1 //===-- X86AsmBackend.cpp - X86 Assembler Backend -------------------------===// 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 "MCTargetDesc/X86FixupKinds.h" 12 #include "llvm/ADT/StringSwitch.h" 13 #include "llvm/MC/MCAsmBackend.h" 14 #include "llvm/MC/MCELFObjectWriter.h" 15 #include "llvm/MC/MCExpr.h" 16 #include "llvm/MC/MCFixupKindInfo.h" 17 #include "llvm/MC/MCMachObjectWriter.h" 18 #include "llvm/MC/MCObjectWriter.h" 19 #include "llvm/MC/MCSectionCOFF.h" 20 #include "llvm/MC/MCSectionELF.h" 21 #include "llvm/MC/MCSectionMachO.h" 22 #include "llvm/Support/CommandLine.h" 23 #include "llvm/Support/ELF.h" 24 #include "llvm/Support/ErrorHandling.h" 25 #include "llvm/Support/MachO.h" 26 #include "llvm/Support/TargetRegistry.h" 27 #include "llvm/Support/raw_ostream.h" 28 using namespace llvm; 29 30 // Option to allow disabling arithmetic relaxation to workaround PR9807, which 31 // is useful when running bitwise comparison experiments on Darwin. We should be 32 // able to remove this once PR9807 is resolved. 33 static cl::opt<bool> 34 MCDisableArithRelaxation("mc-x86-disable-arith-relaxation", 35 cl::desc("Disable relaxation of arithmetic instruction for X86")); 36 37 static unsigned getFixupKindLog2Size(unsigned Kind) { 38 switch (Kind) { 39 default: 40 llvm_unreachable("invalid fixup kind!"); 41 case FK_PCRel_1: 42 case FK_SecRel_1: 43 case FK_Data_1: 44 return 0; 45 case FK_PCRel_2: 46 case FK_SecRel_2: 47 case FK_Data_2: 48 return 1; 49 case FK_PCRel_4: 50 case X86::reloc_riprel_4byte: 51 case X86::reloc_riprel_4byte_movq_load: 52 case X86::reloc_signed_4byte: 53 case X86::reloc_global_offset_table: 54 case FK_SecRel_4: 55 case FK_Data_4: 56 return 2; 57 case FK_PCRel_8: 58 case FK_SecRel_8: 59 case FK_Data_8: 60 case X86::reloc_global_offset_table8: 61 return 3; 62 } 63 } 64 65 namespace { 66 67 class X86ELFObjectWriter : public MCELFObjectTargetWriter { 68 public: 69 X86ELFObjectWriter(bool is64Bit, uint8_t OSABI, uint16_t EMachine, 70 bool HasRelocationAddend, bool foobar) 71 : MCELFObjectTargetWriter(is64Bit, OSABI, EMachine, HasRelocationAddend) {} 72 }; 73 74 class X86AsmBackend : public MCAsmBackend { 75 const StringRef CPU; 76 bool HasNopl; 77 const uint64_t MaxNopLength; 78 public: 79 X86AsmBackend(const Target &T, StringRef CPU) 80 : MCAsmBackend(), CPU(CPU), MaxNopLength(CPU == "slm" ? 7 : 15) { 81 HasNopl = CPU != "generic" && CPU != "i386" && CPU != "i486" && 82 CPU != "i586" && CPU != "pentium" && CPU != "pentium-mmx" && 83 CPU != "i686" && CPU != "k6" && CPU != "k6-2" && CPU != "k6-3" && 84 CPU != "geode" && CPU != "winchip-c6" && CPU != "winchip2" && 85 CPU != "c3" && CPU != "c3-2"; 86 } 87 88 unsigned getNumFixupKinds() const override { 89 return X86::NumTargetFixupKinds; 90 } 91 92 const MCFixupKindInfo &getFixupKindInfo(MCFixupKind Kind) const override { 93 const static MCFixupKindInfo Infos[X86::NumTargetFixupKinds] = { 94 { "reloc_riprel_4byte", 0, 4 * 8, MCFixupKindInfo::FKF_IsPCRel }, 95 { "reloc_riprel_4byte_movq_load", 0, 4 * 8, MCFixupKindInfo::FKF_IsPCRel}, 96 { "reloc_signed_4byte", 0, 4 * 8, 0}, 97 { "reloc_global_offset_table", 0, 4 * 8, 0} 98 }; 99 100 if (Kind < FirstTargetFixupKind) 101 return MCAsmBackend::getFixupKindInfo(Kind); 102 103 assert(unsigned(Kind - FirstTargetFixupKind) < getNumFixupKinds() && 104 "Invalid kind!"); 105 return Infos[Kind - FirstTargetFixupKind]; 106 } 107 108 void applyFixup(const MCFixup &Fixup, char *Data, unsigned DataSize, 109 uint64_t Value, bool IsPCRel) const override { 110 unsigned Size = 1 << getFixupKindLog2Size(Fixup.getKind()); 111 112 assert(Fixup.getOffset() + Size <= DataSize && 113 "Invalid fixup offset!"); 114 115 // Check that uppper bits are either all zeros or all ones. 116 // Specifically ignore overflow/underflow as long as the leakage is 117 // limited to the lower bits. This is to remain compatible with 118 // other assemblers. 119 assert(isIntN(Size * 8 + 1, Value) && 120 "Value does not fit in the Fixup field"); 121 122 for (unsigned i = 0; i != Size; ++i) 123 Data[Fixup.getOffset() + i] = uint8_t(Value >> (i * 8)); 124 } 125 126 bool mayNeedRelaxation(const MCInst &Inst) const override; 127 128 bool fixupNeedsRelaxation(const MCFixup &Fixup, uint64_t Value, 129 const MCRelaxableFragment *DF, 130 const MCAsmLayout &Layout) const override; 131 132 void relaxInstruction(const MCInst &Inst, MCInst &Res) const override; 133 134 bool writeNopData(uint64_t Count, MCObjectWriter *OW) const override; 135 }; 136 } // end anonymous namespace 137 138 static unsigned getRelaxedOpcodeBranch(unsigned Op) { 139 switch (Op) { 140 default: 141 return Op; 142 143 case X86::JAE_1: return X86::JAE_4; 144 case X86::JA_1: return X86::JA_4; 145 case X86::JBE_1: return X86::JBE_4; 146 case X86::JB_1: return X86::JB_4; 147 case X86::JE_1: return X86::JE_4; 148 case X86::JGE_1: return X86::JGE_4; 149 case X86::JG_1: return X86::JG_4; 150 case X86::JLE_1: return X86::JLE_4; 151 case X86::JL_1: return X86::JL_4; 152 case X86::JMP_1: return X86::JMP_4; 153 case X86::JNE_1: return X86::JNE_4; 154 case X86::JNO_1: return X86::JNO_4; 155 case X86::JNP_1: return X86::JNP_4; 156 case X86::JNS_1: return X86::JNS_4; 157 case X86::JO_1: return X86::JO_4; 158 case X86::JP_1: return X86::JP_4; 159 case X86::JS_1: return X86::JS_4; 160 } 161 } 162 163 static unsigned getRelaxedOpcodeArith(unsigned Op) { 164 switch (Op) { 165 default: 166 return Op; 167 168 // IMUL 169 case X86::IMUL16rri8: return X86::IMUL16rri; 170 case X86::IMUL16rmi8: return X86::IMUL16rmi; 171 case X86::IMUL32rri8: return X86::IMUL32rri; 172 case X86::IMUL32rmi8: return X86::IMUL32rmi; 173 case X86::IMUL64rri8: return X86::IMUL64rri32; 174 case X86::IMUL64rmi8: return X86::IMUL64rmi32; 175 176 // AND 177 case X86::AND16ri8: return X86::AND16ri; 178 case X86::AND16mi8: return X86::AND16mi; 179 case X86::AND32ri8: return X86::AND32ri; 180 case X86::AND32mi8: return X86::AND32mi; 181 case X86::AND64ri8: return X86::AND64ri32; 182 case X86::AND64mi8: return X86::AND64mi32; 183 184 // OR 185 case X86::OR16ri8: return X86::OR16ri; 186 case X86::OR16mi8: return X86::OR16mi; 187 case X86::OR32ri8: return X86::OR32ri; 188 case X86::OR32mi8: return X86::OR32mi; 189 case X86::OR64ri8: return X86::OR64ri32; 190 case X86::OR64mi8: return X86::OR64mi32; 191 192 // XOR 193 case X86::XOR16ri8: return X86::XOR16ri; 194 case X86::XOR16mi8: return X86::XOR16mi; 195 case X86::XOR32ri8: return X86::XOR32ri; 196 case X86::XOR32mi8: return X86::XOR32mi; 197 case X86::XOR64ri8: return X86::XOR64ri32; 198 case X86::XOR64mi8: return X86::XOR64mi32; 199 200 // ADD 201 case X86::ADD16ri8: return X86::ADD16ri; 202 case X86::ADD16mi8: return X86::ADD16mi; 203 case X86::ADD32ri8: return X86::ADD32ri; 204 