Documentation

Mathlib.Order.RelSeries

Series of a relation #

If r is a relation on α then a relation series of length n is a series a_0, a_1, ..., a_n such that r a_i a_{i+1} for all i < n

structure RelSeries {α : Type u_1} (r : Rel α α) :
Type u_1

Let r be a relation on α, a relation series of r of length n is a series a_0, a_1, ..., a_n such that r a_i a_{i+1} for all i < n

  • length :

    The number of inequalities in the series

  • toFun : Fin (self.length + 1)α

    The underlying function of a relation series

  • step : ∀ (i : Fin self.length), r (self.toFun i.castSucc) (self.toFun i.succ)

    Adjacent elements are related

Instances For
    theorem RelSeries.step {α : Type u_1} {r : Rel α α} (self : RelSeries r) (i : Fin self.length) :
    r (self.toFun i.castSucc) (self.toFun i.succ)

    Adjacent elements are related

    instance RelSeries.instCoeFunForallFinHAddNatLengthOfNat {α : Type u_1} (r : Rel α α) :
    CoeFun (RelSeries r) fun (x : RelSeries r) => Fin (x.length + 1)α
    Equations
    @[simp]
    theorem RelSeries.singleton_length {α : Type u_1} (r : Rel α α) (a : α) :
    (RelSeries.singleton r a).length = 0
    @[simp]
    theorem RelSeries.singleton_toFun {α : Type u_1} (r : Rel α α) (a : α) :
    ∀ (x : Fin (0 + 1)), (RelSeries.singleton r a).toFun x = a
    def RelSeries.singleton {α : Type u_1} (r : Rel α α) (a : α) :

    For any type α, each term of α gives a relation series with the right most index to be 0.

    Equations
    Instances For
      instance RelSeries.instIsEmpty {α : Type u_1} (r : Rel α α) [IsEmpty α] :
      Equations
      • =
      instance RelSeries.instInhabited {α : Type u_1} (r : Rel α α) [Inhabited α] :
      Equations
      instance RelSeries.instNonempty {α : Type u_1} (r : Rel α α) [Nonempty α] :
      Equations
      • =
      theorem RelSeries.ext {α : Type u_1} {r : Rel α α} {x : RelSeries r} {y : RelSeries r} (length_eq : x.length = y.length) (toFun_eq : x.toFun = y.toFun Fin.cast ) :
      x = y
      theorem RelSeries.rel_of_lt {α : Type u_1} {r : Rel α α} [IsTrans α r] (x : RelSeries r) {i : Fin (x.length + 1)} {j : Fin (x.length + 1)} (h : i < j) :
      r (x.toFun i) (x.toFun j)
      theorem RelSeries.rel_or_eq_of_le {α : Type u_1} {r : Rel α α} [IsTrans α r] (x : RelSeries r) {i : Fin (x.length + 1)} {j : Fin (x.length + 1)} (h : i j) :
      r (x.toFun i) (x.toFun j) x.toFun i = x.toFun j
      @[simp]
      theorem RelSeries.ofLE_length {α : Type u_1} {r : Rel α α} (x : RelSeries r) {s : Rel α α} (h : r s) :
      (x.ofLE h).length = x.length
      @[simp]
      theorem RelSeries.ofLE_toFun {α : Type u_1} {r : Rel α α} (x : RelSeries r) {s : Rel α α} (h : r s) :
      ∀ (a : Fin (x.length + 1)), (x.ofLE h).toFun a = x.toFun a
      def RelSeries.ofLE {α : Type u_1} {r : Rel α α} (x : RelSeries r) {s : Rel α α} (h : r s) :

      Given two relations r, s on α such that r ≤ s, any relation series of r induces a relation series of s

      Equations
      • x.ofLE h = { length := x.length, toFun := x.toFun, step := }
      Instances For
        theorem RelSeries.coe_ofLE {α : Type u_1} {r : Rel α α} (x : RelSeries r) {s : Rel α α} (h : r s) :
        (x.ofLE h).toFun = x.toFun
        def RelSeries.toList {α : Type u_1} {r : Rel α α} (x : RelSeries r) :
        List α

