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fpc/compiler/ncal.pas
florian 8a9758c5e2 * logs truncated
2004-06-20 08:55:28 +00:00

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{
$Id$
Copyright (c) 1998-2002 by Florian Klaempfl
This file implements the node for sub procedure calling.
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., 675 Mass Ave, Cambridge, MA 02139, USA.
****************************************************************************
}
unit ncal;
{$i fpcdefs.inc}
interface
uses
cutils,cclasses,
globtype,cpuinfo,
paramgr,
node,nbas,
{$ifdef state_tracking}
nstate,
{$endif state_tracking}
symbase,symtype,symsym,symdef,symtable;
type
tcallnodeflag = (
cnf_restypeset,
cnf_return_value_used,
cnf_inherited,
cnf_anon_inherited,
cnf_new_call,
cnf_dispose_call,
cnf_member_call { called with implicit methodpointer tree }
);
tcallnodeflags = set of tcallnodeflag;
tcallnode = class(tbinarynode)
private
{ number of parameters passed from the source, this does not include the hidden parameters }
paralength : smallint;
function gen_self_tree_methodpointer:tnode;
function gen_self_tree:tnode;
function gen_vmt_tree:tnode;
procedure bind_paraitem;
{ function return node, this is used to pass the data for a
ret_in_param return value }
_funcretnode : tnode;
procedure setfuncretnode(const returnnode: tnode);
procedure convert_carg_array_of_const;
procedure order_parameters;
protected
pushedparasize : longint;
public
{ the symbol containing the definition of the procedure }
{ to call }
symtableprocentry : tprocsym;
symtableprocentryderef : tderef;
{ symtable where the entry was found, needed for with support }
symtableproc : tsymtable;
{ the definition of the procedure to call }
procdefinition : tabstractprocdef;
procdefinitionderef : tderef;
{ tree that contains the pointer to the object for this method }
methodpointerinit,
methodpointerdone,
methodpointer : tnode;
{ inline function body }
inlinecode : tnode;
{ varargs tparaitems }
varargsparas : tvarargspara;
{ node that specifies where the result should be put for calls }
{ that return their result in a parameter }
property funcretnode: tnode read _funcretnode write setfuncretnode;
{ separately specified resulttype for some compilerprocs (e.g. }
{ you can't have a function with an "array of char" resulttype }
{ the RTL) (JM) }
restype: ttype;
callnodeflags : tcallnodeflags;
{ only the processor specific nodes need to override this }
{ constructor }
constructor create(l:tnode; v : tprocsym;st : tsymtable; mp: tnode; callflags:tcallnodeflags);virtual;
constructor create_procvar(l,r:tnode);
constructor createintern(const name: string; params: tnode);
constructor createinternres(const name: string; params: tnode; const res: ttype);
constructor createinternreturn(const name: string; params: tnode; returnnode : tnode);
destructor destroy;override;
constructor ppuload(t:tnodetype;ppufile:tcompilerppufile);override;
procedure ppuwrite(ppufile:tcompilerppufile);override;
procedure buildderefimpl;override;
procedure derefimpl;override;
function getcopy : tnode;override;
{ Goes through all symbols in a class and subclasses and calls
verify abstract for each .
}
procedure verifyabstractcalls;
{ called for each definition in a class and verifies if a method
is abstract or not, if it is abstract, give out a warning
}
procedure verifyabstract(p : tnamedindexitem;arg:pointer);
procedure insertintolist(l : tnodelist);override;
function pass_1 : tnode;override;
function det_resulttype:tnode;override;
{$ifdef state_tracking}
function track_state_pass(exec_known:boolean):boolean;override;
{$endif state_tracking}
function docompare(p: tnode): boolean; override;
procedure printnodedata(var t:text);override;
function para_count:longint;
private
AbstractMethodsList : TStringList;
end;
tcallnodeclass = class of tcallnode;
tcallparaflag = (
cpf_is_colon_para,
cpf_varargs_para { belongs this para to varargs }
);
tcallparaflags = set of tcallparaflag;
tcallparanode = class(tbinarynode)
public
callparaflags : tcallparaflags;
paraitem : tparaitem;
used_by_callnode : boolean;
{ only the processor specific nodes need to override this }
{ constructor }
constructor create(expr,next : tnode);virtual;
destructor destroy;override;
constructor ppuload(t:tnodetype;ppufile:tcompilerppufile);override;
procedure ppuwrite(ppufile:tcompilerppufile);override;
function getcopy : tnode;override;
procedure insertintolist(l : tnodelist);override;
procedure get_paratype;
procedure insert_typeconv(do_count : boolean);
procedure det_registers;
procedure firstcallparan;
procedure secondcallparan;virtual;abstract;
function docompare(p: tnode): boolean; override;
procedure printnodetree(var t:text);override;
end;
tcallparanodeclass = class of tcallparanode;
function reverseparameters(p: tcallparanode): tcallparanode;
var
ccallnode : tcallnodeclass;
ccallparanode : tcallparanodeclass;
{ Current callnode, this is needed for having a link
between the callparanodes and the callnode they belong to }
aktcallnode : tcallnode;
implementation
uses
systems,
verbose,globals,
symconst,defutil,defcmp,
htypechk,pass_1,
ncnv,nld,ninl,nadd,ncon,nmem,nutils,
procinfo,
cgbase
;
type
tobjectinfoitem = class(tlinkedlistitem)
objinfo : tobjectdef;
constructor create(def : tobjectdef);
end;
{****************************************************************************
HELPERS
****************************************************************************}
function reverseparameters(p: tcallparanode): tcallparanode;
var
hp1, hp2: tcallparanode;
begin
hp1:=nil;
while assigned(p) do
begin
{ pull out }
hp2:=p;
p:=tcallparanode(p.right);
{ pull in }
hp2.right:=hp1;
hp1:=hp2;
end;
reverseparameters:=hp1;
end;
function gen_high_tree(p:tnode;paradef:tdef):tnode;
var
temp: tnode;
len : integer;
loadconst : boolean;
hightree : tnode;
begin
len:=-1;
loadconst:=true;
hightree:=nil;
case p.resulttype.def.deftype of
arraydef :
begin
if (paradef.deftype<>arraydef) then
internalerror(200405241);
{ handle special case of passing an single array to an array of array }
if compare_defs(tarraydef(paradef).elementtype.def,p.resulttype.def,nothingn)>=te_equal then
len:=0
else
begin
{ handle via a normal inline in_high_x node }
loadconst := false;
hightree := geninlinenode(in_high_x,false,p.getcopy);
resulttypepass(hightree);
{ only substract low(array) if it's <> 0 }
temp := geninlinenode(in_low_x,false,p.getcopy);
resulttypepass(temp);
if (temp.nodetype <> ordconstn) or
(tordconstnode(temp).value <> 0) then
hightree := caddnode.create(subn,hightree,temp)
else
temp.free;
end;
end;
stringdef :
begin
if is_open_string(paradef) then
begin
{ handle via a normal inline in_high_x node }
loadconst := false;
hightree := geninlinenode(in_high_x,false,p.getcopy);
end
else
begin
{ passing a string to an array of char }
if (p.nodetype=stringconstn) then
begin
len:=str_length(p);
if len>0 then
dec(len);
end
else
begin
hightree:=caddnode.create(subn,geninlinenode(in_length_x,false,p.getcopy),
cordconstnode.create(1,s32inttype,false));
loadconst:=false;
end;
