(* * 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 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 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 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 | AccInline | 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 -> unify_stack := List.tl !unify_stack; error (cannot_unify a b :: l) end | _ , 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 a (apply_params t.t_types tl t.t_type); unify_stack := List.tl !unify_stack; with Unify_error l -> unify_stack := List.tl !unify_stack; error (cannot_unify a b :: l) end | TEnum (ea,tl1) , TEnum (eb,tl2) -> if ea != eb then error [cannot_unify a b]; unify_types a b tl1 tl2 | TAbstract (a1,tl1) , TAbstract (a2,tl2) when a1 == a2 -> unify_types a b tl1 tl2 | TAbstract ({a_path=[],"Void"},_) , _ | _ , TAbstract ({a_path=[],"Void"},_) -> error [cannot_unify a b] | TAbstract (a1,tl1) , TAbstract (a2,tl2) -> if not (List.exists (unify_to_field a1 tl1 b) a1.a_to) && not (List.exists (unify_from_field a2 tl2 a b) a2.a_from) then error [cannot_unify a b] | TInst (c1,tl1) , TInst (c2,tl2) -> let rec loop c tl = if c == c2 then begin unify_types a b tl tl2; true end else (match c.cl_super with | None -> false | Some (cs,tls) -> loop cs (List.map (apply_params c.cl_types tl) tls) ) || List.exists (fun (cs,tls) -> loop cs (List.map (apply_params c.cl_types tl) tls) ) c.cl_implements || (match c.cl_kind with | KTypeParameter pl -> List.exists (fun t -> match follow t with TInst (cs,tls) -> loop cs (List.map (apply_params c.cl_types tl) tls) | _ -> false) pl | _ -> false) in if not (loop c1 tl1) then error [cannot_unify a b] | TFun (l1,r1) , TFun (l2,r2) when List.length l1 = List.length l2 -> let i = ref 0 in (try (match r2 with | TAbstract ({a_path=[],"Void"},_) -> () | _ -> unify r1 r2; incr i); List.iter2 (fun (_,o1,t1) (_,o2,t2) -> if o1 && not o2 then error [Cant_force_optional]; unify t1 t2; incr i ) l2 l1 (* contravariance *) with Unify_error l -> let msg = if !i = 0 then "Cannot unify return types" else "Cannot unify argument " ^ (string_of_int !i) in error (cannot_unify a b :: Unify_custom msg :: l)) | TInst (c,tl) , TAnon an -> if PMap.is_empty an.a_fields then (match c.cl_kind with | KTypeParameter pl -> (* one of the constraints must unify with { } *) if not (List.exists (fun t -> match t with TInst _ | TAnon _ -> true | _ -> false) pl) then error [cannot_unify a b] | _ -> ()); (try PMap.iter (fun n f2 -> let _, ft, f1 = (try class_field c n with Not_found -> error [has_no_field a n]) in if not (unify_kind f1.cf_kind f2.cf_kind) then error [invalid_kind n f1.cf_kind f2.cf_kind]; if f2.cf_public && not f1.cf_public then error [invalid_visibility n]; (try unify_with_access (apply_params c.cl_types tl ft) f2 with Unify_error l -> error (invalid_field n :: l)); List.iter (fun f2o -> if not (List.exists (fun f1o -> type_iseq f1o.cf_type f2o.cf_type) (f1 :: f1.cf_overloads)) then error [Missing_overload (f1, f2o.cf_type)] ) f2.cf_overloads; (* we mark the field as :?used because it might be used through the structure *) if not (Meta.has Meta.MaybeUsed f1.cf_meta) then f1.cf_meta <- (Meta.MaybeUsed,[],f1.cf_pos) :: f1.cf_meta; (match f1.cf_kind with | Method MethInline -> if (c.cl_extern || Meta.has Meta.Extern f1.cf_meta) && not (Meta.has Meta.Runtime f1.cf_meta) then error [Has_no_runtime_field (a,n)]; | _ -> ()); ) an.a_fields; (match !