1 // Copyright (c) 1994-2006 Sun Microsystems Inc. 2 // All Rights Reserved. 3 // 4 // Redistribution and use in source and binary forms, with or without 5 // modification, are permitted provided that the following conditions are 6 // met: 7 // 8 // - Redistributions of source code must retain the above copyright notice, 9 // this list of conditions and the following disclaimer. 10 // 11 // - Redistribution in binary form must reproduce the above copyright 12 // notice, this list of conditions and the following disclaimer in the 13 // documentation and/or other materials provided with the distribution. 14 // 15 // - Neither the name of Sun Microsystems or the names of contributors may 16 // be used to endorse or promote products derived from this software without 17 // specific prior written permission. 18 // 19 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS 20 // IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, 21 // THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 // PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR 23 // CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, 24 // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, 25 // PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR 26 // PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF 27 // LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING 28 // NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS 29 // SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 30 31 // The original source code covered by the above license above has been 32 // modified significantly by Google Inc. 33 // Copyright 2012 the V8 project authors. All rights reserved. 34 35 #ifndef V8_ASSEMBLER_H_ 36 #define V8_ASSEMBLER_H_ 37 38 #include <forward_list> 39 #include <iosfwd> 40 #include <map> 41 42 #include "src/allocation.h" 43 #include "src/code-reference.h" 44 #include "src/contexts.h" 45 #include "src/deoptimize-reason.h" 46 #include "src/double.h" 47 #include "src/external-reference.h" 48 #include "src/flags.h" 49 #include "src/globals.h" 50 #include "src/label.h" 51 #include "src/objects.h" 52 #include "src/register-configuration.h" 53 #include "src/reglist.h" 54 #include "src/reloc-info.h" 55 56 namespace v8 { 57 58 // Forward declarations. 59 class ApiFunction; 60 61 namespace internal { 62 63 // Forward declarations. 64 class EmbeddedData; 65 class InstructionStream; 66 class Isolate; 67 class SCTableReference; 68 class SourcePosition; 69 class StatsCounter; 70 71 // ----------------------------------------------------------------------------- 72 // Optimization for far-jmp like instructions that can be replaced by shorter. 73 74 class JumpOptimizationInfo { 75 public: is_collecting()76 bool is_collecting() const { return stage_ == kCollection; } is_optimizing()77 bool is_optimizing() const { return stage_ == kOptimization; } set_optimizing()78 void set_optimizing() { stage_ = kOptimization; } 79 is_optimizable()80 bool is_optimizable() const { return optimizable_; } set_optimizable()81 void set_optimizable() { optimizable_ = true; } 82 83 // Used to verify the instruction sequence is always the same in two stages. hash_code()84 size_t hash_code() const { return hash_code_; } set_hash_code(size_t hash_code)85 void set_hash_code(size_t hash_code) { hash_code_ = hash_code; } 86 farjmp_bitmap()87 std::vector<uint32_t>& farjmp_bitmap() { return farjmp_bitmap_; } 88 89 private: 90 enum { kCollection, kOptimization } stage_ = kCollection; 91 bool optimizable_ = false; 92 std::vector<uint32_t> farjmp_bitmap_; 93 size_t hash_code_ = 0u; 94 }; 95 96 class HeapObjectRequest { 97 public: 98 explicit HeapObjectRequest(double heap_number, int offset = -1); 99 explicit HeapObjectRequest(CodeStub* code_stub, int offset = -1); 100 101 enum Kind { kHeapNumber, kCodeStub }; kind()102 Kind kind() const { return kind_; } 103 heap_number()104 double heap_number() const { 105 DCHECK_EQ(kind(), kHeapNumber); 106 return value_.heap_number; 107 } 108 code_stub()109 CodeStub* code_stub() const { 110 DCHECK_EQ(kind(), kCodeStub); 111 return value_.code_stub; 112 } 113 114 // The code buffer offset at the time of the request. offset()115 int offset() const { 116 DCHECK_GE(offset_, 0); 117 return offset_; 118 } set_offset(int offset)119 void set_offset(int offset) { 120 DCHECK_LT(offset_, 0); 121 offset_ = offset; 122 DCHECK_GE(offset_, 0); 123 } 124 125 private: 126 Kind kind_; 127 128 union { 129 double heap_number; 130 CodeStub* code_stub; 131 } value_; 132 133 int offset_; 134 }; 135 136 // ----------------------------------------------------------------------------- 137 // Platform independent assembler base class. 