Proof of Nuprl Lemma : member_bs_tree

Step * 3 4 of Lemma member_bs_tree_insert

1. [E] : Type
2. cmp : comparison(E)
3. x : E
4. left : bs_tree(E)
5. value : E
6. ¬0 < cmp value x
7. right : bs_tree(E)
8. bs_tree_ordered(E;cmp;left)
9. bs_tree_ordered(E;cmp;right)
10. ∀x:E. (x ∈ left ⇒ 0 < cmp x value)
11. ∀x:E. (x ∈ right ⇒ 0 < cmp value x)
12. y : E
13. cmp value x < 0
14. value = y ∈ E
15. ∀y:E. (y ∈ bs_tree_insert(cmp;x;right) ⇐⇒ (y = x ∈ E) ∨ (y ∈ right ∧ (¬((cmp x y) = 0 ∈ ℤ))))
16. ∀y:E. (y ∈ bs_tree_insert(cmp;x;left) ⇐⇒ (y = x ∈ E) ∨ (y ∈ left ∧ (¬((cmp x y) = 0 ∈ ℤ))))

⊢ (y = x ∈ E) ∨ (((value = y ∈ E) ∨ y ∈ left ∨ y ∈ right) ∧ (¬((cmp x y) = 0 ∈ ℤ)))

BY
{ ((Eliminate ⌜value⌝⋅ THENA Auto)
   THEN (Assert (cmp y x) = (-(cmp x y)) ∈ ℤ BY
               (RW (AddrC [2] (LemmaC `comparison-anti`)) 0  THEN Auto))
   THEN Auto) }

Latex:

Latex:
1. [E] : Type 2. cmp : comparison(E) 3. x : E 4. left : bs\_tree(E) 5. value : E 6. \mneg{}0 < cmp value x 7. right : bs\_tree(E) 8. bs\_tree\_ordered(E;cmp;left) 9. bs\_tree\_ordered(E;cmp;right) 10. \mforall{}x:E. (x \mmember{} left {}\mRightarrow{} 0 < cmp x value) 11. \mforall{}x:E. (x \mmember{} right {}\mRightarrow{} 0 < cmp value x) 12. y : E 13. cmp value x < 0 14. value = y 15. \mforall{}y:E. (y \mmember{} bs\_tree\_insert(cmp;x;right) \mLeftarrow{}{}\mRightarrow{} (y = x) \mvee{} (y \mmember{} right \mwedge{} (\mneg{}((cmp x y) = 0)))) 16. \mforall{}y:E. (y \mmember{} bs\_tree\_insert(cmp;x;left) \mLeftarrow{}{}\mRightarrow{} (y = x) \mvee{} (y \mmember{} left \mwedge{} (\mneg{}((cmp x y) = 0)))) \mvdash{} (y = x) \mvee{} (((value = y) \mvee{} y \mmember{} left \mvee{} y \mmember{} right) \mwedge{} (\mneg{}((cmp x y) = 0))) By Latex: ((Eliminate \mkleeneopen{}value\mkleeneclose{}\mcdot{} THENA Auto) THEN (Assert (cmp y x) = (-(cmp x y)) BY (RW (AddrC [2] (LemmaC `comparison-anti`)) 0 THEN Auto)) THEN Auto) Home Index