{ Copyright (c) 1998-2002 by Carl Eric Codere and Peter Vreman This unit implements some support routines for assembler parsing independent of the processor 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 RAUtils; {$i fpcdefs.inc} Interface Uses cutils,cclasses, globtype,aasmbase,aasmtai,aasmdata,cpubase,cpuinfo,cgbase,cgutils, symconst,symbase,symtype,symdef,symsym; Const RPNMax = 10; { I think you only need 4, but just to be safe } OpMax = 25; {--------------------------------------------------------------------- Local Label Management ---------------------------------------------------------------------} Type { Each local label has this structure associated with it } TLocalLabel = class(TFPHashObject) Emitted : boolean; constructor Create(AList:TFPHashObjectList;const n:string); function Gettasmlabel:tasmlabel; private lab : tasmlabel; end; TLocalLabelList = class(TFPHashObjectList) procedure CheckEmitted; end; var LocalLabelList : TLocalLabelList; function CreateLocalLabel(const s: string; var hl: tasmlabel; emit:boolean):boolean; Function SearchLabel(const s: string; var hl: tasmlabel;emit:boolean): boolean; {--------------------------------------------------------------------- Instruction management ---------------------------------------------------------------------} type TOprType=(OPR_NONE,OPR_CONSTANT,OPR_SYMBOL,OPR_LOCAL, OPR_REFERENCE,OPR_REGISTER,OPR_REGLIST,OPR_COND,OPR_REGSET,OPR_SHIFTEROP); TOprRec = record case typ:TOprType of OPR_NONE : (); OPR_CONSTANT : (val:aint); OPR_SYMBOL : (symbol:tasmsymbol;symofs:aint); OPR_REFERENCE : (ref:treference); OPR_LOCAL : (localsym:tabstractnormalvarsym;localsymofs:aint;localindexreg:tregister;localscale:byte;localgetoffset,localforceref:boolean); OPR_REGISTER : (reg:tregister); {$ifdef m68k} OPR_REGLIST : (regset : tcpuregisterset); {$endif m68k} {$ifdef powerpc} OPR_COND : (cond : tasmcond); {$endif powerpc} {$ifdef POWERPC64} OPR_COND : (cond : tasmcond); {$endif POWERPC64} {$ifdef arm} OPR_REGSET : (regset : tcpuregisterset); OPR_SHIFTEROP : (shifterop : tshifterop); {$endif arm} end; TOperand = class typesize : aint; hastype, { if the operand has typecasted variable } hasvar : boolean; { if the operand is loaded with a variable } size : TCGSize; opr : TOprRec; constructor create;virtual; destructor destroy;override; Procedure SetSize(_size:longint;force:boolean);virtual; Procedure SetCorrectSize(opcode:tasmop);virtual; Function SetupResult:boolean;virtual; Function SetupSelf:boolean; Function SetupOldEBP:boolean; Function SetupVar(const s:string;GetOffset : boolean): Boolean; Procedure CheckOperand; virtual; Procedure InitRef; end; TCOperand = class of TOperand; TInstruction = class opcode : tasmop; condition : tasmcond; ops : byte; labeled : boolean; operands : array[1..max_operands] of toperand; constructor create(optype : tcoperand);virtual; destructor destroy;override; { converts the instruction to an instruction how it's used by the assembler writer and concats it to the passed list, the newly created item is returned } function ConcatInstruction(p:TAsmList) : tai;virtual; Procedure Swapoperands; end; {---------------------------------------------------------------------} { Expression parser types } {---------------------------------------------------------------------} TExprOperator = record ch: char; { operator } is_prefix: boolean; { was it a prefix, possible prefixes are +,- and not } end; {**********************************************************************} { The following operators are supported: } { '+' : addition } { '-' : subtraction } { '*' : multiplication } { '/' : modulo division } { '^' : exclusive or } { '<' : shift left } { '>' : shift right } { '&' : bitwise and } { '|' : bitwise or } { '~' : bitwise complement } { '%' : modulo division } { nnn: longint numbers } { ( and ) parenthesis } {**********************************************************************} TExprParse = class public Constructor create; Destructor Destroy;override; Function