{ $Id$ Copyright (c) 2000-2002 by Florian Klaempfl Type checking and register allocation for type converting nodes 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 ncnv; {$i fpcdefs.inc} interface uses node, symtype, defutil,defcmp, nld {$ifdef Delphi} ,dmisc {$endif} ; type ttypeconvnode = class(tunarynode) totype : ttype; convtype : tconverttype; constructor create(node : tnode;const t : ttype);virtual; constructor create_explicit(node : tnode;const t : ttype); constructor ppuload(t:tnodetype;ppufile:tcompilerppufile);override; procedure ppuwrite(ppufile:tcompilerppufile);override; procedure buildderefimpl;override; procedure derefimpl;override; function getcopy : tnode;override; function pass_1 : tnode;override; function det_resulttype:tnode;override; procedure mark_write;override; function docompare(p: tnode) : boolean; override; procedure second_call_helper(c : tconverttype); private function resulttype_int_to_int : tnode; function resulttype_cord_to_pointer : tnode; function resulttype_chararray_to_string : tnode; function resulttype_string_to_chararray : tnode; function resulttype_string_to_string : tnode; function resulttype_char_to_string : tnode; function resulttype_char_to_chararray : tnode; function resulttype_int_to_real : tnode; function resulttype_real_to_real : tnode; function resulttype_real_to_currency : tnode; function resulttype_cchar_to_pchar : tnode; function resulttype_cstring_to_pchar : tnode; function resulttype_char_to_char : tnode; function resulttype_arrayconstructor_to_set : tnode; function resulttype_pchar_to_string : tnode; function resulttype_interface_to_guid : tnode; function resulttype_dynarray_to_openarray : tnode; function resulttype_pwchar_to_string : tnode; function resulttype_variant_to_dynarray : tnode; function resulttype_dynarray_to_variant : tnode; function resulttype_call_helper(c : tconverttype) : tnode; function resulttype_variant_to_enum : tnode; function resulttype_enum_to_variant : tnode; protected function first_int_to_int : tnode;virtual; function first_cstring_to_pchar : tnode;virtual; function first_string_to_chararray : tnode;virtual; function first_char_to_string : tnode;virtual; function first_nothing : tnode;virtual; function first_array_to_pointer : tnode;virtual; function first_int_to_real : tnode;virtual; function first_real_to_real : tnode;virtual; function first_pointer_to_array : tnode;virtual; function first_cchar_to_pchar : tnode;virtual; function first_bool_to_int : tnode;virtual; function first_int_to_bool : tnode;virtual; function first_bool_to_bool : tnode;virtual; function first_proc_to_procvar : tnode;virtual; function first_load_smallset : tnode;virtual; function first_cord_to_pointer : tnode;virtual; function first_ansistring_to_pchar : tnode;virtual; function first_arrayconstructor_to_set : tnode;virtual; function first_class_to_intf : tnode;virtual; function first_char_to_char : tnode;virtual; function first_call_helper(c : tconverttype) : tnode; { these wrapper are necessary, because the first_* stuff is called } { through a table. Without the wrappers override wouldn't have } { any effect } function _first_int_to_int : tnode; function _first_cstring_to_pchar : tnode; function _first_string_to_chararray : tnode; function _first_char_to_string : tnode; function _first_nothing : tnode; function _first_array_to_pointer : tnode; function _first_int_to_real : tnode; function _first_real_to_real: tnode; function _first_pointer_to_array : tnode; function _first_cchar_to_pchar : tnode; function _first_bool_to_int : tnode; function _first_int_to_bool : tnode; function _first_bool_to_bool : tnode; function _first_proc_to_procvar : tnode; function _first_load_smallset : tnode; function _first_cord_to_pointer : tnode; function _first_ansistring_to_pchar : tnode; function _first_arrayconstructor_to_set : tnode; function _first_class_to_intf : tnode; function _first_char_to_char : tnode; procedure _second_int_to_int;virtual; procedure _second_string_to_string;virtual; procedure _second_cstring_to_pchar;virtual; procedure _second_string_to_chararray;virtual; procedure _second_array_to_pointer;virtual; procedure _second_pointer_to_array;virtual; procedure _second_chararray_to_string;virtual; procedure _second_char_to_string;virtual; procedure _second_int_to_real;virtual; procedure _second_real_to_real;virtual; procedure _second_cord_to_pointer;virtual; procedure _second_proc_to_procvar;virtual; procedure _second_bool_to_int;virtual; procedure _second_int_to_bool;virtual; procedure _second_bool_to_bool;virtual; procedure _second_load_smallset;virtual; procedure _second_ansistring_to_pchar;virtual; procedure _second_class_to_intf;virtual; procedure _second_char_to_char;virtual; procedure _second_nothing; virtual; procedure second_int_to_int;virtual;abstract; procedure second_string_to_string;virtual;abstract; procedure second_cstring_to_pchar;virtual;abstract; procedure second_string_to_chararray;virtual;abstract; procedure second_array_to_pointer;virtual;abstract; procedure second_pointer_to_array;virtual;abstract; procedure second_chararray_to_string;virtual;abstract; procedure second_char_to_string;virtual;abstract; procedure second_int_to_real;virtual;abstract; procedure second_real_to_real;virtual;abstract; procedure second_cord_to_pointer;virtual;abstract; procedure second_proc_to_procvar;virtual;abstract; procedure second_bool_to_int;virtual;abstract; procedure second_int_to_bool;virtual;abstract; procedure second_bool_to_bool;virtual;abstract; procedure second_load_smallset;virtual;abstract; procedure second_ansistring_to_pchar;virtual;abstract; procedure second_class_to_intf;virtual;abstract; procedure second_char_to_char;virtual;abstract; procedure second_nothing; virtual;abstract; end; ttypeconvnodeclass = class of ttypeconvnode; tasnode = class(tbinarynode) constructor create(l,r : tnode);virtual; function pass_1 : tnode;override; function det_resulttype:tnode;override; function getcopy: tnode;override; destructor destroy; override; protected call: tnode; end; tasnodeclass = class of tasnode; tisnode = class(tbinarynode) constructor create(l,r : tnode);virtual; function pass_1 : tnode;override; function det_resulttype:tnode;override; procedure pass_2;override; end; tisnodeclass = class of tisnode; var ctypeconvnode : ttypeconvnodeclass; casnode : tasnodeclass; cisnode : tisnodeclass; procedure inserttypeconv(var p:tnode;const t:ttype); procedure inserttypeconv_explicit(var p:tnode;const t:ttype); procedure arrayconstructor_to_set(var p : tnode); implementation uses globtype,systems,tokens, cutils,verbose,globals,widestr, symconst,symdef,symsym,symtable, ncon,ncal,nset,nadd,ninl,nmem,nmat,nutils, cgbase,procinfo, htypechk,pass_1,cpuinfo; {***************************************************************************** Helpers *****************************************************************************} procedure inserttypeconv(var p:tnode;const t:ttype); begin if not assigned(p.resulttype.def) then begin resulttypepass(p); if codegenerror then exit; end; { don't insert obsolete type conversions } if equal_defs(p.resulttype.def,t.def) and not ((p.resulttype.def.deftype=setdef) and (tsetdef(p.resulttype.def).settype <> tsetdef(t.def).settype)) then begin p.resulttype:=t; end else begin p:=ctypeconvnode.create(p,t); resulttypepass(p); end; end; procedure inserttypeconv_explicit(var p:tnode;const t:ttype); begin if not assigned(p.resulttype.def) then begin resulttypepass(p); if codegenerror then exit; end; { don't insert obsolete type conversions } if equal_defs(p.resulttype.def,t.def) and not ((p.resulttype.def.deftype=setdef) and (tsetdef(p.resulttype.def).settype <> tsetdef(t.def).settype)) then begin p.resulttype:=t; end else begin p:=ctypeconvnode.create_explicit(p,t); resulttypepass(p); end; end; {***************************************************************************** Array constructor to Set Conversion *****************************************************************************} procedure arrayconstructor_to_set(var p : tnode); var constp : tsetconstnode; buildp, p2,p3,p4 : tnode; htype : ttype; constset : Pconstset; constsetlo, constsethi : TConstExprInt; procedure update_constsethi(t:ttype); begin if ((t.def.deftype=orddef) and (torddef(t.def).high>=constsethi)) then begin constsethi:=torddef(t.def).high; if htype.def=nil then begin if (constsethi>255) or (torddef(t.def).low<0) then