HepLean Documentation

Mathlib.Data.Setoid.Basic

Equivalence relations #

This file defines the complete lattice of equivalence relations on a type, results about the inductively defined equivalence closure of a binary relation, and the analogues of some isomorphism theorems for quotients of arbitrary types.

Implementation notes #

The complete lattice instance for equivalence relations could have been defined by lifting the Galois insertion of equivalence relations on α into binary relations on α, and then using CompleteLattice.copy to define a complete lattice instance with more appropriate definitional equalities (a similar example is Filter.CompleteLattice in Order/Filter/Basic.lean). This does not save space, however, and is less clear.

Partitions are not defined as a separate structure here; users are encouraged to reason about them using the existing Setoid and its infrastructure.

Tags #

setoid, equivalence, iseqv, relation, equivalence relation

@[deprecated]
def Setoid.Rel {α : Type u_1} (r : Setoid α) :
ααProp

A version of Setoid.r that takes the equivalence relation as an explicit argument.

Equations
  • r.Rel = r
Instances For
    @[deprecated]
    instance Setoid.decidableRel {α : Type u_1} (r : Setoid α) [h : DecidableRel r] :
    Equations
    • r.decidableRel = h
    @[deprecated Quotient.eq']
    theorem Quotient.eq_rel {α : Type u_1} {r : Setoid α} {x : α} {y : α} :

    A version of Quotient.eq' compatible with Setoid.Rel, to make rewriting possible.

    theorem Setoid.ext_iff {α : Sort u_3} {s : Setoid α} {t : Setoid α} :
    s = t ∀ (a b : α), s a b t a b
    @[deprecated Setoid.ext]
    theorem Setoid.ext' {α : Type u_1} {r : Setoid α} {s : Setoid α} (H : ∀ (a b : α), r.Rel a b s.Rel a b) :
    r = s
    @[deprecated Setoid.ext_iff]
    theorem Setoid.ext'_iff {α : Type u_1} {r : Setoid α} {s : Setoid α} :
    r = s ∀ (a b : α), r.Rel a b s.Rel a b
    theorem Setoid.eq_iff_rel_eq {α : Type u_1} {r₁ : Setoid α} {r₂ : Setoid α} :
    r₁ = r₂ r₁ = r₂

    Two equivalence relations are equal iff their underlying binary operations are equal.

    instance Setoid.instLE_mathlib {α : Type u_1} :
    LE (Setoid α)

    Defining for equivalence relations.

    Equations
    • Setoid.instLE_mathlib = { le := fun (r s : Setoid α) => ∀ ⦃x y : α⦄, r x ys x y }
    theorem Setoid.le_def {α : Type u_1} {r : Setoid α} {s : Setoid α} :
    r s ∀ {x y : α}, r x ys x y
    theorem Setoid.refl' {α : Type u_1} (r : Setoid α) (x : α) :
    r x x
    theorem Setoid.symm' {α : Type u_1} (r : Setoid α) {x : α} {y : α} :
    r x yr y x
    theorem Setoid.trans' {α : Type u_1} (r : Setoid α) {x : α} {y : α} {z : α} :
    r x yr y zr x z
    theorem Setoid.comm' {α : Type u_1} (s : Setoid α) {x : α} {y : α} :
    s x y s y x
    def Setoid.ker {α : Type u_1} {β : Type u_2} (f : αβ) :

    The kernel of a function is an equivalence relation.

