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type.ml
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(*
* Copyright (C)2005-2013 Haxe Foundation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
* DEALINGS IN THE SOFTWARE.
*)
open Ast
type path = string list * string
type field_kind =
| Var of var_kind
| Method of method_kind
and var_kind = {
v_read : var_access;
v_write : var_access;
}
and var_access =
| AccNormal
| AccNo (* can't be accessed outside of the class itself and its subclasses *)
| AccNever (* can't be accessed, even in subclasses *)
| AccResolve (* call resolve("field") when accessed *)
| AccCall (* perform a method call when accessed *)
| AccInline (* similar to Normal but inline when accessed *)
| AccRequire of string * string option (* set when @:require(cond) fails *)
and method_kind =
| MethNormal
| MethInline
| MethDynamic
| MethMacro
type t =
| TMono of t option ref
| TEnum of tenum * tparams
| TInst of tclass * tparams
| TType of tdef * tparams
| TFun of (string * bool * t) list * t
| TAnon of tanon
| TDynamic of t
| TLazy of (unit -> t) ref
| TAbstract of tabstract * tparams
and tparams = t list
and type_params = (string * t) list
and tconstant =
| TInt of int32
| TFloat of string
| TString of string
| TBool of bool
| TNull
| TThis
| TSuper
and tvar = {
mutable v_id : int;
mutable v_name : string;
mutable v_type : t;
mutable v_capture : bool;
mutable v_extra : (type_params * texpr option) option;
}
and tfunc = {
tf_args : (tvar * tconstant option) list;
tf_type : t;
tf_expr : texpr;
}
and anon_status =
| Closed
| Opened
| Const
| Statics of tclass
| EnumStatics of tenum
| AbstractStatics of tabstract
and tanon = {
mutable a_fields : (string, tclass_field) PMap.t;
a_status : anon_status ref;
}
and texpr_expr =
| TConst of tconstant
| TLocal of tvar
| TArray of texpr * texpr
| TBinop of Ast.binop * texpr * texpr
| TField of texpr * tfield_access
| TTypeExpr of module_type
| TParenthesis of texpr
| TObjectDecl of (string * texpr) list
| TArrayDecl of texpr list
| TCall of texpr * texpr list
| TNew of tclass * tparams * texpr list
| TUnop of Ast.unop * Ast.unop_flag * texpr
| TFunction of tfunc
| TVars of (tvar * texpr option) list
| TBlock of texpr list
| TFor of tvar * texpr * texpr
| TIf of texpr * texpr * texpr option
| TWhile of texpr * texpr * Ast.while_flag
| TSwitch of texpr * (texpr list * texpr) list * texpr option
| TMatch of texpr * (tenum * tparams) * (int list * tvar option list option * texpr) list * texpr option
| TTry of texpr * (tvar * texpr) list
| TReturn of texpr option
| TBreak
| TContinue
| TThrow of texpr
| TCast of texpr * module_type option
| TMeta of metadata_entry * texpr
and tfield_access =
| FInstance of tclass * tclass_field
| FStatic of tclass * tclass_field
| FAnon of tclass_field
| FDynamic of string
| FClosure of tclass option * tclass_field (* None class = TAnon *)
| FEnum of tenum * tenum_field
and texpr = {
eexpr : texpr_expr;
etype : t;
epos : Ast.pos;
}
and tclass_field = {
cf_name : string;
mutable cf_type : t;
mutable cf_public : bool;
cf_pos : pos;
mutable cf_doc : Ast.documentation;
mutable cf_meta : metadata;
mutable cf_kind : field_kind;
mutable cf_params : type_params;
mutable cf_expr : texpr option;
mutable cf_overloads : tclass_field list;
}
and tclass_kind =
| KNormal
| KTypeParameter of t list
| KExtension of tclass * tparams
| KExpr of Ast.expr
| KGeneric