end;
end;
else
len:=0;
end;
if loadconst then
hightree:=cordconstnode.create(len,s32inttype,true)
else
begin
if not assigned(hightree) then
internalerror(200304071);
{ Need to use explicit, because it can also be a enum }
hightree:=ctypeconvnode.create_explicit(hightree,s32inttype);
end;
result:=hightree;
end;
{****************************************************************************
TOBJECTINFOITEM
****************************************************************************}
constructor tobjectinfoitem.create(def : tobjectdef);
begin
inherited create;
objinfo := def;
end;
{****************************************************************************
TCALLPARANODE
****************************************************************************}
constructor tcallparanode.create(expr,next : tnode);
begin
inherited create(callparan,expr,next);
if not assigned(expr) then
internalerror(200305091);
expr.set_file_line(self);
callparaflags:=[];
end;
destructor tcallparanode.destroy;
begin
{ When the node is used by callnode then
we don't destroy left, the callnode takes care of it }
if used_by_callnode then
left:=nil;
inherited destroy;
end;
constructor tcallparanode.ppuload(t:tnodetype;ppufile:tcompilerppufile);
begin
inherited ppuload(t,ppufile);
ppufile.getsmallset(callparaflags);
end;
procedure tcallparanode.ppuwrite(ppufile:tcompilerppufile);
begin
inherited ppuwrite(ppufile);
ppufile.putsmallset(callparaflags);
end;
function tcallparanode.getcopy : tnode;
var
n : tcallparanode;
begin
n:=tcallparanode(inherited getcopy);
n.callparaflags:=callparaflags;
n.paraitem:=paraitem;
result:=n;
end;
procedure tcallparanode.insertintolist(l : tnodelist);
begin
end;
procedure tcallparanode.get_paratype;
var
old_array_constructor : boolean;
begin
inc(parsing_para_level);
if assigned(right) then
tcallparanode(right).get_paratype;
old_array_constructor:=allow_array_constructor;
allow_array_constructor:=true;
resulttypepass(left);
allow_array_constructor:=old_array_constructor;
if codegenerror then
resulttype:=generrortype
else
resulttype:=left.resulttype;
dec(parsing_para_level);
end;
procedure tcallparanode.insert_typeconv(do_count : boolean);
var
oldtype : ttype;
{$ifdef extdebug}
store_count_ref : boolean;
{$endif def extdebug}
begin
inc(parsing_para_level);
{$ifdef extdebug}
if do_count then
begin
store_count_ref:=count_ref;
count_ref:=true;
end;
{$endif def extdebug}
{ Be sure to have the resulttype }
if not assigned(left.resulttype.def) then
resulttypepass(left);
if (left.nodetype<>nothingn) then
begin
{ Convert tp procvars, this is needs to be done
here to make the change permanent. in the overload
choosing the changes are only made temporary }
if (left.resulttype.def.deftype=procvardef) and
(paraitem.paratype.def.deftype<>procvardef) then
begin
if maybe_call_procvar(left,true) then
resulttype:=left.resulttype;
end;
{ Handle varargs and hidden paras directly, no typeconvs or }
{ typechecking needed }
if (cpf_varargs_para in callparaflags) then
begin
{ convert pascal to C types }
case left.resulttype.def.deftype of
stringdef :
inserttypeconv(left,charpointertype);
floatdef :
inserttypeconv(left,s64floattype);
end;
set_varstate(left,vs_used,true);
resulttype:=left.resulttype;
{ also update paraitem type to get the correct parameter location
for the new types }
paraitem.paratype:=left.resulttype;
end
else
if (paraitem.is_hidden) then
begin
set_varstate(left,vs_used,true);
resulttype:=left.resulttype;
end
else
begin
{ Do we need arrayconstructor -> set conversion, then insert
it here before the arrayconstructor node breaks the tree
with its conversions of enum->ord }
if (left.nodetype=arrayconstructorn) and
(paraitem.paratype.def.deftype=setdef) then
inserttypeconv(left,paraitem.paratype);
{ set some settings needed for arrayconstructor }
if is_array_constructor(left.resulttype.def) then
begin
if is_array_of_const(paraitem.paratype.def) then
begin
{ force variant array }
include(left.flags,nf_forcevaria);
end
else
begin
include(left.flags,nf_novariaallowed);
{ now that the resultting type is know we can insert the required
typeconvs for the array constructor }
tarrayconstructornode(left).force_type(tarraydef(paraitem.paratype.def).elementtype);
end;
end;
{ check if local proc/func is assigned to procvar }
if left.resulttype.def.deftype=procvardef then
test_local_to_procvar(tprocvardef(left.resulttype.def),paraitem.paratype.def);
{ test conversions }
if not(is_shortstring(left.resulttype.def) and
is_shortstring(paraitem.paratype.def)) and
(paraitem.paratype.def.deftype<>formaldef) then
begin
{ Process open parameters }
if paramanager.push_high_param(paraitem.paratyp,paraitem.paratype.def,aktcallnode.procdefinition.proccalloption) then
begin
{ insert type conv but hold the ranges of the array }
oldtype:=left.resulttype;
inserttypeconv(left,paraitem.paratype);
left.resulttype:=oldtype;
end
else
begin
{ for ordinals, floats and enums, verify if we might cause
some range-check errors. }
if (paraitem.paratype.def.deftype in [enumdef,orddef,floatdef]) and
(left.resulttype.def.deftype in [enumdef,orddef,floatdef]) and
(left.nodetype in [vecn,loadn,calln]) then
begin
if (left.resulttype.def.size>paraitem.paratype.def.size) then
begin
if (cs_check_range in aktlocalswitches) then
Message(type_w_smaller_possible_range_check)
else
Message(type_h_smaller_possible_range_check);
end;
end;
inserttypeconv(left,paraitem.paratype);
end;
if codegenerror then
begin
dec(parsing_para_level);
exit;
end;
end;
{ check var strings }
if (cs_strict_var_strings in aktlocalswitches) and
is_shortstring(left.resulttype.def) and
is_shortstring(paraitem.paratype.def) and
(paraitem.paratyp in [vs_out,vs_var]) and
not(is_open_string(paraitem.paratype.def)) and
not(equal_defs(left.resulttype.def,paraitem.paratype.def)) then
begin
aktfilepos:=left.fileinfo;
CGMessage(type_e_strict_var_string_violation);
end;
{ Handle formal parameters separate }
if (paraitem.paratype.def.deftype=formaldef) then
begin
{ load procvar if a procedure is passed }
if (m_tp_procvar in aktmodeswitches) and
(left.nodetype=calln) and
(is_void(left.resulttype.def)) then
load_procvar_from_calln(left);
case paraitem.paratyp of
vs_var,
vs_out :
begin
if not valid_for_formal_var(left) then
CGMessagePos(left.fileinfo,parser_e_illegal_parameter_list);
end;
vs_const :
begin
if not valid_for_formal_const(left) then
CGMessagePos(left.fileinfo,parser_e_illegal_parameter_list);
end;
end;
end
else
begin
{ check if the argument is allowed }
if (paraitem.paratyp in [vs_out,vs_var]) then
valid_for_var(left);
end;
if paraitem.paratyp in [vs_var,vs_const] then
begin
{ Causes problems with const ansistrings if also }
{ done for vs_const (JM) }
if paraitem.paratyp = vs_var then
set_unique(left);
make_not_regable(left);
end;
{ ansistrings out paramaters doesn't need to be }
{ unique, they are finalized }
if paraitem.paratyp=vs_out then
make_not_regable(left);
if do_count then
begin
if paraitem.paratyp in [vs_var,vs_out] then
set_varstate(left,vs_used,false)
else
set_varstate(left,vs_used,true);
end;