    Equations
    • Setoid.ker f = { r := (fun (x1 x2 : β) => x1 = x2) on f, iseqv := }
    Instances For
      @[simp]
      theorem Setoid.ker_mk_eq {α : Type u_1} (r : Setoid α) :
      Setoid.ker Quotient.mk'' = r

      The kernel of the quotient map induced by an equivalence relation r equals r.

      theorem Setoid.ker_apply_mk_out {α : Type u_1} {β : Type u_2} {f : αβ} (a : α) :
      f a.out = f a
      theorem Setoid.ker_apply_mk_out' {α : Type u_1} {β : Type u_2} {f : αβ} (a : α) :
      f a.out' = f a
      theorem Setoid.ker_def {α : Type u_1} {β : Type u_2} {f : αβ} {x : α} {y : α} :
      (Setoid.ker f) x y f x = f y
      def Setoid.prod {α : Type u_1} {β : Type u_2} (r : Setoid α) (s : Setoid β) :
      Setoid (α × β)

      Given types α, β, the product of two equivalence relations r on α and s on β: (x₁, x₂), (y₁, y₂) ∈ α × β are related by r.prod s iff x₁ is related to y₁ by r and x₂ is related to y₂ by s.

      Equations
      • r.prod s = { r := fun (x y : α × β) => r x.1 y.1 s x.2 y.2, iseqv := }
      Instances For
        theorem Setoid.prod_apply {α : Type u_1} {β : Type u_2} {r : Setoid α} {s : Setoid β} {x₁ : α} {x₂ : α} {y₁ : β} {y₂ : β} :
        (r.prod s) (x₁, y₁) (x₂, y₂) r x₁ x₂ s y₁ y₂
        theorem Setoid.piSetoid_apply {ι : Sort u_3} {α : ιSort u_4} {r : (i : ι) → Setoid (α i)} {x : (i : ι) → α i} {y : (i : ι) → α i} :
        piSetoid x y ∀ (i : ι), (r i) (x i) (y i)
        @[simp]
        theorem Setoid.prodQuotientEquiv_symm_apply {α : Type u_1} {β : Type u_2} (r : Setoid α) (s : Setoid β) (q : Quotient (r.prod s)) :
        (r.prodQuotientEquiv s).symm q = q.liftOn' (fun (xy : α × β) => (Quotient.mk'' xy.1, Quotient.mk'' xy.2))
        @[simp]
        theorem Setoid.prodQuotientEquiv_apply {α : Type u_1} {β : Type u_2} (r : Setoid α) (s : Setoid β) :
        ∀ (x : Quotient r × Quotient s), (r.prodQuotientEquiv s) x = match x with | (x, y) => Quotient.map₂' Prod.mk x y
        def Setoid.prodQuotientEquiv {α : Type u_1} {β : Type u_2} (r : Setoid α) (s : Setoid β) :

        A bijection between the product of two quotients and the quotient by the product of the equivalence relations.

        Equations
        • One or more equations did not get rendered due to their size.
        Instances For
          @[simp]
          theorem Setoid.piQuotientEquiv_apply {ι : Sort u_3} {α : ιSort u_4} (r : (i : ι) → Setoid (α i)) (x : (i : ι) → Quotient (r i)) :
          (Setoid.piQuotientEquiv r) x = Quotient.mk'' fun (i : ι) => (x i).out'
          @[simp]
          theorem Setoid.piQuotientEquiv_symm_apply {ι : Sort u_3} {α : ιSort u_4} (r : (i : ι) → Setoid (α i)) (q : Quotient piSetoid) (i : ι) :
          (Setoid.piQuotientEquiv r).symm q i = q.liftOn' (fun (x : (i : ι) → α i) (i : ι) => Quotient.mk'' (x i)) i
          noncomputable def Setoid.piQuotientEquiv {ι : Sort u_3} {α : ιSort u_4} (r : (i : ι) → Setoid (α i)) :
          ((i : ι) → Quotient (r i)) Quotient piSetoid

          A bijection between an indexed product of quotients and the quotient by the product of the equivalence relations.

          Equations
          • One or more equations did not get rendered due to their size.
          Instances For
            instance Setoid.instInf {α : Type u_1} :
            Inf (Setoid α)

            The infimum of two equivalence relations.

