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fpc/compiler/htypechk.pas

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{
Copyright (c) 1998-2002 by Florian Klaempfl
This unit exports some help routines for the type checking
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 htypechk;
{$i fpcdefs.inc}
interface
uses
cclasses,cmsgs,tokens,
node,globtype,compinnr,
symconst,symtype,symdef,symsym,symbase,
pgentype;
type
TSupportedOpOverload = (op_unary, op_binary);
Ttok2nodeRec=record
tok : ttoken;
nod : tnodetype;
inr : tinlinenumber;
supported_op_overloads: set of TSupportedOpOverload;
end;
Ttok2opRec=record
tok : ttoken;
managementoperator : tmanagementoperator;
end;
pcandidate = ^tcandidate;
tcandidate = object
next : pcandidate;
data : tprocdef;
wrongparaidx,
firstparaidx : integer;
te_count : array[te_convert_operator .. te_exact] of integer; { should be signed }
ordinal_distance_lo : uint64;
ordinal_distance_hi,ordinal_distance_secondary : uint32; { “hi” allows summing many uint64s, “secondary” allows tie-break corrections. }
invalid : boolean;
{$ifndef DISABLE_FAST_OVERLOAD_PATCH}
saved_validity : boolean;
{$endif}
wrongparanr : byte;
procedure increment_ordinal_distance(by: uint64);
end;
tcallcandidatesflag =
(
cc_ignorevisibility,cc_allowdefaultparas,cc_objcidcall,cc_explicitunit,cc_searchhelpers,cc_anoninherited
);
tcallcandidatesflags = set of tcallcandidatesflag;
tcallcandidates = object
private
FProcsym : tprocsym;
FProcsymtable : tsymtable;
FOperator : ttoken;
FCandidateProcs : pcandidate;
FIgnoredCandidateProcs : tfplist;
FProcCnt : integer;
FParaNode : tnode;
FParaLength : smallint;
FAllowVariant : boolean;
FParaAnonSyms : tfplist;
procedure collect_overloads_in_struct(structdef:tabstractrecorddef;ProcdefOverloadList:TFPObjectList;flags:tcallcandidatesflags;spezcontext:tspecializationcontext);
procedure collect_overloads_in_units(ProcdefOverloadList:TFPObjectList; flags:tcallcandidatesflags;spezcontext:tspecializationcontext);
procedure create_candidate_list(flags:tcallcandidatesflags;spezcontext:tspecializationcontext);
procedure calc_distance(st_root:tsymtable;flags:tcallcandidatesflags);
function proc_add(st:tsymtable;pd:tprocdef):pcandidate;
public
constructor init(sym:tprocsym;st:TSymtable;ppn:tnode;flags:tcallcandidatesflags;spezcontext:tspecializationcontext);
constructor init_operator(op:ttoken;ppn:tnode);
destructor done;
procedure list(all:boolean);
{$ifdef EXTDEBUG}
procedure dump_info(lvl:longint);
{$endif EXTDEBUG}
procedure get_information;
function choose_best(var bestpd:tabstractprocdef; singlevariant: boolean):integer;
procedure find_wrong_para;
property Count:integer read FProcCnt;
{ list of symbols for anonymous types required for implicit specializations;
these should be handed over to the picked procdef, otherwise they'll be
freed by tcallcandidates }
property para_anon_syms:tfplist read FParaAnonSyms;
end;
type
tregableinfoflag = (
// can be put in a register if it's the address of a var/out/const parameter
ra_addr_regable,
{ orthogonal to above flag: the address of the node is taken and may
possibly escape the block in which this node is declared (e.g. a
local variable is passed as var parameter to another procedure)
}
ra_addr_taken,
{ variable is accessed in a different scope }
ra_different_scope);
tregableinfoflags = set of tregableinfoflag;
const
tok2nodes=27;
tok2node:array[1..tok2nodes] of ttok2noderec=(
(tok:_PLUS ;nod:addn ;inr:in_none ;supported_op_overloads:[op_unary,op_binary]),
(tok:_MINUS ;nod:subn ;inr:in_none ;supported_op_overloads:[op_unary,op_binary]),
(tok:_STAR ;nod:muln ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_SLASH ;nod:slashn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_EQ ;nod:equaln ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_GT ;nod:gtn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_LT ;nod:ltn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_GTE ;nod:gten ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_LTE ;nod:lten ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_SYMDIF ;nod:symdifn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_STARSTAR ;nod:starstarn;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_OP_AS ;nod:asn ;inr:in_none ;supported_op_overloads:[]),
(tok:_OP_IN ;nod:inn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_OP_IS ;nod:isn ;inr:in_none ;supported_op_overloads:[]),
(tok:_OP_OR ;nod:orn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_OP_AND ;nod:andn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_OP_DIV ;nod:divn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_OP_NOT ;nod:notn ;inr:in_none ;supported_op_overloads:[op_unary]),
(tok:_OP_MOD ;nod:modn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_OP_SHL ;nod:shln ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_OP_SHR ;nod:shrn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_OP_XOR ;nod:xorn ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_ASSIGNMENT ;nod:assignn ;inr:in_none ;supported_op_overloads:[op_unary]),
(tok:_OP_EXPLICIT;nod:assignn ;inr:in_none ;supported_op_overloads:[op_unary]),
(tok:_NE ;nod:unequaln ;inr:in_none ;supported_op_overloads:[op_binary]),
(tok:_OP_INC ;nod:inlinen ;inr:in_inc_x;supported_op_overloads:[op_unary]),
(tok:_OP_DEC ;nod:inlinen ;inr:in_dec_x;supported_op_overloads:[op_unary])
);
tok2ops=4;
tok2op: array[1..tok2ops] of ttok2oprec=(
(tok:_OP_INITIALIZE; managementoperator: mop_initialize),
(tok:_OP_FINALIZE ; managementoperator: mop_finalize),
(tok:_OP_ADDREF ; managementoperator: mop_addref),
(tok:_OP_COPY ; managementoperator: mop_copy)
);
function node2opstr(nt:tnodetype):string;
function token2managementoperator(optoken:ttoken):tmanagementoperator;
{ check operator args and result type }
type
toverload_check_flag = (
ocf_check_non_overloadable, { also check operators that are (currently) considered as
not overloadable (e.g. the "+" operator for dynamic arrays
if modeswitch arrayoperators is active) }
ocf_check_only { only check whether the operator is overloaded, but don't
modify the passed in node (return true if the operator is
overloaded, false otherwise) }
);
toverload_check_flags = set of toverload_check_flag;
function isbinaryoperatoroverloadable(treetyp:tnodetype;ld:tdef;lt:tnodetype;rd:tdef;rt:tnodetype) : boolean;
function isoperatoracceptable(pf : tprocdef; optoken : ttoken) : boolean;
function isunaryoverloaded(var t : tnode;ocf:toverload_check_flags) : boolean;
function isbinaryoverloaded(var t : tnode;ocf:toverload_check_flags) : boolean;
{ Register Allocation }
procedure make_not_regable(p : tnode; how: tregableinfoflags);
{ procvar handling }
function is_proc2procvar_load(p:tnode;out realprocdef:tprocdef):boolean;
{ returns whether a node represents a load of the function result node via
the function name (so it could also be a recursive call to the function
in case there or no parameters, or the function could be passed as
procvar }
function is_ambiguous_funcret_load(p: tnode; out owningprocdef: tprocdef): boolean;
procedure test_local_to_procvar(from_def:tprocvardef;to_def:tdef);
{ sets varsym varstate field correctly }
type
tvarstateflag = (vsf_must_be_valid,vsf_use_hints,vsf_use_hint_for_string_result);
tvarstateflags = set of tvarstateflag;
procedure set_varstate(p:tnode;newstate:tvarstate;varstateflags:tvarstateflags);
{ sets the callunique flag, if the node is a vecn, }
{ takes care of type casts etc. }
procedure set_unique(p : tnode);
function valid_for_formal_var(p : tnode; report_errors: boolean) : boolean;
function valid_for_formal_constref(p : tnode; report_errors: boolean) : boolean;
function valid_for_formal_const(p : tnode; report_errors: boolean) : boolean;
function valid_for_var(p:tnode; report_errors: boolean):boolean;
function valid_for_assignment(p:tnode; report_errors: boolean):boolean;
function valid_for_loopvar(p:tnode; report_errors: boolean):boolean;
function valid_for_addr(p : tnode; report_errors: boolean) : boolean;
function allowenumop(nt:tnodetype):boolean;
procedure check_ranges(const location: tfileposinfo; source: tnode; destdef: tdef);
{ returns whether the def may be used in the Default() intrinsic; static
arrays, records and objects are checked recursively }
function is_valid_for_default(def:tdef):boolean;
procedure UninitializedVariableMessage(pos : tfileposinfo;warning,local,managed : boolean;name : TMsgStr);
implementation
uses
systems,constexp,globals,
cutils,verbose,
symtable,symutil,
defutil,defcmp,
nbas,ncnv,nld,nmem,ncal,nmat,ninl,nutils,procinfo,
pgenutil
;
type
TValidAssign=(Valid_Property,Valid_Void,Valid_Const,Valid_Addr,Valid_Packed,Valid_Range);
TValidAssigns=set of TValidAssign;
{ keep these two in sync! }
const
non_commutative_op_tokens=[_OP_SHL,_OP_SHR,_OP_DIV,_OP_MOD,_STARSTAR,_SLASH,_MINUS];
non_commutative_op_nodes=[shln,shrn,divn,modn,starstarn,slashn,subn];
function node2opstr(nt:tnodetype):string;
var
i : integer;
begin
result:='<unknown>';
for i:=1 to tok2nodes do
if tok2node[i].nod=nt then
begin
result:=tokeninfo^[tok2node[i].tok].str;
break;
end;
end;
function token2managementoperator(optoken:ttoken):tmanagementoperator;
var
i : integer;
begin
result:=mop_none;
for i:=1 to tok2ops do
if tok2op[i].tok=optoken then
begin
result:=tok2op[i].managementoperator;
break;
end;
end;
function isbinaryoperatoroverloadable(treetyp:tnodetype;ld:tdef;lt:tnodetype;rd:tdef;rt:tnodetype) : boolean;
function internal_check(treetyp:tnodetype;ld:tdef;lt:tnodetype;rd:tdef;rt:tnodetype;var allowed:boolean):boolean;
const
identity_operators=[equaln,unequaln];
order_theoretic_operators=identity_operators+[ltn,lten,gtn,gten];
arithmetic_operators=[addn,subn,muln,divn,modn];
rational_operators=[addn,subn,muln,slashn];
numerical_operators=arithmetic_operators+[slashn];
pointer_arithmetic_operators=[addn,subn];
logical_operators=[andn,orn,xorn];
bit_manipulation_operators=logical_operators+[shln,shrn];
set_set_operators=identity_operators+[addn,subn,muln,symdifn]+
order_theoretic_operators;
element_set_operators=[inn];
string_comparison_operators=order_theoretic_operators;
string_manipulation_operators=[addn];
string_operators =
string_comparison_operators+string_manipulation_operators;
begin
internal_check:=true;
{ Reject the cases permitted by the default interpretation (DI). }
case ld.typ of
formaldef,
recorddef,
variantdef :
begin
allowed:=true;
end;
enumdef:
begin
allowed:=not (
(
is_set(rd) and
(treetyp in element_set_operators)
) or
(
is_enum(rd) and
(treetyp in (order_theoretic_operators+[addn, subn]))
) or
(
{ for enum definitions, see webtbs/tw22860.pp }
is_integer(rd) and
(treetyp in (order_theoretic_operators+bit_manipulation_operators+arithmetic_operators))
)
);
end;
setdef:
begin
allowed:=not (
(
is_set(rd) and
(treetyp in (set_set_operators+identity_operators))
) or
(
{ This clause is a hack but its due to a hack somewhere
else---while set + element is not permitted by DI, it
seems to be used when a set is constructed inline }
(rd.typ in [enumdef,orddef]) and
(treetyp=addn)
)
);
end;
orddef, floatdef:
begin
allowed:=not (
(
(rd.typ in [orddef,floatdef]) and
(treetyp in order_theoretic_operators)
) or
(
(m_mac in current_settings.modeswitches) and
is_stringlike(rd) and
(ld.typ=orddef) and
(treetyp in string_comparison_operators)) or
{ c.f. $(source)\tests\tmacpas5.pp }
(
(rd.typ=setdef) and
(ld.typ=orddef) and
(treetyp in element_set_operators)
)
{ This clause may be too restrictive---not all types under
orddef have a corresponding set type; despite this the
restriction should be very unlikely to become
a practical obstacle, and can be relaxed by simply
adding an extra check on TOrdDef(rd).ordtype }
);
{ Note that Currency can be under either orddef or floatdef;
when its under floatdef, is_currency() implies is_float();
when its under orddef, is_currency() does NOT imply
is_integer(). }
if allowed then
begin
if is_anychar(ld) then
allowed:=not (
is_stringlike(rd) and
(treetyp in string_operators)
)
else if is_boolean(ld) then
allowed:=not (
is_boolean(rd) and
(treetyp in logical_operators)
)
else if is_integer(ld) or
(
(ld.typ=orddef) and
is_currency(ld)
{ Here ld is Currency but behaves like an integer }
) then
allowed:=not (
(
(
is_integer(rd) or
(
(rd.typ=orddef) and
is_currency(rd)
)
) and
(treetyp in (bit_manipulation_operators+numerical_operators))
) or
(
is_fpu(rd) and
(treetyp in rational_operators)
) or
(
{ When an integer type is used as the first operand in
pointer arithmetic, DI doesnt accept minus as the
operator (Currency cant be used in pointer
arithmetic even if its under orddef) }
is_integer(ld) and
(rd.typ=pointerdef) and
(treetyp in pointer_arithmetic_operators-[subn])
)
)
else { is_fpu(ld) = True }
allowed:=not (
(
is_fpu(rd) or
is_integer(rd) or
is_currency(rd)
) and
(treetyp in rational_operators)
);
end;
end;
procvardef :
begin
if (rd.typ in [pointerdef,procdef,procvardef]) then
begin
allowed:=false;
exit;
end;
allowed:=true;
end;
pointerdef :
begin
{ DI permits pointer arithmetic for pointer + pointer, pointer -
integer, pointer - pointer, but not for pointer + pointer.
