third_party/v8/src/codegen/reloc-info.cc - cobalt - Git at Google

 // Copyright 2018 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "src/codegen/reloc-info.h"

 #include "src/codegen/assembler-inl.h"
 #include "src/codegen/code-reference.h"
 #include "src/codegen/external-reference-encoder.h"
 #include "src/deoptimizer/deoptimize-reason.h"
 #include "src/deoptimizer/deoptimizer.h"
 #include "src/heap/heap-write-barrier-inl.h"
 #include "src/objects/code-inl.h"
 #include "src/snapshot/embedded/embedded-data.h"

 namespace v8 {
 namespace internal {

 const char* const RelocInfo::kFillerCommentString = "DEOPTIMIZATION PADDING";

 // -----------------------------------------------------------------------------
 // Implementation of RelocInfoWriter and RelocIterator
 //
 // Relocation information is written backwards in memory, from high addresses
 // towards low addresses, byte by byte.  Therefore, in the encodings listed
 // below, the first byte listed it at the highest address, and successive
 // bytes in the record are at progressively lower addresses.
 //
 // Encoding
 //
 // The most common modes are given single-byte encodings.  Also, it is
 // easy to identify the type of reloc info and skip unwanted modes in
 // an iteration.
 //
 // The encoding relies on the fact that there are fewer than 14
 // different relocation modes using standard non-compact encoding.
 //
 // The first byte of a relocation record has a tag in its low 2 bits:
 // Here are the record schemes, depending on the low tag and optional higher
 // tags.
 //
 // Low tag:
 //   00: embedded_object:      [6-bit pc delta] 00
 //
 //   01: code_target:          [6-bit pc delta] 01
 //
 //   10: wasm_stub_call:       [6-bit pc delta] 10
 //
 //   11: long_record           [6 bit reloc mode] 11
 //                             followed by pc delta
 //                             followed by optional data depending on type.
 //
 //  If a pc delta exceeds 6 bits, it is split into a remainder that fits into
 //  6 bits and a part that does not. The latter is encoded as a long record
 //  with PC_JUMP as pseudo reloc info mode. The former is encoded as part of
 //  the following record in the usual way. The long pc jump record has variable
 //  length:
 //               pc-jump:        [PC_JUMP] 11
 //                               [7 bits data] 0
 //                                  ...
 //                               [7 bits data] 1
 //               (Bits 6..31 of pc delta, with leading zeroes
 //                dropped, and last non-zero chunk tagged with 1.)

 const int kTagBits = 2;
 const int kTagMask = (1 << kTagBits) - 1;
 const int kLongTagBits = 6;

 const int kEmbeddedObjectTag = 0;
 const int kCodeTargetTag = 1;
 const int kWasmStubCallTag = 2;
 const int kDefaultTag = 3;

 const int kSmallPCDeltaBits = kBitsPerByte - kTagBits;
 const int kSmallPCDeltaMask = (1 << kSmallPCDeltaBits) - 1;
 const int RelocInfo::kMaxSmallPCDelta = kSmallPCDeltaMask;

 const int kChunkBits = 7;
 const int kChunkMask = (1 << kChunkBits) - 1;
 const int kLastChunkTagBits = 1;
 const int kLastChunkTagMask = 1;
 const int kLastChunkTag = 1;

 uint32_t RelocInfoWriter::WriteLongPCJump(uint32_t pc_delta) {
   // Return if the pc_delta can fit in kSmallPCDeltaBits bits.
   // Otherwise write a variable length PC jump for the bits that do
   // not fit in the kSmallPCDeltaBits bits.
   if (is_uintn(pc_delta, kSmallPCDeltaBits)) return pc_delta;
   WriteMode(RelocInfo::PC_JUMP);
   uint32_t pc_jump = pc_delta >> kSmallPCDeltaBits;
   DCHECK_GT(pc_jump, 0);
   // Write kChunkBits size chunks of the pc_jump.
   for (; pc_jump > 0; pc_jump = pc_jump >> kChunkBits) {
     byte b = pc_jump & kChunkMask;
     *--pos_ = b << kLastChunkTagBits;
   }
   // Tag the last chunk so it can be identified.
   *pos_ = *pos_ | kLastChunkTag;
   // Return the remaining kSmallPCDeltaBits of the pc_delta.
   return pc_delta & kSmallPCDeltaMask;
 }

 void RelocInfoWriter::WriteShortTaggedPC(uint32_t pc_delta, int tag) {
   // Write a byte of tagged pc-delta, possibly preceded by an explicit pc-jump.
   pc_delta = WriteLongPCJump(pc_delta);
   *--pos_ = pc_delta << kTagBits | tag;
 }

 void RelocInfoWriter::WriteShortData(intptr_t data_delta) {
   *--pos_ = static_cast<byte>(data_delta);
 }

 void RelocInfoWriter::WriteMode(RelocInfo::Mode rmode) {
   STATIC_ASSERT(RelocInfo::NUMBER_OF_MODES <= (1 << kLongTagBits));
   *--pos_ = static_cast<int>((rmode << kTagBits) | kDefaultTag);
 }

 void RelocInfoWriter::WriteModeAndPC(uint32_t pc_delta, RelocInfo::Mode rmode) {
   // Write two-byte tagged pc-delta, possibly preceded by var. length pc-jump.
   pc_delta = WriteLongPCJump(pc_delta);
   WriteMode(rmode);
   *--pos_ = pc_delta;
 }

 void RelocInfoWriter::WriteIntData(int number) {
   for (int i = 0; i < kIntSize; i++) {
     *--pos_ = static_cast<byte>(number);
     // Signed right shift is arithmetic shift.  Tested in test-utils.cc.
     number = number >> kBitsPerByte;
   }
 }

 void RelocInfoWriter::WriteData(intptr_t data_delta) {
   for (int i = 0; i < kIntptrSize; i++) {
     *--pos_ = static_cast<byte>(data_delta);
     // Signed right shift is arithmetic shift.  Tested in test-utils.cc.
     data_delta = data_delta >> kBitsPerByte;
   }
 }

 void RelocInfoWriter::Write(const RelocInfo* rinfo) {
   RelocInfo::Mode rmode = rinfo->rmode();
 #ifdef DEBUG
   byte* begin_pos = pos_;
 #endif
   DCHECK(rinfo->rmode() < RelocInfo::NUMBER_OF_MODES);
   DCHECK_GE(rinfo->pc() - reinterpret_cast<Address>(last_pc_), 0);
   // Use unsigned delta-encoding for pc.
   uint32_t pc_delta =
       static_cast<uint32_t>(rinfo->pc() - reinterpret_cast<Address>(last_pc_));

