data.finset.locally_finite | Mathlib porting status

(last sync)

feat(data/finset/lattice): sup'/inf' lemmas (#18989)

Match (most of) the lemmas between finset.sup/finset.inf and finset.sup'/finset.inf'. Also golf two proofs using eq_of_forall_ge_iff to make sure both APIs prove their lemmas in as closely as possible a way. Also define finset.nontrivial to match set.nontrivial.

Diff

@@ -199,16 +199,16 @@ end
 
 lemma Icc_filter_lt_of_lt_right {a b c : α} [decidable_pred (< c)] (h : b < c) :
   (Icc a b).filter (< c) = Icc a b :=
-(finset.filter_eq_self _).2 (λ x hx, lt_of_le_of_lt (mem_Icc.1 hx).2 h)
+filter_true_of_mem $ λ x hx, (mem_Icc.1 hx).2.trans_lt h
 
 lemma Ioc_filter_lt_of_lt_right {a b c : α} [decidable_pred (< c)] (h : b < c) :
   (Ioc a b).filter (< c) = Ioc a b :=
-(finset.filter_eq_self _).2 (λ x hx, lt_of_le_of_lt (mem_Ioc.1 hx).2 h)
+filter_true_of_mem $ λ x hx, (mem_Ioc.1 hx).2.trans_lt h
 
 lemma Iic_filter_lt_of_lt_right {α} [preorder α] [locally_finite_order_bot α]
     {a c : α} [decidable_pred (< c)] (h : a < c) :
   (Iic a).filter (< c) = Iic a :=
-(finset.filter_eq_self _).2 (λ x hx, lt_of_le_of_lt (mem_Iic.1 hx) h)
+filter_true_of_mem $ λ x hx, (mem_Iic.1 hx).trans_lt h
 
 variables (a b) [fintype α]

feat(data/*/interval): finset.uIcc on concrete structures (#18838)

Calculate the size of finset.uIcc in ℕ, ℤ, fin, prod, pi, multiset, finset...

Co-authored-by: Eric Wieser <wieser.eric@gmail.com>

Diff

@@ -564,8 +564,11 @@ lemma Icc_subset_uIcc' : Icc b a ⊆ [a, b] := Icc_subset_Icc inf_le_right le_su
 @[simp] lemma left_mem_uIcc : a ∈ [a, b] := mem_Icc.2 ⟨inf_le_left, le_sup_left⟩
 @[simp] lemma right_mem_uIcc : b ∈ [a, b] := mem_Icc.2 ⟨inf_le_right, le_sup_right⟩
 
-lemma mem_uIcc_of_le (ha : a ≤ x) (hb : x ≤ b) : x ∈ [a, b] := Icc_subset_uIcc $ mem_Icc.2 ⟨ha, hb⟩
-lemma mem_uIcc_of_ge (hb : b ≤ x) (ha : x ≤ a) : x ∈ [a, b] := Icc_subset_uIcc' $ mem_Icc.2 ⟨hb, ha⟩
+lemma mem_uIcc_of_le (ha : a ≤ x) (hb : x ≤ b) : x ∈ [a, b] :=
+Icc_subset_uIcc $ mem_Icc.2 ⟨ha, hb⟩
+
+lemma mem_uIcc_of_ge (hb : b ≤ x) (ha : x ≤ a) : x ∈ [a, b] :=
+Icc_subset_uIcc' $ mem_Icc.2 ⟨hb, ha⟩
 
 lemma uIcc_subset_uIcc (h₁ : a₁ ∈ [a₂, b₂]) (h₂ : b₁ ∈ [a₂, b₂]) : [a₁, b₁] ⊆ [a₂, b₂] :=
 by { rw mem_uIcc at h₁ h₂, exact Icc_subset_Icc (le_inf h₁.1 h₂.1) (sup_le h₁.2 h₂.2) }
@@ -576,11 +579,15 @@ by { rw mem_Icc at ha hb, exact Icc_subset_Icc (le_inf ha.1 hb.1) (sup_le ha.2 h
 lemma uIcc_subset_uIcc_iff_mem : [a₁, b₁] ⊆ [a₂, b₂] ↔ a₁ ∈ [a₂, b₂] ∧ b₁ ∈ [a₂, b₂] :=
 ⟨λ h, ⟨h left_mem_uIcc, h right_mem_uIcc⟩, λ h, uIcc_subset_uIcc h.1 h.2⟩
 
-lemma uIcc_subset_uIcc_iff_le' : [a₁, b₁] ⊆ [a₂, b₂] ↔ a₂ ⊓ b₂ ≤ a₁ ⊓ b₁ ∧ a₁ ⊔ b₁ ≤ a₂ ⊔ b₂ :=
+lemma uIcc_subset_uIcc_iff_le' :
+  [a₁, b₁] ⊆ [a₂, b₂] ↔ a₂ ⊓ b₂ ≤ a₁ ⊓ b₁ ∧ a₁ ⊔ b₁ ≤ a₂ ⊔ b₂ :=
 Icc_subset_Icc_iff inf_le_sup
 
-lemma uIcc_subset_uIcc_right (h : x ∈ [a, b]) : [x, b] ⊆ [a, b] := uIcc_subset_uIcc h right_mem_uIcc
-lemma uIcc_subset_uIcc_left (h : x ∈ [a, b]) : [a, x] ⊆ [a, b] := uIcc_subset_uIcc left_mem_uIcc h
+lemma uIcc_subset_uIcc_right (h : x ∈ [a, b]) : [x, b] ⊆ [a, b] :=
+uIcc_subset_uIcc h right_mem_uIcc
+
+lemma uIcc_subset_uIcc_left (h : x ∈ [a, b]) : [a, x] ⊆ [a, b] :=
+uIcc_subset_uIcc left_mem_uIcc h
 
 end lattice

feat(data/set/finite): Add lemmas relating definitions of infinite sets (#18620)

Prove the following lemmas (and their dual)

set.infinite_of_forall_exists_lt: (∀ a, ∃ b ∈ s, a < b) → s.infinite in a nonempty preorder
set.infinite_iff_exists_lt: (∀ a, ∃ b ∈ s, a < b) ↔ s.infinite in a locally finite order with a bottom element

Co-authored-by: Yaël Dillies <yael.dillies@gmail.com> Co-authored-by: Eric Wieser <wieser.eric@gmail.com>

Diff

@@ -259,6 +259,9 @@ lemma Ioi_subset_Ici_self : Ioi a ⊆ Ici a := by simpa [←coe_subset] using se
 lemma _root_.bdd_below.finite {s : set α} (hs : bdd_below s) : s.finite :=
 let ⟨a, ha⟩ := hs in (Ici a).finite_to_set.subset $ λ x hx, mem_Ici.2 $ ha hx
 
+lemma _root_.set.infinite.not_bdd_below {s : set α} : s.infinite → ¬ bdd_below s :=
+mt bdd_below.finite
+
 variables [fintype α]
 
 lemma filter_lt_eq_Ioi [decidable_pred ((<) a)] : univ.filter ((<) a) = Ioi a := by { ext, simp }
@@ -273,6 +276,9 @@ lemma Iio_subset_Iic_self : Iio a ⊆ Iic a := by simpa [←coe_subset] using se
 
 lemma _root_.bdd_above.finite {s : set α} (hs : bdd_above s) : s.finite := hs.dual.finite
 
+lemma _root_.set.infinite.not_bdd_above {s : set α} : s.infinite → ¬ bdd_above s :=
+mt bdd_above.finite
+
 variables [fintype α]
 
 lemma filter_gt_eq_Iio [decidable_pred (< a)] : univ.filter (< a) = Iio a := by { ext, simp }
@@ -504,6 +510,28 @@ end
 
 end locally_finite_order
 
+section locally_finite_order_bot
+variables [locally_finite_order_bot α] {s : set α}
+
+lemma _root_.set.infinite.exists_gt (hs : s.infinite) : ∀ a, ∃ b ∈ s, a < b :=
+not_bdd_above_iff.1 hs.not_bdd_above
+
+lemma _root_.set.infinite_iff_exists_gt [nonempty α] : s.infinite ↔ ∀ a, ∃ b ∈ s, a < b :=
+⟨set.infinite.exists_gt, set.infinite_of_forall_exists_gt⟩
+
+end locally_finite_order_bot
+
+section locally_finite_order_top
+variables [locally_finite_order_top α] {s : set α}
+
+lemma _root_.set.infinite.exists_lt (hs : s.infinite) : ∀ a, ∃ b ∈ s, b < a :=
+not_bdd_below_iff.1 hs.not_bdd_below
+
+lemma _root_.set.infinite_iff_exists_lt [nonempty α] : s.infinite ↔ ∀ a, ∃ b ∈ s, b < a :=
+⟨set.infinite.exists_lt, set.infinite_of_forall_exists_lt⟩
+
+end locally_finite_order_top
+
 variables [fintype α] [locally_finite_order_top α] [locally_finite_order_bot α]
 
 lemma Ioi_disj_union_Iio (a : α) :

chore(data/finset/locally_finite): lemmas about open intervals (#18533)

We had cons lemmas for the other four cases, but not these two.

The new lemmas golf a proof a little.

Also adds some docstrings to makes these lemmas easier to find.

Forward-ported in https://github.com/leanprover-community/mathlib4/pull/2812

Diff

@@ -332,12 +332,22 @@ end decidable_eq
 
 -- Those lemmas are purposefully the other way around
 
+/-- `finset.cons` version of `finset.Ico_insert_right`. -/
 lemma Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico :=
 by { classical, rw [cons_eq_insert, Ico_insert_right h] }
 
+/-- `finset.cons` version of `finset.Ioc_insert_left`. -/
 lemma Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc :=
 by { classical, rw [cons_eq_insert, Ioc_insert_left h] }
 
+/-- `finset.cons` version of `finset.Ioo_insert_right`. -/
+lemma Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo :=
+by { classical, rw [cons_eq_insert, Ioo_insert_right h], }
+
+/-- `finset.cons` version of `finset.Ioo_insert_left`. -/
+lemma Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo :=
+by { classical, rw [cons_eq_insert, Ioo_insert_left h] }
+
 lemma Ico_filter_le_left {a b : α} [decidable_pred (≤ a)] (hab : a < b) :
   (Ico a b).filter (λ x, x ≤ a) = {a} :=
 begin
@@ -350,7 +360,7 @@ lemma card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card
 begin
   classical,
   by_cases h : a ≤ b,
-  { rw [←Ico_insert_right h, card_insert_of_not_mem right_not_mem_Ico],
+  { rw [Icc_eq_cons_Ico h, card_cons],
     exact (nat.add_sub_cancel _ _).symm },
   { rw [Ico_eq_empty (λ h', h h'.le), Icc_eq_empty h, card_empty, zero_tsub] }
 end
@@ -361,12 +371,10 @@ lemma card_Ioc_eq_card_Icc_sub_one (a b : α) : (Ioc a b).card = (Icc a b).card
 lemma card_Ioo_eq_card_Ico_sub_one (a b : α) : (Ioo a b).card = (Ico a b).card - 1 :=
 begin
   classical,
-  by_cases h : a ≤ b,
-  { obtain rfl | h' := h.eq_or_lt,
-    { rw [Ioo_self, Ico_self, card_empty] },
-    rw [←Ioo_insert_left h', card_insert_of_not_mem left_not_mem_Ioo],
+  by_cases h : a < b,
+  { rw [Ico_eq_cons_Ioo h, card_cons],
     exact (nat.add_sub_cancel _ _).symm },
-  { rw [Ioo_eq_empty (λ h', h h'.le), Ico_eq_empty (λ h', h h'.le), card_empty, zero_tsub] }
+  { rw [Ioo_eq_empty h, Ico_eq_empty h, card_empty, zero_tsub] }
 end
 
 lemma card_Ioo_eq_card_Ioc_sub_one (a b : α) : (Ioo a b).card = (Ioc a b).card - 1 :=
@@ -391,6 +399,7 @@ by { ext, simp_rw [finset.mem_insert, mem_Ici, mem_Ioi, le_iff_lt_or_eq, or_comm
 @[simp] lemma not_mem_Ioi_self {b : α} : b ∉ Ioi b := λ h, lt_irrefl _ (mem_Ioi.1 h)
 
 -- Purposefully written the other way around
+/-- `finset.cons` version of `finset.Ioi_insert`. -/
 lemma Ici_eq_cons_Ioi (a : α) : Ici a = (Ioi a).cons a not_mem_Ioi_self :=
 by { classical, rw [cons_eq_insert, Ioi_insert] }
 
@@ -410,6 +419,7 @@ by { ext, simp_rw [finset.mem_insert, mem_Iic, mem_Iio, le_iff_lt_or_eq, or_comm
 @[simp] lemma not_mem_Iio_self {b : α} : b ∉ Iio b := λ h, lt_irrefl _ (mem_Iio.1 h)
 
 -- Purposefully written the other way around
+/-- `finset.cons` version of `finset.Iio_insert`. -/
 lemma Iic_eq_cons_Iio (b : α) : Iic b = (Iio b).cons b not_mem_Iio_self :=
 by { classical, rw [cons_eq_insert, Iio_insert] }

(first ported)

Changes in mathlib3port

mathlib3

mathlib3port

bump to nightly-2024-04-26-08

mathlib commit https://github.com/leanprover-community/mathlib/commit/65a1391a0106c9204fe45bc73a039f056558cb83

ab3b6a0f

Diff

@@ -3,8 +3,8 @@ Copyright (c) 2019 Scott Morrison. All rights reserved.
 Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 -/
-import Order.LocallyFinite
-import Data.Set.Intervals.Monoid
+import Order.Interval.Finset.Defs
+import Algebra.Order.Interval.Set.Monoid
 
 #align_import data.finset.locally_finite from "leanprover-community/mathlib"@"442a83d738cb208d3600056c489be16900ba701d"

bump to nightly-2024-04-25-08

mathlib commit https://github.com/leanprover-community/mathlib/commit/65a1391a0106c9204fe45bc73a039f056558cb83

ad7a2212

Diff

@@ -436,7 +436,7 @@ theorem Ico_filter_le_of_right_le {a b : α} [DecidablePred ((· ≤ ·) b)] :
 theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred ((· ≤ ·) c)] (hac : a ≤ c) :
     (Ico a b).filterₓ ((· ≤ ·) c) = Ico c b := by
   ext x
-  rw [mem_filter, mem_Ico, mem_Ico, and_comm', and_left_comm]
+  rw [mem_filter, mem_Ico, mem_Ico, and_comm, and_left_comm]
   exact and_iff_right_of_imp fun h => hac.trans h.1
 #align finset.Ico_filter_le_of_left_le Finset.Ico_filter_le_of_left_le
 -/
@@ -873,14 +873,14 @@ variable [LocallyFiniteOrderTop α]
 #print Finset.Ici_erase /-
 @[simp]
 theorem Ici_erase [DecidableEq α] (a : α) : (Ici a).eraseₓ a = Ioi a := by ext;
-  simp_rw [Finset.mem_erase, mem_Ici, mem_Ioi, lt_iff_le_and_ne, and_comm', ne_comm]
+  simp_rw [Finset.mem_erase, mem_Ici, mem_Ioi, lt_iff_le_and_ne, and_comm, ne_comm]
 #align finset.Ici_erase Finset.Ici_erase
 -/
 
 #print Finset.Ioi_insert /-
 @[simp]
 theorem Ioi_insert [DecidableEq α] (a : α) : insert a (Ioi a) = Ici a := by ext;
-  simp_rw [Finset.mem_insert, mem_Ici, mem_Ioi, le_iff_lt_or_eq, or_comm', eq_comm]
+  simp_rw [Finset.mem_insert, mem_Ici, mem_Ioi, le_iff_lt_or_eq, or_comm, eq_comm]
 #align finset.Ioi_insert Finset.Ioi_insert
 -/
 
@@ -913,14 +913,14 @@ variable [LocallyFiniteOrderBot α]
 #print Finset.Iic_erase /-
 @[simp]
 theorem Iic_erase [DecidableEq α] (b : α) : (Iic b).eraseₓ b = Iio b := by ext;
-  simp_rw [Finset.mem_erase, mem_Iic, mem_Iio, lt_iff_le_and_ne, and_comm']
+  simp_rw [Finset.mem_erase, mem_Iic, mem_Iio, lt_iff_le_and_ne, and_comm]
 #align finset.Iic_erase Finset.Iic_erase
 -/
 
 #print Finset.Iio_insert /-
 @[simp]
 theorem Iio_insert [DecidableEq α] (b : α) : insert b (Iio b) = Iic b := by ext;
-  simp_rw [Finset.mem_insert, mem_Iic, mem_Iio, le_iff_lt_or_eq, or_comm']
+  simp_rw [Finset.mem_insert, mem_Iic, mem_Iio, le_iff_lt_or_eq, or_comm]
 #align finset.Iio_insert Finset.Iio_insert
 -/
 
@@ -1027,14 +1027,14 @@ theorem Ico_filter_le (a b c : α) : ((Ico a b).filterₓ fun x => c ≤ x) = Ic
 #print Finset.Ioo_filter_lt /-
 @[simp]
 theorem Ioo_filter_lt (a b c : α) : (Ioo a b).filterₓ (· < c) = Ioo a (min b c) := by ext;
-  simp [and_assoc']
+  simp [and_assoc]
 #align finset.Ioo_filter_lt Finset.Ioo_filter_lt
 -/
 
 #print Finset.Iio_filter_lt /-
 @[simp]
 theorem Iio_filter_lt {α} [LinearOrder α] [LocallyFiniteOrderBot α] (a b : α) :
-    (Iio a).filterₓ (· < b) = Iio (min a b) := by ext; simp [and_assoc']
+    (Iio a).filterₓ (· < b) = Iio (min a b) := by ext; simp [and_assoc]
 #align finset.Iio_filter_lt Finset.Iio_filter_lt
 -/
 
@@ -1057,7 +1057,7 @@ theorem Ico_diff_Ico_right (a b c : α) : Ico a b \ Ico c b = Ico a (min b c) :=
   cases le_total b c
   · rw [Ico_eq_empty_of_le h, sdiff_empty, min_eq_left h]
   · ext x
-    rw [mem_sdiff, mem_Ico, mem_Ico, mem_Ico, min_eq_right h, and_assoc', not_and', not_le]
+    rw [mem_sdiff, mem_Ico, mem_Ico, mem_Ico, min_eq_right h, and_assoc, not_and', not_le]
     exact and_congr_right' ⟨fun hx => hx.2 hx.1, fun hx => ⟨hx.trans_le h, fun _ => hx⟩⟩
 #align finset.Ico_diff_Ico_right Finset.Ico_diff_Ico_right
 -/

bump to nightly-2024-03-17-08

mathlib commit https://github.com/leanprover-community/mathlib/commit/65a1391a0106c9204fe45bc73a039f056558cb83

22f01ce4

Diff

@@ -1190,13 +1190,13 @@ theorem mem_uIcc_of_ge (hb : b ≤ x) (ha : x ≤ a) : x ∈ [a, b] :=
 
 #print Finset.uIcc_subset_uIcc /-
 theorem uIcc_subset_uIcc (h₁ : a₁ ∈ [a₂, b₂]) (h₂ : b₁ ∈ [a₂, b₂]) : [a₁, b₁] ⊆ [a₂, b₂] := by
-  rw [mem_uIcc] at h₁ h₂ ; exact Icc_subset_Icc (le_inf h₁.1 h₂.1) (sup_le h₁.2 h₂.2)
+  rw [mem_uIcc] at h₁ h₂; exact Icc_subset_Icc (le_inf h₁.1 h₂.1) (sup_le h₁.2 h₂.2)
 #align finset.uIcc_subset_uIcc Finset.uIcc_subset_uIcc
 -/
 
 #print Finset.uIcc_subset_Icc /-
 theorem uIcc_subset_Icc (ha : a₁ ∈ Icc a₂ b₂) (hb : b₁ ∈ Icc a₂ b₂) : [a₁, b₁] ⊆ Icc a₂ b₂ := by
-  rw [mem_Icc] at ha hb ; exact Icc_subset_Icc (le_inf ha.1 hb.1) (sup_le ha.2 hb.2)
+  rw [mem_Icc] at ha hb; exact Icc_subset_Icc (le_inf ha.1 hb.1) (sup_le ha.2 hb.2)
 #align finset.uIcc_subset_Icc Finset.uIcc_subset_Icc
 -/
 
@@ -1245,7 +1245,7 @@ theorem eq_of_mem_uIcc_of_mem_uIcc' : b ∈ [a, c] → c ∈ [a, b] → b = c :=
 #print Finset.uIcc_injective_right /-
 theorem uIcc_injective_right (a : α) : Injective fun b => [b, a] := fun b c h =>
   by
-  rw [ext_iff] at h 
+  rw [ext_iff] at h
   exact eq_of_mem_uIcc_of_mem_uIcc ((h _).1 left_mem_uIcc) ((h _).2 left_mem_uIcc)
 #align finset.uIcc_injective_right Finset.uIcc_injective_right
 -/

bump to nightly-2024-02-01-06

mathlib commit https://github.com/leanprover-community/mathlib/commit/65a1391a0106c9204fe45bc73a039f056558cb83

5433bded

Diff

@@ -389,7 +389,7 @@ theorem BddBelow.finite_of_bddAbove {s : Set α} (h₀ : BddBelow s) (h₁ : Bdd
   by
   let ⟨a, ha⟩ := h₀
   let ⟨b, hb⟩ := h₁
-  classical
+  classical exact ⟨Set.fintypeOfMemBounds ha hb⟩
 #align bdd_below.finite_of_bdd_above BddBelow.finite_of_bddAbove
 -/
 
@@ -786,25 +786,29 @@ end DecidableEq
 #print Finset.Icc_eq_cons_Ico /-
 -- Those lemmas are purposefully the other way around
 /-- `finset.cons` version of `finset.Ico_insert_right`. -/
-theorem Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico := by classical
+theorem Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico := by
+  classical rw [cons_eq_insert, Ico_insert_right h]
 #align finset.Icc_eq_cons_Ico Finset.Icc_eq_cons_Ico
 -/
 
 #print Finset.Icc_eq_cons_Ioc /-
 /-- `finset.cons` version of `finset.Ioc_insert_left`. -/
-theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc := by classical
+theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc := by
+  classical rw [cons_eq_insert, Ioc_insert_left h]
 #align finset.Icc_eq_cons_Ioc Finset.Icc_eq_cons_Ioc
 -/
 
 #print Finset.Ioc_eq_cons_Ioo /-
 /-- `finset.cons` version of `finset.Ioo_insert_right`. -/
-theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by classical
+theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by
+  classical rw [cons_eq_insert, Ioo_insert_right h]
 #align finset.Ioc_eq_cons_Ioo Finset.Ioc_eq_cons_Ioo
 -/
 
 #print Finset.Ico_eq_cons_Ioo /-
 /-- `finset.cons` version of `finset.Ioo_insert_left`. -/
-theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by classical
+theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by
+  classical rw [cons_eq_insert, Ioo_insert_left h]
 #align finset.Ico_eq_cons_Ioo Finset.Ico_eq_cons_Ioo
 -/
 
@@ -819,7 +823,12 @@ theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
 -/
 
 #print Finset.card_Ico_eq_card_Icc_sub_one /-
-theorem card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card - 1 := by classical
+theorem card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card - 1 := by
+  classical
+  by_cases h : a ≤ b
+  · rw [Icc_eq_cons_Ico h, card_cons]
+    exact (Nat.add_sub_cancel _ _).symm
+  · rw [Ico_eq_empty fun h' => h h'.le, Icc_eq_empty h, card_empty, zero_tsub]
 #align finset.card_Ico_eq_card_Icc_sub_one Finset.card_Ico_eq_card_Icc_sub_one
 -/
 
@@ -830,7 +839,12 @@ theorem card_Ioc_eq_card_Icc_sub_one (a b : α) : (Ioc a b).card = (Icc a b).car
 -/
 
 #print Finset.card_Ioo_eq_card_Ico_sub_one /-
-theorem card_Ioo_eq_card_Ico_sub_one (a b : α) : (Ioo a b).card = (Ico a b).card - 1 := by classical
+theorem card_Ioo_eq_card_Ico_sub_one (a b : α) : (Ioo a b).card = (Ico a b).card - 1 := by
+  classical
+  by_cases h : a < b
+  · rw [Ico_eq_cons_Ioo h, card_cons]
+    exact (Nat.add_sub_cancel _ _).symm
+  · rw [Ioo_eq_empty h, Ico_eq_empty h, card_empty, zero_tsub]
 #align finset.card_Ioo_eq_card_Ico_sub_one Finset.card_Ioo_eq_card_Ico_sub_one
 -/
 
@@ -879,7 +893,8 @@ theorem not_mem_Ioi_self {b : α} : b ∉ Ioi b := fun h => lt_irrefl _ (mem_Ioi
 #print Finset.Ici_eq_cons_Ioi /-
 -- Purposefully written the other way around
 /-- `finset.cons` version of `finset.Ioi_insert`. -/
-theorem Ici_eq_cons_Ioi (a : α) : Ici a = (Ioi a).cons a not_mem_Ioi_self := by classical
+theorem Ici_eq_cons_Ioi (a : α) : Ici a = (Ioi a).cons a not_mem_Ioi_self := by
+  classical rw [cons_eq_insert, Ioi_insert]
 #align finset.Ici_eq_cons_Ioi Finset.Ici_eq_cons_Ioi
 -/
 
@@ -918,7 +933,8 @@ theorem not_mem_Iio_self {b : α} : b ∉ Iio b := fun h => lt_irrefl _ (mem_Iio
 #print Finset.Iic_eq_cons_Iio /-
 -- Purposefully written the other way around
 /-- `finset.cons` version of `finset.Iio_insert`. -/
-theorem Iic_eq_cons_Iio (b : α) : Iic b = (Iio b).cons b not_mem_Iio_self := by classical
+theorem Iic_eq_cons_Iio (b : α) : Iic b = (Iio b).cons b not_mem_Iio_self := by
+  classical rw [cons_eq_insert, Iio_insert]
 #align finset.Iic_eq_cons_Iio Finset.Iic_eq_cons_Iio
 -/

bump to nightly-2024-01-31-06

mathlib commit https://github.com/leanprover-community/mathlib/commit/65a1391a0106c9204fe45bc73a039f056558cb83

61100fe9

Diff

@@ -389,7 +389,7 @@ theorem BddBelow.finite_of_bddAbove {s : Set α} (h₀ : BddBelow s) (h₁ : Bdd
   by
   let ⟨a, ha⟩ := h₀
   let ⟨b, hb⟩ := h₁
-  classical exact ⟨Set.fintypeOfMemBounds ha hb⟩
+  classical
 #align bdd_below.finite_of_bdd_above BddBelow.finite_of_bddAbove
 -/
 
@@ -786,29 +786,25 @@ end DecidableEq
 #print Finset.Icc_eq_cons_Ico /-
 -- Those lemmas are purposefully the other way around
 /-- `finset.cons` version of `finset.Ico_insert_right`. -/
-theorem Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico := by
-  classical rw [cons_eq_insert, Ico_insert_right h]
+theorem Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico := by classical
 #align finset.Icc_eq_cons_Ico Finset.Icc_eq_cons_Ico
 -/
 
 #print Finset.Icc_eq_cons_Ioc /-
 /-- `finset.cons` version of `finset.Ioc_insert_left`. -/
-theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc := by
-  classical rw [cons_eq_insert, Ioc_insert_left h]
+theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc := by classical
 #align finset.Icc_eq_cons_Ioc Finset.Icc_eq_cons_Ioc
 -/
 
 #print Finset.Ioc_eq_cons_Ioo /-
 /-- `finset.cons` version of `finset.Ioo_insert_right`. -/
-theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by
-  classical rw [cons_eq_insert, Ioo_insert_right h]
+theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by classical
 #align finset.Ioc_eq_cons_Ioo Finset.Ioc_eq_cons_Ioo
 -/
 
 #print Finset.Ico_eq_cons_Ioo /-
 /-- `finset.cons` version of `finset.Ioo_insert_left`. -/
-theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by
-  classical rw [cons_eq_insert, Ioo_insert_left h]
+theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by classical
 #align finset.Ico_eq_cons_Ioo Finset.Ico_eq_cons_Ioo
 -/
 
@@ -823,12 +819,7 @@ theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
 -/
 
 #print Finset.card_Ico_eq_card_Icc_sub_one /-
-theorem card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card - 1 := by
-  classical
-  by_cases h : a ≤ b
-  · rw [Icc_eq_cons_Ico h, card_cons]
-    exact (Nat.add_sub_cancel _ _).symm
-  · rw [Ico_eq_empty fun h' => h h'.le, Icc_eq_empty h, card_empty, zero_tsub]
+theorem card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card - 1 := by classical
 #align finset.card_Ico_eq_card_Icc_sub_one Finset.card_Ico_eq_card_Icc_sub_one
 -/
 
@@ -839,12 +830,7 @@ theorem card_Ioc_eq_card_Icc_sub_one (a b : α) : (Ioc a b).card = (Icc a b).car
 -/
 
 #print Finset.card_Ioo_eq_card_Ico_sub_one /-
-theorem card_Ioo_eq_card_Ico_sub_one (a b : α) : (Ioo a b).card = (Ico a b).card - 1 := by
-  classical
-  by_cases h : a < b
-  · rw [Ico_eq_cons_Ioo h, card_cons]
-    exact (Nat.add_sub_cancel _ _).symm
-  · rw [Ioo_eq_empty h, Ico_eq_empty h, card_empty, zero_tsub]
+theorem card_Ioo_eq_card_Ico_sub_one (a b : α) : (Ioo a b).card = (Ico a b).card - 1 := by classical
 #align finset.card_Ioo_eq_card_Ico_sub_one Finset.card_Ioo_eq_card_Ico_sub_one
 -/
 
@@ -893,8 +879,7 @@ theorem not_mem_Ioi_self {b : α} : b ∉ Ioi b := fun h => lt_irrefl _ (mem_Ioi
 #print Finset.Ici_eq_cons_Ioi /-
 -- Purposefully written the other way around
 /-- `finset.cons` version of `finset.Ioi_insert`. -/
-theorem Ici_eq_cons_Ioi (a : α) : Ici a = (Ioi a).cons a not_mem_Ioi_self := by
-  classical rw [cons_eq_insert, Ioi_insert]
+theorem Ici_eq_cons_Ioi (a : α) : Ici a = (Ioi a).cons a not_mem_Ioi_self := by classical
 #align finset.Ici_eq_cons_Ioi Finset.Ici_eq_cons_Ioi
 -/
 
@@ -933,8 +918,7 @@ theorem not_mem_Iio_self {b : α} : b ∉ Iio b := fun h => lt_irrefl _ (mem_Iio
 #print Finset.Iic_eq_cons_Iio /-
 -- Purposefully written the other way around
 /-- `finset.cons` version of `finset.Iio_insert`. -/
-theorem Iic_eq_cons_Iio (b : α) : Iic b = (Iio b).cons b not_mem_Iio_self := by
-  classical rw [cons_eq_insert, Iio_insert]
+theorem Iic_eq_cons_Iio (b : α) : Iic b = (Iio b).cons b not_mem_Iio_self := by classical
 #align finset.Iic_eq_cons_Iio Finset.Iic_eq_cons_Iio
 -/

bump to nightly-2023-11-29-11

mathlib commit https://github.com/leanprover-community/mathlib/commit/65a1391a0106c9204fe45bc73a039f056558cb83

049e2cad

Diff

@@ -1282,7 +1282,7 @@ theorem uIcc_of_not_ge (h : ¬b ≤ a) : [a, b] = Icc a b :=
 
 #print Finset.uIcc_eq_union /-
 theorem uIcc_eq_union : [a, b] = Icc a b ∪ Icc b a :=
-  coe_injective <| by push_cast ; exact Set.uIcc_eq_union
+  coe_injective <| by push_cast; exact Set.uIcc_eq_union
 #align finset.uIcc_eq_union Finset.uIcc_eq_union
 -/
 
@@ -1313,7 +1313,7 @@ theorem uIcc_subset_uIcc_iff_le :
 #print Finset.uIcc_subset_uIcc_union_uIcc /-
 /-- A sort of triangle inequality. -/
 theorem uIcc_subset_uIcc_union_uIcc : [a, c] ⊆ [a, b] ∪ [b, c] :=
-  coe_subset.1 <| by push_cast ; exact Set.uIcc_subset_uIcc_union_uIcc
+  coe_subset.1 <| by push_cast; exact Set.uIcc_subset_uIcc_union_uIcc
 #align finset.uIcc_subset_uIcc_union_uIcc Finset.uIcc_subset_uIcc_union_uIcc
 -/

bump to nightly-2023-09-24-06

mathlib commit https://github.com/leanprover-community/mathlib/commit/ce64cd319bb6b3e82f31c2d38e79080d377be451

5655435f

Diff

@@ -3,8 +3,8 @@ Copyright (c) 2019 Scott Morrison. All rights reserved.
 Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 -/
-import Mathbin.Order.LocallyFinite
-import Mathbin.Data.Set.Intervals.Monoid
+import Order.LocallyFinite
+import Data.Set.Intervals.Monoid
 
 #align_import data.finset.locally_finite from "leanprover-community/mathlib"@"442a83d738cb208d3600056c489be16900ba701d"

bump to nightly-2023-09-01-06

mathlib commit https://github.com/leanprover-community/mathlib/commit/442a83d738cb208d3600056c489be16900ba701d

8077ee24

Diff

@@ -6,7 +6,7 @@ Authors: Scott Morrison, Yaël Dillies
 import Mathbin.Order.LocallyFinite
 import Mathbin.Data.Set.Intervals.Monoid
 
-#align_import data.finset.locally_finite from "leanprover-community/mathlib"@"1d29de43a5ba4662dd33b5cfeecfc2a27a5a8a29"
+#align_import data.finset.locally_finite from "leanprover-community/mathlib"@"442a83d738cb208d3600056c489be16900ba701d"
 
 /-!
 # Intervals as finsets
@@ -444,21 +444,21 @@ theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred ((· ≤ ·) c)] (h
 #print Finset.Icc_filter_lt_of_lt_right /-
 theorem Icc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Icc a b).filterₓ (· < c) = Icc a b :=
-  (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Icc.1 hx).2 h
+  filter_true_of_mem fun x hx => (mem_Icc.1 hx).2.trans_lt h
 #align finset.Icc_filter_lt_of_lt_right Finset.Icc_filter_lt_of_lt_right
 -/
 
 #print Finset.Ioc_filter_lt_of_lt_right /-
 theorem Ioc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Ioc a b).filterₓ (· < c) = Ioc a b :=
-  (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Ioc.1 hx).2 h
+  filter_true_of_mem fun x hx => (mem_Ioc.1 hx).2.trans_lt h
 #align finset.Ioc_filter_lt_of_lt_right Finset.Ioc_filter_lt_of_lt_right
 -/
 
 #print Finset.Iic_filter_lt_of_lt_right /-
 theorem Iic_filter_lt_of_lt_right {α} [Preorder α] [LocallyFiniteOrderBot α] {a c : α}
     [DecidablePred (· < c)] (h : a < c) : (Iic a).filterₓ (· < c) = Iic a :=
-  (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Iic.1 hx) h
+  filter_true_of_mem fun x hx => (mem_Iic.1 hx).trans_lt h
 #align finset.Iic_filter_lt_of_lt_right Finset.Iic_filter_lt_of_lt_right
 -/

bump to nightly-2023-08-23-23

mathlib commit https://github.com/leanprover-community/mathlib/commit/32a7e535287f9c73f2e4d2aef306a39190f0b504

f612b9e0

Diff

@@ -101,13 +101,13 @@ theorem Ioo_eq_empty_iff [DenselyOrdered α] : Ioo a b = ∅ ↔ ¬a < b := by
 #align finset.Ioo_eq_empty_iff Finset.Ioo_eq_empty_iff
 -/
 
-alias Icc_eq_empty_iff ↔ _ Icc_eq_empty
+alias ⟨_, Icc_eq_empty⟩ := Icc_eq_empty_iff
 #align finset.Icc_eq_empty Finset.Icc_eq_empty
 
-alias Ico_eq_empty_iff ↔ _ Ico_eq_empty
+alias ⟨_, Ico_eq_empty⟩ := Ico_eq_empty_iff
 #align finset.Ico_eq_empty Finset.Ico_eq_empty
 
-alias Ioc_eq_empty_iff ↔ _ Ioc_eq_empty
+alias ⟨_, Ioc_eq_empty⟩ := Ioc_eq_empty_iff
 #align finset.Ioc_eq_empty Finset.Ioc_eq_empty
 
 #print Finset.Ioo_eq_empty /-

bump to nightly-2023-07-20-09

mathlib commit https://github.com/leanprover-community/mathlib/commit/8ea5598db6caeddde6cb734aa179cc2408dbd345

9c56d0dd

Diff

@@ -2,15 +2,12 @@
 Copyright (c) 2019 Scott Morrison. All rights reserved.
 Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
-
-! This file was ported from Lean 3 source module data.finset.locally_finite
-! leanprover-community/mathlib commit 1d29de43a5ba4662dd33b5cfeecfc2a27a5a8a29
-! Please do not edit these lines, except to modify the commit id
-! if you have ported upstream changes.
 -/
 import Mathbin.Order.LocallyFinite
 import Mathbin.Data.Set.Intervals.Monoid
 
+#align_import data.finset.locally_finite from "leanprover-community/mathlib"@"1d29de43a5ba4662dd33b5cfeecfc2a27a5a8a29"
+
 /-!
 # Intervals as finsets

bump to nightly-2023-07-16-03

mathlib commit https://github.com/leanprover-community/mathlib/commit/2fe465deb81bcd7ccafa065bb686888a82f15372

bb547586

Diff

@@ -4,7 +4,7 @@ Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 
 ! This file was ported from Lean 3 source module data.finset.locally_finite
-! leanprover-community/mathlib commit 52fa514ec337dd970d71d8de8d0fd68b455a1e54
+! leanprover-community/mathlib commit 1d29de43a5ba4662dd33b5cfeecfc2a27a5a8a29
 ! Please do not edit these lines, except to modify the commit id
 ! if you have ported upstream changes.
 -/

bump to nightly-2023-06-13-21

mathlib commit https://github.com/leanprover-community/mathlib/commit/9fb8964792b4237dac6200193a0d533f1b3f7423

829520ac

Diff

@@ -654,9 +654,11 @@ end LocallyFiniteOrderBot
 
 variable [LocallyFiniteOrderTop α] [LocallyFiniteOrderBot α]
 
+#print Finset.disjoint_Ioi_Iio /-
 theorem disjoint_Ioi_Iio (a : α) : Disjoint (Ioi a) (Iio a) :=
   disjoint_left.2 fun b hab hba => (mem_Ioi.1 hab).not_lt <| mem_Iio.1 hba
 #align finset.disjoint_Ioi_Iio Finset.disjoint_Ioi_Iio
+-/
 
 end Preorder
 
@@ -677,9 +679,11 @@ theorem Icc_eq_singleton_iff : Icc a b = {c} ↔ a = c ∧ b = c := by
 #align finset.Icc_eq_singleton_iff Finset.Icc_eq_singleton_iff
 -/
 
+#print Finset.Ico_disjoint_Ico_consecutive /-
 theorem Ico_disjoint_Ico_consecutive (a b c : α) : Disjoint (Ico a b) (Ico b c) :=
   disjoint_left.2 fun x hab hbc => (mem_Ico.mp hab).2.not_le (mem_Ico.mp hbc).1
 #align finset.Ico_disjoint_Ico_consecutive Finset.Ico_disjoint_Ico_consecutive
+-/
 
 section DecidableEq
 
@@ -982,20 +986,26 @@ theorem Ico_subset_Ico_union_Ico {a b c : α} : Ico a c ⊆ Ico a b ∪ Ico b c
 #align finset.Ico_subset_Ico_union_Ico Finset.Ico_subset_Ico_union_Ico
 -/
 
+#print Finset.Ico_union_Ico' /-
 theorem Ico_union_Ico' {a b c d : α} (hcb : c ≤ b) (had : a ≤ d) :
     Ico a b ∪ Ico c d = Ico (min a c) (max b d) := by
   rw [← coe_inj, coe_union, coe_Ico, coe_Ico, coe_Ico, Set.Ico_union_Ico' hcb had]
 #align finset.Ico_union_Ico' Finset.Ico_union_Ico'
+-/
 
+#print Finset.Ico_union_Ico /-
 theorem Ico_union_Ico {a b c d : α} (h₁ : min a b ≤ max c d) (h₂ : min c d ≤ max a b) :
     Ico a b ∪ Ico c d = Ico (min a c) (max b d) := by
   rw [← coe_inj, coe_union, coe_Ico, coe_Ico, coe_Ico, Set.Ico_union_Ico h₁ h₂]
 #align finset.Ico_union_Ico Finset.Ico_union_Ico
+-/
 
+#print Finset.Ico_inter_Ico /-
 theorem Ico_inter_Ico {a b c d : α} : Ico a b ∩ Ico c d = Ico (max a c) (min b d) := by
   rw [← coe_inj, coe_inter, coe_Ico, coe_Ico, coe_Ico, ← inf_eq_min, ← sup_eq_max,
     Set.Ico_inter_Ico]
 #align finset.Ico_inter_Ico Finset.Ico_inter_Ico
+-/
 
 #print Finset.Ico_filter_lt /-
 @[simp]
@@ -1031,6 +1041,7 @@ theorem Iio_filter_lt {α} [LinearOrder α] [LocallyFiniteOrderBot α] (a b : α
 #align finset.Iio_filter_lt Finset.Iio_filter_lt
 -/
 
+#print Finset.Ico_diff_Ico_left /-
 @[simp]
 theorem Ico_diff_Ico_left (a b c : α) : Ico a b \ Ico a c = Ico (max a c) b :=
   by
@@ -1040,7 +1051,9 @@ theorem Ico_diff_Ico_left (a b c : α) : Ico a b \ Ico a c = Ico (max a c) b :=
     exact and_congr_left' ⟨fun hx => hx.2 hx.1, fun hx => ⟨h.trans hx, fun _ => hx⟩⟩
   · rw [Ico_eq_empty_of_le h, sdiff_empty, max_eq_left h]
 #align finset.Ico_diff_Ico_left Finset.Ico_diff_Ico_left
+-/
 
+#print Finset.Ico_diff_Ico_right /-
 @[simp]
 theorem Ico_diff_Ico_right (a b c : α) : Ico a b \ Ico c b = Ico a (min b c) :=
   by
@@ -1050,6 +1063,7 @@ theorem Ico_diff_Ico_right (a b c : α) : Ico a b \ Ico c b = Ico a (min b c) :=
     rw [mem_sdiff, mem_Ico, mem_Ico, mem_Ico, min_eq_right h, and_assoc', not_and', not_le]
     exact and_congr_right' ⟨fun hx => hx.2 hx.1, fun hx => ⟨hx.trans_le h, fun _ => hx⟩⟩
 #align finset.Ico_diff_Ico_right Finset.Ico_diff_Ico_right
+-/
 
 end LocallyFiniteOrder
 
@@ -1057,13 +1071,17 @@ section LocallyFiniteOrderBot
 
 variable [LocallyFiniteOrderBot α] {s : Set α}
 
+#print Set.Infinite.exists_gt /-
 theorem Set.Infinite.exists_gt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, a < b :=
   not_bddAbove_iff.1 hs.not_bddAbove
 #align set.infinite.exists_gt Set.Infinite.exists_gt
+-/
 
+#print Set.infinite_iff_exists_gt /-
 theorem Set.infinite_iff_exists_gt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, a < b :=
   ⟨Set.Infinite.exists_gt, Set.infinite_of_forall_exists_gt⟩
 #align set.infinite_iff_exists_gt Set.infinite_iff_exists_gt
+-/
 
 end LocallyFiniteOrderBot
 
@@ -1071,13 +1089,17 @@ section LocallyFiniteOrderTop
 
 variable [LocallyFiniteOrderTop α] {s : Set α}
 
+#print Set.Infinite.exists_lt /-
 theorem Set.Infinite.exists_lt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, b < a :=
   not_bddBelow_iff.1 hs.not_bddBelow
 #align set.infinite.exists_lt Set.Infinite.exists_lt
+-/
 
+#print Set.infinite_iff_exists_lt /-
 theorem Set.infinite_iff_exists_lt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, b < a :=
   ⟨Set.Infinite.exists_lt, Set.infinite_of_forall_exists_lt⟩
 #align set.infinite_iff_exists_lt Set.infinite_iff_exists_lt
+-/
 
 end LocallyFiniteOrderTop
 
@@ -1187,9 +1209,11 @@ theorem uIcc_subset_uIcc_iff_mem : [a₁, b₁] ⊆ [a₂, b₂] ↔ a₁ ∈ [a
 #align finset.uIcc_subset_uIcc_iff_mem Finset.uIcc_subset_uIcc_iff_mem
 -/
 
+#print Finset.uIcc_subset_uIcc_iff_le' /-
 theorem uIcc_subset_uIcc_iff_le' : [a₁, b₁] ⊆ [a₂, b₂] ↔ a₂ ⊓ b₂ ≤ a₁ ⊓ b₁ ∧ a₁ ⊔ b₁ ≤ a₂ ⊔ b₂ :=
   Icc_subset_Icc_iff inf_le_sup
 #align finset.uIcc_subset_uIcc_iff_le' Finset.uIcc_subset_uIcc_iff_le'
+-/
 
 #print Finset.uIcc_subset_uIcc_right /-
 theorem uIcc_subset_uIcc_right (h : x ∈ [a, b]) : [x, b] ⊆ [a, b] :=
@@ -1241,9 +1265,11 @@ section LinearOrder
 
 variable [LinearOrder α] [LocallyFiniteOrder α] {a a₁ a₂ b b₁ b₂ c x : α}
 
+#print Finset.Icc_min_max /-
 theorem Icc_min_max : Icc (min a b) (max a b) = [a, b] :=
   rfl
 #align finset.Icc_min_max Finset.Icc_min_max
+-/
 
 #print Finset.uIcc_of_not_le /-
 theorem uIcc_of_not_le (h : ¬a ≤ b) : [a, b] = Icc b a :=
@@ -1280,10 +1306,12 @@ theorem not_mem_uIcc_of_gt : a < c → b < c → c ∉ [a, b] := by rw [mem_uIcc
 #align finset.not_mem_uIcc_of_gt Finset.not_mem_uIcc_of_gt
 -/
 
+#print Finset.uIcc_subset_uIcc_iff_le /-
 theorem uIcc_subset_uIcc_iff_le :
     [a₁, b₁] ⊆ [a₂, b₂] ↔ min a₂ b₂ ≤ min a₁ b₁ ∧ max a₁ b₁ ≤ max a₂ b₂ :=
   uIcc_subset_uIcc_iff_le'
 #align finset.uIcc_subset_uIcc_iff_le Finset.uIcc_subset_uIcc_iff_le
+-/
 
