(* need this or the Haskell extraction fails *)
Set Printing Width 1300000.
-Require Import Coq.Lists.List.
Require Import Coq.Strings.Ascii.
Require Import Coq.Strings.String.
+Require Import Coq.Lists.List.
Require Import Preamble.
Require Import General.
Require Import HaskCoreToWeak.
Require Import HaskWeakToStrong.
Require Import HaskStrongToProof.
-(*Require Import HaskProofToStrong.*)
+Require Import HaskProofToStrong.
Require Import HaskProofToLatex.
Require Import HaskStrongToWeak.
Require Import HaskWeakToCore.
Open Scope string_scope.
Extraction Language Haskell.
+(*Extract Inductive vec => "([])" [ "([])" "(:)" ].*)
+(*Extract Inductive Tree => "([])" [ "([])" "(:)" ].*)
+(*Extract Inlined Constant map => "Prelude.map".*)
+
(* I try to reuse Haskell types mostly to get the "deriving Show" aspect *)
Extract Inductive option => "Prelude.Maybe" [ "Prelude.Just" "Prelude.Nothing" ].
Extract Inductive list => "([])" [ "([])" "(:)" ].
-(*Extract Inductive vec => "([])" [ "([])" "(:)" ].*)
-(*Extract Inductive Tree => "([])" [ "([])" "(:)" ].*)
-Extract Inlined Constant map => "Prelude.map".
-Extract Inductive string => "Prelude.String" [ "([])" "(:)" ].
+Extract Inductive string => "Prelude.String" [ "[]" "(:)" ].
Extract Inductive prod => "(,)" [ "(,)" ].
Extract Inductive sum => "Prelude.Either" [ "Prelude.Left" "Prelude.Right" ].
Extract Inductive sumbool => "Prelude.Bool" [ "Prelude.True" "Prelude.False" ].
Extract Inductive unit => "()" [ "()" ].
Extract Inlined Constant string_dec => "(==)".
Extract Inlined Constant ascii_dec => "(==)".
-Extract Inductive string => "Prelude.String" [ "[]" "(:)" ].
(* adapted from ExtrOcamlString.v *)
-Extract Inductive ascii => "Prelude.Char" [ "bin2ascii" ] "bin2ascii'".
+Extract Inductive ascii => "Char" [ "bin2ascii" ] "bin2ascii'".
Extract Constant zero => "'\000'".
Extract Constant one => "'\001'".
Extract Constant shift => "shiftAscii".
Unset Extraction Optimize.
Unset Extraction AutoInline.
-
Variable Name : Type. Extract Inlined Constant Name => "Name.Name".
Variable mkSystemName : Unique -> string -> nat -> Name.
- Extract Inlined Constant mkSystemName => "(\u s d -> Name.mkSystemName u (OccName.mkOccName (OccName.varNameDepth (nat2int d)) s))".
+ Extract Inlined Constant mkSystemName =>
+ "(\u s d -> Name.mkSystemName u (OccName.mkOccName (OccName.varNameDepth (nat2int d)) s))".
Variable mkTyVar : Name -> Kind -> CoreVar.
Extract Inlined Constant mkTyVar => "(\n k -> Var.mkTyVar n (kindToCoreKind k))".
Variable mkCoVar : Name -> CoreType -> CoreType -> CoreVar.
eol+++"\end{document}"+++
eol.
+
Definition coreToStringExpr' (ce:@CoreExpr CoreVar) : ???string :=
addErrorMessage ("input CoreSyn: " +++ ce)
(addErrorMessage ("input CoreType: " +++ coreTypeOfCoreExpr ce) (
Context (hetmet_esc : WeakExprVar).
Context (uniqueSupply : UniqSupply).
+ Definition useUniqueSupply {T}(ut:UniqM T) : ???T :=
+ match ut with
+ uniqM f =>
+ f uniqueSupply >>= fun x => OK (snd x)
+ end.
+
+ Definition larger : forall ln:list nat, { n:nat & forall n', In n' ln -> gt n n' }.
+ intros.
+ induction ln.
+ exists O.
+ intros.
+ inversion H.
+ destruct IHln as [n pf].
+ exists (plus (S n) a).
+ intros.
+ destruct H.
+ omega.
+ fold (@In _ n' ln) in H.
+ set (pf n' H) as q.
+ omega.
+ Defined.
+
+ Definition FreshNat : @FreshMonad nat.
+ refine {| FMT := fun T => nat -> prod nat T
+ ; FMT_fresh := _
+ |}.
+ Focus 2.
+ intros.
+ refine ((S H),_).
+ set (larger tl) as q.
+ destruct q as [n' pf].
+ exists n'.
+ intros.
+ set (pf _ H0) as qq.
+ omega.
+
+ refine {| returnM := fun a (v:a) => _ |}.
+ intro n. exact (n,v).
+ intros.
+ set (X H) as q.
+ destruct q as [n' v].
+ set (X0 v n') as q'.
+ exact q'.
+ Defined.
+
+ Definition unFresh {T} : @FreshM _ FreshNat T -> T.
+ intros.
+ destruct X.
+ exact O.
+ apply t.
+ Defined.
+
+ Definition env := ★::nil.
+ Definition freshTV : HaskType env ★ := haskTyVarToType (FreshHaskTyVar _).
+ Definition idproof0 : ND Rule [] [env > nil > [] |- [freshTV--->freshTV @@ nil]].
+ eapply nd_comp.
+ eapply nd_comp.
+ eapply nd_rule.
+ apply RVar.
+ eapply nd_rule.
+ eapply (RURule _ _ _ _ (RuCanL _ _)) .
+ eapply nd_rule.
+ eapply RLam.
+ Defined.
+(*
+ Definition TInt : HaskType nil ★.
+ assert (tyConKind' intPrimTyCon = ★).
+ admit.