Evaluate(Expr: String): aint; Function Priority(_Operator: Char): aint; private RPNStack : Array[1..RPNMax] of aint; { Stack For RPN calculator } RPNTop : aint; OpStack : Array[1..OpMax] of TExprOperator; { Operator stack For conversion } OpTop : aint; Procedure RPNPush(Num: aint); Function RPNPop: aint; Procedure RPNCalc(const token: String; prefix: boolean); Procedure OpPush(_Operator: char; prefix: boolean); { In reality returns TExprOperaotr } Procedure OpPop(var _Operator:TExprOperator); end; { Evaluate an expression string to a aint } Function CalculateExpression(const expression: string): aint; {---------------------------------------------------------------------} { String routines } {---------------------------------------------------------------------} Function ParseVal(const S:String;base:byte):aint; Function PadZero(Var s: String; n: byte): Boolean; Function EscapeToPascal(const s:string): string; {--------------------------------------------------------------------- Symbol helper routines ---------------------------------------------------------------------} procedure AsmSearchSym(const s:string;var srsym:tsym;var srsymtable:TSymtable); Function GetRecordOffsetSize(s:string;Var Offset: aint;var Size:aint):boolean; Function SearchType(const hs:string;var size:aint): Boolean; Function SearchRecordType(const s:string): boolean; Function SearchIConstant(const s:string; var l:aint): boolean; {--------------------------------------------------------------------- Instruction generation routines ---------------------------------------------------------------------} Procedure ConcatPasString(p : TAsmList;s:string); Procedure ConcatLabel(p: TAsmList;var l : tasmlabel); Procedure ConcatConstant(p : TAsmList;value: aint; constsize:byte); Procedure ConcatConstSymbol(p : TAsmList;const sym:string;symtyp:tasmsymtype;l:aint); Procedure ConcatRealConstant(p : TAsmList;value: bestreal; real_typ : tfloattype); Procedure ConcatString(p : TAsmList;s:string); procedure ConcatAlign(p:TAsmList;l:aint); Procedure ConcatPublic(p:TAsmList;const s : string); Procedure ConcatLocal(p:TAsmList;const s : string); Implementation uses SysUtils, defutil,systems,verbose,globals, symtable,paramgr, aasmcpu, procinfo; {************************************************************************* TExprParse *************************************************************************} Constructor TExprParse.create; Begin end; Procedure TExprParse.RPNPush(Num : aint); { Add an operand to the top of the RPN stack } begin if RPNTop < RPNMax then begin Inc(RPNTop); RPNStack[RPNTop]:=Num; end else Message(asmr_e_expr_illegal); end; Function TExprParse.RPNPop : aint; { Get the operand at the top of the RPN stack } begin if RPNTop > 0 then begin RPNPop:=RPNStack[RPNTop]; Dec(RPNTop); end else Message(asmr_e_expr_illegal); end; Procedure TExprParse.RPNCalc(const Token : String; prefix:boolean); { RPN Calculator } Var Temp : aint; n1,n2 : aint; LocalError : Integer; begin { Handle operators } if (Length(Token) = 1) and (Token[1] in ['+', '-', '*', '/','&','|','%','^','~','<','>']) then Case Token[1] of '+' : Begin if not prefix then RPNPush(RPNPop + RPNPop); end; '-' : Begin if prefix then RPNPush(-(RPNPop)) else begin n1:=RPNPop; n2:=RPNPop; RPNPush(n2 - n1); end; end; '*' : RPNPush(RPNPop * RPNPop); '&' : begin n1:=RPNPop; n2:=RPNPop; RPNPush(n2 and n1); end; '|' : begin n1:=RPNPop; n2:=RPNPop; RPNPush(n2 or n1); end; '~' : RPNPush(NOT RPNPop); '<' : begin n1:=RPNPop; n2:=RPNPop; RPNPush(n2 SHL n1); end; '>' : begin n1:=RPNPop; n2:=RPNPop; RPNPush(n2 SHR n1); end; '%' : begin Temp:=RPNPop; if Temp <> 0 then RPNPush(RPNPop mod Temp) else begin Message(asmr_e_expr_zero_divide); { push 1 for error recovery } RPNPush(1); end; end; '^' : RPNPush(RPNPop XOR RPNPop); '/' : begin Temp:=RPNPop; if Temp <> 0 then RPNPush(RPNPop div Temp) else begin Message(asmr_e_expr_zero_divide); { push 1 for error recovery } RPNPush(1); end; end; end else begin { Convert String to number and add to stack } Val(Token, Temp, LocalError); if LocalError = 0 then RPNPush(Temp) else begin Message(asmr_e_expr_illegal); { push 1 for error recovery } RPNPush(1); end; end; end; Procedure TExprParse.OpPush(_Operator : char;prefix: boolean); { Add an operator onto top of the stack } begin if OpTop < OpMax then begin Inc(OpTop); OpStack[OpTop].ch:=_Operator; OpStack[OpTop].is_prefix:=prefix; end else Message(asmr_e_expr_illegal); end; Procedure TExprParse.OpPop(var _Operator:TExprOperator); { Get operator at the top of the stack } begin if OpTop > 0 then begin _Operator:=OpStack[OpTop]; Dec(OpTop); end else Message(asmr_e_expr_illegal); end; Function TExprParse.Priority(_Operator : Char) : aint; { Return priority of operator } { The greater the priority, the higher the precedence } begin Case _Operator OF '(' : Priority:=0; '+', '-' : Priority:=1; '*', '/','%','<','>' : Priority:=2; '|','&','^','~' : Priority:=0; else Message(asmr_e_expr_illegal); end; end; Function TExprParse.Evaluate(Expr : String):aint; Var I : longint; Token : String; opr : TExprOperator; begin Evaluate:=0; { Reset stacks } OpTop :=0; RPNTop:=0; Token :=''; { nothing to do ? } if Expr='' then exit; For I:=1 to Length(Expr) DO begin if Expr[I] in ['0'..'9'] then begin { Build multi-digit numbers } Token:=Token + Expr[I]; if I = Length(Expr) then { Send last one to calculator } RPNCalc(Token,false); end else if Expr[I] in ['+', '-', '*', '/', '(', ')','^','&','|','%','~','<','>'] then begin if Token <> '' then begin { Send last built number to calc. } RPNCalc(Token,false); Token:=''; end; Case Expr[I] OF '(' : OpPush('(',false); ')' : begin While (OpTop>0) and (OpStack[OpTop].ch <> '(') DO Begin OpPop(opr); RPNCalc(opr.ch,opr.is_prefix); end; OpPop(opr); { Pop off and ignore the '(' } end; '+','-','~' : Begin { workaround for -2147483648 } if (expr[I]='-') and (expr[i+1] in ['0'..'9']) then begin token:='-'; expr[i]:='+'; end; { if start of expression then surely a prefix } { or if previous char was also an operator } if (I = 1) or (not (Expr[I-1] in ['0'..'9','(',')'])) then OpPush(Expr[I],true) else Begin { Evaluate all higher priority operators } While (OpTop > 0) AND (Priority(Expr[I]) <= Priority(OpStack[OpTop].ch)) DO Begin OpPop(opr); RPNCalc(opr.ch,opr.is_prefix); end; OpPush(Expr[I],false); End; end; '*', '/', '^','|','&', '%','<','>' : begin While (OpTop > 0) and (Priority(Expr[I]) <= Priority(OpStack[OpTop].ch)) DO Begin OpPop(opr); RPNCalc(opr.ch,opr.is_prefix); end; OpPush(Expr[I],false); end; end; { Case } end else Message(asmr_e_expr_illegal); { Handle bad input error } end; { Pop off the remaining operators } While OpTop > 0 do Begin OpPop(opr); RPNCalc(opr.ch,opr.is_prefix); end; { The result is stored on the top of the stack } Evaluate:=RPNPop; end; Destructor TExprParse.Destroy; Begin end; Function CalculateExpression(const expression: string): aint; var expr: TExprParse; Begin expr:=TExprParse.create; CalculateExpression:=expr.Evaluate(expression); expr.Free; end; {*************************************************************************} { String conversions/utils } {*************************************************************************} Function EscapeToPascal(const s:string): string; { converts a C styled string - which contains escape } { characters to a pascal style string. } var i,len : aint; hs : string; temp : string; c : char; Begin hs:=''; len:=0; i:=0; while (i0 then begin val(prefix+s,aword(result),code); if code<>0 then begin Message1(errmsg,s); result:=0; end; end; end; Function PadZero(Var s: String; n: byte): Boolean; Begin PadZero:=TRUE; { Do some error checking first } if Length(s) = n then exit else if Length(s) > n then Begin PadZero:=FALSE; delete(s,n+1,length(s)); exit; end else PadZero:=TRUE; { Fill it up with the specified character } fillchar(s[length(s)+1],n-1,#0); s[0]:=chr(n); end; {**************************************************************************** TOperand ****************************************************************************} constructor