 #print Finset.uIcc_subset_uIcc_union_uIcc /-
 /-- A sort of triangle inequality. -/
@@ -1298,87 +1326,120 @@ section OrderedCancelAddCommMonoid
 
 variable [OrderedCancelAddCommMonoid α] [ExistsAddOfLE α] [LocallyFiniteOrder α]
 
+#print Finset.map_add_left_Icc /-
 @[simp]
 theorem map_add_left_Icc (a b c : α) : (Icc a b).map (addLeftEmbedding c) = Icc (c + a) (c + b) :=
   by rw [← coe_inj, coe_map, coe_Icc, coe_Icc]; exact Set.image_const_add_Icc _ _ _
 #align finset.map_add_left_Icc Finset.map_add_left_Icc
+-/
 
+#print Finset.map_add_right_Icc /-
 @[simp]
 theorem map_add_right_Icc (a b c : α) : (Icc a b).map (addRightEmbedding c) = Icc (a + c) (b + c) :=
   by rw [← coe_inj, coe_map, coe_Icc, coe_Icc]; exact Set.image_add_const_Icc _ _ _
 #align finset.map_add_right_Icc Finset.map_add_right_Icc
+-/
 
+#print Finset.map_add_left_Ico /-
 @[simp]
 theorem map_add_left_Ico (a b c : α) : (Ico a b).map (addLeftEmbedding c) = Ico (c + a) (c + b) :=
   by rw [← coe_inj, coe_map, coe_Ico, coe_Ico]; exact Set.image_const_add_Ico _ _ _
 #align finset.map_add_left_Ico Finset.map_add_left_Ico
+-/
 
+#print Finset.map_add_right_Ico /-
 @[simp]
 theorem map_add_right_Ico (a b c : α) : (Ico a b).map (addRightEmbedding c) = Ico (a + c) (b + c) :=
   by rw [← coe_inj, coe_map, coe_Ico, coe_Ico]; exact Set.image_add_const_Ico _ _ _
 #align finset.map_add_right_Ico Finset.map_add_right_Ico
+-/
 
+#print Finset.map_add_left_Ioc /-
 @[simp]
 theorem map_add_left_Ioc (a b c : α) : (Ioc a b).map (addLeftEmbedding c) = Ioc (c + a) (c + b) :=
   by rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]; exact Set.image_const_add_Ioc _ _ _
 #align finset.map_add_left_Ioc Finset.map_add_left_Ioc
+-/
 
+#print Finset.map_add_right_Ioc /-
 @[simp]
 theorem map_add_right_Ioc (a b c : α) : (Ioc a b).map (addRightEmbedding c) = Ioc (a + c) (b + c) :=
   by rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]; exact Set.image_add_const_Ioc _ _ _
 #align finset.map_add_right_Ioc Finset.map_add_right_Ioc
+-/
 
+#print Finset.map_add_left_Ioo /-
 @[simp]
 theorem map_add_left_Ioo (a b c : α) : (Ioo a b).map (addLeftEmbedding c) = Ioo (c + a) (c + b) :=
   by rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]; exact Set.image_const_add_Ioo _ _ _
 #align finset.map_add_left_Ioo Finset.map_add_left_Ioo
+-/
 
+#print Finset.map_add_right_Ioo /-
 @[simp]
 theorem map_add_right_Ioo (a b c : α) : (Ioo a b).map (addRightEmbedding c) = Ioo (a + c) (b + c) :=
   by rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]; exact Set.image_add_const_Ioo _ _ _
 #align finset.map_add_right_Ioo Finset.map_add_right_Ioo
+-/
 
 variable [DecidableEq α]
 
+#print Finset.image_add_left_Icc /-
 @[simp]
 theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) := by
   rw [← map_add_left_Icc, map_eq_image]; rfl
 #align finset.image_add_left_Icc Finset.image_add_left_Icc
+-/
 
+#print Finset.image_add_left_Ico /-
 @[simp]
 theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) := by
   rw [← map_add_left_Ico, map_eq_image]; rfl
 #align finset.image_add_left_Ico Finset.image_add_left_Ico
+-/
 
+#print Finset.image_add_left_Ioc /-
 @[simp]
 theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) := by
   rw [← map_add_left_Ioc, map_eq_image]; rfl
 #align finset.image_add_left_Ioc Finset.image_add_left_Ioc
+-/
 
+#print Finset.image_add_left_Ioo /-
 @[simp]
 theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) := by
   rw [← map_add_left_Ioo, map_eq_image]; rfl
 #align finset.image_add_left_Ioo Finset.image_add_left_Ioo
+-/
 
+#print Finset.image_add_right_Icc /-
 @[simp]
 theorem image_add_right_Icc (a b c : α) : (Icc a b).image (· + c) = Icc (a + c) (b + c) := by
   rw [← map_add_right_Icc, map_eq_image]; rfl
 #align finset.image_add_right_Icc Finset.image_add_right_Icc
+-/
 
+#print Finset.image_add_right_Ico /-
 theorem image_add_right_Ico (a b c : α) : (Ico a b).image (· + c) = Ico (a + c) (b + c) := by
   rw [← map_add_right_Ico, map_eq_image]; rfl
 #align finset.image_add_right_Ico Finset.image_add_right_Ico
+-/
 
+#print Finset.image_add_right_Ioc /-
 theorem image_add_right_Ioc (a b c : α) : (Ioc a b).image (· + c) = Ioc (a + c) (b + c) := by
   rw [← map_add_right_Ioc, map_eq_image]; rfl
 #align finset.image_add_right_Ioc Finset.image_add_right_Ioc
+-/
 
+#print Finset.image_add_right_Ioo /-
 theorem image_add_right_Ioo (a b c : α) : (Ioo a b).image (· + c) = Ioo (a + c) (b + c) := by
   rw [← map_add_right_Ioo, map_eq_image]; rfl
 #align finset.image_add_right_Ioo Finset.image_add_right_Ioo
+-/
 
 end OrderedCancelAddCommMonoid
 
+#print Finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag /-
 @[to_additive]
 theorem prod_prod_Ioi_mul_eq_prod_prod_off_diag [Fintype ι] [LinearOrder ι]
     [LocallyFiniteOrderTop ι] [LocallyFiniteOrderBot ι] [CommMonoid α] (f : ι → ι → α) :
@@ -1390,6 +1451,7 @@ theorem prod_prod_Ioi_mul_eq_prod_prod_off_diag [Fintype ι] [LinearOrder ι]
   refine' prod_bij' (fun i hi => ⟨i.2, i.1⟩) _ _ (fun i hi => ⟨i.2, i.1⟩) _ _ _ <;> simp
 #align finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag Finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag
 #align finset.sum_sum_Ioi_add_eq_sum_sum_off_diag Finset.sum_sum_Ioi_add_eq_sum_sum_off_diag
+-/
 
 end Finset

bump to nightly-2023-06-10-07

mathlib commit https://github.com/leanprover-community/mathlib/commit/a3e83f0fa4391c8740f7d773a7a9b74e311ae2a3

3fdc57bc

Diff

@@ -1382,7 +1382,7 @@ end OrderedCancelAddCommMonoid
 @[to_additive]
 theorem prod_prod_Ioi_mul_eq_prod_prod_off_diag [Fintype ι] [LinearOrder ι]
     [LocallyFiniteOrderTop ι] [LocallyFiniteOrderBot ι] [CommMonoid α] (f : ι → ι → α) :
-    (∏ i, ∏ j in Ioi i, f j i * f i j) = ∏ i, ∏ j in {i}ᶜ, f j i :=
+    ∏ i, ∏ j in Ioi i, f j i * f i j = ∏ i, ∏ j in {i}ᶜ, f j i :=
   by
   simp_rw [← Ioi_disj_union_Iio, prod_disj_union, prod_mul_distrib]
   congr 1

bump to nightly-2023-06-04-18

mathlib commit https://github.com/leanprover-community/mathlib/commit/5f25c089cb34db4db112556f23c50d12da81b297

3fb4268b

Diff

@@ -824,10 +824,10 @@ theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
 #print Finset.card_Ico_eq_card_Icc_sub_one /-
 theorem card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card - 1 := by
   classical
-    by_cases h : a ≤ b
-    · rw [Icc_eq_cons_Ico h, card_cons]
-      exact (Nat.add_sub_cancel _ _).symm
-    · rw [Ico_eq_empty fun h' => h h'.le, Icc_eq_empty h, card_empty, zero_tsub]
+  by_cases h : a ≤ b
+  · rw [Icc_eq_cons_Ico h, card_cons]
+    exact (Nat.add_sub_cancel _ _).symm
+  · rw [Ico_eq_empty fun h' => h h'.le, Icc_eq_empty h, card_empty, zero_tsub]
 #align finset.card_Ico_eq_card_Icc_sub_one Finset.card_Ico_eq_card_Icc_sub_one
 -/
 
@@ -840,10 +840,10 @@ theorem card_Ioc_eq_card_Icc_sub_one (a b : α) : (Ioc a b).card = (Icc a b).car
 #print Finset.card_Ioo_eq_card_Ico_sub_one /-
 theorem card_Ioo_eq_card_Ico_sub_one (a b : α) : (Ioo a b).card = (Ico a b).card - 1 := by
   classical
-    by_cases h : a < b
-    · rw [Ico_eq_cons_Ioo h, card_cons]
-      exact (Nat.add_sub_cancel _ _).symm
-    · rw [Ioo_eq_empty h, Ico_eq_empty h, card_empty, zero_tsub]
+  by_cases h : a < b
+  · rw [Ico_eq_cons_Ioo h, card_cons]
+    exact (Nat.add_sub_cancel _ _).symm
+  · rw [Ioo_eq_empty h, Ico_eq_empty h, card_empty, zero_tsub]
 #align finset.card_Ioo_eq_card_Ico_sub_one Finset.card_Ioo_eq_card_Ico_sub_one
 -/

bump to nightly-2023-06-01-16

mathlib commit https://github.com/leanprover-community/mathlib/commit/cca40788df1b8755d5baf17ab2f27dacc2e17acb

b9c87c70

Diff

@@ -1171,13 +1171,13 @@ theorem mem_uIcc_of_ge (hb : b ≤ x) (ha : x ≤ a) : x ∈ [a, b] :=
 
 #print Finset.uIcc_subset_uIcc /-
 theorem uIcc_subset_uIcc (h₁ : a₁ ∈ [a₂, b₂]) (h₂ : b₁ ∈ [a₂, b₂]) : [a₁, b₁] ⊆ [a₂, b₂] := by
-  rw [mem_uIcc] at h₁ h₂; exact Icc_subset_Icc (le_inf h₁.1 h₂.1) (sup_le h₁.2 h₂.2)
+  rw [mem_uIcc] at h₁ h₂ ; exact Icc_subset_Icc (le_inf h₁.1 h₂.1) (sup_le h₁.2 h₂.2)
 #align finset.uIcc_subset_uIcc Finset.uIcc_subset_uIcc
 -/
 
 #print Finset.uIcc_subset_Icc /-
 theorem uIcc_subset_Icc (ha : a₁ ∈ Icc a₂ b₂) (hb : b₁ ∈ Icc a₂ b₂) : [a₁, b₁] ⊆ Icc a₂ b₂ := by
-  rw [mem_Icc] at ha hb; exact Icc_subset_Icc (le_inf ha.1 hb.1) (sup_le ha.2 hb.2)
+  rw [mem_Icc] at ha hb ; exact Icc_subset_Icc (le_inf ha.1 hb.1) (sup_le ha.2 hb.2)
 #align finset.uIcc_subset_Icc Finset.uIcc_subset_Icc
 -/
 
@@ -1224,7 +1224,7 @@ theorem eq_of_mem_uIcc_of_mem_uIcc' : b ∈ [a, c] → c ∈ [a, b] → b = c :=
 #print Finset.uIcc_injective_right /-
 theorem uIcc_injective_right (a : α) : Injective fun b => [b, a] := fun b c h =>
   by
-  rw [ext_iff] at h
+  rw [ext_iff] at h 
   exact eq_of_mem_uIcc_of_mem_uIcc ((h _).1 left_mem_uIcc) ((h _).2 left_mem_uIcc)
 #align finset.uIcc_injective_right Finset.uIcc_injective_right
 -/

bump to nightly-2023-05-28-18

mathlib commit https://github.com/leanprover-community/mathlib/commit/917c3c072e487b3cccdbfeff17e75b40e45f66cb

8d353152

Diff

@@ -34,7 +34,7 @@ for some ideas.
 
 open Function OrderDual
 
-open BigOperators FinsetInterval
+open scoped BigOperators FinsetInterval
 
 variable {ι α : Type _}
 
@@ -48,45 +48,61 @@ section LocallyFiniteOrder
 
 variable [LocallyFiniteOrder α] {a a₁ a₂ b b₁ b₂ c x : α}
 
+#print Finset.nonempty_Icc /-
 @[simp]
 theorem nonempty_Icc : (Icc a b).Nonempty ↔ a ≤ b := by
   rw [← coe_nonempty, coe_Icc, Set.nonempty_Icc]
 #align finset.nonempty_Icc Finset.nonempty_Icc
+-/
 
+#print Finset.nonempty_Ico /-
 @[simp]
 theorem nonempty_Ico : (Ico a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ico, Set.nonempty_Ico]
 #align finset.nonempty_Ico Finset.nonempty_Ico
+-/
 
+#print Finset.nonempty_Ioc /-
 @[simp]
 theorem nonempty_Ioc : (Ioc a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioc, Set.nonempty_Ioc]
 #align finset.nonempty_Ioc Finset.nonempty_Ioc
+-/
 
+#print Finset.nonempty_Ioo /-
 @[simp]
 theorem nonempty_Ioo [DenselyOrdered α] : (Ioo a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioo, Set.nonempty_Ioo]
 #align finset.nonempty_Ioo Finset.nonempty_Ioo
+-/
 
+#print Finset.Icc_eq_empty_iff /-
 @[simp]
 theorem Icc_eq_empty_iff : Icc a b = ∅ ↔ ¬a ≤ b := by
   rw [← coe_eq_empty, coe_Icc, Set.Icc_eq_empty_iff]
 #align finset.Icc_eq_empty_iff Finset.Icc_eq_empty_iff
+-/
 
+#print Finset.Ico_eq_empty_iff /-
 @[simp]
 theorem Ico_eq_empty_iff : Ico a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ico, Set.Ico_eq_empty_iff]
 #align finset.Ico_eq_empty_iff Finset.Ico_eq_empty_iff
+-/
 
+#print Finset.Ioc_eq_empty_iff /-
 @[simp]
 theorem Ioc_eq_empty_iff : Ioc a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ioc, Set.Ioc_eq_empty_iff]
 #align finset.Ioc_eq_empty_iff Finset.Ioc_eq_empty_iff
+-/
 
+#print Finset.Ioo_eq_empty_iff /-
 @[simp]
 theorem Ioo_eq_empty_iff [DenselyOrdered α] : Ioo a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ioo, Set.Ioo_eq_empty_iff]
 #align finset.Ioo_eq_empty_iff Finset.Ioo_eq_empty_iff
+-/
 
 alias Icc_eq_empty_iff ↔ _ Icc_eq_empty
 #align finset.Icc_eq_empty Finset.Icc_eq_empty
@@ -97,46 +113,64 @@ alias Ico_eq_empty_iff ↔ _ Ico_eq_empty
 alias Ioc_eq_empty_iff ↔ _ Ioc_eq_empty
 #align finset.Ioc_eq_empty Finset.Ioc_eq_empty
 
+#print Finset.Ioo_eq_empty /-
 @[simp]
 theorem Ioo_eq_empty (h : ¬a < b) : Ioo a b = ∅ :=
   eq_empty_iff_forall_not_mem.2 fun x hx => h ((mem_Ioo.1 hx).1.trans (mem_Ioo.1 hx).2)
 #align finset.Ioo_eq_empty Finset.Ioo_eq_empty
+-/
 
+#print Finset.Icc_eq_empty_of_lt /-
 @[simp]
 theorem Icc_eq_empty_of_lt (h : b < a) : Icc a b = ∅ :=
   Icc_eq_empty h.not_le
 #align finset.Icc_eq_empty_of_lt Finset.Icc_eq_empty_of_lt
+-/
 
+#print Finset.Ico_eq_empty_of_le /-
 @[simp]
 theorem Ico_eq_empty_of_le (h : b ≤ a) : Ico a b = ∅ :=
   Ico_eq_empty h.not_lt
 #align finset.Ico_eq_empty_of_le Finset.Ico_eq_empty_of_le
+-/
 
+#print Finset.Ioc_eq_empty_of_le /-
 @[simp]
 theorem Ioc_eq_empty_of_le (h : b ≤ a) : Ioc a b = ∅ :=
   Ioc_eq_empty h.not_lt
 #align finset.Ioc_eq_empty_of_le Finset.Ioc_eq_empty_of_le
+-/
 
+#print Finset.Ioo_eq_empty_of_le /-
 @[simp]
 theorem Ioo_eq_empty_of_le (h : b ≤ a) : Ioo a b = ∅ :=
   Ioo_eq_empty h.not_lt
 #align finset.Ioo_eq_empty_of_le Finset.Ioo_eq_empty_of_le
+-/
 
+#print Finset.left_mem_Icc /-
 @[simp]
 theorem left_mem_Icc : a ∈ Icc a b ↔ a ≤ b := by simp only [mem_Icc, true_and_iff, le_rfl]
 #align finset.left_mem_Icc Finset.left_mem_Icc
+-/
 
+#print Finset.left_mem_Ico /-
 @[simp]
 theorem left_mem_Ico : a ∈ Ico a b ↔ a < b := by simp only [mem_Ico, true_and_iff, le_refl]
 #align finset.left_mem_Ico Finset.left_mem_Ico
+-/
 
+#print Finset.right_mem_Icc /-
 @[simp]
 theorem right_mem_Icc : b ∈ Icc a b ↔ a ≤ b := by simp only [mem_Icc, and_true_iff, le_rfl]
 #align finset.right_mem_Icc Finset.right_mem_Icc
+-/
 
+#print Finset.right_mem_Ioc /-
 @[simp]
 theorem right_mem_Ioc : b ∈ Ioc a b ↔ a < b := by simp only [mem_Ioc, and_true_iff, le_rfl]
 #align finset.right_mem_Ioc Finset.right_mem_Ioc
+-/
 
 #print Finset.left_not_mem_Ioc /-
 @[simp]
@@ -162,65 +196,95 @@ theorem right_not_mem_Ioo : b ∉ Ioo a b := fun h => lt_irrefl _ (mem_Ioo.1 h).
 #align finset.right_not_mem_Ioo Finset.right_not_mem_Ioo
 -/
 
+#print Finset.Icc_subset_Icc /-
 theorem Icc_subset_Icc (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Icc a₁ b₁ ⊆ Icc a₂ b₂ := by
   simpa [← coe_subset] using Set.Icc_subset_Icc ha hb
 #align finset.Icc_subset_Icc Finset.Icc_subset_Icc
+-/
 
+#print Finset.Ico_subset_Ico /-
 theorem Ico_subset_Ico (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Ico a₁ b₁ ⊆ Ico a₂ b₂ := by
   simpa [← coe_subset] using Set.Ico_subset_Ico ha hb
 #align finset.Ico_subset_Ico Finset.Ico_subset_Ico
+-/
 
+#print Finset.Ioc_subset_Ioc /-
 theorem Ioc_subset_Ioc (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Ioc a₁ b₁ ⊆ Ioc a₂ b₂ := by
   simpa [← coe_subset] using Set.Ioc_subset_Ioc ha hb
 #align finset.Ioc_subset_Ioc Finset.Ioc_subset_Ioc
+-/
 
+#print Finset.Ioo_subset_Ioo /-
 theorem Ioo_subset_Ioo (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Ioo a₁ b₁ ⊆ Ioo a₂ b₂ := by
   simpa [← coe_subset] using Set.Ioo_subset_Ioo ha hb
 #align finset.Ioo_subset_Ioo Finset.Ioo_subset_Ioo
+-/
 
+#print Finset.Icc_subset_Icc_left /-
 theorem Icc_subset_Icc_left (h : a₁ ≤ a₂) : Icc a₂ b ⊆ Icc a₁ b :=
   Icc_subset_Icc h le_rfl
 #align finset.Icc_subset_Icc_left Finset.Icc_subset_Icc_left
+-/
 
+#print Finset.Ico_subset_Ico_left /-
 theorem Ico_subset_Ico_left (h : a₁ ≤ a₂) : Ico a₂ b ⊆ Ico a₁ b :=
   Ico_subset_Ico h le_rfl
 #align finset.Ico_subset_Ico_left Finset.Ico_subset_Ico_left
+-/
 
+#print Finset.Ioc_subset_Ioc_left /-
 theorem Ioc_subset_Ioc_left (h : a₁ ≤ a₂) : Ioc a₂ b ⊆ Ioc a₁ b :=
   Ioc_subset_Ioc h le_rfl
 #align finset.Ioc_subset_Ioc_left Finset.Ioc_subset_Ioc_left
+-/
 
+#print Finset.Ioo_subset_Ioo_left /-
 theorem Ioo_subset_Ioo_left (h : a₁ ≤ a₂) : Ioo a₂ b ⊆ Ioo a₁ b :=
   Ioo_subset_Ioo h le_rfl
 #align finset.Ioo_subset_Ioo_left Finset.Ioo_subset_Ioo_left
+-/
 
+#print Finset.Icc_subset_Icc_right /-
 theorem Icc_subset_Icc_right (h : b₁ ≤ b₂) : Icc a b₁ ⊆ Icc a b₂ :=
   Icc_subset_Icc le_rfl h
 #align finset.Icc_subset_Icc_right Finset.Icc_subset_Icc_right
+-/
 
+#print Finset.Ico_subset_Ico_right /-
 theorem Ico_subset_Ico_right (h : b₁ ≤ b₂) : Ico a b₁ ⊆ Ico a b₂ :=
   Ico_subset_Ico le_rfl h
 #align finset.Ico_subset_Ico_right Finset.Ico_subset_Ico_right
+-/
 
+#print Finset.Ioc_subset_Ioc_right /-
 theorem Ioc_subset_Ioc_right (h : b₁ ≤ b₂) : Ioc a b₁ ⊆ Ioc a b₂ :=
   Ioc_subset_Ioc le_rfl h
 #align finset.Ioc_subset_Ioc_right Finset.Ioc_subset_Ioc_right
+-/
 
+#print Finset.Ioo_subset_Ioo_right /-
 theorem Ioo_subset_Ioo_right (h : b₁ ≤ b₂) : Ioo a b₁ ⊆ Ioo a b₂ :=
   Ioo_subset_Ioo le_rfl h
 #align finset.Ioo_subset_Ioo_right Finset.Ioo_subset_Ioo_right
+-/
 
+#print Finset.Ico_subset_Ioo_left /-
 theorem Ico_subset_Ioo_left (h : a₁ < a₂) : Ico a₂ b ⊆ Ioo a₁ b := by
   rw [← coe_subset, coe_Ico, coe_Ioo]; exact Set.Ico_subset_Ioo_left h
 #align finset.Ico_subset_Ioo_left Finset.Ico_subset_Ioo_left
+-/
 
+#print Finset.Ioc_subset_Ioo_right /-
 theorem Ioc_subset_Ioo_right (h : b₁ < b₂) : Ioc a b₁ ⊆ Ioo a b₂ := by
   rw [← coe_subset, coe_Ioc, coe_Ioo]; exact Set.Ioc_subset_Ioo_right h
 #align finset.Ioc_subset_Ioo_right Finset.Ioc_subset_Ioo_right
+-/
 
+#print Finset.Icc_subset_Ico_right /-
 theorem Icc_subset_Ico_right (h : b₁ < b₂) : Icc a b₁ ⊆ Ico a b₂ := by
   rw [← coe_subset, coe_Icc, coe_Ico]; exact Set.Icc_subset_Ico_right h
 #align finset.Icc_subset_Ico_right Finset.Icc_subset_Ico_right
+-/
 
 #print Finset.Ioo_subset_Ico_self /-
 theorem Ioo_subset_Ico_self : Ioo a b ⊆ Ico a b := by rw [← coe_subset, coe_Ioo, coe_Ico];
@@ -252,31 +316,43 @@ theorem Ioo_subset_Icc_self : Ioo a b ⊆ Icc a b :=
 #align finset.Ioo_subset_Icc_self Finset.Ioo_subset_Icc_self
 -/
 
+#print Finset.Icc_subset_Icc_iff /-
 theorem Icc_subset_Icc_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Icc a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ ≤ b₂ := by
   rw [← coe_subset, coe_Icc, coe_Icc, Set.Icc_subset_Icc_iff h₁]
 #align finset.Icc_subset_Icc_iff Finset.Icc_subset_Icc_iff
+-/
 
+#print Finset.Icc_subset_Ioo_iff /-
 theorem Icc_subset_Ioo_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioo a₂ b₂ ↔ a₂ < a₁ ∧ b₁ < b₂ := by
   rw [← coe_subset, coe_Icc, coe_Ioo, Set.Icc_subset_Ioo_iff h₁]
 #align finset.Icc_subset_Ioo_iff Finset.Icc_subset_Ioo_iff
+-/
 
+#print Finset.Icc_subset_Ico_iff /-
 theorem Icc_subset_Ico_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ico a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ < b₂ := by
   rw [← coe_subset, coe_Icc, coe_Ico, Set.Icc_subset_Ico_iff h₁]
 #align finset.Icc_subset_Ico_iff Finset.Icc_subset_Ico_iff
+-/
 
+#print Finset.Icc_subset_Ioc_iff /-
 theorem Icc_subset_Ioc_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioc a₂ b₂ ↔ a₂ < a₁ ∧ b₁ ≤ b₂ :=
   (Icc_subset_Ico_iff h₁.dual).trans and_comm
 #align finset.Icc_subset_Ioc_iff Finset.Icc_subset_Ioc_iff
+-/
 
+#print Finset.Icc_ssubset_Icc_left /-
 --TODO: `Ico_subset_Ioo_iff`, `Ioc_subset_Ioo_iff`
 theorem Icc_ssubset_Icc_left (hI : a₂ ≤ b₂) (ha : a₂ < a₁) (hb : b₁ ≤ b₂) : Icc a₁ b₁ ⊂ Icc a₂ b₂ :=
   by rw [← coe_ssubset, coe_Icc, coe_Icc]; exact Set.Icc_ssubset_Icc_left hI ha hb
 #align finset.Icc_ssubset_Icc_left Finset.Icc_ssubset_Icc_left
+-/
 
+#print Finset.Icc_ssubset_Icc_right /-
 theorem Icc_ssubset_Icc_right (hI : a₂ ≤ b₂) (ha : a₂ ≤ a₁) (hb : b₁ < b₂) :
     Icc a₁ b₁ ⊂ Icc a₂ b₂ := by rw [← coe_ssubset, coe_Icc, coe_Icc];
   exact Set.Icc_ssubset_Icc_right hI ha hb
 #align finset.Icc_ssubset_Icc_right Finset.Icc_ssubset_Icc_right
+-/
 
 variable (a)
 
@@ -322,72 +398,98 @@ theorem BddBelow.finite_of_bddAbove {s : Set α} (h₀ : BddBelow s) (h₁ : Bdd
 
 section Filter
 
+#print Finset.Ico_filter_lt_of_le_left /-
 theorem Ico_filter_lt_of_le_left [DecidablePred (· < c)] (hca : c ≤ a) :
     (Ico a b).filterₓ (· < c) = ∅ :=
   filter_false_of_mem fun x hx => (hca.trans (mem_Ico.1 hx).1).not_lt
 #align finset.Ico_filter_lt_of_le_left Finset.Ico_filter_lt_of_le_left
+-/
 
+#print Finset.Ico_filter_lt_of_right_le /-
 theorem Ico_filter_lt_of_right_le [DecidablePred (· < c)] (hbc : b ≤ c) :
     (Ico a b).filterₓ (· < c) = Ico a b :=
   filter_true_of_mem fun x hx => (mem_Ico.1 hx).2.trans_le hbc
 #align finset.Ico_filter_lt_of_right_le Finset.Ico_filter_lt_of_right_le
+-/
 
+#print Finset.Ico_filter_lt_of_le_right /-
 theorem Ico_filter_lt_of_le_right [DecidablePred (· < c)] (hcb : c ≤ b) :
     (Ico a b).filterₓ (· < c) = Ico a c := by
   ext x
   rw [mem_filter, mem_Ico, mem_Ico, and_right_comm]
   exact and_iff_left_of_imp fun h => h.2.trans_le hcb
 #align finset.Ico_filter_lt_of_le_right Finset.Ico_filter_lt_of_le_right
+-/
 
+#print Finset.Ico_filter_le_of_le_left /-
 theorem Ico_filter_le_of_le_left {a b c : α} [DecidablePred ((· ≤ ·) c)] (hca : c ≤ a) :
     (Ico a b).filterₓ ((· ≤ ·) c) = Ico a b :=
   filter_true_of_mem fun x hx => hca.trans (mem_Ico.1 hx).1
 #align finset.Ico_filter_le_of_le_left Finset.Ico_filter_le_of_le_left
+-/
 
+#print Finset.Ico_filter_le_of_right_le /-
 theorem Ico_filter_le_of_right_le {a b : α} [DecidablePred ((· ≤ ·) b)] :
     (Ico a b).filterₓ ((· ≤ ·) b) = ∅ :=
   filter_false_of_mem fun x hx => (mem_Ico.1 hx).2.not_le
 #align finset.Ico_filter_le_of_right_le Finset.Ico_filter_le_of_right_le
+-/
 
+#print Finset.Ico_filter_le_of_left_le /-
 theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred ((· ≤ ·) c)] (hac : a ≤ c) :
     (Ico a b).filterₓ ((· ≤ ·) c) = Ico c b := by
   ext x
   rw [mem_filter, mem_Ico, mem_Ico, and_comm', and_left_comm]
   exact and_iff_right_of_imp fun h => hac.trans h.1
 #align finset.Ico_filter_le_of_left_le Finset.Ico_filter_le_of_left_le
+-/
 
+#print Finset.Icc_filter_lt_of_lt_right /-
 theorem Icc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Icc a b).filterₓ (· < c) = Icc a b :=
   (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Icc.1 hx).2 h
 #align finset.Icc_filter_lt_of_lt_right Finset.Icc_filter_lt_of_lt_right
+-/
 
+#print Finset.Ioc_filter_lt_of_lt_right /-
 theorem Ioc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Ioc a b).filterₓ (· < c) = Ioc a b :=
   (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Ioc.1 hx).2 h
 #align finset.Ioc_filter_lt_of_lt_right Finset.Ioc_filter_lt_of_lt_right
+-/
 
+#print Finset.Iic_filter_lt_of_lt_right /-
 theorem Iic_filter_lt_of_lt_right {α} [Preorder α] [LocallyFiniteOrderBot α] {a c : α}
     [DecidablePred (· < c)] (h : a < c) : (Iic a).filterₓ (· < c) = Iic a :=
   (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Iic.1 hx) h
 #align finset.Iic_filter_lt_of_lt_right Finset.Iic_filter_lt_of_lt_right
+-/
 
 variable (a b) [Fintype α]
 
+#print Finset.filter_lt_lt_eq_Ioo /-
 theorem filter_lt_lt_eq_Ioo [DecidablePred fun j => a < j ∧ j < b] :
     (univ.filterₓ fun j => a < j ∧ j < b) = Ioo a b := by ext; simp
 #align finset.filter_lt_lt_eq_Ioo Finset.filter_lt_lt_eq_Ioo
+-/
 
+#print Finset.filter_lt_le_eq_Ioc /-
 theorem filter_lt_le_eq_Ioc [DecidablePred fun j => a < j ∧ j ≤ b] :
     (univ.filterₓ fun j => a < j ∧ j ≤ b) = Ioc a b := by ext; simp
 #align finset.filter_lt_le_eq_Ioc Finset.filter_lt_le_eq_Ioc
+-/
 
+#print Finset.filter_le_lt_eq_Ico /-
 theorem filter_le_lt_eq_Ico [DecidablePred fun j => a ≤ j ∧ j < b] :
     (univ.filterₓ fun j => a ≤ j ∧ j < b) = Ico a b := by ext; simp
 #align finset.filter_le_lt_eq_Ico Finset.filter_le_lt_eq_Ico
+-/
 
+#print Finset.filter_le_le_eq_Icc /-
 theorem filter_le_le_eq_Icc [DecidablePred fun j => a ≤ j ∧ j ≤ b] :
     (univ.filterₓ fun j => a ≤ j ∧ j ≤ b) = Icc a b := by ext; simp
 #align finset.filter_le_le_eq_Icc Finset.filter_le_le_eq_Icc
+-/
 
 end Filter
 
@@ -501,13 +603,17 @@ theorem Set.Infinite.not_bddBelow {s : Set α} : s.Infinite → ¬BddBelow s :=
 
 variable [Fintype α]
 
+#print Finset.filter_lt_eq_Ioi /-
 theorem filter_lt_eq_Ioi [DecidablePred ((· < ·) a)] : univ.filterₓ ((· < ·) a) = Ioi a := by ext;
   simp
 #align finset.filter_lt_eq_Ioi Finset.filter_lt_eq_Ioi
+-/
 
+#print Finset.filter_le_eq_Ici /-
 theorem filter_le_eq_Ici [DecidablePred ((· ≤ ·) a)] : univ.filterₓ ((· ≤ ·) a) = Ici a := by ext;
   simp
 #align finset.filter_le_eq_Ici Finset.filter_le_eq_Ici
+-/
 
 end LocallyFiniteOrderTop
 
@@ -534,11 +640,15 @@ theorem Set.Infinite.not_bddAbove {s : Set α} : s.Infinite → ¬BddAbove s :=
 
 variable [Fintype α]
 
+#print Finset.filter_gt_eq_Iio /-
 theorem filter_gt_eq_Iio [DecidablePred (· < a)] : univ.filterₓ (· < a) = Iio a := by ext; simp
 #align finset.filter_gt_eq_Iio Finset.filter_gt_eq_Iio
+-/
 
+#print Finset.filter_ge_eq_Iic /-
 theorem filter_ge_eq_Iic [DecidablePred (· ≤ a)] : univ.filterₓ (· ≤ a) = Iic a := by ext; simp
 #align finset.filter_ge_eq_Iic Finset.filter_ge_eq_Iic
+-/
 
 end LocallyFiniteOrderBot
 
@@ -605,45 +715,63 @@ theorem Icc_diff_both (a b : α) : Icc a b \ {a, b} = Ioo a b := by simp [← co
 #align finset.Icc_diff_both Finset.Icc_diff_both
 -/
 
+#print Finset.Ico_insert_right /-
 @[simp]
 theorem Ico_insert_right (h : a ≤ b) : insert b (Ico a b) = Icc a b := by
   rw [← coe_inj, coe_insert, coe_Icc, coe_Ico, Set.insert_eq, Set.union_comm, Set.Ico_union_right h]
 #align finset.Ico_insert_right Finset.Ico_insert_right
+-/
 
+#print Finset.Ioc_insert_left /-
 @[simp]
 theorem Ioc_insert_left (h : a ≤ b) : insert a (Ioc a b) = Icc a b := by
   rw [← coe_inj, coe_insert, coe_Ioc, coe_Icc, Set.insert_eq, Set.union_comm, Set.Ioc_union_left h]
 #align finset.Ioc_insert_left Finset.Ioc_insert_left
+-/
 
+#print Finset.Ioo_insert_left /-
 @[simp]
 theorem Ioo_insert_left (h : a < b) : insert a (Ioo a b) = Ico a b := by
   rw [← coe_inj, coe_insert, coe_Ioo, coe_Ico, Set.insert_eq, Set.union_comm, Set.Ioo_union_left h]
 #align finset.Ioo_insert_left Finset.Ioo_insert_left
+-/
 
+#print Finset.Ioo_insert_right /-
 @[simp]
 theorem Ioo_insert_right (h : a < b) : insert b (Ioo a b) = Ioc a b := by
   rw [← coe_inj, coe_insert, coe_Ioo, coe_Ioc, Set.insert_eq, Set.union_comm, Set.Ioo_union_right h]
 #align finset.Ioo_insert_right Finset.Ioo_insert_right
+-/
 
+#print Finset.Icc_diff_Ico_self /-
 @[simp]
 theorem Icc_diff_Ico_self (h : a ≤ b) : Icc a b \ Ico a b = {b} := by simp [← coe_inj, h]
 #align finset.Icc_diff_Ico_self Finset.Icc_diff_Ico_self
+-/
 
+#print Finset.Icc_diff_Ioc_self /-
 @[simp]
 theorem Icc_diff_Ioc_self (h : a ≤ b) : Icc a b \ Ioc a b = {a} := by simp [← coe_inj, h]
 #align finset.Icc_diff_Ioc_self Finset.Icc_diff_Ioc_self
+-/
 
+#print Finset.Icc_diff_Ioo_self /-
 @[simp]
 theorem Icc_diff_Ioo_self (h : a ≤ b) : Icc a b \ Ioo a b = {a, b} := by simp [← coe_inj, h]
 #align finset.Icc_diff_Ioo_self Finset.Icc_diff_Ioo_self
+-/
 
+#print Finset.Ico_diff_Ioo_self /-
 @[simp]
 theorem Ico_diff_Ioo_self (h : a < b) : Ico a b \ Ioo a b = {a} := by simp [← coe_inj, h]
 #align finset.Ico_diff_Ioo_self Finset.Ico_diff_Ioo_self
+-/
 
+#print Finset.Ioc_diff_Ioo_self /-
 @[simp]
 theorem Ioc_diff_Ioo_self (h : a < b) : Ioc a b \ Ioo a b = {b} := by simp [← coe_inj, h]
 #align finset.Ioc_diff_Ioo_self Finset.Ioc_diff_Ioo_self
+-/
 
 #print Finset.Ico_inter_Ico_consecutive /-
 @[simp]
@@ -654,27 +782,36 @@ theorem Ico_inter_Ico_consecutive (a b c : α) : Ico a b ∩ Ico b c = ∅ :=
 
 end DecidableEq
 
+#print Finset.Icc_eq_cons_Ico /-
 -- Those lemmas are purposefully the other way around
 /-- `finset.cons` version of `finset.Ico_insert_right`. -/
 theorem Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico := by
   classical rw [cons_eq_insert, Ico_insert_right h]
 #align finset.Icc_eq_cons_Ico Finset.Icc_eq_cons_Ico
+-/
 
+#print Finset.Icc_eq_cons_Ioc /-
 /-- `finset.cons` version of `finset.Ioc_insert_left`. -/
 theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc := by
   classical rw [cons_eq_insert, Ioc_insert_left h]
 #align finset.Icc_eq_cons_Ioc Finset.Icc_eq_cons_Ioc
+-/
 
+#print Finset.Ioc_eq_cons_Ioo /-
 /-- `finset.cons` version of `finset.Ioo_insert_right`. -/
 theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by
   classical rw [cons_eq_insert, Ioo_insert_right h]
 #align finset.Ioc_eq_cons_Ioo Finset.Ioc_eq_cons_Ioo
+-/
 
+#print Finset.Ico_eq_cons_Ioo /-
 /-- `finset.cons` version of `finset.Ioo_insert_left`. -/
 theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by
   classical rw [cons_eq_insert, Ioo_insert_left h]
 #align finset.Ico_eq_cons_Ioo Finset.Ico_eq_cons_Ioo
+-/
 
+#print Finset.Ico_filter_le_left /-
 theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
     ((Ico a b).filterₓ fun x => x ≤ a) = {a} :=
   by
@@ -682,6 +819,7 @@ theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
   rw [mem_filter, mem_Ico, mem_singleton, and_right_comm, ← le_antisymm_iff, eq_comm]
   exact and_iff_left_of_imp fun h => h.le.trans_lt hab
 #align finset.Ico_filter_le_left Finset.Ico_filter_le_left
+-/
 
 #print Finset.card_Ico_eq_card_Icc_sub_one /-
 theorem card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card - 1 := by
@@ -817,20 +955,26 @@ section LocallyFiniteOrder
 
 variable [LocallyFiniteOrder α] {a b : α}
 
+#print Finset.Ico_subset_Ico_iff /-
 theorem Ico_subset_Ico_iff {a₁ b₁ a₂ b₂ : α} (h : a₁ < b₁) :
     Ico a₁ b₁ ⊆ Ico a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ ≤ b₂ := by
   rw [← coe_subset, coe_Ico, coe_Ico, Set.Ico_subset_Ico_iff h]
 #align finset.Ico_subset_Ico_iff Finset.Ico_subset_Ico_iff
+-/
 
+#print Finset.Ico_union_Ico_eq_Ico /-
 theorem Ico_union_Ico_eq_Ico {a b c : α} (hab : a ≤ b) (hbc : b ≤ c) :
     Ico a b ∪ Ico b c = Ico a c := by
   rw [← coe_inj, coe_union, coe_Ico, coe_Ico, coe_Ico, Set.Ico_union_Ico_eq_Ico hab hbc]
 #align finset.Ico_union_Ico_eq_Ico Finset.Ico_union_Ico_eq_Ico
+-/
 
+#print Finset.Ioc_union_Ioc_eq_Ioc /-
 @[simp]
 theorem Ioc_union_Ioc_eq_Ioc {a b c : α} (h₁ : a ≤ b) (h₂ : b ≤ c) : Ioc a b ∪ Ioc b c = Ioc a c :=
   by rw [← coe_inj, coe_union, coe_Ioc, coe_Ioc, coe_Ioc, Set.Ioc_union_Ioc_eq_Ioc h₁ h₂]
 #align finset.Ioc_union_Ioc_eq_Ioc Finset.Ioc_union_Ioc_eq_Ioc
+-/
 
 #print Finset.Ico_subset_Ico_union_Ico /-
 theorem Ico_subset_Ico_union_Ico {a b c : α} : Ico a c ⊆ Ico a b ∪ Ico b c := by
@@ -957,13 +1101,17 @@ theorem uIcc_toDual (a b : α) : [toDual a, toDual b] = [a, b].map toDual.toEmbe
 #align finset.uIcc_to_dual Finset.uIcc_toDual
 -/
 
+#print Finset.uIcc_of_le /-
 @[simp]
 theorem uIcc_of_le (h : a ≤ b) : [a, b] = Icc a b := by rw [uIcc, inf_eq_left.2 h, sup_eq_right.2 h]
 #align finset.uIcc_of_le Finset.uIcc_of_le
+-/
 
+#print Finset.uIcc_of_ge /-
 @[simp]
 theorem uIcc_of_ge (h : b ≤ a) : [a, b] = Icc b a := by rw [uIcc, inf_eq_right.2 h, sup_eq_left.2 h]
 #align finset.uIcc_of_ge Finset.uIcc_of_ge
+-/
 
 #print Finset.uIcc_comm /-
 theorem uIcc_comm (a b : α) : [a, b] = [b, a] := by rw [uIcc, uIcc, inf_comm, sup_comm]
@@ -1009,13 +1157,17 @@ theorem right_mem_uIcc : b ∈ [a, b] :=
 #align finset.right_mem_uIcc Finset.right_mem_uIcc
 -/
 
+#print Finset.mem_uIcc_of_le /-
 theorem mem_uIcc_of_le (ha : a ≤ x) (hb : x ≤ b) : x ∈ [a, b] :=
   Icc_subset_uIcc <| mem_Icc.2 ⟨ha, hb⟩
 #align finset.mem_uIcc_of_le Finset.mem_uIcc_of_le
+-/
 
+#print Finset.mem_uIcc_of_ge /-
 theorem mem_uIcc_of_ge (hb : b ≤ x) (ha : x ≤ a) : x ∈ [a, b] :=
   Icc_subset_uIcc' <| mem_Icc.2 ⟨hb, ha⟩
 #align finset.mem_uIcc_of_ge Finset.mem_uIcc_of_ge
+-/
 
 #print Finset.uIcc_subset_uIcc /-
 theorem uIcc_subset_uIcc (h₁ : a₁ ∈ [a₂, b₂]) (h₂ : b₁ ∈ [a₂, b₂]) : [a₁, b₁] ⊆ [a₂, b₂] := by
@@ -1093,13 +1245,17 @@ theorem Icc_min_max : Icc (min a b) (max a b) = [a, b] :=
   rfl
 #align finset.Icc_min_max Finset.Icc_min_max
 
+#print Finset.uIcc_of_not_le /-
 theorem uIcc_of_not_le (h : ¬a ≤ b) : [a, b] = Icc b a :=
   uIcc_of_ge <| le_of_not_ge h
 #align finset.uIcc_of_not_le Finset.uIcc_of_not_le
+-/
 
+#print Finset.uIcc_of_not_ge /-
 theorem uIcc_of_not_ge (h : ¬b ≤ a) : [a, b] = Icc a b :=
   uIcc_of_le <| le_of_not_ge h
 #align finset.uIcc_of_not_ge Finset.uIcc_of_not_ge
+-/
 
 #print Finset.uIcc_eq_union /-
 theorem uIcc_eq_union : [a, b] = Icc a b ∪ Icc b a :=
@@ -1107,16 +1263,22 @@ theorem uIcc_eq_union : [a, b] = Icc a b ∪ Icc b a :=
 #align finset.uIcc_eq_union Finset.uIcc_eq_union
 -/
 
+#print Finset.mem_uIcc' /-
 theorem mem_uIcc' : a ∈ [b, c] ↔ b ≤ a ∧ a ≤ c ∨ c ≤ a ∧ a ≤ b := by simp [uIcc_eq_union]
 #align finset.mem_uIcc' Finset.mem_uIcc'
+-/
 
+#print Finset.not_mem_uIcc_of_lt /-
 theorem not_mem_uIcc_of_lt : c < a → c < b → c ∉ [a, b] := by rw [mem_uIcc];
   exact Set.not_mem_uIcc_of_lt
 #align finset.not_mem_uIcc_of_lt Finset.not_mem_uIcc_of_lt
+-/
 
+#print Finset.not_mem_uIcc_of_gt /-
 theorem not_mem_uIcc_of_gt : a < c → b < c → c ∉ [a, b] := by rw [mem_uIcc];
   exact Set.not_mem_uIcc_of_gt
 #align finset.not_mem_uIcc_of_gt Finset.not_mem_uIcc_of_gt
+-/
 
 theorem uIcc_subset_uIcc_iff_le :
     [a₁, b₁] ⊆ [a₂, b₂] ↔ min a₂ b₂ ≤ min a₁ b₁ ∧ max a₁ b₁ ≤ max a₂ b₂ :=

bump to nightly-2023-05-28-06

mathlib commit https://github.com/leanprover-community/mathlib/commit/917c3c072e487b3cccdbfeff17e75b40e45f66cb

ba5d8b97

Diff

@@ -48,212 +48,92 @@ section LocallyFiniteOrder
 
 variable [LocallyFiniteOrder α] {a a₁ a₂ b b₁ b₂ c x : α}
 
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-but is expected to have type
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-Case conversion may be inaccurate. Consider using '#align finset.nonempty_Icc Finset.nonempty_Iccₓ'. -/
 @[simp]
 theorem nonempty_Icc : (Icc a b).Nonempty ↔ a ≤ b := by
   rw [← coe_nonempty, coe_Icc, Set.nonempty_Icc]
 #align finset.nonempty_Icc Finset.nonempty_Icc
 