The last case is only valid in DI when both sides are
stringlike. }
if is_stringlike(ld) then
if is_stringlike(rd) then
{ DI in this case permits string operations and pointer
arithmetic. }
allowed:=not (treetyp in (string_operators+pointer_arithmetic_operators))
else if rd.typ = pointerdef then
{ DI in this case permits minus for pointer arithmetic and
order-theoretic operators for pointer comparison. }
allowed:=not (
treetyp in (
pointer_arithmetic_operators-[addn]+
order_theoretic_operators
)
)
else if is_integer(rd) then
{ DI in this case permits pointer arithmetic. }
allowed:=not (treetyp in pointer_arithmetic_operators)
else
allowed:=true
else
allowed:=not (
(
is_integer(rd) and
(treetyp in pointer_arithmetic_operators)
) or
(
(rd.typ=pointerdef) and
(
treetyp in (
pointer_arithmetic_operators-[addn]+
order_theoretic_operators
)
)
) or
(
(lt=niln) and
((rd.typ in [procvardef,procdef,classrefdef]) or
(is_dynamic_array(rd))) and
(treetyp in identity_operators)
) or
(
is_implicit_pointer_object_type(rd) and
(treetyp in identity_operators)
)
);
end;
arraydef :
begin
{ not vector/mmx }
if ((cs_mmx in current_settings.localswitches) and
is_mmx_able_array(ld)) or
((cs_support_vectors in current_settings.globalswitches) and
is_vector(ld)) then
begin
allowed:=false;
exit;
end;
if is_stringlike(ld) and
(
(
(
is_stringlike(rd) or
(rt = niln)
) and
(treetyp in string_operators)
) or
(
is_integer(rd) and
(treetyp in pointer_arithmetic_operators)
) or
(
(
is_pchar(rd) or
is_pwidechar(rd)) and
(treetyp in pointer_arithmetic_operators) and
(tpointerdef(rd).pointeddef=tarraydef(ld).elementdef
)
)
) then
begin
allowed:=false;
exit;
end;
{ dynamic array compare with niln }
if is_dynamic_array(ld) and
(treetyp in identity_operators) then
if is_dynamic_array(rd) or
(rt=niln) then
begin
allowed:=false;
exit;
end;
{ <dyn. array> + <dyn. array> is handled by the compiler }
if (m_array_operators in current_settings.modeswitches) and
(treetyp=addn) and
(is_dynamic_array(ld) or is_dynamic_array(rd)) then
begin
allowed:=false;
exit;
end;
allowed:=true;
end;
objectdef :
begin
{ <> and = are defined for implicit pointer object types }
allowed:=not (
is_implicit_pointer_object_type(ld) and
(
(
is_implicit_pointer_object_type(rd) or
(rd.typ=pointerdef) or
(rt=niln) or
((ld=java_jlstring) and
is_stringlike(rd))
)
) and
(treetyp in identity_operators)
);
end;
stringdef :
begin
allowed:=not (
is_stringlike(rd) and
(treetyp in string_operators)
);
end;
else
internal_check:=false;
end;
end;
begin
{ power ** is always possible }
result:=treetyp=starstarn;
if not result then
begin
if not internal_check(treetyp,ld,lt,rd,rt,result) and
not (treetyp in non_commutative_op_nodes) then
internal_check(treetyp,rd,rt,ld,lt,result)
end;
end;
function isunaryoperatoroverloadable(treetyp:tnodetype;inlinenumber:tinlinenumber;ld:tdef) : boolean;
begin
result:=false;
case treetyp of
subn,
addn,
unaryminusn,
unaryplusn,
inlinen:
begin
{ only Inc, Dec inline functions are supported for now, so skip check inlinenumber }
if (ld.typ in [orddef,enumdef,floatdef]) then
exit;
{$ifdef SUPPORT_MMX}
if (cs_mmx in current_settings.localswitches) and
is_mmx_able_array(ld) then
exit;
{$endif SUPPORT_MMX}
result:=true;
end;
notn :
begin
if ld.typ = orddef then exit;
{$ifdef SUPPORT_MMX}
if (cs_mmx in current_settings.localswitches) and
is_mmx_able_array(ld) then
exit;
{$endif SUPPORT_MMX}
result:=true;
end;
else
;
end;
end;
function isoperatoracceptable(pf : tprocdef; optoken : ttoken) : boolean;
var
ld,rd : tdef;
i : longint;
eq : tequaltype;
conv : tconverttype;
cdo : tcompare_defs_options;
pd : tprocdef;
oldcount,
count: longint;
sym : tsym;
parasym : tparavarsym absolute sym;
begin
result:=false;
count := pf.parast.SymList.count;
oldcount:=count;
while count > 0 do
begin
sym:=tsym(pf.parast.SymList[count-1]);
if sym.typ<>paravarsym then
begin
dec(count);
end
else if is_boolean(parasym.vardef) then
begin
if parasym.name='RANGECHECK' then
begin
Include(parasym.varoptions, vo_is_hidden_para);
Include(parasym.varoptions, vo_is_range_check);
Dec(count);
end
else if parasym.name='OVERFLOWCHECK' then
begin
Include(parasym.varoptions, vo_is_hidden_para);
Include(parasym.varoptions, vo_is_overflow_check);
Dec(count);
end
else
break;
end
else
break;
end;
if count<>oldcount then
pf.calcparas;
case count of
1 : begin
ld:=tparavarsym(pf.parast.SymList[0]).vardef;
{ assignment is a special case }
if optoken in [_ASSIGNMENT,_OP_EXPLICIT] then
begin
cdo:=[];
if optoken=_OP_EXPLICIT then
include(cdo,cdo_explicit);
eq:=compare_defs_ext(ld,pf.returndef,nothingn,conv,pd,cdo);
result:=
(eq=te_exact) or
(eq=te_incompatible);
end
else
{ enumerator is a special case too }
if optoken=_OP_ENUMERATOR then
begin
result:=
is_class_or_interface_or_object(pf.returndef) or
is_record(pf.returndef);
if result then
begin
if not assigned(tabstractrecorddef(pf.returndef).search_enumerator_move) then
begin
Message1(sym_e_no_enumerator_move, pf.returndef.typename);
result:=false;
end;
if not assigned(tabstractrecorddef(pf.returndef).search_enumerator_current) then
begin
Message1(sym_e_no_enumerator_current,pf.returndef.typename);
result:=false;
end;
end;
end
else
begin
for i:=1 to tok2nodes do
if tok2node[i].tok=optoken then
begin
result:=
(op_unary in tok2node[i].supported_op_overloads) and
isunaryoperatoroverloadable(tok2node[i].nod,tok2node[i].inr,ld);
break;
end;
{ Inc, Dec operators are valid if only result type is the same as argument type }
if result and (optoken in [_OP_INC,_OP_DEC]) then
result:=pf.returndef=ld;
end;
end;
2 : begin
ld:=tparavarsym(pf.parast.SymList[0]).vardef;
rd:=tparavarsym(pf.parast.SymList[1]).vardef;
for i:=1 to tok2nodes do
if tok2node[i].tok=optoken then
begin
result:=
(op_binary in tok2node[i].supported_op_overloads) and
isbinaryoperatoroverloadable(tok2node[i].nod,ld,nothingn,rd,nothingn);
break;
end;
end;
end;
end;
function isunaryoverloaded(var t : tnode;ocf:toverload_check_flags) : boolean;
var
ld : tdef;
optoken : ttoken;
operpd : tprocdef;
ppn : tcallparanode;
candidates : tcallcandidates;
cand_cnt : integer;
inlinenumber: tinlinenumber;
begin
result:=false;
operpd:=nil;
{ load easier access variables }
ld:=tunarynode(t).left.resultdef;
{ if we are dealing with inline function then get the function }
if t.nodetype=inlinen then
inlinenumber:=tinlinenode(t).inlinenumber
else
inlinenumber:=in_none;
if not (ocf_check_non_overloadable in ocf) and not isunaryoperatoroverloadable(t.nodetype,inlinenumber,ld) then
exit;
{ operator overload is possible }
result:=not (ocf_check_only in ocf);
optoken:=NOTOKEN;
case t.nodetype of
notn:
optoken:=_OP_NOT;
unaryminusn:
optoken:=_MINUS;
unaryplusn:
optoken:=_PLUS;
inlinen:
case inlinenumber of
in_inc_x:
optoken:=_OP_INC;
in_dec_x:
optoken:=_OP_DEC;
else
;
end;
else
;
end;
if (optoken=NOTOKEN) then
begin
if not (ocf_check_only in ocf) then
begin
CGMessage(parser_e_operator_not_overloaded);
t:=cnothingnode.create;
end;
exit;
end;
{ generate parameter nodes }
{ for inline nodes just copy existent callparanode }
if (t.nodetype=inlinen) and (tinlinenode(t).left.nodetype=callparan) then
ppn:=tcallparanode(tinlinenode(t).left.getcopy)
else
begin
ppn:=ccallparanode.create(tunarynode(t).left.getcopy,nil);
ppn.get_paratype;
end;
candidates.init_operator(optoken,ppn);
{ stop when there are no operators found }
if candidates.count=0 then
begin
candidates.done;
ppn.free;
if not (ocf_check_only in ocf) then
begin
CGMessage2(parser_e_operator_not_overloaded_2,ld.typename,arraytokeninfo[optoken].str);
t:=cnothingnode.create;
end;
exit;
end;
{ Retrieve information about the candidates }
candidates.get_information;
{$ifdef EXTDEBUG}
{ Display info when multiple candidates are found }
candidates.dump_info(V_Debug);
{$endif EXTDEBUG}
cand_cnt:=candidates.choose_best(tabstractprocdef(operpd),false);
{ exit when no overloads are found }
if cand_cnt=0 then
begin
candidates.done;
ppn.free;
if not (ocf_check_only in ocf) then
begin
CGMessage2(parser_e_operator_not_overloaded_2,ld.typename,arraytokeninfo[optoken].str);
t:=cnothingnode.create;
end;
exit;
end;
{ Multiple candidates left? }
if (cand_cnt>1) and not (ocf_check_only in ocf) then
begin
CGMessage(type_e_cant_choose_overload_function);
{$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;
candidates.done;
if ocf_check_only in ocf then
begin
ppn.free;
result:=true;
exit;
end;
addsymref(operpd.procsym,operpd);
{ the nil as symtable signs firstcalln that this is
an overloaded operator }
t:=ccallnode.create(ppn,Tprocsym(operpd.procsym),nil,nil,[],nil);
{ we already know the procdef to use, so it can
skip the overload choosing in callnode.pass_typecheck }
tcallnode(t).procdefinition:=operpd;
end;
function isbinaryoverloaded(var t : tnode;ocf:toverload_check_flags) : boolean;
var
rd,ld : tdef;
optoken : ttoken;
operpd : tprocdef;
ht : tnode;
ppn : tcallparanode;
i,cand_cnt : sizeint;
function search_operator(optoken:ttoken;generror:boolean): integer;
var
candidates : tcallcandidates;
begin
{ generate parameter nodes }
ppn:=ccallparanode.create(tbinarynode(t).right.getcopy,ccallparanode.create(tbinarynode(t).left.getcopy,nil));
ppn.get_paratype;
candidates.init_operator(optoken,ppn);
{ for commutative operators we can swap arguments and try again }
if (candidates.count=0) and
not(optoken in non_commutative_op_tokens) then
begin
candidates.done;
reverseparameters(ppn);
{ reverse compare operators }
case optoken of
_LT:
optoken:=_GTE;
_GT:
optoken:=_LTE;
_LTE:
optoken:=_GT;
_GTE:
optoken:=_LT;
else
;
end;
candidates.init_operator(optoken,ppn);
end;
{ stop when there are no operators found }
result:=candidates.count;
if (result=0) and generror then
begin
CGMessage(parser_e_operator_not_overloaded);
candidates.done;
ppn.free;
ppn:=nil;
exit;
end;
if (result>0) then
begin
{ Retrieve information about the candidates }
candidates.get_information;
{$ifdef EXTDEBUG}
{ Display info when multiple candidates are found }
candidates.dump_info(V_Debug);
{$endif EXTDEBUG}
result:=candidates.choose_best(tabstractprocdef(operpd),false);
end;
{ exit when no overloads are found }
if (result=0) and generror then
begin
CGMessage3(parser_e_operator_not_overloaded_3,ld.GetTypeName,arraytokeninfo[optoken].str,rd.GetTypeName);
candidates.done;
ppn.free;
ppn:=nil;
exit;
end;
{ Multiple candidates left? }
if result>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;
candidates.done;
end;
begin
isbinaryoverloaded:=false;
operpd:=nil;
ppn:=nil;
{ load easier access variables }
ld:=tbinarynode(t).left.resultdef;
rd:=tbinarynode(t).right.resultdef;
if not (ocf_check_non_overloadable in ocf) and
not isbinaryoperatoroverloadable(t.nodetype,ld,tbinarynode(t).left.nodetype,rd,tbinarynode(t).right.nodetype) then
exit;
{ operator overload is possible }
{ if we only check for the existance of the overload, then we assume that
it is not overloaded }
result:=not (ocf_check_only in ocf);
optoken:=NOTOKEN;
for i:=1 to tok2nodes do
if (t.nodetype=tok2node[i].nod) and (op_binary in tok2node[i].supported_op_overloads) then
begin
optoken:=tok2node[i].tok;
break;
end;
if optoken=NOTOKEN then
begin
if not (ocf_check_only in ocf) then
begin
CGMessage(parser_e_operator_not_overloaded);
t:=cnothingnode.create;
end;
exit;
end;
cand_cnt:=search_operator(optoken,(optoken<>_NE) and not (ocf_check_only in ocf));
{ no operator found for "<>" then search for "=" operator }
if (cand_cnt=0) and (optoken=_NE) and not (ocf_check_only in ocf) then
begin
ppn.free;
ppn:=nil;
operpd:=nil;
optoken:=_EQ;
cand_cnt:=search_operator(optoken,true);
end;
if (cand_cnt=0) then
begin
ppn.free;
if not (ocf_check_only in ocf) then
t:=cnothingnode.create;
exit;
end;
if ocf_check_only in ocf then
begin
ppn.free;
result:=true;
exit;
end;
addsymref(operpd.procsym,operpd);
{ the nil as symtable signs firstcalln that this is
an overloaded operator }
ht:=ccallnode.create(ppn,Tprocsym(operpd.procsym),nil,nil,[],nil);
{ we already know the procdef to use, so it can
skip the overload choosing in callnode.pass_typecheck }
tcallnode(ht).procdefinition:=operpd;
{ if we found "=" operator for "<>" expression then use it
together with "not" }
if (t.nodetype=unequaln) and (optoken=_EQ) then
ht:=cnotnode.create(ht);
t:=ht;
end;
{****************************************************************************
Register Calculation
****************************************************************************}
{ marks an lvalue as "unregable" }
procedure make_not_regable_intern(p : tnode; how: tregableinfoflags; records_only: boolean);
begin
if ra_addr_taken in how then
include(p.flags,nf_address_taken);
repeat
case p.nodetype of
subscriptn:
begin
records_only:=true;
p:=tsubscriptnode(p).left;
end;
vecn:
begin
{ if there's an implicit dereference, we can stop (just like
when there is an actual derefn) }
if ((tvecnode(p).left.resultdef.typ=arraydef) and
not is_special_array(tvecnode(p).left.resultdef)) or
((tvecnode(p).left.resultdef.typ=stringdef) and
(tstringdef(tvecnode(p).left.resultdef).stringtype in [st_shortstring,st_longstring])) then
p:=tvecnode(p).left
else
break;
end;
typeconvn :
begin
{ implicit dereference -> stop }
if (ttypeconvnode(p).convtype=tc_pointer_2_array) then
break;
if (ttypeconvnode(p).resultdef.typ=recorddef) then