138 139 enum class CodeObjectRequired { kNo, kYes }; 140 141 struct V8_EXPORT_PRIVATE AssemblerOptions { 142 // Recording reloc info for external references and off-heap targets is 143 // needed whenever code is serialized, e.g. into the snapshot or as a WASM 144 // module. This flag allows this reloc info to be disabled for code that 145 // will not survive process destruction. 146 bool record_reloc_info_for_serialization = true; 147 // Recording reloc info can be disabled wholesale. This is needed when the 148 // assembler is used on existing code directly (e.g. JumpTableAssembler) 149 // without any buffer to hold reloc information. 150 bool disable_reloc_info_for_patching = false; 151 // Enables access to exrefs by computing a delta from the root array. 152 // Only valid if code will not survive the process. 153 bool enable_root_array_delta_access = false; 154 // Enables specific assembler sequences only used for the simulator. 155 bool enable_simulator_code = false; 156 // Enables use of isolate-independent constants, indirected through the 157 // root array. 158 // (macro assembler feature). 159 bool isolate_independent_code = false; 160 // Enables the use of isolate-independent builtins through an off-heap 161 // trampoline. (macro assembler feature). 162 bool inline_offheap_trampolines = false; 163 // On some platforms, all code is within a given range in the process, 164 // and the start of this range is configured here. 165 Address code_range_start = 0; 166 // Enable pc-relative calls/jumps on platforms that support it. When setting 167 // this flag, the code range must be small enough to fit all offsets into 168 // the instruction immediates. 169 bool use_pc_relative_calls_and_jumps = false; 170 171 static AssemblerOptions Default( 172 Isolate* isolate, bool explicitly_support_serialization = false); 173 }; 174 175 class V8_EXPORT_PRIVATE AssemblerBase : public Malloced { 176 public: 177 AssemblerBase(const AssemblerOptions& options, void* buffer, int buffer_size); 178 virtual ~AssemblerBase(); 179 options()180 const AssemblerOptions& options() const { return options_; } 181 emit_debug_code()182 bool emit_debug_code() const { return emit_debug_code_; } set_emit_debug_code(bool value)183 void set_emit_debug_code(bool value) { emit_debug_code_ = value; } 184 predictable_code_size()185 bool predictable_code_size() const { return predictable_code_size_; } set_predictable_code_size(bool value)186 void set_predictable_code_size(bool value) { predictable_code_size_ = value; } 187 enabled_cpu_features()188 uint64_t enabled_cpu_features() const { return enabled_cpu_features_; } set_enabled_cpu_features(uint64_t features)189 void set_enabled_cpu_features(uint64_t features) { 190 enabled_cpu_features_ = features; 191 } 192 // Features are usually enabled by CpuFeatureScope, which also asserts that 193 // the features are supported before they are enabled. IsEnabled(CpuFeature f)194 bool IsEnabled(CpuFeature f) { 195 return (enabled_cpu_features_ & (static_cast<uint64_t>(1) << f)) != 0; 196 } EnableCpuFeature(CpuFeature f)197 void EnableCpuFeature(CpuFeature f) { 198 enabled_cpu_features_ |= (static_cast<uint64_t>(1) << f); 199 } 200 is_constant_pool_available()201 bool is_constant_pool_available() const { 202 if (FLAG_enable_embedded_constant_pool) { 203 return constant_pool_available_; 204 } else { 205 // Embedded constant pool not supported on this architecture. 