Index: src/eh-frame.cc |
diff --git a/src/eh-frame.cc b/src/eh-frame.cc |
index af85e0b8d5f7143beb3c5243513a69fef0f5f919..5f0f1c1b35ef486653bf3015b34a57c74728aced 100644 |
--- a/src/eh-frame.cc |
+++ b/src/eh-frame.cc |
@@ -3,94 +3,627 @@ |
// found in the LICENSE file. |
#include "src/eh-frame.h" |
-#include "src/objects-inl.h" |
-#include "src/objects.h" |
+ |
+#include <iomanip> |
+#include <ostream> |
+ |
+#if !defined(V8_TARGET_ARCH_X64) && !defined(V8_TARGET_ARCH_ARM) && \ |
+ !defined(V8_TARGET_ARCH_ARM64) |
+ |
+// Placeholders for unsupported architectures. |
namespace v8 { |
namespace internal { |
-static const int DW_EH_PE_pcrel = 0x10; |
-static const int DW_EH_PE_datarel = 0x30; |
-static const int DW_EH_PE_udata4 = 0x03; |
-static const int DW_EH_PE_sdata4 = 0x0b; |
- |
-const int EhFrameHdr::kCIESize = 0; |
- |
-static const int kVersionSize = 1; |
-static const int kEncodingSpecifiersSize = 3; |
- |
-// |
-// In order to calculate offsets in the .eh_frame_hdr, we must know the layout |
-// of the DSO generated by perf inject, which is assumed to be the following: |
-// |
-// | ... | | |
-// +---------------+ <-- (F) --- | Larger offsets in file |
-// | | ^ | |
-// | Instructions | | .text v |
-// | | v |
-// +---------------+ <-- (E) --- |
-// |///////////////| |
-// |////Padding////| |
-// |///////////////| |
-// +---------------+ <-- (D) --- |
-// | | ^ |
-// | CIE | | |
-// | | | |
-// +---------------+ <-- (C) | .eh_frame |
-// | | | |
-// | FDE | | |
-// | | v |
-// +---------------+ <-- (B) --- |
-// | version | ^ |
-// +---------------+ | |
-// | encoding | | |
-// | specifiers | | |
-// +---------------+ <---(A) | .eh_frame_hdr |
-// | offset to | | |
-// | .eh_frame | | |
-// +---------------+ | |
-// | ... | ... |
-// |
-// (F) is aligned at a 16-byte boundary. |
-// (D) is aligned at a 8-byte boundary. |
-// (B) is aligned at a 4-byte boundary. |
-// (E), (C) and (A) have no alignment requirements. |
-// |
-// The distance between (A) and (B) is 4 bytes. |
-// |
-// The size of the .eh_frame is required to be a multiple of the pointer size, |
-// which means that (B) will be naturally aligned to a 4-byte boundary on all |
-// the architectures we support. |
-// |
-// Because (E) has no alignment requirements, there is padding between (E) and |
-// (D). (F) is aligned at a 16-byte boundary, thus to a 8-byte one as well. |
-// |
-EhFrameHdr::EhFrameHdr(Code* code) { |
- int code_size = code->is_crankshafted() ? code->safepoint_table_offset() |
- : code->instruction_size(); |
- version_ = 1; |
- eh_frame_ptr_encoding_ = DW_EH_PE_sdata4 | DW_EH_PE_pcrel; |
- lut_size_encoding_ = DW_EH_PE_udata4; |
- lut_entries_encoding_ = DW_EH_PE_sdata4 | DW_EH_PE_datarel; |
- |
- // .eh_frame pointer and LUT |
- if (code->has_unwinding_info()) { |
- DCHECK_GE(code->unwinding_info_size(), EhFrameHdr::kRecordSize); |
- int eh_frame_size = code->unwinding_info_size() - EhFrameHdr::kRecordSize; |
- |
- offset_to_eh_frame_ = |
- -(eh_frame_size + kVersionSize + kEncodingSpecifiersSize); // A -> D |
