Proof of Nuprl Lemma : add-polynom-val

Step * of Lemma add-polynom-val

∀[n:ℕ]. ∀[p,q:polyform(n)]. ∀[l:{l:ℤ List| n ≤ ||l||} ].  (add-polynom(p;q)@l = (p@l + q@l) ∈ ℤ)

BY
{ ((Assert ⌜∀k:ℕ
              ∀[n:ℕ]. ∀[p,q:polyform(n)].
                (((tree_size(p) + tree_size(q)) ≤ k)
                ⇒ (∀[l:{l:ℤ List| n ≤ ||l||} ]. (add-polynom(p;q)@l = (p@l + q@l) ∈ ℤ)))⌝⋅
   THENM (Auto THEN InstHyp [⌜tree_size(p) + tree_size(q)⌝;⌜n⌝;⌜p⌝;⌜q⌝] 1⋅ THEN Auto)
   )
   THEN CompleteInductionOnNat
   THEN Auto
   THEN RecUnfold `tree_size` (-2)
   THEN ((Assert p ∈ polyform(n) BY Auto) THEN FoldTop `guard` (-1) THEN RepeatFor 2 (DVar `p'))
   THEN (Assert q ∈ polyform(n) BY
               Auto)
   THEN FoldTop `guard` (-1)
   THEN RepeatFor 2 (DVar `q')
   THEN All Reduce
   THEN All (Unfold  `guard`)
   THEN RecUnfold `add-polynom` 0
   THEN Reduce 0) }

1
1. k : ℕ
2. ∀k:ℕk
     ∀[n:ℕ]. ∀[p,q:polyform(n)].
       (((tree_size(p) + tree_size(q)) ≤ k) ⇒ (∀[l:{l:ℤ List| n ≤ ||l||} ]. (add-polynom(p;q)@l = (p@l + q@l) ∈ ℤ)))
3. n : ℕ
4. p1 : ℤ
5. True
6. q1 : ℤ
7. True
8. 0 ≤ k
9. l : {l:ℤ List| n ≤ ||l||}
10. tree_leaf(p1) ∈ polyform(n)
11. tree_leaf(q1) ∈ polyform(n)
⊢ eval a = p1 + q1 in tree_leaf(a)@l = (tree_leaf(p1)@l + tree_leaf(q1)@l) ∈ ℤ

2
1. k : ℕ
2. ∀k:ℕk
     ∀[n:ℕ]. ∀[p,q:polyform(n)].
       (((tree_size(p) + tree_size(q)) ≤ k) ⇒ (∀[l:{l:ℤ List| n ≤ ||l||} ]. (add-polynom(p;q)@l = (p@l + q@l) ∈ ℤ)))
3. n : ℕ
4. p1 : ℤ
5. True
6. left : tree(ℤ)
7. q2 : tree(ℤ)
8. ↑(((ispolyform(left) (n - 1)) ∧_b (ispolyform(q2) n)) ∧_b 0 <z n)
9. (0 + (1 + tree_size(left)) + tree_size(q2)) ≤ k
10. l : {l:ℤ List| n ≤ ||l||}
11. tree_leaf(p1) ∈ polyform(n)
12. tree_node(left;q2) ∈ polyform(n)
⊢ eval a = add-polynom(tree_leaf(p1);left) in
  eval b = q2 in
    tree_node(a;b)@l
= (tree_leaf(p1)@l + tree_node(left;q2)@l)
∈ ℤ

3
1. k : ℕ
2. ∀k:ℕk
     ∀[n:ℕ]. ∀[p,q:polyform(n)].
       (((tree_size(p) + tree_size(q)) ≤ k) ⇒ (∀[l:{l:ℤ List| n ≤ ||l||} ]. (add-polynom(p;q)@l = (p@l + q@l) ∈ ℤ)))
3. n : ℕ
4. left : tree(ℤ)
5. p2 : tree(ℤ)
6. ↑(((ispolyform(left) (n - 1)) ∧_b (ispolyform(p2) n)) ∧_b 0 <z n)
7. q1 : ℤ
8. True
9. (((1 + tree_size(left)) + tree_size(p2)) + 0) ≤ k
10. l : {l:ℤ List| n ≤ ||l||}
11. tree_node(left;p2) ∈ polyform(n)
12. tree_leaf(q1) ∈ polyform(n)
⊢ eval a = add-polynom(left;tree_leaf(q1)) in
  eval b = p2 in
    tree_node(a;b)@l
= (tree_node(left;p2)@l + tree_leaf(q1)@l)
∈ ℤ

4
1. k : ℕ
2. ∀k:ℕk
     ∀[n:ℕ]. ∀[p,q:polyform(n)].
       (((tree_size(p) + tree_size(q)) ≤ k) ⇒ (∀[l:{l:ℤ List| n ≤ ||l||} ]. (add-polynom(p;q)@l = (p@l + q@l) ∈ ℤ)))
3. n : ℕ
4. left : tree(ℤ)
5. p2 : tree(ℤ)
6. ↑(((ispolyform(left) (n - 1)) ∧_b (ispolyform(p2) n)) ∧_b 0 <z n)
7. l1 : tree(ℤ)
8. q2 : tree(ℤ)
9. ↑(((ispolyform(l1) (n - 1)) ∧_b (ispolyform(q2) n)) ∧_b 0 <z n)
10. (((1 + tree_size(left)) + tree_size(p2)) + (1 + tree_size(l1)) + tree_size(q2)) ≤ k
11. l : {l:ℤ List| n ≤ ||l||}
12. tree_node(left;p2) ∈ polyform(n)
13. tree_node(l1;q2) ∈ polyform(n)
⊢ eval a = add-polynom(left;l1) in
  eval b = add-polynom(p2;q2) in
    if poly-zero(b) ∧_b poly-int(a) then a else tree_node(a;b) fi @l
= (tree_node(left;p2)@l + tree_node(l1;q2)@l)
∈ ℤ

Latex:

Latex:
\mforall{}[n:\mBbbN{}]. \mforall{}[p,q:polyform(n)]. \mforall{}[l:\{l:\mBbbZ{} List| n \mleq{} ||l||\} ]. (add-polynom(p;q)@l = (p@l + q@l)) By Latex: ((Assert \mkleeneopen{}\mforall{}k:\mBbbN{} \mforall{}[n:\mBbbN{}]. \mforall{}[p,q:polyform(n)]. (((tree\_size(p) + tree\_size(q)) \mleq{} k) {}\mRightarrow{} (\mforall{}[l:\{l:\mBbbZ{} List| n \mleq{} ||l||\} ]. (add-polynom(p;q)@l = (p@l + q@l))))\mkleeneclose{}\mcdot{} THENM (Auto THEN InstHyp [\mkleeneopen{}tree\_size(p) + tree\_size(q)\mkleeneclose{};\mkleeneopen{}n\mkleeneclose{};\mkleeneopen{}p\mkleeneclose{};\mkleeneopen{}q\mkleeneclose{}] 1\mcdot{} THEN Auto) ) THEN CompleteInductionOnNat THEN Auto THEN RecUnfold `tree\_size` (-2) THEN ((Assert p \mmember{} polyform(n) BY Auto) THEN FoldTop `guard` (-1) THEN RepeatFor 2 (DVar `p')) THEN (Assert q \mmember{} polyform(n) BY Auto) THEN FoldTop `guard` (-1) THEN RepeatFor 2 (DVar `q') THEN All Reduce THEN All (Unfold `guard`) THEN RecUnfold `add-polynom` 0 THEN Reduce 0) Home Index