| KGenericInstance of tclass * tparams
| KMacroType
| KAbstractImpl of tabstract
and metadata = Ast.metadata
and tinfos = {
mt_path : path;
mt_module : module_def;
mt_pos : Ast.pos;
mt_private : bool;
mt_doc : Ast.documentation;
mutable mt_meta : metadata;
mt_types : type_params;
}
and tclass = {
mutable cl_path : path;
mutable cl_module : module_def;
mutable cl_pos : Ast.pos;
mutable cl_private : bool;
mutable cl_doc : Ast.documentation;
mutable cl_meta : metadata;
mutable cl_types : type_params;
mutable cl_kind : tclass_kind;
mutable cl_extern : bool;
mutable cl_interface : bool;
mutable cl_super : (tclass * tparams) option;
mutable cl_implements : (tclass * tparams) list;
mutable cl_fields : (string , tclass_field) PMap.t;
mutable cl_statics : (string, tclass_field) PMap.t;
mutable cl_ordered_statics : tclass_field list;
mutable cl_ordered_fields : tclass_field list;
mutable cl_dynamic : t option;
mutable cl_array_access : t option;
mutable cl_constructor : tclass_field option;
mutable cl_init : texpr option;
mutable cl_overrides : tclass_field list;
mutable cl_build : unit -> unit;
mutable cl_restore : unit -> unit;
}
and tenum_field = {
ef_name : string;
ef_type : t;
ef_pos : Ast.pos;
ef_doc : Ast.documentation;
ef_index : int;
ef_params : type_params;
mutable ef_meta : metadata;
}
and tenum = {
mutable e_path : path;
e_module : module_def;
e_pos : Ast.pos;
e_private : bool;
e_doc : Ast.documentation;
mutable e_meta : metadata;
mutable e_types : type_params;
mutable e_extern : bool;
mutable e_constrs : (string , tenum_field) PMap.t;
mutable e_names : string list;
}
and tdef = {
t_path : path;
t_module : module_def;
t_pos : Ast.pos;
t_private : bool;
t_doc : Ast.documentation;
mutable t_meta : metadata;
mutable t_types : type_params;
mutable t_type : t;
}
and tabstract = {
a_path : path;
a_module : module_def;
a_pos : Ast.pos;
a_private : bool;
a_doc : Ast.documentation;
mutable a_meta : metadata;
mutable a_types : type_params;
mutable a_ops : (Ast.binop * tclass_field) list;
mutable a_unops : (Ast.unop * unop_flag * tclass_field) list;
mutable a_impl : tclass option;
mutable a_this : t;
mutable a_from : (t * tclass_field option) list;
mutable a_array : tclass_field list;
mutable a_to : (t * tclass_field option) list;
}
and module_type =
| TClassDecl of tclass
| TEnumDecl of tenum
| TTypeDecl of tdef
| TAbstractDecl of tabstract
and module_def = {
m_id : int;
m_path : path;
mutable m_types : module_type list;
m_extra : module_def_extra;
}
and module_def_extra = {
m_file : string;
m_sign : string;
mutable m_time : float;
mutable m_dirty : bool;
mutable m_added : int;
mutable m_mark : int;
mutable m_deps : (int,module_def) PMap.t;
mutable m_processed : int;
mutable m_kind : module_kind;
mutable m_binded_res : (string, string) PMap.t;
mutable m_macro_calls : string list;
}
and module_kind =
| MCode
| MMacro
| MFake
let alloc_var =
let uid = ref 0 in
(fun n t -> incr uid; { v_name = n; v_type = t; v_id = !uid; v_capture = false; v_extra = None })
let alloc_mid =
let mid = ref 0 in
(fun() -> incr mid; !mid)
let mk e t p = { eexpr = e; etype = t; epos = p }
let mk_block e =
match e.eexpr with
| TBlock (_ :: _) -> e
| _ -> mk (TBlock [e]) e.etype e.epos
let null t p = mk (TConst TNull) t p
let mk_mono() = TMono (ref None)
let rec t_dynamic = TDynamic t_dynamic
let tfun pl r = TFun (List.map (fun t -> "",false,t) pl,r)
let fun_args l = List.map (fun (a,c,t) -> a, c <> None, t) l