- lut_entries_number_ = 1; |
- offset_to_procedure_ = -(RoundUp(code_size, 8) + eh_frame_size); // B -> F |
- offset_to_fde_ = -(eh_frame_size - kCIESize); // B -> C |
+const int EhFrameConstants::kCodeAlignmentFactor = 1; |
+const int EhFrameConstants::kDataAlignmentFactor = 1; |
+ |
+void EhFrameWriter::WriteReturnAddressRegisterCode() { UNIMPLEMENTED(); } |
+ |
+void EhFrameWriter::WriteInitialStateInCie() { UNIMPLEMENTED(); } |
+ |
+int EhFrameWriter::RegisterToDwarfCode(Register) { |
+ UNIMPLEMENTED(); |
+ return -1; |
+} |
+ |
+#ifdef ENABLE_DISASSEMBLER |
+ |
+const char* EhFrameDisassembler::DwarfRegisterCodeToString(int) { |
+ UNIMPLEMENTED(); |
+ return nullptr; |
+} |
+ |
+#endif |
+ |
+} // namespace internal |
+} // namespace v8 |
+ |
+#endif |
+ |
+namespace v8 { |
+namespace internal { |
+ |
+STATIC_CONST_MEMBER_DEFINITION const int |
+ EhFrameConstants::kEhFrameTerminatorSize; |
+STATIC_CONST_MEMBER_DEFINITION const int EhFrameConstants::kEhFrameHdrVersion; |
+STATIC_CONST_MEMBER_DEFINITION const int EhFrameConstants::kEhFrameHdrSize; |
+ |
+STATIC_CONST_MEMBER_DEFINITION const uint32_t EhFrameWriter::kInt32Placeholder; |
+ |
+// static |
+void EhFrameWriter::WriteEmptyEhFrame(std::ostream& stream) { // NOLINT |
+ stream.put(EhFrameConstants::kEhFrameHdrVersion); |
+ |
+ // .eh_frame pointer encoding specifier. |
+ stream.put(EhFrameConstants::kSData4 | EhFrameConstants::kPcRel); |
+ |
+ // Lookup table size encoding. |
+ stream.put(EhFrameConstants::kUData4); |
+ |
+ // Lookup table entries encoding. |
+ stream.put(EhFrameConstants::kSData4 | EhFrameConstants::kDataRel); |
+ |
+ // Dummy pointers and 0 entries in the lookup table. |
+ char dummy_data[EhFrameConstants::kEhFrameHdrSize - 4] = {0}; |
+ stream.write(&dummy_data[0], sizeof(dummy_data)); |
+} |
+ |
+EhFrameWriter::EhFrameWriter(Zone* zone) |
+ : cie_size_(0), |
+ last_pc_offset_(0), |
+ writer_state_(InternalState::kUndefined), |
+ base_register_(no_reg), |
+ base_offset_(0), |
+ eh_frame_buffer_(zone) {} |
+ |
+void EhFrameWriter::Initialize() { |
+ DCHECK(writer_state_ == InternalState::kUndefined); |
+ eh_frame_buffer_.reserve(128); |
+ writer_state_ = InternalState::kInitialized; |
+ WriteCie(); |
+ WriteFdeHeader(); |
+} |
+ |
+void EhFrameWriter::WriteCie() { |
+ static const int kCIEIdentifier = 0; |
+ static const int kCIEVersion = 3; |
+ static const int kAugmentationDataSize = 2; |
+ static const byte kAugmentationString[] = {'z', 'L', 'R', 0}; |
+ |
+ // Placeholder for the size of the CIE. |
+ int size_offset = eh_frame_offset(); |
+ WriteInt32(kInt32Placeholder); |
+ |
+ // CIE identifier and version. |
+ int record_start_offset = eh_frame_offset(); |
+ WriteInt32(kCIEIdentifier); |
+ WriteByte(kCIEVersion); |
+ |
+ // Augmentation data contents descriptor: LSDA and FDE encoding. |
+ WriteBytes(&kAugmentationString[0], sizeof(kAugmentationString)); |
+ |
+ // Alignment factors. |
+ WriteSLeb128(EhFrameConstants::kCodeAlignmentFactor); |
+ WriteSLeb128(EhFrameConstants::kDataAlignmentFactor); |
