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typeSystemScript.sml
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typeSystemScript.sml
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(*
Specification of CakeML's type system.
*)
open HolKernel Parse boolLib bossLib;
open (* libTheory *) fpValTreeTheory astTheory namespaceTheory semanticPrimitivesTheory;
val _ = numLib.temp_prefer_num();
val _ = new_theory "typeSystem"
Type type_ident = “:num”
(* Types *)
Datatype:
t =
(* Type variables that the user writes down ('a, 'b, etc.) *)
Tvar tvarN
(* deBruijn indexed type variables. *)
| Tvar_db num
(* The two numbers represent the identity of the type constructor. The first
is the identity of the compilation unit that it was defined in, and the
second is its identity inside of that unit *)
| Tapp (t list) type_ident
End
(* Some abbreviations *)
val _ = Define `
((Tarray_num:num) : type_ident= (( 0 : num)))`;
val _ = Define `
((Tbool_num:num) : type_ident= (( 1 : num)))`;
val _ = Define `
((Tchar_num:num) : type_ident= (( 2 : num)))`;
val _ = Define `
((Texn_num:num) : type_ident= (( 3 : num)))`;
val _ = Define `
((Tfn_num:num) : type_ident= (( 4 : num)))`;
val _ = Define `
((Tint_num:num) : type_ident= (( 5 : num)))`;
val _ = Define `
((Tlist_num:num) : type_ident= (( 6 : num)))`;
val _ = Define `
((Tref_num:num) : type_ident= (( 7 : num)))`;
val _ = Define `
((Tstring_num:num) : type_ident= (( 8 : num)))`;
val _ = Define `
((Ttup_num:num) : type_ident= (( 9 : num)))`;
val _ = Define `
((Tvector_num:num) : type_ident= (( 10 : num)))`;
val _ = Define `
((Tword64_num:num) : type_ident= (( 11 : num)))`;
val _ = Define `
((Tword8_num:num) : type_ident= (( 12 : num)))`;
val _ = Define `
((Tword8array_num:num) : type_ident= (( 13 : num)))`;
val _ = Define `
((Tdouble_num:num) : type_ident= (( 14 : num)))`;
val _ = Define `
((Treal_num:num) : type_ident= (( 15 : num)))`;
(* The numbers for the primitive types *)
val _ = Define `
((prim_type_nums:(num)list)=
([Tarray_num; Tchar_num; Texn_num; Tfn_num; Tint_num; Tref_num; Tstring_num; Ttup_num;
Tvector_num; Tword64_num; Tword8_num; Tword8array_num; Tdouble_num; Treal_num]))`;
val _ = Define `
((Tarray:t -> t) t= (Tapp [t] Tarray_num))`;
val _ = Define `
((Tbool:t)= (Tapp [] Tbool_num))`;
val _ = Define `
((Tchar:t)= (Tapp [] Tchar_num))`;
val _ = Define `
((Texn:t)= (Tapp [] Texn_num))`;
val _ = Define `
((Tfn:t -> t -> t) t1 t2= (Tapp [t1;t2] Tfn_num))`;
val _ = Define `
((Tint:t)= (Tapp [] Tint_num))`;
val _ = Define `
((Tlist:t -> t) t= (Tapp [t] Tlist_num))`;
val _ = Define `
((Tref:t -> t) t= (Tapp [t] Tref_num))`;
val _ = Define `
((Tstring:t)= (Tapp [] Tstring_num))`;
val _ = Define `
((Ttup:(t)list -> t) ts= (Tapp ts Ttup_num))`;
val _ = Define `
((Tvector:t -> t) t= (Tapp [t] Tvector_num))`;
val _ = Define `
((Tword64:t)= (Tapp [] Tword64_num))`;
val _ = Define `
((Tword8:t)= (Tapp [] Tword8_num))`;
val _ = Define `
((Tword8array:t)= (Tapp [] Tword8array_num))`;
val _ = Define `
((Tdouble:t)= (Tapp [] Tdouble_num))`;
val _ = Define `
((Treal:t)= (Tapp [] Treal_num))`;
(* Check that the free type variables are in the given list. Every deBruijn
* variable must be smaller than the first argument. So if it is 0, no deBruijn
* indices are permitted. *)
Definition check_freevars_def:
((check_freevars:num ->(string)list -> t -> bool) dbmax tvs (Tvar tv)=
(MEM tv tvs))
/\
((check_freevars:num ->(string)list -> t -> bool) dbmax tvs (Tapp ts tn)=
(EVERY (check_freevars dbmax tvs) ts))
/\
((check_freevars:num ->(string)list -> t -> bool) dbmax tvs (Tvar_db n)= (n < dbmax))
Termination
WF_REL_TAC `measure (t_size o SND o SND)`
End
Definition check_freevars_ast_def:
((check_freevars_ast:(string)list -> ast_t -> bool) tvs (Atvar tv)=
(MEM tv tvs))
/\
((check_freevars_ast:(string)list -> ast_t -> bool) tvs (Attup ts)=
(EVERY (check_freevars_ast tvs) ts))
/\
((check_freevars_ast:(string)list -> ast_t -> bool) tvs (Atfun t1 t2)=