{ must only be done after typeconv PM }
resulttype:=paraitem.paratype;
end;
end;
{ process next node }
if assigned(right) then
tcallparanode(right).insert_typeconv(do_count);
dec(parsing_para_level);
{$ifdef extdebug}
if do_count then
count_ref:=store_count_ref;
{$endif def extdebug}
end;
procedure tcallparanode.det_registers;
begin
if assigned(right) then
begin
tcallparanode(right).det_registers;
registersint:=right.registersint;
registersfpu:=right.registersfpu;
{$ifdef SUPPORT_MMX}
registersmmx:=right.registersmmx;
{$endif}
end;
firstpass(left);
if left.registersint>registersint then
registersint:=left.registersint;
if left.registersfpu>registersfpu then
registersfpu:=left.registersfpu;
{$ifdef SUPPORT_MMX}
if left.registersmmx>registersmmx then
registersmmx:=left.registersmmx;
{$endif SUPPORT_MMX}
end;
procedure tcallparanode.firstcallparan;
begin
if not assigned(left.resulttype.def) then
get_paratype;
det_registers;
end;
function tcallparanode.docompare(p: tnode): boolean;
begin
docompare :=
inherited docompare(p) and
(callparaflags = tcallparanode(p).callparaflags)
;
end;
procedure tcallparanode.printnodetree(var t:text);
begin
printnodelist(t);
end;
{****************************************************************************
TCALLNODE
****************************************************************************}
constructor tcallnode.create(l:tnode;v : tprocsym;st : tsymtable; mp: tnode; callflags:tcallnodeflags);
begin
inherited create(calln,l,nil);
symtableprocentry:=v;
symtableproc:=st;
callnodeflags:=callflags+[cnf_return_value_used];
methodpointer:=mp;
methodpointerinit:=nil;
methodpointerdone:=nil;
procdefinition:=nil;
_funcretnode:=nil;
inlinecode:=nil;
paralength:=-1;
varargsparas:=nil;
end;
constructor tcallnode.create_procvar(l,r:tnode);
begin
inherited create(calln,l,r);
symtableprocentry:=nil;
symtableproc:=nil;
methodpointer:=nil;
methodpointerinit:=nil;
methodpointerdone:=nil;
procdefinition:=nil;
callnodeflags:=[cnf_return_value_used];
_funcretnode:=nil;
inlinecode:=nil;
paralength:=-1;
varargsparas:=nil;
end;
constructor tcallnode.createintern(const name: string; params: tnode);
var
srsym: tsym;
symowner: tsymtable;
begin
if not (cs_compilesystem in aktmoduleswitches) then
begin
srsym := searchsymonlyin(systemunit,name);
symowner := systemunit;
end
else
begin
searchsym(name,srsym,symowner);
if not assigned(srsym) then
searchsym(upper(name),srsym,symowner);
end;
if not assigned(srsym) or
(srsym.typ <> procsym) then
begin
{$ifdef EXTDEBUG}
Comment(V_Error,'unknown compilerproc '+name);
{$endif EXTDEBUG}
internalerror(200107271);
end;
self.create(params,tprocsym(srsym),symowner,nil,[]);
end;
constructor tcallnode.createinternres(const name: string; params: tnode; const res: ttype);
begin
self.createintern(name,params);
restype := res;
include(callnodeflags,cnf_restypeset);
{ both the normal and specified resulttype either have to be returned via a }
{ parameter or not, but no mixing (JM) }
if paramanager.ret_in_param(restype.def,pocall_compilerproc) xor
paramanager.ret_in_param(symtableprocentry.first_procdef.rettype.def,symtableprocentry.first_procdef.proccalloption) then
internalerror(200108291);
end;
constructor tcallnode.createinternreturn(const name: string; params: tnode; returnnode : tnode);
begin
self.createintern(name,params);
_funcretnode:=returnnode;
if not paramanager.ret_in_param(symtableprocentry.first_procdef.rettype.def,symtableprocentry.first_procdef.proccalloption) then
internalerror(200204247);
end;
procedure tcallnode.setfuncretnode(const returnnode: tnode);
var
para: tcallparanode;
begin
if assigned(_funcretnode) then
_funcretnode.free;
_funcretnode := returnnode;
{ if the resulttype pass hasn't occurred yet, that one will do }
{ everything }
if assigned(resulttype.def) then
begin
{ these are returned as values, but we can optimize their loading }
{ as well }
if is_ansistring(resulttype.def) or
is_widestring(resulttype.def) then
exit;
para := tcallparanode(left);
while assigned(para) do
begin
if para.paraitem.is_hidden and
(vo_is_funcret in tvarsym(para.paraitem.parasym).varoptions) then
begin
para.left.free;
para.left := _funcretnode.getcopy;
exit;
end;
para := tcallparanode(para.right);
end;
{ no hidden resultpara found, error! }
internalerror(200306087);
end;
end;
destructor tcallnode.destroy;
begin
methodpointer.free;
methodpointerinit.free;
methodpointerdone.free;
_funcretnode.free;
inlinecode.free;
if assigned(varargsparas) then
varargsparas.free;
inherited destroy;
end;
constructor tcallnode.ppuload(t:tnodetype;ppufile:tcompilerppufile);
begin
inherited ppuload(t,ppufile);
ppufile.getderef(symtableprocentryderef);
{$ifdef fpc}
{$warning FIXME: No withsymtable support}
{$endif}
symtableproc:=nil;
ppufile.getderef(procdefinitionderef);
ppufile.getsmallset(callnodeflags);
methodpointer:=ppuloadnode(ppufile);
methodpointerinit:=ppuloadnode(ppufile);
methodpointerdone:=ppuloadnode(ppufile);
_funcretnode:=ppuloadnode(ppufile);
inlinecode:=ppuloadnode(ppufile);
end;
procedure tcallnode.ppuwrite(ppufile:tcompilerppufile);
begin
inherited ppuwrite(ppufile);
ppufile.putderef(symtableprocentryderef);
ppufile.putderef(procdefinitionderef);
ppufile.putsmallset(callnodeflags);
ppuwritenode(ppufile,methodpointer);
ppuwritenode(ppufile,methodpointerinit);
ppuwritenode(ppufile,methodpointerdone);
ppuwritenode(ppufile,_funcretnode);
ppuwritenode(ppufile,inlinecode);
end;
procedure tcallnode.buildderefimpl;
begin
inherited buildderefimpl;
symtableprocentryderef.build(symtableprocentry);
procdefinitionderef.build(procdefinition);
if assigned(methodpointer) then
methodpointer.buildderefimpl;
if assigned(methodpointerinit) then
methodpointerinit.buildderefimpl;
if assigned(methodpointerdone) then
methodpointerdone.buildderefimpl;
if assigned(_funcretnode) then
_funcretnode.buildderefimpl;
if assigned(inlinecode) then
inlinecode.buildderefimpl;
end;
procedure tcallnode.derefimpl;
var
pt : tcallparanode;
currpara : tparaitem;
begin
inherited derefimpl;
symtableprocentry:=tprocsym(symtableprocentryderef.resolve);
symtableproc:=symtableprocentry.owner;
procdefinition:=tprocdef(procdefinitionderef.resolve);
if assigned(methodpointer) then
methodpointer.derefimpl;
if assigned(methodpointerinit) then
methodpointerinit.derefimpl;
if assigned(methodpointerdone) then
methodpointerdone.derefimpl;
if assigned(_funcretnode) then
_funcretnode.derefimpl;
if assigned(inlinecode) then
inlinecode.derefimpl;
{ Connect paraitems }
pt:=tcallparanode(left);
while assigned(pt) and
(cpf_varargs_para in pt.callparaflags) do
pt:=tcallparanode(pt.right);
currpara:=tparaitem(procdefinition.Para.last);
while assigned(currpara) do
begin
if not assigned(pt) then
internalerror(200311077);
pt.paraitem:=currpara;
pt:=tcallparanode(pt.right);
currpara:=tparaitem(currpara.previous);
end;
if assigned(currpara) or assigned(pt) then
internalerror(200311078);
end;
function tcallnode.getcopy : tnode;
var
n : tcallnode;
hp : tparaitem;
oldleft : tnode;
begin
{ Need to use a hack here to prevent the parameters from being copied.