+ |
+ WriteReturnAddressRegisterCode(); |
+ |
+ // Augmentation data. |
+ WriteULeb128(kAugmentationDataSize); |
+ // No language-specific data area (LSDA). |
+ WriteByte(EhFrameConstants::kOmit); |
+ // FDE pointers encoding. |
+ WriteByte(EhFrameConstants::kSData4 | EhFrameConstants::kPcRel); |
+ |
+ // Write directives to build the initial state of the unwinding table. |
+ DCHECK_EQ(eh_frame_offset() - size_offset, |
+ EhFrameConstants::kInitialStateOffsetInCie); |
+ WriteInitialStateInCie(); |
+ |
+ WritePaddingToAlignedSize(eh_frame_offset() - record_start_offset); |
+ |
+ int record_end_offset = eh_frame_offset(); |
+ int encoded_cie_size = record_end_offset - record_start_offset; |
+ cie_size_ = record_end_offset - size_offset; |
+ |
+ // Patch the size of the CIE now that we know it. |
+ PatchInt32(size_offset, encoded_cie_size); |
+} |
+ |
+void EhFrameWriter::WriteFdeHeader() { |
+ DCHECK_NE(cie_size_, 0); |
+ |
+ // Placeholder for size of the FDE. Will be filled in Finish(). |
+ DCHECK_EQ(eh_frame_offset(), fde_offset()); |
+ WriteInt32(kInt32Placeholder); |
+ |
+ // Backwards offset to the CIE. |
+ WriteInt32(cie_size_ + kInt32Size); |
+ |
+ // Placeholder for pointer to procedure. Will be filled in Finish(). |
+ DCHECK_EQ(eh_frame_offset(), GetProcedureAddressOffset()); |
+ WriteInt32(kInt32Placeholder); |
+ |
+ // Placeholder for size of the procedure. Will be filled in Finish(). |
+ DCHECK_EQ(eh_frame_offset(), GetProcedureSizeOffset()); |
+ WriteInt32(kInt32Placeholder); |
+ |
+ // No augmentation data. |
+ WriteByte(0); |
+} |
+ |
+void EhFrameWriter::WriteEhFrameHdr(int code_size) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ |
+ // |
+ // In order to calculate offsets in the .eh_frame_hdr, we must know the layout |
+ // of the DSO generated by perf inject, which is assumed to be the following: |
+ // |
+ // | ... | | |
+ // +---------------+ <-- (F) --- | Larger offsets in file |
+ // | | ^ | |
+ // | Instructions | | .text v |
+ // | | v |
+ // +---------------+ <-- (E) --- |
+ // |///////////////| |
+ // |////Padding////| |
+ // |///////////////| |
+ // +---------------+ <-- (D) --- |
+ // | | ^ |
+ // | CIE | | |
+ // | | | |
+ // +---------------+ <-- (C) | |
+ // | | | .eh_frame |
+ // | FDE | | |
+ // | | | |
+ // +---------------+ | |
+ // | terminator | v |
+ // +---------------+ <-- (B) --- |
+ // | version | ^ |
+ // +---------------+ | |
+ // | encoding | | |
+ // | specifiers | | |
+ // +---------------+ <---(A) | .eh_frame_hdr |
+ // | offset to | | |
+ // | .eh_frame | | |
+ // +---------------+ | |
+ // | ... | ... |
+ // |
+ // (F) is aligned to a 16-byte boundary. |
+ // (D) is aligned to a 8-byte boundary. |
+ // (B) is aligned to a 4-byte boundary. |
+ // (C), (E) and (A) have no alignment requirements. |
+ // |
+ // The distance between (A) and (B) is 4 bytes. |
+ // |
+ // The size of the FDE is required to be a multiple of the pointer size, which |
+ // means that (B) will be naturally aligned to a 4-byte boundary on all the |
+ // architectures we support. |