+ rewrite <- H.
+ unfold HaskType; intros.
+ apply TCon.
+ Defined.
+
+ Definition idproof1 : ND Rule [] [nil > nil > [TInt @@ nil] |- [TInt @@ nil]].
+ apply nd_rule.
+ apply RVar.
+ Defined.
+
+ Definition idtype :=
+ HaskTAll(Γ:=nil) ★ (fun TV ite tv => (TApp (TApp TArrow (TVar tv)) (TVar tv))).
+
+ Definition idproof : ND Rule [] [nil > nil > [] |- [idtype @@ nil]].
+ eapply nd_comp; [ idtac | eapply nd_rule ; eapply RAbsT ].
+ apply idproof0.
+ Defined.
+*)
+(*
+ Definition coreToCoreExpr' (ce:@CoreExpr CoreVar) : ???(@CoreExpr CoreVar) :=
+ addErrorMessage ("input CoreSyn: " +++ ce)
+ (addErrorMessage ("input CoreType: " +++ coreTypeOfCoreExpr ce) (
+ coreExprToWeakExpr ce >>= fun we =>
+ addErrorMessage ("WeakExpr: " +++ we)
+ ((addErrorMessage ("CoreType of WeakExpr: " +++ coreTypeOfCoreExpr (weakExprToCoreExpr we))
+ ((weakTypeOfWeakExpr we) >>= fun t =>
+ (addErrorMessage ("WeakType: " +++ t)
+ ((weakTypeToTypeOfKind φ t ★) >>= fun τ =>
+ addErrorMessage ("HaskType: " +++ τ)
+ ((weakExprToStrongExpr Γ Δ φ ψ ξ (fun _ => true) τ nil we) >>= fun e =>
+ (let haskProof := @expr2proof _ _ _ _ _ _ e
+ in (* insert HaskProof-to-HaskProof manipulations here *)
+ (unFresh (@proof2expr nat _ FreshNat _ _ _ _ (fun _ => Prelude_error "unbound unique") _ haskProof))
+ >>= fun e' => Error (@toString _ (ExprToString _ _ _ _) (projT2 e'))
+(*
+ >>= fun e' =>
+ Prelude_error (@toString _ (@ExprToString nat _ _ _ _ _ _) (projT2 e'))
+ *)
+)
+)))))))).
+(* Error "X").*)
+(*
+ strongExprToWeakExpr hetmet_brak hetmet_esc mkWeakTypeVar mkWeakCoerVar mkWeakExprVar uniqueSupply
+ (projT2 e')
+ INil
+ >>= fun q => Error (toString q)
+ ))))))))).
+*)
+*)
+
Definition coreToCoreExpr' (ce:@CoreExpr CoreVar) : ???(@CoreExpr CoreVar) :=
addErrorMessage ("input CoreSyn: " +++ ce)
(addErrorMessage ("input CoreType: " +++ coreTypeOfCoreExpr ce) (
((weakTypeToTypeOfKind φ t ★) >>= fun τ =>
((weakExprToStrongExpr Γ Δ φ ψ ξ (fun _ => true) τ nil we) >>= fun e =>
- (* insert HaskStrong-to-HaskStrong manipulations here *)
- strongExprToWeakExpr hetmet_brak hetmet_esc mkWeakTypeVar mkWeakCoerVar mkWeakExprVar uniqueSupply e INil
- >>= fun q => OK (weakExprToCoreExpr q)
-(*
- OK (weakExprToCoreExpr we)
-*)
- )))))))).
+
+ (addErrorMessage ("HaskStrong...")
+ (let haskProof := @expr2proof _ _ _ _ _ _ e
+ in (* insert HaskProof-to-HaskProof manipulations here *)
+ OK ((@proof2expr nat _ FreshNat _ _ _ _ (fun _ => Prelude_error "unbound unique") _ haskProof) O)
+ >>= fun e' =>
+ (snd e') >>= fun e'' =>
+ strongExprToWeakExpr hetmet_brak hetmet_esc mkWeakTypeVar mkWeakCoerVar mkWeakExprVar uniqueSupply
+ (projT2 e'') INil
+ >>= fun q =>
+ OK (weakExprToCoreExpr q)
+ )))))))))).
Definition coreToCoreExpr (ce:@CoreExpr CoreVar) : (@CoreExpr CoreVar) :=
match coreToCoreExpr' ce with
end.
End core2proof.
-
+(*Set Extraction Optimize.*)
+(*Set Extraction AutoInline.*)
Extraction "Extraction.hs" coqPassCoreToString coqPassCoreToCore.
Section HaskProofToStrong.
- Context {VV:Type} {eqdec_vv:EqDecidable VV}.
+ Context {VV:Type} {eqdec_vv:EqDecidable VV} {freshM:FreshMonad VV}.
- Definition Exprs Γ Δ ξ τ :=
- ITree _ (fun τ => Expr Γ Δ ξ τ) τ.
+ Definition fresh := FMT_fresh freshM.
+ Definition FreshM := FMT freshM.
+ Definition FreshMon := FMT_Monad freshM.
+ Existing Instance FreshMon.
+
+ Definition ExprVarResolver Γ := VV -> LeveledHaskType Γ ★.
+
+ Definition ujudg2exprType {Γ}{Δ}(ξ:ExprVarResolver Γ)(j:UJudg Γ Δ) : Type :=
+ match j with
+ mkUJudg Σ τ => forall vars, Σ = mapOptionTree ξ vars ->
+ FreshM (ITree _ (fun t => Expr Γ Δ ξ t) τ)
+ end.
Definition judg2exprType (j:Judg) : Type :=
match j with
- (Γ > Δ > Σ |- τ) => forall (ξ:VV -> LeveledHaskType Γ ★ ) vars, Σ=mapOptionTree ξ vars -> Exprs Γ Δ ξ τ
+ (Γ > Δ > Σ |- τ) => forall (ξ:ExprVarResolver Γ) vars, Σ = mapOptionTree ξ vars ->
+ FreshM (ITree _ (fun t => Expr Γ Δ ξ t) τ)
end.