   // The two most common modes are given small tags, and usually fit in a byte.
   if (rmode == RelocInfo::FULL_EMBEDDED_OBJECT) {
     WriteShortTaggedPC(pc_delta, kEmbeddedObjectTag);
   } else if (rmode == RelocInfo::CODE_TARGET) {
     WriteShortTaggedPC(pc_delta, kCodeTargetTag);
     DCHECK_LE(begin_pos - pos_, RelocInfo::kMaxCallSize);
   } else if (rmode == RelocInfo::WASM_STUB_CALL) {
     WriteShortTaggedPC(pc_delta, kWasmStubCallTag);
   } else {
     WriteModeAndPC(pc_delta, rmode);
     if (RelocInfo::IsDeoptReason(rmode)) {
       DCHECK_LT(rinfo->data(), 1 << kBitsPerByte);
       WriteShortData(rinfo->data());
     } else if (RelocInfo::IsConstPool(rmode) ||
                RelocInfo::IsVeneerPool(rmode) || RelocInfo::IsDeoptId(rmode) ||
                RelocInfo::IsDeoptPosition(rmode)) {
       WriteIntData(static_cast<int>(rinfo->data()));
     }
   }
   last_pc_ = reinterpret_cast<byte*>(rinfo->pc());
 #ifdef DEBUG
   DCHECK_LE(begin_pos - pos_, kMaxSize);
 #endif
 }

 inline int RelocIterator::AdvanceGetTag() { return *--pos_ & kTagMask; }

 inline RelocInfo::Mode RelocIterator::GetMode() {
   return static_cast<RelocInfo::Mode>((*pos_ >> kTagBits) &
                                       ((1 << kLongTagBits) - 1));
 }

 inline void RelocIterator::ReadShortTaggedPC() {
   rinfo_.pc_ += *pos_ >> kTagBits;
 }

 inline void RelocIterator::AdvanceReadPC() { rinfo_.pc_ += *--pos_; }

 void RelocIterator::AdvanceReadInt() {
   int x = 0;
   for (int i = 0; i < kIntSize; i++) {
     x |= static_cast<int>(*--pos_) << i * kBitsPerByte;
   }
   rinfo_.data_ = x;
 }

 void RelocIterator::AdvanceReadData() {
   intptr_t x = 0;
   for (int i = 0; i < kIntptrSize; i++) {
     x |= static_cast<intptr_t>(*--pos_) << i * kBitsPerByte;
   }
   rinfo_.data_ = x;
 }

 void RelocIterator::AdvanceReadLongPCJump() {
   // Read the 32-kSmallPCDeltaBits most significant bits of the
   // pc jump in kChunkBits bit chunks and shift them into place.
   // Stop when the last chunk is encountered.
   uint32_t pc_jump = 0;
   for (int i = 0; i < kIntSize; i++) {
     byte pc_jump_part = *--pos_;
     pc_jump |= (pc_jump_part >> kLastChunkTagBits) << i * kChunkBits;
     if ((pc_jump_part & kLastChunkTagMask) == 1) break;
   }
   // The least significant kSmallPCDeltaBits bits will be added
   // later.
   rinfo_.pc_ += pc_jump << kSmallPCDeltaBits;
 }

 inline void RelocIterator::ReadShortData() {
   uint8_t unsigned_b = *pos_;
   rinfo_.data_ = unsigned_b;
 }

 void RelocIterator::next() {
   DCHECK(!done());
   // Basically, do the opposite of RelocInfoWriter::Write.
   // Reading of data is as far as possible avoided for unwanted modes,
   // but we must always update the pc.
   //
   // We exit this loop by returning when we find a mode we want.
   while (pos_ > end_) {
     int tag = AdvanceGetTag();
     if (tag == kEmbeddedObjectTag) {
       ReadShortTaggedPC();
       if (SetMode(RelocInfo::FULL_EMBEDDED_OBJECT)) return;
     } else if (tag == kCodeTargetTag) {
       ReadShortTaggedPC();
       if (SetMode(RelocInfo::CODE_TARGET)) return;
     } else if (tag == kWasmStubCallTag) {
       ReadShortTaggedPC();
       if (SetMode(RelocInfo::WASM_STUB_CALL)) return;
     } else {
       DCHECK_EQ(tag, kDefaultTag);
       RelocInfo::Mode rmode = GetMode();
       if (rmode == RelocInfo::PC_JUMP) {
         AdvanceReadLongPCJump();
       } else {
         AdvanceReadPC();
         if (RelocInfo::IsDeoptReason(rmode)) {
           Advance();
           if (SetMode(rmode)) {
             ReadShortData();
             return;
           }
         } else if (RelocInfo::IsConstPool(rmode) ||
                    RelocInfo::IsVeneerPool(rmode) ||
                    RelocInfo::IsDeoptId(rmode) ||
                    RelocInfo::IsDeoptPosition(rmode)) {
           if (SetMode(rmode)) {
             AdvanceReadInt();
             return;
           }
           Advance(kIntSize);
         } else if (SetMode(static_cast<RelocInfo::Mode>(rmode))) {
           return;
         }
       }
     }
   }
   done_ = true;
 }

 RelocIterator::RelocIterator(Code code, int mode_mask)
     : RelocIterator(code, code.unchecked_relocation_info(), mode_mask) {}

