Proof of Nuprl Lemma : primed-class-opt-classrel

Step * 2 of Lemma primed-class-opt-classrel

1. T : Type
2. Info : Type
3. X : EClass(T)
4. init : Id ─→ bag(T)
5. es : EO+(Info)
6. e : E
7. v : T
8. P : E ─→ 𝔹@i
9. (λe'.0 <z #(X es e')) = P ∈ (E ─→ 𝔹)@i
10. Q : E ─→ ℙ@i'
11. (λe'.(↓∃w:T. w ↓∈ X es e')) = Q ∈ (E ─→ ℙ)@i'
12. y : ¬(∃e':{E| ((e' <loc e) ∧ (↑(P e')))})@i
13. (last(P) e)
= (inr y )
∈ ((∃e':{E| ((e' <loc e) ∧ (↑(P e')) ∧ (∀e'':E. ((e' <loc e'') ⇒ (e'' <loc e) ⇒ (¬↑(P e'')))))})
∨ (¬(∃e':{E| ((e' <loc e) ∧ (↑(P e')))})))@i
14. (¬↑first(e))
∧ (((↑(P pred(e))) ∧ (⊥ = pred(e) ∈ E))

      ∨ ((¬↑(P pred(e))) ∧ (↑isl(last(P) pred(e))) ∧ (⊥ = outl(last(P) pred(e)) ∈ E)))

    supposing False@i
⊢ uiff(v ↓∈ init loc(e);↓(∃e':E. ((es-p-local-pred(es;Q) e e') ∧ v ↓∈ X es e'))
                         ∨ ((∀e':E. ((e' <loc e) ⇒ (∀w:T. (¬w ↓∈ X es e')))) ∧ v ↓∈ init loc(e)))
BY
{ (Thin (-1) THEN (Auto THEN Try ((Unhide⋅ THENA Auto)))⋅) }

1
1. T : Type
2. Info : Type
3. X : EClass(T)
4. init : Id ─→ bag(T)
5. es : EO+(Info)
6. e : E
7. v : T
8. P : E ─→ 𝔹@i
9. (λe'.0 <z #(X es e')) = P ∈ (E ─→ 𝔹)@i
10. Q : E ─→ ℙ@i'
11. (λe'.(↓∃w:T. w ↓∈ X es e')) = Q ∈ (E ─→ ℙ)@i'
12. y : ¬(∃e':{E| ((e' <loc e) ∧ (↑(P e')))})@i
13. (last(P) e)
= (inr y )
∈ ((∃e':{E| ((e' <loc e) ∧ (↑(P e')) ∧ (∀e'':E. ((e' <loc e'') ⇒ (e'' <loc e) ⇒ (¬↑(P e'')))))})
  ∨ (¬(∃e':{E| ((e' <loc e) ∧ (↑(P e')))})))@i
14. v ↓∈ init loc(e)
⊢ ↓(∃e':E. ((es-p-local-pred(es;Q) e e') ∧ v ↓∈ X es e'))
   ∨ ((∀e':E. ((e' <loc e) ⇒ (∀w:T. (¬w ↓∈ X es e')))) ∧ v ↓∈ init loc(e))

2
1. T : Type
2. Info : Type
3. X : EClass(T)
4. init : Id ─→ bag(T)
5. es : EO+(Info)
6. e : E
7. v : T
8. P : E ─→ 𝔹@i
9. (λe'.0 <z #(X es e')) = P ∈ (E ─→ 𝔹)@i
10. Q : E ─→ ℙ@i'
11. (λe'.(↓∃w:T. w ↓∈ X es e')) = Q ∈ (E ─→ ℙ)@i'
12. y : ¬(∃e':{E| ((e' <loc e) ∧ (↑(P e')))})@i
13. (last(P) e)
= (inr y )
∈ ((∃e':{E| ((e' <loc e) ∧ (↑(P e')) ∧ (∀e'':E. ((e' <loc e'') ⇒ (e'' <loc e) ⇒ (¬↑(P e'')))))})
  ∨ (¬(∃e':{E| ((e' <loc e) ∧ (↑(P e')))})))@i
14. ↓(∃e':E. ((es-p-local-pred(es;Q) e e') ∧ v ↓∈ X es e'))
     ∨ ((∀e':E. ((e' <loc e) ⇒ (∀w:T. (¬w ↓∈ X es e')))) ∧ v ↓∈ init loc(e))
⊢ v ↓∈ init loc(e)

Latex:

Latex:
1. T : Type 2. Info : Type 3. X : EClass(T) 4. init : Id {}\mrightarrow{} bag(T) 5. es : EO+(Info) 6. e : E 7. v : T 8. P : E {}\mrightarrow{} \mBbbB{}@i 9. (\mlambda{}e'.0 <z \#(X es e')) = P@i 10. Q : E {}\mrightarrow{} \mBbbP{}@i' 11. (\mlambda{}e'.(\mdownarrow{}\mexists{}w:T. w \mdownarrow{}\mmember{} X es e')) = Q@i' 12. y : \mneg{}(\mexists{}e':\{E| ((e' <loc e) \mwedge{} (\muparrow{}(P e')))\})@i 13. (last(P) e) = (inr y )@i 14. (\mneg{}\muparrow{}first(e)) \mwedge{} (((\muparrow{}(P pred(e))) \mwedge{} (\mbot{} = pred(e))) \mvee{} ((\mneg{}\muparrow{}(P pred(e))) \mwedge{} (\muparrow{}isl(last(P) pred(e))) \mwedge{} (\mbot{} = outl(last(P) pred(e))))) supposing False@i \mvdash{} uiff(v \mdownarrow{}\mmember{} init loc(e);\mdownarrow{}(\mexists{}e':E. ((es-p-local-pred(es;Q) e e') \mwedge{} v \mdownarrow{}\mmember{} X es e')) \mvee{} ((\mforall{}e':E. ((e' <loc e) {}\mRightarrow{} (\mforall{}w:T. (\mneg{}w \mdownarrow{}\mmember{} X es e')))) \mwedge{} v \mdownarrow{}\mmember{} init loc(e))) By Latex: (Thin (-1) THEN (Auto THEN Try ((Unhide\mcdot{} THENA Auto)))\mcdot{}) Home Index