{ $Id$ Copyright (c) 2000 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 defines.inc} interface uses node, symtype,types, nld; type ttypeconvnode = class(tunarynode) convtype : tconverttype; constructor create(node : tnode;t : pdef);virtual; function getcopy : tnode;override; function pass_1 : tnode;override; function first_int_to_int : tnode;virtual; function first_cstring_to_pchar : tnode;virtual; function first_string_to_chararray : tnode;virtual; function first_string_to_string : 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_int_to_fix : tnode;virtual; function first_real_to_fix : tnode;virtual; function first_fix_to_real : tnode;virtual; function first_real_to_real : tnode;virtual; function first_pointer_to_array : tnode;virtual; function first_chararray_to_string : 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_pchar_to_string : 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_call_helper(c : tconverttype) : tnode; end; tasnode = class(tbinarynode) constructor create(l,r : tnode);virtual; function pass_1 : tnode;override; end; tisnode = class(tbinarynode) constructor create(l,r : tnode);virtual; function pass_1 : tnode;override; end; var ctypeconvnode : class of ttypeconvnode; casnode : class of tasnode; cisnode : class of tisnode; function gentypeconvnode(node : tnode;t : pdef) : ttypeconvnode; procedure arrayconstructor_to_set(var p : tarrayconstructornode); implementation uses globtype,systems,tokens, cutils,cobjects,verbose,globals, symconst,symdef,symsym,symtable,aasm, ncon,ncal,nset,nadd, {$ifdef newcg} cgbase, {$else newcg} hcodegen, {$endif newcg} htypechk,pass_1,cpubase; function gentypeconvnode(node : tnode;t : pdef) : ttypeconvnode; begin gentypeconvnode:=ctypeconvnode.create(node,t); end; {***************************************************************************** Array constructor to Set Conversion *****************************************************************************} procedure arrayconstructor_to_set(var p : tarrayconstructornode); var constp : tsetconstnode; buildp, p2,p3,p4 : tnode; pd : pdef; constset : pconstset; constsetlo, constsethi : longint; procedure update_constsethi(p:pdef); begin if ((p^.deftype=orddef) and (porddef(p)^.high>=constsethi)) then begin constsethi:=porddef(p)^.high; if pd=nil then begin if (constsethi>255) or (porddef(p)^.low<0) then pd:=u8bitdef else pd:=p; end; if constsethi>255 then constsethi:=255; end else if ((p^.deftype=enumdef) and (penumdef(p)^.max>=constsethi)) then begin if pd=nil then pd:=p; constsethi:=penumdef(p)^.max; end; end; procedure do_set(pos : longint); var mask,l : longint; begin if (pos>255) or (pos<0) then Message(parser_e_illegal_set_expr); if pos>constsethi then constsethi:=pos; if pos0 then Message(parser_e_illegal_set_expr); constset^[l]:=constset^[l] or mask; end; var l : longint; lr,hr : longint; begin new(constset); FillChar(constset^,sizeof(constset^),0); pd:=nil; constsetlo:=0; constsethi:=0; constp:=csetconstnode.create(nil,nil); constp.value_set:=constset; buildp:=constp; if assigned(p.left) then begin while assigned(p) do begin p4:=nil; { will contain the tree to create the set } {split a range into p2 and p3 } if p.left.nodetype=arrayconstructorrangen then begin p2:=tarrayconstructorrangenode(p.left).left; p3:=tarrayconstructorrangenode(p.left).right; tarrayconstructorrangenode(p.left).left:=nil; tarrayconstructorrangenode(p.left).right:=nil; end else begin p2:=p.left; p.left:=nil; p3:=nil; end; firstpass(p2); if assigned(p3) then firstpass(p3); if codegenerror then break; case p2.resulttype^.deftype of enumdef, orddef: begin getrange(p2.resulttype,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) then begin p3:=gentypeconvnode(p3,u8bitdef); firstpass(p3); end; } if assigned(pd) and not(is_equal(pd,p3.resulttype)) 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)) then pd:=p3.resulttype else begin p3:=gentypeconvnode(p3,u8bitdef); p2:=gentypeconvnode(p2,u8bitdef); firstpass(p2); firstpass(p3); 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); p2:=gentypeconvnode(p2,pd); firstpass(p2); update_constsethi(p3.resulttype); p3:=gentypeconvnode(p3,pd); firstpass(p3); if