case X86::ADD32mi8: return X86::ADD32mi; 205 case X86::ADD64ri8: return X86::ADD64ri32; 206 case X86::ADD64mi8: return X86::ADD64mi32; 207 208 // SUB 209 case X86::SUB16ri8: return X86::SUB16ri; 210 case X86::SUB16mi8: return X86::SUB16mi; 211 case X86::SUB32ri8: return X86::SUB32ri; 212 case X86::SUB32mi8: return X86::SUB32mi; 213 case X86::SUB64ri8: return X86::SUB64ri32; 214 case X86::SUB64mi8: return X86::SUB64mi32; 215 216 // CMP 217 case X86::CMP16ri8: return X86::CMP16ri; 218 case X86::CMP16mi8: return X86::CMP16mi; 219 case X86::CMP32ri8: return X86::CMP32ri; 220 case X86::CMP32mi8: return X86::CMP32mi; 221 case X86::CMP64ri8: return X86::CMP64ri32; 222 case X86::CMP64mi8: return X86::CMP64mi32; 223 224 // PUSH 225 case X86::PUSH32i8: return X86::PUSHi32; 226 case X86::PUSH16i8: return X86::PUSHi16; 227 case X86::PUSH64i8: return X86::PUSH64i32; 228 case X86::PUSH64i16: return X86::PUSH64i32; 229 } 230 } 231 232 static unsigned getRelaxedOpcode(unsigned Op) { 233 unsigned R = getRelaxedOpcodeArith(Op); 234 if (R != Op) 235 return R; 236 return getRelaxedOpcodeBranch(Op); 237 } 238 239 bool X86AsmBackend::mayNeedRelaxation(const MCInst &Inst) const { 240 // Branches can always be relaxed. 241 if (getRelaxedOpcodeBranch(Inst.getOpcode()) != Inst.getOpcode()) 242 return true; 243 244 if (MCDisableArithRelaxation) 245 return false; 246 247 // Check if this instruction is ever relaxable. 248 if (getRelaxedOpcodeArith(Inst.getOpcode()) == Inst.getOpcode()) 249 return false; 250 251 252 // Check if it has an expression and is not RIP relative. 253 bool hasExp = false; 254 bool hasRIP = false; 255 for (unsigned i = 0; i < Inst.getNumOperands(); ++i) { 256 const MCOperand &Op = Inst.getOperand(i); 257 if (Op.isExpr()) 258 hasExp = true; 259 260 if (Op.isReg() && Op.getReg() == X86::RIP) 261 hasRIP = true; 262 } 263 264 // FIXME: Why exactly do we need the !hasRIP? Is it just a limitation on 265 // how we do relaxations? 266 return hasExp && !hasRIP; 267 } 268 269 bool X86AsmBackend::fixupNeedsRelaxation(const MCFixup &Fixup, 270 uint64_t Value, 271 const MCRelaxableFragment *DF, 272 const MCAsmLayout &Layout) const { 273 // Relax if the value is too big for a (signed) i8. 274 return int64_t(Value) != int64_t(int8_t(Value)); 275 } 276 277 // FIXME: Can tblgen help at all here to verify there aren't other instructions 278 // we can relax? 279 void X86AsmBackend::relaxInstruction(const MCInst &Inst, MCInst &Res) const { 280 // The only relaxations X86 does is from a 1byte pcrel to a 4byte pcrel. 281 unsigned RelaxedOp = getRelaxedOpcode(Inst.getOpcode()); 282 283 if (RelaxedOp == Inst.getOpcode()) { 284 SmallString<256> Tmp; 285 raw_svector_ostream OS(Tmp); 286 Inst.dump_pretty(OS); 287 OS << "\n"; 288 report_fatal_error("unexpected instruction to relax: " + OS.str()); 289 } 290 291 Res = Inst; 292 Res.setOpcode(RelaxedOp); 293 } 294 295 /// \brief Write a sequence of optimal nops to the output, covering \p Count 296 /// bytes. 