htype:=u8inttype else htype:=t; end; if constsethi>255 then constsethi:=255; end else if ((t.def.deftype=enumdef) and (tenumdef(t.def).max>=constsethi)) then begin if htype.def=nil then htype:=t; constsethi:=tenumdef(t.def).max; end; end; procedure do_set(pos : longint); begin if (pos and not $ff)<>0 then Message(parser_e_illegal_set_expr); if pos>constsethi then constsethi:=pos; if posarrayconstructorn then internalerror(200205105); new(constset); constset^:=[]; htype.reset; constsetlo:=0; constsethi:=0; constp:=csetconstnode.create(nil,htype); constp.value_set:=constset; buildp:=constp; hp:=tarrayconstructornode(p); if assigned(hp.left) then begin while assigned(hp) do begin p4:=nil; { will contain the tree to create the set } {split a range into p2 and p3 } if hp.left.nodetype=arrayconstructorrangen then begin p2:=tarrayconstructorrangenode(hp.left).left; p3:=tarrayconstructorrangenode(hp.left).right; tarrayconstructorrangenode(hp.left).left:=nil; tarrayconstructorrangenode(hp.left).right:=nil; end else begin p2:=hp.left; hp.left:=nil; p3:=nil; end; resulttypepass(p2); if assigned(p3) then resulttypepass(p3); if codegenerror then break; case p2.resulttype.def.deftype of enumdef, orddef: begin getrange(p2.resulttype.def,lr,hr); if assigned(p3) then begin { this isn't good, you'll get problems with type t010 = 0..10; ts = set of t010; var s : ts;b : t010 begin s:=[1,2,b]; end. if is_integer(p3^.resulttype.def) then begin inserttypeconv(p3,u8bitdef); end; } if assigned(htype.def) and not(equal_defs(htype.def,p3.resulttype.def)) then begin aktfilepos:=p3.fileinfo; CGMessage(type_e_typeconflict_in_set); end else begin if (p2.nodetype=ordconstn) and (p3.nodetype=ordconstn) then begin if not(is_integer(p3.resulttype.def)) then htype:=p3.resulttype else begin inserttypeconv(p3,u8inttype); inserttypeconv(p2,u8inttype); end; for l:=tordconstnode(p2).value to tordconstnode(p3).value do do_set(l); p2.free; p3.free; end else begin update_constsethi(p2.resulttype); inserttypeconv(p2,htype); update_constsethi(p3.resulttype); inserttypeconv(p3,htype); if assigned(htype.def) then inserttypeconv(p3,htype) else inserttypeconv(p3,u8inttype); p4:=csetelementnode.create(p2,p3); end; end; end else begin { Single value } if p2.nodetype=ordconstn then begin if not(is_integer(p2.resulttype.def)) then update_constsethi(p2.resulttype) else inserttypeconv(p2,u8inttype); do_set(tordconstnode(p2).value); p2.free; end else begin update_constsethi(p2.resulttype); if assigned(htype.def) then inserttypeconv(p2,htype) else inserttypeconv(p2,u8inttype); p4:=csetelementnode.create(p2,nil); end; end; end; stringdef : begin { if we've already set elements which are constants } { throw an error } if ((htype.def=nil) and assigned(buildp)) or not(is_char(htype.def)) then CGMessage(type_e_typeconflict_in_set) else for l:=1 to length(pstring(tstringconstnode(p2).value_str)^) do do_set(ord(pstring(tstringconstnode(p2).value_str)^[l])); if htype.def=nil then htype:=cchartype; p2.free; end; else CGMessage(type_e_ordinal_expr_expected); end; { insert the set creation tree } if assigned(p4) then buildp:=caddnode.create(addn,buildp,p4); { load next and dispose current node } p2:=hp; hp:=tarrayconstructornode(tarrayconstructornode(p2).right); tarrayconstructornode(p2).right:=nil; p2.free; end; if (htype.def=nil) then htype:=u8inttype; end else begin { empty set [], only remove node } p.free; end; { set the initial set type } constp.resulttype.setdef(tsetdef.create(htype,constsethi)); { determine the resulttype for the tree } resulttypepass(buildp); { set the new tree } p:=buildp; end; {***************************************************************************** TTYPECONVNODE *****************************************************************************} constructor ttypeconvnode.create(node : tnode;const t:ttype); begin inherited create(typeconvn,node); convtype:=tc_not_possible; totype:=t; if t.def=nil then internalerror(200103281); set_file_line(node); end; constructor ttypeconvnode.create_explicit(node : tnode;const t:ttype); begin self.create(node,t); include(flags,nf_explicit); end; constructor ttypeconvnode.ppuload(t:tnodetype;ppufile:tcompilerppufile); begin inherited ppuload(t,ppufile); ppufile.gettype(totype); convtype:=tconverttype(ppufile.getbyte); end; procedure ttypeconvnode.ppuwrite(ppufile:tcompilerppufile); begin inherited ppuwrite(ppufile); ppufile.puttype(totype); ppufile.putbyte(byte(convtype)); end; procedure ttypeconvnode.buildderefimpl; begin inherited buildderefimpl; totype.buildderef; end; procedure ttypeconvnode.derefimpl; begin inherited derefimpl; totype.resolve; end; function ttypeconvnode.getcopy : tnode; var n : ttypeconvnode; begin n:=ttypeconvnode(inherited getcopy); n.convtype:=convtype; getcopy:=n; end; function ttypeconvnode.resulttype_cord_to_pointer : tnode; var t : tnode; begin result:=nil; if left.nodetype=ordconstn then begin { check if we have a valid pointer constant (JM) } if (sizeof(pointer) > sizeof(TConstPtrUInt)) then if (sizeof(TConstPtrUInt) = 4) then begin if (tordconstnode(left).value < low(longint)) or (tordconstnode(left).value > high(cardinal)) then CGMessage(parser_e_range_check_error); end else if (sizeof(TConstPtrUInt) = 8) then begin if (tordconstnode(left).value < low(int64)) or (tordconstnode(left).value > high(qword)) then CGMessage(parser_e_range_check_error); end else internalerror(2001020801); t:=cpointerconstnode.create(TConstPtrUInt(tordconstnode(left).value),resulttype); result:=t; end else internalerror(200104023); end; function ttypeconvnode.resulttype_chararray_to_string : tnode; begin result := ccallnode.createinternres( 'fpc_chararray_to_'+tstringdef(resulttype.def).stringtypname, ccallparanode.create(left,nil),resulttype); left := nil; end; function ttypeconvnode.resulttype_string_to_chararray : tnode; var arrsize: longint; begin with tarraydef(resulttype.def) do begin if highrange= arrsize) and (tstringdef(left.resulttype.def).string_typ=st_shortstring) then begin { handled separately } result := nil; exit; end; result := ccallnode.createinternres( 'fpc_'+tstringdef(left.resulttype.def).stringtypname+ '_to_chararray',ccallparanode.create(left,ccallparanode.create( cordconstnode.create(arrsize,s32inttype,true),nil)),resulttype); left := nil; end; function ttypeconvnode.resulttype_string_to_string : tnode; var procname: string[31]; stringpara : tcallparanode; pw : pcompilerwidestring; pc : pchar; begin result:=nil; if left.nodetype=stringconstn then begin { convert ascii 2 unicode } if (tstringdef(resulttype.def).string_typ=st_widestring) and (tstringconstnode(left).st_type in [st_ansistring,st_shortstring,st_longstring]) then begin initwidestring(pw); ascii2unicode(tstringconstnode(left).value_str,tstringconstnode(left).len,pw); ansistringdispose(tstringconstnode(left).value_str,tstringconstnode(left).len); pcompilerwidestring(tstringconstnode(left).value_str):=pw; end else { convert unicode 2 ascii } if (tstringconstnode(left).st_type=st_widestring) and (tstringdef(resulttype.def).string_typ in [st_ansistring,st_shortstring,st_longstring]) then begin pw:=pcompilerwidestring(tstringconstnode(left).value_str); getmem(pc,getlengthwidestring(pw)+1); unicode2ascii(pw,pc); donewidestring(pw); tstringconstnode(left).value_str:=pc; end; tstringconstnode(left).st_type:=tstringdef(resulttype.def).string_typ; tstringconstnode(left).resulttype:=resulttype; result:=left; left:=nil; end else begin { get the correct procedure name } procname := 'fpc_'+tstringdef(left.resulttype.def).stringtypname+ '_to_'+tstringdef(resulttype.def).stringtypname; { create parameter (and remove left node from typeconvnode } { since it's reused as parameter) } stringpara := ccallparanode.create(left,nil); left := nil; { when converting to shortstrings, we have to pass high(destination) too } if (tstringdef(resulttype.def).string_typ = st_shortstring) then stringpara.right := ccallparanode.create(cinlinenode.create( in_high_x,false,self.getcopy),nil); { and create the callnode } result := ccallnode.createinternres(procname,stringpara,resulttype); end; end; function ttypeconvnode.resulttype_char_to_string : tnode; var procname: string[31]; para : tcallparanode; hp : tstringconstnode; ws : pcompilerwidestring; begin result:=nil; if left.nodetype=ordconstn then begin if tstringdef(resulttype.def).string_typ=st_widestring then begin