Proof of Nuprl Lemma : hdf-compose2-ap

Step * of Lemma hdf-compose2-ap

∀[A,B,C:Type]. ∀[X:hdataflow(A;B ⟶ bag(C))]. ∀[Y:hdataflow(A;B)].

  ∀[a:A]. (X o Y(a) = <(fst(X(a))) o (fst(Y(a))), ⋃f∈snd(X(a)).⋃b∈snd(Y(a)).f b> ∈ (hdataflow(A;C) × bag(C)))

  supposing valueall-type(C)
BY
{ (Auto
   THEN RepUR ``hdf-compose2 hdf-ap`` 0
   THEN RW (AddrC [2] (RecUnfoldC `mk-hdf`)) 0
   THEN Reduce 0
   THEN Fold `hdf-ap` 0
   THEN Repeat (AutoSplit)
   THEN HDataflowHDAll
   THEN Try ((CallByValueReduceAtAddr [2;1] 0 THENA Auto))
   THEN Reduce 0
   THEN Try (Complete ((RecUnfold `mk-hdf` 0 THEN Reduce 0 THEN Auto)))
   THEN Fold `hdf-compose2` 0
   THEN Auto
   THEN EqCD
   THEN Auto) }

Latex:

Latex:
\mforall{}[A,B,C:Type]. \mforall{}[X:hdataflow(A;B {}\mrightarrow{} bag(C))]. \mforall{}[Y:hdataflow(A;B)]. \mforall{}[a:A]. (X o Y(a) = <(fst(X(a))) o (fst(Y(a))), \mcup{}f\mmember{}snd(X(a)).\mcup{}b\mmember{}snd(Y(a)).f b>) supposing valueall-type(C) By Latex: (Auto THEN RepUR ``hdf-compose2 hdf-ap`` 0 THEN RW (AddrC [2] (RecUnfoldC `mk-hdf`)) 0 THEN Reduce 0 THEN Fold `hdf-ap` 0 THEN Repeat (AutoSplit) THEN HDataflowHDAll THEN Try ((CallByValueReduceAtAddr [2;1] 0 THENA Auto)) THEN Reduce 0 THEN Try (Complete ((RecUnfold `mk-hdf` 0 THEN Reduce 0 THEN Auto))) THEN Fold `hdf-compose2` 0 THEN Auto THEN EqCD THEN Auto) Home Index