1 //===-- X86AsmParser.cpp - Parse X86 assembly to MCInst instructions ------===// 2 // 3 // The LLVM Compiler Infrastructure 4 // 5 // This file is distributed under the University of Illinois Open Source 6 // License. See LICENSE.TXT for details. 7 // 8 //===----------------------------------------------------------------------===// 9 10 #include "MCTargetDesc/X86BaseInfo.h" 11 #include "llvm/ADT/APFloat.h" 12 #include "llvm/ADT/SmallString.h" 13 #include "llvm/ADT/SmallVector.h" 14 #include "llvm/ADT/StringSwitch.h" 15 #include "llvm/ADT/Twine.h" 16 #include "llvm/MC/MCContext.h" 17 #include "llvm/MC/MCExpr.h" 18 #include "llvm/MC/MCInst.h" 19 #include "llvm/MC/MCParser/MCAsmLexer.h" 20 #include "llvm/MC/MCParser/MCAsmParser.h" 21 #include "llvm/MC/MCParser/MCParsedAsmOperand.h" 22 #include "llvm/MC/MCRegisterInfo.h" 23 #include "llvm/MC/MCStreamer.h" 24 #include "llvm/MC/MCSubtargetInfo.h" 25 #include "llvm/MC/MCSymbol.h" 26 #include "llvm/MC/MCTargetAsmParser.h" 27 #include "llvm/Support/SourceMgr.h" 28 #include "llvm/Support/TargetRegistry.h" 29 #include "llvm/Support/raw_ostream.h" 30 31 using namespace llvm; 32 33 namespace { 34 struct X86Operand; 35 36 static const char OpPrecedence[] = { 37 0, // IC_PLUS 38 0, // IC_MINUS 39 1, // IC_MULTIPLY 40 1, // IC_DIVIDE 41 2, // IC_RPAREN 42 3, // IC_LPAREN 43 0, // IC_IMM 44 0 // IC_REGISTER 45 }; 46 47 class X86AsmParser : public MCTargetAsmParser { 48 MCSubtargetInfo &STI; 49 MCAsmParser &Parser; 50 ParseInstructionInfo *InstInfo; 51 private: 52 enum InfixCalculatorTok { 53 IC_PLUS = 0, 54 IC_MINUS, 55 IC_MULTIPLY, 56 IC_DIVIDE, 57 IC_RPAREN, 58 IC_LPAREN, 59 IC_IMM, 60 IC_REGISTER 61 }; 62 63 class InfixCalculator { 64 typedef std::pair< InfixCalculatorTok, int64_t > ICToken; 65 SmallVector<InfixCalculatorTok, 4> InfixOperatorStack; 66 SmallVector<ICToken, 4> PostfixStack; 67 68 public: 69 int64_t popOperand() { 70 assert (!PostfixStack.empty() && "Poped an empty stack!"); 71 ICToken Op = PostfixStack.pop_back_val(); 72 assert ((Op.first == IC_IMM || Op.first == IC_REGISTER) 73 && "Expected and immediate or register!"); 74 return Op.second; 75 } 76 void pushOperand(InfixCalculatorTok Op, int64_t Val = 0) { 77 assert ((Op == IC_IMM || Op == IC_REGISTER) && 78 "Unexpected operand!"); 79 PostfixStack.push_back(std::make_pair(Op, Val)); 80 } 81 82 void popOperator() { InfixOperatorStack.pop_back_val(); } 83 void pushOperator(InfixCalculatorTok Op) { 84 // Push the new operator if the stack is empty. 85 if (InfixOperatorStack.empty()) { 86 InfixOperatorStack.push_back(Op); 87 return; 88 } 89 90 // Push the new operator if it has a higher precedence than the operator 91 // on the top of the stack or the operator on the top of the stack is a 92 // left parentheses. 93 unsigned Idx = InfixOperatorStack.size() - 1; 94 InfixCalculatorTok StackOp = InfixOperatorStack[Idx]; 95 if (OpPrecedence[Op] > OpPrecedence[StackOp] || StackOp == IC_LPAREN) { 96 InfixOperatorStack.push_back(Op); 97 return; 98 } 99 100 // The operator on the top of the stack has higher precedence than the 101 // new operator. 102 unsigned ParenCount = 0; 103 while (1) { 104 // Nothing to process. 105 if (InfixOperatorStack.empty()) 106 break; 107 108 Idx = InfixOperatorStack.size() - 1; 109 StackOp = InfixOperatorStack[Idx]; 110 if (!(OpPrecedence[StackOp] >= OpPrecedence[Op] || ParenCount)) 111 break; 112 113 // If we have an even parentheses count and we see a left parentheses, 114 // then stop processing. 115 if (!ParenCount && StackOp == IC_LPAREN) 116 break; 117 118 if (StackOp == IC_RPAREN) { 119 ++ParenCount; 120 InfixOperatorStack.pop_back_val(); 121 } else if (StackOp == IC_LPAREN) { 122 --ParenCount; 123 InfixOperatorStack.pop_back_val(); 124 } else { 125 InfixOperatorStack.pop_back_val(); 126 PostfixStack.push_back(std::make_pair(StackOp, 0)); 127 } 128 } 129 // Push the new operator. 130 InfixOperatorStack.push_back(Op); 131 } 132 int64_t execute() { 133 // Push any remaining operators onto the postfix stack. 134 while (!InfixOperatorStack.empty()) { 135 InfixCalculatorTok StackOp = InfixOperatorStack.pop_back_val(); 136 if (StackOp != IC_LPAREN && StackOp != IC_RPAREN) 137 PostfixStack.push_back(std::make_pair(StackOp, 0)); 138 } 139 140 if (PostfixStack.empty()) 141 return 0; 142 143 SmallVector<ICToken, 16> OperandStack; 144 for (unsigned i = 0, e = PostfixStack.size(); i != e; ++i) { 145 ICToken Op = PostfixStack[i]; 146 if (Op.first == IC_IMM || Op.first == IC_REGISTER) { 147 OperandStack.push_back(Op); 148 } else { 149 assert (OperandStack.size() > 1 && "Too few operands."); 150 int64_t Val; 151 ICToken Op2 = OperandStack.pop_back_val(); 152 ICToken Op1 = OperandStack.pop_back_val(); 153 switch (Op.first) { 154 default: 155 report_fatal_error("Unexpected operator!"); 156 break; 157 case IC_PLUS: 158 Val = Op1.second + Op2.second; 159 OperandStack.push_back(std::make_pair(IC_IMM, Val)); 160 break; 161 case IC_MINUS: 162 Val = Op1.second - Op2.second; 163 OperandStack.push_back(std::make_pair(IC_IMM, Val)); 164 break; 165 case IC_MULTIPLY: 166 assert (Op1.first == IC_IMM && Op2.first == IC_IMM && 167 "Multiply operation with an immediate and a register!"); 168 Val = Op1.second * Op2.second; 169 OperandStack.push_back(std::make_pair(IC_IMM, Val)); 170 break; 171 case IC_DIVIDE: 172 assert (Op1.first == IC_IMM && Op2.first == IC_IMM && 173 "Divide operation with an immediate and a register!"); 174 assert (Op2.second != 0 && "Division by zero!"); 175 Val = Op1.second / Op2.second; 176 OperandStack.push_back(std::make_pair(IC_IMM, Val)); 177 break; 178 } 179 } 180 } 181 assert (OperandStack.size() == 1 && "Expected a single result."); 182 return OperandStack.pop_back_val().second; 183 } 184 }; 185 186 enum IntelExprState { 187 IES_PLUS, 188 IES_MINUS, 189 IES_MULTIPLY, 190 IES_DIVIDE, 191 IES_LBRAC, 192 IES_RBRAC, 193 IES_LPAREN, 194 IES_RPAREN, 195 IES_REGISTER, 196 IES_INTEGER, 197 IES_IDENTIFIER, 198 IES_ERROR 199 }; 200 201 class IntelExprStateMachine { 202 IntelExprState State, PrevState; 203 unsigned BaseReg, IndexReg, TmpReg, Scale; 204 int64_t Imm; 205 const MCExpr *Sym; 206 StringRef SymName; 207 bool StopOnLBrac, AddImmPrefix; 208 InfixCalculator IC; 209 InlineAsmIdentifierInfo Info; 210 public: 211 IntelExprStateMachine(int64_t imm, bool stoponlbrac, bool addimmprefix) : 212 State(IES_PLUS), PrevState(IES_ERROR), BaseReg(0), IndexReg(0), TmpReg(0), 213 Scale(1), Imm(imm), Sym(0), StopOnLBrac(stoponlbrac), 214 AddImmPrefix(addimmprefix) { Info.clear(); } 215 216 unsigned getBaseReg() { return BaseReg; } 217 unsigned getIndexReg() { return IndexReg; } 218 unsigned getScale() { return Scale; } 219 const MCExpr *getSym() { return Sym; } 220 StringRef getSymName() { return SymName; } 221 int64_t getImm() { return Imm + IC.execute(); } 222 bool isValidEndState() { 223 return State == IES_RBRAC || State == IES_INTEGER; 224 } 225 bool getStopOnLBrac() { return StopOnLBrac; } 226 bool getAddImmPrefix() { return AddImmPrefix; } 227 bool hadError() { return State == IES_ERROR; } 228 229 InlineAsmIdentifierInfo &getIdentifierInfo() { 230 return Info; 231 } 232 233 void onPlus() { 234 IntelExprState CurrState = State; 235 switch (State) { 236 default: 237 State = IES_ERROR; 238 break; 239 case IES_INTEGER: 240 case IES_RPAREN: 241 case IES_REGISTER: 242 State = IES_PLUS; 243 IC.pushOperator(IC_PLUS); 244 if (CurrState == IES_REGISTER && PrevState != IES_MULTIPLY) { 245 // If we already have a BaseReg, then assume this is the IndexReg with 246 // a scale of 1. 247 if (!BaseReg) { 248 BaseReg = TmpReg; 249 } else { 250 assert (!IndexReg && "BaseReg/IndexReg already set!"); 251 IndexReg = TmpReg; 252 Scale = 1; 253 } 254 } 255 break; 256 } 257 PrevState = CurrState; 258 } 259 void onMinus() { 260 IntelExprState CurrState = State; 261 switch (State) { 262 default: 263 State = IES_ERROR; 264 break; 265 case IES_PLUS: 266 case IES_MULTIPLY: 267 case IES_DIVIDE: 268 case IES_LPAREN: 269 case IES_RPAREN: 270 case IES_LBRAC: 271 case IES_RBRAC: 272 case IES_INTEGER: 273 case IES_REGISTER: 274 State = IES_MINUS; 275 // Only push the minus operator if it is not a unary operator. 276 if (!(CurrState == IES_PLUS || CurrState == IES_MINUS || 277 CurrState == IES_MULTIPLY || CurrState == IES_DIVIDE || 278 CurrState == IES_LPAREN || CurrState == IES_LBRAC)) 279 IC.pushOperator(IC_MINUS); 280 if (CurrState == IES_REGISTER && PrevState != IES_MULTIPLY) { 281 // If we already have a BaseReg, then assume this is the IndexReg with 282 // a scale of 1. 283 if (!BaseReg) { 284 BaseReg = TmpReg; 285 } else { 286 assert (!IndexReg && "BaseReg/IndexReg already set!"); 287 IndexReg = TmpReg; 288 Scale = 1; 289 } 290 } 291 break; 292 } 293 PrevState = CurrState; 294 } 295 void onRegister(unsigned Reg) { 296 IntelExprState CurrState = State; 297 switch (State) { 298 default: 299 State = IES_ERROR; 300 break; 301 case IES_PLUS: 302 case IES_LPAREN: 303 State = IES_REGISTER; 304 TmpReg = Reg; 305 IC.pushOperand(IC_REGISTER); 306 break; 307 case IES_MULTIPLY: 308 // Index Register - Scale * Register 309 if (PrevState == IES_INTEGER) { 310 assert (!IndexReg && "IndexReg already set!"); 311 State = IES_REGISTER; 312 IndexReg = Reg; 313 // Get the scale and replace the 'Scale * Register' with '0'. 314 Scale = IC.popOperand(); 315 IC.pushOperand(IC_IMM); 316 IC.popOperator(); 317 } else { 318 State = IES_ERROR; 319 } 320 break; 321 } 322 PrevState = CurrState; 323 } 324 void onIdentifierExpr(const MCExpr *SymRef, StringRef SymRefName) { 325 PrevState = State; 326 switch (State) { 327 default: 328 State = IES_ERROR; 329 break; 330 case IES_PLUS: 331 case IES_MINUS: 332 State = IES_INTEGER; 333 Sym = SymRef; 334 SymName = SymRefName; 335 IC.pushOperand(IC_IMM); 336 break; 337 } 338 } 339 void onInteger(int64_t TmpInt) { 340 IntelExprState CurrState = State; 341 switch (State) { 342 default: 343 State = IES_ERROR; 344 break; 345 case IES_PLUS: 346 case IES_MINUS: 347 case IES_DIVIDE: 348 case IES_MULTIPLY: 349 case IES_LPAREN: 350 State = IES_INTEGER; 351 if (PrevState == IES_REGISTER && CurrState == IES_MULTIPLY) { 352 // Index Register - Register * Scale 353 assert (!IndexReg && "IndexReg already set!"); 354 IndexReg = TmpReg; 355 Scale = TmpInt; 356 // Get the scale and replace the 'Register * Scale' with '0'. 357 IC.popOperator(); 358 } else if ((PrevState == IES_PLUS || PrevState == IES_MINUS || 359 PrevState == IES_MULTIPLY || PrevState == IES_DIVIDE || 360 PrevState == IES_LPAREN || PrevState == IES_LBRAC) && 361 CurrState == IES_MINUS) { 362 // Unary minus. No need to pop the minus operand because it was never 363 // pushed. 