(check_freevars_ast tvs t1 /\ check_freevars_ast tvs t2))
/\
((check_freevars_ast:(string)list -> ast_t -> bool) tvs (Atapp ts tn)=
(EVERY (check_freevars_ast tvs) ts))
Termination
WF_REL_TAC `measure (ast_t_size o SND)`
End
(* Simultaneous substitution of types for type variables in a type *)
Definition type_subst_def:
((type_subst:((string),(t))fmap -> t -> t) s (Tvar tv)=
((case FLOOKUP s tv of
NONE => Tvar tv
| SOME(t) => t
)))
/\
((type_subst:((string),(t))fmap -> t -> t) s (Tapp ts tn)=
(Tapp (MAP (type_subst s) ts) tn))
/\
((type_subst:((string),(t))fmap -> t -> t) s (Tvar_db n)= (Tvar_db n))
Termination
WF_REL_TAC `measure (λ(x,y). t_size y)`
End
(* Increment the deBruijn indices in a type by n levels, skipping all levels
* less than skip. *)
Definition deBruijn_inc_def:
((deBruijn_inc:num -> num -> t -> t) skip n (Tvar tv)= (Tvar tv))
/\
((deBruijn_inc:num -> num -> t -> t) skip n (Tvar_db m)=
(if m < skip then
Tvar_db m
else
Tvar_db (m + n)))
/\
((deBruijn_inc:num -> num -> t -> t) skip n (Tapp ts tn)= (Tapp (MAP (deBruijn_inc skip n) ts) tn))
Termination
WF_REL_TAC `measure (t_size o SND o SND)`
End
(* skip the lowest given indices and replace the next (LENGTH ts) with the given types and reduce all the higher ones *)
Definition deBruijn_subst_def:
((deBruijn_subst:num ->(t)list -> t -> t) skip ts (Tvar tv)= (Tvar tv))
/\
((deBruijn_subst:num ->(t)list -> t -> t) skip ts (Tvar_db n)=
(if ~ (n < skip) /\ (n < (LENGTH ts + skip)) then
EL (n - skip) ts
else if ~ (n < skip) then
Tvar_db (n - LENGTH ts)
else
Tvar_db n))
/\
((deBruijn_subst:num ->(t)list -> t -> t) skip ts (Tapp ts' tn)=
(Tapp (MAP (deBruijn_subst skip ts) ts') tn))
Termination
WF_REL_TAC `measure (λ(_,x,y). t_size y)`
End
(* Type environments *)
Datatype:
tenv_val_exp =
Empty
(* Binds several de Bruijn type variables *)
| Bind_tvar num tenv_val_exp
(* The number is how many de Bruijn type variables the typescheme binds *)
| Bind_name varN num t tenv_val_exp
End
(*val bind_tvar : nat -> tenv_val_exp -> tenv_val_exp*)
val _ = Define `
((bind_tvar:num -> tenv_val_exp -> tenv_val_exp) tvs tenvE= (if tvs =( 0 : num) then tenvE else Bind_tvar tvs tenvE))`;
(*val opt_bind_name : maybe varN -> nat -> t -> tenv_val_exp -> tenv_val_exp*)
val _ = Define `
((opt_bind_name:(string)option -> num -> t -> tenv_val_exp -> tenv_val_exp) n tvs t tenvE=
((case n of
NONE => tenvE
| SOME n' => Bind_name n' tvs t tenvE
)))`;
(*val tveLookup : varN -> nat -> tenv_val_exp -> maybe (nat * t)*)
val _ = Define `
((tveLookup:string -> num -> tenv_val_exp ->(num#t)option) n inc Empty= NONE)
/\
((tveLookup:string -> num -> tenv_val_exp ->(num#t)option) n inc (Bind_tvar tvs tenvE)= (tveLookup n (inc + tvs) tenvE))
/\
((tveLookup:string -> num -> tenv_val_exp ->(num#t)option) n inc (Bind_name n' tvs t tenvE)=
(if n' = n then
SOME (tvs, deBruijn_inc tvs inc t)
else
tveLookup n inc tenvE))`;
Type tenv_abbrev = ``: (modN, typeN, ( tvarN list # t)) namespace``
Type tenv_ctor = ``: (modN, conN, ( tvarN list # t list # type_ident)) namespace``
Type tenv_val = ``: (modN, varN, (num # t)) namespace``
Datatype:
type_env =
<| v : tenv_val
; c : tenv_ctor
; t : tenv_abbrev
|>
End
(*val extend_dec_tenv : type_env -> type_env -> type_env*)
val _ = Define `
((extend_dec_tenv:type_env -> type_env -> type_env) tenv' tenv=
(<| v := (nsAppend tenv'.v tenv.v);
c := (nsAppend tenv'.c tenv.c);
t := (nsAppend tenv'.t tenv.t) |>))`;
(*val lookup_varE : id modN varN -> tenv_val_exp -> maybe (nat * t)*)
val _ = Define `
((lookup_varE:((string),(string))id -> tenv_val_exp ->(num#t)option) id tenvE=
((case id of
Short x => tveLookup x(( 0 : num)) tenvE
| _ => NONE
)))`;
(*val lookup_var : id modN varN -> tenv_val_exp -> type_env -> maybe (nat * t)*)
val _ = Define `
((lookup_var:((modN),(varN))id -> tenv_val_exp -> type_env ->(num#t)option) id tenvE tenv=
((case lookup_varE id tenvE of
SOME x => SOME x
| NONE => nsLookup tenv.v id
)))`;