let field_name f =
match f with
| FAnon f | FInstance (_,f) | FStatic (_,f) | FClosure (_,f) -> f.cf_name
| FEnum (_,f) -> f.ef_name
| FDynamic n -> n
let extract_field = function
| FAnon f | FInstance (_,f) | FStatic (_,f) | FClosure (_,f) -> Some f
| _ -> None
let mk_class m path pos =
{
cl_path = path;
cl_module = m;
cl_pos = pos;
cl_doc = None;
cl_meta = [];
cl_private = false;
cl_kind = KNormal;
cl_extern = false;
cl_interface = false;
cl_types = [];
cl_super = None;
cl_implements = [];
cl_fields = PMap.empty;
cl_ordered_statics = [];
cl_ordered_fields = [];
cl_statics = PMap.empty;
cl_dynamic = None;
cl_array_access = None;
cl_constructor = None;
cl_init = None;
cl_overrides = [];
cl_build = (fun() -> ());
cl_restore = (fun() -> ());
}
let module_extra file sign time kind =
{
m_file = file;
m_sign = sign;
m_dirty = false;
m_added = 0;
m_mark = 0;
m_time = time;
m_processed = 0;
m_deps = PMap.empty;
m_kind = kind;
m_binded_res = PMap.empty;
m_macro_calls = [];
}
let mk_field name t p = {
cf_name = name;
cf_type = t;
cf_pos = p;
cf_doc = None;
cf_meta = [];
cf_public = true;
cf_kind = Var { v_read = AccNormal; v_write = AccNormal };
cf_expr = None;
cf_params = [];
cf_overloads = [];
}
let null_module = {
m_id = alloc_mid();
m_path = [] , "";
m_types = [];
m_extra = module_extra "" "" 0. MFake;
}
let null_class =
let c = mk_class null_module ([],"") Ast.null_pos in
c.cl_private <- true;
c
let null_field = mk_field "" t_dynamic Ast.null_pos
let add_dependency m mdep =
if m != null_module && m != mdep then m.m_extra.m_deps <- PMap.add mdep.m_id mdep m.m_extra.m_deps
let arg_name (a,_) = a.v_name
let t_infos t : tinfos =
match t with
| TClassDecl c -> Obj.magic c
| TEnumDecl e -> Obj.magic e
| TTypeDecl t -> Obj.magic t
| TAbstractDecl a -> Obj.magic a
let t_path t = (t_infos t).mt_path
let print_context() = ref []
let is_closed a = !(a.a_status) <> Opened
let rec s_type ctx t =
match t with
| TMono r ->
(match !r with
| None -> Printf.sprintf "Unknown<%d>" (try List.assq t (!ctx) with Not_found -> let n = List.length !ctx in ctx := (t,n) :: !ctx; n)
| Some t -> s_type ctx t)
| TEnum (e,tl) ->
Ast.s_type_path e.e_path ^ s_type_params ctx tl
| TInst (c,tl) ->
Ast.s_type_path c.cl_path ^ s_type_params ctx tl
| TType (t,tl) ->
Ast.s_type_path t.t_path ^ s_type_params ctx tl
| TAbstract (a,tl) ->
Ast.s_type_path a.a_path ^ s_type_params ctx tl
| TFun ([],t) ->
"Void -> " ^ s_fun ctx t false
| TFun (l,t) ->
String.concat " -> " (List.map (fun (s,b,t) ->
(if b then "?" else "") ^ (if s = "" then "" else s ^ " : ") ^ s_fun ctx t true
) l) ^ " -> " ^ s_fun ctx t false
| TAnon a ->
let fl = PMap.fold (fun f acc -> ((if Meta.has Meta.Optional f.cf_meta then " ?" else " ") ^ f.cf_name ^ " : " ^ s_type ctx f.cf_type) :: acc) a.a_fields [] in
"{" ^ (if not (is_closed a) then "+" else "") ^ String.concat "," fl ^ " }"
| TDynamic t2 ->
"Dynamic" ^ s_type_params ctx (if t == t2 then [] else [t2])
| TLazy f ->
s_type ctx (!f())
and s_fun ctx t void =
match t with
| TFun _ ->
"(" ^ s_type ctx t ^ ")"
| TAbstract ({ a_path = ([],"Void") },[]) when void ->
"(" ^ s_type ctx t ^ ")"
| TMono r ->
(match !r with
| None -> s_type ctx t
| Some t -> s_fun ctx t void)
| TLazy f ->
s_fun ctx (!f()) void
| _ ->
s_type ctx t
and s_type_params ctx = function
| [] -> ""
| l -> "<" ^ String.concat ", " (List.map (s_type ctx) l) ^ ">"
let s_access = function