297 /// \return - true on success, false on failure 298 bool X86AsmBackend::writeNopData(uint64_t Count, MCObjectWriter *OW) const { 299 static const uint8_t Nops[10][10] = { 300 // nop 301 {0x90}, 302 // xchg %ax,%ax 303 {0x66, 0x90}, 304 // nopl (%[re]ax) 305 {0x0f, 0x1f, 0x00}, 306 // nopl 0(%[re]ax) 307 {0x0f, 0x1f, 0x40, 0x00}, 308 // nopl 0(%[re]ax,%[re]ax,1) 309 {0x0f, 0x1f, 0x44, 0x00, 0x00}, 310 // nopw 0(%[re]ax,%[re]ax,1) 311 {0x66, 0x0f, 0x1f, 0x44, 0x00, 0x00}, 312 // nopl 0L(%[re]ax) 313 {0x0f, 0x1f, 0x80, 0x00, 0x00, 0x00, 0x00}, 314 // nopl 0L(%[re]ax,%[re]ax,1) 315 {0x0f, 0x1f, 0x84, 0x00, 0x00, 0x00, 0x00, 0x00}, 316 // nopw 0L(%[re]ax,%[re]ax,1) 317 {0x66, 0x0f, 0x1f, 0x84, 0x00, 0x00, 0x00, 0x00, 0x00}, 318 // nopw %cs:0L(%[re]ax,%[re]ax,1) 319 {0x66, 0x2e, 0x0f, 0x1f, 0x84, 0x00, 0x00, 0x00, 0x00, 0x00}, 320 }; 321 322 // This CPU doesn't support long nops. If needed add more. 323 // FIXME: Can we get this from the subtarget somehow? 324 // FIXME: We could generated something better than plain 0x90. 325 if (!HasNopl) { 326 for (uint64_t i = 0; i < Count; ++i) 327 OW->Write8(0x90); 328 return true; 329 } 330 331 // 15 is the longest single nop instruction. Emit as many 15-byte nops as 332 // needed, then emit a nop of the remaining length. 333 do { 334 const uint8_t ThisNopLength = (uint8_t) std::min(Count, MaxNopLength); 335 const uint8_t Prefixes = ThisNopLength <= 10 ? 0 : ThisNopLength - 10; 336 for (uint8_t i = 0; i < Prefixes; i++) 337 OW->Write8(0x66); 338 const uint8_t Rest = ThisNopLength - Prefixes; 339 for (uint8_t i = 0; i < Rest; i++) 340 OW->Write8(Nops[Rest - 1][i]); 341 Count -= ThisNopLength; 342 } while (Count != 0); 343 344 return true; 345 } 346 347 /* *** */ 348 349 namespace { 350 351 class ELFX86AsmBackend : public X86AsmBackend { 352 public: 353 uint8_t OSABI; 354 ELFX86AsmBackend(const Target &T, uint8_t OSABI, StringRef CPU) 355 : X86AsmBackend(T, CPU), OSABI(OSABI) {} 356 }; 357 358 class ELFX86_32AsmBackend : public ELFX86AsmBackend { 359 public: 360 ELFX86_32AsmBackend(const Target &T, uint8_t OSABI, StringRef CPU) 361 : ELFX86AsmBackend(T, OSABI, CPU) {} 362 363 MCObjectWriter *createObjectWriter(raw_pwrite_stream &OS) const override { 364 return createX86ELFObjectWriter(OS, /*IsELF64*/ false, OSABI, ELF::EM_386); 365 } 366 }; 367 368 class ELFX86_X32AsmBackend : public ELFX86AsmBackend { 369 public: 370 ELFX86_X32AsmBackend(const Target &T, uint8_t OSABI, StringRef CPU) 371 : ELFX86AsmBackend(T, OSABI, CPU) {} 372 373 MCObjectWriter *createObjectWriter(raw_pwrite_stream &OS) const override { 374 return createX86ELFObjectWriter(OS, /*IsELF64*/ false, OSABI, 375 ELF::EM_X86_64); 376 } 377 }; 378 379 class ELFX86_64AsmBackend : public ELFX86AsmBackend { 380 public: 381 ELFX86_64AsmBackend(const Target &T, uint8_t OSABI, StringRef CPU) 382 : ELFX86AsmBackend(T, OSABI, CPU) {} 383 384 MCObjectWriter *createObjectWriter(raw_pwrite_stream &OS) const override { 385 return createX86ELFObjectWriter(OS, /*IsELF64*/ true, OSABI, ELF::EM_X86_64); 386 } 387 }; 388 389 class WindowsX86AsmBackend : public X86AsmBackend { 390 bool Is64Bit; 391 392 public: 393 WindowsX86AsmBackend(const Target &T, bool is64Bit, StringRef CPU) 394 : X86AsmBackend(T, CPU) 395 , Is64Bit(is64Bit) { 396 } 397 398 MCObjectWriter *createObjectWriter(raw_pwrite_stream &OS) const override { 399 return createX86WinCOFFObjectWriter(OS, Is64Bit); 400 } 401 }; 402 403 namespace CU { 404 405 /// Compact unwind encoding values. 406 enum CompactUnwindEncodings { 407 /// [RE]BP based frame where [RE]BP is pused on the stack immediately after 408 /// the return address, then [RE]SP is moved to [RE]BP. 409 UNWIND_MODE_BP_FRAME = 0x01000000, 410 411 /// A frameless function with a small constant stack size. 412 UNWIND_MODE_STACK_IMMD = 0x02000000, 413 414 /// A frameless function with a large constant stack size. 415 UNWIND_MODE_STACK_IND = 0x03000000, 416 417 /// No compact unwind encoding is available. 