            Equations
            • Setoid.instInf = { inf := fun (r s : Setoid α) => { r := fun (x y : α) => r x y s x y, iseqv := } }
            theorem Setoid.inf_def {α : Type u_1} {r : Setoid α} {s : Setoid α} :
            (r s) = r s

            The infimum of 2 equivalence relations r and s is the same relation as the infimum of the underlying binary operations.

            theorem Setoid.inf_iff_and {α : Type u_1} {r : Setoid α} {s : Setoid α} {x : α} {y : α} :
            (r s) x y r x y s x y
            instance Setoid.instInfSet {α : Type u_1} :

            The infimum of a set of equivalence relations.

            Equations
            • Setoid.instInfSet = { sInf := fun (S : Set (Setoid α)) => { r := fun (x y : α) => rS, r x y, iseqv := } }
            theorem Setoid.sInf_def {α : Type u_1} {s : Set (Setoid α)} :
            (sInf s) = sInf (@Setoid.r α '' s)

            The underlying binary operation of the infimum of a set of equivalence relations is the infimum of the set's image under the map to the underlying binary operation.

            Equations

            The complete lattice of equivalence relations on a type, with bottom element = and top element the trivial equivalence relation.

            Equations
            @[simp]
            theorem Setoid.top_def {α : Type u_1} :
            =
            @[simp]
            theorem Setoid.bot_def {α : Type u_1} :
            = fun (x1 x2 : α) => x1 = x2
            theorem Setoid.eq_top_iff {α : Type u_1} {s : Setoid α} :
            s = ∀ (x y : α), s x y
            theorem Setoid.sInf_equiv {α : Type u_1} {S : Set (Setoid α)} {x : α} {y : α} :
            x y sS, s x y
            theorem Setoid.sInf_iff {α : Type u_1} {S : Set (Setoid α)} {x : α} {y : α} :
            (sInf S) x y sS, s x y
            theorem Setoid.quotient_mk_sInf_eq {α : Type u_1} {S : Set (Setoid α)} {x : α} {y : α} :
            x = y sS, s x y
            def Setoid.map_of_le {α : Type u_1} {s : Setoid α} {t : Setoid α} (h : s t) :

            The map induced between quotients by a setoid inequality.

            Equations
            Instances For
              def Setoid.map_sInf {α : Type u_1} {S : Set (Setoid α)} {s : Setoid α} (h : s S) :

              The map from the quotient of the infimum of a set of setoids into the quotient by an element of this set.

              Equations
              Instances For
                theorem Setoid.eqvGen_eq {α : Type u_1} (r : ααProp) :
                Relation.EqvGen.setoid r = sInf {s : Setoid α | ∀ ⦃x y : α⦄, r x ys x y}

                The inductively defined equivalence closure of a binary relation r is the infimum of the set of all equivalence relations containing r.

                theorem Setoid.sup_eq_eqvGen {α : Type u_1} (r : Setoid α) (s : Setoid α) :
                r s = Relation.EqvGen.setoid fun (x y : α) => r x y s x y

                The supremum of two equivalence relations r and s is the equivalence closure of the binary relation x is related to y by r or s.

                theorem Setoid.sup_def {α : Type u_1} {r : Setoid α} {s : Setoid α} :

                The supremum of 2 equivalence relations r and s is the equivalence closure of the supremum of the underlying binary operations.

                theorem Setoid.sSup_eq_eqvGen {α : Type u_1} (S : Set (Setoid α)) :
                sSup S = Relation.EqvGen.setoid fun (x y : α) => rS, r x y

                The supremum of a set S of equivalence relations is the equivalence closure of the binary relation there exists r ∈ S relating x and y.

                theorem Setoid.sSup_def {α : Type u_1} {s : Set (Setoid α)} :

                The supremum of a set of equivalence relations is the equivalence closure of the supremum of the set's image under the map to the underlying binary operation.

                @[simp]
                theorem Setoid.eqvGen_of_setoid {α : Type u_1} (r : Setoid α) :

                The equivalence closure of an equivalence relation r is r.