(*val num_tvs : tenv_val_exp -> nat*)
val _ = Define `
((num_tvs:tenv_val_exp -> num) Empty= (( 0 : num)))
/\
((num_tvs:tenv_val_exp -> num) (Bind_tvar tvs tenvE)= (tvs + num_tvs tenvE))
/\
((num_tvs:tenv_val_exp -> num) (Bind_name n tvs t tenvE)= (num_tvs tenvE))`;
(*val bind_var_list : nat -> list (varN * t) -> tenv_val_exp -> tenv_val_exp*)
val _ = Define `
((bind_var_list:num ->(string#t)list -> tenv_val_exp -> tenv_val_exp) tvs [] tenvE= tenvE)
/\
((bind_var_list:num ->(string#t)list -> tenv_val_exp -> tenv_val_exp) tvs ((n,t)::binds) tenvE=
(Bind_name n tvs t (bind_var_list tvs binds tenvE)))`;
(* A pattern matches values of a certain type and extends the type environment
* with the pattern's binders. The number is the maximum deBruijn type variable
* allowed. *)
(*val type_p : nat -> type_env -> pat -> t -> list (varN * t) -> bool*)
(* An expression has a type *)
(*val type_e : type_env -> tenv_val_exp -> exp -> t -> bool*)
(* A list of expressions has a list of types *)
(*val type_es : type_env -> tenv_val_exp -> list exp -> list t -> bool*)
(* Type a mutually recursive bundle of functions. Unlike pattern typing, the
* resulting environment does not extend the input environment, but just
* represents the functions *)
(*val type_funs : type_env -> tenv_val_exp -> list (varN * varN * exp) -> list (varN * t) -> bool*)
(* Check a declaration and update the top-level environments
* The arguments are in order:
* - whether to do extra checks
* - the type environment
* - the declaration
* - the set of type identity stamps defined here
* - the environment of new stuff declared here *)
(*val type_d : bool -> type_env -> dec -> set nat -> type_env -> bool*)
(*val type_ds : bool -> type_env -> list dec -> set nat -> type_env -> bool*)
(* Check that the operator can have type (t1 -> ... -> tn -> t) *)
(*val type_op : op -> list t -> t -> bool*)
val _ = Define `
((type_op:op ->(t)list -> t -> bool) op ts t=
((case (op,ts) of
(Opapp, [t1; t2]) => t1 = Tfn t2 t
| (Opn _, [t1; t2]) => (t1 = Tint) /\ (t2 = Tint) /\ (t = Tint)
| (Opb _, [t1; t2]) => (t1 = Tint) /\ (t2 = Tint) /\ (t = Tbool)
| (Opw W8 _, [t1; t2]) => (t1 = Tword8) /\ (t2 = Tword8) /\ (t = Tword8)
| (Opw W64 _, [t1; t2]) => (t1 = Tword64) /\ (t2 = Tword64) /\ (t = Tword64)
| (FP_top _, [t1; t2; t3]) => (t1 = Tdouble) /\ (t2 = Tdouble) /\ (t3 = Tdouble) /\ (t = Tdouble)
| (FP_bop _, [t1; t2]) => (t1 = Tdouble) /\ (t2 = Tdouble) /\ (t = Tdouble)
| (FP_uop _, [t1]) => ((t1 = Tdouble) /\ (t = Tdouble))
| (FP_cmp _, [t1; t2]) => (t1 = Tdouble) /\ (t2 = Tdouble) /\ (t = Tbool)
| (FpToWord, [t1]) => (t1 = Tdouble) /\ (t = Tword64)
| (FpFromWord, [t1]) => (t1 = Tword64) /\ (t = Tdouble)
| (Real_cmp _, [t1; t2]) => F (* t1 = Treal && t2 = Treal && t = Tbool *)
| (Real_bop _, [t1; t2]) => F (* t1 = Treal && t2 = Treal && t = Treal *)
| (Real_uop _, [t1]) => F (* t1 = Treal && t = Treal *)
| (RealFromFP, [t1]) => F
| (Shift W8 _ _, [t1]) => (t1 = Tword8) /\ (t = Tword8)
| (Shift W64 _ _, [t1]) => (t1 = Tword64) /\ (t = Tword64)
| (Equality, [t1; t2]) => (t1 = t2) /\ (t = Tbool)
| (Opassign, [t1; t2]) => (t1 = Tref t2) /\ (t = Ttup [])
| (Opref, [t1]) => t = Tref t1
| (Opderef, [t1]) => t1 = Tref t
| (Aw8alloc, [t1; t2]) => (t1 = Tint) /\ (t2 = Tword8) /\ (t = Tword8array)
| (Aw8sub, [t1; t2]) => (t1 = Tword8array) /\ (t2 = Tint) /\ (t = Tword8)
| (Aw8length, [t1]) => (t1 = Tword8array) /\ (t = Tint)
| (Aw8update, [t1; t2; t3]) => (t1 = Tword8array) /\ (t2 = Tint) /\ (t3 = Tword8) /\ (t = Ttup [])
| (WordFromInt W8, [t1]) => (t1 = Tint) /\ (t = Tword8)
| (WordToInt W8, [t1]) => (t1 = Tword8) /\ (t = Tint)
| (WordFromInt W64, [t1]) => (t1 = Tint) /\ (t = Tword64)
| (WordToInt W64, [t1]) => (t1 = Tword64) /\ (t = Tint)
| (CopyStrStr, [t1; t2; t3]) => (t1 = Tstring) /\ (t2 = Tint) /\ (t3 = Tint) /\ (t = Tstring)
| (CopyStrAw8, [t1; t2; t3; t4; t5]) =>
(t1 = Tstring) /\ (t2 = Tint) /\ (t3 = Tint) /\ (t4 = Tword8array) /\ (t5 = Tint) /\ (t = Ttup [])