- Definition judges2exprType (j:Tree ??Judg) : Type :=
- ITree _ judg2exprType j.
+ Definition justOne Γ Δ ξ τ : ITree _ (fun t => Expr Γ Δ ξ t) [τ] -> Expr Γ Δ ξ τ.
+ intros.
+ inversion X; auto.
+ Defined.
- Definition urule2expr Γ Δ : forall h j (r:@URule Γ Δ h j),
- judges2exprType (mapOptionTree UJudg2judg h) -> judges2exprType (mapOptionTree UJudg2judg j).
+ Definition ileaf `(it:ITree X F [t]) : F t.
+ inversion it.
+ apply X0.
+ Defined.
- intros h j r.
+ Lemma update_branches : forall Γ (ξ:VV -> LeveledHaskType Γ ★) l1 l2 q,
+ update_ξ ξ (app l1 l2) q = update_ξ (update_ξ ξ l2) l1 q.
+ intros.
+ induction l1.
+ reflexivity.
+ simpl.
+ destruct a; simpl.
+ rewrite IHl1.
+ reflexivity.
+ Qed.
+
+ Lemma mapOptionTree_extensional {A}{B}(f g:A->B) : (forall a, f a = g a) -> (forall t, mapOptionTree f t = mapOptionTree g t).
+ intros.
+ induction t.
+ destruct a; auto.
+ simpl; rewrite H; auto.
+ simpl; rewrite IHt1; rewrite IHt2; auto.
+ Qed.
+
+ Lemma quark {T} (l1:list T) l2 vf :
+ (In vf (app l1 l2)) <->
+ (In vf l1) \/ (In vf l2).
+ induction l1.
+ simpl; auto.
+ split; intro.
+ right; auto.
+ inversion H.
+ inversion H0.
+ auto.
+ split.
+
+ destruct IHl1.
+ simpl in *.
+ intro.
+ destruct H1.
+ left; left; auto.
+ set (H H1) as q.
+ destruct q.
+ left; right; auto.
+ right; auto.
+ simpl.
+
+ destruct IHl1.
+ simpl in *.
+ intro.
+ destruct H1.
+ destruct H1.
+ left; auto.
+ right; apply H0; auto.
+ right; apply H0; auto.
+ Qed.
+
+ Lemma splitter {T} (l1:list T) l2 vf :
+ (In vf (app l1 l2) → False)
+ -> (In vf l1 → False) /\ (In vf l2 → False).
+ intros.
+ split; intros; apply H; rewrite quark.
+ auto.
+ auto.
+ Qed.
+
+ Lemma helper
+ : forall T Z {eqdt:EqDecidable T}(tl:Tree ??T)(vf:T) ξ (q:Z),
+ (In vf (leaves tl) -> False) ->
+ mapOptionTree (fun v' => if eqd_dec vf v' then q else ξ v') tl =
+ mapOptionTree ξ tl.
+ intros.
+ induction tl;
+ try destruct a;
+ simpl in *.
+ set (eqd_dec vf t) as x in *.
+ destruct x.
+ subst.
+ assert False.
+ apply H.
+ left; auto.
+ inversion H0.
+ auto.
+ auto.
+ apply splitter in H.
+ destruct H.
+ rewrite (IHtl1 H).
+ rewrite (IHtl2 H0).
+ reflexivity.
+ Qed.
+
+ Lemma fresh_lemma' Γ
+ : forall types vars Σ ξ, Σ = mapOptionTree ξ vars ->
+ FreshM { varstypes : _
+ | mapOptionTree (update_ξ(Γ:=Γ) ξ (leaves varstypes)) vars = Σ
+ /\ mapOptionTree (update_ξ ξ (leaves varstypes)) (mapOptionTree (@fst _ _) varstypes) = types }.
+ induction types.
+ intros; destruct a.
+ refine (bind vf = fresh (leaves vars) ; return _).
+ apply FreshMon.
+ destruct vf as [ vf vf_pf ].
+ exists [(vf,l)].
+ split; auto.
+ simpl.
+ set (helper VV _ vars vf ξ l vf_pf) as q.
+ rewrite q.
+ symmetry; auto.
+ simpl.
+ destruct (eqd_dec vf vf); [ idtac | set (n (refl_equal _)) as n'; inversion n' ]; auto.
+ refine (return _).
+ exists []; auto.
+ intros vars Σ ξ pf; refine (bind x2 = IHtypes2 vars Σ ξ pf; _).
+ apply FreshMon.
+ destruct x2 as [vt2 [pf21 pf22]].
+ refine (bind x1 = IHtypes1 (vars,,(mapOptionTree (@fst _ _) vt2)) (Σ,,types2) (update_ξ ξ (leaves vt2)) _; return _).
+ apply FreshMon.
+ simpl.
+ rewrite pf21.
+ rewrite pf22.
+ reflexivity.
+ clear IHtypes1 IHtypes2.
+ destruct x1 as [vt1 [pf11 pf12]].
+ exists (vt1,,vt2); split; auto.
+
+ set (update_branches Γ ξ (leaves vt1) (leaves vt2)) as q.
+ set (mapOptionTree_extensional _ _ q) as q'.
+ rewrite q'.
+ clear q' q.
+ inversion pf11.
+ reflexivity.
+
+ simpl.
+ set (update_branches Γ ξ (leaves vt1) (leaves vt2)) as q.
+ set (mapOptionTree_extensional _ _ q) as q'.
+ rewrite q'.
+ rewrite q'.
+ clear q' q.
+ rewrite <- mapOptionTree_compose.
+ rewrite <- mapOptionTree_compose.