-/- warning: finset.nonempty_Ico -> Finset.nonempty_Ico is a dubious translation:
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-Case conversion may be inaccurate. Consider using '#align finset.nonempty_Ico Finset.nonempty_Icoₓ'. -/
 @[simp]
 theorem nonempty_Ico : (Ico a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ico, Set.nonempty_Ico]
 #align finset.nonempty_Ico Finset.nonempty_Ico
 
-/- warning: finset.nonempty_Ioc -> Finset.nonempty_Ioc is a dubious translation:
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-Case conversion may be inaccurate. Consider using '#align finset.nonempty_Ioc Finset.nonempty_Iocₓ'. -/
 @[simp]
 theorem nonempty_Ioc : (Ioc a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioc, Set.nonempty_Ioc]
 #align finset.nonempty_Ioc Finset.nonempty_Ioc
 
-/- warning: finset.nonempty_Ioo -> Finset.nonempty_Ioo is a dubious translation:
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-Case conversion may be inaccurate. Consider using '#align finset.nonempty_Ioo Finset.nonempty_Iooₓ'. -/
 @[simp]
 theorem nonempty_Ioo [DenselyOrdered α] : (Ioo a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioo, Set.nonempty_Ioo]
 #align finset.nonempty_Ioo Finset.nonempty_Ioo
 
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-Case conversion may be inaccurate. Consider using '#align finset.Icc_eq_empty_iff Finset.Icc_eq_empty_iffₓ'. -/
 @[simp]
 theorem Icc_eq_empty_iff : Icc a b = ∅ ↔ ¬a ≤ b := by
   rw [← coe_eq_empty, coe_Icc, Set.Icc_eq_empty_iff]
 #align finset.Icc_eq_empty_iff Finset.Icc_eq_empty_iff
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ico_eq_empty_iff Finset.Ico_eq_empty_iffₓ'. -/
 @[simp]
 theorem Ico_eq_empty_iff : Ico a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ico, Set.Ico_eq_empty_iff]
 #align finset.Ico_eq_empty_iff Finset.Ico_eq_empty_iff
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ioc_eq_empty_iff Finset.Ioc_eq_empty_iffₓ'. -/
 @[simp]
 theorem Ioc_eq_empty_iff : Ioc a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ioc, Set.Ioc_eq_empty_iff]
 #align finset.Ioc_eq_empty_iff Finset.Ioc_eq_empty_iff
 
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 @[simp]
 theorem Ioo_eq_empty_iff [DenselyOrdered α] : Ioo a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ioo, Set.Ioo_eq_empty_iff]
 #align finset.Ioo_eq_empty_iff Finset.Ioo_eq_empty_iff
 
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-Case conversion may be inaccurate. Consider using '#align finset.Icc_eq_empty Finset.Icc_eq_emptyₓ'. -/
 alias Icc_eq_empty_iff ↔ _ Icc_eq_empty
 #align finset.Icc_eq_empty Finset.Icc_eq_empty
 
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 alias Ico_eq_empty_iff ↔ _ Ico_eq_empty
 #align finset.Ico_eq_empty Finset.Ico_eq_empty
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ioc_eq_empty Finset.Ioc_eq_emptyₓ'. -/
 alias Ioc_eq_empty_iff ↔ _ Ioc_eq_empty
 #align finset.Ioc_eq_empty Finset.Ioc_eq_empty
 
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 @[simp]
 theorem Ioo_eq_empty (h : ¬a < b) : Ioo a b = ∅ :=
   eq_empty_iff_forall_not_mem.2 fun x hx => h ((mem_Ioo.1 hx).1.trans (mem_Ioo.1 hx).2)
 #align finset.Ioo_eq_empty Finset.Ioo_eq_empty
 
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 @[simp]
 theorem Icc_eq_empty_of_lt (h : b < a) : Icc a b = ∅ :=
   Icc_eq_empty h.not_le
 #align finset.Icc_eq_empty_of_lt Finset.Icc_eq_empty_of_lt
 
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 @[simp]
 theorem Ico_eq_empty_of_le (h : b ≤ a) : Ico a b = ∅ :=
   Ico_eq_empty h.not_lt
 #align finset.Ico_eq_empty_of_le Finset.Ico_eq_empty_of_le
 
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 @[simp]
 theorem Ioc_eq_empty_of_le (h : b ≤ a) : Ioc a b = ∅ :=
   Ioc_eq_empty h.not_lt
 #align finset.Ioc_eq_empty_of_le Finset.Ioc_eq_empty_of_le
 
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 @[simp]
 theorem Ioo_eq_empty_of_le (h : b ≤ a) : Ioo a b = ∅ :=
   Ioo_eq_empty h.not_lt
 #align finset.Ioo_eq_empty_of_le Finset.Ioo_eq_empty_of_le
 
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-Case conversion may be inaccurate. Consider using '#align finset.left_mem_Icc Finset.left_mem_Iccₓ'. -/
 @[simp]
 theorem left_mem_Icc : a ∈ Icc a b ↔ a ≤ b := by simp only [mem_Icc, true_and_iff, le_rfl]
 #align finset.left_mem_Icc Finset.left_mem_Icc
 
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-Case conversion may be inaccurate. Consider using '#align finset.left_mem_Ico Finset.left_mem_Icoₓ'. -/
 @[simp]
 theorem left_mem_Ico : a ∈ Ico a b ↔ a < b := by simp only [mem_Ico, true_and_iff, le_refl]
 #align finset.left_mem_Ico Finset.left_mem_Ico
 
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-Case conversion may be inaccurate. Consider using '#align finset.right_mem_Icc Finset.right_mem_Iccₓ'. -/
 @[simp]
 theorem right_mem_Icc : b ∈ Icc a b ↔ a ≤ b := by simp only [mem_Icc, and_true_iff, le_rfl]
 #align finset.right_mem_Icc Finset.right_mem_Icc
 
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-Case conversion may be inaccurate. Consider using '#align finset.right_mem_Ioc Finset.right_mem_Iocₓ'. -/
 @[simp]
 theorem right_mem_Ioc : b ∈ Ioc a b ↔ a < b := by simp only [mem_Ioc, and_true_iff, le_rfl]
 #align finset.right_mem_Ioc Finset.right_mem_Ioc
@@ -282,152 +162,62 @@ theorem right_not_mem_Ioo : b ∉ Ioo a b := fun h => lt_irrefl _ (mem_Ioo.1 h).
 #align finset.right_not_mem_Ioo Finset.right_not_mem_Ioo
 -/
 
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-Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Icc Finset.Icc_subset_Iccₓ'. -/
 theorem Icc_subset_Icc (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Icc a₁ b₁ ⊆ Icc a₂ b₂ := by
   simpa [← coe_subset] using Set.Icc_subset_Icc ha hb
 #align finset.Icc_subset_Icc Finset.Icc_subset_Icc
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ico_subset_Ico Finset.Ico_subset_Icoₓ'. -/
 theorem Ico_subset_Ico (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Ico a₁ b₁ ⊆ Ico a₂ b₂ := by
   simpa [← coe_subset] using Set.Ico_subset_Ico ha hb
 #align finset.Ico_subset_Ico Finset.Ico_subset_Ico
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ioc_subset_Ioc Finset.Ioc_subset_Iocₓ'. -/
 theorem Ioc_subset_Ioc (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Ioc a₁ b₁ ⊆ Ioc a₂ b₂ := by
   simpa [← coe_subset] using Set.Ioc_subset_Ioc ha hb
 #align finset.Ioc_subset_Ioc Finset.Ioc_subset_Ioc
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ioo_subset_Ioo Finset.Ioo_subset_Iooₓ'. -/
 theorem Ioo_subset_Ioo (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Ioo a₁ b₁ ⊆ Ioo a₂ b₂ := by
   simpa [← coe_subset] using Set.Ioo_subset_Ioo ha hb
 #align finset.Ioo_subset_Ioo Finset.Ioo_subset_Ioo
 
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 theorem Icc_subset_Icc_left (h : a₁ ≤ a₂) : Icc a₂ b ⊆ Icc a₁ b :=
   Icc_subset_Icc h le_rfl
 #align finset.Icc_subset_Icc_left Finset.Icc_subset_Icc_left
 
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 theorem Ico_subset_Ico_left (h : a₁ ≤ a₂) : Ico a₂ b ⊆ Ico a₁ b :=
   Ico_subset_Ico h le_rfl
 #align finset.Ico_subset_Ico_left Finset.Ico_subset_Ico_left
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ioc_subset_Ioc_left Finset.Ioc_subset_Ioc_leftₓ'. -/
 theorem Ioc_subset_Ioc_left (h : a₁ ≤ a₂) : Ioc a₂ b ⊆ Ioc a₁ b :=
   Ioc_subset_Ioc h le_rfl
 #align finset.Ioc_subset_Ioc_left Finset.Ioc_subset_Ioc_left
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ioo_subset_Ioo_left Finset.Ioo_subset_Ioo_leftₓ'. -/
 theorem Ioo_subset_Ioo_left (h : a₁ ≤ a₂) : Ioo a₂ b ⊆ Ioo a₁ b :=
   Ioo_subset_Ioo h le_rfl
 #align finset.Ioo_subset_Ioo_left Finset.Ioo_subset_Ioo_left
 
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-Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Icc_right Finset.Icc_subset_Icc_rightₓ'. -/
 theorem Icc_subset_Icc_right (h : b₁ ≤ b₂) : Icc a b₁ ⊆ Icc a b₂ :=
   Icc_subset_Icc le_rfl h
 #align finset.Icc_subset_Icc_right Finset.Icc_subset_Icc_right
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ico_subset_Ico_right Finset.Ico_subset_Ico_rightₓ'. -/
 theorem Ico_subset_Ico_right (h : b₁ ≤ b₂) : Ico a b₁ ⊆ Ico a b₂ :=
   Ico_subset_Ico le_rfl h
 #align finset.Ico_subset_Ico_right Finset.Ico_subset_Ico_right
 
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 theorem Ioc_subset_Ioc_right (h : b₁ ≤ b₂) : Ioc a b₁ ⊆ Ioc a b₂ :=
   Ioc_subset_Ioc le_rfl h
 #align finset.Ioc_subset_Ioc_right Finset.Ioc_subset_Ioc_right
 
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 theorem Ioo_subset_Ioo_right (h : b₁ ≤ b₂) : Ioo a b₁ ⊆ Ioo a b₂ :=
   Ioo_subset_Ioo le_rfl h
 #align finset.Ioo_subset_Ioo_right Finset.Ioo_subset_Ioo_right
 
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 theorem Ico_subset_Ioo_left (h : a₁ < a₂) : Ico a₂ b ⊆ Ioo a₁ b := by
   rw [← coe_subset, coe_Ico, coe_Ioo]; exact Set.Ico_subset_Ioo_left h
 #align finset.Ico_subset_Ioo_left Finset.Ico_subset_Ioo_left
 
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 theorem Ioc_subset_Ioo_right (h : b₁ < b₂) : Ioc a b₁ ⊆ Ioo a b₂ := by
   rw [← coe_subset, coe_Ioc, coe_Ioo]; exact Set.Ioc_subset_Ioo_right h
 #align finset.Ioc_subset_Ioo_right Finset.Ioc_subset_Ioo_right
 
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 theorem Icc_subset_Ico_right (h : b₁ < b₂) : Icc a b₁ ⊆ Ico a b₂ := by
   rw [← coe_subset, coe_Icc, coe_Ico]; exact Set.Icc_subset_Ico_right h
 #align finset.Icc_subset_Ico_right Finset.Icc_subset_Ico_right
@@ -462,63 +252,27 @@ theorem Ioo_subset_Icc_self : Ioo a b ⊆ Icc a b :=
 #align finset.Ioo_subset_Icc_self Finset.Ioo_subset_Icc_self
 -/
 
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 theorem Icc_subset_Icc_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Icc a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ ≤ b₂ := by
   rw [← coe_subset, coe_Icc, coe_Icc, Set.Icc_subset_Icc_iff h₁]
 #align finset.Icc_subset_Icc_iff Finset.Icc_subset_Icc_iff
 
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 theorem Icc_subset_Ioo_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioo a₂ b₂ ↔ a₂ < a₁ ∧ b₁ < b₂ := by
   rw [← coe_subset, coe_Icc, coe_Ioo, Set.Icc_subset_Ioo_iff h₁]
 #align finset.Icc_subset_Ioo_iff Finset.Icc_subset_Ioo_iff
 
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 theorem Icc_subset_Ico_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ico a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ < b₂ := by
   rw [← coe_subset, coe_Icc, coe_Ico, Set.Icc_subset_Ico_iff h₁]
 #align finset.Icc_subset_Ico_iff Finset.Icc_subset_Ico_iff
 
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 theorem Icc_subset_Ioc_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioc a₂ b₂ ↔ a₂ < a₁ ∧ b₁ ≤ b₂ :=
   (Icc_subset_Ico_iff h₁.dual).trans and_comm
 #align finset.Icc_subset_Ioc_iff Finset.Icc_subset_Ioc_iff
 
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 --TODO: `Ico_subset_Ioo_iff`, `Ioc_subset_Ioo_iff`
 theorem Icc_ssubset_Icc_left (hI : a₂ ≤ b₂) (ha : a₂ < a₁) (hb : b₁ ≤ b₂) : Icc a₁ b₁ ⊂ Icc a₂ b₂ :=
   by rw [← coe_ssubset, coe_Icc, coe_Icc]; exact Set.Icc_ssubset_Icc_left hI ha hb
 #align finset.Icc_ssubset_Icc_left Finset.Icc_ssubset_Icc_left
 
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-Case conversion may be inaccurate. Consider using '#align finset.Icc_ssubset_Icc_right Finset.Icc_ssubset_Icc_rightₓ'. -/
 theorem Icc_ssubset_Icc_right (hI : a₂ ≤ b₂) (ha : a₂ ≤ a₁) (hb : b₁ < b₂) :
     Icc a₁ b₁ ⊂ Icc a₂ b₂ := by rw [← coe_ssubset, coe_Icc, coe_Icc];
   exact Set.Icc_ssubset_Icc_right hI ha hb
@@ -568,34 +322,16 @@ theorem BddBelow.finite_of_bddAbove {s : Set α} (h₀ : BddBelow s) (h₁ : Bdd
 
 section Filter
 
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 theorem Ico_filter_lt_of_le_left [DecidablePred (· < c)] (hca : c ≤ a) :
     (Ico a b).filterₓ (· < c) = ∅ :=
   filter_false_of_mem fun x hx => (hca.trans (mem_Ico.1 hx).1).not_lt
 #align finset.Ico_filter_lt_of_le_left Finset.Ico_filter_lt_of_le_left
 
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 theorem Ico_filter_lt_of_right_le [DecidablePred (· < c)] (hbc : b ≤ c) :
     (Ico a b).filterₓ (· < c) = Ico a b :=
   filter_true_of_mem fun x hx => (mem_Ico.1 hx).2.trans_le hbc
 #align finset.Ico_filter_lt_of_right_le Finset.Ico_filter_lt_of_right_le
 
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 theorem Ico_filter_lt_of_le_right [DecidablePred (· < c)] (hcb : c ≤ b) :
     (Ico a b).filterₓ (· < c) = Ico a c := by
   ext x
@@ -603,34 +339,16 @@ theorem Ico_filter_lt_of_le_right [DecidablePred (· < c)] (hcb : c ≤ b) :
   exact and_iff_left_of_imp fun h => h.2.trans_le hcb
 #align finset.Ico_filter_lt_of_le_right Finset.Ico_filter_lt_of_le_right
 
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 theorem Ico_filter_le_of_le_left {a b c : α} [DecidablePred ((· ≤ ·) c)] (hca : c ≤ a) :
     (Ico a b).filterₓ ((· ≤ ·) c) = Ico a b :=
   filter_true_of_mem fun x hx => hca.trans (mem_Ico.1 hx).1
 #align finset.Ico_filter_le_of_le_left Finset.Ico_filter_le_of_le_left
 
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 theorem Ico_filter_le_of_right_le {a b : α} [DecidablePred ((· ≤ ·) b)] :
     (Ico a b).filterₓ ((· ≤ ·) b) = ∅ :=
   filter_false_of_mem fun x hx => (mem_Ico.1 hx).2.not_le
 #align finset.Ico_filter_le_of_right_le Finset.Ico_filter_le_of_right_le
 
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 theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred ((· ≤ ·) c)] (hac : a ≤ c) :
     (Ico a b).filterₓ ((· ≤ ·) c) = Ico c b := by
   ext x
@@ -638,34 +356,16 @@ theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred ((· ≤ ·) c)] (h
   exact and_iff_right_of_imp fun h => hac.trans h.1
 #align finset.Ico_filter_le_of_left_le Finset.Ico_filter_le_of_left_le
 
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 theorem Icc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Icc a b).filterₓ (· < c) = Icc a b :=
   (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Icc.1 hx).2 h
 #align finset.Icc_filter_lt_of_lt_right Finset.Icc_filter_lt_of_lt_right
 
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 theorem Ioc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Ioc a b).filterₓ (· < c) = Ioc a b :=
   (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Ioc.1 hx).2 h
 #align finset.Ioc_filter_lt_of_lt_right Finset.Ioc_filter_lt_of_lt_right
 
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 theorem Iic_filter_lt_of_lt_right {α} [Preorder α] [LocallyFiniteOrderBot α] {a c : α}
     [DecidablePred (· < c)] (h : a < c) : (Iic a).filterₓ (· < c) = Iic a :=
   (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Iic.1 hx) h
@@ -673,42 +373,18 @@ theorem Iic_filter_lt_of_lt_right {α} [Preorder α] [LocallyFiniteOrderBot α]
 
 variable (a b) [Fintype α]
 
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 theorem filter_lt_lt_eq_Ioo [DecidablePred fun j => a < j ∧ j < b] :
     (univ.filterₓ fun j => a < j ∧ j < b) = Ioo a b := by ext; simp
 #align finset.filter_lt_lt_eq_Ioo Finset.filter_lt_lt_eq_Ioo
 
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 theorem filter_lt_le_eq_Ioc [DecidablePred fun j => a < j ∧ j ≤ b] :
     (univ.filterₓ fun j => a < j ∧ j ≤ b) = Ioc a b := by ext; simp
 #align finset.filter_lt_le_eq_Ioc Finset.filter_lt_le_eq_Ioc
 
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 theorem filter_le_lt_eq_Ico [DecidablePred fun j => a ≤ j ∧ j < b] :
     (univ.filterₓ fun j => a ≤ j ∧ j < b) = Ico a b := by ext; simp
 #align finset.filter_le_lt_eq_Ico Finset.filter_le_lt_eq_Ico
 
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 theorem filter_le_le_eq_Icc [DecidablePred fun j => a ≤ j ∧ j ≤ b] :
     (univ.filterₓ fun j => a ≤ j ∧ j ≤ b) = Icc a b := by ext; simp
 #align finset.filter_le_le_eq_Icc Finset.filter_le_le_eq_Icc
@@ -825,22 +501,10 @@ theorem Set.Infinite.not_bddBelow {s : Set α} : s.Infinite → ¬BddBelow s :=
 
 variable [Fintype α]
 
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 theorem filter_lt_eq_Ioi [DecidablePred ((· < ·) a)] : univ.filterₓ ((· < ·) a) = Ioi a := by ext;
   simp
 #align finset.filter_lt_eq_Ioi Finset.filter_lt_eq_Ioi
 
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 theorem filter_le_eq_Ici [DecidablePred ((· ≤ ·) a)] : univ.filterₓ ((· ≤ ·) a) = Ici a := by ext;
   simp
 #align finset.filter_le_eq_Ici Finset.filter_le_eq_Ici
@@ -870,21 +534,9 @@ theorem Set.Infinite.not_bddAbove {s : Set α} : s.Infinite → ¬BddAbove s :=
 
 variable [Fintype α]
 
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 theorem filter_gt_eq_Iio [DecidablePred (· < a)] : univ.filterₓ (· < a) = Iio a := by ext; simp
 #align finset.filter_gt_eq_Iio Finset.filter_gt_eq_Iio
 
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 theorem filter_ge_eq_Iic [DecidablePred (· ≤ a)] : univ.filterₓ (· ≤ a) = Iic a := by ext; simp
 #align finset.filter_ge_eq_Iic Finset.filter_ge_eq_Iic
 
@@ -892,12 +544,6 @@ end LocallyFiniteOrderBot
 
 variable [LocallyFiniteOrderTop α] [LocallyFiniteOrderBot α]
 
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 theorem disjoint_Ioi_Iio (a : α) : Disjoint (Ioi a) (Iio a) :=
   disjoint_left.2 fun b hab hba => (mem_Ioi.1 hab).not_lt <| mem_Iio.1 hba
 #align finset.disjoint_Ioi_Iio Finset.disjoint_Ioi_Iio
@@ -921,12 +567,6 @@ theorem Icc_eq_singleton_iff : Icc a b = {c} ↔ a = c ∧ b = c := by
 #align finset.Icc_eq_singleton_iff Finset.Icc_eq_singleton_iff
 -/
 
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 theorem Ico_disjoint_Ico_consecutive (a b c : α) : Disjoint (Ico a b) (Ico b c) :=
   disjoint_left.2 fun x hab hbc => (mem_Ico.mp hab).2.not_le (mem_Ico.mp hbc).1
 #align finset.Ico_disjoint_Ico_consecutive Finset.Ico_disjoint_Ico_consecutive
@@ -965,96 +605,42 @@ theorem Icc_diff_both (a b : α) : Icc a b \ {a, b} = Ioo a b := by simp [← co
 #align finset.Icc_diff_both Finset.Icc_diff_both
 -/
 
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 @[simp]
 theorem Ico_insert_right (h : a ≤ b) : insert b (Ico a b) = Icc a b := by
   rw [← coe_inj, coe_insert, coe_Icc, coe_Ico, Set.insert_eq, Set.union_comm, Set.Ico_union_right h]
 #align finset.Ico_insert_right Finset.Ico_insert_right
 
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 @[simp]
 theorem Ioc_insert_left (h : a ≤ b) : insert a (Ioc a b) = Icc a b := by
   rw [← coe_inj, coe_insert, coe_Ioc, coe_Icc, Set.insert_eq, Set.union_comm, Set.Ioc_union_left h]
 #align finset.Ioc_insert_left Finset.Ioc_insert_left
 
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 @[simp]
 theorem Ioo_insert_left (h : a < b) : insert a (Ioo a b) = Ico a b := by
   rw [← coe_inj, coe_insert, coe_Ioo, coe_Ico, Set.insert_eq, Set.union_comm, Set.Ioo_union_left h]
 #align finset.Ioo_insert_left Finset.Ioo_insert_left
 
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 @[simp]
 theorem Ioo_insert_right (h : a < b) : insert b (Ioo a b) = Ioc a b := by
   rw [← coe_inj, coe_insert, coe_Ioo, coe_Ioc, Set.insert_eq, Set.union_comm, Set.Ioo_union_right h]
 #align finset.Ioo_insert_right Finset.Ioo_insert_right
 
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 @[simp]
 theorem Icc_diff_Ico_self (h : a ≤ b) : Icc a b \ Ico a b = {b} := by simp [← coe_inj, h]
 #align finset.Icc_diff_Ico_self Finset.Icc_diff_Ico_self
 
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 @[simp]
 theorem Icc_diff_Ioc_self (h : a ≤ b) : Icc a b \ Ioc a b = {a} := by simp [← coe_inj, h]
 #align finset.Icc_diff_Ioc_self Finset.Icc_diff_Ioc_self
 
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 @[simp]
 theorem Icc_diff_Ioo_self (h : a ≤ b) : Icc a b \ Ioo a b = {a, b} := by simp [← coe_inj, h]
 #align finset.Icc_diff_Ioo_self Finset.Icc_diff_Ioo_self
 
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 @[simp]
 theorem Ico_diff_Ioo_self (h : a < b) : Ico a b \ Ioo a b = {a} := by simp [← coe_inj, h]
 #align finset.Ico_diff_Ioo_self Finset.Ico_diff_Ioo_self
 
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 @[simp]
 theorem Ioc_diff_Ioo_self (h : a < b) : Ioc a b \ Ioo a b = {b} := by simp [← coe_inj, h]
 #align finset.Ioc_diff_Ioo_self Finset.Ioc_diff_Ioo_self
@@ -1068,57 +654,27 @@ theorem Ico_inter_Ico_consecutive (a b c : α) : Ico a b ∩ Ico b c = ∅ :=
 
 end DecidableEq
 
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 -- Those lemmas are purposefully the other way around
 /-- `finset.cons` version of `finset.Ico_insert_right`. -/
 theorem Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico := by
   classical rw [cons_eq_insert, Ico_insert_right h]
 #align finset.Icc_eq_cons_Ico Finset.Icc_eq_cons_Ico
 
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 /-- `finset.cons` version of `finset.Ioc_insert_left`. -/
 theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc := by
   classical rw [cons_eq_insert, Ioc_insert_left h]
 #align finset.Icc_eq_cons_Ioc Finset.Icc_eq_cons_Ioc
 
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 /-- `finset.cons` version of `finset.Ioo_insert_right`. -/
 theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by
   classical rw [cons_eq_insert, Ioo_insert_right h]
 #align finset.Ioc_eq_cons_Ioo Finset.Ioc_eq_cons_Ioo
 
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 /-- `finset.cons` version of `finset.Ioo_insert_left`. -/
 theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by
   classical rw [cons_eq_insert, Ioo_insert_left h]
 #align finset.Ico_eq_cons_Ioo Finset.Ico_eq_cons_Ioo
 
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 theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
     ((Ico a b).filterₓ fun x => x ≤ a) = {a} :=
   by
@@ -1261,34 +817,16 @@ section LocallyFiniteOrder
 
 variable [LocallyFiniteOrder α] {a b : α}
 
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 theorem Ico_subset_Ico_iff {a₁ b₁ a₂ b₂ : α} (h : a₁ < b₁) :
     Ico a₁ b₁ ⊆ Ico a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ ≤ b₂ := by
   rw [← coe_subset, coe_Ico, coe_Ico, Set.Ico_subset_Ico_iff h]
 #align finset.Ico_subset_Ico_iff Finset.Ico_subset_Ico_iff
 
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 theorem Ico_union_Ico_eq_Ico {a b c : α} (hab : a ≤ b) (hbc : b ≤ c) :
     Ico a b ∪ Ico b c = Ico a c := by
   rw [← coe_inj, coe_union, coe_Ico, coe_Ico, coe_Ico, Set.Ico_union_Ico_eq_Ico hab hbc]
 #align finset.Ico_union_Ico_eq_Ico Finset.Ico_union_Ico_eq_Ico
 
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 @[simp]
 theorem Ioc_union_Ioc_eq_Ioc {a b c : α} (h₁ : a ≤ b) (h₂ : b ≤ c) : Ioc a b ∪ Ioc b c = Ioc a c :=
   by rw [← coe_inj, coe_union, coe_Ioc, coe_Ioc, coe_Ioc, Set.Ioc_union_Ioc_eq_Ioc h₁ h₂]
@@ -1300,34 +838,16 @@ theorem Ico_subset_Ico_union_Ico {a b c : α} : Ico a c ⊆ Ico a b ∪ Ico b c
 #align finset.Ico_subset_Ico_union_Ico Finset.Ico_subset_Ico_union_Ico
 -/
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ico_union_Ico' Finset.Ico_union_Ico'ₓ'. -/
 theorem Ico_union_Ico' {a b c d : α} (hcb : c ≤ b) (had : a ≤ d) :
     Ico a b ∪ Ico c d = Ico (min a c) (max b d) := by
   rw [← coe_inj, coe_union, coe_Ico, coe_Ico, coe_Ico, Set.Ico_union_Ico' hcb had]
 #align finset.Ico_union_Ico' Finset.Ico_union_Ico'
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ico_union_Ico Finset.Ico_union_Icoₓ'. -/
 theorem Ico_union_Ico {a b c d : α} (h₁ : min a b ≤ max c d) (h₂ : min c d ≤ max a b) :
     Ico a b ∪ Ico c d = Ico (min a c) (max b d) := by
   rw [← coe_inj, coe_union, coe_Ico, coe_Ico, coe_Ico, Set.Ico_union_Ico h₁ h₂]
 #align finset.Ico_union_Ico Finset.Ico_union_Ico
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ico_inter_Ico Finset.Ico_inter_Icoₓ'. -/
 theorem Ico_inter_Ico {a b c d : α} : Ico a b ∩ Ico c d = Ico (max a c) (min b d) := by
   rw [← coe_inj, coe_inter, coe_Ico, coe_Ico, coe_Ico, ← inf_eq_min, ← sup_eq_max,
     Set.Ico_inter_Ico]
@@ -1367,12 +887,6 @@ theorem Iio_filter_lt {α} [LinearOrder α] [LocallyFiniteOrderBot α] (a b : α
 #align finset.Iio_filter_lt Finset.Iio_filter_lt
 -/
 
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-Case conversion may be inaccurate. Consider using '#align finset.Ico_diff_Ico_left Finset.Ico_diff_Ico_leftₓ'. -/
 @[simp]
 theorem Ico_diff_Ico_left (a b c : α) : Ico a b \ Ico a c = Ico (max a c) b :=
   by
@@ -1383,12 +897,6 @@ theorem Ico_diff_Ico_left (a b c : α) : Ico a b \ Ico a c = Ico (max a c) b :=
   · rw [Ico_eq_empty_of_le h, sdiff_empty, max_eq_left h]
 #align finset.Ico_diff_Ico_left Finset.Ico_diff_Ico_left
 
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 @[simp]
 theorem Ico_diff_Ico_right (a b c : α) : Ico a b \ Ico c b = Ico a (min b c) :=
   by
@@ -1405,22 +913,10 @@ section LocallyFiniteOrderBot
 
 variable [LocallyFiniteOrderBot α] {s : Set α}
 
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-Case conversion may be inaccurate. Consider using '#align set.infinite.exists_gt Set.Infinite.exists_gtₓ'. -/
 theorem Set.Infinite.exists_gt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, a < b :=
   not_bddAbove_iff.1 hs.not_bddAbove
 #align set.infinite.exists_gt Set.Infinite.exists_gt
 
-/- warning: set.infinite_iff_exists_gt -> Set.infinite_iff_exists_gt is a dubious translation:
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-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => And (Membership.mem.{u1, u1} α (Set.{u1} α) (Set.instMembershipSet.{u1} α) b s) (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b)))
-Case conversion may be inaccurate. Consider using '#align set.infinite_iff_exists_gt Set.infinite_iff_exists_gtₓ'. -/
 theorem Set.infinite_iff_exists_gt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, a < b :=
   ⟨Set.Infinite.exists_gt, Set.infinite_of_forall_exists_gt⟩
 #align set.infinite_iff_exists_gt Set.infinite_iff_exists_gt
@@ -1431,22 +927,10 @@ section LocallyFiniteOrderTop
 
 variable [LocallyFiniteOrderTop α] {s : Set α}
 
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-Case conversion may be inaccurate. Consider using '#align set.infinite.exists_lt Set.Infinite.exists_ltₓ'. -/
 theorem Set.Infinite.exists_lt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, b < a :=
   not_bddBelow_iff.1 hs.not_bddBelow
 #align set.infinite.exists_lt Set.Infinite.exists_lt
 
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-but is expected to have type
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-Case conversion may be inaccurate. Consider using '#align set.infinite_iff_exists_lt Set.infinite_iff_exists_ltₓ'. -/
 theorem Set.infinite_iff_exists_lt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, b < a :=
   ⟨Set.Infinite.exists_lt, Set.infinite_of_forall_exists_lt⟩
 #align set.infinite_iff_exists_lt Set.infinite_iff_exists_lt
@@ -1473,22 +957,10 @@ theorem uIcc_toDual (a b : α) : [toDual a, toDual b] = [a, b].map toDual.toEmbe
 #align finset.uIcc_to_dual Finset.uIcc_toDual
 -/
 
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-Case conversion may be inaccurate. Consider using '#align finset.uIcc_of_le Finset.uIcc_of_leₓ'. -/
 @[simp]
 theorem uIcc_of_le (h : a ≤ b) : [a, b] = Icc a b := by rw [uIcc, inf_eq_left.2 h, sup_eq_right.2 h]
 #align finset.uIcc_of_le Finset.uIcc_of_le
 
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-Case conversion may be inaccurate. Consider using '#align finset.uIcc_of_ge Finset.uIcc_of_geₓ'. -/
 @[simp]
 theorem uIcc_of_ge (h : b ≤ a) : [a, b] = Icc b a := by rw [uIcc, inf_eq_right.2 h, sup_eq_left.2 h]
 #align finset.uIcc_of_ge Finset.uIcc_of_ge
@@ -1537,22 +1009,10 @@ theorem right_mem_uIcc : b ∈ [a, b] :=
 #align finset.right_mem_uIcc Finset.right_mem_uIcc
 -/
 
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-Case conversion may be inaccurate. Consider using '#align finset.mem_uIcc_of_le Finset.mem_uIcc_of_leₓ'. -/
 theorem mem_uIcc_of_le (ha : a ≤ x) (hb : x ≤ b) : x ∈ [a, b] :=
   Icc_subset_uIcc <| mem_Icc.2 ⟨ha, hb⟩
 #align finset.mem_uIcc_of_le Finset.mem_uIcc_of_le
 
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-Case conversion may be inaccurate. Consider using '#align finset.mem_uIcc_of_ge Finset.mem_uIcc_of_geₓ'. -/
 theorem mem_uIcc_of_ge (hb : b ≤ x) (ha : x ≤ a) : x ∈ [a, b] :=
   Icc_subset_uIcc' <| mem_Icc.2 ⟨hb, ha⟩
 #align finset.mem_uIcc_of_ge Finset.mem_uIcc_of_ge
@@ -1575,12 +1035,6 @@ theorem uIcc_subset_uIcc_iff_mem : [a₁, b₁] ⊆ [a₂, b₂] ↔ a₁ ∈ [a
 #align finset.uIcc_subset_uIcc_iff_mem Finset.uIcc_subset_uIcc_iff_mem
 -/
 
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-Case conversion may be inaccurate. Consider using '#align finset.uIcc_subset_uIcc_iff_le' Finset.uIcc_subset_uIcc_iff_le'ₓ'. -/
 theorem uIcc_subset_uIcc_iff_le' : [a₁, b₁] ⊆ [a₂, b₂] ↔ a₂ ⊓ b₂ ≤ a₁ ⊓ b₁ ∧ a₁ ⊔ b₁ ≤ a₂ ⊔ b₂ :=
   Icc_subset_Icc_iff inf_le_sup
 #align finset.uIcc_subset_uIcc_iff_le' Finset.uIcc_subset_uIcc_iff_le'
@@ -1635,32 +1089,14 @@ section LinearOrder
 
 variable [LinearOrder α] [LocallyFiniteOrder α] {a a₁ a₂ b b₁ b₂ c x : α}
 
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-Case conversion may be inaccurate. Consider using '#align finset.Icc_min_max Finset.Icc_min_maxₓ'. -/
 theorem Icc_min_max : Icc (min a b) (max a b) = [a, b] :=
   rfl
 #align finset.Icc_min_max Finset.Icc_min_max
 
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 theorem uIcc_of_not_le (h : ¬a ≤ b) : [a, b] = Icc b a :=
   uIcc_of_ge <| le_of_not_ge h
 #align finset.uIcc_of_not_le Finset.uIcc_of_not_le
 
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 theorem uIcc_of_not_ge (h : ¬b ≤ a) : [a, b] = Icc a b :=
   uIcc_of_le <| le_of_not_ge h
 #align finset.uIcc_of_not_ge Finset.uIcc_of_not_ge
@@ -1671,41 +1107,17 @@ theorem uIcc_eq_union : [a, b] = Icc a b ∪ Icc b a :=
 #align finset.uIcc_eq_union Finset.uIcc_eq_union
 -/
 
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 theorem mem_uIcc' : a ∈ [b, c] ↔ b ≤ a ∧ a ≤ c ∨ c ≤ a ∧ a ≤ b := by simp [uIcc_eq_union]
 #align finset.mem_uIcc' Finset.mem_uIcc'
 
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 theorem not_mem_uIcc_of_lt : c < a → c < b → c ∉ [a, b] := by rw [mem_uIcc];
   exact Set.not_mem_uIcc_of_lt
 #align finset.not_mem_uIcc_of_lt Finset.not_mem_uIcc_of_lt
 
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-Case conversion may be inaccurate. Consider using '#align finset.not_mem_uIcc_of_gt Finset.not_mem_uIcc_of_gtₓ'. -/
 theorem not_mem_uIcc_of_gt : a < c → b < c → c ∉ [a, b] := by rw [mem_uIcc];
   exact Set.not_mem_uIcc_of_gt
 #align finset.not_mem_uIcc_of_gt Finset.not_mem_uIcc_of_gt
 
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 theorem uIcc_subset_uIcc_iff_le :
     [a₁, b₁] ⊆ [a₂, b₂] ↔ min a₂ b₂ ≤ min a₁ b₁ ∧ max a₁ b₁ ≤ max a₂ b₂ :=
   uIcc_subset_uIcc_iff_le'
@@ -1724,89 +1136,41 @@ section OrderedCancelAddCommMonoid
 
 variable [OrderedCancelAddCommMonoid α] [ExistsAddOfLE α] [LocallyFiniteOrder α]
 
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 @[simp]
 theorem map_add_left_Icc (a b c : α) : (Icc a b).map (addLeftEmbedding c) = Icc (c + a) (c + b) :=
   by rw [← coe_inj, coe_map, coe_Icc, coe_Icc]; exact Set.image_const_add_Icc _ _ _
 #align finset.map_add_left_Icc Finset.map_add_left_Icc
 
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 @[simp]
 theorem map_add_right_Icc (a b c : α) : (Icc a b).map (addRightEmbedding c) = Icc (a + c) (b + c) :=
   by rw [← coe_inj, coe_map, coe_Icc, coe_Icc]; exact Set.image_add_const_Icc _ _ _
 #align finset.map_add_right_Icc Finset.map_add_right_Icc
 
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 @[simp]
 theorem map_add_left_Ico (a b c : α) : (Ico a b).map (addLeftEmbedding c) = Ico (c + a) (c + b) :=
   by rw [← coe_inj, coe_map, coe_Ico, coe_Ico]; exact Set.image_const_add_Ico _ _ _
 #align finset.map_add_left_Ico Finset.map_add_left_Ico
 
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 @[simp]
 theorem map_add_right_Ico (a b c : α) : (Ico a b).map (addRightEmbedding c) = Ico (a + c) (b + c) :=
   by rw [← coe_inj, coe_map, coe_Ico, coe_Ico]; exact Set.image_add_const_Ico _ _ _
 #align finset.map_add_right_Ico Finset.map_add_right_Ico
 
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 @[simp]
 theorem map_add_left_Ioc (a b c : α) : (Ioc a b).map (addLeftEmbedding c) = Ioc (c + a) (c + b) :=
   by rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]; exact Set.image_const_add_Ioc _ _ _
 #align finset.map_add_left_Ioc Finset.map_add_left_Ioc
 
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 @[simp]
 theorem map_add_right_Ioc (a b c : α) : (Ioc a b).map (addRightEmbedding c) = Ioc (a + c) (b + c) :=
   by rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]; exact Set.image_add_const_Ioc _ _ _
 #align finset.map_add_right_Ioc Finset.map_add_right_Ioc
 
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-Case conversion may be inaccurate. Consider using '#align finset.map_add_left_Ioo Finset.map_add_left_Iooₓ'. -/
 @[simp]
 theorem map_add_left_Ioo (a b c : α) : (Ioo a b).map (addLeftEmbedding c) = Ioo (c + a) (c + b) :=
   by rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]; exact Set.image_const_add_Ioo _ _ _
 #align finset.map_add_left_Ioo Finset.map_add_left_Ioo
 
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-Case conversion may be inaccurate. Consider using '#align finset.map_add_right_Ioo Finset.map_add_right_Iooₓ'. -/
 @[simp]
 theorem map_add_right_Ioo (a b c : α) : (Ioo a b).map (addRightEmbedding c) = Ioo (a + c) (b + c) :=
   by rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]; exact Set.image_add_const_Ioo _ _ _
@@ -1814,99 +1178,45 @@ theorem map_add_right_Ioo (a b c : α) : (Ioo a b).map (addRightEmbedding c) = I
 
 variable [DecidableEq α]
 
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-Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Icc Finset.image_add_left_Iccₓ'. -/
 @[simp]
 theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) := by
   rw [← map_add_left_Icc, map_eq_image]; rfl
 #align finset.image_add_left_Icc Finset.image_add_left_Icc
 
-/- warning: finset.image_add_left_Ico -> Finset.image_add_left_Ico is a dubious translation:
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-Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ico Finset.image_add_left_Icoₓ'. -/
 @[simp]
 theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) := by
   rw [← map_add_left_Ico, map_eq_image]; rfl
 #align finset.image_add_left_Ico Finset.image_add_left_Ico
 
-/- warning: finset.image_add_left_Ioc -> Finset.image_add_left_Ioc is a dubious translation:
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-Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioc Finset.image_add_left_Iocₓ'. -/
 @[simp]
 theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) := by
   rw [← map_add_left_Ioc, map_eq_image]; rfl
 #align finset.image_add_left_Ioc Finset.image_add_left_Ioc
 
-/- warning: finset.image_add_left_Ioo -> Finset.image_add_left_Ioo is a dubious translation:
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-Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioo Finset.image_add_left_Iooₓ'. -/
 @[simp]
 theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) := by
   rw [← map_add_left_Ioo, map_eq_image]; rfl
 #align finset.image_add_left_Ioo Finset.image_add_left_Ioo
 
-/- warning: finset.image_add_right_Icc -> Finset.image_add_right_Icc is a dubious translation:
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-Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Icc Finset.image_add_right_Iccₓ'. -/
 @[simp]
 theorem image_add_right_Icc (a b c : α) : (Icc a b).image (· + c) = Icc (a + c) (b + c) := by
   rw [← map_add_right_Icc, map_eq_image]; rfl
 #align finset.image_add_right_Icc Finset.image_add_right_Icc
 
-/- warning: finset.image_add_right_Ico -> Finset.image_add_right_Ico is a dubious translation:
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-Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Ico Finset.image_add_right_Icoₓ'. -/
 theorem image_add_right_Ico (a b c : α) : (Ico a b).image (· + c) = Ico (a + c) (b + c) := by
   rw [← map_add_right_Ico, map_eq_image]; rfl
 #align finset.image_add_right_Ico Finset.image_add_right_Ico
 
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-Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Ioc Finset.image_add_right_Iocₓ'. -/
 theorem image_add_right_Ioc (a b c : α) : (Ioc a b).image (· + c) = Ioc (a + c) (b + c) := by
   rw [← map_add_right_Ioc, map_eq_image]; rfl
 #align finset.image_add_right_Ioc Finset.image_add_right_Ioc
 
-/- warning: finset.image_add_right_Ioo -> Finset.image_add_right_Ioo is a dubious translation:
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-Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Ioo Finset.image_add_right_Iooₓ'. -/
 theorem image_add_right_Ioo (a b c : α) : (Ioo a b).image (· + c) = Ioo (a + c) (b + c) := by
   rw [← map_add_right_Ioo, map_eq_image]; rfl
 #align finset.image_add_right_Ioo Finset.image_add_right_Ioo
 
 end OrderedCancelAddCommMonoid
 
-/- warning: finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag -> Finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag is a dubious translation:
-lean 3 declaration is
-  forall {ι : Type.{u1}} {α : Type.{u2}} [_inst_1 : Fintype.{u1} ι] [_inst_2 : LinearOrder.{u1} ι] [_inst_3 : LocallyFiniteOrderTop.{u1} ι (PartialOrder.toPreorder.{u1} ι (SemilatticeInf.toPartialOrder.{u1} ι (Lattice.toSemilatticeInf.{u1} ι (LinearOrder.toLattice.{u1} ι _inst_2))))] [_inst_4 : LocallyFiniteOrderBot.{u1} ι (PartialOrder.toPreorder.{u1} ι (SemilatticeInf.toPartialOrder.{u1} ι (Lattice.toSemilatticeInf.{u1} ι (LinearOrder.toLattice.{u1} ι _inst_2))))] [_inst_5 : CommMonoid.{u2} α] (f : ι -> ι -> α), Eq.{succ u2} α (Finset.prod.{u2, u1} α ι _inst_5 (Finset.univ.{u1} ι _inst_1) (fun (i : ι) => Finset.prod.{u2, u1} α ι _inst_5 (Finset.Ioi.{u1} ι (PartialOrder.toPreorder.{u1} ι (SemilatticeInf.toPartialOrder.{u1} ι (Lattice.toSemilatticeInf.{u1} ι (LinearOrder.toLattice.{u1} ι _inst_2)))) _inst_3 i) (fun (j : ι) => HMul.hMul.{u2, u2, u2} α α α (instHMul.{u2} α (MulOneClass.toHasMul.{u2} α (Monoid.toMulOneClass.{u2} α (CommMonoid.toMonoid.{u2} α _inst_5)))) (f j i) (f i j)))) (Finset.prod.{u2, u1} α ι _inst_5 (Finset.univ.{u1} ι _inst_1) (fun (i : ι) => Finset.prod.{u2, u1} α ι _inst_5 (HasCompl.compl.{u1} (Finset.{u1} ι) (BooleanAlgebra.toHasCompl.{u1} (Finset.{u1} ι) (Finset.booleanAlgebra.{u1} ι _inst_1 (fun (a : ι) (b : ι) => Eq.decidable.{u1} ι _inst_2 a b))) (Singleton.singleton.{u1, u1} ι (Finset.{u1} ι) (Finset.hasSingleton.{u1} ι) i)) (fun (j : ι) => f j i)))
-but is expected to have type
-  forall {ι : Type.{u2}} {α : Type.{u1}} [_inst_1 : Fintype.{u2} ι] [_inst_2 : LinearOrder.{u2} ι] [_inst_3 : LocallyFiniteOrderTop.{u2} ι (PartialOrder.toPreorder.{u2} ι (SemilatticeInf.toPartialOrder.{u2} ι (Lattice.toSemilatticeInf.{u2} ι (DistribLattice.toLattice.{u2} ι (instDistribLattice.{u2} ι _inst_2)))))] [_inst_4 : LocallyFiniteOrderBot.{u2} ι (PartialOrder.toPreorder.{u2} ι (SemilatticeInf.toPartialOrder.{u2} ι (Lattice.toSemilatticeInf.{u2} ι (DistribLattice.toLattice.{u2} ι (instDistribLattice.{u2} ι _inst_2)))))] [_inst_5 : CommMonoid.{u1} α] (f : ι -> ι -> α), Eq.{succ u1} α (Finset.prod.{u1, u2} α ι _inst_5 (Finset.univ.{u2} ι _inst_1) (fun (i : ι) => Finset.prod.{u1, u2} α ι _inst_5 (Finset.Ioi.{u2} ι (PartialOrder.toPreorder.{u2} ι (SemilatticeInf.toPartialOrder.{u2} ι (Lattice.toSemilatticeInf.{u2} ι (DistribLattice.toLattice.{u2} ι (instDistribLattice.{u2} ι _inst_2))))) _inst_3 i) (fun (j : ι) => HMul.hMul.{u1, u1, u1} α α α (instHMul.{u1} α (MulOneClass.toMul.{u1} α (Monoid.toMulOneClass.{u1} α (CommMonoid.toMonoid.{u1} α _inst_5)))) (f j i) (f i j)))) (Finset.prod.{u1, u2} α ι _inst_5 (Finset.univ.{u2} ι _inst_1) (fun (i : ι) => Finset.prod.{u1, u2} α ι _inst_5 (HasCompl.compl.{u2} (Finset.{u2} ι) (BooleanAlgebra.toHasCompl.{u2} (Finset.{u2} ι) (Finset.booleanAlgebra.{u2} ι _inst_1 (fun (a : ι) (b : ι) => instDecidableEq.{u2} ι _inst_2 a b))) (Singleton.singleton.{u2, u2} ι (Finset.{u2} ι) (Finset.instSingletonFinset.{u2} ι) i)) (fun (j : ι) => f j i)))
-Case conversion may be inaccurate. Consider using '#align finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag Finset.prod_prod_Ioi_mul_eq_prod_prod_off_diagₓ'. -/
 @[to_additive]
 theorem prod_prod_Ioi_mul_eq_prod_prod_off_diag [Fintype ι] [LinearOrder ι]
     [LocallyFiniteOrderTop ι] [LocallyFiniteOrderBot ι] [CommMonoid α] (f : ι → ι → α) :

bump to nightly-2023-05-28-04

mathlib commit https://github.com/leanprover-community/mathlib/commit/917c3c072e487b3cccdbfeff17e75b40e45f66cb