206 UNREACHABLE(); 207 } 208 } 209 jump_optimization_info()210 JumpOptimizationInfo* jump_optimization_info() { 211 return jump_optimization_info_; 212 } set_jump_optimization_info(JumpOptimizationInfo * jump_opt)213 void set_jump_optimization_info(JumpOptimizationInfo* jump_opt) { 214 jump_optimization_info_ = jump_opt; 215 } 216 217 // Overwrite a host NaN with a quiet target NaN. Used by mksnapshot for 218 // cross-snapshotting. QuietNaN(HeapObject * nan)219 static void QuietNaN(HeapObject* nan) { } 220 pc_offset()221 int pc_offset() const { return static_cast<int>(pc_ - buffer_); } 222 223 // This function is called when code generation is aborted, so that 224 // the assembler could clean up internal data structures. AbortedCodeGeneration()225 virtual void AbortedCodeGeneration() { } 226 227 // Debugging 228 void Print(Isolate* isolate); 229 230 static const int kMinimalBufferSize = 4*KB; 231 232 static void FlushICache(void* start, size_t size); FlushICache(Address start,size_t size)233 static void FlushICache(Address start, size_t size) { 234 return FlushICache(reinterpret_cast<void*>(start), size); 235 } 236 237 // Used to print the name of some special registers. GetSpecialRegisterName(int code)238 static const char* GetSpecialRegisterName(int code) { return "UNKNOWN"; } 239 240 protected: 241 // Add 'target' to the {code_targets_} vector, if necessary, and return the 242 // offset at which it is stored. 243 int AddCodeTarget(Handle<Code> target); 244 Handle<Code> GetCodeTarget(intptr_t code_target_index) const; 245 // Update to the code target at {code_target_index} to {target}. 246 void UpdateCodeTarget(intptr_t code_target_index, Handle<Code> target); 247 // Reserves space in the code target vector. ReserveCodeTargetSpace(size_t num_of_code_targets)248 void ReserveCodeTargetSpace(size_t num_of_code_targets) { 249 code_targets_.reserve(num_of_code_targets); 250 } 251 252 // The buffer into which code and relocation info are generated. It could 253 // either be owned by the assembler or be provided externally. 254 byte* buffer_; 255 int buffer_size_; 256 bool own_buffer_; 257 std::forward_list<HeapObjectRequest> heap_object_requests_; 258 // The program counter, which points into the buffer above and moves forward. 259 // TODO(jkummerow): This should probably have type {Address}. 260 byte* pc_; 261 set_constant_pool_available(bool available)262 void set_constant_pool_available(bool available) { 263 if (FLAG_enable_embedded_constant_pool) { 264 constant_pool_available_ = available; 265 } else { 266 // Embedded constant pool not supported on this architecture. 267 UNREACHABLE(); 268 } 269 } 270 271 // {RequestHeapObject} records the need for a future heap number allocation or 272 // code stub generation. After code assembly, each platform's 273 // {Assembler::AllocateAndInstallRequestedHeapObjects} will allocate these 274 // objects and place them where they are expected (determined by the pc offset 275 // associated with each request). 276 void RequestHeapObject(HeapObjectRequest request); 277 278 private: 279 // Before we copy code into the code space, we sometimes cannot encode 280 // call/jump code targets as we normally would, as the difference between the 281 // instruction's location in the temporary buffer and the call target is not 282 // guaranteed to fit in the instruction's offset field. We keep track of the 283 // code handles we encounter in calls in this vector, and encode the index of 284 // the code handle in the vector instead. 285 std::vector<Handle<Code>> code_targets_; 286 287 const AssemblerOptions options_; 288 uint64_t enabled_cpu_features_; 289 bool emit_debug_code_; 290 bool predictable_code_size_; 291 292 // Indicates whether the constant pool can be accessed, which is only possible 293 // if the pp register points to the current code object's constant pool. 294 bool constant_pool_available_; 295 296 JumpOptimizationInfo* jump_optimization_info_; 297 298 // Constant pool. 299 friend class FrameAndConstantPoolScope; 300 friend class ConstantPoolUnavailableScope; 301 }; 302 303 // Avoids emitting debug code during the lifetime of this scope object. 