TOperand.Create; begin size:=OS_NO; hastype:=false; hasvar:=false; FillChar(Opr,sizeof(Opr),0); end; destructor TOperand.destroy; begin end; Procedure TOperand.SetSize(_size:longint;force:boolean); begin if force or ((size = OS_NO) and (_size<=16)) then Begin case _size of 1 : size:=OS_8; 2 : size:=OS_16{ could be S_IS}; 4 : size:=OS_32{ could be S_IL or S_FS}; 8 : size:=OS_64{ could be S_D or S_FL}; 10 : size:=OS_F80; 16 : size:=OS_128; end; end; end; Procedure TOperand.SetCorrectSize(opcode:tasmop); begin end; function TOperand.SetupResult:boolean; begin SetupResult:=false; { replace by correct offset. } with current_procinfo.procdef do if (not is_void(returndef)) then begin if (m_tp7 in current_settings.modeswitches) and (not paramanager.ret_in_param(returndef,proccalloption)) then begin message(asmr_e_cannot_use_RESULT_here); exit; end; SetupResult:=setupvar('result',false) end else message(asmr_e_void_function); end; Function TOperand.SetupSelf:boolean; Begin SetupSelf:=false; if assigned(current_procinfo.procdef._class) then SetupSelf:=setupvar('self',false) else Message(asmr_e_cannot_use_SELF_outside_a_method); end; Function TOperand.SetupOldEBP:boolean; Begin SetupOldEBP:=false; if current_procinfo.procdef.parast.symtablelevel>normal_function_level then SetupOldEBP:=setupvar('parentframe',false) else Message(asmr_e_cannot_use_OLDEBP_outside_nested_procedure); end; Function TOperand.SetupVar(const s:string;GetOffset : boolean): Boolean; function symtable_has_localvarsyms(st:TSymtable):boolean; var sym : tsym; i : longint; begin result:=false; for i:=0 to st.SymList.Count-1 do begin sym:=tsym(st.SymList[i]); if sym.typ=localvarsym then begin result:=true; exit; end; end; end; procedure setconst(l:aint); begin { We return the address of the field, just like Delphi/TP } case opr.typ of OPR_NONE : begin opr.typ:=OPR_CONSTANT; opr.val:=l; end; OPR_CONSTANT : inc(opr.val,l); OPR_REFERENCE : inc(opr.ref.offset,l); OPR_LOCAL : inc(opr.localsymofs,l); else Message(asmr_e_invalid_operand_type); end; end; { search and sets up the correct fields in the Instr record } { for the NON-constant identifier passed to the routine. } { if not found returns FALSE. } var sym : tsym; srsymtable : TSymtable; harrdef : tarraydef; indexreg : tregister; l : aint; plist : ppropaccesslistitem; Begin SetupVar:=false; asmsearchsym(s,sym,srsymtable); if sym = nil then exit; if sym.typ=absolutevarsym then begin if (tabsolutevarsym(sym).abstyp=tovar) then begin { Only support simple loads } plist:=tabsolutevarsym(sym).ref.firstsym; if assigned(plist) and (plist^.sltype=sl_load) then sym:=plist^.sym else begin Message(asmr_e_unsupported_symbol_type); exit; end; end else begin Message(asmr_e_unsupported_symbol_type); exit; end; end; case sym.typ of fieldvarsym : begin setconst(tfieldvarsym(sym).fieldoffset); hasvar:=true; SetupVar:=true; end; staticvarsym, localvarsym, paravarsym : begin { we always assume in asm statements that } { that the variable is valid. } tabstractvarsym(sym).varstate:=vs_readwritten; inc(tabstractvarsym(sym).refs); { variable can't be placed in a register } tabstractvarsym(sym).varregable:=vr_none; case sym.typ of staticvarsym : begin initref; opr.ref.symbol:=current_asmdata.RefAsmSymbol(tstaticvarsym(sym).mangledname); end; paravarsym, localvarsym : begin if opr.typ=OPR_REFERENCE then begin indexreg:=opr.ref.base; if opr.ref.index<>NR_NO then begin if indexreg=NR_NO then indexreg:=opr.ref.index else Message(asmr_e_multiple_index); end; end else indexreg:=NR_NO; opr.typ:=OPR_LOCAL; if assigned(current_procinfo.parent) and not(po_inline in current_procinfo.procdef.procoptions) and (sym.owner<>current_procinfo.procdef.localst) and (sym.owner<>current_procinfo.procdef.parast) and (current_procinfo.procdef.localst.symtablelevel>normal_function_level) and symtable_has_localvarsyms(current_procinfo.procdef.localst) then message1(asmr_e_local_para_unreachable,s); opr.localsym:=tabstractnormalvarsym(sym); opr.localsymofs:=0; opr.localindexreg:=indexreg; opr.localscale:=0; opr.localgetoffset:=GetOffset; if