/
inlineConstructors.ml
753 lines (730 loc) · 28.7 KB
/
inlineConstructors.ml
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(*
The Haxe Compiler
Copyright (C) 2005-2019 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
open Error
open Globals
(* INLINE CONSTRUCTORS *)
(*
First pass:
Finds all inline objects and variables that alias them.
Inline objects reference instances of TNew TObjectDecl and TArrayDecl.
When an inline object is assigned to a variable, this variable is considered an alias of it.
If an aliasing variable is assigned more than once then inlining will be cancelled for the inline
object the variable would have aliased.
The algorithm supports unassigned variables to be used as aliases 'var a; a = new Inl();'. For this
reason variable declarations without assignment are tracked as IVKUnassigned inline variables.
When an unassigned inline variable is assigned an alias it's scope is limited to that in which the
assignment happened, after which the variable is set as "closed" and any appearance will cancel inlining.
Fields of inline objects behave in the same way as unassigned inline variables, allowing nested object
inlining.
Second pass:
Replaces inline objects with their inlined constructor expressions.
Replaces field access of aliasing variables with the respective field inline variable or inlined methods.
Because some replacements turn a single expression into many, this pass will map texpr into texpr list,
which is converted into TBlocks by the caller as needed.
*)
type inline_object_ctor = {
ioc_class : Type.tclass;
ioc_tparams : Type.tparams;
ioc_field : Type.tclass_field;
ioc_forced : bool; (* Cancelling a forced constructor should produce an error *)
}
and inline_object_kind =
| IOKCtor of inline_object_ctor
| IOKStructure
| IOKArray of int
(*
inline_object
Represents an instance of TNew TObjectDecl or TArrayDecl that has potential to be inlined.
Wether the inlining is cancelled or not is decided during the analysis phase.
*)
and inline_object = {
io_kind : inline_object_kind;
io_expr : texpr; (* This is the inlined constructor expression *)
io_pos : pos; (* The original position of the constructor expression *)
mutable io_has_untyped : bool; (* Wether inlining this object would bring untyped expressions into the parent expression *)
mutable io_cancelled : bool; (* Wether this inline object has been cancelled *)
mutable io_declared : bool; (* Wether the variable declarations for this inline object's fields have already been output. (Used in final_map) *)
mutable io_aliases : inline_var list; (* List of variables that are aliasing/referencing this inline object *)
mutable io_fields : (string,inline_var) PMap.t; (* The fields that this inline object supports, fields are inline variables which might alias other inline_objects *)
mutable io_inline_methods : texpr list; (* List of inlined method calls. Populated during analysis and consumed by the final_map phase *)
mutable io_dependent_vars : tvar list; (* List of variables that should be cancelled if this inline object is cancelled *)
}
and inline_var_kind =
| IVKField of
inline_object *
string * (* The field name *)
texpr option (* If this is Some _ then this field is a constant. (Used for Array .length property) *)
| IVKLocal
and inline_var_state =
| IVSUnassigned (* The variable isn't yet assigned *)
| IVSAliasing of inline_object (* The variable is aliasing an inline object *)
| IVSCancelled (* The variable was cancelled and should no longer be considered for aliasing inline objects *)
(*
inline_var
Represents a local variable that is tracked by the inline constructor analysis.
It's main purpose is to track variables that are considered aliases of inline objects.
It also tracks all unassigned variables in the program.