assigned(pd) then p3:=gentypeconvnode(p3,pd) else p3:=gentypeconvnode(p3,u8bitdef); firstpass(p3); p4:=csetelementnode.create(p2,p3); end; end; end else begin { Single value } if p2.nodetype=ordconstn then begin if not(is_integer(p2.resulttype)) then update_constsethi(p2.resulttype) else begin p2:=gentypeconvnode(p2,u8bitdef); firstpass(p2); end; do_set(tordconstnode(p2).value); p2.free; end else begin update_constsethi(p2.resulttype); if assigned(pd) then p2:=gentypeconvnode(p2,pd) else p2:=gentypeconvnode(p2,u8bitdef); firstpass(p2); p4:=csetelementnode.create(p2,nil); end; end; end; stringdef : begin { if we've already set elements which are constants } { throw an error } if ((pd=nil) and assigned(buildp)) or not(is_equal(pd,cchardef)) 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 pd=nil then pd:=cchardef; 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:=p; p:=tarrayconstructornode(tarrayconstructornode(p2).right); tarrayconstructornode(p2).right:=nil; p2.free; end; if (pd=nil) then begin pd:=u8bitdef; constsethi:=255; end; end else begin { empty set [], only remove node } p.free; end; { set the initial set type } constp.resulttype:=new(psetdef,init(pd,constsethi)); { set the new tree } p:=tarrayconstructornode(buildp); end; {***************************************************************************** TTYPECONVNODE *****************************************************************************} constructor ttypeconvnode.create(node : tnode;t : pdef); begin inherited create(typeconvn,node); convtype:=tc_not_possible; resulttype:=t; set_file_line(node); end; function ttypeconvnode.getcopy : tnode; var n : ttypeconvnode; begin n:=ttypeconvnode(inherited getcopy); n.convtype:=convtype; getcopy:=n; end; function ttypeconvnode.first_int_to_int : tnode; begin first_int_to_int:=nil; if (left.location.loc<>LOC_REGISTER) and (resulttype^.size>left.resulttype^.size) then location.loc:=LOC_REGISTER; if is_64bitint(resulttype) then registers32:=max(registers32,2) else registers32:=max(registers32,1); end; function ttypeconvnode.first_cstring_to_pchar : tnode; begin first_cstring_to_pchar:=nil; registers32:=1; location.loc:=LOC_REGISTER; end; function ttypeconvnode.first_string_to_chararray : tnode; begin first_string_to_chararray:=nil; registers32:=1; location.loc:=LOC_REGISTER; end; function ttypeconvnode.first_string_to_string : tnode; begin first_string_to_string:=nil; if pstringdef(resulttype)^.string_typ<> pstringdef(left.resulttype)^.string_typ then begin if left.nodetype=stringconstn then begin tstringconstnode(left).stringtype:=pstringdef(resulttype)^.string_typ; tstringconstnode(left).resulttype:=resulttype; { remove typeconv node } first_string_to_string:=left; left:=nil; exit; end else procinfo^.flags:=procinfo^.flags or pi_do_call; end; { for simplicity lets first keep all ansistrings as LOC_MEM, could also become LOC_REGISTER } if pstringdef(resulttype)^.string_typ in [st_ansistring,st_widestring] then { we may use ansistrings so no fast exit here } procinfo^.no_fast_exit:=true; location.loc:=LOC_MEM; end; function ttypeconvnode.first_char_to_string : tnode; var hp : tstringconstnode; begin first_char_to_string:=nil; if left.nodetype=ordconstn then begin hp:=genstringconstnode(chr(tordconstnode(left).value),st_default); hp.stringtype:=pstringdef(resulttype)^.string_typ; firstpass(hp); first_char_to_string:=hp; end else location.loc:=LOC_MEM; end; function ttypeconvnode.first_nothing : tnode; begin first_nothing:=nil; location.loc:=LOC_MEM; end; function ttypeconvnode.first_array_to_pointer : tnode; begin first_array_to_pointer:=nil; if registers32<1 then registers32:=1; location.loc:=LOC_REGISTER; end; function ttypeconvnode.first_int_to_real : tnode; var t : trealconstnode; begin first_int_to_real:=nil; if left.nodetype=ordconstn then begin t:=genrealconstnode(tordconstnode(left).value,pfloatdef(resulttype)); firstpass(t); first_int_to_real:=t; exit; end; if registersfpu<1 then registersfpu:=1; location.loc:=LOC_FPU; end; function ttypeconvnode.first_int_to_fix : tnode; var t : tnode; begin