 RelocIterator::RelocIterator(Code code, ByteArray relocation_info,
                              int mode_mask)
     : RelocIterator(code, code.raw_instruction_start(), code.constant_pool(),
                     relocation_info.GetDataEndAddress(),
                     relocation_info.GetDataStartAddress(), mode_mask) {}

 RelocIterator::RelocIterator(const CodeReference code_reference, int mode_mask)
     : RelocIterator(Code(), code_reference.instruction_start(),
                     code_reference.constant_pool(),
                     code_reference.relocation_end(),
                     code_reference.relocation_start(), mode_mask) {}

 RelocIterator::RelocIterator(EmbeddedData* embedded_data, Code code,
                              int mode_mask)
     : RelocIterator(
           code, embedded_data->InstructionStartOfBuiltin(code.builtin_index()),
           code.constant_pool(),
           code.relocation_start() + code.relocation_size(),
           code.relocation_start(), mode_mask) {}

 RelocIterator::RelocIterator(const CodeDesc& desc, int mode_mask)
     : RelocIterator(Code(), reinterpret_cast<Address>(desc.buffer), 0,
                     desc.buffer + desc.buffer_size,
                     desc.buffer + desc.buffer_size - desc.reloc_size,
                     mode_mask) {}

 RelocIterator::RelocIterator(Vector<byte> instructions,
                              Vector<const byte> reloc_info, Address const_pool,
                              int mode_mask)
     : RelocIterator(Code(), reinterpret_cast<Address>(instructions.begin()),
                     const_pool, reloc_info.begin() + reloc_info.size(),
                     reloc_info.begin(), mode_mask) {}

 RelocIterator::RelocIterator(Code host, Address pc, Address constant_pool,
                              const byte* pos, const byte* end, int mode_mask)
     : pos_(pos), end_(end), mode_mask_(mode_mask) {
   // Relocation info is read backwards.
   DCHECK_GE(pos_, end_);
   rinfo_.host_ = host;
   rinfo_.pc_ = pc;
   rinfo_.constant_pool_ = constant_pool;
   if (mode_mask_ == 0) pos_ = end_;
   next();
 }

 // -----------------------------------------------------------------------------
 // Implementation of RelocInfo

 // static
 bool RelocInfo::OffHeapTargetIsCodedSpecially() {
 #if defined(V8_TARGET_ARCH_ARM) || defined(V8_TARGET_ARCH_ARM64) || \
     defined(V8_TARGET_ARCH_X64)
   return false;
 #elif defined(V8_TARGET_ARCH_IA32) || defined(V8_TARGET_ARCH_MIPS) || \
     defined(V8_TARGET_ARCH_MIPS64) || defined(V8_TARGET_ARCH_PPC) ||  \
     defined(V8_TARGET_ARCH_PPC64) || defined(V8_TARGET_ARCH_S390)
   return true;
 #endif
 }

 Address RelocInfo::wasm_call_address() const {
   DCHECK_EQ(rmode_, WASM_CALL);
   return Assembler::target_address_at(pc_, constant_pool_);
 }

 void RelocInfo::set_wasm_call_address(Address address,
                                       ICacheFlushMode icache_flush_mode) {
   DCHECK_EQ(rmode_, WASM_CALL);
   Assembler::set_target_address_at(pc_, constant_pool_, address,
                                    icache_flush_mode);
 }

 Address RelocInfo::wasm_stub_call_address() const {
   DCHECK_EQ(rmode_, WASM_STUB_CALL);
   return Assembler::target_address_at(pc_, constant_pool_);
 }

 void RelocInfo::set_wasm_stub_call_address(Address address,
                                            ICacheFlushMode icache_flush_mode) {
   DCHECK_EQ(rmode_, WASM_STUB_CALL);
   Assembler::set_target_address_at(pc_, constant_pool_, address,
                                    icache_flush_mode);
 }

 void RelocInfo::set_target_address(Address target,
                                    WriteBarrierMode write_barrier_mode,
                                    ICacheFlushMode icache_flush_mode) {
   DCHECK(IsCodeTargetMode(rmode_) || IsRuntimeEntry(rmode_) ||
          IsWasmCall(rmode_));
   Assembler::set_target_address_at(pc_, constant_pool_, target,
                                    icache_flush_mode);
   if (write_barrier_mode == UPDATE_WRITE_BARRIER && !host().is_null() &&
       IsCodeTargetMode(rmode_) && !FLAG_disable_write_barriers) {
     Code target_code = Code::GetCodeFromTargetAddress(target);
     WriteBarrier::Marking(host(), this, target_code);
   }
 }

 bool RelocInfo::HasTargetAddressAddress() const {
   // TODO(jgruber): Investigate whether WASM_CALL is still appropriate on
   // non-intel platforms now that wasm code is no longer on the heap.
 #if defined(V8_TARGET_ARCH_IA32) || defined(V8_TARGET_ARCH_X64)
   static constexpr int kTargetAddressAddressModeMask =
       ModeMask(CODE_TARGET) | ModeMask(FULL_EMBEDDED_OBJECT) |
       ModeMask(COMPRESSED_EMBEDDED_OBJECT) | ModeMask(EXTERNAL_REFERENCE) |
       ModeMask(OFF_HEAP_TARGET) | ModeMask(RUNTIME_ENTRY) |
       ModeMask(WASM_CALL) | ModeMask(WASM_STUB_CALL);
 #else
   static constexpr int kTargetAddressAddressModeMask =
       ModeMask(CODE_TARGET) | ModeMask(RELATIVE_CODE_TARGET) |
       ModeMask(FULL_EMBEDDED_OBJECT) | ModeMask(EXTERNAL_REFERENCE) |
       ModeMask(OFF_HEAP_TARGET) | ModeMask(RUNTIME_ENTRY) | ModeMask(WASM_CALL);
 #endif
   return (ModeMask(rmode_) & kTargetAddressAddressModeMask) != 0;
 }

 bool RelocInfo::RequiresRelocationAfterCodegen(const CodeDesc& desc) {
   RelocIterator it(desc, RelocInfo::PostCodegenRelocationMask());
   return !it.done();
 }

 bool RelocInfo::RequiresRelocation(Code code) {
   RelocIterator it(code, RelocInfo::kApplyMask);
   return !it.done();
 }