The parameters must be copied between methodpointerinit/methodpointerdone because
the can reference methodpointer }
oldleft:=left;
left:=nil;
n:=tcallnode(inherited getcopy);
left:=oldleft;
n.symtableprocentry:=symtableprocentry;
n.symtableproc:=symtableproc;
n.procdefinition:=procdefinition;
n.restype := restype;
n.callnodeflags := callnodeflags;
if assigned(methodpointerinit) then
n.methodpointerinit:=methodpointerinit.getcopy
else
n.methodpointerinit:=nil;
{ methodpointerinit is copied, now references to the temp will also be copied
correctly. We can now copy the parameters and methodpointer }
if assigned(left) then
n.left:=left.getcopy
else
n.left:=nil;
if assigned(methodpointer) then
n.methodpointer:=methodpointer.getcopy
else
n.methodpointer:=nil;
if assigned(methodpointerdone) then
n.methodpointerdone:=methodpointerdone.getcopy
else
n.methodpointerdone:=nil;
if assigned(_funcretnode) then
n._funcretnode:=_funcretnode.getcopy
else
n._funcretnode:=nil;
if assigned(inlinecode) then
n.inlinecode:=inlinecode.getcopy
else
n.inlinecode:=nil;
if assigned(varargsparas) then
begin
n.varargsparas:=tvarargspara.create;
hp:=tparaitem(varargsparas.first);
while assigned(hp) do
begin
n.varargsparas.concat(hp.getcopy);
hp:=tparaitem(hp.next);
end;
end
else
n.varargsparas:=nil;
result:=n;
end;
procedure tcallnode.insertintolist(l : tnodelist);
begin
end;
procedure tcallnode.convert_carg_array_of_const;
var
hp : tarrayconstructornode;
oldleft : tcallparanode;
begin
oldleft:=tcallparanode(left);
if oldleft.left.nodetype<>arrayconstructorn then
begin
CGMessage1(type_e_wrong_type_in_array_constructor,oldleft.left.resulttype.def.typename);
exit;
end;
{ Get arrayconstructor node and insert typeconvs }
hp:=tarrayconstructornode(oldleft.left);
hp.insert_typeconvs;
{ Add c args parameters }
{ It could be an empty set }
if assigned(hp) and
assigned(hp.left) then
begin
while assigned(hp) do
begin
left:=ccallparanode.create(hp.left,left);
{ set callparanode resulttype and flags }
left.resulttype:=hp.left.resulttype;
include(tcallparanode(left).callparaflags,cpf_varargs_para);
hp.left:=nil;
hp:=tarrayconstructornode(hp.right);
end;
end;
{ Remove value of old array of const parameter, but keep it
in the list because it is required for bind_paraitem.
Generate a nothign to keep callparanoed.left valid }
oldleft.left.free;
oldleft.left:=cnothingnode.create;
end;
procedure tcallnode.verifyabstract(p : tnamedindexitem;arg:pointer);
var
hp : tprocdef;
j: integer;
begin
if (tsym(p).typ=procsym) then
begin
for j:=1 to tprocsym(p).procdef_count do
begin
{ index starts at 1 }
hp:=tprocsym(p).procdef[j];
{ If this is an abstract method insert into the list }
if (po_abstractmethod in hp.procoptions) then
AbstractMethodsList.Insert(hp.procsym.name)
else
{ If this symbol is already in the list, and it is
an overriding method or dynamic, then remove it from the list
}
begin
{ symbol was found }
if AbstractMethodsList.Find(hp.procsym.name) <> nil then
begin
if po_overridingmethod in hp.procoptions then
AbstractMethodsList.Remove(hp.procsym.name);
end;
end;
end;
end;
end;
procedure tcallnode.verifyabstractcalls;
var
objectdf : tobjectdef;
parents : tlinkedlist;
objectinfo : tobjectinfoitem;
stritem : tstringlistitem;
begin
objectdf := nil;
{ verify if trying to create an instance of a class which contains
non-implemented abstract methods }
{ first verify this class type, no class than exit }
{ also, this checking can only be done if the constructor is directly
called, indirect constructor calls cannot be checked.
}
if assigned(methodpointer) then
begin
if (methodpointer.resulttype.def.deftype = objectdef) then
objectdf:=tobjectdef(methodpointer.resulttype.def)
else
if (methodpointer.resulttype.def.deftype = classrefdef) and
(tclassrefdef(methodpointer.resulttype.def).pointertype.def.deftype = objectdef) and
(methodpointer.nodetype in [typen,loadvmtaddrn]) then
objectdf:=tobjectdef(tclassrefdef(methodpointer.resulttype.def).pointertype.def);
end;
if not assigned(objectdf) then
exit;
parents := tlinkedlist.create;
AbstractMethodsList := tstringlist.create;
{ insert all parents in this class : the first item in the
list will be the base parent of the class .
}
while assigned(objectdf) do
begin
objectinfo:=tobjectinfoitem.create(objectdf);
parents.insert(objectinfo);
objectdf := objectdf.childof;
end;
{ now all parents are in the correct order
insert all abstract methods in the list, and remove
those which are overriden by parent classes.
}
objectinfo:=tobjectinfoitem(parents.first);
while assigned(objectinfo) do
begin
objectdf := objectinfo.objinfo;
if assigned(objectdf.symtable) then
objectdf.symtable.foreach({$ifdef FPCPROCVAR}@{$endif}verifyabstract,nil);
objectinfo:=tobjectinfoitem(objectinfo.next);
end;
if assigned(parents) then
parents.free;
{ Finally give out a warning for each abstract method still in the list }
stritem := tstringlistitem(AbstractMethodsList.first);
if assigned(stritem) then
Message1(type_w_instance_with_abstract,objectdf.objname^);
while assigned(stritem) do
begin
if assigned(stritem.fpstr) then
Message1(sym_h_param_list,stritem.str);
stritem := tstringlistitem(stritem.next);
end;
if assigned(AbstractMethodsList) then
AbstractMethodsList.Free;
end;
function tcallnode.gen_self_tree_methodpointer:tnode;
var
hsym : tvarsym;
begin
{ find self field in methodpointer record }
hsym:=tvarsym(trecorddef(methodpointertype.def).symtable.search('self'));
if not assigned(hsym) then
internalerror(200305251);
{ Load tmehodpointer(right).self }
result:=csubscriptnode.create(
hsym,
ctypeconvnode.create_explicit(right.getcopy,methodpointertype));
end;
function tcallnode.gen_self_tree:tnode;
var
selftree : tnode;
begin
selftree:=nil;
{ inherited }
if (cnf_inherited in callnodeflags) then
selftree:=load_self_node
else
{ constructors }
if (procdefinition.proctypeoption=potype_constructor) then
begin
{ push 0 as self when allocation is needed }
if (methodpointer.resulttype.def.deftype=classrefdef) or
(cnf_new_call in callnodeflags) then
selftree:=cpointerconstnode.create(0,voidpointertype)
else
begin
if methodpointer.nodetype=typen then
selftree:=load_self_node
else
selftree:=methodpointer.getcopy;
end;
end
else
{ Calling a static/class method }
if (po_classmethod in procdefinition.procoptions) or
(po_staticmethod in procdefinition.procoptions) then
begin
if (procdefinition.deftype<>procdef) then
internalerror(200305062);
if (oo_has_vmt in tprocdef(procdefinition)._class.objectoptions) then
begin
{ we only need the vmt, loading self is not required and there is no
need to check for typen, because that will always get the
loadvmtaddrnode added }
selftree:=methodpointer.getcopy;
if methodpointer.resulttype.def.deftype<>classrefdef then
selftree:=cloadvmtaddrnode.create(selftree);
end
else
selftree:=cpointerconstnode.create(0,voidpointertype);
end
else
begin
if methodpointer.nodetype=typen then