records_only:=false;
p:=ttypeconvnode(p).left;
end;
loadn :
begin
if (tloadnode(p).symtableentry.typ in [staticvarsym,localvarsym,paravarsym]) then
begin
if (ra_addr_taken in how) then
tabstractvarsym(tloadnode(p).symtableentry).addr_taken:=true;
if (ra_different_scope in how) then
tabstractvarsym(tloadnode(p).symtableentry).different_scope:=true;
if (tabstractvarsym(tloadnode(p).symtableentry).varregable <> vr_none) and
((not records_only) or
(tabstractvarsym(tloadnode(p).symtableentry).vardef.typ = recorddef)) then
if (tloadnode(p).symtableentry.typ = paravarsym) and
(ra_addr_regable in how) then
tabstractvarsym(tloadnode(p).symtableentry).varregable:=vr_addr
else
tabstractvarsym(tloadnode(p).symtableentry).varregable:=vr_none;
end;
break;
end;
temprefn :
begin
if (ra_addr_taken in how) then
ttemprefnode(p).includetempflag(ti_addr_taken);
if (ti_may_be_in_reg in ttemprefnode(p).tempflags) and
((not records_only) or
(ttemprefnode(p).tempinfo^.typedef.typ = recorddef)) then
ttemprefnode(p).excludetempflag(ti_may_be_in_reg);
break;
end;
else
break;
end;
until false;
end;
procedure make_not_regable(p : tnode; how: tregableinfoflags);
begin
make_not_regable_intern(p,how,false);
end;
{****************************************************************************
Subroutine Handling
****************************************************************************}
function is_proc2procvar_load(p:tnode;out realprocdef:tprocdef):boolean;
begin
result:=false;
{ remove voidpointer typecast for tp procvars }
if ((m_tp_procvar in current_settings.modeswitches) or
(m_mac_procvar in current_settings.modeswitches)) and
(p.nodetype=typeconvn) and
is_voidpointer(p.resultdef) then
p:=tunarynode(p).left;
result:=(p.nodetype=typeconvn) and
(ttypeconvnode(p).convtype=tc_proc_2_procvar);
if result then
realprocdef:=tprocdef(ttypeconvnode(p).left.resultdef);
end;
function is_ambiguous_funcret_load(p: tnode; out owningprocdef: tprocdef): boolean;
begin
result:=false;
{ the funcret is an absolutevarsym, which gets converted into a type
conversion node of the loadnode of the actual function result. Its
resulttype is obviously the same as that of the real function result }
if (p.nodetype=typeconvn) and
(p.resultdef=ttypeconvnode(p).left.resultdef) then
p:=ttypeconvnode(p).left;
if (p.nodetype=loadn) and
(tloadnode(p).symtableentry.typ in [absolutevarsym,localvarsym,paravarsym]) and
([vo_is_funcret,vo_is_result] * tabstractvarsym(tloadnode(p).symtableentry).varoptions = [vo_is_funcret]) then
begin
owningprocdef:=tprocdef(tloadnode(p).symtableentry.owner.defowner);
result:=true;
end;
end;
{ local routines can't be assigned to procvars }
procedure test_local_to_procvar(from_def:tprocvardef;to_def:tdef);
begin
if not(m_nested_procvars in current_settings.modeswitches) and
(from_def.parast.symtablelevel>normal_function_level) and
not (po_anonymous in from_def.procoptions) and
(to_def.typ=procvardef) and
(tprocvardef(to_def).parast.symtablelevel <= normal_function_level) then
CGMessage(type_e_cannot_local_proc_to_procvar);
end;
procedure UninitializedVariableMessage(pos : tfileposinfo;warning,local,managed : boolean;name : TMsgStr);
const
msg : array[false..true,false..true,false..true] of dword = (
(
(sym_h_uninitialized_variable,sym_h_uninitialized_managed_variable),
(sym_h_uninitialized_local_variable,sym_h_uninitialized_managed_local_variable)
),
(
(sym_w_uninitialized_variable,sym_w_uninitialized_managed_variable),
(sym_w_uninitialized_local_variable,sym_w_uninitialized_managed_local_variable)
)
);
begin
CGMessagePos1(pos,msg[warning,local,managed],name);
end;
procedure set_varstate(p:tnode;newstate:tvarstate;varstateflags:tvarstateflags);
const
vstrans: array[tvarstate,tvarstate] of tvarstate = (
{ vs_none -> ... }
(vs_none,vs_declared,vs_initialised,vs_read,vs_read_not_warned,vs_referred_not_inited,vs_written,vs_readwritten),
{ vs_declared -> ... }
(vs_none,vs_declared,vs_initialised,vs_read,vs_read_not_warned,vs_referred_not_inited,vs_written,vs_readwritten),
{ vs_initialised -> ... }
(vs_none,vs_initialised,vs_initialised,vs_read,vs_read,vs_read,vs_written,vs_readwritten),
{ vs_read -> ... }
(vs_none,vs_read,vs_read,vs_read,vs_read,vs_read,vs_readwritten,vs_readwritten),
{ vs_read_not_warned -> ... }
(vs_none,vs_read_not_warned,vs_read,vs_read,vs_read_not_warned,vs_read_not_warned,vs_readwritten,vs_readwritten),
{ vs_referred_not_inited }
(vs_none,vs_referred_not_inited,vs_read,vs_read,vs_read_not_warned,vs_referred_not_inited,vs_written,vs_readwritten),
{ vs_written -> ... }
(vs_none,vs_written,vs_written,vs_readwritten,vs_readwritten,vs_written,vs_written,vs_readwritten),
{ vs_readwritten -> ... }
(vs_none,vs_readwritten,vs_readwritten,vs_readwritten,vs_readwritten,vs_readwritten,vs_readwritten,vs_readwritten));
var
hsym : tabstractvarsym;
begin
{ make sure we can still warn about uninitialised use after high(v), @v etc }
if (newstate = vs_read) and
not(vsf_must_be_valid in varstateflags) then
newstate := vs_referred_not_inited;
while assigned(p) do
begin
case p.nodetype of
derefn:
begin
if (tderefnode(p).left.nodetype=temprefn) and
assigned(ttemprefnode(tderefnode(p).left).tempinfo^.withnode) then
p:=ttemprefnode(tderefnode(p).left).tempinfo^.withnode
else
break;
end;
typeconvn :
begin
case ttypeconvnode(p).convtype of
tc_cchar_2_pchar,
tc_cstring_2_pchar,
tc_array_2_pointer :
exclude(varstateflags,vsf_must_be_valid);
tc_pchar_2_string,
tc_pointer_2_array :
begin
include(varstateflags,vsf_must_be_valid);
{ when a pointer is used for array access, the
pointer itself is read and never written }
newstate := vs_read;
end;
else
;
end;
p:=tunarynode(p).left;
end;
subscriptn :
begin
if is_implicit_pointer_object_type(tunarynode(p).left.resultdef) then
newstate := vs_read;
p:=tunarynode(p).left;
end;
vecn:
begin
set_varstate(tbinarynode(p).right,vs_read,[vsf_must_be_valid]);
{ dyn. arrays and dyn. strings are read }
if is_implicit_array_pointer(tunarynode(p).left.resultdef) then
newstate:=vs_read;
if (newstate in [vs_read,vs_readwritten]) or
not(tunarynode(p).left.resultdef.typ in [stringdef,arraydef]) then
include(varstateflags,vsf_must_be_valid)
else if (newstate = vs_written) then
exclude(varstateflags,vsf_must_be_valid);
p:=tunarynode(p).left;
end;
{ do not parse calln }
calln :
break;
loadn :
begin
{ the methodpointer/framepointer is read }
if assigned(tunarynode(p).left) then
set_varstate(tunarynode(p).left,vs_read,[vsf_must_be_valid]);
if (tloadnode(p).symtableentry.typ in [localvarsym,paravarsym,staticvarsym]) then
begin
hsym:=tabstractvarsym(tloadnode(p).symtableentry);
{ this check requires proper data flow analysis... }
(* if (hsym.varspez=vs_final) and
(hsym.varstate in [vs_written,vs_readwritten]) and
(newstate in [vs_written,vs_readwritten]) then
CGMessagePos1(p.fileinfo,sym_e_final_write_once); *)
if (vsf_must_be_valid in varstateflags) and
(hsym.varstate in [vs_declared,vs_read_not_warned,vs_referred_not_inited]) then
begin
{ Give warning/note for uninitialized locals }
if assigned(hsym.owner) and
not(vo_is_external in hsym.varoptions) and
(hsym.owner.symtabletype in [parasymtable,localsymtable,staticsymtable]) and
((hsym.owner=current_procinfo.procdef.localst) or
(hsym.owner=current_procinfo.procdef.parast)) then
begin
if vsf_use_hints in varstateflags then
include(tloadnode(p).loadnodeflags,loadnf_only_uninitialized_hint);
if not(cs_opt_nodedfa in current_settings.optimizerswitches) then
begin
if (vo_is_funcret in hsym.varoptions) then
begin
{ An uninitialized function Result of a managed type needs special handling.
When passing it as a var parameter a warning need to be emitted, since a user
may expect Result to be empty (nil) by default as it happens with local vars
of a managed type. But this is not true for Result and may lead to serious issues.
The only exception is SetLength(Result, ?) for a string Result. A user always
expects undefined contents of the string after calling SetLength(). In such
case a hint need to be emitted.
}
if is_managed_type(hsym.vardef) then
if not ( is_string(hsym.vardef) and (vsf_use_hint_for_string_result in varstateflags) ) then
exclude(varstateflags,vsf_use_hints);
if vsf_use_hints in varstateflags then
begin
if is_managed_type(hsym.vardef) then
CGMessagePos(p.fileinfo,sym_h_managed_function_result_uninitialized)
else
CGMessagePos(p.fileinfo,sym_h_function_result_uninitialized);
end
else
begin
if is_managed_type(hsym.vardef) then
CGMessagePos(p.fileinfo,sym_w_managed_function_result_uninitialized)
else
CGMessagePos(p.fileinfo,sym_w_function_result_uninitialized);
end;
end
else
begin
UninitializedVariableMessage(p.fileinfo,
{ on the JVM, an uninitialized var-parameter
is just as fatal as a nil pointer dereference }
not((vsf_use_hints in varstateflags) and not(target_info.system in systems_jvm)),
tloadnode(p).symtable.symtabletype=localsymtable,
is_managed_type(tloadnode(p).resultdef),
hsym.realname);
end;
end;
end
else if (newstate = vs_read) then
newstate := vs_read_not_warned;
end;
hsym.varstate := vstrans[hsym.varstate,newstate];
end;
case newstate of
vs_written:
include(tloadnode(p).flags,nf_write);
vs_readwritten:
if not(nf_write in tloadnode(p).flags) then
include(tloadnode(p).flags,nf_modify);
else
;
end;
break;
end;
addrn:
break;
callparan :
internalerror(200310081);
else
break;
end;{case }
end;
end;
procedure set_unique(p : tnode);
begin
while assigned(p) do
begin
case p.nodetype of
vecn:
begin
include(tvecnode(p).vecnodeflags,vnf_callunique);
break;
end;
typeconvn,
subscriptn,
derefn:
p:=tunarynode(p).left;
else
break;
end;
end;
end;
function valid_for_assign(p:tnode;opts:TValidAssigns; report_errors: boolean):boolean;
var
typeconvs: tfpobjectlist;
hp2,
hp : tnode;
gotstring,
gotsubscript,
gotrecord,
gotvec,
gottypeconv : boolean;
fromdef,
todef : tdef;
errmsg,
temp : longint;
function constaccessok(vs: tabstractvarsym): boolean;
begin
result:=false;
{ allow p^:= constructions with p is const parameter }
if (Valid_Const in opts) or
((hp.nodetype=loadn) and
(loadnf_isinternal_ignoreconst in tloadnode(hp).loadnodeflags)) then
result:=true
{ final (class) fields can only be initialised in the (class) constructors of
class in which they have been declared (not in descendent constructors) }
else if vs.varspez=vs_final then
begin
if (current_procinfo.procdef.owner=vs.owner) then
if vs.typ=staticvarsym then
result:=current_procinfo.procdef.proctypeoption=potype_class_constructor
else
result:=current_procinfo.procdef.proctypeoption=potype_constructor;
if not result and
report_errors then
CGMessagePos(hp.fileinfo,type_e_invalid_final_assignment);
end
else
if report_errors then
CGMessagePos(hp.fileinfo,type_e_no_assign_to_const);
end;
procedure mayberesettypeconvs;
var
i: longint;
begin
if assigned(typeconvs) then
begin
if not report_errors and
not result then
for i:=0 to typeconvs.Count-1 do
ttypeconvnode(typeconvs[i]).assignment_side:=false;
typeconvs.free;
end;
end;
begin
if valid_const in opts then
errmsg:=type_e_variable_id_expected
else if valid_property in opts then
errmsg:=type_e_argument_cant_be_assigned
else
errmsg:=type_e_no_addr_of_constant;
result:=false;
gotsubscript:=false;
gotvec:=false;
gotrecord:=false;
gotstring:=false;
gottypeconv:=false;
hp:=p;
if not(valid_void in opts) and
is_void(hp.resultdef) then
begin
if report_errors then
CGMessagePos(hp.fileinfo,errmsg);
exit;
end;
typeconvs:=nil;
while assigned(hp) do
begin
{ property allowed? calln has a property check itself }
if (nf_isproperty in hp.flags) then
begin
{ check return type }
case hp.resultdef.typ of
recorddef :
gotrecord:=true;
stringdef :
gotstring:=true;
else
;
end;
if (valid_property in opts) then
begin
{ don't allow writing to calls that will create
temps like calls that return a structure and we
are assigning to a member }
if (valid_const in opts) or
(
{ allowing assignments to typecasted properties
a) is Delphi-incompatible
b) causes problems in case the getter is a function
(because then the result of the getter is
typecasted to this type, and then we "assign" to
this typecasted function result) -> always
disallow, since property accessors should be
transparantly changeable to functions at all
times
}
not(gottypeconv) and
not(gotsubscript and gotrecord) and
not(gotstring and gotvec) and
not(nf_no_lvalue in hp.flags)
) then
result:=true
else
if report_errors then
CGMessagePos(hp.fileinfo,errmsg);
end
else
begin
{ 1. if it returns a pointer and we've found a deref,
2. if it returns a class and a subscription or with is found
3. if the address is needed of a field (subscriptn, vecn) }
if (gotstring and gotvec) or
(
(Valid_Addr in opts) and
(hp.nodetype in [subscriptn,vecn])
) then
result:=true
else
if report_errors then
CGMessagePos(hp.fileinfo,errmsg);
end;
mayberesettypeconvs;
exit;
end;
case hp.nodetype of
temprefn :
begin
valid_for_assign := not(ti_readonly in ttemprefnode(hp).tempflags);
mayberesettypeconvs;
exit;
end;
derefn :
begin
{ dereference -> always valid }
valid_for_assign:=true;
mayberesettypeconvs;
exit;
end;
typeconvn :
begin
gottypeconv:=true;
{ typecast sizes must match, exceptions:
- implicit typecast made by absolute
- from formaldef
- from void
- from/to open array
- typecast from pointer to array }
