t h =>
⟨by rw [← get_zero_cons x s, h, get_zero_cons],
Stream'.ext fun n => by rw [← get_succ_cons n _ x, h, get_succ_cons]⟩
theorem cons_injective_left (s : Stream' α) : Function.Injective fun x => cons x s :=
cons_injective2.left _
theorem cons_injective_right (x : α) : Function.Injective (cons x) :=
cons_injective2.right _
theorem all_def (p : α → Prop) (s : Stream' α) : All p s = ∀ n, p (get s n) :=
rfl
theorem any_def (p : α → Prop) (s : Stream' α) : Any p s = ∃ n, p (get s n) :=
rfl
@[simp]
theorem mem_cons (a : α) (s : Stream' α) : a ∈ a::s :=
Exists.intro 0 rfl
theorem mem_cons_of_mem {a : α} {s : Stream' α} (b : α) : a ∈ s → a ∈ b::s := fun ⟨n, h⟩ =>
Exists.intro (succ n) (by rw [get_succ, tail_cons, h])
theorem eq_or_mem_of_mem_cons {a b : α} {s : Stream' α} : (a ∈ b::s) → a = b ∨ a ∈ s :=
fun ⟨n, h⟩ => by
rcases n with - | n'
· left
exact h
· right
rw [get_succ, tail_cons] at h
exact ⟨n', h⟩
theorem mem_of_get_eq {n : ℕ} {s : Stream' α} {a : α} : a = get s n → a ∈ s := fun h =>
Exists.intro n h
section Map
variable (f : α → β)
theorem drop_map (n : ℕ) (s : Stream' α) : drop n (map f s) = map f (drop n s) :=
Stream'.ext fun _ => rfl
@[simp]
theorem get_map (n : ℕ) (s : Stream' α) : get (map f s) n = f (get s n) :=
rfl
theorem tail_map (s : Stream' α) : tail (map f s) = map f (tail s) := rfl
@[simp]
theorem head_map (s : Stream' α) : head (map f s) = f (head s) :=
rfl
theorem map_eq (s : Stream' α) : map f s = f (head s)::map f (tail s) := by
rw [← Stream'.eta (map f s), tail_map, head_map]
theorem map_cons (a : α) (s : Stream' α) : map f (a::s) = f a::map f s := by
rw [← Stream'.eta (map f (a::s)), map_eq]; rfl
@[simp]
theorem map_id (s : Stream' α) : map id s = s :=
rfl
@[simp]
theorem map_map (g : β → δ) (f : α → β) (s : Stream' α) : map g (map f s) = map (g ∘ f) s :=
rfl
@[simp]
theorem map_tail (s : Stream' α) : map f (tail s) = tail (map f s) :=
rfl
theorem mem_map {a : α} {s : Stream' α} : a ∈ s → f a ∈ map f s := fun ⟨n, h⟩ =>
Exists.intro n (by rw [get_map, h])
theorem exists_of_mem_map {f} {b : β} {s : Stream' α} : b ∈ map f s → ∃ a, a ∈ s ∧ f a = b :=
fun ⟨n, h⟩ => ⟨get s n, ⟨n, rfl⟩, h.symm⟩
end Map
section Zip
variable (f : α → β → δ)
theorem drop_zip (n : ℕ) (s₁ : Stream' α) (s₂ : Stream' β) :
drop n (zip f s₁ s₂) = zip f (drop n s₁) (drop n s₂) :=
Stream'.ext fun _ => rfl
@[simp]
theorem get_zip (n : ℕ) (s₁ : Stream' α) (s₂ : Stream' β) :
get (zip f s₁ s₂) n = f (get s₁ n) (get s₂ n) :=
rfl
theorem head_zip (s₁ : Stream' α) (s₂ : Stream' β) : head (zip f s₁ s₂) = f (head s₁) (head s₂) :=
rfl
theorem tail_zip (s₁ : Stream' α) (s₂ : Stream' β) :
tail (zip f s₁ s₂) = zip f (tail s₁) (tail s₂) :=
rfl
theorem zip_eq (s₁ : Stream' α) (s₂ : Stream' β) :
zip f s₁ s₂ = f (head s₁) (head s₂)::zip f (tail s₁) (tail s₂) := by
rw [← Stream'.eta (zip f s₁ s₂)]; rfl
@[simp]
theorem get_enum (s : Stream' α) (n : ℕ) : get (enum s) n = (n, s.get n) :=
rfl
theorem enum_eq_zip (s : Stream' α) : enum s = zip Prod.mk nats s :=
rfl
end Zip
@[simp]
theorem mem_const (a : α) : a ∈ const a :=
Exists.intro 0 rfl
theorem const_eq (a : α) : const a = a::const a := by
apply Stream'.ext; intro n
cases n <;> rfl
@[simp]
theorem tail_const (a : α) : tail (const a) = const a :=
suffices tail (a::const a) = const a by rwa [← const_eq] at this
rfl
@[simp]
theorem map_const (f : α → β) (a : α) : map f (const a) = const (f a) :=
rfl
@[simp]
theorem get_const (n : ℕ) (a : α) : get (const a) n = a :=
rfl
@[simp]
theorem drop_const (n : ℕ) (a : α) : drop n (const a) = const a :=
Stream'.ext fun _ => rfl
@[simp]
theorem head_iterate (f : α → α) (a : α) : head (iterate f a) = a :=
rfl
theorem get_succ_iterate' (n : ℕ) (f : α → α) (a : α) :
get (iterate f a) (succ n) = f (get (iterate f a) n) := rfl
theorem tail_iterate (f : α → α) (a : α) : tail (iterate f a) = iterate f (f a) := by
ext n
rw [get_tail]
induction' n with n' ih
· rfl
· rw [get_succ_iterate', ih, get_succ_iterate']
theorem iterate_eq (f : α → α) (a : α) : iterate f a = a::iterate f (f a) := by
rw [← Stream'.eta (iterate f a)]
rw [tail_iterate]; rfl
@[simp]
theorem get_zero_iterate (f : α → α) (a : α) : get (iterate f a) 0 = a :=
rfl
theorem get_succ_iterate (n : ℕ) (f : α → α) (a : α) :
get (iterate f a) (succ n) = get (iterate f (f a)) n := by rw [get_succ, tail_iterate]
section Bisim
variable (R : Stream' α → Stream' α → Prop)
/-- equivalence relation -/
local infixl:50 " ~ " => R
/-- Streams `s₁` and `s₂` are defined to be bisimulations if
their heads are equal and tails are bisimulations. -/
def IsBisimulation :=
∀ ⦃s₁ s₂⦄, s₁ ~ s₂ →
head s₁ = head s₂ ∧ tail s₁ ~ tail s₂
theorem get_of_bisim (bisim : IsBisimulation R) {s₁ s₂} :
∀ n, s₁ ~ s₂ → get s₁ n = get s₂ n ∧ drop (n + 1) s₁ ~ drop (n + 1) s₂
| 0, h => bisim h
| n + 1, h =>
match bisim h with
| ⟨_, trel⟩ => get_of_bisim bisim n trel
-- If two streams are bisimilar, then they are equal
theorem eq_of_bisim (bisim : IsBisimulation R) {s₁ s₂} : s₁ ~ s₂ → s₁ = s₂ := fun r =>
Stream'.ext fun n => And.left (get_of_bisim R bisim n r)
end Bisim
theorem bisim_simple (s₁ s₂ : Stream' α) :
head s₁ = head s₂ → s₁ = tail s₁ → s₂ = tail s₂ → s₁ = s₂ := fun hh ht₁ ht₂ =>
eq_of_bisim (fun s₁ s₂ => head s₁ = head s₂ ∧ s₁ = tail s₁ ∧ s₂ = tail s₂)
(fun s₁ s₂ ⟨h₁, h₂, h₃⟩ => by
constructor
· exact h₁
rw [← h₂, ← h₃]
(repeat' constructor) <;> assumption)
(And.intro hh (And.intro ht₁ ht₂))
theorem coinduction {s₁ s₂ : Stream' α} :
head s₁ = head s₂ →
(∀ (β : Type u) (fr : Stream' α → β),
fr s₁ = fr s₂ → fr (tail s₁) = fr (tail s₂)) → s₁ = s₂ :=
fun hh ht =>
eq_of_bisim
(fun s₁ s₂ =>
head s₁ = head s₂ ∧
∀ (β : Type u) (fr : Stream' α → β), fr s₁ = fr s₂ → fr (tail s₁) = fr (tail s₂))
(fun s₁ s₂ h =>
have h₁ : head s₁ = head s₂ := And.left h
have h₂ : head (tail s₁) = head (tail s₂) := And.right h α (@head α) h₁
have h₃ :
∀ (β : Type u) (fr : Stream' α → β),
fr (tail s₁) = fr (tail s₂) → fr (tail (tail s₁)) = fr (tail (tail s₂)) :=
fun β fr => And.right h β fun s => fr (tail s)
And.intro h₁ (And.intro h₂ h₃))
(And.intro hh ht)
@[simp]
theorem iterate_id (a : α) : iterate id a = const a :=
coinduction rfl fun β fr ch => by rw [tail_iterate, tail_const]; exact ch
theorem map_iterate (f : α → α) (a : α) : iterate f (f a) = map f (iterate f a) := by
funext n
induction' n with n' ih
· rfl
· unfold map iterate get
rw [map, get] at ih
rw [iterate]
exact congrArg f ih
section Corec
theorem corec_def (f : α → β) (g : α → α) (a : α) : corec f g a = map f (iterate g a) :=
rfl
theorem corec_eq (f : α → β) (g : α → α) (a : α) : corec f g a = f a :: corec f g (g a) := by
rw [corec_def, map_eq, head_iterate, tail_iterate]; rfl
theorem corec_id_id_eq_const (a : α) : corec id id a = const a := by
rw [corec_def, map_id, iterate_id]
theorem corec_id_f_eq_iterate (f : α → α) (a : α) : corec id f a = iterate f a :=
rfl
end Corec
section Corec'
theorem corec'_eq (f : α → β × α) (a : α) : corec' f a = (f a).1 :: corec' f (f a).2 :=
corec_eq _ _ _
end Corec'
theorem unfolds_eq (g : α → β) (f : α → α) (a : α) : unfolds g f a = g a :: unfolds g f (f a) := by
unfold unfolds; rw [corec_eq]
theorem get_unfolds_head_tail : ∀ (n : ℕ) (s : Stream' α),
get (unfolds head tail s) n = get s n := by
intro n; induction' n with n' ih
· intro s
rfl
· intro s
rw [get_succ, get_succ, unfolds_eq, tail_cons, ih]
theorem unfolds_head_eq : ∀ s : Stream' α, unfolds head tail s = s := fun s =>
Stream'.ext fun n => get_unfolds_head_tail n s
theorem interleave_eq (s₁ s₂ : Stream' α) : s₁ ⋈ s₂ = head s₁::head s₂::(tail s₁ ⋈ tail s₂) := by
let t := tail s₁ ⋈ tail s₂
show s₁ ⋈ s₂ = head s₁::head s₂::t
unfold interleave; unfold corecOn; rw [corec_eq]; dsimp; rw [corec_eq]; rfl
theorem tail_interleave (s₁ s₂ : Stream' α) : tail (s₁ ⋈ s₂) = s₂ ⋈ tail s₁ := by
unfold interleave corecOn; rw [corec_eq]; rfl
theorem interleave_tail_tail (s₁ s₂ : Stream' α) : tail s₁ ⋈ tail s₂ = tail (tail (s₁ ⋈ s₂)) := by
rw [interleave_eq s₁ s₂]; rfl
theorem get_interleave_left : ∀ (n : ℕ) (s₁ s₂ : Stream' α),
get (s₁ ⋈ s₂) (2 * n) = get s₁ n
| 0, _, _ => rfl
| n + 1, s₁, s₂ => by
change get (s₁ ⋈ s₂) (succ (succ (2 * n))) = get s₁ (succ n)
rw [get_succ, get_succ, interleave_eq, tail_cons, tail_cons]
rw [get_interleave_left n (tail s₁) (tail s₂)]
rfl
theorem get_interleave_right : ∀ (n : ℕ) (s₁ s₂ : Stream' α),
get (s₁ ⋈ s₂) (2 * n + 1) = get s₂ n
| 0, _, _ => rfl
| n + 1, s₁, s₂ => by
change get (s₁ ⋈ s₂) (succ (succ (2 * n + 1))) = get s₂ (succ n)
rw [get_succ, get_succ, interleave_eq, tail_cons, tail_cons,
get_interleave_right n (tail s₁) (tail s₂)]
rfl
theorem mem_interleave_left {a : α} {s₁ : Stream' α} (s₂ : Stream' α) : a ∈ s₁ → a ∈ s₁ ⋈ s₂ :=
fun ⟨n, h⟩ => Exists.intro (2 * n) (by rw [h, get_interleave_left])
theorem mem_interleave_right {a : α} {s₁ : Stream' α} (s₂ : Stream' α) : a ∈ s₂ → a ∈ s₁ ⋈ s₂ :=
fun ⟨n, h⟩ => Exists.intro (2 * n + 1) (by rw [h, get_interleave_right])
theorem odd_eq (s : Stream' α) : odd s = even (tail s) :=
rfl
@[simp]
theorem head_even (s : Stream' α) : head (even s) = head s :=
rfl
theorem tail_even (s : Stream' α) : tail (even s) = even (tail (tail s)) := by
unfold even
rw [corec_eq]
rfl
theorem even_cons_cons (a₁ a₂ : α) (s : Stream' α) : even (a₁::a₂::s) = a₁::even s := by
unfold even
rw [corec_eq]; rfl
theorem even_tail (s : Stream' α) : even (tail s) = odd s :=
rfl
theorem even_interleave (s₁ s₂ : Stream' α) : even (s₁ ⋈ s₂) = s₁ :=
eq_of_bisim (fun s₁' s₁ => ∃ s₂, s₁' = even (s₁ ⋈ s₂))
(fun s₁' s₁ ⟨s₂, h₁⟩ => by
rw [h₁]
constructor
· rfl
· exact ⟨tail s₂, by rw [interleave_eq, even_cons_cons, tail_cons]⟩)
(Exists.intro s₂ rfl)
theorem interleave_even_odd (s₁ : Stream' α) : even s₁ ⋈ odd s₁ = s₁ :=
eq_of_bisim (fun s' s => s' = even s ⋈ odd s)
(fun s' s (h : s' = even s ⋈ odd s) => by
rw [h]; constructor
· rfl
· simp [odd_eq, odd_eq, tail_interleave, tail_even])
rfl
theorem get_even : ∀ (n : ℕ) (s : Stream' α), get (even s) n = get s (2 * n)
| 0, _ => rfl
| succ n, s => by
change get (even s) (succ n) = get s (succ (succ (2 * n)))
rw [get_succ, get_succ, tail_even, get_even n]; rfl
theorem get_odd : ∀ (n : ℕ) (s : Stream' α), get (odd s) n = get s (2 * n + 1) := fun n s => by
rw [odd_eq, get_even]; rfl
theorem mem_of_mem_even (a : α) (s : Stream' α) : a ∈ even s → a ∈ s := fun ⟨n, h⟩ =>
Exists.intro (2 * n) (by rw [h, get_even])
theorem mem_of_mem_odd (a : α) (s : Stream' α) : a ∈ odd s → a ∈ s := fun ⟨n, h⟩ =>
Exists.intro (2 * n + 1) (by rw [h, get_odd])
@[simp] theorem nil_append_stream (s : Stream' α) : appendStream' [] s = s :=
rfl
theorem cons_append_stream (a : α) (l : List α) (s : Stream' α) :
appendStream' (a::l) s = a::appendStream' l s :=
rfl
@[simp] theorem append_append_stream : ∀ (l₁ l₂ : List α) (s : Stream' α),
l₁ ++ l₂ ++ₛ s = l₁ ++ₛ (l₂ ++ₛ s)
| [], _, _ => rfl
| List.cons a l₁, l₂, s => by
rw [List.cons_append, cons_append_stream, cons_append_stream, append_append_stream l₁]
lemma get_append_left (h : n < x.length) : (x ++ₛ a).get n = x[n] := by
induction' x with b x ih generalizing n
· simp at h
· rcases n with (_ | n)
· simp
· simp [ih n (by simpa using h), cons_append_stream]
@[simp] lemma get_append_right : (x ++ₛ a).get (x.length + n) = a.get n := by
induction' x <;> simp [Nat.succ_add, *, cons_append_stream]
@[simp] lemma get_append_length : (x ++ₛ a).get x.length = a.get 0 := get_append_right 0 x a
lemma append_right_injective (h : x ++ₛ a = x ++ₛ b) : a = b := by
ext n; replace h := congr_arg (fun a ↦ a.get (x.length + n)) h; simpa using h
@[simp] lemma append_right_inj : x ++ₛ a = x ++ₛ b ↔ a = b :=
⟨append_right_injective x a b, by simp +contextual⟩
lemma append_left_injective (h : x ++ₛ a = y ++ₛ b) (hl : x.length = y.length) : x = y := by
apply List.ext_getElem hl
intros
rw [← get_append_left, ← get_append_left, h]
theorem map_append_stream (f : α → β) :
∀ (l : List α) (s : Stream' α), map f (l ++ₛ s) = List.map f l ++ₛ map f s
| [], _ => rfl
| List.cons a l, s => by
rw [cons_append_stream, List.map_cons, map_cons, cons_append_stream, map_append_stream f l]
theorem drop_append_stream : ∀ (l : List α) (s : Stream' α), drop l.length (l ++ₛ s) = s
| [], s => by rfl
| List.cons a l, s => by
rw [List.length_cons, drop_succ, cons_append_stream, tail_cons, drop_append_stream l s]
theorem append_stream_head_tail (s : Stream' α) : [head s] ++ₛ tail s = s := by
simp
theorem mem_append_stream_right : ∀ {a : α} (l : List α) {s : Stream' α}, a ∈ s → a ∈ l ++ₛ s
| | _, [], _, h => h
| a, List.cons _ l, s, h =>
have ih : a ∈ l ++ₛ s := mem_append_stream_right l h
mem_cons_of_mem _ ih
theorem mem_append_stream_left : ∀ {a : α} {l : List α} (s : Stream' α), a ∈ l → a ∈ l ++ₛ s
| _, [], _, h => absurd h List.not_mem_nil
| Mathlib/Data/Stream/Init.lean | 492 | 498 |
/-
Copyright (c) 2021 Yaël Dillies. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies, Violeta Hernández Palacios, Grayson Burton, Floris van Doorn
-/
import Mathlib.Order.Antisymmetrization
import Mathlib.Order.Hom.WithTopBot
import Mathlib.Order.Interval.Set.OrdConnected
import Mathlib.Order.Interval.Set.WithBotTop
/-!