418 UNWIND_MODE_DWARF = 0x04000000, 419 420 /// Mask for encoding the frame registers. 421 UNWIND_BP_FRAME_REGISTERS = 0x00007FFF, 422 423 /// Mask for encoding the frameless registers. 424 UNWIND_FRAMELESS_STACK_REG_PERMUTATION = 0x000003FF 425 }; 426 427 } // end CU namespace 428 429 class DarwinX86AsmBackend : public X86AsmBackend { 430 const MCRegisterInfo &MRI; 431 432 /// \brief Number of registers that can be saved in a compact unwind encoding. 433 enum { CU_NUM_SAVED_REGS = 6 }; 434 435 mutable unsigned SavedRegs[CU_NUM_SAVED_REGS]; 436 bool Is64Bit; 437 438 unsigned OffsetSize; ///< Offset of a "push" instruction. 439 unsigned MoveInstrSize; ///< Size of a "move" instruction. 440 unsigned StackDivide; ///< Amount to adjust stack size by. 441 protected: 442 /// \brief Size of a "push" instruction for the given register. 443 unsigned PushInstrSize(unsigned Reg) const { 444 switch (Reg) { 445 case X86::EBX: 446 case X86::ECX: 447 case X86::EDX: 448 case X86::EDI: 449 case X86::ESI: 450 case X86::EBP: 451 case X86::RBX: 452 case X86::RBP: 453 return 1; 454 case X86::R12: 455 case X86::R13: 456 case X86::R14: 457 case X86::R15: 458 return 2; 459 } 460 return 1; 461 } 462 463 /// \brief Implementation of algorithm to generate the compact unwind encoding 464 /// for the CFI instructions. 465 uint32_t 466 generateCompactUnwindEncodingImpl(ArrayRef<MCCFIInstruction> Instrs) const { 467 if (Instrs.empty()) return 0; 468 469 // Reset the saved registers. 470 unsigned SavedRegIdx = 0; 471 memset(SavedRegs, 0, sizeof(SavedRegs)); 472 473 bool HasFP = false; 474 475 // Encode that we are using EBP/RBP as the frame pointer. 476 uint32_t CompactUnwindEncoding = 0; 477 478 unsigned SubtractInstrIdx = Is64Bit ? 3 : 2; 479 unsigned InstrOffset = 0; 480 unsigned StackAdjust = 0; 481 unsigned StackSize = 0; 482 unsigned PrevStackSize = 0; 483 unsigned NumDefCFAOffsets = 0; 484 485 for (unsigned i = 0, e = Instrs.size(); i != e; ++i) { 486 const MCCFIInstruction &Inst = Instrs[i]; 487 488 switch (Inst.getOperation()) { 489 default: 490 // Any other CFI directives indicate a frame that we aren't prepared 491 // to represent via compact unwind, so just bail out. 492 return 0; 493 case MCCFIInstruction::OpDefCfaRegister: { 494 // Defines a frame pointer. E.g. 495 // 496 // movq %rsp, %rbp 497 // L0: 498 // .cfi_def_cfa_register %rbp 499 // 500 HasFP = true; 501 assert(MRI.getLLVMRegNum(Inst.getRegister(), true) == 502 (Is64Bit ? X86::RBP : X86::EBP) && "Invalid frame pointer!"); 503 504 // Reset the counts. 505 memset(SavedRegs, 0, sizeof(SavedRegs)); 506 StackAdjust = 0; 507 SavedRegIdx = 0; 508 InstrOffset += MoveInstrSize; 509 break; 510 } 511 case MCCFIInstruction::OpDefCfaOffset: { 512 // Defines a new offset for the CFA. E.g. 513 // 514 // With frame: 515 // 516 // pushq %rbp 517 // L0: 518 // .cfi_def_cfa_offset 16 519 // 520 // Without frame: 521 // 522 // subq $72, %rsp 523 // L0: 524 // .cfi_def_cfa_offset 80 525 // 526 PrevStackSize = StackSize; 527 StackSize = std::abs(Inst.getOffset()) / StackDivide; 528 ++NumDefCFAOffsets; 529 break; 530 } 531 case MCCFIInstruction::OpOffset: { 532 // Defines a "push" of a callee-saved register. E.g. 533 // 534 // pushq %r15 535 // pushq %r14 536 // pushq %rbx 537 // L0: 538 // subq $120, %rsp 539 // L1: 540 // .cfi_offset %rbx, -40 541 // .cfi_offset %r14, -32 542 // .cfi_offset %r15, -24 543 // 544 if (SavedRegIdx == CU_NUM_SAVED_REGS) 545 // If there are too many saved registers, we cannot use a compact 546 // unwind encoding. 