feat(builtin/proof_irrel): prove proof irrelevance

Signed-off-by: Leonardo de Moura <leonardo@microsoft.com>
2014-02-16 18:06:10 -08:00 · 2014-02-16 18:06:10 -08:00 · 4692e04d70
commit 4692e04d70
parent c526e5ec00
1 changed files with 64 additions and 0 deletions
--- a/src/builtin/proof_irrel.lean
+++ b/src/builtin/proof_irrel.lean
@ -0,0 +1,64 @@
+import macros
+
+definition has_fixpoint (A : Bool) : Bool
+:= ∃ F : (A → A) → A, ∀ f : A → A, F f = f (F f)
+
+theorem eq_arrow (A : Bool) : inhabited A → (A → A) = A
+:= assume Hin : inhabited A,
+   obtain (p : A) (Hp : true), from Hin,
+   iff_intro
+     (assume Hl : A → A, p)
+     (assume Hr : A, (assume H : A, H))
+
+theorem bool_fixpoint (A : Bool) : inhabited A → has_fixpoint A
+:= assume Hin : inhabited A,
+   have Heq1 : (A → A) == A,
+     from (to_heq (eq_arrow A Hin)),
+   have Heq2 : A == (A → A),
+     from hsymm Heq1,
+   let g1 : A → (A → A)  := λ x : A,      cast Heq2 x,
+       g2 : (A → A) → A  := λ x : A → A, cast Heq1 x,
+       Y  : (A → A) → A  := (λ f : A → A, (λ x : A, f (g1 x x)) (g2 (λ x : A, f (g1 x x)))) in
+   have R : ∀ f, g1 (g2 f) = f,
+       from take f : A → A,
+            calc g1 (g2 f) = cast Heq2 (cast Heq1 f)   : refl _
+                      ...  = cast (htrans Heq1 Heq2) f : cast_trans _ _ _
+                      ...  = f                         : cast_eq _ _,
+   have Fix : (∀ f, Y f = f (Y f)),
+     from take f : A → A,
+          let  h : A → A := λ x : A, f (g1 x x) in
+          have H1 : Y f = f (g1 (g2 h) (g2 h)),
+            from refl (Y f),
+          have H2 : g1 (g2 h) = h,
+            from R h,
+          have H3 : Y f = f (h (g2 h)),
+            from substp (λ x, Y f = f (x (g2 h))) H1 H2,
+          have H4 : f (Y f) = f (h (g2 h)),
+            from refl (f (Y f)),
+          trans H3 (symm H4),
+   @exists_intro ((A → A) → A) (λ Y, ∀ f, Y f = f (Y f)) Y Fix
+
+theorem proof_irrel_new (A : Bool) (p1 p2 : A) : p1 = p2
+:= have H1 : inhabited A,
+     from inhabited_intro p1,
+   obtain (Y : (A → A) → A) (HY : ∀ f : A → A, Y f = f (Y f)), from bool_fixpoint A H1,
+   let h : A → A := (λ x : A, if x = p1 then p2 else p1) in
+   have HYh : Y h = h (Y h),
+     from HY h,
+   or_elim (em (Y h = p1))
+     (assume Heq : Y h = p1,
+        have Heq1 : h (Y h) = p2,
+          from calc h (Y h)  = if Y h = p1 then p2 else p1 : refl _
+                         ... = if true then p2 else p1     : { eqt_intro Heq }
+                         ... = p2                          : if_true _ _,
+        calc p1  =  Y h      : symm Heq
+             ... =  h (Y h)  : HYh
+             ... =  p2       : Heq1)
+     (assume Hne : Y h ≠ p1,
+        have Heq1 : h (Y h) = p1,
+          from calc h (Y h)  = if Y h = p1 then p2 else p1 : refl _
+                         ... = if false then p2 else p1    : { eqf_intro Hne }
+                         ... = p1                          : if_false _ _,
+        have Heq2 : Y h = p1,
+          from trans HYh Heq1,
+        absurd_elim (p1 = p2) Heq2 Hne)