304 class DontEmitDebugCodeScope BASE_EMBEDDED { 305 public: DontEmitDebugCodeScope(AssemblerBase * assembler)306 explicit DontEmitDebugCodeScope(AssemblerBase* assembler) 307 : assembler_(assembler), old_value_(assembler->emit_debug_code()) { 308 assembler_->set_emit_debug_code(false); 309 } ~DontEmitDebugCodeScope()310 ~DontEmitDebugCodeScope() { 311 assembler_->set_emit_debug_code(old_value_); 312 } 313 private: 314 AssemblerBase* assembler_; 315 bool old_value_; 316 }; 317 318 319 // Avoids using instructions that vary in size in unpredictable ways between the 320 // snapshot and the running VM. 321 class PredictableCodeSizeScope { 322 public: 323 PredictableCodeSizeScope(AssemblerBase* assembler, int expected_size); 324 ~PredictableCodeSizeScope(); 325 326 private: 327 AssemblerBase* const assembler_; 328 int const expected_size_; 329 int const start_offset_; 330 bool const old_value_; 331 }; 332 333 334 // Enable a specified feature within a scope. 335 class CpuFeatureScope BASE_EMBEDDED { 336 public: 337 enum CheckPolicy { 338 kCheckSupported, 339 kDontCheckSupported, 340 }; 341 342 #ifdef DEBUG 343 CpuFeatureScope(AssemblerBase* assembler, CpuFeature f, 344 CheckPolicy check = kCheckSupported); 345 ~CpuFeatureScope(); 346 347 private: 348 AssemblerBase* assembler_; 349 uint64_t old_enabled_; 350 #else 351 CpuFeatureScope(AssemblerBase* assembler, CpuFeature f, 352 CheckPolicy check = kCheckSupported) {} 353 // Define a destructor to avoid unused variable warnings. ~CpuFeatureScope()354 ~CpuFeatureScope() {} 355 #endif 356 }; 357 358 359 // CpuFeatures keeps track of which features are supported by the target CPU. 360 // Supported features must be enabled by a CpuFeatureScope before use. 361 // Example: 362 // if (assembler->IsSupported(SSE3)) { 363 // CpuFeatureScope fscope(assembler, SSE3); 364 // // Generate code containing SSE3 instructions. 365 // } else { 366 // // Generate alternative code. 367 // } 368 class CpuFeatures : public AllStatic { 369 public: Probe(bool cross_compile)370 static void Probe(bool cross_compile) { 371 STATIC_ASSERT(NUMBER_OF_CPU_FEATURES <= kBitsPerInt); 372 if (initialized_) return; 373 initialized_ = true; 374 ProbeImpl(cross_compile); 375 } 376 SupportedFeatures()377 static unsigned SupportedFeatures() { 378 Probe(false); 379 return supported_; 380 } 381 IsSupported(CpuFeature f)382 static bool IsSupported(CpuFeature f) { 383 return (supported_ & (1u << f)) != 0; 384 } 385 386 static inline bool SupportsOptimizer(); 387 388 static inline bool SupportsWasmSimd128(); 389 icache_line_size()390 static inline unsigned icache_line_size() { 391 DCHECK_NE(icache_line_size_, 0); 392 return icache_line_size_; 393 } 394 dcache_line_size()395 static inline unsigned dcache_line_size() { 396 DCHECK_NE(dcache_line_size_, 0); 397 return dcache_line_size_; 398 } 399 400 static void PrintTarget(); 401 static void PrintFeatures(); 402 403 private: 404 friend class ExternalReference; 405 friend class AssemblerBase; 406 // Flush instruction cache. 407 static void FlushICache(void* start, size_t size); 408 409 // Platform-dependent implementation. 410 static void ProbeImpl(bool cross_compile); 411 412 static unsigned supported_; 413 static unsigned icache_line_size_; 414 static unsigned dcache_line_size_; 415 static bool initialized_; 416 DISALLOW_COPY_AND_ASSIGN(CpuFeatures); 417 }; 418 419 // ----------------------------------------------------------------------------- 420 // Utility functions 421 422 // Computes pow(x, y) with the special cases in the spec for Math.pow. 423 double power_helper(Isolate* isolate, double x, double y); 424 double power_double_int(double x, int y); 425 double power_double_double(double x, double y); 426 427 428 // ----------------------------------------------------------------------------- 429 // Constant pool support 430 431 class ConstantPoolEntry { 432 public: ConstantPoolEntry()433 ConstantPoolEntry() {} 434 ConstantPoolEntry(int position, intptr_t value, bool sharing_ok, 435 RelocInfo::Mode rmode = RelocInfo::NONE) position_(position)436 : position_(position), 