Proof of Nuprl Lemma : loop-class-program

Step * 1 1 1 1 1 1 of Lemma loop-class-program_wf

1. Info : Type
2. B : Type
3. valueall-type(B)
4. X : EClass(B ─→ bag(B))
5. init : Id ─→ bag(B)
6. loop-class(X;init) ∈ EClass(B)
7. F : Id ─→ hdataflow(Info;B ─→ bag(B))

8. ∀es:EO+(Info). ∀e:E.  (X(e) = (snd(F loc(e)*(map(λx.info(x);before(e)))(info(e)))) ∈ bag(B ─→ bag(B)))

9. es : EO+(Info)@i'
10. e : E@i
11. ∀e1:E
      ((e1 < e)
      ⇒ (simple-hdf-buffer(F loc(e1);init loc(e1))*(map(λx.info(x);before(e1)))
         = simple-hdf-buffer(F loc(e1)*(map(λx.info(x);before(e1)));Prior(loop-class(X;init))?init(e1))
         ∈ hdataflow(Info;B)))
12. ¬↑first(e)
13. simple-hdf-buffer(F loc(e);init loc(e))*(map(λx.info(x);before(pred(e))))
= simple-hdf-buffer(F loc(e)*(map(λx.info(x);before(pred(e))));Prior(loop-class(X;init))?init(pred(e)))
∈ hdataflow(Info;B)
14. v : bag(B)@i
15. Prior(loop-class(X;init))?init(pred(e)) = v ∈ bag(B)@i
16. x : Info ─→ (hdataflow(Info;B ─→ bag(B)) × bag(B ─→ bag(B)))@i
⊢ (F loc(pred(e))*(map(λx.info(x);before(pred(e)))) = (inl x) ∈ hdataflow(Info;B ─→ bag(B)))
⇒ ((fst(let s1,b = let X',fs = x info(pred(e))
                    in let bs' ←─ ∪f∈fs.∪b∈v.f b
                       in <<X', if bag-null(bs') then v else bs' fi >, bs'>
         in <mk-hdf(Xbs,a.let X,bs = Xbs

                          in let X',fs = case X of inl(P) => P a | inr(z) => <inr ⋅ , {}>

in let bs' ←─ ∪f∈fs.∪b∈bs.f b

                                in <<X', if bag-null(bs') then bs else bs' fi >, bs'>;s.ff;s1)

            , b
            >))
   = simple-hdf-buffer(fst((x info(pred(e))));if 0 <z #(loop-class(X;init)(pred(e)))
     then loop-class(X;init)(pred(e))
     else v
     fi )
   ∈ hdataflow(Info;B))
BY
{ ((GenApply (-1) THENA Auto)
   THEN D -2
   THEN Reduce 0
   THEN Fold `hdf-ap` 0
   THEN (CallByValueReduceOn ⌈∪f∈z2.∪b∈v.f b⌉ 0⋅ THENA MaAuto)
   THEN Reduce 0
   THEN Fold `simple-hdf-buffer` 0
   THEN Auto
   THEN Try ((Fold `hdf-run` 0 THEN Auto))
   THEN EqCD
   THEN Auto)⋅ }

1
.....subterm..... T:t
2:n
1. Info : Type
2. B : Type
3. valueall-type(B)
4. X : EClass(B ─→ bag(B))
5. init : Id ─→ bag(B)
6. loop-class(X;init) ∈ EClass(B)
7. F : Id ─→ hdataflow(Info;B ─→ bag(B))

8. ∀es:EO+(Info). ∀e:E.  (X(e) = (snd(F loc(e)*(map(λx.info(x);before(e)))(info(e)))) ∈ bag(B ─→ bag(B)))