first_int_to_fix:=nil; if left.nodetype=ordconstn then begin t:=genfixconstnode(tordconstnode(left).value shl 16,resulttype); firstpass(t); first_int_to_fix:=t; exit; end; if registers32<1 then registers32:=1; location.loc:=LOC_REGISTER; end; function ttypeconvnode.first_real_to_fix : tnode; var t : tnode; begin first_real_to_fix:=nil; if left.nodetype=realconstn then begin t:=genfixconstnode(round(trealconstnode(left).value_real*65536),resulttype); firstpass(t); first_real_to_fix:=t; exit; end; { at least one fpu and int register needed } if registers32<1 then registers32:=1; if registersfpu<1 then registersfpu:=1; location.loc:=LOC_REGISTER; end; function ttypeconvnode.first_fix_to_real : tnode; var t : tnode; begin first_fix_to_real:=nil; if left.nodetype=fixconstn then begin t:=genrealconstnode(round(tfixconstnode(left).value_fix/65536.0),resulttype); firstpass(t); first_fix_to_real:=t; exit; end; if registersfpu<1 then registersfpu:=1; location.loc:=LOC_FPU; end; function ttypeconvnode.first_real_to_real : tnode; var t : tnode; begin first_real_to_real:=nil; if left.nodetype=realconstn then begin t:=genrealconstnode(trealconstnode(left).value_real,resulttype); firstpass(t); first_real_to_real:=t; exit; end; { comp isn't a floating type } {$ifdef i386} if (pfloatdef(resulttype)^.typ=s64comp) and (pfloatdef(left.resulttype)^.typ<>s64comp) and not (nf_explizit in flags) then CGMessage(type_w_convert_real_2_comp); {$endif} if registersfpu<1 then registersfpu:=1; location.loc:=LOC_FPU; end; function ttypeconvnode.first_pointer_to_array : tnode; begin first_pointer_to_array:=nil; if registers32<1 then registers32:=1; location.loc:=LOC_REFERENCE; end; function ttypeconvnode.first_chararray_to_string : tnode; begin first_chararray_to_string:=nil; { the only important information is the location of the } { result } { other stuff is done by firsttypeconv } location.loc:=LOC_MEM; end; function ttypeconvnode.first_cchar_to_pchar : tnode; begin first_cchar_to_pchar:=nil; left:=gentypeconvnode(left,cshortstringdef); { convert constant char to constant string } firstpass(left); { evalute tree } first_cchar_to_pchar:=pass_1; 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_explizit in flags) and (left.resulttype^.size=resulttype^.size) and (left.location.loc in [LOC_REFERENCE,LOC_MEM,LOC_CREGISTER]) then exit; location.loc:=LOC_REGISTER; if registers32<1 then registers32:=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_explizit in flags) and (left.resulttype^.size=resulttype^.size) and (left.location.loc in [LOC_REFERENCE,LOC_MEM,LOC_CREGISTER]) then exit; location.loc:=LOC_REGISTER; { need if bool to bool !! not very nice !! left:=gentypeconvnode(left,s32bitdef); left.explizit:=true; firstpass(left); } if registers32<1 then registers32:=1; end; function ttypeconvnode.first_bool_to_bool : tnode; begin first_bool_to_bool:=nil; location.loc:=LOC_REGISTER; if registers32<1 then registers32:=1; end; function ttypeconvnode.first_proc_to_procvar : tnode; begin first_proc_to_procvar:=nil; { hmmm, I'am not sure if that is necessary (FK) } firstpass(left); if codegenerror then exit; if (left.location.loc<>LOC_REFERENCE) then CGMessage(cg_e_illegal_expression); registers32:=left.registers32; if registers32<1 then registers32:=1; location.loc:=LOC_REGISTER; end; function ttypeconvnode.first_load_smallset : tnode; begin first_load_smallset:=nil; end; function ttypeconvnode.first_cord_to_pointer : tnode; var t : tnode; begin first_cord_to_pointer:=nil; if left.nodetype=ordconstn then begin t:=genpointerconstnode(tordconstnode(left).value,resulttype); firstpass(t); first_cord_to_pointer:=t; exit; end else internalerror(432472389); end; function ttypeconvnode.first_pchar_to_string : tnode; begin first_pchar_to_string:=nil; location.loc:=LOC_REFERENCE; end; function ttypeconvnode.first_ansistring_to_pchar : tnode; begin first_ansistring_to_pchar:=nil; location.loc:=LOC_REGISTER; if registers32<1 then registers32:=1; end; function ttypeconvnode.first_arrayconstructor_to_set : tnode; var hp : tnode; begin first_arrayconstructor_to_set:=nil; if left.nodetype<>arrayconstructorn