+ rewrite <- mapOptionTree_compose in *.
+ rewrite pf12.
+ inversion pf11.
+ rewrite <- mapOptionTree_compose.
+ reflexivity.
+ Defined.
- refine (match r as R in URule H C
- return judges2exprType (mapOptionTree UJudg2judg H) -> judges2exprType (mapOptionTree UJudg2judg C) with
- | RLeft h c ctx r => let case_RLeft := tt in _
- | RRight h c ctx r => let case_RRight := tt in _
- | RCanL t a => let case_RCanL := tt in _
- | RCanR t a => let case_RCanR := tt in _
- | RuCanL t a => let case_RuCanL := tt in _
- | RuCanR t a => let case_RuCanR := tt in _
- | RAssoc t a b c => let case_RAssoc := tt in _
- | RCossa t a b c => let case_RCossa := tt in _
- | RExch t a b => let case_RExch := tt in _
- | RWeak t a => let case_RWeak := tt in _
- | RCont t a => let case_RCont := tt in _
- end ); intros.
+ Lemma fresh_lemma Γ ξ vars Σ Σ'
+ : Σ = mapOptionTree ξ vars ->
+ FreshM { vars' : _
+ | mapOptionTree (update_ξ(Γ:=Γ) ξ ((vars',Σ')::nil)) vars = Σ
+ /\ mapOptionTree (update_ξ ξ ((vars',Σ')::nil)) [vars'] = [Σ'] }.
+ intros.
+ set (fresh_lemma' Γ [Σ'] vars Σ ξ H) as q.
+ refine (q >>>= fun q' => return _).
+ apply FreshMon.
+ clear q.
+ destruct q' as [varstypes [pf1 pf2]].
+ destruct varstypes; try destruct o; try destruct p; simpl in *.
+ destruct (eqd_dec v v); [ idtac | set (n (refl_equal _)) as n'; inversion n' ].
+ inversion pf2; subst.
+ exists v.
+ destruct (eqd_dec v v); [ idtac | set (n (refl_equal _)) as n'; inversion n' ].
+ split; auto.
+ inversion pf2.
+ inversion pf2.
+ Defined.
+
+ Lemma manyFresh : forall Γ Σ (ξ0:VV -> LeveledHaskType Γ ★),
+ FreshM { vars : _ & { ξ : VV -> LeveledHaskType Γ ★ & Σ = mapOptionTree ξ vars } }.
+ intros.
+ set (fresh_lemma' Γ Σ [] [] ξ0 (refl_equal _)) as q.
+ refine (q >>>= fun q' => return _).
+ apply FreshMon.
+ clear q.
+ destruct q' as [varstypes [pf1 pf2]].
+ exists (mapOptionTree (@fst _ _) varstypes).
+ exists (update_ξ ξ0 (leaves varstypes)).
+ symmetry; auto.
+ Defined.
+
+ Definition urule2expr : forall Γ Δ h j (r:@URule Γ Δ h j) (ξ:VV -> LeveledHaskType Γ ★),
+ ITree _ (ujudg2exprType ξ) h -> ITree _ (ujudg2exprType ξ) j.
+
+ refine (fix urule2expr Γ Δ h j (r:@URule Γ Δ h j) ξ {struct r} :
+ ITree _ (ujudg2exprType ξ) h -> ITree _ (ujudg2exprType ξ) j :=
+ match r as R in URule H C return ITree _ (ujudg2exprType ξ) H -> ITree _ (ujudg2exprType ξ) C with
+ | RLeft h c ctx r => let case_RLeft := tt in (fun e => _) (urule2expr _ _ _ _ r)
+ | RRight h c ctx r => let case_RRight := tt in (fun e => _) (urule2expr _ _ _ _ r)
+ | RCanL t a => let case_RCanL := tt in _
+ | RCanR t a => let case_RCanR := tt in _
+ | RuCanL t a => let case_RuCanL := tt in _
+ | RuCanR t a => let case_RuCanR := tt in _
+ | RAssoc t a b c => let case_RAssoc := tt in _
+ | RCossa t a b c => let case_RCossa := tt in _
+ | RExch t a b => let case_RExch := tt in _
+ | RWeak t a => let case_RWeak := tt in _
+ | RCont t a => let case_RCont := tt in _
+ end); clear urule2expr; intros.
destruct case_RCanL.
apply ILeaf; simpl; intros.
inversion X.
simpl in X0.
- apply (X0 ξ ([],,vars)).
+ apply (X0 ([],,vars)).
simpl; rewrite <- H; auto.
destruct case_RCanR.
apply ILeaf; simpl; intros.
inversion X.
simpl in X0.
- apply (X0 ξ (vars,,[])).
+ apply (X0 (vars,,[])).
simpl; rewrite <- H; auto.
destruct case_RuCanL.
destruct vars; try destruct o; inversion H.
inversion X.
simpl in X0.
- apply (X0 ξ vars2); auto.
+ apply (X0 vars2); auto.
destruct case_RuCanR.
apply ILeaf; simpl; intros.
destruct vars; try destruct o; inversion H.
inversion X.
simpl in X0.
- apply (X0 ξ vars1); auto.
+ apply (X0 vars1); auto.
destruct case_RAssoc.
apply ILeaf; simpl; intros.
simpl in X0.
destruct vars; try destruct o; inversion H.
destruct vars1; try destruct o; inversion H.
- apply (X0 ξ (vars1_1,,(vars1_2,,vars2))).
+ apply (X0 (vars1_1,,(vars1_2,,vars2))).
subst; auto.
destruct case_RCossa.
simpl in X0.
destruct vars; try destruct o; inversion H.
destruct vars2; try destruct o; inversion H.
- apply (X0 ξ ((vars1,,vars2_1),,vars2_2)).