initwidestring(ws); concatwidestringchar(ws,tcompilerwidechar(chr(tordconstnode(left).value))); hp:=cstringconstnode.createwstr(ws); donewidestring(ws); end else hp:=cstringconstnode.createstr(chr(tordconstnode(left).value),tstringdef(resulttype.def).string_typ); result:=hp; end else { shortstrings are handled 'inline' } if tstringdef(resulttype.def).string_typ <> st_shortstring then begin { create the parameter } para := ccallparanode.create(left,nil); left := nil; { and the procname } procname := 'fpc_char_to_' +tstringdef(resulttype.def).stringtypname; { and finally the call } result := ccallnode.createinternres(procname,para,resulttype); end else begin { create word(byte(char) shl 8 or 1) for litte endian machines } { and word(byte(char) or 256) for big endian machines } left := ctypeconvnode.create_explicit(left,u8inttype); if (target_info.endian = endian_little) then left := caddnode.create(orn, cshlshrnode.create(shln,left,cordconstnode.create(8,s32inttype,false)), cordconstnode.create(1,s32inttype,false)) else left := caddnode.create(orn,left, cordconstnode.create(1 shl 8,s32inttype,false)); left := ctypeconvnode.create_explicit(left,u16inttype); resulttypepass(left); end; end; function ttypeconvnode.resulttype_char_to_chararray : tnode; begin if resulttype.def.size <> 1 then begin { convert first to string, then to chararray } inserttypeconv(left,cshortstringtype); inserttypeconv(left,resulttype); result:=left; left := nil; exit; end; result := nil; end; function ttypeconvnode.resulttype_char_to_char : tnode; var hp : tordconstnode; begin result:=nil; if left.nodetype=ordconstn then begin if (torddef(resulttype.def).typ=uchar) and (torddef(left.resulttype.def).typ=uwidechar) then begin hp:=cordconstnode.create( ord(unicode2asciichar(tcompilerwidechar(tordconstnode(left).value))), cchartype,true); result:=hp; end else if (torddef(resulttype.def).typ=uwidechar) and (torddef(left.resulttype.def).typ=uchar) then begin hp:=cordconstnode.create( asciichar2unicode(chr(tordconstnode(left).value)), cwidechartype,true); result:=hp; end else internalerror(200105131); exit; end; end; function ttypeconvnode.resulttype_int_to_int : tnode; var v : TConstExprInt; begin result:=nil; if left.nodetype=ordconstn then begin v:=tordconstnode(left).value; if is_currency(resulttype.def) then v:=v*10000; if (resulttype.def.deftype=pointerdef) then result:=cpointerconstnode.create(TConstPtrUInt(v),resulttype) else begin if is_currency(left.resulttype.def) then v:=v div 10000; result:=cordconstnode.create(v,resulttype,false); end; end else if left.nodetype=pointerconstn then begin v:=tpointerconstnode(left).value; if (resulttype.def.deftype=pointerdef) then result:=cpointerconstnode.create(v,resulttype) else begin if is_currency(resulttype.def) then v:=v*10000; result:=cordconstnode.create(v,resulttype,false); end; end else begin { multiply by 10000 for currency. We need to use getcopy to pass the argument because the current node is always disposed. Only inserting the multiply in the left node is not possible because it'll get in an infinite loop to convert int->currency } if is_currency(resulttype.def) then begin result:=caddnode.create(muln,getcopy,cordconstnode.create(10000,resulttype,false)); include(result.flags,nf_is_currency); end else if is_currency(left.resulttype.def) then begin result:=cmoddivnode.create(divn,getcopy,cordconstnode.create(10000,resulttype,false)); include(result.flags,nf_is_currency); end; end; end; function ttypeconvnode.resulttype_int_to_real : tnode; var rv : bestreal; begin result:=nil; if left.nodetype=ordconstn then begin rv:=tordconstnode(left).value; if is_currency(resulttype.def) then rv:=rv*10000.0 else if is_currency(left.resulttype.def) then rv:=rv/10000.0; result:=crealconstnode.create(rv,resulttype); end else begin { multiply by 10000 for currency. We need to use getcopy to pass the argument because the current node is always disposed. Only inserting the multiply in the left node is not possible because it'll get in an infinite loop to convert int->currency } if is_currency(resulttype.def) then begin result:=caddnode.create(muln,getcopy,crealconstnode.create(10000.0,resulttype)); include(result.flags,nf_is_currency); end else if is_currency(left.resulttype.def) then begin result:=caddnode.create(slashn,getcopy,crealconstnode.create(10000.0,resulttype)); include(result.flags,nf_is_currency); end; end; end; function ttypeconvnode.resulttype_real_to_currency : tnode; begin if not is_currency(resulttype.def) then internalerror(200304221); result:=nil; left:=caddnode.create(muln,left,crealconstnode.create(10000.0,left.resulttype)); include(left.flags,nf_is_currency); resulttypepass(left); { Convert constants directly, else call Round() } if left.nodetype=realconstn then result:=cordconstnode.create(round(trealconstnode(left).value_real),resulttype,false) else result:=ccallnode.createinternres('fpc_round', ccallparanode.create(left,nil),resulttype); left:=nil; end; function ttypeconvnode.resulttype_real_to_real : tnode; begin result:=nil; if is_currency(left.resulttype.def) and not(is_currency(resulttype.def)) then begin left:=caddnode.create(slashn,left,crealconstnode.create(10000.0,left.resulttype)); include(left.flags,nf_is_currency); resulttypepass(left); end else if is_currency(resulttype.def) and not(is_currency(left.resulttype.def)) then begin left:=caddnode.create(muln,left,crealconstnode.create(10000.0,left.resulttype)); include(left.flags,nf_is_currency); resulttypepass(left); end; if left.nodetype=realconstn then result:=crealconstnode.create(trealconstnode(left).value_real,resulttype); end; function ttypeconvnode.resulttype_cchar_to_pchar : tnode; begin result:=nil; if is_pwidechar(resulttype.def) then inserttypeconv(left,cwidestringtype) else inserttypeconv(left,cshortstringtype); { evaluate again, reset resulttype so the convert_typ will be calculated again and cstring_to_pchar will be used for futher conversion } result:=det_resulttype; end; function ttypeconvnode.resulttype_cstring_to_pchar : tnode; begin result:=nil; if is_pwidechar(resulttype.def) then inserttypeconv(left,cwidestringtype); end; function ttypeconvnode.resulttype_arrayconstructor_to_set : tnode; var hp : tnode; begin result:=nil; if left.nodetype<>arrayconstructorn then internalerror(5546); { remove typeconv node } hp:=left; left:=nil; { create a set constructor tree } arrayconstructor_to_set(hp); result:=hp; end; function ttypeconvnode.resulttype_pchar_to_string : tnode; begin result := ccallnode.createinternres( 'fpc_pchar_to_'+tstringdef(resulttype.def).stringtypname, ccallparanode.create(left,nil),resulttype); left := nil; end; function ttypeconvnode.resulttype_interface_to_guid : tnode; begin if assigned(tobjectdef(left.resulttype.def).iidguid) then result:=cguidconstnode.create(tobjectdef(left.resulttype.def).iidguid^); end; function ttypeconvnode.resulttype_dynarray_to_openarray : tnode; begin { a dynamic array is a pointer to an array, so to convert it to } { an open array, we have to dereference it (JM) } result := ctypeconvnode.create_explicit(left,voidpointertype); resulttypepass(result); { left is reused } left := nil; result := cderefnode.create(result); result.resulttype := resulttype; end; function ttypeconvnode.resulttype_pwchar_to_string : tnode; begin result := ccallnode.createinternres( 'fpc_pwidechar_to_'+tstringdef(resulttype.def).stringtypname, ccallparanode.create(left,nil),resulttype); left := nil; end; function ttypeconvnode.resulttype_variant_to_dynarray : tnode; begin result := ccallnode.createinternres( 'fpc_variant_to_dynarray', ccallparanode.create(caddrnode.create(crttinode.create(tstoreddef(resulttype.def),initrtti)), ccallparanode.create(left,nil) ),resulttype); left := nil; end; function ttypeconvnode.resulttype_dynarray_to_variant : tnode; begin result := ccallnode.createinternres( 'fpc_dynarray_to_variant', ccallparanode.create(caddrnode.create(crttinode.create(tstoreddef(resulttype.def),initrtti)), ccallparanode.create(left,nil) ),resulttype); result:=nil; end; function ttypeconvnode.resulttype_variant_to_enum : tnode; begin result := ctypeconvnode.create_explicit(left,sinttype); result := ctypeconvnode.create_explicit(result,resulttype); resulttypepass(result); { left is reused } left := nil; end; function ttypeconvnode.resulttype_enum_to_variant : tnode; begin result := ctypeconvnode.create_explicit(left,sinttype); result := ctypeconvnode.create_explicit(result,cvarianttype); resulttypepass(result); { left