# The covering relation
This file proves properties of the covering relation in an order.
We say that `b` *covers* `a` if `a < b` and there is no element in between.
We say that `b` *weakly covers* `a` if `a ≤ b` and there is no element between `a` and `b`.
In a partial order this is equivalent to `a ⋖ b ∨ a = b`,
in a preorder this is equivalent to `a ⋖ b ∨ (a ≤ b ∧ b ≤ a)`
## Notation
* `a ⋖ b` means that `b` covers `a`.
* `a ⩿ b` means that `b` weakly covers `a`.
-/
open Set OrderDual
variable {α β : Type*}
section WeaklyCovers
section Preorder
variable [Preorder α] [Preorder β] {a b c : α}
theorem WCovBy.le (h : a ⩿ b) : a ≤ b :=
h.1
theorem WCovBy.refl (a : α) : a ⩿ a :=
⟨le_rfl, fun _ hc => hc.not_lt⟩
@[simp] lemma WCovBy.rfl : a ⩿ a := WCovBy.refl a
protected theorem Eq.wcovBy (h : a = b) : a ⩿ b :=
h ▸ WCovBy.rfl
theorem wcovBy_of_le_of_le (h1 : a ≤ b) (h2 : b ≤ a) : a ⩿ b :=
⟨h1, fun _ hac hcb => (hac.trans hcb).not_le h2⟩
alias LE.le.wcovBy_of_le := wcovBy_of_le_of_le
theorem AntisymmRel.wcovBy (h : AntisymmRel (· ≤ ·) a b) : a ⩿ b :=
wcovBy_of_le_of_le h.1 h.2
theorem WCovBy.wcovBy_iff_le (hab : a ⩿ b) : b ⩿ a ↔ b ≤ a :=
⟨fun h => h.le, fun h => h.wcovBy_of_le hab.le⟩
theorem wcovBy_of_eq_or_eq (hab : a ≤ b) (h : ∀ c, a ≤ c → c ≤ b → c = a ∨ c = b) : a ⩿ b :=
⟨hab, fun c ha hb => (h c ha.le hb.le).elim ha.ne' hb.ne⟩
theorem AntisymmRel.trans_wcovBy (hab : AntisymmRel (· ≤ ·) a b) (hbc : b ⩿ c) : a ⩿ c :=
⟨hab.1.trans hbc.le, fun _ had hdc => hbc.2 (hab.2.trans_lt had) hdc⟩
theorem wcovBy_congr_left (hab : AntisymmRel (· ≤ ·) a b) : a ⩿ c ↔ b ⩿ c :=
⟨hab.symm.trans_wcovBy, hab.trans_wcovBy⟩
theorem WCovBy.trans_antisymm_rel (hab : a ⩿ b) (hbc : AntisymmRel (· ≤ ·) b c) : a ⩿ c :=
⟨hab.le.trans hbc.1, fun _ had hdc => hab.2 had <| hdc.trans_le hbc.2⟩
theorem wcovBy_congr_right (hab : AntisymmRel (· ≤ ·) a b) : c ⩿ a ↔ c ⩿ b :=
⟨fun h => h.trans_antisymm_rel hab, fun h => h.trans_antisymm_rel hab.symm⟩
/-- If `a ≤ b`, then `b` does not cover `a` iff there's an element in between. -/
theorem not_wcovBy_iff (h : a ≤ b) : ¬a ⩿ b ↔ ∃ c, a < c ∧ c < b := by
simp_rw [WCovBy, h, true_and, not_forall, exists_prop, not_not]
instance WCovBy.isRefl : IsRefl α (· ⩿ ·) :=
⟨WCovBy.refl⟩
theorem WCovBy.Ioo_eq (h : a ⩿ b) : Ioo a b = ∅ :=
eq_empty_iff_forall_not_mem.2 fun _ hx => h.2 hx.1 hx.2
theorem wcovBy_iff_Ioo_eq : a ⩿ b ↔ a ≤ b ∧ Ioo a b = ∅ :=
and_congr_right' <| by simp [eq_empty_iff_forall_not_mem]
lemma WCovBy.of_le_of_le (hac : a ⩿ c) (hab : a ≤ b) (hbc : b ≤ c) : b ⩿ c :=
⟨hbc, fun _x hbx hxc ↦ hac.2 (hab.trans_lt hbx) hxc⟩
lemma WCovBy.of_le_of_le' (hac : a ⩿ c) (hab : a ≤ b) (hbc : b ≤ c) : a ⩿ b :=
⟨hab, fun _x hax hxb ↦ hac.2 hax <| hxb.trans_le hbc⟩
theorem WCovBy.of_image (f : α ↪o β) (h : f a ⩿ f b) : a ⩿ b :=
⟨f.le_iff_le.mp h.le, fun _ hac hcb => h.2 (f.lt_iff_lt.mpr hac) (f.lt_iff_lt.mpr hcb)⟩
theorem WCovBy.image (f : α ↪o β) (hab : a ⩿ b) (h : (range f).OrdConnected) : f a ⩿ f b := by
refine ⟨f.monotone hab.le, fun c ha hb => ?_⟩
obtain ⟨c, rfl⟩ := h.out (mem_range_self _) (mem_range_self _) ⟨ha.le, hb.le⟩
rw [f.lt_iff_lt] at ha hb
exact hab.2 ha hb
theorem Set.OrdConnected.apply_wcovBy_apply_iff (f : α ↪o β) (h : (range f).OrdConnected) :
f a ⩿ f b ↔ a ⩿ b :=
⟨fun h2 => h2.of_image f, fun hab => hab.image f h⟩
@[simp]
theorem apply_wcovBy_apply_iff {E : Type*} [EquivLike E α β] [OrderIsoClass E α β] (e : E) :
e a ⩿ e b ↔ a ⩿ b :=
(ordConnected_range (e : α ≃o β)).apply_wcovBy_apply_iff ((e : α ≃o β) : α ↪o β)
@[simp]
theorem toDual_wcovBy_toDual_iff : toDual b ⩿ toDual a ↔ a ⩿ b :=
and_congr_right' <| forall_congr' fun _ => forall_swap
@[simp]
theorem ofDual_wcovBy_ofDual_iff {a b : αᵒᵈ} : ofDual a ⩿ ofDual b ↔ b ⩿ a :=
and_congr_right' <| forall_congr' fun _ => forall_swap
alias ⟨_, WCovBy.toDual⟩ := toDual_wcovBy_toDual_iff
alias ⟨_, WCovBy.ofDual⟩ := ofDual_wcovBy_ofDual_iff
theorem OrderEmbedding.wcovBy_of_apply {α β : Type*} [Preorder α] [Preorder β]
(f : α ↪o β) {x y : α} (h : f x ⩿ f y) : x ⩿ y := by
use f.le_iff_le.1 h.1
intro a
rw [← f.lt_iff_lt, ← f.lt_iff_lt]
apply h.2
theorem OrderIso.map_wcovBy {α β : Type*} [Preorder α] [Preorder β]
(f : α ≃o β) {x y : α} : f x ⩿ f y ↔ x ⩿ y := by
use f.toOrderEmbedding.wcovBy_of_apply
conv_lhs => rw [← f.symm_apply_apply x, ← f.symm_apply_apply y]
exact f.symm.toOrderEmbedding.wcovBy_of_apply
end Preorder
section PartialOrder
variable [PartialOrder α] {a b c : α}
theorem WCovBy.eq_or_eq (h : a ⩿ b) (h2 : a ≤ c) (h3 : c ≤ b) : c = a ∨ c = b := by
rcases h2.eq_or_lt with (h2 | h2); · exact Or.inl h2.symm
rcases h3.eq_or_lt with (h3 | h3); · exact Or.inr h3
exact (h.2 h2 h3).elim
/-- An `iff` version of `WCovBy.eq_or_eq` and `wcovBy_of_eq_or_eq`. -/
theorem wcovBy_iff_le_and_eq_or_eq : a ⩿ b ↔ a ≤ b ∧ ∀ c, a ≤ c → c ≤ b → c = a ∨ c = b :=
⟨fun h => ⟨h.le, fun _ => h.eq_or_eq⟩, And.rec wcovBy_of_eq_or_eq⟩
theorem WCovBy.le_and_le_iff (h : a ⩿ b) : a ≤ c ∧ c ≤ b ↔ c = a ∨ c = b := by
refine ⟨fun h2 => h.eq_or_eq h2.1 h2.2, ?_⟩; rintro (rfl | rfl)
exacts [⟨le_rfl, h.le⟩, ⟨h.le, le_rfl⟩]
theorem WCovBy.Icc_eq (h : a ⩿ b) : Icc a b = {a, b} := by
ext c
exact h.le_and_le_iff
theorem WCovBy.Ico_subset (h : a ⩿ b) : Ico a b ⊆ {a} := by
rw [← Icc_diff_right, h.Icc_eq, diff_singleton_subset_iff, pair_comm]
theorem WCovBy.Ioc_subset (h : a ⩿ b) : Ioc a b ⊆ {b} := by
rw [← Icc_diff_left, h.Icc_eq, diff_singleton_subset_iff]
end PartialOrder
section SemilatticeSup
variable [SemilatticeSup α] {a b c : α}
theorem WCovBy.sup_eq (hac : a ⩿ c) (hbc : b ⩿ c) (hab : a ≠ b) : a ⊔ b = c :=
(sup_le hac.le hbc.le).eq_of_not_lt fun h =>
hab.lt_sup_or_lt_sup.elim (fun h' => hac.2 h' h) fun h' => hbc.2 h' h
end SemilatticeSup
section SemilatticeInf
variable [SemilatticeInf α] {a b c : α}
theorem WCovBy.inf_eq (hca : c ⩿ a) (hcb : c ⩿ b) (hab : a ≠ b) : a ⊓ b = c :=
(le_inf hca.le hcb.le).eq_of_not_gt fun h => hab.inf_lt_or_inf_lt.elim (hca.2 h) (hcb.2 h)
end SemilatticeInf
end WeaklyCovers
section LT
variable [LT α] {a b : α}
theorem CovBy.lt (h : a ⋖ b) : a < b :=
h.1
/-- If `a < b`, then `b` does not cover `a` iff there's an element in between. -/
theorem not_covBy_iff (h : a < b) : ¬a ⋖ b ↔ ∃ c, a < c ∧ c < b := by
simp_rw [CovBy, h, true_and, not_forall, exists_prop, not_not]
alias ⟨exists_lt_lt_of_not_covBy, _⟩ := not_covBy_iff
alias LT.lt.exists_lt_lt := exists_lt_lt_of_not_covBy
/-- In a dense order, nothing covers anything. -/
theorem not_covBy [DenselyOrdered α] : ¬a ⋖ b := fun h =>
let ⟨_, hc⟩ := exists_between h.1
h.2 hc.1 hc.2
theorem denselyOrdered_iff_forall_not_covBy : DenselyOrdered α ↔ ∀ a b : α, ¬a ⋖ b :=
⟨fun h _ _ => @not_covBy _ _ _ _ h, fun h =>
⟨fun _ _ hab => exists_lt_lt_of_not_covBy hab <| h _ _⟩⟩
@[simp]
theorem toDual_covBy_toDual_iff : toDual b ⋖ toDual a ↔ a ⋖ b :=
and_congr_right' <| forall_congr' fun _ => forall_swap
@[simp]
theorem ofDual_covBy_ofDual_iff {a b : αᵒᵈ} : ofDual a ⋖ ofDual b ↔ b ⋖ a :=
and_congr_right' <| forall_congr' fun _ => forall_swap
alias ⟨_, CovBy.toDual⟩ := toDual_covBy_toDual_iff
alias ⟨_, CovBy.ofDual⟩ := ofDual_covBy_ofDual_iff
end LT
section Preorder
variable [Preorder α] [Preorder β] {a b c : α}
theorem CovBy.le (h : a ⋖ b) : a ≤ b :=
h.1.le
protected theorem CovBy.ne (h : a ⋖ b) : a ≠ b :=
h.lt.ne
theorem CovBy.ne' (h : a ⋖ b) : b ≠ a :=
h.lt.ne'
protected theorem CovBy.wcovBy (h : a ⋖ b) : a ⩿ b :=
⟨h.le, h.2⟩
theorem WCovBy.covBy_of_not_le (h : a ⩿ b) (h2 : ¬b ≤ a) : a ⋖ b :=
⟨h.le.lt_of_not_le h2, h.2⟩
theorem WCovBy.covBy_of_lt (h : a ⩿ b) (h2 : a < b) : a ⋖ b :=
⟨h2, h.2⟩
lemma CovBy.of_le_of_lt (hac : a ⋖ c) (hab : a ≤ b) (hbc : b < c) : b ⋖ c :=
⟨hbc, fun _x hbx hxc ↦ hac.2 (hab.trans_lt hbx) hxc⟩
lemma CovBy.of_lt_of_le (hac : a ⋖ c) (hab : a < b) (hbc : b ≤ c) : a ⋖ b :=
⟨hab, fun _x hax hxb ↦ hac.2 hax <| hxb.trans_le hbc⟩
theorem not_covBy_of_lt_of_lt (h₁ : a < b) (h₂ : b < c) : ¬a ⋖ c :=
(not_covBy_iff (h₁.trans h₂)).2 ⟨b, h₁, h₂⟩
theorem covBy_iff_wcovBy_and_lt : a ⋖ b ↔ a ⩿ b ∧ a < b :=
⟨fun h => ⟨h.wcovBy, h.lt⟩, fun h => h.1.covBy_of_lt h.2⟩
theorem covBy_iff_wcovBy_and_not_le : a ⋖ b ↔ a ⩿ b ∧ ¬b ≤ a :=
⟨fun h => ⟨h.wcovBy, h.lt.not_le⟩, fun h => h.1.covBy_of_not_le h.2⟩
theorem wcovBy_iff_covBy_or_le_and_le : a ⩿ b ↔ a ⋖ b ∨ a ≤ b ∧ b ≤ a :=
⟨fun h => or_iff_not_imp_right.mpr fun h' => h.covBy_of_not_le fun hba => h' ⟨h.le, hba⟩,
fun h' => h'.elim (fun h => h.wcovBy) fun h => h.1.wcovBy_of_le h.2⟩
alias ⟨WCovBy.covBy_or_le_and_le, _⟩ := wcovBy_iff_covBy_or_le_and_le
theorem AntisymmRel.trans_covBy (hab : AntisymmRel (· ≤ ·) a b) (hbc : b ⋖ c) : a ⋖ c :=
⟨hab.1.trans_lt hbc.lt, fun _ had hdc => hbc.2 (hab.2.trans_lt had) hdc⟩
theorem covBy_congr_left (hab : AntisymmRel (· ≤ ·) a b) : a ⋖ c ↔ b ⋖ c :=
