/* see copyright notice in squirrel.h */ #include "sqpcheader.h" #ifndef NO_COMPILER #include #include #include "sqopcodes.h" #include "sqstring.h" #include "sqfuncproto.h" #include "sqcompiler.h" #include "sqfuncstate.h" #include "sqlexer.h" #include "sqvm.h" #include "sqtable.h" #define EXPR 1 #define OBJECT 2 #define BASE 3 #define LOCAL 4 #define OUTER 5 struct SQExpState { SQInteger etype; /* expr. type; one of EXPR, OBJECT, BASE, OUTER or LOCAL */ SQInteger epos; /* expr. location on stack; -1 for OBJECT and BASE */ bool donot_get; /* signal not to deref the next value */ }; struct SQScope { SQInteger outers; SQInteger stacksize; }; #define BEGIN_SCOPE() SQScope __oldscope__ = _scope; \ _scope.outers = _fs->_outers; \ _scope.stacksize = _fs->GetStackSize(); #define RESOLVE_OUTERS() if(_fs->GetStackSize() != _scope.stacksize) { \ if(_fs->CountOuters(_scope.stacksize)) { \ _fs->AddInstruction(_OP_CLOSE,0,_scope.stacksize); \ } \ } #define END_SCOPE_NO_CLOSE() { if(_fs->GetStackSize() != _scope.stacksize) { \ _fs->SetStackSize(_scope.stacksize); \ } \ _scope = __oldscope__; \ } #define END_SCOPE() { SQInteger oldouters = _fs->_outers;\ if(_fs->GetStackSize() != _scope.stacksize) { \ _fs->SetStackSize(_scope.stacksize); \ if(oldouters != _fs->_outers) { \ _fs->AddInstruction(_OP_CLOSE,0,_scope.stacksize); \ } \ } \ _scope = __oldscope__; \ } #define BEGIN_BREAKBLE_BLOCK() SQInteger __nbreaks__=_fs->_unresolvedbreaks.size(); \ SQInteger __ncontinues__=_fs->_unresolvedcontinues.size(); \ _fs->_breaktargets.push_back(0);_fs->_continuetargets.push_back(0); #define END_BREAKBLE_BLOCK(continue_target) {__nbreaks__=_fs->_unresolvedbreaks.size()-__nbreaks__; \ __ncontinues__=_fs->_unresolvedcontinues.size()-__ncontinues__; \ if(__ncontinues__>0)ResolveContinues(_fs,__ncontinues__,continue_target); \ if(__nbreaks__>0)ResolveBreaks(_fs,__nbreaks__); \ _fs->_breaktargets.pop_back();_fs->_continuetargets.pop_back();} class SQCompiler { public: SQCompiler(SQVM *v, SQLEXREADFUNC rg, SQUserPointer up, const SQChar* sourcename, bool raiseerror, bool lineinfo) { _vm=v; _lex.Init(_ss(v), rg, up,ThrowError,this); _sourcename = SQString::Create(_ss(v), sourcename); _lineinfo = lineinfo;_raiseerror = raiseerror; _scope.outers = 0; _scope.stacksize = 0; compilererror = NULL; } static void ThrowError(void *ud, const SQChar *s) { SQCompiler *c = (SQCompiler *)ud; c->Error(s); } void Error(const SQChar *s, ...) { static SQChar temp[256]; va_list vl; va_start(vl, s); scvsprintf(temp, s, vl); va_end(vl); compilererror = temp; longjmp(_errorjmp,1); } void Lex(){ _token = _lex.Lex();} SQObject Expect(SQInteger tok) { if(_token != tok) { if(_token == TK_CONSTRUCTOR && tok == TK_IDENTIFIER) { //do nothing } else { const SQChar *etypename; if(tok > 255) { switch(tok) { case TK_IDENTIFIER: etypename = _SC("IDENTIFIER"); break; case TK_STRING_LITERAL: etypename = _SC("STRING_LITERAL"); break; case TK_INTEGER: etypename = _SC("INTEGER"); break; case TK_FLOAT: etypename = _SC("FLOAT"); break; default: etypename = _lex.Tok2Str(tok); } Error(_SC("expected '%s'"), etypename); } Error(_SC("expected '%c'"), tok); } } SQObjectPtr ret; switch(tok) { case TK_IDENTIFIER: ret = _fs->CreateString(_lex._svalue); break; case TK_STRING_LITERAL: ret = _fs->CreateString(_lex._svalue,_lex._longstr.size()-1); break; case TK_INTEGER: ret = SQObjectPtr(_lex._nvalue); break; case TK_FLOAT: ret = SQObjectPtr(_lex._fvalue); break; } Lex(); return ret; } bool IsEndOfStatement() { return ((_lex._prevtoken == _SC('\n')) || (_token == SQUIRREL_EOB) || (_token == _SC('}')) || (_token == _SC(';'))); } void OptionalSemicolon() { if(_token == _SC(';')) { Lex(); return; } if(!IsEndOfStatement()) { Error(_SC("end of statement expected (; or lf)")); } } void MoveIfCurrentTargetIsLocal() { SQInteger trg = _fs->TopTarget(); if(_fs->IsLocal(trg)) { trg = _fs->PopTarget(); //no pops the target and move it _fs->AddInstruction(_OP_MOVE, _fs->PushTarget(), trg); } } bool Compile(SQObjectPtr &o) { _debugline = 1; _debugop = 0; SQFuncState funcstate(_ss(_vm), NULL,ThrowError,this); funcstate._name = SQString::Create(_ss(_vm), _SC("main")); _fs = &funcstate; _fs->AddParameter(_fs->CreateString(_SC("this"))); _fs->AddParameter(_fs->CreateString(_SC("vargv"))); _fs->_varparams = true; _fs->_sourcename = _sourcename; SQInteger stacksize = _fs->GetStackSize(); if(setjmp(_errorjmp) == 0) { Lex(); while(_token > 0){ Statement(); if(_lex._prevtoken != _SC('}') && _lex._prevtoken != _SC(';')) OptionalSemicolon(); } _fs->SetStackSize(stacksize); _fs->AddLineInfos(_lex._currentline, _lineinfo, true); _fs->AddInstruction(_OP_RETURN, 0xFF); _fs->SetStackSize(0); o =_fs->BuildProto(); #ifdef _DEBUG_DUMP _fs->Dump(_funcproto(o)); #endif } else { if(_raiseerror && _ss(_vm)->_compilererrorhandler) { _ss(_vm)->_compilererrorhandler(_vm, compilererror, type(_sourcename) == OT_STRING?