        Every relation series gives a list

        Equations
        Instances For
          @[simp]
          theorem RelSeries.length_toList {α : Type u_1} {r : Rel α α} (x : RelSeries r) :
          x.toList.length = x.length + 1
          theorem RelSeries.toList_chain' {α : Type u_1} {r : Rel α α} (x : RelSeries r) :
          List.Chain' r x.toList
          theorem RelSeries.toList_ne_nil {α : Type u_1} {r : Rel α α} (x : RelSeries r) :
          x.toList []
          @[simp]
          theorem RelSeries.fromListChain'_length {α : Type u_1} {r : Rel α α} (x : List α) (x_ne_nil : x []) (hx : List.Chain' r x) :
          (RelSeries.fromListChain' x x_ne_nil hx).length = x.length - 1
          @[simp]
          theorem RelSeries.fromListChain'_toFun {α : Type u_1} {r : Rel α α} (x : List α) (x_ne_nil : x []) (hx : List.Chain' r x) (i : Fin (x.length - 1 + 1)) :
          (RelSeries.fromListChain' x x_ne_nil hx).toFun i = x[Fin.cast i]
          def RelSeries.fromListChain' {α : Type u_1} {r : Rel α α} (x : List α) (x_ne_nil : x []) (hx : List.Chain' r x) :

          Every nonempty list satisfying the chain condition gives a relation series

          Equations
          Instances For
            def RelSeries.Equiv {α : Type u_1} {r : Rel α α} :
            RelSeries r {x : List α | x [] List.Chain' r x}

            Relation series of r and nonempty list of α satisfying r-chain condition bijectively corresponds to each other.

            Equations
            • One or more equations did not get rendered due to their size.
            Instances For
              theorem RelSeries.toList_injective {α : Type u_1} {r : Rel α α} :
              Function.Injective RelSeries.toList
              class Rel.FiniteDimensional {α : Type u_1} (r : Rel α α) :

              A relation r is said to be finite dimensional iff there is a relation series of r with the maximum length.

              • exists_longest_relSeries : ∃ (x : RelSeries r), ∀ (y : RelSeries r), y.length x.length

                A relation r is said to be finite dimensional iff there is a relation series of r with the maximum length.

              Instances
                theorem Rel.FiniteDimensional.exists_longest_relSeries {α : Type u_1} {r : Rel α α} [self : r.FiniteDimensional] :
                ∃ (x : RelSeries r), ∀ (y : RelSeries r), y.length x.length

                A relation r is said to be finite dimensional iff there is a relation series of r with the maximum length.

                class Rel.InfiniteDimensional {α : Type u_1} (r : Rel α α) :

                A relation r is said to be infinite dimensional iff there exists relation series of arbitrary length.

                • exists_relSeries_with_length : ∀ (n : ), ∃ (x : RelSeries r), x.length = n

                  A relation r is said to be infinite dimensional iff there exists relation series of arbitrary length.

                Instances
                  theorem Rel.InfiniteDimensional.exists_relSeries_with_length {α : Type u_1} {r : Rel α α} [self : r.InfiniteDimensional] (n : ) :
                  ∃ (x : RelSeries r), x.length = n

                  A relation r is said to be infinite dimensional iff there exists relation series of arbitrary length.

                  noncomputable def RelSeries.longestOf {α : Type u_1} (r : Rel α α) [r.FiniteDimensional] :

                  The longest relational series when a relation is finite dimensional

                  Equations
                  Instances For
                    theorem RelSeries.length_le_length_longestOf {α : Type u_1} (r : Rel α α) [r.FiniteDimensional] (x : RelSeries r) :
                    x.length (RelSeries.longestOf r).length
                    noncomputable def RelSeries.withLength {α : Type u_1} (r : Rel α α) [r.InfiniteDimensional] (n : ) :

                    A relation series with length n if the relation is infinite dimensional

                    Equations
                    Instances For
                      @[simp]
                      theorem RelSeries.length_withLength {α : Type u_1} (r : Rel α α) [r.InfiniteDimensional] (n : ) :
                      (RelSeries.withLength r n).length = n
                      theorem RelSeries.nonempty_of_infiniteDimensional {α : Type u_1} {r : Rel α α} [r.InfiniteDimensional] :

                      If a relation on α is infinite dimensional, then α is nonempty.