paramanager.push_addr_param(tabstractvarsym(sym).varspez,tabstractvarsym(sym).vardef,current_procinfo.procdef.proccalloption) then SetSize(sizeof(aint),false); end; end; case tabstractvarsym(sym).vardef.typ of orddef, enumdef, pointerdef, floatdef : SetSize(tabstractvarsym(sym).getsize,false); arraydef : begin { for arrays try to get the element size, take care of multiple indexes } harrdef:=tarraydef(tabstractvarsym(sym).vardef); while assigned(harrdef.elementdef) and (harrdef.elementdef.typ=arraydef) do harrdef:=tarraydef(harrdef.elementdef); if not is_packed_array(harrdef) then SetSize(harrdef.elesize,false) else begin if (harrdef.elepackedbitsize mod 8) <> 0 then Message(asmr_e_packed_element); SetSize((harrdef.elepackedbitsize + 7) div 8,false); end; end; end; hasvar:=true; SetupVar:=true; Exit; end; constsym : begin if tconstsym(sym).consttyp=constord then begin setconst(tconstsym(sym).value.valueord); SetupVar:=true; Exit; end; end; typesym : begin if ttypesym(sym).typedef.typ in [recorddef,objectdef] then begin setconst(0); SetupVar:=TRUE; Exit; end; end; procsym : begin if opr.typ<>OPR_NONE then Message(asmr_e_invalid_operand_type); if Tprocsym(sym).ProcdefList.Count>1 then Message(asmr_w_calling_overload_func); l:=opr.ref.offset; opr.typ:=OPR_SYMBOL; opr.symbol:=current_asmdata.RefAsmSymbol(tprocdef(tprocsym(sym).ProcdefList[0]).mangledname); opr.symofs:=l; hasvar:=true; SetupVar:=TRUE; Exit; end; else begin Message(asmr_e_unsupported_symbol_type); exit; end; end; end; procedure TOperand.InitRef; {*********************************************************************} { Description: This routine first check if the opcode is of } { type OPR_NONE, or OPR_REFERENCE , if not it gives out an error. } { If the operandtype = OPR_NONE or <> OPR_REFERENCE then it sets up } { the operand type to OPR_REFERENCE, as well as setting up the ref } { to point to the default segment. } {*********************************************************************} var l : aint; hsymofs : aint; hsymbol : tasmsymbol; reg : tregister; Begin case opr.typ of OPR_REFERENCE : exit; OPR_CONSTANT : begin l:=opr.val; opr.typ:=OPR_REFERENCE; Fillchar(opr.ref,sizeof(treference),0); opr.Ref.Offset:=l; end; OPR_NONE : begin opr.typ:=OPR_REFERENCE; Fillchar(opr.ref,sizeof(treference),0); end; OPR_REGISTER : begin reg:=opr.reg; opr.typ:=OPR_REFERENCE; Fillchar(opr.ref,sizeof(treference),0); opr.Ref.base:=reg; end; OPR_SYMBOL : begin hsymbol:=opr.symbol; hsymofs:=opr.symofs; opr.typ:=OPR_REFERENCE; Fillchar(opr.ref,sizeof(treference),0); opr.ref.symbol:=hsymbol; opr.ref.offset:=hsymofs; end; else begin Message(asmr_e_invalid_operand_type); { Recover } opr.typ:=OPR_REFERENCE; Fillchar(opr.ref,sizeof(treference),0); end; end; end; Procedure TOperand.CheckOperand; {*********************************************************************} { Description: This routine checks if the operand is of } { valid. Does nothing by default. } {*********************************************************************} begin end; {**************************************************************************** TInstruction ****************************************************************************} constructor TInstruction.create(optype : tcoperand); var i : longint; Begin { these field are set to 0 anyways by the constructor helper (FK) Opcode:=A_NONE; Condition:=C_NONE; Ops:=0; } for i:=1 to max_operands do Operands[i]:=optype.create; Labeled:=false; end; destructor TInstruction.destroy; var i : longint; Begin for i:=1 to max_operands do Operands[i].free; end; Procedure TInstruction.Swapoperands; Var p : toperand; Begin case Ops of 2 : begin p:=Operands[1]; Operands[1]:=Operands[2]; Operands[2]:=p; end; 3 : begin p:=Operands[1]; Operands[1]:=Operands[3]; Operands[3]:=p; end; end; end; function TInstruction.ConcatInstruction(p:TAsmList) : tai; var ai : taicpu; i : longint; begin for i:=1 to Ops do