+ apply (X0 ((vars1,,vars2_1),,vars2_2)).
subst; auto.
destruct case_RLeft.
- (* this will require recursion *)
- admit.
+ destruct c; [ idtac | apply no_urules_with_multiple_conclusions in r0; inversion r0; exists c1; exists c2; auto ].
+ destruct o; [ idtac | apply INone ].
+ destruct u; simpl in *.
+ apply ILeaf; simpl; intros.
+ destruct vars; try destruct o; inversion H.
+ set (fun q => ileaf (e ξ q)) as r'.
+ simpl in r'.
+ apply r' with (vars:=vars2).
+ clear r' e.
+ clear r0.
+ induction h0.
+ destruct a.
+ destruct u.
+ simpl in X.
+ apply ileaf in X.
+ apply ILeaf.
+ simpl.
+ simpl in X.
+ intros.
+ apply X with (vars:=vars1,,vars).
+ simpl.
+ rewrite H0.
+ rewrite H1.
+ reflexivity.
+ apply INone.
+ apply IBranch.
+ apply IHh0_1. inversion X; auto.
+ apply IHh0_2. inversion X; auto.
+ auto.
destruct case_RRight.
- (* this will require recursion *)
- admit.
+ destruct c; [ idtac | apply no_urules_with_multiple_conclusions in r0; inversion r0; exists c1; exists c2; auto ].
+ destruct o; [ idtac | apply INone ].
+ destruct u; simpl in *.
+ apply ILeaf; simpl; intros.
+ destruct vars; try destruct o; inversion H.
+ set (fun q => ileaf (e ξ q)) as r'.
+ simpl in r'.
+ apply r' with (vars:=vars1).
+ clear r' e.
+ clear r0.
+ induction h0.
+ destruct a.
+ destruct u.
+ simpl in X.
+ apply ileaf in X.
+ apply ILeaf.
+ simpl.
+ simpl in X.
+ intros.
+ apply X with (vars:=vars,,vars2).
+ simpl.
+ rewrite H0.
+ rewrite H2.
+ reflexivity.
+ apply INone.
+ apply IBranch.
+ apply IHh0_1. inversion X; auto.
+ apply IHh0_2. inversion X; auto.
+ auto.
destruct case_RExch.
apply ILeaf; simpl; intros.
inversion X.
simpl in X0.
destruct vars; try destruct o; inversion H.
- apply (X0 ξ (vars2,,vars1)).
+ apply (X0 (vars2,,vars1)).
inversion H; subst; auto.
destruct case_RWeak.
apply ILeaf; simpl; intros.
inversion X.
simpl in X0.
- apply (X0 ξ []).
+ apply (X0 []).
auto.
destruct case_RCont.
apply ILeaf; simpl; intros.
inversion X.
simpl in X0.
- apply (X0 ξ (vars,,vars)).
+ apply (X0 (vars,,vars)).
simpl.
rewrite <- H.
auto.
Defined.
- Definition rule2expr : forall h j (r:Rule h j), judges2exprType h -> judges2exprType j.
+ Definition bridge Γ Δ (c:Tree ??(UJudg Γ Δ)) ξ :
+ ITree Judg judg2exprType (mapOptionTree UJudg2judg c) -> ITree (UJudg Γ Δ) (ujudg2exprType ξ) c.
+ intro it.
+ induction c.
+ destruct a.
+ destruct u; simpl in *.
+ apply ileaf in it.
+ apply ILeaf.
+ simpl in *.
+ intros; apply it with (vars:=vars); auto.
+ apply INone.
+ apply IBranch; [ apply IHc1 | apply IHc2 ]; inversion it; auto.
+ Defined.
+
+ Definition letrec_helper Γ Δ l varstypes ξ' :
+ ITree (LeveledHaskType Γ ★)
+ (fun t : LeveledHaskType Γ ★ => Expr Γ Δ ξ' t)
+ (mapOptionTree (ξ' ○ (@fst _ _)) varstypes)
+ -> ELetRecBindings Γ Δ ξ' l
+ (mapOptionTree (fun x : VV * LeveledHaskType Γ ★ => ⟨fst x, unlev (snd x) ⟩) varstypes).
+ intros.
+ induction varstypes.
+ destruct a; simpl in *.
+ destruct p.
+ destruct l0 as [τ l'].
+ simpl.
+ apply ileaf in X. simpl in X.
+ assert (unlev (ξ' v) = τ).
+ admit.
+ rewrite <- H.
+ apply ELR_leaf.
+ rewrite H.
+ destruct (ξ' v).
+ rewrite <- H.
+ simpl.
+ assert (h0=l). admit.
+ rewrite H0 in X.
+ apply X.
+
+ apply ELR_nil.
+
+ simpl; apply ELR_branch.
+ apply IHvarstypes1.
+ simpl in X.
+ inversion X; auto.
+ apply IHvarstypes2.
+ simpl in X.
+ inversion X; auto.
+
+ Defined.
+
+
+(*
+ Definition case_helper tc Γ Δ lev tbranches avars ξ (Σ:Tree ??VV) tys :
+ forall pcb : ProofCaseBranch tc Γ Δ lev tbranches avars,
+ judg2exprType (pcb_judg pcb) -> FreshM
+ {scb : StrongCaseBranchWithVVs VV eqdec_vv tc avars &
+ Expr (sac_Γ scb Γ) (sac_Δ scb Γ avars (weakCK'' Δ))
+ (scbwv_ξ scb ξ lev) (weakLT' (tbranches @@ lev))}.
+ intros.
+ simpl in X.
+ destruct pcb.
+ simpl in *.
+ refine (bind ξvars = fresh_lemma' Γ pcb_freevars Σ [] ξ _ ; _). apply FreshMon.
+ destruct ξvars as [vars [ξ'
+ Defined.