*)
and inline_var = {
iv_var : tvar;
mutable iv_state : inline_var_state;
mutable iv_kind : inline_var_kind;
mutable iv_closed : bool (* Inline variables are marked as closed when the scope they were first assigned on ends, any appearance of this variable after it has been closed causes cancellation *)
}
and inline_object_field =
| IOFInlineMethod of inline_object * inline_var * tclass * Type.tparams * tclass_field * tfunc
| IOFInlineVar of inline_var
| IOFNone
(*
inline_expression_handled
Defines what will happen to the expression being analized by analyze_aliases
*)
and inline_expression_handled =
| IEHCaptured (* The expression will be assigned to a variable *)
| IEHIgnored (* The result of the expression will not be used *)
| IEHNotHandled (* Cases that are not handled (usually leads to cancelling inlining *)
let inline_constructors ctx original_e =
let inline_objs = ref IntMap.empty in
let vars = ref IntMap.empty in
let scoped_ivs = ref [] in
let get_io (ioid:int) : inline_object = IntMap.find ioid !inline_objs in
let get_iv (vid:int) : inline_var = IntMap.find (abs vid) !vars in
let rec cancel_io (io:inline_object) (p:pos) : unit =
if not io.io_cancelled then begin
io.io_cancelled <- true;
List.iter (fun iv -> cancel_iv iv p) io.io_aliases;
PMap.iter (fun _ iv -> cancel_iv iv p) io.io_fields;
match io.io_kind with
| IOKCtor(ioc) ->
List.iter (fun v -> if v.v_id < 0 then cancel_v v p) io.io_dependent_vars;
if ioc.ioc_forced then begin
(* TODO construct error with sub *)
display_error ctx.com "Forced inline constructor could not be inlined" io.io_pos;
display_error ~depth:1 ctx.com (compl_msg "Cancellation happened here") p;
end
| _ -> ()
end
and cancel_iv (iv:inline_var) (p:pos) : unit =
if (iv.iv_state <> IVSCancelled) then begin
let old = iv.iv_state in
iv.iv_state <- IVSCancelled;
begin match old with
| IVSAliasing(io) -> cancel_io io p
| _ -> ()
end;
let remove = match iv.iv_kind with
| IVKField(io,_,_) -> io.io_cancelled
| IVKLocal -> true
in
if remove then begin
let v = iv.iv_var in
vars := IntMap.remove (abs v.v_id) !vars;
v.v_id <- (abs v.v_id);
end
end
and cancel_v (v:tvar) (p:pos) : unit =
try let iv = get_iv v.v_id in
cancel_iv iv p
with Not_found -> ()
in
let set_iv_alias iv io =
if iv.iv_state <> IVSUnassigned || io.io_cancelled then begin
cancel_io io io.io_pos;
cancel_iv iv io.io_pos
end else begin
iv.iv_state <- IVSAliasing io;
io.io_aliases <- iv :: io.io_aliases;
end
in
let add (v:tvar) (kind:inline_var_kind) : inline_var =
let iv = {
iv_var = v;
iv_state = IVSUnassigned;
iv_kind = kind;
iv_closed = false
} in
v.v_id <- -v.v_id;
vars := IntMap.add (abs v.v_id) iv !vars;
iv
in
let get_io_field (io:inline_object) (s:string) : inline_var =
PMap.find s io.io_fields
in
let alloc_io_field_full (io:inline_object) (fname:string) (constexpr_option:texpr option) (t:t) (p:pos) : inline_var =
let v = alloc_var VInlined fname t p in
let iv = add v (IVKField (io,fname,constexpr_option)) in
io.io_fields <- PMap.add fname iv io.io_fields;
iv
in
let alloc_const_io_field (io:inline_object) (fname:string) (constexpr:texpr) : inline_var =
let iv = alloc_io_field_full io fname (Some constexpr) constexpr.etype constexpr.epos in
iv.iv_state <- IVSCancelled;
iv
in
let alloc_io_field (io:inline_object) (fname:string) (t:t) (p:pos) : inline_var = alloc_io_field_full io fname None t p in
let int_field_name i =
if i < 0 then "n" ^ (string_of_int (-i))
else (string_of_int i)
in
let is_extern_ctor c cf = (has_class_flag c CExtern) || has_class_field_flag cf CfExtern in
let make_expr_for_list (el:texpr list) (t:t) (p:pos): texpr = match el with
| [] -> mk (TBlock[]) ctx.t.tvoid p
| [e] -> e
| _ -> mk (TBlock (el)) t p
in
let make_expr_for_rev_list (el:texpr list) (t:t) (p:pos) : texpr = make_expr_for_list (List.rev el) t p in
let curr_io_id = ref 0 in
(*
check_for_ctors
Returns true if there are any potential inline objects in the expression.