selftree:=load_self_node
else
selftree:=methodpointer.getcopy;
end;
result:=selftree;
end;
function tcallnode.gen_vmt_tree:tnode;
var
vmttree : tnode;
begin
vmttree:=nil;
if not(procdefinition.proctypeoption in [potype_constructor,potype_destructor]) then
internalerror(200305051);
{ inherited call, no create/destroy }
if (cnf_inherited in callnodeflags) then
vmttree:=cpointerconstnode.create(0,voidpointertype)
else
{ do not create/destroy when called from member function
without specifying self explicit }
if (cnf_member_call in callnodeflags) then
begin
if (methodpointer.resulttype.def.deftype=classrefdef) and
(procdefinition.proctypeoption=potype_constructor) then
vmttree:=methodpointer.getcopy
else
vmttree:=cpointerconstnode.create(0,voidpointertype);
end
else
{ constructor with extended syntax called from new }
if (cnf_new_call in callnodeflags) then
vmttree:=cloadvmtaddrnode.create(ctypenode.create(methodpointer.resulttype))
else
{ destructor with extended syntax called from dispose }
if (cnf_dispose_call in callnodeflags) then
vmttree:=cloadvmtaddrnode.create(methodpointer.getcopy)
else
if (methodpointer.resulttype.def.deftype=classrefdef) then
begin
{ constructor call via classreference => allocate memory }
if (procdefinition.proctypeoption=potype_constructor) and
is_class(tclassrefdef(methodpointer.resulttype.def).pointertype.def) then
begin
vmttree:=methodpointer.getcopy;
{ Only a typenode can be passed when it is called with <class of xx>.create }
if vmttree.nodetype=typen then
vmttree:=cloadvmtaddrnode.create(vmttree);
end
else
vmttree:=cpointerconstnode.create(0,voidpointertype);
end
else
{ class }
if is_class(methodpointer.resulttype.def) then
begin
{ destructor: release instance, flag(vmt)=1
constructor: direct call, do nothing, leave vmt=0 }
if (procdefinition.proctypeoption=potype_destructor) then
vmttree:=cpointerconstnode.create(1,voidpointertype)
else
vmttree:=cpointerconstnode.create(0,voidpointertype);
end
else
{ object }
begin
{ destructor: direct call, no dispose, vmt=0
constructor: initialize object, load vmt }
if (procdefinition.proctypeoption=potype_constructor) then
{ old styled inherited call? }
if (methodpointer.nodetype=typen) then
vmttree:=cpointerconstnode.create(0,voidpointertype)
else
vmttree:=cloadvmtaddrnode.create(ctypenode.create(methodpointer.resulttype))
else
vmttree:=cpointerconstnode.create(0,voidpointertype);
end;
result:=vmttree;
end;
procedure tcallnode.bind_paraitem;
var
i : integer;
pt : tcallparanode;
oldppt : ^tcallparanode;
varargspara,
currpara : tparaitem;
used_by_callnode : boolean;
hiddentree : tnode;
newstatement : tstatementnode;
temp : ttempcreatenode;
begin
pt:=tcallparanode(left);
oldppt:=@left;
{ flag all callparanodes that belong to the varargs }
i:=paralength;
while (i>procdefinition.maxparacount) do
begin
include(pt.callparaflags,cpf_varargs_para);
oldppt:=@pt.right;
pt:=tcallparanode(pt.right);
dec(i);
end;
{ skip varargs that are inserted by array of const }
while assigned(pt) and
(cpf_varargs_para in pt.callparaflags) do
pt:=tcallparanode(pt.right);
{ process normal parameters and insert hidden parameters }
currpara:=tparaitem(procdefinition.Para.last);
while assigned(currpara) do
begin
if currpara.is_hidden then
begin
{ generate hidden tree }
used_by_callnode:=false;
hiddentree:=nil;
if (vo_is_funcret in tvarsym(currpara.parasym).varoptions) then
begin
{ Generate funcretnode if not specified }
if assigned(funcretnode) then
begin
hiddentree:=funcretnode.getcopy;
end
else
begin
hiddentree:=internalstatements(newstatement);
{ need to use resulttype instead of procdefinition.rettype,
because they can be different }
temp:=ctempcreatenode.create(resulttype,resulttype.def.size,tt_persistent);
addstatement(newstatement,temp);
addstatement(newstatement,ctempdeletenode.create_normal_temp(temp));
addstatement(newstatement,ctemprefnode.create(temp));
end;
end
else
if vo_is_high_value in tvarsym(currpara.parasym).varoptions then
begin
if not assigned(pt) then
internalerror(200304082);
{ we need the information of the previous parameter }
hiddentree:=gen_high_tree(pt.left,tparaitem(currpara.previous).paratype.def);
end
else
if vo_is_self in tvarsym(currpara.parasym).varoptions then
begin
if assigned(right) then
hiddentree:=gen_self_tree_methodpointer
else
hiddentree:=gen_self_tree;
end
else
if vo_is_vmt in tvarsym(currpara.parasym).varoptions then
begin
hiddentree:=gen_vmt_tree;
end
else
if vo_is_parentfp in tvarsym(currpara.parasym).varoptions then
begin
if not(assigned(procdefinition.owner.defowner)) then
internalerror(200309287);
hiddentree:=cloadparentfpnode.create(tprocdef(procdefinition.owner.defowner));
end
{$ifdef powerpc}
else
{ lib parameter has no special type but proccalloptions must be a syscall }
if (target_info.system in [system_powerpc_morphos,system_m68k_amiga]) and
(procdefinition.proccalloption=pocall_syscall) then
begin
hiddentree:=cloadnode.create(tprocdef(procdefinition).libsym,tprocdef(procdefinition).libsym.owner);
end
{$endif powerpc}
else
{ add the hidden parameter }
if not assigned(hiddentree) then
internalerror(200304073);
{ Already insert para and let the previous node point to
this new node }
pt:=ccallparanode.create(hiddentree,oldppt^);
pt.used_by_callnode:=used_by_callnode;
oldppt^:=pt;
end;
if not assigned(pt) then
internalerror(200310052);
pt.paraitem:=currpara;
oldppt:=@pt.right;
pt:=tcallparanode(pt.right);
currpara:=tparaitem(currpara.previous)
end;
{ Create paraitems for varargs }
pt:=tcallparanode(left);
while assigned(pt) do
begin
if cpf_varargs_para in pt.callparaflags then
begin
if not assigned(varargsparas) then
varargsparas:=tvarargspara.create;
varargspara:=tparaitem.create;
varargspara.paratyp:=vs_value;
varargspara.paratype:=pt.resulttype;
{ varargspara is left-right, use insert
instead of concat }
varargsparas.insert(varargspara);
pt.paraitem:=varargspara;
end;
pt:=tcallparanode(pt.right);
end;
end;
function tcallnode.det_resulttype:tnode;
var
candidates : tcallcandidates;
oldcallnode : tcallnode;
hpt : tnode;
pt : tcallparanode;
lastpara : longint;
currpara : tparaitem;
cand_cnt : integer;
i : longint;
method_must_be_valid,
is_const : boolean;
hp : tnode;
mptemp : ttempcreatenode;
newstatement : tstatementnode;
label
errorexit;
begin
result:=nil;
candidates:=nil;
oldcallnode:=aktcallnode;
aktcallnode:=nil;
{ determine length of parameter list }
pt:=tcallparanode(left);
paralength:=0;
while assigned(pt) do
begin
inc(paralength);
pt:=tcallparanode(pt.right);
end;
{ determine the type of the parameters }
if assigned(left) then
begin
tcallparanode(left).get_paratype;
if codegenerror then
goto errorexit;
end;
if assigned(methodpointer) then
begin
resulttypepass(methodpointer);
hp:=methodpointer;
while assigned(hp) and
(hp.nodetype=typeconvn) do
hp:=tunarynode(hp).left;
if assigned(hp) and
(
{ call result must always be loaded in temp to prevent
double creation }
