Require Import General.
Require Import NaturalDeduction.
+Require Import NaturalDeductionContext.
Require Import HaskKinds.
Require Import HaskLiterals.
OK (eol+++eol+++eol+++
"\begin{preview}"+++eol+++
"$\displaystyle "+++
- toString (nd_ml_toLatexMath (@expr2proof _ _ _ _ _ _ e))+++
+ toString (nd_ml_toLatexMath (@expr2proof _ _ _ _ _ _ _ e))+++
" $"+++eol+++
"\end{preview}"+++eol+++eol+++eol)
)))))))).
Definition curry {Γ}{Δ}{a}{s}{Σ}{lev} :
ND Rule
- [ Γ > Δ > Σ |- [a ---> s @@ lev ] ]
- [ Γ > Δ > Σ,,[a @@ lev] |- [ s @@ lev ] ].
- eapply nd_comp; [ idtac | eapply nd_rule; apply (@RApp Γ Δ Σ [a@@lev] a s lev) ].
+ [ Γ > Δ > Σ |- [a ---> s ]@lev ]
+ [ Γ > Δ > [a @@ lev],,Σ |- [ s ]@lev ].
+ eapply nd_comp; [ idtac | eapply nd_rule; eapply RArrange; eapply RExch ].
+ eapply nd_comp; [ idtac | eapply nd_rule; eapply RApp ].
eapply nd_comp; [ apply nd_rlecnac | idtac ].
- apply nd_prod.
+ apply nd_prod.
apply nd_id.
apply nd_rule.
apply RVar.
Defined.
Definition fToC1 {Γ}{Δ}{a}{s}{lev} :
- ND Rule [] [ Γ > Δ > [ ] |- [a ---> s @@ lev ] ] ->
- ND Rule [] [ Γ > Δ > [a @@ lev] |- [ s @@ lev ] ].
+ ND Rule [] [ Γ > Δ > [ ] |- [a ---> s ]@lev ] ->
+ ND Rule [] [ Γ > Δ > [a @@ lev] |- [ s ]@lev ].
intro pf.
eapply nd_comp.
apply pf.
- eapply nd_comp; [ idtac | eapply nd_rule; eapply RArrange; apply RCanL ].
+ eapply nd_comp; [ idtac | eapply nd_rule; eapply RArrange; apply RCanR ].
apply curry.
Defined.
Definition fToC2 {Γ}{Δ}{a1}{a2}{s}{lev} :
- ND Rule [] [ Γ > Δ > [] |- [a1 ---> (a2 ---> s) @@ lev ] ] ->
- ND Rule [] [ Γ > Δ > [a1 @@ lev],,[a2 @@ lev] |- [ s @@ lev ] ].
+ ND Rule [] [ Γ > Δ > [] |- [a1 ---> (a2 ---> s) ]@lev ] ->
+ ND Rule [] [ Γ > Δ > [a1 @@ lev],,[a2 @@ lev] |- [ s ]@lev ].
intro pf.
eapply nd_comp.
eapply pf.
eapply nd_comp.
eapply nd_rule.
eapply RArrange.
- eapply RCanL.
+ eapply RCanR.
+ eapply nd_comp; [ idtac | eapply nd_rule; eapply RArrange; eapply RExch ].
apply curry.
Defined.
Definition ga_unit TV (ec:RawHaskType TV ECKind) : RawHaskType TV ★ :=
@TyFunApp TV hetmet_PGArrow_unit_TyCon (ECKind::nil) ★ (TyFunApp_cons _ _ ec TyFunApp_nil).
+
Definition ga_prod TV (ec:RawHaskType TV ECKind) (a b:RawHaskType TV ★) : RawHaskType TV ★ :=
- TApp (TApp (@TyFunApp TV hetmet_PGArrow_tensor_TyCon (ECKind::nil) _ (TyFunApp_cons _ _ ec TyFunApp_nil)) a) b.
+ (@TyFunApp TV
+ hetmet_PGArrow_tensor_TyCon
+ (ECKind::★ ::★ ::nil) ★
+ (TyFunApp_cons _ _ ec
+ (TyFunApp_cons _ _ a
+ (TyFunApp_cons _ _ b
+ TyFunApp_nil)))).
+
Definition ga_type {TV}(a:RawHaskType TV ECKind)(b c:RawHaskType TV ★) : RawHaskType TV ★ :=
TApp (TApp (TApp (@TyFunApp TV
hetmet_PGArrowTyCon
nil _ TyFunApp_nil) a) b) c.