 #ifdef ENABLE_DISASSEMBLER
 const char* RelocInfo::RelocModeName(RelocInfo::Mode rmode) {
   switch (rmode) {
     case NONE:
       return "no reloc";
     case COMPRESSED_EMBEDDED_OBJECT:
       return "compressed embedded object";
     case FULL_EMBEDDED_OBJECT:
       return "full embedded object";
     case CODE_TARGET:
       return "code target";
     case RELATIVE_CODE_TARGET:
       return "relative code target";
     case RUNTIME_ENTRY:
       return "runtime entry";
     case EXTERNAL_REFERENCE:
       return "external reference";
     case INTERNAL_REFERENCE:
       return "internal reference";
     case INTERNAL_REFERENCE_ENCODED:
       return "encoded internal reference";
     case OFF_HEAP_TARGET:
       return "off heap target";
     case DEOPT_SCRIPT_OFFSET:
       return "deopt script offset";
     case DEOPT_INLINING_ID:
       return "deopt inlining id";
     case DEOPT_REASON:
       return "deopt reason";
     case DEOPT_ID:
       return "deopt index";
     case CONST_POOL:
       return "constant pool";
     case VENEER_POOL:
       return "veneer pool";
     case WASM_CALL:
       return "internal wasm call";
     case WASM_STUB_CALL:
       return "wasm stub call";
     case NUMBER_OF_MODES:
     case PC_JUMP:
       UNREACHABLE();
   }
   return "unknown relocation type";
 }

 void RelocInfo::Print(Isolate* isolate, std::ostream& os) {  // NOLINT
   os << reinterpret_cast<const void*>(pc_) << "  " << RelocModeName(rmode_);
   if (rmode_ == DEOPT_SCRIPT_OFFSET || rmode_ == DEOPT_INLINING_ID) {
     os << "  (" << data() << ")";
   } else if (rmode_ == DEOPT_REASON) {
     os << "  ("
        << DeoptimizeReasonToString(static_cast<DeoptimizeReason>(data_)) << ")";
   } else if (rmode_ == FULL_EMBEDDED_OBJECT) {
     os << "  (" << Brief(target_object()) << ")";
   } else if (rmode_ == COMPRESSED_EMBEDDED_OBJECT) {
     os << "  (" << Brief(target_object()) << " compressed)";
   } else if (rmode_ == EXTERNAL_REFERENCE) {
     if (isolate) {
       ExternalReferenceEncoder ref_encoder(isolate);
       os << " ("
          << ref_encoder.NameOfAddress(isolate, target_external_reference())
          << ") ";
     }
     os << " (" << reinterpret_cast<const void*>(target_external_reference())
        << ")";
   } else if (IsCodeTargetMode(rmode_)) {
     const Address code_target = target_address();
     Code code = Code::GetCodeFromTargetAddress(code_target);
     DCHECK(code.IsCode());
     os << " (" << CodeKindToString(code.kind());
     if (Builtins::IsBuiltin(code)) {
       os << " " << Builtins::name(code.builtin_index());
     }
     os << ")  (" << reinterpret_cast<const void*>(target_address()) << ")";
   } else if (IsRuntimeEntry(rmode_)) {
     // Deoptimization bailouts are stored as runtime entries.
     DeoptimizeKind type;
     if (Deoptimizer::IsDeoptimizationEntry(isolate, target_address(), &type)) {
       os << "  (" << Deoptimizer::MessageFor(type, false)
          << " deoptimization bailout)";
     }
   } else if (IsConstPool(rmode_)) {
     os << " (size " << static_cast<int>(data_) << ")";
   }

   os << "\n";
 }
 #endif  // ENABLE_DISASSEMBLER

 #ifdef VERIFY_HEAP
 void RelocInfo::Verify(Isolate* isolate) {
   switch (rmode_) {
     case COMPRESSED_EMBEDDED_OBJECT:
     case FULL_EMBEDDED_OBJECT:
       Object::VerifyPointer(isolate, target_object());
       break;
     case CODE_TARGET:
     case RELATIVE_CODE_TARGET: {
       // convert inline target address to code object
       Address addr = target_address();
       CHECK_NE(addr, kNullAddress);
       // Check that we can find the right code object.
       Code code = Code::GetCodeFromTargetAddress(addr);
       Object found = isolate->FindCodeObject(addr);
       CHECK(found.IsCode());
       CHECK(code.address() == HeapObject::cast(found).address());
       break;
     }
     case INTERNAL_REFERENCE:
     case INTERNAL_REFERENCE_ENCODED: {
       Address target = target_internal_reference();
       Address pc = target_internal_reference_address();
       Code code = Code::cast(isolate->FindCodeObject(pc));
       CHECK(target >= code.InstructionStart());
       CHECK(target <= code.InstructionEnd());
       break;
     }
     case OFF_HEAP_TARGET: {
       Address addr = target_off_heap_target();
       CHECK_NE(addr, kNullAddress);
       CHECK(!InstructionStream::TryLookupCode(isolate, addr).is_null());
       break;
     }
     case RUNTIME_ENTRY:
     case EXTERNAL_REFERENCE:
     case DEOPT_SCRIPT_OFFSET:
     case DEOPT_INLINING_ID:
     case DEOPT_REASON:
     case DEOPT_ID:
     case CONST_POOL:
     case VENEER_POOL:
     case WASM_CALL:
     case WASM_STUB_CALL:
     case NONE:
       break;
     case NUMBER_OF_MODES:
     case PC_JUMP:
       UNREACHABLE();
   }
 }
 #endif  // VERIFY_HEAP