(an.a_status) with | Opened -> an.a_status := Closed; | Statics _ | EnumStatics _ | AbstractStatics _ -> error [] | Closed | Const -> ()) with Unify_error l -> error (cannot_unify a b :: l)) | TAnon a1, TAnon a2 -> (try PMap.iter (fun n f2 -> try let f1 = PMap.find n a1.a_fields in if not (unify_kind f1.cf_kind f2.cf_kind) then (match !(a1.a_status), f1.cf_kind, f2.cf_kind with | Opened, Var { v_read = AccNormal; v_write = AccNo }, Var { v_read = AccNormal; v_write = AccNormal } -> f1.cf_kind <- f2.cf_kind; | _ -> error [invalid_kind n f1.cf_kind f2.cf_kind]); if f2.cf_public && not f1.cf_public then error [invalid_visibility n]; try unify_with_access f1.cf_type f2; (match !(a1.a_status) with | Statics c when not (Meta.has Meta.MaybeUsed f1.cf_meta) -> f1.cf_meta <- (Meta.MaybeUsed,[],f1.cf_pos) :: f1.cf_meta | _ -> ()); with Unify_error l -> error (invalid_field n :: l) with Not_found -> match !(a1.a_status) with | Opened -> if not (link (ref None) a f2.cf_type) then error []; a1.a_fields <- PMap.add n f2 a1.a_fields | Const when Meta.has Meta.Optional f2.cf_meta -> () | _ -> error [has_no_field a n]; ) a2.a_fields; (match !(a1.a_status) with | Const when not (PMap.is_empty a2.a_fields) -> PMap.iter (fun n _ -> if not (PMap.mem n a2.a_fields) then error [has_extra_field a n]) a1.a_fields; | Opened -> a1.a_status := Closed | _ -> ()); (match !(a2.a_status) with | Statics c -> (match !(a1.a_status) with Statics c2 when c == c2 -> () | _ -> error []) | EnumStatics e -> (match !(a1.a_status) with EnumStatics e2 when e == e2 -> () | _ -> error []) | AbstractStatics a -> (match !(a1.a_status) with AbstractStatics a2 when a == a2 -> () | _ -> error []) | Opened -> a2.a_status := Closed | Const | Closed -> ()) with Unify_error l -> error (cannot_unify a b :: l)) | TAnon an, TAbstract ({ a_path = [],"Class" },[pt]) -> (match !(an.a_status) with | Statics cl -> unify (TInst (cl,List.map (fun _ -> mk_mono()) cl.cl_types)) pt | _ -> error [cannot_unify a b]) | TAnon an, TAbstract ({ a_path = [],"Enum" },[pt]) -> (match !(an.a_status) with | EnumStatics e -> unify (TEnum (e,List.map (fun _ -> mk_mono()) e.e_types)) pt | _ -> error [cannot_unify a b]) | TEnum _, TAbstract ({ a_path = [],"EnumValue" },[]) -> () | TDynamic t , _ -> if t == a then () else (match b with | TDynamic t2 -> if t2 != b then (try type_eq EqRightDynamic t t2 with Unify_error l -> error (cannot_unify a b :: l)); | _ -> error [cannot_unify a b]) | _ , TDynamic t -> if t == b then () else (match a with | TDynamic t2 -> if t2 != a then (try type_eq EqRightDynamic t t2 with Unify_error l -> error (cannot_unify a b :: l)); | TAnon an -> (try (match !(an.a_status) with | Statics _ | EnumStatics _ -> error [] | Opened -> an.a_status := Closed | _ -> ()); PMap.iter (fun _ f -> try type_eq EqStrict (field_type f) t with Unify_error l -> error (invalid_field f.cf_name :: l) ) an.a_fields with Unify_error l -> error (cannot_unify a b :: l)) | _ -> error [cannot_unify a b]) | TAbstract (aa,tl), _ -> if not (List.exists (unify_to_field aa tl b) aa.a_to) then error [cannot_unify a b]; | TInst ({ cl_kind = KTypeParameter ctl } as c,pl), TAbstract _ -> (* one of the constraints must satisfy the abstract *) if not (List.exists (fun t -> let t = apply_params c.cl_types pl t in try