6797a637

Diff

@@ -408,10 +408,8 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₁ b))
 Case conversion may be inaccurate. Consider using '#align finset.Ico_subset_Ioo_left Finset.Ico_subset_Ioo_leftₓ'. -/
-theorem Ico_subset_Ioo_left (h : a₁ < a₂) : Ico a₂ b ⊆ Ioo a₁ b :=
-  by
-  rw [← coe_subset, coe_Ico, coe_Ioo]
-  exact Set.Ico_subset_Ioo_left h
+theorem Ico_subset_Ioo_left (h : a₁ < a₂) : Ico a₂ b ⊆ Ioo a₁ b := by
+  rw [← coe_subset, coe_Ico, coe_Ioo]; exact Set.Ico_subset_Ioo_left h
 #align finset.Ico_subset_Ioo_left Finset.Ico_subset_Ioo_left
 
 /- warning: finset.Ioc_subset_Ioo_right -> Finset.Ioc_subset_Ioo_right is a dubious translation:
@@ -420,10 +418,8 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b₂))
 Case conversion may be inaccurate. Consider using '#align finset.Ioc_subset_Ioo_right Finset.Ioc_subset_Ioo_rightₓ'. -/
-theorem Ioc_subset_Ioo_right (h : b₁ < b₂) : Ioc a b₁ ⊆ Ioo a b₂ :=
-  by
-  rw [← coe_subset, coe_Ioc, coe_Ioo]
-  exact Set.Ioc_subset_Ioo_right h
+theorem Ioc_subset_Ioo_right (h : b₁ < b₂) : Ioc a b₁ ⊆ Ioo a b₂ := by
+  rw [← coe_subset, coe_Ioc, coe_Ioo]; exact Set.Ioc_subset_Ioo_right h
 #align finset.Ioc_subset_Ioo_right Finset.Ioc_subset_Ioo_right
 
 /- warning: finset.Icc_subset_Ico_right -> Finset.Icc_subset_Ico_right is a dubious translation:
@@ -432,40 +428,30 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ico.{u1} α _inst_1 _inst_2 a b₂))
 Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Ico_right Finset.Icc_subset_Ico_rightₓ'. -/
-theorem Icc_subset_Ico_right (h : b₁ < b₂) : Icc a b₁ ⊆ Ico a b₂ :=
-  by
-  rw [← coe_subset, coe_Icc, coe_Ico]
-  exact Set.Icc_subset_Ico_right h
+theorem Icc_subset_Ico_right (h : b₁ < b₂) : Icc a b₁ ⊆ Ico a b₂ := by
+  rw [← coe_subset, coe_Icc, coe_Ico]; exact Set.Icc_subset_Ico_right h
 #align finset.Icc_subset_Ico_right Finset.Icc_subset_Ico_right
 
 #print Finset.Ioo_subset_Ico_self /-
-theorem Ioo_subset_Ico_self : Ioo a b ⊆ Ico a b :=
-  by
-  rw [← coe_subset, coe_Ioo, coe_Ico]
+theorem Ioo_subset_Ico_self : Ioo a b ⊆ Ico a b := by rw [← coe_subset, coe_Ioo, coe_Ico];
   exact Set.Ioo_subset_Ico_self
 #align finset.Ioo_subset_Ico_self Finset.Ioo_subset_Ico_self
 -/
 
 #print Finset.Ioo_subset_Ioc_self /-
-theorem Ioo_subset_Ioc_self : Ioo a b ⊆ Ioc a b :=
-  by
-  rw [← coe_subset, coe_Ioo, coe_Ioc]
+theorem Ioo_subset_Ioc_self : Ioo a b ⊆ Ioc a b := by rw [← coe_subset, coe_Ioo, coe_Ioc];
   exact Set.Ioo_subset_Ioc_self
 #align finset.Ioo_subset_Ioc_self Finset.Ioo_subset_Ioc_self
 -/
 
 #print Finset.Ico_subset_Icc_self /-
-theorem Ico_subset_Icc_self : Ico a b ⊆ Icc a b :=
-  by
-  rw [← coe_subset, coe_Ico, coe_Icc]
+theorem Ico_subset_Icc_self : Ico a b ⊆ Icc a b := by rw [← coe_subset, coe_Ico, coe_Icc];
   exact Set.Ico_subset_Icc_self
 #align finset.Ico_subset_Icc_self Finset.Ico_subset_Icc_self
 -/
 
 #print Finset.Ioc_subset_Icc_self /-
-theorem Ioc_subset_Icc_self : Ioc a b ⊆ Icc a b :=
-  by
-  rw [← coe_subset, coe_Ioc, coe_Icc]
+theorem Ioc_subset_Icc_self : Ioc a b ⊆ Icc a b := by rw [← coe_subset, coe_Ioc, coe_Icc];
   exact Set.Ioc_subset_Icc_self
 #align finset.Ioc_subset_Icc_self Finset.Ioc_subset_Icc_self
 -/
@@ -524,9 +510,7 @@ but is expected to have type
 Case conversion may be inaccurate. Consider using '#align finset.Icc_ssubset_Icc_left Finset.Icc_ssubset_Icc_leftₓ'. -/
 --TODO: `Ico_subset_Ioo_iff`, `Ioc_subset_Ioo_iff`
 theorem Icc_ssubset_Icc_left (hI : a₂ ≤ b₂) (ha : a₂ < a₁) (hb : b₁ ≤ b₂) : Icc a₁ b₁ ⊂ Icc a₂ b₂ :=
-  by
-  rw [← coe_ssubset, coe_Icc, coe_Icc]
-  exact Set.Icc_ssubset_Icc_left hI ha hb
+  by rw [← coe_ssubset, coe_Icc, coe_Icc]; exact Set.Icc_ssubset_Icc_left hI ha hb
 #align finset.Icc_ssubset_Icc_left Finset.Icc_ssubset_Icc_left
 
 /- warning: finset.Icc_ssubset_Icc_right -> Finset.Icc_ssubset_Icc_right is a dubious translation:
@@ -536,8 +520,7 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ b₂) -> (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ a₁) -> (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b₁ b₂) -> (HasSSubset.SSubset.{u1} (Finset.{u1} α) (Finset.instHasSSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b₂))
 Case conversion may be inaccurate. Consider using '#align finset.Icc_ssubset_Icc_right Finset.Icc_ssubset_Icc_rightₓ'. -/
 theorem Icc_ssubset_Icc_right (hI : a₂ ≤ b₂) (ha : a₂ ≤ a₁) (hb : b₁ < b₂) :
-    Icc a₁ b₁ ⊂ Icc a₂ b₂ := by
-  rw [← coe_ssubset, coe_Icc, coe_Icc]
+    Icc a₁ b₁ ⊂ Icc a₂ b₂ := by rw [← coe_ssubset, coe_Icc, coe_Icc];
   exact Set.Icc_ssubset_Icc_right hI ha hb
 #align finset.Icc_ssubset_Icc_right Finset.Icc_ssubset_Icc_right
 
@@ -697,10 +680,7 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b)
 Case conversion may be inaccurate. Consider using '#align finset.filter_lt_lt_eq_Ioo Finset.filter_lt_lt_eq_Iooₓ'. -/
 theorem filter_lt_lt_eq_Ioo [DecidablePred fun j => a < j ∧ j < b] :
-    (univ.filterₓ fun j => a < j ∧ j < b) = Ioo a b :=
-  by
-  ext
-  simp
+    (univ.filterₓ fun j => a < j ∧ j < b) = Ioo a b := by ext; simp
 #align finset.filter_lt_lt_eq_Ioo Finset.filter_lt_lt_eq_Ioo
 
 /- warning: finset.filter_lt_le_eq_Ioc -> Finset.filter_lt_le_eq_Ioc is a dubious translation:
@@ -710,10 +690,7 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b)
 Case conversion may be inaccurate. Consider using '#align finset.filter_lt_le_eq_Ioc Finset.filter_lt_le_eq_Iocₓ'. -/
 theorem filter_lt_le_eq_Ioc [DecidablePred fun j => a < j ∧ j ≤ b] :
-    (univ.filterₓ fun j => a < j ∧ j ≤ b) = Ioc a b :=
-  by
-  ext
-  simp
+    (univ.filterₓ fun j => a < j ∧ j ≤ b) = Ioc a b := by ext; simp
 #align finset.filter_lt_le_eq_Ioc Finset.filter_lt_le_eq_Ioc
 
 /- warning: finset.filter_le_lt_eq_Ico -> Finset.filter_le_lt_eq_Ico is a dubious translation:
@@ -723,10 +700,7 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)
 Case conversion may be inaccurate. Consider using '#align finset.filter_le_lt_eq_Ico Finset.filter_le_lt_eq_Icoₓ'. -/
 theorem filter_le_lt_eq_Ico [DecidablePred fun j => a ≤ j ∧ j < b] :
-    (univ.filterₓ fun j => a ≤ j ∧ j < b) = Ico a b :=
-  by
-  ext
-  simp
+    (univ.filterₓ fun j => a ≤ j ∧ j < b) = Ico a b := by ext; simp
 #align finset.filter_le_lt_eq_Ico Finset.filter_le_lt_eq_Ico
 
 /- warning: finset.filter_le_le_eq_Icc -> Finset.filter_le_le_eq_Icc is a dubious translation:
@@ -736,10 +710,7 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Icc.{u1} α _inst_1 _inst_2 a b)
 Case conversion may be inaccurate. Consider using '#align finset.filter_le_le_eq_Icc Finset.filter_le_le_eq_Iccₓ'. -/
 theorem filter_le_le_eq_Icc [DecidablePred fun j => a ≤ j ∧ j ≤ b] :
-    (univ.filterₓ fun j => a ≤ j ∧ j ≤ b) = Icc a b :=
-  by
-  ext
-  simp
+    (univ.filterₓ fun j => a ≤ j ∧ j ≤ b) = Icc a b := by ext; simp
 #align finset.filter_le_le_eq_Icc Finset.filter_le_le_eq_Icc
 
 end Filter
@@ -860,9 +831,7 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4470 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4472 : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4470 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4472) a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4493 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4495 : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4493 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4495) a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ioi.{u1} α _inst_1 _inst_2 a)
 Case conversion may be inaccurate. Consider using '#align finset.filter_lt_eq_Ioi Finset.filter_lt_eq_Ioiₓ'. -/
-theorem filter_lt_eq_Ioi [DecidablePred ((· < ·) a)] : univ.filterₓ ((· < ·) a) = Ioi a :=
-  by
-  ext
+theorem filter_lt_eq_Ioi [DecidablePred ((· < ·) a)] : univ.filterₓ ((· < ·) a) = Ioi a := by ext;
   simp
 #align finset.filter_lt_eq_Ioi Finset.filter_lt_eq_Ioi
 
@@ -872,9 +841,7 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4536 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4538 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4536 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4538) a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4559 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4561 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4559 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4561) a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ici.{u1} α _inst_1 _inst_2 a)
 Case conversion may be inaccurate. Consider using '#align finset.filter_le_eq_Ici Finset.filter_le_eq_Iciₓ'. -/
-theorem filter_le_eq_Ici [DecidablePred ((· ≤ ·) a)] : univ.filterₓ ((· ≤ ·) a) = Ici a :=
-  by
-  ext
+theorem filter_le_eq_Ici [DecidablePred ((· ≤ ·) a)] : univ.filterₓ ((· ≤ ·) a) = Ici a := by ext;
   simp
 #align finset.filter_le_eq_Ici Finset.filter_le_eq_Ici
 
@@ -909,10 +876,7 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Iio.{u1} α _inst_1 _inst_2 a)
 Case conversion may be inaccurate. Consider using '#align finset.filter_gt_eq_Iio Finset.filter_gt_eq_Iioₓ'. -/
-theorem filter_gt_eq_Iio [DecidablePred (· < a)] : univ.filterₓ (· < a) = Iio a :=
-  by
-  ext
-  simp
+theorem filter_gt_eq_Iio [DecidablePred (· < a)] : univ.filterₓ (· < a) = Iio a := by ext; simp
 #align finset.filter_gt_eq_Iio Finset.filter_gt_eq_Iio
 
 /- warning: finset.filter_ge_eq_Iic -> Finset.filter_ge_eq_Iic is a dubious translation:
@@ -921,10 +885,7 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (_x : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) _x a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) _x a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Iic.{u1} α _inst_1 _inst_2 a)
 Case conversion may be inaccurate. Consider using '#align finset.filter_ge_eq_Iic Finset.filter_ge_eq_Iicₓ'. -/
-theorem filter_ge_eq_Iic [DecidablePred (· ≤ a)] : univ.filterₓ (· ≤ a) = Iic a :=
-  by
-  ext
-  simp
+theorem filter_ge_eq_Iic [DecidablePred (· ≤ a)] : univ.filterₓ (· ≤ a) = Iic a := by ext; simp
 #align finset.filter_ge_eq_Iic Finset.filter_ge_eq_Iic
 
 end LocallyFiniteOrderBot
@@ -1199,10 +1160,8 @@ theorem card_Ioo_eq_card_Ioc_sub_one (a b : α) : (Ioo a b).card = (Ioc a b).car
 -/
 
 #print Finset.card_Ioo_eq_card_Icc_sub_two /-
-theorem card_Ioo_eq_card_Icc_sub_two (a b : α) : (Ioo a b).card = (Icc a b).card - 2 :=
-  by
-  rw [card_Ioo_eq_card_Ico_sub_one, card_Ico_eq_card_Icc_sub_one]
-  rfl
+theorem card_Ioo_eq_card_Icc_sub_two (a b : α) : (Ioo a b).card = (Icc a b).card - 2 := by
+  rw [card_Ioo_eq_card_Ico_sub_one, card_Ico_eq_card_Icc_sub_one]; rfl
 #align finset.card_Ioo_eq_card_Icc_sub_two Finset.card_Ioo_eq_card_Icc_sub_two
 -/
 
@@ -1218,18 +1177,14 @@ variable [LocallyFiniteOrderTop α]
 
 #print Finset.Ici_erase /-
 @[simp]
-theorem Ici_erase [DecidableEq α] (a : α) : (Ici a).eraseₓ a = Ioi a :=
-  by
-  ext
+theorem Ici_erase [DecidableEq α] (a : α) : (Ici a).eraseₓ a = Ioi a := by ext;
   simp_rw [Finset.mem_erase, mem_Ici, mem_Ioi, lt_iff_le_and_ne, and_comm', ne_comm]
 #align finset.Ici_erase Finset.Ici_erase
 -/
 
 #print Finset.Ioi_insert /-
 @[simp]
-theorem Ioi_insert [DecidableEq α] (a : α) : insert a (Ioi a) = Ici a :=
-  by
-  ext
+theorem Ioi_insert [DecidableEq α] (a : α) : insert a (Ioi a) = Ici a := by ext;
   simp_rw [Finset.mem_insert, mem_Ici, mem_Ioi, le_iff_lt_or_eq, or_comm', eq_comm]
 #align finset.Ioi_insert Finset.Ioi_insert
 -/
@@ -1262,18 +1217,14 @@ variable [LocallyFiniteOrderBot α]
 
 #print Finset.Iic_erase /-
 @[simp]
-theorem Iic_erase [DecidableEq α] (b : α) : (Iic b).eraseₓ b = Iio b :=
-  by
-  ext
+theorem Iic_erase [DecidableEq α] (b : α) : (Iic b).eraseₓ b = Iio b := by ext;
   simp_rw [Finset.mem_erase, mem_Iic, mem_Iio, lt_iff_le_and_ne, and_comm']
 #align finset.Iic_erase Finset.Iic_erase
 -/
 
 #print Finset.Iio_insert /-
 @[simp]
-theorem Iio_insert [DecidableEq α] (b : α) : insert b (Iio b) = Iic b :=
-  by
-  ext
+theorem Iio_insert [DecidableEq α] (b : α) : insert b (Iio b) = Iic b := by ext;
   simp_rw [Finset.mem_insert, mem_Iic, mem_Iio, le_iff_lt_or_eq, or_comm']
 #align finset.Iio_insert Finset.Iio_insert
 -/
@@ -1344,10 +1295,8 @@ theorem Ioc_union_Ioc_eq_Ioc {a b c : α} (h₁ : a ≤ b) (h₂ : b ≤ c) : Io
 #align finset.Ioc_union_Ioc_eq_Ioc Finset.Ioc_union_Ioc_eq_Ioc
 
 #print Finset.Ico_subset_Ico_union_Ico /-
-theorem Ico_subset_Ico_union_Ico {a b c : α} : Ico a c ⊆ Ico a b ∪ Ico b c :=
-  by
-  rw [← coe_subset, coe_union, coe_Ico, coe_Ico, coe_Ico]
-  exact Set.Ico_subset_Ico_union_Ico
+theorem Ico_subset_Ico_union_Ico {a b c : α} : Ico a c ⊆ Ico a b ∪ Ico b c := by
+  rw [← coe_subset, coe_union, coe_Ico, coe_Ico, coe_Ico]; exact Set.Ico_subset_Ico_union_Ico
 #align finset.Ico_subset_Ico_union_Ico Finset.Ico_subset_Ico_union_Ico
 -/
 
@@ -1406,9 +1355,7 @@ theorem Ico_filter_le (a b c : α) : ((Ico a b).filterₓ fun x => c ≤ x) = Ic
 
 #print Finset.Ioo_filter_lt /-
 @[simp]
-theorem Ioo_filter_lt (a b c : α) : (Ioo a b).filterₓ (· < c) = Ioo a (min b c) :=
-  by
-  ext
+theorem Ioo_filter_lt (a b c : α) : (Ioo a b).filterₓ (· < c) = Ioo a (min b c) := by ext;
   simp [and_assoc']
 #align finset.Ioo_filter_lt Finset.Ioo_filter_lt
 -/
@@ -1416,9 +1363,7 @@ theorem Ioo_filter_lt (a b c : α) : (Ioo a b).filterₓ (· < c) = Ioo a (min b
 #print Finset.Iio_filter_lt /-
 @[simp]
 theorem Iio_filter_lt {α} [LinearOrder α] [LocallyFiniteOrderBot α] (a b : α) :
-    (Iio a).filterₓ (· < b) = Iio (min a b) := by
-  ext
-  simp [and_assoc']
+    (Iio a).filterₓ (· < b) = Iio (min a b) := by ext; simp [and_assoc']
 #align finset.Iio_filter_lt Finset.Iio_filter_lt
 -/
 
@@ -1512,10 +1457,7 @@ variable [Fintype α] [LocallyFiniteOrderTop α] [LocallyFiniteOrderBot α]
 
 #print Finset.Ioi_disjUnion_Iio /-
 theorem Ioi_disjUnion_Iio (a : α) :
-    (Ioi a).disjUnion (Iio a) (disjoint_Ioi_Iio a) = ({a} : Finset α)ᶜ :=
-  by
-  ext
-  simp [eq_comm]
+    (Ioi a).disjUnion (Iio a) (disjoint_Ioi_Iio a) = ({a} : Finset α)ᶜ := by ext; simp [eq_comm]
 #align finset.Ioi_disj_union_Iio Finset.Ioi_disjUnion_Iio
 -/
 
@@ -1616,18 +1558,14 @@ theorem mem_uIcc_of_ge (hb : b ≤ x) (ha : x ≤ a) : x ∈ [a, b] :=
 #align finset.mem_uIcc_of_ge Finset.mem_uIcc_of_ge
 
 #print Finset.uIcc_subset_uIcc /-
-theorem uIcc_subset_uIcc (h₁ : a₁ ∈ [a₂, b₂]) (h₂ : b₁ ∈ [a₂, b₂]) : [a₁, b₁] ⊆ [a₂, b₂] :=
-  by
-  rw [mem_uIcc] at h₁ h₂
-  exact Icc_subset_Icc (le_inf h₁.1 h₂.1) (sup_le h₁.2 h₂.2)
+theorem uIcc_subset_uIcc (h₁ : a₁ ∈ [a₂, b₂]) (h₂ : b₁ ∈ [a₂, b₂]) : [a₁, b₁] ⊆ [a₂, b₂] := by
+  rw [mem_uIcc] at h₁ h₂; exact Icc_subset_Icc (le_inf h₁.1 h₂.1) (sup_le h₁.2 h₂.2)
 #align finset.uIcc_subset_uIcc Finset.uIcc_subset_uIcc
 -/
 
 #print Finset.uIcc_subset_Icc /-
-theorem uIcc_subset_Icc (ha : a₁ ∈ Icc a₂ b₂) (hb : b₁ ∈ Icc a₂ b₂) : [a₁, b₁] ⊆ Icc a₂ b₂ :=
-  by
-  rw [mem_Icc] at ha hb
-  exact Icc_subset_Icc (le_inf ha.1 hb.1) (sup_le ha.2 hb.2)
+theorem uIcc_subset_Icc (ha : a₁ ∈ Icc a₂ b₂) (hb : b₁ ∈ Icc a₂ b₂) : [a₁, b₁] ⊆ Icc a₂ b₂ := by
+  rw [mem_Icc] at ha hb; exact Icc_subset_Icc (le_inf ha.1 hb.1) (sup_le ha.2 hb.2)
 #align finset.uIcc_subset_Icc Finset.uIcc_subset_Icc
 -/
 
@@ -1666,17 +1604,13 @@ section DistribLattice
 variable [DistribLattice α] [LocallyFiniteOrder α] {a a₁ a₂ b b₁ b₂ c x : α}
 
 #print Finset.eq_of_mem_uIcc_of_mem_uIcc /-
-theorem eq_of_mem_uIcc_of_mem_uIcc : a ∈ [b, c] → b ∈ [a, c] → a = b :=
-  by
-  simp_rw [mem_uIcc]
+theorem eq_of_mem_uIcc_of_mem_uIcc : a ∈ [b, c] → b ∈ [a, c] → a = b := by simp_rw [mem_uIcc];
   exact Set.eq_of_mem_uIcc_of_mem_uIcc
 #align finset.eq_of_mem_uIcc_of_mem_uIcc Finset.eq_of_mem_uIcc_of_mem_uIcc
 -/
 
 #print Finset.eq_of_mem_uIcc_of_mem_uIcc' /-
-theorem eq_of_mem_uIcc_of_mem_uIcc' : b ∈ [a, c] → c ∈ [a, b] → b = c :=
-  by
-  simp_rw [mem_uIcc]
+theorem eq_of_mem_uIcc_of_mem_uIcc' : b ∈ [a, c] → c ∈ [a, b] → b = c := by simp_rw [mem_uIcc];
   exact Set.eq_of_mem_uIcc_of_mem_uIcc'
 #align finset.eq_of_mem_uIcc_of_mem_uIcc' Finset.eq_of_mem_uIcc_of_mem_uIcc'
 -/
@@ -1733,9 +1667,7 @@ theorem uIcc_of_not_ge (h : ¬b ≤ a) : [a, b] = Icc a b :=
 
 #print Finset.uIcc_eq_union /-
 theorem uIcc_eq_union : [a, b] = Icc a b ∪ Icc b a :=
-  coe_injective <| by
-    push_cast
-    exact Set.uIcc_eq_union
+  coe_injective <| by push_cast ; exact Set.uIcc_eq_union
 #align finset.uIcc_eq_union Finset.uIcc_eq_union
 -/
 
@@ -1754,9 +1686,7 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) c a) -> (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) c b) -> (Not (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) c (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a b)))
 Case conversion may be inaccurate. Consider using '#align finset.not_mem_uIcc_of_lt Finset.not_mem_uIcc_of_ltₓ'. -/
-theorem not_mem_uIcc_of_lt : c < a → c < b → c ∉ [a, b] :=
-  by
-  rw [mem_uIcc]
+theorem not_mem_uIcc_of_lt : c < a → c < b → c ∉ [a, b] := by rw [mem_uIcc];
   exact Set.not_mem_uIcc_of_lt
 #align finset.not_mem_uIcc_of_lt Finset.not_mem_uIcc_of_lt
 
@@ -1766,9 +1696,7 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a c) -> (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b c) -> (Not (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) c (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a b)))
 Case conversion may be inaccurate. Consider using '#align finset.not_mem_uIcc_of_gt Finset.not_mem_uIcc_of_gtₓ'. -/
-theorem not_mem_uIcc_of_gt : a < c → b < c → c ∉ [a, b] :=
-  by
-  rw [mem_uIcc]
+theorem not_mem_uIcc_of_gt : a < c → b < c → c ∉ [a, b] := by rw [mem_uIcc];
   exact Set.not_mem_uIcc_of_gt
 #align finset.not_mem_uIcc_of_gt Finset.not_mem_uIcc_of_gt
 
@@ -1786,9 +1714,7 @@ theorem uIcc_subset_uIcc_iff_le :
 #print Finset.uIcc_subset_uIcc_union_uIcc /-
 /-- A sort of triangle inequality. -/
 theorem uIcc_subset_uIcc_union_uIcc : [a, c] ⊆ [a, b] ∪ [b, c] :=
-  coe_subset.1 <| by
-    push_cast
-    exact Set.uIcc_subset_uIcc_union_uIcc
+  coe_subset.1 <| by push_cast ; exact Set.uIcc_subset_uIcc_union_uIcc
 #align finset.uIcc_subset_uIcc_union_uIcc Finset.uIcc_subset_uIcc_union_uIcc
 -/
 
@@ -1806,9 +1732,7 @@ but is expected to have type
 Case conversion may be inaccurate. Consider using '#align finset.map_add_left_Icc Finset.map_add_left_Iccₓ'. -/
 @[simp]
 theorem map_add_left_Icc (a b c : α) : (Icc a b).map (addLeftEmbedding c) = Icc (c + a) (c + b) :=
-  by
-  rw [← coe_inj, coe_map, coe_Icc, coe_Icc]
-  exact Set.image_const_add_Icc _ _ _
+  by rw [← coe_inj, coe_map, coe_Icc, coe_Icc]; exact Set.image_const_add_Icc _ _ _
 #align finset.map_add_left_Icc Finset.map_add_left_Icc
 
 /- warning: finset.map_add_right_Icc -> Finset.map_add_right_Icc is a dubious translation:
@@ -1819,9 +1743,7 @@ but is expected to have type
 Case conversion may be inaccurate. Consider using '#align finset.map_add_right_Icc Finset.map_add_right_Iccₓ'. -/
 @[simp]
 theorem map_add_right_Icc (a b c : α) : (Icc a b).map (addRightEmbedding c) = Icc (a + c) (b + c) :=
-  by
-  rw [← coe_inj, coe_map, coe_Icc, coe_Icc]
-  exact Set.image_add_const_Icc _ _ _
+  by rw [← coe_inj, coe_map, coe_Icc, coe_Icc]; exact Set.image_add_const_Icc _ _ _
 #align finset.map_add_right_Icc Finset.map_add_right_Icc
 
 /- warning: finset.map_add_left_Ico -> Finset.map_add_left_Ico is a dubious translation:
@@ -1832,9 +1754,7 @@ but is expected to have type
 Case conversion may be inaccurate. Consider using '#align finset.map_add_left_Ico Finset.map_add_left_Icoₓ'. -/
 @[simp]
 theorem map_add_left_Ico (a b c : α) : (Ico a b).map (addLeftEmbedding c) = Ico (c + a) (c + b) :=
-  by
-  rw [← coe_inj, coe_map, coe_Ico, coe_Ico]
-  exact Set.image_const_add_Ico _ _ _
+  by rw [← coe_inj, coe_map, coe_Ico, coe_Ico]; exact Set.image_const_add_Ico _ _ _
 #align finset.map_add_left_Ico Finset.map_add_left_Ico
 
 /- warning: finset.map_add_right_Ico -> Finset.map_add_right_Ico is a dubious translation:
@@ -1845,9 +1765,7 @@ but is expected to have type
 Case conversion may be inaccurate. Consider using '#align finset.map_add_right_Ico Finset.map_add_right_Icoₓ'. -/
 @[simp]
 theorem map_add_right_Ico (a b c : α) : (Ico a b).map (addRightEmbedding c) = Ico (a + c) (b + c) :=
-  by
-  rw [← coe_inj, coe_map, coe_Ico, coe_Ico]
-  exact Set.image_add_const_Ico _ _ _
+  by rw [← coe_inj, coe_map, coe_Ico, coe_Ico]; exact Set.image_add_const_Ico _ _ _
 #align finset.map_add_right_Ico Finset.map_add_right_Ico
 
 /- warning: finset.map_add_left_Ioc -> Finset.map_add_left_Ioc is a dubious translation:
@@ -1858,9 +1776,7 @@ but is expected to have type
 Case conversion may be inaccurate. Consider using '#align finset.map_add_left_Ioc Finset.map_add_left_Iocₓ'. -/
 @[simp]
 theorem map_add_left_Ioc (a b c : α) : (Ioc a b).map (addLeftEmbedding c) = Ioc (c + a) (c + b) :=
-  by
-  rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]
-  exact Set.image_const_add_Ioc _ _ _
+  by rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]; exact Set.image_const_add_Ioc _ _ _
 #align finset.map_add_left_Ioc Finset.map_add_left_Ioc
 
 /- warning: finset.map_add_right_Ioc -> Finset.map_add_right_Ioc is a dubious translation:
@@ -1871,9 +1787,7 @@ but is expected to have type
 Case conversion may be inaccurate. Consider using '#align finset.map_add_right_Ioc Finset.map_add_right_Iocₓ'. -/
 @[simp]
 theorem map_add_right_Ioc (a b c : α) : (Ioc a b).map (addRightEmbedding c) = Ioc (a + c) (b + c) :=
-  by
-  rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]
-  exact Set.image_add_const_Ioc _ _ _
+  by rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]; exact Set.image_add_const_Ioc _ _ _
 #align finset.map_add_right_Ioc Finset.map_add_right_Ioc
 
 /- warning: finset.map_add_left_Ioo -> Finset.map_add_left_Ioo is a dubious translation:
@@ -1884,9 +1798,7 @@ but is expected to have type
 Case conversion may be inaccurate. Consider using '#align finset.map_add_left_Ioo Finset.map_add_left_Iooₓ'. -/
 @[simp]
 theorem map_add_left_Ioo (a b c : α) : (Ioo a b).map (addLeftEmbedding c) = Ioo (c + a) (c + b) :=
-  by
-  rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]
-  exact Set.image_const_add_Ioo _ _ _
+  by rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]; exact Set.image_const_add_Ioo _ _ _
 #align finset.map_add_left_Ioo Finset.map_add_left_Ioo
 
 /- warning: finset.map_add_right_Ioo -> Finset.map_add_right_Ioo is a dubious translation:
@@ -1897,9 +1809,7 @@ but is expected to have type
 Case conversion may be inaccurate. Consider using '#align finset.map_add_right_Ioo Finset.map_add_right_Iooₓ'. -/
 @[simp]
 theorem map_add_right_Ioo (a b c : α) : (Ioo a b).map (addRightEmbedding c) = Ioo (a + c) (b + c) :=
-  by
-  rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]
-  exact Set.image_add_const_Ioo _ _ _
+  by rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]; exact Set.image_add_const_Ioo _ _ _
 #align finset.map_add_right_Ioo Finset.map_add_right_Ioo
 
 variable [DecidableEq α]
@@ -1911,10 +1821,8 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11216 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11218 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11216 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11218) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Icc Finset.image_add_left_Iccₓ'. -/
 @[simp]
-theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) :=
-  by
-  rw [← map_add_left_Icc, map_eq_image]
-  rfl
+theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) := by
+  rw [← map_add_left_Icc, map_eq_image]; rfl
 #align finset.image_add_left_Icc Finset.image_add_left_Icc
 
 /- warning: finset.image_add_left_Ico -> Finset.image_add_left_Ico is a dubious translation:
@@ -1924,10 +1832,8 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11317 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11319 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11317 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11319) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ico Finset.image_add_left_Icoₓ'. -/
 @[simp]
-theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) :=
-  by
-  rw [← map_add_left_Ico, map_eq_image]
-  rfl
+theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) := by
+  rw [← map_add_left_Ico, map_eq_image]; rfl
 #align finset.image_add_left_Ico Finset.image_add_left_Ico
 
 /- warning: finset.image_add_left_Ioc -> Finset.image_add_left_Ioc is a dubious translation:
@@ -1937,10 +1843,8 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11418 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11420 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11418 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11420) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioc Finset.image_add_left_Iocₓ'. -/
 @[simp]
-theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) :=
-  by
-  rw [← map_add_left_Ioc, map_eq_image]
-  rfl
+theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) := by
+  rw [← map_add_left_Ioc, map_eq_image]; rfl
 #align finset.image_add_left_Ioc Finset.image_add_left_Ioc
 
 /- warning: finset.image_add_left_Ioo -> Finset.image_add_left_Ioo is a dubious translation:
@@ -1950,10 +1854,8 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11519 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11521 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11519 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11521) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioo Finset.image_add_left_Iooₓ'. -/
 @[simp]
-theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) :=
-  by
-  rw [← map_add_left_Ioo, map_eq_image]
-  rfl
+theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) := by
+  rw [← map_add_left_Ioo, map_eq_image]; rfl
 #align finset.image_add_left_Ioo Finset.image_add_left_Ioo
 
 /- warning: finset.image_add_right_Icc -> Finset.image_add_right_Icc is a dubious translation:
@@ -1963,10 +1865,8 @@ but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Icc Finset.image_add_right_Iccₓ'. -/
 @[simp]
-theorem image_add_right_Icc (a b c : α) : (Icc a b).image (· + c) = Icc (a + c) (b + c) :=
-  by
-  rw [← map_add_right_Icc, map_eq_image]
-  rfl
+theorem image_add_right_Icc (a b c : α) : (Icc a b).image (· + c) = Icc (a + c) (b + c) := by
+  rw [← map_add_right_Icc, map_eq_image]; rfl
 #align finset.image_add_right_Icc Finset.image_add_right_Icc
 
 /- warning: finset.image_add_right_Ico -> Finset.image_add_right_Ico is a dubious translation:
@@ -1975,10 +1875,8 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Ico Finset.image_add_right_Icoₓ'. -/
-theorem image_add_right_Ico (a b c : α) : (Ico a b).image (· + c) = Ico (a + c) (b + c) :=
-  by
-  rw [← map_add_right_Ico, map_eq_image]
-  rfl
+theorem image_add_right_Ico (a b c : α) : (Ico a b).image (· + c) = Ico (a + c) (b + c) := by
+  rw [← map_add_right_Ico, map_eq_image]; rfl
 #align finset.image_add_right_Ico Finset.image_add_right_Ico
 
 /- warning: finset.image_add_right_Ioc -> Finset.image_add_right_Ioc is a dubious translation:
@@ -1987,10 +1885,8 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Ioc Finset.image_add_right_Iocₓ'. -/
-theorem image_add_right_Ioc (a b c : α) : (Ioc a b).image (· + c) = Ioc (a + c) (b + c) :=
-  by
-  rw [← map_add_right_Ioc, map_eq_image]
-  rfl
+theorem image_add_right_Ioc (a b c : α) : (Ioc a b).image (· + c) = Ioc (a + c) (b + c) := by
+  rw [← map_add_right_Ioc, map_eq_image]; rfl
 #align finset.image_add_right_Ioc Finset.image_add_right_Ioc
 
 /- warning: finset.image_add_right_Ioo -> Finset.image_add_right_Ioo is a dubious translation:
@@ -1999,10 +1895,8 @@ lean 3 declaration is
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Ioo Finset.image_add_right_Iooₓ'. -/
-theorem image_add_right_Ioo (a b c : α) : (Ioo a b).image (· + c) = Ioo (a + c) (b + c) :=
-  by
-  rw [← map_add_right_Ioo, map_eq_image]
-  rfl
+theorem image_add_right_Ioo (a b c : α) : (Ioo a b).image (· + c) = Ioo (a + c) (b + c) := by
+  rw [← map_add_right_Ioo, map_eq_image]; rfl
 #align finset.image_add_right_Ioo Finset.image_add_right_Ioo
 
 end OrderedCancelAddCommMonoid

bump to nightly-2023-05-16-16

mathlib commit https://github.com/leanprover-community/mathlib/commit/0b9eaaa7686280fad8cce467f5c3c57ee6ce77f8

9cb92e8c

Diff

@@ -48,129 +48,215 @@ section LocallyFiniteOrder
 
 variable [LocallyFiniteOrder α] {a a₁ a₂ b b₁ b₂ c x : α}
 
-#print Finset.nonempty_Icc /-
+/- warning: finset.nonempty_Icc -> Finset.nonempty_Icc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Finset.Nonempty.{u1} α (Finset.Icc.{u1} α _inst_1 _inst_2 a b)) (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Finset.Nonempty.{u1} α (Finset.Icc.{u1} α _inst_1 _inst_2 a b)) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a b)
+Case conversion may be inaccurate. Consider using '#align finset.nonempty_Icc Finset.nonempty_Iccₓ'. -/
 @[simp]
 theorem nonempty_Icc : (Icc a b).Nonempty ↔ a ≤ b := by
   rw [← coe_nonempty, coe_Icc, Set.nonempty_Icc]
 #align finset.nonempty_Icc Finset.nonempty_Icc
--/
 
-#print Finset.nonempty_Ico /-
+/- warning: finset.nonempty_Ico -> Finset.nonempty_Ico is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Finset.Nonempty.{u1} α (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Finset.Nonempty.{u1} α (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b)
+Case conversion may be inaccurate. Consider using '#align finset.nonempty_Ico Finset.nonempty_Icoₓ'. -/
 @[simp]
 theorem nonempty_Ico : (Ico a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ico, Set.nonempty_Ico]
 #align finset.nonempty_Ico Finset.nonempty_Ico
--/
 
-#print Finset.nonempty_Ioc /-
+/- warning: finset.nonempty_Ioc -> Finset.nonempty_Ioc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Finset.Nonempty.{u1} α (Finset.Ioc.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Finset.Nonempty.{u1} α (Finset.Ioc.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b)
+Case conversion may be inaccurate. Consider using '#align finset.nonempty_Ioc Finset.nonempty_Iocₓ'. -/
 @[simp]
 theorem nonempty_Ioc : (Ioc a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioc, Set.nonempty_Ioc]
 #align finset.nonempty_Ioc Finset.nonempty_Ioc
--/
 
-#print Finset.nonempty_Ioo /-
+/- warning: finset.nonempty_Ioo -> Finset.nonempty_Ioo is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} [_inst_3 : DenselyOrdered.{u1} α (Preorder.toHasLt.{u1} α _inst_1)], Iff (Finset.Nonempty.{u1} α (Finset.Ioo.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} [_inst_3 : DenselyOrdered.{u1} α (Preorder.toLT.{u1} α _inst_1)], Iff (Finset.Nonempty.{u1} α (Finset.Ioo.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b)
+Case conversion may be inaccurate. Consider using '#align finset.nonempty_Ioo Finset.nonempty_Iooₓ'. -/
 @[simp]
 theorem nonempty_Ioo [DenselyOrdered α] : (Ioo a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioo, Set.nonempty_Ioo]
 #align finset.nonempty_Ioo Finset.nonempty_Ioo
--/
 
-#print Finset.Icc_eq_empty_iff /-
+/- warning: finset.Icc_eq_empty_iff -> Finset.Icc_eq_empty_iff is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α))) (Not (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α))) (Not (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a b))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_eq_empty_iff Finset.Icc_eq_empty_iffₓ'. -/
 @[simp]
 theorem Icc_eq_empty_iff : Icc a b = ∅ ↔ ¬a ≤ b := by
   rw [← coe_eq_empty, coe_Icc, Set.Icc_eq_empty_iff]
 #align finset.Icc_eq_empty_iff Finset.Icc_eq_empty_iff
--/
 
-#print Finset.Ico_eq_empty_iff /-
+/- warning: finset.Ico_eq_empty_iff -> Finset.Ico_eq_empty_iff is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Eq.{succ u1} (Finset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α))) (Not (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Eq.{succ u1} (Finset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α))) (Not (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_eq_empty_iff Finset.Ico_eq_empty_iffₓ'. -/
 @[simp]
 theorem Ico_eq_empty_iff : Ico a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ico, Set.Ico_eq_empty_iff]
 #align finset.Ico_eq_empty_iff Finset.Ico_eq_empty_iff
--/
 
-#print Finset.Ioc_eq_empty_iff /-
+/- warning: finset.Ioc_eq_empty_iff -> Finset.Ioc_eq_empty_iff is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α))) (Not (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α))) (Not (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_eq_empty_iff Finset.Ioc_eq_empty_iffₓ'. -/
 @[simp]
 theorem Ioc_eq_empty_iff : Ioc a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ioc, Set.Ioc_eq_empty_iff]
 #align finset.Ioc_eq_empty_iff Finset.Ioc_eq_empty_iff
--/
 
-#print Finset.Ioo_eq_empty_iff /-
+/- warning: finset.Ioo_eq_empty_iff -> Finset.Ioo_eq_empty_iff is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} [_inst_3 : DenselyOrdered.{u1} α (Preorder.toHasLt.{u1} α _inst_1)], Iff (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α))) (Not (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} [_inst_3 : DenselyOrdered.{u1} α (Preorder.toLT.{u1} α _inst_1)], Iff (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α))) (Not (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ioo_eq_empty_iff Finset.Ioo_eq_empty_iffₓ'. -/
 @[simp]
 theorem Ioo_eq_empty_iff [DenselyOrdered α] : Ioo a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ioo, Set.Ioo_eq_empty_iff]
 #align finset.Ioo_eq_empty_iff Finset.Ioo_eq_empty_iff
--/
 
+/- warning: finset.Icc_eq_empty -> Finset.Icc_eq_empty is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (Not (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (Not (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α)))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_eq_empty Finset.Icc_eq_emptyₓ'. -/
 alias Icc_eq_empty_iff ↔ _ Icc_eq_empty
 #align finset.Icc_eq_empty Finset.Icc_eq_empty
 
+/- warning: finset.Ico_eq_empty -> Finset.Ico_eq_empty is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (Not (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (Not (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α)))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_eq_empty Finset.Ico_eq_emptyₓ'. -/
 alias Ico_eq_empty_iff ↔ _ Ico_eq_empty
 #align finset.Ico_eq_empty Finset.Ico_eq_empty
 
+/- warning: finset.Ioc_eq_empty -> Finset.Ioc_eq_empty is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (Not (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (Not (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α)))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_eq_empty Finset.Ioc_eq_emptyₓ'. -/
 alias Ioc_eq_empty_iff ↔ _ Ioc_eq_empty
 #align finset.Ioc_eq_empty Finset.Ioc_eq_empty
 
-#print Finset.Ioo_eq_empty /-
+/- warning: finset.Ioo_eq_empty -> Finset.Ioo_eq_empty is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (Not (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (Not (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α)))
+Case conversion may be inaccurate. Consider using '#align finset.Ioo_eq_empty Finset.Ioo_eq_emptyₓ'. -/
 @[simp]
 theorem Ioo_eq_empty (h : ¬a < b) : Ioo a b = ∅ :=
   eq_empty_iff_forall_not_mem.2 fun x hx => h ((mem_Ioo.1 hx).1.trans (mem_Ioo.1 hx).2)
 #align finset.Ioo_eq_empty Finset.Ioo_eq_empty
--/
 
-#print Finset.Icc_eq_empty_of_lt /-
+/- warning: finset.Icc_eq_empty_of_lt -> Finset.Icc_eq_empty_of_lt is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α)))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_eq_empty_of_lt Finset.Icc_eq_empty_of_ltₓ'. -/
 @[simp]
 theorem Icc_eq_empty_of_lt (h : b < a) : Icc a b = ∅ :=
   Icc_eq_empty h.not_le
 #align finset.Icc_eq_empty_of_lt Finset.Icc_eq_empty_of_lt
--/
 
-#print Finset.Ico_eq_empty_of_le /-
+/- warning: finset.Ico_eq_empty_of_le -> Finset.Ico_eq_empty_of_le is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α)))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_eq_empty_of_le Finset.Ico_eq_empty_of_leₓ'. -/
 @[simp]
 theorem Ico_eq_empty_of_le (h : b ≤ a) : Ico a b = ∅ :=
   Ico_eq_empty h.not_lt
 #align finset.Ico_eq_empty_of_le Finset.Ico_eq_empty_of_le
--/
 
-#print Finset.Ioc_eq_empty_of_le /-
+/- warning: finset.Ioc_eq_empty_of_le -> Finset.Ioc_eq_empty_of_le is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α)))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_eq_empty_of_le Finset.Ioc_eq_empty_of_leₓ'. -/
 @[simp]
 theorem Ioc_eq_empty_of_le (h : b ≤ a) : Ioc a b = ∅ :=
   Ioc_eq_empty h.not_lt
 #align finset.Ioc_eq_empty_of_le Finset.Ioc_eq_empty_of_le
--/
 
-#print Finset.Ioo_eq_empty_of_le /-
+/- warning: finset.Ioo_eq_empty_of_le -> Finset.Ioo_eq_empty_of_le is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α)))
+Case conversion may be inaccurate. Consider using '#align finset.Ioo_eq_empty_of_le Finset.Ioo_eq_empty_of_leₓ'. -/
 @[simp]
 theorem Ioo_eq_empty_of_le (h : b ≤ a) : Ioo a b = ∅ :=
   Ioo_eq_empty h.not_lt
 #align finset.Ioo_eq_empty_of_le Finset.Ioo_eq_empty_of_le
--/
 