operands[i].CheckOperand; ai:=taicpu.op_none(opcode); ai.Ops:=Ops; ai.Allocate_oper(Ops); for i:=1 to Ops do with operands[i].opr do begin case typ of OPR_CONSTANT : ai.loadconst(i-1,val); OPR_REGISTER: ai.loadreg(i-1,reg); OPR_SYMBOL: ai.loadsymbol(i-1,symbol,symofs); OPR_LOCAL : ai.loadlocal(i-1,localsym,localsymofs,localindexreg, localscale,localgetoffset,localforceref); OPR_REFERENCE: ai.loadref(i-1,ref); {$ifdef ARM} OPR_REGSET: ai.loadregset(i-1,regset); OPR_SHIFTEROP: ai.loadshifterop(i-1,shifterop); {$endif ARM} else internalerror(200501051); end; end; ai.SetCondition(condition); { Concat the opcode or give an error } if assigned(ai) then p.concat(ai) else Message(asmr_e_invalid_opcode_and_operand); result:=ai; end; {*************************************************************************** TLocalLabel ***************************************************************************} constructor TLocalLabel.create(AList:TFPHashObjectList;const n:string); begin inherited Create(AList,n); lab:=nil; emitted:=false; end; function TLocalLabel.Gettasmlabel:tasmlabel; begin if not assigned(lab) then begin current_asmdata.getjumplabel(lab); { this label is forced to be used so it's always written } lab.increfs; end; Gettasmlabel:=lab; end; {*************************************************************************** TLocalLabelList ***************************************************************************} procedure TLocalLabelList.CheckEmitted; var i : longint; lab : TLocalLabel; begin for i:=0 to LocalLabelList.Count-1 do begin lab:=TLocalLabel(LocalLabelList[i]); if not lab.emitted then Message1(asmr_e_unknown_label_identifier,lab.name); end; end; function CreateLocalLabel(const s: string; var hl: tasmlabel; emit:boolean):boolean; var lab : TLocalLabel; Begin CreateLocalLabel:=true; { Check if it already is defined } lab:=TLocalLabel(LocalLabellist.Find(s)); if not assigned(lab) then lab:=TLocalLabel.Create(LocalLabellist,s); { set emitted flag and check for dup syms } if emit then begin if lab.Emitted then begin Message1(asmr_e_dup_local_sym,lab.Name); CreateLocalLabel:=false; end; lab.Emitted:=true; end; hl:=lab.Gettasmlabel; end; {**************************************************************************** Symbol table helper routines ****************************************************************************} procedure AsmSearchSym(const s:string;var srsym:tsym;var srsymtable:TSymtable); var i : integer; begin i:=pos('.',s); { allow unit.identifier } if i>0 then begin searchsym(Copy(s,1,i-1),srsym,srsymtable); if assigned(srsym) then begin if (srsym.typ=unitsym) and (srsym.owner.symtabletype in [staticsymtable,globalsymtable]) and srsym.owner.iscurrentunit then searchsym_in_module(tunitsym(srsym).module,Copy(s,i+1,255),srsym,srsymtable) else begin srsym:=nil; srsymtable:=nil; end; end; end else searchsym(s,srsym,srsymtable); end; Function SearchType(const hs:string;var size:aint): Boolean; var srsym : tsym; srsymtable : TSymtable; begin result:=false; size:=0; asmsearchsym(hs,srsym,srsymtable); if assigned(srsym) and (srsym.typ=typesym) then begin size:=ttypesym(srsym).typedef.size; result:=true; end; end; Function SearchRecordType(const s:string): boolean; var srsym : tsym; srsymtable : TSymtable; Begin SearchRecordType:=false; { Check the constants in symtable } asmsearchsym(s,srsym,srsymtable); if srsym <> nil then Begin case srsym.typ of typesym : begin if ttypesym(srsym).typedef.typ in [recorddef,objectdef] then begin SearchRecordType:=true; exit; end; end; end; end; end; Function SearchIConstant(const s:string; var l:aint): boolean; {**********************************************************************} { Description: Searches for a CONSTANT of name s in either the local } { symbol list, then in the global symbol list, and returns the value } { of that constant in l. Returns TRUE if successfull, if not found, } { or if the constant is not of correct type, then returns FALSE } { Remarks: Also handle TRUE and FALSE returning in those