364 IC.pushOperand(IC_IMM, -TmpInt); // Push -Imm. 365 } else { 366 IC.pushOperand(IC_IMM, TmpInt); 367 } 368 break; 369 } 370 PrevState = CurrState; 371 } 372 void onStar() { 373 PrevState = State; 374 switch (State) { 375 default: 376 State = IES_ERROR; 377 break; 378 case IES_INTEGER: 379 case IES_REGISTER: 380 case IES_RPAREN: 381 State = IES_MULTIPLY; 382 IC.pushOperator(IC_MULTIPLY); 383 break; 384 } 385 } 386 void onDivide() { 387 PrevState = State; 388 switch (State) { 389 default: 390 State = IES_ERROR; 391 break; 392 case IES_INTEGER: 393 case IES_RPAREN: 394 State = IES_DIVIDE; 395 IC.pushOperator(IC_DIVIDE); 396 break; 397 } 398 } 399 void onLBrac() { 400 PrevState = State; 401 switch (State) { 402 default: 403 State = IES_ERROR; 404 break; 405 case IES_RBRAC: 406 State = IES_PLUS; 407 IC.pushOperator(IC_PLUS); 408 break; 409 } 410 } 411 void onRBrac() { 412 IntelExprState CurrState = State; 413 switch (State) { 414 default: 415 State = IES_ERROR; 416 break; 417 case IES_INTEGER: 418 case IES_REGISTER: 419 case IES_RPAREN: 420 State = IES_RBRAC; 421 if (CurrState == IES_REGISTER && PrevState != IES_MULTIPLY) { 422 // If we already have a BaseReg, then assume this is the IndexReg with 423 // a scale of 1. 424 if (!BaseReg) { 425 BaseReg = TmpReg; 426 } else { 427 assert (!IndexReg && "BaseReg/IndexReg already set!"); 428 IndexReg = TmpReg; 429 Scale = 1; 430 } 431 } 432 break; 433 } 434 PrevState = CurrState; 435 } 436 void onLParen() { 437 IntelExprState CurrState = State; 438 switch (State) { 439 default: 440 State = IES_ERROR; 441 break; 442 case IES_PLUS: 443 case IES_MINUS: 444 case IES_MULTIPLY: 445 case IES_DIVIDE: 446 case IES_LPAREN: 447 // FIXME: We don't handle this type of unary minus, yet. 448 if ((PrevState == IES_PLUS || PrevState == IES_MINUS || 449 PrevState == IES_MULTIPLY || PrevState == IES_DIVIDE || 450 PrevState == IES_LPAREN || PrevState == IES_LBRAC) && 451 CurrState == IES_MINUS) { 452 State = IES_ERROR; 453 break; 454 } 455 State = IES_LPAREN; 456 IC.pushOperator(IC_LPAREN); 457 break; 458 } 459 PrevState = CurrState; 460 } 461 void onRParen() { 462 PrevState = State; 463 switch (State) { 464 default: 465 State = IES_ERROR; 466 break; 467 case IES_INTEGER: 468 case IES_REGISTER: 469 case IES_RPAREN: 470 State = IES_RPAREN; 471 IC.pushOperator(IC_RPAREN); 472 break; 473 } 474 } 475 }; 476 477 MCAsmParser &getParser() const { return Parser; } 478 479 MCAsmLexer &getLexer() const { return Parser.getLexer(); } 480 481 bool Error(SMLoc L, const Twine &Msg, 482 ArrayRef<SMRange> Ranges = None, 483 bool MatchingInlineAsm = false) { 484 if (MatchingInlineAsm) return true; 485 return Parser.Error(L, Msg, Ranges); 486 } 487 488 X86Operand *ErrorOperand(SMLoc Loc, StringRef Msg) { 489 Error(Loc, Msg); 490 return 0; 491 } 492 493 X86Operand *ParseOperand(); 494 X86Operand *ParseATTOperand(); 495 X86Operand *ParseIntelOperand(); 496 X86Operand *ParseIntelOffsetOfOperator(); 497 X86Operand *ParseIntelDotOperator(const MCExpr *Disp, const MCExpr *&NewDisp); 498 X86Operand *ParseIntelOperator(unsigned OpKind); 499 X86Operand *ParseIntelMemOperand(unsigned SegReg, int64_t ImmDisp, 500 SMLoc StartLoc); 501 X86Operand *ParseIntelExpression(IntelExprStateMachine &SM, SMLoc &End); 502 X86Operand *ParseIntelBracExpression(unsigned SegReg, SMLoc Start, 503 int64_t ImmDisp, unsigned Size); 504 X86Operand *ParseIntelIdentifier(const MCExpr *&Val, StringRef &Identifier, 505 InlineAsmIdentifierInfo &Info, 506 bool IsUnevaluatedOperand, SMLoc &End); 507 508 X86Operand *ParseMemOperand(unsigned SegReg, SMLoc StartLoc); 509 510 X86Operand *CreateMemForInlineAsm(unsigned SegReg, const MCExpr *Disp, 511 unsigned BaseReg, unsigned IndexReg, 512 unsigned Scale, SMLoc Start, SMLoc End, 513 unsigned Size, StringRef Identifier, 514 InlineAsmIdentifierInfo &Info); 515 516 bool ParseDirectiveWord(unsigned Size, SMLoc L); 517 bool ParseDirectiveCode(StringRef IDVal, SMLoc L); 518 519 bool processInstruction(MCInst &Inst, 520 const SmallVectorImpl<MCParsedAsmOperand*> &Ops); 521 522 bool MatchAndEmitInstruction(SMLoc IDLoc, unsigned &Opcode, 523 SmallVectorImpl<MCParsedAsmOperand*> &Operands, 524 MCStreamer &Out, unsigned &ErrorInfo, 525 bool MatchingInlineAsm); 526 527 /// isSrcOp - Returns true if operand is either (%rsi) or %ds:%(rsi) 528 /// in 64bit mode or (%esi) or %es:(%esi) in 32bit mode. 529 bool isSrcOp(X86Operand &Op); 530 531 /// isDstOp - Returns true if operand is either (%rdi) or %es:(%rdi) 532 /// in 64bit mode or (%edi) or %es:(%edi) in 32bit mode. 533 bool isDstOp(X86Operand &Op); 534 535 bool is64BitMode() const { 536 // FIXME: Can tablegen auto-generate this? 537 return (STI.getFeatureBits() & X86::Mode64Bit) != 0; 538 } 539 void SwitchMode() { 540 unsigned FB = ComputeAvailableFeatures(STI.ToggleFeature(X86::Mode64Bit)); 541 setAvailableFeatures(FB); 542 } 543 544 bool isParsingIntelSyntax() { 545 return getParser().getAssemblerDialect(); 546 } 547 548 /// @name Auto-generated Matcher Functions 549 /// { 550 551 #define GET_ASSEMBLER_HEADER 552 #include "X86GenAsmMatcher.inc" 553 554 /// } 555 556 public: 557 X86AsmParser(MCSubtargetInfo &sti, MCAsmParser &parser) 558 : MCTargetAsmParser(), STI(sti), Parser(parser), InstInfo(0) { 559 560 // Initialize the set of available features. 561 setAvailableFeatures(ComputeAvailableFeatures(STI.getFeatureBits())); 562 } 563 virtual bool ParseRegister(unsigned &RegNo, SMLoc &StartLoc, SMLoc &EndLoc); 564 565 virtual bool ParseInstruction(ParseInstructionInfo &Info, StringRef Name, 566 SMLoc NameLoc, 567 SmallVectorImpl<MCParsedAsmOperand*> &Operands); 568 569 virtual bool ParseDirective(AsmToken DirectiveID); 570 }; 571 } // end anonymous namespace 572 573 /// @name Auto-generated Match Functions 574 /// { 575 576 static unsigned MatchRegisterName(StringRef Name); 577 578 /// } 579 580 static bool isImmSExti16i8Value(uint64_t Value) { 581 return (( Value <= 0x000000000000007FULL)|| 582 (0x000000000000FF80ULL <= Value && Value <= 0x000000000000FFFFULL)|| 583 (0xFFFFFFFFFFFFFF80ULL <= Value && Value <= 0xFFFFFFFFFFFFFFFFULL)); 584 } 585 586 static bool isImmSExti32i8Value(uint64_t Value) { 587 return (( Value <= 0x000000000000007FULL)|| 588 (0x00000000FFFFFF80ULL <= Value && Value <= 0x00000000FFFFFFFFULL)|| 589 (0xFFFFFFFFFFFFFF80ULL <= Value && Value <= 0xFFFFFFFFFFFFFFFFULL)); 590 } 591 592 static bool isImmZExtu32u8Value(uint64_t Value) { 593 return (Value <= 0x00000000000000FFULL); 594 } 595 596 static bool isImmSExti64i8Value(uint64_t Value) { 597 return (( Value <= 0x000000000000007FULL)|| 598 (0xFFFFFFFFFFFFFF80ULL <= Value && Value <= 0xFFFFFFFFFFFFFFFFULL)); 599 } 600 601 static bool isImmSExti64i32Value(uint64_t Value) { 602 return (( Value <= 0x000000007FFFFFFFULL)|| 603 (0xFFFFFFFF80000000ULL <= Value && Value <= 0xFFFFFFFFFFFFFFFFULL)); 604 } 605 namespace { 606 607 /// X86Operand - Instances of this class represent a parsed X86 machine 608 /// instruction. 609 struct X86Operand : public MCParsedAsmOperand { 610 enum KindTy { 611 Token, 612 Register, 613 Immediate, 614 Memory 615 } Kind; 616 617 SMLoc StartLoc, EndLoc; 618 SMLoc OffsetOfLoc; 619 StringRef SymName; 620 void *OpDecl; 621 bool AddressOf; 622 623 struct TokOp { 624 const char *Data; 625 unsigned Length; 626 }; 627 628 struct RegOp { 629 unsigned RegNo; 630 }; 631 632 struct ImmOp { 633 const MCExpr *Val; 634 }; 635 636 struct MemOp { 637 unsigned SegReg; 638 const MCExpr *Disp; 639 unsigned BaseReg; 640 unsigned IndexReg; 641 unsigned Scale; 642 unsigned Size; 643 }; 644 645 union { 646 struct TokOp Tok; 647 struct RegOp Reg; 648 struct ImmOp Imm; 649 struct MemOp Mem; 650 }; 651 652 X86Operand(KindTy K, SMLoc Start, SMLoc End) 653 : Kind(K), StartLoc(Start), EndLoc(End) {} 654 655 StringRef getSymName() { return SymName; } 656 void *getOpDecl() { return OpDecl; } 657 658 /// getStartLoc - Get the location of the first token of this operand. 659 SMLoc getStartLoc() const { return StartLoc; } 660 /// getEndLoc - Get the location of the last token of this operand. 661 SMLoc getEndLoc() const { return EndLoc; } 662 /// getLocRange - Get the range between the first and last token of this 663 /// operand. 664 SMRange getLocRange() const { return SMRange(StartLoc, EndLoc); } 665 /// getOffsetOfLoc - Get the location of the offset operator. 666 SMLoc getOffsetOfLoc() const { return OffsetOfLoc; } 667 668 virtual void print(raw_ostream &OS) const {} 669 670 StringRef getToken() const { 671 assert(Kind == Token && "Invalid access!"); 672 return StringRef(Tok.Data, Tok.Length); 673 } 674 void setTokenValue(StringRef Value) { 675 assert(Kind == Token && "Invalid access!"); 676 Tok.Data = Value.data(); 677 Tok.Length = Value.size(); 678 } 679 680 unsigned getReg() const { 681 assert(Kind == Register && "Invalid access!"); 682 return Reg.RegNo; 683 } 684 685 const MCExpr *getImm() const { 686 assert(Kind == Immediate && "Invalid access!"); 687 return Imm.Val; 688 } 689 690 const MCExpr *getMemDisp() const { 691 assert(Kind == Memory && "Invalid access!"); 692 return Mem.Disp; 693 } 694 unsigned getMemSegReg() const { 695 assert(Kind == Memory && "Invalid access!"); 696 return Mem.SegReg; 697 } 698 unsigned getMemBaseReg() const { 699 assert(Kind == Memory && "Invalid access!"); 700 return Mem.BaseReg; 701 } 702 unsigned getMemIndexReg() const { 703 assert(Kind == Memory && "Invalid access!"); 704 return Mem.IndexReg; 705 } 706 unsigned getMemScale() const { 707 assert(Kind == Memory && "Invalid access!"); 708 return Mem.Scale; 709 } 710 711 bool isToken() const {return Kind == Token; } 712 713 bool isImm() const { return Kind == Immediate; } 714 715 bool isImmSExti16i8() const { 716 if (!isImm()) 717 return false; 718 719 // If this isn't a constant expr, just assume it fits and let relaxation 720 // handle it. 721 const MCConstantExpr *CE = dyn_cast<MCConstantExpr>(getImm()); 722 if (!CE) 723 return true; 724 725 // Otherwise, check the value is in a range that makes sense for this 726 // extension. 727 return isImmSExti16i8Value(CE->getValue()); 728 } 729 bool isImmSExti32i8() const { 730 if (!isImm()) 731 return false; 732 733 // If this isn't a constant expr, just assume it fits and let relaxation 734 // handle it. 735 const MCConstantExpr *CE = dyn_cast<MCConstantExpr>(getImm()); 736 if (!CE) 737 return true; 738 739 // Otherwise, check the value is in a range that makes sense for this 740 // extension. 741 return isImmSExti32i8Value(CE->getValue()); 742 } 743 bool isImmZExtu32u8() const { 744 if (!isImm()) 745 return false; 746 747 // If this isn't a constant expr, just assume it fits and let relaxation 748 // handle it. 749 const MCConstantExpr *CE = dyn_cast<MCConstantExpr>(getImm()); 750 if (!CE) 751 return true; 752 753 // Otherwise, check the value is in a range that makes sense for this 754 // extension. 