⟨hab.symm.trans_covBy, hab.trans_covBy⟩
theorem CovBy.trans_antisymmRel (hab : a ⋖ b) (hbc : AntisymmRel (· ≤ ·) b c) : a ⋖ c :=
⟨hab.lt.trans_le hbc.1, fun _ had hdb => hab.2 had <| hdb.trans_le hbc.2⟩
theorem covBy_congr_right (hab : AntisymmRel (· ≤ ·) a b) : c ⋖ a ↔ c ⋖ b :=
⟨fun h => h.trans_antisymmRel hab, fun h => h.trans_antisymmRel hab.symm⟩
instance : IsNonstrictStrictOrder α (· ⩿ ·) (· ⋖ ·) :=
⟨fun _ _ =>
covBy_iff_wcovBy_and_not_le.trans <| and_congr_right fun h => h.wcovBy_iff_le.not.symm⟩
instance CovBy.isIrrefl : IsIrrefl α (· ⋖ ·) :=
⟨fun _ ha => ha.ne rfl⟩
theorem CovBy.Ioo_eq (h : a ⋖ b) : Ioo a b = ∅ :=
h.wcovBy.Ioo_eq
theorem covBy_iff_Ioo_eq : a ⋖ b ↔ a < b ∧ Ioo a b = ∅ :=
and_congr_right' <| by simp [eq_empty_iff_forall_not_mem]
theorem CovBy.of_image (f : α ↪o β) (h : f a ⋖ f b) : a ⋖ b :=
⟨f.lt_iff_lt.mp h.lt, fun _ hac hcb => h.2 (f.lt_iff_lt.mpr hac) (f.lt_iff_lt.mpr hcb)⟩
theorem CovBy.image (f : α ↪o β) (hab : a ⋖ b) (h : (range f).OrdConnected) : f a ⋖ f b :=
(hab.wcovBy.image f h).covBy_of_lt <| f.strictMono hab.lt
theorem Set.OrdConnected.apply_covBy_apply_iff (f : α ↪o β) (h : (range f).OrdConnected) :
f a ⋖ f b ↔ a ⋖ b :=
⟨CovBy.of_image f, fun hab => hab.image f h⟩
@[simp]
theorem apply_covBy_apply_iff {E : Type*} [EquivLike E α β] [OrderIsoClass E α β] (e : E) :
e a ⋖ e b ↔ a ⋖ b :=
(ordConnected_range (e : α ≃o β)).apply_covBy_apply_iff ((e : α ≃o β) : α ↪o β)
theorem covBy_of_eq_or_eq (hab : a < b) (h : ∀ c, a ≤ c → c ≤ b → c = a ∨ c = b) : a ⋖ b :=
⟨hab, fun c ha hb => (h c ha.le hb.le).elim ha.ne' hb.ne⟩
theorem OrderEmbedding.covBy_of_apply {α β : Type*} [Preorder α] [Preorder β]
(f : α ↪o β) {x y : α} (h : f x ⋖ f y) : x ⋖ y := by
use f.lt_iff_lt.1 h.1
intro a
rw [← f.lt_iff_lt, ← f.lt_iff_lt]
apply h.2
theorem OrderIso.map_covBy {α β : Type*} [Preorder α] [Preorder β]
(f : α ≃o β) {x y : α} : f x ⋖ f y ↔ x ⋖ y := by
use f.toOrderEmbedding.covBy_of_apply
conv_lhs => rw [← f.symm_apply_apply x, ← f.symm_apply_apply y]
exact f.symm.toOrderEmbedding.covBy_of_apply
end Preorder
section PartialOrder
variable [PartialOrder α] {a b c : α}
theorem WCovBy.covBy_of_ne (h : a ⩿ b) (h2 : a ≠ b) : a ⋖ b :=
⟨h.le.lt_of_ne h2, h.2⟩
theorem covBy_iff_wcovBy_and_ne : a ⋖ b ↔ a ⩿ b ∧ a ≠ b :=
⟨fun h => ⟨h.wcovBy, h.ne⟩, fun h => h.1.covBy_of_ne h.2⟩
theorem wcovBy_iff_covBy_or_eq : a ⩿ b ↔ a ⋖ b ∨ a = b := by
rw [le_antisymm_iff, wcovBy_iff_covBy_or_le_and_le]
theorem wcovBy_iff_eq_or_covBy : a ⩿ b ↔ a = b ∨ a ⋖ b :=
wcovBy_iff_covBy_or_eq.trans or_comm
alias ⟨WCovBy.covBy_or_eq, _⟩ := wcovBy_iff_covBy_or_eq
alias ⟨WCovBy.eq_or_covBy, _⟩ := wcovBy_iff_eq_or_covBy
theorem CovBy.eq_or_eq (h : a ⋖ b) (h2 : a ≤ c) (h3 : c ≤ b) : c = a ∨ c = b :=
h.wcovBy.eq_or_eq h2 h3
/-- An `iff` version of `CovBy.eq_or_eq` and `covBy_of_eq_or_eq`. -/
theorem covBy_iff_lt_and_eq_or_eq : a ⋖ b ↔ a < b ∧ ∀ c, a ≤ c → c ≤ b → c = a ∨ c = b :=
⟨fun h => ⟨h.lt, fun _ => h.eq_or_eq⟩, And.rec covBy_of_eq_or_eq⟩
theorem CovBy.Ico_eq (h : a ⋖ b) : Ico a b = {a} := by
rw [← Ioo_union_left h.lt, h.Ioo_eq, empty_union]
theorem CovBy.Ioc_eq (h : a ⋖ b) : Ioc a b = {b} := by
rw [← Ioo_union_right h.lt, h.Ioo_eq, empty_union]
theorem CovBy.Icc_eq (h : a ⋖ b) : Icc a b = {a, b} :=
h.wcovBy.Icc_eq
end PartialOrder
section LinearOrder
variable [LinearOrder α] {a b c : α}
theorem CovBy.Ioi_eq (h : a ⋖ b) : Ioi a = Ici b := by
rw [← Ioo_union_Ici_eq_Ioi h.lt, h.Ioo_eq, empty_union]
theorem CovBy.Iio_eq (h : a ⋖ b) : Iio b = Iic a := by
rw [← Iic_union_Ioo_eq_Iio h.lt, h.Ioo_eq, union_empty]
theorem WCovBy.le_of_lt (hab : a ⩿ b) (hcb : c < b) : c ≤ a :=
not_lt.1 fun hac => hab.2 hac hcb
theorem WCovBy.ge_of_gt (hab : a ⩿ b) (hac : a < c) : b ≤ c :=
not_lt.1 <| hab.2 hac
theorem CovBy.le_of_lt (hab : a ⋖ b) : c < b → c ≤ a :=
hab.wcovBy.le_of_lt
theorem CovBy.ge_of_gt (hab : a ⋖ b) : a < c → b ≤ c :=
hab.wcovBy.ge_of_gt
theorem CovBy.unique_left (ha : a ⋖ c) (hb : b ⋖ c) : a = b :=
(hb.le_of_lt ha.lt).antisymm <| ha.le_of_lt hb.lt
theorem CovBy.unique_right (hb : a ⋖ b) (hc : a ⋖ c) : b = c :=
(hb.ge_of_gt hc.lt).antisymm <| hc.ge_of_gt hb.lt
/-- If `a`, `b`, `c` are consecutive and `a < x < c` then `x = b`. -/
theorem CovBy.eq_of_between {x : α} (hab : a ⋖ b) (hbc : b ⋖ c) (hax : a < x) (hxc : x < c) :
x = b :=
le_antisymm (le_of_not_lt fun h => hbc.2 h hxc) (le_of_not_lt <| hab.2 hax)
theorem covBy_iff_lt_iff_le_left {x y : α} : x ⋖ y ↔ ∀ {z}, z < y ↔ z ≤ x where
mp := fun hx _z ↦ ⟨hx.le_of_lt, fun hz ↦ hz.trans_lt hx.lt⟩
mpr := fun H ↦ ⟨H.2 le_rfl, fun _z hx hz ↦ (H.1 hz).not_lt hx⟩
theorem covBy_iff_le_iff_lt_left {x y : α} : x ⋖ y ↔ ∀ {z}, z ≤ x ↔ z < y := by
simp_rw [covBy_iff_lt_iff_le_left, iff_comm]
theorem covBy_iff_lt_iff_le_right {x y : α} : x ⋖ y ↔ ∀ {z}, x < z ↔ y ≤ z := by
trans ∀ {z}, ¬ z ≤ x ↔ ¬ z < y
· simp_rw [covBy_iff_le_iff_lt_left, not_iff_not]
· simp
theorem covBy_iff_le_iff_lt_right {x y : α} : x ⋖ y ↔ ∀ {z}, y ≤ z ↔ x < z := by
simp_rw [covBy_iff_lt_iff_le_right, iff_comm]
alias ⟨CovBy.lt_iff_le_left, _⟩ := covBy_iff_lt_iff_le_left
alias ⟨CovBy.le_iff_lt_left, _⟩ := covBy_iff_le_iff_lt_left
alias ⟨CovBy.lt_iff_le_right, _⟩ := covBy_iff_lt_iff_le_right
alias ⟨CovBy.le_iff_lt_right, _⟩ := covBy_iff_le_iff_lt_right
/-- If `a < b` then there exist `a' > a` and `b' < b` such that `Set.Iio a'` is strictly to the left
of `Set.Ioi b'`. -/
lemma LT.lt.exists_disjoint_Iio_Ioi (h : a < b) :
∃ a' > a, ∃ b' < b, ∀ x < a', ∀ y > b', x < y := by
by_cases h' : a ⋖ b
· exact ⟨b, h, a, h, fun x hx y hy => hx.trans_le <| h'.ge_of_gt hy⟩
· rcases h.exists_lt_lt h' with ⟨c, ha, hb⟩
exact ⟨c, ha, c, hb, fun _ h₁ _ => lt_trans h₁⟩
end LinearOrder
namespace Bool
@[simp] theorem wcovBy_iff : ∀ {a b : Bool}, a ⩿ b ↔ a ≤ b := by unfold WCovBy; decide
@[simp] theorem covBy_iff : ∀ {a b : Bool}, a ⋖ b ↔ a < b := by unfold CovBy; decide
instance instDecidableRelWCovBy : DecidableRel (· ⩿ · : Bool → Bool → Prop) := fun _ _ ↦
decidable_of_iff _ wcovBy_iff.symm
instance instDecidableRelCovBy : DecidableRel (· ⋖ · : Bool → Bool → Prop) := fun _ _ ↦
decidable_of_iff _ covBy_iff.symm
end Bool
namespace Set
variable {s t : Set α} {a : α}
@[simp] lemma wcovBy_insert (x : α) (s : Set α) : s ⩿ insert x s := by
refine wcovBy_of_eq_or_eq (subset_insert x s) fun t hst h2t => ?_
by_cases h : x ∈ t
· exact Or.inr (subset_antisymm h2t <| insert_subset_iff.mpr ⟨h, hst⟩)
· refine Or.inl (subset_antisymm ?_ hst)
rwa [← diff_singleton_eq_self h, diff_singleton_subset_iff]
@[simp] lemma sdiff_singleton_wcovBy (s : Set α) (a : α) : s \ {a} ⩿ s := by
by_cases ha : a ∈ s
· convert wcovBy_insert a _
ext
simp [ha]
· simp [ha]
@[simp] lemma covBy_insert (ha : a ∉ s) : s ⋖ insert a s :=
(wcovBy_insert _ _).covBy_of_lt <| ssubset_insert ha
@[simp] lemma sdiff_singleton_covBy (ha : a ∈ s) : s \ {a} ⋖ s :=
⟨sdiff_lt (singleton_subset_iff.2 ha) <| singleton_ne_empty _, (sdiff_singleton_wcovBy _ _).2⟩
lemma _root_.CovBy.exists_set_insert (h : s ⋖ t) : ∃ a ∉ s, insert a s = t :=
let ⟨a, ha, hst⟩ := ssubset_iff_insert.1 h.lt
⟨a, ha, (hst.eq_of_not_ssuperset <| h.2 <| ssubset_insert ha).symm⟩
lemma _root_.CovBy.exists_set_sdiff_singleton (h : s ⋖ t) : ∃ a ∈ t, t \ {a} = s :=
let ⟨a, ha, hst⟩ := ssubset_iff_sdiff_singleton.1 h.lt
⟨a, ha, (hst.eq_of_not_ssubset fun h' ↦ h.2 h' <|
sdiff_lt (singleton_subset_iff.2 ha) <| singleton_ne_empty _).symm⟩
lemma covBy_iff_exists_insert : s ⋖ t ↔ ∃ a ∉ s, insert a s = t :=
⟨CovBy.exists_set_insert, by rintro ⟨a, ha, rfl⟩; exact covBy_insert ha⟩
lemma covBy_iff_exists_sdiff_singleton : s ⋖ t ↔ ∃ a ∈ t, t \ {a} = s :=
⟨CovBy.exists_set_sdiff_singleton, by rintro ⟨a, ha, rfl⟩; exact sdiff_singleton_covBy ha⟩
end Set
section Relation
open Relation
lemma wcovBy_eq_reflGen_covBy [PartialOrder α] : ((· : α) ⩿ ·) = ReflGen (· ⋖ ·) := by
ext x y; simp_rw [wcovBy_iff_eq_or_covBy, @eq_comm _ x, reflGen_iff]
lemma transGen_wcovBy_eq_reflTransGen_covBy [PartialOrder α] :
TransGen ((· : α) ⩿ ·) = ReflTransGen (· ⋖ ·) := by
rw [wcovBy_eq_reflGen_covBy, transGen_reflGen]
lemma reflTransGen_wcovBy_eq_reflTransGen_covBy [PartialOrder α] :
ReflTransGen ((· : α) ⩿ ·) = ReflTransGen (· ⋖ ·) := by
rw [wcovBy_eq_reflGen_covBy, reflTransGen_reflGen]
end Relation
namespace Prod
variable [PartialOrder α] [PartialOrder β] {a a₁ a₂ : α} {b b₁ b₂ : β} {x y : α × β}
@[simp]
theorem swap_wcovBy_swap : x.swap ⩿ y.swap ↔ x ⩿ y :=
apply_wcovBy_apply_iff (OrderIso.prodComm : α × β ≃o β × α)
@[simp]
theorem swap_covBy_swap : x.swap ⋖ y.swap ↔ x ⋖ y :=
apply_covBy_apply_iff (OrderIso.prodComm : α × β ≃o β × α)
theorem fst_eq_or_snd_eq_of_wcovBy : x ⩿ y → x.1 = y.1 ∨ x.2 = y.2 := by
refine fun h => of_not_not fun hab => ?_