                      instance RelSeries.membership {α : Type u_1} {r : Rel α α} :
                      Equations
                      theorem RelSeries.mem_def {α : Type u_1} {r : Rel α α} {s : RelSeries r} {x : α} :
                      x s x Set.range s.toFun
                      @[simp]
                      theorem RelSeries.mem_toList {α : Type u_1} {r : Rel α α} {s : RelSeries r} {x : α} :
                      x s.toList x s
                      theorem RelSeries.subsingleton_of_length_eq_zero {α : Type u_1} {r : Rel α α} {s : RelSeries r} (hs : s.length = 0) :
                      {x : α | x s}.Subsingleton
                      theorem RelSeries.length_ne_zero_of_nontrivial {α : Type u_1} {r : Rel α α} {s : RelSeries r} (h : {x : α | x s}.Nontrivial) :
                      s.length 0
                      theorem RelSeries.length_pos_of_nontrivial {α : Type u_1} {r : Rel α α} {s : RelSeries r} (h : {x : α | x s}.Nontrivial) :
                      0 < s.length
                      theorem RelSeries.length_ne_zero {α : Type u_1} {r : Rel α α} {s : RelSeries r} (irrefl : Irreflexive r) :
                      s.length 0 {x : α | x s}.Nontrivial
                      theorem RelSeries.length_pos {α : Type u_1} {r : Rel α α} {s : RelSeries r} (irrefl : Irreflexive r) :
                      0 < s.length {x : α | x s}.Nontrivial
                      theorem RelSeries.length_eq_zero {α : Type u_1} {r : Rel α α} {s : RelSeries r} (irrefl : Irreflexive r) :
                      s.length = 0 {x : α | x s}.Subsingleton
                      def RelSeries.head {α : Type u_1} {r : Rel α α} (x : RelSeries r) :
                      α

                      Start of a series, i.e. for a₀ -r→ a₁ -r→ ... -r→ aₙ, its head is a₀.

                      Since a relation series is assumed to be non-empty, this is well defined.

                      Equations
                      • x.head = x.toFun 0
                      Instances For
                        def RelSeries.last {α : Type u_1} {r : Rel α α} (x : RelSeries r) :
                        α

                        End of a series, i.e. for a₀ -r→ a₁ -r→ ... -r→ aₙ, its last element is aₙ.

                        Since a relation series is assumed to be non-empty, this is well defined.

                        Equations
                        Instances For
                          theorem RelSeries.apply_last {α : Type u_1} {r : Rel α α} (x : RelSeries r) :
                          x.toFun (Fin.last x.length) = x.last
                          theorem RelSeries.head_mem {α : Type u_1} {r : Rel α α} (x : RelSeries r) :
                          x.head x
                          theorem RelSeries.last_mem {α : Type u_1} {r : Rel α α} (x : RelSeries r) :
                          x.last x
                          @[simp]
                          theorem RelSeries.head_singleton {α : Type u_1} {r : Rel α α} (x : α) :
                          (RelSeries.singleton r x).head = x
                          @[simp]
                          theorem RelSeries.last_singleton {α : Type u_1} {r : Rel α α} (x : α) :
                          (RelSeries.singleton r x).last = x
                          @[simp]
                          theorem RelSeries.append_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) (q : RelSeries r) (connect : r p.last q.head) :
                          (p.append q connect).length = p.length + q.length + 1
                          def RelSeries.append {α : Type u_1} {r : Rel α α} (p : RelSeries r) (q : RelSeries r) (connect : r p.last q.head) :

                          If a₀ -r→ a₁ -r→ ... -r→ aₙ and b₀ -r→ b₁ -r→ ... -r→ bₘ are two strict series such that r aₙ b₀, then there is a chain of length n + m + 1 given by a₀ -r→ a₁ -r→ ... -r→ aₙ -r→ b₀ -r→ b₁ -r→ ... -r→ bₘ.

                          Equations
                          • p.append q connect = { length := p.length + q.length + 1, toFun := Fin.append p.toFun q.toFun Fin.cast , step := }
                          Instances For
                            theorem RelSeries.append_apply_left {α : Type u_1} {r : Rel α α} (p : RelSeries r) (q : RelSeries r) (connect : r p.last q.head) (i : Fin (p.length + 1)) :
                            (p.append q connect).toFun (Fin.cast (Fin.castAdd (q.length + 1) i)) = p.toFun i
                            theorem RelSeries.append_apply_right {α : Type u_1} {r : Rel α α} (p : RelSeries r) (q : RelSeries r) (connect : r p.last q.head) (i : Fin (q.length + 1)) :
                            (p.append q connect).toFun ((Fin.natAdd p.length i) + 1) = q.toFun i
                            @[simp]
                            theorem RelSeries.head_append {α : Type u_1} {r : Rel α α} (p : RelSeries r) (q : RelSeries r) (connect : r p.last q.head) :
                            (p.append q connect).head = p.head
                            @[simp]
                            theorem RelSeries.last_append {α : Type u_1} {r : Rel α α} (p : RelSeries r) (q : RelSeries r) (connect : r p.last q.head) :
                            (p.append q connect).last = q.last
                            @[simp]
                            theorem RelSeries.map_length {α : Type u_1} {r : Rel α α} {β : Type u_2} {s : Rel β β} (p : RelSeries r) (f : r →r s) :
                            (p.map f).length = p.length
                            def RelSeries.map {α : Type u_1} {r : Rel α α} {β : Type u_2} {s : Rel β β} (p : RelSeries r) (f : r →r s) :

