Proof of Nuprl Lemma : combine-list-as-reduce

Step * 1 1 1 1 1 of Lemma combine-list-as-reduce

.....equality.....
1. A : Type
2. f : A ⟶ A ⟶ A
3. Assoc(A;λx,y. f[x;y])
4. Comm(A;λx,y. f[x;y])
5. L : A List
6. ∀L:A List. (0 < ||L|| ⇒ (isl(reduce(λx,y. case y of inl(z) => inl f[x;z] | inr(z) => inl x;inr ⋅ ;L)) ~ tt))
7. n : A@i
8. outl(reduce(λx,y. case y of inl(z) => inl f[x;z] | inr(z) => inl x;inr ⋅ ;L @ [n])) ∈ A
⊢ reduce(λx,y. case y of inl(z) => inl f[x;z] | inr(z) => inl x;inr ⋅ ;L @ [n])
= (inl combine-list(x,y.f[x;y];[n / L]))
∈ {z:A?| ↑isl(z)}
BY
{ (Thin (-1) THEN Thin (-2)) }

1
1. A : Type
2. f : A ⟶ A ⟶ A
3. Assoc(A;λx,y. f[x;y])
4. Comm(A;λx,y. f[x;y])
5. L : A List
6. n : A@i
⊢ reduce(λx,y. case y of inl(z) => inl f[x;z] | inr(z) => inl x;inr ⋅ ;L @ [n])
= (inl combine-list(x,y.f[x;y];[n / L]))
∈ {z:A?| ↑isl(z)}

Latex:

Latex:
.....equality..... 1. A : Type 2. f : A {}\mrightarrow{} A {}\mrightarrow{} A 3. Assoc(A;\mlambda{}x,y. f[x;y]) 4. Comm(A;\mlambda{}x,y. f[x;y]) 5. L : A List 6. \mforall{}L:A List (0 < ||L|| {}\mRightarrow{} (isl(reduce(\mlambda{}x,y. case y of inl(z) => inl f[x;z] | inr(z) => inl x;inr \mcdot{} ;L)) \msim{} t\000Ct)) 7. n : A@i 8. outl(reduce(\mlambda{}x,y. case y of inl(z) => inl f[x;z] | inr(z) => inl x;inr \mcdot{} ;L @ [n])) \mmember{} A \mvdash{} reduce(\mlambda{}x,y. case y of inl(z) => inl f[x;z] | inr(z) => inl x;inr \mcdot{} ;L @ [n]) = (inl combine-list(x,y.f[x;y];[n / L])) By Latex: (Thin (-1) THEN Thin (-2)) Home Index