| AccNormal -> "default"
| AccNo -> "null"
| AccNever -> "never"
| AccResolve -> "resolve"
| AccCall -> "accessor"
| AccInline -> "inline"
| AccRequire (n,_) -> "require " ^ n
let s_kind = function
| Var { v_read = AccNormal; v_write = AccNormal } -> "var"
| Var v -> "(" ^ s_access v.v_read ^ "," ^ s_access v.v_write ^ ")"
| Method m ->
match m with
| MethNormal -> "method"
| MethDynamic -> "dynamic method"
| MethInline -> "inline method"
| MethMacro -> "macro method"
let rec is_parent csup c =
if c == csup || List.exists (fun (i,_) -> is_parent csup i) c.cl_implements then
true
else match c.cl_super with
| None -> false
| Some (c,_) -> is_parent csup c
let map loop t =
match t with
| TMono r ->
(match !r with
| None -> t
| Some t -> loop t) (* erase*)
| TEnum (_,[]) | TInst (_,[]) | TType (_,[]) ->
t
| TEnum (e,tl) ->
TEnum (e, List.map loop tl)
| TInst (c,tl) ->
TInst (c, List.map loop tl)
| TType (t2,tl) ->
TType (t2,List.map loop tl)
| TAbstract (a,tl) ->
TAbstract (a,List.map loop tl)
| TFun (tl,r) ->
TFun (List.map (fun (s,o,t) -> s, o, loop t) tl,loop r)
| TAnon a ->
TAnon {
a_fields = PMap.map (fun f -> { f with cf_type = loop f.cf_type }) a.a_fields;
a_status = a.a_status;
}
| TLazy f ->
let ft = !f() in
let ft2 = loop ft in
if ft == ft2 then t else ft2
| TDynamic t2 ->
if t == t2 then t else TDynamic (loop t2)
(* substitute parameters with other types *)
let apply_params cparams params t =
match cparams with
| [] -> t
| _ ->
let rec loop l1 l2 =
match l1, l2 with
| [] , [] -> []
| (x,TLazy f) :: l1, _ -> loop ((x,(!f)()) :: l1) l2
| (_,t1) :: l1 , t2 :: l2 -> (t1,t2) :: loop l1 l2
| _ -> assert false
in
let subst = loop cparams params in
let rec loop t =
try
List.assq t subst
with Not_found ->
match t with
| TMono r ->
(match !r with
| None -> t
| Some t -> loop t)
| TEnum (e,tl) ->
(match tl with
| [] -> t
| _ -> TEnum (e,List.map loop tl))
| TType (t2,tl) ->
(match tl with
| [] -> t
| _ -> TType (t2,List.map loop tl))
| TAbstract (a,tl) ->
(match tl with
| [] -> t
| _ -> TAbstract (a,List.map loop tl))
| TInst (c,tl) ->
(match tl with
| [] ->
t
| [TMono r] ->
(match !r with
| Some tt when t == tt ->
(* for dynamic *)
let pt = mk_mono() in
let t = TInst (c,[pt]) in
(match pt with TMono r -> r := Some t | _ -> assert false);
t
| _ -> TInst (c,List.map loop tl))
| _ ->
TInst (c,List.map loop tl))
| TFun (tl,r) ->
TFun (List.map (fun (s,o,t) -> s, o, loop t) tl,loop r)
| TAnon a ->
TAnon {
a_fields = PMap.map (fun f -> { f with cf_type = loop f.cf_type }) a.a_fields;
a_status = a.a_status;
}
| TLazy f ->
let ft = !f() in
let ft2 = loop ft in
if ft == ft2 then
t
else
ft2
| TDynamic t2 ->
if t == t2 then
t
else
TDynamic (loop t2)
in
loop t
let rec follow t =
match t with
| TMono r ->
(match !r with
| Some t -> follow t
| _ -> t)
| TLazy f ->
follow (!f())
| TType (t,tl) ->
follow (apply_params t.t_types tl t.t_type)
| _ -> t
let rec is_nullable ?(no_lazy=false) = function
| TMono r ->
(match !r with None -> false | Some t -> is_nullable t)
| TType ({ t_path = ([],"Null") },[_]) ->
true
| TLazy f ->
if no_lazy then raise Exit else is_nullable (!f())
| TType (t,tl) ->
is_nullable (apply_params t.t_types tl t.t_type)
| TFun _ ->
false
(*
Type parameters will most of the time be nullable objects, so we don't want to make it hard for users
to have to specify Null<T> all over the place, so while they could be a basic type, let's assume they will not.