547 return CU::UNWIND_MODE_DWARF; 548 549 unsigned Reg = MRI.getLLVMRegNum(Inst.getRegister(), true); 550 SavedRegs[SavedRegIdx++] = Reg; 551 StackAdjust += OffsetSize; 552 InstrOffset += PushInstrSize(Reg); 553 break; 554 } 555 } 556 } 557 558 StackAdjust /= StackDivide; 559 560 if (HasFP) { 561 if ((StackAdjust & 0xFF) != StackAdjust) 562 // Offset was too big for a compact unwind encoding. 563 return CU::UNWIND_MODE_DWARF; 564 565 // Get the encoding of the saved registers when we have a frame pointer. 566 uint32_t RegEnc = encodeCompactUnwindRegistersWithFrame(); 567 if (RegEnc == ~0U) return CU::UNWIND_MODE_DWARF; 568 569 CompactUnwindEncoding |= CU::UNWIND_MODE_BP_FRAME; 570 CompactUnwindEncoding |= (StackAdjust & 0xFF) << 16; 571 CompactUnwindEncoding |= RegEnc & CU::UNWIND_BP_FRAME_REGISTERS; 572 } else { 573 // If the amount of the stack allocation is the size of a register, then 574 // we "push" the RAX/EAX register onto the stack instead of adjusting the 575 // stack pointer with a SUB instruction. We don't support the push of the 576 // RAX/EAX register with compact unwind. So we check for that situation 577 // here. 578 if ((NumDefCFAOffsets == SavedRegIdx + 1 && 579 StackSize - PrevStackSize == 1) || 580 (Instrs.size() == 1 && NumDefCFAOffsets == 1 && StackSize == 2)) 581 return CU::UNWIND_MODE_DWARF; 582 583 SubtractInstrIdx += InstrOffset; 584 ++StackAdjust; 585 586 if ((StackSize & 0xFF) == StackSize) { 587 // Frameless stack with a small stack size. 588 CompactUnwindEncoding |= CU::UNWIND_MODE_STACK_IMMD; 589 590 // Encode the stack size. 591 CompactUnwindEncoding |= (StackSize & 0xFF) << 16; 592 } else { 593 if ((StackAdjust & 0x7) != StackAdjust) 594 // The extra stack adjustments are too big for us to handle. 595 return CU::UNWIND_MODE_DWARF; 596 597 // Frameless stack with an offset too large for us to encode compactly. 598 CompactUnwindEncoding |= CU::UNWIND_MODE_STACK_IND; 599 600 // Encode the offset to the nnnnnn value in the 'subl $nnnnnn, ESP' 601 // instruction. 602 CompactUnwindEncoding |= (SubtractInstrIdx & 0xFF) << 16; 603 604 // Encode any extra stack stack adjustments (done via push 605 // instructions). 606 CompactUnwindEncoding |= (StackAdjust & 0x7) << 13; 607 } 608 609 // Encode the number of registers saved. (Reverse the list first.) 610 std::reverse(&SavedRegs[0], &SavedRegs[SavedRegIdx]); 611 CompactUnwindEncoding |= (SavedRegIdx & 0x7) << 10; 612 613 // Get the encoding of the saved registers when we don't have a frame 614 // pointer. 615 uint32_t RegEnc = encodeCompactUnwindRegistersWithoutFrame(SavedRegIdx); 616 if (RegEnc == ~0U) return CU::UNWIND_MODE_DWARF; 617 618 // Encode the register encoding. 