| (CopyAw8Str, [t1; t2; t3]) => (t1 = Tword8array) /\ (t2 = Tint) /\ (t3 = Tint) /\ (t = Tstring)
| (CopyAw8Aw8, [t1; t2; t3; t4; t5]) =>
(t1 = Tword8array) /\ (t2 = Tint) /\ (t3 = Tint) /\ (t4 = Tword8array) /\ (t5 = Tint) /\ (t = Ttup [])
| (Chr, [t1]) => (t1 = Tint) /\ (t = Tchar)
| (Ord, [t1]) => (t1 = Tchar) /\ (t = Tint)
| (Chopb _, [t1; t2]) => (t1 = Tchar) /\ (t2 = Tchar) /\ (t = Tbool)
| (Implode, [t1]) => (t1 = Tlist Tchar) /\ (t = Tstring)
| (Explode, [t1]) => (t1 = Tstring) /\ (t = Tlist Tchar)
| (Strsub, [t1; t2]) => (t1 = Tstring) /\ (t2 = Tint) /\ (t = Tchar)
| (Strlen, [t1]) => (t1 = Tstring) /\ (t = Tint)
| (Strcat, [t1]) => (t1 = Tlist Tstring) /\ (t = Tstring)
| (VfromList, [Tapp [t1] ctor]) => (ctor = Tlist_num) /\ (t = Tvector t1)
| (Vsub, [t1; t2]) => (t2 = Tint) /\ (Tvector t = t1)
| (Vlength, [Tapp [t1] ctor]) => (ctor = Tvector_num) /\ (t = Tint)
| (Aalloc, [t1; t2]) => (t1 = Tint) /\ (t = Tarray t2)
| (AallocEmpty, [t1]) => (t1 = Ttup []) /\ (? t2. t = Tarray t2)
| (Asub, [t1; t2]) => (t2 = Tint) /\ (Tarray t = t1)
| (Alength, [Tapp [t1] ctor]) => (ctor = Tarray_num) /\ (t = Tint)
| (Aupdate, [t1; t2; t3]) => (t1 = Tarray t3) /\ (t2 = Tint) /\ (t = Ttup [])
| (ConfigGC, [t1;t2]) => (t1 = Tint) /\ (t2 = Tint) /\ (t = Ttup [])
| (FFI n, [t1;t2]) => (t1 = Tstring) /\ (t2 = Tword8array) /\ (t = Ttup [])
| (ListAppend, [Tapp [t1] ctor; t2]) => (ctor = Tlist_num) /\ (t2 = Tapp [t1] ctor) /\ (t = t2)
| _ => F
)))`;
Definition check_type_names_def:
((check_type_names:((string),(string),((string)list#t))namespace -> ast_t -> bool) tenvT (Atvar tv)=
T)
/\
((check_type_names:((string),(string),((string)list#t))namespace -> ast_t -> bool) tenvT (Attup ts)=
(EVERY (check_type_names tenvT) ts))
/\
((check_type_names:((string),(string),((string)list#t))namespace -> ast_t -> bool) tenvT (Atfun t1 t2)=
(check_type_names tenvT t1 /\ check_type_names tenvT t2))
/\
((check_type_names:((string),(string),((string)list#t))namespace -> ast_t -> bool) tenvT (Atapp ts tn)=
((case nsLookup tenvT tn of
SOME (tvs, _) => LENGTH tvs = LENGTH ts
| NONE => F
) /\
EVERY (check_type_names tenvT) ts))
Termination
WF_REL_TAC `measure (λ(x,y). ast_t_size y)`
End
(* Substitution of type names for the type they abbreviate *)
Definition type_name_subst_def:
((type_name_subst:((string),(string),((string)list#t))namespace -> ast_t -> t) tenvT (Atvar tv)= (Tvar tv))
/\
((type_name_subst:((string),(string),((string)list#t))namespace -> ast_t -> t) tenvT (Attup ts)=
(Ttup (MAP (type_name_subst tenvT) ts)))
/\
((type_name_subst:((string),(string),((string)list#t))namespace -> ast_t -> t) tenvT (Atfun t1 t2)=
(Tfn (type_name_subst tenvT t1) (type_name_subst tenvT t2)))
/\
((type_name_subst:((string),(string),((string)list#t))namespace -> ast_t -> t) tenvT (Atapp ts tc)=
(let args = (MAP (type_name_subst tenvT) ts) in
(case nsLookup tenvT tc of
SOME (tvs, t) => type_subst (alist_to_fmap (ZIP (tvs, args))) t
| NONE => Ttup args (* can't happen, for a type that passes the check *)
)))
Termination
WF_REL_TAC `measure (λ(x,y). ast_t_size y)`
End
(* Check that a type definition defines no already defined types or duplicate
* constructors, and that the free type variables of each constructor argument
* type are included in the type's type parameters. Also check that all of the
* types mentioned are in scope. *)
(*val check_ctor_tenv : tenv_abbrev -> list (list tvarN * typeN * list (conN * list ast_t)) -> bool*)
val _ = Define `
((check_ctor_tenv:((modN),(typeN),((tvarN)list#t))namespace ->((tvarN)list#string#(conN#(ast_t)list)list)list -> bool) tenvT []= T)
/\ ((check_ctor_tenv:((modN),(typeN),((tvarN)list#t))namespace ->((tvarN)list#string#(conN#(ast_t)list)list)list -> bool) tenvT ((tvs,tn,ctors)::tds)=
(check_dup_ctors (tvs,tn,ctors) /\
ALL_DISTINCT tvs /\
EVERY
(\ (cn,ts) . EVERY (check_freevars_ast tvs) ts /\ EVERY (check_type_names tenvT) ts)
ctors /\
~ (MEM tn (MAP (\p .