+*)
+
+ Lemma itree_mapOptionTree : forall T T' F (f:T->T') t,
+ ITree _ F (mapOptionTree f t) ->
+ ITree _ (F ○ f) t.
+ intros.
+ induction t; try destruct a; simpl in *.
+ apply ILeaf.
+ inversion X; auto.
+ apply INone.
+ apply IBranch.
+ apply IHt1; inversion X; auto.
+ apply IHt2; inversion X; auto.
+ Defined.
+
+ Definition rule2expr : forall h j (r:Rule h j), ITree _ judg2exprType h -> ITree _ judg2exprType j.
intros h j r.
- refine (match r as R in Rule H C return judges2exprType H -> judges2exprType C with
- | RURule a b c d e => let case_RURule := tt in _
- | RNote Γ Δ Σ τ l n => let case_RNote := tt in _
- | RLit Γ Δ l _ => let case_RLit := tt in _
- | RVar Γ Δ σ p => let case_RVar := tt in _
- | RGlobal Γ Δ σ l wev => let case_RGlobal := tt in _
- | RLam Γ Δ Σ tx te x => let case_RLam := tt in _
- | RCast Γ Δ Σ σ τ γ x => let case_RCast := tt in _
- | RAbsT Γ Δ Σ κ σ a => let case_RAbsT := tt in _
- | RAppT Γ Δ Σ κ σ τ y => let case_RAppT := tt in _
- | RAppCo Γ Δ Σ κ σ₁ σ₂ γ σ l => let case_RAppCo := tt in _
- | RAbsCo Γ Δ Σ κ σ σ₁ σ₂ y => let case_RAbsCo := tt in _
- | RApp Γ Δ Σ₁ Σ₂ tx te p => let case_RApp := tt in _
- | RLet Γ Δ Σ₁ Σ₂ σ₁ σ₂ p => let case_RLet := tt in _
- | RLetRec Γ p lri x y => let case_RLetRec := tt in _
- | RBindingGroup Γ p lri m x q => let case_RBindingGroup := tt in _
- | REmptyGroup _ _ => let case_REmptyGroup := tt in _
- | RCase Σ Γ T κlen κ θ ldcd τ => let case_RCase := tt in _
- | RBrak Σ a b c n m => let case_RBrak := tt in _
- | REsc Σ a b c n m => let case_REsc := tt in _
- end); intros.
+ refine (match r as R in Rule H C return ITree _ judg2exprType H -> ITree _ judg2exprType C with
+ | RURule a b c d e => let case_RURule := tt in _
+ | RNote Γ Δ Σ τ l n => let case_RNote := tt in _
+ | RLit Γ Δ l _ => let case_RLit := tt in _
+ | RVar Γ Δ σ p => let case_RVar := tt in _
+ | RGlobal Γ Δ σ l wev => let case_RGlobal := tt in _
+ | RLam Γ Δ Σ tx te x => let case_RLam := tt in _
+ | RCast Γ Δ Σ σ τ γ x => let case_RCast := tt in _
+ | RAbsT Γ Δ Σ κ σ a => let case_RAbsT := tt in _
+ | RAppT Γ Δ Σ κ σ τ y => let case_RAppT := tt in _
+ | RAppCo Γ Δ Σ κ σ₁ σ₂ γ σ l => let case_RAppCo := tt in _
+ | RAbsCo Γ Δ Σ κ σ σ₁ σ₂ y => let case_RAbsCo := tt in _
+ | RApp Γ Δ Σ₁ Σ₂ tx te p => let case_RApp := tt in _
+ | RLet Γ Δ Σ₁ Σ₂ σ₁ σ₂ p => let case_RLet := tt in _
+ | RBindingGroup Γ p lri m x q => let case_RBindingGroup := tt in _
+ | REmptyGroup _ _ => let case_REmptyGroup := tt in _
+ | RBrak Σ a b c n m => let case_RBrak := tt in _
+ | REsc Σ a b c n m => let case_REsc := tt in _
+ | RCase Γ Δ lev tc Σ avars tbranches alts => let case_RCase := tt in _
+ | RLetRec Γ Δ lri x y => let case_RLetRec := tt in _
+ end); intro X_; try apply ileaf in X_; simpl in X_.
destruct case_RURule.
- eapply urule2expr.
- apply e.
- apply X.
+ destruct d; try destruct o.
+ apply ILeaf; destruct u; simpl; intros.
+ set (@urule2expr a b _ _ e ξ) as q.
+ set (fun z => ileaf (q z)) as q'.
+ simpl in q'.
+ apply q' with (vars:=vars).
+ clear q' q.
+ apply bridge.
+ apply X_.
+ auto.
+ apply no_urules_with_empty_conclusion in e; inversion e; auto.
+ apply no_urules_with_multiple_conclusions in e; inversion e; auto; exists d1; exists d2; auto.
destruct case_RBrak.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (X_ ξ vars H >>>= fun X => return ILeaf _ _). apply FreshMon.
apply EBrak.
- inversion X.
- set (X0 ξ vars H) as X'.
- inversion X'.
- apply X1.
+ apply (ileaf X).
destruct case_REsc.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (X_ ξ vars H >>>= fun X => return ILeaf _ _). apply FreshMon.
apply EEsc.
- inversion X.
- set (X0 ξ vars H) as X'.
- inversion X'.
- apply X1.
+ apply (ileaf X).
destruct case_RNote.
- apply ILeaf; simpl; intros; apply ILeaf.
- inversion X.
- apply ENote.
- apply n.
- simpl in X0.
- set (X0 ξ vars H) as x1.
- inversion x1.
- apply X1.
+ apply ILeaf; simpl; intros; refine (X_ ξ vars H >>>= fun X => return ILeaf _ _). apply FreshMon.
+ apply ENote; auto.