+ // |
+ // Because (E) has no alignment requirements, there is padding between (E) and |
+ // (D). (F) is aligned at a 16-byte boundary, thus to a 8-byte one as well. |
+ // |
+ |
+ int eh_frame_size = eh_frame_offset(); |
+ |
+ WriteByte(EhFrameConstants::kEhFrameHdrVersion); |
+ |
+ // .eh_frame pointer encoding specifier. |
+ WriteByte(EhFrameConstants::kSData4 | EhFrameConstants::kPcRel); |
+ // Lookup table size encoding specifier. |
+ WriteByte(EhFrameConstants::kUData4); |
+ // Lookup table entries encoding specifier. |
+ WriteByte(EhFrameConstants::kSData4 | EhFrameConstants::kDataRel); |
+ |
+ // Pointer to .eh_frame, relative to this offset (A -> D in the diagram). |
+ WriteInt32(-(eh_frame_size + EhFrameConstants::kFdeVersionSize + |
+ EhFrameConstants::kFdeEncodingSpecifiersSize)); |
+ |
+ // Number of entries in the LUT, one for the only routine. |
+ WriteInt32(1); |
+ |
+ // Pointer to the start of the routine, relative to the beginning of the |
+ // .eh_frame_hdr (B -> F in the diagram). |
+ WriteInt32(-(RoundUp(code_size, 8) + eh_frame_size)); |
+ |
+ // Pointer to the start of the associated FDE, relative to the start of the |
+ // .eh_frame_hdr (B -> C in the diagram). |
+ WriteInt32(-(eh_frame_size - cie_size_)); |
+ |
+ DCHECK_EQ(eh_frame_offset() - eh_frame_size, |
+ EhFrameConstants::kEhFrameHdrSize); |
+} |
+ |
+void EhFrameWriter::WritePaddingToAlignedSize(int unpadded_size) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ DCHECK_GE(unpadded_size, 0); |
+ |
+ int padding_size = RoundUp(unpadded_size, kPointerSize) - unpadded_size; |
+ |
+ byte nop = static_cast<byte>(EhFrameConstants::DwarfOpcodes::kNop); |
+ static const byte kPadding[] = {nop, nop, nop, nop, nop, nop, nop, nop}; |
+ DCHECK_LE(padding_size, static_cast<int>(sizeof(kPadding))); |
+ WriteBytes(&kPadding[0], padding_size); |
+} |
+ |
+void EhFrameWriter::AdvanceLocation(int pc_offset) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ DCHECK_GE(pc_offset, last_pc_offset_); |
+ uint32_t delta = pc_offset - last_pc_offset_; |
+ |
+ DCHECK_EQ(delta % EhFrameConstants::kCodeAlignmentFactor, 0); |
+ uint32_t factored_delta = delta / EhFrameConstants::kCodeAlignmentFactor; |
+ |
+ if (factored_delta <= EhFrameConstants::kLocationMask) { |
+ WriteByte((EhFrameConstants::kLocationTag |
+ << EhFrameConstants::kLocationMaskSize) | |
+ (factored_delta & EhFrameConstants::kLocationMask)); |
+ } else if (factored_delta <= kMaxUInt8) { |
+ WriteOpcode(EhFrameConstants::DwarfOpcodes::kAdvanceLoc1); |
+ WriteByte(factored_delta); |
+ } else if (factored_delta <= kMaxUInt16) { |
+ WriteOpcode(EhFrameConstants::DwarfOpcodes::kAdvanceLoc2); |
+ WriteInt16(factored_delta); |
} else { |
- // Create a dummy table |
- offset_to_eh_frame_ = 0; |
- lut_entries_number_ = 0; |
- offset_to_procedure_ = 0; |
- offset_to_fde_ = 0; |
+ WriteOpcode(EhFrameConstants::DwarfOpcodes::kAdvanceLoc4); |
+ WriteInt32(factored_delta); |
} |
+ |
+ last_pc_offset_ = pc_offset; |
+} |
+ |
