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optimizer.ml
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optimizer.ml
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(*
The Haxe Compiler
Copyright (C) 2005-2015 Haxe Foundation
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*)
open Ast
open Type
open Common
open Typecore
(* ---------------------------------------------------------------------- *)
(* API OPTIMIZATIONS *)
(* tells if an expression causes side effects. This does not account for potential null accesses (fields/arrays/ops) *)
let has_side_effect e =
let rec loop e =
match e.eexpr with
| TConst _ | TLocal _ | TTypeExpr _ | TFunction _ -> ()
| TCall ({ eexpr = TField(_,FStatic({ cl_path = ([],"Std") },{ cf_name = "string" })) },args) -> Type.iter loop e
| TNew _ | TCall _ | TBinop ((OpAssignOp _ | OpAssign),_,_) | TUnop ((Increment|Decrement),_,_) -> raise Exit
| TReturn _ | TBreak | TContinue | TThrow _ | TCast (_,Some _) -> raise Exit
| TArray _ | TEnumParameter _ | TCast (_,None) | TBinop _ | TUnop _ | TParenthesis _ | TMeta _ | TWhile _ | TFor _
| TField _ | TIf _ | TTry _ | TSwitch _ | TArrayDecl _ | TBlock _ | TObjectDecl _ | TVar _ -> Type.iter loop e
in
try
loop e; false
with Exit ->
true
let rec is_exhaustive e1 = match e1.eexpr with
| TMeta((Meta.Exhaustive,_,_),_) -> true
| TMeta(_, e1) | TParenthesis e1 -> is_exhaustive e1
| _ -> false
let mk_untyped_call name p params =
{
eexpr = TCall({ eexpr = TLocal(alloc_unbound_var name t_dynamic); etype = t_dynamic; epos = p }, params);
etype = t_dynamic;
epos = p;
}
let api_inline2 com c field params p =
match c.cl_path, field, params with
| ([],"Type"),"enumIndex",[{ eexpr = TField (_,FEnum (en,f)) }] -> (match com.platform with
| Cs when en.e_extern && not (Meta.has Meta.HxGen en.e_meta) ->
(* We don't want to optimize enums from external sources; as they might change unexpectedly *)
(* and since native C# enums don't have the concept of index - they have rather a value, *)
(* which can't be mapped to a native API - this kind of substitution is dangerous *)
None
| _ ->
Some (mk (TConst (TInt (Int32.of_int f.ef_index))) com.basic.tint p))
| ([],"Type"),"enumIndex",[{ eexpr = TCall({ eexpr = TField (_,FEnum (en,f)) },pl) }] when List.for_all (fun e -> not (has_side_effect e)) pl ->
(match com.platform with
| Cs when en.e_extern && not (Meta.has Meta.HxGen en.e_meta) ->
(* see comment above *)
None
| _ ->
Some (mk (TConst (TInt (Int32.of_int f.ef_index))) com.basic.tint p))
| ([],"Std"),"int",[{ eexpr = TConst (TInt _) } as e] ->
Some { e with epos = p }
| ([],"String"),"fromCharCode",[{ eexpr = TConst (TInt i) }] when i > 0l && i < 128l ->
Some (mk (TConst (TString (String.make 1 (char_of_int (Int32.to_int i))))) com.basic.tstring p)
| ([],"Std"),"string",[{ eexpr = TConst c } as e] ->
(match c with
| TString s ->
Some { e with epos = p }
| TInt i ->
Some { eexpr = TConst (TString (Int32.to_string i)); epos = p; etype = com.basic.tstring }
| TBool b ->
Some { eexpr = TConst (TString (if b then "true" else "false")); epos = p; etype = com.basic.tstring }
| _ ->
None)
| ([],"Std"),"string",[{ eexpr = TIf (_,{ eexpr = TConst (TString _)},Some { eexpr = TConst (TString _) }) } as e] ->
Some e
| ([],"Std"),"string",[{ eexpr = TLocal v | TField({ eexpr = TLocal v },_) } as ev] when (com.platform = Js || com.platform = Flash) && not (Meta.has Meta.CompilerGenerated v.v_meta) ->
let pos = ev.epos in
let stringv() =
let to_str = mk (TBinop (Ast.OpAdd, mk (TConst (TString "")) com.basic.tstring pos, ev)) com.basic.tstring pos in
if com.platform = Js || is_nullable ev.etype then
let chk_null = mk (TBinop (Ast.OpEq, ev, mk (TConst TNull) t_dynamic pos)) com.basic.tbool pos in
mk (TIf (chk_null, mk (TConst (TString "null")) com.basic.tstring pos, Some to_str)) com.basic.tstring pos
else
to_str
in
(match follow ev.etype with
| TInst ({ cl_path = [],"String" }, []) ->
Some (stringv())
| TAbstract ({ a_path = [],"Float" }, []) ->
Some (stringv())
| TAbstract ({ a_path = [],"Int" }, []) ->
Some (stringv())
| TAbstract ({ a_path = [],"UInt" }, []) ->
Some (stringv())
| TAbstract ({ a_path = [],"Bool" }, []) ->
Some (stringv())
| _ ->
None)
| ([],"Std"),"int",[{ eexpr = TConst (TFloat f) }] ->
let f = float_of_string f in