cases 1 and 0 } { respectively. } {**********************************************************************} var srsym : tsym; srsymtable : TSymtable; Begin SearchIConstant:=false; { check for TRUE or FALSE reserved words first } if s = 'TRUE' then Begin SearchIConstant:=TRUE; l:=1; exit; end; if s = 'FALSE' then Begin SearchIConstant:=TRUE; l:=0; exit; end; { Check the constants in symtable } asmsearchsym(s,srsym,srsymtable); if srsym <> nil then Begin case srsym.typ of constsym : begin if tconstsym(srsym).consttyp=constord then Begin l:=tconstsym(srsym).value.valueord; SearchIConstant:=TRUE; exit; end; end; enumsym: Begin l:=tenumsym(srsym).value; SearchIConstant:=TRUE; exit; end; end; end; end; Function GetRecordOffsetSize(s:string;Var Offset: aint;var Size:aint):boolean; { search and returns the offset and size of records/objects of the base } { with field name setup in field. } { returns FALSE if not found. } { used when base is a variable or a typed constant name. } var st : TSymtable; harrdef : tarraydef; sym : tsym; srsymtable : TSymtable; i : longint; base : string; Begin GetRecordOffsetSize:=FALSE; Offset:=0; Size:=0; i:=pos('.',s); if i=0 then i:=255; base:=Copy(s,1,i-1); delete(s,1,i); if base='SELF' then st:=current_procinfo.procdef._class.symtable else begin asmsearchsym(base,sym,srsymtable); st:=nil; { we can start with a var,type,typedconst } if assigned(sym) then case sym.typ of staticvarsym, localvarsym, paravarsym : st:=Tabstractvarsym(sym).vardef.GetSymtable(gs_record); typesym : st:=Ttypesym(sym).typedef.GetSymtable(gs_record); end else s:=''; end; { now walk all recordsymtables } while assigned(st) and (s<>'') do begin { load next field in base } i:=pos('.',s); if i=0 then i:=255; base:=Copy(s,1,i-1); delete(s,1,i); if st.symtabletype=ObjectSymtable then sym:=search_class_member(tobjectdef(st.defowner),base) else sym:=tsym(st.Find(base)); if not assigned(sym) then begin GetRecordOffsetSize:=false; exit; end; st:=nil; case sym.typ of fieldvarsym : with Tfieldvarsym(sym) do begin inc(Offset,fieldoffset); size:=getsize; case vardef.typ of arraydef : begin { for arrays try to get the element size, take care of multiple indexes } harrdef:=tarraydef(vardef); while assigned(harrdef.elementdef) and (harrdef.elementdef.typ=arraydef) do harrdef:=tarraydef(harrdef.elementdef); if not is_packed_array(harrdef) then size:=harrdef.elesize else begin if (harrdef.elepackedbitsize mod 8) <> 0 then Message(asmr_e_packed_element); size := (harrdef.elepackedbitsize + 7) div 8; end; end; recorddef : st:=trecorddef(vardef).symtable; objectdef : st:=tobjectdef(vardef).symtable; end; end; end; end; { Support Field.Type as typecasting } if (st=nil) and (s<>'') then begin asmsearchsym(s,sym,srsymtable); if assigned(sym) and (sym.typ=typesym) then begin size:=ttypesym(sym).typedef.size; s:='' end; end; GetRecordOffsetSize:=(s=''); end; Function SearchLabel(const s: string; var hl: tasmlabel;emit:boolean): boolean; var sym : tsym; srsymtable : TSymtable; hs : string; Begin hl:=nil; SearchLabel:=false; { Check for pascal labels, which are case insensetive } hs:=upper(s); asmsearchsym(hs,sym,srsymtable); if sym=nil then exit; case sym.typ of labelsym : begin if not(assigned(tlabelsym(sym).asmblocklabel)) then current_asmdata.getjumplabel(tlabelsym(sym).asmblocklabel); hl:=tlabelsym(sym).asmblocklabel; if emit then tlabelsym(sym).defined:=true else tlabelsym(sym).used:=true; SearchLabel:=true; end; end; end; {*************************************************************************} { Instruction Generation Utilities } {*************************************************************************} Procedure ConcatString(p : TAsmList;s:string); {*********************************************************************} { PROCEDURE ConcatString(s:string); } { Description: This routine adds the character chain pointed to in } { s to the instruction linked list. } {*********************************************************************} Var pc: PChar; Begin