fromdef:=ttypeconvnode(hp).left.resultdef;
todef:=hp.resultdef;
{ typeconversions on the assignment side must keep
left.location the same }
if not((target_info.system in systems_jvm) and
(gotsubscript or gotvec)) then
begin
ttypeconvnode(hp).assignment_side:=true;
if not assigned(typeconvs) then
typeconvs:=tfpobjectlist.create(false);
typeconvs.add(hp);
end;
{ in managed VMs, you cannot typecast formaldef when assigning
to it, see http://hallvards.blogspot.com/2007/10/dn4dp24-net-vs-win32-untyped-parameters.html }
if (target_info.system in systems_managed_vm) and
(fromdef.typ=formaldef) then
begin
if report_errors then
CGMessagePos(hp.fileinfo,type_e_no_managed_formal_assign_typecast);
mayberesettypeconvs;
exit;
end
else if not((nf_absolute in ttypeconvnode(hp).flags) or
ttypeconvnode(hp).target_specific_general_typeconv or
((nf_explicit in hp.flags) and
ttypeconvnode(hp).target_specific_explicit_typeconv) or
(fromdef.typ=formaldef) or
is_void(fromdef) or
is_open_array(fromdef) or
is_open_array(todef) or
((fromdef.typ=pointerdef) and (todef.typ=arraydef)) or
(def_is_related(fromdef,todef))) then
begin
if (fromdef.size<>todef.size) then
begin
{ in TP it is allowed to typecast to smaller types. But the variable can't
be in a register }
if (m_tp7 in current_settings.modeswitches) or
(todef.size<fromdef.size) then
make_not_regable(hp,[ra_addr_regable])
else
if report_errors then
CGMessagePos2(hp.fileinfo,type_e_typecast_wrong_size_for_assignment,tostr(fromdef.size),tostr(todef.size));
end
{$ifdef llvm}
{ we can never typecast a non-memory value on the assignment
side in llvm }
else
make_not_regable(hp,[ra_addr_regable])
{$endif llvm}
end;
{ don't allow assignments to typeconvs that need special code }
if not(gotsubscript or gotvec) and
not(ttypeconvnode(hp).assign_allowed) then
begin
if report_errors then
CGMessagePos(hp.fileinfo,errmsg);
mayberesettypeconvs;
exit;
end;
case hp.resultdef.typ of
arraydef :
begin
{ pointer -> array conversion is done then we need to see it
as a deref, because a ^ is then not required anymore }
if ttypeconvnode(hp).convtype=tc_pointer_2_array then
begin
valid_for_assign:=true;
mayberesettypeconvs;
exit
end;
end;
else
;
end;
hp:=ttypeconvnode(hp).left;
end;
vecn :
begin
if (tvecnode(hp).right.nodetype=rangen) and
not(valid_range in opts) then
begin
if report_errors then
CGMessagePos(tvecnode(hp).right.fileinfo,parser_e_illegal_expression);
mayberesettypeconvs;
exit;
end;
if { only check for first (= outermost) vec node }
not gotvec and
not(valid_packed in opts) and
(tvecnode(hp).left.resultdef.typ = arraydef) and
(ado_IsBitPacked in tarraydef(tvecnode(hp).left.resultdef).arrayoptions) and
((tarraydef(tvecnode(hp).left.resultdef).elepackedbitsize mod 8 <> 0) or
(is_ordinal(tarraydef(tvecnode(hp).left.resultdef).elementdef) and
not ispowerof2(tarraydef(tvecnode(hp).left.resultdef).elepackedbitsize div 8,temp))) then
begin
if report_errors then
if (valid_property in opts) then
CGMessagePos(hp.fileinfo,parser_e_packed_element_no_loop)
else
CGMessagePos(hp.fileinfo,parser_e_packed_element_no_var_addr);
mayberesettypeconvs;
exit;
end;
gotvec:=true;
{ accesses to dyn. arrays override read only access in delphi
-- now also in FPC, because the elements of a dynamic array
returned by a function can also be changed, or you can
assign the dynamic array to a variable and then change
its elements anyway }
if is_dynamic_array(tunarynode(hp).left.resultdef) then
begin
result:=true;
mayberesettypeconvs;
exit;
end;
hp:=tunarynode(hp).left;
end;
asn :
begin
{ asn can't be assigned directly, it returns the value in a register instead
of reference. }
if not(gotsubscript or gotvec) then
begin
if report_errors then
CGMessagePos(hp.fileinfo,errmsg);
mayberesettypeconvs;
exit;
end;
hp:=tunarynode(hp).left;
end;
subscriptn :
begin
{ only check first (= outermost) subscriptn }
if not gotsubscript and
not(valid_packed in opts) and
is_packed_record_or_object(tsubscriptnode(hp).left.resultdef) and
((tsubscriptnode(hp).vs.fieldoffset mod 8 <> 0) or
(is_ordinal(tsubscriptnode(hp).resultdef) and
not ispowerof2(tsubscriptnode(hp).resultdef.packedbitsize div 8,temp))) then
begin
if report_errors then
if (valid_property in opts) then
CGMessagePos(hp.fileinfo,parser_e_packed_element_no_loop)
else
CGMessagePos(hp.fileinfo,parser_e_packed_element_no_var_addr);
mayberesettypeconvs;
exit;
end;
{ check for final fields }
if (tsubscriptnode(hp).vs.varspez=vs_final) and
not constaccessok(tsubscriptnode(hp).vs) then
begin
mayberesettypeconvs;
exit;
end;
{ if we assign something to a field of a record that is not
regable, then then the record can't be kept in a regvar,
because we will force the record into memory for this
subscript operation (to a temp location, so the assignment
will happen to the temp and be lost) }
if not gotsubscript and
not gotvec and
not tstoreddef(hp.resultdef).is_intregable then
make_not_regable(hp,[ra_addr_regable]);
gotsubscript:=true;
{ loop counter? }
if not(Valid_Const in opts) and
(vo_is_loop_counter in tsubscriptnode(hp).vs.varoptions) then
begin
if report_errors then
CGMessage1(parser_e_illegal_assignment_to_count_var,tsubscriptnode(hp).vs.realname);
mayberesettypeconvs;
exit;
end;
{ implicit pointer object types result in dereferencing }
hp:=tsubscriptnode(hp).left;
if is_implicit_pointer_object_type(hp.resultdef) or
(hp.resultdef.typ=classrefdef) then
begin
valid_for_assign:=true;
mayberesettypeconvs;
exit
end;
end;
muln,
divn,
andn,
xorn,
orn,
notn,
subn,
addn :
begin
{ Temp strings are stored in memory, for compatibility with
delphi only }
if (m_delphi in current_settings.modeswitches) and
((valid_addr in opts) or
(valid_const in opts)) and
(hp.resultdef.typ=stringdef) then
result:=true
else
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
niln,
pointerconstn :
begin
{ this is an implicit dereference, so it is valid for assign }
if hp.resultdef.typ=arraydef then
begin
valid_for_assign:=true;
mayberesettypeconvs;
exit;
end;
if report_errors then
CGMessagePos(hp.fileinfo,type_e_no_assign_to_addr);
mayberesettypeconvs;
exit;
end;
ordconstn,
realconstn :
begin
{ these constants will be passed by value }
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
arrayconstructorn,
setconstn,
stringconstn,
guidconstn :
begin
{ these constants will be passed by reference }
if valid_const in opts then
result:=true
else
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
addrn :
begin
if report_errors then
CGMessagePos(hp.fileinfo,type_e_no_assign_to_addr);
mayberesettypeconvs;
exit;
end;
blockn,
calln :
begin
if ((hp.nodetype=calln) and not(is_void(hp.resultdef))) or
(nf_no_lvalue in hp.flags) then
begin
{ Temp strings are stored in memory, for compatibility with
delphi only }
if (m_delphi in current_settings.modeswitches) and
(valid_addr in opts) and
(hp.resultdef.typ=stringdef) then
result:=true
else
if ([valid_const,valid_addr] * opts = [valid_const]) then
result:=true
else
if report_errors then
CGMessagePos(hp.fileinfo,errmsg);
mayberesettypeconvs;
exit;
end
else if hp.nodetype=blockn then
begin
hp2:=tblocknode(hp).statements;
if assigned(hp2) then
begin
if hp2.nodetype<>statementn then
internalerror(2006110801);
while assigned(tstatementnode(hp2).next) do
hp2:=tstatementnode(hp2).next;
hp:=tstatementnode(hp2).statement;
end
else
begin
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
end
else
begin
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
end;
inlinen :
begin
if ((valid_const in opts) and
(tinlinenode(hp).inlinenumber in [in_typeof_x])) or
(tinlinenode(hp).inlinenumber in [in_unaligned_x,in_aligned_x,in_volatile_x]) then
result:=true
else
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
nothingn :
begin
{ generics can generate nothing nodes, just allow everything }
if df_generic in current_procinfo.procdef.defoptions then
result:=true
else if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
loadn :
begin
case tloadnode(hp).symtableentry.typ of
absolutevarsym,
staticvarsym,
localvarsym,
paravarsym :
begin
{ loop counter? }
if not(Valid_Const in opts) and
(vo_is_loop_counter in tabstractvarsym(tloadnode(hp).symtableentry).varoptions) then
begin
if report_errors then
CGMessage1(parser_e_illegal_assignment_to_count_var,tloadnode(hp).symtableentry.realname);
mayberesettypeconvs;
exit;
end;
{ read-only variable? }
if (tabstractvarsym(tloadnode(hp).symtableentry).varspez in [vs_const,vs_constref,vs_final]) then
begin
result:=constaccessok(tabstractvarsym(tloadnode(hp).symtableentry));
mayberesettypeconvs;
exit;
end;
result:=true;
mayberesettypeconvs;
exit;
end;
procsym :
begin
if (Valid_Const in opts) then
result:=true
else
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
labelsym :
begin
if (Valid_Addr in opts) then
result:=true
else
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
constsym:
begin
if (tconstsym(tloadnode(hp).symtableentry).consttyp in [constresourcestring,constwresourcestring]) and
(valid_addr in opts) then
result:=true
else
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
else
begin
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
end;
end;
else
begin
if report_errors then
CGMessagePos(hp.fileinfo,type_e_variable_id_expected);
mayberesettypeconvs;
exit;
end;
end;
end;
mayberesettypeconvs;
end;
function valid_for_var(p:tnode; report_errors: boolean):boolean;
begin
valid_for_var:=valid_for_assign(p,[valid_range],report_errors);
end;
function valid_for_formal_var(p : tnode; report_errors: boolean) : boolean;
begin
valid_for_formal_var:=valid_for_assign(p,[valid_void,valid_range],report_errors);
end;
function valid_for_formal_constref(p : tnode; report_errors: boolean) : boolean;
begin
valid_for_formal_constref:=(p.resultdef.typ=formaldef) or
valid_for_assign(p,[valid_void,valid_range],report_errors);
end;
function valid_for_formal_const(p : tnode; report_errors: boolean) : boolean;
begin
valid_for_formal_const:=(p.resultdef.typ=formaldef) or
valid_for_assign(p,[valid_void,valid_const,valid_property,valid_range],report_errors);
end;
function valid_for_assignment(p:tnode; report_errors: boolean):boolean;
begin
valid_for_assignment:=valid_for_assign(p,[valid_property,valid_packed],report_errors);
end;
function valid_for_loopvar(p:tnode; report_errors: boolean):boolean;
begin
valid_for_loopvar:=valid_for_assign(p,[valid_property],report_errors);
end;
function valid_for_addr(p : tnode; report_errors: boolean) : boolean;
begin
result:=valid_for_assign(p,[valid_const,valid_addr,valid_void],report_errors);
end;
procedure var_para_allowed(var eq:tequaltype;def_from,def_to:Tdef; fromnode: tnode);
begin
{ Note: eq must be already valid, it will only be updated! }
case def_to.typ of
formaldef :
begin
{ all types can be passed to a formaldef,
but it is not the prefered way }
if not is_constnode(fromnode) then
eq:=te_convert_l6
else
eq:=te_incompatible;
end;
orddef :
begin
{ allows conversion from word to integer and
byte to shortint, but only for TP7 compatibility }
if (m_tp7 in current_settings.modeswitches) and
(def_from.typ=orddef) and
(def_from.size=def_to.size) then
eq:=te_convert_l1;
end;
arraydef :
begin
if is_open_array(def_to) then
begin
if is_dynamic_array(def_from) and
equal_defs(tarraydef(def_from).elementdef,tarraydef(def_to).elementdef) then
eq:=te_convert_l2
else
if equal_defs(def_from,tarraydef(def_to).elementdef) then
eq:=te_convert_l3;
end;
end;
pointerdef :
begin
{ an implicit pointer conversion is allowed }
if (def_from.typ=pointerdef) then
eq:=te_convert_l1;
end;
stringdef :
begin
{ all shortstrings are allowed, size is not important }
if is_shortstring(def_from) and
is_shortstring(def_to) then
eq:=te_equal;
end;
objectdef :
begin
{ child objects can be also passed }
{ in non-delphi mode, otherwise }
{ they must match exactly, except }
{ if they are objects }
if (def_from.typ=objectdef) and
(
(tobjectdef(def_from).objecttype=odt_object) and
(tobjectdef(def_to).objecttype=odt_object)
) and
(def_is_related(tobjectdef(def_from),tobjectdef(def_to))) then
eq:=te_convert_l1;
end;
filedef :
begin
{ an implicit file conversion is also allowed }
{ from a typed file to an untyped one }
if (def_from.typ=filedef) and
(tfiledef(def_from).filetyp = ft_typed) and
(tfiledef(def_to).filetyp = ft_untyped) then
eq:=te_convert_l1;
end;
else
;
end;
end;
procedure para_allowed(var eq:tequaltype;p:tcallparanode;def_to:tdef);
var
acn: tarrayconstructornode;
realprocdef: tprocdef;
tmpeq: tequaltype;
begin
{ Note: eq must be already valid, it will only be updated! }
case def_to.typ of
stringdef :
begin
{ to support ansi/long/wide strings in a proper way }
{ string and string[10] are assumed as equal }
{ when searching the correct overloaded procedure }
if (p.resultdef.typ=stringdef) and
(tstringdef(def_to).stringtype=tstringdef(p.resultdef).stringtype) and
(tstringdef(def_to).encoding=tstringdef(p.resultdef).encoding) then
eq:=te_equal
end;
formaldef,
setdef :
begin
{ set can also be a not yet converted array constructor }
if (p.resultdef.typ=arraydef) and
is_array_constructor(p.resultdef) and
not is_variant_array(p.resultdef) then
eq:=te_equal;
end;
procvardef :
begin
tmpeq:=te_incompatible;
{ in tp/macpas mode proc -> procvar is allowed }
if ((m_tp_procvar in current_settings.modeswitches) or