                            For two types α, β and relation on them r, s, if f : α → β preserves relation r, then an r-series can be pushed out to an s-series by a₀ -r→ a₁ -r→ ... -r→ aₙ ↦ f a₀ -s→ f a₁ -s→ ... -s→ f aₙ

                            Equations
                            • p.map f = { length := p.length, toFun := f.toFun p.toFun, step := }
                            Instances For
                              @[simp]
                              theorem RelSeries.map_apply {α : Type u_1} {r : Rel α α} {β : Type u_2} {s : Rel β β} (p : RelSeries r) (f : r →r s) (i : Fin (p.length + 1)) :
                              (p.map f).toFun i = f (p.toFun i)
                              @[simp]
                              theorem RelSeries.head_map {α : Type u_1} {r : Rel α α} {β : Type u_2} {s : Rel β β} (p : RelSeries r) (f : r →r s) :
                              (p.map f).head = f p.head
                              @[simp]
                              theorem RelSeries.last_map {α : Type u_1} {r : Rel α α} {β : Type u_2} {s : Rel β β} (p : RelSeries r) (f : r →r s) :
                              (p.map f).last = f p.last
                              @[simp]
                              theorem RelSeries.insertNth_toFun {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin p.length) (a : α) (prev_connect : r (p.toFun i.castSucc) a) (connect_next : r a (p.toFun i.succ)) (j : Fin (p.length + 1 + 1)) :
                              (p.insertNth i a prev_connect connect_next).toFun j = i.succ.castSucc.insertNth a p.toFun j
                              @[simp]
                              theorem RelSeries.insertNth_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin p.length) (a : α) (prev_connect : r (p.toFun i.castSucc) a) (connect_next : r a (p.toFun i.succ)) :
                              (p.insertNth i a prev_connect connect_next).length = p.length + 1
                              def RelSeries.insertNth {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin p.length) (a : α) (prev_connect : r (p.toFun i.castSucc) a) (connect_next : r a (p.toFun i.succ)) :

                              If a₀ -r→ a₁ -r→ ... -r→ aₙ is an r-series and a is such that aᵢ -r→ a -r→ a_ᵢ₊₁, then a₀ -r→ a₁ -r→ ... -r→ aᵢ -r→ a -r→ aᵢ₊₁ -r→ ... -r→ aₙ is another r-series

                              Equations
                              • p.insertNth i a prev_connect connect_next = { length := p.length + 1, toFun := i.succ.castSucc.insertNth a p.toFun, step := }
                              Instances For
                                @[simp]
                                theorem RelSeries.reverse_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) :
                                p.reverse.length = p.length
                                def RelSeries.reverse {α : Type u_1} {r : Rel α α} (p : RelSeries r) :
                                RelSeries fun (a b : α) => r b a

                                A relation series a₀ -r→ a₁ -r→ ... -r→ aₙ of r gives a relation series of the reverse of r by reversing the series aₙ ←r- aₙ₋₁ ←r- ... ←r- a₁ ←r- a₀.

                                Equations
                                • p.reverse = { length := p.length, toFun := p.toFun Fin.rev, step := }
                                Instances For
                                  @[simp]
                                  theorem RelSeries.reverse_apply {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length + 1)) :
                                  p.reverse.toFun i = p.toFun i.rev
                                  @[simp]
                                  theorem RelSeries.last_reverse {α : Type u_1} {r : Rel α α} (p : RelSeries r) :
                                  p.reverse.last = p.head
                                  @[simp]
                                  theorem RelSeries.head_reverse {α : Type u_1} {r : Rel α α} (p : RelSeries r) :
                                  p.reverse.head = p.last
                                  @[simp]
                                  theorem RelSeries.reverse_reverse {α : Type u_1} {r : Rel α α} (p : RelSeries r) :
                                  p.reverse.reverse = p
                                  @[simp]
                                  theorem RelSeries.cons_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) (newHead : α) (rel : r newHead p.head) :
                                  (p.cons newHead rel).length = p.length + 1
                                  def RelSeries.cons {α : Type u_1} {r : Rel α α} (p : RelSeries r) (newHead : α) (rel : r newHead p.head) :

                                  Given a series a₀ -r→ a₁ -r→ ... -r→ aₙ and an a such that a₀ -r→ a holds, there is a series of length n+1: a -r→ a₀ -r→ a₁ -r→ ... -r→ aₙ.