(hp.nodetype=calln)
{ Also optimize also complex loads }
{$warning Complex loads can also be optimized}
// not(hp.nodetype in [typen,loadvmtaddrn,loadn])
) then
begin
{ methodpointer loading }
methodpointerinit:=internalstatements(newstatement);
mptemp:=ctempcreatenode.create_reg(methodpointer.resulttype,methodpointer.resulttype.def.size,tt_persistent);
addstatement(newstatement,mptemp);
addstatement(newstatement,cassignmentnode.create(
ctemprefnode.create(mptemp),
methodpointer));
resulttypepass(methodpointerinit);
{ new methodpointer is only a temp reference }
methodpointer:=ctemprefnode.create(mptemp);
resulttypepass(methodpointer);
{ methodpointer cleanup }
methodpointerdone:=ctempdeletenode.create(mptemp);
resulttypepass(methodpointerdone);
end;
end;
{ procedure variable ? }
if assigned(right) then
begin
set_varstate(right,vs_used,true);
resulttypepass(right);
if codegenerror then
exit;
procdefinition:=tabstractprocdef(right.resulttype.def);
{ Compare parameters from right to left }
currpara:=tparaitem(procdefinition.Para.last);
{ Skip default parameters }
if not(po_varargs in procdefinition.procoptions) then
begin
{ ignore hidden parameters }
while assigned(currpara) and (currpara.is_hidden) do
currpara:=tparaitem(currpara.previous);
for i:=1 to procdefinition.maxparacount-paralength do
begin
if not assigned(currpara) then
internalerror(200402261);
if not assigned(currpara.defaultvalue) then
begin
CGMessage(parser_e_wrong_parameter_size);
goto errorexit;
end;
currpara:=tparaitem(currpara.previous);
end;
end;
while assigned(currpara) and (currpara.is_hidden) do
currpara:=tparaitem(currpara.previous);
pt:=tcallparanode(left);
lastpara:=paralength;
while assigned(currpara) and assigned(pt) do
begin
{ only goto next para if we're out of the varargs }
if not(po_varargs in procdefinition.procoptions) or
(lastpara<=procdefinition.maxparacount) then
begin
repeat
currpara:=tparaitem(currpara.previous);
until (not assigned(currpara)) or (not currpara.is_hidden);
end;
pt:=tcallparanode(pt.right);
dec(lastpara);
end;
if assigned(pt) or
(assigned(currpara) and
not assigned(currpara.defaultvalue)) then
begin
if assigned(pt) then
aktfilepos:=pt.fileinfo;
CGMessage(parser_e_wrong_parameter_size);
goto errorexit;
end;
end
else
{ not a procedure variable }
begin
{ do we know the procedure to call ? }
if not(assigned(procdefinition)) then
begin
candidates:=tcallcandidates.create(symtableprocentry,symtableproc,left,(nf_isproperty in flags));
{ no procedures found? then there is something wrong
with the parameter size or the procedures are
not accessible }
if candidates.count=0 then
begin
{ when it's an auto inherited call and there
is no procedure found, but the procedures
were defined with overload directive and at
least two procedures are defined then we ignore
this inherited by inserting a nothingn. Only
do this ugly hack in Delphi mode as it looks more
like a bug. It's also not documented }
if (m_delphi in aktmodeswitches) and
(cnf_anon_inherited in callnodeflags) and
(symtableprocentry.owner.symtabletype=objectsymtable) and
(po_overload in symtableprocentry.first_procdef.procoptions) and
(symtableprocentry.procdef_count>=2) then
result:=cnothingnode.create
else
begin
{ in tp mode we can try to convert to procvar if
there are no parameters specified. Only try it
when there is only one proc definition, else the
loadnode will give a strange error }
if not(assigned(left)) and
not(cnf_inherited in callnodeflags) and
(m_tp_procvar in aktmodeswitches) and
(symtableprocentry.procdef_count=1) then
begin
hpt:=cloadnode.create(tprocsym(symtableprocentry),symtableproc);
if assigned(methodpointer) then
tloadnode(hpt).set_mp(methodpointer.getcopy);
resulttypepass(hpt);
result:=hpt;
end
else
begin
if assigned(left) then
aktfilepos:=left.fileinfo;
CGMessage(parser_e_wrong_parameter_size);
symtableprocentry.write_parameter_lists(nil);
end;
end;
goto errorexit;
end;
{ Retrieve information about the candidates }
candidates.get_information;
{$ifdef EXTDEBUG}
{ Display info when multiple candidates are found }
if candidates.count>1 then
candidates.dump_info(V_Debug);
{$endif EXTDEBUG}
{ Choose the best candidate and count the number of
candidates left }
cand_cnt:=candidates.choose_best(procdefinition);
{ All parameters are checked, check if there are any
procedures left }
if cand_cnt>0 then
begin
{ Multiple candidates left? }
if cand_cnt>1 then
begin
CGMessage(type_e_cant_choose_overload_function);
{$ifdef EXTDEBUG}
candidates.dump_info(V_Hint);
{$else EXTDEBUG}
candidates.list(false);
{$endif EXTDEBUG}
{ we'll just use the first candidate to make the
call }
end;
{ assign procdefinition }
if symtableproc=nil then
symtableproc:=procdefinition.owner;
{ update browser information }
if make_ref then
begin
tprocdef(procdefinition).lastref:=tref.create(tprocdef(procdefinition).lastref,@fileinfo);
inc(tprocdef(procdefinition).refcount);
if tprocdef(procdefinition).defref=nil then
tprocdef(procdefinition).defref:=tprocdef(procdefinition).lastref;
end;
end
else
begin
{ No candidates left, this must be a type error,
because wrong size is already checked. procdefinition
is filled with the first (random) definition that is
found. We use this definition to display a nice error
message that the wrong type is passed }
candidates.find_wrong_para;
candidates.list(true);
{$ifdef EXTDEBUG}
candidates.dump_info(V_Hint);
{$endif EXTDEBUG}
{ We can not proceed, release all procs and exit }
candidates.free;
goto errorexit;
end;
candidates.free;
end; { end of procedure to call determination }
end;
{ add needed default parameters }
if assigned(procdefinition) and
(paralength<procdefinition.maxparacount) then
begin
currpara:=tparaitem(procdefinition.Para.first);
i:=0;
while (i<paralength) do
begin
if not assigned(currpara) then
internalerror(200306181);
if not currpara.is_hidden then
inc(i);
currpara:=tparaitem(currpara.next);
end;
while assigned(currpara) and currpara.is_hidden do
currpara:=tparaitem(currpara.next);
while assigned(currpara) do
begin
if not assigned(currpara.defaultvalue) then
internalerror(200212142);
left:=ccallparanode.create(genconstsymtree(tconstsym(currpara.defaultvalue)),left);
{ Ignore vs_hidden parameters }
repeat
currpara:=tparaitem(currpara.next);
until (not assigned(currpara)) or (not currpara.is_hidden);
end;
end;
{ handle predefined procedures }
is_const:=(po_internconst in procdefinition.procoptions) and
((block_type in [bt_const,bt_type]) or
(assigned(left) and (tcallparanode(left).left.nodetype in [realconstn,ordconstn])));
if (procdefinition.proccalloption=pocall_internproc) or is_const then
begin
if assigned(left) then
begin
{ ptr and settextbuf needs two args }
if assigned(tcallparanode(left).right) then
begin
hpt:=geninlinenode(tprocdef(procdefinition).extnumber,is_const,left);
left:=nil;
end
else
begin
hpt:=geninlinenode(tprocdef(procdefinition).extnumber,is_const,tcallparanode(left).left);