-#print Finset.left_mem_Icc /-
+/- warning: finset.left_mem_Icc -> Finset.left_mem_Icc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Membership.Mem.{u1, u1} α (Finset.{u1} α) (Finset.hasMem.{u1} α) a (Finset.Icc.{u1} α _inst_1 _inst_2 a b)) (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) a (Finset.Icc.{u1} α _inst_1 _inst_2 a b)) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a b)
+Case conversion may be inaccurate. Consider using '#align finset.left_mem_Icc Finset.left_mem_Iccₓ'. -/
 @[simp]
 theorem left_mem_Icc : a ∈ Icc a b ↔ a ≤ b := by simp only [mem_Icc, true_and_iff, le_rfl]
 #align finset.left_mem_Icc Finset.left_mem_Icc
--/
 
-#print Finset.left_mem_Ico /-
+/- warning: finset.left_mem_Ico -> Finset.left_mem_Ico is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Membership.Mem.{u1, u1} α (Finset.{u1} α) (Finset.hasMem.{u1} α) a (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) a (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b)
+Case conversion may be inaccurate. Consider using '#align finset.left_mem_Ico Finset.left_mem_Icoₓ'. -/
 @[simp]
 theorem left_mem_Ico : a ∈ Ico a b ↔ a < b := by simp only [mem_Ico, true_and_iff, le_refl]
 #align finset.left_mem_Ico Finset.left_mem_Ico
--/
 
-#print Finset.right_mem_Icc /-
+/- warning: finset.right_mem_Icc -> Finset.right_mem_Icc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Membership.Mem.{u1, u1} α (Finset.{u1} α) (Finset.hasMem.{u1} α) b (Finset.Icc.{u1} α _inst_1 _inst_2 a b)) (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) b (Finset.Icc.{u1} α _inst_1 _inst_2 a b)) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a b)
+Case conversion may be inaccurate. Consider using '#align finset.right_mem_Icc Finset.right_mem_Iccₓ'. -/
 @[simp]
 theorem right_mem_Icc : b ∈ Icc a b ↔ a ≤ b := by simp only [mem_Icc, and_true_iff, le_rfl]
 #align finset.right_mem_Icc Finset.right_mem_Icc
--/
 
-#print Finset.right_mem_Ioc /-
+/- warning: finset.right_mem_Ioc -> Finset.right_mem_Ioc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Membership.Mem.{u1, u1} α (Finset.{u1} α) (Finset.hasMem.{u1} α) b (Finset.Ioc.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α}, Iff (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) b (Finset.Ioc.{u1} α _inst_1 _inst_2 a b)) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a b)
+Case conversion may be inaccurate. Consider using '#align finset.right_mem_Ioc Finset.right_mem_Iocₓ'. -/
 @[simp]
 theorem right_mem_Ioc : b ∈ Ioc a b ↔ a < b := by simp only [mem_Ioc, and_true_iff, le_rfl]
 #align finset.right_mem_Ioc Finset.right_mem_Ioc
--/
 
 #print Finset.left_not_mem_Ioc /-
 @[simp]
@@ -196,101 +282,161 @@ theorem right_not_mem_Ioo : b ∉ Ioo a b := fun h => lt_irrefl _ (mem_Ioo.1 h).
 #align finset.right_not_mem_Ioo Finset.right_not_mem_Ioo
 -/
 
-#print Finset.Icc_subset_Icc /-
+/- warning: finset.Icc_subset_Icc -> Finset.Icc_subset_Icc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Icc Finset.Icc_subset_Iccₓ'. -/
 theorem Icc_subset_Icc (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Icc a₁ b₁ ⊆ Icc a₂ b₂ := by
   simpa [← coe_subset] using Set.Icc_subset_Icc ha hb
 #align finset.Icc_subset_Icc Finset.Icc_subset_Icc
--/
 
-#print Finset.Ico_subset_Ico /-
+/- warning: finset.Ico_subset_Ico -> Finset.Ico_subset_Ico is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ico.{u1} α _inst_1 _inst_2 a₂ b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ico.{u1} α _inst_1 _inst_2 a₂ b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_subset_Ico Finset.Ico_subset_Icoₓ'. -/
 theorem Ico_subset_Ico (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Ico a₁ b₁ ⊆ Ico a₂ b₂ := by
   simpa [← coe_subset] using Set.Ico_subset_Ico ha hb
 #align finset.Ico_subset_Ico Finset.Ico_subset_Ico
--/
 
-#print Finset.Ioc_subset_Ioc /-
+/- warning: finset.Ioc_subset_Ioc -> Finset.Ioc_subset_Ioc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₂ b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₂ b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_subset_Ioc Finset.Ioc_subset_Iocₓ'. -/
 theorem Ioc_subset_Ioc (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Ioc a₁ b₁ ⊆ Ioc a₂ b₂ := by
   simpa [← coe_subset] using Set.Ioc_subset_Ioc ha hb
 #align finset.Ioc_subset_Ioc Finset.Ioc_subset_Ioc
--/
 
-#print Finset.Ioo_subset_Ioo /-
+/- warning: finset.Ioo_subset_Ioo -> Finset.Ioo_subset_Ioo is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₂ b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₂ b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Ioo_subset_Ioo Finset.Ioo_subset_Iooₓ'. -/
 theorem Ioo_subset_Ioo (ha : a₂ ≤ a₁) (hb : b₁ ≤ b₂) : Ioo a₁ b₁ ⊆ Ioo a₂ b₂ := by
   simpa [← coe_subset] using Set.Ioo_subset_Ioo ha hb
 #align finset.Ioo_subset_Ioo Finset.Ioo_subset_Ioo
--/
 
-#print Finset.Icc_subset_Icc_left /-
+/- warning: finset.Icc_subset_Icc_left -> Finset.Icc_subset_Icc_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Icc_left Finset.Icc_subset_Icc_leftₓ'. -/
 theorem Icc_subset_Icc_left (h : a₁ ≤ a₂) : Icc a₂ b ⊆ Icc a₁ b :=
   Icc_subset_Icc h le_rfl
 #align finset.Icc_subset_Icc_left Finset.Icc_subset_Icc_left
--/
 
-#print Finset.Ico_subset_Ico_left /-
+/- warning: finset.Ico_subset_Ico_left -> Finset.Ico_subset_Ico_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Ico.{u1} α _inst_1 _inst_2 a₁ b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Ico.{u1} α _inst_1 _inst_2 a₁ b))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_subset_Ico_left Finset.Ico_subset_Ico_leftₓ'. -/
 theorem Ico_subset_Ico_left (h : a₁ ≤ a₂) : Ico a₂ b ⊆ Ico a₁ b :=
   Ico_subset_Ico h le_rfl
 #align finset.Ico_subset_Ico_left Finset.Ico_subset_Ico_left
--/
 
-#print Finset.Ioc_subset_Ioc_left /-
+/- warning: finset.Ioc_subset_Ioc_left -> Finset.Ioc_subset_Ioc_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₁ b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₁ b))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_subset_Ioc_left Finset.Ioc_subset_Ioc_leftₓ'. -/
 theorem Ioc_subset_Ioc_left (h : a₁ ≤ a₂) : Ioc a₂ b ⊆ Ioc a₁ b :=
   Ioc_subset_Ioc h le_rfl
 #align finset.Ioc_subset_Ioc_left Finset.Ioc_subset_Ioc_left
--/
 
-#print Finset.Ioo_subset_Ioo_left /-
+/- warning: finset.Ioo_subset_Ioo_left -> Finset.Ioo_subset_Ioo_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₁ b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₁ b))
+Case conversion may be inaccurate. Consider using '#align finset.Ioo_subset_Ioo_left Finset.Ioo_subset_Ioo_leftₓ'. -/
 theorem Ioo_subset_Ioo_left (h : a₁ ≤ a₂) : Ioo a₂ b ⊆ Ioo a₁ b :=
   Ioo_subset_Ioo h le_rfl
 #align finset.Ioo_subset_Ioo_left Finset.Ioo_subset_Ioo_left
--/
 
-#print Finset.Icc_subset_Icc_right /-
+/- warning: finset.Icc_subset_Icc_right -> Finset.Icc_subset_Icc_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Icc_right Finset.Icc_subset_Icc_rightₓ'. -/
 theorem Icc_subset_Icc_right (h : b₁ ≤ b₂) : Icc a b₁ ⊆ Icc a b₂ :=
   Icc_subset_Icc le_rfl h
 #align finset.Icc_subset_Icc_right Finset.Icc_subset_Icc_right
--/
 
-#print Finset.Ico_subset_Ico_right /-
+/- warning: finset.Ico_subset_Ico_right -> Finset.Ico_subset_Ico_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ico.{u1} α _inst_1 _inst_2 a b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ico.{u1} α _inst_1 _inst_2 a b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_subset_Ico_right Finset.Ico_subset_Ico_rightₓ'. -/
 theorem Ico_subset_Ico_right (h : b₁ ≤ b₂) : Ico a b₁ ⊆ Ico a b₂ :=
   Ico_subset_Ico le_rfl h
 #align finset.Ico_subset_Ico_right Finset.Ico_subset_Ico_right
--/
 
-#print Finset.Ioc_subset_Ioc_right /-
+/- warning: finset.Ioc_subset_Ioc_right -> Finset.Ioc_subset_Ioc_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_subset_Ioc_right Finset.Ioc_subset_Ioc_rightₓ'. -/
 theorem Ioc_subset_Ioc_right (h : b₁ ≤ b₂) : Ioc a b₁ ⊆ Ioc a b₂ :=
   Ioc_subset_Ioc le_rfl h
 #align finset.Ioc_subset_Ioc_right Finset.Ioc_subset_Ioc_right
--/
 
-#print Finset.Ioo_subset_Ioo_right /-
+/- warning: finset.Ioo_subset_Ioo_right -> Finset.Ioo_subset_Ioo_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Ioo_subset_Ioo_right Finset.Ioo_subset_Ioo_rightₓ'. -/
 theorem Ioo_subset_Ioo_right (h : b₁ ≤ b₂) : Ioo a b₁ ⊆ Ioo a b₂ :=
   Ioo_subset_Ioo le_rfl h
 #align finset.Ioo_subset_Ioo_right Finset.Ioo_subset_Ioo_right
--/
 
-#print Finset.Ico_subset_Ioo_left /-
+/- warning: finset.Ico_subset_Ioo_left -> Finset.Ico_subset_Ioo_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₁ b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a₁ a₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ico.{u1} α _inst_1 _inst_2 a₂ b) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₁ b))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_subset_Ioo_left Finset.Ico_subset_Ioo_leftₓ'. -/
 theorem Ico_subset_Ioo_left (h : a₁ < a₂) : Ico a₂ b ⊆ Ioo a₁ b :=
   by
   rw [← coe_subset, coe_Ico, coe_Ioo]
   exact Set.Ico_subset_Ioo_left h
 #align finset.Ico_subset_Ioo_left Finset.Ico_subset_Ioo_left
--/
 
-#print Finset.Ioc_subset_Ioo_right /-
+/- warning: finset.Ioc_subset_Ioo_right -> Finset.Ioc_subset_Ioo_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_subset_Ioo_right Finset.Ioc_subset_Ioo_rightₓ'. -/
 theorem Ioc_subset_Ioo_right (h : b₁ < b₂) : Ioc a b₁ ⊆ Ioo a b₂ :=
   by
   rw [← coe_subset, coe_Ioc, coe_Ioo]
   exact Set.Ioc_subset_Ioo_right h
 #align finset.Ioc_subset_Ioo_right Finset.Ioc_subset_Ioo_right
--/
 
-#print Finset.Icc_subset_Ico_right /-
+/- warning: finset.Icc_subset_Ico_right -> Finset.Icc_subset_Ico_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ico.{u1} α _inst_1 _inst_2 a b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b₁ : α} {b₂ : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b₁ b₂) -> (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a b₁) (Finset.Ico.{u1} α _inst_1 _inst_2 a b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Ico_right Finset.Icc_subset_Ico_rightₓ'. -/
 theorem Icc_subset_Ico_right (h : b₁ < b₂) : Icc a b₁ ⊆ Ico a b₂ :=
   by
   rw [← coe_subset, coe_Icc, coe_Ico]
   exact Set.Icc_subset_Ico_right h
 #align finset.Icc_subset_Ico_right Finset.Icc_subset_Ico_right
--/
 
 #print Finset.Ioo_subset_Ico_self /-
 theorem Ioo_subset_Ico_self : Ioo a b ⊆ Ico a b :=
@@ -330,46 +476,70 @@ theorem Ioo_subset_Icc_self : Ioo a b ⊆ Icc a b :=
 #align finset.Ioo_subset_Icc_self Finset.Ioo_subset_Icc_self
 -/
 
-#print Finset.Icc_subset_Icc_iff /-
+/- warning: finset.Icc_subset_Icc_iff -> Finset.Icc_subset_Icc_iff is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₂ a₁) (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ a₁) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂)))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Icc_iff Finset.Icc_subset_Icc_iffₓ'. -/
 theorem Icc_subset_Icc_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Icc a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ ≤ b₂ := by
   rw [← coe_subset, coe_Icc, coe_Icc, Set.Icc_subset_Icc_iff h₁]
 #align finset.Icc_subset_Icc_iff Finset.Icc_subset_Icc_iff
--/
 
-#print Finset.Icc_subset_Ioo_iff /-
+/- warning: finset.Icc_subset_Ioo_iff -> Finset.Icc_subset_Ioo_iff is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a₂ a₁) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) b₁ b₂)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ioo.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a₂ a₁) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b₁ b₂)))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Ioo_iff Finset.Icc_subset_Ioo_iffₓ'. -/
 theorem Icc_subset_Ioo_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioo a₂ b₂ ↔ a₂ < a₁ ∧ b₁ < b₂ := by
   rw [← coe_subset, coe_Icc, coe_Ioo, Set.Icc_subset_Ioo_iff h₁]
 #align finset.Icc_subset_Ioo_iff Finset.Icc_subset_Ioo_iff
--/
 
-#print Finset.Icc_subset_Ico_iff /-
+/- warning: finset.Icc_subset_Ico_iff -> Finset.Icc_subset_Ico_iff is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ico.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₂ a₁) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) b₁ b₂)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ico.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ a₁) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b₁ b₂)))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Ico_iff Finset.Icc_subset_Ico_iffₓ'. -/
 theorem Icc_subset_Ico_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ico a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ < b₂ := by
   rw [← coe_subset, coe_Icc, coe_Ico, Set.Icc_subset_Ico_iff h₁]
 #align finset.Icc_subset_Ico_iff Finset.Icc_subset_Ico_iff
--/
 
-#print Finset.Icc_subset_Ioc_iff /-
+/- warning: finset.Icc_subset_Ioc_iff -> Finset.Icc_subset_Ioc_iff is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a₂ a₁) (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Ioc.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a₂ a₁) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂)))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_subset_Ioc_iff Finset.Icc_subset_Ioc_iffₓ'. -/
 theorem Icc_subset_Ioc_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioc a₂ b₂ ↔ a₂ < a₁ ∧ b₁ ≤ b₂ :=
   (Icc_subset_Ico_iff h₁.dual).trans and_comm
 #align finset.Icc_subset_Ioc_iff Finset.Icc_subset_Ioc_iff
--/
 
-#print Finset.Icc_ssubset_Icc_left /-
+/- warning: finset.Icc_ssubset_Icc_left -> Finset.Icc_ssubset_Icc_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₂ b₂) -> (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b₁ b₂) -> (HasSSubset.SSubset.{u1} (Finset.{u1} α) (Finset.hasSsubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ b₂) -> (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a₂ a₁) -> (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b₁ b₂) -> (HasSSubset.SSubset.{u1} (Finset.{u1} α) (Finset.instHasSSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_ssubset_Icc_left Finset.Icc_ssubset_Icc_leftₓ'. -/
 --TODO: `Ico_subset_Ioo_iff`, `Ioc_subset_Ioo_iff`
 theorem Icc_ssubset_Icc_left (hI : a₂ ≤ b₂) (ha : a₂ < a₁) (hb : b₁ ≤ b₂) : Icc a₁ b₁ ⊂ Icc a₂ b₂ :=
   by
   rw [← coe_ssubset, coe_Icc, coe_Icc]
   exact Set.Icc_ssubset_Icc_left hI ha hb
 #align finset.Icc_ssubset_Icc_left Finset.Icc_ssubset_Icc_left
--/
 
-#print Finset.Icc_ssubset_Icc_right /-
+/- warning: finset.Icc_ssubset_Icc_right -> Finset.Icc_ssubset_Icc_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₂ b₂) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a₂ a₁) -> (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) b₁ b₂) -> (HasSSubset.SSubset.{u1} (Finset.{u1} α) (Finset.hasSsubset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b₂))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ b₂) -> (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a₂ a₁) -> (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b₁ b₂) -> (HasSSubset.SSubset.{u1} (Finset.{u1} α) (Finset.instHasSSubsetFinset.{u1} α) (Finset.Icc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.Icc.{u1} α _inst_1 _inst_2 a₂ b₂))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_ssubset_Icc_right Finset.Icc_ssubset_Icc_rightₓ'. -/
 theorem Icc_ssubset_Icc_right (hI : a₂ ≤ b₂) (ha : a₂ ≤ a₁) (hb : b₁ < b₂) :
     Icc a₁ b₁ ⊂ Icc a₂ b₂ := by
   rw [← coe_ssubset, coe_Icc, coe_Icc]
   exact Set.Icc_ssubset_Icc_right hI ha hb
 #align finset.Icc_ssubset_Icc_right Finset.Icc_ssubset_Icc_right
--/
 
 variable (a)
 
@@ -415,110 +585,162 @@ theorem BddBelow.finite_of_bddAbove {s : Set α} (h₀ : BddBelow s) (h₁ : Bdd
 
 section Filter
 
-#print Finset.Ico_filter_lt_of_le_left /-
+/- warning: finset.Ico_filter_lt_of_le_left -> Finset.Ico_filter_lt_of_le_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c)], (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) c a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c)], (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) c a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α)))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_filter_lt_of_le_left Finset.Ico_filter_lt_of_le_leftₓ'. -/
 theorem Ico_filter_lt_of_le_left [DecidablePred (· < c)] (hca : c ≤ a) :
     (Ico a b).filterₓ (· < c) = ∅ :=
   filter_false_of_mem fun x hx => (hca.trans (mem_Ico.1 hx).1).not_lt
 #align finset.Ico_filter_lt_of_le_left Finset.Ico_filter_lt_of_le_left
--/
 
-#print Finset.Ico_filter_lt_of_right_le /-
+/- warning: finset.Ico_filter_lt_of_right_le -> Finset.Ico_filter_lt_of_right_le is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c)], (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (Finset.Ico.{u1} α _inst_1 _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c)], (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (Finset.Ico.{u1} α _inst_1 _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_filter_lt_of_right_le Finset.Ico_filter_lt_of_right_leₓ'. -/
 theorem Ico_filter_lt_of_right_le [DecidablePred (· < c)] (hbc : b ≤ c) :
     (Ico a b).filterₓ (· < c) = Ico a b :=
   filter_true_of_mem fun x hx => (mem_Ico.1 hx).2.trans_le hbc
 #align finset.Ico_filter_lt_of_right_le Finset.Ico_filter_lt_of_right_le
--/
 
-#print Finset.Ico_filter_lt_of_le_right /-
+/- warning: finset.Ico_filter_lt_of_le_right -> Finset.Ico_filter_lt_of_le_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c)], (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) c b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (Finset.Ico.{u1} α _inst_1 _inst_2 a c))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c)], (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) c b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (Finset.Ico.{u1} α _inst_1 _inst_2 a c))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_filter_lt_of_le_right Finset.Ico_filter_lt_of_le_rightₓ'. -/
 theorem Ico_filter_lt_of_le_right [DecidablePred (· < c)] (hcb : c ≤ b) :
     (Ico a b).filterₓ (· < c) = Ico a c := by
   ext x
   rw [mem_filter, mem_Ico, mem_Ico, and_right_comm]
   exact and_iff_left_of_imp fun h => h.2.trans_le hcb
 #align finset.Ico_filter_lt_of_le_right Finset.Ico_filter_lt_of_le_right
--/
 
-#print Finset.Ico_filter_le_of_le_left /-
+/- warning: finset.Ico_filter_le_of_le_left -> Finset.Ico_filter_le_of_le_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) c)], (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) c a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (Finset.Ico.{u1} α _inst_1 _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3053 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3055 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3053 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3055) c)], (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) c a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3086 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3088 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3086 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3088) c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (Finset.Ico.{u1} α _inst_1 _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_filter_le_of_le_left Finset.Ico_filter_le_of_le_leftₓ'. -/
 theorem Ico_filter_le_of_le_left {a b c : α} [DecidablePred ((· ≤ ·) c)] (hca : c ≤ a) :
     (Ico a b).filterₓ ((· ≤ ·) c) = Ico a b :=
   filter_true_of_mem fun x hx => hca.trans (mem_Ico.1 hx).1
 #align finset.Ico_filter_le_of_le_left Finset.Ico_filter_le_of_le_left
--/
 
-#print Finset.Ico_filter_le_of_right_le /-
+/- warning: finset.Ico_filter_le_of_right_le -> Finset.Ico_filter_le_of_right_le is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} [_inst_3 : DecidablePred.{succ u1} α (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) b) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.hasEmptyc.{u1} α))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} [_inst_3 : DecidablePred.{succ u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3142 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3144 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3142 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3144) b)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3170 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3172 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3170 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3172) b) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (EmptyCollection.emptyCollection.{u1} (Finset.{u1} α) (Finset.instEmptyCollectionFinset.{u1} α))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_filter_le_of_right_le Finset.Ico_filter_le_of_right_leₓ'. -/
 theorem Ico_filter_le_of_right_le {a b : α} [DecidablePred ((· ≤ ·) b)] :
     (Ico a b).filterₓ ((· ≤ ·) b) = ∅ :=
   filter_false_of_mem fun x hx => (mem_Ico.1 hx).2.not_le
 #align finset.Ico_filter_le_of_right_le Finset.Ico_filter_le_of_right_le
--/
 
-#print Finset.Ico_filter_le_of_left_le /-
+/- warning: finset.Ico_filter_le_of_left_le -> Finset.Ico_filter_le_of_left_le is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) c)], (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (Finset.Ico.{u1} α _inst_1 _inst_2 c b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3225 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3227 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3225 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3227) c)], (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3258 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3260 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3258 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.3260) c) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)) (Finset.Ico.{u1} α _inst_1 _inst_2 c b))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_filter_le_of_left_le Finset.Ico_filter_le_of_left_leₓ'. -/
 theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred ((· ≤ ·) c)] (hac : a ≤ c) :
     (Ico a b).filterₓ ((· ≤ ·) c) = Ico c b := by
   ext x
   rw [mem_filter, mem_Ico, mem_Ico, and_comm', and_left_comm]
   exact and_iff_right_of_imp fun h => hac.trans h.1
 #align finset.Ico_filter_le_of_left_le Finset.Ico_filter_le_of_left_le
--/
 
-#print Finset.Icc_filter_lt_of_lt_right /-
+/- warning: finset.Icc_filter_lt_of_lt_right -> Finset.Icc_filter_lt_of_lt_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c)], (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Icc.{u1} α _inst_1 _inst_2 a b)) (Finset.Icc.{u1} α _inst_1 _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c)], (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Icc.{u1} α _inst_1 _inst_2 a b)) (Finset.Icc.{u1} α _inst_1 _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_filter_lt_of_lt_right Finset.Icc_filter_lt_of_lt_rightₓ'. -/
 theorem Icc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Icc a b).filterₓ (· < c) = Icc a b :=
   (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Icc.1 hx).2 h
 #align finset.Icc_filter_lt_of_lt_right Finset.Icc_filter_lt_of_lt_right
--/
 
-#print Finset.Ioc_filter_lt_of_lt_right /-
+/- warning: finset.Ioc_filter_lt_of_lt_right -> Finset.Ioc_filter_lt_of_lt_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c)], (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b)) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] {a : α} {b : α} {c : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c)], (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x c) (fun (a : α) => _inst_3 a) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b)) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_filter_lt_of_lt_right Finset.Ioc_filter_lt_of_lt_rightₓ'. -/
 theorem Ioc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Ioc a b).filterₓ (· < c) = Ioc a b :=
   (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Ioc.1 hx).2 h
 #align finset.Ioc_filter_lt_of_lt_right Finset.Ioc_filter_lt_of_lt_right
--/
 
-#print Finset.Iic_filter_lt_of_lt_right /-
+/- warning: finset.Iic_filter_lt_of_lt_right -> Finset.Iic_filter_lt_of_lt_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_3 : Preorder.{u1} α] [_inst_4 : LocallyFiniteOrderBot.{u1} α _inst_3] {a : α} {c : α} [_inst_5 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_3) _x c)], (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_3) a c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_3) _x c) (fun (a : α) => _inst_5 a) (Finset.Iic.{u1} α _inst_3 _inst_4 a)) (Finset.Iic.{u1} α _inst_3 _inst_4 a))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_3 : Preorder.{u1} α] [_inst_4 : LocallyFiniteOrderBot.{u1} α _inst_3] {a : α} {c : α} [_inst_5 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_3) _x c)], (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_3) a c) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_3) _x c) (fun (a : α) => _inst_5 a) (Finset.Iic.{u1} α _inst_3 _inst_4 a)) (Finset.Iic.{u1} α _inst_3 _inst_4 a))
+Case conversion may be inaccurate. Consider using '#align finset.Iic_filter_lt_of_lt_right Finset.Iic_filter_lt_of_lt_rightₓ'. -/
 theorem Iic_filter_lt_of_lt_right {α} [Preorder α] [LocallyFiniteOrderBot α] {a c : α}
     [DecidablePred (· < c)] (h : a < c) : (Iic a).filterₓ (· < c) = Iic a :=
   (Finset.filter_eq_self _).2 fun x hx => lt_of_le_of_lt (mem_Iic.1 hx) h
 #align finset.Iic_filter_lt_of_lt_right Finset.Iic_filter_lt_of_lt_right
--/
 
 variable (a b) [Fintype α]
 
-#print Finset.filter_lt_lt_eq_Ioo /-
+/- warning: finset.filter_lt_lt_eq_Ioo -> Finset.filter_lt_lt_eq_Ioo is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ioo.{u1} α _inst_1 _inst_2 a b)
+Case conversion may be inaccurate. Consider using '#align finset.filter_lt_lt_eq_Ioo Finset.filter_lt_lt_eq_Iooₓ'. -/
 theorem filter_lt_lt_eq_Ioo [DecidablePred fun j => a < j ∧ j < b] :
     (univ.filterₓ fun j => a < j ∧ j < b) = Ioo a b :=
   by
   ext
   simp
 #align finset.filter_lt_lt_eq_Ioo Finset.filter_lt_lt_eq_Ioo
--/
 
-#print Finset.filter_lt_le_eq_Ioc /-
+/- warning: finset.filter_lt_le_eq_Ioc -> Finset.filter_lt_le_eq_Ioc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ioc.{u1} α _inst_1 _inst_2 a b)
+Case conversion may be inaccurate. Consider using '#align finset.filter_lt_le_eq_Ioc Finset.filter_lt_le_eq_Iocₓ'. -/
 theorem filter_lt_le_eq_Ioc [DecidablePred fun j => a < j ∧ j ≤ b] :
     (univ.filterₓ fun j => a < j ∧ j ≤ b) = Ioc a b :=
   by
   ext
   simp
 #align finset.filter_lt_le_eq_Ioc Finset.filter_lt_le_eq_Ioc
--/
 
-#print Finset.filter_le_lt_eq_Ico /-
+/- warning: finset.filter_le_lt_eq_Ico -> Finset.filter_le_lt_eq_Ico is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a j) (LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ico.{u1} α _inst_1 _inst_2 a b)
+Case conversion may be inaccurate. Consider using '#align finset.filter_le_lt_eq_Ico Finset.filter_le_lt_eq_Icoₓ'. -/
 theorem filter_le_lt_eq_Ico [DecidablePred fun j => a ≤ j ∧ j < b] :
     (univ.filterₓ fun j => a ≤ j ∧ j < b) = Ico a b :=
   by
   ext
   simp
 #align finset.filter_le_lt_eq_Ico Finset.filter_le_lt_eq_Ico
--/
 
-#print Finset.filter_le_le_eq_Icc /-
+/- warning: finset.filter_le_le_eq_Icc -> Finset.filter_le_le_eq_Icc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Icc.{u1} α _inst_1 _inst_2 a b)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α _inst_1] (a : α) (b : α) [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) j b))], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (j : α) => And (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) a j) (LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) j b)) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Icc.{u1} α _inst_1 _inst_2 a b)
+Case conversion may be inaccurate. Consider using '#align finset.filter_le_le_eq_Icc Finset.filter_le_le_eq_Iccₓ'. -/
 theorem filter_le_le_eq_Icc [DecidablePred fun j => a ≤ j ∧ j ≤ b] :
     (univ.filterₓ fun j => a ≤ j ∧ j ≤ b) = Icc a b :=
   by
   ext
   simp
 #align finset.filter_le_le_eq_Icc Finset.filter_le_le_eq_Icc
--/
 
 end Filter
 
@@ -632,21 +854,29 @@ theorem Set.Infinite.not_bddBelow {s : Set α} : s.Infinite → ¬BddBelow s :=
 
 variable [Fintype α]
 
-#print Finset.filter_lt_eq_Ioi /-
+/- warning: finset.filter_lt_eq_Ioi -> Finset.filter_lt_eq_Ioi is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ioi.{u1} α _inst_1 _inst_2 a)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4470 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4472 : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4470 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4472) a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4493 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4495 : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4493 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4495) a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ioi.{u1} α _inst_1 _inst_2 a)
+Case conversion may be inaccurate. Consider using '#align finset.filter_lt_eq_Ioi Finset.filter_lt_eq_Ioiₓ'. -/
 theorem filter_lt_eq_Ioi [DecidablePred ((· < ·) a)] : univ.filterₓ ((· < ·) a) = Ioi a :=
   by
   ext
   simp
 #align finset.filter_lt_eq_Ioi Finset.filter_lt_eq_Ioi
--/
 
-#print Finset.filter_le_eq_Ici /-
+/- warning: finset.filter_le_eq_Ici -> Finset.filter_le_eq_Ici is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ici.{u1} α _inst_1 _inst_2 a)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4536 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4538 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4536 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4538) a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4559 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4561 : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4559 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.4561) a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Ici.{u1} α _inst_1 _inst_2 a)
+Case conversion may be inaccurate. Consider using '#align finset.filter_le_eq_Ici Finset.filter_le_eq_Iciₓ'. -/
 theorem filter_le_eq_Ici [DecidablePred ((· ≤ ·) a)] : univ.filterₓ ((· ≤ ·) a) = Ici a :=
   by
   ext
   simp
 #align finset.filter_le_eq_Ici Finset.filter_le_eq_Ici
--/
 
 end LocallyFiniteOrderTop
 
@@ -673,21 +903,29 @@ theorem Set.Infinite.not_bddAbove {s : Set α} : s.Infinite → ¬BddAbove s :=
 
 variable [Fintype α]
 
-#print Finset.filter_gt_eq_Iio /-
+/- warning: finset.filter_gt_eq_Iio -> Finset.filter_gt_eq_Iio is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α _inst_1) _x a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Iio.{u1} α _inst_1 _inst_2 a)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LT.lt.{u1} α (Preorder.toLT.{u1} α _inst_1) _x a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Iio.{u1} α _inst_1 _inst_2 a)
+Case conversion may be inaccurate. Consider using '#align finset.filter_gt_eq_Iio Finset.filter_gt_eq_Iioₓ'. -/
 theorem filter_gt_eq_Iio [DecidablePred (· < a)] : univ.filterₓ (· < a) = Iio a :=
   by
   ext
   simp
 #align finset.filter_gt_eq_Iio Finset.filter_gt_eq_Iio
--/
 
-#print Finset.filter_ge_eq_Iic /-
+/- warning: finset.filter_ge_eq_Iic -> Finset.filter_ge_eq_Iic is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (_x : α) => LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) _x a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LE.le.{u1} α (Preorder.toHasLe.{u1} α _inst_1) _x a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Iic.{u1} α _inst_1 _inst_2 a)
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Preorder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α _inst_1] {a : α} [_inst_3 : Fintype.{u1} α] [_inst_4 : DecidablePred.{succ u1} α (fun (_x : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) _x a)], Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (_x : α) => LE.le.{u1} α (Preorder.toLE.{u1} α _inst_1) _x a) (fun (a : α) => _inst_4 a) (Finset.univ.{u1} α _inst_3)) (Finset.Iic.{u1} α _inst_1 _inst_2 a)
+Case conversion may be inaccurate. Consider using '#align finset.filter_ge_eq_Iic Finset.filter_ge_eq_Iicₓ'. -/
 theorem filter_ge_eq_Iic [DecidablePred (· ≤ a)] : univ.filterₓ (· ≤ a) = Iic a :=
   by
   ext
   simp
 #align finset.filter_ge_eq_Iic Finset.filter_ge_eq_Iic
--/
 
 end LocallyFiniteOrderBot
 
@@ -766,63 +1004,99 @@ theorem Icc_diff_both (a b : α) : Icc a b \ {a, b} = Ioo a b := by simp [← co
 #align finset.Icc_diff_both Finset.Icc_diff_both
 -/
 
-#print Finset.Ico_insert_right /-
+/- warning: finset.Ico_insert_right -> Finset.Ico_insert_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.hasInsert.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) b (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.instInsertFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) b (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_insert_right Finset.Ico_insert_rightₓ'. -/
 @[simp]
 theorem Ico_insert_right (h : a ≤ b) : insert b (Ico a b) = Icc a b := by
   rw [← coe_inj, coe_insert, coe_Icc, coe_Ico, Set.insert_eq, Set.union_comm, Set.Ico_union_right h]
 #align finset.Ico_insert_right Finset.Ico_insert_right
--/
 
-#print Finset.Ioc_insert_left /-
+/- warning: finset.Ioc_insert_left -> Finset.Ioc_insert_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.hasInsert.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) a (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.instInsertFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) a (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_insert_left Finset.Ioc_insert_leftₓ'. -/
 @[simp]
 theorem Ioc_insert_left (h : a ≤ b) : insert a (Ioc a b) = Icc a b := by
   rw [← coe_inj, coe_insert, coe_Ioc, coe_Icc, Set.insert_eq, Set.union_comm, Set.Ioc_union_left h]
 #align finset.Ioc_insert_left Finset.Ioc_insert_left
--/
 
-#print Finset.Ioo_insert_left /-
+/- warning: finset.Ioo_insert_left -> Finset.Ioo_insert_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.hasInsert.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) a (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.instInsertFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) a (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ioo_insert_left Finset.Ioo_insert_leftₓ'. -/
 @[simp]
 theorem Ioo_insert_left (h : a < b) : insert a (Ioo a b) = Ico a b := by
   rw [← coe_inj, coe_insert, coe_Ioo, coe_Ico, Set.insert_eq, Set.union_comm, Set.Ioo_union_left h]
 #align finset.Ioo_insert_left Finset.Ioo_insert_left
--/
 
-#print Finset.Ioo_insert_right /-
+/- warning: finset.Ioo_insert_right -> Finset.Ioo_insert_right is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.hasInsert.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) b (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.instInsertFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) b (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.Ioo_insert_right Finset.Ioo_insert_rightₓ'. -/
 @[simp]
 theorem Ioo_insert_right (h : a < b) : insert b (Ioo a b) = Ioc a b := by
   rw [← coe_inj, coe_insert, coe_Ioo, coe_Ioc, Set.insert_eq, Set.union_comm, Set.Ioo_union_right h]
 #align finset.Ioo_insert_right Finset.Ioo_insert_right
--/
 
-#print Finset.Icc_diff_Ico_self /-
+/- warning: finset.Icc_diff_Ico_self -> Finset.Icc_diff_Ico_self is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.hasSdiff.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.hasSingleton.{u1} α) b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.instSDiffFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.instSingletonFinset.{u1} α) b))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_diff_Ico_self Finset.Icc_diff_Ico_selfₓ'. -/
 @[simp]
 theorem Icc_diff_Ico_self (h : a ≤ b) : Icc a b \ Ico a b = {b} := by simp [← coe_inj, h]
 #align finset.Icc_diff_Ico_self Finset.Icc_diff_Ico_self
--/
 
-#print Finset.Icc_diff_Ioc_self /-
+/- warning: finset.Icc_diff_Ioc_self -> Finset.Icc_diff_Ioc_self is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.hasSdiff.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.hasSingleton.{u1} α) a))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.instSDiffFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.instSingletonFinset.{u1} α) a))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_diff_Ioc_self Finset.Icc_diff_Ioc_selfₓ'. -/
 @[simp]
 theorem Icc_diff_Ioc_self (h : a ≤ b) : Icc a b \ Ioc a b = {a} := by simp [← coe_inj, h]
 #align finset.Icc_diff_Ioc_self Finset.Icc_diff_Ioc_self
--/
 
-#print Finset.Icc_diff_Ioo_self /-
+/- warning: finset.Icc_diff_Ioo_self -> Finset.Icc_diff_Ioo_self is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.hasSdiff.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.hasInsert.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) a (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.hasSingleton.{u1} α) b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.instSDiffFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Insert.insert.{u1, u1} α (Finset.{u1} α) (Finset.instInsertFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) a (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.instSingletonFinset.{u1} α) b)))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_diff_Ioo_self Finset.Icc_diff_Ioo_selfₓ'. -/
 @[simp]
 theorem Icc_diff_Ioo_self (h : a ≤ b) : Icc a b \ Ioo a b = {a, b} := by simp [← coe_inj, h]
 #align finset.Icc_diff_Ioo_self Finset.Icc_diff_Ioo_self
--/
 
-#print Finset.Ico_diff_Ioo_self /-
+/- warning: finset.Ico_diff_Ioo_self -> Finset.Ico_diff_Ioo_self is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.hasSdiff.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.hasSingleton.{u1} α) a))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.instSDiffFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.instSingletonFinset.{u1} α) a))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_diff_Ioo_self Finset.Ico_diff_Ioo_selfₓ'. -/
 @[simp]
 theorem Ico_diff_Ioo_self (h : a < b) : Ico a b \ Ioo a b = {a} := by simp [← coe_inj, h]
 #align finset.Ico_diff_Ioo_self Finset.Ico_diff_Ioo_self
--/
 
-#print Finset.Ioc_diff_Ioo_self /-
+/- warning: finset.Ioc_diff_Ioo_self -> Finset.Ioc_diff_Ioo_self is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.hasSdiff.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.hasSingleton.{u1} α) b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidableEq.{succ u1} α], (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (SDiff.sdiff.{u1} (Finset.{u1} α) (Finset.instSDiffFinset.{u1} α (fun (a : α) (b : α) => _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.instSingletonFinset.{u1} α) b))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_diff_Ioo_self Finset.Ioc_diff_Ioo_selfₓ'. -/
 @[simp]
 theorem Ioc_diff_Ioo_self (h : a < b) : Ioc a b \ Ioo a b = {b} := by simp [← coe_inj, h]
 #align finset.Ioc_diff_Ioo_self Finset.Ioc_diff_Ioo_self
--/
 
 #print Finset.Ico_inter_Ico_consecutive /-
 @[simp]
@@ -833,36 +1107,57 @@ theorem Ico_inter_Ico_consecutive (a b c : α) : Ico a b ∩ Ico b c = ∅ :=
 
 end DecidableEq
 
-#print Finset.Icc_eq_cons_Ico /-
+/- warning: finset.Icc_eq_cons_Ico -> Finset.Icc_eq_cons_Ico is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.cons.{u1} α b (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.right_not_mem_Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.cons.{u1} α b (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.right_not_mem_Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_eq_cons_Ico Finset.Icc_eq_cons_Icoₓ'. -/
 -- Those lemmas are purposefully the other way around
 /-- `finset.cons` version of `finset.Ico_insert_right`. -/
 theorem Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico := by
   classical rw [cons_eq_insert, Ico_insert_right h]
 #align finset.Icc_eq_cons_Ico Finset.Icc_eq_cons_Ico
--/
 
-#print Finset.Icc_eq_cons_Ioc /-
+/- warning: finset.Icc_eq_cons_Ioc -> Finset.Icc_eq_cons_Ioc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.cons.{u1} α a (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.left_not_mem_Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.cons.{u1} α a (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.left_not_mem_Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)))
+Case conversion may be inaccurate. Consider using '#align finset.Icc_eq_cons_Ioc Finset.Icc_eq_cons_Iocₓ'. -/
 /-- `finset.cons` version of `finset.Ioc_insert_left`. -/
 theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc := by
   classical rw [cons_eq_insert, Ioc_insert_left h]
 #align finset.Icc_eq_cons_Ioc Finset.Icc_eq_cons_Ioc
--/
 
-#print Finset.Ioc_eq_cons_Ioo /-
+/- warning: finset.Ioc_eq_cons_Ioo -> Finset.Ioc_eq_cons_Ioo is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α}, (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.cons.{u1} α b (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.right_not_mem_Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.cons.{u1} α b (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.right_not_mem_Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_eq_cons_Ioo Finset.Ioc_eq_cons_Iooₓ'. -/
 /-- `finset.cons` version of `finset.Ioo_insert_right`. -/
 theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by
   classical rw [cons_eq_insert, Ioo_insert_right h]
 #align finset.Ioc_eq_cons_Ioo Finset.Ioc_eq_cons_Ioo
--/
 
-#print Finset.Ico_eq_cons_Ioo /-
+/- warning: finset.Ico_eq_cons_Ioo -> Finset.Ico_eq_cons_Ioo is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α}, (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.cons.{u1} α a (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.left_not_mem_Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.cons.{u1} α a (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b) (Finset.left_not_mem_Ioo.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_eq_cons_Ioo Finset.Ico_eq_cons_Iooₓ'. -/
 /-- `finset.cons` version of `finset.Ioo_insert_left`. -/
 theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by
   classical rw [cons_eq_insert, Ioo_insert_left h]
 #align finset.Ico_eq_cons_Ioo Finset.Ico_eq_cons_Ioo
--/
 
-#print Finset.Ico_filter_le_left /-
+/- warning: finset.Ico_filter_le_left -> Finset.Ico_filter_le_left is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) _x a)], (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (x : α) => LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) x a) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.hasSingleton.{u1} α) a))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : PartialOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)] {a : α} {b : α} [_inst_3 : DecidablePred.{succ u1} α (fun (_x : α) => LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) _x a)], (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.filter.{u1} α (fun (x : α) => LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1)) x a) (fun (a : α) => _inst_3 a) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α _inst_1) _inst_2 a b)) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.instSingletonFinset.{u1} α) a))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_filter_le_left Finset.Ico_filter_le_leftₓ'. -/
 theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
     ((Ico a b).filterₓ fun x => x ≤ a) = {a} :=
   by
@@ -870,7 +1165,6 @@ theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
   rw [mem_filter, mem_Ico, mem_singleton, and_right_comm, ← le_antisymm_iff, eq_comm]
   exact and_iff_left_of_imp fun h => h.le.trans_lt hab
 #align finset.Ico_filter_le_left Finset.Ico_filter_le_left
--/
 
 #print Finset.card_Ico_eq_card_Icc_sub_one /-
 theorem card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card - 1 := by
@@ -1016,26 +1310,38 @@ section LocallyFiniteOrder
 
 variable [LocallyFiniteOrder α] {a b : α}
 
-#print Finset.Ico_subset_Ico_iff /-
+/- warning: finset.Ico_subset_Ico_iff -> Finset.Ico_subset_Ico_iff is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a₁ : α} {b₁ : α} {a₂ : α} {b₂ : α}, (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a₁ b₁) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a₂ a₁) (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b₁ b₂)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a₁ : α} {b₁ : α} {a₂ : α} {b₂ : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a₁ b₁) -> (Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a₁ b₁) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a₂ a₁) (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b₁ b₂)))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_subset_Ico_iff Finset.Ico_subset_Ico_iffₓ'. -/
 theorem Ico_subset_Ico_iff {a₁ b₁ a₂ b₂ : α} (h : a₁ < b₁) :
     Ico a₁ b₁ ⊆ Ico a₂ b₂ ↔ a₂ ≤ a₁ ∧ b₁ ≤ b₂ := by
   rw [← coe_subset, coe_Ico, coe_Ico, Set.Ico_subset_Ico_iff h]
 #align finset.Ico_subset_Ico_iff Finset.Ico_subset_Ico_iff
--/
 
-#print Finset.Ico_union_Ico_eq_Ico /-
+/- warning: finset.Ico_union_Ico_eq_Ico -> Finset.Ico_union_Ico_eq_Ico is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 b c)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a c))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.instUnionFinset.{u1} α (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 b c)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a c))
+Case conversion may be inaccurate. Consider using '#align finset.Ico_union_Ico_eq_Ico Finset.Ico_union_Ico_eq_Icoₓ'. -/
 theorem Ico_union_Ico_eq_Ico {a b c : α} (hab : a ≤ b) (hbc : b ≤ c) :
     Ico a b ∪ Ico b c = Ico a c := by
   rw [← coe_inj, coe_union, coe_Ico, coe_Ico, coe_Ico, Set.Ico_union_Ico_eq_Ico hab hbc]
 #align finset.Ico_union_Ico_eq_Ico Finset.Ico_union_Ico_eq_Ico
--/
 
-#print Finset.Ioc_union_Ioc_eq_Ioc /-
+/- warning: finset.Ioc_union_Ioc_eq_Ioc -> Finset.Ioc_union_Ioc_eq_Ioc is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 b c)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a c))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.instUnionFinset.{u1} α (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a b) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 b c)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a c))
+Case conversion may be inaccurate. Consider using '#align finset.Ioc_union_Ioc_eq_Ioc Finset.Ioc_union_Ioc_eq_Iocₓ'. -/
 @[simp]
 theorem Ioc_union_Ioc_eq_Ioc {a b c : α} (h₁ : a ≤ b) (h₂ : b ≤ c) : Ioc a b ∪ Ioc b c = Ioc a c :=
   by rw [← coe_inj, coe_union, coe_Ioc, coe_Ioc, coe_Ioc, Set.Ioc_union_Ioc_eq_Ioc h₁ h₂]
 #align finset.Ioc_union_Ioc_eq_Ioc Finset.Ioc_union_Ioc_eq_Ioc
--/
 
 #print Finset.Ico_subset_Ico_union_Ico /-
 theorem Ico_subset_Ico_union_Ico {a b c : α} : Ico a c ⊆ Ico a b ∪ Ico b c :=
@@ -1047,7 +1353,7 @@ theorem Ico_subset_Ico_union_Ico {a b c : α} : Ico a c ⊆ Ico a b ∪ Ico b c
 