(case (p ) of ( (_,tn,_) ) => tn )) tds)) /\
check_ctor_tenv tenvT tds))`;
(*val build_ctor_tenv : tenv_abbrev -> list (list tvarN * typeN * list (conN * list ast_t)) -> list nat -> tenv_ctor*)
val _ = Define `
(build_ctor_tenv tenvT [] []= (alist_to_ns []))
/\ (build_ctor_tenv tenvT ((tvs,tn,ctors)::tds) (id::ids)=
(nsAppend
(build_ctor_tenv tenvT tds ids)
(alist_to_ns
(REVERSE
(MAP
(\ (cn,ts) . (cn,(tvs,MAP (type_name_subst tenvT) ts, id)))
ctors)))))
/\ (build_ctor_tenv tenvT _ _= (alist_to_ns []))`;
(* For the value restriction on let-based polymorphism *)
Definition is_value_def:
((is_value:exp -> bool) (Lit _)= T)
/\
((is_value:exp -> bool) (Con _ es)= (EVERY is_value es))
/\
((is_value:exp -> bool) (Var _)= T)
/\
((is_value:exp -> bool) (Fun _ _)= T)
/\
((is_value:exp -> bool) (Tannot e _)= (is_value e))
/\
((is_value:exp -> bool) (Lannot e _)= (is_value e))
/\
((is_value:exp -> bool) _= F)
Termination
WF_REL_TAC `measure (exp_size)`
End
Inductive type_p:
(! tvs tenv t.
(check_freevars tvs [] t)
==>
type_p tvs tenv Pany t [])
/\ (! tvs tenv n t.
(check_freevars tvs [] t)
==>
type_p tvs tenv (Pvar n) t [(n,t)])
/\ (! tvs tenv n.
T
==>
type_p tvs tenv (Plit (IntLit n)) Tint [])
/\ (! tvs tenv c.
T
==>
type_p tvs tenv (Plit (Char c)) Tchar [])
/\ (! tvs tenv s.
T
==>
type_p tvs tenv (Plit (StrLit s)) Tstring [])
/\ (! tvs tenv w.
T
==>
type_p tvs tenv (Plit (Word8 w)) Tword8 [])
/\ (! tvs tenv w.
T
==>
type_p tvs tenv (Plit (Word64 w)) Tword64 [])
/\ (! tvs tenv cn ps ts tvs' tn ts' bindings.
(EVERY (check_freevars tvs []) ts' /\
(LENGTH ts' = LENGTH tvs') /\
type_ps tvs tenv ps (MAP (type_subst (alist_to_fmap (ZIP (tvs', ts')))) ts) bindings /\
(nsLookup tenv.c cn = SOME (tvs', ts, tn)))
==>
type_p tvs tenv (Pcon (SOME cn) ps) (Tapp ts' tn) bindings)
/\ (! tvs tenv ps ts bindings.
(type_ps tvs tenv ps ts bindings)
==>
type_p tvs tenv (Pcon NONE ps) (Ttup ts) bindings)
/\ (! tvs tenv p t bindings.
(type_p tvs tenv p t bindings)
==>
type_p tvs tenv (Pref p) (Tref t) bindings)
/\ (!tvs tenv pat v t bindings.
(type_p tvs tenv pat t bindings)
==>
type_p tvs tenv (Pas pat v) t (bindings ++ [(v,t)]))
/\ (! tvs tenv p t bindings.
(check_freevars_ast [] t /\
check_type_names tenv.t t /\
type_p tvs tenv p (type_name_subst tenv.t t) bindings)
==>
type_p tvs tenv (Ptannot p t) (type_name_subst tenv.t t) bindings)
/\ (! tvs tenv.
T
==>
type_ps tvs tenv [] [] [])
/\ (! tvs tenv p ps t ts bindings bindings'.
(type_p tvs tenv p t bindings /\
type_ps tvs tenv ps ts bindings')
==>
type_ps tvs tenv (p::ps) (t::ts) (bindings'++bindings))
End
Inductive type_e:
(! tenv tenvE n.
T
==>
type_e tenv tenvE (Lit (IntLit n)) Tint)
/\ (! tenv tenvE c.
T
==>
type_e tenv tenvE (Lit (Char c)) Tchar)
/\ (! tenv tenvE s.
T
==>
type_e tenv tenvE (Lit (StrLit s)) Tstring)
/\ (! tenv tenvE w.
T
==>
type_e tenv tenvE (Lit (Word8 w)) Tword8)
/\ (! tenv tenvE w.
T
==>
type_e tenv tenvE (Lit (Word64 w)) Tword64)
/\ (! tenv tenvE e t.
(check_freevars (num_tvs tenvE) [] t /\
type_e tenv tenvE e Texn)
==>
type_e tenv tenvE (Raise e) t)
/\ (! tenv tenvE e pes t.
(type_e tenv tenvE e t /\ ~ (pes = []) /\
(! ((p,e) :: LIST_TO_SET pes). ? bindings.
ALL_DISTINCT (pat_bindings p []) /\
type_p (num_tvs tenvE) tenv p Texn bindings /\
type_e tenv (bind_var_list(( 0 : num)) bindings tenvE) e t))
==>
type_e tenv tenvE (Handle e pes) t)
/\ (! tenv tenvE cn es tvs tn ts' ts.
(EVERY (check_freevars (num_tvs tenvE) []) ts' /\
(LENGTH tvs = LENGTH ts') /\
type_es tenv tenvE es (MAP (type_subst (alist_to_fmap (ZIP (tvs, ts')))) ts) /\
(nsLookup tenv.c cn = SOME (tvs, ts, tn)))
==>
type_e tenv tenvE (Con (SOME cn) es) (Tapp ts' tn))
/\ (! tenv tenvE es ts.
(type_es tenv tenvE es ts)
==>
type_e tenv tenvE (Con NONE es) (Ttup ts))
/\ (! tenv tenvE n t targs tvs.