It is used to save work before running mark_ctors and analyze_aliases.
*)
let rec check_for_ctors ?(force_inline=false) e =
let is_ctor, is_meta_inline = match e.eexpr, force_inline with
| TMeta((Meta.Inline,_,_),_), _ ->
false, true
| TObjectDecl _, _
| TArrayDecl _, _
| TNew _, true ->
true, false
| TNew({ cl_constructor = Some ({cf_kind = Method MethInline; cf_expr = Some ({eexpr = TFunction _})} as cf)} as c,_,_), _ ->
needs_inline ctx (Some c) cf, false
| _ -> false, false
in
is_ctor || Type.check_expr (check_for_ctors ~force_inline:is_meta_inline) e
in
(*
mark_ctors
Finds all instances of potential inline objects in an expression and wraps them with metadata @:inlineObject(id).
The id is incremented each time and is used later in the final_map phase to identify the correct inline_object.
*)
let rec mark_ctors ?(force_inline=false) e : texpr =
let is_meta_inline = match e.eexpr with (TMeta((Meta.Inline,_,_),e)) -> true | _ -> false in
let e = Type.map_expr (mark_ctors ~force_inline:is_meta_inline) e in
let mark() =
incr curr_io_id;
let id_expr = (EConst(Int (string_of_int !curr_io_id, None)), e.epos) in
let meta = (Meta.InlineObject, [id_expr], e.epos) in
mk (TMeta(meta, e)) e.etype e.epos
in
match e.eexpr, force_inline with
| TObjectDecl _, _
| TArrayDecl _, _
| TNew _, true ->
mark()
| TNew({ cl_constructor = Some ({cf_kind = Method MethInline; cf_expr = Some ({eexpr = TFunction _})} as cf)} as c,_,_), _ ->
if needs_inline ctx (Some c) cf then mark()
else e
| _ -> e
in
(*
analyze_aliases is the main work-horse of the constructor inliner analysis.
It runs recursively over all expressions, it must do so in code execution order.
The expression being analyzed should have been processed with mark_ctors before hand.
returns: Some(inline variable) if the expression being analyzed returns an inline variable. None otherwise.
seen_ctors: used to avoid infinite constructor inlining loops.
captured: Wether the caller is ready to accept an inline variable. If analysis results in an inline
variable and this argument is false then the inline variable must be cancelled before returning.
is_lvalue: Wether the expression being analyzed is on the left side of an assignment.
e: The expression to analyze
*)
let rec analyze_aliases (seen_ctors:tclass_field list) (captured:inline_expression_handled) (is_lvalue:bool) (e:texpr) : inline_var option =
let mk_io ?(has_untyped=false) (iok : inline_object_kind) (id:int) (expr:texpr) : inline_object =
let io = {
io_kind = iok;
io_expr = expr;
io_pos = expr.epos;
io_cancelled = false;
io_declared = false;
io_fields = PMap.empty;
io_aliases = [];
io_has_untyped = has_untyped;
io_inline_methods = [];
io_dependent_vars = [];
} in
inline_objs := IntMap.add id io !inline_objs;
io
in
let analyze_aliases_in_lvalue e = analyze_aliases seen_ctors captured true e in
let analyze_aliases_in_ctor cf captured e = analyze_aliases (cf::seen_ctors) captured false e in