This will still cause issues with inlining and haxe.rtti.Generic. In that case proper explicit Null<T> is required to
work correctly with basic types. This could still be fixed by redoing a nullability inference on the typed AST.
| TInst ({ cl_kind = KTypeParameter },_) -> false
*)
| TAbstract (a,_) -> not (Meta.has Meta.NotNull a.a_meta)
| _ ->
true
let rec is_null = function
| TMono r ->
(match !r with None -> false | Some t -> is_null t)
| TType ({ t_path = ([],"Null") },[t]) ->
not (is_nullable t)
| TLazy f ->
is_null (!f())
| TType (t,tl) ->
is_null (apply_params t.t_types tl t.t_type)
| _ ->
false
let rec has_mono t = match t with
| TMono r ->
(match !r with None -> true | Some t -> has_mono t)
| TInst(_,pl) | TEnum(_,pl) | TAbstract(_,pl) | TType(_,pl) ->
List.exists has_mono pl
| TDynamic _ ->
false
| TFun(args,r) ->
has_mono r || List.exists (fun (_,_,t) -> has_mono t) args
| TAnon a ->
PMap.fold (fun cf b -> has_mono cf.cf_type && b) a.a_fields true
| TLazy r ->
has_mono (!r())
let rec link e a b =
(* tell if setting a == b will create a type-loop *)
let rec loop t =
if t == a then
true
else match t with
| TMono t -> (match !t with None -> false | Some t -> loop t)
| TEnum (_,tl) -> List.exists loop tl
| TInst (_,tl) | TType (_,tl) | TAbstract (_,tl) -> List.exists loop tl
| TFun (tl,t) -> List.exists (fun (_,_,t) -> loop t) tl || loop t
| TDynamic t2 ->
if t == t2 then
false
else
loop t2
| TLazy f ->
loop (!f())
| TAnon a ->
try
PMap.iter (fun _ f -> if loop f.cf_type then raise Exit) a.a_fields;
false
with
Exit -> true
in
(* tell is already a ~= b *)
if loop b then
(follow b) == a
else if b == t_dynamic then
true
else begin
e := Some b;
true
end
let monomorphs eparams t =
apply_params eparams (List.map (fun _ -> mk_mono()) eparams) t
let rec fast_eq a b =
if a == b then
true
else match a , b with
| TFun (l1,r1) , TFun (l2,r2) when List.length l1 = List.length l2 ->
List.for_all2 (fun (_,_,t1) (_,_,t2) -> fast_eq t1 t2) l1 l2 && fast_eq r1 r2
| TType (t1,l1), TType (t2,l2) ->
t1 == t2 && List.for_all2 fast_eq l1 l2
| TEnum (e1,l1), TEnum (e2,l2) ->
e1 == e2 && List.for_all2 fast_eq l1 l2
| TInst (c1,l1), TInst (c2,l2) ->
c1 == c2 && List.for_all2 fast_eq l1 l2
| TAbstract (a1,l1), TAbstract (a2,l2) ->
a1 == a2 && List.for_all2 fast_eq l1 l2
| _ , _ ->
false
(* perform unification with subtyping.
the first type is always the most down in the class hierarchy
it's also the one that is pointed by the position.
It's actually a typecheck of A :> B where some mutations can happen *)
type unify_error =
| Cannot_unify of t * t
| Invalid_field_type of string
| Has_no_field of t * string
| Has_no_runtime_field of t * string
| Has_extra_field of t * string
| Invalid_kind of string * field_kind * field_kind
| Invalid_visibility of string
| Not_matching_optional of string
| Cant_force_optional
| Invariant_parameter of t * t
| Constraint_failure of string
| Missing_overload of tclass_field * t
| Unify_custom of string
exception Unify_error of unify_error list
let cannot_unify a b = Cannot_unify (a,b)
let invalid_field n = Invalid_field_type n
let invalid_kind n a b = Invalid_kind (n,a,b)
let invalid_visibility n = Invalid_visibility n
let has_no_field t n = Has_no_field (t,n)
let has_extra_field t n = Has_extra_field (t,n)
let error l = raise (Unify_error l)
let has_meta m ml = List.exists (fun (m2,_,_) -> m = m2) ml
let get_meta m ml = List.find (fun (m2,_,_) -> m = m2) ml
let no_meta = []
(*
we can restrict access as soon as both are runtime-compatible
*)