+
Definition ga := @ga_mk ga_unit ga_prod (@ga_type).
Definition ga_type' {Γ}(a:HaskType Γ ECKind)(b c:HaskType Γ ★) : HaskType Γ ★ :=
Defined.
Definition mkGlob2 {Γ}{Δ}{l}{κ₁}{κ₂}(cv:CoreVar)(f:HaskType Γ κ₁ -> HaskType Γ κ₂ -> HaskType Γ ★) x y
- : ND Rule [] [ Γ > Δ > [] |- [f x y @@ l] ].
+ : ND Rule [] [ Γ > Δ > [] |- [f x y ]@l ].
apply nd_rule.
refine (@RGlobal Γ Δ l
{| glob_wv := coreVarToWeakExprVarOrError cv
Defined.
Definition mkGlob3 {Γ}{Δ}{l}{κ₁}{κ₂}{κ₃}(cv:CoreVar)(f:HaskType Γ κ₁ -> HaskType Γ κ₂ -> HaskType Γ κ₃ -> HaskType Γ ★) x y z
- : ND Rule [] [ Γ > Δ > [] |- [f x y z @@ l] ].
+ : ND Rule [] [ Γ > Δ > [] |- [f x y z ]@l ].
apply nd_rule.
refine (@RGlobal Γ Δ l
{| glob_wv := coreVarToWeakExprVarOrError cv
Defined.
Definition mkGlob4 {Γ}{Δ}{l}{κ₁}{κ₂}{κ₃}{κ₄}(cv:CoreVar)(f:HaskType Γ κ₁ -> HaskType Γ κ₂ -> HaskType Γ κ₃ -> HaskType Γ κ₄ -> HaskType Γ ★) x y z q
- : ND Rule [] [ Γ > Δ > [] |- [f x y z q @@ l] ].
+ : ND Rule [] [ Γ > Δ > [] |- [f x y z q ] @l].
apply nd_rule.
refine (@RGlobal Γ Δ l
{| glob_wv := coreVarToWeakExprVarOrError cv
Definition hetmet_unflatten' := coreVarToWeakExprVarOrError hetmet_unflatten.
Definition hetmet_flattened_id' := coreVarToWeakExprVarOrError hetmet_flattened_id.
- Definition coreToCoreExpr' (ce:@CoreExpr CoreVar) : ???(@CoreExpr CoreVar) :=
- addErrorMessage ("input CoreSyn: " +++ toString ce)
- (addErrorMessage ("input CoreType: " +++ toString (coreTypeOfCoreExpr ce)) (
- coreExprToWeakExpr ce >>= fun we =>
+ Definition coreToCoreExpr' (cex:@CoreExpr CoreVar) : ???(@CoreExpr CoreVar) :=
+ addErrorMessage ("input CoreSyn: " +++ toString cex)
+ (addErrorMessage ("input CoreType: " +++ toString (coreTypeOfCoreExpr cex)) (
+ coreExprToWeakExpr cex >>= fun we =>
addErrorMessage ("WeakExpr: " +++ toString we)
((addErrorMessage ("CoreType of WeakExpr: " +++ toString (coreTypeOfCoreExpr (weakExprToCoreExpr we)))
((weakTypeOfWeakExpr we) >>= fun t =>
((weakExprToStrongExpr Γ Δ φ ψ ξ (fun _ => true) τ nil we) >>= fun e =>
(addErrorMessage ("HaskStrong...")
- (let haskProof := flatten_proof hetmet_flatten' hetmet_unflatten'
- hetmet_flattened_id' my_ga (@expr2proof _ _ _ _ _ _ e)
+ (let haskProof := skolemize_and_flatten_proof hetmet_flatten' hetmet_unflatten'
+ hetmet_flattened_id' my_ga (@expr2proof _ _ _ _ _ _ _ e)
in (* insert HaskProof-to-HaskProof manipulations here *)
- OK ((@proof2expr nat _ FreshNat _ _ _ _ (fun _ => Prelude_error "unbound unique") _ haskProof) O)
+ OK ((@proof2expr nat _ FreshNat _ _ (flatten_type τ) nil _ (fun _ => Prelude_error "unbound unique") _ haskProof) O)
>>= fun e' =>
(snd e') >>= fun e'' =>
strongExprToWeakExpr hetmet_brak' hetmet_esc'
hetmet_pga_applyr
hetmet_pga_curryl
*)
+
.
End core2proof.