(match classify_float f with
| FP_infinite | FP_nan ->
None
| _ when f <= Int32.to_float Int32.min_int -. 1. || f >= Int32.to_float Int32.max_int +. 1. ->
None (* out range, keep platform-specific behavior *)
| _ ->
Some { eexpr = TConst (TInt (Int32.of_float f)); etype = com.basic.tint; epos = p })
| ([],"Math"),"ceil",[{ eexpr = TConst (TFloat f) }] ->
let f = float_of_string f in
(match classify_float f with
| FP_infinite | FP_nan ->
None
| _ when f <= Int32.to_float Int32.min_int -. 1. || f >= Int32.to_float Int32.max_int ->
None (* out range, keep platform-specific behavior *)
| _ ->
Some { eexpr = TConst (TInt (Int32.of_float (ceil f))); etype = com.basic.tint; epos = p })
| ([],"Math"),"floor",[{ eexpr = TConst (TFloat f) }] ->
let f = float_of_string f in
(match classify_float f with
| FP_infinite | FP_nan ->
None
| _ when f <= Int32.to_float Int32.min_int || f >= Int32.to_float Int32.max_int +. 1. ->
None (* out range, keep platform-specific behavior *)
| _ ->
Some { eexpr = TConst (TInt (Int32.of_float (floor f))); etype = com.basic.tint; epos = p })
| (["cs"],"Lib"),("fixed" | "checked" | "unsafe"),[e] ->
Some (mk_untyped_call ("__" ^ field ^ "__") p [e])
| (["cs"],"Lib"),("lock"),[obj;block] ->
Some (mk_untyped_call ("__lock__") p [obj;mk_block block])
| (["java"],"Lib"),("lock"),[obj;block] ->
Some (mk_untyped_call ("__lock__") p [obj;mk_block block])
| _ ->
None
let api_inline ctx c field params p = match c.cl_path, field, params with
| ([],"Std"),"is",[o;t] | (["js"],"Boot"),"__instanceof",[o;t] when ctx.com.platform = Js ->
let mk_local ctx n t pos =
mk (TLocal (try
PMap.find n ctx.locals
with _ ->
let v = add_local ctx n t in
v.v_meta <- [Meta.Unbound,[],p];
v
)) t pos in
let tstring = ctx.com.basic.tstring in
let tbool = ctx.com.basic.tbool in
let tint = ctx.com.basic.tint in
let is_trivial e =
match e.eexpr with
| TConst _ | TLocal _ -> true
| _ -> false
in
let typeof t =
let tof = mk_local ctx "__typeof__" (tfun [o.etype] tstring) p in
let tof = mk (TCall (tof, [o])) tstring p in
mk (TBinop (Ast.OpEq, tof, (mk (TConst (TString t)) tstring p))) tbool p
in
(match t.eexpr with
(* generate simple typeof checks for basic types *)
| TTypeExpr (TClassDecl ({ cl_path = [],"String" })) -> Some (typeof "string")
| TTypeExpr (TAbstractDecl ({ a_path = [],"Bool" })) -> Some (typeof "boolean")
| TTypeExpr (TAbstractDecl ({ a_path = [],"Float" })) -> Some (typeof "number")
| TTypeExpr (TAbstractDecl ({ a_path = [],"Int" })) when is_trivial o ->
(* generate (o|0) === o check *)
let teq = mk_local ctx "__strict_eq__" (tfun [tint; tint] tbool) p in
let lhs = mk (TBinop (Ast.OpOr, o, mk (TConst (TInt Int32.zero)) tint p)) tint p in
Some (mk (TCall (teq, [lhs; o])) tbool p)
| TTypeExpr (TClassDecl ({ cl_path = [],"Array" })) ->
(* generate (o instanceof Array) && o.__enum__ == null check *)
let iof = mk_local ctx "__instanceof__" (tfun [o.etype;t.etype] tbool) p in
let iof = mk (TCall (iof, [o; t])) tbool p in
let enum = mk (TField (o, FDynamic "__enum__")) (mk_mono()) p in
let null = mk (TConst TNull) (mk_mono()) p in
let not_enum = mk (TBinop (Ast.OpEq, enum, null)) tbool p in
Some (mk (TBinop (Ast.OpBoolAnd, iof, not_enum)) tbool p)
| _ ->
None)
| (["cs" | "java"],"Lib"),("nativeArray"),[{ eexpr = TArrayDecl args } as edecl; _]
| (["haxe";"ds";"_Vector"],"Vector_Impl_"),("fromArrayCopy"),[{ eexpr = TArrayDecl args } as edecl] -> (try
let platf = match ctx.com.platform with
| Cs -> "cs"
| Java -> "java"
| _ -> raise Exit
in
let mpath = if field = "fromArrayCopy" then
(["haxe";"ds"],"Vector")
else
([platf],"NativeArray")
in
let m = ctx.g.do_load_module ctx mpath null_pos in
let main = List.find (function | TClassDecl _ | TAbstractDecl _ -> true | _ -> false) m.m_types in
let t = match follow edecl.etype, main with
| TInst({ cl_path = [],"Array" }, [t]), TClassDecl(cl) ->
TInst(cl,[t])
| TInst({ cl_path = [],"Array" }, [t]), TAbstractDecl(a) ->
TAbstract(a,[t])
| _ -> assert false
in
Some ({ (mk_untyped_call "__array__" p args) with etype = t })
with | Exit ->
None)
| _ ->
api_inline2 ctx.com c field params p
(* ---------------------------------------------------------------------- *)
(* INLINING *)
type in_local = {
i_var : tvar;
i_subst : tvar;
mutable i_captured : bool;