                                  Equations
                                  Instances For
                                    @[simp]
                                    theorem RelSeries.head_cons {α : Type u_1} {r : Rel α α} (p : RelSeries r) (newHead : α) (rel : r newHead p.head) :
                                    (p.cons newHead rel).head = newHead
                                    @[simp]
                                    theorem RelSeries.last_cons {α : Type u_1} {r : Rel α α} (p : RelSeries r) (newHead : α) (rel : r newHead p.head) :
                                    (p.cons newHead rel).last = p.last
                                    @[simp]
                                    theorem RelSeries.snoc_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) (newLast : α) (rel : r p.last newLast) :
                                    (p.snoc newLast rel).length = p.length + 1
                                    def RelSeries.snoc {α : Type u_1} {r : Rel α α} (p : RelSeries r) (newLast : α) (rel : r p.last newLast) :

                                    Given a series a₀ -r→ a₁ -r→ ... -r→ aₙ and an a such that aₙ -r→ a holds, there is a series of length n+1: a₀ -r→ a₁ -r→ ... -r→ aₙ -r→ a.

                                    Equations
                                    Instances For
                                      @[simp]
                                      theorem RelSeries.head_snoc {α : Type u_1} {r : Rel α α} (p : RelSeries r) (newLast : α) (rel : r p.last newLast) :
                                      (p.snoc newLast rel).head = p.head
                                      @[simp]
                                      theorem RelSeries.last_snoc {α : Type u_1} {r : Rel α α} (p : RelSeries r) (newLast : α) (rel : r p.last newLast) :
                                      (p.snoc newLast rel).last = newLast
                                      @[simp]
                                      theorem RelSeries.last_snoc' {α : Type u_1} {r : Rel α α} (p : RelSeries r) (newLast : α) (rel : r p.last newLast) :
                                      (p.snoc newLast rel).toFun (Fin.last (p.length + 1)) = newLast
                                      @[simp]
                                      theorem RelSeries.snoc_castSucc {α : Type u_1} {r : Rel α α} (s : RelSeries r) (a : α) (connect : r s.last a) (i : Fin (s.length + 1)) :
                                      (s.snoc a connect).toFun i.castSucc = s.toFun i
                                      theorem RelSeries.mem_snoc {α : Type u_1} {r : Rel α α} {p : RelSeries r} {newLast : α} {rel : r p.last newLast} {x : α} :
                                      x p.snoc newLast rel x p x = newLast
                                      @[simp]
                                      theorem RelSeries.tail_toFun {α : Type u_1} {r : Rel α α} (p : RelSeries r) (len_pos : p.length 0) :
                                      ∀ (a : Fin (p.length - 1 + 1)), (p.tail len_pos).toFun a = (Fin.tail p.toFun Fin.cast ) a
                                      @[simp]
                                      theorem RelSeries.tail_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) (len_pos : p.length 0) :
                                      (p.tail len_pos).length = p.length - 1
                                      def RelSeries.tail {α : Type u_1} {r : Rel α α} (p : RelSeries r) (len_pos : p.length 0) :

                                      If a series a₀ -r→ a₁ -r→ ... has positive length, then a₁ -r→ ... is another series

                                      Equations
                                      Instances For
                                        @[simp]
                                        theorem RelSeries.head_tail {α : Type u_1} {r : Rel α α} (p : RelSeries r) (len_pos : p.length 0) :
                                        (p.tail len_pos).head = p.toFun 1
                                        @[simp]
                                        theorem RelSeries.last_tail {α : Type u_1} {r : Rel α α} (p : RelSeries r) (len_pos : p.length 0) :
                                        (p.tail len_pos).last = p.last
                                        @[simp]
                                        theorem RelSeries.eraseLast_toFun {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length - 1 + 1)) :
                                        p.eraseLast.toFun i = p.toFun i,
                                        @[simp]
                                        theorem RelSeries.eraseLast_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) :
                                        p.eraseLast.length = p.length - 1
                                        def RelSeries.eraseLast {α : Type u_1} {r : Rel α α} (p : RelSeries r) :

                                        If a series a₀ -r→ a₁ -r→ ... -r→ aₙ, then a₀ -r→ a₁ -r→ ... -r→ aₙ₋₁ is another series