 /- warning: finset.Ico_union_Ico' -> Finset.Ico_union_Ico' is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α} {d : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) c b) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a d) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 c d)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 (LinearOrder.min.{u1} α _inst_1 a c) (LinearOrder.max.{u1} α _inst_1 b d)))
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α} {d : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) c b) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a d) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 c d)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 (LinearOrder.min.{u1} α _inst_1 a c) (LinearOrder.max.{u1} α _inst_1 b d)))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α} {d : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) c b) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a d) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.instUnionFinset.{u1} α (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 c d)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 (Min.min.{u1} α (LinearOrder.toMin.{u1} α _inst_1) a c) (Max.max.{u1} α (LinearOrder.toMax.{u1} α _inst_1) b d)))
 Case conversion may be inaccurate. Consider using '#align finset.Ico_union_Ico' Finset.Ico_union_Ico'ₓ'. -/
@@ -1058,7 +1364,7 @@ theorem Ico_union_Ico' {a b c d : α} (hcb : c ≤ b) (had : a ≤ d) :
 
 /- warning: finset.Ico_union_Ico -> Finset.Ico_union_Ico is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α} {d : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) (LinearOrder.min.{u1} α _inst_1 a b) (LinearOrder.max.{u1} α _inst_1 c d)) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) (LinearOrder.min.{u1} α _inst_1 c d) (LinearOrder.max.{u1} α _inst_1 a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 c d)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 (LinearOrder.min.{u1} α _inst_1 a c) (LinearOrder.max.{u1} α _inst_1 b d)))
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α} {d : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) (LinearOrder.min.{u1} α _inst_1 a b) (LinearOrder.max.{u1} α _inst_1 c d)) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) (LinearOrder.min.{u1} α _inst_1 c d) (LinearOrder.max.{u1} α _inst_1 a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 c d)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 (LinearOrder.min.{u1} α _inst_1 a c) (LinearOrder.max.{u1} α _inst_1 b d)))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α} {d : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) (Min.min.{u1} α (LinearOrder.toMin.{u1} α _inst_1) a b) (Max.max.{u1} α (LinearOrder.toMax.{u1} α _inst_1) c d)) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) (Min.min.{u1} α (LinearOrder.toMin.{u1} α _inst_1) c d) (Max.max.{u1} α (LinearOrder.toMax.{u1} α _inst_1) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.instUnionFinset.{u1} α (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 c d)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 (Min.min.{u1} α (LinearOrder.toMin.{u1} α _inst_1) a c) (Max.max.{u1} α (LinearOrder.toMax.{u1} α _inst_1) b d)))
 Case conversion may be inaccurate. Consider using '#align finset.Ico_union_Ico Finset.Ico_union_Icoₓ'. -/
@@ -1156,7 +1462,7 @@ variable [LocallyFiniteOrderBot α] {s : Set α}
 
 /- warning: set.infinite.exists_gt -> Set.Infinite.exists_gt is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b)))
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b)))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => And (Membership.mem.{u1, u1} α (Set.{u1} α) (Set.instMembershipSet.{u1} α) b s) (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b)))
 Case conversion may be inaccurate. Consider using '#align set.infinite.exists_gt Set.Infinite.exists_gtₓ'. -/
@@ -1166,7 +1472,7 @@ theorem Set.Infinite.exists_gt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, a < b :=
 
 /- warning: set.infinite_iff_exists_gt -> Set.infinite_iff_exists_gt is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b)))
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b)))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => And (Membership.mem.{u1, u1} α (Set.{u1} α) (Set.instMembershipSet.{u1} α) b s) (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b)))
 Case conversion may be inaccurate. Consider using '#align set.infinite_iff_exists_gt Set.infinite_iff_exists_gtₓ'. -/
@@ -1182,7 +1488,7 @@ variable [LocallyFiniteOrderTop α] {s : Set α}
 
 /- warning: set.infinite.exists_lt -> Set.Infinite.exists_lt is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b a)))
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b a)))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => And (Membership.mem.{u1, u1} α (Set.{u1} α) (Set.instMembershipSet.{u1} α) b s) (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b a)))
 Case conversion may be inaccurate. Consider using '#align set.infinite.exists_lt Set.Infinite.exists_ltₓ'. -/
@@ -1192,7 +1498,7 @@ theorem Set.Infinite.exists_lt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, b < a :=
 
 /- warning: set.infinite_iff_exists_lt -> Set.infinite_iff_exists_lt is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b a)))
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b a)))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => And (Membership.mem.{u1, u1} α (Set.{u1} α) (Set.instMembershipSet.{u1} α) b s) (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b a)))
 Case conversion may be inaccurate. Consider using '#align set.infinite_iff_exists_lt Set.infinite_iff_exists_ltₓ'. -/
@@ -1225,17 +1531,25 @@ theorem uIcc_toDual (a b : α) : [toDual a, toDual b] = [a, b].map toDual.toEmbe
 #align finset.uIcc_to_dual Finset.uIcc_toDual
 -/
 
-#print Finset.uIcc_of_le /-
+/- warning: finset.uIcc_of_le -> Finset.uIcc_of_le is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α _inst_1 _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1))) _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) a b) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α _inst_1 _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1))) _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.uIcc_of_le Finset.uIcc_of_leₓ'. -/
 @[simp]
 theorem uIcc_of_le (h : a ≤ b) : [a, b] = Icc a b := by rw [uIcc, inf_eq_left.2 h, sup_eq_right.2 h]
 #align finset.uIcc_of_le Finset.uIcc_of_le
--/
 
-#print Finset.uIcc_of_ge /-
+/- warning: finset.uIcc_of_ge -> Finset.uIcc_of_ge is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α _inst_1 _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1))) _inst_2 b a))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a : α} {b : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) b a) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α _inst_1 _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1))) _inst_2 b a))
+Case conversion may be inaccurate. Consider using '#align finset.uIcc_of_ge Finset.uIcc_of_geₓ'. -/
 @[simp]
 theorem uIcc_of_ge (h : b ≤ a) : [a, b] = Icc b a := by rw [uIcc, inf_eq_right.2 h, sup_eq_left.2 h]
 #align finset.uIcc_of_ge Finset.uIcc_of_ge
--/
 
 #print Finset.uIcc_comm /-
 theorem uIcc_comm (a b : α) : [a, b] = [b, a] := by rw [uIcc, uIcc, inf_comm, sup_comm]
@@ -1281,17 +1595,25 @@ theorem right_mem_uIcc : b ∈ [a, b] :=
 #align finset.right_mem_uIcc Finset.right_mem_uIcc
 -/
 
-#print Finset.mem_uIcc_of_le /-
+/- warning: finset.mem_uIcc_of_le -> Finset.mem_uIcc_of_le is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a : α} {b : α} {x : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) a x) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) x b) -> (Membership.Mem.{u1, u1} α (Finset.{u1} α) (Finset.hasMem.{u1} α) x (Finset.uIcc.{u1} α _inst_1 _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a : α} {b : α} {x : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) a x) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) x b) -> (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) x (Finset.uIcc.{u1} α _inst_1 _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.mem_uIcc_of_le Finset.mem_uIcc_of_leₓ'. -/
 theorem mem_uIcc_of_le (ha : a ≤ x) (hb : x ≤ b) : x ∈ [a, b] :=
   Icc_subset_uIcc <| mem_Icc.2 ⟨ha, hb⟩
 #align finset.mem_uIcc_of_le Finset.mem_uIcc_of_le
--/
 
-#print Finset.mem_uIcc_of_ge /-
+/- warning: finset.mem_uIcc_of_ge -> Finset.mem_uIcc_of_ge is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a : α} {b : α} {x : α}, (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) b x) -> (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) x a) -> (Membership.Mem.{u1, u1} α (Finset.{u1} α) (Finset.hasMem.{u1} α) x (Finset.uIcc.{u1} α _inst_1 _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a : α} {b : α} {x : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) b x) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) x a) -> (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) x (Finset.uIcc.{u1} α _inst_1 _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.mem_uIcc_of_ge Finset.mem_uIcc_of_geₓ'. -/
 theorem mem_uIcc_of_ge (hb : b ≤ x) (ha : x ≤ a) : x ∈ [a, b] :=
   Icc_subset_uIcc' <| mem_Icc.2 ⟨hb, ha⟩
 #align finset.mem_uIcc_of_ge Finset.mem_uIcc_of_ge
--/
 
 #print Finset.uIcc_subset_uIcc /-
 theorem uIcc_subset_uIcc (h₁ : a₁ ∈ [a₂, b₂]) (h₂ : b₁ ∈ [a₂, b₂]) : [a₁, b₁] ⊆ [a₂, b₂] :=
@@ -1317,7 +1639,7 @@ theorem uIcc_subset_uIcc_iff_mem : [a₁, b₁] ⊆ [a₂, b₂] ↔ a₁ ∈ [a
 
 /- warning: finset.uIcc_subset_uIcc_iff_le' -> Finset.uIcc_subset_uIcc_iff_le' is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Inf.inf.{u1} α (SemilatticeInf.toHasInf.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)) a₂ b₂) (Inf.inf.{u1} α (SemilatticeInf.toHasInf.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)) a₁ b₁)) (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Sup.sup.{u1} α (SemilatticeSup.toHasSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₁ b₁) (Sup.sup.{u1} α (SemilatticeSup.toHasSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₂ b₂)))
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Inf.inf.{u1} α (SemilatticeInf.toHasInf.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)) a₂ b₂) (Inf.inf.{u1} α (SemilatticeInf.toHasInf.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)) a₁ b₁)) (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Sup.sup.{u1} α (SemilatticeSup.toHasSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₁ b₁) (Sup.sup.{u1} α (SemilatticeSup.toHasSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₂ b₂)))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Inf.inf.{u1} α (Lattice.toInf.{u1} α _inst_1) a₂ b₂) (Inf.inf.{u1} α (Lattice.toInf.{u1} α _inst_1) a₁ b₁)) (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Sup.sup.{u1} α (SemilatticeSup.toSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₁ b₁) (Sup.sup.{u1} α (SemilatticeSup.toSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₂ b₂)))
 Case conversion may be inaccurate. Consider using '#align finset.uIcc_subset_uIcc_iff_le' Finset.uIcc_subset_uIcc_iff_le'ₓ'. -/
@@ -1389,17 +1711,25 @@ theorem Icc_min_max : Icc (min a b) (max a b) = [a, b] :=
   rfl
 #align finset.Icc_min_max Finset.Icc_min_max
 
-#print Finset.uIcc_of_not_le /-
+/- warning: finset.uIcc_of_not_le -> Finset.uIcc_of_not_le is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α}, (Not (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 b a))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α}, (Not (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 b a))
+Case conversion may be inaccurate. Consider using '#align finset.uIcc_of_not_le Finset.uIcc_of_not_leₓ'. -/
 theorem uIcc_of_not_le (h : ¬a ≤ b) : [a, b] = Icc b a :=
   uIcc_of_ge <| le_of_not_ge h
 #align finset.uIcc_of_not_le Finset.uIcc_of_not_le
--/
 
-#print Finset.uIcc_of_not_ge /-
+/- warning: finset.uIcc_of_not_ge -> Finset.uIcc_of_not_ge is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α}, (Not (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b a)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α}, (Not (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b a)) -> (Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a b))
+Case conversion may be inaccurate. Consider using '#align finset.uIcc_of_not_ge Finset.uIcc_of_not_geₓ'. -/
 theorem uIcc_of_not_ge (h : ¬b ≤ a) : [a, b] = Icc a b :=
   uIcc_of_le <| le_of_not_ge h
 #align finset.uIcc_of_not_ge Finset.uIcc_of_not_ge
--/
 
 #print Finset.uIcc_eq_union /-
 theorem uIcc_eq_union : [a, b] = Icc a b ∪ Icc b a :=
@@ -1409,30 +1739,42 @@ theorem uIcc_eq_union : [a, b] = Icc a b ∪ Icc b a :=
 #align finset.uIcc_eq_union Finset.uIcc_eq_union
 -/
 
-#print Finset.mem_uIcc' /-
+/- warning: finset.mem_uIcc' -> Finset.mem_uIcc' is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α}, Iff (Membership.Mem.{u1, u1} α (Finset.{u1} α) (Finset.hasMem.{u1} α) a (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 b c)) (Or (And (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b a) (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a c)) (And (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) c a) (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, Iff (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) a (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 b c)) (Or (And (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b a) (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a c)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) c a) (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b)))
+Case conversion may be inaccurate. Consider using '#align finset.mem_uIcc' Finset.mem_uIcc'ₓ'. -/
 theorem mem_uIcc' : a ∈ [b, c] ↔ b ≤ a ∧ a ≤ c ∨ c ≤ a ∧ a ≤ b := by simp [uIcc_eq_union]
 #align finset.mem_uIcc' Finset.mem_uIcc'
--/
 
-#print Finset.not_mem_uIcc_of_lt /-
+/- warning: finset.not_mem_uIcc_of_lt -> Finset.not_mem_uIcc_of_lt is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α}, (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) c a) -> (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) c b) -> (Not (Membership.Mem.{u1, u1} α (Finset.{u1} α) (Finset.hasMem.{u1} α) c (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) c a) -> (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) c b) -> (Not (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) c (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a b)))
+Case conversion may be inaccurate. Consider using '#align finset.not_mem_uIcc_of_lt Finset.not_mem_uIcc_of_ltₓ'. -/
 theorem not_mem_uIcc_of_lt : c < a → c < b → c ∉ [a, b] :=
   by
   rw [mem_uIcc]
   exact Set.not_mem_uIcc_of_lt
 #align finset.not_mem_uIcc_of_lt Finset.not_mem_uIcc_of_lt
--/
 
-#print Finset.not_mem_uIcc_of_gt /-
+/- warning: finset.not_mem_uIcc_of_gt -> Finset.not_mem_uIcc_of_gt is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α}, (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a c) -> (LT.lt.{u1} α (Preorder.toHasLt.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b c) -> (Not (Membership.Mem.{u1, u1} α (Finset.{u1} α) (Finset.hasMem.{u1} α) c (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a c) -> (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b c) -> (Not (Membership.mem.{u1, u1} α (Finset.{u1} α) (Finset.instMembershipFinset.{u1} α) c (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a b)))
+Case conversion may be inaccurate. Consider using '#align finset.not_mem_uIcc_of_gt Finset.not_mem_uIcc_of_gtₓ'. -/
 theorem not_mem_uIcc_of_gt : a < c → b < c → c ∉ [a, b] :=
   by
   rw [mem_uIcc]
   exact Set.not_mem_uIcc_of_gt
 #align finset.not_mem_uIcc_of_gt Finset.not_mem_uIcc_of_gt
--/
 
 /- warning: finset.uIcc_subset_uIcc_iff_le -> Finset.uIcc_subset_uIcc_iff_le is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a₁ b₁) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) (LinearOrder.min.{u1} α _inst_1 a₂ b₂) (LinearOrder.min.{u1} α _inst_1 a₁ b₁)) (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) (LinearOrder.max.{u1} α _inst_1 a₁ b₁) (LinearOrder.max.{u1} α _inst_1 a₂ b₂)))
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a₁ b₁) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) (LinearOrder.min.{u1} α _inst_1 a₂ b₂) (LinearOrder.min.{u1} α _inst_1 a₁ b₁)) (LE.le.{u1} α (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) (LinearOrder.max.{u1} α _inst_1 a₁ b₁) (LinearOrder.max.{u1} α _inst_1 a₂ b₂)))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a₁ b₁) (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) (Min.min.{u1} α (LinearOrder.toMin.{u1} α _inst_1) a₂ b₂) (Min.min.{u1} α (LinearOrder.toMin.{u1} α _inst_1) a₁ b₁)) (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) (Max.max.{u1} α (LinearOrder.toMax.{u1} α _inst_1) a₁ b₁) (Max.max.{u1} α (LinearOrder.toMax.{u1} α _inst_1) a₂ b₂)))
 Case conversion may be inaccurate. Consider using '#align finset.uIcc_subset_uIcc_iff_le Finset.uIcc_subset_uIcc_iff_leₓ'. -/
@@ -1458,7 +1800,7 @@ variable [OrderedCancelAddCommMonoid α] [ExistsAddOfLE α] [LocallyFiniteOrder
 
 /- warning: finset.map_add_left_Icc -> Finset.map_add_left_Icc is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.map_add_left_Icc Finset.map_add_left_Iccₓ'. -/
@@ -1471,7 +1813,7 @@ theorem map_add_left_Icc (a b c : α) : (Icc a b).map (addLeftEmbedding c) = Icc
 
 /- warning: finset.map_add_right_Icc -> Finset.map_add_right_Icc is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.map_add_right_Icc Finset.map_add_right_Iccₓ'. -/
@@ -1484,7 +1826,7 @@ theorem map_add_right_Icc (a b c : α) : (Icc a b).map (addRightEmbedding c) = I
 
 /- warning: finset.map_add_left_Ico -> Finset.map_add_left_Ico is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.map_add_left_Ico Finset.map_add_left_Icoₓ'. -/
@@ -1497,7 +1839,7 @@ theorem map_add_left_Ico (a b c : α) : (Ico a b).map (addLeftEmbedding c) = Ico
 
 /- warning: finset.map_add_right_Ico -> Finset.map_add_right_Ico is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.map_add_right_Ico Finset.map_add_right_Icoₓ'. -/
@@ -1510,7 +1852,7 @@ theorem map_add_right_Ico (a b c : α) : (Ico a b).map (addRightEmbedding c) = I
 
 /- warning: finset.map_add_left_Ioc -> Finset.map_add_left_Ioc is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.map_add_left_Ioc Finset.map_add_left_Iocₓ'. -/
@@ -1523,7 +1865,7 @@ theorem map_add_left_Ioc (a b c : α) : (Ioc a b).map (addLeftEmbedding c) = Ioc
 
 /- warning: finset.map_add_right_Ioc -> Finset.map_add_right_Ioc is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.map_add_right_Ioc Finset.map_add_right_Iocₓ'. -/
@@ -1536,7 +1878,7 @@ theorem map_add_right_Ioc (a b c : α) : (Ioc a b).map (addRightEmbedding c) = I
 
 /- warning: finset.map_add_left_Ioo -> Finset.map_add_left_Ioo is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addLeftEmbedding.{u1} α (AddLeftCancelMonoid.toAddLeftCancelSemigroup.{u1} α (AddCancelCommMonoid.toAddLeftCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.map_add_left_Ioo Finset.map_add_left_Iooₓ'. -/
@@ -1549,7 +1891,7 @@ theorem map_add_left_Ioo (a b c : α) : (Ioo a b).map (addLeftEmbedding c) = Ioo
 
 /- warning: finset.map_add_right_Ioo -> Finset.map_add_right_Ioo is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.map.{u1, u1} α α (addRightEmbedding.{u1} α (AddRightCancelMonoid.toAddRightCancelSemigroup.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.map_add_right_Ioo Finset.map_add_right_Iooₓ'. -/
@@ -1564,7 +1906,7 @@ variable [DecidableEq α]
 
 /- warning: finset.image_add_left_Icc -> Finset.image_add_left_Icc is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11216 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11218 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11216 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11218) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Icc Finset.image_add_left_Iccₓ'. -/
@@ -1577,7 +1919,7 @@ theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c
 
 /- warning: finset.image_add_left_Ico -> Finset.image_add_left_Ico is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11317 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11319 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11317 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11319) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ico Finset.image_add_left_Icoₓ'. -/
@@ -1590,7 +1932,7 @@ theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c
 
 /- warning: finset.image_add_left_Ioc -> Finset.image_add_left_Ioc is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11418 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11420 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11418 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11420) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioc Finset.image_add_left_Iocₓ'. -/
@@ -1603,7 +1945,7 @@ theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c
 
 /- warning: finset.image_add_left_Ioo -> Finset.image_add_left_Ioo is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11519 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11521 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11519 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11521) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioo Finset.image_add_left_Iooₓ'. -/
@@ -1616,7 +1958,7 @@ theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c
 
 /- warning: finset.image_add_right_Icc -> Finset.image_add_right_Icc is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Icc Finset.image_add_right_Iccₓ'. -/
@@ -1629,7 +1971,7 @@ theorem image_add_right_Icc (a b c : α) : (Icc a b).image (· + c) = Icc (a + c
 
 /- warning: finset.image_add_right_Ico -> Finset.image_add_right_Ico is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Ico Finset.image_add_right_Icoₓ'. -/
@@ -1641,7 +1983,7 @@ theorem image_add_right_Ico (a b c : α) : (Ico a b).image (· + c) = Ico (a + c
 
 /- warning: finset.image_add_right_Ioc -> Finset.image_add_right_Ioc is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Ioc Finset.image_add_right_Iocₓ'. -/
@@ -1653,7 +1995,7 @@ theorem image_add_right_Ioc (a b c : α) : (Ioc a b).image (· + c) = Ioc (a + c
 
 /- warning: finset.image_add_right_Ioo -> Finset.image_add_right_Ioo is a dubious translation:
 lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toHasLe.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 but is expected to have type
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (fun (_x : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) _x c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) a c) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) b c))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_right_Ioo Finset.image_add_right_Iooₓ'. -/

bump to nightly-2023-05-16-00

mathlib commit https://github.com/leanprover-community/mathlib/commit/7ad820c4997738e2f542f8a20f32911f52020e26

ab5785da

Diff

@@ -1023,39 +1023,27 @@ theorem Ico_subset_Ico_iff {a₁ b₁ a₂ b₂ : α} (h : a₁ < b₁) :
 #align finset.Ico_subset_Ico_iff Finset.Ico_subset_Ico_iff
 -/
 
-/- warning: finset.Ico_union_Ico_eq_Ico -> Finset.Ico_union_Ico_eq_Ico is a dubious translation:
-lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 b c)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a c))
-but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.instUnionFinset.{u1} α (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 b c)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a c))
-Case conversion may be inaccurate. Consider using '#align finset.Ico_union_Ico_eq_Ico Finset.Ico_union_Ico_eq_Icoₓ'. -/
+#print Finset.Ico_union_Ico_eq_Ico /-
 theorem Ico_union_Ico_eq_Ico {a b c : α} (hab : a ≤ b) (hbc : b ≤ c) :
     Ico a b ∪ Ico b c = Ico a c := by
   rw [← coe_inj, coe_union, coe_Ico, coe_Ico, coe_Ico, Set.Ico_union_Ico_eq_Ico hab hbc]
 #align finset.Ico_union_Ico_eq_Ico Finset.Ico_union_Ico_eq_Ico
+-/
 
-/- warning: finset.Ioc_union_Ioc_eq_Ioc -> Finset.Ioc_union_Ioc_eq_Ioc is a dubious translation:
-lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 b c)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a c))
-but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b) -> (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b c) -> (Eq.{succ u1} (Finset.{u1} α) (Union.union.{u1} (Finset.{u1} α) (Finset.instUnionFinset.{u1} α (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a b) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 b c)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a c))
-Case conversion may be inaccurate. Consider using '#align finset.Ioc_union_Ioc_eq_Ioc Finset.Ioc_union_Ioc_eq_Iocₓ'. -/
+#print Finset.Ioc_union_Ioc_eq_Ioc /-
 @[simp]
 theorem Ioc_union_Ioc_eq_Ioc {a b c : α} (h₁ : a ≤ b) (h₂ : b ≤ c) : Ioc a b ∪ Ioc b c = Ioc a c :=
   by rw [← coe_inj, coe_union, coe_Ioc, coe_Ioc, coe_Ioc, Set.Ioc_union_Ioc_eq_Ioc h₁ h₂]
 #align finset.Ioc_union_Ioc_eq_Ioc Finset.Ioc_union_Ioc_eq_Ioc
+-/
 
-/- warning: finset.Ico_subset_Ico_union_Ico -> Finset.Ico_subset_Ico_union_Ico is a dubious translation:
-lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α}, HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a c) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 b c))
-but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a c) (Union.union.{u1} (Finset.{u1} α) (Finset.instUnionFinset.{u1} α (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a b) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 b c))
-Case conversion may be inaccurate. Consider using '#align finset.Ico_subset_Ico_union_Ico Finset.Ico_subset_Ico_union_Icoₓ'. -/
+#print Finset.Ico_subset_Ico_union_Ico /-
 theorem Ico_subset_Ico_union_Ico {a b c : α} : Ico a c ⊆ Ico a b ∪ Ico b c :=
   by
   rw [← coe_subset, coe_union, coe_Ico, coe_Ico, coe_Ico]
   exact Set.Ico_subset_Ico_union_Ico
 #align finset.Ico_subset_Ico_union_Ico Finset.Ico_subset_Ico_union_Ico
+-/
 
 /- warning: finset.Ico_union_Ico' -> Finset.Ico_union_Ico' is a dubious translation:
 lean 3 declaration is
@@ -1216,18 +1204,14 @@ end LocallyFiniteOrderTop
 
 variable [Fintype α] [LocallyFiniteOrderTop α] [LocallyFiniteOrderBot α]
 
-/- warning: finset.Ioi_disj_union_Iio -> Finset.Ioi_disjUnion_Iio is a dubious translation:
-lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : Fintype.{u1} α] [_inst_3 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] [_inst_4 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] (a : α), Eq.{succ u1} (Finset.{u1} α) (Finset.disjUnion.{u1} α (Finset.Ioi.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_3 a) (Finset.Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_4 a) (Finset.disjoint_Ioi_Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_3 _inst_4 a)) (HasCompl.compl.{u1} (Finset.{u1} α) (BooleanAlgebra.toHasCompl.{u1} (Finset.{u1} α) (Finset.booleanAlgebra.{u1} α _inst_2 (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b))) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.hasSingleton.{u1} α) a))
-but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : Fintype.{u1} α] [_inst_3 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] [_inst_4 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] (a : α), Eq.{succ u1} (Finset.{u1} α) (Finset.disjUnion.{u1} α (Finset.Ioi.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_3 a) (Finset.Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_4 a) (Finset.disjoint_Ioi_Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_3 _inst_4 a)) (HasCompl.compl.{u1} (Finset.{u1} α) (BooleanAlgebra.toHasCompl.{u1} (Finset.{u1} α) (Finset.booleanAlgebra.{u1} α _inst_2 (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b))) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.instSingletonFinset.{u1} α) a))
-Case conversion may be inaccurate. Consider using '#align finset.Ioi_disj_union_Iio Finset.Ioi_disjUnion_Iioₓ'. -/
+#print Finset.Ioi_disjUnion_Iio /-
 theorem Ioi_disjUnion_Iio (a : α) :
     (Ioi a).disjUnion (Iio a) (disjoint_Ioi_Iio a) = ({a} : Finset α)ᶜ :=
   by
   ext
   simp [eq_comm]
 #align finset.Ioi_disj_union_Iio Finset.Ioi_disjUnion_Iio
+-/
 
 end LinearOrder
 
@@ -1417,17 +1401,13 @@ theorem uIcc_of_not_ge (h : ¬b ≤ a) : [a, b] = Icc a b :=
 #align finset.uIcc_of_not_ge Finset.uIcc_of_not_ge
 -/
 
-/- warning: finset.uIcc_eq_union -> Finset.uIcc_eq_union is a dubious translation:
-lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α}, Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a b) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_2 b a))
-but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α}, Eq.{succ u1} (Finset.{u1} α) (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a b) (Union.union.{u1} (Finset.{u1} α) (Finset.instUnionFinset.{u1} α (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 a b) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_2 b a))
-Case conversion may be inaccurate. Consider using '#align finset.uIcc_eq_union Finset.uIcc_eq_unionₓ'. -/
+#print Finset.uIcc_eq_union /-
 theorem uIcc_eq_union : [a, b] = Icc a b ∪ Icc b a :=
   coe_injective <| by
     push_cast
     exact Set.uIcc_eq_union
 #align finset.uIcc_eq_union Finset.uIcc_eq_union
+-/
 
 #print Finset.mem_uIcc' /-
 theorem mem_uIcc' : a ∈ [b, c] ↔ b ≤ a ∧ a ≤ c ∨ c ≤ a ∧ a ≤ b := by simp [uIcc_eq_union]
@@ -1461,18 +1441,14 @@ theorem uIcc_subset_uIcc_iff_le :
   uIcc_subset_uIcc_iff_le'
 #align finset.uIcc_subset_uIcc_iff_le Finset.uIcc_subset_uIcc_iff_le
 
-/- warning: finset.uIcc_subset_uIcc_union_uIcc -> Finset.uIcc_subset_uIcc_union_uIcc is a dubious translation:
-lean 3 declaration is
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {a : α} {b : α} {c : α}, HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a c) (Union.union.{u1} (Finset.{u1} α) (Finset.hasUnion.{u1} α (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b)) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 a b) (Finset.uIcc.{u1} α (LinearOrder.toLattice.{u1} α _inst_1) _inst_2 b c))
-but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {a : α} {b : α} {c : α}, HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a c) (Union.union.{u1} (Finset.{u1} α) (Finset.instUnionFinset.{u1} α (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b)) (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 a b) (Finset.uIcc.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)) _inst_2 b c))
-Case conversion may be inaccurate. Consider using '#align finset.uIcc_subset_uIcc_union_uIcc Finset.uIcc_subset_uIcc_union_uIccₓ'. -/
+#print Finset.uIcc_subset_uIcc_union_uIcc /-
 /-- A sort of triangle inequality. -/
 theorem uIcc_subset_uIcc_union_uIcc : [a, c] ⊆ [a, b] ∪ [b, c] :=
   coe_subset.1 <| by
     push_cast
     exact Set.uIcc_subset_uIcc_union_uIcc
 #align finset.uIcc_subset_uIcc_union_uIcc Finset.uIcc_subset_uIcc_union_uIcc
+-/
 
 end LinearOrder

bump to nightly-2023-05-03-22

mathlib commit https://github.com/leanprover-community/mathlib/commit/36b8aa61ea7c05727161f96a0532897bd72aedab

aa7b8e08

Diff

@@ -1590,7 +1590,7 @@ variable [DecidableEq α]
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11228 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11230 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11228 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11230) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11216 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11218 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11216 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11218) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Icc Finset.image_add_left_Iccₓ'. -/
 @[simp]
 theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) :=
@@ -1603,7 +1603,7 @@ theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11329 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11331 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11329 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11331) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11317 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11319 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11317 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11319) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ico Finset.image_add_left_Icoₓ'. -/
 @[simp]
 theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) :=
@@ -1616,7 +1616,7 @@ theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11430 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11432 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11430 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11432) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11418 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11420 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11418 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11420) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioc Finset.image_add_left_Iocₓ'. -/
 @[simp]
 theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) :=
@@ -1629,7 +1629,7 @@ theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11531 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11533 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11531 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11533) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11519 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11521 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11519 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11521) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioo Finset.image_add_left_Iooₓ'. -/
 @[simp]
 theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) :=

bump to nightly-2023-04-28-18

mathlib commit https://github.com/leanprover-community/mathlib/commit/fa78268d4d77cb2b2fbc89f0527e2e7807763780

7a408b20

Diff

@@ -624,9 +624,11 @@ theorem BddBelow.finite {s : Set α} (hs : BddBelow s) : s.Finite :=
 #align bdd_below.finite BddBelow.finite
 -/
 
+#print Set.Infinite.not_bddBelow /-
 theorem Set.Infinite.not_bddBelow {s : Set α} : s.Infinite → ¬BddBelow s :=
   mt BddBelow.finite
 #align set.infinite.not_bdd_below Set.Infinite.not_bddBelow
+-/
 
 variable [Fintype α]
 
@@ -663,9 +665,11 @@ theorem BddAbove.finite {s : Set α} (hs : BddAbove s) : s.Finite :=
 #align bdd_above.finite BddAbove.finite
 -/
 
+#print Set.Infinite.not_bddAbove /-
 theorem Set.Infinite.not_bddAbove {s : Set α} : s.Infinite → ¬BddAbove s :=
   mt BddAbove.finite
 #align set.infinite.not_bdd_above Set.Infinite.not_bddAbove
+-/
 
 variable [Fintype α]
 
@@ -1162,10 +1166,22 @@ section LocallyFiniteOrderBot
 
 variable [LocallyFiniteOrderBot α] {s : Set α}
 
+/- warning: set.infinite.exists_gt -> Set.Infinite.exists_gt is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => And (Membership.mem.{u1, u1} α (Set.{u1} α) (Set.instMembershipSet.{u1} α) b s) (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b)))
+Case conversion may be inaccurate. Consider using '#align set.infinite.exists_gt Set.Infinite.exists_gtₓ'. -/
 theorem Set.Infinite.exists_gt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, a < b :=
   not_bddAbove_iff.1 hs.not_bddAbove
 #align set.infinite.exists_gt Set.Infinite.exists_gt
 
+/- warning: set.infinite_iff_exists_gt -> Set.infinite_iff_exists_gt is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) a b)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => And (Membership.mem.{u1, u1} α (Set.{u1} α) (Set.instMembershipSet.{u1} α) b s) (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) a b)))
+Case conversion may be inaccurate. Consider using '#align set.infinite_iff_exists_gt Set.infinite_iff_exists_gtₓ'. -/
 theorem Set.infinite_iff_exists_gt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, a < b :=
   ⟨Set.Infinite.exists_gt, Set.infinite_of_forall_exists_gt⟩
 #align set.infinite_iff_exists_gt Set.infinite_iff_exists_gt
@@ -1176,10 +1192,22 @@ section LocallyFiniteOrderTop
 
 variable [LocallyFiniteOrderTop α] {s : Set α}
 
+/- warning: set.infinite.exists_lt -> Set.Infinite.exists_lt is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b a)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {s : Set.{u1} α}, (Set.Infinite.{u1} α s) -> (forall (a : α), Exists.{succ u1} α (fun (b : α) => And (Membership.mem.{u1, u1} α (Set.{u1} α) (Set.instMembershipSet.{u1} α) b s) (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b a)))
+Case conversion may be inaccurate. Consider using '#align set.infinite.exists_lt Set.Infinite.exists_ltₓ'. -/
 theorem Set.Infinite.exists_lt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, b < a :=
   not_bddBelow_iff.1 hs.not_bddBelow
 #align set.infinite.exists_lt Set.Infinite.exists_lt
 
+/- warning: set.infinite_iff_exists_lt -> Set.infinite_iff_exists_lt is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => Exists.{0} (Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) (fun (H : Membership.Mem.{u1, u1} α (Set.{u1} α) (Set.hasMem.{u1} α) b s) => LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))) b a)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] {s : Set.{u1} α} [_inst_3 : Nonempty.{succ u1} α], Iff (Set.Infinite.{u1} α s) (forall (a : α), Exists.{succ u1} α (fun (b : α) => And (Membership.mem.{u1, u1} α (Set.{u1} α) (Set.instMembershipSet.{u1} α) b s) (LT.lt.{u1} α (Preorder.toLT.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))) b a)))
+Case conversion may be inaccurate. Consider using '#align set.infinite_iff_exists_lt Set.infinite_iff_exists_ltₓ'. -/
 theorem Set.infinite_iff_exists_lt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, b < a :=
   ⟨Set.Infinite.exists_lt, Set.infinite_of_forall_exists_lt⟩
 #align set.infinite_iff_exists_lt Set.infinite_iff_exists_lt
@@ -1562,7 +1590,7 @@ variable [DecidableEq α]
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10974 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10976 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10974 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10976) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11228 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11230 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11228 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11230) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Icc Finset.image_add_left_Iccₓ'. -/
 @[simp]
 theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) :=
@@ -1575,7 +1603,7 @@ theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11075 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11077 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11075 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11077) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11329 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11331 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11329 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11331) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ico Finset.image_add_left_Icoₓ'. -/
 @[simp]
 theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) :=
@@ -1588,7 +1616,7 @@ theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11176 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11178 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11176 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11178) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11430 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11432 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11430 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11432) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioc Finset.image_add_left_Iocₓ'. -/
 @[simp]
 theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) :=
@@ -1601,7 +1629,7 @@ theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11277 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11279 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11277 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11279) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11531 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11533 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11531 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11533) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioo Finset.image_add_left_Iooₓ'. -/
 @[simp]
 theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) :=

bump to nightly-2023-04-27-02

mathlib commit https://github.com/leanprover-community/mathlib/commit/9b2b58d6b14b895b2f375108e765cb47de71aebd

5e92de8b

Diff

@@ -4,7 +4,7 @@ Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 
 ! This file was ported from Lean 3 source module data.finset.locally_finite
-! leanprover-community/mathlib commit f24cc2891c0e328f0ee8c57387103aa462c44b5e
+! leanprover-community/mathlib commit 52fa514ec337dd970d71d8de8d0fd68b455a1e54
 ! Please do not edit these lines, except to modify the commit id
 ! if you have ported upstream changes.
 -/
@@ -624,6 +624,10 @@ theorem BddBelow.finite {s : Set α} (hs : BddBelow s) : s.Finite :=
 #align bdd_below.finite BddBelow.finite
 -/
 
+theorem Set.Infinite.not_bddBelow {s : Set α} : s.Infinite → ¬BddBelow s :=
+  mt BddBelow.finite
+#align set.infinite.not_bdd_below Set.Infinite.not_bddBelow
+
 variable [Fintype α]
 
 #print Finset.filter_lt_eq_Ioi /-
@@ -659,6 +663,10 @@ theorem BddAbove.finite {s : Set α} (hs : BddAbove s) : s.Finite :=
 #align bdd_above.finite BddAbove.finite
 -/
 
+theorem Set.Infinite.not_bddAbove {s : Set α} : s.Infinite → ¬BddAbove s :=
+  mt BddAbove.finite
+#align set.infinite.not_bdd_above Set.Infinite.not_bddAbove
+
 variable [Fintype α]
 
 #print Finset.filter_gt_eq_Iio /-
@@ -1150,6 +1158,34 @@ theorem Ico_diff_Ico_right (a b c : α) : Ico a b \ Ico c b = Ico a (min b c) :=
 
 end LocallyFiniteOrder
 
+section LocallyFiniteOrderBot
+
+variable [LocallyFiniteOrderBot α] {s : Set α}
+
+theorem Set.Infinite.exists_gt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, a < b :=
+  not_bddAbove_iff.1 hs.not_bddAbove
+#align set.infinite.exists_gt Set.Infinite.exists_gt
+
+theorem Set.infinite_iff_exists_gt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, a < b :=
+  ⟨Set.Infinite.exists_gt, Set.infinite_of_forall_exists_gt⟩
+#align set.infinite_iff_exists_gt Set.infinite_iff_exists_gt
+
+end LocallyFiniteOrderBot
+
+section LocallyFiniteOrderTop
+
+variable [LocallyFiniteOrderTop α] {s : Set α}
+
+theorem Set.Infinite.exists_lt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, b < a :=
+  not_bddBelow_iff.1 hs.not_bddBelow
+#align set.infinite.exists_lt Set.Infinite.exists_lt
+
+theorem Set.infinite_iff_exists_lt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, b < a :=
+  ⟨Set.Infinite.exists_lt, Set.infinite_of_forall_exists_lt⟩
+#align set.infinite_iff_exists_lt Set.infinite_iff_exists_lt
+
+end LocallyFiniteOrderTop
+
 variable [Fintype α] [LocallyFiniteOrderTop α] [LocallyFiniteOrderBot α]
 
 /- warning: finset.Ioi_disj_union_Iio -> Finset.Ioi_disjUnion_Iio is a dubious translation:

bump to nightly-2023-03-18-12

mathlib commit https://github.com/leanprover-community/mathlib/commit/02ba8949f486ebecf93fe7460f1ed0564b5e442c

19ae714b

Diff

@@ -836,15 +836,19 @@ theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_
 #align finset.Icc_eq_cons_Ioc Finset.Icc_eq_cons_Ioc
 -/
 
+#print Finset.Ioc_eq_cons_Ioo /-
 /-- `finset.cons` version of `finset.Ioo_insert_right`. -/
 theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by
   classical rw [cons_eq_insert, Ioo_insert_right h]
 #align finset.Ioc_eq_cons_Ioo Finset.Ioc_eq_cons_Ioo
+-/
 
+#print Finset.Ico_eq_cons_Ioo /-
 /-- `finset.cons` version of `finset.Ioo_insert_left`. -/
 theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by
   classical rw [cons_eq_insert, Ioo_insert_left h]
 #align finset.Ico_eq_cons_Ioo Finset.Ico_eq_cons_Ioo
+-/
 
 #print Finset.Ico_filter_le_left /-
 theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
@@ -1522,7 +1526,7 @@ variable [DecidableEq α]
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10886 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10888 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10886 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10888) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10974 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10976 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10974 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10976) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Icc Finset.image_add_left_Iccₓ'. -/
 @[simp]
 theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) :=
@@ -1535,7 +1539,7 @@ theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10987 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10989 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10987 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10989) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11075 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11077 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11075 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11077) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ico Finset.image_add_left_Icoₓ'. -/
 @[simp]
 theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) :=
@@ -1548,7 +1552,7 @@ theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11088 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11090 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11088 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11090) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11176 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11178 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11176 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11178) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioc Finset.image_add_left_Iocₓ'. -/
 @[simp]
 theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) :=
@@ -1561,7 +1565,7 @@ theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11189 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11191 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11189 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11191) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11277 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11279 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11277 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11279) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioo Finset.image_add_left_Iooₓ'. -/
 @[simp]
 theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) :=

bump to nightly-2023-03-12-03

mathlib commit https://github.com/leanprover-community/mathlib/commit/f24cc2891c0e328f0ee8c57387103aa462c44b5e

5e501a2f

Diff

@@ -4,7 +4,7 @@ Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 
 ! This file was ported from Lean 3 source module data.finset.locally_finite
-! leanprover-community/mathlib commit a11f9106a169dd302a285019e5165f8ab32ff433
+! leanprover-community/mathlib commit f24cc2891c0e328f0ee8c57387103aa462c44b5e
 ! Please do not edit these lines, except to modify the commit id
 ! if you have ported upstream changes.
 -/
@@ -823,17 +823,29 @@ end DecidableEq
 
 #print Finset.Icc_eq_cons_Ico /-
 -- Those lemmas are purposefully the other way around
+/-- `finset.cons` version of `finset.Ico_insert_right`. -/
 theorem Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico := by
   classical rw [cons_eq_insert, Ico_insert_right h]
 #align finset.Icc_eq_cons_Ico Finset.Icc_eq_cons_Ico
 -/
 
 #print Finset.Icc_eq_cons_Ioc /-
+/-- `finset.cons` version of `finset.Ioc_insert_left`. -/
 theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc := by
   classical rw [cons_eq_insert, Ioc_insert_left h]
 #align finset.Icc_eq_cons_Ioc Finset.Icc_eq_cons_Ioc
 -/
 
+/-- `finset.cons` version of `finset.Ioo_insert_right`. -/
+theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by
+  classical rw [cons_eq_insert, Ioo_insert_right h]
+#align finset.Ioc_eq_cons_Ioo Finset.Ioc_eq_cons_Ioo
+
+/-- `finset.cons` version of `finset.Ioo_insert_left`. -/
+theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by
+  classical rw [cons_eq_insert, Ioo_insert_left h]
+#align finset.Ico_eq_cons_Ioo Finset.Ico_eq_cons_Ioo
+
 #print Finset.Ico_filter_le_left /-
 theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
     ((Ico a b).filterₓ fun x => x ≤ a) = {a} :=
@@ -848,7 +860,7 @@ theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
 theorem card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card - 1 := by
   classical
     by_cases h : a ≤ b
-    · rw [← Ico_insert_right h, card_insert_of_not_mem right_not_mem_Ico]
+    · rw [Icc_eq_cons_Ico h, card_cons]
       exact (Nat.add_sub_cancel _ _).symm
     · rw [Ico_eq_empty fun h' => h h'.le, Icc_eq_empty h, card_empty, zero_tsub]
 #align finset.card_Ico_eq_card_Icc_sub_one Finset.card_Ico_eq_card_Icc_sub_one
@@ -863,12 +875,10 @@ theorem card_Ioc_eq_card_Icc_sub_one (a b : α) : (Ioc a b).card = (Icc a b).car
 #print Finset.card_Ioo_eq_card_Ico_sub_one /-
 theorem card_Ioo_eq_card_Ico_sub_one (a b : α) : (Ioo a b).card = (Ico a b).card - 1 := by
   classical
-    by_cases h : a ≤ b
-    · obtain rfl | h' := h.eq_or_lt
-      · rw [Ioo_self, Ico_self, card_empty]
-      rw [← Ioo_insert_left h', card_insert_of_not_mem left_not_mem_Ioo]
+    by_cases h : a < b
+    · rw [Ico_eq_cons_Ioo h, card_cons]
       exact (Nat.add_sub_cancel _ _).symm
-    · rw [Ioo_eq_empty fun h' => h h'.le, Ico_eq_empty fun h' => h h'.le, card_empty, zero_tsub]
+    · rw [Ioo_eq_empty h, Ico_eq_empty h, card_empty, zero_tsub]
 #align finset.card_Ioo_eq_card_Ico_sub_one Finset.card_Ioo_eq_card_Ico_sub_one
 -/
 
@@ -922,6 +932,7 @@ theorem not_mem_Ioi_self {b : α} : b ∉ Ioi b := fun h => lt_irrefl _ (mem_Ioi
 
 #print Finset.Ici_eq_cons_Ioi /-
 -- Purposefully written the other way around
+/-- `finset.cons` version of `finset.Ioi_insert`. -/
 theorem Ici_eq_cons_Ioi (a : α) : Ici a = (Ioi a).cons a not_mem_Ioi_self := by
   classical rw [cons_eq_insert, Ioi_insert]
 #align finset.Ici_eq_cons_Ioi Finset.Ici_eq_cons_Ioi
@@ -965,6 +976,7 @@ theorem not_mem_Iio_self {b : α} : b ∉ Iio b := fun h => lt_irrefl _ (mem_Iio
 
 #print Finset.Iic_eq_cons_Iio /-
 -- Purposefully written the other way around
+/-- `finset.cons` version of `finset.Iio_insert`. -/
 theorem Iic_eq_cons_Iio (b : α) : Iic b = (Iio b).cons b not_mem_Iio_self := by
   classical rw [cons_eq_insert, Iio_insert]
 #align finset.Iic_eq_cons_Iio Finset.Iic_eq_cons_Iio

bump to nightly-2023-03-11-22

mathlib commit https://github.com/leanprover-community/mathlib/commit/3180fab693e2cee3bff62675571264cb8778b212

a8ee822f

Diff

@@ -1510,7 +1510,7 @@ variable [DecidableEq α]
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10884 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10886 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10884 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10886) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10886 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10888 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10886 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10888) c) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Icc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Icc Finset.image_add_left_Iccₓ'. -/
 @[simp]
 theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) :=
@@ -1523,7 +1523,7 @@ theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10985 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10987 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10985 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10987) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10987 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10989 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10987 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.10989) c) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ico.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ico Finset.image_add_left_Icoₓ'. -/
 @[simp]
 theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) :=
@@ -1536,7 +1536,7 @@ theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11086 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11088 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11086 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11088) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11088 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11090 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11088 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11090) c) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioc.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioc Finset.image_add_left_Iocₓ'. -/
 @[simp]
 theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) :=
@@ -1549,7 +1549,7 @@ theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toHasAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11187 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11189 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11187 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11189) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
+  forall {α : Type.{u1}} [_inst_1 : OrderedCancelAddCommMonoid.{u1} α] [_inst_2 : ExistsAddOfLE.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1)))))) (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)))] [_inst_3 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1))] [_inst_4 : DecidableEq.{succ u1} α] (a : α) (b : α) (c : α), Eq.{succ u1} (Finset.{u1} α) (Finset.image.{u1, u1} α α (fun (a : α) (b : α) => _inst_4 a b) ((fun (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11189 : α) (x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11191 : α) => HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11189 x._@.Mathlib.Data.Finset.LocallyFinite._hyg.11191) c) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 a b)) (Finset.Ioo.{u1} α (PartialOrder.toPreorder.{u1} α (OrderedCancelAddCommMonoid.toPartialOrder.{u1} α _inst_1)) _inst_3 (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c a) (HAdd.hAdd.{u1, u1, u1} α α α (instHAdd.{u1} α (AddZeroClass.toAdd.{u1} α (AddMonoid.toAddZeroClass.{u1} α (AddRightCancelMonoid.toAddMonoid.{u1} α (AddCancelMonoid.toAddRightCancelMonoid.{u1} α (AddCancelCommMonoid.toAddCancelMonoid.{u1} α (OrderedCancelAddCommMonoid.toCancelAddCommMonoid.{u1} α _inst_1))))))) c b))
 Case conversion may be inaccurate. Consider using '#align finset.image_add_left_Ioo Finset.image_add_left_Iooₓ'. -/
 @[simp]
 theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) :=

bump to nightly-2023-03-11-18

mathlib commit https://github.com/leanprover-community/mathlib/commit/3180fab693e2cee3bff62675571264cb8778b212