((tvs = LENGTH targs) /\
EVERY (check_freevars (num_tvs tenvE) []) targs /\
(lookup_var n tenvE tenv = SOME (tvs,t)))
==>
type_e tenv tenvE (Var n) (deBruijn_subst(( 0 : num)) targs t))
/\ (! tenv tenvE n e t1 t2.
(check_freevars (num_tvs tenvE) [] t1 /\
type_e tenv (Bind_name n(( 0 : num)) t1 tenvE) e t2)
==>
type_e tenv tenvE (Fun n e) (Tfn t1 t2))
/\ (! tenv tenvE op es ts t.
(type_es tenv tenvE es ts /\
type_op op ts t /\
check_freevars (num_tvs tenvE) [] t)
==>
type_e tenv tenvE (App op es) t)
/\ (! tenv tenvE l e1 e2.
(type_e tenv tenvE e1 Tbool /\
type_e tenv tenvE e2 Tbool)
==>
type_e tenv tenvE (Log l e1 e2) Tbool)
/\ (! tenv tenvE e1 e2 e3 t.
(type_e tenv tenvE e1 Tbool /\
type_e tenv tenvE e2 t /\
type_e tenv tenvE e3 t)
==>
type_e tenv tenvE (If e1 e2 e3) t)
/\ (! tenv tenvE e pes t1 t2.
(type_e tenv tenvE e t1 /\ ~ (pes = []) /\
(! ((p,e) :: LIST_TO_SET pes) . ? bindings.
ALL_DISTINCT (pat_bindings p []) /\
type_p (num_tvs tenvE) tenv p t1 bindings /\
type_e tenv (bind_var_list(( 0 : num)) bindings tenvE) e t2))
==>
type_e tenv tenvE (Mat e pes) t2)
/\ (! tenv tenvE n e1 e2 t1 t2.
(type_e tenv tenvE e1 t1 /\
type_e tenv (opt_bind_name n(( 0 : num)) t1 tenvE) e2 t2)
==>
type_e tenv tenvE (Let n e1 e2) t2)
(*
and
letrec : forall tenv tenvE funs e t tenv' tvs.
type_funs tenv (bind_var_list 0 tenv' (bind_tvar tvs tenvE)) funs tenv' &&
type_e tenv (bind_var_list tvs tenv' tenvE) e t
==>
type_e tenv tenvE (Letrec funs e) t
*)
/\ (! tenv tenvE funs e t bindings.
(type_funs tenv (bind_var_list(( 0 : num)) bindings tenvE) funs bindings /\
type_e tenv (bind_var_list(( 0 : num)) bindings tenvE) e t)
==>
type_e tenv tenvE (Letrec funs e) t)
/\ (! tenv tenvE e t.
(check_freevars_ast [] t /\
check_type_names tenv.t t /\
type_e tenv tenvE e (type_name_subst tenv.t t))
==>
type_e tenv tenvE (Tannot e t) (type_name_subst tenv.t t))
/\ (! tenv tenvE e l t.
(type_e tenv tenvE e t)
==>
type_e tenv tenvE (Lannot e l) t)
/\ (! tenv tenvE e opt t.
(type_e tenv tenvE e t)
==>
type_e tenv tenvE (FpOptimise opt e) t)
/\ (! tenv tenvE.
T
==>
type_es tenv tenvE [] [])
/\ (! tenv tenvE e es t ts.
(type_e tenv tenvE e t /\
type_es tenv tenvE es ts)
==>
type_es tenv tenvE (e::es) (t::ts))
/\ (! tenv tenvE.
T
==>
type_funs tenv tenvE [] [])
/\ (! tenv tenvE fn n e funs bindings t1 t2.
(check_freevars (num_tvs tenvE) [] (Tfn t1 t2) /\
type_e tenv (Bind_name n(( 0 : num)) t1 tenvE) e t2 /\
type_funs tenv tenvE funs bindings /\
(ALOOKUP bindings fn = NONE))
==>
type_funs tenv tenvE ((fn, n, e)::funs) ((fn, Tfn t1 t2)::bindings))
End
(*val tenv_add_tvs : nat -> alist varN t -> alist varN (nat * t)*)
val _ = Define `
((tenv_add_tvs:num ->(string#t)list ->(string#(num#t))list) tvs bindings=
(MAP (\ (n,t) . (n,(tvs,t))) bindings))`;
(*val type_pe_determ : type_env -> tenv_val_exp -> pat -> exp -> bool*)
val _ = Define `
((type_pe_determ:type_env -> tenv_val_exp -> pat -> exp -> bool) tenv tenvE p e=
(! t1 tenv1 t2 tenv2.
(type_p(( 0 : num)) tenv p t1 tenv1 /\ type_e tenv tenvE e t1 /\
type_p(( 0 : num)) tenv p t2 tenv2 /\ type_e tenv tenvE e t2)
==>
(tenv1 = tenv2)))`;
(*val tscheme_inst : (nat * t) -> (nat * t) -> bool*)
val _ = Define `
((tscheme_inst:num#t -> num#t -> bool) (tvs_spec, t_spec) (tvs_impl, t_impl)=
(? subst.
(LENGTH subst = tvs_impl) /\
check_freevars tvs_impl [] t_impl /\
EVERY (check_freevars tvs_spec []) subst /\
(deBruijn_subst(( 0 : num)) subst t_impl = t_spec)))`;
val _ = Define `
((tenvLift:string -> type_env -> type_env) mn tenv=
(<| v := (nsLift mn tenv.v); c := (nsLift mn tenv.c); t := (nsLift mn tenv.t) |>))`;
Inductive type_d:
(! extra_checks tvs tenv p e t bindings locs.