619 CompactUnwindEncoding |= 620 RegEnc & CU::UNWIND_FRAMELESS_STACK_REG_PERMUTATION; 621 } 622 623 return CompactUnwindEncoding; 624 } 625 626 private: 627 /// \brief Get the compact unwind number for a given register. The number 628 /// corresponds to the enum lists in compact_unwind_encoding.h. 629 int getCompactUnwindRegNum(unsigned Reg) const { 630 static const uint16_t CU32BitRegs[7] = { 631 X86::EBX, X86::ECX, X86::EDX, X86::EDI, X86::ESI, X86::EBP, 0 632 }; 633 static const uint16_t CU64BitRegs[] = { 634 X86::RBX, X86::R12, X86::R13, X86::R14, X86::R15, X86::RBP, 0 635 }; 636 const uint16_t *CURegs = Is64Bit ? CU64BitRegs : CU32BitRegs; 637 for (int Idx = 1; *CURegs; ++CURegs, ++Idx) 638 if (*CURegs == Reg) 639 return Idx; 640 641 return -1; 642 } 643 644 /// \brief Return the registers encoded for a compact encoding with a frame 645 /// pointer. 646 uint32_t encodeCompactUnwindRegistersWithFrame() const { 647 // Encode the registers in the order they were saved --- 3-bits per 648 // register. The list of saved registers is assumed to be in reverse 649 // order. The registers are numbered from 1 to CU_NUM_SAVED_REGS. 650 uint32_t RegEnc = 0; 651 for (int i = 0, Idx = 0; i != CU_NUM_SAVED_REGS; ++i) { 652 unsigned Reg = SavedRegs[i]; 653 if (Reg == 0) break; 654 655 int CURegNum = getCompactUnwindRegNum(Reg); 656 if (CURegNum == -1) return ~0U; 657 658 // Encode the 3-bit register number in order, skipping over 3-bits for 659 // each register. 660 RegEnc |= (CURegNum & 0x7) << (Idx++ * 3); 661 } 662 663 assert((RegEnc & 0x3FFFF) == RegEnc && 664 "Invalid compact register encoding!"); 665 return RegEnc; 666 } 667 668 /// \brief Create the permutation encoding used with frameless stacks. It is 669 /// passed the number of registers to be saved and an array of the registers 670 /// saved. 671 uint32_t encodeCompactUnwindRegistersWithoutFrame(unsigned RegCount) const { 672 // The saved registers are numbered from 1 to 6. In order to encode the 673 // order in which they were saved, we re-number them according to their 674 // place in the register order. The re-numbering is relative to the last 675 // re-numbered register. E.g., if we have registers {6, 2, 4, 5} saved in 676 // that order: 677 // 678 // Orig Re-Num 679 // ---- ------ 680 // 6 6 681 // 2 2 682 // 4 3 683 // 5 3 684 // 685 for (unsigned i = 0; i < RegCount; ++i) { 686 int CUReg = getCompactUnwindRegNum(SavedRegs[i]); 687 if (CUReg == -1) return ~0U; 688 SavedRegs[i] = CUReg; 689 } 690 691 // Reverse the list. 692 std::reverse(&SavedRegs[0], &SavedRegs[CU_NUM_SAVED_REGS]); 693 694 uint32_t RenumRegs[CU_NUM_SAVED_REGS]; 695 for (unsigned i = CU_NUM_SAVED_REGS - RegCount; i < CU_NUM_SAVED_REGS; ++i){ 696 unsigned Countless = 0; 697 for (unsigned j = CU_NUM_SAVED_REGS - RegCount; j < i; ++j) 698 if (SavedRegs[j] < SavedRegs[i]) 699 ++Countless; 700 701 RenumRegs[i] = SavedRegs[i] - Countless - 1; 702 } 703 704 // Take the renumbered values and encode them into a 10-bit number. 705 uint32_t permutationEncoding = 0; 706 switch (RegCount) { 707 case 6: 708 permutationEncoding |= 120 * RenumRegs[0] + 24 * RenumRegs[1] 709 + 6 * RenumRegs[2] + 2 * RenumRegs[3] 710 + RenumRegs[4]; 711 break; 712 case 5: 713 permutationEncoding |= 120 * RenumRegs[1] + 24 * RenumRegs[2] 714 + 6 * RenumRegs[3] + 2 * RenumRegs[4] 715 + RenumRegs[5]; 716 break; 717 case 4: 718 permutationEncoding |= 60 * RenumRegs[2] + 12 * RenumRegs[3] 719 + 3 * RenumRegs[4] + RenumRegs[5]; 720 break; 721 case 3: 722 permutationEncoding |= 20 * RenumRegs[3] + 4 * RenumRegs[4] 723 + RenumRegs[5]; 724 break; 725 case 2: 726 permutationEncoding |= 5 * RenumRegs[4] + RenumRegs[5]; 727 break; 728 case 1: 729 permutationEncoding |= RenumRegs[5]; 730 break; 731 } 732 733 assert((permutationEncoding & 0x3FF) == permutationEncoding && 734 "Invalid compact register encoding!"); 735 return permutationEncoding; 736 } 737 738 public: 739 DarwinX86AsmBackend(const Target &T, const MCRegisterInfo &MRI, StringRef CPU, 740 bool Is64Bit) 741 : X86AsmBackend(T, CPU), MRI(MRI), Is64Bit(Is64Bit) { 742 memset(SavedRegs, 0, sizeof(SavedRegs)); 743 OffsetSize = Is64Bit ? 