Proof of Nuprl Lemma : prime-factors-unique

Step * 1 1 2 1 2 2 1 1 of Lemma prime-factors-unique

.....assertion.....
1. u : {m:ℕ| prime(m)}
2. v : {m:ℕ| prime(m)}  List
3. ∀qs:{m:ℕ| prime(m)}  List. ((reduce(λx,y. (x * y);1;v) = reduce(λx,y. (x * y);1;qs) ∈ ℤ) ⇒ permutation(ℤ;v;qs))
4. qs : {m:ℕ| prime(m)}  List
5. (u * reduce(λx,y. (x * y);1;v)) = reduce(λx,y. (x * y);1;qs) ∈ ℤ
6. (u ∈ qs)
7. qs' : {m:ℕ| prime(m)}  List
8. permutation(ℤ;[u / qs'];qs)
⊢ reduce(λx,y. (x * y);1;[u / qs']) = reduce(λx,y. (x * y);1;qs) ∈ ℤ
BY
{ (BLemma `reduce-permutation` THEN Auto THEN RepUR ``comm assoc so_apply`` 0 THEN Auto) }

Latex:

Latex:
.....assertion..... 1. u : \{m:\mBbbN{}| prime(m)\} 2. v : \{m:\mBbbN{}| prime(m)\} List 3. \mforall{}qs:\{m:\mBbbN{}| prime(m)\} List ((reduce(\mlambda{}x,y. (x * y);1;v) = reduce(\mlambda{}x,y. (x * y);1;qs)) {}\mRightarrow{} permutation(\mBbbZ{};v;qs)) 4. qs : \{m:\mBbbN{}| prime(m)\} List 5. (u * reduce(\mlambda{}x,y. (x * y);1;v)) = reduce(\mlambda{}x,y. (x * y);1;qs) 6. (u \mmember{} qs) 7. qs' : \{m:\mBbbN{}| prime(m)\} List 8. permutation(\mBbbZ{};[u / qs'];qs) \mvdash{} reduce(\mlambda{}x,y. (x * y);1;[u / qs']) = reduce(\mlambda{}x,y. (x * y);1;qs) By Latex: (BLemma `reduce-permutation` THEN Auto THEN RepUR ``comm assoc so\_apply`` 0 THEN Auto) Home Index