9. es : EO+(Info)@i'
10. e : E@i
11. ∀e1:E
      ((e1 < e)
      ⇒ (simple-hdf-buffer(F loc(e1);init loc(e1))*(map(λx.info(x);before(e1)))
         = simple-hdf-buffer(F loc(e1)*(map(λx.info(x);before(e1)));Prior(loop-class(X;init))?init(e1))
         ∈ hdataflow(Info;B)))
12. ¬↑first(e)
13. simple-hdf-buffer(F loc(e);init loc(e))*(map(λx.info(x);before(pred(e))))
= simple-hdf-buffer(F loc(e)*(map(λx.info(x);before(pred(e))));Prior(loop-class(X;init))?init(pred(e)))
∈ hdataflow(Info;B)
14. v : bag(B)@i
15. Prior(loop-class(X;init))?init(pred(e)) = v ∈ bag(B)@i
16. x : Info ─→ (hdataflow(Info;B ─→ bag(B)) × bag(B ─→ bag(B)))@i
17. z1 : hdataflow(Info;B ─→ bag(B))@i
18. z2 : bag(B ─→ bag(B))@i
19. (x info(pred(e))) = <z1, z2> ∈ (hdataflow(Info;B ─→ bag(B)) × bag(B ─→ bag(B)))@i
20. F loc(pred(e))*(map(λx.info(x);before(pred(e)))) = (inl x) ∈ hdataflow(Info;B ─→ bag(B))@i
⊢ if bag-null(∪f∈z2.∪b∈v.f b) then v else ∪f∈z2.∪b∈v.f b fi
= if 0 <z #(loop-class(X;init)(pred(e))) then loop-class(X;init)(pred(e)) else v fi
∈ bag(B)

Latex:

Latex:
1. Info : Type 2. B : Type 3. valueall-type(B) 4. X : EClass(B {}\mrightarrow{} bag(B)) 5. init : Id {}\mrightarrow{} bag(B) 6. loop-class(X;init) \mmember{} EClass(B) 7. F : Id {}\mrightarrow{} hdataflow(Info;B {}\mrightarrow{} bag(B)) 8. \mforall{}es:EO+(Info). \mforall{}e:E. (X(e) = (snd(F loc(e)*(map(\mlambda{}x.info(x);before(e)))(info(e))))) 9. es : EO+(Info)@i' 10. e : E@i 11. \mforall{}e1:E ((e1 < e) {}\mRightarrow{} (simple-hdf-buffer(F loc(e1);init loc(e1))*(map(\mlambda{}x.info(x);before(e1))) = simple-hdf-buffer(F loc(e1)*(map(\mlambda{}x.info(x); before(e1)));Prior(loop-class(X;init))?init(e1)))) 12. \mneg{}\muparrow{}first(e) 13. simple-hdf-buffer(F loc(e);init loc(e))*(map(\mlambda{}x.info(x);before(pred(e)))) = simple-hdf-buffer(F loc(e)*(map(\mlambda{}x.info(x); before(pred(e))));Prior(loop-class(X;init))?init(pred(e))) 14. v : bag(B)@i 15. Prior(loop-class(X;init))?init(pred(e)) = v@i 16. x : Info {}\mrightarrow{} (hdataflow(Info;B {}\mrightarrow{} bag(B)) \mtimes{} bag(B {}\mrightarrow{} bag(B)))@i \mvdash{} (F loc(pred(e))*(map(\mlambda{}x.info(x);before(pred(e)))) = (inl x)) {}\mRightarrow{} ((fst(let s1,b = let X',fs = x info(pred(e)) in let bs' \mleftarrow{}{} \mcup{}f\mmember{}fs.\mcup{}b\mmember{}v.f b in <<X', if bag-null(bs') then v else bs' fi >, bs'> in <mk-hdf(Xbs,a.let X,bs = Xbs in let X',fs = case X of inl(P) => P a | inr(z) => <inr \mcdot{} , \{\}> in let bs' \mleftarrow{}{} \mcup{}f\mmember{}fs.\mcup{}b\mmember{}bs.f b in <<X', if bag-null(bs') then bs else bs' fi >, bs'>s.ff;s1) , b >)) = simple-hdf-buffer(fst((x info(pred(e))));if 0 <z \#(loop-class(X;init)(pred(e))) then loop-class(X;init)(pred(e)) else v fi )) By Latex: ((GenApply (-1) THENA Auto) THEN D -2 THEN Reduce 0 THEN Fold `hdf-ap` 0 THEN (CallByValueReduceOn \mkleeneopen{}\mcup{}f\mmember{}z2.\mcup{}b\mmember{}v.f b\mkleeneclose{} 0\mcdot{} THENA MaAuto) THEN Reduce 0 THEN Fold `simple-hdf-buffer` 0 THEN Auto THEN Try ((Fold `hdf-run` 0 THEN Auto)) THEN EqCD THEN Auto)\mcdot{} Home Index