mutable i_write : bool;
mutable i_read : int;
mutable i_force_temp : bool;
}
let inline_default_config cf t =
(* type substitution on both class and function type parameters *)
let rec get_params c pl =
match c.cl_super with
| None -> c.cl_params, pl
| Some (csup,spl) ->
let spl = (match apply_params c.cl_params pl (TInst (csup,spl)) with
| TInst (_,pl) -> pl
| _ -> assert false
) in
let ct, cpl = get_params csup spl in
c.cl_params @ ct, pl @ cpl
in
let tparams = (match follow t with
| TInst (c,pl) -> get_params c pl
| _ -> ([],[]))
in
let pmonos = List.map (fun _ -> mk_mono()) cf.cf_params in
let tmonos = snd tparams @ pmonos in
let tparams = fst tparams @ cf.cf_params in
tparams <> [], apply_params tparams tmonos
let rec type_inline ctx cf f ethis params tret config p ?(self_calling_closure=false) force =
(* perform some specific optimization before we inline the call since it's not possible to detect at final optimization time *)
try
let cl = (match follow ethis.etype with
| TInst (c,_) -> c
| TAnon a -> (match !(a.a_status) with Statics c -> c | _ -> raise Exit)
| _ -> raise Exit
) in
(match api_inline ctx cl cf.cf_name params p with
| None -> raise Exit
| Some e -> Some e)
with Exit ->
let has_params,map_type = match config with Some config -> config | None -> inline_default_config cf ethis.etype in
(* locals substitution *)
let locals = Hashtbl.create 0 in
let local v =
try
Hashtbl.find locals v.v_id
with Not_found ->
let v' = alloc_var v.v_name v.v_type in
if Meta.has Meta.Unbound v.v_meta then v'.v_meta <- [Meta.Unbound,[],p];
let i = {
i_var = v;
i_subst = v';
i_captured = false;
i_write = false;
i_force_temp = false;
i_read = 0;
} in
i.i_subst.v_meta <- v.v_meta;
Hashtbl.add locals v.v_id i;
Hashtbl.add locals i.i_subst.v_id i;
i
in
let in_local_fun = ref false in
let read_local v =
let l = try
Hashtbl.find locals v.v_id
with Not_found ->
(* make sure to duplicate unbound inline variable to prevent dependency leak when unifying monomorph *)
if has_meta Meta.Unbound v.v_meta then local v else
{
i_var = v;
i_subst = v;
i_captured = false;
i_write = false;
i_force_temp = false;
i_read = 0;
}
in
if !in_local_fun then l.i_captured <- true;
l
in
(* use default values for null/unset arguments *)
let rec loop pl al first =
match pl, al with
| _, [] -> []
| e :: pl, (v, opt) :: al ->
(*
if we pass a Null<T> var to an inlined method that needs a T.
we need to force a local var to be created on some platforms.
*)
if ctx.com.config.pf_static && not (is_nullable v.v_type) && is_null e.etype then (local v).i_force_temp <- true;
(*
if we cast from Dynamic, create a local var as well to do the cast
once and allow DCE to perform properly.
*)
if v.v_type != t_dynamic && follow e.etype == t_dynamic then (local v).i_write <- true;
(match e.eexpr, opt with
| TConst TNull , Some c -> mk (TConst c) v.v_type e.epos
(*
This is really weird and should be reviewed again. The problem is that we cannot insert a TCast here because
the abstract `this` value could be written to, which is not possible if it is wrapped in a cast.
The original problem here is that we do not generate a temporary variable and thus mute the type of the
`this` variable, which leads to unification errors down the line. See issues #2236 and #3713.
*)
(* | _ when first && (Meta.has Meta.Impl cf.cf_meta) -> {e with etype = v.v_type} *)
| _ -> e) :: loop pl al false
| [], (v,opt) :: al ->
(mk (TConst (match opt with None -> TNull | Some c -> c)) v.v_type p) :: loop [] al false
in
(*
Build the expr/var subst list
*)
let ethis = (match ethis.eexpr with TConst TSuper -> { ethis with eexpr = TConst TThis } | _ -> ethis) in
let vthis = alloc_var "_this" ethis.etype in
let inlined_vars = List.map2 (fun e (v,_) ->
let l = local v in
if has_side_effect e then l.i_force_temp <- true; (* force tmp var *)
l, e
) (ethis :: loop params f.tf_args true) ((vthis,None) :: f.tf_args) in
let inlined_vars = List.rev inlined_vars in
(*
here, we try to eliminate final returns from the expression tree.
However, this is not entirely correct since we don't yet correctly propagate
the type of returned expressions upwards ("return" expr itself being Dynamic).
We also substitute variables with fresh ones that might be renamed at later stage.
