Proof of Nuprl Lemma : es-pplus_functionality_wrt_rev

Step * of Lemma es-pplus_functionality_wrt_rev_implies

∀es:EO. ∀e1:E. ∀e2:{e:E| loc(e) = loc(e1) ∈ Id} .
  ∀[p,p':{e:E| loc(e) = loc(e1) ∈ Id}  ⟶ {e:E| loc(e) = loc(e1) ∈ Id}  ⟶ ℙ].
    ((∀a,b:{e:E| loc(e) = loc(e1) ∈ Id} .  ((a ∈ [e1, e2]) ⇒ (b ∈ [e1, e2]) ⇒ {p[a;b] ⇐ p'[a;b]}))
    ⇒ {[e1,e2]~([a,b].p[a;b])+ ⇐ [e1,e2]~([a,b].p'[a;b])+})
BY
{ ((InstLemma `es-pstar-q_functionality_wrt_rev_implies` [])
   THEN Auto
   THEN Unfold `es-pplus` 0
   THEN (InstHyp [⌜es⌝; ⌜e1⌝; ⌜e2⌝; ⌜p'⌝; ⌜p'⌝; ⌜p⌝; ⌜p⌝] 1)⋅
   THEN Try (Trivial)
   THEN Unfold `guard` 0
   THEN Trivial) }

Latex:

Latex:
\mforall{}es:EO. \mforall{}e1:E. \mforall{}e2:\{e:E| loc(e) = loc(e1)\} . \mforall{}[p,p':\{e:E| loc(e) = loc(e1)\} {}\mrightarrow{} \{e:E| loc(e) = loc(e1)\} {}\mrightarrow{} \mBbbP{}]. ((\mforall{}a,b:\{e:E| loc(e) = loc(e1)\} . ((a \mmember{} [e1, e2]) {}\mRightarrow{} (b \mmember{} [e1, e2]) {}\mRightarrow{} \{p[a;b] \mLeftarrow{}{} p'[a;b]\})) {}\mRightarrow{} \{[e1,e2]\msim{}([a,b].p[a;b])+ \mLeftarrow{}{} [e1,e2]\msim{}([a,b].p'[a;b])+\}) By Latex: ((InstLemma `es-pstar-q\_functionality\_wrt\_rev\_implies` []) THEN Auto THEN Unfold `es-pplus` 0 THEN (InstHyp [\mkleeneopen{}es\mkleeneclose{}; \mkleeneopen{}e1\mkleeneclose{}; \mkleeneopen{}e2\mkleeneclose{}; \mkleeneopen{}p'\mkleeneclose{}; \mkleeneopen{}p'\mkleeneclose{}; \mkleeneopen{}p\mkleeneclose{}; \mkleeneopen{}p\mkleeneclose{}] 1)\mcdot{} THEN Try (Trivial) THEN Unfold `guard` 0 THEN Trivial) Home Index