Proof of Nuprl Lemma : satisfies-gcd-reduce-ineq-constraints

Step * 1 2 1 2 2 2 of Lemma satisfies-gcd-reduce-ineq-constraints

1. n : ℕ⁺
2. v : ℤ List
3. ||[1 / v]|| = n ∈ ℤ
4. u : ℤ
5. v2 : ℤ List
6. ||[u / v2]|| = n ∈ ℤ
7. v1 : {L:ℤ List| ||L|| = n ∈ ℤ}  List
8. ∀sat:{L:ℤ List| ||L|| = n ∈ ℤ}  List
     ((∀as∈sat.[1 / v] ⋅ as ≥0)
     ⇒ (∀as∈v1.[1 / v] ⋅ as ≥0)
     ⇒

 ((↑isl(gcd-reduce-ineq-constraints(sat;v1))) ∧ (∀as∈outl(gcd-reduce-ineq-constraints(sat;v1)).[1 / v] ⋅ as ≥0)))

9. sat : {L:ℤ List| ||L|| = n ∈ ℤ}  List
10. (∀as∈sat.[1 / v] ⋅ as ≥0)
11. (∀as∈[[u / v2] / v1].[1 / v] ⋅ as ≥0)
12. ¬↑null(v2)
⊢ (↑isl(let s' ⟵ eval g = |gcd-list(v2)| in
                  if (1) < (g)
                     then eval h' = u ÷↓ g in
                          eval t' = eager-map(λx.(x ÷ g);v2) in
                            inl [[h' / t'] / sat]
                     else (inl [[u / v2] / sat])
        in accumulate_abort(L,Ls.let h,t = L

                                 in if t = Ax then if (h) < (0)  then inr ⋅   else (inl [L / Ls])

otherwise eval g = |gcd-list(t)| in
if (1) < (g)

                                                 then eval h' = h ÷↓ g in

                                                      eval t' = eager-map(λx.(x ÷ g);t) in

                                                        inl [[h' / t'] / Ls]

                                                 else (inl [L / Ls]);s';v1)))

∧ (∀as∈outl(let s' ⟵ eval g = |gcd-list(v2)| in
                      if (1) < (g)
                         then eval h' = u ÷↓ g in
                              eval t' = eager-map(λx.(x ÷ g);v2) in
                                inl [[h' / t'] / sat]
                         else (inl [[u / v2] / sat])
            in accumulate_abort(L,Ls.let h,t = L

                                     in if t = Ax then if (h) < (0)  then inr ⋅   else (inl [L / Ls])

otherwise eval g = |gcd-list(t)| in
if (1) < (g)

                                                     then eval h' = h ÷↓ g in

                                                          eval t' = eager-map(λx.(x ÷ g);t) in

                                                            inl [[h' / t'] / Ls]

                                                     else (inl [L / Ls]);s';v1)).[1 / v] ⋅ as ≥0)

BY
{ ((GenConcl ⌜|gcd-list(v2)| = gg ∈ ℤ⌝⋅ THENA Auto)
   THEN (CallByValueReduceOn ⌜gg⌝ 0⋅ THENA Auto)
   THEN (Decide 1 < gg THENA Auto)
   THEN (Reduce 0 THENA Auto)
   THEN (((CallByValueReduce 0 THENA Auto) THEN Fold `gcd-reduce-ineq-constraints` 0)
   ORELSE ((CallByValueReduceOn ⌜u ÷↓ gg⌝ 0⋅ THENA Auto)
           THEN (CallByValueReduceOn ⌜eager-map(λx.(x ÷ gg);v2)⌝ 0⋅ THENA Auto)
           THEN (CallByValueReduce 0 THENA Auto)
           THEN Fold `gcd-reduce-ineq-constraints` 0
           THEN (RWO "eager-map-is-map" 0 THENA Auto))
   )) }

