Proof of Nuprl Lemma : hdf-union-ap

Step * 4 1 1 of Lemma hdf-union-ap

.....subterm..... T:t
1:n
1. A : Type
2. B : Type
3. C : Type
4. a : A
5. valueall-type(C)
6. valueall-type(B)
7. x : A ─→ (hdataflow(A;B) × bag(B))@i
8. z1 : hdataflow(A;B)@i
9. z2 : bag(B)@i
10. (x a) = <z1, z2> ∈ (hdataflow(A;B) × bag(B))@i
11. x1 : A ─→ (hdataflow(A;C) × bag(C))@i
12. z3 : hdataflow(A;C)@i
13. ¬((↑hdf-halted(z1)) ∧ (↑hdf-halted(z3)))
14. z4 : bag(C)@i
15. (x1 a) = <z3, z4> ∈ (hdataflow(A;C) × bag(C))@i
16. b : bag(B + C)@i
17. (bag-map(λx.(inl x);z2) + bag-map(λx.(inr x );z4)) = b ∈ bag(B + C)@i
18. ff ∈ 𝔹
19. a1 : A@i
20. v1 : hdataflow(A;B)@i
21. v2 : bag(B)@i
22. z1(a1) = <v1, v2> ∈ (hdataflow(A;B) × bag(B))@i
23. v3 : hdataflow(A;C)@i
24. v4 : bag(C)@i
25. z3(a1) = <v3, v4> ∈ (hdataflow(A;C) × bag(C))@i
26. v : bag(B + C)@i
27. (bag-map(λx.(inl x);v2) + bag-map(λx.(inr x );v4)) = v ∈ bag(B + C)@i
⊢ mk-hdf(XY,a.let X,Y = XY
              in let X',xs = X(a)
                 in let Y',ys = Y(a)
                    in let out ←─ bag-map(λx.(inl x);xs) + bag-map(λx.(inr x );ys)
                       in <<X', Y'>, out>;XY.let X,Y = XY

                                          in hdf-halted(X) ∧_b hdf-halted(Y);<v1, v3>) ∈ hdataflow(A;B + C)

BY
{ (Using [`S',⌈hdataflow(A;B) × hdataflow(A;C)⌉] (BLemma `mk-hdf_wf`)⋅
   THEN Try (QuickAuto)
   THEN (MemCD THEN Try (QuickAuto))
   THEN D -1
   THEN Reduce 0
   THEN MemCD
   THEN Try ((RepeatFor 2 ((GenConclAtAddr [2;1] THEN D -2 THEN Reduce 0))
              THEN (GenConclAtAddrType ⌈bag(B + C)⌉ [2;1]⋅ THENA Auto)
              THEN Auto))
   THEN Auto) }

Latex:

.....subterm..... T:t 1:n 1. A : Type 2. B : Type 3. C : Type 4. a : A 5. valueall-type(C) 6. valueall-type(B) 7. x : A {}\mrightarrow{} (hdataflow(A;B) \mtimes{} bag(B))@i 8. z1 : hdataflow(A;B)@i 9. z2 : bag(B)@i 10. (x a) = <z1, z2>@i 11. x1 : A {}\mrightarrow{} (hdataflow(A;C) \mtimes{} bag(C))@i 12. z3 : hdataflow(A;C)@i 13. \mneg{}((\muparrow{}hdf-halted(z1)) \mwedge{} (\muparrow{}hdf-halted(z3))) 14. z4 : bag(C)@i 15. (x1 a) = <z3, z4>@i 16. b : bag(B + C)@i 17. (bag-map(\mlambda{}x.(inl x);z2) + bag-map(\mlambda{}x.(inr x );z4)) = b@i 18. ff \mmember{} \mBbbB{} 19. a1 : A@i 20. v1 : hdataflow(A;B)@i 21. v2 : bag(B)@i 22. z1(a1) = <v1, v2>@i 23. v3 : hdataflow(A;C)@i 24. v4 : bag(C)@i 25. z3(a1) = <v3, v4>@i 26. v : bag(B + C)@i 27. (bag-map(\mlambda{}x.(inl x);v2) + bag-map(\mlambda{}x.(inr x );v4)) = v@i \mvdash{} mk-hdf(XY,a.let X,Y = XY in let X',xs = X(a) in let Y',ys = Y(a) in let out \mleftarrow{}{} bag-map(\mlambda{}x.(inl x);xs) + bag-map(\mlambda{}x.(inr x );ys) in <<X', Y'>, out>XY.let X,Y = XY in hdf-halted(X) \mwedge{}\msubb{} hdf-halted(Y);<v1, v3>) \mmember{} hdataflow(A;\000CB + C) By (Using [`S',\mkleeneopen{}hdataflow(A;B) \mtimes{} hdataflow(A;C)\mkleeneclose{}] (BLemma `mk-hdf\_wf`)\mcdot{} THEN Try (QuickAuto) THEN (MemCD THEN Try (QuickAuto)) THEN D -1 THEN Reduce 0 THEN MemCD THEN Try ((RepeatFor 2 ((GenConclAtAddr [2;1] THEN D -2 THEN Reduce 0)) THEN (GenConclAtAddrType \mkleeneopen{}bag(B + C)\mkleeneclose{} [2;1]\mcdot{} THENA Auto) THEN Auto)) THEN Auto) Home Index