755 return isImmZExtu32u8Value(CE->getValue()); 756 } 757 bool isImmSExti64i8() const { 758 if (!isImm()) 759 return false; 760 761 // If this isn't a constant expr, just assume it fits and let relaxation 762 // handle it. 763 const MCConstantExpr *CE = dyn_cast<MCConstantExpr>(getImm()); 764 if (!CE) 765 return true; 766 767 // Otherwise, check the value is in a range that makes sense for this 768 // extension. 769 return isImmSExti64i8Value(CE->getValue()); 770 } 771 bool isImmSExti64i32() const { 772 if (!isImm()) 773 return false; 774 775 // If this isn't a constant expr, just assume it fits and let relaxation 776 // handle it. 777 const MCConstantExpr *CE = dyn_cast<MCConstantExpr>(getImm()); 778 if (!CE) 779 return true; 780 781 // Otherwise, check the value is in a range that makes sense for this 782 // extension. 783 return isImmSExti64i32Value(CE->getValue()); 784 } 785 786 bool isOffsetOf() const { 787 return OffsetOfLoc.getPointer(); 788 } 789 790 bool needAddressOf() const { 791 return AddressOf; 792 } 793 794 bool isMem() const { return Kind == Memory; } 795 bool isMem8() const { 796 return Kind == Memory && (!Mem.Size || Mem.Size == 8); 797 } 798 bool isMem16() const { 799 return Kind == Memory && (!Mem.Size || Mem.Size == 16); 800 } 801 bool isMem32() const { 802 return Kind == Memory && (!Mem.Size || Mem.Size == 32); 803 } 804 bool isMem64() const { 805 return Kind == Memory && (!Mem.Size || Mem.Size == 64); 806 } 807 bool isMem80() const { 808 return Kind == Memory && (!Mem.Size || Mem.Size == 80); 809 } 810 bool isMem128() const { 811 return Kind == Memory && (!Mem.Size || Mem.Size == 128); 812 } 813 bool isMem256() const { 814 return Kind == Memory && (!Mem.Size || Mem.Size == 256); 815 } 816 817 bool isMemVX32() const { 818 return Kind == Memory && (!Mem.Size || Mem.Size == 32) && 819 getMemIndexReg() >= X86::XMM0 && getMemIndexReg() <= X86::XMM15; 820 } 821 bool isMemVY32() const { 822 return Kind == Memory && (!Mem.Size || Mem.Size == 32) && 823 getMemIndexReg() >= X86::YMM0 && getMemIndexReg() <= X86::YMM15; 824 } 825 bool isMemVX64() const { 826 return Kind == Memory && (!Mem.Size || Mem.Size == 64) && 827 getMemIndexReg() >= X86::XMM0 && getMemIndexReg() <= X86::XMM15; 828 } 829 bool isMemVY64() const { 830 return Kind == Memory && (!Mem.Size || Mem.Size == 64) && 831 getMemIndexReg() >= X86::YMM0 && getMemIndexReg() <= X86::YMM15; 832 } 833 834 bool isAbsMem() const { 835 return Kind == Memory && !getMemSegReg() && !getMemBaseReg() && 836 !getMemIndexReg() && getMemScale() == 1; 837 } 838 839 bool isReg() const { return Kind == Register; } 840 841 void addExpr(MCInst &Inst, const MCExpr *Expr) const { 842 // Add as immediates when possible. 843 if (const MCConstantExpr *CE = dyn_cast<MCConstantExpr>(Expr)) 844 Inst.addOperand(MCOperand::CreateImm(CE->getValue())); 845 else 846 Inst.addOperand(MCOperand::CreateExpr(Expr)); 847 } 848 849 void addRegOperands(MCInst &Inst, unsigned N) const { 850 assert(N == 1 && "Invalid number of operands!"); 851 Inst.addOperand(MCOperand::CreateReg(getReg())); 852 } 853 854 void addImmOperands(MCInst &Inst, unsigned N) const { 855 assert(N == 1 && "Invalid number of operands!"); 856 addExpr(Inst, getImm()); 857 } 858 859 void addMem8Operands(MCInst &Inst, unsigned N) const { 860 addMemOperands(Inst, N); 861 } 862 void addMem16Operands(MCInst &Inst, unsigned N) const { 863 addMemOperands(Inst, N); 864 } 865 void addMem32Operands(MCInst &Inst, unsigned N) const { 866 addMemOperands(Inst, N); 867 } 868 void addMem64Operands(MCInst &Inst, unsigned N) const { 869 addMemOperands(Inst, N); 870 } 871 void addMem80Operands(MCInst &Inst, unsigned N) const { 872 addMemOperands(Inst, N); 873 } 874 void addMem128Operands(MCInst &Inst, unsigned N) const { 875 addMemOperands(Inst, N); 876 } 877 void addMem256Operands(MCInst &Inst, unsigned N) const { 878 addMemOperands(Inst, N); 879 } 880 void addMemVX32Operands(MCInst &Inst, unsigned N) const { 881 addMemOperands(Inst, N); 882 } 883 void addMemVY32Operands(MCInst &Inst, unsigned N) const { 884 addMemOperands(Inst, N); 885 } 886 void addMemVX64Operands(MCInst &Inst, unsigned N) const { 887 addMemOperands(Inst, N); 888 } 889 void addMemVY64Operands(MCInst &Inst, unsigned N) const { 890 addMemOperands(Inst, N); 891 } 892 893 void addMemOperands(MCInst &Inst, unsigned N) const { 894 assert((N == 5) && "Invalid number of operands!"); 895 Inst.addOperand(MCOperand::CreateReg(getMemBaseReg())); 896 Inst.addOperand(MCOperand::CreateImm(getMemScale())); 897 Inst.addOperand(MCOperand::CreateReg(getMemIndexReg())); 898 addExpr(Inst, getMemDisp()); 899 Inst.addOperand(MCOperand::CreateReg(getMemSegReg())); 900 } 901 902 void addAbsMemOperands(MCInst &Inst, unsigned N) const { 903 assert((N == 1) && "Invalid number of operands!"); 904 // Add as immediates when possible. 905 if (const MCConstantExpr *CE = dyn_cast<MCConstantExpr>(getMemDisp())) 906 Inst.addOperand(MCOperand::CreateImm(CE->getValue())); 907 else 908 Inst.addOperand(MCOperand::CreateExpr(getMemDisp())); 909 } 910 911 static X86Operand *CreateToken(StringRef Str, SMLoc Loc) { 912 SMLoc EndLoc = SMLoc::getFromPointer(Loc.getPointer() + Str.size()); 913 X86Operand *Res = new X86Operand(Token, Loc, EndLoc); 914 Res->Tok.Data = Str.data(); 915 Res->Tok.Length = Str.size(); 916 return Res; 917 } 918 919 static X86Operand *CreateReg(unsigned RegNo, SMLoc StartLoc, SMLoc EndLoc, 920 bool AddressOf = false, 921 SMLoc OffsetOfLoc = SMLoc(), 922 StringRef SymName = StringRef(), 923 void *OpDecl = 0) { 924 X86Operand *Res = new X86Operand(Register, StartLoc, EndLoc); 925 Res->Reg.RegNo = RegNo; 926 Res->AddressOf = AddressOf; 927 Res->OffsetOfLoc = OffsetOfLoc; 928 Res->SymName = SymName; 929 Res->OpDecl = OpDecl; 930 return Res; 931 } 932 933 static X86Operand *CreateImm(const MCExpr *Val, SMLoc StartLoc, SMLoc EndLoc){ 934 X86Operand *Res = new X86Operand(Immediate, StartLoc, EndLoc); 935 Res->Imm.Val = Val; 936 return Res; 937 } 938 939 /// Create an absolute memory operand. 940 static X86Operand *CreateMem(const MCExpr *Disp, SMLoc StartLoc, SMLoc EndLoc, 941 unsigned Size = 0, StringRef SymName = StringRef(), 942 void *OpDecl = 0) { 943 X86Operand *Res = new X86Operand(Memory, StartLoc, EndLoc); 944 Res->Mem.SegReg = 0; 945 Res->Mem.Disp = Disp; 946 Res->Mem.BaseReg = 0; 947 Res->Mem.IndexReg = 0; 948 Res->Mem.Scale = 1; 949 Res->Mem.Size = Size; 950 Res->SymName = SymName; 951 Res->OpDecl = OpDecl; 952 Res->AddressOf = false; 953 return Res; 954 } 955 956 /// Create a generalized memory operand. 957 static X86Operand *CreateMem(unsigned SegReg, const MCExpr *Disp, 958 unsigned BaseReg, unsigned IndexReg, 959 unsigned Scale, SMLoc StartLoc, SMLoc EndLoc, 960 unsigned Size = 0, 961 StringRef SymName = StringRef(), 962 void *OpDecl = 0) { 963 // We should never just have a displacement, that should be parsed as an 964 // absolute memory operand. 965 assert((SegReg || BaseReg || IndexReg) && "Invalid memory operand!"); 966 967 // The scale should always be one of {1,2,4,8}. 968 assert(((Scale == 1 || Scale == 2 || Scale == 4 || Scale == 8)) && 969 "Invalid scale!"); 970 X86Operand *Res = new X86Operand(Memory, StartLoc, EndLoc); 971 Res->Mem.SegReg = SegReg; 972 Res->Mem.Disp = Disp; 973 Res->Mem.BaseReg = BaseReg; 974 Res->Mem.IndexReg = IndexReg; 975 Res->Mem.Scale = Scale; 976 Res->Mem.Size = Size; 977 Res->SymName = SymName; 978 Res->OpDecl = OpDecl; 979 Res->AddressOf = false; 980 return Res; 981 } 982 }; 983 984 } // end anonymous namespace. 985 986 bool X86AsmParser::isSrcOp(X86Operand &Op) { 987 unsigned basereg = is64BitMode() ? X86::RSI : X86::ESI; 988 989 return (Op.isMem() && 990 (Op.Mem.SegReg == 0 || Op.Mem.SegReg == X86::DS) && 991 isa<MCConstantExpr>(Op.Mem.Disp) && 992 cast<MCConstantExpr>(Op.Mem.Disp)->getValue() == 0 && 993 Op.Mem.BaseReg == basereg && Op.Mem.IndexReg == 0); 994 } 995 996 bool X86AsmParser::isDstOp(X86Operand &Op) { 997 unsigned basereg = is64BitMode() ? X86::RDI : X86::EDI; 998 999 return Op.isMem() && 1000 (Op.Mem.SegReg == 0 || Op.Mem.SegReg == X86::ES) && 1001 isa<MCConstantExpr>(Op.Mem.Disp) && 1002 cast<MCConstantExpr>(Op.Mem.Disp)->getValue() == 0 && 1003 Op.Mem.BaseReg == basereg && Op.Mem.IndexReg == 0; 1004 } 1005 1006 bool X86AsmParser::ParseRegister(unsigned &RegNo, 1007 SMLoc &StartLoc, SMLoc &EndLoc) { 1008 RegNo = 0; 1009 const AsmToken &PercentTok = Parser.getTok(); 1010 StartLoc = PercentTok.getLoc(); 1011 1012 // If we encounter a %, ignore it. This code handles registers with and 1013 // without the prefix, unprefixed registers can occur in cfi directives. 1014 if (!isParsingIntelSyntax() && PercentTok.is(AsmToken::Percent)) 1015 Parser.Lex(); // Eat percent token. 1016 1017 const AsmToken &Tok = Parser.getTok(); 1018 EndLoc = Tok.getEndLoc(); 1019 1020 if (Tok.isNot(AsmToken::Identifier)) { 1021 if (isParsingIntelSyntax()) return true; 1022 return Error(StartLoc, "invalid register name", 1023 SMRange(StartLoc, EndLoc)); 1024 } 1025 1026 RegNo = MatchRegisterName(Tok.getString()); 1027 1028 // If the match failed, try the register name as lowercase. 1029 if (RegNo == 0) 1030 RegNo = MatchRegisterName(Tok.getString().lower()); 1031 1032 if (!is64BitMode()) { 1033 // FIXME: This should be done using Requires<In32BitMode> and 1034 // Requires<In64BitMode> so "eiz" usage in 64-bit instructions can be also 1035 // checked. 1036 // FIXME: Check AH, CH, DH, BH cannot be used in an instruction requiring a 1037 // REX prefix. 1038 if (RegNo == X86::RIZ || 1039 X86MCRegisterClasses[X86::GR64RegClassID].contains(RegNo) || 1040 X86II::isX86_64NonExtLowByteReg(RegNo) || 1041 X86II::isX86_64ExtendedReg(RegNo)) 1042 return Error(StartLoc, "register %" 1043 + Tok.getString() + " is only available in 64-bit mode", 1044 SMRange(StartLoc, EndLoc)); 1045 } 1046 1047 // Parse "%st" as "%st(0)" and "%st(1)", which is multiple tokens. 1048 if (RegNo == 0 && (Tok.getString() == "st" || Tok.getString() == "ST")) { 1049 RegNo = X86::ST0; 1050 Parser.Lex(); // Eat 'st' 1051 1052 // Check to see if we have '(4)' after %st. 1053 if (getLexer().isNot(AsmToken::LParen)) 1054 return false; 1055 // Lex the paren. 1056 getParser().Lex(); 1057 1058 const AsmToken &IntTok = Parser.getTok(); 1059 if (IntTok.isNot(AsmToken::Integer)) 1060 return Error(IntTok.getLoc(), "expected stack index"); 1061 switch (IntTok.getIntVal()) { 1062 case 0: RegNo = X86::ST0; break; 1063 case 1: RegNo = X86::ST1; break; 1064 case 2: RegNo = X86::ST2; break; 1065 case 3: RegNo = X86::ST3; break; 1066 case 4: RegNo = X86::ST4; break; 1067 case 5: RegNo = X86::ST5; break; 1068 case 6: RegNo = X86::ST6; break; 1069 case 7: RegNo = X86::ST7; break; 1070 default: return Error(IntTok.getLoc(), "invalid stack index"); 1071 } 1072 1073 if (getParser().Lex().isNot(AsmToken::RParen)) 1074 return Error(Parser.getTok().getLoc(), "expected ')'"); 1075 1076 EndLoc = Parser.getTok().getEndLoc(); 1077 Parser.Lex(); // Eat ')' 1078 return false; 1079 } 1080 1081 EndLoc = Parser.getTok().getEndLoc(); 1082 1083 // If this is "db[0-7]", match it as an alias 1084 // for dr[0-7]. 