is reused } left := nil; end; function ttypeconvnode.resulttype_call_helper(c : tconverttype) : tnode; {$ifdef fpc} const resulttypeconvert : array[tconverttype] of pointer = ( {equal} nil, {not_possible} nil, { string_2_string } @ttypeconvnode.resulttype_string_to_string, { char_2_string } @ttypeconvnode.resulttype_char_to_string, { char_2_chararray } @ttypeconvnode.resulttype_char_to_chararray, { pchar_2_string } @ttypeconvnode.resulttype_pchar_to_string, { cchar_2_pchar } @ttypeconvnode.resulttype_cchar_to_pchar, { cstring_2_pchar } @ttypeconvnode.resulttype_cstring_to_pchar, { ansistring_2_pchar } nil, { string_2_chararray } @ttypeconvnode.resulttype_string_to_chararray, { chararray_2_string } @ttypeconvnode.resulttype_chararray_to_string, { array_2_pointer } nil, { pointer_2_array } nil, { int_2_int } @ttypeconvnode.resulttype_int_to_int, { int_2_bool } nil, { bool_2_bool } nil, { bool_2_int } nil, { real_2_real } @ttypeconvnode.resulttype_real_to_real, { int_2_real } @ttypeconvnode.resulttype_int_to_real, { real_2_currency } @ttypeconvnode.resulttype_real_to_currency, { proc_2_procvar } nil, { arrayconstructor_2_set } @ttypeconvnode.resulttype_arrayconstructor_to_set, { load_smallset } nil, { cord_2_pointer } @ttypeconvnode.resulttype_cord_to_pointer, { intf_2_string } nil, { intf_2_guid } @ttypeconvnode.resulttype_interface_to_guid, { class_2_intf } nil, { char_2_char } @ttypeconvnode.resulttype_char_to_char, { normal_2_smallset} nil, { dynarray_2_openarray} @resulttype_dynarray_to_openarray, { pwchar_2_string} @resulttype_pwchar_to_string, { variant_2_dynarray} @resulttype_variant_to_dynarray, { dynarray_2_variant} @resulttype_dynarray_to_variant, { variant_2_enum} @resulttype_variant_to_enum, { enum_2_variant} @resulttype_enum_to_variant ); type tprocedureofobject = function : tnode of object; var r : packed record proc : pointer; obj : pointer; end; begin result:=nil; { this is a little bit dirty but it works } { and should be quite portable too } r.proc:=resulttypeconvert[c]; r.obj:=self; if assigned(r.proc) then result:=tprocedureofobject(r)(); end; {$else} begin case c of tc_string_2_string: resulttype_string_to_string; tc_char_2_string : resulttype_char_to_string; tc_char_2_chararray: resulttype_char_to_chararray; tc_pchar_2_string : resulttype_pchar_to_string; tc_cchar_2_pchar : resulttype_cchar_to_pchar; tc_cstring_2_pchar : resulttype_cstring_to_pchar; tc_string_2_chararray : resulttype_string_to_chararray; tc_chararray_2_string : resulttype_chararray_to_string; tc_real_2_real : resulttype_real_to_real; tc_int_2_real : resulttype_int_to_real; tc_real_2_currency : resulttype_real_to_currency; tc_arrayconstructor_2_set : resulttype_arrayconstructor_to_set; tc_cord_2_pointer : resulttype_cord_to_pointer; tc_intf_2_guid : resulttype_interface_to_guid; tc_char_2_char : resulttype_char_to_char; tc_dynarray_2_openarray : resulttype_dynarray_to_openarray; tc_pwchar_2_string : resulttype_pwchar_to_string; tc_variant_2_dynarray : resulttype_variant_to_dynarray; tc_dynarray_2_variant : resulttype_dynarray_to_variant; end; end; {$Endif fpc} function ttypeconvnode.det_resulttype:tnode; var hp : tnode; currprocdef, aprocdef : tprocdef; eq : tequaltype; cdoptions : tcompare_defs_options; begin result:=nil; resulttype:=totype; resulttypepass(left); if codegenerror then exit; { When absolute force tc_equal } if (nf_absolute in flags) then begin convtype:=tc_equal; exit; end; { tp procvar support. Skip typecasts to record or set. Those convert on the procvar value. This is used to access the fields of a methodpointer } if not(resulttype.def.deftype in [recorddef,setdef]) then maybe_call_procvar(left,true); cdoptions:=[cdo_check_operator,cdo_allow_variant]; if nf_explicit in flags then include(cdoptions,cdo_explicit); eq:=compare_defs_ext(left.resulttype.def,resulttype.def,left.nodetype,convtype,aprocdef,cdoptions); case eq of te_exact, te_equal : begin { because is_equal only checks the basetype for sets we need to check here if we are loading a smallset into a normalset } if (resulttype.def.deftype=setdef) and (left.resulttype.def.deftype=setdef) and ((tsetdef(resulttype.def).settype = smallset) xor (tsetdef(left.resulttype.def).settype = smallset)) then begin { constant sets can be converted by changing the type only } if (left.nodetype=setconstn) then begin left.resulttype:=resulttype; result:=left; left:=nil; exit; end; if (tsetdef(resulttype.def).settype <> smallset) then convtype:=tc_load_smallset else convtype := tc_normal_2_smallset; exit; end else begin { Only leave when there is no conversion to do. We can still need to call a conversion routine, like the routine to convert a stringconstnode } if convtype in [tc_equal,tc_not_possible] then begin left.resulttype:=resulttype; result:=left; left:=nil; exit; end; end; end; te_convert_l1, te_convert_l2, te_convert_l3 : begin { nothing to do } end; te_convert_operator : begin include(current_procinfo.flags,pi_do_call); inc(aprocdef.procsym.refs); hp:=ccallnode.create(ccallparanode.create(left,nil), Tprocsym(aprocdef.procsym),nil,nil); { tell explicitly which def we must use !! (PM) } tcallnode(hp).procdefinition:=aprocdef; left:=nil; result:=hp; exit; end; te_incompatible : begin { Procedures have a resulttype.def of voiddef and functions of their own resulttype.def. They will therefore always be incompatible with a procvar. Because isconvertable cannot check for procedures we use an extra check for them.} if (m_tp_procvar in aktmodeswitches) and (resulttype.def.deftype=procvardef) then begin if is_procsym_load(left) then begin if (left.nodetype<>addrn) then begin convtype:=tc_proc_2_procvar; { Now check if the procedure we are going to assign to the procvar, is compatible with the procvar's type } if not(nf_explicit in flags) and (proc_to_procvar_equal(tprocsym(tloadnode(left).symtableentry).first_procdef, tprocvardef(resulttype.def),true)=te_incompatible) then IncompatibleTypes(tprocsym(tloadnode(left).symtableentry).first_procdef,resulttype.def); exit; end; end else if (left.nodetype=calln) and (tcallnode(left).para_count=0) then begin if assigned(tcallnode(left).right) then begin { this is already a procvar, if it is really equal is checked below } convtype:=tc_equal; hp:=tcallnode(left).right.getcopy; currprocdef:=tprocdef(hp.resulttype.def); end else begin convtype:=tc_proc_2_procvar; currprocdef:=Tprocsym(Tcallnode(left).symtableprocentry).search_procdef_byprocvardef(Tprocvardef(resulttype.def)); hp:=cloadnode.create_procvar(tprocsym(tcallnode(left).symtableprocentry), currprocdef,tcallnode(left).symtableproc); if (tcallnode(left).symtableprocentry.owner.symtabletype=objectsymtable) then begin if assigned(tcallnode(left).methodpointer) then begin { Under certain circumstances the methodpointer is a loadvmtaddrn which isn't possible if it is used as a method pointer, so fix this. If you change this, ensure that tests/tbs/tw2669.pp still works } if tcallnode(left).methodpointer.nodetype=loadvmtaddrn then tloadnode(hp).set_mp(tloadvmtaddrnode(tcallnode(left).methodpointer).left.getcopy) else tloadnode(hp).set_mp(tcallnode(left).methodpointer.getcopy); end else tloadnode(hp).set_mp(load_self_node); end; resulttypepass(hp); end; left.free; left:=hp; { Now check if the procedure we are going to assign to the procvar, is compatible with the procvar's type } if not(nf_explicit in flags) and (proc_to_procvar_equal(currprocdef, tprocvardef(resulttype.def),true)=te_incompatible) then IncompatibleTypes(left.resulttype.def,resulttype.def); exit; end; end; { Handle explicit type conversions } if nf_explicit in flags then begin { do common tc_equal cast } convtype:=tc_equal; { check if the result could be in a register } if (not(tstoreddef(resulttype.def).is_intregable) and not(tstoreddef(resulttype.def).is_fpuregable)) or ((left.resulttype.def.deftype = floatdef) and (resulttype.def.deftype <> floatdef)) then make_not_regable(left); { class to class or object to object, with checkobject support } if (resulttype.def.deftype=objectdef) and (left.resulttype.def.deftype=objectdef) then begin if (cs_check_object in aktlocalswitches) then begin if is_class_or_interface(resulttype.def) then begin { we can translate the typeconvnode to 'as' when typecasting to a class or interface } hp:=casnode.create(left,cloadvmtaddrnode.create(ctypenode.create(resulttype))); left:=nil; result:=hp; exit; end; end else begin { check