let analyze_aliases captured e = analyze_aliases seen_ctors captured false e in
let get_io_inline_method io fname =
begin match io.io_kind with
| IOKCtor(ctor) ->
begin try
let f = PMap.find fname ctor.ioc_class.cl_fields in
begin match f.cf_params, f.cf_kind, f.cf_expr with
| [], Method MethInline, Some({eexpr = TFunction tf}) ->
if needs_inline ctx (Some ctor.ioc_class) f then
Some (ctor.ioc_class, ctor.ioc_tparams, f, tf)
else
None
| _ -> None
end
with Not_found -> None
end
| _ -> None
end
in
let handle_field_case ?(captured=IEHNotHandled) ?(is_lvalue=false) efield ethis fname validate_io : inline_object_field =
begin match analyze_aliases IEHCaptured ethis with
| Some({iv_state = IVSAliasing io} as iv) when validate_io io ->
begin match get_io_inline_method io fname with
| Some(c, tl, cf, tf)->
let method_type = apply_params c.cl_params tl cf.cf_type in
let field_is_function = match efield.etype with | TFun _ -> true | _ -> false in
if field_is_function && Type.does_unify method_type efield.etype then
IOFInlineMethod(io,iv,c,tl,cf,tf)
else begin
cancel_iv iv efield.epos;
IOFNone
end
| None ->
begin try
let fiv = get_io_field io fname in
if not (type_iseq_strict fiv.iv_var.v_type efield.etype) then raise Not_found;
let iv_is_const iv = match iv.iv_kind with IVKField(_,_,Some(_)) -> true | _ -> false in
if is_lvalue && iv_is_const fiv then raise Not_found;
if fiv.iv_closed then raise Not_found;
if not is_lvalue && fiv.iv_state == IVSUnassigned then (
warning ctx WConstructorInliningCancelled ("Constructor inlining cancelled because of use of uninitialized member field " ^ fname) ethis.epos;
raise Not_found
);
if captured == IEHNotHandled then cancel_iv fiv efield.epos;
IOFInlineVar(fiv)
with Not_found ->
cancel_iv iv efield.epos;
IOFNone
end
end
| Some(iv) ->
cancel_iv iv efield.epos;
IOFNone
| _ ->
IOFNone
end
in
let handle_field_case_no_methods efield ethis fname validate_io = match handle_field_case ~captured:captured ~is_lvalue:is_lvalue efield ethis fname validate_io with
| IOFInlineMethod(io,_,_,_,_,_) -> cancel_io io efield.epos; None
| IOFInlineVar(iv) -> Some(iv)
| IOFNone -> None
in
let handle_default_case e =
let old = !scoped_ivs in
scoped_ivs := [];
let f e = ignore(analyze_aliases IEHNotHandled e) in
Type.iter f e;
List.iter (fun iv -> iv.iv_closed <- true) !scoped_ivs;
scoped_ivs := old;
None
in
let analyze_call_args call_args =
let rec loop (vs, es) el = match el with
| e :: el ->
begin match e.eexpr with
| TConst _ -> loop (vs, e::es) el
| _ ->
let v = alloc_var VGenerated "arg" e.etype e.epos in
let decle = mk (TVar(v, Some e)) ctx.t.tvoid e.epos in
ignore(analyze_aliases IEHIgnored decle);
let mde = (Meta.InlineConstructorArgument (v.v_id, 0)), [], e.epos in
let e = mk (TMeta(mde, e)) e.etype e.epos in
loop (v::vs, e::es) el
end
| [] -> vs, (List.rev es)
in
loop ([],[]) call_args
in
let handle_inline_object_case (io_id:int) (force_inline:bool) (e:texpr) =