1085 if (RegNo == 0 && Tok.getString().size() == 3 && 1086 Tok.getString().startswith("db")) { 1087 switch (Tok.getString()[2]) { 1088 case '0': RegNo = X86::DR0; break; 1089 case '1': RegNo = X86::DR1; break; 1090 case '2': RegNo = X86::DR2; break; 1091 case '3': RegNo = X86::DR3; break; 1092 case '4': RegNo = X86::DR4; break; 1093 case '5': RegNo = X86::DR5; break; 1094 case '6': RegNo = X86::DR6; break; 1095 case '7': RegNo = X86::DR7; break; 1096 } 1097 1098 if (RegNo != 0) { 1099 EndLoc = Parser.getTok().getEndLoc(); 1100 Parser.Lex(); // Eat it. 1101 return false; 1102 } 1103 } 1104 1105 if (RegNo == 0) { 1106 if (isParsingIntelSyntax()) return true; 1107 return Error(StartLoc, "invalid register name", 1108 SMRange(StartLoc, EndLoc)); 1109 } 1110 1111 Parser.Lex(); // Eat identifier token. 1112 return false; 1113 } 1114 1115 X86Operand *X86AsmParser::ParseOperand() { 1116 if (isParsingIntelSyntax()) 1117 return ParseIntelOperand(); 1118 return ParseATTOperand(); 1119 } 1120 1121 /// getIntelMemOperandSize - Return intel memory operand size. 1122 static unsigned getIntelMemOperandSize(StringRef OpStr) { 1123 unsigned Size = StringSwitch<unsigned>(OpStr) 1124 .Cases("BYTE", "byte", 8) 1125 .Cases("WORD", "word", 16) 1126 .Cases("DWORD", "dword", 32) 1127 .Cases("QWORD", "qword", 64) 1128 .Cases("XWORD", "xword", 80) 1129 .Cases("XMMWORD", "xmmword", 128) 1130 .Cases("YMMWORD", "ymmword", 256) 1131 .Default(0); 1132 return Size; 1133 } 1134 1135 X86Operand * 1136 X86AsmParser::CreateMemForInlineAsm(unsigned SegReg, const MCExpr *Disp, 1137 unsigned BaseReg, unsigned IndexReg, 1138 unsigned Scale, SMLoc Start, SMLoc End, 1139 unsigned Size, StringRef Identifier, 1140 InlineAsmIdentifierInfo &Info){ 1141 if (isa<MCSymbolRefExpr>(Disp)) { 1142 // If this is not a VarDecl then assume it is a FuncDecl or some other label 1143 // reference. We need an 'r' constraint here, so we need to create register 1144 // operand to ensure proper matching. Just pick a GPR based on the size of 1145 // a pointer. 1146 if (!Info.IsVarDecl) { 1147 unsigned RegNo = is64BitMode() ? X86::RBX : X86::EBX; 1148 return X86Operand::CreateReg(RegNo, Start, End, /*AddressOf=*/true, 1149 SMLoc(), Identifier, Info.OpDecl); 1150 } 1151 if (!Size) { 1152 Size = Info.Type * 8; // Size is in terms of bits in this context. 1153 if (Size) 1154 InstInfo->AsmRewrites->push_back(AsmRewrite(AOK_SizeDirective, Start, 1155 /*Len=*/0, Size)); 1156 } 1157 } 1158 1159 // When parsing inline assembly we set the base register to a non-zero value 1160 // if we don't know the actual value at this time. This is necessary to 1161 // get the matching correct in some cases. 1162 BaseReg = BaseReg ? BaseReg : 1; 1163 return X86Operand::CreateMem(SegReg, Disp, BaseReg, IndexReg, Scale, Start, 1164 End, Size, Identifier, Info.OpDecl); 1165 } 1166 1167 static void 1168 RewriteIntelBracExpression(SmallVectorImpl<AsmRewrite> *AsmRewrites, 1169 StringRef SymName, int64_t ImmDisp, 1170 int64_t FinalImmDisp, SMLoc &BracLoc, 1171 SMLoc &StartInBrac, SMLoc &End) { 1172 // Remove the '[' and ']' from the IR string. 1173 AsmRewrites->push_back(AsmRewrite(AOK_Skip, BracLoc, 1)); 1174 AsmRewrites->push_back(AsmRewrite(AOK_Skip, End, 1)); 1175 1176 // If ImmDisp is non-zero, then we parsed a displacement before the 1177 // bracketed expression (i.e., ImmDisp [ BaseReg + Scale*IndexReg + Disp]) 1178 // If ImmDisp doesn't match the displacement computed by the state machine 1179 // then we have an additional displacement in the bracketed expression. 1180 if (ImmDisp != FinalImmDisp) { 1181 if (ImmDisp) { 1182 // We have an immediate displacement before the bracketed expression. 1183 // Adjust this to match the final immediate displacement. 1184 bool Found = false; 1185 for (SmallVectorImpl<AsmRewrite>::iterator I = AsmRewrites->begin(), 1186 E = AsmRewrites->end(); I != E; ++I) { 1187 if ((*I).Loc.getPointer() > BracLoc.getPointer()) 1188 continue; 1189 if ((*I).Kind == AOK_ImmPrefix || (*I).Kind == AOK_Imm) { 1190 assert (!Found && "ImmDisp already rewritten."); 1191 (*I).Kind = AOK_Imm; 1192 (*I).Len = BracLoc.getPointer() - (*I).Loc.getPointer(); 1193 (*I).Val = FinalImmDisp; 1194 Found = true; 1195 break; 1196 } 1197 } 1198 assert (Found && "Unable to rewrite ImmDisp."); 1199 } else { 1200 // We have a symbolic and an immediate displacement, but no displacement 1201 // before the bracketed expression. Put the immediate displacement 1202 // before the bracketed expression. 1203 AsmRewrites->push_back(AsmRewrite(AOK_Imm, BracLoc, 0, FinalImmDisp)); 1204 } 1205 } 1206 // Remove all the ImmPrefix rewrites within the brackets. 1207 for (SmallVectorImpl<AsmRewrite>::iterator I = AsmRewrites->begin(), 1208 E = AsmRewrites->end(); I != E; ++I) { 1209 if ((*I).Loc.getPointer() < StartInBrac.getPointer()) 1210 continue; 1211 if ((*I).Kind == AOK_ImmPrefix) 1212 (*I).Kind = AOK_Delete; 1213 } 1214 const char *SymLocPtr = SymName.data(); 1215 // Skip everything before the symbol. 1216 if (unsigned Len = SymLocPtr - StartInBrac.getPointer()) { 1217 assert(Len > 0 && "Expected a non-negative length."); 1218 AsmRewrites->push_back(AsmRewrite(AOK_Skip, StartInBrac, Len)); 1219 } 1220 // Skip everything after the symbol. 1221 if (unsigned Len = End.getPointer() - (SymLocPtr + SymName.size())) { 1222 SMLoc Loc = SMLoc::getFromPointer(SymLocPtr + SymName.size()); 1223 assert(Len > 0 && "Expected a non-negative length."); 1224 AsmRewrites->push_back(AsmRewrite(AOK_Skip, Loc, Len)); 1225 } 1226 } 1227 1228 X86Operand * 1229 X86AsmParser::ParseIntelExpression(IntelExprStateMachine &SM, SMLoc &End) { 1230 const AsmToken &Tok = Parser.getTok(); 1231 1232 bool Done = false; 1233 while (!Done) { 1234 bool UpdateLocLex = true; 1235 1236 // The period in the dot operator (e.g., [ebx].foo.bar) is parsed as an 1237 // identifier. Don't try an parse it as a register. 1238 if (Tok.getString().startswith(".")) 1239 break; 1240 1241 // If we're parsing an immediate expression, we don't expect a '['. 1242 if (SM.getStopOnLBrac() && getLexer().getKind() == AsmToken::LBrac) 1243 break; 1244 1245 switch (getLexer().getKind()) { 1246 default: { 1247 if (SM.isValidEndState()) { 1248 Done = true; 1249 break; 1250 } 1251 return ErrorOperand(Tok.getLoc(), "Unexpected token!"); 1252 } 1253 case AsmToken::EndOfStatement: { 1254 Done = true; 1255 break; 1256 } 1257 case AsmToken::Identifier: { 1258 // This could be a register or a symbolic displacement. 1259 unsigned TmpReg; 1260 const MCExpr *Val; 1261 SMLoc IdentLoc = Tok.getLoc(); 1262 StringRef Identifier = Tok.getString(); 1263 if(!ParseRegister(TmpReg, IdentLoc, End)) { 1264 SM.onRegister(TmpReg); 1265 UpdateLocLex = false; 1266 break; 1267 } else { 1268 if (!isParsingInlineAsm()) { 1269 if (getParser().parsePrimaryExpr(Val, End)) 1270 return ErrorOperand(Tok.getLoc(), "Unexpected identifier!"); 1271 } else { 1272 InlineAsmIdentifierInfo &Info = SM.getIdentifierInfo(); 1273 if (X86Operand *Err = ParseIntelIdentifier(Val, Identifier, Info, 1274 /*Unevaluated*/ false, End)) 1275 return Err; 1276 } 1277 SM.onIdentifierExpr(Val, Identifier); 1278 UpdateLocLex = false; 1279 break; 1280 } 1281 return ErrorOperand(Tok.getLoc(), "Unexpected identifier!"); 1282 } 1283 case AsmToken::Integer: 1284 if (isParsingInlineAsm() && SM.getAddImmPrefix()) 1285 InstInfo->AsmRewrites->push_back(AsmRewrite(AOK_ImmPrefix, 1286 Tok.getLoc())); 1287 SM.onInteger(Tok.getIntVal()); 1288 break; 1289 case AsmToken::Plus: SM.onPlus(); break; 1290 case AsmToken::Minus: SM.onMinus(); break; 1291 case AsmToken::Star: SM.onStar(); break; 1292 case AsmToken::Slash: SM.onDivide(); break; 1293 case AsmToken::LBrac: SM.onLBrac(); break; 1294 case AsmToken::RBrac: SM.onRBrac(); break; 1295 case AsmToken::LParen: SM.onLParen(); break; 1296 case AsmToken::RParen: SM.onRParen(); break; 1297 } 1298 if (SM.hadError()) 1299 return ErrorOperand(Tok.getLoc(), "Unexpected token!"); 1300 1301 if (!Done && UpdateLocLex) { 1302 End = Tok.getLoc(); 1303 Parser.Lex(); // Consume the token. 1304 } 1305 } 1306 return 0; 1307 } 1308 1309 X86Operand *X86AsmParser::ParseIntelBracExpression(unsigned SegReg, SMLoc Start, 1310 int64_t ImmDisp, 1311 unsigned Size) { 1312 const AsmToken &Tok = Parser.getTok(); 1313 SMLoc BracLoc = Tok.getLoc(), End = Tok.getEndLoc(); 1314 if (getLexer().isNot(AsmToken::LBrac)) 1315 return ErrorOperand(BracLoc, "Expected '[' token!"); 1316 Parser.Lex(); // Eat '[' 1317 1318 SMLoc StartInBrac = Tok.getLoc(); 1319 // Parse [ Symbol + ImmDisp ] and [ BaseReg + Scale*IndexReg + ImmDisp ]. We 1320 // may have already parsed an immediate displacement before the bracketed 1321 // expression. 1322 IntelExprStateMachine SM(ImmDisp, /*StopOnLBrac=*/false, /*AddImmPrefix=*/true); 1323 if (X86Operand *Err = ParseIntelExpression(SM, End)) 1324 return Err; 1325 1326 const MCExpr *Disp; 1327 if (const MCExpr *Sym = SM.getSym()) { 1328 // A symbolic displacement. 1329 Disp = Sym; 1330 if (isParsingInlineAsm()) 1331 RewriteIntelBracExpression(InstInfo->AsmRewrites, SM.getSymName(), 1332 ImmDisp, SM.getImm(), BracLoc, StartInBrac, 1333 End); 1334 } else { 1335 // An immediate displacement only. 1336 Disp = MCConstantExpr::Create(SM.getImm(), getContext()); 1337 } 1338 1339 // Parse the dot operator (e.g., [ebx].foo.bar). 1340 if (Tok.getString().startswith(".")) { 1341 const MCExpr *NewDisp; 1342 if (X86Operand *Err = ParseIntelDotOperator(Disp, NewDisp)) 1343 return Err; 1344 1345 End = Tok.getEndLoc(); 1346 Parser.Lex(); // Eat the field. 1347 Disp = NewDisp; 1348 } 1349 1350 int BaseReg = SM.getBaseReg(); 1351 int IndexReg = SM.getIndexReg(); 1352 int Scale = SM.getScale(); 1353 if (!isParsingInlineAsm()) { 1354 // handle [-42] 1355 if (!BaseReg && !IndexReg) { 1356 if (!SegReg) 1357 return X86Operand::CreateMem(Disp, Start, End, Size); 1358 else 1359 return X86Operand::CreateMem(SegReg, Disp, 0, 0, 1, Start, End, Size); 1360 } 1361 return X86Operand::CreateMem(SegReg, Disp, BaseReg, IndexReg, Scale, Start, 1362 End, Size); 1363 } 1364 1365 InlineAsmIdentifierInfo &Info = SM.getIdentifierInfo(); 1366 return CreateMemForInlineAsm(SegReg, Disp, BaseReg, IndexReg, Scale, Start, 1367 End, Size, SM.getSymName(), Info); 1368 } 1369 1370 // Inline assembly may use variable names with namespace alias qualifiers. 