(m_mac_procvar in current_settings.modeswitches)) and
(p.left.nodetype=calln) then
tmpeq:=proc_to_procvar_equal(tprocdef(tcallnode(p.left).procdefinition),tprocvardef(def_to),false);
if (tmpeq=te_incompatible) and
(m_nested_procvars in current_settings.modeswitches) and
is_proc2procvar_load(p.left,realprocdef) then
tmpeq:=proc_to_procvar_equal(realprocdef,tprocvardef(def_to),false);
if (tmpeq=te_incompatible) and
(m_mac in current_settings.modeswitches) and
is_ambiguous_funcret_load(p.left,realprocdef) then
tmpeq:=proc_to_procvar_equal(realprocdef,tprocvardef(def_to),false);
if tmpeq<>te_incompatible then
eq:=tmpeq;
end;
objectdef :
begin
tmpeq:=te_incompatible;
{ in tp/macpas mode proc -> funcref is allowed }
if ((m_tp_procvar in current_settings.modeswitches) or
(m_mac_procvar in current_settings.modeswitches)) and
(p.left.nodetype=calln) and
is_invokable(def_to) then
tmpeq:=proc_to_funcref_conv(tprocdef(tcallnode(p.left).procdefinition),tobjectdef(def_to));
if tmpeq<>te_incompatible then
eq:=tmpeq;
end;
arraydef :
begin
{ an arrayconstructor of proccalls may have to be converted to
an array of procvars }
if ((m_tp_procvar in current_settings.modeswitches) or
(m_mac_procvar in current_settings.modeswitches)) and
(tarraydef(def_to).elementdef.typ=procvardef) and
is_array_constructor(p.resultdef) and
not is_variant_array(p.resultdef) then
begin
acn:=tarrayconstructornode(p.left);
if assigned(acn.left) then
begin
eq:=te_exact;
while assigned(acn) and
(eq<>te_incompatible) do
begin
if (acn.left.nodetype=calln) then
tmpeq:=proc_to_procvar_equal(tprocdef(tcallnode(acn.left).procdefinition),tprocvardef(tarraydef(def_to).elementdef),false)
else
tmpeq:=compare_defs(acn.left.resultdef,tarraydef(def_to).elementdef,acn.left.nodetype);
if tmpeq<eq then
eq:=tmpeq;
acn:=tarrayconstructornode(acn.right);
end;
end
end;
end;
else
;
end;
end;
function allowenumop(nt:tnodetype):boolean;
begin
result:=(nt in [equaln,unequaln,ltn,lten,gtn,gten]) or
((cs_allow_enum_calc in current_settings.localswitches) and
(nt in [addn,subn]));
end;
procedure tcandidate.increment_ordinal_distance(by: uint64);
begin
{$push} {$q-,r-} inc(ordinal_distance_lo,by); {$pop}
if ordinal_distance_lo<by then
inc(ordinal_distance_hi); { Carry. }
end;
{****************************************************************************
TCallCandidates
****************************************************************************}
constructor tcallcandidates.init(sym:tprocsym;st:TSymtable;ppn:tnode;flags:tcallcandidatesflags;spezcontext:tspecializationcontext);
begin
if not assigned(sym) then
internalerror(200411015);
FOperator:=NOTOKEN;
FProcsym:=sym;
FProcsymtable:=st;
FParanode:=ppn;
create_candidate_list(flags,spezcontext);
end;
constructor tcallcandidates.init_operator(op:ttoken;ppn:tnode);
begin
FOperator:=op;
FProcsym:=nil;
FProcsymtable:=nil;
FParanode:=ppn;
create_candidate_list([],nil);
end;
destructor tcallcandidates.done;
var
hpnext,
hp : pcandidate;
psym : tprocsym;
i : longint;
sym : tsym;
begin
FIgnoredCandidateProcs.free;
{ free any symbols for anonymous parameter types that we're used for
specialization when no specialization was picked }
TFPList.FreeAndNilObjects(FParaAnonSyms);
hp:=FCandidateProcs;
while assigned(hp) do
begin
hpnext:=hp^.next;
{ free those procdef specializations that are not owned (thus were discarded) }
if hp^.data.is_specialization and not hp^.data.is_registered then
begin
{ also remove the procdef from its symbol's procdeflist }
psym:=tprocsym(hp^.data.procsym);
for i:=0 to psym.procdeflist.count-1 do
begin
if psym.procdeflist[i]=hp^.data then
begin
psym.procdeflist.delete(i);
break;
end;
end;
hp^.data.free;
end;
dispose(hp);
hp:=hpnext;
end;
end;
procedure tcallcandidates.collect_overloads_in_struct(structdef:tabstractrecorddef;ProcdefOverloadList:TFPObjectList;flags:tcallcandidatesflags;spezcontext:tspecializationcontext);
var
changedhierarchy : boolean;
function processprocsym(srsym:tprocsym; out foundanything: boolean):boolean;
var
j : integer;
pd : tprocdef;
begin
{ add all definitions }
result:=false;
foundanything:=false;
{ try to specialize the procsym }
if srsym.could_be_implicitly_specialized and
try_implicit_specialization(srsym,FParaNode,ProcdefOverloadList,FParaAnonSyms,tsym(FProcsym),result) then
foundanything:=true;
for j:=0 to srsym.ProcdefList.Count-1 do
begin
pd:=tprocdef(srsym.ProcdefList[j]);
if not finalize_specialization(pd,spezcontext) then
continue;
if (po_ignore_for_overload_resolution in pd.procoptions) then
begin
TFPList.AddOnDemand(FIgnoredCandidateProcs,pd);
continue;
end;
{ in case of anonymous inherited, only match procdefs identical
to the current one (apart from hidden parameters), rather than
anything compatible to the parameters -- except in case of
the presence of a messagestr/int, in which case those have to
match exactly }
if cc_anoninherited in flags then
if po_msgint in current_procinfo.procdef.procoptions then
begin
if not(po_msgint in pd.procoptions) or
(pd.messageinf.i<>current_procinfo.procdef.messageinf.i) then
continue
end
else if po_msgstr in current_procinfo.procdef.procoptions then
begin
if not(po_msgstr in pd.procoptions) or
(pd.messageinf.str^<>current_procinfo.procdef.messageinf.str^) then
continue
end
else if (compare_paras(current_procinfo.procdef.paras,pd.paras,cp_all,[cpo_ignorehidden])<te_equal) then
continue;
foundanything:=true;
{ Store first procsym found }
if not assigned(FProcsym) then
FProcsym:=tprocsym(srsym);
if po_overload in pd.procoptions then
result:=true;
{ if the hierarchy had been changed we need to check for duplicates }
if not changedhierarchy or (ProcdefOverloadList.IndexOf(pd)<0) then
ProcdefOverloadList.Add(pd);
end;
end;
function processhelper(hashedid:THashedIDString;helperdef:tobjectdef):boolean;
var
srsym : tsym;
hasoverload,foundanything : boolean;
begin
result:=false;
srsym:=nil;
hasoverload:=false;
while assigned(helperdef) do
begin
srsym:=tsym(helperdef.symtable.FindWithHash(hashedid));
if assigned(srsym) and
{ Delphi allows hiding a property by a procedure with the same name }
(srsym.typ=procsym) and
(tprocsym(srsym).procdeflist.count>0) then
begin
hasoverload:=processprocsym(tprocsym(srsym),foundanything);
{ when there is no explicit overload we stop searching }
if foundanything and
not hasoverload then
break;
end;
helperdef:=helperdef.childof;
end;
if not hasoverload and assigned(srsym) then
exit(true);
end;
var
srsym : tsym;
hashedid : THashedIDString;
hasoverload,
foundanything : boolean;
extendeddef : tabstractrecorddef;
helperdef : tobjectdef;
helperlist : TFPObjectList;
i : integer;
begin
if FOperator=NOTOKEN then
hashedid.id:=FProcsym.name
else
hashedid.id:=overloaded_names[FOperator];
hasoverload:=false;
extendeddef:=nil;
changedhierarchy:=false;
while assigned(structdef) do
begin
{ first search in helpers for this type }
if ((structdef.typ=recorddef) or
(
(structdef.typ=objectdef) and
(tobjectdef(structdef).objecttype in objecttypes_with_helpers)
)
)
and (cc_searchhelpers in flags) then
begin
if m_multi_helpers in current_settings.modeswitches then
begin
helperlist:=get_objectpascal_helpers(structdef);
if assigned(helperlist) and (helperlist.count>0) then
begin
i:=helperlist.count-1;
repeat
helperdef:=tobjectdef(helperlist[i]);
if (helperdef.owner.symtabletype in [staticsymtable,globalsymtable]) or
is_visible_for_object(helperdef.typesym,helperdef) then
if processhelper(hashedid,helperdef) then
exit;
dec(i);
until (i<0);
end;
end
else if search_last_objectpascal_helper(structdef,nil,helperdef) and processhelper(hashedid,helperdef) then
exit;
end;
{ now search in the type itself }
srsym:=tsym(structdef.symtable.FindWithHash(hashedid));
if assigned(srsym) and
{ Delphi allows hiding a property by a procedure with the same name }
(srsym.typ=procsym) then
begin
hasoverload:=processprocsym(tprocsym(srsym),foundanything);
{ when there is no explicit overload we stop searching }
if foundanything and
not hasoverload then
break;
end;
if is_objectpascal_helper(structdef) and
(
(tobjectdef(structdef).extendeddef.typ=recorddef) or
(
(tobjectdef(structdef).extendeddef.typ=objectdef) and
(tobjectdef(tobjectdef(structdef).extendeddef).objecttype in objecttypes_with_helpers)
)
) then
begin
{ remember the first extendeddef of the hierarchy }
if not assigned(extendeddef) then
extendeddef:=tabstractrecorddef(tobjectdef(structdef).extendeddef);
{ search methods in the extended type as well }
srsym:=tprocsym(tabstractrecorddef(tobjectdef(structdef).extendeddef).symtable.FindWithHash(hashedid));
if assigned(srsym) and
{ Delphi allows hiding a property by a procedure with the same name }
(srsym.typ=procsym) and
(tprocsym(srsym).procdeflist.count>0) then
begin
hasoverload:=processprocsym(tprocsym(srsym),foundanything);
{ when there is no explicit overload we stop searching }
if foundanything and
not hasoverload then
break;
end;
end;
{ next parent }
if (structdef.typ=objectdef) then
structdef:=tobjectdef(structdef).childof
else
structdef:=nil;
{ switch over to the extended def's hierarchy }
if not assigned(structdef) and assigned(extendeddef) then
begin
structdef:=extendeddef;
extendeddef:=nil;
changedhierarchy:=true;
end;
end;
end;
procedure tcallcandidates.collect_overloads_in_units(ProcdefOverloadList:TFPObjectList; flags:tcallcandidatesflags;spezcontext:tspecializationcontext);
var
j : integer;
pd : tprocdef;
srsymtable : TSymtable;
srsym : tsym;
checkstack : psymtablestackitem;
hashedid : THashedIDString;
foundanything,
hasoverload : boolean;
begin
{ we search all overloaded operator definitions in the symtablestack. The found
entries are only added to the procs list and not the procsym, because
the list can change in every situation }
if FOperator=NOTOKEN then
begin
if not (cc_objcidcall in flags) then
hashedid.id:=FProcsym.name
else
hashedid.id:=class_helper_prefix+FProcsym.name;
end
else
hashedid.id:=overloaded_names[FOperator];
checkstack:=symtablestack.stack;
if assigned(FProcsymtable) then
begin
while assigned(checkstack) and
(checkstack^.symtable<>FProcsymtable) do
checkstack:=checkstack^.next;
end;
while assigned(checkstack) do
begin
srsymtable:=checkstack^.symtable;
{ if the unit in which the routine has to be searched has been
specified explicitly, stop searching after its symtable(s) have
been checked (can be both the static and the global symtable
in case it's the current unit itself) }
if (cc_explicitunit in flags) and
(FProcsymtable.symtabletype in [globalsymtable,staticsymtable]) and
(srsymtable.moduleid<>FProcsymtable.moduleid) then
break;
if (srsymtable.symtabletype in [localsymtable,staticsymtable,globalsymtable]) and
(
(FOperator=NOTOKEN) or
(sto_has_operator in srsymtable.tableoptions)
)
then
begin
srsym:=tsym(srsymtable.FindWithHash(hashedid));
if assigned(srsym) and
(srsym.typ=procsym) and
(
(tprocsym(srsym).procdeflist.count>0) or
(sp_generic_dummy in srsym.symoptions)
) then
begin
{ add all definitions }
hasoverload:=false;
foundanything:=false;
if tprocsym(srsym).could_be_implicitly_specialized then
foundanything:=try_implicit_specialization(srsym,FParaNode,ProcdefOverloadList,FParaAnonSyms,tsym(FProcsym),hasoverload);
for j:=0 to tprocsym(srsym).ProcdefList.Count-1 do
begin
pd:=tprocdef(tprocsym(srsym).ProcdefList[j]);
if not finalize_specialization(pd,spezcontext) then
continue;
if (po_ignore_for_overload_resolution in pd.procoptions) then
begin
TFPList.AddOnDemand(FIgnoredCandidateProcs,pd);
continue;
end;
{ Store first procsym found }
if not assigned(FProcsym) then
FProcsym:=tprocsym(srsym);
if po_overload in pd.procoptions then
hasoverload:=true;
ProcdefOverloadList.Add(pd);
foundanything:=true;
end;
{ when there is no explicit overload we stop searching,
except for Objective-C methods called via id }
if foundanything and
not hasoverload and
not (cc_objcidcall in flags) then
break;
end;
end;
checkstack:=checkstack^.next
end;
end;
procedure tcallcandidates.create_candidate_list(flags:tcallcandidatesflags;spezcontext:tspecializationcontext);
var
j : integer;
pd : tprocdef;
hp : pcandidate;
pt : tcallparanode;
found,
added : boolean;
st : TSymtable;
contextstructdef : tabstractrecorddef;
ProcdefOverloadList : TFPObjectList;
cpoptions : tcompare_paras_options;
begin
FCandidateProcs:=nil;
{ Find all available overloads for this procsym }
ProcdefOverloadList:=TFPObjectList.Create(false);
if not (cc_objcidcall in flags) and
(FOperator=NOTOKEN) and
(FProcsym.owner.symtabletype in [objectsymtable,recordsymtable]) then
collect_overloads_in_struct(tabstractrecorddef(FProcsym.owner.defowner),ProcdefOverloadList,flags,spezcontext)
else
if (FOperator<>NOTOKEN) then
begin
{ check operands and if they contain records then search in records,
then search in unit }
pt:=tcallparanode(FParaNode);
while assigned(pt) do
begin
if (pt.resultdef.typ=recorddef) and
(sto_has_operator in tabstractrecorddef(pt.resultdef).symtable.tableoptions) then
collect_overloads_in_struct(tabstractrecorddef(pt.resultdef),ProcdefOverloadList,flags,spezcontext);
pt:=tcallparanode(pt.right);
end;
collect_overloads_in_units(ProcdefOverloadList,flags,spezcontext);
end
else
collect_overloads_in_units(ProcdefOverloadList,flags,spezcontext);
{ determine length of parameter list.