if the types are related } if (not(tobjectdef(left.resulttype.def).is_related(tobjectdef(resulttype.def)))) and (not(tobjectdef(resulttype.def).is_related(tobjectdef(left.resulttype.def)))) then CGMessage2(type_w_classes_not_related,left.resulttype.def.typename,resulttype.def.typename); end; end else begin { only if the same size or formal def } if not( (left.resulttype.def.deftype=formaldef) or ( not(is_open_array(left.resulttype.def)) and (left.resulttype.def.size=resulttype.def.size) ) or ( is_void(left.resulttype.def) and (left.nodetype=derefn) ) ) then CGMessage2(cg_e_illegal_type_conversion,left.resulttype.def.gettypename,resulttype.def.gettypename); end; end else IncompatibleTypes(left.resulttype.def,resulttype.def); end; else internalerror(200211231); end; { Give hint for unportable code } if ((left.resulttype.def.deftype=orddef) and (resulttype.def.deftype in [pointerdef,procvardef,classrefdef])) or ((resulttype.def.deftype=orddef) and (left.resulttype.def.deftype in [pointerdef,procvardef,classrefdef])) then CGMessage(cg_h_pointer_to_longint_conv_not_portable); { Constant folding and other node transitions to remove the typeconv node } case left.nodetype of niln : begin { nil to ordinal node } if (resulttype.def.deftype=orddef) then begin hp:=cordconstnode.create(0,resulttype,true); result:=hp; exit; end else { fold nil to any pointer type } if (resulttype.def.deftype=pointerdef) then begin hp:=cnilnode.create; hp.resulttype:=resulttype; result:=hp; exit; end else { remove typeconv after niln, but not when the result is a methodpointer. The typeconv of the methodpointer will then take care of updateing size of niln to OS_64 } if not((resulttype.def.deftype=procvardef) and (po_methodpointer in tprocvardef(resulttype.def).procoptions)) then begin left.resulttype:=resulttype; result:=left; left:=nil; exit; end; end; ordconstn : begin { ordinal contants can be directly converted } { but not char to char because it is a widechar to char or via versa } { which needs extra code to do the code page transistion } if is_ordinal(resulttype.def) and not(convtype=tc_char_2_char) then begin { replace the resulttype and recheck the range } left.resulttype:=resulttype; testrange(left.resulttype.def,tordconstnode(left).value,(nf_explicit in flags)); result:=left; left:=nil; exit; end; end; pointerconstn : begin { pointerconstn to any pointer is folded too } if (resulttype.def.deftype=pointerdef) then begin left.resulttype:=resulttype; result:=left; left:=nil; exit; end { constant pointer to ordinal } else if is_ordinal(resulttype.def) then begin hp:=cordconstnode.create(tpointerconstnode(left).value, resulttype,true); result:=hp; exit; end; end; end; { now call the resulttype helper to do constant folding } result:=resulttype_call_helper(convtype); end; procedure Ttypeconvnode.mark_write; begin left.mark_write; end; function ttypeconvnode.first_cord_to_pointer : tnode; begin result:=nil; internalerror(200104043); end; function ttypeconvnode.first_int_to_int : tnode; begin first_int_to_int:=nil; if (left.expectloc<>LOC_REGISTER) and not is_void(left.resulttype.def) and (resulttype.def.size>left.resulttype.def.size) then expectloc:=LOC_REGISTER else expectloc:=left.expectloc; {$ifndef cpu64bit} if is_64bit(resulttype.def) then registersint:=max(registersint,2) else {$endif cpu64bit} registersint:=max(registersint,1); end; function ttypeconvnode.first_cstring_to_pchar : tnode; begin first_cstring_to_pchar:=nil; registersint:=1; expectloc:=LOC_REGISTER; end; function ttypeconvnode.first_string_to_chararray : tnode; begin first_string_to_chararray:=nil; expectloc:=left.expectloc; end; function ttypeconvnode.first_char_to_string : tnode; begin first_char_to_string:=nil; expectloc:=LOC_REFERENCE; end; function ttypeconvnode.first_nothing : tnode; begin first_nothing:=nil; end; function ttypeconvnode.first_array_to_pointer : tnode; begin first_array_to_pointer:=nil; if registersint<1 then registersint:=1; expectloc:=LOC_REGISTER; end; function ttypeconvnode.first_int_to_real: tnode; var fname: string[32]; typname : string[12]; begin { Get the type name } { Normally the typename should be one of the following: single, double - carl } typname := lower(pbestrealtype^.def.gettypename); { converting a 64bit integer to a float requires a helper } if is_64bit(left.resulttype.def) then begin if is_signed(left.resulttype.def) then fname := 'fpc_int64_to_'+typname else {$warning generic conversion from int to float does not support unsigned integers} fname := 'fpc_int64_to_'+typname; result := ccallnode.createintern(fname,ccallparanode.create( left,nil)); left:=nil; firstpass(result); exit; end else { other integers are supposed to be 32 bit } begin {$warning generic conversion from int to float does not support unsigned integers} if is_signed(left.resulttype.def) then fname := 'fpc_longint_to_'+typname else fname := 'fpc_longint_to_'+typname; result := ccallnode.createintern(fname,ccallparanode.create( left,nil)); left:=nil; firstpass(result); exit; end; end; function ttypeconvnode.first_real_to_real : tnode; begin first_real_to_real:=nil; { comp isn't a floating type } if registersfpu<1 then registersfpu:=1; expectloc:=LOC_FPUREGISTER; end; function ttypeconvnode.first_pointer_to_array : tnode; begin first_pointer_to_array:=nil; if registersint<1 then registersint:=1; expectloc:=LOC_REFERENCE; end; function ttypeconvnode.first_cchar_to_pchar : tnode; begin first_cchar_to_pchar:=nil; internalerror(200104021); end; function ttypeconvnode.first_bool_to_int : tnode; begin first_bool_to_int:=nil; { byte(boolean) or word(wordbool) or longint(longbool) must be accepted for var parameters } if (nf_explicit in flags) and (left.resulttype.def.size=resulttype.def.size) and (left.expectloc in [LOC_REFERENCE,LOC_CREFERENCE,LOC_CREGISTER]) then exit; { when converting to 64bit, first convert to a 32bit int and then } { convert to a 64bit int (only necessary for 32bit processors) (JM) } if resulttype.def.size > sizeof(aword) then begin result := ctypeconvnode.create_explicit(left,u32inttype); result := ctypeconvnode.create(result,resulttype); left := nil; firstpass(result); exit; end; expectloc:=LOC_REGISTER; if registersint<1 then registersint:=1; end; function ttypeconvnode.first_int_to_bool : tnode; begin first_int_to_bool:=nil; { byte(boolean) or word(wordbool) or longint(longbool) must be accepted for var parameters } if (nf_explicit in flags) and (left.resulttype.def.size=resulttype.def.size) and (left.expectloc in [LOC_REFERENCE,LOC_CREFERENCE,LOC_CREGISTER]) then exit; expectloc:=LOC_REGISTER; { need if bool to bool !! not very nice !! insertypeconv(left,s32inttype); left.explizit:=true; firstpass(left); } if registersint<1 then registersint:=1; end; function ttypeconvnode.first_bool_to_bool : tnode; begin first_bool_to_bool:=nil; expectloc:=LOC_REGISTER; if registersint<1 then registersint:=1; end; function ttypeconvnode.first_char_to_char : tnode; begin first_char_to_char:=first_int_to_int; end; function ttypeconvnode.first_proc_to_procvar : tnode; begin first_proc_to_procvar:=nil; if assigned(tunarynode(left).left) then begin if (left.expectloc<>LOC_CREFERENCE) then CGMessage(cg_e_illegal_expression); registersint:=left.registersint; expectloc:=left.expectloc end else begin registersint:=left.registersint; if registersint<1 then registersint:=1; expectloc:=LOC_REGISTER; end end; function ttypeconvnode.first_load_smallset : tnode; var srsym: ttypesym; p: tcallparanode; begin if not searchsystype('FPC_SMALL_SET',srsym) then internalerror(200108313); p := ccallparanode.create(left,nil); { reused } left := nil; { convert parameter explicitely to fpc_small_set } p.left := ctypeconvnode.create_explicit(p.left,srsym.restype); { create call, adjust resulttype } result := ccallnode.createinternres('fpc_set_load_small',p,resulttype); firstpass(result); end; function ttypeconvnode.first_ansistring_to_pchar : tnode; begin first_ansistring_to_pchar:=nil; expectloc:=LOC_REGISTER; if registersint<1 then registersint:=1; end; function ttypeconvnode.first_arrayconstructor_to_set : tnode; begin first_arrayconstructor_to_set:=nil; internalerror(200104022); end; function ttypeconvnode.first_class_to_intf : tnode; begin first_class_to_intf:=nil; expectloc:=LOC_REGISTER; if registersint<1 then registersint:=1; end; function ttypeconvnode._first_int_to_int : tnode; begin result:=first_int_to_int; end; function