+ apply (ileaf X).
destruct case_RLit.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (return ILeaf _ _).
apply ELit.
destruct case_RVar.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (return ILeaf _ _).
destruct vars; simpl in H; inversion H; destruct o. inversion H1. rewrite H2.
apply EVar.
inversion H.
destruct case_RGlobal.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (return ILeaf _ _).
apply EGlobal.
apply wev.
destruct case_RLam.
- apply ILeaf; simpl; intros; apply ILeaf.
- (* need a fresh variable here *)
- admit.
+ apply ILeaf.
+ simpl in *; intros.
+ refine (fresh_lemma _ ξ vars _ (tx@@x) H >>>= (fun pf => _)).
+ apply FreshMon.
+ destruct pf as [ vnew [ pf1 pf2 ]].
+ set (update_ξ ξ ((⟨vnew, tx @@ x ⟩) :: nil)) as ξ' in *.
+ refine (X_ ξ' (vars,,[vnew]) _ >>>= _).
+ apply FreshMon.
+ simpl.
+ rewrite pf1.
+ rewrite <- pf2.
+ simpl.
+ reflexivity.
+ intro hyp.
+ refine (return _).
+ apply ILeaf.
+ apply ELam with (ev:=vnew).
+ apply ileaf in hyp.
+ simpl in hyp.
+ unfold ξ' in hyp.
+ apply hyp.
destruct case_RCast.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (X_ ξ vars H >>>= fun X => return ILeaf _ _). apply FreshMon.
eapply ECast.
apply x.
- inversion X.
- simpl in X0.
- set (X0 ξ vars H) as q.
- inversion q.
- apply X1.
+ apply ileaf in X. simpl in X.
+ apply X.
destruct case_RBindingGroup.
apply ILeaf; simpl; intros.
- inversion X.
- inversion X0.
- inversion X1.
+ inversion X_.
+ apply ileaf in X.
+ apply ileaf in X0.
+ simpl in *.
destruct vars; inversion H.
- destruct o; inversion H5.
- set (X2 _ _ H5) as q1.
- set (X3 _ _ H6) as q2.
+ destruct o; inversion H3.
+ refine (X ξ vars1 H3 >>>= fun X' => X0 ξ vars2 H4 >>>= fun X0' => return _).
+ apply FreshMon.
+ apply FreshMon.
apply IBranch; auto.
destruct case_RApp.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf.
+ inversion X_.
inversion X.
inversion X0.
- inversion X1.
- destruct vars; try destruct o; inversion H.
- set (X2 _ _ H5) as q1.
- set (X3 _ _ H6) as q2.
- eapply EApp.
- inversion q1.
- apply X4.
- inversion q2.
- apply X4.
+ simpl in *.
+ intros.
+ destruct vars. try destruct o; inversion H.
+ simpl in H.
+ inversion H.
+ set (X1 ξ vars1 H5) as q1.
+ set (X2 ξ vars2 H6) as q2.
+ refine (q1 >>>= fun q1' => q2 >>>= fun q2' => return _).
+ apply FreshMon.
+ apply FreshMon.
+ apply ILeaf.
+ apply ileaf in q1'.
+ apply ileaf in q2'.
+ simpl in *.
+ apply (EApp _ _ _ _ _ _ q1' q2').
destruct case_RLet.
- apply ILeaf; simpl; intros; apply ILeaf.
- (* FIXME: need a var here, and other work *)
- admit.
+ apply ILeaf.
+ simpl in *; intros.
+ destruct vars; try destruct o; inversion H.
+ refine (fresh_lemma _ ξ vars1 _ (σ₂@@p) H1 >>>= (fun pf => _)).
+ apply FreshMon.
+ destruct pf as [ vnew [ pf1 pf2 ]].
+ set (update_ξ ξ ((⟨vnew, σ₂ @@ p ⟩) :: nil)) as ξ' in *.
+ inversion X_.
+ apply ileaf in X.
+ apply ileaf in X0.
+ simpl in *.
+ refine (X0 ξ vars2 _ >>>= fun X0' => _).
+ apply FreshMon.
+ auto.
+ refine (X ξ' (vars1,,[vnew]) _ >>>= fun X1' => _).
+ apply FreshMon.
+ rewrite H1.
+ simpl.
+ rewrite pf2.
+ rewrite pf1.
+ rewrite H1.
+ reflexivity.
+ refine (return _).
+ apply ILeaf.
+ apply ileaf in X0'.
+ apply ileaf in X1'.
+ simpl in *.
+ apply ELet with (ev:=vnew)(tv:=σ₂).
+ apply X0'.
+ apply X1'.
destruct case_REmptyGroup.
apply ILeaf; simpl; intros.
+ refine (return _).
apply INone.
destruct case_RAppT.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (X_ ξ vars H >>>= fun X => return ILeaf _ _). apply FreshMon.
apply ETyApp.
- inversion X.
- set (X0 _ _ H) as q.
- inversion q.
- apply X1.
+ apply (ileaf X).
destruct case_RAbsT.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (X_ (weakLT ○ ξ) vars _ >>>= fun X => return ILeaf _ _). apply FreshMon.
+ rewrite mapOptionTree_compose.
+ rewrite <- H.
+ reflexivity.
+ apply ileaf in X. simpl in *.
apply ETyLam.
- inversion X.
- simpl in *.
- set (X0 (weakLT ○ ξ) vars) as q.
- rewrite mapOptionTree_compose in q.
- rewrite <- H in q.
- set (q (refl_equal _)) as q'.
- inversion q'.
- apply X1.
+ apply X.
destruct case_RAppCo.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (X_ ξ vars _ >>>= fun X => return ILeaf _ _). apply FreshMon.
+ auto.
eapply ECoApp.
apply γ.
- inversion X.
- set (X0 _ _ H) as q.
- inversion q.
- apply X1.
+ apply (ileaf X).
destruct case_RAbsCo.
- apply ILeaf; simpl; intros; apply ILeaf.