1
1. n : ℕ⁺
2. v : ℤ List
3. ||[1 / v]|| = n ∈ ℤ
4. u : ℤ
5. v2 : ℤ List
6. ||[u / v2]|| = n ∈ ℤ
7. v1 : {L:ℤ List| ||L|| = n ∈ ℤ}  List
8. ∀sat:{L:ℤ List| ||L|| = n ∈ ℤ}  List
     ((∀as∈sat.[1 / v] ⋅ as ≥0)
     ⇒ (∀as∈v1.[1 / v] ⋅ as ≥0)
     ⇒

 ((↑isl(gcd-reduce-ineq-constraints(sat;v1))) ∧ (∀as∈outl(gcd-reduce-ineq-constraints(sat;v1)).[1 / v] ⋅ as ≥0)))

9. sat : {L:ℤ List| ||L|| = n ∈ ℤ}  List
10. (∀as∈sat.[1 / v] ⋅ as ≥0)
11. (∀as∈[[u / v2] / v1].[1 / v] ⋅ as ≥0)
12. ¬↑null(v2)
13. gg : ℤ
14. |gcd-list(v2)| = gg ∈ ℤ
15. 1 < gg
⊢ value-type(ℤ)

2
1. n : ℕ⁺
2. v : ℤ List
3. ||[1 / v]|| = n ∈ ℤ
4. u : ℤ
5. v2 : ℤ List
6. ||[u / v2]|| = n ∈ ℤ
7. v1 : {L:ℤ List| ||L|| = n ∈ ℤ}  List
8. ∀sat:{L:ℤ List| ||L|| = n ∈ ℤ}  List
     ((∀as∈sat.[1 / v] ⋅ as ≥0)
     ⇒ (∀as∈v1.[1 / v] ⋅ as ≥0)
     ⇒

 ((↑isl(gcd-reduce-ineq-constraints(sat;v1))) ∧ (∀as∈outl(gcd-reduce-ineq-constraints(sat;v1)).[1 / v] ⋅ as ≥0)))

9. sat : {L:ℤ List| ||L|| = n ∈ ℤ} List
10. (∀as∈sat.[1 / v] ⋅ as ≥0)
11. (∀as∈[[u / v2] / v1].[1 / v] ⋅ as ≥0)
12. ¬↑null(v2)
13. gg : ℤ
14. |gcd-list(v2)| = gg ∈ ℤ
15. 1 < gg
⊢ (↑isl(gcd-reduce-ineq-constraints([[u ÷↓ gg / map(λx.(x ÷ gg);v2)] / sat];v1)))

∧ (∀as∈outl(gcd-reduce-ineq-constraints([[u ÷↓ gg / map(λx.(x ÷ gg);v2)] / sat];v1)).[1 / v] ⋅ as ≥0)

3
1. n : ℕ⁺
2. v : ℤ List
3. ||[1 / v]|| = n ∈ ℤ
4. u : ℤ
5. v2 : ℤ List
6. ||[u / v2]|| = n ∈ ℤ
7. v1 : {L:ℤ List| ||L|| = n ∈ ℤ}  List
8. ∀sat:{L:ℤ List| ||L|| = n ∈ ℤ}  List
     ((∀as∈sat.[1 / v] ⋅ as ≥0)
     ⇒ (∀as∈v1.[1 / v] ⋅ as ≥0)
     ⇒

 ((↑isl(gcd-reduce-ineq-constraints(sat;v1))) ∧ (∀as∈outl(gcd-reduce-ineq-constraints(sat;v1)).[1 / v] ⋅ as ≥0)))

9. sat : {L:ℤ List| ||L|| = n ∈ ℤ} List
10. (∀as∈sat.[1 / v] ⋅ as ≥0)
11. (∀as∈[[u / v2] / v1].[1 / v] ⋅ as ≥0)
12. ¬↑null(v2)
13. gg : ℤ
14. |gcd-list(v2)| = gg ∈ ℤ
15. ¬1 < gg
⊢ (↑isl(gcd-reduce-ineq-constraints([[u / v2] / sat];v1)))
∧ (∀as∈outl(gcd-reduce-ineq-constraints([[u / v2] / sat];v1)).[1 / v] ⋅ as ≥0)

Latex:

