lean2/tests/lean/run/tree3.lean

import logic data.prod
open eq.ops prod tactic

inductive tree (A : Type) :=
| leaf : A → tree A
| node : tree A → tree A → tree A

inductive one1.{l} : Type.{max 1 l} :=
star : one1

set_option pp.universes true

namespace tree
  namespace manual
  section
    universe variables l₁ l₂
    variable {A : Type.{l₁}}
    variable (C : tree A → Type.{l₂})
    definition below (t : tree A) : Type :=
    tree.rec_on t (λ a, one1.{l₂}) (λ t₁ t₂ r₁ r₂, C t₁ × C t₂ × r₁ × r₂)
  end

  section
    universe variables l₁ l₂
    variable {A : Type.{l₁}}
    variable {C : tree A → Type.{l₂}}
    definition below_rec_on (t : tree A) (H : Π (n : tree A), below C n → C n) : C t
    := have general : C t × below C t, from
        tree.rec_on t
          (λa, (H (leaf a) one1.star, one1.star))
          (λ (l r : tree A) (Hl : C l × below C l) (Hr : C r × below C r),
            have b : below C (node l r), from
              (pr₁ Hl, pr₁ Hr, pr₂ Hl, pr₂ Hr),
            have c : C (node l r), from
              H (node l r) b,
            (c, b)),
       pr₁ general
  end
  end manual
  local abbreviation no_confusion := @tree.no_confusion
  check no_confusion

  theorem leaf_ne_tree {A : Type} (a : A) (l r : tree A) : leaf a ≠ node l r :=
  assume h : leaf a = node l r,
  no_confusion h

  constant A : Type₁
  constants l₁ l₂ r₁ r₂ : tree A
  axiom node_eq : node l₁ r₁ = node l₂ r₂
  check no_confusion node_eq

  definition tst : (l₁ = l₂ → r₁ = r₂ → l₁ = l₂) → l₁ = l₂ := no_confusion node_eq
  check tst (λ e₁ e₂, e₁)

  theorem node.inj1 {A : Type} (l₁ l₂ r₁ r₂ : tree A) : node l₁ r₁ = node l₂ r₂ → l₁ = l₂ :=
  assume h,
    have trivial : (l₁ = l₂ → r₁ = r₂ → l₁ = l₂) → l₁ = l₂, from no_confusion h,
    trivial (λ e₁ e₂, e₁)

  theorem node.inj2 {A : Type} (l₁ l₂ r₁ r₂ : tree A) : node l₁ r₁ = node l₂ r₂ → l₁ = l₂ :=
  begin
    intro h,
    apply (no_confusion h),
    intros, assumption
  end

  theorem node.inj3 {A : Type} {l₁ l₂ r₁ r₂ : tree A} (h : node l₁ r₁ = node l₂ r₂) : l₁ = l₂ :=
  begin
    apply (no_confusion h),
    assume (e₁ : l₁ = l₂) (e₂ : r₁ = r₂), e₁
  end

  theorem node.inj4 {A : Type} {l₁ l₂ r₁ r₂ : tree A} (h : node l₁ r₁ = node l₂ r₂) : l₁ = l₂ :=
  begin
    apply (no_confusion h),
    assume e₁ e₂, e₁
  end

end tree
-												feat(library/tactic/exact_tactic): modify 'exact' tactic semantics, use higher-order unification

See new node.inj4 theorem, we need the extra power to be able to avoid type information at
    exact (assume e₁ e₂, e₁)

											
										
										
											2014-10-26 17:27:33 +00:00
+								import logic data.prod
 								open eq.ops prod tactic
 								inductive tree (A : Type) :=
-												feat(frontends/lean/inductive_cmd): allow '|' in inductive datatype declarations

											
										
										
											2015-02-26 01:00:10 +00:00
+								| leaf : A → tree A
 								| node : tree A → tree A → tree A
-												feat(library/tactic/exact_tactic): modify 'exact' tactic semantics, use higher-order unification

See new node.inj4 theorem, we need the extra power to be able to avoid type information at
    exact (assume e₁ e₂, e₁)

											
										
										
											2014-10-26 17:27:33 +00:00
-												fix(tests/lean/run): adjust some tests to changes in the standard library

											
										
										
											2015-10-13 22:39:03 +00:00
+								inductive one1.{l} : Type.{max 1 l} :=
 								star : one1
-												feat(library/tactic/exact_tactic): modify 'exact' tactic semantics, use higher-order unification

See new node.inj4 theorem, we need the extra power to be able to avoid type information at
    exact (assume e₁ e₂, e₁)

											
										
										
											2014-10-26 17:27:33 +00:00
 								set_option pp.universes true
 								namespace tree
-												feat(library/definitional): define ibelow and below

These are helper definitions for brec_on and binduction_on

											
										
										
											2014-11-13 00:38:46 +00:00
+								  namespace manual
-												feat(library/tactic/exact_tactic): modify 'exact' tactic semantics, use higher-order unification

