Step
*
2
of Lemma
add-ipoly-req
1. n : ℤ
2. 0 < n
3. ∀p,q:iMonomial() List.
(||p|| + ||q|| < n - 1 ⇒ ipolynomial-term(add-ipoly(p;q)) ≡ ipolynomial-term(p) (+) ipolynomial-term(q))
4. p : iMonomial() List
5. q : iMonomial() List
6. ||p|| + ||q|| < n
⊢ ipolynomial-term(add-ipoly(p;q)) ≡ ipolynomial-term(p) (+) ipolynomial-term(q)
BY
{ (DVar `p' THEN RecUnfold `add-ipoly` 0 THEN RepeatFor 2 ((CallByValueReduce 0 THENA Auto)) THEN Reduce 0) }
1
1. n : ℤ
2. 0 < n
3. ∀p,q:iMonomial() List.
(||p|| + ||q|| < n - 1 ⇒ ipolynomial-term(add-ipoly(p;q)) ≡ ipolynomial-term(p) (+) ipolynomial-term(q))
4. q : iMonomial() List
5. ||[]|| + ||q|| < n
⊢ ipolynomial-term(q) ≡ ipolynomial-term([]) (+) ipolynomial-term(q)
2
1. n : ℤ
2. 0 < n
3. ∀p,q:iMonomial() List.
(||p|| + ||q|| < n - 1 ⇒ ipolynomial-term(add-ipoly(p;q)) ≡ ipolynomial-term(p) (+) ipolynomial-term(q))
4. u : iMonomial()
5. v : iMonomial() List
6. q : iMonomial() List
7. ||[u / v]|| + ||q|| < n
⊢ ipolynomial-term(if null(q)
then [u / v]
else let q1,qs = q
in if imonomial-le(u;q1)
then if imonomial-le(q1;u)
then let x ⟵ add-ipoly(v;qs)
in let cp,vs = u
in eval c = cp + (fst(q1)) in
if c=0 then x else [<c, vs> / x]
else let x ⟵ add-ipoly(v;[q1 / qs])
in [u / x]
fi
else let x ⟵ add-ipoly([u / v];qs)
in [q1 / x]
fi
fi ) ≡ ipolynomial-term([u / v]) (+) ipolynomial-term(q)
Latex:
Latex:
1. n : \mBbbZ{}
2. 0 < n
3. \mforall{}p,q:iMonomial() List.
(||p|| + ||q|| < n - 1
{}\mRightarrow{} ipolynomial-term(add-ipoly(p;q)) \mequiv{} ipolynomial-term(p) (+) ipolynomial-term(q))
4. p : iMonomial() List
5. q : iMonomial() List
6. ||p|| + ||q|| < n
\mvdash{} ipolynomial-term(add-ipoly(p;q)) \mequiv{} ipolynomial-term(p) (+) ipolynomial-term(q)
By
Latex:
(DVar `p'
THEN RecUnfold `add-ipoly` 0
THEN RepeatFor 2 ((CallByValueReduce 0 THENA Auto))
THEN Reduce 0)
Home
Index