*)
let opt f = function
| None -> None
| Some e -> Some (f e)
in
let has_vars = ref false in
let in_loop = ref false in
let cancel_inlining = ref false in
let has_return_value = ref false in
let ret_val = (match follow f.tf_type with TAbstract ({ a_path = ([],"Void") },[]) -> false | _ -> true) in
let map_pos = if self_calling_closure then (fun e -> e) else (fun e -> { e with epos = p }) in
let rec map term e =
let po = e.epos in
let e = map_pos e in
match e.eexpr with
| TLocal v ->
let l = read_local v in
l.i_read <- l.i_read + (if !in_loop then 2 else 1);
(* never inline a function which contain a delayed macro because its bound
to its variables and not the calling method *)
if v.v_name = "__dollar__delay_call" then cancel_inlining := true;
let e = { e with eexpr = TLocal l.i_subst } in
if Meta.has Meta.This v.v_meta then mk (TCast(e,None)) v.v_type e.epos else e
| TConst TThis ->
let l = read_local vthis in
l.i_read <- l.i_read + (if !in_loop then 2 else 1);
{ e with eexpr = TLocal l.i_subst }
| TVar (v,eo) ->
has_vars := true;
{ e with eexpr = TVar ((local v).i_subst,opt (map false) eo)}
| TReturn eo when not !in_local_fun ->
if not term then error "Cannot inline a not final return" po;
(match eo with
| None -> mk (TConst TNull) f.tf_type p
| Some e ->
has_return_value := true;
map term e)
| TFor (v,e1,e2) ->
let i = local v in
let e1 = map false e1 in
let old = !in_loop in
in_loop := true;
let e2 = map false e2 in
in_loop := old;
{ e with eexpr = TFor (i.i_subst,e1,e2) }
| TWhile (cond,eloop,flag) ->
let cond = map false cond in
let old = !in_loop in
in_loop := true;
let eloop = map false eloop in
in_loop := old;
{ e with eexpr = TWhile (cond,eloop,flag) }
| TSwitch (e1,cases,def) when term ->
let term = term && (def <> None || is_exhaustive e1) in
let cases = List.map (fun (el,e) ->
let el = List.map (map false) el in
el, map term e
) cases in
let def = opt (map term) def in
{ e with eexpr = TSwitch (map false e1,cases,def); etype = if ret_val then unify_min ctx ((List.map snd cases) @ (match def with None -> [] | Some e -> [e])) else e.etype }
| TTry (e1,catches) ->
{ e with eexpr = TTry (map term e1,List.map (fun (v,e) ->
let lv = (local v).i_subst in
let e = map term e in
lv,e
) catches); etype = if term && ret_val then unify_min ctx (e1::List.map snd catches) else e.etype }
| TBlock l ->
let old = save_locals ctx in
let t = ref e.etype in
let rec has_term_return e =
let rec loop e =
let r = match e.eexpr with
| TReturn _ -> true
| TIf (_,_,None) | TSwitch (_,_,None) | TFor _ | TWhile (_,_,NormalWhile) -> false (* we might not enter this code at all *)
| TTry (a, catches) -> List.for_all has_term_return (a :: List.map snd catches)
| TIf (cond,a,Some b) -> has_term_return cond || (has_term_return a && has_term_return b)
| TSwitch (cond,cases,Some def) -> has_term_return cond || List.for_all has_term_return (def :: List.map snd cases)
| TBinop (OpBoolAnd,a,b) -> has_term_return a && has_term_return b
| _ -> Type.iter loop e; false
in
if r then raise Exit
in
try loop e; false with Exit -> true
in
let rec loop = function
| [] when term ->
t := mk_mono();
[mk (TConst TNull) (!t) p]
| [] -> []
| [e] ->
let e = map term e in
if term then t := e.etype;
[e]
| ({ eexpr = TIf (cond,e1,None) } as e) :: l when term && has_term_return e1 ->
loop [{ e with eexpr = TIf (cond,e1,Some (mk (TBlock l) e.etype e.epos)); epos = punion e.epos (match List.rev l with e :: _ -> e.epos | [] -> assert false) }]
| e :: l ->
let e = map false e in
e :: loop l
in
let l = loop l in
old();
{ e with eexpr = TBlock l; etype = !t }
| TIf (econd,eif,Some eelse) when term ->
let econd = map false econd in
let eif = map term eif in
let eelse = map term eelse in
{ e with eexpr = TIf(econd,eif,Some eelse); etype = if ret_val then unify_min ctx [eif;eelse] else e.etype }
| TParenthesis e1 ->
let e1 = map term e1 in
mk (TParenthesis e1) e1.etype e.epos
| TUnop ((Increment|Decrement) as op,flag,({ eexpr = TLocal v } as e1)) ->
let l = read_local v in
l.i_write <- true;
{e with eexpr = TUnop(op,flag,{e1 with eexpr = TLocal l.i_subst})}
| TBinop ((OpAssign | OpAssignOp _) as op,({ eexpr = TLocal v } as e1),e2) ->
let l = read_local v in
l.i_write <- true;
let e2 = map false e2 in
{e with eexpr = TBinop(op,{e1 with eexpr = TLocal l.i_subst},e2)}
| TObjectDecl fl ->
let fl = List.map (fun (s,e) -> s,map false e) fl in
begin match follow e.etype with
| TAnon an when (match !(an.a_status) with Const -> true | _ -> false) ->