+void EhFrameWriter::SetBaseAddressOffset(int base_offset) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ DCHECK_GE(base_offset, 0); |
+ WriteOpcode(EhFrameConstants::DwarfOpcodes::kDefCfaOffset); |
+ WriteULeb128(base_offset); |
+ base_offset_ = base_offset; |
} |
+void EhFrameWriter::SetBaseAddressRegister(Register base_register) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ int code = RegisterToDwarfCode(base_register); |
+ WriteOpcode(EhFrameConstants::DwarfOpcodes::kDefCfaRegister); |
+ WriteULeb128(code); |
+ base_register_ = base_register; |
+} |
+ |
+void EhFrameWriter::SetBaseAddressRegisterAndOffset(Register base_register, |
+ int base_offset) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ DCHECK_GE(base_offset, 0); |
+ int code = RegisterToDwarfCode(base_register); |
+ WriteOpcode(EhFrameConstants::DwarfOpcodes::kDefCfa); |
+ WriteULeb128(code); |
+ WriteULeb128(base_offset); |
+ base_offset_ = base_offset; |
+ base_register_ = base_register; |
+} |
+ |
+void EhFrameWriter::RecordRegisterSavedToStack(int register_code, int offset) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ DCHECK_EQ(offset % EhFrameConstants::kDataAlignmentFactor, 0); |
+ int factored_offset = offset / EhFrameConstants::kDataAlignmentFactor; |
+ if (factored_offset >= 0) { |
+ DCHECK_LE(register_code, EhFrameConstants::kSavedRegisterMask); |
+ WriteByte((EhFrameConstants::kSavedRegisterTag |
+ << EhFrameConstants::kSavedRegisterMaskSize) | |
+ (register_code & EhFrameConstants::kSavedRegisterMask)); |
+ WriteULeb128(factored_offset); |
+ } else { |
+ WriteOpcode(EhFrameConstants::DwarfOpcodes::kOffsetExtendedSf); |
+ WriteULeb128(register_code); |
+ WriteSLeb128(factored_offset); |
+ } |
+} |
+ |
+void EhFrameWriter::RecordRegisterNotModified(Register name) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ WriteOpcode(EhFrameConstants::DwarfOpcodes::kSameValue); |
+ WriteULeb128(RegisterToDwarfCode(name)); |
+} |
+ |
+void EhFrameWriter::RecordRegisterFollowsInitialRule(Register name) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ int code = RegisterToDwarfCode(name); |
+ DCHECK_LE(code, EhFrameConstants::kFollowInitialRuleMask); |
+ WriteByte((EhFrameConstants::kFollowInitialRuleTag |
+ << EhFrameConstants::kFollowInitialRuleMaskSize) | |
+ (code & EhFrameConstants::kFollowInitialRuleMask)); |
+} |
+ |
+void EhFrameWriter::Finish(int code_size) { |
+ DCHECK(writer_state_ == InternalState::kInitialized); |
+ DCHECK_GE(eh_frame_offset(), cie_size_); |
+ |
+ DCHECK_GE(eh_frame_offset(), fde_offset() + kInt32Size); |
+ WritePaddingToAlignedSize(eh_frame_offset() - fde_offset() - kInt32Size); |
+ |
+ // Write the size of the FDE now that we know it. |
+ // The encoded size does not include the size field itself. |
+ int encoded_fde_size = eh_frame_offset() - fde_offset() - kInt32Size; |
+ PatchInt32(fde_offset(), encoded_fde_size); |
+ |
+ // Write size and offset to procedure. |
+ PatchInt32(GetProcedureAddressOffset(), |
+ -(RoundUp(code_size, 8) + GetProcedureAddressOffset())); |
+ PatchInt32(GetProcedureSizeOffset(), code_size); |
