Proof of Nuprl Lemma : accum_split

Step * 2 1 1 1 of Lemma accum_split_wf

1. A : Type
2. T : Type
3. f : (T List × A) ⟶ 𝔹
4. g : (T List × A) ⟶ A
5. x : A
6. n : ℕ
7. L : T List
8. ¬↑null(L)
9. v1 : (T List × A) List
10. v3 : T List
11. v4 : A
12. firstn(||L|| - 1;L) = (concat(map(λp.(fst(p));v1)) @ v3) ∈ (T List)
13. (∀L'∈v1.(↑(f L'))
        ∧ (¬↑null(fst(L')))
        ∧ (∀S:T List. ((¬↑null(S)) ⇒ S ≤ fst(L') ⇒ (¬(S = (fst(L')) ∈ (T List))) ⇒ (¬↑(f <S, snd(L')>)))))
14. (¬↑null(firstn(||L|| - 1;L))) ⇒ (¬↑null(v3))
15. ∀S:T List. ((¬↑null(S)) ⇒ S ≤ v3 ⇒ (¬(S = v3 ∈ (T List))) ⇒ (¬↑(f <S, v4>)))
16. (snd(hd(v1 @ [<v3, v4>]))) = x ∈ A
17. ∀i:ℕ||v1||. ((snd(v1 @ [<v3, v4>][i + 1])) = (g v1[i]) ∈ A)
18. v3 = [] ∈ (T List)
⊢ is_accum_splitting(T;A;firstn(||L|| - 1;L) @ [last(L)];v1;<[last(L)], v4>;f;g;x)
BY
{ (RepUR ``is_accum_splitting`` 0 THEN SplitAndConcl THEN Intros THEN Try (Trivial)) }

1
1. A : Type
2. T : Type
3. f : (T List × A) ⟶ 𝔹
4. g : (T List × A) ⟶ A
5. x : A
6. n : ℕ
7. L : T List
8. ¬↑null(L)
9. v1 : (T List × A) List
10. v3 : T List
11. v4 : A
12. firstn(||L|| - 1;L) = (concat(map(λp.(fst(p));v1)) @ v3) ∈ (T List)
13. (∀L'∈v1.(↑(f L'))
        ∧ (¬↑null(fst(L')))
        ∧ (∀S:T List. ((¬↑null(S)) ⇒ S ≤ fst(L') ⇒ (¬(S = (fst(L')) ∈ (T List))) ⇒ (¬↑(f <S, snd(L')>)))))
14. (¬↑null(firstn(||L|| - 1;L))) ⇒ (¬↑null(v3))
15. ∀S:T List. ((¬↑null(S)) ⇒ S ≤ v3 ⇒ (¬(S = v3 ∈ (T List))) ⇒ (¬↑(f <S, v4>)))
16. (snd(hd(v1 @ [<v3, v4>]))) = x ∈ A
17. ∀i:ℕ||v1||. ((snd(v1 @ [<v3, v4>][i + 1])) = (g v1[i]) ∈ A)
18. v3 = [] ∈ (T List)
⊢ (firstn(||L|| - 1;L) @ [last(L)]) = (concat(map(λp.(fst(p));v1)) @ [last(L)]) ∈ (T List)

2
1. A : Type
2. T : Type
3. f : (T List × A) ⟶ 𝔹
4. g : (T List × A) ⟶ A
5. x : A
6. n : ℕ
7. L : T List
8. ¬↑null(L)
9. v1 : (T List × A) List
10. v3 : T List
11. v4 : A
12. firstn(||L|| - 1;L) = (concat(map(λp.(fst(p));v1)) @ v3) ∈ (T List)
13. (∀L'∈v1.(↑(f L'))
        ∧ (¬↑null(fst(L')))
        ∧ (∀S:T List. ((¬↑null(S)) ⇒ S ≤ fst(L') ⇒ (¬(S = (fst(L')) ∈ (T List))) ⇒ (¬↑(f <S, snd(L')>)))))
14. (¬↑null(firstn(||L|| - 1;L))) ⇒ (¬↑null(v3))
15. ∀S:T List. ((¬↑null(S)) ⇒ S ≤ v3 ⇒ (¬(S = v3 ∈ (T List))) ⇒ (¬↑(f <S, v4>)))
16. (snd(hd(v1 @ [<v3, v4>]))) = x ∈ A
17. ∀i:ℕ||v1||. ((snd(v1 @ [<v3, v4>][i + 1])) = (g v1[i]) ∈ A)
18. v3 = [] ∈ (T List)
19. ¬↑null(firstn(||L|| - 1;L) @ [last(L)])
⊢ ¬False

3
1. A : Type
2. T : Type
3. f : (T List × A) ⟶ 𝔹
4. g : (T List × A) ⟶ A
5. x : A
6. n : ℕ
7. L : T List
8. ¬↑null(L)
9. v1 : (T List × A) List
10. v3 : T List
11. v4 : A
12. firstn(||L|| - 1;L) = (concat(map(λp.(fst(p));v1)) @ v3) ∈ (T List)
13. (∀L'∈v1.(↑(f L'))
        ∧ (¬↑null(fst(L')))
        ∧ (∀S:T List. ((¬↑null(S)) ⇒ S ≤ fst(L') ⇒ (¬(S = (fst(L')) ∈ (T List))) ⇒ (¬↑(f <S, snd(L')>)))))
14. (¬↑null(firstn(||L|| - 1;L))) ⇒ (¬↑null(v3))
15. ∀S:T List. ((¬↑null(S)) ⇒ S ≤ v3 ⇒ (¬(S = v3 ∈ (T List))) ⇒ (¬↑(f <S, v4>)))
16. (snd(hd(v1 @ [<v3, v4>]))) = x ∈ A
17. ∀i:ℕ||v1||. ((snd(v1 @ [<v3, v4>][i + 1])) = (g v1[i]) ∈ A)
18. v3 = [] ∈ (T List)
19. S : T List
20. ¬↑null(S)
21. S ≤ [last(L)]
22. ¬(S = [last(L)] ∈ (T List))
⊢ ¬↑(f <S, v4>)

