Proof of Nuprl Lemma : bar-separation-implies-twkl!

Step * 2 1 1 1 2 1 2 1 of Lemma bar-separation-implies-twkl!

1. T : Type
2. ∃size:ℕ. T ~ ℕsize
3. BarSep(T;T)
4. A : {A:(T List) ⟶ ℙ| down-closed(T;A) ∧ Unbounded(A)}
5. ¬tbar(T;¬(A))
6. Decidable(A)
7. ∀as,bs:T List.  (as ≤ bs ⇒ (A bs) ⇒ (A as))
8. T
9. ∀a,b:T.  Dec(a = b ∈ T)
10. eff-unique-path(T;A)
11. ∀s:T List. ∃t:T. ∀t':T. ((¬(t' = t ∈ T)) ⇒ tbar(T;¬(λx.(A ((s @ [t']) @ x)))))
12. g : s:(T List) ⟶ T
13. ∀s:T List. ∀t':T.  ((¬(t' = (g s) ∈ T)) ⇒ tbar(T;¬(λx.(A ((s @ [t']) @ x)))))
14. ∀n:ℕ
      ((||primrec(n;[];λn',s. (s @ [g s]))|| = n ∈ ℤ)
      ∧ (0 < n ⇒ (primrec(n;[];λn',s. (s @ [g s]))[n - 1] = (g primrec(n - 1;[];λn',s. (s @ [g s]))) ∈ T))

      ∧ (map(λn.primrec(n + 1;[];λn',s. (s @ [g s]))[n];upto(n)) = primrec(n;[];λn',s. (s @ [g s])) ∈ (T List)))

15. n : ℕ
16. ||primrec(n;[];λn',s. (s @ [g s]))|| = n ∈ ℤ
17. 0 < n ⇒ (primrec(n;[];λn',s. (s @ [g s]))[n - 1] = (g primrec(n - 1;[];λn',s. (s @ [g s]))) ∈ T)

18. map(λn.primrec(n + 1;[];λn',s. (s @ [g s]))[n];upto(n)) = primrec(n;[];λn',s. (s @ [g s])) ∈ (T List)

⊢ A map(λn.primrec(n + 1;[];λn',s. (s @ [g s]))[n];upto(n))
BY

{ (All (Unfold `dec-predicate`) THEN SupposeNot THEN D 5 THEN D 0 THEN Auto THEN RepUR ``predicate-not`` 0) }

1
1. T : Type
2. ∃size:ℕ. T ~ ℕsize
3. BarSep(T;T)
4. A : {A:(T List) ⟶ ℙ| down-closed(T;A) ∧ Unbounded(A)}
5. ∀t:T List. Dec(A t)
6. ∀as,bs:T List.  (as ≤ bs ⇒ (A bs) ⇒ (A as))
7. T
8. ∀a,b:T.  Dec(a = b ∈ T)
9. eff-unique-path(T;A)
10. ∀s:T List. ∃t:T. ∀t':T. ((¬(t' = t ∈ T)) ⇒ tbar(T;¬(λx.(A ((s @ [t']) @ x)))))
11. g : s:(T List) ⟶ T
12. ∀s:T List. ∀t':T.  ((¬(t' = (g s) ∈ T)) ⇒ tbar(T;¬(λx.(A ((s @ [t']) @ x)))))
13. ∀n:ℕ
      ((||primrec(n;[];λn',s. (s @ [g s]))|| = n ∈ ℤ)
      ∧ (0 < n ⇒ (primrec(n;[];λn',s. (s @ [g s]))[n - 1] = (g primrec(n - 1;[];λn',s. (s @ [g s]))) ∈ T))

      ∧ (map(λn.primrec(n + 1;[];λn',s. (s @ [g s]))[n];upto(n)) = primrec(n;[];λn',s. (s @ [g s])) ∈ (T List)))

14. n : ℕ
15. ||primrec(n;[];λn',s. (s @ [g s]))|| = n ∈ ℤ
16. 0 < n ⇒ (primrec(n;[];λn',s. (s @ [g s]))[n - 1] = (g primrec(n - 1;[];λn',s. (s @ [g s]))) ∈ T)

17. map(λn.primrec(n + 1;[];λn',s. (s @ [g s]))[n];upto(n)) = primrec(n;[];λn',s. (s @ [g s])) ∈ (T List)

18. ¬(A map(λn.primrec(n + 1;[];λn',s. (s @ [g s]))[n];upto(n)))
19. f : ℕ ⟶ T
⊢ ∃n:ℕ. (¬(A map(f;upto(n))))

Latex:

Latex:
1. T : Type 2. \mexists{}size:\mBbbN{}. T \msim{} \mBbbN{}size 3. BarSep(T;T) 4. A : \{A:(T List) {}\mrightarrow{} \mBbbP{}| down-closed(T;A) \mwedge{} Unbounded(A)\} 5. \mneg{}tbar(T;\mneg{}(A)) 6. Decidable(A) 7. \mforall{}as,bs:T List. (as \mleq{} bs {}\mRightarrow{} (A bs) {}\mRightarrow{} (A as)) 8. T 9. \mforall{}a,b:T. Dec(a = b) 10. eff-unique-path(T;A) 11. \mforall{}s:T List. \mexists{}t:T. \mforall{}t':T. ((\mneg{}(t' = t)) {}\mRightarrow{} tbar(T;\mneg{}(\mlambda{}x.(A ((s @ [t']) @ x))))) 12. g : s:(T List) {}\mrightarrow{} T 13. \mforall{}s:T List. \mforall{}t':T. ((\mneg{}(t' = (g s))) {}\mRightarrow{} tbar(T;\mneg{}(\mlambda{}x.(A ((s @ [t']) @ x))))) 14. \mforall{}n:\mBbbN{} ((||primrec(n;[];\mlambda{}n',s. (s @ [g s]))|| = n) \mwedge{} (0 < n {}\mRightarrow{} (primrec(n;[];\mlambda{}n',s. (s @ [g s]))[n - 1] = (g primrec(n - 1;[];\mlambda{}n',s. (s @ [g s]))\000C))) \mwedge{} (map(\mlambda{}n.primrec(n + 1;[];\mlambda{}n',s. (s @ [g s]))[n];upto(n)) = primrec(n;[];\mlambda{}n',s. (s @ [g s])))\000C) 15. n : \mBbbN{} 16. ||primrec(n;[];\mlambda{}n',s. (s @ [g s]))|| = n 17. 0 < n {}\mRightarrow{} (primrec(n;[];\mlambda{}n',s. (s @ [g s]))[n - 1] = (g primrec(n - 1;[];\mlambda{}n',s. (s @ [g s])))) 18. map(\mlambda{}n.primrec(n + 1;[];\mlambda{}n',s. (s @ [g s]))[n];upto(n)) = primrec(n;[];\mlambda{}n',s. (s @ [g s])) \mvdash{} A map(\mlambda{}n.primrec(n + 1;[];\mlambda{}n',s. (s @ [g s]))[n];upto(n)) By Latex: (All (Unfold `dec-predicate`) THEN SupposeNot THEN D 5 THEN D 0 THEN Auto THEN RepUR ``predicate-not`` 0) Home Index