+ |
+ // Terminate the .eh_frame. |
+ static const byte kTerminator[EhFrameConstants::kEhFrameTerminatorSize] = {0}; |
+ WriteBytes(&kTerminator[0], EhFrameConstants::kEhFrameTerminatorSize); |
+ |
+ WriteEhFrameHdr(code_size); |
+ |
+ writer_state_ = InternalState::kFinalized; |
+} |
+ |
+void EhFrameWriter::GetEhFrame(CodeDesc* desc) { |
+ DCHECK(writer_state_ == InternalState::kFinalized); |
+ desc->unwinding_info_size = static_cast<int>(eh_frame_buffer_.size()); |
+ desc->unwinding_info = eh_frame_buffer_.data(); |
+} |
+ |
+void EhFrameWriter::WriteULeb128(uint32_t value) { |
+ do { |
+ byte chunk = value & 0x7f; |
+ value >>= 7; |
+ if (value != 0) chunk |= 0x80; |
+ WriteByte(chunk); |
+ } while (value != 0); |
+} |
+ |
+void EhFrameWriter::WriteSLeb128(int32_t value) { |
+ static const int kSignBitMask = 0x40; |
+ bool done; |
+ do { |
+ byte chunk = value & 0x7f; |
+ value >>= 7; |
+ done = ((value == 0) && ((chunk & kSignBitMask) == 0)) || |
+ ((value == -1) && ((chunk & kSignBitMask) != 0)); |
+ if (!done) chunk |= 0x80; |
+ WriteByte(chunk); |
+ } while (!done); |
+} |
+ |
+uint32_t EhFrameIterator::GetNextULeb128() { |
+ int size = 0; |
+ uint32_t result = DecodeULeb128(next_, &size); |
+ DCHECK_LE(next_ + size, end_); |
+ next_ += size; |
+ return result; |
+} |
+ |
+int32_t EhFrameIterator::GetNextSLeb128() { |
+ int size = 0; |
+ int32_t result = DecodeSLeb128(next_, &size); |
+ DCHECK_LE(next_ + size, end_); |
+ next_ += size; |
+ return result; |
+} |
+ |
+// static |
+uint32_t EhFrameIterator::DecodeULeb128(const byte* encoded, |
+ int* encoded_size) { |
+ const byte* current = encoded; |
+ uint32_t result = 0; |
+ int shift = 0; |
+ |
+ do { |
+ DCHECK_LT(shift, 8 * static_cast<int>(sizeof(result))); |
+ result |= (*current & 0x7f) << shift; |
+ shift += 7; |
+ } while (*current++ >= 128); |
+ |
+ DCHECK_NOT_NULL(encoded_size); |
+ *encoded_size = static_cast<int>(current - encoded); |
+ |
+ return result; |
+} |
+ |
+// static |
+int32_t EhFrameIterator::DecodeSLeb128(const byte* encoded, int* encoded_size) { |
+ static const byte kSignBitMask = 0x40; |
+ |
+ const byte* current = encoded; |
+ int32_t result = 0; |
+ int shift = 0; |
+ byte chunk; |
+ |
+ do { |
+ chunk = *current++; |
+ DCHECK_LT(shift, 8 * static_cast<int>(sizeof(result))); |
+ result |= (chunk & 0x7f) << shift; |
+ shift += 7; |
+ } while (chunk >= 128); |
+ |
+ // Sign extend the result if the last chunk has the sign bit set. |
+ if (chunk & kSignBitMask) result |= (~0ull) << shift; |
+ |
+ DCHECK_NOT_NULL(encoded_size); |
+ *encoded_size = static_cast<int>(current - encoded); |
+ |
+ return result; |
+} |
+ |
+#ifdef ENABLE_DISASSEMBLER |
+ |
+namespace { |
+ |
+class StreamModifiersScope final { |
+ public: |
+ explicit StreamModifiersScope(std::ostream* stream) |
+ : stream_(stream), flags_(stream->flags()) {} |
+ ~StreamModifiersScope() { stream_->flags(flags_); } |
+ |
+ private: |
+ std::ostream* stream_; |
+ std::ios::fmtflags flags_; |
+}; |
+ |
+} // namespace |
+ |
+// static |
