lean2/library/data/sigma/wf.lean

-- Copyright (c) 2014 Microsoft Corporation. All rights reserved.
-- Released under Apache 2.0 license as described in the file LICENSE.
-- Author: Leonardo de Moura
import data.sigma.decl logic.wf logic.cast
open well_founded

namespace sigma
  section
  variables {A : Type} {B : A → Type}
  variable  (Ra  : A → A → Prop)
  variable  (Rb  : ∀ a, B a → B a → Prop)

  -- Lexicographical order based on Ra and Rb
  inductive lex : sigma B → sigma B → Prop :=
  left  : ∀{a₁ b₁} a₂ b₂, Ra a₁ a₂   → lex (dpair a₁ b₁) (dpair a₂ b₂),
  right : ∀a {b₁ b₂},     Rb a b₁ b₂ → lex (dpair a b₁)  (dpair a b₂)
  end

  context
  parameters {A : Type} {B : A → Type}
  parameters {Ra  : A → A → Prop} {Rb : Π a : A, B a → B a → Prop}
  infix `≺`:50 := lex Ra Rb

  set_option pp.beta true

  definition lex.accessible {a} (aca : acc Ra a) (acb : ∀a, well_founded (Rb a)) : ∀ (b : B a), acc (lex Ra Rb) (dpair a b) :=
  acc.rec_on aca
    (λxa aca (iHa : ∀y, Ra y xa → ∀b : B y, acc (lex Ra Rb) (dpair y b)),
      λb : B xa, acc.rec_on (acb xa b)
        (λxb acb
          (iHb : ∀y, Rb xa y xb → acc (lex Ra Rb) (dpair xa y)),
          acc.intro (dpair xa xb) (λp (lt : p ≺ (dpair xa xb)),
            have aux : xa = xa → xb == xb → acc (lex Ra Rb) p, from
              @lex.rec_on A B Ra Rb (λp₁ p₂, dpr1 p₂ = xa → dpr2 p₂ == xb → acc (lex Ra Rb) p₁)
                         p (dpair xa xb) lt
                (λa₁ b₁ a₂ b₂ (H : Ra a₁ a₂) (eq₂ : a₂ = xa) (eq₃ : b₂ == xb),
                  show acc (lex Ra Rb) (dpair a₁ b₁), from
                  have Ra₁  : Ra a₁ xa, from eq.rec_on eq₂ H,
                  iHa a₁ Ra₁ b₁)
                (λa b₁ b₂ (H : Rb a b₁ b₂) (eq₂ : a = xa) (eq₃ : b₂ == xb),
                  -- TODO(Leo): cleanup this proof
                  show acc (lex Ra Rb) (dpair a b₁), from
                  let b₁' : B xa := eq.rec_on eq₂ b₁ in
                  have aux₁ : b₁ == b₁', from
                    heq.symm (eq_rec_heq eq₂ b₁),
                  have aux₂ : Rb a b₁ b₂ = Rb xa b₁' xb, from
                    heq.to_eq (hcongr_arg3 Rb eq₂ aux₁ eq₃),
                  have aux₃ : Rb xa b₁' xb, from
                    eq.rec_on aux₂ H,
                  have aux₄ : acc (lex Ra Rb) (dpair xa b₁'), from
                    iHb b₁' aux₃,
                  have aux₅ : ∀ (b₁ b₂ : B a) (H₁ : a = a) (H₂ : b₁ == b₂), acc (lex Ra Rb) (dpair a b₁) → acc (lex Ra Rb) (dpair a b₂), from
                    λ b₁ b₂ H₁ H₂ Ha, eq.rec_on (heq.to_eq H₂) Ha,
                  have aux₆ : ∀ (b₁ : B xa) (b₂ : B a) (H₁ : a = xa) (H₂ : b₁ == b₂), acc (lex Ra Rb) (dpair xa b₁) → acc (lex Ra Rb) (dpair a b₂), from
                    eq.rec_on eq₂ aux₅,
                  aux₆ b₁' b₁ eq₂ (heq.symm aux₁) aux₄),
            aux rfl !heq.refl)))

  -- The lexicographical order of well founded relations is well-founded
  definition lex.wf (Ha : well_founded Ra) (Hb : ∀ x, well_founded (Rb x)) : well_founded (lex Ra Rb) :=
  well_founded.intro (λp, destruct p (λa b, lex.accessible (Ha a) Hb b))

  end

end sigma
feat(library/data/sigma/wf): define 'lex' for 'sigma' types and prove wf theorem 2014-11-17 04:08:52 +00:00			`-- Copyright (c) 2014 Microsoft Corporation. All rights reserved.`
			`-- Released under Apache 2.0 license as described in the file LICENSE.`
			`-- Author: Leonardo de Moura`
			`import data.sigma.decl logic.wf logic.cast`
			`open well_founded`