 }  // namespace internal
 }  // namespace v8
	// Copyright 2018 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "src/codegen/reloc-info.h"

	#include "src/codegen/assembler-inl.h"
	#include "src/codegen/code-reference.h"
	#include "src/codegen/external-reference-encoder.h"
	#include "src/deoptimizer/deoptimize-reason.h"
	#include "src/deoptimizer/deoptimizer.h"
	#include "src/heap/heap-write-barrier-inl.h"
	#include "src/objects/code-inl.h"
	#include "src/snapshot/embedded/embedded-data.h"

	namespace v8 {
	namespace internal {

	const char* const RelocInfo::kFillerCommentString = "DEOPTIMIZATION PADDING";

	// -----------------------------------------------------------------------------
	// Implementation of RelocInfoWriter and RelocIterator
	//
	// Relocation information is written backwards in memory, from high addresses
	// towards low addresses, byte by byte. Therefore, in the encodings listed
	// below, the first byte listed it at the highest address, and successive
	// bytes in the record are at progressively lower addresses.
	//
	// Encoding
	//
	// The most common modes are given single-byte encodings. Also, it is
	// easy to identify the type of reloc info and skip unwanted modes in
	// an iteration.
	//
	// The encoding relies on the fact that there are fewer than 14
	// different relocation modes using standard non-compact encoding.
	//
	// The first byte of a relocation record has a tag in its low 2 bits:
	// Here are the record schemes, depending on the low tag and optional higher
	// tags.
	//
	// Low tag:
	// 00: embedded_object: [6-bit pc delta] 00
	//
	// 01: code_target: [6-bit pc delta] 01
	//
	// 10: wasm_stub_call: [6-bit pc delta] 10
	//
	// 11: long_record [6 bit reloc mode] 11
	// followed by pc delta
	// followed by optional data depending on type.
	//
	// If a pc delta exceeds 6 bits, it is split into a remainder that fits into
	// 6 bits and a part that does not. The latter is encoded as a long record
	// with PC_JUMP as pseudo reloc info mode. The former is encoded as part of
	// the following record in the usual way. The long pc jump record has variable
	// length:
	// pc-jump: [PC_JUMP] 11
	// [7 bits data] 0
	// ...
	// [7 bits data] 1
	// (Bits 6..31 of pc delta, with leading zeroes
	// dropped, and last non-zero chunk tagged with 1.)

	const int kTagBits = 2;
	const int kTagMask = (1 << kTagBits) - 1;
	const int kLongTagBits = 6;

	const int kEmbeddedObjectTag = 0;
	const int kCodeTargetTag = 1;
	const int kWasmStubCallTag = 2;
	const int kDefaultTag = 3;

	const int kSmallPCDeltaBits = kBitsPerByte - kTagBits;
	const int kSmallPCDeltaMask = (1 << kSmallPCDeltaBits) - 1;
	const int RelocInfo::kMaxSmallPCDelta = kSmallPCDeltaMask;

	const int kChunkBits = 7;
	const int kChunkMask = (1 << kChunkBits) - 1;
	const int kLastChunkTagBits = 1;
	const int kLastChunkTagMask = 1;
	const int kLastChunkTag = 1;

	uint32_t RelocInfoWriter::WriteLongPCJump(uint32_t pc_delta) {
	// Return if the pc_delta can fit in kSmallPCDeltaBits bits.
	// Otherwise write a variable length PC jump for the bits that do
	// not fit in the kSmallPCDeltaBits bits.
	if (is_uintn(pc_delta, kSmallPCDeltaBits)) return pc_delta;
	WriteMode(RelocInfo::PC_JUMP);
	uint32_t pc_jump = pc_delta >> kSmallPCDeltaBits;
	DCHECK_GT(pc_jump, 0);
	// Write kChunkBits size chunks of the pc_jump.
	for (; pc_jump > 0; pc_jump = pc_jump >> kChunkBits) {
	byte b = pc_jump & kChunkMask;
	*--pos_ = b << kLastChunkTagBits;
	}
	// Tag the last chunk so it can be identified.
	pos_ = pos_ \| kLastChunkTag;
	// Return the remaining kSmallPCDeltaBits of the pc_delta.
	return pc_delta & kSmallPCDeltaMask;
	}

	void RelocInfoWriter::WriteShortTaggedPC(uint32_t pc_delta, int tag) {
	// Write a byte of tagged pc-delta, possibly preceded by an explicit pc-jump.
	pc_delta = WriteLongPCJump(pc_delta);
	*--pos_ = pc_delta << kTagBits \| tag;
	}

	void RelocInfoWriter::WriteShortData(intptr_t data_delta) {
	*--pos_ = static_cast<byte>(data_delta);
	}

	void RelocInfoWriter::WriteMode(RelocInfo::Mode rmode) {
	STATIC_ASSERT(RelocInfo::NUMBER_OF_MODES <= (1 << kLongTagBits));
	*--pos_ = static_cast<int>((rmode << kTagBits) \| kDefaultTag);
	}

	void RelocInfoWriter::WriteModeAndPC(uint32_t pc_delta, RelocInfo::Mode rmode) {
	// Write two-byte tagged pc-delta, possibly preceded by var. length pc-jump.
	pc_delta = WriteLongPCJump(pc_delta);
	WriteMode(rmode);
	*--pos_ = pc_delta;
	}

	void RelocInfoWriter::WriteIntData(int number) {
	for (int i = 0; i < kIntSize; i++) {
	*--pos_ = static_cast<byte>(number);
	// Signed right shift is arithmetic shift. Tested in test-utils.cc.
	number = number >> kBitsPerByte;
	}
	}

	void RelocInfoWriter::WriteData(intptr_t data_delta) {
	for (int i = 0; i < kIntptrSize; i++) {
	*--pos_ = static_cast<byte>(data_delta);
	// Signed right shift is arithmetic shift. Tested in test-utils.cc.
	data_delta = data_delta >> kBitsPerByte;
	}
	}

	void RelocInfoWriter::Write(const RelocInfo* rinfo) {
	RelocInfo::Mode rmode = rinfo->rmode();
	#ifdef DEBUG
	byte* begin_pos = pos_;
	#endif
	DCHECK(rinfo->rmode() < RelocInfo::NUMBER_OF_MODES);
	DCHECK_GE(rinfo->pc() - reinterpret_cast<Address>(last_pc_), 0);
	// Use unsigned delta-encoding for pc.
	uint32_t pc_delta =
	static_cast<uint32_t>(rinfo->pc() - reinterpret_cast<Address>(last_pc_));