ttypeconvnode._first_cstring_to_pchar : tnode; begin result:=first_cstring_to_pchar; end; function ttypeconvnode._first_string_to_chararray : tnode; begin result:=first_string_to_chararray; end; function ttypeconvnode._first_char_to_string : tnode; begin result:=first_char_to_string; end; function ttypeconvnode._first_nothing : tnode; begin result:=first_nothing; end; function ttypeconvnode._first_array_to_pointer : tnode; begin result:=first_array_to_pointer; end; function ttypeconvnode._first_int_to_real : tnode; begin result:=first_int_to_real; end; function ttypeconvnode._first_real_to_real : tnode; begin result:=first_real_to_real; end; function ttypeconvnode._first_pointer_to_array : tnode; begin result:=first_pointer_to_array; end; function ttypeconvnode._first_cchar_to_pchar : tnode; begin result:=first_cchar_to_pchar; end; function ttypeconvnode._first_bool_to_int : tnode; begin result:=first_bool_to_int; end; function ttypeconvnode._first_int_to_bool : tnode; begin result:=first_int_to_bool; end; function ttypeconvnode._first_bool_to_bool : tnode; begin result:=first_bool_to_bool; end; function ttypeconvnode._first_proc_to_procvar : tnode; begin result:=first_proc_to_procvar; end; function ttypeconvnode._first_load_smallset : tnode; begin result:=first_load_smallset; end; function ttypeconvnode._first_cord_to_pointer : tnode; begin result:=first_cord_to_pointer; end; function ttypeconvnode._first_ansistring_to_pchar : tnode; begin result:=first_ansistring_to_pchar; end; function ttypeconvnode._first_arrayconstructor_to_set : tnode; begin result:=first_arrayconstructor_to_set; end; function ttypeconvnode._first_class_to_intf : tnode; begin result:=first_class_to_intf; end; function ttypeconvnode._first_char_to_char : tnode; begin result:=first_char_to_char; end; function ttypeconvnode.first_call_helper(c : tconverttype) : tnode; const firstconvert : array[tconverttype] of pointer = ( @ttypeconvnode._first_nothing, {equal} @ttypeconvnode._first_nothing, {not_possible} nil, { removed in resulttype_string_to_string } @ttypeconvnode._first_char_to_string, @ttypeconvnode._first_nothing, { char_2_chararray, needs nothing extra } nil, { removed in resulttype_chararray_to_string } @ttypeconvnode._first_cchar_to_pchar, @ttypeconvnode._first_cstring_to_pchar, @ttypeconvnode._first_ansistring_to_pchar, @ttypeconvnode._first_string_to_chararray, nil, { removed in resulttype_chararray_to_string } @ttypeconvnode._first_array_to_pointer, @ttypeconvnode._first_pointer_to_array, @ttypeconvnode._first_int_to_int, @ttypeconvnode._first_int_to_bool, @ttypeconvnode._first_bool_to_bool, @ttypeconvnode._first_bool_to_int, @ttypeconvnode._first_real_to_real, @ttypeconvnode._first_int_to_real, nil, { removed in resulttype_real_to_currency } @ttypeconvnode._first_proc_to_procvar, @ttypeconvnode._first_arrayconstructor_to_set, @ttypeconvnode._first_load_smallset, @ttypeconvnode._first_cord_to_pointer, @ttypeconvnode._first_nothing, @ttypeconvnode._first_nothing, @ttypeconvnode._first_class_to_intf, @ttypeconvnode._first_char_to_char, @ttypeconvnode._first_nothing, @ttypeconvnode._first_nothing, nil, nil, nil, nil, nil ); type tprocedureofobject = function : tnode of object; var r : packed record proc : pointer; obj : pointer; end; begin { this is a little bit dirty but it works } { and should be quite portable too } r.proc:=firstconvert[c]; r.obj:=self; if not assigned(r.proc) then internalerror(200312081); first_call_helper:=tprocedureofobject(r){$ifdef FPC}(){$endif FPC} end; function ttypeconvnode.pass_1 : tnode; begin result:=nil; firstpass(left); if codegenerror then exit; { load the value_str from the left part } registersint:=left.registersint; registersfpu:=left.registersfpu; {$ifdef SUPPORT_MMX} registersmmx:=left.registersmmx; {$endif} expectloc:=left.expectloc; if (nf_explicit in flags) or (nf_absolute in flags) then begin { check if the result could be in a register } if not(tstoreddef(resulttype.def).is_intregable) and not(tstoreddef(resulttype.def).is_fpuregable) then make_not_regable(left); end; result:=first_call_helper(convtype); end; function ttypeconvnode.docompare(p: tnode) : boolean; begin docompare := inherited docompare(p) and (convtype = ttypeconvnode(p).convtype); end; procedure ttypeconvnode._second_int_to_int; begin second_int_to_int; end; procedure ttypeconvnode._second_string_to_string; begin second_string_to_string; end; procedure ttypeconvnode._second_cstring_to_pchar; begin second_cstring_to_pchar; end; procedure ttypeconvnode._second_string_to_chararray; begin second_string_to_chararray; end; procedure ttypeconvnode._second_array_to_pointer; begin second_array_to_pointer; end; procedure ttypeconvnode._second_pointer_to_array; begin second_pointer_to_array; end; procedure ttypeconvnode._second_chararray_to_string; begin second_chararray_to_string; end; procedure ttypeconvnode._second_char_to_string; begin second_char_to_string; end; procedure ttypeconvnode._second_int_to_real; begin second_int_to_real; end; procedure ttypeconvnode._second_real_to_real; begin second_real_to_real; end; procedure ttypeconvnode._second_cord_to_pointer; begin second_cord_to_pointer; end; procedure ttypeconvnode._second_proc_to_procvar; begin second_proc_to_procvar; end; procedure ttypeconvnode._second_bool_to_int; begin second_bool_to_int; end; procedure ttypeconvnode._second_int_to_bool; begin second_int_to_bool; end; procedure ttypeconvnode._second_bool_to_bool; begin second_bool_to_bool; end; procedure ttypeconvnode._second_load_smallset; begin second_load_smallset; end; procedure ttypeconvnode._second_ansistring_to_pchar; begin second_ansistring_to_pchar; end; procedure ttypeconvnode._second_class_to_intf; begin second_class_to_intf; end; procedure ttypeconvnode._second_char_to_char; begin second_char_to_char; end; procedure ttypeconvnode._second_nothing; begin second_nothing; end; procedure ttypeconvnode.second_call_helper(c : tconverttype); {$ifdef fpc} const secondconvert : array[tconverttype] of pointer = ( @_second_nothing, {equal} @_second_nothing, {not_possible} @_second_nothing, {second_string_to_string, handled in resulttype pass } @_second_char_to_string, @_second_nothing, {char_to_charray} @_second_nothing, { pchar_to_string, handled in resulttype pass } @_second_nothing, {cchar_to_pchar} @_second_cstring_to_pchar, @_second_ansistring_to_pchar, @_second_string_to_chararray, @_second_nothing, { chararray_to_string, handled in resulttype pass } @_second_array_to_pointer, @_second_pointer_to_array, @_second_int_to_int, @_second_int_to_bool, @_second_bool_to_bool, @_second_bool_to_int, @_second_real_to_real, @_second_int_to_real, @_second_nothing, { real_to_currency, handled in resulttype pass } @_second_proc_to_procvar, @_second_nothing, { arrayconstructor_to_set } @_second_nothing, { second_load_smallset, handled in first pass } @_second_cord_to_pointer, @_second_nothing, { interface 2 string } @_second_nothing, { interface 2 guid } @_second_class_to_intf, @_second_char_to_char, @_second_nothing, { normal_2_smallset } @_second_nothing, { dynarray_2_openarray } @_second_nothing, { pwchar_2_string } @_second_nothing, { variant_2_dynarray } @_second_nothing, { dynarray_2_variant} @_second_nothing, { variant_2_enum } @_second_nothing { enum_2_variant } ); type tprocedureofobject = procedure of object; var r : packed record proc : pointer; obj : pointer; end; begin { this is a little bit dirty but it works } { and should be quite portable too } r.proc:=secondconvert[c]; r.obj:=self; tprocedureofobject(r)(); end; {$else fpc} begin case c of tc_equal, tc_not_possible, tc_string_2_string : second_nothing; tc_char_2_string : second_char_to_string; tc_char_2_chararray : second_nothing; tc_pchar_2_string : second_nothing; tc_cchar_2_pchar : second_nothing; tc_cstring_2_pchar : second_cstring_to_pchar; tc_ansistring_2_pchar : second_ansistring_to_pchar; tc_string_2_chararray : second_string_to_chararray; tc_chararray_2_string : second_nothing; tc_array_2_pointer : second_array_to_pointer; tc_pointer_2_array : second_pointer_to_array; tc_int_2_int : second_int_to_int; tc_int_2_bool : second_int_to_bool; tc_bool_2_bool : second_bool_to_bool; tc_bool_2_int : second_bool_to_int; tc_real_2_real : second_real_to_real; tc_int_2_real : second_int_to_real; tc_real_2_currency : second_nothing; tc_proc_2_procvar : second_proc_to_procvar; tc_arrayconstructor_2_set : second_nothing; tc_load_smallset : second_nothing; tc_cord_2_pointer : second_cord_to_pointer; tc_intf_2_string : second_nothing; tc_intf_2_guid : second_nothing; tc_class_2_intf : second_class_to_intf; tc_char_2_char : second_char_to_char; tc_normal_2_smallset : second_nothing; tc_dynarray_2_openarray : second_nothing; tc_pwchar_2_string : second_nothing; tc_variant_2_dynarray : second_nothing; tc_dynarray_2_variant : second_nothing; else internalerror(2002101101); end; end; {$endif fpc} {***************************************************************************** TISNODE *****************************************************************************} constructor tisnode.create(l,r : tnode); begin inherited create(isn,l,r); end; function tisnode.det_resulttype:tnode; var paras: tcallparanode; begin result:=nil; resulttypepass(left); resulttypepass(right); set_varstate(left,vs_used,true); set_varstate(right,vs_used,true); if codegenerror then exit; if (right.resulttype.def.deftype=classrefdef) then begin { left must be a class } if is_class(left.resulttype.def) then begin { the operands must be related } if (not(tobjectdef(left.resulttype.def).is_related( tobjectdef(tclassrefdef(right.resulttype.def).pointertype.def)))) and (not(tobjectdef(tclassrefdef(right.resulttype.def).pointertype.def).is_related( tobjectdef(left.resulttype.def)))) then CGMessage2(type_e_classes_not_related,left.resulttype.def.typename, tclassrefdef(right.resulttype.def).pointertype.def.typename); end else CGMessage1(type_e_class_type_expected,left.resulttype.def.typename); { call fpc_do_is helper } paras := ccallparanode.create( left, ccallparanode.create( right,nil)); result := ccallnode.createintern('fpc_do_is',paras); left := nil; right := nil; end else if is_interface(right.resulttype.def) then begin { left is a class } if is_class(left.resulttype.def) then begin { the operands must be related } if not(assigned(tobjectdef(left.resulttype.def).implementedinterfaces) and (tobjectdef(left.resulttype.def).implementedinterfaces.searchintf(right.resulttype.def)<>-1)) then CGMessage2(type_e_classes_not_related,left.resulttype.def.typename,right.resulttype.def.typename); end { left is an interface } else if is_interface(left.resulttype.def) then begin { the operands must be related } if (not(tobjectdef(left.resulttype.def).is_related(tobjectdef(right.resulttype.def)))) and (not(tobjectdef(right.resulttype.def).is_related(tobjectdef(left.resulttype.def)))) then CGMessage(type_e_mismatch); end else CGMessage1(type_e_class_type_expected,left.resulttype.def.typename); { call fpc_do_is helper } paras := ccallparanode.create( left, ccallparanode.create( right,nil)); result := ccallnode.createintern('fpc_do_is',paras); left := nil; right := nil; end else CGMessage1(type_e_class_or_interface_type_expected,right.resulttype.def.typename); resulttype:=booltype; end; function tisnode.pass_1 : tnode; begin internalerror(200204254); result:=nil; end; { dummy pass_2, it will never be called, but we need one since } { you can't instantiate an abstract class } procedure tisnode.pass_2; begin end; {***************************************************************************** TASNODE *****************************************************************************} constructor tasnode.create(l,r : tnode); begin inherited create(asn,l,r); call := nil; end; destructor tasnode.destroy; begin call.free; inherited destroy; end; function tasnode.det_resulttype:tnode; var hp : tnode; begin result:=nil; resulttypepass(right); resulttypepass(left); set_varstate(right,vs_used,true); set_varstate(left,vs_used,true); if codegenerror then exit; if (right.resulttype.def.deftype=classrefdef) then begin { left must be a class } if is_class(left.resulttype.def) then begin { the operands must be related } if (not(tobjectdef(left.resulttype.def).is_related( tobjectdef(tclassrefdef(right.resulttype.def).pointertype.def)))) and (not(tobjectdef(tclassrefdef(right.resulttype.def).pointertype.def).is_related( tobjectdef(left.resulttype.def)))) then CGMessage2(type_e_classes_not_related,left.resulttype.def.typename, tclassrefdef(right.resulttype.def).pointertype.def.typename); end else CGMessage1(type_e_class_type_expected,left.resulttype.def.typename); resulttype:=tclassrefdef(right.resulttype.def).pointertype; end else if is_interface(right.resulttype.def) then begin { left is a class } if is_class(left.resulttype.def) then begin { the operands must be related no, because the class instance could be a child class of the current one which implements additional interfaces (FK) b:=false; o:=tobjectdef(left.resulttype.def); while assigned(o) do begin if assigned(o.implementedinterfaces) and (o.implementedinterfaces.searchintf(right.resulttype.def)<>-1) then begin b:=true; break; end; o:=o.childof; end; if not(b) then CGMessage2(type_e_classes_not_related,left.resulttype.def.typename,right.resulttype.def.typename); } end { left is an interface } else if is_interface(left.resulttype.def) then begin { the operands must be related we don't necessarily know how the both interfaces are implemented, so we can't do this check (FK) if (not(tobjectdef(left.resulttype.def).is_related(tobjectdef(right.resulttype.def)))) and (not(tobjectdef(right.resulttype.def).is_related(tobjectdef(left.resulttype.def)))) then CGMessage2(type_e_classes_not_related,left.resulttype.def.typename,right.resulttype.def.typename); } end else CGMessage1(type_e_class_type_expected,left.resulttype.def.typename); resulttype:=right.resulttype; { load the GUID of the interface } if (right.nodetype=typen) then begin if assigned(tobjectdef(right.resulttype.def).iidguid) then begin hp:=cguidconstnode.create(tobjectdef(right.resulttype.def).iidguid^); right.free; right:=hp; end else internalerror(200206282); resulttypepass(right); end; end else CGMessage1(type_e_class_or_interface_type_expected,right.resulttype.def.typename); end; function tasnode.getcopy: tnode; begin result := inherited getcopy; if assigned(call) then tasnode(result).call := call.getcopy else tasnode(result).call := nil; end; function tasnode.pass_1 : tnode; var procname: string; begin result:=nil; if not assigned(call) then begin if is_class(left.resulttype.def) and (right.resulttype.def.deftype=classrefdef) then call := ccallnode.createinternres('fpc_do_as', ccallparanode.create(left,ccallparanode.create(right,nil)), resulttype) else begin if is_class(left.resulttype.def) then procname := 'fpc_class_as_intf' else procname := 'fpc_intf_as'; call := ccallnode.createinternres(procname, ccallparanode.create(right,ccallparanode.create(left,nil)), resulttype); end; left := nil; right := nil; firstpass(call); if codegenerror then exit; expectloc:=call.expectloc; registersint:=call.registersint; registersfpu:=call.registersfpu; {$ifdef SUPPORT_MMX} registersmmx:=call.registersmmx; {$endif SUPPORT_MMX} end; end; begin ctypeconvnode:=ttypeconvnode; casnode:=tasnode; cisnode:=tisnode; end. { $Log$ Revision 1.141 2004-02-21 16:03:10 florian * message about illegal type conversion reports now the types Revision 1.140 2004/02/20 21:55:59 peter * procvar cleanup Revision 1.139 2004/02/13 15:42:21 peter * compare_defs_ext has now a options argument * fixes for variants Revision 1.138 2004/02/05 01:24:08 florian * several fixes to compile x86-64 system Revision 1.137 2004/02/04 22:15:15 daniel * Rtti generation moved to ncgutil * Assmtai usage of symsym removed * operator overloading cleanup up Revision 1.136 2004/02/03 22:32:54 peter * renamed xNNbittype to xNNinttype * renamed registers32 to registersint * replace some s32bit,u32bit with torddef([su]inttype).def.typ Revision 1.135 2004/01/26 16:12:27 daniel * reginfo now also only allocated during register allocation * third round of gdb cleanups: kick out most of concatstabto Revision 1.134 2003/12/26 00:32:21 florian + fpu<->mm register conversion Revision 1.133 2003/12/22 23:11:15 peter * fix rangecheck error Revision 1.132 2003/12/08 22:35:28 peter * again procvar fixes Revision 1.131 2003/11/22 00:31:52 jonas * fixed range error Revision 1.130 2003/11/04 22:30:15 florian + type cast variant<->enum * cnv. node second pass uses now as well helper wrappers Revision 1.129 2003/10/31 18:42:03 peter * don't call proc_to_procvar for explicit typecasts Revision 1.128 2003/10/29 22:01:20 florian * fixed passing of dyn. arrays to open array parameters Revision 1.127 2003/10/28 15:36:01 peter * absolute to object field