Proof of Nuprl Lemma : adjacent-append

Step * 1 1 1 of Lemma adjacent-append

1. [T] : Type
2. x : T
3. y : T
4. L1 : T List
5. L2 : T List
6. i : ℕ||L1 @ L2|| - 1
7. x = L1 @ L2[i] ∈ T
8. y = L1 @ L2[i + 1] ∈ T
9. i < ||L1||
10. i < ||L1|| - 1
⊢ (∃i:ℕ||L1|| - 1. ((x = L1[i] ∈ T) ∧ (y = L1[i + 1] ∈ T)))
∨ (0 < ||L1|| ∧ 0 < ||L2|| ∧ (x = last(L1) ∈ T) ∧ (y = hd(L2) ∈ T))
∨ (∃i:ℕ||L2|| - 1. ((x = L2[i] ∈ T) ∧ (y = L2[i + 1] ∈ T)))
BY
{ (OrLeft THENA (Auto THEN DVar `L1' THEN All Reduce THEN Auto)) }

1
1. [T] : Type
2. x : T
3. y : T
4. L1 : T List
5. L2 : T List
6. i : ℕ||L1 @ L2|| - 1
7. x = L1 @ L2[i] ∈ T
8. y = L1 @ L2[i + 1] ∈ T
9. i < ||L1||
10. i < ||L1|| - 1
⊢ ∃i:ℕ||L1|| - 1. ((x = L1[i] ∈ T) ∧ (y = L1[i + 1] ∈ T))

Latex:

Latex:
1. [T] : Type 2. x : T 3. y : T 4. L1 : T List 5. L2 : T List 6. i : \mBbbN{}||L1 @ L2|| - 1 7. x = L1 @ L2[i] 8. y = L1 @ L2[i + 1] 9. i < ||L1|| 10. i < ||L1|| - 1 \mvdash{} (\mexists{}i:\mBbbN{}||L1|| - 1. ((x = L1[i]) \mwedge{} (y = L1[i + 1]))) \mvee{} (0 < ||L1|| \mwedge{} 0 < ||L2|| \mwedge{} (x = last(L1)) \mwedge{} (y = hd(L2))) \mvee{} (\mexists{}i:\mBbbN{}||L2|| - 1. ((x = L2[i]) \mwedge{} (y = L2[i + 1]))) By Latex: (OrLeft THENA (Auto THEN DVar `L1' THEN All Reduce THEN Auto)) Home Index