	// The two most common modes are given small tags, and usually fit in a byte.
	if (rmode == RelocInfo::FULL_EMBEDDED_OBJECT) {
	WriteShortTaggedPC(pc_delta, kEmbeddedObjectTag);
	} else if (rmode == RelocInfo::CODE_TARGET) {
	WriteShortTaggedPC(pc_delta, kCodeTargetTag);
	DCHECK_LE(begin_pos - pos_, RelocInfo::kMaxCallSize);
	} else if (rmode == RelocInfo::WASM_STUB_CALL) {
	WriteShortTaggedPC(pc_delta, kWasmStubCallTag);
	} else {
	WriteModeAndPC(pc_delta, rmode);
	if (RelocInfo::IsDeoptReason(rmode)) {
	DCHECK_LT(rinfo->data(), 1 << kBitsPerByte);
	WriteShortData(rinfo->data());
	} else if (RelocInfo::IsConstPool(rmode) \|\|
	RelocInfo::IsVeneerPool(rmode) \|\| RelocInfo::IsDeoptId(rmode) \|\|
	RelocInfo::IsDeoptPosition(rmode)) {
	WriteIntData(static_cast<int>(rinfo->data()));
	}
	}
	last_pc_ = reinterpret_cast<byte*>(rinfo->pc());
	#ifdef DEBUG
	DCHECK_LE(begin_pos - pos_, kMaxSize);
	#endif
	}

	inline int RelocIterator::AdvanceGetTag() { return *--pos_ & kTagMask; }

	inline RelocInfo::Mode RelocIterator::GetMode() {
	return static_cast<RelocInfo::Mode>((*pos_ >> kTagBits) &
	((1 << kLongTagBits) - 1));
	}

	inline void RelocIterator::ReadShortTaggedPC() {
	rinfo_.pc_ += *pos_ >> kTagBits;
	}

	inline void RelocIterator::AdvanceReadPC() { rinfo_.pc_ += *--pos_; }

	void RelocIterator::AdvanceReadInt() {
	int x = 0;
	for (int i = 0; i < kIntSize; i++) {
	x \|= static_cast<int>(--pos_) << i kBitsPerByte;
	}
	rinfo_.data_ = x;
	}

	void RelocIterator::AdvanceReadData() {
	intptr_t x = 0;
	for (int i = 0; i < kIntptrSize; i++) {
	x \|= static_cast<intptr_t>(--pos_) << i kBitsPerByte;
	}
	rinfo_.data_ = x;
	}

	void RelocIterator::AdvanceReadLongPCJump() {
	// Read the 32-kSmallPCDeltaBits most significant bits of the
	// pc jump in kChunkBits bit chunks and shift them into place.
	// Stop when the last chunk is encountered.
	uint32_t pc_jump = 0;
	for (int i = 0; i < kIntSize; i++) {
	byte pc_jump_part = *--pos_;
	pc_jump \|= (pc_jump_part >> kLastChunkTagBits) << i * kChunkBits;
	if ((pc_jump_part & kLastChunkTagMask) == 1) break;
	}
	// The least significant kSmallPCDeltaBits bits will be added
	// later.
	rinfo_.pc_ += pc_jump << kSmallPCDeltaBits;
	}

	inline void RelocIterator::ReadShortData() {
	uint8_t unsigned_b = *pos_;
	rinfo_.data_ = unsigned_b;
	}

	void RelocIterator::next() {
	DCHECK(!done());
	// Basically, do the opposite of RelocInfoWriter::Write.
	// Reading of data is as far as possible avoided for unwanted modes,
	// but we must always update the pc.
	//
	// We exit this loop by returning when we find a mode we want.
	while (pos_ > end_) {
	int tag = AdvanceGetTag();
	if (tag == kEmbeddedObjectTag) {
	ReadShortTaggedPC();
	if (SetMode(RelocInfo::FULL_EMBEDDED_OBJECT)) return;
	} else if (tag == kCodeTargetTag) {
	ReadShortTaggedPC();
	if (SetMode(RelocInfo::CODE_TARGET)) return;
	} else if (tag == kWasmStubCallTag) {
	ReadShortTaggedPC();
	if (SetMode(RelocInfo::WASM_STUB_CALL)) return;
	} else {
	DCHECK_EQ(tag, kDefaultTag);
	RelocInfo::Mode rmode = GetMode();
	if (rmode == RelocInfo::PC_JUMP) {
	AdvanceReadLongPCJump();
	} else {
	AdvanceReadPC();
	if (RelocInfo::IsDeoptReason(rmode)) {
	Advance();
	if (SetMode(rmode)) {
	ReadShortData();
	return;
	}
	} else if (RelocInfo::IsConstPool(rmode) \|\|
	RelocInfo::IsVeneerPool(rmode) \|\|
	RelocInfo::IsDeoptId(rmode) \|\|
	RelocInfo::IsDeoptPosition(rmode)) {
	if (SetMode(rmode)) {
	AdvanceReadInt();
	return;
	}
	Advance(kIntSize);
	} else if (SetMode(static_cast<RelocInfo::Mode>(rmode))) {
	return;
	}
	}
	}
	}
	done_ = true;
	}

	RelocIterator::RelocIterator(Code code, int mode_mask)
	: RelocIterator(code, code.unchecked_relocation_info(), mode_mask) {}