match e.eexpr, e.etype with
| TNew({ cl_constructor = Some ({cf_expr = Some ({eexpr = TFunction tf})} as cf)} as c,tl,pl),_
when captured!=IEHNotHandled && not (List.memq cf seen_ctors) ->
begin
let argvs, pl = analyze_call_args pl in
let _, cname = c.cl_path in
let v = alloc_var VGenerated ("inl"^cname) e.etype e.epos in
let inlined_expr = Inline.type_inline_ctor ctx c cf tf (mk (TLocal v) (TInst (c,tl)) e.epos) pl e.epos in
let inlined_expr = mark_ctors inlined_expr in
let has_untyped = (Meta.has Meta.HasUntyped cf.cf_meta) in
let forced = is_extern_ctor c cf || force_inline in
let io = mk_io (IOKCtor{ioc_class=c; ioc_tparams=tl; ioc_field=cf; ioc_forced=forced}) io_id inlined_expr ~has_untyped:has_untyped in
io.io_dependent_vars <- argvs;
let rec loop (c:tclass) (tl:t list) =
let apply = apply_params c.cl_params tl in
List.iter (fun cf ->
match cf.cf_kind,cf.cf_expr with
| Var _, _ ->
let fieldt = apply cf.cf_type in
ignore(alloc_io_field io cf.cf_name fieldt v.v_pos);
| _ -> ()
) c.cl_ordered_fields;
match c.cl_super with
| Some (c,tl) -> loop c (List.map apply tl)
| None -> ()
in loop c tl;
let iv = add v IVKLocal in
set_iv_alias iv io;
ignore(analyze_aliases_in_ctor cf IEHIgnored io.io_expr);
Some iv
end
| TNew({ cl_constructor = Some ({cf_kind = Method MethInline; cf_expr = Some _} as cf)} as c,_,pl),_ when is_extern_ctor c cf ->
raise_typing_error "Extern constructor could not be inlined" e.epos;
| TObjectDecl fl, _ when captured!=IEHNotHandled && fl <> [] && List.for_all (fun((s,_,_),_) -> Lexer.is_valid_identifier s) fl ->
let v = alloc_var VGenerated "inlobj" e.etype e.epos in
let ev = mk (TLocal v) v.v_type e.epos in
let el = List.map (fun ((s,_,_),e) ->
let ef = mk (TField(ev,FDynamic s)) e.etype e.epos in
let e = mk (TBinop(OpAssign,ef,e)) e.etype e.epos in
e
) fl in
let io_expr = make_expr_for_list el ctx.t.tvoid e.epos in
let io = mk_io (IOKStructure) io_id io_expr in
List.iter (fun ((s,_,_),e) -> ignore(alloc_io_field io s e.etype v.v_pos)) fl;
let iv = add v IVKLocal in
set_iv_alias iv io;
List.iter (fun e -> ignore(analyze_aliases IEHIgnored e)) el;
Some iv
| TArrayDecl el, TInst(_, [elemtype]) when captured!=IEHNotHandled ->
let len = List.length el in
let v = alloc_var VGenerated "inlarr" e.etype e.epos in
let ev = mk (TLocal v) v.v_type e.epos in
let el = List.mapi (fun i e ->
let ef = mk (TArray(ev,(mk (TConst(TInt (Int32.of_int i))) e.etype e.epos))) elemtype e.epos in
mk (TBinop(OpAssign,ef,e)) elemtype e.epos
) el in
let io_expr = make_expr_for_list el ctx.t.tvoid e.epos in
let io = mk_io (IOKArray(len)) io_id io_expr in
ignore(alloc_const_io_field io "length" (mk (TConst(TInt (Int32.of_int len))) ctx.t.tint e.epos));
for i = 0 to len-1 do ignore(alloc_io_field io (int_field_name i) elemtype v.v_pos) done;
let iv = add v IVKLocal in
set_iv_alias iv io;
List.iter (fun e -> ignore(analyze_aliases IEHIgnored e)) el;
Some iv