for operators also enable the variant-operators if
a variant parameter is passed }
FParalength:=0;
FAllowVariant:=(FOperator=NOTOKEN);
pt:=tcallparanode(FParaNode);
while assigned(pt) do
begin
if (pt.resultdef.typ=variantdef) then
FAllowVariant:=true;
inc(FParalength);
pt:=tcallparanode(pt.right);
end;
{ when the class passed is defined in this unit we
need to use the scope of that class. This is a trick
that can be used to access protected members in other
units. At least kylix supports it this way (PFV) }
if assigned(FProcSymtable) and
(
(FProcSymtable.symtabletype in [ObjectSymtable,recordsymtable]) or
((FProcSymtable.symtabletype=withsymtable) and
(FProcSymtable.defowner.typ in [objectdef,recorddef]))
) and
(FProcSymtable.defowner.owner.symtabletype in [globalsymtable,staticsymtable,objectsymtable,recordsymtable]) and
FProcSymtable.defowner.owner.iscurrentunit then
contextstructdef:=tabstractrecorddef(FProcSymtable.defowner)
else
contextstructdef:=current_structdef;
{ symtable is needed later to calculate the distance }
if assigned(FProcsym) then
st:=FProcsym.Owner
else
st:=nil;
{ Process all found overloads }
for j:=0 to ProcdefOverloadList.Count-1 do
begin
pd:=tprocdef(ProcdefOverloadList[j]);
added:=false;
{ only when the # of parameter are supported by the procedure and
it is visible }
{$ifdef DISABLE_FAST_OVERLOAD_PATCH}
if (FParalength>=pd.minparacount) and
{$else}
if (pd.seenmarker<>pointer(@self)) and (FParalength>=pd.minparacount) and
{$endif}
(
(
(cc_allowdefaultparas in flags) and
(
(FParalength<=pd.maxparacount) or
(po_varargs in pd.procoptions)
)
) or
(
not (cc_allowdefaultparas in flags) and
(FParalength=pd.maxparacount)
)
) and
(
(cc_ignorevisibility in flags) or
(
pd.is_specialization and not assigned(pd.owner) and
(
not (pd.genericdef.owner.symtabletype in [objectsymtable,recordsymtable]) or
is_visible_for_object(tprocdef(pd.genericdef),contextstructdef)
)
) or
(
assigned(pd.owner) and
(
not (pd.owner.symtabletype in [objectsymtable,recordsymtable]) or
is_visible_for_object(pd,contextstructdef)
)
)
) then
begin
{ don't add duplicates, only compare visible parameters for the user }
cpoptions:=[cpo_ignorehidden];
if (po_compilerproc in pd.procoptions) then
cpoptions:=cpoptions+[cpo_compilerproc];
if (po_rtlproc in pd.procoptions) then
cpoptions:=cpoptions+[cpo_rtlproc];
found:=false;
hp:=FCandidateProcs;
{$ifdef DISABLE_FAST_OVERLOAD_PATCH}
while assigned(hp) do
begin
if (compare_paras(hp^.data.paras,pd.paras,cp_value_equal_const,cpoptions)>=te_equal) and
(not(po_objc in pd.procoptions) or
(pd.messageinf.str^=hp^.data.messageinf.str^)) then
begin
found:=true;
break;
end;
hp:=hp^.next;
end;
{$endif}
if not found then
begin
proc_add(st,pd);
added:=true;
{$ifndef DISABLE_FAST_OVERLOAD_PATCH}
pd.seenmarker:=pointer(@self);
{$endif}
end;
end;
{ we need to remove all specializations that were not used from their
procsyms as no code must be generated for them (if they are used
later on they'll be added like the ones that were used now) }
if not added and assigned(spezcontext) and not pd.is_registered then
begin
if tprocsym(pd.procsym).procdeflist.extract(pd)<>pd then
internalerror(20150828);
pd.free;
end;
end;
{$ifndef DISABLE_FAST_OVERLOAD_PATCH}
{cleanup modified duplicate pd markers}
hp := FCandidateProcs;
while assigned(hp) do begin
hp^.data.seenmarker := nil;
hp := hp^.next;
end;
{$endif}
calc_distance(st,flags);
ProcdefOverloadList.Free;
end;
procedure tcallcandidates.calc_distance(st_root: tsymtable; flags:tcallcandidatesflags);
var
pd:tprocdef;
candidate:pcandidate;
st: tsymtable;
begin
{ Give a small penalty for overloaded methods not defined in the
current class/unit }
st:=nil;
if (cc_objcidcall in flags) or
not assigned(st_root) or
not assigned(st_root.defowner) or
(st_root.defowner.typ<>objectdef) then
st:=st_root
else
repeat
{ In case of a method, st_root is the symtable of the first found
procsym with the called method's name, but this procsym may not
contain any of the overloads that match the used parameters (which
are the procdefs that have been collected as candidates) -> walk
up the class hierarchy and look for the first class that actually
defines at least one of the candidate procdefs.
The reason is that we will penalise methods in other classes/
symtables, so if we pick a symtable that does not contain any of
the candidates, this won't help with picking the best/
most-inner-scoped one (since all of them will be penalised) }
candidate:=FCandidateProcs;
{ the current class contains one of the candidates? }
while assigned(candidate) do
begin
pd:=candidate^.data;
if pd.owner=st_root then
begin
{ yes -> choose this class }
st:=st_root;
break;
end;
candidate:=candidate^.next;
end;
{ None found -> go to parent class }
if not assigned(st) then
begin
if not assigned(st_root.defowner) then
internalerror(201605301);
{ no more parent class -> take current class as root anyway
(could maybe happen in case of a class helper?) }
if not assigned(tobjectdef(st_root.defowner).childof) then
begin
st:=st_root;
break;
end;
st_root:=tobjectdef(st_root.defowner).childof.symtable;
end;
until assigned(st);
candidate:=FCandidateProcs;
{ when calling Objective-C methods via id.method, then the found
procsym will be inside an arbitrary ObjectSymtable, and we don't
want to give the methods of that particular objcclass precedence
over other methods, so instead check against the symtable in
which this objcclass is defined }
if cc_objcidcall in flags then
st:=st.defowner.owner;
while assigned(candidate) do
begin
pd:=candidate^.data;
if st<>pd.owner then
candidate^.increment_ordinal_distance(1);
candidate:=candidate^.next;
end;
end;
function tcallcandidates.proc_add(st:tsymtable;pd:tprocdef):pcandidate;
var
defaultparacnt : integer;
begin
{ generate new candidate entry }
new(result);
fillchar(result^,sizeof(tcandidate),0);
result^.data:=pd;
result^.next:=FCandidateProcs;
FCandidateProcs:=result;
inc(FProccnt);
{ Find last parameter, skip all default parameters
that are not passed. Ignore this skipping for varargs }
result^.firstparaidx:=pd.paras.count-1;
if not(po_varargs in pd.procoptions) then
begin
{ ignore hidden parameters }
while (result^.firstparaidx>=0) and (vo_is_hidden_para in tparavarsym(pd.paras[result^.firstparaidx]).varoptions) do
dec(result^.firstparaidx);
defaultparacnt:=pd.maxparacount-FParalength;
if defaultparacnt>0 then
begin
if defaultparacnt>result^.firstparaidx+1 then
internalerror(200401141);
dec(result^.firstparaidx,defaultparacnt);
end;
end;
end;
procedure tcallcandidates.list(all:boolean);
var
hp : pcandidate;
begin
hp:=FCandidateProcs;
while assigned(hp) do
begin
if all or
(not hp^.invalid) then
MessagePos1(hp^.data.fileinfo,sym_h_param_list,hp^.data.fullprocname(false));
hp:=hp^.next;
end;
end;
{$ifdef EXTDEBUG}
procedure tcallcandidates.dump_info(lvl:longint);
function ParaTreeStr(p:tcallparanode):string;
begin
result:='';
while assigned(p) do
begin
if result<>'' then
result:=','+result;
result:=p.resultdef.typename+result;
p:=tcallparanode(p.right);
end;
end;
var
hp : pcandidate;
i : integer;
currpara : tparavarsym;
begin
if not CheckVerbosity(lvl) then
exit;
Comment(lvl+V_LineInfo,'Overloaded callnode: '+FProcsym.name+'('+ParaTreeStr(tcallparanode(FParaNode))+')');
hp:=FCandidateProcs;
while assigned(hp) do
begin
Comment(lvl,' '+hp^.data.fullprocname(false));
if (hp^.invalid) then
Comment(lvl,' invalid')
else
begin
Comment(lvl,' ex: '+tostr(hp^.te_count[te_exact])+
' eq: '+tostr(hp^.te_count[te_equal])+
' l1: '+tostr(hp^.te_count[te_convert_l1])+
' l2: '+tostr(hp^.te_count[te_convert_l2])+
' l3: '+tostr(hp^.te_count[te_convert_l3])+
' l4: '+tostr(hp^.te_count[te_convert_l4])+
' l5: '+tostr(hp^.te_count[te_convert_l5])+
' l6: '+tostr(hp^.te_count[te_convert_l6])+
' oper: '+tostr(hp^.te_count[te_convert_operator])+
' ordhi: '+tostr(hp^.ordinal_distance_hi)+
' ordlo: '+tostr(hp^.ordinal_distance_lo)+
' ord2: '+tostr(hp^.ordinal_distance_secondary));
{ Print parameters in left-right order }
for i:=0 to hp^.data.paras.count-1 do
begin
currpara:=tparavarsym(hp^.data.paras[i]);
if not(vo_is_hidden_para in currpara.varoptions) then
Comment(lvl,' - '+currpara.vardef.typename+' : '+EqualTypeName[currpara.eqval]);
end;
end;
hp:=hp^.next;
end;
end;
{$endif EXTDEBUG}
procedure tcallcandidates.get_information;
var
hp : pcandidate;
currpara : tparavarsym;
paraidx,fp_precision_distance : integer;
currparanr : byte;
obj_from,
obj_to : tobjectdef;
def_from,
def_to : tdef;
currpt,
pt : tcallparanode;
eq,
mineq : tequaltype;
convtype : tconverttype;
pdtemp,
pdoper : tprocdef;
releasecurrpt, check_valid_var : boolean;
cdoptions : tcompare_defs_options;
n : tnode;
function fp_precision_score(def: tdef): integer;
begin
if is_extended(def) then
result:=4
else if is_double(def) then
result:=2
else
result:=1;
end;
begin
cdoptions:=[cdo_check_operator];
if FAllowVariant then
include(cdoptions,cdo_allow_variant);
{ process all procs }
hp:=FCandidateProcs;
while assigned(hp) do
begin
{ We compare parameters in reverse order (right to left),
the firstpara is already pointing to the last parameter
were we need to start comparing }
currparanr:=FParalength;
paraidx:=hp^.firstparaidx;
while (paraidx>=0) and (vo_is_hidden_para in tparavarsym(hp^.data.paras[paraidx]).varoptions) do
dec(paraidx);
pt:=tcallparanode(FParaNode);
while assigned(pt) and (paraidx>=0) do
begin
currpara:=tparavarsym(hp^.data.paras[paraidx]);
{ currpt can be changed from loadn to calln when a procvar
is passed. This is to prevent that the change is permanent }
currpt:=pt;
releasecurrpt:=false;
{ Should we check if the callparanode.left is valid for var }
check_valid_var:=true;
{ retrieve current parameter definitions to compares }
eq:=te_incompatible;
def_from:=currpt.resultdef;
def_to:=currpara.vardef;
if not(assigned(def_from)) then
internalerror(200212091);
if not(
assigned(def_to) or
((po_varargs in hp^.data.procoptions) and
(currparanr>hp^.data.minparacount))
) then
internalerror(200212092);
{ Convert tp procvars when not expecting a procvar }
if (currpt.left.resultdef.typ=procvardef) and
not(def_to.typ in [procvardef,formaldef]) and
{ if it doesn't require any parameters }
(tprocvardef(currpt.left.resultdef).minparacount=0) and
{ Only convert to call when there is no overload or the return type
is compatible with the expected type. }
(
(count=1) or
(compare_defs_ext(tprocvardef(currpt.left.resultdef).returndef,def_to,nothingn,convtype,pdoper,[])>te_incompatible)
) then
begin
releasecurrpt:=true;
currpt:=tcallparanode(pt.getcopy);
if maybe_call_procvar(currpt.left,true) then
begin
currpt.resultdef:=currpt.left.resultdef;
def_from:=currpt.left.resultdef;
end;
end;
{ If we expect a procvar and the left is loadnode that
returns a procdef we need to find the correct overloaded
procdef that matches the expected procvar. The loadnode
temporary returned the first procdef (PFV) }
if (
(def_to.typ=procvardef) or
is_funcref(def_to)
) and
(currpt.left.nodetype=loadn) and
(currpt.left.resultdef.typ=procdef) then
begin
if def_to.typ=procvardef then
pdtemp:=tprocsym(Tloadnode(currpt.left).symtableentry).Find_procdef_byprocvardef(Tprocvardef(def_to))
else
pdtemp:=tprocsym(tloadnode(currpt.left).symtableentry).find_procdef_byfuncrefdef(tobjectdef(def_to));
if assigned(pdtemp) then
begin
tloadnode(currpt.left).setprocdef(pdtemp,def_to.typ<>procvardef);
currpt.resultdef:=currpt.left.resultdef;
def_from:=currpt.left.resultdef;
end;
end;
{ same as above, but for the case that we have a proc-2-procvar
conversion together with a load }
if (
(def_to.typ=procvardef) or
is_funcref(def_to)
) and
(currpt.left.nodetype=typeconvn) and
(ttypeconvnode(currpt.left).convtype=tc_proc_2_procvar) and
(ttypeconvnode(currpt.left).totypedef=voidtype) and
not (nf_explicit in currpt.left.flags) and
(ttypeconvnode(currpt.left).left.nodetype=loadn) and
(ttypeconvnode(currpt.left).left.resultdef.typ=procdef) then
begin
if def_to.typ=procvardef then
pdtemp:=tprocsym(tloadnode(ttypeconvnode(currpt.left).left).symtableentry).Find_procdef_byprocvardef(Tprocvardef(def_to))
else
pdtemp:=tprocsym(tloadnode(ttypeconvnode(currpt.left).left).symtableentry).find_procdef_byfuncrefdef(tobjectdef(def_to));
if assigned(pdtemp) then
begin
tloadnode(ttypeconvnode(currpt.left).left).setprocdef(pdtemp,def_to.typ<>procvardef);
ttypeconvnode(currpt.left).totypedef:=cprocvardef.getreusableprocaddr(pdtemp,pc_normal);
ttypeconvnode(currpt.left).resultdef:=ttypeconvnode(currpt.left).totypedef;
def_from:=ttypeconvnode(currpt.left).resultdef;
end;
end;
{ varargs are always equal, but not exact }
if (po_varargs in hp^.data.procoptions) and
(currparanr>hp^.data.minparacount) and
not is_array_of_const(def_from) and
not is_array_constructor(def_from) then
eq:=te_equal
else
{ same definition -> exact }
if (def_from=def_to) then
eq:=te_exact
else
{ for value and const parameters check if a integer is constant or
included in other integer -> equal and calc ordinal_distance }
if not(currpara.varspez in [vs_var,vs_out]) and
is_integer(def_from) and
is_integer(def_to) and
is_in_limit(def_from,def_to) then
begin
eq:=te_equal;
{ is_in_limit(def_from, def_to) means that def_from.low >= def_to.low and def_from.high <= def_to.high. }
hp^.increment_ordinal_distance(torddef(def_from).low-torddef(def_to).low);
hp^.increment_ordinal_distance(torddef(def_to).high-torddef(def_from).high);
{ Give wrong sign a small penalty, this is need to get a diffrence
from word->[longword,longint] }
if (is_signed(def_from)<>is_signed(def_to)) then
inc(hp^.ordinal_distance_secondary);
end
else
{ for value and const parameters check precision of real, give
penalty for loosing of precision. var and out parameters must match exactly }
if not(currpara.varspez in [vs_var,vs_out]) and
is_real_or_cextended(def_from) and