	RelocIterator::RelocIterator(Code code, ByteArray relocation_info,
	int mode_mask)
	: RelocIterator(code, code.raw_instruction_start(), code.constant_pool(),
	relocation_info.GetDataEndAddress(),
	relocation_info.GetDataStartAddress(), mode_mask) {}

	RelocIterator::RelocIterator(const CodeReference code_reference, int mode_mask)
	: RelocIterator(Code(), code_reference.instruction_start(),
	code_reference.constant_pool(),
	code_reference.relocation_end(),
	code_reference.relocation_start(), mode_mask) {}

	RelocIterator::RelocIterator(EmbeddedData* embedded_data, Code code,
	int mode_mask)
	: RelocIterator(
	code, embedded_data->InstructionStartOfBuiltin(code.builtin_index()),
	code.constant_pool(),
	code.relocation_start() + code.relocation_size(),
	code.relocation_start(), mode_mask) {}

	RelocIterator::RelocIterator(const CodeDesc& desc, int mode_mask)
	: RelocIterator(Code(), reinterpret_cast<Address>(desc.buffer), 0,
	desc.buffer + desc.buffer_size,
	desc.buffer + desc.buffer_size - desc.reloc_size,
	mode_mask) {}

	RelocIterator::RelocIterator(Vector<byte> instructions,
	Vector<const byte> reloc_info, Address const_pool,
	int mode_mask)
	: RelocIterator(Code(), reinterpret_cast<Address>(instructions.begin()),
	const_pool, reloc_info.begin() + reloc_info.size(),
	reloc_info.begin(), mode_mask) {}

	RelocIterator::RelocIterator(Code host, Address pc, Address constant_pool,
	const byte* pos, const byte* end, int mode_mask)
	: pos_(pos), end_(end), mode_mask_(mode_mask) {
	// Relocation info is read backwards.
	DCHECK_GE(pos_, end_);
	rinfo_.host_ = host;
	rinfo_.pc_ = pc;
	rinfo_.constant_pool_ = constant_pool;
	if (mode_mask_ == 0) pos_ = end_;
	next();
	}

	// -----------------------------------------------------------------------------
	// Implementation of RelocInfo

	// static
	bool RelocInfo::OffHeapTargetIsCodedSpecially() {
	#if defined(V8_TARGET_ARCH_ARM) \|\| defined(V8_TARGET_ARCH_ARM64) \|\| \
	defined(V8_TARGET_ARCH_X64)
	return false;
	#elif defined(V8_TARGET_ARCH_IA32) \|\| defined(V8_TARGET_ARCH_MIPS) \|\| \
	defined(V8_TARGET_ARCH_MIPS64) \|\| defined(V8_TARGET_ARCH_PPC) \|\| \
	defined(V8_TARGET_ARCH_PPC64) \|\| defined(V8_TARGET_ARCH_S390)
	return true;
	#endif
	}

	Address RelocInfo::wasm_call_address() const {
	DCHECK_EQ(rmode_, WASM_CALL);
	return Assembler::target_address_at(pc_, constant_pool_);
	}

	void RelocInfo::set_wasm_call_address(Address address,
	ICacheFlushMode icache_flush_mode) {
	DCHECK_EQ(rmode_, WASM_CALL);
	Assembler::set_target_address_at(pc_, constant_pool_, address,
	icache_flush_mode);
	}

	Address RelocInfo::wasm_stub_call_address() const {
	DCHECK_EQ(rmode_, WASM_STUB_CALL);
	return Assembler::target_address_at(pc_, constant_pool_);
	}

	void RelocInfo::set_wasm_stub_call_address(Address address,
	ICacheFlushMode icache_flush_mode) {
	DCHECK_EQ(rmode_, WASM_STUB_CALL);
	Assembler::set_target_address_at(pc_, constant_pool_, address,
	icache_flush_mode);
	}

	void RelocInfo::set_target_address(Address target,
	WriteBarrierMode write_barrier_mode,
	ICacheFlushMode icache_flush_mode) {
	DCHECK(IsCodeTargetMode(rmode_) \|\| IsRuntimeEntry(rmode_) \|\|
	IsWasmCall(rmode_));
	Assembler::set_target_address_at(pc_, constant_pool_, target,
	icache_flush_mode);
	if (write_barrier_mode == UPDATE_WRITE_BARRIER && !host().is_null() &&
	IsCodeTargetMode(rmode_) && !FLAG_disable_write_barriers) {
	Code target_code = Code::GetCodeFromTargetAddress(target);
	WriteBarrier::Marking(host(), this, target_code);
	}
	}

	bool RelocInfo::HasTargetAddressAddress() const {
	// TODO(jgruber): Investigate whether WASM_CALL is still appropriate on
	// non-intel platforms now that wasm code is no longer on the heap.
	#if defined(V8_TARGET_ARCH_IA32) \|\| defined(V8_TARGET_ARCH_X64)
	static constexpr int kTargetAddressAddressModeMask =
	ModeMask(CODE_TARGET) \| ModeMask(FULL_EMBEDDED_OBJECT) \|
	ModeMask(COMPRESSED_EMBEDDED_OBJECT) \| ModeMask(EXTERNAL_REFERENCE) \|
	ModeMask(OFF_HEAP_TARGET) \| ModeMask(RUNTIME_ENTRY) \|
	ModeMask(WASM_CALL) \| ModeMask(WASM_STUB_CALL);
	#else
	static constexpr int kTargetAddressAddressModeMask =
	ModeMask(CODE_TARGET) \| ModeMask(RELATIVE_CODE_TARGET) \|
	ModeMask(FULL_EMBEDDED_OBJECT) \| ModeMask(EXTERNAL_REFERENCE) \|
	ModeMask(OFF_HEAP_TARGET) \| ModeMask(RUNTIME_ENTRY) \| ModeMask(WASM_CALL);
	#endif
	return (ModeMask(rmode_) & kTargetAddressAddressModeMask) != 0;
	}

	bool RelocInfo::RequiresRelocationAfterCodegen(const CodeDesc& desc) {
	RelocIterator it(desc, RelocInfo::PostCodegenRelocationMask());
	return !it.done();
	}

	bool RelocInfo::RequiresRelocation(Code code) {
	RelocIterator it(code, RelocInfo::kApplyMask);
	return !it.done();
	}