_stringval(_sourcename):_SC("unknown"), _lex._currentline, _lex._currentcolumn); } _vm->_lasterror = SQString::Create(_ss(_vm), compilererror, -1); return false; } return true; } void Statements() { while(_token != _SC('}') && _token != TK_DEFAULT && _token != TK_CASE) { Statement(); if(_lex._prevtoken != _SC('}') && _lex._prevtoken != _SC(';')) OptionalSemicolon(); } } void Statement(bool closeframe = true) { _fs->AddLineInfos(_lex._currentline, _lineinfo); switch(_token){ case _SC(';'): Lex(); break; case TK_IF: IfStatement(); break; case TK_WHILE: WhileStatement(); break; case TK_DO: DoWhileStatement(); break; case TK_FOR: ForStatement(); break; case TK_FOREACH: ForEachStatement(); break; case TK_SWITCH: SwitchStatement(); break; case TK_LOCAL: LocalDeclStatement(); break; case TK_RETURN: case TK_YIELD: { SQOpcode op; if(_token == TK_RETURN) { op = _OP_RETURN; } else { op = _OP_YIELD; _fs->_bgenerator = true; } Lex(); if(!IsEndOfStatement()) { SQInteger retexp = _fs->GetCurrentPos()+1; CommaExpr(); if(op == _OP_RETURN && _fs->_traps > 0) _fs->AddInstruction(_OP_POPTRAP, _fs->_traps, 0); _fs->_returnexp = retexp; _fs->AddInstruction(op, 1, _fs->PopTarget(),_fs->GetStackSize()); } else{ if(op == _OP_RETURN && _fs->_traps > 0) _fs->AddInstruction(_OP_POPTRAP, _fs->_traps ,0); _fs->_returnexp = -1; _fs->AddInstruction(op, 0xFF,0,_fs->GetStackSize()); } break;} case TK_BREAK: if(_fs->_breaktargets.size() <= 0)Error(_SC("'break' has to be in a loop block")); if(_fs->_breaktargets.top() > 0){ _fs->AddInstruction(_OP_POPTRAP, _fs->_breaktargets.top(), 0); } RESOLVE_OUTERS(); _fs->AddInstruction(_OP_JMP, 0, -1234); _fs->_unresolvedbreaks.push_back(_fs->GetCurrentPos()); Lex(); break; case TK_CONTINUE: if(_fs->_continuetargets.size() <= 0)Error(_SC("'continue' has to be in a loop block")); if(_fs->_continuetargets.top() > 0) { _fs->AddInstruction(_OP_POPTRAP, _fs->_continuetargets.top(), 0); } RESOLVE_OUTERS(); _fs->AddInstruction(_OP_JMP, 0, -1234); _fs->_unresolvedcontinues.push_back(_fs->GetCurrentPos()); Lex(); break; case TK_FUNCTION: FunctionStatement(); break; case TK_CLASS: ClassStatement(); break; case TK_ENUM: EnumStatement(); break; case _SC('{'):{ BEGIN_SCOPE(); Lex(); Statements(); Expect(_SC('}')); if(closeframe) { END_SCOPE(); } else { END_SCOPE_NO_CLOSE(); } } break; case TK_TRY: TryCatchStatement(); break; case TK_THROW: Lex(); CommaExpr(); _fs->AddInstruction(_OP_THROW, _fs->PopTarget()); break; case TK_CONST: { Lex(); SQObject id = Expect(TK_IDENTIFIER); Expect('='); SQObject val = ExpectScalar(); OptionalSemicolon(); SQTable *enums = _table(_ss(_vm)->_consts); SQObjectPtr strongid = id; enums->NewSlot(strongid,SQObjectPtr(val)); strongid.Null(); } break; default: CommaExpr(); _fs->DiscardTarget(); //_fs->PopTarget(); break; } _fs->SnoozeOpt(); } void EmitDerefOp(SQOpcode op) { SQInteger val = _fs->PopTarget(); SQInteger key = _fs->PopTarget(); SQInteger src = _fs->PopTarget(); _fs->AddInstruction(op,_fs->PushTarget(),src,key,val); } void Emit2ArgsOP(SQOpcode op, SQInteger p3 = 0) { SQInteger p2 = _fs->PopTarget(); //src in OP_GET SQInteger p1 = _fs->PopTarget(); //key in OP_GET _fs->AddInstruction(op,_fs->PushTarget(), p1, p2, p3); } void EmitCompoundArith(SQInteger tok, SQInteger etype, SQInteger pos) { /* Generate code depending on the expression type */ switch(etype) { case LOCAL:{ SQInteger p2 = _fs->PopTarget(); //src in OP_GET SQInteger p1 = _fs->PopTarget(); //key in OP_GET _fs->PushTarget(p1); //EmitCompArithLocal(tok, p1, p1, p2); _fs->AddInstruction(ChooseArithOpByToken(tok),p1, p2, p1, 0); } break; case OBJECT: case BASE: { SQInteger val = _fs->PopTarget(); SQInteger key = _fs->PopTarget(); SQInteger src = _fs->PopTarget(); /* _OP_COMPARITH mixes dest obj and source val in the arg1 */ _fs->AddInstruction(_OP_COMPARITH, _fs->PushTarget(), (src<<16)|val, key, ChooseCompArithCharByToken(tok)); } break; case OUTER: { SQInteger val = _fs->TopTarget(); SQInteger tmp = _fs->PushTarget(); _fs->AddInstruction(_OP_GETOUTER, tmp, pos); _fs->AddInstruction(ChooseArithOpByToken(tok), tmp, val, tmp, 0); _fs->AddInstruction(_OP_SETOUTER, tmp, pos, tmp); } break; } } void CommaExpr() { for(Expression();_token == ',';_fs->PopTarget(), Lex(), CommaExpr()); } void Expression() { SQExpState es = _es; _es.etype = EXPR; _es.epos = -1; _es.donot_get = false; LogicalOrExp(); switch(_token) { case _SC('='): case TK_NEWSLOT: case TK_MINUSEQ: case TK_PLUSEQ: case TK_MULEQ: case TK_DIVEQ: case TK_MODEQ:{ SQInteger op = _token; SQInteger ds = _es.etype; SQInteger pos = _es.epos; if(ds == EXPR) Error(_SC("can't assign expression")); Lex(); Expression(); switch(op){ case TK_NEWSLOT: if(ds == OBJECT || ds == BASE) EmitDerefOp(_OP_NEWSLOT); else //if _derefstate != DEREF_NO_DEREF && DEREF_FIELD so is the index of a local Error(_SC("can't 'create' a local slot")); break; case _SC('='): //ASSIGN switch(ds) { case LOCAL: { SQInteger src = _fs->PopTarget(); SQInteger dst = _fs->TopTarget(); _fs->AddInstruction(_OP_MOVE, dst, src); } break; case OBJECT: case BASE: EmitDerefOp(_OP_SET); break; case OUTER: { SQInteger src = _fs->PopTarget(); SQInteger dst = _fs->PushTarget(); _fs->AddInstruction(_OP_SETOUTER, dst, pos, src); } } break; case TK_MINUSEQ: case TK_PLUSEQ: case TK_MULEQ: case TK_DIVEQ: case TK_MODEQ: EmitCompoundArith(op, ds, pos); break; } } break; case _SC('?'): { Lex(); _fs->AddInstruction(_OP_JZ, _fs->PopTarget()); SQInteger jzpos = _fs->GetCurrentPos(); SQInteger trg = _fs->PushTarget(); Expression(); SQInteger first_exp = _fs->PopTarget(); if(trg != first_exp) _fs->AddInstruction(_OP_MOVE, trg, first_exp); SQInteger endfirstexp = _fs->GetCurrentPos(); _fs->AddInstruction(_OP_JMP, 0, 0); Expect(_SC(':')); SQInteger jmppos = _fs->GetCurrentPos(); Expression(); SQInteger second_exp = _fs->PopTarget(); if(trg != second_exp) _fs->AddInstruction(_OP_MOVE, trg, second_exp); _fs->SetIntructionParam(jmppos, 1, _fs->GetCurrentPos() - jmppos); _fs->SetIntructionParam(jzpos, 1, endfirstexp - jzpos + 1); _fs->SnoozeOpt(); } break; } _es = es; } template void BIN_EXP(SQOpcode op, T f,SQInteger op3 = 0) { Lex(); (this->*f)(); SQInteger op1 = _fs->PopTarget();SQInteger op2 = _fs->PopTarget(); _fs->AddInstruction(op, _fs->PushTarget(), op1, op2, op3); } void LogicalOrExp() { LogicalAndExp(); for(;;) if(_token == TK_OR) { SQInteger first_exp = _fs->PopTarget(); SQInteger trg = _fs->PushTarget(); _fs->AddInstruction(_OP_OR, trg, 0, first_exp, 0); SQInteger jpos = _fs->GetCurrentPos(); if(trg != first_exp) _fs->AddInstruction(_OP_MOVE, trg, first_exp); Lex(); LogicalOrExp(); _fs->SnoozeOpt(); SQInteger second_exp = _fs->PopTarget(); if(trg != second_exp) _fs->AddInstruction(_OP_MOVE, trg, second_exp); _fs->SnoozeOpt(); _fs->SetIntructionParam(jpos, 1, (_fs->GetCurrentPos() - jpos)); break; }else return; } void LogicalAndExp() { BitwiseOrExp(); for(;;) switch(_token) { case TK_AND: { SQInteger first_exp = _fs->PopTarget(); SQInteger trg = _fs->PushTarget(); _fs->AddInstruction(_OP_AND, trg, 0, first_exp, 0); SQInteger jpos = _fs->GetCurrentPos(); if(trg != first_exp) _fs->AddInstruction(_OP_MOVE, trg, first_exp); Lex(); LogicalAndExp(); _fs->SnoozeOpt(); SQInteger second_exp = _fs->PopTarget(); if(trg != second_exp) _fs->AddInstruction(_OP_MOVE, trg, second_exp); _fs->SnoozeOpt(); _fs->SetIntructionParam(jpos, 1, (_fs->GetCurrentPos() - jpos)); break; } case TK_IN: BIN_EXP(_OP_EXISTS, &SQCompiler::BitwiseOrExp); break; case TK_INSTANCEOF: BIN_EXP(_OP_INSTANCEOF, &SQCompiler::BitwiseOrExp); break; default: return; } } void BitwiseOrExp() { BitwiseXorExp(); for(;;) if(_token == _SC('|')) {BIN_EXP(_OP_BITW, &SQCompiler::BitwiseXorExp,BW_OR); }else return; } void BitwiseXorExp() { BitwiseAndExp(); for(;;) if(_token == _SC('^')) {BIN_EXP(_OP_BITW, &SQCompiler::BitwiseAndExp,BW_XOR); }else return; } void BitwiseAndExp() { EqExp(); for(;;) if(_token == _SC('&')) {BIN_EXP(_OP_BITW, &SQCompiler::EqExp,BW_AND); }else return; } void EqExp() { CompExp(); for(;;) switch(_token) { case TK_EQ: BIN_EXP(_OP_EQ, &SQCompiler::CompExp); break; case TK_NE: BIN_EXP(_OP_NE, &SQCompiler::CompExp); break; case TK_3WAYSCMP: BIN_EXP(_OP_CMP, &SQCompiler::CompExp,CMP_3W); break; default: return; } } void CompExp() { ShiftExp(); for(;;) switch(_token) { case _SC('>'): BIN_EXP(_OP_CMP, &SQCompiler::ShiftExp,CMP_G); break; case _SC('<'): BIN_EXP(_OP_CMP, &SQCompiler::ShiftExp,CMP_L); break; case TK_GE: BIN_EXP(_OP_CMP, &SQCompiler::ShiftExp,CMP_GE); break; case TK_LE: BIN_EXP(_OP_CMP, &SQCompiler::ShiftExp,CMP_LE); break; default: return; } } void ShiftExp() { PlusExp(); for(;;) switch(_token) { case TK_USHIFTR: BIN_EXP(_OP_BITW, &SQCompiler::PlusExp,BW_USHIFTR); break; case TK_SHIFTL: BIN_EXP(_OP_BITW, &SQCompiler::PlusExp,BW_SHIFTL); break; case TK_SHIFTR: BIN_EXP(_OP_BITW, &SQCompiler::PlusExp,BW_SHIFTR); break; default: return; } } SQOpcode ChooseArithOpByToken(SQInteger tok) { switch(tok) { case TK_PLUSEQ: case '+': return _OP_ADD; case TK_MINUSEQ: case '-': return _OP_SUB; case TK_MULEQ: case '*': return _OP_MUL; case TK_DIVEQ: case '/': return _OP_DIV; case TK_MODEQ: case '%': return _OP_MOD; default: assert(0); } return _OP_ADD; } SQInteger ChooseCompArithCharByToken(SQInteger tok) { SQInteger oper; switch(tok){ case TK_MINUSEQ: oper = '-'; break; case TK_PLUSEQ: oper = '+'; break; case TK_MULEQ: oper = '*'; break; case TK_DIVEQ: oper = '/'; break; case TK_MODEQ: oper = '%'; break; default: oper = 0; //shut up compiler assert(0); break; }; return oper; } void PlusExp() { MultExp(); for(;;) switch(_token) { case _SC('+'): case _SC('-'): BIN_EXP(ChooseArithOpByToken(_token), &SQCompiler::MultExp); break; default: return; } } void MultExp() { PrefixedExpr(); for(;;) switch(_token) { case _SC('*'): case _SC('/'): case _SC('%'): BIN_EXP(ChooseArithOpByToken(_token), &SQCompiler::PrefixedExpr); break; default: return; } } //if 'pos' != -1 the previous variable is a local variable void PrefixedExpr() { SQInteger pos = Factor(); for(;;) { switch(_token) { case _SC('.'): pos = -1; Lex(); _fs->AddInstruction(_OP_LOAD, _fs->PushTarget(), _fs->GetConstant(Expect(TK_IDENTIFIER))); if(_es.etype==BASE) { Emit2ArgsOP(_OP_GET); pos = _fs->TopTarget(); _es.etype = EXPR; _es.epos = pos; } else { if(NeedGet()) { Emit2ArgsOP(_OP_GET); } _es.etype = OBJECT; } break; case _SC('['): if(_lex._prevtoken == _SC('\n')) Error(_SC("cannot brake deref/or comma needed after [exp]=exp slot declaration")); Lex(); Expression(); Expect(_SC(']')); pos = -1; if(_es.etype==BASE) { Emit2ArgsOP(_OP_GET); pos = _fs->TopTarget(); _es.etype = EXPR; _es.epos = pos; } else { if(NeedGet()) { Emit2ArgsOP(_OP_GET); } _es.etype = OBJECT; } break; case TK_MINUSMINUS: case TK_PLUSPLUS: { if(IsEndOfStatement()) return; SQInteger diff = (_token==TK_MINUSMINUS) ? -1 : 1; Lex(); switch(_es.etype) { case EXPR: Error(_SC("can't '++' or '--' an expression")); break; case OBJECT: case BASE: Emit2ArgsOP(_OP_PINC, diff); break; case LOCAL: { SQInteger src = _fs->PopTarget(); _fs->AddInstruction(_OP_PINCL, _fs->PushTarget(), src, 0, diff); } break; case OUTER: { SQInteger tmp1 = _fs->PushTarget(); SQInteger tmp2 = _fs->PushTarget(); _fs->AddInstruction(_OP_GETOUTER, tmp2, _es.epos); _fs->AddInstruction(_OP_PINCL, tmp1, tmp2, 0, diff); _fs->AddInstruction(_OP_SETOUTER, tmp2, _es.epos, tmp2); _fs->PopTarget(); } } } return; break; case _SC('('): switch(_es.etype) { case OBJECT: { SQInteger key = _fs->PopTarget(); /* location of the key */ SQInteger table = _fs->PopTarget(); /* location of the object */ SQInteger closure = _fs->PushTarget(); /* location for the closure */ SQInteger ttarget = _fs->PushTarget(); /* location for 'this' pointer */ _fs->AddInstruction(_OP_PREPCALL, closure, key, table, ttarget); } break; case BASE: //Emit2ArgsOP(_OP_GET); _fs->AddInstruction(_OP_MOVE, _fs->PushTarget(), 0); break; case OUTER: _fs->AddInstruction(_OP_GETOUTER, _fs->PushTarget(), _es.epos); _fs->AddInstruction(_OP_MOVE, _fs->PushTarget(), 0); break; default: _fs->AddInstruction(_OP_MOVE, _fs->PushTarget(), 0); } _es.etype = EXPR; Lex(); FunctionCallArgs(); break; default: return; } } } SQInteger Factor() { _es.etype = EXPR; switch(_token) { case TK_STRING_LITERAL: _fs->AddInstruction(_OP_LOAD, _fs->PushTarget(), _fs->GetConstant(_fs->CreateString(_lex._svalue,_lex._longstr.size()-1))); Lex(); break; case TK_BASE: Lex(); _fs->AddInstruction(_OP_GETBASE, _fs->PushTarget()); _es.etype = BASE; _es.epos = _fs->TopTarget(); return (_es.epos); break; case TK_IDENTIFIER: case TK_CONSTRUCTOR: case TK_THIS:{ SQObject id; SQObject constant; switch(_token) { case TK_IDENTIFIER: id = _fs->CreateString(_lex._svalue); break; case TK_THIS: id = _fs->CreateString(_SC("this")); break; case TK_CONSTRUCTOR: id = _fs->CreateString(_SC("constructor")); break; } SQInteger pos = -1; Lex(); if((pos = _fs->GetLocalVariable(id)) != -1) { /* Handle a local variable (includes 'this') */ _fs->PushTarget(pos); _es.etype = LOCAL; _es.epos = pos; } else if((pos = _fs->GetOuterVariable(id)) != -1) { /* Handle a free var */ if(NeedGet()) { _es.epos = _fs->PushTarget(); _fs->AddInstruction(_OP_GETOUTER, _es.epos, pos); /* _es.etype = EXPR; already default value */ } else { _es.etype = OUTER; _es.epos = pos; } } else if(_fs->IsConstant(id, constant)) { /* Handle named constant */ SQObjectPtr constval; SQObject constid; if(type(constant) == OT_TABLE) { Expect('.'); constid = Expect(TK_IDENTIFIER); if(!_table(constant)->Get(constid, constval)) { constval.Null(); Error(_SC("invalid constant [%s.%s]"), _stringval(id), _stringval(constid)); } } else { constval = constant; } _es.epos = _fs->PushTarget(); /* generate direct or literal function depending on size */ SQObjectType ctype = type(constval); switch(ctype) { case OT_INTEGER: EmitLoadConstInt(_integer(constval),_es.epos); break; case OT_FLOAT: EmitLoadConstFloat(_float(constval),_es.epos); break; default: _fs->AddInstruction(_OP_LOAD,_es.epos,_fs->GetConstant(constval)); break; } _es.etype = EXPR; } else { /* Handle a non-local variable, aka a field. Push the 'this' pointer on * the virtual stack (always found in offset 0, so no instruction needs to * be generated), and push the key next. Generate an _OP_LOAD instruction * for the latter. If we are not using the variable as a dref expr, generate * the _OP_GET instruction. */ _fs->PushTarget(0); _fs->AddInstruction(_OP_LOAD, _fs->PushTarget(), _fs->GetConstant(id)); if(NeedGet()) { Emit2ArgsOP(_OP_GET); } _es.etype = OBJECT; } return _es.epos; } break; case TK_DOUBLE_COLON: // "::" _fs->AddInstruction(_OP_LOADROOT, _fs->PushTarget()); _es.etype = OBJECT; _token = _SC('.'); /* hack: drop into PrefixExpr, case '.'