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3 changed files with 132 additions and 48 deletions
34
coq/terms.v
34
coq/terms.v
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@ -36,10 +36,36 @@ Coercion type_var : string >-> type_term.
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Coercion expr_var : string >-> expr_term.
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Coercion expr_var : string >-> expr_term.
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(*
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(*
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Notation "( x )" := x (at level 70).
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Coercion type_var : string >-> type_term.
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Notation "x ~ y" := (type_rung x y) (at level 69, left associativity).
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Coercion expr_var : string >-> expr_term.
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Notation "< x y >" := (type_app x y) (at level 68, left associativity).
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Notation "'$' x" := (type_id x) (at level 66).
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*)
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*)
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Declare Scope ladder_type_scope.
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Declare Scope ladder_expr_scope.
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Declare Custom Entry ladder_type.
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Notation "[ e ]" := e (e custom ladder_type at level 80) : ladder_type_scope.
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(* TODO: allow any variable names in notation, not just α,β,γ *)
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Notation "'∀α.' τ" := (type_univ "α" τ) (in custom ladder_type at level 80) : ladder_type_scope.
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Notation "'∀β.' τ" := (type_univ "β" τ) (in custom ladder_type at level 80) : ladder_type_scope.
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Notation "'∀γ.' τ" := (type_univ "γ" τ) (in custom ladder_type at level 80) : ladder_type_scope.
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Notation "'<' σ τ '>'" := (type_spec σ τ) (in custom ladder_type at level 80, left associativity) : ladder_type_scope.
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Notation "'(' τ ')'" := τ (in custom ladder_type at level 70) : ladder_type_scope.
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Notation "σ '->' τ" := (type_fun σ τ) (in custom ladder_type at level 75, right associativity) : ladder_type_scope.
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Notation "σ '->morph' τ" := (type_morph σ τ) (in custom ladder_type at level 75, right associativity) : ladder_type_scope.
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Notation "σ '~' τ" := (type_ladder σ τ) (in custom ladder_type at level 70, right associativity) : ladder_type_scope.
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Notation "'α'" := (type_var "α") (in custom ladder_type at level 60, right associativity) : ladder_type_scope.
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Notation "'β'" := (type_var "β") (in custom ladder_type at level 60, right associativity) : ladder_type_scope.
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Notation "'γ'" := (type_var "γ") (in custom ladder_type at level 60, right associativity) : ladder_type_scope.
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Open Scope ladder_type_scope.
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Definition t1 : type_term := [ ∀α.∀β.(α~β~γ)->β->(α->α)->β ].
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Compute t1.
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Close Scope ladder_type_scope.
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End Terms.
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End Terms.
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72
coq/typing.v
72
coq/typing.v
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@ -21,35 +21,69 @@ Inductive context_contains : context -> string -> type_term -> Prop :=
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(context_contains Γ x X) ->
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(context_contains Γ x X) ->
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(context_contains (ctx_assign y Y Γ) x X).
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(context_contains (ctx_assign y Y Γ) x X).
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Reserved Notation "Gamma '|-' x '\in' X" (at level 101, x at next level, X at level 0).
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Reserved Notation "Gamma '|-' x '\is' X" (at level 101, x at next level, X at level 0).
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Reserved Notation "Gamma '|-' x '\compatible' X" (at level 101, x at next level, X at level 0).
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Inductive expr_type : context -> expr -> ladder_type -> Prop :=
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Inductive expr_type : context -> expr_term -> type_term -> Prop :=
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| T_Var : forall Γ x X,
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| T_Var : forall Γ x τ,
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(context_contains Γ x X) ->
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(context_contains Γ x τ) ->
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Γ |- x \in X
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(Γ |- x \is τ)
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| T_Let : forall Γ s (σ:ladder_type) t τ x,
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| T_Let : forall Γ s (σ:type_term) t τ x,
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Γ |- s \in σ ->
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(Γ |- s \is σ) ->
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Γ |- t \in τ ->
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(Γ |- t \is τ) ->
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Γ |- (expr_let x σ s t) \in τ
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(Γ |- (expr_let x σ s t) \is τ)
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| T_Abs : forall (Γ:context) (x:string) (X:ladder_type) (t:expr) (T:ladder_type),
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| T_TypeAbs : forall Γ (e:expr_term) (τ:type_term) α,
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Γ |- t \in T ->
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Γ |- e \is τ ->
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Γ |- (expr_tm_abs x X t) \in (type_fun X T)
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Γ |- (expr_ty_abs α e) \is (type_univ α τ)
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| T_App : forall (Γ:context) (f:expr) (a:expr) (S:ladder_type) (T:ladder_type),
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| T_TypeApp : forall Γ α (e:expr_term) (σ:type_term) (τ:type_term),
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Γ |- f \in (type_fun S T) ->
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Γ |- e \is (type_univ α τ) ->
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Γ |- a \in S ->
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Γ |- (expr_ty_app e σ) \is (type_subst α σ τ)
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Γ |- (expr_tm_app f a) \in T
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where "Γ '|-' x '\in' X" := (expr_type Γ x X).
