Proof of Nuprl Lemma : find-xover

Step * 1 of Lemma find-xover_wf

.....assertion.....
∀d:ℕ
∀[x:ℤ]. ∀[n:{x...}]. ∀[step:ℕ⁺]. ∀[f:{x...} ⟶ 𝔹].
find-xover(f;x;n;step) ∈ n':{n':ℤ| (n ≤ n') ∧ f n' = tt} × {x':ℤ|

                                    ((n' = n ∈ ℤ) ∧ (x' = x ∈ ℤ))

                                    ∨ (((n ≤ x') ∧ f x' = ff) ∧ ((n' = (n + step) ∈ ℤ) ∨ ((n + step) ≤ x')))}

    supposing ∃m:{n..n + d^-}. ∀k:{m...}. f k = tt
BY
{ (CompleteInductionOnNat
   THEN (UnivCD THENA Auto)
   THEN RecUnfold `find-xover` 0
   THEN AutoSplit
   THEN RepeatFor 2 ((CallByValueReduce 0 THENA Auto))) }

1
1. d : ℕ
2. ∀d:ℕd
     ∀[x:ℤ]. ∀[n:{x...}]. ∀[step:ℕ⁺]. ∀[f:{x...} ⟶ 𝔹].
       find-xover(f;x;n;step) ∈ n':{n':ℤ| (n ≤ n') ∧ f n' = tt}  × {x':ℤ|

                                       ((n' = n ∈ ℤ) ∧ (x' = x ∈ ℤ))

                                       ∨ (((n ≤ x') ∧ f x' = ff) ∧ ((n' = (n + step) ∈ ℤ) ∨ ((n + step) ≤ x')))}

       supposing ∃m:{n..n + d^-}. ∀k:{m...}. f k = tt
3. x : ℤ
4. n : {x...}
5. step : ℕ⁺
6. f : {x...} ⟶ 𝔹
7. ¬↑(f n)
8. ∃m:{n..n + d^-}. ∀k:{m...}. f k = tt
⊢ find-xover(f;n;n + step;2 * step) ∈ n':{n':ℤ| (n ≤ n') ∧ f n' = tt}  × {x':ℤ|
                                  ((n' = n ∈ ℤ) ∧ (x' = x ∈ ℤ))

                                  ∨ (((n ≤ x') ∧ f x' = ff) ∧ ((n' = (n + step) ∈ ℤ) ∨ ((n + step) ≤ x')))}

Latex:

Latex:
.....assertion..... \mforall{}d:\mBbbN{} \mforall{}[x:\mBbbZ{}]. \mforall{}[n:\{x...\}]. \mforall{}[step:\mBbbN{}\msupplus{}]. \mforall{}[f:\{x...\} {}\mrightarrow{} \mBbbB{}]. find-xover(f;x;n;step) \mmember{} n':\{n':\mBbbZ{}| (n \mleq{} n') \mwedge{} f n' = tt\} \mtimes{} \{x':\mBbbZ{}| ((n' = n) \mwedge{} (x' = x)) \mvee{} (((n \mleq{} x') \mwedge{} f x' = ff) \mwedge{} ((n' = (n + step)) \mvee{} ((n + step) \mleq{} x')))\} supposing \mexists{}m:\{n..n + d\msupminus{}\}. \mforall{}k:\{m...\}. f k = tt By Latex: (CompleteInductionOnNat THEN (UnivCD THENA Auto) THEN RecUnfold `find-xover` 0 THEN AutoSplit THEN RepeatFor 2 ((CallByValueReduce 0 THENA Auto))) Home Index