8 : 4; 744 MoveInstrSize = Is64Bit ? 3 : 2; 745 StackDivide = Is64Bit ? 8 : 4; 746 } 747 }; 748 749 class DarwinX86_32AsmBackend : public DarwinX86AsmBackend { 750 public: 751 DarwinX86_32AsmBackend(const Target &T, const MCRegisterInfo &MRI, 752 StringRef CPU) 753 : DarwinX86AsmBackend(T, MRI, CPU, false) {} 754 755 MCObjectWriter *createObjectWriter(raw_pwrite_stream &OS) const override { 756 return createX86MachObjectWriter(OS, /*Is64Bit=*/false, 757 MachO::CPU_TYPE_I386, 758 MachO::CPU_SUBTYPE_I386_ALL); 759 } 760 761 /// \brief Generate the compact unwind encoding for the CFI instructions. 762 uint32_t generateCompactUnwindEncoding( 763 ArrayRef<MCCFIInstruction> Instrs) const override { 764 return generateCompactUnwindEncodingImpl(Instrs); 765 } 766 }; 767 768 class DarwinX86_64AsmBackend : public DarwinX86AsmBackend { 769 const MachO::CPUSubTypeX86 Subtype; 770 public: 771 DarwinX86_64AsmBackend(const Target &T, const MCRegisterInfo &MRI, 772 StringRef CPU, MachO::CPUSubTypeX86 st) 773 : DarwinX86AsmBackend(T, MRI, CPU, true), Subtype(st) {} 774 775 MCObjectWriter *createObjectWriter(raw_pwrite_stream &OS) const override { 776 return createX86MachObjectWriter(OS, /*Is64Bit=*/true, 777 MachO::CPU_TYPE_X86_64, Subtype); 778 } 779 780 /// \brief Generate the compact unwind encoding for the CFI instructions. 781 uint32_t generateCompactUnwindEncoding( 782 ArrayRef<MCCFIInstruction> Instrs) const override { 783 return generateCompactUnwindEncodingImpl(Instrs); 784 } 785 }; 786 787 } // end anonymous namespace 788 789 MCAsmBackend *llvm::createX86_32AsmBackend(const Target &T, 790 const MCRegisterInfo &MRI, 791 StringRef TT, 792 StringRef CPU) { 793 Triple TheTriple(TT); 794 795 if (TheTriple.isOSBinFormatMachO()) 796 return new DarwinX86_32AsmBackend(T, MRI, CPU); 797 798 if (TheTriple.isOSWindows() && !TheTriple.isOSBinFormatELF()) 799 return new WindowsX86AsmBackend(T, false, CPU); 800 801 uint8_t OSABI = MCELFObjectTargetWriter::getOSABI(TheTriple.getOS()); 802 return new ELFX86_32AsmBackend(T, OSABI, CPU); 803 } 804 805 MCAsmBackend *llvm::createX86_64AsmBackend(const Target &T, 806 const MCRegisterInfo &MRI, 807 StringRef TT, 808 StringRef CPU) { 809 Triple TheTriple(TT); 810 811 if (TheTriple.isOSBinFormatMachO()) { 812 MachO::CPUSubTypeX86 CS = 813 StringSwitch<MachO::CPUSubTypeX86>(TheTriple.getArchName()) 814 .Case("x86_64h", MachO::CPU_SUBTYPE_X86_64_H) 815 .Default(MachO::CPU_SUBTYPE_X86_64_ALL); 816 return new DarwinX86_64AsmBackend(T, MRI, CPU, CS); 817 } 818 819 if (TheTriple.isOSWindows() && !TheTriple.isOSBinFormatELF()) 820 return new WindowsX86AsmBackend(T, true, CPU); 821 822 uint8_t OSABI = MCELFObjectTargetWriter::getOSABI(TheTriple.getOS()); 823 824 if (TheTriple.getEnvironment() == Triple::GNUX32) 825 return new ELFX86_X32AsmBackend(T, OSABI, CPU); 826 return new ELFX86_64AsmBackend(T, OSABI, CPU); 827 } 828