See new node.inj4 theorem, we need the extra power to be able to avoid type information at
    exact (assume e₁ e₂, e₁)

											
										
										
											2014-10-26 17:27:33 +00:00
+								  section
 								    universe variables l₁ l₂
 								    variable {A : Type.{l₁}}
 								    variable (C : tree A → Type.{l₂})
 								    definition below (t : tree A) : Type :=
-												fix(tests/lean/run): adjust some tests to changes in the standard library

											
										
										
											2015-10-13 22:39:03 +00:00
+								    tree.rec_on t (λ a, one1.{l₂}) (λ t₁ t₂ r₁ r₂, C t₁ × C t₂ × r₁ × r₂)
-												feat(library/tactic/exact_tactic): modify 'exact' tactic semantics, use higher-order unification

See new node.inj4 theorem, we need the extra power to be able to avoid type information at
    exact (assume e₁ e₂, e₁)

											
										
										
											2014-10-26 17:27:33 +00:00
+								  end
 								  section
 								    universe variables l₁ l₂
 								    variable {A : Type.{l₁}}
 								    variable {C : tree A → Type.{l₂}}
 								    definition below_rec_on (t : tree A) (H : Π (n : tree A), below C n → C n) : C t
 								    := have general : C t × below C t, from
-												feat(frontends/lean): new semantics for "protected" declarations

closes #426

											
										
										
											2015-02-11 20:49:27 +00:00
+								        tree.rec_on t
-												fix(tests/lean/run): adjust some tests to changes in the standard library

											
										
										
											2015-10-13 22:39:03 +00:00
+								          (λa, (H (leaf a) one1.star, one1.star))
-												feat(library/tactic/exact_tactic): modify 'exact' tactic semantics, use higher-order unification

See new node.inj4 theorem, we need the extra power to be able to avoid type information at
    exact (assume e₁ e₂, e₁)

											
										
										
											2014-10-26 17:27:33 +00:00
+								          (λ (l r : tree A) (Hl : C l × below C l) (Hr : C r × below C r),
 								            have b : below C (node l r), from
 								              (pr₁ Hl, pr₁ Hr, pr₂ Hl, pr₂ Hr),
 								            have c : C (node l r), from
 								              H (node l r) b,
 								            (c, b)),
 								       pr₁ general
 								  end
-												feat(library/definitional): define ibelow and below

These are helper definitions for brec_on and binduction_on

											
										
										
											2014-11-13 00:38:46 +00:00
+								  end manual
-												feat(frontends/lean): new semantics for "protected" declarations

closes #426

											
										
										
											2015-02-11 20:49:27 +00:00
+								  local abbreviation no_confusion := @tree.no_confusion
-												feat(library/tactic/exact_tactic): modify 'exact' tactic semantics, use higher-order unification

See new node.inj4 theorem, we need the extra power to be able to avoid type information at
    exact (assume e₁ e₂, e₁)

											
										
										
											2014-10-26 17:27:33 +00:00
+								  check no_confusion
 								  theorem leaf_ne_tree {A : Type} (a : A) (l r : tree A) : leaf a ≠ node l r :=
 								  assume h : leaf a = node l r,
 								  no_confusion h
 								  constant A : Type₁
 								  constants l₁ l₂ r₁ r₂ : tree A
 								  axiom node_eq : node l₁ r₁ = node l₂ r₂
 								  check no_confusion node_eq
 								  definition tst : (l₁ = l₂ → r₁ = r₂ → l₁ = l₂) → l₁ = l₂ := no_confusion node_eq
 								  check tst (λ e₁ e₂, e₁)
 								  theorem node.inj1 {A : Type} (l₁ l₂ r₁ r₂ : tree A) : node l₁ r₁ = node l₂ r₂ → l₁ = l₂ :=
 								  assume h,
 								    have trivial : (l₁ = l₂ → r₁ = r₂ → l₁ = l₂) → l₁ = l₂, from no_confusion h,
 								    trivial (λ e₁ e₂, e₁)
 								  theorem node.inj2 {A : Type} (l₁ l₂ r₁ r₂ : tree A) : node l₁ r₁ = node l₂ r₂ → l₁ = l₂ :=
 								  begin
 								    intro h,
 								    apply (no_confusion h),
 								    intros, assumption
 								  end
 								  theorem node.inj3 {A : Type} {l₁ l₂ r₁ r₂ : tree A} (h : node l₁ r₁ = node l₂ r₂) : l₁ = l₂ :=
 								  begin
 								    apply (no_confusion h),
 								    assume (e₁ : l₁ = l₂) (e₂ : r₁ = r₂), e₁
 								  end
 								  theorem node.inj4 {A : Type} {l₁ l₂ r₁ r₂ : tree A} (h : node l₁ r₁ = node l₂ r₂) : l₁ = l₂ :=
 								  begin
 								    apply (no_confusion h),
 								    assume e₁ e₂, e₁
 								  end
 								end tree