+void EhFrameDisassembler::DumpDwarfDirectives(std::ostream& stream, // NOLINT |
+ const byte* start, |
+ const byte* end) { |
+ StreamModifiersScope modifiers_scope(&stream); |
+ |
+ EhFrameIterator eh_frame_iterator(start, end); |
+ uint32_t offset_in_procedure = 0; |
+ |
+ while (!eh_frame_iterator.Done()) { |
+ stream << eh_frame_iterator.current_address() << " "; |
+ |
+ byte bytecode = eh_frame_iterator.GetNextByte(); |
+ |
+ if (((bytecode >> EhFrameConstants::kLocationMaskSize) & 0xff) == |
+ EhFrameConstants::kLocationTag) { |
+ int value = (bytecode & EhFrameConstants::kLocationMask) * |
+ EhFrameConstants::kCodeAlignmentFactor; |
+ offset_in_procedure += value; |
+ stream << "| pc_offset=" << offset_in_procedure << " (delta=" << value |
+ << ")\n"; |
+ continue; |
+ } |
+ |
+ if (((bytecode >> EhFrameConstants::kSavedRegisterMaskSize) & 0xff) == |
+ EhFrameConstants::kSavedRegisterTag) { |
+ int32_t decoded_offset = eh_frame_iterator.GetNextULeb128(); |
+ stream << "| " << DwarfRegisterCodeToString( |
+ bytecode & EhFrameConstants::kLocationMask) |
+ << " saved at base" << std::showpos |
+ << decoded_offset * EhFrameConstants::kDataAlignmentFactor |
+ << std::noshowpos << '\n'; |
+ continue; |
+ } |
+ |
+ if (((bytecode >> EhFrameConstants::kFollowInitialRuleMaskSize) & 0xff) == |
+ EhFrameConstants::kFollowInitialRuleTag) { |
+ stream << "| " << DwarfRegisterCodeToString( |
+ bytecode & EhFrameConstants::kLocationMask) |
+ << " follows rule in CIE\n"; |
+ continue; |
+ } |
+ |
+ switch (static_cast<EhFrameConstants::DwarfOpcodes>(bytecode)) { |
+ case EhFrameConstants::DwarfOpcodes::kOffsetExtendedSf: { |
+ stream << "| " |
+ << DwarfRegisterCodeToString(eh_frame_iterator.GetNextULeb128()); |
+ int32_t decoded_offset = eh_frame_iterator.GetNextSLeb128(); |
+ stream << " saved at base" << std::showpos |
+ << decoded_offset * EhFrameConstants::kDataAlignmentFactor |
+ << std::noshowpos << '\n'; |
+ break; |
+ } |
+ case EhFrameConstants::DwarfOpcodes::kAdvanceLoc1: { |
+ int value = eh_frame_iterator.GetNextByte() * |
+ EhFrameConstants::kCodeAlignmentFactor; |
+ offset_in_procedure += value; |
+ stream << "| pc_offset=" << offset_in_procedure << " (delta=" << value |
+ << ")\n"; |
+ break; |
+ } |
+ case EhFrameConstants::DwarfOpcodes::kAdvanceLoc2: { |
+ int value = eh_frame_iterator.GetNextUInt16() * |
+ EhFrameConstants::kCodeAlignmentFactor; |
+ offset_in_procedure += value; |
+ stream << "| pc_offset=" << offset_in_procedure << " (delta=" << value |
+ << ")\n"; |
+ break; |
+ } |
+ case EhFrameConstants::DwarfOpcodes::kAdvanceLoc4: { |
+ int value = eh_frame_iterator.GetNextUInt32() * |
+ EhFrameConstants::kCodeAlignmentFactor; |
+ offset_in_procedure += value; |
+ stream << "| pc_offset=" << offset_in_procedure << " (delta=" << value |
+ << ")\n"; |
+ break; |
+ } |
+ case EhFrameConstants::DwarfOpcodes::kDefCfa: { |
+ uint32_t base_register = eh_frame_iterator.GetNextULeb128(); |
+ uint32_t base_offset = eh_frame_iterator.GetNextULeb128(); |