1371 X86Operand *X86AsmParser::ParseIntelIdentifier(const MCExpr *&Val, 1372 StringRef &Identifier, 1373 InlineAsmIdentifierInfo &Info, 1374 bool IsUnevaluatedOperand, 1375 SMLoc &End) { 1376 assert (isParsingInlineAsm() && "Expected to be parsing inline assembly."); 1377 Val = 0; 1378 1379 StringRef LineBuf(Identifier.data()); 1380 SemaCallback->LookupInlineAsmIdentifier(LineBuf, Info, IsUnevaluatedOperand); 1381 1382 const AsmToken &Tok = Parser.getTok(); 1383 1384 // Advance the token stream until the end of the current token is 1385 // after the end of what the frontend claimed. 1386 const char *EndPtr = Tok.getLoc().getPointer() + LineBuf.size(); 1387 while (true) { 1388 End = Tok.getEndLoc(); 1389 getLexer().Lex(); 1390 1391 assert(End.getPointer() <= EndPtr && "frontend claimed part of a token?"); 1392 if (End.getPointer() == EndPtr) break; 1393 } 1394 1395 // Create the symbol reference. 1396 Identifier = LineBuf; 1397 MCSymbol *Sym = getContext().GetOrCreateSymbol(Identifier); 1398 MCSymbolRefExpr::VariantKind Variant = MCSymbolRefExpr::VK_None; 1399 Val = MCSymbolRefExpr::Create(Sym, Variant, getParser().getContext()); 1400 return 0; 1401 } 1402 1403 /// ParseIntelMemOperand - Parse intel style memory operand. 1404 X86Operand *X86AsmParser::ParseIntelMemOperand(unsigned SegReg, 1405 int64_t ImmDisp, 1406 SMLoc Start) { 1407 const AsmToken &Tok = Parser.getTok(); 1408 SMLoc End; 1409 1410 unsigned Size = getIntelMemOperandSize(Tok.getString()); 1411 if (Size) { 1412 Parser.Lex(); // Eat operand size (e.g., byte, word). 1413 if (Tok.getString() != "PTR" && Tok.getString() != "ptr") 1414 return ErrorOperand(Start, "Expected 'PTR' or 'ptr' token!"); 1415 Parser.Lex(); // Eat ptr. 1416 } 1417 1418 // Parse ImmDisp [ BaseReg + Scale*IndexReg + Disp ]. 1419 if (getLexer().is(AsmToken::Integer)) { 1420 if (isParsingInlineAsm()) 1421 InstInfo->AsmRewrites->push_back(AsmRewrite(AOK_ImmPrefix, 1422 Tok.getLoc())); 1423 int64_t ImmDisp = Tok.getIntVal(); 1424 Parser.Lex(); // Eat the integer. 1425 if (getLexer().isNot(AsmToken::LBrac)) 1426 return ErrorOperand(Start, "Expected '[' token!"); 1427 return ParseIntelBracExpression(SegReg, Start, ImmDisp, Size); 1428 } 1429 1430 if (getLexer().is(AsmToken::LBrac)) 1431 return ParseIntelBracExpression(SegReg, Start, ImmDisp, Size); 1432 1433 if (!ParseRegister(SegReg, Start, End)) { 1434 // Handel SegReg : [ ... ] 1435 if (getLexer().isNot(AsmToken::Colon)) 1436 return ErrorOperand(Start, "Expected ':' token!"); 1437 Parser.Lex(); // Eat : 1438 if (getLexer().isNot(AsmToken::LBrac)) 1439 return ErrorOperand(Start, "Expected '[' token!"); 1440 return ParseIntelBracExpression(SegReg, Start, ImmDisp, Size); 1441 } 1442 1443 const MCExpr *Val; 1444 if (!isParsingInlineAsm()) { 1445 if (getParser().parsePrimaryExpr(Val, End)) 1446 return ErrorOperand(Tok.getLoc(), "Unexpected token!"); 1447 1448 return X86Operand::CreateMem(Val, Start, End, Size); 1449 } 1450 1451 InlineAsmIdentifierInfo Info; 1452 StringRef Identifier = Tok.getString(); 1453 if (X86Operand *Err = ParseIntelIdentifier(Val, Identifier, Info, 1454 /*Unevaluated*/ false, End)) 1455 return Err; 1456 return CreateMemForInlineAsm(/*SegReg=*/0, Val, /*BaseReg=*/0,/*IndexReg=*/0, 1457 /*Scale=*/1, Start, End, Size, Identifier, Info); 1458 } 1459 1460 /// Parse the '.' operator. 1461 X86Operand *X86AsmParser::ParseIntelDotOperator(const MCExpr *Disp, 1462 const MCExpr *&NewDisp) { 1463 const AsmToken &Tok = Parser.getTok(); 1464 int64_t OrigDispVal, DotDispVal; 1465 1466 // FIXME: Handle non-constant expressions. 1467 if (const MCConstantExpr *OrigDisp = dyn_cast<MCConstantExpr>(Disp)) 1468 OrigDispVal = OrigDisp->getValue(); 1469 else 1470 return ErrorOperand(Tok.getLoc(), "Non-constant offsets are not supported!"); 1471 1472 // Drop the '.'. 1473 StringRef DotDispStr = Tok.getString().drop_front(1); 1474 1475 // .Imm gets lexed as a real. 1476 if (Tok.is(AsmToken::Real)) { 1477 APInt DotDisp; 1478 DotDispStr.getAsInteger(10, DotDisp); 1479 DotDispVal = DotDisp.getZExtValue(); 1480 } else if (isParsingInlineAsm() && Tok.is(AsmToken::Identifier)) { 1481 unsigned DotDisp; 1482 std::pair<StringRef, StringRef> BaseMember = DotDispStr.split('.'); 1483 if (SemaCallback->LookupInlineAsmField(BaseMember.first, BaseMember.second, 1484 DotDisp)) 1485 return ErrorOperand(Tok.getLoc(), "Unable to lookup field reference!"); 1486 DotDispVal = DotDisp; 1487 } else 1488 return ErrorOperand(Tok.getLoc(), "Unexpected token type!"); 1489 1490 if (isParsingInlineAsm() && Tok.is(AsmToken::Identifier)) { 1491 SMLoc Loc = SMLoc::getFromPointer(DotDispStr.data()); 1492 unsigned Len = DotDispStr.size(); 1493 unsigned Val = OrigDispVal + DotDispVal; 1494 InstInfo->AsmRewrites->push_back(AsmRewrite(AOK_DotOperator, Loc, Len, 1495 Val)); 1496 } 1497 1498 NewDisp = MCConstantExpr::Create(OrigDispVal + DotDispVal, getContext()); 1499 return 0; 1500 } 1501 1502 /// Parse the 'offset' operator. This operator is used to specify the 1503 /// location rather then the content of a variable. 1504 X86Operand *X86AsmParser::ParseIntelOffsetOfOperator() { 1505 const AsmToken &Tok = Parser.getTok(); 1506 SMLoc OffsetOfLoc = Tok.getLoc(); 1507 Parser.Lex(); // Eat offset. 1508 1509 const MCExpr *Val; 1510 InlineAsmIdentifierInfo Info; 1511 SMLoc Start = Tok.getLoc(), End; 1512 StringRef Identifier = Tok.getString(); 1513 if (X86Operand *Err = ParseIntelIdentifier(Val, Identifier, Info, 1514 /*Unevaluated*/ false, End)) 1515 return Err; 1516 1517 // Don't emit the offset operator. 1518 InstInfo->AsmRewrites->push_back(AsmRewrite(AOK_Skip, OffsetOfLoc, 7)); 1519 1520 // The offset operator will have an 'r' constraint, thus we need to create 1521 // register operand to ensure proper matching. Just pick a GPR based on 1522 // the size of a pointer. 1523 unsigned RegNo = is64BitMode() ? X86::RBX : X86::EBX; 1524 return X86Operand::CreateReg(RegNo, Start, End, /*GetAddress=*/true, 1525 OffsetOfLoc, Identifier, Info.OpDecl); 1526 } 1527 1528 enum IntelOperatorKind { 1529 IOK_LENGTH, 1530 IOK_SIZE, 1531 IOK_TYPE 1532 }; 1533 1534 /// Parse the 'LENGTH', 'TYPE' and 'SIZE' operators. The LENGTH operator 1535 /// returns the number of elements in an array. It returns the value 1 for 1536 /// non-array variables. The SIZE operator returns the size of a C or C++ 1537 /// variable. A variable's size is the product of its LENGTH and TYPE. The 1538 /// TYPE operator returns the size of a C or C++ type or variable. If the 1539 /// variable is an array, TYPE returns the size of a single element. 1540 X86Operand *X86AsmParser::ParseIntelOperator(unsigned OpKind) { 1541 const AsmToken &Tok = Parser.getTok(); 1542 SMLoc TypeLoc = Tok.getLoc(); 1543 Parser.Lex(); // Eat operator. 1544 1545 const MCExpr *Val = 0; 1546 InlineAsmIdentifierInfo Info; 1547 SMLoc Start = Tok.getLoc(), End; 1548 StringRef Identifier = Tok.getString(); 1549 if (X86Operand *Err = ParseIntelIdentifier(Val, Identifier, Info, 1550 /*Unevaluated*/ true, End)) 1551 return Err; 1552 1553 unsigned CVal = 0; 1554 switch(OpKind) { 1555 default: llvm_unreachable("Unexpected operand kind!"); 1556 case IOK_LENGTH: CVal = Info.Length; break; 1557 case IOK_SIZE: CVal = Info.Size; break; 1558 case IOK_TYPE: CVal = Info.Type; break; 1559 } 1560 1561 // Rewrite the type operator and the C or C++ type or variable in terms of an 1562 // immediate. E.g. TYPE foo -> $$4 1563 unsigned Len = End.getPointer() - TypeLoc.getPointer(); 1564 InstInfo->AsmRewrites->push_back(AsmRewrite(AOK_Imm, TypeLoc, Len, CVal)); 1565 1566 const MCExpr *Imm = MCConstantExpr::Create(CVal, getContext()); 1567 return X86Operand::CreateImm(Imm, Start, End); 1568 } 1569 1570 X86Operand *X86AsmParser::ParseIntelOperand() { 1571 const AsmToken &Tok = Parser.getTok(); 1572 SMLoc Start = Tok.getLoc(), End; 1573 1574 // Offset, length, type and size operators. 1575 if (isParsingInlineAsm()) { 1576 StringRef AsmTokStr = Tok.getString(); 1577 if (AsmTokStr == "offset" || AsmTokStr == "OFFSET") 1578 return ParseIntelOffsetOfOperator(); 1579 if (AsmTokStr == "length" || AsmTokStr == "LENGTH") 1580 return ParseIntelOperator(IOK_LENGTH); 1581 if (AsmTokStr == "size" || AsmTokStr == "SIZE") 1582 return ParseIntelOperator(IOK_SIZE); 1583 if (AsmTokStr == "type" || AsmTokStr == "TYPE") 1584 return ParseIntelOperator(IOK_TYPE); 1585 } 1586 1587 // Immediate. 1588 if (getLexer().is(AsmToken::Integer) || getLexer().is(AsmToken::Minus) || 1589 getLexer().is(AsmToken::LParen)) { 1590 AsmToken StartTok = Tok; 1591 IntelExprStateMachine SM(/*Imm=*/0, /*StopOnLBrac=*/true, 1592 /*AddImmPrefix=*/false); 1593 if (X86Operand *Err = ParseIntelExpression(SM, End)) 1594 return Err; 1595 1596 int64_t Imm = SM.getImm(); 1597 if (isParsingInlineAsm()) { 1598 unsigned Len = Tok.getLoc().getPointer() - Start.getPointer(); 1599 if (StartTok.getString().size() == Len) 1600 // Just add a prefix if this wasn't a complex immediate expression. 1601 InstInfo->AsmRewrites->push_back(AsmRewrite(AOK_ImmPrefix, Start)); 1602 else 1603 // Otherwise, rewrite the complex expression as a single immediate. 1604 InstInfo->AsmRewrites->push_back(AsmRewrite(AOK_Imm, Start, Len, Imm)); 1605 } 1606 1607 if (getLexer().isNot(AsmToken::LBrac)) { 1608 const MCExpr *ImmExpr = MCConstantExpr::Create(Imm, getContext()); 1609 return X86Operand::CreateImm(ImmExpr, Start, End); 1610 } 1611 1612 // Only positive immediates are valid. 1613 if (Imm < 0) 1614 return ErrorOperand(Start, "expected a positive immediate displacement " 1615 "before bracketed expr."); 1616 1617 // Parse ImmDisp [ BaseReg + Scale*IndexReg + Disp ]. 1618 return ParseIntelMemOperand(/*SegReg=*/0, Imm, Start); 1619 } 1620 1621 // Register. 1622 unsigned RegNo = 0; 1623 if (!ParseRegister(RegNo, Start, End)) { 1624 // If this is a segment register followed by a ':', then this is the start 1625 // of a memory reference, otherwise this is a normal register reference. 1626 if (getLexer().isNot(AsmToken::Colon)) 1627 return X86Operand::CreateReg(RegNo, Start, End); 1628 1629 getParser().Lex(); // Eat the colon. 1630 return ParseIntelMemOperand(/*SegReg=*/RegNo, /*Disp=*/0, Start); 1631 } 1632 1633 // Memory operand. 1634 return ParseIntelMemOperand(/*SegReg=*/0, /*Disp=*/0, Start); 1635 } 1636 1637 X86Operand *X86AsmParser::ParseATTOperand() { 1638 switch (getLexer().getKind()) { 1639 default: 1640 // Parse a memory operand with no segment register. 1641 return ParseMemOperand(0, Parser.getTok().getLoc()); 1642 case AsmToken::Percent: { 1643 // Read the register. 1644 unsigned RegNo; 1645 SMLoc Start, End; 1646 if (ParseRegister(RegNo, Start, End)) return 0; 1647 if (RegNo == X86::EIZ || RegNo == X86::RIZ) { 1648 Error(Start, "%eiz and %riz can only be used as index registers", 1649 SMRange(Start, End)); 1650 return 0; 1651 } 1652 1653 // If this is a segment register followed by a ':', then this is the start 1654 // of a memory reference, otherwise this is a normal register reference. 