                                        Equations
                                        • p.eraseLast = { length := p.length - 1, toFun := fun (i : Fin (p.length - 1 + 1)) => p.toFun i, , step := }
                                        Instances For
                                          @[simp]
                                          theorem RelSeries.head_eraseLast {α : Type u_1} {r : Rel α α} (p : RelSeries r) :
                                          p.eraseLast.head = p.head
                                          @[simp]
                                          theorem RelSeries.last_eraseLast {α : Type u_1} {r : Rel α α} (p : RelSeries r) :
                                          p.eraseLast.last = p.toFun p.length.pred,
                                          theorem RelSeries.eraseLast_last_rel_last {α : Type u_1} {r : Rel α α} (p : RelSeries r) (h : p.length 0) :
                                          r p.eraseLast.last p.last

                                          In a non-trivial series p, the last element of p.eraseLast is related to p.last

                                          @[simp]
                                          theorem RelSeries.smash_toFun {α : Type u_1} {r : Rel α α} (p : RelSeries r) (q : RelSeries r) (connect : p.last = q.head) (i : Fin (p.length + q.length + 1)) :
                                          (p.smash q connect).toFun i = if H : i < p.length then p.toFun i, else q.toFun i - p.length,
                                          @[simp]
                                          theorem RelSeries.smash_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) (q : RelSeries r) (connect : p.last = q.head) :
                                          (p.smash q connect).length = p.length + q.length
                                          def RelSeries.smash {α : Type u_1} {r : Rel α α} (p : RelSeries r) (q : RelSeries r) (connect : p.last = q.head) :

                                          Given two series of the form a₀ -r→ ... -r→ X and X -r→ b ---> ..., then a₀ -r→ ... -r→ X -r→ b ... is another series obtained by combining the given two.

                                          Equations
                                          • One or more equations did not get rendered due to their size.
                                          Instances For
                                            theorem RelSeries.smash_castAdd {α : Type u_1} {r : Rel α α} {p : RelSeries r} {q : RelSeries r} (connect : p.last = q.head) (i : Fin p.length) :
                                            (p.smash q connect).toFun (Fin.castAdd q.length i).castSucc = p.toFun i.castSucc
                                            theorem RelSeries.smash_succ_castAdd {α : Type u_1} {r : Rel α α} {p : RelSeries r} {q : RelSeries r} (h : p.last = q.head) (i : Fin p.length) :
                                            (p.smash q h).toFun (Fin.castAdd q.length i).succ = p.toFun i.succ
                                            theorem RelSeries.smash_natAdd {α : Type u_1} {r : Rel α α} {p : RelSeries r} {q : RelSeries r} (h : p.last = q.head) (i : Fin q.length) :
                                            (p.smash q h).toFun (Fin.natAdd p.length i).castSucc = q.toFun i.castSucc
                                            theorem RelSeries.smash_succ_natAdd {α : Type u_1} {r : Rel α α} {p : RelSeries r} {q : RelSeries r} (h : p.last = q.head) (i : Fin q.length) :
                                            (p.smash q h).toFun (Fin.natAdd p.length i).succ = q.toFun i.succ
                                            @[simp]
                                            theorem RelSeries.head_smash {α : Type u_1} {r : Rel α α} {p : RelSeries r} {q : RelSeries r} (h : p.last = q.head) :
                                            (p.smash q h).head = p.head
                                            @[simp]
                                            theorem RelSeries.last_smash {α : Type u_1} {r : Rel α α} {p : RelSeries r} {q : RelSeries r} (h : p.last = q.head) :
                                            (p.smash q h).last = q.last
                                            @[simp]
                                            theorem RelSeries.take_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length + 1)) :
                                            (p.take i).length = i
                                            def RelSeries.take {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length + 1)) :

                                            Given the series a₀ -r→ … -r→ aᵢ -r→ … -r→ aₙ, the series a₀ -r→ … -r→ aᵢ.

                                            Equations
                                            • p.take i = { length := i, toFun := fun (x : Fin (i + 1)) => match x with | j, h => p.toFun j, , step := }
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                                              @[simp]
                                              theorem RelSeries.head_take {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length + 1)) :
                                              (p.take i).head = p.head
                                              @[simp]
                                              theorem RelSeries.last_take {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length + 1)) :
                                              (p.take i).last = p.toFun i
                                              @[simp]
                                              theorem RelSeries.drop_length {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length + 1)) :
                                              (p.drop i).length = p.length - i
                                              def RelSeries.drop {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length + 1)) :

                                              Given the series a₀ -r→ … -r→ aᵢ -r→ … -r→ aₙ, the series aᵢ₊₁ -r→ … -r→ aᵢ.