Latex:
1. n : \mBbbN{}\msupplus{} 2. v : \mBbbZ{} List 3. ||[1 / v]|| = n 4. u : \mBbbZ{} 5. v2 : \mBbbZ{} List 6. ||[u / v2]|| = n 7. v1 : \{L:\mBbbZ{} List| ||L|| = n\} List 8. \mforall{}sat:\{L:\mBbbZ{} List| ||L|| = n\} List ((\mforall{}as\mmember{}sat.[1 / v] \mcdot{} as \mgeq{}0) {}\mRightarrow{} (\mforall{}as\mmember{}v1.[1 / v] \mcdot{} as \mgeq{}0) {}\mRightarrow{} ((\muparrow{}isl(gcd-reduce-ineq-constraints(sat;v1))) \mwedge{} (\mforall{}as\mmember{}outl(gcd-reduce-ineq-constraints(sat;v1)).[1 / v] \mcdot{} as \mgeq{}0))) 9. sat : \{L:\mBbbZ{} List| ||L|| = n\} List 10. (\mforall{}as\mmember{}sat.[1 / v] \mcdot{} as \mgeq{}0) 11. (\mforall{}as\mmember{}[[u / v2] / v1].[1 / v] \mcdot{} as \mgeq{}0) 12. \mneg{}\muparrow{}null(v2) \mvdash{} (\muparrow{}isl(let s' \mleftarrow{}{} eval g = |gcd-list(v2)| in if (1) < (g) then eval h' = u \mdiv{}\mdownarrow{} g in eval t' = eager-map(\mlambda{}x.(x \mdiv{} g);v2) in inl [[h' / t'] / sat] else (inl [[u / v2] / sat]) in accumulate\_abort(L,Ls.let h,t = L in if t = Ax then if (h) < (0) then inr \mcdot{} else (inl [L / Ls]) otherwise eval g = |gcd-list(t)| in if (1) < (g) then eval h' = h \mdiv{}\mdownarrow{} g in eval t' = eager-map(\mlambda{}x.(x \mdiv{} g);t) in inl [[h' / t'] / Ls] else (inl [L / Ls]);s';v1))) \mwedge{} (\mforall{}as\mmember{}outl(let s' \mleftarrow{}{} eval g = |gcd-list(v2)| in if (1) < (g) then eval h' = u \mdiv{}\mdownarrow{} g in eval t' = eager-map(\mlambda{}x.(x \mdiv{} g);v2) in inl [[h' / t'] / sat] else (inl [[u / v2] / sat]) in accumulate\_abort(L,Ls.let h,t = L in if t = Ax then if (h) < (0) then inr \mcdot{} else (inl [L / Ls]) otherwise eval g = |gcd-list(t)| in if (1) < (g) then eval h' = h \mdiv{}\mdownarrow{} g in eval t' = eager-map(\mlambda{}x.(x \mdiv{} g);t) in inl [[h' / t'] / Ls] else (inl [L / Ls]);s';v1)).[1 / v] \mcdot{} as \mgeq{}0) By Latex: ((GenConcl \mkleeneopen{}|gcd-list(v2)| = gg\mkleeneclose{}\mcdot{} THENA Auto) THEN (CallByValueReduceOn \mkleeneopen{}gg\mkleeneclose{} 0\mcdot{} THENA Auto) THEN (Decide 1 < gg THENA Auto) THEN (Reduce 0 THENA Auto) THEN (((CallByValueReduce 0 THENA Auto) THEN Fold `gcd-reduce-ineq-constraints` 0) ORELSE ((CallByValueReduceOn \mkleeneopen{}u \mdiv{}\mdownarrow{} gg\mkleeneclose{} 0\mcdot{} THENA Auto) THEN (CallByValueReduceOn \mkleeneopen{}eager-map(\mlambda{}x.(x \mdiv{} gg);v2)\mkleeneclose{} 0\mcdot{} THENA Auto) THEN (CallByValueReduce 0 THENA Auto) THEN Fold `gcd-reduce-ineq-constraints` 0 THEN (RWO "eager-map-is-map" 0 THENA Auto)) )) Home Index