*/ _es.epos = -1; return _es.epos; break; case TK_NULL: _fs->AddInstruction(_OP_LOADNULLS, _fs->PushTarget(),1); Lex(); break; case TK_INTEGER: EmitLoadConstInt(_lex._nvalue,-1); Lex(); break; case TK_FLOAT: EmitLoadConstFloat(_lex._fvalue,-1); Lex(); break; case TK_TRUE: case TK_FALSE: _fs->AddInstruction(_OP_LOADBOOL, _fs->PushTarget(),_token == TK_TRUE?1:0); Lex(); break; case _SC('['): { _fs->AddInstruction(_OP_NEWOBJ, _fs->PushTarget(),0,0,NOT_ARRAY); SQInteger apos = _fs->GetCurrentPos(),key = 0; Lex(); while(_token != _SC(']')) { Expression(); if(_token == _SC(',')) Lex(); SQInteger val = _fs->PopTarget(); SQInteger array = _fs->TopTarget(); _fs->AddInstruction(_OP_APPENDARRAY, array, val, AAT_STACK); key++; } _fs->SetIntructionParam(apos, 1, key); Lex(); } break; case _SC('{'): _fs->AddInstruction(_OP_NEWOBJ, _fs->PushTarget(),0,NOT_TABLE); Lex();ParseTableOrClass(_SC(','),_SC('}')); break; case TK_FUNCTION: FunctionExp(_token);break; case _SC('@'): FunctionExp(_token,true);break; case TK_CLASS: Lex(); ClassExp();break; case _SC('-'): Lex(); switch(_token) { case TK_INTEGER: EmitLoadConstInt(-_lex._nvalue,-1); Lex(); break; case TK_FLOAT: EmitLoadConstFloat(-_lex._fvalue,-1); Lex(); break; default: UnaryOP(_OP_NEG); } break; case _SC('!'): Lex(); UnaryOP(_OP_NOT); break; case _SC('~'): Lex(); if(_token == TK_INTEGER) { EmitLoadConstInt(~_lex._nvalue,-1); Lex(); break; } UnaryOP(_OP_BWNOT); break; case TK_TYPEOF : Lex() ;UnaryOP(_OP_TYPEOF); break; case TK_RESUME : Lex(); UnaryOP(_OP_RESUME); break; case TK_CLONE : Lex(); UnaryOP(_OP_CLONE); break; case TK_MINUSMINUS : case TK_PLUSPLUS :PrefixIncDec(_token); break; case TK_DELETE : DeleteExpr(); break; case _SC('('): Lex(); CommaExpr(); Expect(_SC(')')); break; default: Error(_SC("expression expected")); } return -1; } void EmitLoadConstInt(SQInteger value,SQInteger target) { if(target < 0) { target = _fs->PushTarget(); } if((value & (~((SQInteger)0xFFFFFFFF))) == 0) { //does it fit in 32 bits? _fs->AddInstruction(_OP_LOADINT, target,value); } else { _fs->AddInstruction(_OP_LOAD, target, _fs->GetNumericConstant(value)); } } void EmitLoadConstFloat(SQFloat value,SQInteger target) { if(target < 0) { target = _fs->PushTarget(); } if(sizeof(SQFloat) == sizeof(SQInt32)) { _fs->AddInstruction(_OP_LOADFLOAT, target,*((SQInt32 *)&value)); } else { _fs->AddInstruction(_OP_LOAD, target, _fs->GetNumericConstant(value)); } } void UnaryOP(SQOpcode op) { PrefixedExpr(); SQInteger src = _fs->PopTarget(); _fs->AddInstruction(op, _fs->PushTarget(), src); } bool NeedGet() { switch(_token) { case _SC('='): case _SC('('): case TK_NEWSLOT: case TK_MODEQ: case TK_MULEQ: case TK_DIVEQ: case TK_MINUSEQ: case TK_PLUSEQ: case TK_PLUSPLUS: case TK_MINUSMINUS: return false; } return (!_es.donot_get || ( _es.donot_get && (_token == _SC('.') || _token == _SC('[')))); } void FunctionCallArgs() { SQInteger nargs = 1;//this while(_token != _SC(')')) { Expression(); MoveIfCurrentTargetIsLocal(); nargs++; if(_token == _SC(',')){ Lex(); if(_token == ')') Error(_SC("expression expected, found ')'")); } } Lex(); for(SQInteger i = 0; i < (nargs - 1); i++) _fs->PopTarget(); SQInteger stackbase = _fs->PopTarget(); SQInteger closure = _fs->PopTarget(); _fs->AddInstruction(_OP_CALL, _fs->PushTarget(), closure, stackbase, nargs); } void ParseTableOrClass(SQInteger separator,SQInteger terminator) { SQInteger tpos = _fs->GetCurrentPos(),nkeys = 0; while(_token != terminator) { bool hasattrs = false; bool isstatic = false; //check if is an attribute if(separator == ';') { if(_token == TK_ATTR_OPEN) { _fs->AddInstruction(_OP_NEWOBJ, _fs->PushTarget(),0,NOT_TABLE); Lex(); ParseTableOrClass(',',TK_ATTR_CLOSE); hasattrs = true; } if(_token == TK_STATIC) { isstatic = true; Lex(); } } switch(_token) { case TK_FUNCTION: case TK_CONSTRUCTOR:{ SQInteger tk = _token; Lex(); SQObject id = tk == TK_FUNCTION ? Expect(TK_IDENTIFIER) : _fs->CreateString(_SC("constructor")); Expect(_SC('(')); _fs->AddInstruction(_OP_LOAD, _fs->PushTarget(), _fs->GetConstant(id)); CreateFunction(id); _fs->AddInstruction(_OP_CLOSURE, _fs->PushTarget(), _fs->_functions.size() - 1, 0); } break; case _SC('['): Lex(); CommaExpr(); Expect(_SC(']')); Expect(_SC('=')); Expression(); break; case TK_STRING_LITERAL: //JSON if(separator == ',') { //only works for tables _fs->AddInstruction(_OP_LOAD, _fs->PushTarget(), _fs->GetConstant(Expect(TK_STRING_LITERAL))); Expect(_SC(':')); Expression(); break; } default : _fs->AddInstruction(_OP_LOAD, _fs->PushTarget(), _fs->GetConstant(Expect(TK_IDENTIFIER))); Expect(_SC('=')); Expression(); } if(_token == separator) Lex();//optional comma/semicolon nkeys++; SQInteger val = _fs->PopTarget(); SQInteger key = _fs->PopTarget(); SQInteger attrs = hasattrs ? _fs->PopTarget():-1; assert((hasattrs && (attrs == key-1)) || !hasattrs); unsigned char flags = (hasattrs?NEW_SLOT_ATTRIBUTES_FLAG:0)|(isstatic?NEW_SLOT_STATIC_FLAG:0); SQInteger table = _fs->TopTarget(); //<AddInstruction(_OP_NEWSLOT, 0xFF, table, key, val); } else { _fs->AddInstruction(_OP_NEWSLOTA, flags, table, key, val); //this for classes only as it invokes _newmember } } if(separator == _SC(',')) //hack recognizes a table from the separator _fs->SetIntructionParam(tpos, 1, nkeys); Lex(); } void LocalDeclStatement() { SQObject varname; Lex(); if( _token == TK_FUNCTION) { Lex(); varname = Expect(TK_IDENTIFIER); Expect(_SC('(')); CreateFunction(varname,false); _fs->AddInstruction(_OP_CLOSURE, _fs->PushTarget(), _fs->_functions.size() - 1, 0); _fs->PopTarget(); _fs->PushLocalVariable(varname); return; } do { varname = Expect(TK_IDENTIFIER); if(_token == _SC('=')) { Lex(); Expression(); SQInteger src = _fs->PopTarget(); SQInteger dest = _fs->PushTarget(); if(dest != src) _fs->AddInstruction(_OP_MOVE, dest, src); } else{ _fs->AddInstruction(_OP_LOADNULLS, _fs->PushTarget(),1); } _fs->PopTarget(); _fs->PushLocalVariable(varname); if(_token == _SC(',')) Lex(); else break; } while(1); } void IfStatement() { SQInteger jmppos; bool haselse = false; Lex(); Expect(_SC('(')); CommaExpr(); Expect(_SC(')')); _fs->AddInstruction(_OP_JZ, _fs->PopTarget()); SQInteger jnepos = _fs->GetCurrentPos(); BEGIN_SCOPE(); Statement(); // if(_token != _SC('}') && _token != TK_ELSE) OptionalSemicolon(); END_SCOPE(); SQInteger endifblock = _fs->GetCurrentPos(); if(_token == TK_ELSE){ haselse = true; BEGIN_SCOPE(); _fs->AddInstruction(_OP_JMP); jmppos = _fs->GetCurrentPos(); Lex(); Statement(); OptionalSemicolon(); END_SCOPE(); _fs->SetIntructionParam(jmppos, 1, _fs->GetCurrentPos() - jmppos); } _fs->SetIntructionParam(jnepos, 1, endifblock - jnepos + (haselse?1:0)); } void WhileStatement() { SQInteger jzpos, jmppos; jmppos = _fs->GetCurrentPos(); Lex(); Expect(_SC('(')); CommaExpr(); Expect(_SC(')')); BEGIN_BREAKBLE_BLOCK(); _fs->AddInstruction(_OP_JZ, _fs->PopTarget()); jzpos = _fs->GetCurrentPos(); BEGIN_SCOPE(); Statement(); END_SCOPE(); _fs->AddInstruction(_OP_JMP, 0, jmppos - _fs->GetCurrentPos() - 1); _fs->SetIntructionParam(jzpos, 1, _fs->GetCurrentPos() - jzpos); END_BREAKBLE_BLOCK(jmppos); } void DoWhileStatement() { Lex(); SQInteger jmptrg = _fs->GetCurrentPos(); BEGIN_BREAKBLE_BLOCK() BEGIN_SCOPE(); Statement(); END_SCOPE(); Expect(TK_WHILE); SQInteger continuetrg = _fs->GetCurrentPos(); Expect(_SC('(')); CommaExpr(); Expect(_SC(')')); _fs->AddInstruction(_OP_JZ, _fs->PopTarget(), 1); _fs->AddInstruction(_OP_JMP, 0, jmptrg - _fs->GetCurrentPos() - 1); END_BREAKBLE_BLOCK(continuetrg); } void ForStatement() { Lex(); BEGIN_SCOPE(); Expect(_SC('(')); if(_token == TK_LOCAL) LocalDeclStatement(); else if(_token != _SC(';')){ CommaExpr(); _fs->PopTarget(); } Expect(_SC(';')); _fs->SnoozeOpt(); SQInteger jmppos = _fs->GetCurrentPos(); SQInteger jzpos = -1; if(_token != _SC(';')) { CommaExpr(); _fs->AddInstruction(_OP_JZ, _fs->PopTarget()); jzpos = _fs->GetCurrentPos(); } Expect(_SC(';')); _fs->SnoozeOpt(); SQInteger expstart = _fs->GetCurrentPos() + 1; if(_token != _SC(')')) { CommaExpr(); _fs->PopTarget(); } Expect(_SC(')')); _fs->SnoozeOpt(); SQInteger expend = _fs->GetCurrentPos(); SQInteger expsize = (expend - expstart) + 1; SQInstructionVec exp; if(expsize > 0) { for(SQInteger i = 0; i < expsize; i++) exp.push_back(_fs->GetInstruction(expstart + i)); _fs->PopInstructions(expsize); } BEGIN_BREAKBLE_BLOCK() Statement(); SQInteger continuetrg = _fs->GetCurrentPos(); if(expsize > 0) { for(SQInteger i = 0; i < expsize; i++) _fs->AddInstruction(exp[i]); } _fs->AddInstruction(_OP_JMP, 0, jmppos - _fs->GetCurrentPos() - 1, 0); if(jzpos> 0) _fs->SetIntructionParam(jzpos, 1, _fs->GetCurrentPos() - jzpos); END_SCOPE(); END_BREAKBLE_BLOCK(continuetrg); } void ForEachStatement() { SQObject idxname, valname; Lex(); Expect(_SC('(')); valname = Expect(TK_IDENTIFIER); if(_token == _SC(',')) { idxname = valname; Lex(); valname = Expect(TK_IDENTIFIER); } else{ idxname = _fs->CreateString(_SC("@INDEX@")); } Expect(TK_IN); //save the stack size BEGIN_SCOPE(); //put the table in the stack(evaluate the table expression) Expression(); Expect(_SC(')')); SQInteger container = _fs->TopTarget(); //push the index local var SQInteger indexpos = _fs->PushLocalVariable(idxname); _fs->AddInstruction(_OP_LOADNULLS, indexpos,1); //push the value local var SQInteger valuepos = _fs->PushLocalVariable(valname); _fs->AddInstruction(_OP_LOADNULLS, valuepos,1); //push reference index SQInteger itrpos = _fs->PushLocalVariable(_fs->CreateString(_SC("@ITERATOR@"))); //use invalid id to make it inaccessible _fs->AddInstruction(_OP_LOADNULLS, itrpos,1); SQInteger jmppos = _fs->GetCurrentPos(); _fs->AddInstruction(_OP_FOREACH, container, 0, indexpos); SQInteger foreachpos = _fs->GetCurrentPos(); _fs->AddInstruction(_OP_POSTFOREACH, container, 0, indexpos); //generate the statement code BEGIN_BREAKBLE_BLOCK() Statement(); _fs->AddInstruction(_OP_JMP, 0, jmppos - _fs->GetCurrentPos() - 1); _fs->SetIntructionParam(foreachpos, 1, _fs->GetCurrentPos() - foreachpos); _fs->SetIntructionParam(foreachpos + 1, 1, _fs->GetCurrentPos() - foreachpos); END_BREAKBLE_BLOCK(foreachpos - 1); //restore the local variable stack(remove index,val and ref idx) END_SCOPE(); } void SwitchStatement() { Lex(); Expect(_SC('(')); CommaExpr(); Expect(_SC(')')); Expect(_SC('{')); SQInteger expr = _fs->TopTarget(); bool bfirst = true; SQInteger tonextcondjmp = -1; SQInteger skipcondjmp = -1; SQInteger __nbreaks__ = _fs->_unresolvedbreaks.size(); _fs->_breaktargets.push_back(0); while(_token == TK_CASE) { if(!bfirst) { _fs->AddInstruction(_OP_JMP, 0, 0); skipcondjmp = _fs->GetCurrentPos(); _fs->SetIntructionParam(tonextcondjmp, 1, _fs->GetCurrentPos() - tonextcondjmp); } //condition Lex(); Expression(); Expect(_SC(':')); SQInteger trg = _fs->PopTarget(); _fs->AddInstruction(_OP_EQ, trg, trg, expr); _fs->AddInstruction(_OP_JZ, trg, 0); //end condition if(skipcondjmp != -1) { _fs->SetIntructionParam(skipcondjmp, 1, (_fs->GetCurrentPos() - skipcondjmp)); } tonextcondjmp = _fs->GetCurrentPos(); BEGIN_SCOPE(); Statements(); END_SCOPE(); bfirst = false; } if(tonextcondjmp != -1) _fs->SetIntructionParam(tonextcondjmp, 1, _fs->GetCurrentPos() - tonextcondjmp); if(_token == TK_DEFAULT) { Lex(); Expect(_SC(':')); BEGIN_SCOPE(); Statements(); END_SCOPE(); } Expect(_SC('}')); _fs->PopTarget(); __nbreaks__ = _fs->_unresolvedbreaks.size() - __nbreaks__; if(__nbreaks__ > 0)ResolveBreaks(_fs, __nbreaks__); _fs->_breaktargets.pop_back(); } void FunctionStatement() { SQObject id; Lex(); id = Expect(TK_IDENTIFIER); _fs->PushTarget(0); _fs->AddInstruction(_OP_LOAD, _fs->PushTarget(), _fs->GetConstant(id)); if(_token == TK_DOUBLE_COLON) Emit2ArgsOP(_OP_GET); while(_token == TK_DOUBLE_COLON) { Lex(); id = Expect(TK_IDENTIFIER); _fs->AddInstruction(_OP_LOAD, _fs->PushTarget(), _fs->GetConstant(id)); if(_token == TK_DOUBLE_COLON) Emit2ArgsOP(_OP_GET); } Expect(_SC('(')); CreateFunction(id); _fs->AddInstruction(_OP_CLOSURE, _fs->PushTarget(), _fs->_functions.size() - 1, 0); EmitDerefOp(_OP_NEWSLOT); _fs->PopTarget(); } void ClassStatement() { SQExpState es; Lex(); es = _es; _es.donot_get = true; PrefixedExpr(); if(_es.etype == EXPR) { Error(_SC("invalid class name")); } else if(_es.etype == OBJECT || _es.etype == BASE) { ClassExp(); EmitDerefOp(_OP_NEWSLOT); _fs->PopTarget(); } else { Error(_SC("cannot create a class in a local with the syntax(class )")); } _es = es; } SQObject ExpectScalar() { SQObject val; val._type = OT_NULL; val._unVal.nInteger = 0; //shut up GCC 4.x switch(_token) { case TK_INTEGER: val._type = OT_INTEGER; val._unVal.nInteger = _lex._nvalue; break; case TK_FLOAT: val._type = OT_FLOAT; val._unVal.fFloat = _lex._fvalue; break; case TK_STRING_LITERAL: val = _fs->CreateString(_lex._svalue,_lex._longstr.size()-1); break; case '-': Lex(); switch(_token) { case TK_INTEGER: val._type = OT_INTEGER; val._unVal.nInteger = -_lex._nvalue; break; case TK_FLOAT: val._type = OT_FLOAT; val._unVal.fFloat = -_lex._fvalue; break; default: Error(_SC("scalar expected : integer,float")); } break; default: Error(_SC("scalar expected : integer,float or string")); } Lex(); return val; } void EnumStatement() { Lex(); SQObject id = Expect(TK_IDENTIFIER); Expect(_SC('{')); SQObject table = _fs->CreateTable(); SQInteger nval = 0; while(_token != _SC('}')) { SQObject key = Expect(TK_IDENTIFIER); SQObject val; if(_token == _SC('=')) { Lex(); val = ExpectScalar(); } else { val._type = OT_INTEGER; val._unVal.nInteger = nval++; } _table(table)->NewSlot(SQObjectPtr(key),SQObjectPtr(val)); if(_token == ',') Lex(); } SQTable *enums = _table(_ss(_vm)->_consts); SQObjectPtr strongid = id; enums->NewSlot(SQObjectPtr(strongid),SQObjectPtr(table)); strongid.Null(); Lex(); } void TryCatchStatement() { SQObject exid; Lex(); _fs->AddInstruction(_OP_PUSHTRAP,0,0); _fs->_traps++; if(_fs->_breaktargets.size()) _fs->_breaktargets.top()++; if(_fs->_continuetargets.size()) _fs->_continuetargets.top()++; SQInteger trappos = _fs->GetCurrentPos(); { BEGIN_SCOPE(); Statement(); END_SCOPE(); } _fs->_traps--; _fs->AddInstruction(_OP_POPTRAP, 1, 0); if(_fs->_breaktargets.size()) _fs->_breaktargets.top()--; if(_fs->_continuetargets.size()) _fs->_continuetargets.top()--; _fs->AddInstruction(_OP_JMP, 