1d00e3b6

Diff

@@ -1140,7 +1140,7 @@ variable [Fintype α] [LocallyFiniteOrderTop α] [LocallyFiniteOrderBot α]
 lean 3 declaration is
   forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : Fintype.{u1} α] [_inst_3 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] [_inst_4 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1))))] (a : α), Eq.{succ u1} (Finset.{u1} α) (Finset.disjUnion.{u1} α (Finset.Ioi.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_3 a) (Finset.Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_4 a) (Finset.disjoint_Ioi_Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (LinearOrder.toLattice.{u1} α _inst_1)))) _inst_3 _inst_4 a)) (HasCompl.compl.{u1} (Finset.{u1} α) (BooleanAlgebra.toHasCompl.{u1} (Finset.{u1} α) (Finset.booleanAlgebra.{u1} α _inst_2 (fun (a : α) (b : α) => Eq.decidable.{u1} α _inst_1 a b))) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.hasSingleton.{u1} α) a))
 but is expected to have type
-  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : Fintype.{u1} α] [_inst_3 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] [_inst_4 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] (a : α), Eq.{succ u1} (Finset.{u1} α) (Finset.disjUnion.{u1} α (Finset.Ioi.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_3 a) (Finset.Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_4 a) (Finset.disjoint_Ioi_Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_3 _inst_4 a)) (HasCompl.compl.{u1} (Finset.{u1} α) (BooleanAlgebra.toHasCompl.{u1} (Finset.{u1} α) (Finset.instBooleanAlgebraFinset.{u1} α _inst_2 (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b))) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.instSingletonFinset.{u1} α) a))
+  forall {α : Type.{u1}} [_inst_1 : LinearOrder.{u1} α] [_inst_2 : Fintype.{u1} α] [_inst_3 : LocallyFiniteOrderTop.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] [_inst_4 : LocallyFiniteOrderBot.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1)))))] (a : α), Eq.{succ u1} (Finset.{u1} α) (Finset.disjUnion.{u1} α (Finset.Ioi.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_3 a) (Finset.Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_4 a) (Finset.disjoint_Ioi_Iio.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α (DistribLattice.toLattice.{u1} α (instDistribLattice.{u1} α _inst_1))))) _inst_3 _inst_4 a)) (HasCompl.compl.{u1} (Finset.{u1} α) (BooleanAlgebra.toHasCompl.{u1} (Finset.{u1} α) (Finset.booleanAlgebra.{u1} α _inst_2 (fun (a : α) (b : α) => instDecidableEq.{u1} α _inst_1 a b))) (Singleton.singleton.{u1, u1} α (Finset.{u1} α) (Finset.instSingletonFinset.{u1} α) a))
 Case conversion may be inaccurate. Consider using '#align finset.Ioi_disj_union_Iio Finset.Ioi_disjUnion_Iioₓ'. -/
 theorem Ioi_disjUnion_Iio (a : α) :
     (Ioi a).disjUnion (Iio a) (disjoint_Ioi_Iio a) = ({a} : Finset α)ᶜ :=
@@ -1613,7 +1613,7 @@ end OrderedCancelAddCommMonoid
 lean 3 declaration is
   forall {ι : Type.{u1}} {α : Type.{u2}} [_inst_1 : Fintype.{u1} ι] [_inst_2 : LinearOrder.{u1} ι] [_inst_3 : LocallyFiniteOrderTop.{u1} ι (PartialOrder.toPreorder.{u1} ι (SemilatticeInf.toPartialOrder.{u1} ι (Lattice.toSemilatticeInf.{u1} ι (LinearOrder.toLattice.{u1} ι _inst_2))))] [_inst_4 : LocallyFiniteOrderBot.{u1} ι (PartialOrder.toPreorder.{u1} ι (SemilatticeInf.toPartialOrder.{u1} ι (Lattice.toSemilatticeInf.{u1} ι (LinearOrder.toLattice.{u1} ι _inst_2))))] [_inst_5 : CommMonoid.{u2} α] (f : ι -> ι -> α), Eq.{succ u2} α (Finset.prod.{u2, u1} α ι _inst_5 (Finset.univ.{u1} ι _inst_1) (fun (i : ι) => Finset.prod.{u2, u1} α ι _inst_5 (Finset.Ioi.{u1} ι (PartialOrder.toPreorder.{u1} ι (SemilatticeInf.toPartialOrder.{u1} ι (Lattice.toSemilatticeInf.{u1} ι (LinearOrder.toLattice.{u1} ι _inst_2)))) _inst_3 i) (fun (j : ι) => HMul.hMul.{u2, u2, u2} α α α (instHMul.{u2} α (MulOneClass.toHasMul.{u2} α (Monoid.toMulOneClass.{u2} α (CommMonoid.toMonoid.{u2} α _inst_5)))) (f j i) (f i j)))) (Finset.prod.{u2, u1} α ι _inst_5 (Finset.univ.{u1} ι _inst_1) (fun (i : ι) => Finset.prod.{u2, u1} α ι _inst_5 (HasCompl.compl.{u1} (Finset.{u1} ι) (BooleanAlgebra.toHasCompl.{u1} (Finset.{u1} ι) (Finset.booleanAlgebra.{u1} ι _inst_1 (fun (a : ι) (b : ι) => Eq.decidable.{u1} ι _inst_2 a b))) (Singleton.singleton.{u1, u1} ι (Finset.{u1} ι) (Finset.hasSingleton.{u1} ι) i)) (fun (j : ι) => f j i)))
 but is expected to have type
-  forall {ι : Type.{u2}} {α : Type.{u1}} [_inst_1 : Fintype.{u2} ι] [_inst_2 : LinearOrder.{u2} ι] [_inst_3 : LocallyFiniteOrderTop.{u2} ι (PartialOrder.toPreorder.{u2} ι (SemilatticeInf.toPartialOrder.{u2} ι (Lattice.toSemilatticeInf.{u2} ι (DistribLattice.toLattice.{u2} ι (instDistribLattice.{u2} ι _inst_2)))))] [_inst_4 : LocallyFiniteOrderBot.{u2} ι (PartialOrder.toPreorder.{u2} ι (SemilatticeInf.toPartialOrder.{u2} ι (Lattice.toSemilatticeInf.{u2} ι (DistribLattice.toLattice.{u2} ι (instDistribLattice.{u2} ι _inst_2)))))] [_inst_5 : CommMonoid.{u1} α] (f : ι -> ι -> α), Eq.{succ u1} α (Finset.prod.{u1, u2} α ι _inst_5 (Finset.univ.{u2} ι _inst_1) (fun (i : ι) => Finset.prod.{u1, u2} α ι _inst_5 (Finset.Ioi.{u2} ι (PartialOrder.toPreorder.{u2} ι (SemilatticeInf.toPartialOrder.{u2} ι (Lattice.toSemilatticeInf.{u2} ι (DistribLattice.toLattice.{u2} ι (instDistribLattice.{u2} ι _inst_2))))) _inst_3 i) (fun (j : ι) => HMul.hMul.{u1, u1, u1} α α α (instHMul.{u1} α (MulOneClass.toMul.{u1} α (Monoid.toMulOneClass.{u1} α (CommMonoid.toMonoid.{u1} α _inst_5)))) (f j i) (f i j)))) (Finset.prod.{u1, u2} α ι _inst_5 (Finset.univ.{u2} ι _inst_1) (fun (i : ι) => Finset.prod.{u1, u2} α ι _inst_5 (HasCompl.compl.{u2} (Finset.{u2} ι) (BooleanAlgebra.toHasCompl.{u2} (Finset.{u2} ι) (Finset.instBooleanAlgebraFinset.{u2} ι _inst_1 (fun (a : ι) (b : ι) => instDecidableEq.{u2} ι _inst_2 a b))) (Singleton.singleton.{u2, u2} ι (Finset.{u2} ι) (Finset.instSingletonFinset.{u2} ι) i)) (fun (j : ι) => f j i)))
+  forall {ι : Type.{u2}} {α : Type.{u1}} [_inst_1 : Fintype.{u2} ι] [_inst_2 : LinearOrder.{u2} ι] [_inst_3 : LocallyFiniteOrderTop.{u2} ι (PartialOrder.toPreorder.{u2} ι (SemilatticeInf.toPartialOrder.{u2} ι (Lattice.toSemilatticeInf.{u2} ι (DistribLattice.toLattice.{u2} ι (instDistribLattice.{u2} ι _inst_2)))))] [_inst_4 : LocallyFiniteOrderBot.{u2} ι (PartialOrder.toPreorder.{u2} ι (SemilatticeInf.toPartialOrder.{u2} ι (Lattice.toSemilatticeInf.{u2} ι (DistribLattice.toLattice.{u2} ι (instDistribLattice.{u2} ι _inst_2)))))] [_inst_5 : CommMonoid.{u1} α] (f : ι -> ι -> α), Eq.{succ u1} α (Finset.prod.{u1, u2} α ι _inst_5 (Finset.univ.{u2} ι _inst_1) (fun (i : ι) => Finset.prod.{u1, u2} α ι _inst_5 (Finset.Ioi.{u2} ι (PartialOrder.toPreorder.{u2} ι (SemilatticeInf.toPartialOrder.{u2} ι (Lattice.toSemilatticeInf.{u2} ι (DistribLattice.toLattice.{u2} ι (instDistribLattice.{u2} ι _inst_2))))) _inst_3 i) (fun (j : ι) => HMul.hMul.{u1, u1, u1} α α α (instHMul.{u1} α (MulOneClass.toMul.{u1} α (Monoid.toMulOneClass.{u1} α (CommMonoid.toMonoid.{u1} α _inst_5)))) (f j i) (f i j)))) (Finset.prod.{u1, u2} α ι _inst_5 (Finset.univ.{u2} ι _inst_1) (fun (i : ι) => Finset.prod.{u1, u2} α ι _inst_5 (HasCompl.compl.{u2} (Finset.{u2} ι) (BooleanAlgebra.toHasCompl.{u2} (Finset.{u2} ι) (Finset.booleanAlgebra.{u2} ι _inst_1 (fun (a : ι) (b : ι) => instDecidableEq.{u2} ι _inst_2 a b))) (Singleton.singleton.{u2, u2} ι (Finset.{u2} ι) (Finset.instSingletonFinset.{u2} ι) i)) (fun (j : ι) => f j i)))
 Case conversion may be inaccurate. Consider using '#align finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag Finset.prod_prod_Ioi_mul_eq_prod_prod_off_diagₓ'. -/
 @[to_additive]
 theorem prod_prod_Ioi_mul_eq_prod_prod_off_diag [Fintype ι] [LinearOrder ι]

bump to nightly-2023-02-28-04

mathlib commit https://github.com/leanprover-community/mathlib/commit/9da1b3534b65d9661eb8f42443598a92bbb49211

2097f8af

Diff

@@ -1251,11 +1251,15 @@ theorem uIcc_subset_uIcc_iff_mem : [a₁, b₁] ⊆ [a₂, b₂] ↔ a₁ ∈ [a
 #align finset.uIcc_subset_uIcc_iff_mem Finset.uIcc_subset_uIcc_iff_mem
 -/
 
-#print Finset.uIcc_subset_uIcc_iff_le' /-
+/- warning: finset.uIcc_subset_uIcc_iff_le' -> Finset.uIcc_subset_uIcc_iff_le' is a dubious translation:
+lean 3 declaration is
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.hasSubset.{u1} α) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Inf.inf.{u1} α (SemilatticeInf.toHasInf.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)) a₂ b₂) (Inf.inf.{u1} α (SemilatticeInf.toHasInf.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)) a₁ b₁)) (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Sup.sup.{u1} α (SemilatticeSup.toHasSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₁ b₁) (Sup.sup.{u1} α (SemilatticeSup.toHasSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₂ b₂)))
+but is expected to have type
+  forall {α : Type.{u1}} [_inst_1 : Lattice.{u1} α] [_inst_2 : LocallyFiniteOrder.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))] {a₁ : α} {a₂ : α} {b₁ : α} {b₂ : α}, Iff (HasSubset.Subset.{u1} (Finset.{u1} α) (Finset.instHasSubsetFinset.{u1} α) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₁ b₁) (Finset.uIcc.{u1} α _inst_1 _inst_2 a₂ b₂)) (And (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Inf.inf.{u1} α (Lattice.toInf.{u1} α _inst_1) a₂ b₂) (Inf.inf.{u1} α (Lattice.toInf.{u1} α _inst_1) a₁ b₁)) (LE.le.{u1} α (Preorder.toLE.{u1} α (PartialOrder.toPreorder.{u1} α (SemilatticeInf.toPartialOrder.{u1} α (Lattice.toSemilatticeInf.{u1} α _inst_1)))) (Sup.sup.{u1} α (SemilatticeSup.toSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₁ b₁) (Sup.sup.{u1} α (SemilatticeSup.toSup.{u1} α (Lattice.toSemilatticeSup.{u1} α _inst_1)) a₂ b₂)))
+Case conversion may be inaccurate. Consider using '#align finset.uIcc_subset_uIcc_iff_le' Finset.uIcc_subset_uIcc_iff_le'ₓ'. -/
 theorem uIcc_subset_uIcc_iff_le' : [a₁, b₁] ⊆ [a₂, b₂] ↔ a₂ ⊓ b₂ ≤ a₁ ⊓ b₁ ∧ a₁ ⊔ b₁ ≤ a₂ ⊔ b₂ :=
   Icc_subset_Icc_iff inf_le_sup
 #align finset.uIcc_subset_uIcc_iff_le' Finset.uIcc_subset_uIcc_iff_le'
--/
 
 #print Finset.uIcc_subset_uIcc_right /-
 theorem uIcc_subset_uIcc_right (h : x ∈ [a, b]) : [x, b] ⊆ [a, b] :=

bump to nightly-2023-02-21-16

mathlib commit https://github.com/leanprover-community/mathlib/commit/bd9851ca476957ea4549eb19b40e7b5ade9428cc

1107b979

Changes in mathlib4

mathlib3

mathlib4

chore: remove unnecessary cdots (#12417)

These · are scoping when there is a single active goal.

These were found using a modification of the linter at #12339.

5450e922

Diff

@@ -1170,7 +1170,7 @@ lemma strictMono_iff_forall_covBy [Preorder α] [LocallyFiniteOrder α] [Preorde
   refine ⟨fun hf _ _ h ↦ hf h.lt, fun h a b hab ↦ ?_⟩
   have := Relation.TransGen.lift f h (a := a) (b := b)
   rw [← lt_iff_transGen_covBy, transGen_eq_self (@lt_trans β _)] at this
-  · exact this hab
+  exact this hab
 
 /-- A function from a locally finite preorder is antitone if and only if it is antitone when
 restricted to pairs satisfying `a ⩿ b`. -/

chore: Move intervals (#11765)

Move Set.Ixx, Finset.Ixx, Multiset.Ixx together under two different folders:

Order.Interval for their definition and basic properties
Algebra.Order.Interval for their algebraic properties

Move the definitions of Multiset.Ixx to what is now Order.Interval.Multiset. I believe we could just delete this file in a later PR as nothing uses it (and I already had doubts when defining Multiset.Ixx three years ago).

Move the algebraic results out of what is now Order.Interval.Finset.Basic to a new file Algebra.Order.Interval.Finset.Basic.

c7fa7063

Diff

@@ -4,8 +4,7 @@ Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 -/
 import Mathlib.Order.Cover
-import Mathlib.Order.LocallyFinite
-import Mathlib.Data.Set.Intervals.Monoid
+import Mathlib.Order.Interval.Finset.Defs
 
 #align_import data.finset.locally_finite from "leanprover-community/mathlib"@"442a83d738cb208d3600056c489be16900ba701d"
 
@@ -13,7 +12,7 @@ import Mathlib.Data.Set.Intervals.Monoid
 # Intervals as finsets
 
 This file provides basic results about all the `Finset.Ixx`, which are defined in
-`Order.LocallyFinite`.
+`Order.Interval.Finset.Defs`.
 
 In addition, it shows that in a locally finite order `≤` and `<` are the transitive closures of,
 respectively, `⩿` and `⋖`, which then leads to a characterization of monotone and strictly
@@ -1066,107 +1065,6 @@ theorem uIcc_subset_uIcc_union_uIcc : [[a, c]] ⊆ [[a, b]] ∪ [[b, c]] :=
 #align finset.uIcc_subset_uIcc_union_uIcc Finset.uIcc_subset_uIcc_union_uIcc
 
 end LinearOrder
-
-section OrderedCancelAddCommMonoid
-
-variable [OrderedCancelAddCommMonoid α] [ExistsAddOfLE α] [LocallyFiniteOrder α]
-
-@[simp]
-theorem map_add_left_Icc (a b c : α) :
-    (Icc a b).map (addLeftEmbedding c) = Icc (c + a) (c + b) := by
-  rw [← coe_inj, coe_map, coe_Icc, coe_Icc]
-  exact Set.image_const_add_Icc _ _ _
-#align finset.map_add_left_Icc Finset.map_add_left_Icc
-
-@[simp]
-theorem map_add_right_Icc (a b c : α) :
-    (Icc a b).map (addRightEmbedding c) = Icc (a + c) (b + c) := by
-  rw [← coe_inj, coe_map, coe_Icc, coe_Icc]
-  exact Set.image_add_const_Icc _ _ _
-#align finset.map_add_right_Icc Finset.map_add_right_Icc
-
-@[simp]
-theorem map_add_left_Ico (a b c : α) :
-    (Ico a b).map (addLeftEmbedding c) = Ico (c + a) (c + b) := by
-  rw [← coe_inj, coe_map, coe_Ico, coe_Ico]
-  exact Set.image_const_add_Ico _ _ _
-#align finset.map_add_left_Ico Finset.map_add_left_Ico
-
-@[simp]
-theorem map_add_right_Ico (a b c : α) :
-    (Ico a b).map (addRightEmbedding c) = Ico (a + c) (b + c) := by
-  rw [← coe_inj, coe_map, coe_Ico, coe_Ico]
-  exact Set.image_add_const_Ico _ _ _
-#align finset.map_add_right_Ico Finset.map_add_right_Ico
-
-@[simp]
-theorem map_add_left_Ioc (a b c : α) :
-    (Ioc a b).map (addLeftEmbedding c) = Ioc (c + a) (c + b) := by
-  rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]
-  exact Set.image_const_add_Ioc _ _ _
-#align finset.map_add_left_Ioc Finset.map_add_left_Ioc
-
-@[simp]
-theorem map_add_right_Ioc (a b c : α) :
-    (Ioc a b).map (addRightEmbedding c) = Ioc (a + c) (b + c) := by
-  rw [← coe_inj, coe_map, coe_Ioc, coe_Ioc]
-  exact Set.image_add_const_Ioc _ _ _
-#align finset.map_add_right_Ioc Finset.map_add_right_Ioc
-
-@[simp]
-theorem map_add_left_Ioo (a b c : α) :
-    (Ioo a b).map (addLeftEmbedding c) = Ioo (c + a) (c + b) := by
-  rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]
-  exact Set.image_const_add_Ioo _ _ _
-#align finset.map_add_left_Ioo Finset.map_add_left_Ioo
-
-@[simp]
-theorem map_add_right_Ioo (a b c : α) :
-    (Ioo a b).map (addRightEmbedding c) = Ioo (a + c) (b + c) := by
-  rw [← coe_inj, coe_map, coe_Ioo, coe_Ioo]
-  exact Set.image_add_const_Ioo _ _ _
-#align finset.map_add_right_Ioo Finset.map_add_right_Ioo
-
-variable [DecidableEq α]
-
-@[simp]
-theorem image_add_left_Icc (a b c : α) : (Icc a b).image (c + ·) = Icc (c + a) (c + b) := by
-  rw [← map_add_left_Icc, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
-#align finset.image_add_left_Icc Finset.image_add_left_Icc
-
-@[simp]
-theorem image_add_left_Ico (a b c : α) : (Ico a b).image (c + ·) = Ico (c + a) (c + b) := by
-  rw [← map_add_left_Ico, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
-#align finset.image_add_left_Ico Finset.image_add_left_Ico
-
-@[simp]
-theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image (c + ·) = Ioc (c + a) (c + b) := by
-  rw [← map_add_left_Ioc, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
-#align finset.image_add_left_Ioc Finset.image_add_left_Ioc
-
-@[simp]
-theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image (c + ·) = Ioo (c + a) (c + b) := by
-  rw [← map_add_left_Ioo, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
-#align finset.image_add_left_Ioo Finset.image_add_left_Ioo
-
-@[simp]
-theorem image_add_right_Icc (a b c : α) : (Icc a b).image (· + c) = Icc (a + c) (b + c) := by
-  rw [← map_add_right_Icc, map_eq_image, addRightEmbedding, Embedding.coeFn_mk]
-#align finset.image_add_right_Icc Finset.image_add_right_Icc
-
-theorem image_add_right_Ico (a b c : α) : (Ico a b).image (· + c) = Ico (a + c) (b + c) := by
-  rw [← map_add_right_Ico, map_eq_image, addRightEmbedding, Embedding.coeFn_mk]
-#align finset.image_add_right_Ico Finset.image_add_right_Ico
-
-theorem image_add_right_Ioc (a b c : α) : (Ioc a b).image (· + c) = Ioc (a + c) (b + c) := by
-  rw [← map_add_right_Ioc, map_eq_image, addRightEmbedding, Embedding.coeFn_mk]
-#align finset.image_add_right_Ioc Finset.image_add_right_Ioc
-
-theorem image_add_right_Ioo (a b c : α) : (Ioo a b).image (· + c) = Ioo (a + c) (b + c) := by
-  rw [← map_add_right_Ioo, map_eq_image, addRightEmbedding, Embedding.coeFn_mk]
-#align finset.image_add_right_Ioo Finset.image_add_right_Ioo
-
-end OrderedCancelAddCommMonoid
 end Finset
 
 /-! ### `⩿`, `⋖` and monotonicity -/

chore: Move intervals (#11765)

Move Set.Ixx, Finset.Ixx, Multiset.Ixx together under two different folders:

Order.Interval for their definition and basic properties
Algebra.Order.Interval for their algebraic properties

Move the algebraic results out of what is now Order.Interval.Finset.Basic to a new file Algebra.Order.Interval.Finset.Basic.

c7fa7063

chore: Make Finset.preimage not depend on Finset.sum (#11601)

and Data.Finset.LocallyFinite not depend on Finset.sum too

d6a4b5d2

Diff

@@ -35,10 +35,11 @@ https://github.com/leanprover-community/mathlib/pull/14448#discussion_r906109235
 for some ideas.
 -/
 
+assert_not_exists Finset.sum
 
 open Function OrderDual
 
-open BigOperators FinsetInterval
+open FinsetInterval
 
 variable {ι α : Type*}
 
@@ -1166,18 +1167,6 @@ theorem image_add_right_Ioo (a b c : α) : (Ioo a b).image (· + c) = Ioo (a + c
 #align finset.image_add_right_Ioo Finset.image_add_right_Ioo
 
 end OrderedCancelAddCommMonoid
-
-@[to_additive]
-theorem prod_prod_Ioi_mul_eq_prod_prod_off_diag [Fintype ι] [LinearOrder ι]
-    [LocallyFiniteOrderTop ι] [LocallyFiniteOrderBot ι] [CommMonoid α] (f : ι → ι → α) :
-    (∏ i, ∏ j in Ioi i, f j i * f i j) = ∏ i, ∏ j in {i}ᶜ, f j i := by
-  simp_rw [← Ioi_disjUnion_Iio, prod_disjUnion, prod_mul_distrib]
-  congr 1
-  rw [prod_sigma', prod_sigma']
-  refine' prod_nbij' (fun i ↦ ⟨i.2, i.1⟩) (fun i ↦ ⟨i.2, i.1⟩) _ _ _ _ _ <;> simp
-#align finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag Finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag
-#align finset.sum_sum_Ioi_add_eq_sum_sum_off_diag Finset.sum_sum_Ioi_add_eq_sum_sum_off_diag
-
 end Finset
 
 /-! ### `⩿`, `⋖` and monotonicity -/

chore: bump aesop; update syntax (#10955)

Co-authored-by: Scott Morrison <scott.morrison@gmail.com>

46974e92

Diff

@@ -52,17 +52,17 @@ section LocallyFiniteOrder
 
 variable [LocallyFiniteOrder α] {a a₁ a₂ b b₁ b₂ c x : α}
 
-@[simp, aesop safe apply (rule_sets [finsetNonempty])]
+@[simp, aesop safe apply (rule_sets := [finsetNonempty])]
 theorem nonempty_Icc : (Icc a b).Nonempty ↔ a ≤ b := by
   rw [← coe_nonempty, coe_Icc, Set.nonempty_Icc]
 #align finset.nonempty_Icc Finset.nonempty_Icc
 
-@[simp, aesop safe apply (rule_sets [finsetNonempty])]
+@[simp, aesop safe apply (rule_sets := [finsetNonempty])]
 theorem nonempty_Ico : (Ico a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ico, Set.nonempty_Ico]
 #align finset.nonempty_Ico Finset.nonempty_Ico
 
-@[simp, aesop safe apply (rule_sets [finsetNonempty])]
+@[simp, aesop safe apply (rule_sets := [finsetNonempty])]
 theorem nonempty_Ioc : (Ioc a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioc, Set.nonempty_Ioc]
 #align finset.nonempty_Ioc Finset.nonempty_Ioc
@@ -395,9 +395,9 @@ section LocallyFiniteOrderTop
 
 variable [LocallyFiniteOrderTop α]
 
-@[simp, aesop safe apply (rule_sets [finsetNonempty])]
+@[simp, aesop safe apply (rule_sets := [finsetNonempty])]
 lemma nonempty_Ici : (Ici a).Nonempty := ⟨a, mem_Ici.2 le_rfl⟩
-@[simp, aesop safe apply (rule_sets [finsetNonempty])]
+@[simp, aesop safe apply (rule_sets := [finsetNonempty])]
 lemma nonempty_Ioi : (Ioi a).Nonempty ↔ ¬ IsMax a := by simp [Finset.Nonempty]
 
 theorem Icc_subset_Ici_self : Icc a b ⊆ Ici a := by

feat: Positivity extension for Finset.sum (#10538)

Also define a new aesop rule-set and an auxiliary metaprogram proveFinsetNonempty for dealing with Finset.Nonempty conditions.

From LeanAPAP

Co-authored-by: Alex J. Best <alex.j.best@gmail.com>

Co-authored-by: Eric Wieser <wieser.eric@gmail.com> Co-authored-by: Alex J Best <alex.j.best@gmail.com>

f2d8a000

Diff

@@ -52,17 +52,17 @@ section LocallyFiniteOrder
 
 variable [LocallyFiniteOrder α] {a a₁ a₂ b b₁ b₂ c x : α}
 
-@[simp]
+@[simp, aesop safe apply (rule_sets [finsetNonempty])]
 theorem nonempty_Icc : (Icc a b).Nonempty ↔ a ≤ b := by
   rw [← coe_nonempty, coe_Icc, Set.nonempty_Icc]
 #align finset.nonempty_Icc Finset.nonempty_Icc
 
-@[simp]
+@[simp, aesop safe apply (rule_sets [finsetNonempty])]
 theorem nonempty_Ico : (Ico a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ico, Set.nonempty_Ico]
 #align finset.nonempty_Ico Finset.nonempty_Ico
 
-@[simp]
+@[simp, aesop safe apply (rule_sets [finsetNonempty])]
 theorem nonempty_Ioc : (Ioc a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioc, Set.nonempty_Ioc]
 #align finset.nonempty_Ioc Finset.nonempty_Ioc
@@ -395,8 +395,10 @@ section LocallyFiniteOrderTop
 
 variable [LocallyFiniteOrderTop α]
 
-@[simp] lemma nonempty_Ici : (Ici a).Nonempty := ⟨a, mem_Ici.2 le_rfl⟩
-@[simp] lemma nonempty_Ioi : (Ioi a).Nonempty ↔ ¬ IsMax a := by simp [Finset.Nonempty]
+@[simp, aesop safe apply (rule_sets [finsetNonempty])]
+lemma nonempty_Ici : (Ici a).Nonempty := ⟨a, mem_Ici.2 le_rfl⟩
+@[simp, aesop safe apply (rule_sets [finsetNonempty])]
+lemma nonempty_Ioi : (Ioi a).Nonempty ↔ ¬ IsMax a := by simp [Finset.Nonempty]
 
 theorem Icc_subset_Ici_self : Icc a b ⊆ Ici a := by
   simpa [← coe_subset] using Set.Icc_subset_Ici_self

chore: classify simp can do this porting notes (#10619)

Classify by adding issue number (#10618) to porting notes claiming anything semantically equivalent to simp can prove this or simp can simplify this.

de765f60

Diff

@@ -128,42 +128,42 @@ theorem Ioo_eq_empty_of_le (h : b ≤ a) : Ioo a b = ∅ :=
   Ioo_eq_empty h.not_lt
 #align finset.Ioo_eq_empty_of_le Finset.Ioo_eq_empty_of_le
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem left_mem_Icc : a ∈ Icc a b ↔ a ≤ b := by simp only [mem_Icc, true_and_iff, le_rfl]
 #align finset.left_mem_Icc Finset.left_mem_Icc
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem left_mem_Ico : a ∈ Ico a b ↔ a < b := by simp only [mem_Ico, true_and_iff, le_refl]
 #align finset.left_mem_Ico Finset.left_mem_Ico
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem right_mem_Icc : b ∈ Icc a b ↔ a ≤ b := by simp only [mem_Icc, and_true_iff, le_rfl]
 #align finset.right_mem_Icc Finset.right_mem_Icc
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem right_mem_Ioc : b ∈ Ioc a b ↔ a < b := by simp only [mem_Ioc, and_true_iff, le_rfl]
 #align finset.right_mem_Ioc Finset.right_mem_Ioc
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem left_not_mem_Ioc : a ∉ Ioc a b := fun h => lt_irrefl _ (mem_Ioc.1 h).1
 #align finset.left_not_mem_Ioc Finset.left_not_mem_Ioc
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem left_not_mem_Ioo : a ∉ Ioo a b := fun h => lt_irrefl _ (mem_Ioo.1 h).1
 #align finset.left_not_mem_Ioo Finset.left_not_mem_Ioo
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem right_not_mem_Ico : b ∉ Ico a b := fun h => lt_irrefl _ (mem_Ico.1 h).2
 #align finset.right_not_mem_Ico Finset.right_not_mem_Ico
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem right_not_mem_Ioo : b ∉ Ioo a b := fun h => lt_irrefl _ (mem_Ioo.1 h).2
 #align finset.right_not_mem_Ioo Finset.right_not_mem_Ioo
@@ -286,19 +286,19 @@ theorem Icc_ssubset_Icc_right (hI : a₂ ≤ b₂) (ha : a₂ ≤ a₁) (hb : b
 
 variable (a)
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem Ico_self : Ico a a = ∅ :=
   Ico_eq_empty <| lt_irrefl _
 #align finset.Ico_self Finset.Ico_self
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem Ioc_self : Ioc a a = ∅ :=
   Ioc_eq_empty <| lt_irrefl _
 #align finset.Ioc_self Finset.Ioc_self
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem Ioo_self : Ioo a a = ∅ :=
   Ioo_eq_empty <| lt_irrefl _
@@ -696,7 +696,7 @@ theorem Ioi_insert [DecidableEq α] (a : α) : insert a (Ioi a) = Ici a := by
   simp_rw [Finset.mem_insert, mem_Ici, mem_Ioi, le_iff_lt_or_eq, or_comm, eq_comm]
 #align finset.Ioi_insert Finset.Ioi_insert
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem not_mem_Ioi_self {b : α} : b ∉ Ioi b := fun h => lt_irrefl _ (mem_Ioi.1 h)
 #align finset.not_mem_Ioi_self Finset.not_mem_Ioi_self
@@ -729,7 +729,7 @@ theorem Iio_insert [DecidableEq α] (b : α) : insert b (Iio b) = Iic b := by
   simp_rw [Finset.mem_insert, mem_Iic, mem_Iio, le_iff_lt_or_eq, or_comm]
 #align finset.Iio_insert Finset.Iio_insert
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem not_mem_Iio_self {b : α} : b ∉ Iio b := fun h => lt_irrefl _ (mem_Iio.1 h)
 #align finset.not_mem_Iio_self Finset.not_mem_Iio_self
@@ -922,7 +922,7 @@ theorem uIcc_comm (a b : α) : [[a, b]] = [[b, a]] := by
   rw [uIcc, uIcc, inf_comm, sup_comm]
 #align finset.uIcc_comm Finset.uIcc_comm
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem uIcc_self : [[a, a]] = {a} := by simp [uIcc]
 #align finset.uIcc_self Finset.uIcc_self
@@ -940,13 +940,13 @@ theorem Icc_subset_uIcc' : Icc b a ⊆ [[a, b]] :=
   Icc_subset_Icc inf_le_right le_sup_left
 #align finset.Icc_subset_uIcc' Finset.Icc_subset_uIcc'
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem left_mem_uIcc : a ∈ [[a, b]] :=
   mem_Icc.2 ⟨inf_le_left, le_sup_left⟩
 #align finset.left_mem_uIcc Finset.left_mem_uIcc
 
--- Porting note : simp can prove this
+-- porting note (#10618): simp can prove this
 -- @[simp]
 theorem right_mem_uIcc : b ∈ [[a, b]] :=
   mem_Icc.2 ⟨inf_le_right, le_sup_right⟩

chore: move BddBelow.finite_of_bddAbove to Order.LocallyFinite (#10613)

b255974f

Diff

@@ -312,14 +312,6 @@ def _root_.Set.fintypeOfMemBounds {s : Set α} [DecidablePred (· ∈ s)] (ha :
   Set.fintypeSubset (Set.Icc a b) fun _ hx => ⟨ha hx, hb hx⟩
 #align set.fintype_of_mem_bounds Set.fintypeOfMemBounds
 
--- TODO: move to `Order/LocallyFinite`
-theorem _root_.BddBelow.finite_of_bddAbove {s : Set α} (h₀ : BddBelow s) (h₁ : BddAbove s) :
-    s.Finite :=
-  let ⟨a, ha⟩ := h₀
-  let ⟨b, hb⟩ := h₁
-  (Set.finite_Icc a b).subset fun _x hx ↦ ⟨ha hx, hb hx⟩
-#align bdd_below.finite_of_bdd_above BddBelow.finite_of_bddAbove
-
 section Filter
 
 theorem Ico_filter_lt_of_le_left [DecidablePred (· < c)] (hca : c ≤ a) :

refactor(Set/Finite): redefine using _root_.Finite (#10542)

a39f83f3

Diff

@@ -312,11 +312,12 @@ def _root_.Set.fintypeOfMemBounds {s : Set α} [DecidablePred (· ∈ s)] (ha :
   Set.fintypeSubset (Set.Icc a b) fun _ hx => ⟨ha hx, hb hx⟩
 #align set.fintype_of_mem_bounds Set.fintypeOfMemBounds
 
+-- TODO: move to `Order/LocallyFinite`
 theorem _root_.BddBelow.finite_of_bddAbove {s : Set α} (h₀ : BddBelow s) (h₁ : BddAbove s) :
-    s.Finite := by
+    s.Finite :=
   let ⟨a, ha⟩ := h₀
   let ⟨b, hb⟩ := h₁
-  classical exact ⟨Set.fintypeOfMemBounds ha hb⟩
+  (Set.finite_Icc a b).subset fun _x hx ↦ ⟨ha hx, hb hx⟩
 #align bdd_below.finite_of_bdd_above BddBelow.finite_of_bddAbove
 
 section Filter

chore: move to v4.6.0-rc1, merging adaptations from bump/v4.6.0 (#10176)

Co-authored-by: Scott Morrison <scott.morrison@gmail.com> Co-authored-by: Eric Wieser <wieser.eric@gmail.com> Co-authored-by: Joachim Breitner <mail@joachim-breitner.de>

490d2d48

Diff

@@ -1215,7 +1215,7 @@ lemma transGen_wcovBy_of_le [Preorder α] [LocallyFiniteOrder α] {x y : α} (hx
       refine ⟨(mem_Ico.mp z_mem).2.le, fun c hzc hcy ↦ hz c ?_ hzc⟩
       exact mem_Ico.mpr <| ⟨(mem_Ico.mp z_mem).1.trans hzc.le, hcy⟩
     exact .tail h₁ h₂
-termination_by _ => (Icc x y).card
+termination_by (Icc x y).card
 
 /-- In a locally finite preorder, `≤` is the transitive closure of `⩿`. -/
 lemma le_iff_transGen_wcovBy [Preorder α] [LocallyFiniteOrder α] {x y : α} :
@@ -1253,7 +1253,7 @@ lemma transGen_covBy_of_lt [Preorder α] [LocallyFiniteOrder α] {x y : α} (hxy
   `x ≤ z`), and since `z ⋖ y` we conclude that `x ⋖ y` , then `Relation.TransGen.single`. -/
   · simp only [lt_iff_le_not_le, not_and, not_not] at hxz
     exact .single (hzy.of_le_of_lt (hxz (mem_Ico.mp z_mem).1) hxy)
-termination_by _ => (Ico x y).card
+termination_by (Ico x y).card
 
 /-- In a locally finite preorder, `<` is the transitive closure of `⋖`. -/
 lemma lt_iff_transGen_covBy [Preorder α] [LocallyFiniteOrder α] {x y : α} :

chore(Covby): rename Covby to CovBy (#9578)

Rename

Covby → CovBy, Wcovby → WCovBy
*covby* → *covBy*
wcovby.finset_val → WCovBy.finset_val, wcovby.finset_coe → WCovBy.finset_coe
Covby.is_coatom → CovBy.isCoatom

8b47b2fc

Diff

@@ -19,10 +19,10 @@ In addition, it shows that in a locally finite order `≤` and `<` are the trans
 respectively, `⩿` and `⋖`, which then leads to a characterization of monotone and strictly
 functions whose domain is a locally finite order. In particular, this file proves:
 
-* `le_iff_transGen_wcovby`: `≤` is the transitive closure of `⩿`
-* `lt_iff_transGen_covby`: `≤` is the transitive closure of `⩿`
-* `monotone_iff_forall_wcovby`: Characterization of monotone functions
-* `strictMono_iff_forall_covby`: Characterization of strictly monotone functions
+* `le_iff_transGen_wcovBy`: `≤` is the transitive closure of `⩿`
+* `lt_iff_transGen_covBy`: `≤` is the transitive closure of `⩿`
+* `monotone_iff_forall_wcovBy`: Characterization of monotone functions
+* `strictMono_iff_forall_covBy`: Characterization of strictly monotone functions
 
 ## TODO
 
@@ -1192,7 +1192,7 @@ section Cover
 open Finset Relation
 
 set_option linter.unusedVariables false in -- `have` for wf induction triggers linter
-lemma transGen_wcovby_of_le [Preorder α] [LocallyFiniteOrder α] {x y : α} (hxy : x ≤ y) :
+lemma transGen_wcovBy_of_le [Preorder α] [LocallyFiniteOrder α] {x y : α} (hxy : x ≤ y) :
     TransGen (· ⩿ ·) x y := by
   -- We proceed by well-founded induction on the cardinality of `Icc x y`.
   -- It's impossible for the cardinality to be zero since `x ≤ y`
@@ -1200,7 +1200,7 @@ lemma transGen_wcovby_of_le [Preorder α] [LocallyFiniteOrder α] {x y : α} (hx
     ⟨Ico_subset_Icc_self, not_subset.mpr ⟨y, ⟨right_mem_Icc.mpr hxy, right_not_mem_Ico⟩⟩⟩
   by_cases hxy' : y ≤ x
   -- If `y ≤ x`, then `x ⩿ y`
-  · exact .single <| wcovby_of_le_of_le hxy hxy'
+  · exact .single <| wcovBy_of_le_of_le hxy hxy'
   /- and if `¬ y ≤ x`, then `x < y`, not because it is a linear order, but because `x ≤ y`
   already. In that case, since `z` is maximal in `Ico x y`, then `z ⩿ y` and we can use the
   induction hypothesis to show that `Relation.TransGen (· ⩿ ·) x z`. -/
@@ -1210,7 +1210,7 @@ lemma transGen_wcovby_of_le [Preorder α] [LocallyFiniteOrder α] {x y : α} (hx
       (Icc x z).card ≤ (Ico x y).card :=
         card_le_card <| Icc_subset_Ico_right (mem_Ico.mp z_mem).2
       _              < (Icc x y).card := this
-    have h₁ := transGen_wcovby_of_le (mem_Ico.mp z_mem).1
+    have h₁ := transGen_wcovBy_of_le (mem_Ico.mp z_mem).1
     have h₂ : z ⩿ y := by
       refine ⟨(mem_Ico.mp z_mem).2.le, fun c hzc hcy ↦ hz c ?_ hzc⟩
       exact mem_Ico.mpr <| ⟨(mem_Ico.mp z_mem).1.trans hzc.le, hcy⟩
@@ -1218,20 +1218,20 @@ lemma transGen_wcovby_of_le [Preorder α] [LocallyFiniteOrder α] {x y : α} (hx
 termination_by _ => (Icc x y).card
 
 /-- In a locally finite preorder, `≤` is the transitive closure of `⩿`. -/
-lemma le_iff_transGen_wcovby [Preorder α] [LocallyFiniteOrder α] {x y : α} :
+lemma le_iff_transGen_wcovBy [Preorder α] [LocallyFiniteOrder α] {x y : α} :
     x ≤ y ↔ TransGen (· ⩿ ·) x y := by
-  refine ⟨transGen_wcovby_of_le, fun h ↦ ?_⟩
+  refine ⟨transGen_wcovBy_of_le, fun h ↦ ?_⟩
   induction h with
   | single h => exact h.le
   | tail _ h₁ h₂ => exact h₂.trans h₁.le
 
 /-- In a locally finite partial order, `≤` is the reflexive transitive closure of `⋖`. -/
-lemma le_iff_reflTransGen_covby [PartialOrder α] [LocallyFiniteOrder α] {x y : α} :
+lemma le_iff_reflTransGen_covBy [PartialOrder α] [LocallyFiniteOrder α] {x y : α} :
     x ≤ y ↔ ReflTransGen (· ⋖ ·) x y := by
-  rw [le_iff_transGen_wcovby, wcovby_eq_reflGen_covby, transGen_reflGen]
+  rw [le_iff_transGen_wcovBy, wcovBy_eq_reflGen_covBy, transGen_reflGen]
 
 set_option linter.unusedVariables false in -- `have` for wf induction triggers linter
-lemma transGen_covby_of_lt [Preorder α] [LocallyFiniteOrder α] {x y : α} (hxy : x < y) :
+lemma transGen_covBy_of_lt [Preorder α] [LocallyFiniteOrder α] {x y : α} (hxy : x < y) :
     TransGen (· ⋖ ·) x y := by
   -- We proceed by well-founded induction on the cardinality of `Ico x y`.
   -- It's impossible for the cardinality to be zero since `x < y`
@@ -1248,7 +1248,7 @@ lemma transGen_covby_of_lt [Preorder α] [LocallyFiniteOrder α] {x y : α} (hxy
   by_cases hxz : x < z
   /- when `x < z`, then we may use the induction hypothesis to get a chain
   `Relation.TransGen (· ⋖ ·) x z`, which we can extend with `Relation.TransGen.tail`. -/
-  · exact .tail (transGen_covby_of_lt hxz) hzy
+  · exact .tail (transGen_covBy_of_lt hxz) hzy
   /- when `¬ x < z`, then actually `z ≤ x` (not because it's a linear order, but because
   `x ≤ z`), and since `z ⋖ y` we conclude that `x ⋖ y` , then `Relation.TransGen.single`. -/
   · simp only [lt_iff_le_not_le, not_and, not_not] at hxz
@@ -1256,9 +1256,9 @@ lemma transGen_covby_of_lt [Preorder α] [LocallyFiniteOrder α] {x y : α} (hxy
 termination_by _ => (Ico x y).card
 
 /-- In a locally finite preorder, `<` is the transitive closure of `⋖`. -/
-lemma lt_iff_transGen_covby [Preorder α] [LocallyFiniteOrder α] {x y : α} :
+lemma lt_iff_transGen_covBy [Preorder α] [LocallyFiniteOrder α] {x y : α} :
     x < y ↔ TransGen (· ⋖ ·) x y := by
-  refine ⟨transGen_covby_of_lt, fun h ↦ ?_⟩
+  refine ⟨transGen_covBy_of_lt, fun h ↦ ?_⟩
   induction h with
   | single hx => exact hx.1
   | tail _ hb ih => exact ih.trans hb.1
@@ -1267,45 +1267,45 @@ variable {β : Type*}
 
 /-- A function from a locally finite preorder is monotone if and only if it is monotone when
 restricted to pairs satisfying `a ⩿ b`. -/
-lemma monotone_iff_forall_wcovby [Preorder α] [LocallyFiniteOrder α] [Preorder β]
+lemma monotone_iff_forall_wcovBy [Preorder α] [LocallyFiniteOrder α] [Preorder β]
     (f : α → β) : Monotone f ↔ ∀ a b : α, a ⩿ b → f a ≤ f b := by
   refine ⟨fun hf _ _ h ↦ hf h.le, fun h a b hab ↦ ?_⟩
   simpa [transGen_eq_self (r := ((· : β) ≤ ·)) transitive_le]
-    using TransGen.lift f h <| le_iff_transGen_wcovby.mp hab
+    using TransGen.lift f h <| le_iff_transGen_wcovBy.mp hab
 
 /-- A function from a locally finite partial order is monotone if and only if it is monotone when
 restricted to pairs satisfying `a ⋖ b`. -/
-lemma monotone_iff_forall_covby [PartialOrder α] [LocallyFiniteOrder α] [Preorder β]
+lemma monotone_iff_forall_covBy [PartialOrder α] [LocallyFiniteOrder α] [Preorder β]
     (f : α → β) : Monotone f ↔ ∀ a b : α, a ⋖ b → f a ≤ f b := by
   refine ⟨fun hf _ _ h ↦ hf h.le, fun h a b hab ↦ ?_⟩
   simpa [reflTransGen_eq_self (r := ((· : β) ≤ ·)) IsRefl.reflexive transitive_le]
-    using ReflTransGen.lift f h <| le_iff_reflTransGen_covby.mp hab
+    using ReflTransGen.lift f h <| le_iff_reflTransGen_covBy.mp hab
 
 /-- A function from a locally finite preorder is strictly monotone if and only if it is strictly
 monotone when restricted to pairs satisfying `a ⋖ b`. -/
-lemma strictMono_iff_forall_covby [Preorder α] [LocallyFiniteOrder α] [Preorder β]
+lemma strictMono_iff_forall_covBy [Preorder α] [LocallyFiniteOrder α] [Preorder β]
     (f : α → β) : StrictMono f ↔ ∀ a b : α, a ⋖ b → f a < f b := by
   refine ⟨fun hf _ _ h ↦ hf h.lt, fun h a b hab ↦ ?_⟩
   have := Relation.TransGen.lift f h (a := a) (b := b)
-  rw [← lt_iff_transGen_covby, transGen_eq_self (@lt_trans β _)] at this
+  rw [← lt_iff_transGen_covBy, transGen_eq_self (@lt_trans β _)] at this
   · exact this hab
 
 /-- A function from a locally finite preorder is antitone if and only if it is antitone when
 restricted to pairs satisfying `a ⩿ b`. -/
-lemma antitone_iff_forall_wcovby [Preorder α] [LocallyFiniteOrder α] [Preorder β]
+lemma antitone_iff_forall_wcovBy [Preorder α] [LocallyFiniteOrder α] [Preorder β]
     (f : α → β) : Antitone f ↔ ∀ a b : α, a ⩿ b → f b ≤ f a :=
-  monotone_iff_forall_wcovby (β := βᵒᵈ) f
+  monotone_iff_forall_wcovBy (β := βᵒᵈ) f
 
 /-- A function from a locally finite partial order is antitone if and only if it is antitone when
 restricted to pairs satisfying `a ⋖ b`. -/
-lemma antitone_iff_forall_covby [PartialOrder α] [LocallyFiniteOrder α] [Preorder β]
+lemma antitone_iff_forall_covBy [PartialOrder α] [LocallyFiniteOrder α] [Preorder β]
     (f : α → β) : Antitone f ↔ ∀ a b : α, a ⋖ b → f b ≤ f a :=
-  monotone_iff_forall_covby (β := βᵒᵈ) f
+  monotone_iff_forall_covBy (β := βᵒᵈ) f
 
 /-- A function from a locally finite preorder is strictly antitone if and only if it is strictly
 antitone when restricted to pairs satisfying `a ⋖ b`. -/
-lemma strictAnti_iff_forall_covby [Preorder α] [LocallyFiniteOrder α] [Preorder β]
+lemma strictAnti_iff_forall_covBy [Preorder α] [LocallyFiniteOrder α] [Preorder β]
     (f : α → β) : StrictAnti f ↔ ∀ a b : α, a ⋖ b → f b < f a :=
-  strictMono_iff_forall_covby (β := βᵒᵈ) f
+  strictMono_iff_forall_covBy (β := βᵒᵈ) f
 
 end Cover

feat: Better lemmas for transferring finite sums along equivalences (#9237)

Lemmas around this were a mess, throth in terms of names, statement and location. This PR standardises everything to be in Algebra.BigOperators.Basic and changes the lemmas to take in InjOn and SurjOn assumptions where possible (and where impossible make sure the hypotheses are taken in the correct order) and moves the equality of functions hypothesis last.