push_neg at hab
exact
h.2 (mk_lt_mk.2 <| Or.inl ⟨hab.1.lt_of_le h.1.1, le_rfl⟩)
(mk_lt_mk.2 <| Or.inr ⟨le_rfl, hab.2.lt_of_le h.1.2⟩)
| theorem _root_.WCovBy.fst (h : x ⩿ y) : x.1 ⩿ y.1 :=
⟨h.1.1, fun _ h₁ h₂ => h.2 (mk_lt_mk_iff_left.2 h₁) ⟨⟨h₂.le, h.1.2⟩, fun hc => h₂.not_le hc.1⟩⟩
| Mathlib/Order/Cover.lean | 518 | 519 |
/-
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
theorem sOppSide_lineMap_left {s : AffineSubspace R P} {x y : P} (hx : x ∈ s) (hy : y ∉ s) {t : R}
(ht : t < 0) : s.SOppSide (lineMap x y t) y :=
sOppSide_smul_vsub_vadd_left hy hx hx ht
theorem sOppSide_lineMap_right {s : AffineSubspace R P} {x y : P} (hx : x ∈ s) (hy : y ∉ s) {t : R}
(ht : t < 0) : s.SOppSide y (lineMap x y t) :=
(sOppSide_lineMap_left hx hy ht).symm
theorem setOf_wSameSide_eq_image2 {s : AffineSubspace R P} {x p : P} (hx : x ∉ s) (hp : p ∈ s) :
{ y | s.WSameSide x y } = Set.image2 (fun (t : R) q => t • (x -ᵥ p) +ᵥ q) (Set.Ici 0) s := by
ext y
simp_rw [Set.mem_setOf, Set.mem_image2, Set.mem_Ici]
constructor
· rw [wSameSide_iff_exists_left hp, or_iff_right hx]
rintro ⟨p₂, hp₂, h | h | ⟨r₁, r₂, hr₁, hr₂, h⟩⟩
· rw [vsub_eq_zero_iff_eq] at h
exact False.elim (hx (h.symm ▸ hp))
· rw [vsub_eq_zero_iff_eq] at h
refine ⟨0, le_rfl, p₂, hp₂, ?_⟩
simp [h]
· refine ⟨r₁ / r₂, (div_pos hr₁ hr₂).le, p₂, hp₂, ?_⟩
rw [div_eq_inv_mul, ← smul_smul, h, smul_smul, inv_mul_cancel₀ hr₂.ne.symm, one_smul,
vsub_vadd]
· rintro ⟨t, ht, p', hp', rfl⟩
exact wSameSide_smul_vsub_vadd_right x hp hp' ht
theorem setOf_sSameSide_eq_image2 {s : AffineSubspace R P} {x p : P} (hx : x ∉ s) (hp : p ∈ s) :
{ y | s.SSameSide x y } = Set.image2 (fun (t : R) q => t • (x -ᵥ p) +ᵥ q) (Set.Ioi 0) s := by
ext y
simp_rw [Set.mem_setOf, Set.mem_image2, Set.mem_Ioi]
constructor
· rw [sSameSide_iff_exists_left hp]
rintro ⟨-, hy, p₂, hp₂, h | h | ⟨r₁, r₂, hr₁, hr₂, h⟩⟩
· rw [vsub_eq_zero_iff_eq] at h
exact False.elim (hx (h.symm ▸ hp))
· rw [vsub_eq_zero_iff_eq] at h
exact False.elim (hy (h.symm ▸ hp₂))
· refine ⟨r₁ / r₂, div_pos hr₁ hr₂, p₂, hp₂, ?_⟩
rw [div_eq_inv_mul, ← smul_smul, h, smul_smul, inv_mul_cancel₀ hr₂.ne.symm, one_smul,
vsub_vadd]
· rintro ⟨t, ht, p', hp', rfl⟩
exact sSameSide_smul_vsub_vadd_right hx hp hp' ht
theorem setOf_wOppSide_eq_image2 {s : AffineSubspace R P} {x p : P} (hx : x ∉ s) (hp : p ∈ s) :
{ y | s.WOppSide x y } = Set.image2 (fun (t : R) q => t • (x -ᵥ p) +ᵥ q) (Set.Iic 0) s := by
ext y
simp_rw [Set.mem_setOf, Set.mem_image2, Set.mem_Iic]
constructor
· rw [wOppSide_iff_exists_left hp, or_iff_right hx]
rintro ⟨p₂, hp₂, h | h | ⟨r₁, r₂, hr₁, hr₂, h⟩⟩
· rw [vsub_eq_zero_iff_eq] at h
exact False.elim (hx (h.symm ▸ hp))
· rw [vsub_eq_zero_iff_eq] at h
refine ⟨0, le_rfl, p₂, hp₂, ?_⟩
simp [h]
· refine ⟨-r₁ / r₂, (div_neg_of_neg_of_pos (Left.neg_neg_iff.2 hr₁) hr₂).le, p₂, hp₂, ?_⟩
rw [div_eq_inv_mul, ← smul_smul, neg_smul, h, smul_neg, smul_smul,
inv_mul_cancel₀ hr₂.ne.symm, one_smul, neg_vsub_eq_vsub_rev, vsub_vadd]
· rintro ⟨t, ht, p', hp', rfl⟩
exact wOppSide_smul_vsub_vadd_right x hp hp' ht
theorem setOf_sOppSide_eq_image2 {s : AffineSubspace R P} {x p : P} (hx : x ∉ s) (hp : p ∈ s) :
{ y | s.SOppSide x y } = Set.image2 (fun (t : R) q => t • (x -ᵥ p) +ᵥ q) (Set.Iio 0) s := by
ext y
simp_rw [Set.mem_setOf, Set.mem_image2, Set.mem_Iio]
constructor
· rw [sOppSide_iff_exists_left hp]
rintro ⟨-, hy, p₂, hp₂, h | h | ⟨r₁, r₂, hr₁, hr₂, h⟩⟩
· rw [vsub_eq_zero_iff_eq] at h
exact False.elim (hx (h.symm ▸ hp))
· rw [vsub_eq_zero_iff_eq] at h
exact False.elim (hy (h ▸ hp₂))
· refine ⟨-r₁ / r₂, div_neg_of_neg_of_pos (Left.neg_neg_iff.2 hr₁) hr₂, p₂, hp₂, ?_⟩
rw [div_eq_inv_mul, ← smul_smul, neg_smul, h, smul_neg, smul_smul,
inv_mul_cancel₀ hr₂.ne.symm, one_smul, neg_vsub_eq_vsub_rev, vsub_vadd]
· rintro ⟨t, ht, p', hp', rfl⟩
exact sOppSide_smul_vsub_vadd_right hx hp hp' ht
theorem wOppSide_pointReflection {s : AffineSubspace R P} {x : P} (y : P) (hx : x ∈ s) :
s.WOppSide y (pointReflection R x y) :=
(wbtw_pointReflection R _ _).wOppSide₁₃ hx
theorem sOppSide_pointReflection {s : AffineSubspace R P} {x y : P} (hx : x ∈ s) (hy : y ∉ s) :
s.SOppSide y (pointReflection R x y) := by
refine (sbtw_pointReflection_of_ne R fun h => hy ?_).sOppSide_of_not_mem_of_mem hy hx
rwa [← h]
end LinearOrderedField
section Normed
variable [SeminormedAddCommGroup V] [NormedSpace ℝ V] [PseudoMetricSpace P]
variable [NormedAddTorsor V P]
theorem isConnected_setOf_wSameSide {s : AffineSubspace ℝ P} (x : P) (h : (s : Set P).Nonempty) :
IsConnected { y | s.WSameSide x y } := by
obtain ⟨p, hp⟩ := h
haveI : Nonempty s := ⟨⟨p, hp⟩⟩
by_cases hx : x ∈ s
· simp only [wSameSide_of_left_mem, hx]
have := AddTorsor.connectedSpace V P
exact isConnected_univ
· rw [setOf_wSameSide_eq_image2 hx hp, ← Set.image_prod]
refine (isConnected_Ici.prod (isConnected_iff_connectedSpace.2 ?_)).image _
((continuous_fst.smul continuous_const).vadd continuous_snd).continuousOn
convert AddTorsor.connectedSpace s.direction s
theorem isPreconnected_setOf_wSameSide (s : AffineSubspace ℝ P) (x : P) :
IsPreconnected { y | s.WSameSide x y } := by
rcases Set.eq_empty_or_nonempty (s : Set P) with (h | h)
· rw [coe_eq_bot_iff] at h
simp only [h, not_wSameSide_bot]
exact isPreconnected_empty
· exact (isConnected_setOf_wSameSide x h).isPreconnected
theorem isConnected_setOf_sSameSide {s : AffineSubspace ℝ P} {x : P} (hx : x ∉ s)
(h : (s : Set P).Nonempty) : IsConnected { y | s.SSameSide x y } := by
obtain ⟨p, hp⟩ := h
haveI : Nonempty s := ⟨⟨p, hp⟩⟩
rw [setOf_sSameSide_eq_image2 hx hp, ← Set.image_prod]
refine (isConnected_Ioi.prod (isConnected_iff_connectedSpace.2 ?_)).image _
((continuous_fst.smul continuous_const).vadd continuous_snd).continuousOn
convert AddTorsor.connectedSpace s.direction s
theorem isPreconnected_setOf_sSameSide (s : AffineSubspace ℝ P) (x : P) :
IsPreconnected { y | s.SSameSide x y } := by
rcases Set.eq_empty_or_nonempty (s : Set P) with (h | h)
· rw [coe_eq_bot_iff] at h
simp only [h, not_sSameSide_bot]
exact isPreconnected_empty
· by_cases hx : x ∈ s
· simp only [hx, SSameSide, not_true, false_and, and_false]
exact isPreconnected_empty
· exact (isConnected_setOf_sSameSide hx h).isPreconnected
theorem isConnected_setOf_wOppSide {s : AffineSubspace ℝ P} (x : P) (h : (s : Set P).Nonempty) :
IsConnected { y | s.WOppSide x y } := by
obtain ⟨p, hp⟩ := h
haveI : Nonempty s := ⟨⟨p, hp⟩⟩
by_cases hx : x ∈ s
· simp only [wOppSide_of_left_mem, hx]
have := AddTorsor.connectedSpace V P
exact isConnected_univ
· rw [setOf_wOppSide_eq_image2 hx hp, ← Set.image_prod]
refine (isConnected_Iic.prod (isConnected_iff_connectedSpace.2 ?_)).image _
((continuous_fst.smul continuous_const).vadd continuous_snd).continuousOn
convert AddTorsor.connectedSpace s.direction s
theorem isPreconnected_setOf_wOppSide (s : AffineSubspace ℝ P) (x : P) :
IsPreconnected { y | s.WOppSide x y } := by
rcases Set.eq_empty_or_nonempty (s : Set P) with (h | h)
· rw [coe_eq_bot_iff] at h
simp only [h, not_wOppSide_bot]
exact isPreconnected_empty
· exact (isConnected_setOf_wOppSide x h).isPreconnected
theorem isConnected_setOf_sOppSide {s : AffineSubspace ℝ P} {x : P} (hx : x ∉ s)
(h : (s : Set P).Nonempty) : IsConnected { y | s.SOppSide x y } := by
obtain ⟨p, hp⟩ := h
haveI : Nonempty s := ⟨⟨p, hp⟩⟩
rw [setOf_sOppSide_eq_image2 hx hp, ← Set.image_prod]
refine (isConnected_Iio.prod (isConnected_iff_connectedSpace.2 ?_)).image _
((continuous_fst.smul continuous_const).vadd continuous_snd).continuousOn
convert AddTorsor.connectedSpace s.direction s
theorem isPreconnected_setOf_sOppSide (s : AffineSubspace ℝ P) (x : P) :
IsPreconnected { y | s.SOppSide x y } := by
rcases Set.eq_empty_or_nonempty (s : Set P) with (h | h)
· rw [coe_eq_bot_iff] at h
simp only [h, not_sOppSide_bot]
exact isPreconnected_empty
· by_cases hx : x ∈ s
· simp only [hx, SOppSide, not_true, false_and, and_false]
exact isPreconnected_empty
· exact (isConnected_setOf_sOppSide hx h).isPreconnected
end Normed
end AffineSubspace
| Mathlib/Analysis/Convex/Side.lean | 822 | 837 | |
/-
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) :=
| Mathlib/Algebra/GeomSum.lean | 251 | 258 |
/-
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.Group.Basic
import Mathlib.Data.Int.Cast.Defs
import Mathlib.CategoryTheory.Shift.Basic
import Mathlib.CategoryTheory.ConcreteCategory.Basic
/-!
# Differential objects in a category.
A differential object in a category with zero morphisms and a shift is
an object `X` equipped with
a morphism `d : obj ⟶ obj⟦1⟧`, such that `d^2 = 0`.
We build the category of differential objects, and some basic constructions
such as the forgetful functor, zero morphisms and zero objects, and the shift functor
on differential objects.