supported, fixes tb0458 Revision 1.126 2003/10/23 14:44:07 peter * splitted buildderef and buildderefimpl to fix interface crc calculation Revision 1.125 2003/10/22 20:40:00 peter * write derefdata in a separate ppu entry Revision 1.124 2003/10/21 18:16:13 peter * IncompatibleTypes() added that will include unit names when the typenames are the same Revision 1.123 2003/10/09 14:39:03 peter * allow explicit typecasts from classrefdef, fixes 2728 Revision 1.122 2003/10/08 19:19:45 peter * set_varstate cleanup Revision 1.121 2003/10/07 14:30:27 peter * fix 2720 Revision 1.120 2003/10/01 20:34:48 peter * procinfo unit contains tprocinfo * cginfo renamed to cgbase * moved cgmessage to verbose * fixed ppc and sparc compiles Revision 1.119 2003/09/25 14:57:51 peter * fix different expectloc Revision 1.118 2003/09/06 22:27:08 florian * fixed web bug 2669 * cosmetic fix in printnode * tobjectdef.gettypename implemented Revision 1.117 2003/09/03 15:55:01 peter * NEWRA branch merged Revision 1.116 2003/08/10 17:25:23 peter * fixed some reported bugs Revision 1.115 2003/06/05 20:05:55 peter * removed changesettype because that will change the definition of the setdef forever and can result in a different between original interface and current implementation definition Revision 1.114 2003/06/04 17:55:09 jonas * disable fpuregable for fpu variables typecasted to non fpu-type Revision 1.113 2003/06/04 17:29:01 jonas * fixed void_to_(int,pointer) typeconversion Revision 1.112 2003/06/03 21:05:48 peter * fix check for procedure without parameters * calling constructor as member will not allocate memory Revision 1.111 2003/05/11 21:37:03 peter * moved implicit exception frame from ncgutil to psub * constructor/destructor helpers moved from cobj/ncgutil to psub Revision 1.110 2003/05/09 17:47:02 peter * self moved to hidden parameter * removed hdisposen,hnewn,selfn Revision 1.109 2003/04/27 11:21:33 peter * aktprocdef renamed to current_procdef * procinfo renamed to current_procinfo * procinfo will now be stored in current_module so it can be cleaned up properly * gen_main_procsym changed to create_main_proc and release_main_proc to also generate a tprocinfo structure * fixed unit implicit initfinal Revision 1.108 2003/04/23 20:16:04 peter + added currency support based on int64 + is_64bit for use in cg units instead of is_64bitint * removed cgmessage from n386add, replace with internalerrors Revision 1.107 2003/04/23 13:13:08 peter * fix checking of procdef type which was broken since loadn returned pointertype for tp procvar Revision 1.106 2003/04/23 10:10:07 peter * expectloc fixes Revision 1.105 2003/04/22 23:50:23 peter * firstpass uses expectloc * checks if there are differences between the expectloc and location.loc from secondpass in EXTDEBUG Revision 1.104 2003/04/22 09:52:30 peter * do not convert procvars with void return to callnode Revision 1.103 2003/03/17 18:54:23 peter * fix missing self setting for method to procvar conversion in tp_procvar mode Revision 1.102 2003/02/15 22:15:57 carl * generic conversaion routines only work on signed types Revision 1.101 2003/01/16 22:13:52 peter * convert_l3 convertlevel added. This level is used for conversions where information can be lost like converting widestring->ansistring or dword->byte Revision 1.100 2003/01/15 01:44:32 peter * merged methodpointer fixes from 1.0.x Revision 1.99 2003/01/09 21:43:39 peter * constant string conversion fixed, it's now equal to both shortstring, ansistring and the typeconvnode will return te_equal but still return convtype to change the constnode Revision 1.98 2003/01/05 22:41:40 peter * move code that checks for longint-pointer conversion hint Revision 1.97 2003/01/03 12:15:56 daniel * Removed ifdefs around notifications ifdefs around for loop optimizations remain Revision 1.96 2002/12/22 16:34:49 peter * proc-procvar crash fixed (tw2277) Revision 1.95 2002/12/20 16:01:26 peter * don't allow class(classref) conversion Revision 1.94 2002/12/05 14:27:26 florian * some variant <-> dyn. array stuff Revision 1.93 2002/11/30 10:45:14 carl * fix bug with checking of duplicated items in sets (new sets bug only) Revision 1.92 2002/11/27 19:43:21 carl * updated notes and hints Revision 1.91 2002/11/27 13:11:38 peter * more currency fixes, taddcurr runs now successfull Revision 1.90 2002/11/27 11:29:21 peter * when converting from and to currency divide or multiple the result by 10000 Revision 1.89 2002/11/25 17:43:18 peter * splitted defbase in defutil,symutil,defcmp * merged isconvertable and is_equal into compare_defs(_ext) * made operator search faster by walking the list only once Revision 1.88 2002/11/17 16:31:56 carl * memory optimization (3-4%) : cleanup of tai fields, cleanup of tdef and tsym fields. * make it work for m68k Revision 1.87 2002/10/10 16:07:57 florian + several widestring/pwidechar related stuff added Revision 1.86 2002/10/06 16:10:23 florian * when compiling as we can't assume anything about relation Revision 1.85 2002/10/05 12:43:25 carl * fixes for Delphi 6 compilation (warning : Some features do not work under Delphi) Revision 1.84 2002/10/02 20:23:50 florian - removed the relation check for as because we don't know the runtime type of ! It could be a child class of the given type which implements additional interfaces Revision 1.83 2002/10/02 20:17:14 florian + the as operator for as has to check the parent classes as well Revision 1.82 2002/09/30 07:00:47 florian * fixes to common code to get the alpha compiler compiled applied Revision 1.81 2002/09/16 14:11:13 peter * add argument to equal_paras() to support default values or not Revision 1.80 2002/09/07 20:40:23 carl * cardinal -> longword Revision 1.79 2002/09/07 15:25:03 peter * old logs removed and tabs fixed Revision 1.78 2002/09/07 12:16:04 carl * second part bug report 1996 fix, testrange in cordconstnode only called if option is set (also make parsing a tiny faster) Revision 1.77 2002/09/05 05:56:07 jonas - reverted my last commit, it was completely bogus :( Revision 1.75 2002/09/02 19:24:42 peter * array of char support for Str() Revision 1.74 2002/09/01 08:01:16 daniel * Removed sets from Tcallnode.det_resulttype + Added read/write notifications of variables. These will be usefull for providing information for several optimizations. For example the value of the loop variable of a for loop does matter is the variable is read after the for loop, but if it's no longer used or written, it doesn't matter and this can be used to optimize the loop code generation. Revision 1.73 2002/08/23 16:14:49 peter * tempgen cleanup * tt_noreuse temp type added that will be used in genentrycode Revision 1.72 2002/08/20 18:23:33 jonas * the as node again uses a compilerproc + (untested) support for interface "as" statements Revision 1.71 2002/08/19 19:36:43 peter * More fixes for cross unit inlining, all tnodes are now implemented * Moved pocall_internconst to po_internconst because it is not a calling type at all and it conflicted when inlining of these small functions was requested Revision 1.70 2002/08/17 09:23:36 florian * first part of current_procinfo rewrite Revision 1.69 2002/08/14 19:26:55 carl + generic int_to_real type conversion + generic unaryminus node Revision 1.68 2002/08/11 16:08:55 florian + support of explicit type case boolean->char Revision 1.67 2002/08/11 15:28:00 florian + support of explicit type case ->pointer (delphi mode only) Revision 1.66 2002/08/09 07:33:01 florian * a couple of interface related fixes Revision 1.65 2002/07/29 21:23:42 florian * more fixes for the ppc + wrappers for the tcnvnode.first_* stuff introduced Revision 1.64 2002/07/23 12:34:30 daniel * Readded old set code. To use it define 'oldset'. Activated by default for ppc. Revision 1.63 2002/07/23 09:51:22 daniel * Tried to make Tprocsym.defs protected. I didn't succeed but the cleanups are worth comitting. Revision 1.62 2002/07/22 11:48:04 daniel * Sets are now internally sets. Revision 1.61 2002/07/20 17:16:02 florian + source code page support Revision 1.60 2002/07/20 11:57:54 florian * types.pas renamed to defbase.pas because D6 contains a types unit so this would conflicts if D6 programms are compiled + Willamette/SSE2 instructions to assembler added Revision 1.59 2002/07/01 16:23:53 peter * cg64 patch * basics for currency * asnode updates for class and interface (not finished) Revision 1.58 2002/05/18 13:34:09 peter * readded missing revisions }