then internalerror(5546); { remove typeconv node } hp:=left; left:=nil; { create a set constructor tree } arrayconstructor_to_set(tarrayconstructornode(hp)); { now firstpass the set } firstpass(hp); first_arrayconstructor_to_set:=hp; end; function ttypeconvnode.first_class_to_intf : tnode; begin first_class_to_intf:=nil; location.loc:=LOC_REFERENCE; if registers32<1 then registers32:=1; end; function ttypeconvnode.first_call_helper(c : tconverttype) : tnode; const firstconvert : array[tconverttype] of pointer = ( @ttypeconvnode.first_nothing, {equal} @ttypeconvnode.first_nothing, {not_possible} @ttypeconvnode.first_string_to_string, @ttypeconvnode.first_char_to_string, @ttypeconvnode.first_pchar_to_string, @ttypeconvnode.first_cchar_to_pchar, @ttypeconvnode.first_cstring_to_pchar, @ttypeconvnode.first_ansistring_to_pchar, @ttypeconvnode.first_string_to_chararray, @ttypeconvnode.first_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, @ttypeconvnode.first_int_to_fix, @ttypeconvnode.first_real_to_fix, @ttypeconvnode.first_fix_to_real, @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 ); 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; first_call_helper:=tprocedureofobject(r){$ifdef FPC}();{$endif FPC} end; function ttypeconvnode.pass_1 : tnode; var hp : tnode; aprocdef : pprocdef; begin pass_1:=nil; aprocdef:=nil; { if explicite type cast, then run firstpass } if (nf_explizit in flags) or not assigned(left.resulttype) then firstpass(left); if (left.nodetype=typen) and (left.resulttype=generrordef) then begin codegenerror:=true; Message(parser_e_no_type_not_allowed_here); end; if codegenerror then begin resulttype:=generrordef; exit; end; if not assigned(left.resulttype) then begin codegenerror:=true; internalerror(52349); exit; end; { load the value_str from the left part } registers32:=left.registers32; registersfpu:=left.registersfpu; {$ifdef SUPPORT_MMX} registersmmx:=left.registersmmx; {$endif} set_location(location,left.location); { remove obsolete type conversions } if is_equal(left.resulttype,resulttype) then begin { becuase is_equal only checks the basetype for sets we need to check here if we are loading a smallset into a normalset } if (resulttype^.deftype=setdef) and (left.resulttype^.deftype=setdef) and (psetdef(resulttype)^.settype<>smallset) and (psetdef(left.resulttype)^.settype=smallset) then begin { try to define the set as a normalset if it's a constant set } if left.nodetype=setconstn then begin resulttype:=left.resulttype; psetdef(resulttype)^.settype:=normset end else convtype:=tc_load_smallset; exit; end else begin pass_1:=left; left.resulttype:=resulttype; left:=nil; exit; end; end; aprocdef:=assignment_overloaded(left.resulttype,resulttype); if assigned(aprocdef) then begin procinfo^.flags:=procinfo^.flags or pi_do_call; hp:=gencallnode(overloaded_operators[_assignment],nil); { tell explicitly which def we must use !! (PM) } tcallnode(hp).procdefinition:=aprocdef; tcallnode(hp).left:=gencallparanode(left,nil); left:=nil; firstpass(hp); pass_1:=hp; exit; end; if isconvertable(left.resulttype,resulttype,convtype,left,left.nodetype,nf_explizit in flags)=0 then begin {Procedures have a resulttype of voiddef and functions of their own resulttype. 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) then begin if (resulttype^.deftype=procvardef) and (is_procsym_load(left) or is_procsym_call(left)) then begin if is_procsym_call(left) then begin {if left.right=nil then begin} if (tcallnode(left).symtableprocentry^.owner^.symtabletype=objectsymtable){ and (pobjectdef(left.symtableprocentry^.owner^.defowner)^.is_class) }then hp:=genloadmethodcallnode(pprocsym(tcallnode(left).symtableprocentry), tcallnode(left).symtableproc, tcallnode(left).methodpointer.getcopy) else hp:=genloadcallnode(pprocsym(tcallnode(left).symtableprocentry), tcallnode(left).symtableproc); firstpass(hp); left.free; left:=hp; aprocdef:=pprocdef(left.resulttype); (* end else begin left.right.nodetype:=loadn; left.right.symtableentry:=left.right.symtableentry; left.right.resulttype:=pvarsym(left.symtableentry)^.definition; hp:=left.right; putnode(left); left:=hp; { should