is_real_or_cextended(def_to) then
begin
eq:=te_equal;
fp_precision_distance:=fp_precision_score(def_to)-fp_precision_score(def_from);
{ penalty for shrinking of precision }
if fp_precision_distance<0 then
fp_precision_distance:=16*-fp_precision_distance;
hp^.increment_ordinal_distance(fp_precision_distance);
end
else
{ related object parameters also need to determine the distance between the current
object and the object we are comparing with. var and out parameters must match exactly }
if not(currpara.varspez in [vs_var,vs_out]) and
(def_from.typ=objectdef) and
(def_to.typ=objectdef) and
(tobjectdef(def_from).objecttype=tobjectdef(def_to).objecttype) and
def_is_related(tobjectdef(def_from),tobjectdef(def_to)) then
begin
eq:=te_convert_l1;
check_valid_var:=false;
{ resolve anonymous external class definitions }
obj_from:=find_real_class_definition(tobjectdef(def_from),false);
obj_to:=find_real_class_definition(tobjectdef(def_to),false);
while assigned(obj_from) do
begin
if obj_from=obj_to then
break;
hp^.increment_ordinal_distance(1);
obj_from:=obj_from.childof;
end;
end
{ compare_defs_ext compares sets and array constructors very poorly because
it has too little information. So we do explicitly a detailed comparisation,
see also bug #11288 (FK)
}
else if (def_to.typ=setdef) and is_array_constructor(currpt.left.resultdef) then
begin
n:=currpt.left.getcopy;
arrayconstructor_to_set(n);
eq:=compare_defs_ext(n.resultdef,def_to,n.nodetype,convtype,pdoper,cdoptions);
check_valid_var:=false;
n.free;
end
else if is_open_array(def_to) and
is_class_or_interface_or_dispinterface_or_objc_or_java(tarraydef(def_to).elementdef) and
is_array_constructor(currpt.left.resultdef) and
assigned(tarrayconstructornode(currpt.left).left) then
begin
{ ensure that [nil] can be converted to "array of tobject",
because if we just try to convert "array of pointer" to
"array of tobject", we get type conversion errors in
non-Delphi modes }
n:=currpt.left;
mineq:=te_exact;
repeat
if tarrayconstructornode(n).left.nodetype=arrayconstructorrangen then
eq:=te_incompatible
else
eq:=compare_defs_ext(tarrayconstructornode(n).left.resultdef,tarraydef(def_to).elementdef,tarrayconstructornode(n).left.nodetype,convtype,pdoper,cdoptions);
if eq<mineq then
mineq:=eq;
if eq=te_incompatible then
break;
n:=tarrayconstructornode(n).right;
until not assigned(n);
eq:=mineq;
check_valid_var:=false;
end
else
{ generic type comparision }
begin
if (hp^.data.procoptions*[po_rtlproc,po_compilerproc]=[]) and
is_ansistring(def_from) and
is_ansistring(def_to) and
(tstringdef(def_from).encoding<>tstringdef(def_to).encoding) and
(currpara.varspez in [vs_var,vs_out]) then
begin
eq:=te_convert_l1; // don't allow to pass different ansistring types to each-other
check_valid_var:=false;
end
else
eq:=compare_defs_ext(def_from,def_to,currpt.left.nodetype,convtype,pdoper,cdoptions);
{ when the types are not equal we need to check
some special case for parameter passing }
if (eq<te_equal) then
begin
if currpara.varspez in [vs_var,vs_out] then
begin
{ para requires an equal type so the previous found
match was not good enough, reset to incompatible }
eq:=te_incompatible;
var_para_allowed(eq,currpt.resultdef,currpara.vardef,currpt.left);
check_valid_var:=false;
end
else
para_allowed(eq,currpt,def_to);
end;
end;
{ univ parameters match if the size matches (don't override the
comparison result if it was ok, since a match based on the
"univ" character is the lowest possible match) }
if (eq=te_incompatible) and
currpara.univpara and
is_valid_univ_para_type(def_from) and
(def_from.size=def_to.size) then
eq:=te_convert_l5;
{ when a procvar was changed to a call an exact match is
downgraded to equal. This way an overload call with the
procvar is choosen. See tb0471 (PFV) }
if (pt<>currpt) and (eq=te_exact) then
eq:=te_equal;
{ if var or out parameter type but paranode not is_valid_for_var }
if check_valid_var and (currpara.varspez in [vs_var,vs_out]) and not valid_for_var(currpt.left,false)
and (def_to.typ<>formaldef) and not is_open_array(def_to) then
eq:=te_incompatible;
{ increase correct counter }
if eq<>te_incompatible then
inc(hp^.te_count[eq])
else
hp^.invalid:=true;
{ stop checking when an incompatible parameter is found }
if hp^.invalid then
begin
{ store the current parameter info for
a nice error message when no procedure is found }
hp^.wrongparaidx:=paraidx;
hp^.wrongparanr:=currparanr;
break;
end;
{$ifdef EXTDEBUG}
{ store equal in node tree for dump }
currpara.eqval:=eq;
{$endif EXTDEBUG}
{ maybe release temp currpt }
if releasecurrpt then
currpt.free;
{ next parameter in the call tree }
pt:=tcallparanode(pt.right);
{ next parameter for definition, only goto next para
if we're out of the varargs }
if not(po_varargs in hp^.data.procoptions) or
(currparanr<=hp^.data.maxparacount) then
begin
{ Ignore vs_hidden parameters }
repeat
dec(paraidx);
until (paraidx<0) or not(vo_is_hidden_para in tparavarsym(hp^.data.paras[paraidx]).varoptions);
end;
dec(currparanr);
end;
if not(hp^.invalid) and
(assigned(pt) or (paraidx>=0) or (currparanr<>0)) then
internalerror(200212141);
{ next candidate }
hp:=hp^.next;
end;
end;
function get_variantequaltype(def: tdef): tvariantequaltype;
const
variantorddef_cl: array[tordtype] of tvariantequaltype =
(tve_incompatible,tve_byte,tve_word,tve_cardinal,tve_chari64,tve_incompatible,
tve_shortint,tve_smallint,tve_longint,tve_chari64,tve_incompatible,
tve_boolformal,tve_boolformal,tve_boolformal,tve_boolformal,tve_boolformal,
tve_boolformal,tve_boolformal,tve_boolformal,tve_boolformal,
tve_chari64,tve_chari64,tve_dblcurrency,tve_incompatible);
{ TODO: fixme for 128 bit floats }
variantfloatdef_cl: array[tfloattype] of tvariantequaltype =
(tve_single,tve_dblcurrency,tve_extended,tve_extended,
tve_dblcurrency,tve_dblcurrency,tve_extended);
variantstringdef_cl: array[tstringtype] of tvariantequaltype =
(tve_sstring,tve_astring,tve_astring,tve_wstring,tve_ustring);
begin
case def.typ of
orddef:
begin
result:=variantorddef_cl[torddef(def).ordtype];
end;
floatdef:
begin
result:=variantfloatdef_cl[tfloatdef(def).floattype];
end;
stringdef:
begin
result:=variantstringdef_cl[tstringdef(def).stringtype];
end;
formaldef:
begin
result:=tve_boolformal;
end;
else
begin
result:=tve_incompatible;
end;
end
end;
function is_better_candidate(currpd,bestpd:pcandidate):integer;
begin
{
Return values:
> 0 when currpd is better than bestpd
< 0 when bestpd is better than currpd
= 0 when both are equal
To choose the best candidate we use the following order:
- Incompatible flag
- (Smaller) Number of convert operator parameters.
- (Smaller) Number of convertlevel 2 parameters.
- (Smaller) Number of convertlevel 1 parameters.
- (Bigger) Number of exact parameters.
- (Smaller) Number of equal parameters.
- (Smaller) Total of ordinal distance. For example, the distance of a word
to a byte is 65535-255=65280.
}
if bestpd^.invalid or currpd^.invalid then
exit(ord(bestpd^.invalid)-ord(currpd^.invalid)); { 1 if bestpd^.invalid, -1 if currpd^.invalid, 0 if both. }
{ less operator parameters? }
is_better_candidate:=(bestpd^.te_count[te_convert_operator]-currpd^.te_count[te_convert_operator]);
if is_better_candidate<>0 then
exit;
{ less cl6 parameters? }
is_better_candidate:=bestpd^.te_count[te_convert_l6]-currpd^.te_count[te_convert_l6];
if is_better_candidate<>0 then
exit;
{ less cl5 parameters? }
is_better_candidate:=bestpd^.te_count[te_convert_l5]-currpd^.te_count[te_convert_l5];
if is_better_candidate<>0 then
exit;
{ less cl4 parameters? }
is_better_candidate:=bestpd^.te_count[te_convert_l4]-currpd^.te_count[te_convert_l4];
if is_better_candidate<>0 then
exit;
{ less cl3 parameters? }
is_better_candidate:=bestpd^.te_count[te_convert_l3]-currpd^.te_count[te_convert_l3];
if is_better_candidate<>0 then
exit;
{ less cl2 parameters? }
is_better_candidate:=bestpd^.te_count[te_convert_l2]-currpd^.te_count[te_convert_l2];
if is_better_candidate<>0 then
exit;
{ less cl1 parameters? }
is_better_candidate:=bestpd^.te_count[te_convert_l1]-currpd^.te_count[te_convert_l1];
if is_better_candidate<>0 then
exit;
{ more exact parameters? }
is_better_candidate:=currpd^.te_count[te_exact]-bestpd^.te_count[te_exact];
if is_better_candidate<>0 then
exit;
{ less equal parameters? }
is_better_candidate:=bestpd^.te_count[te_equal]-currpd^.te_count[te_equal];
if is_better_candidate<>0 then
exit;
{ if a specialization is better than a non-specialization then
the non-generic always wins }
if m_implicit_function_specialization in current_settings.modeswitches then
begin
is_better_candidate:=ord(bestpd^.data.is_specialization)-ord(currpd^.data.is_specialization); { 1 if bestpd^.data.is_specialization and not currpd^.data.is_specialization, -1 if the reverse, 0 if same is_specialization. }
if is_better_candidate<>0 then
exit;
end;
{ smaller ordinal distance? }
is_better_candidate:=int32(bestpd^.ordinal_distance_hi)-int32(currpd^.ordinal_distance_hi); { >0 if currpd^.ordinal_distance_hi < bestpd^.ordinal_distance_hi. }
if is_better_candidate<>0 then
exit;
if currpd^.ordinal_distance_lo<>bestpd^.ordinal_distance_lo then
exit(2*ord(currpd^.ordinal_distance_lo<bestpd^.ordinal_distance_lo)-1); { 1 if currpd^.ordinal_distance_lo < bestpd^.ordinal_distance_lo, -1 if the reverse. }
is_better_candidate:=int32(bestpd^.ordinal_distance_secondary)-int32(currpd^.ordinal_distance_secondary); { >0 if currpd^.ordinal_distance_secondary < bestpd^.ordinal_distance_secondary. }
end;
{ Delphi precedence rules extracted from test programs. Only valid if passing
a variant parameter to overloaded procedures expecting exactly one parameter.
single > (char, currency, int64, shortstring, ansistring, widestring, unicodestring, extended, double)
double/currency > (char, int64, shortstring, ansistring, widestring, unicodestring, extended)
extended > (char, int64, shortstring, ansistring, widestring, unicodestring)
longint/cardinal > (int64, shortstring, ansistring, widestring, unicodestring, extended, double, single, char, currency)
smallint > (longint, int64, shortstring, ansistring, widestring, unicodestring, extended, double single, char, currency);
word > (longint, cardinal, int64, shortstring, ansistring, widestring, unicodestring, extended, double single, char, currency);
shortint > (longint, smallint, int64, shortstring, ansistring, widestring, unicodestring, extended, double, single, char, currency)
byte > (longint, cardinal, word, smallint, int64, shortstring, ansistring, widestring, unicodestring, extended, double, single, char, currency);
boolean/formal > (char, int64, shortstring, ansistring, widestring, unicodestring)
widestring > (char, int64, shortstring, ansistring, unicodestring)
unicodestring > (char, int64, shortstring, ansistring)
ansistring > (char, int64, shortstring)
shortstring > (char, int64)
Relations not mentioned mean that they conflict: no decision possible }
function is_better_candidate_single_variant(currpd,bestpd:pcandidate):integer;
function calculate_relation(const currvcl, bestvcl, testvcl:
tvariantequaltype; const conflictvcls: tvariantequaltypes):integer;
begin
{ if (bestvcl=conflictvcl) or
(currvcl=conflictvcl) then
result:=0
else if (bestvcl=testvcl) then
result:=-1
else result:=1 }
result:=1-2*ord(bestvcl=testvcl)+
ord(currvcl in conflictvcls)-ord(bestvcl in conflictvcls);
end;
function getfirstrealparaidx(pd: pcandidate): integer;
begin
{ can be different for currpd and bestpd in case of overloaded }
{ functions, e.g. lowercase():char and lowercase():shortstring }
{ (depending on the calling convention and parameter order) }
result:=pd^.firstparaidx;
while (result>=0) and (vo_is_hidden_para in tparavarsym(pd^.data.paras[result]).varoptions) do
dec(result);
if (vo_is_hidden_para in tparavarsym(pd^.data.paras[result]).varoptions) then
internalerror(2006122803);
end;
var
currpara, bestpara: tparavarsym;
currvcl, bestvcl: tvariantequaltype;
begin
{
Return values:
> 0 when currpd is better than bestpd
< 0 when bestpd is better than currpd
= 0 when both are equal
}
currpara:=tparavarsym(currpd^.data.paras[getfirstrealparaidx(currpd)]);
bestpara:=tparavarsym(bestpd^.data.paras[getfirstrealparaidx(bestpd)]);
{ if one of the parameters is a regular variant, fall back to the }
{ default algorithm }
if (currpara.vardef.typ = variantdef) or
(bestpara.vardef.typ = variantdef) then
begin
result:=is_better_candidate(currpd,bestpd);
exit;
end;
currvcl:=get_variantequaltype(currpara.vardef);
bestvcl:=get_variantequaltype(bestpara.vardef);
{ sanity check }
result:=-5;
{ if both are the same, there is a conflict }
if (currvcl=bestvcl) then
result:=0
{ if one of the two cannot be used as variant, the other is better }
else if (bestvcl=tve_incompatible) then
result:=1
else if (currvcl=tve_incompatible) then
result:=-1
{ boolean and formal are better than chari64str, but conflict with }
{ everything else }
else if (currvcl=tve_boolformal) or
(bestvcl=tve_boolformal) then
if (currvcl=tve_boolformal) then
result:=ord(bestvcl in [tve_chari64,tve_sstring,tve_astring,tve_wstring,tve_ustring])
else
result:=-ord(currvcl in [tve_chari64,tve_sstring,tve_astring,tve_wstring,tve_ustring])
{ byte is better than everything else (we assume both aren't byte, }
{ since there's only one parameter and that one can't be the same) }
else if (currvcl=tve_byte) or
(bestvcl=tve_byte) then
result:=calculate_relation(currvcl,bestvcl,tve_byte,[tve_shortint])
{ shortint conflicts with word and cardinal, but is better than }
{ everything else but byte (which has already been handled) }
else if (currvcl=tve_shortint) or
(bestvcl=tve_shortint) then
result:=calculate_relation(currvcl,bestvcl,tve_shortint,[tve_word, tve_cardinal])
{ word conflicts with smallint, but is better than everything else }