+ apply ILeaf; simpl; intros; refine (X_ ξ vars _ >>>= fun X => return ILeaf _ _). apply FreshMon.
+ auto.
eapply ECoLam.
- inversion X.
- set (X0 _ _ H) as q.
- inversion q; auto.
+ apply (ileaf X).
destruct case_RLetRec.
- admit.
+ apply ILeaf; simpl; intros.
+ refine (bind ξvars = fresh_lemma' _ y _ _ _ H; _). apply FreshMon.
+ destruct ξvars as [ varstypes [ pf1 pf2 ]].
+ refine (X_ ((update_ξ ξ (leaves varstypes)))
+ (vars,,(mapOptionTree (@fst _ _) varstypes)) _ >>>= fun X => return _); clear X_. apply FreshMon.
+ simpl.
+ rewrite pf2.
+ rewrite pf1.
+ auto.
+ apply ILeaf.
+ destruct x as [τ l].
+ inversion X; subst; clear X.
+
+ (* getting rid of this will require strengthening RLetRec *)
+ assert ((mapOptionTree (fun x : VV * LeveledHaskType Γ ★ => ⟨fst x, unlev (snd x) @@ l ⟩) varstypes) = varstypes) as HHH.
+ admit.
+
+ apply (@ELetRec _ _ _ _ _ _ _ (mapOptionTree (fun x => ((fst x),unlev (snd x))) varstypes));
+ rewrite mapleaves; rewrite <- map_compose; simpl;
+ [ idtac
+ | rewrite <- mapleaves; rewrite HHH; apply (ileaf X0) ].
+
+ clear X0.
+ rewrite <- mapOptionTree_compose in X1.
+ set (fun x : VV * LeveledHaskType Γ ★ => ⟨fst x, unlev (snd x) @@ l ⟩) as ξ' in *.
+ rewrite <- mapleaves.
+ rewrite HHH.
+
+ apply (letrec_helper _ _ _ _ _ X1).
destruct case_RCase.
- admit.
+ apply ILeaf.
+simpl.
+intros.
+apply (Prelude_error "FIXME").
- Defined.
+
+(*
+ apply ILeaf; simpl; intros.
+ inversion X_.
+ clear X_.
+ subst.
+ apply ileaf in X0.
+ simpl in X0.
+ set (mapOptionTreeAndFlatten pcb_freevars alts) as Σalts in *.
+ refine (bind ξvars = fresh_lemma' _ (Σalts,,Σ) _ _ _ H ; _).
+ apply FreshMon.
+ destruct vars; try destruct o; inversion H; clear H.
+ rename vars1 into varsalts.
+ rename vars2 into varsΣ.
+
+ refine (X0 ξ varsΣ _ >>>= fun X => return ILeaf _ _); auto. apply FreshMon.
+ clear X0.
+ eapply (ECase _ _ _ _ _ _ _ (ileaf X1)).
+ clear X1.
+
+ destruct ξvars as [varstypes [pf1 pf2]].
+
+ apply itree_mapOptionTree in X.
+ refine (itree_to_tree (itmap _ X)).
+ apply case_helper.
+*)
+ Defined.
Definition closed2expr : forall c (pn:@ClosedND _ Rule c), ITree _ judg2exprType c.
refine ((
fix closed2expr' j (pn:@ClosedND _ Rule j) {struct pn} : ITree _ judg2exprType j :=
match pn in @ClosedND _ _ J return ITree _ judg2exprType J with
- | cnd_weak => let case_nil := tt in _
- | cnd_rule h c cnd' r => let case_rule := tt in (fun rest => _) (closed2expr' _ cnd')
- | cnd_branch _ _ c1 c2 => let case_branch := tt in (fun rest1 rest2 => _) (closed2expr' _ c1) (closed2expr' _ c2)
+ | cnd_weak => let case_nil := tt in INone _ _
+ | cnd_rule h c cnd' r => let case_rule := tt in rule2expr _ _ r (closed2expr' _ cnd')
+ | cnd_branch _ _ c1 c2 => let case_branch := tt in IBranch _ _ (closed2expr' _ c1) (closed2expr' _ c2)
end)); clear closed2expr'; intros; subst.
-
- destruct case_nil.
- apply INone.
-
- destruct case_rule.
- eapply rule2expr.
- apply r.
- apply rest.
-
- destruct case_branch.
- apply IBranch.
- apply rest1.
- apply rest2.
Defined.
- Definition proof2expr Γ Δ τ Σ : ND Rule [] [Γ > Δ > Σ |- [τ]] -> { ξ:VV -> LeveledHaskType Γ ★ & Expr Γ Δ ξ τ }.
+ Definition proof2expr Γ Δ τ Σ (ξ0: VV -> LeveledHaskType Γ ★)
+ {zz:ToString VV} : ND Rule [] [Γ > Δ > Σ |- [τ]] ->
+ FreshM (???{ ξ : _ & Expr Γ Δ ξ τ}).
intro pf.
set (closedFromSCND _ _ (mkSCND systemfc_all_rules_one_conclusion _ _ _ pf (scnd_weak [])) cnd_weak) as cnd.
apply closed2expr in cnd.
- inversion cnd; subst.
- simpl in X.
- clear cnd pf.
- destruct X.
- exists x.
- inversion e.
- subst.
- apply X.
+ apply ileaf in cnd.
+ simpl in *.
+ clear pf.
+ refine (bind ξvars = manyFresh _ Σ ξ0; _).
+ apply FreshMon.
+ destruct ξvars as [vars ξpf].
+ destruct ξpf as [ξ pf].
+ refine (cnd ξ vars _ >>>= fun it => _).
+ apply FreshMon.
+ auto.
+ refine (return OK _).
+ exists ξ.
+ apply (ileaf it).
Defined.
End HaskProofToStrong.