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| T_Abs : forall (Γ:context) (x:string) (σ:type_term) (t:expr_term) (τ:type_term),
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(context_contains Γ x σ) ->
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Γ |- t \is τ ->
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Γ |- (expr_tm_abs x σ t) \is (type_fun σ τ)
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| T_App : forall (Γ:context) (f:expr_term) (a:expr_term) (σ:type_term) (τ:type_term),
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Γ |- f \is (type_fun σ τ) ->
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Γ |- a \is σ ->
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Γ |- (expr_tm_app f a) \is τ
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where "Γ '|-' x '\is' τ" := (expr_type Γ x τ).
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Inductive expr_type_compatible : context -> expr_term -> type_term -> Prop :=
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| T_Compatible : forall Γ x τ,
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(Γ |- x \is τ) ->
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(Γ |- x \compatible τ)
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where "Γ '|-' x '\compatible' τ" := (expr_type_compatible Γ x τ).
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Example typing1 :
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Example typing1 :
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ctx_empty |-
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forall Γ,
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(expr_ty_abs "T" (expr_tm_abs "x" (type_var "T") (expr_var "x"))) \in
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(context_contains Γ "x" (type_var "T")) ->
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Γ |- (expr_ty_abs "T" (expr_tm_abs "x" (type_var "T") (expr_var "x"))) \is
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(type_univ "T" (type_fun (type_var "T") (type_var "T"))).
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(type_univ "T" (type_fun (type_var "T") (type_var "T"))).
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Proof.
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Proof.
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intros.
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apply T_TypeAbs.
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apply T_Abs.
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apply H.
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apply T_Var.
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apply H.
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Admitted.
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Example typing2 :
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ctx_empty |- (expr_ty_abs "T" (expr_tm_abs "x" (type_var "T") (expr_var "x"))) \is
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(type_univ "T" (type_fun (type_var "T") (type_var "T"))).
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Proof.
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apply T_TypeAbs.
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apply T_Abs.
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Admitted.
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Admitted.
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End Typing.
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End Typing.
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@ -176,11 +176,11 @@ $$\\$$
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\metavariable{x} \quad \valnonterm{\typevars}{\exprvars}
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\metavariable{x} \quad \valnonterm{\typevars}{\exprvars}
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}{Value Conactenation}
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}{Value Conactenation}
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%\otherform{
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\otherform{
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% \exprterminal{\Lambda} \metavariable{\alpha} \quad
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\exprterminal{\Lambda} \metavariable{\alpha} \quad
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% \exprterminal{\mapsto} \quad
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\exprterminal{\mapsto} \quad
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% \valnonterm{ \typevars \cup \{ \metavariable{\alpha} \} }
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\valnonterm{ \typevars \cup \{ \metavariable{\alpha} \} }
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%}{Type-Function Value}
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\{Type-Function Value}
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\otherform{
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\otherform{
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\exprterminal{\lambda} \metavariable{x} \quad
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\exprterminal{\lambda} \metavariable{x} \quad
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@ -371,8 +371,8 @@ As usual, each rule is composed of premises (above the horizontal line) and a co
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}
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}
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\inferrule[T-TypeApp]{
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\inferrule[T-TypeApp]{
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\Gamma \vdash \metavariable{e} : \metavariable{\tau} \\
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\metavariable{\tau} \in \typenonterm{\typevars \cup \{\metavariable{\alpha}\}} \\
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\metavariable{\tau} \in \typenonterm{\typevars \cup \metavariable{\alpha}} \\
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\Gamma \vdash \metavariable{e} : \typeterminal{\forall} \metavariable{\alpha} \typeterminal{.} \metavariable{\tau} \\
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\metavariable{\sigma} \in \typenonterm{\typevars}
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\metavariable{\sigma} \in \typenonterm{\typevars}
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}{
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}{
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\Gamma \vdash ( \metavariable{e} \quad \metavariable{\sigma} ) : \{\metavariable{\alpha} \mapsto \metavariable{\sigma}\} \metavariable{\tau}
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\Gamma \vdash ( \metavariable{e} \quad \metavariable{\sigma} ) : \{\metavariable{\alpha} \mapsto \metavariable{\sigma}\} \metavariable{\tau}
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@ -520,42 +520,66 @@ which are given in \ref{def:evalrules}.
