Proof of Nuprl Lemma : hdf-union-eq-disju

Step * 2 of Lemma hdf-union-eq-disju

1. A : Type
2. B : Type
3. C : Type
4. X : hdataflow(A;B)
5. Y : hdataflow(A;C)
6. valueall-type(C)
7. valueall-type(B)
8. inputs : A List
9. hdf-halted(X + Y*(inputs)) = hdf-halted((λx.(inl x)) o X || (λx.(inr x )) o Y*(inputs))
10. a : A

⊢ hdf-out(X + Y*(inputs);a) = hdf-out((λx.(inl x)) o X || (λx.(inr x )) o Y*(inputs);a) ∈ bag(B + C)

{ (Thin (-2) THEN MoveToConcl (-1) THEN RepeatFor 2 (MoveToConcl (-4)) THEN ListInd (-1) THEN Reduce 0 THEN Auto) }

1
1. A : Type
2. B : Type
3. C : Type
4. valueall-type(C)
5. valueall-type(B)
6. X : hdataflow(A;B)@i
7. Y : hdataflow(A;C)@i
8. a : A@i
⊢ hdf-out(X + Y;a) = hdf-out((λx.(inl x)) o X || (λx.(inr x )) o Y;a) ∈ bag(B + C)

2
1. A : Type
2. B : Type
3. C : Type
4. valueall-type(C)
5. valueall-type(B)
6. u : A@i
7. v : A List@i
8. ∀X:hdataflow(A;B). ∀Y:hdataflow(A;C). ∀a:A.

     (hdf-out(X + Y*(v);a) = hdf-out((λx.(inl x)) o X || (λx.(inr x )) o Y*(v);a) ∈ bag(B + C))@i

9. X : hdataflow(A;B)@i
10. Y : hdataflow(A;C)@i
11. a : A@i

⊢ hdf-out(fst(X + Y(u))*(v);a) = hdf-out(fst((λx.(inl x)) o X || (λx.(inr x )) o Y(u))*(v);a) ∈ bag(B + C)

Latex:

Latex:
1. A : Type 2. B : Type 3. C : Type 4. X : hdataflow(A;B) 5. Y : hdataflow(A;C) 6. valueall-type(C) 7. valueall-type(B) 8. inputs : A List 9. hdf-halted(X + Y*(inputs)) = hdf-halted((\mlambda{}x.(inl x)) o X || (\mlambda{}x.(inr x )) o Y*(inputs)) 10. a : A \mvdash{} hdf-out(X + Y*(inputs);a) = hdf-out((\mlambda{}x.(inl x)) o X || (\mlambda{}x.(inr x )) o Y*(inputs);a) By Latex: (Thin (-2) THEN MoveToConcl (-1) THEN RepeatFor 2 (MoveToConcl (-4)) THEN ListInd (-1) THEN Reduce 0 THEN Auto) Home Index