-/
open CategoryTheory.Limits
universe v u
namespace CategoryTheory
variable (S : Type*) [AddMonoidWithOne S] (C : Type u) [Category.{v} C]
variable [HasZeroMorphisms C] [HasShift C S]
/-- A differential object in a category with zero morphisms and a shift is
an object `obj` equipped with
a morphism `d : obj ⟶ obj⟦1⟧`, such that `d^2 = 0`. -/
structure DifferentialObject where
/-- The underlying object of a differential object. -/
obj : C
/-- The differential of a differential object. -/
d : obj ⟶ obj⟦(1 : S)⟧
/-- The differential `d` satisfies that `d² = 0`. -/
d_squared : d ≫ d⟦(1 : S)⟧' = 0 := by aesop_cat
attribute [reassoc (attr := simp)] DifferentialObject.d_squared
variable {S C}
namespace DifferentialObject
/-- A morphism of differential objects is a morphism commuting with the differentials. -/
@[ext]
structure Hom (X Y : DifferentialObject S C) where
/-- The morphism between underlying objects of the two differentiable objects. -/
f : X.obj ⟶ Y.obj
comm : X.d ≫ f⟦1⟧' = f ≫ Y.d := by aesop_cat
attribute [reassoc (attr := simp)] Hom.comm
namespace Hom
/-- The identity morphism of a differential object. -/
@[simps]
def id (X : DifferentialObject S C) : Hom X X where
f := 𝟙 X.obj
/-- The composition of morphisms of differential objects. -/
@[simps]
def comp {X Y Z : DifferentialObject S C} (f : Hom X Y) (g : Hom Y Z) : Hom X Z where
f := f.f ≫ g.f
end Hom
instance categoryOfDifferentialObjects : Category (DifferentialObject S C) where
Hom := Hom
id := Hom.id
comp f g := Hom.comp f g
@[ext]
theorem ext {A B : DifferentialObject S C} {f g : A ⟶ B} (w : f.f = g.f := by aesop_cat) : f = g :=
Hom.ext w
@[simp]
theorem id_f (X : DifferentialObject S C) : (𝟙 X : X ⟶ X).f = 𝟙 X.obj := rfl
@[simp]
theorem comp_f {X Y Z : DifferentialObject S C} (f : X ⟶ Y) (g : Y ⟶ Z) :
(f ≫ g).f = f.f ≫ g.f :=
rfl
@[simp]
theorem eqToHom_f {X Y : DifferentialObject S C} (h : X = Y) :
Hom.f (eqToHom h) = eqToHom (congr_arg _ h) := by
subst h
rw [eqToHom_refl, eqToHom_refl]
rfl
variable (S C)
/-- The forgetful functor taking a differential object to its underlying object. -/
def forget : DifferentialObject S C ⥤ C where
obj X := X.obj
map f := f.f
| instance forget_faithful : (forget S C).Faithful where
variable {S C}
section
| Mathlib/CategoryTheory/DifferentialObject.lean | 104 | 108 |
/-
Copyright (c) 2022 Joël Riou. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Joël Riou
-/
import Mathlib.AlgebraicTopology.SimplicialObject.Split
import Mathlib.AlgebraicTopology.DoldKan.PInfty
/-!
# Construction of the inverse functor of the Dold-Kan equivalence
In this file, we construct the functor `Γ₀ : ChainComplex C ℕ ⥤ SimplicialObject C`
which shall be the inverse functor of the Dold-Kan equivalence in the case of abelian categories,
and more generally pseudoabelian categories.
By definition, when `K` is a chain_complex, `Γ₀.obj K` is a simplicial object which
sends `Δ : SimplexCategoryᵒᵖ` to a certain coproduct indexed by the set
`Splitting.IndexSet Δ` whose elements consists of epimorphisms `e : Δ.unop ⟶ Δ'.unop`
(with `Δ' : SimplexCategoryᵒᵖ`); the summand attached to such an `e` is `K.X Δ'.unop.len`.
By construction, `Γ₀.obj K` is a split simplicial object whose splitting is `Γ₀.splitting K`.
We also construct `Γ₂ : Karoubi (ChainComplex C ℕ) ⥤ Karoubi (SimplicialObject C)`
which shall be an equivalence for any additive category `C`.
(See `Equivalence.lean` for the general strategy of proof of the Dold-Kan equivalence.)
-/
noncomputable section
open CategoryTheory CategoryTheory.Category CategoryTheory.Limits SimplexCategory
SimplicialObject Opposite CategoryTheory.Idempotents Simplicial DoldKan
namespace AlgebraicTopology
namespace DoldKan
variable {C : Type*} [Category C] [Preadditive C] (K K' : ChainComplex C ℕ) (f : K ⟶ K')
{Δ Δ' Δ'' : SimplexCategory}
/-- `Isδ₀ i` is a simple condition used to check whether a monomorphism `i` in
`SimplexCategory` identifies to the coface map `δ 0`. -/
@[nolint unusedArguments]
def Isδ₀ {Δ Δ' : SimplexCategory} (i : Δ' ⟶ Δ) [Mono i] : Prop :=
Δ.len = Δ'.len + 1 ∧ i.toOrderHom 0 ≠ 0
namespace Isδ₀
theorem iff {j : ℕ} {i : Fin (j + 2)} : Isδ₀ (SimplexCategory.δ i) ↔ i = 0 := by
constructor
· rintro ⟨_, h₂⟩
by_contra h
exact h₂ (Fin.succAbove_ne_zero_zero h)
· rintro rfl
exact ⟨rfl, by dsimp; exact Fin.succ_ne_zero (0 : Fin (j + 1))⟩
theorem eq_δ₀ {n : ℕ} {i : ⦋n⦌ ⟶ ⦋n + 1⦌} [Mono i] (hi : Isδ₀ i) :
i = SimplexCategory.δ 0 := by
obtain ⟨j, rfl⟩ := SimplexCategory.eq_δ_of_mono i
rw [iff] at hi
rw [hi]
end Isδ₀
namespace Γ₀
namespace Obj
/-- In the definition of `(Γ₀.obj K).obj Δ` as a direct sum indexed by `A : Splitting.IndexSet Δ`,
the summand `summand K Δ A` is `K.X A.1.len`. -/
def summand (Δ : SimplexCategoryᵒᵖ) (A : Splitting.IndexSet Δ) : C :=
K.X A.1.unop.len
/-- The functor `Γ₀` sends a chain complex `K` to the simplicial object which
sends `Δ` to the direct sum of the objects `summand K Δ A` for all `A : Splitting.IndexSet Δ` -/
def obj₂ (K : ChainComplex C ℕ) (Δ : SimplexCategoryᵒᵖ) [HasFiniteCoproducts C] : C :=
∐ fun A : Splitting.IndexSet Δ => summand K Δ A
namespace Termwise
/-- A monomorphism `i : Δ' ⟶ Δ` induces a morphism `K.X Δ.len ⟶ K.X Δ'.len` which
is the identity if `Δ = Δ'`, the differential on the complex `K` if `i = δ 0`, and
zero otherwise. -/
def mapMono (K : ChainComplex C ℕ) {Δ' Δ : SimplexCategory} (i : Δ' ⟶ Δ) [Mono i] :
K.X Δ.len ⟶ K.X Δ'.len := by
by_cases Δ = Δ'
· exact eqToHom (by congr)
· by_cases Isδ₀ i
· exact K.d Δ.len Δ'.len
· exact 0
variable (Δ) in
theorem mapMono_id : mapMono K (𝟙 Δ) = 𝟙 _ := by
unfold mapMono
simp only [eq_self_iff_true, eqToHom_refl, dite_eq_ite, if_true]
theorem mapMono_δ₀' (i : Δ' ⟶ Δ) [Mono i] (hi : Isδ₀ i) : mapMono K i = K.d Δ.len Δ'.len := by
unfold mapMono
suffices Δ ≠ Δ' by
simp only [dif_neg this, dif_pos hi]
rintro rfl
simpa only [left_eq_add, Nat.one_ne_zero] using hi.1
@[simp]
theorem mapMono_δ₀ {n : ℕ} : mapMono K (δ (0 : Fin (n + 2))) = K.d (n + 1) n :=
mapMono_δ₀' K _ (by rw [Isδ₀.iff])
theorem mapMono_eq_zero (i : Δ' ⟶ Δ) [Mono i] (h₁ : Δ ≠ Δ') (h₂ : ¬Isδ₀ i) : mapMono K i = 0 := by
unfold mapMono
rw [Ne] at h₁
split_ifs
rfl
variable {K K'}
@[reassoc (attr := simp)]
theorem mapMono_naturality (i : Δ ⟶ Δ') [Mono i] :
mapMono K i ≫ f.f Δ.len = f.f Δ'.len ≫ mapMono K' i := by
unfold mapMono
split_ifs with h
· subst h
simp only [id_comp, eqToHom_refl, comp_id]
· rw [HomologicalComplex.Hom.comm]
· rw [zero_comp, comp_zero]
variable (K)
@[reassoc (attr := simp)]
theorem mapMono_comp (i' : Δ'' ⟶ Δ') (i : Δ' ⟶ Δ) [Mono i'] [Mono i] :
mapMono K i ≫ mapMono K i' = mapMono K (i' ≫ i) := by
-- case where i : Δ' ⟶ Δ is the identity
by_cases h₁ : Δ = Δ'
· subst h₁
simp only [SimplexCategory.eq_id_of_mono i, comp_id, id_comp, mapMono_id K, eqToHom_refl]
-- case where i' : Δ'' ⟶ Δ' is the identity
by_cases h₂ : Δ' = Δ''
· subst h₂
simp only [SimplexCategory.eq_id_of_mono i', comp_id, id_comp, mapMono_id K, eqToHom_refl]
-- then the RHS is always zero
obtain ⟨k, hk⟩ := Nat.exists_eq_add_of_lt (len_lt_of_mono i h₁)
obtain ⟨k', hk'⟩ := Nat.exists_eq_add_of_lt (len_lt_of_mono i' h₂)
have eq : Δ.len = Δ''.len + (k + k' + 2) := by omega
rw [mapMono_eq_zero K (i' ≫ i) _ _]; rotate_left
· by_contra h
| simp only [left_eq_add, h, add_eq_zero, and_false, reduceCtorEq] at eq
· by_contra h
simp only [h.1, add_right_inj] at eq
omega
-- in all cases, the LHS is also zero, either by definition, or because d ≫ d = 0
by_cases h₃ : Isδ₀ i
· by_cases h₄ : Isδ₀ i'
· rw [mapMono_δ₀' K i h₃, mapMono_δ₀' K i' h₄, HomologicalComplex.d_comp_d]
· simp only [mapMono_eq_zero K i' h₂ h₄, comp_zero]
· simp only [mapMono_eq_zero K i h₁ h₃, zero_comp]
end Termwise
variable [HasFiniteCoproducts C]
/-- The simplicial morphism on the simplicial object `Γ₀.obj K` induced by
a morphism `Δ' → Δ` in `SimplexCategory` is defined on each summand
associated to an `A : Splitting.IndexSet Δ` in terms of the epi-mono factorisation
of `θ ≫ A.e`. -/
def map (K : ChainComplex C ℕ) {Δ' Δ : SimplexCategoryᵒᵖ} (θ : Δ ⟶ Δ') : obj₂ K Δ ⟶ obj₂ K Δ' :=
Sigma.desc fun A =>
Termwise.mapMono K (image.ι (θ.unop ≫ A.e)) ≫ Sigma.ι (summand K Δ') (A.pull θ)
@[reassoc]
theorem map_on_summand₀ {Δ Δ' : SimplexCategoryᵒᵖ} (A : Splitting.IndexSet Δ) {θ : Δ ⟶ Δ'}
{Δ'' : SimplexCategory} {e : Δ'.unop ⟶ Δ''} {i : Δ'' ⟶ A.1.unop} [Epi e] [Mono i]
| Mathlib/AlgebraicTopology/DoldKan/FunctorGamma.lean | 148 | 173 |
/-
Copyright (c) 2024 Yaël Dillies. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Yaël Dillies
-/
import Mathlib.Algebra.Order.Disjointed
import Mathlib.Algebra.Order.Ring.Prod
import Mathlib.Data.Int.Interval
import Mathlib.Tactic.Ring
import Mathlib.Tactic.Zify
/-!
# Decomposing a locally finite ordered ring into boxes
This file proves that any locally finite ordered ring can be decomposed into "boxes", namely
differences of consecutive intervals.
## Implementation notes
We don't need the full ring structure, only that there is an order embedding `ℤ → `
-/
/-! ### General locally finite ordered ring -/
namespace Finset
variable {α : Type*} [Ring α] [PartialOrder α] [IsOrderedRing α] [LocallyFiniteOrder α] {n : ℕ}
private lemma Icc_neg_mono : Monotone fun n : ℕ ↦ Icc (-n : α) n := by
refine fun m n hmn ↦ by apply Icc_subset_Icc <;> simpa using Nat.mono_cast hmn
variable [DecidableEq α]
|
/-- Hollow box centered at `0 : α` going from `-n` to `n`. -/
| Mathlib/Order/Interval/Finset/Box.lean | 32 | 33 |
/-
Copyright (c) 2021 Kalle Kytölä. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kalle Kytölä
-/
import Mathlib.Topology.MetricSpace.HausdorffDistance
/-!
# Thickenings in pseudo-metric spaces
## Main definitions
* `Metric.thickening δ s`, the open thickening by radius `δ` of a set `s` in a pseudo emetric space.
* `Metric.cthickening δ s`, the closed thickening by radius `δ` of a set `s` in a pseudo emetric
space.
## Main results
* `Disjoint.exists_thickenings`: two disjoint sets admit disjoint thickenings
* `Disjoint.exists_cthickenings`: two disjoint sets admit disjoint closed thickenings
* `IsCompact.exists_cthickening_subset_open`: if `s` is compact, `t` is open and `s ⊆ t`,
some `cthickening` of `s` is contained in `t`.
* `Metric.hasBasis_nhdsSet_cthickening`: the `cthickening`s of a compact set `K` form a basis
of the neighbourhoods of `K`
* `Metric.closure_eq_iInter_cthickening'`: the closure of a set equals the intersection
of its closed thickenings of positive radii accumulating at zero.
The same holds for open thickenings.
* `IsCompact.cthickening_eq_biUnion_closedBall`: if `s` is compact, `cthickening δ s` is the union
of `closedBall`s of radius `δ` around `x : E`.