{e with eexpr = TObjectDecl fl; etype = TAnon { an with a_status = ref Closed}}
| _ ->
{e with eexpr = TObjectDecl fl}
end
| TFunction f ->
(match f.tf_args with [] -> () | _ -> has_vars := true);
let old = save_locals ctx and old_fun = !in_local_fun in
let args = List.map (function(v,c) -> (local v).i_subst, c) f.tf_args in
in_local_fun := true;
let expr = map false f.tf_expr in
in_local_fun := old_fun;
old();
{ e with eexpr = TFunction { tf_args = args; tf_expr = expr; tf_type = f.tf_type } }
| TConst TSuper ->
error "Cannot inline function containing super" po
| TMeta(m,e1) ->
let e1 = map term e1 in
{e with eexpr = TMeta(m,e1)}
| _ ->
Type.map_expr (map false) e
in
let e = map true f.tf_expr in
(*
if variables are not written and used with a const value, let's substitute
with the actual value, either create a temp var
*)
let subst = ref PMap.empty in
let is_constant e =
let rec loop e =
match e.eexpr with
| TLocal _
| TConst TThis (* not really, but should not be move inside a function body *)
-> raise Exit
| TField (_,FEnum _)
| TTypeExpr _
| TConst _ -> ()
| _ ->
Type.iter loop e
in
try loop e; true with Exit -> false
in
let is_writable e =
match e.eexpr with
| TField _ | TEnumParameter _ | TLocal _ | TArray _ -> true
| _ -> false
in
let force = ref force in
let vars = List.fold_left (fun acc (i,e) ->
let flag = not i.i_force_temp && (match e.eexpr with
| TLocal v when Meta.has Meta.This v.v_meta -> true
| TLocal _ | TConst _ -> not i.i_write
| TFunction _ -> if i.i_write then error "Cannot modify a closure parameter inside inline method" p; true
| _ -> not i.i_write && i.i_read <= 1
) in
let flag = flag && (not i.i_captured || is_constant e) in
(* force inlining if we modify 'this' *)
if i.i_write && (Meta.has Meta.This i.i_var.v_meta) then force := true;
(* force inlining of 'this' variable if it is written *)
let flag = if not flag && (Meta.has Meta.This i.i_var.v_meta) && i.i_write then begin
if not (is_writable e) then error "Cannot modify the abstract value, store it into a local first" p;
true
end else flag in
if flag then begin
subst := PMap.add i.i_subst.v_id e !subst;
acc
end else
(i.i_subst,Some e) :: acc
) [] inlined_vars in
let subst = !subst in
let rec inline_params e =
match e.eexpr with
| TLocal v -> (try PMap.find v.v_id subst with Not_found -> e)
| _ -> Type.map_expr inline_params e
in
let e = (if PMap.is_empty subst then e else inline_params e) in
let init = match vars with [] -> None | l -> Some l in
(*
If we have local variables and returning a value, then this will result in
unoptimized JS code, so let's instead skip inlining.
This could be fixed with better post process code cleanup (planed)
*)
if !cancel_inlining || (not (Common.defined ctx.com Define.Analyzer) && Common.platform ctx.com Js && not !force && (init <> None || !has_vars)) then
None
else
let wrap e =
(* we can't mute the type of the expression because it is not correct to do so *)
let etype = if has_params then map_type e.etype else e.etype in
(* if the expression is "untyped" and we don't want to unify it accidentally ! *)
try (match follow e.etype with
| TMono _ | TInst ({cl_kind = KTypeParameter _ },_) ->
(match follow tret with
| TAbstract ({ a_path = [],"Void" },_) -> e
| _ -> raise (Unify_error []))
| _ ->
type_eq (if ctx.com.config.pf_static then EqDoNotFollowNull else EqStrict) etype tret;
e)
with Unify_error _ ->
mk (TCast (e,None)) tret e.epos
in
let e = (match e.eexpr, init with
| _, None when not !has_return_value ->
{e with etype = tret}
| TBlock [e] , None -> wrap e
| _ , None -> wrap e
| TBlock l, Some vl ->
let el_v = List.map (fun (v,eo) -> mk (TVar (v,eo)) ctx.t.tvoid e.epos) vl in
mk (TBlock (el_v @ l)) tret e.epos
| _, Some vl ->
let el_v = List.map (fun (v,eo) -> mk (TVar (v,eo)) ctx.t.tvoid e.epos) vl in
mk (TBlock (el_v @ [e])) tret e.epos
) in
let inline_meta e meta = match meta with
| Meta.Deprecated,_,_ -> mk (TMeta(meta,e)) e.etype e.epos
| _ -> e
in
let e = List.fold_left inline_meta e cf.cf_meta in
(* we need to replace type-parameters that were used in the expression *)
if not has_params then
Some e
else
let mt = map_type cf.cf_type in
let unify_func () = unify_raise ctx mt (TFun (List.map (fun e -> "",false,e.etype) params,tret)) p in
(match follow ethis.etype with
| TAnon a -> (match !(a.a_status) with
| Statics {cl_kind = KAbstractImpl a } when Meta.has Meta.Impl cf.cf_meta ->
if cf.cf_name <> "_new" then begin
