Proof of Nuprl Lemma : do-apply-p-first

Step * 2 2 2 1 2 1 1 of Lemma do-apply-p-first

1. A : Type
2. B : Type
3. u : A ⟶ (B + Top)
4. v : (A ⟶ (B + Top)) List

5. ∀[x:A]. do-apply(p-first(v);x) = do-apply(hd(filter(λf.can-apply(f;x);v));x) ∈ B supposing ↑can-apply(p-first(v);x)

6. x : A
7. ↑can-apply(p-first(v);x)
8. ¬↑can-apply(p-first([u]);x)
9. ¬↑can-apply(u;x)
10. do-apply(p-first(v);x) = do-apply(hd(filter(λf.can-apply(f;x);v));x) ∈ B
⊢ ↑can-apply(p-first([u / v]);x)
BY
{ xxxSubst' [u / v] ~ [u] @ v 0xxx }

1
.....equality.....
1. A : Type
2. B : Type
3. u : A ⟶ (B + Top)
4. v : (A ⟶ (B + Top)) List

5. ∀[x:A]. do-apply(p-first(v);x) = do-apply(hd(filter(λf.can-apply(f;x);v));x) ∈ B supposing ↑can-apply(p-first(v);x)

6. x : A
7. ↑can-apply(p-first(v);x)
8. ¬↑can-apply(p-first([u]);x)
9. ¬↑can-apply(u;x)
10. do-apply(p-first(v);x) = do-apply(hd(filter(λf.can-apply(f;x);v));x) ∈ B
⊢ [u / v] ~ [u] @ v

2
1. A : Type
2. B : Type
3. u : A ⟶ (B + Top)
4. v : (A ⟶ (B + Top)) List

5. ∀[x:A]. do-apply(p-first(v);x) = do-apply(hd(filter(λf.can-apply(f;x);v));x) ∈ B supposing ↑can-apply(p-first(v);x)

Latex:

Latex:
1. A : Type 2. B : Type 3. u : A {}\mrightarrow{} (B + Top) 4. v : (A {}\mrightarrow{} (B + Top)) List 5. \mforall{}[x:A] do-apply(p-first(v);x) = do-apply(hd(filter(\mlambda{}f.can-apply(f;x);v));x) supposing \muparrow{}can-apply(p-first(v);x) 6. x : A 7. \muparrow{}can-apply(p-first(v);x) 8. \mneg{}\muparrow{}can-apply(p-first([u]);x) 9. \mneg{}\muparrow{}can-apply(u;x) 10. do-apply(p-first(v);x) = do-apply(hd(filter(\mlambda{}f.can-apply(f;x);v));x) \mvdash{} \muparrow{}can-apply(p-first([u / v]);x) By Latex: xxxSubst' [u / v] \msim{} [u] @ v 0xxx Home Index