1655 if (getLexer().isNot(AsmToken::Colon)) 1656 return X86Operand::CreateReg(RegNo, Start, End); 1657 1658 getParser().Lex(); // Eat the colon. 1659 return ParseMemOperand(RegNo, Start); 1660 } 1661 case AsmToken::Dollar: { 1662 // $42 -> immediate. 1663 SMLoc Start = Parser.getTok().getLoc(), End; 1664 Parser.Lex(); 1665 const MCExpr *Val; 1666 if (getParser().parseExpression(Val, End)) 1667 return 0; 1668 return X86Operand::CreateImm(Val, Start, End); 1669 } 1670 } 1671 } 1672 1673 /// ParseMemOperand: segment: disp(basereg, indexreg, scale). The '%ds:' prefix 1674 /// has already been parsed if present. 1675 X86Operand *X86AsmParser::ParseMemOperand(unsigned SegReg, SMLoc MemStart) { 1676 1677 // We have to disambiguate a parenthesized expression "(4+5)" from the start 1678 // of a memory operand with a missing displacement "(%ebx)" or "(,%eax)". The 1679 // only way to do this without lookahead is to eat the '(' and see what is 1680 // after it. 1681 const MCExpr *Disp = MCConstantExpr::Create(0, getParser().getContext()); 1682 if (getLexer().isNot(AsmToken::LParen)) { 1683 SMLoc ExprEnd; 1684 if (getParser().parseExpression(Disp, ExprEnd)) return 0; 1685 1686 // After parsing the base expression we could either have a parenthesized 1687 // memory address or not. If not, return now. If so, eat the (. 1688 if (getLexer().isNot(AsmToken::LParen)) { 1689 // Unless we have a segment register, treat this as an immediate. 1690 if (SegReg == 0) 1691 return X86Operand::CreateMem(Disp, MemStart, ExprEnd); 1692 return X86Operand::CreateMem(SegReg, Disp, 0, 0, 1, MemStart, ExprEnd); 1693 } 1694 1695 // Eat the '('. 1696 Parser.Lex(); 1697 } else { 1698 // Okay, we have a '('. We don't know if this is an expression or not, but 1699 // so we have to eat the ( to see beyond it. 1700 SMLoc LParenLoc = Parser.getTok().getLoc(); 1701 Parser.Lex(); // Eat the '('. 1702 1703 if (getLexer().is(AsmToken::Percent) || getLexer().is(AsmToken::Comma)) { 1704 // Nothing to do here, fall into the code below with the '(' part of the 1705 // memory operand consumed. 1706 } else { 1707 SMLoc ExprEnd; 1708 1709 // It must be an parenthesized expression, parse it now. 1710 if (getParser().parseParenExpression(Disp, ExprEnd)) 1711 return 0; 1712 1713 // After parsing the base expression we could either have a parenthesized 1714 // memory address or not. If not, return now. If so, eat the (. 1715 if (getLexer().isNot(AsmToken::LParen)) { 1716 // Unless we have a segment register, treat this as an immediate. 1717 if (SegReg == 0) 1718 return X86Operand::CreateMem(Disp, LParenLoc, ExprEnd); 1719 return X86Operand::CreateMem(SegReg, Disp, 0, 0, 1, MemStart, ExprEnd); 1720 } 1721 1722 // Eat the '('. 1723 Parser.Lex(); 1724 } 1725 } 1726 1727 // If we reached here, then we just ate the ( of the memory operand. Process 1728 // the rest of the memory operand. 1729 unsigned BaseReg = 0, IndexReg = 0, Scale = 1; 1730 SMLoc IndexLoc; 1731 1732 if (getLexer().is(AsmToken::Percent)) { 1733 SMLoc StartLoc, EndLoc; 1734 if (ParseRegister(BaseReg, StartLoc, EndLoc)) return 0; 1735 if (BaseReg == X86::EIZ || BaseReg == X86::RIZ) { 1736 Error(StartLoc, "eiz and riz can only be used as index registers", 1737 SMRange(StartLoc, EndLoc)); 1738 return 0; 1739 } 1740 } 1741 1742 if (getLexer().is(AsmToken::Comma)) { 1743 Parser.Lex(); // Eat the comma. 1744 IndexLoc = Parser.getTok().getLoc(); 1745 1746 // Following the comma we should have either an index register, or a scale 1747 // value. We don't support the later form, but we want to parse it 1748 // correctly. 1749 // 1750 // Not that even though it would be completely consistent to support syntax 1751 // like "1(%eax,,1)", the assembler doesn't. Use "eiz" or "riz" for this. 1752 if (getLexer().is(AsmToken::Percent)) { 1753 SMLoc L; 1754 if (ParseRegister(IndexReg, L, L)) return 0; 1755 1756 if (getLexer().isNot(AsmToken::RParen)) { 1757 // Parse the scale amount: 1758 // ::= ',' [scale-expression] 1759 if (getLexer().isNot(AsmToken::Comma)) { 1760 Error(Parser.getTok().getLoc(), 1761 "expected comma in scale expression"); 1762 return 0; 1763 } 1764 Parser.Lex(); // Eat the comma. 1765 1766 if (getLexer().isNot(AsmToken::RParen)) { 1767 SMLoc Loc = Parser.getTok().getLoc(); 1768 1769 int64_t ScaleVal; 1770 if (getParser().parseAbsoluteExpression(ScaleVal)){ 1771 Error(Loc, "expected scale expression"); 1772 return 0; 1773 } 1774 1775 // Validate the scale amount. 1776 if (ScaleVal != 1 && ScaleVal != 2 && ScaleVal != 4 && ScaleVal != 8){ 1777 Error(Loc, "scale factor in address must be 1, 2, 4 or 8"); 1778 return 0; 1779 } 1780 Scale = (unsigned)ScaleVal; 1781 } 1782 } 1783 } else if (getLexer().isNot(AsmToken::RParen)) { 1784 // A scale amount without an index is ignored. 1785 // index. 1786 SMLoc Loc = Parser.getTok().getLoc(); 1787 1788 int64_t Value; 1789 if (getParser().parseAbsoluteExpression(Value)) 1790 return 0; 1791 1792 if (Value != 1) 1793 Warning(Loc, "scale factor without index register is ignored"); 1794 Scale = 1; 1795 } 1796 } 1797 1798 // Ok, we've eaten the memory operand, verify we have a ')' and eat it too. 1799 if (getLexer().isNot(AsmToken::RParen)) { 1800 Error(Parser.getTok().getLoc(), "unexpected token in memory operand"); 1801 return 0; 1802 } 1803 SMLoc MemEnd = Parser.getTok().getEndLoc(); 1804 Parser.Lex(); // Eat the ')'. 1805 1806 // If we have both a base register and an index register make sure they are 1807 // both 64-bit or 32-bit registers. 1808 // To support VSIB, IndexReg can be 128-bit or 256-bit registers. 1809 if (BaseReg != 0 && IndexReg != 0) { 1810 if (X86MCRegisterClasses[X86::GR64RegClassID].contains(BaseReg) && 1811 (X86MCRegisterClasses[X86::GR16RegClassID].contains(IndexReg) || 1812 X86MCRegisterClasses[X86::GR32RegClassID].contains(IndexReg)) && 1813 IndexReg != X86::RIZ) { 1814 Error(IndexLoc, "index register is 32-bit, but base register is 64-bit"); 1815 return 0; 1816 } 1817 if (X86MCRegisterClasses[X86::GR32RegClassID].contains(BaseReg) && 1818 (X86MCRegisterClasses[X86::GR16RegClassID].contains(IndexReg) || 1819 X86MCRegisterClasses[X86::GR64RegClassID].contains(IndexReg)) && 1820 IndexReg != X86::EIZ){ 1821 Error(IndexLoc, "index register is 64-bit, but base register is 32-bit"); 1822 return 0; 1823 } 1824 } 1825 1826 return X86Operand::CreateMem(SegReg, Disp, BaseReg, IndexReg, Scale, 1827 MemStart, MemEnd); 1828 } 1829 1830 bool X86AsmParser:: 1831 ParseInstruction(ParseInstructionInfo &Info, StringRef Name, SMLoc NameLoc, 1832 SmallVectorImpl<MCParsedAsmOperand*> &Operands) { 1833 InstInfo = &Info; 1834 StringRef PatchedName = Name; 1835 1836 // FIXME: Hack to recognize setneb as setne. 1837 if (PatchedName.startswith("set") && PatchedName.endswith("b") && 1838 PatchedName != "setb" && PatchedName != "setnb") 1839 PatchedName = PatchedName.substr(0, Name.size()-1); 1840 1841 // FIXME: Hack to recognize cmp<comparison code>{ss,sd,ps,pd}. 1842 const MCExpr *ExtraImmOp = 0; 1843 if ((PatchedName.startswith("cmp") || PatchedName.startswith("vcmp")) && 1844 (PatchedName.endswith("ss") || PatchedName.endswith("sd") || 1845 PatchedName.endswith("ps") || PatchedName.endswith("pd"))) { 1846 bool IsVCMP = PatchedName[0] == 'v'; 1847 unsigned SSECCIdx = IsVCMP ? 4 : 3; 1848 unsigned SSEComparisonCode = StringSwitch<unsigned>( 1849 PatchedName.slice(SSECCIdx, PatchedName.size() - 2)) 1850 .Case("eq", 0x00) 1851 .Case("lt", 0x01) 1852 .Case("le", 0x02) 1853 .Case("unord", 0x03) 1854 .Case("neq", 0x04) 1855 .Case("nlt", 0x05) 1856 .Case("nle", 0x06) 1857 .Case("ord", 0x07) 1858 /* AVX only from here */ 1859 .Case("eq_uq", 0x08) 1860 .Case("nge", 0x09) 1861 .Case("ngt", 0x0A) 1862 .Case("false", 0x0B) 1863 .Case("neq_oq", 0x0C) 1864 .Case("ge", 0x0D) 1865 .Case("gt", 0x0E) 1866 .Case("true", 0x0F) 1867 .Case("eq_os", 0x10) 1868 .Case("lt_oq", 0x11) 1869 .Case("le_oq", 0x12) 1870 .Case("unord_s", 0x13) 1871 .Case("neq_us", 0x14) 1872 .Case("nlt_uq", 0x15) 1873 .Case("nle_uq", 0x16) 1874 .Case("ord_s", 0x17) 1875 .Case("eq_us", 0x18) 1876 .Case("nge_uq", 0x19) 1877 .Case("ngt_uq", 0x1A) 1878 .Case("false_os", 0x1B) 1879 .Case("neq_os", 0x1C) 1880 .Case("ge_oq", 0x1D) 1881 .Case("gt_oq", 0x1E) 1882 .Case("true_us", 0x1F) 1883 .Default(~0U); 1884 if (SSEComparisonCode != ~0U && (IsVCMP || SSEComparisonCode < 8)) { 1885 ExtraImmOp = MCConstantExpr::Create(SSEComparisonCode, 1886 getParser().getContext()); 1887 if (PatchedName.endswith("ss")) { 1888 PatchedName = IsVCMP ? "vcmpss" : "cmpss"; 1889 } else if (PatchedName.endswith("sd")) { 1890 PatchedName = IsVCMP ? "vcmpsd" : "cmpsd"; 1891 } else if (PatchedName.endswith("ps")) { 1892 PatchedName = IsVCMP ? "vcmpps" : "cmpps"; 1893 } else { 1894 assert(PatchedName.endswith("pd") && "Unexpected mnemonic!"); 1895 PatchedName = IsVCMP ? "vcmppd" : "cmppd"; 1896 } 1897 } 1898 } 1899 1900 Operands.push_back(X86Operand::CreateToken(PatchedName, NameLoc)); 1901 1902 if (ExtraImmOp && !isParsingIntelSyntax()) 1903 Operands.push_back(X86Operand::CreateImm(ExtraImmOp, NameLoc, NameLoc)); 1904 1905 // Determine whether this is an instruction prefix. 1906 bool isPrefix = 1907 Name == "lock" || Name == "rep" || 1908 Name == "repe" || Name == "repz" || 1909 Name == "repne" || Name == "repnz" || 1910 Name == "rex64" || Name == "data16"; 1911 1912 1913 // This does the actual operand parsing. Don't parse any more if we have a 1914 // prefix juxtaposed with an operation like "lock incl 4(%rax)", because we 1915 // just want to parse the "lock" as the first instruction and the "incl" as 1916 // the next one. 1917 if (getLexer().isNot(AsmToken::EndOfStatement) && !isPrefix) { 1918 1919 // Parse '*' modifier. 1920 if (getLexer().is(AsmToken::Star)) { 1921 SMLoc Loc = Parser.getTok().getLoc(); 1922 Operands.push_back(X86Operand::CreateToken("*", Loc)); 1923 Parser.Lex(); // Eat the star. 1924 } 1925 1926 // Read the first operand. 1927 if (X86Operand *Op = ParseOperand()) 1928 Operands.push_back(Op); 1929 else { 1930 Parser.eatToEndOfStatement(); 1931 return true; 1932 } 1933 1934 while (getLexer().is(AsmToken::Comma)) { 1935 Parser.Lex(); // Eat the comma. 1936 1937 // Parse and remember the operand. 