tcallparanode(left).left:=nil;
end;
end
else
hpt:=geninlinenode(tprocdef(procdefinition).extnumber,is_const,nil);
result:=hpt;
goto errorexit;
end;
{ ensure that the result type is set }
if not(cnf_restypeset in callnodeflags) then
begin
{ constructors return their current class type, not the type where the
constructor is declared, this can be different because of inheritance }
if (procdefinition.proctypeoption=potype_constructor) and
assigned(methodpointer) and
assigned(methodpointer.resulttype.def) and
(methodpointer.resulttype.def.deftype=classrefdef) then
resulttype:=tclassrefdef(methodpointer.resulttype.def).pointertype
else
resulttype:=procdefinition.rettype;
end
else
resulttype:=restype;
{if resulttype.def.needs_inittable then
include(current_procinfo.flags,pi_needs_implicit_finally);}
if assigned(methodpointer) then
begin
{ when methodpointer is a callnode we must load it first into a
temp to prevent the processing callnode twice }
if (methodpointer.nodetype=calln) then
internalerror(200405121);
{ direct call to inherited abstract method, then we
can already give a error in the compiler instead
of a runtime error }
if (cnf_inherited in callnodeflags) and
(po_abstractmethod in procdefinition.procoptions) then
CGMessage(cg_e_cant_call_abstract_method);
{ if an inherited con- or destructor should be }
{ called in a con- or destructor then a warning }
{ will be made }
{ con- and destructors need a pointer to the vmt }
if (cnf_inherited in callnodeflags) and
(procdefinition.proctypeoption in [potype_constructor,potype_destructor]) and
is_object(methodpointer.resulttype.def) and
not(current_procinfo.procdef.proctypeoption in [potype_constructor,potype_destructor]) then
CGMessage(cg_w_member_cd_call_from_method);
if methodpointer.nodetype<>typen then
begin
{ Remove all postfix operators }
hpt:=methodpointer;
while assigned(hpt) and (hpt.nodetype in [subscriptn,vecn]) do
hpt:=tunarynode(hpt).left;
if (procdefinition.proctypeoption=potype_constructor) and
assigned(symtableproc) and
(symtableproc.symtabletype=withsymtable) and
(tnode(twithsymtable(symtableproc).withrefnode).nodetype=temprefn) then
CGmessage(cg_e_cannot_call_cons_dest_inside_with);
{ R.Init then R will be initialized by the constructor,
Also allow it for simple loads }
if (procdefinition.proctypeoption=potype_constructor) or
((hpt.nodetype=loadn) and
(
(methodpointer.resulttype.def.deftype=classrefdef) or
(
(methodpointer.resulttype.def.deftype=objectdef) and
not(oo_has_virtual in tobjectdef(methodpointer.resulttype.def).objectoptions)
)
)
) then
method_must_be_valid:=false
else
method_must_be_valid:=true;
set_varstate(methodpointer,vs_used,method_must_be_valid);
{ The object is already used if it is called once }
if (hpt.nodetype=loadn) and
(tloadnode(hpt).symtableentry.typ=varsym) then
tvarsym(tloadnode(hpt).symtableentry).varstate:=vs_used;
end;
{ if we are calling the constructor check for abstract
methods. Ignore inherited and member calls, because the
class is then already created }
if (procdefinition.proctypeoption=potype_constructor) and
not(cnf_inherited in callnodeflags) and
not(cnf_member_call in callnodeflags) then
verifyabstractcalls;
end
else
begin
{ When this is method the methodpointer must be available }
if (right=nil) and
(procdefinition.owner.symtabletype=objectsymtable) then
internalerror(200305061);
end;
{ Change loading of array of const to varargs }
if assigned(left) and
is_array_of_const(tparaitem(procdefinition.para.last).paratype.def) and
(procdefinition.proccalloption in [pocall_cppdecl,pocall_cdecl]) then
convert_carg_array_of_const;
{ bind paraitems to the callparanodes and insert hidden parameters }
aktcallnode:=self;
bind_paraitem;
{ methodpointer is only needed for virtual calls, and
it should then be loaded with the VMT }
if (po_virtualmethod in procdefinition.procoptions) and
not(assigned(methodpointer) and
(methodpointer.nodetype=typen)) then
begin
if not assigned(methodpointer) then
internalerror(200305063);
if (methodpointer.resulttype.def.deftype<>classrefdef) then
begin
methodpointer:=cloadvmtaddrnode.create(methodpointer);
resulttypepass(methodpointer);
end;
end
else
begin
{ not needed anymore }
methodpointer.free;
methodpointer:=nil;
end;
{ insert type conversions for parameters }
if assigned(left) then
tcallparanode(left).insert_typeconv(true);
errorexit:
aktcallnode:=oldcallnode;
end;
procedure tcallnode.order_parameters;
var
hp,hpcurr,hpnext,hpfirst,hpprev : tcallparanode;
currloc : tcgloc;
begin
hpfirst:=nil;
hpcurr:=tcallparanode(left);
while assigned(hpcurr) do
begin
{ pull out }
hpnext:=tcallparanode(hpcurr.right);
{ pull in at the correct place.
Used order:
1. LOC_REFERENCE with smallest offset (x86 only)
2. LOC_REFERENCE with most registers
3. LOC_REGISTER with most registers }
currloc:=hpcurr.paraitem.paraloc[callerside].loc;
hpprev:=nil;
hp:=hpfirst;
while assigned(hp) do
begin
case currloc of
LOC_REFERENCE :
begin
case hp.paraitem.paraloc[callerside].loc of
LOC_REFERENCE :
begin
{ Offset is calculated like:
sub esp,12
mov [esp+8],para3
mov [esp+4],para2
mov [esp],para1
call function
That means the for pushes the para with the
highest offset (see para3) needs to be pushed first
}
if (hpcurr.registersint>hp.registersint)
{$ifdef x86}
or (hpcurr.paraitem.paraloc[callerside].reference.offset>hp.paraitem.paraloc[callerside].reference.offset)
{$endif x86}
then
break;
end;
LOC_REGISTER,
LOC_FPUREGISTER :
break;
end;
end;
LOC_FPUREGISTER,
LOC_REGISTER :
begin
if (hp.paraitem.paraloc[callerside].loc=currloc) and
(hpcurr.registersint>hp.registersint) then
break;
end;
end;
hpprev:=hp;
hp:=tcallparanode(hp.right);
end;
hpcurr.right:=hp;
if assigned(hpprev) then
hpprev.right:=hpcurr
else
hpfirst:=hpcurr;
{ next }
hpcurr:=hpnext;
end;
left:=hpfirst;
end;
function tcallnode.pass_1 : tnode;
{$ifdef m68k}
var
regi : tregister;
{$endif}
label
errorexit;
begin
result:=nil;
{ calculate the parameter info for the procdef }
if not procdefinition.has_paraloc_info then
begin
procdefinition.requiredargarea:=paramanager.create_paraloc_info(procdefinition,callerside);
procdefinition.has_paraloc_info:=true;
end;
{ calculate the parameter size needed for this call include varargs if they are available }
if assigned(varargsparas) then
pushedparasize:=paramanager.create_varargs_paraloc_info(procdefinition,varargsparas)
else
pushedparasize:=procdefinition.requiredargarea;
{ record maximum parameter size used in this proc }
current_procinfo.allocate_push_parasize(pushedparasize);
{ work trough all parameters to get the register requirements }
if assigned(left) then
tcallparanode(left).det_registers;
{ order parameters }
order_parameters;
if assigned(methodpointerinit) then
firstpass(methodpointerinit);
if assigned(methodpointerdone) then
firstpass(methodpointerdone);
{ function result node }
if assigned(_funcretnode) then
firstpass(_funcretnode);
{ procedure variable ? }