| _ ->
handle_default_case e
in
match e.eexpr with
| TMeta((Meta.Inline,_,_),{eexpr = TMeta((Meta.InlineObject, [(EConst(Int (id_str, None)), _)], _), e)}) ->
let io_id = int_of_string id_str in
handle_inline_object_case io_id true e
| TMeta((Meta.InlineObject, [(EConst(Int (id_str, None)), _)], _), e) ->
let io_id = int_of_string id_str in
handle_inline_object_case io_id false e
| TVar(v,None) -> ignore(add v IVKLocal); None
| TVar(v,Some rve) ->
begin match analyze_aliases IEHCaptured rve with
| Some({iv_state = IVSAliasing(io)}) ->
let iv = add v IVKLocal in
set_iv_alias iv io;
| _ -> ()
end;
None
| TBinop(OpAssign, lve, rve) ->
begin match analyze_aliases_in_lvalue lve with
| Some({iv_state = IVSUnassigned} as iv) ->
begin match analyze_aliases IEHCaptured rve with
| Some({iv_state = IVSAliasing(io)}) ->
scoped_ivs := iv :: !scoped_ivs;
set_iv_alias iv io
| _ -> cancel_iv iv lve.epos
end;
Some iv
| Some(iv) -> cancel_iv iv e.epos; ignore(analyze_aliases IEHNotHandled rve); None
| _ -> ignore(analyze_aliases IEHNotHandled rve); None
end
| TField(ethis, fa) ->
handle_field_case_no_methods e ethis (field_name fa) (fun _ -> true)
| TArray(ethis,{eexpr = TConst (TInt i)}) ->
let i = Int32.to_int i in
let validate_io io = match io.io_kind with IOKArray(l) when i >= 0 && i < l -> true | _ -> false in
handle_field_case_no_methods e ethis (int_field_name i) validate_io
| TLocal(v) when v.v_id < 0 ->
let iv = get_iv v.v_id in
if iv.iv_closed || captured==IEHNotHandled then cancel_iv iv e.epos;
Some iv
| TBlock(el) ->
let rec loop = function
| [e] -> analyze_aliases captured e
| e::el -> ignore(analyze_aliases IEHIgnored e); loop (el)
| [] -> None
in loop el
| TMeta((Meta.InlineConstructorArgument (vid,_),_,_),_) ->
(* The contents have already been analyzed, so we must skip the wrapped expression *)
(try
let iv = get_iv vid in
if iv.iv_closed || captured==IEHNotHandled then cancel_iv iv e.epos;
Some(get_iv vid)
with Not_found -> None)
| TParenthesis e | TMeta(_,e) | TCast(e,None) ->
analyze_aliases captured e
| TCall(({eexpr=TField(ethis,fa)} as efield),call_args) ->
let fname = field_name fa in
let fiv = handle_field_case efield ethis fname (fun _ -> true) in
begin match fiv with
| IOFInlineMethod(io,io_var,c,tl,cf,tf) ->
let argvs, pl = analyze_call_args call_args in
io.io_dependent_vars <- io.io_dependent_vars @ argvs;
io.io_has_untyped <- io.io_has_untyped || (Meta.has Meta.HasUntyped cf.cf_meta);
let e = Inline.type_inline ctx cf tf (mk (TLocal io_var.iv_var) (TInst (c,tl)) e.epos) pl e.etype None e.epos true in
let e = mark_ctors e in
io.io_inline_methods <- io.io_inline_methods @ [e];
begin match analyze_aliases captured e with
| Some(iv) ->
(*
The parent inline object might have been cancelled while analyzing the inlined method body
If the parent inline object is cancelled the inlining of this method will no longer happen,
so the return value must be cancelled.