-/
noncomputable section
open NNReal ENNReal Topology Set Filter Bornology
universe u v w
variable {ι : Sort*} {α : Type u}
namespace Metric
section Thickening
variable [PseudoEMetricSpace α] {δ : ℝ} {s : Set α} {x : α}
open EMetric
/-- The (open) `δ`-thickening `Metric.thickening δ E` of a subset `E` in a pseudo emetric space
consists of those points that are at distance less than `δ` from some point of `E`. -/
def thickening (δ : ℝ) (E : Set α) : Set α :=
{ x : α | infEdist x E < ENNReal.ofReal δ }
theorem mem_thickening_iff_infEdist_lt : x ∈ thickening δ s ↔ infEdist x s < ENNReal.ofReal δ :=
Iff.rfl
/-- An exterior point of a subset `E` (i.e., a point outside the closure of `E`) is not in the
(open) `δ`-thickening of `E` for small enough positive `δ`. -/
lemma eventually_not_mem_thickening_of_infEdist_pos {E : Set α} {x : α} (h : x ∉ closure E) :
∀ᶠ δ in 𝓝 (0 : ℝ), x ∉ Metric.thickening δ E := by
obtain ⟨ε, ⟨ε_pos, ε_lt⟩⟩ := exists_real_pos_lt_infEdist_of_not_mem_closure h
filter_upwards [eventually_lt_nhds ε_pos] with δ hδ
simp only [thickening, mem_setOf_eq, not_lt]
exact (ENNReal.ofReal_le_ofReal hδ.le).trans ε_lt.le
/-- The (open) thickening equals the preimage of an open interval under `EMetric.infEdist`. -/
theorem thickening_eq_preimage_infEdist (δ : ℝ) (E : Set α) :
thickening δ E = (infEdist · E) ⁻¹' Iio (ENNReal.ofReal δ) :=
rfl
/-- The (open) thickening is an open set. -/
theorem isOpen_thickening {δ : ℝ} {E : Set α} : IsOpen (thickening δ E) :=
Continuous.isOpen_preimage continuous_infEdist _ isOpen_Iio
/-- The (open) thickening of the empty set is empty. -/
@[simp]
theorem thickening_empty (δ : ℝ) : thickening δ (∅ : Set α) = ∅ := by
simp only [thickening, setOf_false, infEdist_empty, not_top_lt]
theorem thickening_of_nonpos (hδ : δ ≤ 0) (s : Set α) : thickening δ s = ∅ :=
eq_empty_of_forall_not_mem fun _ => ((ENNReal.ofReal_of_nonpos hδ).trans_le bot_le).not_lt
/-- The (open) thickening `Metric.thickening δ E` of a fixed subset `E` is an increasing function of
the thickening radius `δ`. -/
@[gcongr]
theorem thickening_mono {δ₁ δ₂ : ℝ} (hle : δ₁ ≤ δ₂) (E : Set α) :
thickening δ₁ E ⊆ thickening δ₂ E :=
preimage_mono (Iio_subset_Iio (ENNReal.ofReal_le_ofReal hle))
/-- The (open) thickening `Metric.thickening δ E` with a fixed thickening radius `δ` is
an increasing function of the subset `E`. -/
theorem thickening_subset_of_subset (δ : ℝ) {E₁ E₂ : Set α} (h : E₁ ⊆ E₂) :
thickening δ E₁ ⊆ thickening δ E₂ := fun _ hx => lt_of_le_of_lt (infEdist_anti h) hx
theorem mem_thickening_iff_exists_edist_lt {δ : ℝ} (E : Set α) (x : α) :
x ∈ thickening δ E ↔ ∃ z ∈ E, edist x z < ENNReal.ofReal δ :=
infEdist_lt_iff
/-- The frontier of the (open) thickening of a set is contained in an `EMetric.infEdist` level
set. -/
theorem frontier_thickening_subset (E : Set α) {δ : ℝ} :
frontier (thickening δ E) ⊆ { x : α | infEdist x E = ENNReal.ofReal δ } :=
frontier_lt_subset_eq continuous_infEdist continuous_const
open scoped Function in -- required for scoped `on` notation
theorem frontier_thickening_disjoint (A : Set α) :
Pairwise (Disjoint on fun r : ℝ => frontier (thickening r A)) := by
refine (pairwise_disjoint_on _).2 fun r₁ r₂ hr => ?_
rcases le_total r₁ 0 with h₁ | h₁
· simp [thickening_of_nonpos h₁]
refine ((disjoint_singleton.2 fun h => hr.ne ?_).preimage _).mono (frontier_thickening_subset _)
(frontier_thickening_subset _)
apply_fun ENNReal.toReal at h
rwa [ENNReal.toReal_ofReal h₁, ENNReal.toReal_ofReal (h₁.trans hr.le)] at h
/-- Any set is contained in the complement of the δ-thickening of the complement of its
δ-thickening. -/
lemma subset_compl_thickening_compl_thickening_self (δ : ℝ) (E : Set α) :
E ⊆ (thickening δ (thickening δ E)ᶜ)ᶜ := by
intro x x_in_E
simp only [thickening, mem_compl_iff, mem_setOf_eq, not_lt]
apply EMetric.le_infEdist.mpr fun y hy ↦ ?_
simp only [mem_compl_iff, mem_setOf_eq, not_lt] at hy
simpa only [edist_comm] using le_trans hy <| EMetric.infEdist_le_edist_of_mem x_in_E
/-- The δ-thickening of the complement of the δ-thickening of a set is contained in the complement
of the set. -/
lemma thickening_compl_thickening_self_subset_compl (δ : ℝ) (E : Set α) :
thickening δ (thickening δ E)ᶜ ⊆ Eᶜ := by
apply compl_subset_compl.mp
simpa only [compl_compl] using subset_compl_thickening_compl_thickening_self δ E
variable {X : Type u} [PseudoMetricSpace X]
theorem mem_thickening_iff_infDist_lt {E : Set X} {x : X} (h : E.Nonempty) :
x ∈ thickening δ E ↔ infDist x E < δ :=
lt_ofReal_iff_toReal_lt (infEdist_ne_top h)
/-- A point in a metric space belongs to the (open) `δ`-thickening of a subset `E` if and only if
it is at distance less than `δ` from some point of `E`. -/
theorem mem_thickening_iff {E : Set X} {x : X} : x ∈ thickening δ E ↔ ∃ z ∈ E, dist x z < δ := by
have key_iff : ∀ z : X, edist x z < ENNReal.ofReal δ ↔ dist x z < δ := fun z ↦ by
rw [dist_edist, lt_ofReal_iff_toReal_lt (edist_ne_top _ _)]
simp_rw [mem_thickening_iff_exists_edist_lt, key_iff]
@[simp]
theorem thickening_singleton (δ : ℝ) (x : X) : thickening δ ({x} : Set X) = ball x δ := by
ext
simp [mem_thickening_iff]
theorem ball_subset_thickening {x : X} {E : Set X} (hx : x ∈ E) (δ : ℝ) :
ball x δ ⊆ thickening δ E :=
Subset.trans (by simp [Subset.rfl]) (thickening_subset_of_subset δ <| singleton_subset_iff.mpr hx)
/-- The (open) `δ`-thickening `Metric.thickening δ E` of a subset `E` in a metric space equals the
union of balls of radius `δ` centered at points of `E`. -/
theorem thickening_eq_biUnion_ball {δ : ℝ} {E : Set X} : thickening δ E = ⋃ x ∈ E, ball x δ := by
ext x
simp only [mem_iUnion₂, exists_prop]
exact mem_thickening_iff
protected theorem _root_.Bornology.IsBounded.thickening {δ : ℝ} {E : Set X} (h : IsBounded E) :
IsBounded (thickening δ E) := by
rcases E.eq_empty_or_nonempty with rfl | ⟨x, hx⟩
· simp
· refine (isBounded_iff_subset_closedBall x).2 ⟨δ + diam E, fun y hy ↦ ?_⟩
calc
dist y x ≤ infDist y E + diam E := dist_le_infDist_add_diam (x := y) h hx
_ ≤ δ + diam E := add_le_add_right ((mem_thickening_iff_infDist_lt ⟨x, hx⟩).1 hy).le _
end Thickening
section Cthickening
variable [PseudoEMetricSpace α] {δ ε : ℝ} {s t : Set α} {x : α}
open EMetric
/-- The closed `δ`-thickening `Metric.cthickening δ E` of a subset `E` in a pseudo emetric space
consists of those points that are at infimum distance at most `δ` from `E`. -/
def cthickening (δ : ℝ) (E : Set α) : Set α :=
{ x : α | infEdist x E ≤ ENNReal.ofReal δ }
@[simp]
theorem mem_cthickening_iff : x ∈ cthickening δ s ↔ infEdist x s ≤ ENNReal.ofReal δ :=
Iff.rfl
/-- An exterior point of a subset `E` (i.e., a point outside the closure of `E`) is not in the
closed `δ`-thickening of `E` for small enough positive `δ`. -/
lemma eventually_not_mem_cthickening_of_infEdist_pos {E : Set α} {x : α} (h : x ∉ closure E) :
∀ᶠ δ in 𝓝 (0 : ℝ), x ∉ Metric.cthickening δ E := by
obtain ⟨ε, ⟨ε_pos, ε_lt⟩⟩ := exists_real_pos_lt_infEdist_of_not_mem_closure h
filter_upwards [eventually_lt_nhds ε_pos] with δ hδ
simp only [cthickening, mem_setOf_eq, not_le]
exact ((ofReal_lt_ofReal_iff ε_pos).mpr hδ).trans ε_lt
theorem mem_cthickening_of_edist_le (x y : α) (δ : ℝ) (E : Set α) (h : y ∈ E)
(h' : edist x y ≤ ENNReal.ofReal δ) : x ∈ cthickening δ E :=
(infEdist_le_edist_of_mem h).trans h'
theorem mem_cthickening_of_dist_le {α : Type*} [PseudoMetricSpace α] (x y : α) (δ : ℝ) (E : Set α)
(h : y ∈ E) (h' : dist x y ≤ δ) : x ∈ cthickening δ E := by
apply mem_cthickening_of_edist_le x y δ E h
rw [edist_dist]
exact ENNReal.ofReal_le_ofReal h'
theorem cthickening_eq_preimage_infEdist (δ : ℝ) (E : Set α) :
cthickening δ E = (fun x => infEdist x E) ⁻¹' Iic (ENNReal.ofReal δ) :=
rfl
/-- The closed thickening is a closed set. -/
theorem isClosed_cthickening {δ : ℝ} {E : Set α} : IsClosed (cthickening δ E) :=
IsClosed.preimage continuous_infEdist isClosed_Iic
/-- The closed thickening of the empty set is empty. -/
@[simp]
theorem cthickening_empty (δ : ℝ) : cthickening δ (∅ : Set α) = ∅ := by
simp only [cthickening, ENNReal.ofReal_ne_top, setOf_false, infEdist_empty, top_le_iff]
theorem cthickening_of_nonpos {δ : ℝ} (hδ : δ ≤ 0) (E : Set α) : cthickening δ E = closure E := by
ext x
simp [mem_closure_iff_infEdist_zero, cthickening, ENNReal.ofReal_eq_zero.2 hδ]
/-- The closed thickening with radius zero is the closure of the set. -/
@[simp]
theorem cthickening_zero (E : Set α) : cthickening 0 E = closure E :=
cthickening_of_nonpos le_rfl E
theorem cthickening_max_zero (δ : ℝ) (E : Set α) : cthickening (max 0 δ) E = cthickening δ E := by
cases le_total δ 0 <;> simp [cthickening_of_nonpos, *]
/-- The closed thickening `Metric.cthickening δ E` of a fixed subset `E` is an increasing function
of the thickening radius `δ`. -/
theorem cthickening_mono {δ₁ δ₂ : ℝ} (hle : δ₁ ≤ δ₂) (E : Set α) :
cthickening δ₁ E ⊆ cthickening δ₂ E :=
preimage_mono (Iic_subset_Iic.mpr (ENNReal.ofReal_le_ofReal hle))
@[simp]
theorem cthickening_singleton {α : Type*} [PseudoMetricSpace α] (x : α) {δ : ℝ} (hδ : 0 ≤ δ) :
cthickening δ ({x} : Set α) = closedBall x δ := by
ext y
simp [cthickening, edist_dist, ENNReal.ofReal_le_ofReal_iff hδ]
theorem closedBall_subset_cthickening_singleton {α : Type*} [PseudoMetricSpace α] (x : α) (δ : ℝ) :
closedBall x δ ⊆ cthickening δ ({x} : Set α) := by
rcases lt_or_le δ 0 with (hδ | hδ)
· simp only [closedBall_eq_empty.mpr hδ, empty_subset]
· simp only [cthickening_singleton x hδ, Subset.rfl]
/-- The closed thickening `Metric.cthickening δ E` with a fixed thickening radius `δ` is
an increasing function of the subset `E`. -/
theorem cthickening_subset_of_subset (δ : ℝ) {E₁ E₂ : Set α} (h : E₁ ⊆ E₂) :
cthickening δ E₁ ⊆ cthickening δ E₂ := fun _ hx => le_trans (infEdist_anti h) hx
theorem cthickening_subset_thickening {δ₁ : ℝ≥0} {δ₂ : ℝ} (hlt : (δ₁ : ℝ) < δ₂) (E : Set α) :
cthickening δ₁ E ⊆ thickening δ₂ E := fun _ hx =>
hx.out.trans_lt ((ENNReal.ofReal_lt_ofReal_iff (lt_of_le_of_lt δ₁.prop hlt)).mpr hlt)
/-- The closed thickening `Metric.cthickening δ₁ E` is contained in the open thickening
`Metric.thickening δ₂ E` if the radius of the latter is positive and larger. -/
theorem cthickening_subset_thickening' {δ₁ δ₂ : ℝ} (δ₂_pos : 0 < δ₂) (hlt : δ₁ < δ₂) (E : Set α) :
cthickening δ₁ E ⊆ thickening δ₂ E := fun _ hx =>
lt_of_le_of_lt hx.out ((ENNReal.ofReal_lt_ofReal_iff δ₂_pos).mpr hlt)
/-- The open thickening `Metric.thickening δ E` is contained in the closed thickening
`Metric.cthickening δ E` with the same radius. -/
theorem thickening_subset_cthickening (δ : ℝ) (E : Set α) : thickening δ E ⊆ cthickening δ E := by
intro x hx
rw [thickening, mem_setOf_eq] at hx
exact hx.le
theorem thickening_subset_cthickening_of_le {δ₁ δ₂ : ℝ} (hle : δ₁ ≤ δ₂) (E : Set α) :
thickening δ₁ E ⊆ cthickening δ₂ E :=
(thickening_subset_cthickening δ₁ E).trans (cthickening_mono hle E)
theorem _root_.Bornology.IsBounded.cthickening {α : Type*} [PseudoMetricSpace α] {δ : ℝ} {E : Set α}
(h : IsBounded E) : IsBounded (cthickening δ E) := by
have : IsBounded (thickening (max (δ + 1) 1) E) := h.thickening
apply this.subset
exact cthickening_subset_thickening' (zero_lt_one.trans_le (le_max_right _ _))
((lt_add_one _).trans_le (le_max_left _ _)) _
protected theorem _root_.IsCompact.cthickening
{α : Type*} [PseudoMetricSpace α] [ProperSpace α] {s : Set α}
(hs : IsCompact s) {r : ℝ} : IsCompact (cthickening r s) :=
isCompact_of_isClosed_isBounded isClosed_cthickening hs.isBounded.cthickening
theorem thickening_subset_interior_cthickening (δ : ℝ) (E : Set α) :
thickening δ E ⊆ interior (cthickening δ E) :=
(subset_interior_iff_isOpen.mpr isOpen_thickening).trans
(interior_mono (thickening_subset_cthickening δ E))
theorem closure_thickening_subset_cthickening (δ : ℝ) (E : Set α) :
closure (thickening δ E) ⊆ cthickening δ E :=
(closure_mono (thickening_subset_cthickening δ E)).trans isClosed_cthickening.closure_subset
/-- The closed thickening of a set contains the closure of the set. -/
theorem closure_subset_cthickening (δ : ℝ) (E : Set α) : closure E ⊆ cthickening δ E := by
| rw [← cthickening_of_nonpos (min_le_right δ 0)]
exact cthickening_mono (min_le_left δ 0) E
/-- The (open) thickening of a set contains the closure of the set. -/
| Mathlib/Topology/MetricSpace/Thickening.lean | 297 | 300 |
/-
Copyright (c) 2020 Kim Morrison. All rights reserved.
Released under Apache 2.0 license as described in the file LICENSE.
Authors: Kim Morrison, Shing Tak Lam, Mario Carneiro
-/
import Mathlib.Algebra.BigOperators.Intervals
import Mathlib.Algebra.BigOperators.Ring.List
import Mathlib.Data.Int.ModEq
import Mathlib.Data.Nat.Bits
import Mathlib.Data.Nat.Log
import Mathlib.Data.List.Palindrome
import Mathlib.Tactic.IntervalCases
import Mathlib.Tactic.Linarith
import Mathlib.Tactic.Ring
/-!
# Digits of a natural number
This provides a basic API for extracting the digits of a natural number in a given base,
and reconstructing numbers from their digits.