(* the first argument must unify with a_this for abstract implementation functions *)
let tb = (TFun(("",false,map_type a.a_this) :: List.map (fun e -> "",false,e.etype) (List.tl params),tret)) in
unify_raise ctx mt tb p
end
| _ -> unify_func())
| _ -> unify_func());
(*
this is very expensive since we are building the substitution list for
every expression, but hopefully in such cases the expression size is small
*)
let vars = Hashtbl.create 0 in
let map_var v =
if not (Hashtbl.mem vars v.v_id) then begin
Hashtbl.add vars v.v_id ();
v.v_type <- map_type v.v_type;
end;
v
in
let rec map_expr_type e = Type.map_expr_type map_expr_type map_type map_var e in
Some (map_expr_type e)
(* ---------------------------------------------------------------------- *)
(* LOOPS *)
let rec optimize_for_loop ctx (i,pi) e1 e2 p =
let t_void = ctx.t.tvoid in
let t_int = ctx.t.tint in
let lblock el = Some (mk (TBlock el) t_void p) in
let mk_field e n =
TField (e,try quick_field e.etype n with Not_found -> assert false)
in
let gen_int_iter pt f_get f_length =
let i = add_local ctx i pt in
let index = gen_local ctx t_int in
let arr, avars = (match e1.eexpr with
| TLocal _ -> e1, None
| _ ->
let atmp = gen_local ctx e1.etype in
mk (TLocal atmp) e1.etype e1.epos, (Some (atmp,Some e1))
) in
let iexpr = mk (TLocal index) t_int p in
let e2 = type_expr ctx e2 NoValue in
let aget = mk (TVar (i,Some (f_get arr iexpr pt p))) t_void pi in
let incr = mk (TUnop (Increment,Prefix,iexpr)) t_int p in
let block = match e2.eexpr with
| TBlock el -> mk (TBlock (aget :: incr :: el)) t_void e2.epos
| _ -> mk (TBlock [aget;incr;e2]) t_void p
in
let ivar = Some (mk (TConst (TInt 0l)) t_int p) in
let elength = f_length arr p in
let el = [mk (TWhile (
mk (TBinop (OpLt, iexpr, elength)) ctx.t.tbool p,
block,
NormalWhile
)) t_void p;
] in
let el = match avars with None -> el | Some (v,eo) -> (mk (TVar (v,eo)) t_void p) :: el in
let el = (mk (TVar (index,ivar)) t_void p) :: el in
lblock el
in
let get_next_array_element arr iexpr pt p =
(mk (TArray (arr,iexpr)) pt p)
in
let get_array_length arr p =
mk (mk_field arr "length") ctx.com.basic.tint p
in
match e1.eexpr, follow e1.etype with
| TNew ({ cl_path = ([],"IntIterator") },[],[i1;i2]) , _ ->
let max = (match i1.eexpr , i2.eexpr with
| TConst (TInt a), TConst (TInt b) when Int32.compare b a < 0 -> error "Range operator can't iterate backwards" p
| _, TConst _ | _ , TLocal _ -> None
| _ -> Some (gen_local ctx t_int)
) in
let tmp = gen_local ctx t_int in
let i = add_local ctx i t_int in
let rec check e =
match e.eexpr with
| TBinop (OpAssign,{ eexpr = TLocal l },_)
| TBinop (OpAssignOp _,{ eexpr = TLocal l },_)
| TUnop (Increment,_,{ eexpr = TLocal l })
| TUnop (Decrement,_,{ eexpr = TLocal l }) when l == i ->
error "Loop variable cannot be modified" e.epos
| _ ->
Type.iter check e
in
let e2 = type_expr ctx e2 NoValue in
check e2;
let etmp = mk (TLocal tmp) t_int p in
let incr = mk (TUnop (Increment,Postfix,etmp)) t_int p in
let init = mk (TVar (i,Some incr)) t_void pi in
let block = match e2.eexpr with
| TBlock el -> mk (TBlock (init :: el)) t_void e2.epos
| _ -> mk (TBlock [init;e2]) t_void p
in
(*
force locals to be of Int type (to prevent Int/UInt issues)
*)
let i2 = match follow i2.etype with
| TAbstract ({ a_path = ([],"Int") }, []) -> i2
| _ -> { i2 with eexpr = TCast(i2, None); etype = t_int }
in
(match max with
| None ->
lblock [
mk (TVar (tmp,Some i1)) t_void p;
mk (TWhile (
mk (TBinop (OpLt, etmp, i2)) ctx.t.tbool p,
block,
NormalWhile
)) t_void p;
]
| Some max ->
lblock [
mk (TVar (tmp,Some i1)) t_void p;
mk (TVar (max,Some i2)) t_void p;
mk (TWhile (
mk (TBinop (OpLt, etmp, mk (TLocal max) t_int p)) ctx.t.tbool p,
block,
NormalWhile
)) t_void p;
])
| TArrayDecl el, TInst({ cl_path = [],"Array" },[pt]) when false ->
begin try
let num_expr = ref 0 in
let rec loop e = match fst e with
| EContinue | EBreak ->
raise Exit
| _ ->
incr num_expr;
Ast.map_expr loop e
in
ignore(loop e2);
let v = add_local ctx i pt in
let e2 = type_expr ctx e2 NoValue in
let cost = (List.length el) * !num_expr in
let max_cost = try
int_of_string (Common.defined_value ctx.com Define.LoopUnrollMaxCost)
with Not_found ->
250
in
if cost > max_cost then raise Exit;
let eloc = mk (TLocal v) v.v_type p in
let el = List.map (fun e ->
let e_assign = mk (TBinop(OpAssign,eloc,e)) e.etype e.epos in
concat e_assign e2
) el in
let ev = mk (TVar(v, None)) ctx.t.tvoid p in
Some (mk (TBlock (ev :: el)) ctx.t.tvoid p)
with Exit ->