(is_value e /\
ALL_DISTINCT (pat_bindings p []) /\
type_p tvs tenv p t bindings /\
type_e tenv (bind_tvar tvs Empty) e t /\
(extra_checks ==>
(! tvs' bindings' t'.
(type_p tvs' tenv p t' bindings' /\
type_e tenv (bind_tvar tvs' Empty) e t') ==>
EVERY2 tscheme_inst (MAP SND (tenv_add_tvs tvs' bindings')) (MAP SND (tenv_add_tvs tvs bindings)))))
==>
type_d extra_checks tenv (Dlet locs p e)
{}
<| v := (alist_to_ns (tenv_add_tvs tvs bindings)); c := nsEmpty; t := nsEmpty |>)
/\ (! extra_checks tenv p e t bindings locs.
(
(* The following line makes sure that when the value restriction prohibits
generalisation, a type error is given rather than picking an arbitrary
instantiation. However, we should only do the check when the extra_checks
argument tells us to. *)(extra_checks ==> (~ (is_value e) /\ type_pe_determ tenv Empty p e)) /\
ALL_DISTINCT (pat_bindings p []) /\
type_p(( 0 : num)) tenv p t bindings /\
type_e tenv Empty e t)
==>
type_d extra_checks tenv (Dlet locs p e)
{} <| v := (alist_to_ns (tenv_add_tvs(( 0 : num)) bindings)); c := nsEmpty; t := nsEmpty |>)
/\ (! extra_checks tenv funs bindings tvs locs.
(type_funs tenv (bind_var_list(( 0 : num)) bindings (bind_tvar tvs Empty)) funs bindings /\
(extra_checks ==>
(! tvs' bindings'.
type_funs tenv (bind_var_list(( 0 : num)) bindings' (bind_tvar tvs' Empty)) funs bindings' ==>
EVERY2 tscheme_inst (MAP SND (tenv_add_tvs tvs' bindings')) (MAP SND (tenv_add_tvs tvs bindings)))))
==>
type_d extra_checks tenv (Dletrec locs funs)
{} <| v := (alist_to_ns (tenv_add_tvs tvs bindings)); c := nsEmpty; t := nsEmpty |>)
/\ (! extra_checks tenv tdefs type_identities tenvT locs.
(ALL_DISTINCT type_identities /\
DISJOINT (LIST_TO_SET type_identities)
(LIST_TO_SET (Tlist_num :: (Tbool_num :: prim_type_nums))) /\
check_ctor_tenv (nsAppend tenvT tenv.t) tdefs /\
(LENGTH type_identities = LENGTH tdefs) /\
(tenvT = alist_to_ns (MAP2
(\ (tvs,tn,ctors) i .
(tn, (tvs, Tapp (MAP Tvar tvs) i)))
tdefs type_identities)))
==>
type_d extra_checks tenv (Dtype locs tdefs)
(LIST_TO_SET type_identities)
<| v := nsEmpty; c := (build_ctor_tenv (nsAppend tenvT tenv.t) tdefs type_identities); t := tenvT |>)
/\ (! extra_checks tenv tvs tn t locs.
(check_freevars_ast tvs t /\
check_type_names tenv.t t /\
ALL_DISTINCT tvs)
==>
type_d extra_checks tenv (Dtabbrev locs tvs tn t)
{}
<| v := nsEmpty; c := nsEmpty; t := (nsSing tn (tvs,type_name_subst tenv.t t)) |>)
/\ (! extra_checks tenv cn ts locs.
(EVERY (check_freevars_ast []) ts /\
EVERY (check_type_names tenv.t) ts)
==>
type_d extra_checks tenv (Dexn locs cn ts)
{}
<| v := nsEmpty;
c := (nsSing cn ([], MAP (type_name_subst tenv.t) ts, Texn_num));
t := nsEmpty |>)
/\ (! extra_checks tenv mn ds decls tenv'.
(type_ds extra_checks tenv ds decls tenv')
==>
type_d extra_checks tenv (Dmod mn ds) decls (tenvLift mn tenv'))
/\ (! extra_checks tenv lds ds tenv1 tenv2 decls1 decls2.
(type_ds extra_checks tenv lds decls1 tenv1 /\
type_ds extra_checks (extend_dec_tenv tenv1 tenv) ds decls2 tenv2 /\
DISJOINT decls1 decls2)
==>
type_d extra_checks tenv (Dlocal lds ds) (decls1 UNION decls2) tenv2)
/\ (! extra_checks tenv.
T
==>
type_ds extra_checks tenv []
{}
<| v := nsEmpty; c := nsEmpty; t := nsEmpty |>)
/\ (! extra_checks tenv d ds tenv1 tenv2 decls1 decls2.
