Proof of Nuprl Lemma : es-interface-accum-programmable

Step * 2 2 1 2 4 1 2 1 of Lemma es-interface-accum-programmable

1. Info : Type
2. A : Type
3. B : Type
4. X : EClass(A)
5. x : B
6. f : B ─→ A ─→ B
7. Y : EClass(B)@i'
8. ∀es:EO+(Info). ∀e:E.

     ((Y es e) = if e ∈_b X then if e ∈_b Prior(Y) then {f[Prior(Y)(e);X(e)]} else {f[x;X(e)]} fi  else {} fi  ∈ bag(B))

9. Singlevalued(Y)
10. ∀es:EO+(Info). ∀e:E.  (↑e ∈_b X ⇐⇒ ↑e ∈_b Y)
11. es : EO+(Info)@i'
12. e : E@i
13. ∀e1:E
      ((e1 < e)
      ⇒ (↑e1 ∈_b X)
      ⇒

 (accumulate (with value b and list item e): f b X(e)over list:  ≤(X)(e1)with starting value: x) = Y(e1) ∈ B))

14. ↑e ∈_b X@i
⊢ accumulate (with value b and list item e):
   f b X(e)
  over list:
    if e ∈_b prior(X) then ≤(X)(prior(X)(e)) @ [e] else [e] fi
  with starting value:
   x)
= if e ∈_b Prior(Y) then f[Prior(Y)(e);X(e)] else f[x;X(e)] fi
∈ B
BY
{ (InstHyp [⌈es⌉] 10⋅ THEN Auto) }

1
1. Info : Type
2. A : Type
3. B : Type
4. X : EClass(A)
5. x : B
6. f : B ─→ A ─→ B
7. Y : EClass(B)@i'
8. ∀es:EO+(Info). ∀e:E.

     ((Y es e) = if e ∈_b X then if e ∈_b Prior(Y) then {f[Prior(Y)(e);X(e)]} else {f[x;X(e)]} fi  else {} fi  ∈ bag(B))

9. Singlevalued(Y)
10. ∀es:EO+(Info). ∀e:E.  (↑e ∈_b X ⇐⇒ ↑e ∈_b Y)
11. es : EO+(Info)@i'
12. e : E@i
13. ∀e1:E
      ((e1 < e)
      ⇒ (↑e1 ∈_b X)
      ⇒

 (accumulate (with value b and list item e): f b X(e)over list:  ≤(X)(e1)with starting value: x) = Y(e1) ∈ B))

14. ↑e ∈_b X@i
15. ∀e:E. (↑e ∈_b X ⇐⇒ ↑e ∈_b Y)
⊢ accumulate (with value b and list item e):
   f b X(e)
  over list:
    if e ∈_b prior(X) then ≤(X)(prior(X)(e)) @ [e] else [e] fi
  with starting value:
   x)
= if e ∈_b Prior(Y) then f[Prior(Y)(e);X(e)] else f[x;X(e)] fi
∈ B

Latex:

Latex:
1. Info : Type 2. A : Type 3. B : Type 4. X : EClass(A) 5. x : B 6. f : B {}\mrightarrow{} A {}\mrightarrow{} B 7. Y : EClass(B)@i' 8. \mforall{}es:EO+(Info). \mforall{}e:E. ((Y es e) = if e \mmember{}\msubb{} X then if e \mmember{}\msubb{} Prior(Y) then \{f[Prior(Y)(e);X(e)]\} else \{f[x;X(e)]\} fi else \{\} fi ) 9. Singlevalued(Y) 10. \mforall{}es:EO+(Info). \mforall{}e:E. (\muparrow{}e \mmember{}\msubb{} X \mLeftarrow{}{}\mRightarrow{} \muparrow{}e \mmember{}\msubb{} Y) 11. es : EO+(Info)@i' 12. e : E@i 13. \mforall{}e1:E ((e1 < e) {}\mRightarrow{} (\muparrow{}e1 \mmember{}\msubb{} X) {}\mRightarrow{} (accumulate (with value b and list item e): f b X(e) over list: \mleq{}(X)(e1) with starting value: x) = Y(e1))) 14. \muparrow{}e \mmember{}\msubb{} X@i \mvdash{} accumulate (with value b and list item e): f b X(e) over list: if e \mmember{}\msubb{} prior(X) then \mleq{}(X)(prior(X)(e)) @ [e] else [e] fi with starting value: x) = if e \mmember{}\msubb{} Prior(Y) then f[Prior(Y)(e);X(e)] else f[x;X(e)] fi By Latex: (InstHyp [\mkleeneopen{}es\mkleeneclose{}] 10\mcdot{} THEN Auto) Home Index