Proof of Nuprl Lemma : apply-alist-cases

Step * of Lemma apply-alist-cases

∀[T:Type]. ∀[eq:EqDecider(T)]. ∀[x:T]. ∀[L:(T × Top) List].
(apply-alist(eq;L;x) ~ ff supposing ¬(x ∈ map(λp.(fst(p));L))
∧ (∀[i:ℕ||L||]

       (apply-alist(eq;L;x) ~ inl (snd(L[i]))) supposing (((fst(L[i])) = x ∈ T) and (∀j:ℕi. (¬((fst(L[j])) = x ∈ T))))))

BY
{ InductionOnList }

1
1. T : Type
2. eq : EqDecider(T)
3. x : T
⊢ apply-alist(eq;[];x) ~ ff supposing ¬(x ∈ map(λp.(fst(p));[]))
∧ (∀[i:ℕ||[]||]

     (apply-alist(eq;[];x) ~ inl (snd([][i]))) supposing (((fst([][i])) = x ∈ T) and (∀j:ℕi. (¬((fst([][j])) = x ∈ T))))\000C)

2
1. T : Type
2. eq : EqDecider(T)
3. x : T
4. u : T × Top
5. v : (T × Top) List
6. apply-alist(eq;v;x) ~ ff supposing ¬(x ∈ map(λp.(fst(p));v))
∧ (∀[i:ℕ||v||]

     (apply-alist(eq;v;x) ~ inl (snd(v[i]))) supposing (((fst(v[i])) = x ∈ T) and (∀j:ℕi. (¬((fst(v[j])) = x ∈ T)))))

⊢ apply-alist(eq;[u / v];x) ~ ff supposing ¬(x ∈ map(λp.(fst(p));[u / v]))
∧ (∀[i:ℕ||[u / v]||]
     (apply-alist(eq;[u / v];x) ~ inl (snd([u / v][i]))) supposing
        (((fst([u / v][i])) = x ∈ T) and
        (∀j:ℕi. (¬((fst([u / v][j])) = x ∈ T)))))

Latex:

Latex:
\mforall{}[T:Type]. \mforall{}[eq:EqDecider(T)]. \mforall{}[x:T]. \mforall{}[L:(T \mtimes{} Top) List]. (apply-alist(eq;L;x) \msim{} ff supposing \mneg{}(x \mmember{} map(\mlambda{}p.(fst(p));L)) \mwedge{} (\mforall{}[i:\mBbbN{}||L||] (apply-alist(eq;L;x) \msim{} inl (snd(L[i]))) supposing (((fst(L[i])) = x) and (\mforall{}j:\mBbbN{}i. (\mneg{}((fst(L[j])) = x)))))) By Latex: InductionOnList Home Index