                                              Equations
                                              • p.drop i = { length := p.length - i, toFun := fun (x : Fin (p.length - i + 1)) => match x with | j, h => p.toFun j + i, , step := }
                                              Instances For
                                                @[simp]
                                                theorem RelSeries.head_drop {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length + 1)) :
                                                (p.drop i).head = p.toFun i
                                                @[simp]
                                                theorem RelSeries.last_drop {α : Type u_1} {r : Rel α α} (p : RelSeries r) (i : Fin (p.length + 1)) :
                                                (p.drop i).last = p.last
                                                @[reducible, inline]
                                                abbrev FiniteDimensionalOrder (γ : Type u_3) [Preorder γ] :

                                                A type is finite dimensional if its LTSeries has bounded length.

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                                                  • =
                                                  @[reducible, inline]
                                                  abbrev InfiniteDimensionalOrder (γ : Type u_3) [Preorder γ] :

                                                  A type is infinite dimensional if it has LTSeries of at least arbitrary length

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                                                    @[reducible, inline]
                                                    abbrev LTSeries (α : Type u_1) [Preorder α] :
                                                    Type u_1

                                                    If α is a preorder, a LTSeries is a relation series of the less than relation.

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                                                      noncomputable def LTSeries.longestOf (α : Type u_1) [Preorder α] [FiniteDimensionalOrder α] :

                                                      The longest <-series when a type is finite dimensional

                                                      Equations
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                                                        noncomputable def LTSeries.withLength (α : Type u_1) [Preorder α] [InfiniteDimensionalOrder α] (n : ) :

                                                        A <-series with length n if the relation is infinite dimensional

                                                        Equations
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                                                          @[simp]
                                                          theorem LTSeries.length_withLength (α : Type u_1) [Preorder α] [InfiniteDimensionalOrder α] (n : ) :
                                                          (LTSeries.withLength α n).length = n

                                                          if α is infinite dimensional, then α is nonempty.

                                                          theorem LTSeries.longestOf_is_longest {α : Type u_1} [Preorder α] [FiniteDimensionalOrder α] (x : LTSeries α) :
                                                          x.length (LTSeries.longestOf α).length
                                                          theorem LTSeries.longestOf_len_unique {α : Type u_1} [Preorder α] [FiniteDimensionalOrder α] (p : LTSeries α) (is_longest : ∀ (q : LTSeries α), q.length p.length) :
                                                          p.length = (LTSeries.longestOf α).length
                                                          theorem LTSeries.strictMono {α : Type u_1} [Preorder α] (x : LTSeries α) :
                                                          StrictMono x.toFun
                                                          theorem LTSeries.monotone {α : Type u_1} [Preorder α] (x : LTSeries α) :
                                                          Monotone x.toFun
                                                          @[simp]
                                                          theorem LTSeries.mk_length {α : Type u_1} [Preorder α] (length : ) (toFun : Fin (length + 1)α) (strictMono : StrictMono toFun) :
                                                          (LTSeries.mk length toFun strictMono).length = length
                                                          @[simp]
                                                          theorem LTSeries.mk_toFun {α : Type u_1} [Preorder α] (length : ) (toFun : Fin (length + 1)α) (strictMono : StrictMono toFun) :
                                                          ∀ (a : Fin (length + 1)), (LTSeries.mk length toFun strictMono).toFun a = toFun a
                                                          def LTSeries.mk {α : Type u_1} [Preorder α] (length : ) (toFun : Fin (length + 1)α) (strictMono : StrictMono toFun) :

                                                          An alternative constructor of LTSeries from a strictly monotone function.

                                                          Equations
                                                          • LTSeries.mk length toFun strictMono = { length := length, toFun := toFun, step := }
                                                          Instances For
                                                            def LTSeries.injStrictMono {α : Type u_1} [Preorder α] (n : ) :
                                                            { f : (l : Fin n) × (Fin (l + 1)α) // StrictMono f.snd } LTSeries α

                                                            An injection from the type of strictly monotone functions with limited length to LTSeries.

                                                            Equations
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                                                              @[simp]
                                                              theorem LTSeries.map_length {α : Type u_1} {β : Type u_2} [Preorder α] [Preorder β] (p : LTSeries α) (f : αβ) (hf : StrictMono f) :
                                                              (p.map f hf).length = p.length
                                                              @[simp]
                                                              theorem LTSeries.map_toFun {α : Type u_1} {β : Type u_2} [Preorder α] [Preorder β] (p : LTSeries α) (f : αβ) (hf : StrictMono f) :
                                                              ∀ (a : Fin (p.length + 1)), (p.map f hf).toFun a = f (p.toFun a)
                                                              def LTSeries.map {α : Type u_1} {β : Type u_2} [Preorder α] [Preorder β] (p : LTSeries α) (f : αβ) (hf : StrictMono f) :