			`namespace sigma`
			`section`
			`variables {A : Type} {B : A → Type}`
			`variable (Ra : A → A → Prop)`
			`variable (Rb : ∀ a, B a → B a → Prop)`

			`-- Lexicographical order based on Ra and Rb`
			`inductive lex : sigma B → sigma B → Prop :=`
			`left : ∀{a₁ b₁} a₂ b₂, Ra a₁ a₂ → lex (dpair a₁ b₁) (dpair a₂ b₂),`
			`right : ∀a {b₁ b₂}, Rb a b₁ b₂ → lex (dpair a b₁) (dpair a b₂)`
			`end`

			`context`
			`parameters {A : Type} {B : A → Type}`
			`parameters {Ra : A → A → Prop} {Rb : Π a : A, B a → B a → Prop}`
			infix `≺`:50 := lex Ra Rb

			`set_option pp.beta true`

			`definition lex.accessible {a} (aca : acc Ra a) (acb : ∀a, well_founded (Rb a)) : ∀ (b : B a), acc (lex Ra Rb) (dpair a b) :=`
			`acc.rec_on aca`
			`(λxa aca (iHa : ∀y, Ra y xa → ∀b : B y, acc (lex Ra Rb) (dpair y b)),`
			`λb : B xa, acc.rec_on (acb xa b)`
			`(λxb acb`
			`(iHb : ∀y, Rb xa y xb → acc (lex Ra Rb) (dpair xa y)),`
			`acc.intro (dpair xa xb) (λp (lt : p ≺ (dpair xa xb)),`
			`have aux : xa = xa → xb == xb → acc (lex Ra Rb) p, from`
			`@lex.rec_on A B Ra Rb (λp₁ p₂, dpr1 p₂ = xa → dpr2 p₂ == xb → acc (lex Ra Rb) p₁)`
			`p (dpair xa xb) lt`
			`(λa₁ b₁ a₂ b₂ (H : Ra a₁ a₂) (eq₂ : a₂ = xa) (eq₃ : b₂ == xb),`
			`show acc (lex Ra Rb) (dpair a₁ b₁), from`
			`have Ra₁ : Ra a₁ xa, from eq.rec_on eq₂ H,`
			`iHa a₁ Ra₁ b₁)`
			`(λa b₁ b₂ (H : Rb a b₁ b₂) (eq₂ : a = xa) (eq₃ : b₂ == xb),`
			`-- TODO(Leo): cleanup this proof`
			`show acc (lex Ra Rb) (dpair a b₁), from`
			`let b₁' : B xa := eq.rec_on eq₂ b₁ in`
			`have aux₁ : b₁ == b₁', from`
			`heq.symm (eq_rec_heq eq₂ b₁),`
			`have aux₂ : Rb a b₁ b₂ = Rb xa b₁' xb, from`
			`heq.to_eq (hcongr_arg3 Rb eq₂ aux₁ eq₃),`
			`have aux₃ : Rb xa b₁' xb, from`
			`eq.rec_on aux₂ H,`
			`have aux₄ : acc (lex Ra Rb) (dpair xa b₁'), from`
			`iHb b₁' aux₃,`
			`have aux₅ : ∀ (b₁ b₂ : B a) (H₁ : a = a) (H₂ : b₁ == b₂), acc (lex Ra Rb) (dpair a b₁) → acc (lex Ra Rb) (dpair a b₂), from`
			`λ b₁ b₂ H₁ H₂ Ha, eq.rec_on (heq.to_eq H₂) Ha,`
			`have aux₆ : ∀ (b₁ : B xa) (b₂ : B a) (H₁ : a = xa) (H₂ : b₁ == b₂), acc (lex Ra Rb) (dpair xa b₁) → acc (lex Ra Rb) (dpair a b₂), from`
			`eq.rec_on eq₂ aux₅,`
			`aux₆ b₁' b₁ eq₂ (heq.symm aux₁) aux₄),`
			`aux rfl !heq.refl)))`

			`-- The lexicographical order of well founded relations is well-founded`
			`definition lex.wf (Ha : well_founded Ra) (Hb : ∀ x, well_founded (Rb x)) : well_founded (lex Ra Rb) :=`
			`well_founded.intro (λp, destruct p (λa b, lex.accessible (Ha a) Hb b))`

			`end`

			`end sigma`