gen_int_iter pt get_next_array_element get_array_length
end
| _ , TInst({ cl_path = [],"Array" },[pt])
| _ , TInst({ cl_path = ["flash"],"Vector" },[pt]) ->
gen_int_iter pt get_next_array_element get_array_length
| _ , TInst({ cl_array_access = Some pt } as c,pl) when (try match follow (PMap.find "length" c.cl_fields).cf_type with TAbstract ({ a_path = [],"Int" },[]) -> true | _ -> false with Not_found -> false) && not (PMap.mem "iterator" c.cl_fields) ->
gen_int_iter (apply_params c.cl_params pl pt) get_next_array_element get_array_length
| _, TAbstract({a_impl = Some c} as a,tl) ->
begin try
let cf_length = PMap.find "get_length" c.cl_statics in
let get_length e p =
make_static_call ctx c cf_length (apply_params a.a_params tl) [e] ctx.com.basic.tint p
in
begin match follow cf_length.cf_type with
| TFun(_,tr) ->
begin match follow tr with
| TAbstract({a_path = [],"Int"},_) -> ()
| _ -> raise Not_found
end
| _ ->
raise Not_found
end;
begin try
(* first try: do we have an @:arrayAccess getter field? *)
let todo = mk (TConst TNull) ctx.t.tint p in
let cf,_,r,_,_ = (!find_array_access_raise_ref) ctx a tl todo None p in
let get_next e_base e_index t p =
make_static_call ctx c cf (apply_params a.a_params tl) [e_base;e_index] r p
in
gen_int_iter r get_next get_length
with Not_found ->
(* second try: do we have @:arrayAccess on the abstract itself? *)
if not (Meta.has Meta.ArrayAccess a.a_meta) then raise Not_found;
(* let's allow this only for core-type abstracts *)
if not (Meta.has Meta.CoreType a.a_meta) then raise Not_found;
(* in which case we assume that a singular type parameter is the element type *)
let t = match tl with [t] -> t | _ -> raise Not_found in
gen_int_iter t get_next_array_element get_length
end with Not_found ->
None
end
| _ , TInst ({ cl_kind = KGenericInstance ({ cl_path = ["haxe";"ds"],"GenericStack" },[t]) } as c,[]) ->
let tcell = (try (PMap.find "head" c.cl_fields).cf_type with Not_found -> assert false) in
let i = add_local ctx i t in
let cell = gen_local ctx tcell in
let cexpr = mk (TLocal cell) tcell p in
let e2 = type_expr ctx e2 NoValue in
let evar = mk (TVar (i,Some (mk (mk_field cexpr "elt") t p))) t_void pi in
let enext = mk (TBinop (OpAssign,cexpr,mk (mk_field cexpr "next") tcell p)) tcell p in
let block = match e2.eexpr with
| TBlock el -> mk (TBlock (evar :: enext :: el)) t_void e2.epos
| _ -> mk (TBlock [evar;enext;e2]) t_void p
in
lblock [
mk (TVar (cell,Some (mk (mk_field e1 "head") tcell p))) t_void p;
mk (TWhile (
mk (TBinop (OpNotEq, cexpr, mk (TConst TNull) tcell p)) ctx.t.tbool p,
block,
NormalWhile
)) t_void p
]
| _ ->
None
let optimize_for_loop_iterator ctx v e1 e2 p =
let c,tl = (match follow e1.etype with TInst (c,pl) -> c,pl | _ -> raise Exit) in
let _, _, fhasnext = (try raw_class_field (fun cf -> apply_params c.cl_params tl cf.cf_type) c tl "hasNext" with Not_found -> raise Exit) in
if fhasnext.cf_kind <> Method MethInline then raise Exit;
let tmp = gen_local ctx e1.etype in
let eit = mk (TLocal tmp) e1.etype p in
let ehasnext = make_call ctx (mk (TField (eit,FInstance (c, tl, fhasnext))) (TFun([],ctx.t.tbool)) p) [] ctx.t.tbool p in
let enext = mk (TVar (v,Some (make_call ctx (mk (TField (eit,quick_field_dynamic eit.etype "next")) (TFun ([],v.v_type)) p) [] v.v_type p))) ctx.t.tvoid p in
let eblock = (match e2.eexpr with
| TBlock el -> { e2 with eexpr = TBlock (enext :: el) }
| _ -> mk (TBlock [enext;e2]) ctx.t.tvoid p
) in
mk (TBlock [
mk (TVar (tmp,Some e1)) ctx.t.tvoid p;
mk (TWhile (ehasnext,eblock,NormalWhile)) ctx.t.tvoid p
]) ctx.t.tvoid p
(* ---------------------------------------------------------------------- *)
(* SANITIZE *)
(*
makes sure that when an AST get generated to source code, it will not
generate expressions that evaluate differently. It is then necessary to
add parenthesises around some binary expressions when the AST does not
correspond to the natural operand priority order for the platform
*)
(*
this is the standard C++ operator precedence, which is also used by both JS and PHP
*)
let standard_precedence op =
let left = true and right = false in
match op with
| OpMult | OpDiv | OpMod -> 5, left
| OpAdd | OpSub -> 6, left
| OpShl | OpShr | OpUShr -> 7, left
| OpLt | OpLte | OpGt | OpGte -> 8, left
| OpEq | OpNotEq -> 9, left
| OpAnd -> 10, left
| OpXor -> 11, left
| OpOr -> 12, left
| OpInterval -> 13, right (* haxe specific *)
| OpBoolAnd -> 14, left
| OpBoolOr -> 15, left
| OpArrow -> 16, left