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\begin{lemma}[\(\beta\)-reduction preserves \(\delta\)-normalform]
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\begin{lemma}[\(\beta\)-reduction preserves \(\delta\)-normalform]
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Assume \metavariable{e} is in \(\delta\)-normalform and \(\metavariable{e} \rightarrow \metavariable{e'}\). Then \(\metavariable{e'}\) is in \(\delta\)-normalform as well.
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\label{lemma:preserve-delta-normalform}
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Assume \metavariable{e} is in \(\delta\)-normalform and \(\metavariable{e} \rightarrow_\beta \metavariable{e'}\). Then \(\metavariable{e'}\) is in \(\delta\)-normalform as well.
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\begin{proof}
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\begin{proof}
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\todo{}
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\todo{}
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\end{proof}
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\end{proof}
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\end{lemma}
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\end{lemma}
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\begin{lemma}[\(\delta\)-normalform eliminates compatibility]
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\label{lemma:eliminate-compat}
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Assume \(\emptyset \vdash \metavariable{e} :\approx \metavariable{\tau}\) and \(\metavariable{e} \rightarrow_{\delta}^* \metavariable{e'}\) such that \(\metavariable{e'}\) is in \(\delta\)-normalform.
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Then \(\emptyset \vdash \metavariable{e'} : \metavariable{\tau}\)
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\begin{proof}
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\end{proof}
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\end{lemma}
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\subsection{Proof of Syntactic Type Soundness}
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\subsection{Proof of Syntactic Type Soundness}
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\begin{lemma}[\(\beta\)-Preservation]
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\label{lemma:beta-preservation}
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Assume the expression \(\metavariable{e}\) is \textbf{syntactically well-typed}, i.e. \(\emptyset \vdash \metavariable{e} : \metavariable{\tau}\) for some type \(\metavariable{\tau}\). Then forall \(\metavariable{e'}\) with \(\metavariable{e} \rightarrow_{\beta} \metavariable{e'}\) it holds that \(\emptyset \vdash \metavariable{e'} : \metavariable{\tau}\) as well.
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\begin{proof}
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\todo{}
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\end{proof}
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\end{lemma}
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\begin{lemma}[\(\delta\)-Preservation]
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\label{lemma:delta-preservation}
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\begin{proof}
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\todo{}
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\end{proof}
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\end{lemma}
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\begin{lemma}[Preservation]
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\label{lemma:preservation}
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Assume the expression \(\metavariable{e}\) is well typed, i.e. \(\emptyset \vdash \metavariable{e} : \metavariable{\tau}\) for some type \(\metavariable{\tau}\). Then forall \(\metavariable{e'}\) with \(\metavariable{e} \rightarrow_{eval} \metavariable{e'}\) it holds that \(\emptyset \vdash \metavariable{e'} : \metavariable{\tau}\) as well.
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\begin{proof}
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\todo{}
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\end{proof}
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\end{lemma}
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\begin{lemma}[Progress]
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\begin{lemma}[Progress]
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\label{lemma:progress}
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\label{lemma:progress}
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If \(\emptyset \vdash \metavariable{e} : \metavariable{\tau}\), then either \(\metavariable{e}\) is a value or there exists some \(\metavariable{e'}\) such that \(\metavariable{e} \rightarrow_{eval} \metavariable{e'}\)
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If \(\emptyset \vdash \metavariable{e} : \metavariable{\tau}\), then either \(\metavariable{e}\) is a value or there exists some \(\metavariable{e'}\) such that \(\metavariable{e} \rightarrow_{eval} \metavariable{e'}\)
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\begin{proof}
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\begin{proof}
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\todo{}
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\todo{}
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\end{proof}
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\end{proof}
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\end{lemma}
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\end{lemma}
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\begin{theorem}[Soundness]
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\begin{lemma}[Preservation]
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If \(\emptyset \vdash \metavariable{e}:\approx\metavariable{\tau}\), then it never occurs that \(\metavariable{e} \rightarrow_{eval}^{*} \metavariable{e'}\) where \metavariable{e'} is in normal form but not a value.
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\label{lemma:preservation}
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\begin{proof}
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\todo{}
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\end{proof}
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\end{lemma}
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\begin{theorem}[Type Soundness]
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If \(\emptyset \vdash \metavariable{e}:\metavariable{\tau}\), then it never occurs that \(\metavariable{e} \rightarrow_{eval}^{*} \metavariable{e'}\) where \metavariable{e'} is in normal form but not a value.
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\begin{proof}
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\begin{proof}
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By \ref{lemma:}
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Follows from \ref{lemma:progress} and \ref{lemma:preservation}.
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Follows from \ref{lemma:progress} and \ref{lemma:preservation}.
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\end{proof}
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\end{proof}
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\end{theorem}
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\end{theorem}
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