Proof of Nuprl Lemma : fpf-normalize-dom

Step * of Lemma fpf-normalize-dom

∀[A:Type]. ∀[eq:EqDecider(A)]. ∀[B:A ⟶ Type]. ∀[g:x:A fp-> B[x]]. ∀[x:A].  (x ∈ dom(fpf-normalize(eq;g)) ~ x ∈ dom(g))

BY
{ ((((UnivCD THENA Auto)
     THEN DVar `g'
     THEN RepUR ``fpf-normalize fpf-dom fpf-single fpf-join fpf-empty`` 0
     THEN GenConcl ⌜g1 = G ∈ Top⌝⋅)
    THENA Auto
    )
   THEN (Thin (-1))
   ) }

1
1. A : Type
2. eq : EqDecider(A)
3. B : A ⟶ Type
4. d : A List
5. g1 : x:{x:A| (x ∈ d)}  ⟶ B[x]
6. x : A
7. G : Top@i

⊢ x ∈_b fst(reduce(λx,f. <[x / filter(λa.(¬_b((eq x a) ∨_bff));fst(f))], λa.<[x], λx@0.(G x)>(a)?f(a)>;<[], λx.⋅>;d)) ~ x ∈\000C_b d

Latex:

Latex:
\mforall{}[A:Type]. \mforall{}[eq:EqDecider(A)]. \mforall{}[B:A {}\mrightarrow{} Type]. \mforall{}[g:x:A fp-> B[x]]. \mforall{}[x:A]. (x \mmember{} dom(fpf-normalize(eq;g)) \msim{} x \mmember{} dom(g)) By Latex: ((((UnivCD THENA Auto) THEN DVar `g' THEN RepUR ``fpf-normalize fpf-dom fpf-single fpf-join fpf-empty`` 0 THEN GenConcl \mkleeneopen{}g1 = G\mkleeneclose{}\mcdot{}) THENA Auto ) THEN (Thin (-1)) ) Home Index