(type_d extra_checks tenv d decls1 tenv1 /\
type_ds extra_checks (extend_dec_tenv tenv1 tenv) ds decls2 tenv2 /\
DISJOINT decls1 decls2)
==>
type_ds extra_checks tenv (d::ds)
(decls1 UNION decls2) (extend_dec_tenv tenv2 tenv1))
End
(*
indreln [type_specs : list modN -> tenv_abbrev -> specs -> decls -> type_env -> bool]
empty : forall mn tenvT.
true
==>
type_specs mn tenvT []
empty_decls <| v = nsEmpty; c = nsEmpty; t = nsEmpty |>
and
sval : forall mn tenvT x t specs tenv fvs decls subst.
check_freevars 0 fvs t &&
check_type_names tenvT t &&
type_specs mn tenvT specs decls tenv &&
subst = alistToFmap (List_extra.zipSameLength fvs (List.map Tvar_db (genlist (fun x -> x) (List.length fvs))))
==>
type_specs mn tenvT (Sval x t :: specs)
decls
(extend_dec_tenv tenv
<| v = nsSing x (List.length fvs, type_subst subst (type_name_subst tenvT t));
c = nsEmpty;
t = nsEmpty |>)
and
stype : forall mn tenvT tenv td specs decls' decls tenvT'.
tenvT' = alist_to_ns (List.map (fun (tvs,tn,ctors) -> (tn, (tvs, Tapp (List.map Tvar tvs) (TC_name (mk_id mn tn))))) td) &&
check_ctor_tenv (nsAppend tenvT' tenvT) td &&
type_specs mn (nsAppend tenvT' tenvT) specs decls tenv &&
decls' = <| defined_mods = {};
defined_types = Set.fromList (List.map (fun (tvs,tn,ctors) -> (mk_id mn tn)) td);
defined_exns = {} |>
==>
type_specs mn tenvT (Stype td :: specs)
(union_decls decls decls')
(extend_dec_tenv tenv
<| v = nsEmpty;
c = build_ctor_tenv mn (nsAppend tenvT' tenvT) td;
t = tenvT' |>)
and
stabbrev : forall mn tenvT tenvT' tvs tn t specs decls tenv.
List.allDistinct tvs &&
check_freevars 0 tvs t &&
check_type_names tenvT t &&
tenvT' = nsSing tn (tvs,type_name_subst tenvT t) &&
type_specs mn (nsAppend tenvT' tenvT) specs decls tenv
==>
type_specs mn tenvT (Stabbrev tvs tn t :: specs)
decls (extend_dec_tenv tenv <| v = nsEmpty; c = nsEmpty; t = tenvT' |>)
and
sexn : forall mn tenvT tenv cn ts specs decls.
check_exn_tenv mn cn ts &&
type_specs mn tenvT specs decls tenv &&
List.all (check_type_names tenvT) ts
==>
type_specs mn tenvT (Sexn cn ts :: specs)
(union_decls decls <| defined_mods = {}; defined_types = {}; defined_exns = {mk_id mn cn} |>)
(extend_dec_tenv tenv
<| v = nsEmpty;
c = nsSing cn ([], List.map (type_name_subst tenvT) ts, TypeExn (mk_id mn cn));
t = nsEmpty |>)
and
stype_opq : forall mn tenvT tenv tn specs tvs decls tenvT'.
List.allDistinct tvs &&
tenvT' = nsSing tn (tvs, Tapp (List.map Tvar tvs) (TC_name (mk_id mn tn))) &&
type_specs mn (nsAppend tenvT' tenvT) specs decls tenv
==>
type_specs mn tenvT (Stype_opq tvs tn :: specs)
(union_decls decls <| defined_mods = {}; defined_types = {mk_id mn tn}; defined_exns = {} |>)
(extend_dec_tenv tenv <| v = nsEmpty; c = nsEmpty; t = tenvT' |>)
val weak_decls : decls -> decls -> bool
let weak_decls decls_impl decls_spec =
decls_impl.defined_mods = decls_spec.defined_mods &&
decls_spec.defined_types subset decls_impl.defined_types &&
decls_spec.defined_exns subset decls_impl.defined_exns
*)
(*
val weak_tenvT : id modN typeN -> (list tvarN * t) -> (list tvarN * t) -> bool
let weak_tenvT n (tvs_spec, t_spec) (tvs_impl, t_impl) =
(* For simplicity, we reject matches that differ only by renaming of bound type variables *)
tvs_spec = tvs_impl &&
(t_spec = t_impl ||
(* The specified type is opaque *)
t_spec = Tapp (List.map Tvar tvs_spec) (TC_name n))
*)
val _ = Define `
((tscheme_inst2:'a -> num#t -> num#t -> bool) _ ts1 ts2= (tscheme_inst ts1 ts2))`;
(*val weak_tenv : type_env -> type_env -> bool*)
val _ = Define `
((weak_tenv:type_env -> type_env -> bool) tenv_impl tenv_spec=
(nsSub tscheme_inst2 tenv_spec.v tenv_impl.v /\
nsSub (\i x y . (case (i ,x ,y ) of ( _ , x , y ) => x = y )) tenv_spec.c tenv_impl.c))`;
(* &&
nsSub weak_tenvT tenv_spec.t tenv_impl.t*)
(*
indreln [check_signature : list modN -> tenv_abbrev -> decls -> type_env -> maybe specs -> decls -> type_env -> bool]
none : forall mn tenvT decls tenv.
true
==>
check_signature mn tenvT decls tenv Nothing decls tenv
and
some : forall mn specs tenv_impl tenv_spec decls_impl decls_spec tenvT.
weak_tenv tenv_impl tenv_spec &&
weak_decls decls_impl decls_spec &&
type_specs mn tenvT specs decls_spec tenv_spec
==>
check_signature mn tenvT decls_impl tenv_impl (Just specs) decls_spec tenv_spec
let tenvLift mn tenv =
<| v = nsLift mn tenv.v; c = nsLift mn tenv.c; t = nsLift mn tenv.t; |>
indreln [type_top : bool -> decls -> type_env -> top -> decls -> type_env -> bool]
tdec : forall extra_checks tenv d tenv' decls decls'.
type_d extra_checks [] decls tenv d decls' tenv'
==>
type_top extra_checks decls tenv (Tdec d) decls' tenv'
and
tmod : forall extra_checks tenv mn spec ds tenv_impl tenv_spec decls decls_impl decls_spec.