getmem(pc,length(s)+1); p.concat(Tai_string.Create_pchar(strpcopy(pc,s),length(s))); end; Procedure ConcatPasString(p : TAsmList;s:string); {*********************************************************************} { PROCEDURE ConcatPasString(s:string); } { Description: This routine adds the character chain pointed to in } { s to the instruction linked list, contrary to ConcatString it } { uses a pascal style string, so it conserves null characters. } {*********************************************************************} Begin p.concat(Tai_string.Create(s)); end; Procedure ConcatConstant(p: TAsmList; value: aint; constsize:byte); {*********************************************************************} { PROCEDURE ConcatConstant(value: aint; maxvalue: aint); } { Description: This routine adds the value constant to the current } { instruction linked list. } { maxvalue -> indicates the size of the data to initialize: } { $ff -> create a byte node. } { $ffff -> create a word node. } { $ffffffff -> create a dword node. } {*********************************************************************} var rangelo,rangehi : int64; Begin case constsize of 1 : begin p.concat(Tai_const.Create_8bit(byte(value))); rangelo:=low(shortint); rangehi:=high(byte); end; 2 : begin p.concat(Tai_const.Create_16bit(word(value))); rangelo:=low(smallint); rangehi:=high(word); end; 4 : begin p.concat(Tai_const.Create_32bit(longint(value))); rangelo:=low(longint); rangehi:=high(cardinal); end; 8 : begin p.concat(Tai_const.Create_64bit(int64(value))); rangelo:=0; rangehi:=0; end; else internalerror(200405011); end; { check for out of bounds } if (rangelo<>0) and ((value>rangehi) or (value indicates the type of the real data to initialize: } { s32real -> create a single node. } { s64real -> create a double node. } { s80real -> create an extended node. } { s64bit -> create a comp node. } { f32bit -> create a fixed node. (not used normally) } {***********************************************************************} Begin case real_typ of s32real : p.concat(Tai_real_32bit.Create(value)); s64real : {$ifdef ARM} if (current_settings.fputype in [fpu_fpa,fpu_fpa10,fpu_fpa11]) and not(cs_fp_emulation in current_settings.moduleswitches) then p.concat(Tai_real_64bit.Create_hiloswapped(value)) else {$endif ARM} p.concat(Tai_real_64bit.Create(value)); s80real : p.concat(Tai_real_80bit.Create(value)); s64comp : p.concat(Tai_comp_64bit.Create(trunc(value))); end; end; Procedure ConcatLabel(p: TAsmList;var l : tasmlabel); {*********************************************************************} { PROCEDURE ConcatLabel } { Description: This routine either emits a label or a labeled } { instruction to the linked list of instructions. } {*********************************************************************} begin p.concat(Tai_label.Create(l)); end; procedure ConcatAlign(p:TAsmList;l:aint); {*********************************************************************} { PROCEDURE ConcatPublic } { Description: This routine emits an global definition to the } { linked list of instructions.(used by AT&T styled asm) } {*********************************************************************} begin p.concat(Tai_align.Create(l)); end; procedure ConcatPublic(p:TAsmList;const s : string); {*********************************************************************} { PROCEDURE ConcatPublic } { Description: This routine emits an global definition to the } { linked list of instructions.(used by AT&T styled asm) } {*********************************************************************} begin p.concat(Tai_symbol.Createname_global(s,AT_LABEL,0)); end; procedure ConcatLocal(p:TAsmList;const s : string); {*********************************************************************} { PROCEDURE ConcatLocal } { Description: This routine emits an local definition to the } { linked list of instructions. } {*********************************************************************} begin p.concat(Tai_symbol.Createname(s,AT_LABEL,0)); end; end.