We also prove some divisibility tests based on digits, in particular completing
Theorem #85 from https://www.cs.ru.nl/~freek/100/.
Also included is a bound on the length of `Nat.toDigits` from core.
## TODO
A basic `norm_digits` tactic for proving goals of the form `Nat.digits a b = l` where `a` and `b`
are numerals is not yet ported.
-/
namespace Nat
variable {n : ℕ}
/-- (Impl.) An auxiliary definition for `digits`, to help get the desired definitional unfolding. -/
def digitsAux0 : ℕ → List ℕ
| 0 => []
| n + 1 => [n + 1]
/-- (Impl.) An auxiliary definition for `digits`, to help get the desired definitional unfolding. -/
def digitsAux1 (n : ℕ) : List ℕ :=
List.replicate n 1
/-- (Impl.) An auxiliary definition for `digits`, to help get the desired definitional unfolding. -/
def digitsAux (b : ℕ) (h : 2 ≤ b) : ℕ → List ℕ
| 0 => []
| n + 1 =>
((n + 1) % b) :: digitsAux b h ((n + 1) / b)
decreasing_by exact Nat.div_lt_self (Nat.succ_pos _) h
@[simp]
theorem digitsAux_zero (b : ℕ) (h : 2 ≤ b) : digitsAux b h 0 = [] := by rw [digitsAux]
theorem digitsAux_def (b : ℕ) (h : 2 ≤ b) (n : ℕ) (w : 0 < n) :
digitsAux b h n = (n % b) :: digitsAux b h (n / b) := by
cases n
· cases w
· rw [digitsAux]
/-- `digits b n` gives the digits, in little-endian order,
of a natural number `n` in a specified base `b`.
In any base, we have `ofDigits b L = L.foldr (fun x y ↦ x + b * y) 0`.
* For any `2 ≤ b`, we have `l < b` for any `l ∈ digits b n`,
and the last digit is not zero.
This uniquely specifies the behaviour of `digits b`.
* For `b = 1`, we define `digits 1 n = List.replicate n 1`.
* For `b = 0`, we define `digits 0 n = [n]`, except `digits 0 0 = []`.
Note this differs from the existing `Nat.toDigits` in core, which is used for printing numerals.
In particular, `Nat.toDigits b 0 = ['0']`, while `digits b 0 = []`.
-/
def digits : ℕ → ℕ → List ℕ
| 0 => digitsAux0
| 1 => digitsAux1
| b + 2 => digitsAux (b + 2) (by norm_num)
@[simp]
theorem digits_zero (b : ℕ) : digits b 0 = [] := by
rcases b with (_ | ⟨_ | ⟨_⟩⟩) <;> simp [digits, digitsAux0, digitsAux1]
theorem digits_zero_zero : digits 0 0 = [] :=
rfl
@[simp]
theorem digits_zero_succ (n : ℕ) : digits 0 n.succ = [n + 1] :=
rfl
theorem digits_zero_succ' : ∀ {n : ℕ}, n ≠ 0 → digits 0 n = [n]
| 0, h => (h rfl).elim
| _ + 1, _ => rfl
@[simp]
theorem digits_one (n : ℕ) : digits 1 n = List.replicate n 1 :=
rfl
-- no `@[simp]`: dsimp can prove this
theorem digits_one_succ (n : ℕ) : digits 1 (n + 1) = 1 :: digits 1 n :=
rfl
theorem digits_add_two_add_one (b n : ℕ) :
digits (b + 2) (n + 1) = ((n + 1) % (b + 2)) :: digits (b + 2) ((n + 1) / (b + 2)) := by
simp [digits, digitsAux_def]
@[simp]
lemma digits_of_two_le_of_pos {b : ℕ} (hb : 2 ≤ b) (hn : 0 < n) :
Nat.digits b n = n % b :: Nat.digits b (n / b) := by
rw [Nat.eq_add_of_sub_eq hb rfl, Nat.eq_add_of_sub_eq hn rfl, Nat.digits_add_two_add_one]
theorem digits_def' :
∀ {b : ℕ} (_ : 1 < b) {n : ℕ} (_ : 0 < n), digits b n = (n % b) :: digits b (n / b)
| 0, h => absurd h (by decide)
| 1, h => absurd h (by decide)
| b + 2, _ => digitsAux_def _ (by simp) _
@[simp]
theorem digits_of_lt (b x : ℕ) (hx : x ≠ 0) (hxb : x < b) : digits b x = [x] := by
rcases exists_eq_succ_of_ne_zero hx with ⟨x, rfl⟩
rcases Nat.exists_eq_add_of_le' ((Nat.le_add_left 1 x).trans_lt hxb) with ⟨b, rfl⟩
rw [digits_add_two_add_one, div_eq_of_lt hxb, digits_zero, mod_eq_of_lt hxb]
theorem digits_add (b : ℕ) (h : 1 < b) (x y : ℕ) (hxb : x < b) (hxy : x ≠ 0 ∨ y ≠ 0) :
digits b (x + b * y) = x :: digits b y := by
rcases Nat.exists_eq_add_of_le' h with ⟨b, rfl : _ = _ + 2⟩
cases y
· simp [hxb, hxy.resolve_right (absurd rfl)]
dsimp [digits]
rw [digitsAux_def]
· congr
· simp [Nat.add_mod, mod_eq_of_lt hxb]
· simp [add_mul_div_left, div_eq_of_lt hxb]
· apply Nat.succ_pos
-- If we had a function converting a list into a polynomial,
-- and appropriate lemmas about that function,
-- we could rewrite this in terms of that.
/-- `ofDigits b L` takes a list `L` of natural numbers, and interprets them
as a number in semiring, as the little-endian digits in base `b`.
-/
def ofDigits {α : Type*} [Semiring α] (b : α) : List ℕ → α
| [] => 0
| h :: t => h + b * ofDigits b t
theorem ofDigits_eq_foldr {α : Type*} [Semiring α] (b : α) (L : List ℕ) :
ofDigits b L = List.foldr (fun x y => ↑x + b * y) 0 L := by
induction' L with d L ih
· rfl
· dsimp [ofDigits]
rw [ih]
theorem ofDigits_eq_sum_mapIdx_aux (b : ℕ) (l : List ℕ) :
(l.zipWith ((fun a i : ℕ => a * b ^ (i + 1))) (List.range l.length)).sum =
b * (l.zipWith (fun a i => a * b ^ i) (List.range l.length)).sum := by
suffices
l.zipWith (fun a i : ℕ => a * b ^ (i + 1)) (List.range l.length) =
l.zipWith (fun a i=> b * (a * b ^ i)) (List.range l.length)
by simp [this]
congr; ext; simp [pow_succ]; ring
theorem ofDigits_eq_sum_mapIdx (b : ℕ) (L : List ℕ) :
ofDigits b L = (L.mapIdx fun i a => a * b ^ i).sum := by
rw [List.mapIdx_eq_zipIdx_map, List.zipIdx_eq_zip_range', List.map_zip_eq_zipWith,
ofDigits_eq_foldr, ← List.range_eq_range']
induction' L with hd tl hl
· simp
· simpa [List.range_succ_eq_map, List.zipWith_map_right, ofDigits_eq_sum_mapIdx_aux] using
Or.inl hl
@[simp]
theorem ofDigits_nil {b : ℕ} : ofDigits b [] = 0 := rfl
@[simp]
theorem ofDigits_singleton {b n : ℕ} : ofDigits b [n] = n := by simp [ofDigits]
@[simp]
theorem ofDigits_one_cons {α : Type*} [Semiring α] (h : ℕ) (L : List ℕ) :
ofDigits (1 : α) (h :: L) = h + ofDigits 1 L := by simp [ofDigits]
theorem ofDigits_cons {b hd} {tl : List ℕ} :
ofDigits b (hd :: tl) = hd + b * ofDigits b tl := rfl
theorem ofDigits_append {b : ℕ} {l1 l2 : List ℕ} :
ofDigits b (l1 ++ l2) = ofDigits b l1 + b ^ l1.length * ofDigits b l2 := by
induction' l1 with hd tl IH
· simp [ofDigits]
· rw [ofDigits, List.cons_append, ofDigits, IH, List.length_cons, pow_succ']
ring
@[norm_cast]
theorem coe_ofDigits (α : Type*) [Semiring α] (b : ℕ) (L : List ℕ) :
((ofDigits b L : ℕ) : α) = ofDigits (b : α) L := by
induction' L with d L ih
· simp [ofDigits]
· dsimp [ofDigits]; push_cast; rw [ih]
@[norm_cast]
theorem coe_int_ofDigits (b : ℕ) (L : List ℕ) : ((ofDigits b L : ℕ) : ℤ) = ofDigits (b : ℤ) L := by
induction' L with d L _
· rfl
· dsimp [ofDigits]; push_cast; simp only
theorem digits_zero_of_eq_zero {b : ℕ} (h : b ≠ 0) :
∀ {L : List ℕ} (_ : ofDigits b L = 0), ∀ l ∈ L, l = 0
| _ :: _, h0, _, List.Mem.head .. => Nat.eq_zero_of_add_eq_zero_right h0
| _ :: _, h0, _, List.Mem.tail _ hL =>
digits_zero_of_eq_zero h (mul_right_injective₀ h (Nat.eq_zero_of_add_eq_zero_left h0)) _ hL
theorem digits_ofDigits (b : ℕ) (h : 1 < b) (L : List ℕ) (w₁ : ∀ l ∈ L, l < b)
(w₂ : ∀ h : L ≠ [], L.getLast h ≠ 0) : digits b (ofDigits b L) = L := by
induction' L with d L ih
· dsimp [ofDigits]
simp
· dsimp [ofDigits]
replace w₂ := w₂ (by simp)
rw [digits_add b h]
· rw [ih]
· intro l m
apply w₁
exact List.mem_cons_of_mem _ m
· intro h
rw [List.getLast_cons h] at w₂
convert w₂
· exact w₁ d List.mem_cons_self
· by_cases h' : L = []
· rcases h' with rfl
left
simpa using w₂
· right
contrapose! w₂
refine digits_zero_of_eq_zero h.ne_bot w₂ _ ?_
rw [List.getLast_cons h']
exact List.getLast_mem h'
theorem ofDigits_digits (b n : ℕ) : ofDigits b (digits b n) = n := by
rcases b with - | b
· rcases n with - | n
· rfl
· simp
· rcases b with - | b
· induction' n with n ih
· rfl
· rw [Nat.zero_add] at ih ⊢
simp only [ih, add_comm 1, ofDigits_one_cons, Nat.cast_id, digits_one_succ]
· induction n using Nat.strongRecOn with | ind n h => ?_
cases n
· rw [digits_zero]
rfl
· simp only [Nat.succ_eq_add_one, digits_add_two_add_one]
dsimp [ofDigits]
rw [h _ (Nat.div_lt_self' _ b)]
rw [Nat.mod_add_div]
theorem ofDigits_one (L : List ℕ) : ofDigits 1 L = L.sum := by
induction L with
| nil => rfl
| cons _ _ ih => simp [ofDigits, List.sum_cons, ih]
/-!
### Properties
This section contains various lemmas of properties relating to `digits` and `ofDigits`.