                Equivalence closure is idempotent.

                theorem Setoid.eqvGen_le {α : Type u_1} {r : ααProp} {s : Setoid α} (h : ∀ (x y : α), r x ys x y) :

                The equivalence closure of a binary relation r is contained in any equivalence relation containing r.

                theorem Setoid.eqvGen_mono {α : Type u_1} {r : ααProp} {s : ααProp} (h : ∀ (x y : α), r x ys x y) :

                Equivalence closure of binary relations is monotone.

                def Setoid.gi {α : Type u_1} :
                GaloisInsertion Relation.EqvGen.setoid (@Setoid.r α)

                There is a Galois insertion of equivalence relations on α into binary relations on α, with equivalence closure the lower adjoint.

                Equations
                Instances For
                  theorem Setoid.injective_iff_ker_bot {α : Type u_1} {β : Type u_2} (f : αβ) :

                  A function from α to β is injective iff its kernel is the bottom element of the complete lattice of equivalence relations on α.

                  theorem Setoid.ker_iff_mem_preimage {α : Type u_1} {β : Type u_2} {f : αβ} {x : α} {y : α} :
                  (Setoid.ker f) x y x f ⁻¹' {f y}

                  The elements related to x ∈ α by the kernel of f are those in the preimage of f(x) under f.

                  def Setoid.liftEquiv {α : Type u_1} {β : Type u_2} (r : Setoid α) :
                  { f : αβ // r Setoid.ker f } (Quotient rβ)

                  Equivalence between functions α → β such that r x y → f x = f y and functions quotient r → β.

                  Equations
                  • r.liftEquiv = { toFun := fun (f : { f : αβ // r Setoid.ker f }) => Quotient.lift f , invFun := fun (f : Quotient rβ) => f Quotient.mk'', , left_inv := , right_inv := }
                  Instances For
                    theorem Setoid.lift_unique {α : Type u_1} {β : Type u_2} {r : Setoid α} {f : αβ} (H : r Setoid.ker f) (g : Quotient rβ) (Hg : f = g Quotient.mk'') :

                    The uniqueness part of the universal property for quotients of an arbitrary type.

                    theorem Setoid.ker_lift_injective {α : Type u_1} {β : Type u_2} (f : αβ) :

                    Given a map f from α to β, the natural map from the quotient of α by the kernel of f is injective.

                    theorem Setoid.ker_eq_lift_of_injective {α : Type u_1} {β : Type u_2} {r : Setoid α} (f : αβ) (H : ∀ (x y : α), r x yf x = f y) (h : Function.Injective (Quotient.lift f H)) :

                    Given a map f from α to β, the kernel of f is the unique equivalence relation on α whose induced map from the quotient of α to β is injective.

                    noncomputable def Setoid.quotientKerEquivRange {α : Type u_1} {β : Type u_2} (f : αβ) :

                    The first isomorphism theorem for sets: the quotient of α by the kernel of a function f bijects with f's image.

                    Equations
                    Instances For
                      @[simp]
                      theorem Setoid.quotientKerEquivOfRightInverse_apply {α : Type u_1} {β : Type u_2} (f : αβ) (g : βα) (hf : Function.RightInverse g f) (a : Quotient (Setoid.ker f)) :
                      (Setoid.quotientKerEquivOfRightInverse f g hf) a = a.liftOn' f
                      @[simp]
                      theorem Setoid.quotientKerEquivOfRightInverse_symm_apply {α : Type u_1} {β : Type u_2} (f : αβ) (g : βα) (hf : Function.RightInverse g f) (b : β) :
                      def Setoid.quotientKerEquivOfRightInverse {α : Type u_1} {β : Type u_2} (f : αβ) (g : βα) (hf : Function.RightInverse g f) :

                      If f has a computable right-inverse, then the quotient by its kernel is equivalent to its domain.

                      Equations
                      Instances For
                        noncomputable def Setoid.quotientKerEquivOfSurjective {α : Type u_1} {β : Type u_2} (f : αβ) (hf : Function.Surjective f) :

                        The quotient of α by the kernel of a surjective function f bijects with f's codomain.