if assigned(right) then
begin
firstpass(right);
{ procedure does a call }
if not (block_type in [bt_const,bt_type]) then
include(current_procinfo.flags,pi_do_call);
end
else
{ not a procedure variable }
begin
{ calc the correture value for the register }
{ handle predefined procedures }
if (procdefinition.proccalloption=pocall_inline) then
begin
{ inherit flags }
current_procinfo.flags:=current_procinfo.flags+((procdefinition as tprocdef).inlininginfo^.flags*inherited_inlining_flags);
if assigned(methodpointer) then
CGMessage(cg_e_unable_inline_object_methods);
if assigned(right) then
CGMessage(cg_e_unable_inline_procvar);
if not assigned(inlinecode) then
begin
if assigned(tprocdef(procdefinition).inlininginfo^.code) then
inlinecode:=tprocdef(procdefinition).inlininginfo^.code.getcopy
else
CGMessage(cg_e_no_code_for_inline_stored);
if assigned(inlinecode) then
begin
{ consider it has not inlined if called
again inside the args }
procdefinition.proccalloption:=pocall_default;
firstpass(inlinecode);
end;
end;
end
else
begin
if not (block_type in [bt_const,bt_type]) then
include(current_procinfo.flags,pi_do_call);
end;
end;
{ implicit finally needed ? }
if resulttype.def.needs_inittable and
not paramanager.ret_in_param(resulttype.def,procdefinition.proccalloption) and
not assigned(funcretnode) then
include(current_procinfo.flags,pi_needs_implicit_finally);
{ get a register for the return value }
if (not is_void(resulttype.def)) then
begin
if paramanager.ret_in_param(resulttype.def,procdefinition.proccalloption) then
begin
expectloc:=LOC_REFERENCE;
end
else
{ for win32 records returned in EDX:EAX, we
move them to memory after ... }
if (resulttype.def.deftype=recorddef) then
begin
expectloc:=LOC_REFERENCE;
end
else
{ ansi/widestrings must be registered, so we can dispose them }
if is_ansistring(resulttype.def) or
is_widestring(resulttype.def) then
begin
expectloc:=LOC_REFERENCE;
registersint:=1;
end
else
{ we have only to handle the result if it is used }
if (cnf_return_value_used in callnodeflags) then
begin
case resulttype.def.deftype of
enumdef,
orddef :
begin
if (procdefinition.proctypeoption=potype_constructor) then
begin
expectloc:=LOC_REGISTER;
registersint:=1;
end
else
begin
expectloc:=LOC_REGISTER;
if is_64bit(resulttype.def) then
registersint:=2
else
registersint:=1;
end;
end;
floatdef :
begin
expectloc:=LOC_FPUREGISTER;
{$ifdef cpufpemu}
if (cs_fp_emulation in aktmoduleswitches) then
registersint:=1
else
{$endif cpufpemu}
{$ifdef m68k}
if (tfloatdef(resulttype.def).typ=s32real) then
registersint:=1
else
{$endif m68k}
registersfpu:=1;
end;
else
begin
expectloc:=LOC_REGISTER;
registersint:=1;
end;
end;
end
else
expectloc:=LOC_VOID;
end
else
expectloc:=LOC_VOID;
{$ifdef m68k}
{ we need one more address register for virtual calls on m68k }
if (po_virtualmethod in procdefinition.procoptions) then
inc(registersint);
{$endif m68k}
{ a fpu can be used in any procedure !! }
{$ifdef i386}
registersfpu:=procdefinition.fpu_used;
{$endif i386}
{ if this is a call to a method calc the registers }
if (methodpointer<>nil) then
begin
if methodpointer.nodetype<>typen then
begin
firstpass(methodpointer);
registersfpu:=max(methodpointer.registersfpu,registersfpu);
registersint:=max(methodpointer.registersint,registersint);
{$ifdef SUPPORT_MMX }
registersmmx:=max(methodpointer.registersmmx,registersmmx);
{$endif SUPPORT_MMX}
end;
end;
{ determine the registers of the procedure variable }
{ is this OK for inlined procs also ?? (PM) }
if assigned(inlinecode) then
begin
registersfpu:=max(inlinecode.registersfpu,registersfpu);
registersint:=max(inlinecode.registersint,registersint);
{$ifdef SUPPORT_MMX}
registersmmx:=max(inlinecode.registersmmx,registersmmx);
{$endif SUPPORT_MMX}
end;
{ determine the registers of the procedure variable }
{ is this OK for inlined procs also ?? (PM) }
if assigned(right) then
begin
registersfpu:=max(right.registersfpu,registersfpu);
registersint:=max(right.registersint,registersint);
{$ifdef SUPPORT_MMX}
registersmmx:=max(right.registersmmx,registersmmx);
{$endif SUPPORT_MMX}
end;
{ determine the registers of the procedure }
if assigned(left) then
begin
registersfpu:=max(left.registersfpu,registersfpu);
registersint:=max(left.registersint,registersint);
{$ifdef SUPPORT_MMX}
registersmmx:=max(left.registersmmx,registersmmx);
{$endif SUPPORT_MMX}
end;
errorexit:
if assigned(inlinecode) then
procdefinition.proccalloption:=pocall_inline;
end;
{$ifdef state_tracking}
function Tcallnode.track_state_pass(exec_known:boolean):boolean;
var hp:Tcallparanode;
value:Tnode;
begin
track_state_pass:=false;
hp:=Tcallparanode(left);
while assigned(hp) do
begin
if left.track_state_pass(exec_known) then
begin
left.resulttype.def:=nil;
do_resulttypepass(left);
end;
value:=aktstate.find_fact(hp.left);
if value<>nil then
begin
track_state_pass:=true;
hp.left.destroy;
hp.left:=value.getcopy;
do_resulttypepass(hp.left);
end;
hp:=Tcallparanode(hp.right);
end;
end;
{$endif}
function tcallnode.para_count:longint;
var
ppn : tcallparanode;
begin
result:=0;
ppn:=tcallparanode(left);
while assigned(ppn) do
begin
if not(assigned(ppn.paraitem) and
ppn.paraitem.is_hidden) then
inc(result);
ppn:=tcallparanode(ppn.right);
end;
end;
function tcallnode.docompare(p: tnode): boolean;
begin
docompare :=
inherited docompare(p) and
(symtableprocentry = tcallnode(p).symtableprocentry) and
(procdefinition = tcallnode(p).procdefinition) and
(methodpointer.isequal(tcallnode(p).methodpointer)) and
(((cnf_restypeset in callnodeflags) and (cnf_restypeset in tcallnode(p).callnodeflags) and
(equal_defs(restype.def,tcallnode(p).restype.def))) or
(not(cnf_restypeset in callnodeflags) and not(cnf_restypeset in tcallnode(p).callnodeflags)));
end;
procedure tcallnode.printnodedata(var t:text);
begin
if assigned(procdefinition) and
(procdefinition.deftype=procdef) then
writeln(t,printnodeindention,'proc = ',tprocdef(procdefinition).fullprocname(true))
else
begin
if assigned(symtableprocentry) then
writeln(t,printnodeindention,'proc = ',symtableprocentry.name)
else
writeln(t,printnodeindention,'proc = <nil>');
end;
printnode(t,methodpointer);
printnode(t,right);
printnode(t,left);
end;
begin
ccallnode:=tcallnode;
ccallparanode:=tcallparanode;
end.
{
$Log$
Revision 1.239 2004-06-20 08:55:29 florian
* logs truncated
Revision 1.238 2004/06/16 20:07:08 florian
* dwarf branch merged
Revision 1.237 2004/05/25 18:51:49 peter
* fix tcallnode.getcopy. the parameters need to be copied after
methodpointerinit is copied
Revision 1.236 2004/05/24 17:31:51 peter
* fix passing of array to open array of array (bug 3113)
Revision 1.235 2004/05/23 18:28:41 peter
* methodpointer is loaded into a temp when it was a calln
Revision 1.234 2004/05/23 15:06:20 peter
* implicit_finally flag must be set in pass1
* add check whether the implicit frame is generated when expected
}
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