{ but shortint and byte (which has already been handled) }
else if (currvcl=tve_word) or
(bestvcl=tve_word) then
result:=calculate_relation(currvcl,bestvcl,tve_word,[tve_smallint])
{ smallint conflicts with cardinal, but is better than everything }
{ which has not yet been tested }
else if (currvcl=tve_smallint) or
(bestvcl=tve_smallint) then
result:=calculate_relation(currvcl,bestvcl,tve_smallint,[tve_cardinal])
{ cardinal conflicts with each longint and is better than everything }
{ which has not yet been tested }
else if (currvcl=tve_cardinal) or
(bestvcl=tve_cardinal) then
result:=calculate_relation(currvcl,bestvcl,tve_cardinal,[tve_longint])
{ longint is better than everything which has not yet been tested }
else if (currvcl=tve_longint) or
(bestvcl=tve_longint) then
{ if bestvcl=tve_longint then
result:=-1
else
result:=1 }
result:=1-2*ord(bestvcl=tve_longint)
{ single is better than everything left }
else if (currvcl=tve_single) or
(bestvcl=tve_single) then
result:=1-2*ord(bestvcl=tve_single)
{ double/comp/currency are better than everything left, and conflict }
{ with each other (but that's already tested) }
else if (currvcl=tve_dblcurrency) or
(bestvcl=tve_dblcurrency) then
result:=1-2*ord(bestvcl=tve_dblcurrency)
{ extended is better than everything left }
else if (currvcl=tve_extended) or
(bestvcl=tve_extended) then
result:=1-2*ord(bestvcl=tve_extended)
{ widestring is better than everything left }
else if (currvcl=tve_wstring) or
(bestvcl=tve_wstring) then
result:=1-2*ord(bestvcl=tve_wstring)
{ unicodestring is better than everything left }
else if (currvcl=tve_ustring) or
(bestvcl=tve_ustring) then
result:=1-2*ord(bestvcl=tve_ustring)
{ ansistring is better than everything left }
else if (currvcl=tve_astring) or
(bestvcl=tve_astring) then
result:=1-2*ord(bestvcl=tve_astring)
{ shortstring is better than everything left }
else if (currvcl=tve_sstring) or
(bestvcl=tve_sstring) then
result:=1-2*ord(bestvcl=tve_sstring);
{ all possibilities should have been checked now }
if (result=-5) then
internalerror(2006122805);
end;
{$ifdef DISABLE_FAST_OVERLOAD_PATCH}
function tcallcandidates.choose_best(var bestpd:tabstractprocdef; singlevariant: boolean):integer;
var
pd: tprocdef;
besthpstart,
hp : pcandidate;
cntpd,
res : integer;
begin
{
Returns the number of candidates left and the
first candidate is returned in pdbest
}
{ Setup the first procdef as best, only count it as a result
when it is valid }
bestpd:=FCandidateProcs^.data;
if FCandidateProcs^.invalid then
cntpd:=0
else
cntpd:=1;
if assigned(FCandidateProcs^.next) then
begin
besthpstart:=FCandidateProcs;
hp:=FCandidateProcs^.next;
while assigned(hp) do
begin
if not singlevariant then
res:=is_better_candidate(hp,besthpstart)
else
res:=is_better_candidate_single_variant(hp,besthpstart);
if (res>0) then
begin
{ hp is better, flag all procs to be incompatible }
while (besthpstart<>hp) do
begin
besthpstart^.invalid:=true;
besthpstart:=besthpstart^.next;
end;
{ besthpstart is already set to hp }
bestpd:=besthpstart^.data;
cntpd:=1;
end
else
if (res<0) then
begin
{ besthpstart is better, flag current hp to be incompatible }
hp^.invalid:=true;
end
else
begin
{ res=0, both are valid }
if not hp^.invalid then
inc(cntpd);
end;
hp:=hp^.next;
end;
end;
{ if we've found one, check the procdefs ignored for overload choosing
to see whether they contain one from a child class with the same
parameters (so the overload choosing was not influenced by their
presence, but now that we've decided which overloaded version to call,
make sure we call the version closest in terms of visibility }
if (cntpd=1) and assigned(FIgnoredCandidateProcs) then
begin
for res:=0 to FIgnoredCandidateProcs.count-1 do
begin
pd:=tprocdef(FIgnoredCandidateProcs[res]);
{ stop searching when we start comparing methods of parent of
the struct in which the current best method was found }
if assigned(pd.struct) and
(pd.struct<>tprocdef(bestpd).struct) and
def_is_related(tprocdef(bestpd).struct,pd.struct) then
break;
if (pd.proctypeoption=bestpd.proctypeoption) and
((pd.procoptions*[po_classmethod,po_methodpointer])=(bestpd.procoptions*[po_classmethod,po_methodpointer])) and
(compare_paras(pd.paras,bestpd.paras,cp_all,[cpo_ignorehidden,cpo_ignoreuniv,cpo_openequalisexact])=te_exact) then
begin
{ first one encountered is closest in terms of visibility }
bestpd:=pd;
break;
end;
end;
end;
result:=cntpd;
end;
{$else}
function compare_by_old_sortout_check(pd,bestpd:pcandidate):integer;
var cpoptions : tcompare_paras_options;
begin
{ don't add duplicates, only compare visible parameters for the user }
cpoptions:=[cpo_ignorehidden];
if (po_compilerproc in bestpd^.data.procoptions) then
cpoptions:=cpoptions+[cpo_compilerproc];
if (po_rtlproc in bestpd^.data.procoptions) then
cpoptions:=cpoptions+[cpo_rtlproc];
compare_by_old_sortout_check := 0; // can't decide, bestpd probably wasn't sorted out in unpatched
if (compare_paras(pd^.data.paras,bestpd^.data.paras,cp_value_equal_const,cpoptions)>=te_equal) and
(not(po_objc in bestpd^.data.procoptions) or (bestpd^.data.messageinf.str^=pd^.data.messageinf.str^)) then
compare_by_old_sortout_check := 1; // bestpd was sorted out before patch
{ for implicit specializations non-generics should take precedence so
when comparing a specialization to a non-specialization mark as undecided
and it will be re-evaluated in is_better_candidate }
if (m_implicit_function_specialization in current_settings.modeswitches)
and (pd^.data.is_specialization <> bestpd^.data.is_specialization) then
compare_by_old_sortout_check:=0;
end;
function decide_restart(pd,bestpd:pcandidate) : boolean;
begin
decide_restart := false;
if assigned(bestpd) then
begin
{ don't restart if bestpd is marked invalid already }
if not bestpd^.invalid then
decide_restart := compare_by_old_sortout_check(pd,bestpd)<>0;
end;
end;
procedure save_validity(c : pcandidate);
begin
while assigned(c) do
begin
c^.saved_validity := c^.invalid;
c := c^.next;
end;
end;
procedure restore_validity(c : pcandidate);
begin
while assigned(c) do begin
c^.invalid := c^.saved_validity;
c := c^.next;
end;
end;
function tcallcandidates.choose_best(var bestpd:tabstractprocdef; singlevariant: boolean):integer;
var
pd: tprocdef;
besthpstart,
hp,hp2 : pcandidate;
cntpd,
res : integer;
restart : boolean;
begin
res:=0;
{
Returns the number of candidates left and the
first candidate is returned in pdbest
}
if not(assigned(FCandidateProcs)) then
begin
choose_best := 0;
exit;
end;
bestpd:=FCandidateProcs^.data;
if FCandidateProcs^.invalid then
cntpd:=0
else
cntpd:=1;
if assigned(FCandidateProcs^.next) then
begin
save_validity(FCandidateProcs);
restart := false;
{ keep restarting, until there wasn't a sorted-out besthpstart }
repeat
besthpstart:=FCandidateProcs;
bestpd:=FCandidateProcs^.data;
if restart then
begin
restore_validity(FCandidateProcs);
restart := false;
end;
{ Setup the first procdef as best, only count it as a result
when it is valid }
if besthpstart^.invalid then
cntpd:=0
else
cntpd:=1;
hp:=FCandidateProcs^.next;
while assigned(hp) and not(restart) do
begin
restart := decide_restart(hp,besthpstart);
if not restart then
begin
if besthpstart^.invalid then res := 1
else if hp^.invalid then res := -1
else if not singlevariant then
res:=is_better_candidate(hp,besthpstart)
else
res:=is_better_candidate_single_variant(hp,besthpstart);
end;
if restart then
begin
{ mark the sorted out invalid globally }
besthpstart^.saved_validity := true;
end
else if (res>0) then
begin
{ hp is better, flag all procs to be incompatible }
while (besthpstart<>hp) do
begin
besthpstart^.invalid:=true;
besthpstart:=besthpstart^.next;
end;
{ besthpstart is already set to hp }
bestpd:=besthpstart^.data;
if besthpstart^.invalid then
cntpd:=0
else
cntpd:=1;
end
else if (res<0) then
begin
{ besthpstart is better, flag current hp to be incompatible }
hp^.invalid:=true;
end
else
begin
{ res=0, both are valid }
if not hp^.invalid then
inc(cntpd);
end;
hp:=hp^.next;
end;
until not(restart);
end;
{ check the alternate choices if they would have been sorted out before patch... }
{ note we have procadded the candidates, so order is reversed procadd order here.
this was also used above: each sorted-out always has an "outsorter" counterpart
deeper down the next chain
}
{ for the intial implementation, let's first do some more consistency checking}
res := 0;
hp := FCandidateProcs;
while assigned(hp) do
begin
if not(hp^.invalid) then
inc(res);
hp := hp^.next;
end;
if (res<>cntpd) then
internalerror(202002161);
{ check all valid choices for sortout }
cntpd := 0;
hp := FCandidateProcs;
while assigned(hp) do
begin
if not(hp^.invalid) then
begin
hp2 := hp^.next;
while assigned(hp2) do begin
if compare_by_old_sortout_check(hp2,hp)<>0 then
begin
hp^.invalid := true;
hp2 := nil;
end
else
hp2:=hp2^.next;
end;
if not(hp^.invalid) then
begin
inc(cntpd);
{ check for the impossible event bestpd had become invalid}
if (cntpd=1) and (hp^.data<>bestpd) then
internalerror(202002162);
end;
end;
hp := hp^.next;
end;
{ if we've found one, check the procdefs ignored for overload choosing
to see whether they contain one from a child class with the same
parameters (so the overload choosing was not influenced by their
presence, but now that we've decided which overloaded version to call,
make sure we call the version closest in terms of visibility }
if (cntpd=1) and assigned(FIgnoredCandidateProcs) then
begin
for res:=0 to FIgnoredCandidateProcs.count-1 do
begin
pd:=tprocdef(FIgnoredCandidateProcs[res]);
{ stop searching when we start comparing methods of parent of
the struct in which the current best method was found }
if assigned(pd.struct) and
(pd.struct<>tprocdef(bestpd).struct) and
def_is_related(tprocdef(bestpd).struct,pd.struct) then
break;
if (pd.proctypeoption=bestpd.proctypeoption) and
((pd.procoptions*[po_classmethod,po_methodpointer])=(bestpd.procoptions*[po_classmethod,po_methodpointer])) and
(compare_paras(pd.paras,bestpd.paras,cp_all,[cpo_ignorehidden,cpo_ignoreuniv,cpo_openequalisexact])=te_exact) then
begin
{ first one encountered is closest in terms of visibility }
bestpd:=pd;
break;
end;
end;
end;
result:=cntpd;
end;
{$endif}
procedure tcallcandidates.find_wrong_para;
var
currparanr : smallint;
hp : pcandidate;
pt : tcallparanode;
wrongpara : tparavarsym;
begin
{ Only process the first overloaded procdef }
hp:=FCandidateProcs;
{ Find callparanode corresponding to the argument }
pt:=tcallparanode(FParanode);
currparanr:=FParalength;
while assigned(pt) and
(currparanr>hp^.wrongparanr) do
begin
pt:=tcallparanode(pt.right);
dec(currparanr);
end;
if (currparanr<>hp^.wrongparanr) or
not assigned(pt) then
internalerror(200212094);
{ Show error message, when it was a var or out parameter
guess that it is a missing typeconv }
wrongpara:=tparavarsym(hp^.data.paras[hp^.wrongparaidx]);
if wrongpara.varspez in [vs_var,vs_out] then
begin
{ Maybe passing the correct type but passing a const to var parameter }
if (compare_defs(pt.resultdef,wrongpara.vardef,pt.nodetype)<>te_incompatible) and
not valid_for_var(pt.left,true) then
CGMessagePos(pt.left.fileinfo,type_e_variable_id_expected)
else
CGMessagePos3(pt.left.fileinfo,parser_e_call_by_ref_without_typeconv,tostr(hp^.wrongparanr),
FullTypeName(pt.left.resultdef,wrongpara.vardef),
FullTypeName(wrongpara.vardef,pt.left.resultdef))
end
else
CGMessagePos3(pt.left.fileinfo,type_e_wrong_parameter_type,tostr(hp^.wrongparanr),
FullTypeName(pt.left.resultdef,wrongpara.vardef),
FullTypeName(wrongpara.vardef,pt.left.resultdef));
end;
procedure check_ranges(const location: tfileposinfo; source: tnode; destdef: tdef);
begin
if not(cs_check_ordinal_size in current_settings.localswitches) then
exit;
{ check if the assignment may cause a range check error }
{ if its not explicit, and only if the values are }
{ ordinals, enumdef and floatdef }
if assigned(destdef) and
(destdef.typ in [enumdef,orddef,floatdef]) and
not is_boolean(destdef) and
assigned(source.resultdef) and
(source.resultdef.typ in [enumdef,orddef,floatdef]) and
not is_boolean(source.resultdef) and
not is_constrealnode(source) and
{ constants are handled via regular range checking }
(source.nodetype<>ordconstn) then
begin
if ((destdef.size < source.resultdef.size) and
{ s80real and sc80real have a different size but the same precision }
not((destdef.typ=floatdef) and
(source.resultdef.typ=floatdef) and
(tfloatdef(source.resultdef).floattype in [s80real,sc80real]) and
(tfloatdef(destdef).floattype in [s80real,sc80real]))) or
((destdef.typ<>floatdef) and
(source.resultdef.typ<>floatdef) and
not is_in_limit(source.resultdef,destdef)) then
begin
if (cs_check_range in current_settings.localswitches) then
MessagePos(location,type_w_smaller_possible_range_check)
else
MessagePos(location,type_h_smaller_possible_range_check);
end;
end;
end;
function is_valid_for_default(def:tdef):boolean;
function is_valid_record_or_object(def:tabstractrecorddef):boolean;
var
sym : tsym;
i : longint;
begin
for i:=0 to def.symtable.symlist.count-1 do
begin
sym:=tsym(def.symtable.symlist[i]);
if not is_normal_fieldvarsym(sym) then
continue;
if not is_valid_for_default(tfieldvarsym(sym).vardef) then
begin
result:=false;
exit;
end;
end;
result:=true;
end;
begin
case def.typ of
recorddef:
result:=is_valid_record_or_object(tabstractrecorddef(def));
objectdef:
if is_implicit_pointer_object_type(def) then
result:=true
else
if is_object(def) then
result:=is_valid_record_or_object(tabstractrecorddef(def))
else
result:=false;
arraydef:
if not (ado_isdynamicarray in tarraydef(def).arrayoptions) then
result:=is_valid_for_default(tarraydef(def).elementdef)
else
result:=true;
formaldef,
abstractdef,
filedef:
result:=false;
else
result:=true;
end;
end;
end.
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