*)
if io.io_cancelled then begin
cancel_iv iv e.epos;
None
end else begin
io.io_dependent_vars <- iv.iv_var :: io.io_dependent_vars;
Some(iv)
end
| None -> None
end
| IOFInlineVar(iv) ->
cancel_iv iv e.epos;
List.iter (fun ca -> ignore(analyze_aliases IEHNotHandled ca)) call_args;
None
| IOFNone ->
List.iter (fun ca -> ignore(analyze_aliases IEHNotHandled ca)) call_args;
None
end
| TFunction tf ->
let old = !scoped_ivs in
scoped_ivs := [];
ignore(analyze_aliases IEHIgnored tf.tf_expr);
List.iter (fun iv -> iv.iv_closed <- true) !scoped_ivs;
scoped_ivs := old;
None
| TWhile(condition, body, _) ->
ignore(analyze_aliases IEHNotHandled condition);
ignore(analyze_aliases IEHIgnored body);
None
| TIf (e,e1,e2) when captured=IEHIgnored ->
ignore(analyze_aliases IEHNotHandled e);
ignore(analyze_aliases IEHIgnored e1);
(match e2 with None -> () | Some e -> ignore(analyze_aliases IEHIgnored e));
None
| TTry (e,catches) when captured==IEHIgnored ->
ignore(analyze_aliases IEHIgnored e);
List.iter (fun (_,e) -> ignore(analyze_aliases IEHIgnored e)) catches;
None
| _ ->
handle_default_case e
in
let rec get_iv_var_decls (iv:inline_var) : texpr list =
match iv with
| {iv_state = IVSAliasing io} -> get_io_var_decls io
| {iv_kind = IVKField(_,_,Some _)} -> []
| {iv_state = IVSCancelled} ->
let v = iv.iv_var in
[(mk (TVar(v,None)) ctx.t.tvoid v.v_pos)]
| _ -> []
and get_io_var_decls (io:inline_object) : texpr list =
if io.io_declared then [] else begin
io.io_declared <- true;
PMap.foldi (fun _ iv acc -> acc@(get_iv_var_decls iv)) io.io_fields []
end
in
let included_untyped = ref false in
let rec final_map ?(unwrap_block = false) (e:texpr) : ((texpr list) * (inline_object option)) =
let default_case e =
let f e =
let (el,_) = final_map e in
make_expr_for_rev_list el e.etype e.epos
in
([Type.map_expr f e], None)
in
(*
field_case handles the final map of TField expressions.
The last bool in the returned tuple indicates that the field was handled as an inlined method.
*)
let field_case ethis fa efield : ((texpr list) * (inline_object option) * bool) =
let (tel, thiso) = final_map ethis in
begin match thiso with
| Some io ->
let fname = field_name fa in
begin try match get_io_field io fname with
| {iv_state = IVSAliasing io} ->
tel, Some io, false
| iv ->
let newexpr = match iv.iv_kind with
| IVKField(_,_,Some constexpr) -> {constexpr with epos = e.epos}
| _ -> mk (TLocal iv.iv_var) efield.etype efield.epos
in
(newexpr::tel), None, false
with Not_found ->
(* Since the field is not an inline variable then it must be an inlined method call *)
match io.io_inline_methods with
| e::el ->
(* method fields will appear in the same order as they did during analysis, so we consume the first and remove it from the list *)
io.io_inline_methods <- el;
let el, io = final_map e in
el @ tel, io, true
| _ -> die "" __LOC__
end
| None ->
let te = make_expr_for_rev_list tel ethis.etype ethis.epos in
[mk (TField(te, fa)) efield.etype efield.epos], None, false
end
in
match e.eexpr with
| TMeta((Meta.InlineObject, [(EConst(Int (id_str, _)), _)], _), e) ->
let io_id = int_of_string id_str in
begin try
let io = get_io io_id in
if io.io_cancelled then raise Not_found;
if io.io_has_untyped then included_untyped := true;
let el,_ = final_map ~unwrap_block:true io.io_expr in
let el = el @ get_io_var_decls io in
(el,Some io)
with Not_found ->
default_case e
end
| TVar(v, None) when v.v_id < 0 ->
let iv = get_iv v.v_id in
if iv.iv_state = IVSUnassigned then
(* If the variable is unassigned, leave the expression unchanged *)
([e], None)
else
(get_iv_var_decls (iv)), None
| TVar(v,Some e) when v.v_id < 0 ->
let el = (get_iv_var_decls (get_iv v.v_id)) in
let e,_ = (final_map ~unwrap_block:true e) in (e@el, None)
| TBinop(OpAssign, lve, rve) ->
let (lvel, lvo) = final_map lve in
let (rvel, rvo) = final_map ~unwrap_block:true rve in
begin match lvo with
| Some(io) ->
(rvel@lvel), lvo
| None ->
let rve = make_expr_for_rev_list rvel rve.etype rve.epos in
begin match lvel with
| [] -> die "" __LOC__
| e::el ->
let e = mk (TBinop(OpAssign, e, rve)) e.etype e.epos in
(e::el), None
end
end
| TCall(({eexpr=TField(ethis,fa)} as efield),call_args) ->
begin match field_case ethis fa efield with
| el, io, true -> (* the field was an inlined method *)
el, io
| el, _, false -> (* the field was a normal field access *)
(*
This is equivalent to `default_case e`, but field_case already run final_map
on the TField expression so we must reuse those results.
