Step
*
1
1
1
1
2
2
of Lemma
sq-decider-list-deq
1. eq : Base
2. sq-decider(eq)
3. j : ℤ
4. 0 < j
5. ∀x,y:Base.
((λlist_ind,L. eval v = L in
if v is a pair then let a,as' = v
in λL.(fix((λlist_ind@0,L. eval v = L in
if v is a pair then let b,bs' = v
in (eq a b) ∧b (list_ind as' bs')
otherwise if v = Ax then ff otherwise ⊥))
L) otherwise if v = Ax then λL.null(L) otherwise ⊥^j - 1
⊥
x
y)↓
⇒ (∀z:Base. ((list-deq(eq) x y ~ inl z) ⇒ (Ax ∈ x ~ y))))
6. x : Base
7. y : Base
8. (⊥ y)↓
9. z : Base
10. list-deq(eq) x y ~ inl z
11. (x)↓
12. ∀a,b:Top. (if x is a pair then a otherwise b ~ b)
13. ∀a,b:Top. (if x = Ax then a otherwise b ~ b)
⊢ x ~ y
BY
{ (MoveToConcl 8 THEN (Strictness THEN Auto) THEN BotDiv) }
Latex:
Latex:
1. eq : Base
2. sq-decider(eq)
3. j : \mBbbZ{}
4. 0 < j
5. \mforall{}x,y:Base.
((\mlambda{}list$_{ind}$,L. eval v = L in
if v is a pair then let a,as' = v
in \mlambda{}L.(fix((\mlambda{}list$_{ind@0}$,L. eval v = L\000C in
if v is a pair then let b,bs' = v
in (eq a b)
\mwedge{}\msubb{} (list\mbackslash{}ff2\000C4_{ind}$
as'
bs')
otherwise if v = Ax then ff
otherwise \mbot{}))
L) otherwise if v = Ax then \mlambda{}L.null(L) otherwise \mbot{}\^{}j -\000C 1
\mbot{}
x
y)\mdownarrow{}
{}\mRightarrow{} (\mforall{}z:Base. ((list-deq(eq) x y \msim{} inl z) {}\mRightarrow{} (Ax \mmember{} x \msim{} y))))
6. x : Base
7. y : Base
8. (\mbot{} y)\mdownarrow{}
9. z : Base
10. list-deq(eq) x y \msim{} inl z
11. (x)\mdownarrow{}
12. \mforall{}a,b:Top. (if x is a pair then a otherwise b \msim{} b)
13. \mforall{}a,b:Top. (if x = Ax then a otherwise b \msim{} b)
\mvdash{} x \msim{} y
By
Latex:
(MoveToConcl 8 THEN (Strictness THEN Auto) THEN BotDiv)
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