437 merged_index_(sharing_ok ? SHARING_ALLOWED : SHARING_PROHIBITED), 438 value_(value), 439 rmode_(rmode) {} 440 ConstantPoolEntry(int position, Double value, 441 RelocInfo::Mode rmode = RelocInfo::NONE) position_(position)442 : position_(position), 443 merged_index_(SHARING_ALLOWED), 444 value64_(value.AsUint64()), 445 rmode_(rmode) {} 446 position()447 int position() const { return position_; } sharing_ok()448 bool sharing_ok() const { return merged_index_ != SHARING_PROHIBITED; } is_merged()449 bool is_merged() const { return merged_index_ >= 0; } merged_index(void)450 int merged_index(void) const { 451 DCHECK(is_merged()); 452 return merged_index_; 453 } set_merged_index(int index)454 void set_merged_index(int index) { 455 DCHECK(sharing_ok()); 456 merged_index_ = index; 457 DCHECK(is_merged()); 458 } offset(void)459 int offset(void) const { 460 DCHECK_GE(merged_index_, 0); 461 return merged_index_; 462 } set_offset(int offset)463 void set_offset(int offset) { 464 DCHECK_GE(offset, 0); 465 merged_index_ = offset; 466 } value()467 intptr_t value() const { return value_; } value64()468 uint64_t value64() const { return value64_; } rmode()469 RelocInfo::Mode rmode() const { return rmode_; } 470 471 enum Type { INTPTR, DOUBLE, NUMBER_OF_TYPES }; 472 size(Type type)473 static int size(Type type) { 474 return (type == INTPTR) ? kPointerSize : kDoubleSize; 475 } 476 477 enum Access { REGULAR, OVERFLOWED }; 478 479 private: 480 int position_; 481 int merged_index_; 482 union { 483 intptr_t value_; 484 uint64_t value64_; 485 }; 486 // TODO(leszeks): The way we use this, it could probably be packed into 487 // merged_index_ if size is a concern. 488 RelocInfo::Mode rmode_; 489 enum { SHARING_PROHIBITED = -2, SHARING_ALLOWED = -1 }; 490 }; 491 492 493 // ----------------------------------------------------------------------------- 494 // Embedded constant pool support 495 496 class ConstantPoolBuilder BASE_EMBEDDED { 497 public: 498 ConstantPoolBuilder(int ptr_reach_bits, int double_reach_bits); 499 500 // Add pointer-sized constant to the embedded constant pool AddEntry(int position,intptr_t value,bool sharing_ok)501 ConstantPoolEntry::Access AddEntry(int position, intptr_t value, 502 bool sharing_ok) { 503 ConstantPoolEntry entry(position, value, sharing_ok); 504 return AddEntry(entry, ConstantPoolEntry::INTPTR); 505 } 506 507 // Add double constant to the embedded constant pool AddEntry(int position,Double value)508 ConstantPoolEntry::Access AddEntry(int position, Double value) { 509 ConstantPoolEntry entry(position, value); 510 return AddEntry(entry, ConstantPoolEntry::DOUBLE); 511 } 512 513 // Add double constant to the embedded constant pool AddEntry(int position,double value)514 ConstantPoolEntry::Access AddEntry(int position, double value) { 515 return AddEntry(position, Double(value)); 516 } 517 518 // Previews the access type required for the next new entry to be added. 519 ConstantPoolEntry::Access NextAccess(ConstantPoolEntry::Type type) const; 520 IsEmpty()521 bool IsEmpty() { 522 return info_[ConstantPoolEntry::INTPTR].entries.empty() && 523 info_[ConstantPoolEntry::INTPTR].shared_entries.empty() && 524 info_[ConstantPoolEntry::DOUBLE].entries.empty() && 525 info_[ConstantPoolEntry::DOUBLE].shared_entries.empty(); 526 } 527 528 // Emit the constant pool. Invoke only after all entries have been 529 // added and all instructions have been emitted. 530 // Returns position of the emitted pool (zero implies no constant pool). 