Proof of Nuprl Lemma : monad-from

Step * 5 of Lemma monad-from_wf

1. Mnd : Monad
2. λx,z. (M-bind(Mnd) z (λx.x)) ∈ A:Type ⟶ (M-map(Mnd) (M-map(Mnd) A)) ⟶ (M-map(Mnd) A)
3. X : Type
4. x : M-map(Mnd) (M-map(Mnd) (M-map(Mnd) X))
⊢ (M-bind(Mnd) (M-bind(Mnd) x (λx.x)) (λx.x))
= (M-bind(Mnd) (M-bind(Mnd) x (λx.(M-return(Mnd) (M-bind(Mnd) x (λx.x))))) (λx.x))
∈ (M-map(Mnd) X)
BY

{ ((InstLemma `M-associative` [⌜Mnd⌝;⌜M-map(Mnd) (M-map(Mnd) X)⌝;⌜M-map(Mnd) X⌝;⌜X⌝;⌜x⌝;⌜λx.x⌝;⌜λx.x⌝]⋅ THEN Auto)

THEN NthHypEq (-1)
THEN EqCDA) }

1
.....subterm..... T:t
3:n
1. Mnd : Monad
2. λx,z. (M-bind(Mnd) z (λx.x)) ∈ A:Type ⟶ (M-map(Mnd) (M-map(Mnd) A)) ⟶ (M-map(Mnd) A)
3. X : Type
4. x : M-map(Mnd) (M-map(Mnd) (M-map(Mnd) X))

5. (M-bind(Mnd) (M-bind(Mnd) x (λx.x)) (λx.x)) = (M-bind(Mnd) x (λx.(M-bind(Mnd) ((λx.x) x) (λx.x)))) ∈ (M-map(Mnd) X)

⊢ (M-bind(Mnd) (M-bind(Mnd) x (λx.(M-return(Mnd) (M-bind(Mnd) x (λx.x))))) (λx.x))
= (M-bind(Mnd) x (λx.(M-bind(Mnd) ((λx.x) x) (λx.x))))
∈ (M-map(Mnd) X)

Latex:

Latex:
1. Mnd : Monad 2. \mlambda{}x,z. (M-bind(Mnd) z (\mlambda{}x.x)) \mmember{} A:Type {}\mrightarrow{} (M-map(Mnd) (M-map(Mnd) A)) {}\mrightarrow{} (M-map(Mnd) A) 3. X : Type 4. x : M-map(Mnd) (M-map(Mnd) (M-map(Mnd) X)) \mvdash{} (M-bind(Mnd) (M-bind(Mnd) x (\mlambda{}x.x)) (\mlambda{}x.x)) = (M-bind(Mnd) (M-bind(Mnd) x (\mlambda{}x.(M-return(Mnd) (M-bind(Mnd) x (\mlambda{}x.x))))) (\mlambda{}x.x)) By Latex: ((InstLemma `M-associative` [\mkleeneopen{}Mnd\mkleeneclose{};\mkleeneopen{}M-map(Mnd) (M-map(Mnd) X)\mkleeneclose{};\mkleeneopen{}M-map(Mnd) X\mkleeneclose{};\mkleeneopen{}X\mkleeneclose{};\mkleeneopen{}x\mkleeneclose{};\mkleeneopen{}\mlambda{}x.x\mkleeneclose{};\mkleeneopen{}\mlambda{}x.x\mkleeneclose{}] \mcdot{} THEN Auto ) THEN NthHypEq (-1) THEN EqCDA) Home Index