let unify_access a1 a2 =
a1 = a2 || match a1, a2 with
| _, AccNo | _, AccNever -> true
| AccInline, AccNormal -> true
| _ -> false
let direct_access = function
| AccNo | AccNever | AccNormal | AccInline | AccRequire _ -> true
| AccResolve | AccCall -> false
let unify_kind k1 k2 =
k1 = k2 || match k1, k2 with
| Var v1, Var v2 -> unify_access v1.v_read v2.v_read && unify_access v1.v_write v2.v_write
| Var v, Method m ->
(match v.v_read, v.v_write, m with
| AccNormal, _, MethNormal -> true
| AccNormal, AccNormal, MethDynamic -> true
| _ -> false)
| Method m, Var v ->
(match m with
| MethDynamic -> direct_access v.v_read && direct_access v.v_write
| MethMacro -> false
| MethNormal | MethInline ->
match v.v_write with
| AccNo | AccNever -> true
| _ -> false)
| Method m1, Method m2 ->
match m1,m2 with
| MethInline, MethNormal
| MethDynamic, MethNormal -> true
| _ -> false
let eq_stack = ref []
type eq_kind =
| EqStrict
| EqCoreType
| EqRightDynamic
| EqBothDynamic
let rec type_eq param a b =
if a == b then
()
else match a , b with
| TLazy f , _ -> type_eq param (!f()) b
| _ , TLazy f -> type_eq param a (!f())
| TMono t , _ ->
(match !t with
| None -> if param = EqCoreType || not (link t a b) then error [cannot_unify a b]
| Some t -> type_eq param t b)
| _ , TMono t ->
(match !t with
| None -> if param = EqCoreType || not (link t b a) then error [cannot_unify a b]
| Some t -> type_eq param a t)
| TType (t1,tl1), TType (t2,tl2) when (t1 == t2 || (param = EqCoreType && t1.t_path = t2.t_path)) && List.length tl1 = List.length tl2 ->
List.iter2 (type_eq param) tl1 tl2
| TType (t,tl) , _ when param <> EqCoreType ->
type_eq param (apply_params t.t_types tl t.t_type) b
| _ , TType (t,tl) when param <> EqCoreType ->
if List.exists (fun (a2,b2) -> fast_eq a a2 && fast_eq b b2) (!eq_stack) then
()
else begin
eq_stack := (a,b) :: !eq_stack;
try
type_eq param a (apply_params t.t_types tl t.t_type);
eq_stack := List.tl !eq_stack;
with
Unify_error l ->
eq_stack := List.tl !eq_stack;
error (cannot_unify a b :: l)
end
| TEnum (e1,tl1) , TEnum (e2,tl2) ->
if e1 != e2 && not (param = EqCoreType && e1.e_path = e2.e_path) then error [cannot_unify a b];
List.iter2 (type_eq param) tl1 tl2
| TInst (c1,tl1) , TInst (c2,tl2) ->
if c1 != c2 && not (param = EqCoreType && c1.cl_path = c2.cl_path) && (match c1.cl_kind, c2.cl_kind with KExpr _, KExpr _ -> false | _ -> true) then error [cannot_unify a b];
List.iter2 (type_eq param) tl1 tl2
| TFun (l1,r1) , TFun (l2,r2) when List.length l1 = List.length l2 ->
(try
type_eq param r1 r2;
List.iter2 (fun (n,o1,t1) (_,o2,t2) ->
if o1 <> o2 then error [Not_matching_optional n];
type_eq param t1 t2
) l1 l2
with
Unify_error l -> error (cannot_unify a b :: l))
| TDynamic a , TDynamic b ->
type_eq param a b
| TAbstract (a1,tl1) , TAbstract (a2,tl2) ->
if a1 != a2 && not (param = EqCoreType && a1.a_path = a2.a_path) then error [cannot_unify a b];
List.iter2 (type_eq param) tl1 tl2
| TAnon a1, TAnon a2 ->
(try
PMap.iter (fun n f1 ->
try
let f2 = PMap.find n a2.a_fields in
if f1.cf_kind <> f2.cf_kind && (param = EqStrict || param = EqCoreType || not (unify_kind f1.cf_kind f2.cf_kind)) then error [invalid_kind n f1.cf_kind f2.cf_kind];
try
type_eq param f1.cf_type f2.cf_type
with
Unify_error l -> error (invalid_field n :: l)
with
Not_found ->
if is_closed a2 then error [has_no_field b n];
if not (link (ref None) b f1.cf_type) then error [cannot_unify a b];
a2.a_fields <- PMap.add n f1 a2.a_fields
) a1.a_fields;
PMap.iter (fun n f2 ->
if not (PMap.mem n a1.a_fields) then begin