we do that ? } firstpass(left); if not is_equal(left.resulttype,resulttype) then begin CGMessage(type_e_mismatch); exit; end else begin hp:=p; p:=left; resulttype:=hp.resulttype; putnode(hp); exit; end; end; *) end else begin if (left.nodetype<>addrn) then aprocdef:=pprocsym(tloadnode(left).symtableentry)^.definition; end; 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 assigned(aprocdef) then begin if not proc_to_procvar_equal(aprocdef,pprocvardef(resulttype)) then CGMessage2(type_e_incompatible_types,aprocdef^.typename,resulttype^.typename); pass_1:=first_call_helper(convtype); end else CGMessage2(type_e_incompatible_types,left.resulttype^.typename,resulttype^.typename); exit; end; end; if nf_explizit in flags then begin { check if the result could be in a register } if not(pstoreddef(resulttype)^.is_intregable) and not(pstoreddef(resulttype)^.is_fpuregable) then make_not_regable(left); { boolean to byte are special because the location can be different } if is_integer(resulttype) and is_boolean(left.resulttype) then begin convtype:=tc_bool_2_int; pass_1:=first_call_helper(convtype); exit; end; { ansistring to pchar } if is_pchar(resulttype) and is_ansistring(left.resulttype) then begin convtype:=tc_ansistring_2_pchar; pass_1:=first_call_helper(convtype); exit; end; { do common tc_equal cast } convtype:=tc_equal; { enum to ordinal will always be s32bit } if (left.resulttype^.deftype=enumdef) and is_ordinal(resulttype) then begin if left.nodetype=ordconstn then begin hp:=genordinalconstnode(tordconstnode(left).value,resulttype); firstpass(hp); pass_1:=hp; exit; end else begin if isconvertable(s32bitdef,resulttype,convtype,nil,ordconstn,false)=0 then CGMessage2(type_e_incompatible_types,left.resulttype^.typename,resulttype^.typename); end; end { ordinal to enumeration } else if (resulttype^.deftype=enumdef) and is_ordinal(left.resulttype) then begin if left.nodetype=ordconstn then begin hp:=genordinalconstnode(tordconstnode(left).value,resulttype); firstpass(hp); pass_1:=hp; exit; end else begin if IsConvertable(left.resulttype,s32bitdef,convtype,nil,ordconstn,false)=0 then CGMessage2(type_e_incompatible_types,left.resulttype^.typename,resulttype^.typename); end; end { nil to ordinal node } else if is_ordinal(resulttype) and (left.nodetype=niln) then begin hp:=genordinalconstnode(0,resulttype); firstpass(hp); pass_1:=hp; exit; end {Are we typecasting an ordconst to a char?} else if is_char(resulttype) and is_ordinal(left.resulttype) then begin if left.nodetype=ordconstn then begin hp:=genordinalconstnode(tordconstnode(left).value,resulttype); firstpass(hp); pass_1:=hp; exit; end else begin if IsConvertable(left.resulttype,u8bitdef,convtype,nil,ordconstn,false)=0 then CGMessage2(type_e_incompatible_types,left.resulttype^.typename,resulttype^.typename); end; end { Are we char to ordinal } else if is_char(left.resulttype) and is_ordinal(resulttype) then begin if left.nodetype=ordconstn then begin hp:=genordinalconstnode(tordconstnode(left).value,resulttype); firstpass(hp); pass_1:=hp; exit; end else begin if IsConvertable(u8bitdef,resulttype,convtype,nil,ordconstn,false)=0 then CGMessage2(type_e_incompatible_types,left.resulttype^.typename,resulttype^.typename); end; end { only if the same size or formal def } { why do we allow typecasting of voiddef ?? (PM) } else begin if not( (left.resulttype^.deftype=formaldef) or (left.resulttype^.size=resulttype^.size) or (is_equal(left.resulttype,voiddef) and (left.nodetype=derefn)) ) then CGMessage(cg_e_illegal_type_conversion); if ((left.resulttype^.deftype=orddef) and (resulttype^.deftype=pointerdef)) or ((resulttype^.deftype=orddef) and (left.resulttype^.deftype=pointerdef)) {$ifdef extdebug}and (firstpasscount=0){$endif} then CGMessage(cg_d_pointer_to_longint_conv_not_portable); end; { the conversion into a strutured type is only } { possible, if the source is no register } if ((resulttype^.deftype in [recorddef,stringdef,arraydef]) or ((resulttype^.deftype=objectdef) and not(is_class(resulttype))) ) and (left.location.loc in [LOC_REGISTER,LOC_CREGISTER]) { and it also