unify t b; true with Unify_error _ -> false ) ctl) then error [cannot_unify a b]; | _, TAbstract (bb,tl) -> if not (List.exists (unify_from_field bb tl a b) bb.a_from) then error [cannot_unify a b] | _ , _ -> error [cannot_unify a b] and unify_from_field ab tl a b (t,cfo) = if (List.exists (fun (a2,b2) -> fast_eq a a2 && fast_eq b b2) (!abstract_cast_stack)) then false else begin abstract_cast_stack := (a,b) :: !abstract_cast_stack; let unify_func = match follow a with TAbstract({a_impl = Some _},_) when ab.a_impl <> None -> type_eq EqStrict | _ -> unify in let b = try begin match cfo with | Some cf -> (match follow cf.cf_type with | TFun(_,r) -> let monos = List.map (fun _ -> mk_mono()) cf.cf_params in let map t = apply_params ab.a_types tl (apply_params cf.cf_params monos t) in unify_func a (map t); unify (map r) b; | _ -> assert false) | _ -> unify_func a (apply_params ab.a_types tl t) end; true with Unify_error _ -> false in abstract_cast_stack := List.tl !abstract_cast_stack; b end and unify_to_field ab tl b (t,cfo) = let a = TAbstract(ab,tl) in if (List.exists (fun (b2,a2) -> fast_eq a a2 && fast_eq b b2) (!abstract_cast_stack)) then false else begin abstract_cast_stack := (b,a) :: !abstract_cast_stack; let unify_func = match follow b with TAbstract({a_impl = Some _},_) when ab.a_impl <> None -> type_eq EqStrict | _ -> unify in let b = try begin match cfo with | Some cf -> (match follow cf.cf_type with | TFun((_,_,ta) :: _,_) -> let monos = List.map (fun _ -> mk_mono()) cf.cf_params in let map t = apply_params ab.a_types tl (apply_params cf.cf_params monos t) in let athis = map ab.a_this in (* we cannot allow implicit casts when the this type is not completely known yet *) if has_mono athis then raise (Unify_error []); type_eq EqStrict athis (map ta); (* immediate constraints checking is ok here because we know there are no monomorphs *) List.iter2 (fun m (name,t) -> match follow t with | TInst ({ cl_kind = KTypeParameter constr },_) when constr <> [] -> List.iter (fun tc -> match follow m with TMono _ -> raise (Unify_error []) | _ -> unify m (map tc) ) constr | _ -> () ) monos cf.cf_params; unify_func (map t) b; | _ -> assert false) | _ -> unify_func (apply_params ab.a_types tl t) b; end; true with Unify_error _ -> false in abstract_cast_stack := List.tl !abstract_cast_stack; b end and unify_types a b tl1 tl2 = List.iter2 (fun t1 t2 -> try type_eq EqRightDynamic t1 t2 with Unify_error l -> let err = cannot_unify a b in (try (match follow t1, follow t2 with | TAbstract({a_impl = Some _} as a1,pl1),TAbstract({a_impl = Some _ } as a2,pl2) -> type_eq EqStrict (apply_params a1.a_types pl1 a1.a_this) (apply_params a2.a_types pl2 a2.a_this) | TAbstract({a_impl = Some _} as a,pl),t -> type_eq EqStrict (apply_params a.a_types pl a.a_this) t | t,TAbstract({a_impl = Some _ } as a,pl) -> type_eq EqStrict t (apply_params a.a_types pl a.a_this) | _ -> raise (Unify_error l)) with Unify_error _ -> error (err :: (Invariant_parameter (t1,t2)) :: l)) ) tl1 tl2 and unify_with_access t1 f2 = match f2.cf_kind with (* write only *) | Var { v_read = AccNo } | Var { v_read = AccNever } -> unify f2.cf_type t1 (* read only *) | Method MethNormal | Method MethInline | Var { v_write = AccNo } | Var { v_write = AccNever } -> unify t1 f2.cf_type (* read/write *) | _ -> type_eq EqBothDynamic t1 f2.cf_type let iter