-/
theorem digits_eq_nil_iff_eq_zero {b n : ℕ} : digits b n = [] ↔ n = 0 := by
constructor
· intro h
have : ofDigits b (digits b n) = ofDigits b [] := by rw [h]
convert this
rw [ofDigits_digits]
· rintro rfl
simp
theorem digits_ne_nil_iff_ne_zero {b n : ℕ} : digits b n ≠ [] ↔ n ≠ 0 :=
not_congr digits_eq_nil_iff_eq_zero
theorem digits_eq_cons_digits_div {b n : ℕ} (h : 1 < b) (w : n ≠ 0) :
digits b n = (n % b) :: digits b (n / b) := by
rcases b with (_ | _ | b)
· rw [digits_zero_succ' w, Nat.mod_zero, Nat.div_zero, Nat.digits_zero_zero]
· norm_num at h
rcases n with (_ | n)
· norm_num at w
· simp only [digits_add_two_add_one, ne_eq]
theorem digits_getLast {b : ℕ} (m : ℕ) (h : 1 < b) (p q) :
(digits b m).getLast p = (digits b (m / b)).getLast q := by
by_cases hm : m = 0
· simp [hm]
simp only [digits_eq_cons_digits_div h hm]
rw [List.getLast_cons]
theorem digits.injective (b : ℕ) : Function.Injective b.digits :=
Function.LeftInverse.injective (ofDigits_digits b)
@[simp]
theorem digits_inj_iff {b n m : ℕ} : b.digits n = b.digits m ↔ n = m :=
(digits.injective b).eq_iff
theorem digits_len (b n : ℕ) (hb : 1 < b) (hn : n ≠ 0) : (b.digits n).length = b.log n + 1 := by
induction' n using Nat.strong_induction_on with n IH
rw [digits_eq_cons_digits_div hb hn, List.length]
by_cases h : n / b = 0
· simp [IH, h]
aesop
· have : n / b < n := div_lt_self (Nat.pos_of_ne_zero hn) hb
rw [IH _ this h, log_div_base, tsub_add_cancel_of_le]
refine Nat.succ_le_of_lt (log_pos hb ?_)
contrapose! h
exact div_eq_of_lt h
theorem getLast_digit_ne_zero (b : ℕ) {m : ℕ} (hm : m ≠ 0) :
(digits b m).getLast (digits_ne_nil_iff_ne_zero.mpr hm) ≠ 0 := by
rcases b with (_ | _ | b)
· cases m
· cases hm rfl
· simp
· cases m
· cases hm rfl
rename ℕ => m
simp only [zero_add, digits_one, List.getLast_replicate_succ m 1]
exact Nat.one_ne_zero
revert hm
induction m using Nat.strongRecOn with | ind n IH => ?_
intro hn
by_cases hnb : n < b + 2
· simpa only [digits_of_lt (b + 2) n hn hnb]
· rw [digits_getLast n (le_add_left 2 b)]
refine IH _ (Nat.div_lt_self hn.bot_lt (one_lt_succ_succ b)) ?_
rw [← pos_iff_ne_zero]
exact Nat.div_pos (le_of_not_lt hnb) (zero_lt_succ (succ b))
theorem mul_ofDigits (n : ℕ) {b : ℕ} {l : List ℕ} :
n * ofDigits b l = ofDigits b (l.map (n * ·)) := by
induction l with
| nil => rfl
| cons hd tl ih =>
rw [List.map_cons, ofDigits_cons, ofDigits_cons, ← ih]
ring
lemma ofDigits_inj_of_len_eq {b : ℕ} (hb : 1 < b) {L1 L2 : List ℕ}
(len : L1.length = L2.length) (w1 : ∀ l ∈ L1, l < b) (w2 : ∀ l ∈ L2, l < b)
(h : ofDigits b L1 = ofDigits b L2) : L1 = L2 := by
induction' L1 with D L ih generalizing L2
· simp only [List.length_nil] at len
exact (List.length_eq_zero_iff.mp len.symm).symm
obtain ⟨d, l, rfl⟩ := List.exists_cons_of_length_eq_add_one len.symm
simp only [List.length_cons, add_left_inj] at len
simp only [ofDigits_cons] at h
have eqd : D = d := by
have H : (D + b * ofDigits b L) % b = (d + b * ofDigits b l) % b := by rw [h]
simpa [mod_eq_of_lt (w2 d List.mem_cons_self),
mod_eq_of_lt (w1 D List.mem_cons_self)] using H
simp only [eqd, add_right_inj, mul_left_cancel_iff_of_pos (zero_lt_of_lt hb)] at h
have := ih len (fun a ha ↦ w1 a <| List.mem_cons_of_mem D ha)
(fun a ha ↦ w2 a <| List.mem_cons_of_mem d ha) h
rw [eqd, this]
/-- The addition of ofDigits of two lists is equal to ofDigits of digit-wise addition of them -/
theorem ofDigits_add_ofDigits_eq_ofDigits_zipWith_of_length_eq {b : ℕ} {l1 l2 : List ℕ}
(h : l1.length = l2.length) :
ofDigits b l1 + ofDigits b l2 = ofDigits b (l1.zipWith (· + ·) l2) := by
induction l1 generalizing l2 with
| nil => simp_all [eq_comm, List.length_eq_zero_iff, ofDigits]
| cons hd₁ tl₁ ih₁ =>
induction l2 generalizing tl₁ with
| nil => simp_all
| cons hd₂ tl₂ ih₂ =>
simp_all only [List.length_cons, succ_eq_add_one, ofDigits_cons, add_left_inj,
eq_comm, List.zipWith_cons_cons, add_eq]
rw [← ih₁ h.symm, mul_add]
ac_rfl
/-- The digits in the base b+2 expansion of n are all less than b+2 -/
theorem digits_lt_base' {b m : ℕ} : ∀ {d}, d ∈ digits (b + 2) m → d < b + 2 := by
induction m using Nat.strongRecOn with | ind n IH => ?_
intro d hd
rcases n with - | n
· rw [digits_zero] at hd
cases hd
-- base b+2 expansion of 0 has no digits
rw [digits_add_two_add_one] at hd
cases hd
· exact n.succ.mod_lt (by linarith)
· apply IH ((n + 1) / (b + 2))
· apply Nat.div_lt_self <;> omega
· assumption
/-- The digits in the base b expansion of n are all less than b, if b ≥ 2 -/
theorem digits_lt_base {b m d : ℕ} (hb : 1 < b) (hd : d ∈ digits b m) : d < b := by
rcases b with (_ | _ | b) <;> try simp_all
exact digits_lt_base' hd
/-- an n-digit number in base b + 2 is less than (b + 2)^n -/
theorem ofDigits_lt_base_pow_length' {b : ℕ} {l : List ℕ} (hl : ∀ x ∈ l, x < b + 2) :
ofDigits (b + 2) l < (b + 2) ^ l.length := by
induction' l with hd tl IH
· simp [ofDigits]
· rw [ofDigits, List.length_cons, pow_succ]
have : (ofDigits (b + 2) tl + 1) * (b + 2) ≤ (b + 2) ^ tl.length * (b + 2) :=
mul_le_mul (IH fun x hx => hl _ (List.mem_cons_of_mem _ hx)) (by rfl) (by simp only [zero_le])
(Nat.zero_le _)
suffices ↑hd < b + 2 by linarith
exact hl hd List.mem_cons_self
/-- an n-digit number in base b is less than b^n if b > 1 -/
theorem ofDigits_lt_base_pow_length {b : ℕ} {l : List ℕ} (hb : 1 < b) (hl : ∀ x ∈ l, x < b) :
ofDigits b l < b ^ l.length := by
rcases b with (_ | _ | b) <;> try simp_all
exact ofDigits_lt_base_pow_length' hl
/-- Any number m is less than (b+2)^(number of digits in the base b + 2 representation of m) -/
theorem lt_base_pow_length_digits' {b m : ℕ} : m < (b + 2) ^ (digits (b + 2) m).length := by
convert @ofDigits_lt_base_pow_length' b (digits (b + 2) m) fun _ => digits_lt_base'
rw [ofDigits_digits (b + 2) m]
/-- Any number m is less than b^(number of digits in the base b representation of m) -/
theorem lt_base_pow_length_digits {b m : ℕ} (hb : 1 < b) : m < b ^ (digits b m).length := by
rcases b with (_ | _ | b) <;> try simp_all
exact lt_base_pow_length_digits'
theorem digits_base_pow_mul {b k m : ℕ} (hb : 1 < b) (hm : 0 < m) :
digits b (b ^ k * m) = List.replicate k 0 ++ digits b m := by
induction k generalizing m with
| zero => simp
| succ k ih =>
have hmb : 0 < m * b := lt_mul_of_lt_of_one_lt' hm hb
let h1 := digits_def' hb hmb
have h2 : m = m * b / b :=
Nat.eq_div_of_mul_eq_left (ne_zero_of_lt hb) rfl
simp only [mul_mod_left, ← h2] at h1
rw [List.replicate_succ', List.append_assoc, List.singleton_append, ← h1, ← ih hmb]
ring_nf
theorem ofDigits_digits_append_digits {b m n : ℕ} :
ofDigits b (digits b n ++ digits b m) = n + b ^ (digits b n).length * m := by
rw [ofDigits_append, ofDigits_digits, ofDigits_digits]
theorem digits_append_digits {b m n : ℕ} (hb : 0 < b) :
digits b n ++ digits b m = digits b (n + b ^ (digits b n).length * m) := by
rcases eq_or_lt_of_le (Nat.succ_le_of_lt hb) with (rfl | hb)
· simp
rw [← ofDigits_digits_append_digits]
refine (digits_ofDigits b hb _ (fun l hl => ?_) (fun h_append => ?_)).symm
· rcases (List.mem_append.mp hl) with (h | h) <;> exact digits_lt_base hb h
· by_cases h : digits b m = []
· simp only [h, List.append_nil] at h_append ⊢
exact getLast_digit_ne_zero b <| digits_ne_nil_iff_ne_zero.mp h_append
· exact (List.getLast_append_of_right_ne_nil _ _ h) ▸
(getLast_digit_ne_zero _ <| digits_ne_nil_iff_ne_zero.mp h)
theorem digits_append_zeroes_append_digits {b k m n : ℕ} (hb : 1 < b) (hm : 0 < m) :
digits b n ++ List.replicate k 0 ++ digits b m =
digits b (n + b ^ ((digits b n).length + k) * m) := by
rw [List.append_assoc, ← digits_base_pow_mul hb hm]
simp only [digits_append_digits (zero_lt_of_lt hb), digits_inj_iff, add_right_inj]
ring
theorem digits_len_le_digits_len_succ (b n : ℕ) :
(digits b n).length ≤ (digits b (n + 1)).length := by
rcases Decidable.eq_or_ne n 0 with (rfl | hn)
· simp
rcases le_or_lt b 1 with hb | hb
· interval_cases b <;> simp +arith [digits_zero_succ', hn]
simpa [digits_len, hb, hn] using log_mono_right (le_succ _)
theorem le_digits_len_le (b n m : ℕ) (h : n ≤ m) : (digits b n).length ≤ (digits b m).length :=
monotone_nat_of_le_succ (digits_len_le_digits_len_succ b) h
@[mono]
theorem ofDigits_monotone {p q : ℕ} (L : List ℕ) (h : p ≤ q) : ofDigits p L ≤ ofDigits q L := by
induction L with
| nil => rfl
| cons _ _ hi =>
simp only [ofDigits, cast_id, add_le_add_iff_left]
exact Nat.mul_le_mul h hi
theorem sum_le_ofDigits {p : ℕ} (L : List ℕ) (h : 1 ≤ p) : L.sum ≤ ofDigits p L :=
(ofDigits_one L).symm ▸ ofDigits_monotone L h
theorem digit_sum_le (p n : ℕ) : List.sum (digits p n) ≤ n := by
induction' n with n
· exact digits_zero _ ▸ Nat.le_refl (List.sum [])
· induction' p with p
· rw [digits_zero_succ, List.sum_cons, List.sum_nil, add_zero]
· nth_rw 2 [← ofDigits_digits p.succ (n + 1)]
rw [← ofDigits_one <| digits p.succ n.succ]
exact ofDigits_monotone (digits p.succ n.succ) <| Nat.succ_pos p
theorem pow_length_le_mul_ofDigits {b : ℕ} {l : List ℕ} (hl : l ≠ []) (hl2 : l.getLast hl ≠ 0) :
(b + 2) ^ l.length ≤ (b + 2) * ofDigits (b + 2) l := by
rw [← List.dropLast_append_getLast hl]
simp only [List.length_append, List.length, zero_add, List.length_dropLast, ofDigits_append,
List.length_dropLast, ofDigits_singleton, add_comm (l.length - 1), pow_add, pow_one]
apply Nat.mul_le_mul_left
refine le_trans ?_ (Nat.le_add_left _ _)
have : 0 < l.getLast hl := by rwa [pos_iff_ne_zero]
convert Nat.mul_le_mul_left ((b + 2) ^ (l.length - 1)) this using 1
rw [Nat.mul_one]
/-- Any non-zero natural number `m` is greater than
(b+2)^((number of digits in the base (b+2) representation of m) - 1)
-/
theorem base_pow_length_digits_le' (b m : ℕ) (hm : m ≠ 0) :
(b + 2) ^ (digits (b + 2) m).length ≤ (b + 2) * m := by
have : digits (b + 2) m ≠ [] := digits_ne_nil_iff_ne_zero.mpr hm
convert @pow_length_le_mul_ofDigits b (digits (b+2) m)
this (getLast_digit_ne_zero _ hm)
rw [ofDigits_digits]
/-- Any non-zero natural number `m` is greater than
b^((number of digits in the base b representation of m) - 1)
-/
theorem base_pow_length_digits_le (b m : ℕ) (hb : 1 < b) :
m ≠ 0 → b ^ (digits b m).length ≤ b * m := by
rcases b with (_ | _ | b) <;> try simp_all
exact base_pow_length_digits_le' b m
/-- Interpreting as a base `p` number and dividing by `p` is the same as interpreting the tail.
-/
lemma ofDigits_div_eq_ofDigits_tail {p : ℕ} (hpos : 0 < p) (digits : List ℕ)
(w₁ : ∀ l ∈ digits, l < p) : ofDigits p digits / p = ofDigits p digits.tail := by
induction' digits with hd tl
· simp [ofDigits]
· refine Eq.trans (add_mul_div_left hd _ hpos) ?_
rw [Nat.div_eq_of_lt <| w₁ _ List.mem_cons_self, zero_add]
rfl
/-- Interpreting as a base `p` number and dividing by `p^i` is the same as dropping `i`.
-/
lemma ofDigits_div_pow_eq_ofDigits_drop
{p : ℕ} (i : ℕ) (hpos : 0 < p) (digits : List ℕ) (w₁ : ∀ l ∈ digits, l < p) :
ofDigits p digits / p ^ i = ofDigits p (digits.drop i) := by
induction' i with i hi
· simp
· rw [Nat.pow_succ, ← Nat.div_div_eq_div_mul, hi, ofDigits_div_eq_ofDigits_tail hpos
(List.drop i digits) fun x hx ↦ w₁ x <| List.mem_of_mem_drop hx, ← List.drop_one,
List.drop_drop, add_comm]
/-- Dividing `n` by `p^i` is like truncating the first `i` digits of `n` in base `p`.
-/
lemma self_div_pow_eq_ofDigits_drop {p : ℕ} (i n : ℕ) (h : 2 ≤ p) :
n / p ^ i = ofDigits p ((p.digits n).drop i) := by
convert ofDigits_div_pow_eq_ofDigits_drop i (zero_lt_of_lt h) (p.digits n)
(fun l hl ↦ digits_lt_base h hl)
exact (ofDigits_digits p n).symm
open Finset
theorem sub_one_mul_sum_div_pow_eq_sub_sum_digits {p : ℕ}
(L : List ℕ) {h_nonempty} (h_ne_zero : L.getLast h_nonempty ≠ 0) (h_lt : ∀ l ∈ L, l < p) :
(p - 1) * ∑ i ∈ range L.length, (ofDigits p L) / p ^ i.succ = (ofDigits p L) - L.sum := by
obtain h | rfl | h : 1 < p ∨ 1 = p ∨ p < 1 := trichotomous 1 p
· induction' L with hd tl ih
· simp [ofDigits]
· simp only [List.length_cons, List.sum_cons, self_div_pow_eq_ofDigits_drop _ _ h,
digits_ofDigits p h (hd :: tl) h_lt (fun _ => h_ne_zero)]
simp only [ofDigits]
rw [sum_range_succ, Nat.cast_id]
simp only [List.drop, List.drop_length]
obtain rfl | h' := em <| tl = []
· simp [ofDigits]
· have w₁' := fun l hl ↦ h_lt l <| List.mem_cons_of_mem hd hl
have w₂' := fun (h : tl ≠ []) ↦ (List.getLast_cons h) ▸ h_ne_zero
have ih := ih (w₂' h') w₁'
simp only [self_div_pow_eq_ofDigits_drop _ _ h, digits_ofDigits p h tl w₁' w₂',
← Nat.one_add] at ih
have := sum_singleton (fun x ↦ ofDigits p <| tl.drop x) tl.length
rw [← Ico_succ_singleton, List.drop_length, ofDigits] at this
have h₁ : 1 ≤ tl.length := List.length_pos_iff.mpr h'
rw [← sum_range_add_sum_Ico _ <| h₁, ← add_zero (∑ x ∈ Ico _ _, ofDigits p (tl.drop x)),
← this, sum_Ico_consecutive _ h₁ <| (le_add_right tl.length 1),
← sum_Ico_add _ 0 tl.length 1,
Ico_zero_eq_range, mul_add, mul_add, ih, range_one, sum_singleton, List.drop, ofDigits,
mul_zero, add_zero, ← Nat.add_sub_assoc <| sum_le_ofDigits _ <| Nat.le_of_lt h]
nth_rw 2 [← one_mul <| ofDigits p tl]
rw [← add_mul, Nat.sub_add_cancel (one_le_of_lt h), Nat.add_sub_add_left]
· simp [ofDigits_one]
· simp [lt_one_iff.mp h]
cases L
· rfl
· simp [ofDigits]
theorem sub_one_mul_sum_log_div_pow_eq_sub_sum_digits {p : ℕ} (n : ℕ) :
(p - 1) * ∑ i ∈ range (log p n).succ, n / p ^ i.succ = n - (p.digits n).sum := by
obtain h | rfl | h : 1 < p ∨ 1 = p ∨ p < 1 := trichotomous 1 p
· rcases eq_or_ne n 0 with rfl | hn
· simp
· convert sub_one_mul_sum_div_pow_eq_sub_sum_digits (p.digits n) (getLast_digit_ne_zero p hn) <|
(fun l a ↦ digits_lt_base h a)
· refine (digits_len p n h hn).symm
all_goals exact (ofDigits_digits p n).symm
· simp
· simp [lt_one_iff.mp h]
cases n
all_goals simp
/-! ### Binary -/
theorem digits_two_eq_bits (n : ℕ) : digits 2 n = n.bits.map fun b => cond b 1 0 := by
induction' n using Nat.binaryRecFromOne with b n h ih
· simp
| · simp
rw [bits_append_bit _ _ fun hn => absurd hn h]
cases b
· rw [digits_def' one_lt_two]
· simpa [Nat.bit]
· simpa [Nat.bit, pos_iff_ne_zero]
· simpa [Nat.bit, add_comm, digits_add 2 one_lt_two 1 n, Nat.add_mul_div_left]
/-! ### Modular Arithmetic -/
-- This is really a theorem about polynomials.
theorem dvd_ofDigits_sub_ofDigits {α : Type*} [CommRing α] {a b k : α} (h : k ∣ a - b)
| Mathlib/Data/Nat/Digits.lean | 606 | 618 |
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