0, 0); SQInteger jmppos = _fs->GetCurrentPos(); _fs->SetIntructionParam(trappos, 1, (_fs->GetCurrentPos() - trappos)); Expect(TK_CATCH); Expect(_SC('(')); exid = Expect(TK_IDENTIFIER); Expect(_SC(')')); { BEGIN_SCOPE(); SQInteger ex_target = _fs->PushLocalVariable(exid); _fs->SetIntructionParam(trappos, 0, ex_target); Statement(); _fs->SetIntructionParams(jmppos, 0, (_fs->GetCurrentPos() - jmppos), 0); END_SCOPE(); } } void FunctionExp(SQInteger ftype,bool lambda = false) { Lex(); Expect(_SC('(')); SQObjectPtr dummy; CreateFunction(dummy,lambda); _fs->AddInstruction(_OP_CLOSURE, _fs->PushTarget(), _fs->_functions.size() - 1, ftype == TK_FUNCTION?0:1); } void ClassExp() { SQInteger base = -1; SQInteger attrs = -1; if(_token == TK_EXTENDS) { Lex(); Expression(); base = _fs->TopTarget(); } if(_token == TK_ATTR_OPEN) { Lex(); _fs->AddInstruction(_OP_NEWOBJ, _fs->PushTarget(),0,NOT_TABLE); ParseTableOrClass(_SC(','),TK_ATTR_CLOSE); attrs = _fs->TopTarget(); } Expect(_SC('{')); if(attrs != -1) _fs->PopTarget(); if(base != -1) _fs->PopTarget(); _fs->AddInstruction(_OP_NEWOBJ, _fs->PushTarget(), base, attrs,NOT_CLASS); ParseTableOrClass(_SC(';'),_SC('}')); } void DeleteExpr() { SQExpState es; Lex(); es = _es; _es.donot_get = true; PrefixedExpr(); if(_es.etype==EXPR) Error(_SC("can't delete an expression")); if(_es.etype==OBJECT || _es.etype==BASE) { Emit2ArgsOP(_OP_DELETE); } else { Error(_SC("cannot delete an (outer) local")); } _es = es; } void PrefixIncDec(SQInteger token) { SQExpState es; SQInteger diff = (token==TK_MINUSMINUS) ? -1 : 1; Lex(); es = _es; _es.donot_get = true; PrefixedExpr(); if(_es.etype==EXPR) { Error(_SC("can't '++' or '--' an expression")); } else if(_es.etype==OBJECT || _es.etype==BASE) { Emit2ArgsOP(_OP_INC, diff); } else if(_es.etype==LOCAL) { SQInteger src = _fs->TopTarget(); _fs->AddInstruction(_OP_INCL, src, src, 0, diff); } else if(_es.etype==OUTER) { SQInteger tmp = _fs->PushTarget(); _fs->AddInstruction(_OP_GETOUTER, tmp, _es.epos); _fs->AddInstruction(_OP_INCL, tmp, tmp, 0, diff); _fs->AddInstruction(_OP_SETOUTER, tmp, _es.epos, tmp); } _es = es; } void CreateFunction(SQObject &name,bool lambda = false) { SQFuncState *funcstate = _fs->PushChildState(_ss(_vm)); funcstate->_name = name; SQObject paramname; funcstate->AddParameter(_fs->CreateString(_SC("this"))); funcstate->_sourcename = _sourcename; SQInteger defparams = 0; while(_token!=_SC(')')) { if(_token == TK_VARPARAMS) { if(defparams > 0) Error(_SC("function with default parameters cannot have variable number of parameters")); funcstate->AddParameter(_fs->CreateString(_SC("vargv"))); funcstate->_varparams = true; Lex(); if(_token != _SC(')')) Error(_SC("expected ')'")); break; } else { paramname = Expect(TK_IDENTIFIER); funcstate->AddParameter(paramname); if(_token == _SC('=')) { Lex(); Expression(); funcstate->AddDefaultParam(_fs->TopTarget()); defparams++; } else { if(defparams > 0) Error(_SC("expected '='")); } if(_token == _SC(',')) Lex(); else if(_token != _SC(')')) Error(_SC("expected ')' or ','")); } } Expect(_SC(')')); for(SQInteger n = 0; n < defparams; n++) { _fs->PopTarget(); } SQFuncState *currchunk = _fs; _fs = funcstate; if(lambda) { Expression(); _fs->AddInstruction(_OP_RETURN, 1, _fs->PopTarget());} else { Statement(false); } funcstate->AddLineInfos(_lex._prevtoken == _SC('\n')?_lex._lasttokenline:_lex._currentline, _lineinfo, true); funcstate->AddInstruction(_OP_RETURN, -1); funcstate->SetStackSize(0); SQFunctionProto *func = funcstate->BuildProto(); #ifdef _DEBUG_DUMP funcstate->Dump(func); #endif _fs = currchunk; _fs->_functions.push_back(func); _fs->PopChildState(); } void ResolveBreaks(SQFuncState *funcstate, SQInteger ntoresolve) { while(ntoresolve > 0) { SQInteger pos = funcstate->_unresolvedbreaks.back(); funcstate->_unresolvedbreaks.pop_back(); //set the jmp instruction funcstate->SetIntructionParams(pos, 0, funcstate->GetCurrentPos() - pos, 0); ntoresolve--; } } void ResolveContinues(SQFuncState *funcstate, SQInteger ntoresolve, SQInteger targetpos) { while(ntoresolve > 0) { SQInteger pos = funcstate->_unresolvedcontinues.back(); funcstate->_unresolvedcontinues.pop_back(); //set the jmp instruction funcstate->SetIntructionParams(pos, 0, targetpos - pos, 0); ntoresolve--; } } private: SQInteger _token; SQFuncState *_fs; SQObjectPtr _sourcename; SQLexer _lex; bool _lineinfo; bool _raiseerror; SQInteger _debugline; SQInteger _debugop; SQExpState _es; SQScope _scope; SQChar *compilererror; jmp_buf _errorjmp; SQVM *_vm; }; bool Compile(SQVM *vm,SQLEXREADFUNC rg, SQUserPointer up, const SQChar *sourcename, SQObjectPtr &out, bool raiseerror, bool lineinfo) { SQCompiler p(vm, rg, up, sourcename, raiseerror, lineinfo); return p.Compile(out); } #endif