works if the assignment is overloaded YES but this code is not executed if assignment is overloaded (PM) not assigned(assignment_overloaded(left.resulttype,resulttype))} then CGMessage(cg_e_illegal_type_conversion); end else CGMessage2(type_e_incompatible_types,left.resulttype^.typename,resulttype^.typename); end; { tp7 procvar support, when right is not a procvardef and we got a loadn of a procvar then convert to a calln, the check for the result is already done in is_convertible, also no conflict with @procvar is here because that has an extra addrn } if (m_tp_procvar in aktmodeswitches) and (resulttype^.deftype<>procvardef) and (left.resulttype^.deftype=procvardef) and (left.nodetype=loadn) then begin hp:=gencallnode(nil,nil); tcallnode(hp).right:=left; firstpass(hp); left:=hp; end; { ordinal contants can be directly converted } { but not int64/qword } if (left.nodetype=ordconstn) and is_ordinal(resulttype) and not(is_64bitint(resulttype)) then begin { range checking is done in genordinalconstnode (PFV) } hp:=genordinalconstnode(tordconstnode(left).value,resulttype); firstpass(hp); pass_1:=hp; exit; end; if convtype<>tc_equal then pass_1:=first_call_helper(convtype); end; {***************************************************************************** TISNODE *****************************************************************************} constructor tisnode.create(l,r : tnode); begin inherited create(isn,l,r); end; function tisnode.pass_1 : tnode; begin pass_1:=nil; firstpass(left); set_varstate(left,true); firstpass(right); set_varstate(right,true); if codegenerror then exit; if (right.resulttype^.deftype<>classrefdef) then CGMessage(type_e_mismatch); left_right_max; { left must be a class } if (left.resulttype^.deftype<>objectdef) or not(is_class(left.resulttype)) then CGMessage(type_e_mismatch); { the operands must be related } if (not(pobjectdef(left.resulttype)^.is_related( pobjectdef(pclassrefdef(right.resulttype)^.pointertype.def)))) and (not(pobjectdef(pclassrefdef(right.resulttype)^.pointertype.def)^.is_related( pobjectdef(left.resulttype)))) then CGMessage(type_e_mismatch); location.loc:=LOC_FLAGS; resulttype:=booldef; end; {***************************************************************************** TASNODE *****************************************************************************} constructor tasnode.create(l,r : tnode); begin inherited create(asn,l,r); end; function tasnode.pass_1 : tnode; begin pass_1:=nil; firstpass(right); set_varstate(right,true); firstpass(left); set_varstate(left,true); if codegenerror then exit; if (right.resulttype^.deftype<>classrefdef) then CGMessage(type_e_mismatch); left_right_max; { left must be a class } if (left.resulttype^.deftype<>objectdef) or not(is_class(left.resulttype)) then CGMessage(type_e_mismatch); { the operands must be related } if (not(pobjectdef(left.resulttype)^.is_related( pobjectdef(pclassrefdef(right.resulttype)^.pointertype.def)))) and (not(pobjectdef(pclassrefdef(right.resulttype)^.pointertype.def)^.is_related( pobjectdef(left.resulttype)))) then CGMessage(type_e_mismatch); set_location(location,left.location); resulttype:=pclassrefdef(right.resulttype)^.pointertype.def; end; begin ctypeconvnode:=ttypeconvnode; casnode:=tasnode; cisnode:=tisnode; end. { $Log$ Revision 1.11 2000-11-12 23:24:11 florian * interfaces are basically running Revision 1.10 2000/11/04 14:25:20 florian + merged Attila's changes for interfaces, not tested yet Revision 1.9 2000/10/31 22:02:48 peter * symtable splitted, no real code changes Revision 1.8 2000/10/14 21:52:55 peter * fixed memory leaks Revision 1.7 2000/10/14 10:14:50 peter * moehrendorf oct 2000 rewrite Revision 1.6 2000/10/01 19:48:24 peter * lot of compile updates for cg11 Revision 1.5 2000/09/28 19:49:52 florian *** empty log message *** Revision 1.4 2000/09/27 18:14:31 florian * fixed a lot of syntax errors in the n*.pas stuff Revision 1.3 2000/09/26 20:06:13 florian * hmm, still a lot of work to get things compilable Revision 1.2 2000/09/26 14:59:34 florian * more conversion work done Revision 1.1 2000/09/25 15:37:14 florian * more fixes }