if is_closed a1 then error [has_no_field a n];
if not (link (ref None) a f2.cf_type) then error [cannot_unify a b];
a1.a_fields <- PMap.add n f2 a1.a_fields
end;
) a2.a_fields;
with
Unify_error l -> error (cannot_unify a b :: l))
| _ , _ ->
if b == t_dynamic && (param = EqRightDynamic || param = EqBothDynamic) then
()
else if a == t_dynamic && param = EqBothDynamic then
()
else
error [cannot_unify a b]
let type_iseq a b =
try
type_eq EqStrict a b;
true
with
Unify_error _ -> false
let unify_stack = ref []
let abstract_cast_stack = ref []
let is_extern_field f =
match f.cf_kind with
| Method _ -> false
| Var { v_read = AccNormal | AccNo } | Var { v_write = AccNormal | AccNo } -> false
| _ -> not (Meta.has Meta.IsVar f.cf_meta)
let field_type f =
match f.cf_params with
| [] -> f.cf_type
| l -> monomorphs l f.cf_type
let rec raw_class_field build_type c i =
try
let f = PMap.find i c.cl_fields in
Some c, build_type f , f
with Not_found -> try (match c.cl_constructor with
| Some ctor when i = "new" -> Some c, build_type ctor,ctor
| _ -> raise Not_found)
with Not_found -> try
match c.cl_super with
| None ->
raise Not_found
| Some (c,tl) ->
let c2 , t , f = raw_class_field build_type c i in
c2, apply_params c.cl_types tl t , f
with Not_found ->
match c.cl_kind with
| KTypeParameter tl ->
let rec loop = function
| [] ->
raise Not_found
| t :: ctl ->
match follow t with
| TAnon a ->
(try
let f = PMap.find i a.a_fields in
None, build_type f, f
with
Not_found -> loop ctl)
| TInst (c,pl) ->
(try
let c2, t , f = raw_class_field build_type c i in
c2, apply_params c.cl_types pl t, f
with
Not_found -> loop ctl)
| _ ->
loop ctl
in
loop tl
| _ ->
if not c.cl_interface then raise Not_found;
(*
an interface can implements other interfaces without
having to redeclare its fields
*)
let rec loop = function
| [] ->
raise Not_found
| (c,tl) :: l ->
try
let c2, t , f = raw_class_field build_type c i in
c2, apply_params c.cl_types tl t, f
with
Not_found -> loop l
in
loop c.cl_implements
let class_field = raw_class_field field_type
let quick_field t n =
match follow t with
| TInst (c,_) ->
let c, _, f = raw_class_field (fun f -> f.cf_type) c n in
(match c with None -> FAnon f | Some c -> FInstance (c,f))
| TAnon a ->
(match !(a.a_status) with
| EnumStatics e ->
assert false (* to replace with FEnum later *)
| Statics c ->
FStatic (c,PMap.find n c.cl_statics)
| AbstractStatics _ ->
assert false
| _ ->
FAnon (PMap.find n a.a_fields))
| TDynamic _ ->
FDynamic n
| TEnum _ | TMono _ | TAbstract _ | TFun _ ->
raise Not_found
| TLazy _ | TType _ ->
assert false
let quick_field_dynamic t s =
try quick_field t s
with Not_found -> FDynamic s
let rec get_constructor build_type c =
match c.cl_constructor, c.cl_super with
| Some c, _ -> build_type c, c
| None, None -> raise Not_found
| None, Some (csup,cparams) ->
let t, c = get_constructor build_type csup in
apply_params csup.cl_types cparams t, c
let rec unify a b =
if a == b then
()
else match a, b with
| TLazy f , _ -> unify (!f()) b
| _ , TLazy f -> unify a (!f())
| TMono t , _ ->
(match !t with
| None -> if not (link t a b) then error [cannot_unify a b]
| Some t -> unify t b)
| _ , TMono t ->
(match !t with
| None -> if not (link t b a) then error [cannot_unify a b]
| Some t -> unify a t)
| TType (t,tl) , _ ->
if not (List.exists (fun (a2,b2) -> fast_eq a a2 && fast_eq b b2) (!unify_stack)) then begin
try
unify_stack := (a,b) :: !unify_stack;
unify (apply_params t.t_types tl t.t_type) b;
unify_stack := List.tl !unify_stack;
with
Unify_error l ->