531 int Emit(Assembler* assm); 532 533 // Returns the label associated with the start of the constant pool. 534 // Linking to this label in the function prologue may provide an 535 // efficient means of constant pool pointer register initialization 536 // on some architectures. EmittedPosition()537 inline Label* EmittedPosition() { return &emitted_label_; } 538 539 private: 540 ConstantPoolEntry::Access AddEntry(ConstantPoolEntry& entry, 541 ConstantPoolEntry::Type type); 542 void EmitSharedEntries(Assembler* assm, ConstantPoolEntry::Type type); 543 void EmitGroup(Assembler* assm, ConstantPoolEntry::Access access, 544 ConstantPoolEntry::Type type); 545 546 struct PerTypeEntryInfo { PerTypeEntryInfoPerTypeEntryInfo547 PerTypeEntryInfo() : regular_count(0), overflow_start(-1) {} overflowPerTypeEntryInfo548 bool overflow() const { 549 return (overflow_start >= 0 && 550 overflow_start < static_cast<int>(entries.size())); 551 } 552 int regular_reach_bits; 553 int regular_count; 554 int overflow_start; 555 std::vector<ConstantPoolEntry> entries; 556 std::vector<ConstantPoolEntry> shared_entries; 557 }; 558 559 Label emitted_label_; // Records pc_offset of emitted pool 560 PerTypeEntryInfo info_[ConstantPoolEntry::NUMBER_OF_TYPES]; 561 }; 562 563 // Base type for CPU Registers. 564 // 565 // 1) We would prefer to use an enum for registers, but enum values are 566 // assignment-compatible with int, which has caused code-generation bugs. 567 // 568 // 2) By not using an enum, we are possibly preventing the compiler from 569 // doing certain constant folds, which may significantly reduce the 570 // code generated for some assembly instructions (because they boil down 571 // to a few constants). If this is a problem, we could change the code 572 // such that we use an enum in optimized mode, and the class in debug 573 // mode. This way we get the compile-time error checking in debug mode 574 // and best performance in optimized code. 575 template <typename SubType, int kAfterLastRegister> 576 class RegisterBase { 577 // Internal enum class; used for calling constexpr methods, where we need to 578 // pass an integral type as template parameter. 579 enum class RegisterCode : int { kFirst = 0, kAfterLast = kAfterLastRegister }; 580 581 public: 582 static constexpr int kCode_no_reg = -1; 583 static constexpr int kNumRegisters = kAfterLastRegister; 584 no_reg()585 static constexpr SubType no_reg() { return SubType{kCode_no_reg}; } 586 587 template <int code> from_code()588 static constexpr SubType from_code() { 589 static_assert(code >= 0 && code < kNumRegisters, "must be valid reg code"); 590 return SubType{code}; 591 } 592 RegisterCode()593 constexpr operator RegisterCode() const { 594 return static_cast<RegisterCode>(reg_code_); 595 } 596 597 template <RegisterCode reg_code> code()598 static constexpr int code() { 599 static_assert( 600 reg_code >= RegisterCode::kFirst && reg_code < RegisterCode::kAfterLast, 601 "must be valid reg"); 602 return static_cast<int>(reg_code); 603 } 604 605 template <RegisterCode reg_code> bit()606 static constexpr RegList bit() { 607 return RegList{1} << code<reg_code>(); 608 } 609 from_code(int code)610 static SubType from_code(int code) { 611 DCHECK_LE(0, code); 612 DCHECK_GT(kNumRegisters, code); 613 return SubType{code}; 614 } 615 616 // Constexpr version (pass registers as template parameters). 617 template <RegisterCode... reg_codes> ListOf()618 static constexpr RegList ListOf() { 619 return CombineRegLists(RegisterBase::bit<reg_codes>()...); 620 } 621 622 // Non-constexpr version (pass registers as method parameters). 623 template <typename... Register> ListOf(Register...regs)624 static RegList ListOf(Register... regs) { 625 return CombineRegLists(regs.bit()...); 626 } 627 is_valid()628 bool is_valid() const { return reg_code_ != kCode_no_reg; } 629 code()630 int code() const { 631 DCHECK(is_valid()); 632 return reg_code_; 633 } 634 bit()635 RegList bit() const { return RegList{1} << code(); } 636 637 inline constexpr bool operator==(SubType other) const { 638 return reg_code_ == other.reg_code_; 639 } 640 inline constexpr bool operator!=(SubType other) const { 641 return reg_code_ != other.reg_code_; 642 } 643 644 protected: RegisterBase(int code)645 explicit constexpr RegisterBase(int code) : reg_code_(code) {} 646 int reg_code_; 647 }; 648 649 template <typename SubType, int kAfterLastRegister> 650 inline std::ostream& operator<<(std::ostream& os, 651 RegisterBase<SubType, kAfterLastRegister> reg) { 652 return reg.is_valid() ? os << "r" << reg.code() : os << "<invalid reg>"; 653 } 654 655 } // namespace internal 656 } // namespace v8 657 #endif // V8_ASSEMBLER_H_ 658