f e = match e.eexpr with | TConst _ | TLocal _ | TBreak | TContinue | TTypeExpr _ -> () | TArray (e1,e2) | TBinop (_,e1,e2) | TFor (_,e1,e2) | TWhile (e1,e2,_) -> f e1; f e2; | TThrow e | TField (e,_) | TParenthesis e | TCast (e,_) | TUnop (_,_,e) -> f e | TArrayDecl el | TNew (_,_,el) | TBlock el -> List.iter f el | TObjectDecl fl -> List.iter (fun (_,e) -> f e) fl | TCall (e,el) -> f e; List.iter f el | TVars vl -> List.iter (fun (_,e) -> match e with None -> () | Some e -> f e) vl | TFunction fu -> f fu.tf_expr | TIf (e,e1,e2) -> f e; f e1; (match e2 with None -> () | Some e -> f e) | TSwitch (e,cases,def) -> f e; List.iter (fun (el,e2) -> List.iter f el; f e2) cases; (match def with None -> () | Some e -> f e) | TMatch (e,_,cases,def) -> f e; List.iter (fun (_,_,e) -> f e) cases; (match def with None -> () | Some e -> f e) | TTry (e,catches) -> f e; List.iter (fun (_,e) -> f e) catches | TReturn eo -> (match eo with None -> () | Some e -> f e) let map_expr f e = match e.eexpr with | TConst _ | TLocal _ | TBreak | TContinue | TTypeExpr _ -> e | TArray (e1,e2) -> { e with eexpr = TArray (f e1,f e2) } | TBinop (op,e1,e2) -> { e with eexpr = TBinop (op,f e1,f e2) } | TFor (v,e1,e2) -> { e with eexpr = TFor (v,f e1,f e2) } | TWhile (e1,e2,flag) -> { e with eexpr = TWhile (f e1,f e2,flag) } | TThrow e1 -> { e with eexpr = TThrow (f e1) } | TField (e1,v) -> { e with eexpr = TField (f e1,v) } | TParenthesis e1 -> { e with eexpr = TParenthesis (f e1) } | TUnop (op,pre,e1) -> { e with eexpr = TUnop (op,pre,f e1) } | TArrayDecl el -> { e with eexpr = TArrayDecl (List.map f el) } | TNew (t,pl,el) -> { e with eexpr = TNew (t,pl,List.map f el) } | TBlock el -> { e with eexpr = TBlock (List.map f el) } | TObjectDecl el -> { e with eexpr = TObjectDecl (List.map (fun (v,e) -> v, f e) el) } | TCall (e1,el) -> { e with eexpr = TCall (f e1, List.map f el) } | TVars vl -> { e with eexpr = TVars (List.map (fun (v,e) -> v , match e with None -> None | Some e -> Some (f e)) vl) } | TFunction fu -> { e with eexpr = TFunction { fu with tf_expr = f fu.tf_expr } } | TIf (ec,e1,e2) -> { e with eexpr = TIf (f ec,f e1,match e2 with None -> None | Some e -> Some (f e)) } | TSwitch (e1,cases,def) -> { e with eexpr = TSwitch (f e1, List.map (fun (el,e2) -> List.map f el, f e2) cases, match def with None -> None | Some e -> Some (f e)) } | TMatch (e1,t,cases,def) -> { e with eexpr = TMatch (f e1, t, List.map (fun (cl,params,e) -> cl, params, f e) cases, match def with None -> None | Some e -> Some (f e)) } | TTry (e1,catches) -> { e with eexpr = TTry (f e1, List.map (fun (v,e) -> v, f e) catches) } | TReturn eo -> { e with eexpr = TReturn (match eo with None -> None | Some e -> Some (f e)) } | TCast (e1,t) -> { e with eexpr = TCast (f e1,t) } let map_expr_type f ft fv e = match e.eexpr with | TConst _ | TBreak | TContinue | TTypeExpr _ -> { e with etype = ft e.etype } | TLocal v -> { e with eexpr = TLocal (fv v); etype = ft e.etype } | TArray (e1,e2) -> { e with eexpr = TArray (f e1,f e2); etype = ft e.etype } | TBinop (op,e1,e2) -> { e with eexpr = TBinop (op,f e1,f e2); etype = ft e.etype } | TFor (v,e1,e2) -> { e with eexpr = TFor (fv v,f e1,f e2); etype = ft e.etype } | TWhile (e1,e2,flag) -> { e with eexpr = TWhile (f e1,f e2,flag); etype = ft e.etype } | TThrow e1 -> { e with eexpr = TThrow (f e1); etype = ft e.etype } | TField (e1,v) -> { e with eexpr = TField (f e1,v); etype = ft e.etype } | TParenthesis e1 -> { e with eexpr = TParenthesis (f e1); etype = ft e.etype } | TUnop (op,pre,e1) -> { e with eexpr = TUnop (op,pre,f e1); etype = ft e.etype } | TArrayDecl el -> { e with eexpr = TArrayDecl (List.map f el); etype = ft e.etype } | TNew (_,_,el) -> let et = ft e.etype in (* make sure that we use the class corresponding to the replaced type *) let c, pl = (match follow et with TInst (c,pl) -> (c,pl) | TAbstract({a_impl = Some c},pl) -> c,pl | t -> error [has_no_field t "new"]) in { e with eexpr = TNew (c,pl,List.map f el); etype = et } | TBlock el -> { e with eexpr = TBlock (List.map f el); etype = ft e.etype } | TObjectDecl el -> { e with eexpr = TObjectDecl (List.map (fun (v,e) -> v, f e) el); etype = ft e.etype } | TCall (e1,el) -> { e with eexpr = TCall (f e1, List.map f el); etype = ft e.etype } | TVars vl -> { e with eexpr = TVars (List.map (fun (v,e) -> fv v, match e with None -> None | Some e -> Some (f e)) vl); etype = ft e.etype } | TFunction fu -> let fu = { tf_expr = f fu.tf_expr; tf_args = List.map (fun (v,o) -> fv v, o) fu.tf_args; tf_type = ft fu.tf_type; } in { e with eexpr = TFunction fu; etype = ft e.etype } | TIf (ec,e1,e2) -> { e with eexpr = TIf (f ec,f e1,match e2 with None -> None | Some e -> Some (f e)); etype = ft e.etype } | TSwitch (e1,cases,def) -> { e with eexpr = TSwitch (f e1, List.map (fun (el,e2) -> List.map f el, f e2) cases, match def with None -> None | Some e -> Some (f e)); etype = ft e.etype } | TMatch (e1,(en,pl),cases,def) -> let map_case (cl,params,e) = let params = match params with | None -> None | Some l -> Some (List.map (function None -> None | Some v -> Some (fv v)) l) in cl, params, f e in { e with eexpr = TMatch (f e1, (en,List.map ft pl), List.map map_case cases, match def with None -> None | Some e -> Some (f e)); etype = ft e.etype } | TTry (e1,catches) -> { e with eexpr = TTry (f e1, List.map (fun (v,e) -> fv v, f e) catches); etype = ft e.etype } | TReturn eo -> { e with eexpr = TReturn (match eo with None -> None | Some e -> Some (f e)); etype = ft e.etype } | TCast (e1,t) -> { e with eexpr = TCast (f e1,t); etype = ft e.etype } let s_expr_kind e = match e.eexpr with | TConst _ -> "Const" | TLocal _ -> "Local" | TArray (_,_) -> "Array" | TBinop (_,_,_) -> "Binop" | TField (_,_) -> "Field" | TTypeExpr _ -> "TypeExpr" | TParenthesis _ -> "Parenthesis" | TObjectDecl _ -> "ObjectDecl" | TArrayDecl _ -> "ArrayDecl" | TCall (_,_) -> "Call" | TNew (_,_,_) -> "New" | TUnop (_,_,_) -> "Unop" | TFunction _ -> "Function" | TVars _ -> "Vars" | TBlock _ -> "Block" | TFor (_,_,_) -> "For" | TIf (_,_,_) -> "If" | TWhile (_,_,_) -> "While" | TSwitch (_,_,_) -> "Switch" | TMatch (_,_,_,_) -> "Match" | TTry (_,_) -> "Try" | TReturn _ -> "Return" | TBreak -> "Break" | TContinue -> "Continue" | TThrow _ -> "Throw" | TCast _ -> "Cast" let s_const = function | TInt i -> Int32.to_string i | TFloat s -> s ^ "f" | TString s -> Printf.sprintf "\"%s\"" (Ast.s_escape s) | TBool b -> if b then "true" else "false" | TNull -> "null" | TThis -> "this" | TSuper -> "super" let rec s_expr s_type e = let sprintf = Printf.sprintf in let slist f l = String.concat "," (List.map f l) in let loop = s_expr s_type in let s_var v = v.v_name ^ ":" ^ string_of_int v.v_id ^ if v.v_capture then "[c]" else "" in let str = (match e.eexpr with | TConst c -> "Const " ^ s_const c | TLocal v -> "Local " ^ s_var v | TArray (e1,e2) -> sprintf "%s[%s]" (loop e1) (loop e2) | TBinop (op,e1,e2) -> sprintf "(%s %s %s)" (loop e1) (s_binop op) (loop e2) | TField (e,f) -> let fstr = (match f with | FStatic (c,f) -> "static(" ^ s_type_path c.cl_path ^ "." ^ f.cf_name ^ ")" | FInstance (c,f) -> "inst(" ^ s_type_path c.cl_path ^ "." ^ f.cf_name ^ " : " ^ s_type f.cf_type ^ ")" | FClosure (c,f) -> "closure(" ^ (match c with None -> f.cf_name | Some c -> s_type_path c.cl_path ^ "." ^ f.cf_name) ^ ")" | FAnon f -> "anon(" ^ f.cf_name ^ ")" | FEnum (en,f) -> "enum(" ^ s_type_path en.e_path ^ "." ^ f.ef_name ^ ")" | FDynamic f -> "dynamic(" ^ f ^ ")" ) in sprintf "%s.%s" (loop e) fstr | TTypeExpr m -> sprintf "TypeExpr %s" (s_type_path (t_path m)) | TParenthesis e -> sprintf "Parenthesis %s" (loop e) | TObjectDecl fl -> sprintf "ObjectDecl {%s)" (slist (fun (f,e) -> sprintf "%s : %s" f (loop e)) fl) | TArrayDecl el -> sprintf "ArrayDecl [%s]" (slist loop el) | TCall (e,el) -> sprintf "Call %s(%s)" (loop e) (slist loop el) | TNew (c,pl,el) -> sprintf "New %s%s(%s)" (s_type_path c.cl_path) (match pl with [] -> "" | l -> sprintf "<%s>" (slist s_type l)) (slist loop el) | TUnop (op,f,e) -> (match f with | Prefix -> sprintf "(%s %s)" (s_unop op) (loop e) | Postfix -> sprintf "(%s %s)" (loop e) (s_unop op)) | TFunction f -> let args = slist (fun (v,o) -> sprintf "%s : %s%s" (s_var v) (s_type v.v_type) (match o with None -> "" | Some c -> " = " ^ s_const c)) f.tf_args in sprintf "Function(%s) : %s = %s" args (s_type f.tf_type) (loop f.tf_expr) | TVars vl -> sprintf "Vars %s" (slist (fun (v,eo) -> sprintf "%s : %s%s" (s_var v) (s_type v.v_type) (match eo with None -> "" | Some e -> " = " ^ loop e)) vl) | TBlock el -> sprintf "Block {\n%s}" (String.concat "" (List.map (fun e -> sprintf "%s;\n" (loop e)) el)) | TFor (v,econd,e) -> sprintf "For (%s : %s in %s,%s)" (s_var v) (s_type v.v_type) (loop econd) (loop e) | TIf (e,e1,e2) -> sprintf "If (%s,%s%s)" (loop e) (loop e1) (match e2 with None -> "" | Some e -> "," ^ loop e) | TWhile (econd,e,flag) -> (match flag with | NormalWhile -> sprintf "While (%s,%s)" (loop econd) (loop e) | DoWhile -> sprintf "DoWhile (%s,%s)" (loop e) (loop econd)) | TSwitch (e,cases,def) -> sprintf "Switch (%s,(%s)%s)" (loop e) (slist (fun (cl,e) -> sprintf "case %s: %s" (slist loop cl) (loop e)) cases) (match def with None -> "" | Some e -> "," ^ loop e) | TMatch (e,(en,tparams),cases,def) -> let args vl = slist (function None -> "_" | Some v -> sprintf "%s : %s" (s_var v) (s_type v.v_type)) vl in let cases = slist (fun (il,vl,e) -> sprintf "case %s%s : %s" (slist string_of_int il) (match vl with None -> "" | Some vl -> sprintf "(%s)" (args vl)) (loop e)) cases in sprintf "Match %s (%s,(%s)%s)" (s_type (TEnum (en,tparams))) (loop e) cases (match def with None -> "" | Some e -> "," ^ loop e) | TTry (e,cl) -> sprintf "Try %s(%s) " (loop e) (slist (fun (v,e) -> sprintf "catch( %s : %s ) %s" (s_var v) (s_type v.v_type) (loop e)) cl) | TReturn None -> "Return" | TReturn (Some e) -> sprintf "Return %s" (loop e) | TBreak -> "Break" | TContinue -> "Continue" | TThrow e -> "Throw " ^ (loop e) | TCast (e,t) -> sprintf "Cast %s%s" (match t with None -> "" | Some t -> s_type_path (t_path t) ^ ": ") (loop e) ) in sprintf "(%s : %s)" str (s_type e.etype) let rec s_expr_pretty tabs s_type e = let sprintf = Printf.sprintf in let loop = s_expr_pretty tabs s_type in let slist f l = String.concat "," (List.map f l) in match e.eexpr with | TConst c -> s_const c | TLocal v -> v.v_name | TArray (e1,e2) -> sprintf "%s[%s]" (loop e1) (loop e2) | TBinop (op,e1,e2) -> sprintf "%s %s %s" (loop e1) (s_binop op) (loop e2) | TField (e1,s) -> sprintf "%s.