                                                              For two preorders α, β, if f : α → β is strictly monotonic, then a strict chain of α can be pushed out to a strict chain of β by a₀ < a₁ < ... < aₙ ↦ f a₀ < f a₁ < ... < f aₙ

                                                              Equations
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                                                                @[simp]
                                                                theorem LTSeries.head_map {α : Type u_1} {β : Type u_2} [Preorder α] [Preorder β] (p : LTSeries α) (f : αβ) (hf : StrictMono f) :
                                                                RelSeries.head (p.map f hf) = f (RelSeries.head p)
                                                                @[simp]
                                                                theorem LTSeries.last_map {α : Type u_1} {β : Type u_2} [Preorder α] [Preorder β] (p : LTSeries α) (f : αβ) (hf : StrictMono f) :
                                                                RelSeries.last (p.map f hf) = f (RelSeries.last p)
                                                                @[simp]
                                                                theorem LTSeries.comap_length {α : Type u_1} {β : Type u_2} [Preorder α] [Preorder β] (p : LTSeries β) (f : αβ) (comap : ∀ ⦃x y : α⦄, f x < f yx < y) (surjective : Function.Surjective f) :
                                                                (p.comap f comap surjective).length = p.length
                                                                @[simp]
                                                                theorem LTSeries.comap_toFun {α : Type u_1} {β : Type u_2} [Preorder α] [Preorder β] (p : LTSeries β) (f : αβ) (comap : ∀ ⦃x y : α⦄, f x < f yx < y) (surjective : Function.Surjective f) (i : Fin (p.length + 1)) :
                                                                (p.comap f comap surjective).toFun i = .choose
                                                                noncomputable def LTSeries.comap {α : Type u_1} {β : Type u_2} [Preorder α] [Preorder β] (p : LTSeries β) (f : αβ) (comap : ∀ ⦃x y : α⦄, f x < f yx < y) (surjective : Function.Surjective f) :

                                                                For two preorders α, β, if f : α → β is surjective and strictly comonotonic, then a strict series of β can be pulled back to a strict chain of α by b₀ < b₁ < ... < bₙ ↦ f⁻¹ b₀ < f⁻¹ b₁ < ... < f⁻¹ bₙ where f⁻¹ bᵢ is an arbitrary element in the preimage of f⁻¹ {bᵢ}.

                                                                Equations
                                                                • p.comap f comap surjective = LTSeries.mk p.length (fun (i : Fin (p.length + 1)) => .choose)
                                                                Instances For

                                                                  The strict series 0 < … < n in .

                                                                  Equations
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                                                                    @[simp]
                                                                    theorem LTSeries.length_range (n : ) :
                                                                    (LTSeries.range n).length = n
                                                                    @[simp]
                                                                    theorem LTSeries.range_apply (n : ) (i : Fin (n + 1)) :
                                                                    (LTSeries.range n).toFun i = i
                                                                    theorem LTSeries.apply_add_index_le_apply_add_index_nat (p : LTSeries ) (i : Fin (p.length + 1)) (j : Fin (p.length + 1)) (hij : i j) :
                                                                    p.toFun i + j p.toFun j + i

                                                                    In ℕ, two entries in an LTSeries differ by at least the difference of their indices. (Expressed in a way that avoids subtraction).

                                                                    theorem LTSeries.apply_add_index_le_apply_add_index_int (p : LTSeries ) (i : Fin (p.length + 1)) (j : Fin (p.length + 1)) (hij : i j) :
                                                                    p.toFun i + j p.toFun j + i

                                                                    In ℤ, two entries in an LTSeries differ by at least the difference of their indices. (Expressed in a way that avoids subtraction).

                                                                    In ℕ, the head and tail of an LTSeries differ at least by the length of the series

                                                                    In ℤ, the head and tail of an LTSeries differ at least by the length of the series

                                                                    theorem LTSeries.length_lt_card {α : Type u_1} [Preorder α] [Fintype α] (s : LTSeries α) :
                                                                    s.length < Fintype.card α
                                                                    instance LTSeries.instFintypeOfDecidableRelLt {α : Type u_1} [Preorder α] [Fintype α] [DecidableRel fun (x1 x2 : α) => x1 < x2] :
                                                                    Equations
                                                                    theorem infiniteDimensionalOrder_of_strictMono {α : Type u_1} {β : Type u_2} [Preorder α] [Preorder β] (f : αβ) (hf : StrictMono f) [InfiniteDimensionalOrder α] :

                                                                    If f : α → β is a strictly monotonic function and α is an infinite dimensional type then so is β.