Proof of Nuprl Lemma : factorit

Step * 1 2 of Lemma factorit_wf

.....falsecase.....
1. d : ℕ
2. ∀d:ℕd
     ∀[x:ℕ⁺]. ∀[b:ℕ].
       (x - b * b < d
       ⇒ (2 ≤ b)
       ⇒ (∀[tried:{L:{p:ℕ| prime(p) ∧ p < b}  List| ∀p:{p:ℕ| prime(p)} . (p < b ⇒ ((p ∈ L) ∧ (¬(p | x))))} ].
           ∀[facs:{p:ℕ| prime(p)}  List].
             (factorit(x;b;tried;facs) ∈ {L:{p:ℕ| prime(p)}  List|

                                          reduce(λp,q. (p * q);1;L) = (x * reduce(λp,q. (p * q);1;facs)) ∈ ℤ} )))

3. x : ℕ⁺
4. b : ℕ
5. x - b * b < d
6. 2 ≤ b
7. tried : {L:{p:ℕ| prime(p) ∧ p < b}  List| ∀p:{p:ℕ| prime(p)} . (p < b ⇒ ((p ∈ L) ∧ (¬(p | x))))}
8. facs : {p:ℕ| prime(p)}  List
9. (b * b) ≤ x
⊢ if (∃p∈tried.(b rem p =_z 0))_b then eval b' = b + 1 in factorit(x;b';tried;facs)
  if (x rem b =_z 0) then eval x' = x ÷ b in factorit(x';b;tried;[b / facs])
  else eval b' = b + 1 in
       factorit(x;b';[b / tried];facs)

  fi  ∈ {L:{p:ℕ| prime(p)}  List| reduce(λp,q. (p * q);1;L) = (x * reduce(λp,q. (p * q);1;facs)) ∈ ℤ}

{ ((Assert ∀p:{p:ℕ| prime(p)} . p ≠ 0 BY (Auto THEN RepeatFor 2 ((D (-1) THEN Auto)))) THEN AutoSplit) }

1
1. d : ℕ
2. ∀d:ℕd
     ∀[x:ℕ⁺]. ∀[b:ℕ].
       (x - b * b < d
       ⇒ (2 ≤ b)
       ⇒ (∀[tried:{L:{p:ℕ| prime(p) ∧ p < b}  List| ∀p:{p:ℕ| prime(p)} . (p < b ⇒ ((p ∈ L) ∧ (¬(p | x))))} ].
           ∀[facs:{p:ℕ| prime(p)}  List].
             (factorit(x;b;tried;facs) ∈ {L:{p:ℕ| prime(p)}  List|

                                          reduce(λp,q. (p * q);1;L) = (x * reduce(λp,q. (p * q);1;facs)) ∈ ℤ} )))

3. x : ℕ⁺
4. b : ℕ
5. x - b * b < d
6. 2 ≤ b
7. tried : {L:{p:ℕ| prime(p) ∧ p < b} List| ∀p:{p:ℕ| prime(p)} . (p < b ⇒ ((p ∈ L) ∧ (¬(p | x))))}
8. facs : {p:ℕ| prime(p)} List
9. (b * b) ≤ x
10. ∀p:{p:ℕ| prime(p)} . p ≠ 0
11. (∃p∈tried. (b rem p) = 0 ∈ ℤ)
⊢ eval b' = b + 1 in

  factorit(x;b';tried;facs) ∈ {L:{p:ℕ| prime(p)}  List| reduce(λp,q. (p * q);1;L) = (x * reduce(λp,q. (p * q);1;facs)) ∈\000C ℤ}

2
1. d : ℕ
2. ∀d:ℕd
     ∀[x:ℕ⁺]. ∀[b:ℕ].
       (x - b * b < d
       ⇒ (2 ≤ b)
       ⇒ (∀[tried:{L:{p:ℕ| prime(p) ∧ p < b}  List| ∀p:{p:ℕ| prime(p)} . (p < b ⇒ ((p ∈ L) ∧ (¬(p | x))))} ].
           ∀[facs:{p:ℕ| prime(p)}  List].
             (factorit(x;b;tried;facs) ∈ {L:{p:ℕ| prime(p)}  List|

                                          reduce(λp,q. (p * q);1;L) = (x * reduce(λp,q. (p * q);1;facs)) ∈ ℤ} )))

3. x : ℕ⁺
4. b : ℕ
5. x - b * b < d
6. 2 ≤ b
7. tried : {L:{p:ℕ| prime(p) ∧ p < b}  List| ∀p:{p:ℕ| prime(p)} . (p < b ⇒ ((p ∈ L) ∧ (¬(p | x))))}
8. ¬(∃p∈tried. (b rem p) = 0 ∈ ℤ)
9. facs : {p:ℕ| prime(p)}  List
10. (b * b) ≤ x
11. ∀p:{p:ℕ| prime(p)} . p ≠ 0
⊢ if (x rem b =_z 0)
  then eval x' = x ÷ b in
       factorit(x';b;tried;[b / facs])
  else eval b' = b + 1 in
       factorit(x;b';[b / tried];facs)

  fi  ∈ {L:{p:ℕ| prime(p)}  List| reduce(λp,q. (p * q);1;L) = (x * reduce(λp,q. (p * q);1;facs)) ∈ ℤ}

Latex:

Latex:
.....falsecase..... 1. d : \mBbbN{} 2. \mforall{}d:\mBbbN{}d \mforall{}[x:\mBbbN{}\msupplus{}]. \mforall{}[b:\mBbbN{}]. (x - b * b < d {}\mRightarrow{} (2 \mleq{} b) {}\mRightarrow{} (\mforall{}[tried:\{L:\{p:\mBbbN{}| prime(p) \mwedge{} p < b\} List| \mforall{}p:\{p:\mBbbN{}| prime(p)\} . (p < b {}\mRightarrow{} ((p \mmember{} L) \mwedge{} (\mneg{}(p | x))))\} ]. \mforall{}[facs:\{p:\mBbbN{}| prime(p)\} List]. (factorit(x;b;tried;facs) \mmember{} \{L:\{p:\mBbbN{}| prime(p)\} List| reduce(\mlambda{}p,q. (p * q);1;L) = (x * reduce(\mlambda{}p,q. (p * q);1;fa\000Ccs))\} ))) 3. x : \mBbbN{}\msupplus{} 4. b : \mBbbN{} 5. x - b * b < d 6. 2 \mleq{} b 7. tried : \{L:\{p:\mBbbN{}| prime(p) \mwedge{} p < b\} List| \mforall{}p:\{p:\mBbbN{}| prime(p)\} . (p < b {}\mRightarrow{} ((p \mmember{} L) \mwedge{} (\mneg{}(p | x))))\}\000C 8. facs : \{p:\mBbbN{}| prime(p)\} List 9. (b * b) \mleq{} x \mvdash{} if (\mexists{}p\mmember{}tried.(b rem p =\msubz{} 0))\_b then eval b' = b + 1 in factorit(x;b';tried;facs) if (x rem b =\msubz{} 0) then eval x' = x \mdiv{} b in factorit(x';b;tried;[b / facs]) else eval b' = b + 1 in factorit(x;b';[b / tried];facs) fi \mmember{} \{L:\{p:\mBbbN{}| prime(p)\} List| reduce(\mlambda{}p,q. (p * q);1;L) = (x * reduce(\mlambda{}p,q. (p * q);1;facs))\} By Latex: ((Assert \mforall{}p:\{p:\mBbbN{}| prime(p)\} . p \mneq{} 0 BY (Auto THEN RepeatFor 2 ((D (-1) THEN Auto)))) THEN AutoSplit) Home Index