| OpAssignOp OpAssign -> 17, right (* mimics ?: *)
| OpAssign | OpAssignOp _ -> 18, right
let rec need_parent e =
match e.eexpr with
| TConst _ | TLocal _ | TArray _ | TField _ | TEnumParameter _ | TParenthesis _ | TMeta _ | TCall _ | TNew _ | TTypeExpr _ | TObjectDecl _ | TArrayDecl _ -> false
| TCast (e,None) -> need_parent e
| TCast _ | TThrow _ | TReturn _ | TTry _ | TSwitch _ | TFor _ | TIf _ | TWhile _ | TBinop _ | TContinue | TBreak
| TBlock _ | TVar _ | TFunction _ | TUnop _ -> true
let sanitize_expr com e =
let parent e =
match e.eexpr with
| TParenthesis _ -> e
| _ -> mk (TParenthesis e) e.etype e.epos
in
let block e =
match e.eexpr with
| TBlock _ -> e
| _ -> mk (TBlock [e]) e.etype e.epos
in
let complex e =
(* complex expressions are the one that once generated to source consists in several expressions *)
match e.eexpr with
| TVar _ (* needs to be put into blocks *)
| TFor _ (* a temp var is needed for holding iterator *)
| TCall ({ eexpr = TLocal { v_name = "__js__" } },_) (* we never know *)
-> block e
| _ -> e
in
(* tells if the printed expresssion ends with an if without else *)
let rec has_if e =
match e.eexpr with
| TIf (_,_,None) -> true
| TWhile (_,e,NormalWhile) -> has_if e
| TFor (_,_,e) -> has_if e
| _ -> false
in
match e.eexpr with
| TConst TNull ->
if com.config.pf_static && not (is_nullable e.etype) then begin
let rec loop t = match follow t with
| TMono _ -> () (* in these cases the null will cast to default value *)
| TFun _ -> () (* this is a bit a particular case, maybe flash-specific actually *)
(* TODO: this should use get_underlying_type, but we do not have access to Codegen here. *)
| TAbstract(a,tl) when not (Meta.has Meta.CoreType a.a_meta) -> loop (apply_params a.a_params tl a.a_this)
| _ -> com.error ("On static platforms, null can't be used as basic type " ^ s_type (print_context()) e.etype) e.epos
in
loop e.etype
end;
e
| TBinop (op,e1,e2) ->
let swap op1 op2 =
let p1, left1 = standard_precedence op1 in
let p2, _ = standard_precedence op2 in
left1 && p1 <= p2
in
let rec loop ee left =
match ee.eexpr with
| TBinop (op2,_,_) -> if left then not (swap op2 op) else swap op op2
| TIf _ -> if left then not (swap (OpAssignOp OpAssign) op) else swap op (OpAssignOp OpAssign)
| TCast (e,None) -> loop e left
| _ -> false
in
let e1 = if loop e1 true then parent e1 else e1 in
let e2 = if loop e2 false then parent e2 else e2 in
{ e with eexpr = TBinop (op,e1,e2) }
| TUnop (op,mode,e1) ->
let rec loop ee =
match ee.eexpr with
| TBinop _ | TIf _ | TUnop _ -> parent e1
| TCast (e,None) -> loop e
| _ -> e1
in
{ e with eexpr = TUnop (op,mode,loop e1)}
| TIf (e1,e2,eelse) ->
let e1 = parent e1 in
let e2 = (if (eelse <> None && has_if e2) || (match e2.eexpr with TIf _ -> true | _ -> false) then block e2 else complex e2) in
let eelse = (match eelse with None -> None | Some e -> Some (complex e)) in
{ e with eexpr = TIf (e1,e2,eelse) }
| TWhile (e1,e2,flag) ->
let e1 = parent e1 in
let e2 = complex e2 in
{ e with eexpr = TWhile (e1,e2,flag) }
| TFor (v,e1,e2) ->
let e2 = complex e2 in
{ e with eexpr = TFor (v,e1,e2) }
| TFunction f ->
let f = (match f.tf_expr.eexpr with
| TBlock _ -> f
| _ -> { f with tf_expr = block f.tf_expr }
) in
{ e with eexpr = TFunction f }
| TCall (e2,args) ->
if need_parent e2 then { e with eexpr = TCall(parent e2,args) } else e
| TEnumParameter (e2,ef,i) ->
if need_parent e2 then { e with eexpr = TEnumParameter(parent e2,ef,i) } else e
| TField (e2,f) ->
if need_parent e2 then { e with eexpr = TField(parent e2,f) } else e
| TArray (e1,e2) ->
if need_parent e1 then { e with eexpr = TArray(parent e1,e2) } else e
| TTry (e1,catches) ->
let e1 = block e1 in
let catches = List.map (fun (v,e) -> v, block e) catches in
{ e with eexpr = TTry (e1,catches) }
| TSwitch (e1,cases,def) ->
let e1 = parent e1 in
let cases = List.map (fun (el,e) -> el, complex e) cases in
let def = (match def with None -> None | Some e -> Some (complex e)) in
{ e with eexpr = TSwitch (e1,cases,def) }
| _ ->
e
let reduce_expr com e =
match e.eexpr with
| TSwitch (_,cases,_) ->
List.iter (fun (cl,_) ->
List.iter (fun e ->
match e.eexpr with
| TCall ({ eexpr = TField (_,FEnum _) },_) -> error "Not-constant enum in switch cannot be matched" e.epos
| _ -> ()
) cl
) cases;
e
| TBlock l ->
(match List.rev l with
| [] -> e
| ec :: l ->
(* remove all no-ops : not-final constants in blocks *)
match List.filter (fun e -> match e.eexpr with
| TConst _
| TBlock []
| TObjectDecl [] ->
false
| _ ->