Also add a few lemmas that help fix downstream uses by golfing.

From LeanAPAP and LeanCamCombi

82c60323

Diff

@@ -1179,7 +1179,7 @@ theorem prod_prod_Ioi_mul_eq_prod_prod_off_diag [Fintype ι] [LinearOrder ι]
   simp_rw [← Ioi_disjUnion_Iio, prod_disjUnion, prod_mul_distrib]
   congr 1
   rw [prod_sigma', prod_sigma']
-  refine' prod_bij' (fun i _ => ⟨i.2, i.1⟩) _ _ (fun i _ => ⟨i.2, i.1⟩) _ _ _ <;> simp
+  refine' prod_nbij' (fun i ↦ ⟨i.2, i.1⟩) (fun i ↦ ⟨i.2, i.1⟩) _ _ _ _ _ <;> simp
 #align finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag Finset.prod_prod_Ioi_mul_eq_prod_prod_off_diag
 #align finset.sum_sum_Ioi_add_eq_sum_sum_off_diag Finset.sum_sum_Ioi_add_eq_sum_sum_off_diag

chore: Improve Finset lemma names (#8894)

Change a few lemma names that have historically bothered me.

Finset.card_le_of_subset → Finset.card_le_card
Multiset.card_le_of_le → Multiset.card_le_card
Multiset.card_lt_of_lt → Multiset.card_lt_card
Set.ncard_le_of_subset → Set.ncard_le_ncard
Finset.image_filter → Finset.filter_image
CompleteLattice.finset_sup_compact_of_compact → CompleteLattice.isCompactElement_finset_sup

7d3d6e43

Diff

@@ -1208,7 +1208,7 @@ lemma transGen_wcovby_of_le [Preorder α] [LocallyFiniteOrder α] {x y : α} (hx
     obtain ⟨z, z_mem, hz⟩ := (Ico x y).exists_maximal h_non
     have z_card : (Icc x z).card <(Icc x y).card := calc
       (Icc x z).card ≤ (Ico x y).card :=
-        card_le_of_subset <| Icc_subset_Ico_right (mem_Ico.mp z_mem).2
+        card_le_card <| Icc_subset_Ico_right (mem_Ico.mp z_mem).2
       _              < (Icc x y).card := this
     have h₁ := transGen_wcovby_of_le (mem_Ico.mp z_mem).1
     have h₂ : z ⩿ y := by

chore: Replace (· op ·) a by (a op ·) (#8843)

I used the regex $\(· (.) ·$ (.)\), replacing with ($2 $1 ·).

d14658b4

Diff

@@ -338,18 +338,18 @@ theorem Ico_filter_lt_of_le_right [DecidablePred (· < c)] (hcb : c ≤ b) :
   exact and_iff_left_of_imp fun h => h.2.trans_le hcb
 #align finset.Ico_filter_lt_of_le_right Finset.Ico_filter_lt_of_le_right
 
-theorem Ico_filter_le_of_le_left {a b c : α} [DecidablePred ((· ≤ ·) c)] (hca : c ≤ a) :
-    (Ico a b).filter ((· ≤ ·) c) = Ico a b :=
+theorem Ico_filter_le_of_le_left {a b c : α} [DecidablePred (c ≤ ·)] (hca : c ≤ a) :
+    (Ico a b).filter (c ≤ ·) = Ico a b :=
   filter_true_of_mem fun _ hx => hca.trans (mem_Ico.1 hx).1
 #align finset.Ico_filter_le_of_le_left Finset.Ico_filter_le_of_le_left
 
-theorem Ico_filter_le_of_right_le {a b : α} [DecidablePred ((· ≤ ·) b)] :
-    (Ico a b).filter ((· ≤ ·) b) = ∅ :=
+theorem Ico_filter_le_of_right_le {a b : α} [DecidablePred (b ≤ ·)] :
+    (Ico a b).filter (b ≤ ·) = ∅ :=
   filter_false_of_mem fun _ hx => (mem_Ico.1 hx).2.not_le
 #align finset.Ico_filter_le_of_right_le Finset.Ico_filter_le_of_right_le
 
-theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred ((· ≤ ·) c)] (hac : a ≤ c) :
-    (Ico a b).filter ((· ≤ ·) c) = Ico c b := by
+theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred (c ≤ ·)] (hac : a ≤ c) :
+    (Ico a b).filter (c ≤ ·) = Ico c b := by
   ext x
   rw [mem_filter, mem_Ico, mem_Ico, and_comm, and_left_comm]
   exact and_iff_right_of_imp fun h => hac.trans h.1
@@ -485,12 +485,12 @@ theorem _root_.Set.Infinite.not_bddBelow {s : Set α} : s.Infinite → ¬BddBelo
 
 variable [Fintype α]
 
-theorem filter_lt_eq_Ioi [DecidablePred ((· < ·) a)] : univ.filter ((· < ·) a) = Ioi a := by
+theorem filter_lt_eq_Ioi [DecidablePred (a < ·)] : univ.filter (a < ·) = Ioi a := by
   ext
   simp
 #align finset.filter_lt_eq_Ioi Finset.filter_lt_eq_Ioi
 
-theorem filter_le_eq_Ici [DecidablePred ((· ≤ ·) a)] : univ.filter ((· ≤ ·) a) = Ici a := by
+theorem filter_le_eq_Ici [DecidablePred (a ≤ ·)] : univ.filter (a ≤ ·) = Ici a := by
   ext
   simp
 #align finset.filter_le_eq_Ici Finset.filter_le_eq_Ici
@@ -1134,22 +1134,22 @@ theorem map_add_right_Ioo (a b c : α) :
 variable [DecidableEq α]
 
 @[simp]
-theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) := by
+theorem image_add_left_Icc (a b c : α) : (Icc a b).image (c + ·) = Icc (c + a) (c + b) := by
   rw [← map_add_left_Icc, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_left_Icc Finset.image_add_left_Icc
 
 @[simp]
-theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) := by
+theorem image_add_left_Ico (a b c : α) : (Ico a b).image (c + ·) = Ico (c + a) (c + b) := by
   rw [← map_add_left_Ico, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_left_Ico Finset.image_add_left_Ico
 
 @[simp]
-theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) := by
+theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image (c + ·) = Ioc (c + a) (c + b) := by
   rw [← map_add_left_Ioc, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_left_Ioc Finset.image_add_left_Ioc
 
 @[simp]
-theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) := by
+theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image (c + ·) = Ioo (c + a) (c + b) := by
   rw [← map_add_left_Ioo, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_left_Ioo Finset.image_add_left_Ioo

chore: remove some double spaces (#7983)

Co-authored-by: Moritz Firsching <firsching@google.com>

24cd315a

Diff

@@ -357,12 +357,12 @@ theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred ((· ≤ ·) c)] (h
 
 theorem Icc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Icc a b).filter (· < c) = Icc a b :=
-  filter_true_of_mem  fun _ hx => lt_of_le_of_lt (mem_Icc.1 hx).2 h
+  filter_true_of_mem fun _ hx => lt_of_le_of_lt (mem_Icc.1 hx).2 h
 #align finset.Icc_filter_lt_of_lt_right Finset.Icc_filter_lt_of_lt_right
 
 theorem Ioc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Ioc a b).filter (· < c) = Ioc a b :=
-  filter_true_of_mem  fun _ hx => lt_of_le_of_lt (mem_Ioc.1 hx).2 h
+  filter_true_of_mem fun _ hx => lt_of_le_of_lt (mem_Ioc.1 hx).2 h
 #align finset.Ioc_filter_lt_of_lt_right Finset.Ioc_filter_lt_of_lt_right
 
 theorem Iic_filter_lt_of_lt_right {α} [Preorder α] [LocallyFiniteOrderBot α] {a c : α}

feat: Supremum of Finset.Iic a (#7416)

and lemmas about Set.toFinset of Finset.Ixx

b3b5ba1e

Diff

@@ -67,6 +67,7 @@ theorem nonempty_Ioc : (Ioc a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioc, Set.nonempty_Ioc]
 #align finset.nonempty_Ioc Finset.nonempty_Ioc
 
+-- TODO: This is nonsense. A locally finite order is never densely ordered
 @[simp]
 theorem nonempty_Ioo [DenselyOrdered α] : (Ioo a b).Nonempty ↔ a < b := by
   rw [← coe_nonempty, coe_Ioo, Set.nonempty_Ioo]
@@ -87,6 +88,7 @@ theorem Ioc_eq_empty_iff : Ioc a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ioc, Set.Ioc_eq_empty_iff]
 #align finset.Ioc_eq_empty_iff Finset.Ioc_eq_empty_iff
 
+-- TODO: This is nonsense. A locally finite order is never densely ordered
 @[simp]
 theorem Ioo_eq_empty_iff [DenselyOrdered α] : Ioo a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ioo, Set.Ioo_eq_empty_iff]
@@ -400,6 +402,9 @@ section LocallyFiniteOrderTop
 
 variable [LocallyFiniteOrderTop α]
 
+@[simp] lemma nonempty_Ici : (Ici a).Nonempty := ⟨a, mem_Ici.2 le_rfl⟩
+@[simp] lemma nonempty_Ioi : (Ioi a).Nonempty ↔ ¬ IsMax a := by simp [Finset.Nonempty]
+
 theorem Icc_subset_Ici_self : Icc a b ⊆ Ici a := by
   simpa [← coe_subset] using Set.Icc_subset_Ici_self
 #align finset.Icc_subset_Ici_self Finset.Icc_subset_Ici_self
@@ -430,6 +435,9 @@ section LocallyFiniteOrderBot
 
 variable [LocallyFiniteOrderBot α]
 
+@[simp] lemma nonempty_Iic : (Iic a).Nonempty := ⟨a, mem_Iic.2 le_rfl⟩
+@[simp] lemma nonempty_Iio : (Iio a).Nonempty ↔ ¬ IsMin a := by simp [Finset.Nonempty]
+
 theorem Icc_subset_Iic_self : Icc a b ⊆ Iic b := by
   simpa [← coe_subset] using Set.Icc_subset_Iic_self
 #align finset.Icc_subset_Iic_self Finset.Icc_subset_Iic_self
@@ -747,6 +755,29 @@ end OrderBot
 
 end BoundedPartialOrder
 
+section SemilatticeSup
+variable [SemilatticeSup α] [LocallyFiniteOrderBot α]
+
+-- TODO: Why does `id_eq` simplify the LHS here but not the LHS of `Finset.sup_Iic`?
+lemma sup'_Iic (a : α) : (Iic a).sup' nonempty_Iic id = a :=
+  le_antisymm (sup'_le _ _ fun _ ↦ mem_Iic.1) <| le_sup' (f := id) <| mem_Iic.2 <| le_refl a
+
+@[simp] lemma sup_Iic [OrderBot α] (a : α) : (Iic a).sup id = a :=
+  le_antisymm (Finset.sup_le fun _ ↦ mem_Iic.1) <| le_sup (f := id) <| mem_Iic.2 <| le_refl a
+
+end SemilatticeSup
+
+section SemilatticeInf
+variable [SemilatticeInf α] [LocallyFiniteOrderTop α]
+
+lemma inf'_Ici (a : α) : (Ici a).inf' nonempty_Ici id = a :=
+  ge_antisymm (le_inf' _ _ fun _ ↦ mem_Ici.1) <| inf'_le (f := id) <| mem_Ici.2 <| le_refl a
+
+@[simp] lemma inf_Ici [OrderTop α] (a : α) : (Ici a).inf id = a :=
+  le_antisymm (inf_le (f := id) <| mem_Ici.2 <| le_refl a) <| Finset.le_inf fun _ ↦ mem_Ici.1
+
+end SemilatticeInf
+
 section LinearOrder
 
 variable [LinearOrder α]

feat: characterizations of monotonicity in locally finite orders (#6709)

depends on: #6711
depends on: #6712

Co-authored-by: Heather Macbeth <25316162+hrmacbeth@users.noreply.github.com>

d6303b84

Diff

@@ -3,6 +3,7 @@ Copyright (c) 2019 Scott Morrison. All rights reserved.
 Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 -/
+import Mathlib.Order.Cover
 import Mathlib.Order.LocallyFinite
 import Mathlib.Data.Set.Intervals.Monoid
 
@@ -14,6 +15,15 @@ import Mathlib.Data.Set.Intervals.Monoid
 This file provides basic results about all the `Finset.Ixx`, which are defined in
 `Order.LocallyFinite`.
 
+In addition, it shows that in a locally finite order `≤` and `<` are the transitive closures of,
+respectively, `⩿` and `⋖`, which then leads to a characterization of monotone and strictly
+functions whose domain is a locally finite order. In particular, this file proves:
+
+* `le_iff_transGen_wcovby`: `≤` is the transitive closure of `⩿`
+* `lt_iff_transGen_covby`: `≤` is the transitive closure of `⩿`
+* `monotone_iff_forall_wcovby`: Characterization of monotone functions
+* `strictMono_iff_forall_covby`: Characterization of strictly monotone functions
+
 ## TODO
 
 This file was originally only about `Finset.Ico a b` where `a b : ℕ`. No care has yet been taken to
@@ -1143,3 +1153,128 @@ theorem prod_prod_Ioi_mul_eq_prod_prod_off_diag [Fintype ι] [LinearOrder ι]
 #align finset.sum_sum_Ioi_add_eq_sum_sum_off_diag Finset.sum_sum_Ioi_add_eq_sum_sum_off_diag
 
 end Finset
+
+/-! ### `⩿`, `⋖` and monotonicity -/
+
+section Cover
+
+open Finset Relation
+
+set_option linter.unusedVariables false in -- `have` for wf induction triggers linter
+lemma transGen_wcovby_of_le [Preorder α] [LocallyFiniteOrder α] {x y : α} (hxy : x ≤ y) :
+    TransGen (· ⩿ ·) x y := by
+  -- We proceed by well-founded induction on the cardinality of `Icc x y`.
+  -- It's impossible for the cardinality to be zero since `x ≤ y`
+  have : (Ico x y).card < (Icc x y).card := card_lt_card <|
+    ⟨Ico_subset_Icc_self, not_subset.mpr ⟨y, ⟨right_mem_Icc.mpr hxy, right_not_mem_Ico⟩⟩⟩
+  by_cases hxy' : y ≤ x
+  -- If `y ≤ x`, then `x ⩿ y`
+  · exact .single <| wcovby_of_le_of_le hxy hxy'
+  /- and if `¬ y ≤ x`, then `x < y`, not because it is a linear order, but because `x ≤ y`
+  already. In that case, since `z` is maximal in `Ico x y`, then `z ⩿ y` and we can use the
+  induction hypothesis to show that `Relation.TransGen (· ⩿ ·) x z`. -/
+  · have h_non : (Ico x y).Nonempty := ⟨x, mem_Ico.mpr ⟨le_rfl, lt_of_le_not_le hxy hxy'⟩⟩
+    obtain ⟨z, z_mem, hz⟩ := (Ico x y).exists_maximal h_non
+    have z_card : (Icc x z).card <(Icc x y).card := calc
+      (Icc x z).card ≤ (Ico x y).card :=
+        card_le_of_subset <| Icc_subset_Ico_right (mem_Ico.mp z_mem).2
+      _              < (Icc x y).card := this
+    have h₁ := transGen_wcovby_of_le (mem_Ico.mp z_mem).1
+    have h₂ : z ⩿ y := by
+      refine ⟨(mem_Ico.mp z_mem).2.le, fun c hzc hcy ↦ hz c ?_ hzc⟩
+      exact mem_Ico.mpr <| ⟨(mem_Ico.mp z_mem).1.trans hzc.le, hcy⟩
+    exact .tail h₁ h₂
+termination_by _ => (Icc x y).card
+
+/-- In a locally finite preorder, `≤` is the transitive closure of `⩿`. -/
+lemma le_iff_transGen_wcovby [Preorder α] [LocallyFiniteOrder α] {x y : α} :
+    x ≤ y ↔ TransGen (· ⩿ ·) x y := by
+  refine ⟨transGen_wcovby_of_le, fun h ↦ ?_⟩
+  induction h with
+  | single h => exact h.le
+  | tail _ h₁ h₂ => exact h₂.trans h₁.le
+
+/-- In a locally finite partial order, `≤` is the reflexive transitive closure of `⋖`. -/
+lemma le_iff_reflTransGen_covby [PartialOrder α] [LocallyFiniteOrder α] {x y : α} :
+    x ≤ y ↔ ReflTransGen (· ⋖ ·) x y := by
+  rw [le_iff_transGen_wcovby, wcovby_eq_reflGen_covby, transGen_reflGen]
+
+set_option linter.unusedVariables false in -- `have` for wf induction triggers linter
+lemma transGen_covby_of_lt [Preorder α] [LocallyFiniteOrder α] {x y : α} (hxy : x < y) :
+    TransGen (· ⋖ ·) x y := by
+  -- We proceed by well-founded induction on the cardinality of `Ico x y`.
+  -- It's impossible for the cardinality to be zero since `x < y`
+  have h_non : (Ico x y).Nonempty := ⟨x, mem_Ico.mpr ⟨le_rfl, hxy⟩⟩
+  -- `Ico x y` is a nonempty finset and so contains a maximal element `z` and
+  -- `Ico x z` has cardinality strictly less than the cardinality of `Ico x y`
+  obtain ⟨z, z_mem, hz⟩ := (Ico x y).exists_maximal h_non
+  have z_card : (Ico x z).card < (Ico x y).card := card_lt_card <| ssubset_iff_of_subset
+    (Ico_subset_Ico le_rfl (mem_Ico.mp z_mem).2.le) |>.mpr ⟨z, z_mem, right_not_mem_Ico⟩
+  /- Since `z` is maximal in `Ico x y`, `z ⋖ y`. -/
+  have hzy : z ⋖ y := by
+    refine ⟨(mem_Ico.mp z_mem).2, fun c hc hcy ↦ ?_⟩
+    exact hz _ (mem_Ico.mpr ⟨((mem_Ico.mp z_mem).1.trans_lt hc).le, hcy⟩) hc
+  by_cases hxz : x < z
+  /- when `x < z`, then we may use the induction hypothesis to get a chain
+  `Relation.TransGen (· ⋖ ·) x z`, which we can extend with `Relation.TransGen.tail`. -/
+  · exact .tail (transGen_covby_of_lt hxz) hzy
+  /- when `¬ x < z`, then actually `z ≤ x` (not because it's a linear order, but because
+  `x ≤ z`), and since `z ⋖ y` we conclude that `x ⋖ y` , then `Relation.TransGen.single`. -/
+  · simp only [lt_iff_le_not_le, not_and, not_not] at hxz
+    exact .single (hzy.of_le_of_lt (hxz (mem_Ico.mp z_mem).1) hxy)
+termination_by _ => (Ico x y).card
+
+/-- In a locally finite preorder, `<` is the transitive closure of `⋖`. -/
+lemma lt_iff_transGen_covby [Preorder α] [LocallyFiniteOrder α] {x y : α} :
+    x < y ↔ TransGen (· ⋖ ·) x y := by
+  refine ⟨transGen_covby_of_lt, fun h ↦ ?_⟩
+  induction h with
+  | single hx => exact hx.1
+  | tail _ hb ih => exact ih.trans hb.1
+
+variable {β : Type*}
+
+/-- A function from a locally finite preorder is monotone if and only if it is monotone when
+restricted to pairs satisfying `a ⩿ b`. -/
+lemma monotone_iff_forall_wcovby [Preorder α] [LocallyFiniteOrder α] [Preorder β]
+    (f : α → β) : Monotone f ↔ ∀ a b : α, a ⩿ b → f a ≤ f b := by
+  refine ⟨fun hf _ _ h ↦ hf h.le, fun h a b hab ↦ ?_⟩
+  simpa [transGen_eq_self (r := ((· : β) ≤ ·)) transitive_le]
+    using TransGen.lift f h <| le_iff_transGen_wcovby.mp hab
+
+/-- A function from a locally finite partial order is monotone if and only if it is monotone when
+restricted to pairs satisfying `a ⋖ b`. -/
+lemma monotone_iff_forall_covby [PartialOrder α] [LocallyFiniteOrder α] [Preorder β]
+    (f : α → β) : Monotone f ↔ ∀ a b : α, a ⋖ b → f a ≤ f b := by
+  refine ⟨fun hf _ _ h ↦ hf h.le, fun h a b hab ↦ ?_⟩
+  simpa [reflTransGen_eq_self (r := ((· : β) ≤ ·)) IsRefl.reflexive transitive_le]
+    using ReflTransGen.lift f h <| le_iff_reflTransGen_covby.mp hab
+
+/-- A function from a locally finite preorder is strictly monotone if and only if it is strictly
+monotone when restricted to pairs satisfying `a ⋖ b`. -/
+lemma strictMono_iff_forall_covby [Preorder α] [LocallyFiniteOrder α] [Preorder β]
+    (f : α → β) : StrictMono f ↔ ∀ a b : α, a ⋖ b → f a < f b := by
+  refine ⟨fun hf _ _ h ↦ hf h.lt, fun h a b hab ↦ ?_⟩
+  have := Relation.TransGen.lift f h (a := a) (b := b)
+  rw [← lt_iff_transGen_covby, transGen_eq_self (@lt_trans β _)] at this
+  · exact this hab
+
+/-- A function from a locally finite preorder is antitone if and only if it is antitone when
+restricted to pairs satisfying `a ⩿ b`. -/
+lemma antitone_iff_forall_wcovby [Preorder α] [LocallyFiniteOrder α] [Preorder β]
+    (f : α → β) : Antitone f ↔ ∀ a b : α, a ⩿ b → f b ≤ f a :=
+  monotone_iff_forall_wcovby (β := βᵒᵈ) f
+
+/-- A function from a locally finite partial order is antitone if and only if it is antitone when
+restricted to pairs satisfying `a ⋖ b`. -/
+lemma antitone_iff_forall_covby [PartialOrder α] [LocallyFiniteOrder α] [Preorder β]
+    (f : α → β) : Antitone f ↔ ∀ a b : α, a ⋖ b → f b ≤ f a :=
+  monotone_iff_forall_covby (β := βᵒᵈ) f
+
+/-- A function from a locally finite preorder is strictly antitone if and only if it is strictly
+antitone when restricted to pairs satisfying `a ⋖ b`. -/
+lemma strictAnti_iff_forall_covby [Preorder α] [LocallyFiniteOrder α] [Preorder β]
+    (f : α → β) : StrictAnti f ↔ ∀ a b : α, a ⋖ b → f b < f a :=
+  strictMono_iff_forall_covby (β := βᵒᵈ) f
+
+end Cover

chore: tidy various files (#7041)

4a238556

Diff

@@ -1094,47 +1094,39 @@ variable [DecidableEq α]
 
 @[simp]
 theorem image_add_left_Icc (a b c : α) : (Icc a b).image ((· + ·) c) = Icc (c + a) (c + b) := by
-  rw [← map_add_left_Icc, map_eq_image]
-  rfl
+  rw [← map_add_left_Icc, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_left_Icc Finset.image_add_left_Icc
 
 @[simp]
 theorem image_add_left_Ico (a b c : α) : (Ico a b).image ((· + ·) c) = Ico (c + a) (c + b) := by
-  rw [← map_add_left_Ico, map_eq_image]
-  rfl
+  rw [← map_add_left_Ico, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_left_Ico Finset.image_add_left_Ico
 
 @[simp]
 theorem image_add_left_Ioc (a b c : α) : (Ioc a b).image ((· + ·) c) = Ioc (c + a) (c + b) := by
-  rw [← map_add_left_Ioc, map_eq_image]
-  rfl
+  rw [← map_add_left_Ioc, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_left_Ioc Finset.image_add_left_Ioc
 
 @[simp]
 theorem image_add_left_Ioo (a b c : α) : (Ioo a b).image ((· + ·) c) = Ioo (c + a) (c + b) := by
-  rw [← map_add_left_Ioo, map_eq_image]
-  rfl
+  rw [← map_add_left_Ioo, map_eq_image, addLeftEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_left_Ioo Finset.image_add_left_Ioo
 
 @[simp]
 theorem image_add_right_Icc (a b c : α) : (Icc a b).image (· + c) = Icc (a + c) (b + c) := by
-  rw [← map_add_right_Icc, map_eq_image]
-  rfl
+  rw [← map_add_right_Icc, map_eq_image, addRightEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_right_Icc Finset.image_add_right_Icc
 
 theorem image_add_right_Ico (a b c : α) : (Ico a b).image (· + c) = Ico (a + c) (b + c) := by
-  rw [← map_add_right_Ico, map_eq_image]
-  rfl
+  rw [← map_add_right_Ico, map_eq_image, addRightEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_right_Ico Finset.image_add_right_Ico
 
 theorem image_add_right_Ioc (a b c : α) : (Ioc a b).image (· + c) = Ioc (a + c) (b + c) := by
-  rw [← map_add_right_Ioc, map_eq_image]
-  rfl
+  rw [← map_add_right_Ioc, map_eq_image, addRightEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_right_Ioc Finset.image_add_right_Ioc
 
 theorem image_add_right_Ioo (a b c : α) : (Ioo a b).image (· + c) = Ioo (a + c) (b + c) := by
-  rw [← map_add_right_Ioo, map_eq_image]
-  rfl
+  rw [← map_add_right_Ioo, map_eq_image, addRightEmbedding, Embedding.coeFn_mk]
 #align finset.image_add_right_Ioo Finset.image_add_right_Ioo
 
 end OrderedCancelAddCommMonoid

Match https://github.com/leanprover-community/mathlib/pull/18989

feat: More Finset.sup' lemmas (#7021)

b2cf368d

Diff

@@ -6,7 +6,7 @@ Authors: Scott Morrison, Yaël Dillies
 import Mathlib.Order.LocallyFinite
 import Mathlib.Data.Set.Intervals.Monoid
 
-#align_import data.finset.locally_finite from "leanprover-community/mathlib"@"1d29de43a5ba4662dd33b5cfeecfc2a27a5a8a29"
+#align_import data.finset.locally_finite from "leanprover-community/mathlib"@"442a83d738cb208d3600056c489be16900ba701d"
 
 /-!
 # Intervals as finsets
@@ -345,17 +345,17 @@ theorem Ico_filter_le_of_left_le {a b c : α} [DecidablePred ((· ≤ ·) c)] (h
 
 theorem Icc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Icc a b).filter (· < c) = Icc a b :=
-  (Finset.filter_eq_self _).2 fun _ hx => lt_of_le_of_lt (mem_Icc.1 hx).2 h
+  filter_true_of_mem  fun _ hx => lt_of_le_of_lt (mem_Icc.1 hx).2 h
 #align finset.Icc_filter_lt_of_lt_right Finset.Icc_filter_lt_of_lt_right
 
 theorem Ioc_filter_lt_of_lt_right {a b c : α} [DecidablePred (· < c)] (h : b < c) :
     (Ioc a b).filter (· < c) = Ioc a b :=
-  (Finset.filter_eq_self _).2 fun _ hx => lt_of_le_of_lt (mem_Ioc.1 hx).2 h
+  filter_true_of_mem  fun _ hx => lt_of_le_of_lt (mem_Ioc.1 hx).2 h
 #align finset.Ioc_filter_lt_of_lt_right Finset.Ioc_filter_lt_of_lt_right
 
 theorem Iic_filter_lt_of_lt_right {α} [Preorder α] [LocallyFiniteOrderBot α] {a c : α}
     [DecidablePred (· < c)] (h : a < c) : (Iic a).filter (· < c) = Iic a :=
-  (Finset.filter_eq_self _).2 fun _ hx => lt_of_le_of_lt (mem_Iic.1 hx) h
+  filter_true_of_mem fun _ hx => lt_of_le_of_lt (mem_Iic.1 hx) h
 #align finset.Iic_filter_lt_of_lt_right Finset.Iic_filter_lt_of_lt_right
 
 variable (a b) [Fintype α]

feat: patch for new alias command (#6172)

19e0ba92

Diff

@@ -82,13 +82,13 @@ theorem Ioo_eq_empty_iff [DenselyOrdered α] : Ioo a b = ∅ ↔ ¬a < b := by
   rw [← coe_eq_empty, coe_Ioo, Set.Ioo_eq_empty_iff]
 #align finset.Ioo_eq_empty_iff Finset.Ioo_eq_empty_iff
 
-alias Icc_eq_empty_iff ↔ _ Icc_eq_empty
+alias ⟨_, Icc_eq_empty⟩ := Icc_eq_empty_iff
 #align finset.Icc_eq_empty Finset.Icc_eq_empty
 
-alias Ico_eq_empty_iff ↔ _ Ico_eq_empty
+alias ⟨_, Ico_eq_empty⟩ := Ico_eq_empty_iff
 #align finset.Ico_eq_empty Finset.Ico_eq_empty
 
-alias Ioc_eq_empty_iff ↔ _ Ioc_eq_empty
+alias ⟨_, Ioc_eq_empty⟩ := Ioc_eq_empty_iff
 #align finset.Ioc_eq_empty Finset.Ioc_eq_empty
 
 @[simp]

chore: banish Type _ and Sort _ (#6499)

We remove all possible occurences of Type _ and Sort _ in favor of Type* and Sort*.

This has nice performance benefits.

32de3f67

Diff

@@ -30,7 +30,7 @@ open Function OrderDual
 
 open BigOperators FinsetInterval
 
-variable {ι α : Type _}
+variable {ι α : Type*}
 
 namespace Finset

chore: script to replace headers with #align_import statements (#5979)

depends on: #5966

Co-authored-by: Eric Wieser <wieser.eric@gmail.com> Co-authored-by: Scott Morrison <scott.morrison@gmail.com>

89aa3a3b

Diff

@@ -2,15 +2,12 @@
 Copyright (c) 2019 Scott Morrison. All rights reserved.
 Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
-
-! This file was ported from Lean 3 source module data.finset.locally_finite
-! leanprover-community/mathlib commit 1d29de43a5ba4662dd33b5cfeecfc2a27a5a8a29
-! Please do not edit these lines, except to modify the commit id
-! if you have ported upstream changes.
 -/
 import Mathlib.Order.LocallyFinite
 import Mathlib.Data.Set.Intervals.Monoid
 
+#align_import data.finset.locally_finite from "leanprover-community/mathlib"@"1d29de43a5ba4662dd33b5cfeecfc2a27a5a8a29"
+
 /-!
 # Intervals as finsets

Match https://github.com/leanprover-community/mathlib/pull/18838

feat: finset.uIcc on concrete structures (#5946)

Co-authored-by: Scott Morrison <scott@tqft.net> Co-authored-by: Scott Morrison <scott.morrison@gmail.com>

ae594c90

Diff

@@ -4,7 +4,7 @@ Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 
 ! This file was ported from Lean 3 source module data.finset.locally_finite
-! leanprover-community/mathlib commit 52fa514ec337dd970d71d8de8d0fd68b455a1e54
+! leanprover-community/mathlib commit 1d29de43a5ba4662dd33b5cfeecfc2a27a5a8a29
 ! Please do not edit these lines, except to modify the commit id
 ! if you have ported upstream changes.
 -/

chore: fix upper/lowercase in comments (#4360)

Run a non-interactive version of fix-comments.py on all files.
Go through the diff and manually add/discard/edit chunks.

27d257fc

Diff

@@ -19,7 +19,7 @@ This file provides basic results about all the `Finset.Ixx`, which are defined i
 
 ## TODO
 
-This file was originally only about `finset.Ico a b` where `a b : ℕ`. No care has yet been taken to
+This file was originally only about `Finset.Ico a b` where `a b : ℕ`. No care has yet been taken to
 generalize these lemmas properly and many lemmas about `Icc`, `Ioc`, `Ioo` are missing. In general,
 what's to do is taking the lemmas in `Data.X.Intervals` and abstract away the concrete structure.

Match https://github.com/leanprover-community/mathlib/pull/18620

feat: Lemmas relating definitions of infinite sets (#3672)

7be61534

Diff

@@ -4,7 +4,7 @@ Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 
 ! This file was ported from Lean 3 source module data.finset.locally_finite
-! leanprover-community/mathlib commit f24cc2891c0e328f0ee8c57387103aa462c44b5e
+! leanprover-community/mathlib commit 52fa514ec337dd970d71d8de8d0fd68b455a1e54
 ! Please do not edit these lines, except to modify the commit id
 ! if you have ported upstream changes.
 -/
@@ -464,6 +464,10 @@ theorem _root_.BddBelow.finite {s : Set α} (hs : BddBelow s) : s.Finite :=
   (Ici a).finite_toSet.subset fun _ hx => mem_Ici.2 <| ha hx
 #align bdd_below.finite BddBelow.finite
 
+theorem _root_.Set.Infinite.not_bddBelow {s : Set α} : s.Infinite → ¬BddBelow s :=
+  mt BddBelow.finite
+#align set.infinite.not_bdd_below Set.Infinite.not_bddBelow
+
 variable [Fintype α]
 
 theorem filter_lt_eq_Ioi [DecidablePred ((· < ·) a)] : univ.filter ((· < ·) a) = Ioi a := by
@@ -490,6 +494,10 @@ theorem _root_.BddAbove.finite {s : Set α} (hs : BddAbove s) : s.Finite :=
   hs.dual.finite
 #align bdd_above.finite BddAbove.finite
 
+theorem _root_.Set.Infinite.not_bddAbove {s : Set α} : s.Infinite → ¬BddAbove s :=
+  mt BddAbove.finite
+#align set.infinite.not_bdd_above Set.Infinite.not_bddAbove
+
 variable [Fintype α]
 
 theorem filter_gt_eq_Iio [DecidablePred (· < a)] : univ.filter (· < a) = Iio a := by
@@ -825,6 +833,32 @@ theorem Ico_diff_Ico_right (a b c : α) : Ico a b \ Ico c b = Ico a (min b c) :=
 
 end LocallyFiniteOrder
 
+section LocallyFiniteOrderBot
+variable [LocallyFiniteOrderBot α] {s : Set α}
+
+theorem _root_.Set.Infinite.exists_gt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, a < b :=
+  not_bddAbove_iff.1 hs.not_bddAbove
+#align set.infinite.exists_gt Set.Infinite.exists_gt
+
+theorem _root_.Set.infinite_iff_exists_gt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, a < b :=
+  ⟨Set.Infinite.exists_gt, Set.infinite_of_forall_exists_gt⟩
+#align set.infinite_iff_exists_gt Set.infinite_iff_exists_gt
+
+end LocallyFiniteOrderBot
+
+section LocallyFiniteOrderTop
+variable [LocallyFiniteOrderTop α] {s : Set α}
+
+theorem _root_.Set.Infinite.exists_lt (hs : s.Infinite) : ∀ a, ∃ b ∈ s, b < a :=
+  not_bddBelow_iff.1 hs.not_bddBelow
+#align set.infinite.exists_lt Set.Infinite.exists_lt
+
+theorem _root_.Set.infinite_iff_exists_lt [Nonempty α] : s.Infinite ↔ ∀ a, ∃ b ∈ s, b < a :=
+  ⟨Set.Infinite.exists_lt, Set.infinite_of_forall_exists_lt⟩
+#align set.infinite_iff_exists_lt Set.infinite_iff_exists_lt
+
+end LocallyFiniteOrderTop
+
 variable [Fintype α] [LocallyFiniteOrderTop α] [LocallyFiniteOrderBot α]
 
 theorem Ioi_disjUnion_Iio (a : α) :

chore: forward-port leanprover-community/mathlib#18533 (#2812)

087d585c

Diff

@@ -4,7 +4,7 @@ Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Scott Morrison, Yaël Dillies
 
 ! This file was ported from Lean 3 source module data.finset.locally_finite
-! leanprover-community/mathlib commit e3d9ab8faa9dea8f78155c6c27d62a621f4c152d
+! leanprover-community/mathlib commit f24cc2891c0e328f0ee8c57387103aa462c44b5e
 ! Please do not edit these lines, except to modify the commit id
 ! if you have ported upstream changes.
 -/
@@ -601,14 +601,27 @@ theorem Ico_inter_Ico_consecutive (a b c : α) : Ico a b ∩ Ico b c = ∅ :=
 end DecidableEq
 
 -- Those lemmas are purposefully the other way around
+
+/-- `Finset.cons` version of `Finset.Ico_insert_right`. -/
 theorem Icc_eq_cons_Ico (h : a ≤ b) : Icc a b = (Ico a b).cons b right_not_mem_Ico := by
   classical rw [cons_eq_insert, Ico_insert_right h]
 #align finset.Icc_eq_cons_Ico Finset.Icc_eq_cons_Ico
 
+/-- `Finset.cons` version of `Finset.Ioc_insert_left`. -/
 theorem Icc_eq_cons_Ioc (h : a ≤ b) : Icc a b = (Ioc a b).cons a left_not_mem_Ioc := by
   classical rw [cons_eq_insert, Ioc_insert_left h]
 #align finset.Icc_eq_cons_Ioc Finset.Icc_eq_cons_Ioc
 
+/-- `Finset.cons` version of `Finset.Ioo_insert_right`. -/
+theorem Ioc_eq_cons_Ioo (h : a < b) : Ioc a b = (Ioo a b).cons b right_not_mem_Ioo := by
+  classical rw [cons_eq_insert, Ioo_insert_right h]
+#align finset.Ioc_eq_cons_Ioo Finset.Ioc_eq_cons_Ioo
+
+/-- `Finset.cons` version of `Finset.Ioo_insert_left`. -/
+theorem Ico_eq_cons_Ioo (h : a < b) : Ico a b = (Ioo a b).cons a left_not_mem_Ioo := by
+  classical rw [cons_eq_insert, Ioo_insert_left h]
+#align finset.Ico_eq_cons_Ioo Finset.Ico_eq_cons_Ioo
+
 theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
     ((Ico a b).filter fun x => x ≤ a) = {a} := by
   ext x
@@ -619,7 +632,7 @@ theorem Ico_filter_le_left {a b : α} [DecidablePred (· ≤ a)] (hab : a < b) :
 theorem card_Ico_eq_card_Icc_sub_one (a b : α) : (Ico a b).card = (Icc a b).card - 1 := by
   classical
     by_cases h : a ≤ b
-    · rw [← Ico_insert_right h, card_insert_of_not_mem right_not_mem_Ico]
+    · rw [Icc_eq_cons_Ico h, card_cons]
       exact (Nat.add_sub_cancel _ _).symm
     · rw [Ico_eq_empty fun h' => h h'.le, Icc_eq_empty h, card_empty, zero_tsub]
 #align finset.card_Ico_eq_card_Icc_sub_one Finset.card_Ico_eq_card_Icc_sub_one
@@ -630,12 +643,10 @@ theorem card_Ioc_eq_card_Icc_sub_one (a b : α) : (Ioc a b).card = (Icc a b).car
 
 theorem card_Ioo_eq_card_Ico_sub_one (a b : α) : (Ioo a b).card = (Ico a b).card - 1 := by
   classical
-    by_cases h : a ≤ b
-    · obtain rfl | h' := h.eq_or_lt
-      · rw [Ioo_self, Ico_self, card_empty]
-      rw [← Ioo_insert_left h', card_insert_of_not_mem left_not_mem_Ioo]
+    by_cases h : a < b
+    · rw [Ico_eq_cons_Ioo h, card_cons]
       exact (Nat.add_sub_cancel _ _).symm
-    · rw [Ioo_eq_empty fun h' => h h'.le, Ico_eq_empty fun h' => h h'.le, card_empty, zero_tsub]
+    · rw [Ioo_eq_empty h, Ico_eq_empty h, card_empty, zero_tsub]
 #align finset.card_Ioo_eq_card_Ico_sub_one Finset.card_Ioo_eq_card_Ico_sub_one
 
 theorem card_Ioo_eq_card_Ioc_sub_one (a b : α) : (Ioo a b).card = (Ioc a b).card - 1 :=
@@ -675,6 +686,7 @@ theorem not_mem_Ioi_self {b : α} : b ∉ Ioi b := fun h => lt_irrefl _ (mem_Ioi
 #align finset.not_mem_Ioi_self Finset.not_mem_Ioi_self
 
 -- Purposefully written the other way around
+/-- `Finset.cons` version of `Finset.Ioi_insert`. -/
 theorem Ici_eq_cons_Ioi (a : α) : Ici a = (Ioi a).cons a not_mem_Ioi_self := by
   classical rw [cons_eq_insert, Ioi_insert]
 #align finset.Ici_eq_cons_Ioi Finset.Ici_eq_cons_Ioi
@@ -707,6 +719,7 @@ theorem not_mem_Iio_self {b : α} : b ∉ Iio b := fun h => lt_irrefl _ (mem_Iio
 #align finset.not_mem_Iio_self Finset.not_mem_Iio_self
 
 -- Purposefully written the other way around
+/-- `Finset.cons` version of `Finset.Iio_insert`. -/
 theorem Iic_eq_cons_Iio (b : α) : Iic b = (Iio b).cons b not_mem_Iio_self := by
   classical rw [cons_eq_insert, Iio_insert]
 #align finset.Iic_eq_cons_Iio Finset.Iic_eq_cons_Iio

chore: tidy various files (#2251)

0a70c6a6

Diff

@@ -263,17 +263,17 @@ theorem Icc_subset_Ioc_iff (h₁ : a₁ ≤ b₁) : Icc a₁ b₁ ⊆ Ioc a₂ b
 #align finset.Icc_subset_Ioc_iff Finset.Icc_subset_Ioc_iff
 
 --TODO: `Ico_subset_Ioo_iff`, `Ioc_subset_Ioo_iff`
-theorem Icc_sSubset_Icc_left (hI : a₂ ≤ b₂) (ha : a₂ < a₁) (hb : b₁ ≤ b₂) :
+theorem Icc_ssubset_Icc_left (hI : a₂ ≤ b₂) (ha : a₂ < a₁) (hb : b₁ ≤ b₂) :
     Icc a₁ b₁ ⊂ Icc a₂ b₂ := by
   rw [← coe_ssubset, coe_Icc, coe_Icc]
   exact Set.Icc_ssubset_Icc_left hI ha hb
-#align finset.Icc_ssubset_Icc_left Finset.Icc_sSubset_Icc_left
+#align finset.Icc_ssubset_Icc_left Finset.Icc_ssubset_Icc_left
 
-theorem Icc_sSubset_Icc_right (hI : a₂ ≤ b₂) (ha : a₂ ≤ a₁) (hb : b₁ < b₂) :
+theorem Icc_ssubset_Icc_right (hI : a₂ ≤ b₂) (ha : a₂ ≤ a₁) (hb : b₁ < b₂) :
     Icc a₁ b₁ ⊂ Icc a₂ b₂ := by
   rw [← coe_ssubset, coe_Icc, coe_Icc]
   exact Set.Icc_ssubset_Icc_right hI ha hb
-#align finset.Icc_ssubset_Icc_right Finset.Icc_sSubset_Icc_right
+#align finset.Icc_ssubset_Icc_right Finset.Icc_ssubset_Icc_right
 
 variable (a)

chore: scoped BigOperators notation (#1952)

e707fa67

Diff

@@ -31,9 +31,7 @@ for some ideas.
 
 open Function OrderDual
 
--- Porting note: Fix once big operators are localised again.
--- open BigOperators FinsetInterval
-open FinsetInterval
+open BigOperators FinsetInterval
 
 variable {ι α : Type _}