                        If a specific right-inverse of f is known, Setoid.quotientKerEquivOfRightInverse can be definitionally more useful.

                        Equations
                        Instances For
                          def Setoid.map {α : Type u_1} {β : Type u_2} (r : Setoid α) (f : αβ) :

                          Given a function f : α → β and equivalence relation r on α, the equivalence closure of the relation on f's image defined by 'x ≈ y iff the elements of f⁻¹(x) are related to the elements of f⁻¹(y) by r.'

                          Equations
                          Instances For
                            def Setoid.mapOfSurjective {α : Type u_1} {β : Type u_2} (r : Setoid α) (f : αβ) (h : Setoid.ker f r) (hf : Function.Surjective f) :

                            Given a surjective function f whose kernel is contained in an equivalence relation r, the equivalence relation on f's codomain defined by x ≈ y ↔ the elements of f⁻¹(x) are related to the elements of f⁻¹(y) by r.

                            Equations
                            • r.mapOfSurjective f h hf = { r := fun (x y : β) => ∃ (a : α) (b : α), f a = x f b = y r a b, iseqv := }
                            Instances For
                              theorem Setoid.mapOfSurjective_eq_map {α : Type u_1} {β : Type u_2} {r : Setoid α} {f : αβ} (h : Setoid.ker f r) (hf : Function.Surjective f) :
                              r.map f = r.mapOfSurjective f h hf

                              A special case of the equivalence closure of an equivalence relation r equalling r.

                              @[reducible, inline]
                              abbrev Setoid.comap {α : Type u_1} {β : Type u_2} (f : αβ) (r : Setoid β) :

                              Given a function f : α → β, an equivalence relation r on β induces an equivalence relation on α defined by 'x ≈ y iff f(x) is related to f(y) by r'.

                              See note [reducible non-instances].

                              Equations
                              Instances For
                                theorem Setoid.comap_rel {α : Type u_1} {β : Type u_2} (f : αβ) (r : Setoid β) (x : α) (y : α) :
                                (Setoid.comap f r) x y r (f x) (f y)
                                theorem Setoid.comap_eq {α : Type u_1} {β : Type u_2} {f : αβ} {r : Setoid β} :
                                Setoid.comap f r = Setoid.ker (Quotient.mk'' f)

                                Given a map f : N → M and an equivalence relation r on β, the equivalence relation induced on α by f equals the kernel of r's quotient map composed with f.

                                noncomputable def Setoid.comapQuotientEquiv {α : Type u_1} {β : Type u_2} (f : αβ) (r : Setoid β) :
                                Quotient (Setoid.comap f r) (Set.range (Quotient.mk'' f))

                                The second isomorphism theorem for sets.

                                Equations
                                Instances For

                                  The third isomorphism theorem for sets.

                                  Equations
                                  • One or more equations did not get rendered due to their size.
                                  Instances For
                                    def Setoid.correspondence {α : Type u_1} (r : Setoid α) :
                                    { s : Setoid α // r s } ≃o Setoid (Quotient r)

                                    Given an equivalence relation r on α, the order-preserving bijection between the set of equivalence relations containing r and the equivalence relations on the quotient of α by r.

                                    Equations
                                    • One or more equations did not get rendered due to their size.
                                    Instances For
                                      def Setoid.sigmaQuotientEquivOfLe {α : Type u_1} {r : Setoid α} {s : Setoid α} (hle : r s) :
                                      (q : Quotient s) × Quotient (Setoid.comap Subtype.val r) Quotient r

                                      Given two equivalence relations with r ≤ s, a bijection between the sum of the quotients by r on each equivalence class by s and the quotient by r.

                                      Equations
                                      • One or more equations did not get rendered due to their size.
                                      Instances For
                                        @[simp]
                                        theorem Quotient.subsingleton_iff {α : Type u_1} {s : Setoid α} :
                                        theorem Quot.subsingleton_iff {α : Type u_1} (r : ααProp) :