+ stream << "| base_register=" << DwarfRegisterCodeToString(base_register) |
+ << ", base_offset=" << base_offset << '\n'; |
+ break; |
+ } |
+ case EhFrameConstants::DwarfOpcodes::kDefCfaOffset: { |
+ stream << "| base_offset=" << eh_frame_iterator.GetNextULeb128() |
+ << '\n'; |
+ break; |
+ } |
+ case EhFrameConstants::DwarfOpcodes::kDefCfaRegister: { |
+ stream << "| base_register=" |
+ << DwarfRegisterCodeToString(eh_frame_iterator.GetNextULeb128()) |
+ << '\n'; |
+ break; |
+ } |
+ case EhFrameConstants::DwarfOpcodes::kSameValue: { |
+ stream << "| " |
+ << DwarfRegisterCodeToString(eh_frame_iterator.GetNextULeb128()) |
+ << " not modified from previous frame\n"; |
+ break; |
+ } |
+ case EhFrameConstants::DwarfOpcodes::kNop: |
+ stream << "| nop\n"; |
+ break; |
+ default: |
+ UNREACHABLE(); |
+ return; |
+ } |
+ } |
+} |
+ |
+void EhFrameDisassembler::DisassembleToStream(std::ostream& stream) { // NOLINT |
+ // The encoded CIE size does not include the size field itself. |
+ const int cie_size = ReadUnalignedUInt32(start_) + kInt32Size; |
+ const int fde_offset = cie_size; |
+ |
+ const byte* cie_directives_start = |
+ start_ + EhFrameConstants::kInitialStateOffsetInCie; |
+ const byte* cie_directives_end = start_ + cie_size; |
+ DCHECK_LE(cie_directives_start, cie_directives_end); |
+ |
+ stream << reinterpret_cast<const void*>(start_) << " .eh_frame: CIE\n"; |
+ DumpDwarfDirectives(stream, cie_directives_start, cie_directives_end); |
+ |
+ const byte* procedure_offset_address = |
+ start_ + fde_offset + EhFrameConstants::kProcedureAddressOffsetInFde; |
+ int32_t procedure_offset = |
+ ReadUnalignedValue<int32_t>(procedure_offset_address); |
+ |
+ const byte* procedure_size_address = |
+ start_ + fde_offset + EhFrameConstants::kProcedureSizeOffsetInFde; |
+ uint32_t procedure_size = ReadUnalignedUInt32(procedure_size_address); |
+ |
+ const byte* fde_start = start_ + fde_offset; |
+ stream << reinterpret_cast<const void*>(fde_start) << " .eh_frame: FDE\n" |
+ << reinterpret_cast<const void*>(procedure_offset_address) |
+ << " | procedure_offset=" << procedure_offset << '\n' |
+ << reinterpret_cast<const void*>(procedure_size_address) |
+ << " | procedure_size=" << procedure_size << '\n'; |
+ |
+ const int fde_directives_offset = fde_offset + 4 * kInt32Size + 1; |
+ |
+ const byte* fde_directives_start = start_ + fde_directives_offset; |
+ const byte* fde_directives_end = end_ - EhFrameConstants::kEhFrameHdrSize - |
+ EhFrameConstants::kEhFrameTerminatorSize; |
+ DCHECK_LE(fde_directives_start, fde_directives_end); |
+ |
+ DumpDwarfDirectives(stream, fde_directives_start, fde_directives_end); |
+ |
+ const byte* fde_terminator_start = fde_directives_end; |
+ stream << reinterpret_cast<const void*>(fde_terminator_start) |
+ << " .eh_frame: terminator\n"; |
+ |
+ const byte* eh_frame_hdr_start = |
+ fde_terminator_start + EhFrameConstants::kEhFrameTerminatorSize; |
+ stream << reinterpret_cast<const void*>(eh_frame_hdr_start) |
+ << " .eh_frame_hdr\n"; |
+} |
+ |
+#endif |
+ |
} // namespace internal |
} // namespace v8 |