1938 if (X86Operand *Op = ParseOperand()) 1939 Operands.push_back(Op); 1940 else { 1941 Parser.eatToEndOfStatement(); 1942 return true; 1943 } 1944 } 1945 1946 if (getLexer().isNot(AsmToken::EndOfStatement)) { 1947 SMLoc Loc = getLexer().getLoc(); 1948 Parser.eatToEndOfStatement(); 1949 return Error(Loc, "unexpected token in argument list"); 1950 } 1951 } 1952 1953 if (getLexer().is(AsmToken::EndOfStatement)) 1954 Parser.Lex(); // Consume the EndOfStatement 1955 else if (isPrefix && getLexer().is(AsmToken::Slash)) 1956 Parser.Lex(); // Consume the prefix separator Slash 1957 1958 if (ExtraImmOp && isParsingIntelSyntax()) 1959 Operands.push_back(X86Operand::CreateImm(ExtraImmOp, NameLoc, NameLoc)); 1960 1961 // This is a terrible hack to handle "out[bwl]? %al, (%dx)" -> 1962 // "outb %al, %dx". Out doesn't take a memory form, but this is a widely 1963 // documented form in various unofficial manuals, so a lot of code uses it. 1964 if ((Name == "outb" || Name == "outw" || Name == "outl" || Name == "out") && 1965 Operands.size() == 3) { 1966 X86Operand &Op = *(X86Operand*)Operands.back(); 1967 if (Op.isMem() && Op.Mem.SegReg == 0 && 1968 isa<MCConstantExpr>(Op.Mem.Disp) && 1969 cast<MCConstantExpr>(Op.Mem.Disp)->getValue() == 0 && 1970 Op.Mem.BaseReg == MatchRegisterName("dx") && Op.Mem.IndexReg == 0) { 1971 SMLoc Loc = Op.getEndLoc(); 1972 Operands.back() = X86Operand::CreateReg(Op.Mem.BaseReg, Loc, Loc); 1973 delete &Op; 1974 } 1975 } 1976 // Same hack for "in[bwl]? (%dx), %al" -> "inb %dx, %al". 1977 if ((Name == "inb" || Name == "inw" || Name == "inl" || Name == "in") && 1978 Operands.size() == 3) { 1979 X86Operand &Op = *(X86Operand*)Operands.begin()[1]; 1980 if (Op.isMem() && Op.Mem.SegReg == 0 && 1981 isa<MCConstantExpr>(Op.Mem.Disp) && 1982 cast<MCConstantExpr>(Op.Mem.Disp)->getValue() == 0 && 1983 Op.Mem.BaseReg == MatchRegisterName("dx") && Op.Mem.IndexReg == 0) { 1984 SMLoc Loc = Op.getEndLoc(); 1985 Operands.begin()[1] = X86Operand::CreateReg(Op.Mem.BaseReg, Loc, Loc); 1986 delete &Op; 1987 } 1988 } 1989 // Transform "ins[bwl] %dx, %es:(%edi)" into "ins[bwl]" 1990 if (Name.startswith("ins") && Operands.size() == 3 && 1991 (Name == "insb" || Name == "insw" || Name == "insl")) { 1992 X86Operand &Op = *(X86Operand*)Operands.begin()[1]; 1993 X86Operand &Op2 = *(X86Operand*)Operands.begin()[2]; 1994 if (Op.isReg() && Op.getReg() == X86::DX && isDstOp(Op2)) { 1995 Operands.pop_back(); 1996 Operands.pop_back(); 1997 delete &Op; 1998 delete &Op2; 1999 } 2000 } 2001 2002 // Transform "outs[bwl] %ds:(%esi), %dx" into "out[bwl]" 2003 if (Name.startswith("outs") && Operands.size() == 3 && 2004 (Name == "outsb" || Name == "outsw" || Name == "outsl")) { 2005 X86Operand &Op = *(X86Operand*)Operands.begin()[1]; 2006 X86Operand &Op2 = *(X86Operand*)Operands.begin()[2]; 2007 if (isSrcOp(Op) && Op2.isReg() && Op2.getReg() == X86::DX) { 2008 Operands.pop_back(); 2009 Operands.pop_back(); 2010 delete &Op; 2011 delete &Op2; 2012 } 2013 } 2014 2015 // Transform "movs[bwl] %ds:(%esi), %es:(%edi)" into "movs[bwl]" 2016 if (Name.startswith("movs") && Operands.size() == 3 && 2017 (Name == "movsb" || Name == "movsw" || Name == "movsl" || 2018 (is64BitMode() && Name == "movsq"))) { 2019 X86Operand &Op = *(X86Operand*)Operands.begin()[1]; 2020 X86Operand &Op2 = *(X86Operand*)Operands.begin()[2]; 2021 if (isSrcOp(Op) && isDstOp(Op2)) { 2022 Operands.pop_back(); 2023 Operands.pop_back(); 2024 delete &Op; 2025 delete &Op2; 2026 } 2027 } 2028 // Transform "lods[bwl] %ds:(%esi),{%al,%ax,%eax,%rax}" into "lods[bwl]" 2029 if (Name.startswith("lods") && Operands.size() == 3 && 2030 (Name == "lods" || Name == "lodsb" || Name == "lodsw" || 2031 Name == "lodsl" || (is64BitMode() && Name == "lodsq"))) { 2032 X86Operand *Op1 = static_cast<X86Operand*>(Operands[1]); 2033 X86Operand *Op2 = static_cast<X86Operand*>(Operands[2]); 2034 if (isSrcOp(*Op1) && Op2->isReg()) { 2035 const char *ins; 2036 unsigned reg = Op2->getReg(); 2037 bool isLods = Name == "lods"; 2038 if (reg == X86::AL && (isLods || Name == "lodsb")) 2039 ins = "lodsb"; 2040 else if (reg == X86::AX && (isLods || Name == "lodsw")) 2041 ins = "lodsw"; 2042 else if (reg == X86::EAX && (isLods || Name == "lodsl")) 2043 ins = "lodsl"; 2044 else if (reg == X86::RAX && (isLods || Name == "lodsq")) 2045 ins = "lodsq"; 2046 else 2047 ins = NULL; 2048 if (ins != NULL) { 2049 Operands.pop_back(); 2050 Operands.pop_back(); 2051 delete Op1; 2052 delete Op2; 2053 if (Name != ins) 2054 static_cast<X86Operand*>(Operands[0])->setTokenValue(ins); 2055 } 2056 } 2057 } 2058 // Transform "stos[bwl] {%al,%ax,%eax,%rax},%es:(%edi)" into "stos[bwl]" 2059 if (Name.startswith("stos") && Operands.size() == 3 && 2060 (Name == "stos" || Name == "stosb" || Name == "stosw" || 2061 Name == "stosl" || (is64BitMode() && Name == "stosq"))) { 2062 X86Operand *Op1 = static_cast<X86Operand*>(Operands[1]); 2063 X86Operand *Op2 = static_cast<X86Operand*>(Operands[2]); 2064 if (isDstOp(*Op2) && Op1->isReg()) { 2065 const char *ins; 2066 unsigned reg = Op1->getReg(); 2067 bool isStos = Name == "stos"; 2068 if (reg == X86::AL && (isStos || Name == "stosb")) 2069 ins = "stosb"; 2070 else if (reg == X86::AX && (isStos || Name == "stosw")) 2071 ins = "stosw"; 2072 else if (reg == X86::EAX && (isStos || Name == "stosl")) 2073 ins = "stosl"; 2074 else if (reg == X86::RAX && (isStos || Name == "stosq")) 2075 ins = "stosq"; 2076 else 2077 ins = NULL; 2078 if (ins != NULL) { 2079 Operands.pop_back(); 2080 Operands.pop_back(); 2081 delete Op1; 2082 delete Op2; 2083 if (Name != ins) 2084 static_cast<X86Operand*>(Operands[0])->setTokenValue(ins); 2085 } 2086 } 2087 } 2088 2089 // FIXME: Hack to handle recognize s{hr,ar,hl} $1, <op>. Canonicalize to 2090 // "shift <op>". 2091 if ((Name.startswith("shr") || Name.startswith("sar") || 2092 Name.startswith("shl") || Name.startswith("sal") || 2093 Name.startswith("rcl") || Name.startswith("rcr") || 2094 Name.startswith("rol") || Name.startswith("ror")) && 2095 Operands.size() == 3) { 2096 if (isParsingIntelSyntax()) { 2097 // Intel syntax 2098 X86Operand *Op1 = static_cast<X86Operand*>(Operands[2]); 2099 if (Op1->isImm() && isa<MCConstantExpr>(Op1->getImm()) && 2100 cast<MCConstantExpr>(Op1->getImm())->getValue() == 1) { 2101 delete Operands[2]; 2102 Operands.pop_back(); 2103 } 2104 } else { 2105 X86Operand *Op1 = static_cast<X86Operand*>(Operands[1]); 2106 if (Op1->isImm() && isa<MCConstantExpr>(Op1->getImm()) && 2107 cast<MCConstantExpr>(Op1->getImm())->getValue() == 1) { 2108 delete Operands[1]; 2109 Operands.erase(Operands.begin() + 1); 2110 } 2111 } 2112 } 2113 2114 // Transforms "int $3" into "int3" as a size optimization. We can't write an 2115 // instalias with an immediate operand yet. 2116 if (Name == "int" && Operands.size() == 2) { 2117 X86Operand *Op1 = static_cast<X86Operand*>(Operands[1]); 2118 if (Op1->isImm() && isa<MCConstantExpr>(Op1->getImm()) && 2119 cast<MCConstantExpr>(Op1->getImm())->getValue() == 3) { 2120 delete Operands[1]; 2121 Operands.erase(Operands.begin() + 1); 2122 static_cast<X86Operand*>(Operands[0])->setTokenValue("int3"); 2123 } 2124 } 2125 2126 return false; 2127 } 2128 2129 static bool convertToSExti8(MCInst &Inst, unsigned Opcode, unsigned Reg, 2130 bool isCmp) { 2131 MCInst TmpInst; 2132 TmpInst.setOpcode(Opcode); 2133 if (!isCmp) 2134 TmpInst.addOperand(MCOperand::CreateReg(Reg)); 2135 TmpInst.addOperand(MCOperand::CreateReg(Reg)); 2136 TmpInst.addOperand(Inst.getOperand(0)); 2137 Inst = TmpInst; 2138 return true; 2139 } 2140 2141 static bool convert16i16to16ri8(MCInst &Inst, unsigned Opcode, 2142 bool isCmp = false) { 2143 if (!Inst.getOperand(0).isImm() || 2144 !isImmSExti16i8Value(Inst.getOperand(0).getImm())) 2145 return false; 2146 2147 return convertToSExti8(Inst, Opcode, X86::AX, isCmp); 2148 } 2149 2150 static bool convert32i32to32ri8(MCInst &Inst, unsigned Opcode, 2151 bool isCmp = false) { 2152 if (!Inst.getOperand(0).isImm() || 2153 !isImmSExti32i8Value(Inst.getOperand(0).getImm())) 2154 return false; 2155 2156 return convertToSExti8(Inst, Opcode, X86::EAX, isCmp); 2157 } 2158 2159 static bool convert64i32to64ri8(MCInst &Inst, unsigned Opcode, 2160 bool isCmp = false) { 2161 if (!Inst.getOperand(0).isImm() || 2162 !isImmSExti64i8Value(Inst.getOperand(0).getImm())) 2163 return false; 2164 2165 return convertToSExti8(Inst, Opcode, X86::RAX, isCmp); 2166 } 2167 2168 bool X86AsmParser:: 2169 processInstruction(MCInst &Inst, 2170 const SmallVectorImpl<MCParsedAsmOperand*> &Ops) { 2171 switch (Inst.getOpcode()) { 2172 default: return false; 2173 case X86::AND16i16: return convert16i16to16ri8(Inst, X86::AND16ri8); 2174 case X86::AND32i32: return convert32i32to32ri8(Inst, X86::AND32ri8); 2175 case X86::AND64i32: return convert64i32to64ri8(Inst, X86::AND64ri8); 2176 case X86::XOR16i16: return convert16i16to16ri8(Inst, X86::XOR16ri8); 2177 case X86::XOR32i32: return convert32i32to32ri8(Inst, X86::XOR32ri8); 2178 case X86::XOR64i32: return convert64i32to64ri8(Inst, X86::XOR64ri8); 2179 case X86::OR16i16: return convert16i16to16ri8(Inst, X86::OR16ri8); 2180 case X86::OR32i32: return convert32i32to32ri8(Inst, X86::OR32ri8); 2181 case X86::OR64i32: return convert64i32to64ri8(Inst, X86::OR64ri8); 2182 case X86::CMP16i16: return convert16i16to16ri8(Inst, X86::CMP16ri8, true); 2183 case X86::CMP32i32: return convert32i32to32ri8(Inst, X86::CMP32ri8, true); 2184 case X86::CMP64i32: return convert64i32to64ri8(Inst, X86::CMP64ri8, true); 2185 case X86::ADD16i16: return convert16i16to16ri8(Inst, X86::ADD16ri8); 2186 case X86::ADD32i32: return convert32i32to32ri8(Inst, X86::ADD32ri8); 2187 case X86::ADD64i32: return convert64i32to64ri8(Inst, X86::ADD64ri8); 2188 case X86::SUB16i16: return convert16i16to16ri8(Inst, X86::SUB16ri8); 2189 case X86::SUB32i32: return convert32i32to32ri8(Inst, X86::SUB32ri8); 2190 case X86::SUB64i32: return convert64i32to64ri8(Inst, X86::SUB64ri8); 2191 case X86::ADC16i16: return convert16i16to16ri8(Inst, X86::ADC16ri8); 2192 case X86::ADC32i32: return convert32i32to32ri8(Inst, X86::ADC32ri8); 2193 case X86::ADC64i32: return convert64i32to64ri8(Inst, X86::ADC64ri8); 2194 case X86::SBB16i16: return convert16i16to16ri8(Inst, X86::SBB16ri8); 2195 case X86::SBB32i32: return convert32i32to32ri8(Inst, X86::SBB32ri8); 2196 case X86::SBB64i32: return convert64i32to64ri8(Inst, X86::SBB64ri8); 2197 } 2198 } 2199 2200 static const char *getSubtargetFeatureName(unsigned Val); 2201 bool X86AsmParser:: 2202 MatchAndEmitInstruction(SMLoc IDLoc, unsigned &Opcode, 2203 SmallVectorImpl<MCParsedAsmOperand*> &Operands, 2204 MCStreamer &Out, unsigned &ErrorInfo, 2205 bool MatchingInlineAsm) { 2206 assert(!Operands.empty() && "Unexpect empty operand list!"); 2207 X86Operand *Op = static_cast<X86Operand*>(Operands[0]); 2208 assert(Op->isToken() && "Leading operand should always be a mnemonic!"); 2209 ArrayRef<SMRange> EmptyRanges = None; 2210 2211 // First, handle aliases that expand to multiple instructions. 2212 // FIXME: This should be replaced with a real .td file alias mechanism. 