4
1. A : Type
2. T : Type
3. f : (T List × A) ⟶ 𝔹
4. g : (T List × A) ⟶ A
5. x : A
6. n : ℕ
7. L : T List
8. ¬↑null(L)
9. v1 : (T List × A) List
10. v3 : T List
11. v4 : A
12. firstn(||L|| - 1;L) = (concat(map(λp.(fst(p));v1)) @ v3) ∈ (T List)
13. (∀L'∈v1.(↑(f L'))
        ∧ (¬↑null(fst(L')))
        ∧ (∀S:T List. ((¬↑null(S)) ⇒ S ≤ fst(L') ⇒ (¬(S = (fst(L')) ∈ (T List))) ⇒ (¬↑(f <S, snd(L')>)))))
14. (¬↑null(firstn(||L|| - 1;L))) ⇒ (¬↑null(v3))
15. ∀S:T List. ((¬↑null(S)) ⇒ S ≤ v3 ⇒ (¬(S = v3 ∈ (T List))) ⇒ (¬↑(f <S, v4>)))
16. (snd(hd(v1 @ [<v3, v4>]))) = x ∈ A
17. ∀i:ℕ||v1||. ((snd(v1 @ [<v3, v4>][i + 1])) = (g v1[i]) ∈ A)
18. v3 = [] ∈ (T List)
⊢ (snd(hd(v1 @ [<[last(L)], v4>]))) = x ∈ A

5
1. A : Type
2. T : Type
3. f : (T List × A) ⟶ 𝔹
4. g : (T List × A) ⟶ A
5. x : A
6. n : ℕ
7. L : T List
8. ¬↑null(L)
9. v1 : (T List × A) List
10. v3 : T List
11. v4 : A
12. firstn(||L|| - 1;L) = (concat(map(λp.(fst(p));v1)) @ v3) ∈ (T List)
13. (∀L'∈v1.(↑(f L'))
        ∧ (¬↑null(fst(L')))
        ∧ (∀S:T List. ((¬↑null(S)) ⇒ S ≤ fst(L') ⇒ (¬(S = (fst(L')) ∈ (T List))) ⇒ (¬↑(f <S, snd(L')>)))))
14. (¬↑null(firstn(||L|| - 1;L))) ⇒ (¬↑null(v3))
15. ∀S:T List. ((¬↑null(S)) ⇒ S ≤ v3 ⇒ (¬(S = v3 ∈ (T List))) ⇒ (¬↑(f <S, v4>)))
16. (snd(hd(v1 @ [<v3, v4>]))) = x ∈ A
17. ∀i:ℕ||v1||. ((snd(v1 @ [<v3, v4>][i + 1])) = (g v1[i]) ∈ A)
18. v3 = [] ∈ (T List)
19. i : ℕ||v1||
⊢ (snd(v1 @ [<[last(L)], v4>][i + 1])) = (g v1[i]) ∈ A

Latex:

Latex:
1. A : Type 2. T : Type 3. f : (T List \mtimes{} A) {}\mrightarrow{} \mBbbB{} 4. g : (T List \mtimes{} A) {}\mrightarrow{} A 5. x : A 6. n : \mBbbN{} 7. L : T List 8. \mneg{}\muparrow{}null(L) 9. v1 : (T List \mtimes{} A) List 10. v3 : T List 11. v4 : A 12. firstn(||L|| - 1;L) = (concat(map(\mlambda{}p.(fst(p));v1)) @ v3) 13. (\mforall{}L'\mmember{}v1.(\muparrow{}(f L')) \mwedge{} (\mneg{}\muparrow{}null(fst(L'))) \mwedge{} (\mforall{}S:T List. ((\mneg{}\muparrow{}null(S)) {}\mRightarrow{} S \mleq{} fst(L') {}\mRightarrow{} (\mneg{}(S = (fst(L')))) {}\mRightarrow{} (\mneg{}\muparrow{}(f <S, snd(L')>))))) 14. (\mneg{}\muparrow{}null(firstn(||L|| - 1;L))) {}\mRightarrow{} (\mneg{}\muparrow{}null(v3)) 15. \mforall{}S:T List. ((\mneg{}\muparrow{}null(S)) {}\mRightarrow{} S \mleq{} v3 {}\mRightarrow{} (\mneg{}(S = v3)) {}\mRightarrow{} (\mneg{}\muparrow{}(f <S, v4>))) 16. (snd(hd(v1 @ [<v3, v4>]))) = x 17. \mforall{}i:\mBbbN{}||v1||. ((snd(v1 @ [<v3, v4>][i + 1])) = (g v1[i])) 18. v3 = [] \mvdash{} is\_accum\_splitting(T;A;firstn(||L|| - 1;L) @ [last(L)];v1;<[last(L)], v4>f;g;x) By Latex: (RepUR ``is\_accum\_splitting`` 0 THEN SplitAndConcl THEN Intros THEN Try (Trivial)) Home Index