%s" (loop e1) (field_name s) | TTypeExpr mt -> (s_type_path (t_path mt)) | TParenthesis e1 -> sprintf "(%s)" (loop e1) | TObjectDecl fl -> sprintf "{%s}" (slist (fun (f,e) -> sprintf "%s : %s" f (loop e)) fl) | TArrayDecl el -> sprintf "[%s]" (slist loop el) | TCall (e1,el) -> sprintf "%s(%s)" (loop e1) (slist loop el) | TNew (c,pl,el) -> sprintf "new %s(%s)" (s_type_path c.cl_path) (slist loop el) | TUnop (op,f,e) -> (match f with | Prefix -> sprintf "%s %s" (s_unop op) (loop e) | Postfix -> sprintf "%s %s" (loop e) (s_unop op)) | TFunction f -> let args = slist (fun (v,o) -> sprintf "%s:%s%s" v.v_name (s_type v.v_type) (match o with None -> "" | Some c -> " = " ^ s_const c)) f.tf_args in sprintf "function(%s) = %s" args (loop f.tf_expr) | TVars vl -> sprintf "var %s" (slist (fun (v,eo) -> sprintf "%s%s" v.v_name (match eo with None -> "" | Some e -> " = " ^ loop e)) vl) | TBlock el -> let ntabs = tabs ^ "\t" in let s = sprintf "{\n%s" (String.concat "" (List.map (fun e -> sprintf "%s%s;\n" ntabs (s_expr_pretty ntabs s_type e)) el)) in s ^ tabs ^ "}" | TFor (v,econd,e) -> sprintf "for (%s in %s) %s" v.v_name (loop econd) (loop e) | TIf (e,e1,e2) -> sprintf "if (%s)%s%s)" (loop e) (loop e1) (match e2 with None -> "" | Some e -> " else " ^ loop e) | TWhile (econd,e,flag) -> (match flag with | NormalWhile -> sprintf "while (%s) %s" (loop econd) (loop e) | DoWhile -> sprintf "do (%s) while(%s)" (loop e) (loop econd)) | TSwitch (e,cases,def) -> let ntabs = tabs ^ "\t" in let s = sprintf "switch (%s) {\n%s%s" (loop e) (slist (fun (cl,e) -> sprintf "%scase %s: %s\n" ntabs (slist loop cl) (s_expr_pretty ntabs s_type e)) cases) (match def with None -> "" | Some e -> ntabs ^ "default: " ^ (s_expr_pretty ntabs s_type e) ^ "\n") in s ^ tabs ^ "}" | TMatch (e,(en,tparams),cases,def) -> let ntabs = tabs ^ "\t" in let cases = slist (fun (il,vl,e) -> let ctor i = (PMap.find (List.nth en.e_names i) en.e_constrs).ef_name in let ctors = String.concat "," (List.map ctor il) in begin match vl with | None -> sprintf "%scase %s: %s\n" ntabs ctors (s_expr_pretty ntabs s_type e) | Some vl -> sprintf "%scase %s(%s): %s\n" ntabs ctors (String.concat "," (List.map (fun v -> match v with None -> "_" | Some v -> v.v_name) vl)) (s_expr_pretty ntabs s_type e) end ) cases in let s = sprintf "switch (%s) {\n%s%s" (loop e) cases (match def with None -> "" | Some e -> ntabs ^ "default: " ^ (s_expr_pretty ntabs s_type e) ^ "\n") in s ^ tabs ^ "}" | TTry (e,cl) -> sprintf "try %s%s" (loop e) (slist (fun (v,e) -> sprintf "catch( %s : %s ) %s" v.v_name (s_type v.v_type) (loop e)) cl) | TReturn None -> "return" | TReturn (Some e) -> sprintf "return %s" (loop e) | TBreak -> "break" | TContinue -> "continue" | TThrow e -> "throw " ^ (loop e) | TCast (e,None) -> sprintf "cast %s" (loop e) | TCast (e,Some mt) -> sprintf "cast (%s,%s)" (loop e) (s_type_path (t_path mt))