2213 // Also, MatchInstructionImpl should actually *do* the EmitInstruction 2214 // call. 2215 if (Op->getToken() == "fstsw" || Op->getToken() == "fstcw" || 2216 Op->getToken() == "fstsww" || Op->getToken() == "fstcww" || 2217 Op->getToken() == "finit" || Op->getToken() == "fsave" || 2218 Op->getToken() == "fstenv" || Op->getToken() == "fclex") { 2219 MCInst Inst; 2220 Inst.setOpcode(X86::WAIT); 2221 Inst.setLoc(IDLoc); 2222 if (!MatchingInlineAsm) 2223 Out.EmitInstruction(Inst); 2224 2225 const char *Repl = 2226 StringSwitch<const char*>(Op->getToken()) 2227 .Case("finit", "fninit") 2228 .Case("fsave", "fnsave") 2229 .Case("fstcw", "fnstcw") 2230 .Case("fstcww", "fnstcw") 2231 .Case("fstenv", "fnstenv") 2232 .Case("fstsw", "fnstsw") 2233 .Case("fstsww", "fnstsw") 2234 .Case("fclex", "fnclex") 2235 .Default(0); 2236 assert(Repl && "Unknown wait-prefixed instruction"); 2237 delete Operands[0]; 2238 Operands[0] = X86Operand::CreateToken(Repl, IDLoc); 2239 } 2240 2241 bool WasOriginallyInvalidOperand = false; 2242 MCInst Inst; 2243 2244 // First, try a direct match. 2245 switch (MatchInstructionImpl(Operands, Inst, 2246 ErrorInfo, MatchingInlineAsm, 2247 isParsingIntelSyntax())) { 2248 default: break; 2249 case Match_Success: 2250 // Some instructions need post-processing to, for example, tweak which 2251 // encoding is selected. Loop on it while changes happen so the 2252 // individual transformations can chain off each other. 2253 if (!MatchingInlineAsm) 2254 while (processInstruction(Inst, Operands)) 2255 ; 2256 2257 Inst.setLoc(IDLoc); 2258 if (!MatchingInlineAsm) 2259 Out.EmitInstruction(Inst); 2260 Opcode = Inst.getOpcode(); 2261 return false; 2262 case Match_MissingFeature: { 2263 assert(ErrorInfo && "Unknown missing feature!"); 2264 // Special case the error message for the very common case where only 2265 // a single subtarget feature is missing. 2266 std::string Msg = "instruction requires:"; 2267 unsigned Mask = 1; 2268 for (unsigned i = 0; i < (sizeof(ErrorInfo)*8-1); ++i) { 2269 if (ErrorInfo & Mask) { 2270 Msg += " "; 2271 Msg += getSubtargetFeatureName(ErrorInfo & Mask); 2272 } 2273 Mask <<= 1; 2274 } 2275 return Error(IDLoc, Msg, EmptyRanges, MatchingInlineAsm); 2276 } 2277 case Match_InvalidOperand: 2278 WasOriginallyInvalidOperand = true; 2279 break; 2280 case Match_MnemonicFail: 2281 break; 2282 } 2283 2284 // FIXME: Ideally, we would only attempt suffix matches for things which are 2285 // valid prefixes, and we could just infer the right unambiguous 2286 // type. However, that requires substantially more matcher support than the 2287 // following hack. 2288 2289 // Change the operand to point to a temporary token. 2290 StringRef Base = Op->getToken(); 2291 SmallString<16> Tmp; 2292 Tmp += Base; 2293 Tmp += ' '; 2294 Op->setTokenValue(Tmp.str()); 2295 2296 // If this instruction starts with an 'f', then it is a floating point stack 2297 // instruction. These come in up to three forms for 32-bit, 64-bit, and 2298 // 80-bit floating point, which use the suffixes s,l,t respectively. 2299 // 2300 // Otherwise, we assume that this may be an integer instruction, which comes 2301 // in 8/16/32/64-bit forms using the b,w,l,q suffixes respectively. 2302 const char *Suffixes = Base[0] != 'f' ? "bwlq" : "slt\0"; 2303 2304 // Check for the various suffix matches. 2305 Tmp[Base.size()] = Suffixes[0]; 2306 unsigned ErrorInfoIgnore; 2307 unsigned ErrorInfoMissingFeature = 0; // Init suppresses compiler warnings. 2308 unsigned Match1, Match2, Match3, Match4; 2309 2310 Match1 = MatchInstructionImpl(Operands, Inst, ErrorInfoIgnore, 2311 isParsingIntelSyntax()); 2312 // If this returned as a missing feature failure, remember that. 2313 if (Match1 == Match_MissingFeature) 2314 ErrorInfoMissingFeature = ErrorInfoIgnore; 2315 Tmp[Base.size()] = Suffixes[1]; 2316 Match2 = MatchInstructionImpl(Operands, Inst, ErrorInfoIgnore, 2317 isParsingIntelSyntax()); 2318 // If this returned as a missing feature failure, remember that. 2319 if (Match2 == Match_MissingFeature) 2320 ErrorInfoMissingFeature = ErrorInfoIgnore; 2321 Tmp[Base.size()] = Suffixes[2]; 2322 Match3 = MatchInstructionImpl(Operands, Inst, ErrorInfoIgnore, 2323 isParsingIntelSyntax()); 2324 // If this returned as a missing feature failure, remember that. 2325 if (Match3 == Match_MissingFeature) 2326 ErrorInfoMissingFeature = ErrorInfoIgnore; 2327 Tmp[Base.size()] = Suffixes[3]; 2328 Match4 = MatchInstructionImpl(Operands, Inst, ErrorInfoIgnore, 2329 isParsingIntelSyntax()); 2330 // If this returned as a missing feature failure, remember that. 2331 if (Match4 == Match_MissingFeature) 2332 ErrorInfoMissingFeature = ErrorInfoIgnore; 2333 2334 // Restore the old token. 2335 Op->setTokenValue(Base); 2336 2337 // If exactly one matched, then we treat that as a successful match (and the 2338 // instruction will already have been filled in correctly, since the failing 2339 // matches won't have modified it). 2340 unsigned NumSuccessfulMatches = 2341 (Match1 == Match_Success) + (Match2 == Match_Success) + 2342 (Match3 == Match_Success) + (Match4 == Match_Success); 2343 if (NumSuccessfulMatches == 1) { 2344 Inst.setLoc(IDLoc); 2345 if (!MatchingInlineAsm) 2346 Out.EmitInstruction(Inst); 2347 Opcode = Inst.getOpcode(); 2348 return false; 2349 } 2350 2351 // Otherwise, the match failed, try to produce a decent error message. 2352 2353 // If we had multiple suffix matches, then identify this as an ambiguous 2354 // match. 2355 if (NumSuccessfulMatches > 1) { 2356 char MatchChars[4]; 2357 unsigned NumMatches = 0; 2358 if (Match1 == Match_Success) MatchChars[NumMatches++] = Suffixes[0]; 2359 if (Match2 == Match_Success) MatchChars[NumMatches++] = Suffixes[1]; 2360 if (Match3 == Match_Success) MatchChars[NumMatches++] = Suffixes[2]; 2361 if (Match4 == Match_Success) MatchChars[NumMatches++] = Suffixes[3]; 2362 2363 SmallString<126> Msg; 2364 raw_svector_ostream OS(Msg); 2365 OS << "ambiguous instructions require an explicit suffix (could be "; 2366 for (unsigned i = 0; i != NumMatches; ++i) { 2367 if (i != 0) 2368 OS << ", "; 2369 if (i + 1 == NumMatches) 2370 OS << "or "; 2371 OS << "'" << Base << MatchChars[i] << "'"; 2372 } 2373 OS << ")"; 2374 Error(IDLoc, OS.str(), EmptyRanges, MatchingInlineAsm); 2375 return true; 2376 } 2377 2378 // Okay, we know that none of the variants matched successfully. 2379 2380 // If all of the instructions reported an invalid mnemonic, then the original 2381 // mnemonic was invalid. 2382 if ((Match1 == Match_MnemonicFail) && (Match2 == Match_MnemonicFail) && 2383 (Match3 == Match_MnemonicFail) && (Match4 == Match_MnemonicFail)) { 2384 if (!WasOriginallyInvalidOperand) { 2385 ArrayRef<SMRange> Ranges = MatchingInlineAsm ? EmptyRanges : 2386 Op->getLocRange(); 2387 return Error(IDLoc, "invalid instruction mnemonic '" + Base + "'", 2388 Ranges, MatchingInlineAsm); 2389 } 2390 2391 // Recover location info for the operand if we know which was the problem. 2392 if (ErrorInfo != ~0U) { 2393 if (ErrorInfo >= Operands.size()) 2394 return Error(IDLoc, "too few operands for instruction", 2395 EmptyRanges, MatchingInlineAsm); 2396 2397 X86Operand *Operand = (X86Operand*)Operands[ErrorInfo]; 2398 if (Operand->getStartLoc().isValid()) { 2399 SMRange OperandRange = Operand->getLocRange(); 2400 return Error(Operand->getStartLoc(), "invalid operand for instruction", 2401 OperandRange, MatchingInlineAsm); 2402 } 2403 } 2404 2405 return Error(IDLoc, "invalid operand for instruction", EmptyRanges, 2406 MatchingInlineAsm); 2407 } 2408 2409 // If one instruction matched with a missing feature, report this as a 2410 // missing feature. 2411 if ((Match1 == Match_MissingFeature) + (Match2 == Match_MissingFeature) + 2412 (Match3 == Match_MissingFeature) + (Match4 == Match_MissingFeature) == 1){ 2413 std::string Msg = "instruction requires:"; 2414 unsigned Mask = 1; 2415 for (unsigned i = 0; i < (sizeof(ErrorInfoMissingFeature)*8-1); ++i) { 2416 if (ErrorInfoMissingFeature & Mask) { 2417 Msg += " "; 2418 Msg += getSubtargetFeatureName(ErrorInfoMissingFeature & Mask); 2419 } 2420 Mask <<= 1; 2421 } 2422 return Error(IDLoc, Msg, EmptyRanges, MatchingInlineAsm); 2423 } 2424 2425 // If one instruction matched with an invalid operand, report this as an 2426 // operand failure. 2427 if ((Match1 == Match_InvalidOperand) + (Match2 == Match_InvalidOperand) + 2428 (Match3 == Match_InvalidOperand) + (Match4 == Match_InvalidOperand) == 1){ 2429 Error(IDLoc, "invalid operand for instruction", EmptyRanges, 2430 MatchingInlineAsm); 2431 return true; 2432 } 2433 2434 // If all of these were an outright failure, report it in a useless way. 2435 Error(IDLoc, "unknown use of instruction mnemonic without a size suffix", 2436 EmptyRanges, MatchingInlineAsm); 2437 return true; 2438 } 2439 2440 2441 bool X86AsmParser::ParseDirective(AsmToken DirectiveID) { 2442 StringRef IDVal = DirectiveID.getIdentifier(); 2443 if (IDVal == ".word") 2444 return ParseDirectiveWord(2, DirectiveID.getLoc()); 2445 else if (IDVal.startswith(".code")) 2446 return ParseDirectiveCode(IDVal, DirectiveID.getLoc()); 2447 else if (IDVal.startswith(".att_syntax")) { 2448 getParser().setAssemblerDialect(0); 2449 return false; 2450 } else if (IDVal.startswith(".intel_syntax")) { 2451 getParser().setAssemblerDialect(1); 2452 if (getLexer().isNot(AsmToken::EndOfStatement)) { 2453 if(Parser.getTok().getString() == "noprefix") { 2454 // FIXME : Handle noprefix 2455 Parser.Lex(); 2456 } else 2457 return true; 2458 } 2459 return false; 2460 } 2461 return true; 2462 } 2463 2464 /// ParseDirectiveWord 2465 /// ::= .word [ expression (, expression)* ] 2466 bool X86AsmParser::ParseDirectiveWord(unsigned Size, SMLoc L) { 2467 if (getLexer().isNot(AsmToken::EndOfStatement)) { 2468 for (;;) { 2469 const MCExpr *Value; 2470 if (getParser().parseExpression(Value)) 2471 return true; 2472 2473 getParser().getStreamer().EmitValue(Value, Size); 2474 2475 if (getLexer().is(AsmToken::EndOfStatement)) 2476 break; 2477 2478 // FIXME: Improve diagnostic. 2479 if (getLexer().isNot(AsmToken::Comma)) 2480 return Error(L, "unexpected token in directive"); 2481 Parser.Lex(); 2482 } 2483 } 2484 2485 Parser.Lex(); 2486 return false; 2487 } 2488 2489 /// ParseDirectiveCode 2490 /// ::= .code32 | .code64 2491 bool X86AsmParser::ParseDirectiveCode(StringRef IDVal, SMLoc L) { 2492 if (IDVal == ".code32") { 2493 Parser.Lex(); 2494 if (is64BitMode()) { 2495 SwitchMode(); 2496 getParser().getStreamer().EmitAssemblerFlag(MCAF_Code32); 2497 } 2498 } else if (IDVal == ".code64") { 2499 Parser.Lex(); 2500 if (!is64BitMode()) { 2501 SwitchMode(); 2502 getParser().getStreamer().EmitAssemblerFlag(MCAF_Code64); 2503 } 2504 } else { 2505 return Error(L, "unexpected directive " + IDVal); 2506 } 2507 2508 return false; 2509 } 2510 2511 // Force static initialization. 2512 extern "C" void LLVMInitializeX86AsmParser() { 2513 RegisterMCAsmParser<X86AsmParser> X(TheX86_32Target); 2514 RegisterMCAsmParser<X86AsmParser> Y(TheX86_64Target); 2515 } 2516 2517 #define GET_REGISTER_MATCHER 2518 #define GET_MATCHER_IMPLEMENTATION 2519 #define GET_SUBTARGET_FEATURE_NAME 2520 #include "X86GenAsmMatcher.inc" 2521