Proof of Nuprl Lemma : simple-swap-test

Step * 1 1 1 1 1 1 of Lemma simple-swap-test_wf

.....subterm..... T:t
1:n
1. n : ℕ
2. AType : array{i:l}(ℤ;n)
3. prog : A-map Unit
4. i : ℕn
5. j : ℕn
6. A-fetch'(array-model(AType)) i ∈ A-map'(array-model(AType)) ℤ
7. A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i) ∈ A-map ℤ
8. A-fetch'(array-model(AType)) j ∈ A-map'(array-model(AType)) ℤ
9. A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j) ∈ A-map ℤ
10. i_in : ℤ@i
11. j_in : ℤ@i
⊢ A-bind(array-model(AType)) prog
(λx.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i))
(λi_out.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j))

                (λj_out.(A-return(array-model(AType)) ((i_out =_z j_in) ∧_b (j_out =_z i_in)))))))) ∈ A-map 𝔹

BY
{ Assert ⌜λx.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i))

              (λi_out.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j))

                       (λj_out.(A-return(array-model(AType)) ((i_out =_z j_in) ∧_b (j_out =_z i_in))))))) ∈ Unit ⟶ (A-map

                                                                                                                  𝔹)⌝⋅ }

1
.....assertion.....
1. n : ℕ
2. AType : array{i:l}(ℤ;n)
3. prog : A-map Unit
4. i : ℕn
5. j : ℕn
6. A-fetch'(array-model(AType)) i ∈ A-map'(array-model(AType)) ℤ
7. A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i) ∈ A-map ℤ
8. A-fetch'(array-model(AType)) j ∈ A-map'(array-model(AType)) ℤ
9. A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j) ∈ A-map ℤ
10. i_in : ℤ@i
11. j_in : ℤ@i
⊢ λx.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i))
(λi_out.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j))

               (λj_out.(A-return(array-model(AType)) ((i_out =_z j_in) ∧_b (j_out =_z i_in))))))) ∈ Unit ⟶ (A-map 𝔹)

2
1. n : ℕ
2. AType : array{i:l}(ℤ;n)
3. prog : A-map Unit
4. i : ℕn
5. j : ℕn
6. A-fetch'(array-model(AType)) i ∈ A-map'(array-model(AType)) ℤ
7. A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i) ∈ A-map ℤ
8. A-fetch'(array-model(AType)) j ∈ A-map'(array-model(AType)) ℤ
9. A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j) ∈ A-map ℤ
10. i_in : ℤ@i
11. j_in : ℤ@i
12. λx.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i))

        (λi_out.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j))

                 (λj_out.(A-return(array-model(AType)) ((i_out =_z j_in) ∧_b (j_out =_z i_in))))))) ∈ Unit ⟶ (A-map 𝔹)

⊢ A-bind(array-model(AType)) prog
(λx.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i))
(λi_out.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j))

                (λj_out.(A-return(array-model(AType)) ((i_out =_z j_in) ∧_b (j_out =_z i_in)))))))) ∈ A-map 𝔹

Latex:

Latex:
.....subterm..... T:t 1:n 1. n : \mBbbN{} 2. AType : array\{i:l\}(\mBbbZ{};n) 3. prog : A-map Unit 4. i : \mBbbN{}n 5. j : \mBbbN{}n 6. A-fetch'(array-model(AType)) i \mmember{} A-map'(array-model(AType)) \mBbbZ{} 7. A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i) \mmember{} A-map \mBbbZ{} 8. A-fetch'(array-model(AType)) j \mmember{} A-map'(array-model(AType)) \mBbbZ{} 9. A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j) \mmember{} A-map \mBbbZ{} 10. i$_{in}$ : \mBbbZ{}@i 11. j$_{in}$ : \mBbbZ{}@i \mvdash{} A-bind(array-model(AType)) prog (\mlambda{}x.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i)) (\mlambda{}i$_{out}$.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j)) (\mlambda{}j$_{out}$.(A-return(array-model(AType)) ((i$_{out\mbackslash{}f\000Cf7d$ =\msubz{} j$_{in}$) \mwedge{}\msubb{} (j$_{out}$ =\msubz{} i$_{in\mbackslash{}ff\000C7d$)))))))) \mmember{} A-map \mBbbB{} By Latex: Assert \mkleeneopen{}\mlambda{}x.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) i)) (\mlambda{}i$_{out}$.(A-bind(array-model(AType)) (A-coerce(array-model(AType)) (A-fetch'(array-model(AType)) j)) (\mlambda{}j$_{out}$.(A-return(array-model(AType)) ((i$_{\000Cout}$ =\msubz{} j$_{in}$) \mwedge{}\msubb{} (j$_{out}$ =\msubz{} i$_{\000Cin}$))))))) \mmember{} Unit {}\mrightarrow{} (A-map \mBbbB{})\mkleeneclose{}\mcdot{} Home Index