*)
let f e =
let (el,_) = final_map e in
make_expr_for_rev_list el e.etype e.epos
in
let e1 = make_expr_for_rev_list el efield.etype efield.epos in
let e = {e with eexpr = TCall(e1, List.map f call_args)} in
[e], None
end
| TField(ethis, fa) ->
let el, io, is_method = field_case ethis fa e in
assert(not is_method);
el, io
| TArray(ethis, ({eexpr = TConst (TInt i)} as indexexpr)) ->
let (tel, thiso) = final_map ethis in
begin match thiso with
| Some io ->
let i = Int32.to_int i in
let fname = int_field_name i in
begin match get_io_field io fname with
| {iv_state = IVSAliasing io} ->
tel, Some io
| iv ->
let local = (mk (TLocal iv.iv_var) e.etype e.epos) in
(local::tel), None
end
| None ->
let te = make_expr_for_rev_list tel ethis.etype ethis.epos in
[mk (TArray(te, indexexpr)) e.etype e.epos], None
end
| TLocal v when v.v_id < 0 ->
begin match get_iv v.v_id with
| {iv_state = IVSAliasing io} ->
[], (Some io)
| iv ->
([mk (TLocal iv.iv_var) e.etype e.epos], None)
end
| TBlock el ->
let rec loop acc el = match el with
| [] -> acc, None
| [e] ->
let el',io = final_map ~unwrap_block:unwrap_block e in
(el'@acc), io
| e::el ->
let el',_ = final_map ~unwrap_block:unwrap_block e in
loop (el'@acc) el
in
let el, io = loop [] el in
let el = if unwrap_block || Option.is_some io then el else [mk (TBlock (List.rev el)) e.etype e.epos] in
el, io
| TMeta((Meta.InlineConstructorArgument (_,_),_,_),e) ->
final_map e
| TParenthesis e' | TCast(e',None) | TMeta(_,e') ->
let el, io = final_map e' in
begin match io with
| Some io ->
el, Some io
| None ->
let e' = make_expr_for_rev_list el e'.etype e'.epos in
[Type.map_expr (fun _ -> e') e], None
end
| _ -> default_case e
in
if not (check_for_ctors original_e) then original_e else
let e = mark_ctors original_e in
ignore(analyze_aliases [] IEHNotHandled false e);
if IntMap.for_all (fun _ io -> io.io_cancelled) !inline_objs then begin
IntMap.iter (fun _ iv -> let v = iv.iv_var in if v.v_id < 0 then v.v_id <- -v.v_id ) !vars;
original_e
end else begin
let el,_ = final_map e in
let cf = ctx.curfield in
if !included_untyped && not (Meta.has Meta.HasUntyped cf.cf_meta) then cf.cf_meta <- (Meta.HasUntyped,[],e.epos) :: cf.cf_meta;
let e = make_expr_for_rev_list el e.etype e.epos in
let rec get_pretty_name iv = match iv.iv_kind with
| IVKField(io,fname,None) ->
begin try
let is_user_variable iv = match iv.iv_var.v_kind with VUser _ | VInlined -> true | _ -> false in
let iv = List.find is_user_variable io.io_aliases in
(get_pretty_name iv) ^ "_" ^ fname;
with Not_found ->
(get_pretty_name (List.hd io.io_aliases)) ^ "_" ^ fname;
end
| _ -> iv.iv_var.v_name
in
IntMap.iter (fun _ iv ->
let v = iv.iv_var in
if v.v_id < 0 then begin
v.v_id <- -v.v_id;
v.v_name <- get_pretty_name iv
end
) !vars;
e
end