	#ifdef ENABLE_DISASSEMBLER
	const char* RelocInfo::RelocModeName(RelocInfo::Mode rmode) {
	switch (rmode) {
	case NONE:
	return "no reloc";
	case COMPRESSED_EMBEDDED_OBJECT:
	return "compressed embedded object";
	case FULL_EMBEDDED_OBJECT:
	return "full embedded object";
	case CODE_TARGET:
	return "code target";
	case RELATIVE_CODE_TARGET:
	return "relative code target";
	case RUNTIME_ENTRY:
	return "runtime entry";
	case EXTERNAL_REFERENCE:
	return "external reference";
	case INTERNAL_REFERENCE:
	return "internal reference";
	case INTERNAL_REFERENCE_ENCODED:
	return "encoded internal reference";
	case OFF_HEAP_TARGET:
	return "off heap target";
	case DEOPT_SCRIPT_OFFSET:
	return "deopt script offset";
	case DEOPT_INLINING_ID:
	return "deopt inlining id";
	case DEOPT_REASON:
	return "deopt reason";
	case DEOPT_ID:
	return "deopt index";
	case CONST_POOL:
	return "constant pool";
	case VENEER_POOL:
	return "veneer pool";
	case WASM_CALL:
	return "internal wasm call";
	case WASM_STUB_CALL:
	return "wasm stub call";
	case NUMBER_OF_MODES:
	case PC_JUMP:
	UNREACHABLE();
	}
	return "unknown relocation type";
	}

	void RelocInfo::Print(Isolate* isolate, std::ostream& os) { // NOLINT
	os << reinterpret_cast<const void*>(pc_) << " " << RelocModeName(rmode_);
	if (rmode_ == DEOPT_SCRIPT_OFFSET \|\| rmode_ == DEOPT_INLINING_ID) {
	os << " (" << data() << ")";
	} else if (rmode_ == DEOPT_REASON) {
	os << " ("
	<< DeoptimizeReasonToString(static_cast<DeoptimizeReason>(data_)) << ")";
	} else if (rmode_ == FULL_EMBEDDED_OBJECT) {
	os << " (" << Brief(target_object()) << ")";
	} else if (rmode_ == COMPRESSED_EMBEDDED_OBJECT) {
	os << " (" << Brief(target_object()) << " compressed)";
	} else if (rmode_ == EXTERNAL_REFERENCE) {
	if (isolate) {
	ExternalReferenceEncoder ref_encoder(isolate);
	os << " ("
	<< ref_encoder.NameOfAddress(isolate, target_external_reference())
	<< ") ";
	}
	os << " (" << reinterpret_cast<const void*>(target_external_reference())
	<< ")";
	} else if (IsCodeTargetMode(rmode_)) {
	const Address code_target = target_address();
	Code code = Code::GetCodeFromTargetAddress(code_target);
	DCHECK(code.IsCode());
	os << " (" << CodeKindToString(code.kind());
	if (Builtins::IsBuiltin(code)) {
	os << " " << Builtins::name(code.builtin_index());
	}
	os << ") (" << reinterpret_cast<const void*>(target_address()) << ")";
	} else if (IsRuntimeEntry(rmode_)) {
	// Deoptimization bailouts are stored as runtime entries.
	DeoptimizeKind type;
	if (Deoptimizer::IsDeoptimizationEntry(isolate, target_address(), &type)) {
	os << " (" << Deoptimizer::MessageFor(type, false)
	<< " deoptimization bailout)";
	}
	} else if (IsConstPool(rmode_)) {
	os << " (size " << static_cast<int>(data_) << ")";
	}

	os << "\n";
	}
	#endif // ENABLE_DISASSEMBLER

	#ifdef VERIFY_HEAP
	void RelocInfo::Verify(Isolate* isolate) {
	switch (rmode_) {
	case COMPRESSED_EMBEDDED_OBJECT:
	case FULL_EMBEDDED_OBJECT:
	Object::VerifyPointer(isolate, target_object());
	break;
	case CODE_TARGET:
	case RELATIVE_CODE_TARGET: {
	// convert inline target address to code object
	Address addr = target_address();
	CHECK_NE(addr, kNullAddress);
	// Check that we can find the right code object.
	Code code = Code::GetCodeFromTargetAddress(addr);
	Object found = isolate->FindCodeObject(addr);
	CHECK(found.IsCode());
	CHECK(code.address() == HeapObject::cast(found).address());
	break;
	}
	case INTERNAL_REFERENCE:
	case INTERNAL_REFERENCE_ENCODED: {
	Address target = target_internal_reference();
	Address pc = target_internal_reference_address();
	Code code = Code::cast(isolate->FindCodeObject(pc));
	CHECK(target >= code.InstructionStart());
	CHECK(target <= code.InstructionEnd());
	break;
	}
	case OFF_HEAP_TARGET: {
	Address addr = target_off_heap_target();
	CHECK_NE(addr, kNullAddress);
	CHECK(!InstructionStream::TryLookupCode(isolate, addr).is_null());
	break;
	}
	case RUNTIME_ENTRY:
	case EXTERNAL_REFERENCE:
	case DEOPT_SCRIPT_OFFSET:
	case DEOPT_INLINING_ID:
	case DEOPT_REASON:
	case DEOPT_ID:
	case CONST_POOL:
	case VENEER_POOL:
	case WASM_CALL:
	case WASM_STUB_CALL:
	case NONE:
	break;
	case NUMBER_OF_MODES:
	case PC_JUMP:
	UNREACHABLE();
	}
	}
	#endif // VERIFY_HEAP

	} // namespace internal
	} // namespace v8