bool UnwindAssemblyInstEmulation::GetNonCallSiteUnwindPlanFromAssembly( AddressRange &range, uint8_t *opcode_data, size_t opcode_size, UnwindPlan &unwind_plan) { if (opcode_data == nullptr || opcode_size == 0) return false; if (range.GetByteSize() > 0 && range.GetBaseAddress().IsValid() && m_inst_emulator_ap.get()) { // The instruction emulation subclass setup the unwind plan for the // first instruction. m_inst_emulator_ap->CreateFunctionEntryUnwind(unwind_plan); // CreateFunctionEntryUnwind should have created the first row. If it // doesn't, then we are done. if (unwind_plan.GetRowCount() == 0) return false; const bool prefer_file_cache = true; DisassemblerSP disasm_sp(Disassembler::DisassembleBytes( m_arch, NULL, NULL, range.GetBaseAddress(), opcode_data, opcode_size, 99999, prefer_file_cache)); Log *log(GetLogIfAllCategoriesSet(LIBLLDB_LOG_UNWIND)); if (disasm_sp) { m_range_ptr = ⦥ m_unwind_plan_ptr = &unwind_plan; const uint32_t addr_byte_size = m_arch.GetAddressByteSize(); const bool show_address = true; const bool show_bytes = true; m_inst_emulator_ap->GetRegisterInfo(unwind_plan.GetRegisterKind(), unwind_plan.GetInitialCFARegister(), m_cfa_reg_info); m_fp_is_cfa = false; m_register_values.clear(); m_pushed_regs.clear(); // Initialize the CFA with a known value. In the 32 bit case // it will be 0x80000000, and in the 64 bit case 0x8000000000000000. // We use the address byte size to be safe for any future address sizes m_initial_sp = (1ull << ((addr_byte_size * 8) - 1)); RegisterValue cfa_reg_value; cfa_reg_value.SetUInt(m_initial_sp, m_cfa_reg_info.byte_size); SetRegisterValue(m_cfa_reg_info, cfa_reg_value); const InstructionList &inst_list = disasm_sp->GetInstructionList(); const size_t num_instructions = inst_list.GetSize(); if (num_instructions > 0) { Instruction *inst = inst_list.GetInstructionAtIndex(0).get(); const lldb::addr_t base_addr = inst->GetAddress().GetFileAddress(); // Map for storing the unwind plan row and the value of the registers at // a given offset. // When we see a forward branch we add a new entry to this map with the // actual unwind plan // row and register context for the target address of the branch as the // current data have // to be valid for the target address of the branch too if we are in the // same function. std::map<lldb::addr_t, std::pair<UnwindPlan::RowSP, RegisterValueMap>> saved_unwind_states; // Make a copy of the current instruction Row and save it in m_curr_row // so we can add updates as we process the instructions. UnwindPlan::RowSP last_row = unwind_plan.GetLastRow(); UnwindPlan::Row *newrow = new UnwindPlan::Row; if (last_row.get()) *newrow = *last_row.get(); m_curr_row.reset(newrow); // Add the initial state to the save list with offset 0. saved_unwind_states.insert({0, {last_row, m_register_values}}); // cache the pc register number (in whatever register numbering this // UnwindPlan uses) for // quick reference during instruction parsing. RegisterInfo pc_reg_info; m_inst_emulator_ap->GetRegisterInfo( eRegisterKindGeneric, LLDB_REGNUM_GENERIC_PC, pc_reg_info); // cache the return address register number (in whatever register // numbering this UnwindPlan uses) for // quick reference during instruction parsing. RegisterInfo ra_reg_info; m_inst_emulator_ap->GetRegisterInfo( eRegisterKindGeneric, LLDB_REGNUM_GENERIC_RA, ra_reg_info); // The architecture dependent condition code of the last processed // instruction. EmulateInstruction::InstructionCondition last_condition = EmulateInstruction::UnconditionalCondition; lldb::addr_t condition_block_start_offset = 0; for (size_t idx = 0; idx < num_instructions; ++idx) { m_curr_row_modified = false; m_forward_branch_offset = 0; inst = inst_list.GetInstructionAtIndex(idx).get(); if (inst) { lldb::addr_t current_offset = inst->GetAddress().GetFileAddress() - base_addr; auto it = saved_unwind_states.upper_bound(current_offset); assert(it != saved_unwind_states.begin() && "Unwind row for the function entry missing"); --it; // Move it to the row corresponding to the current offset // If the offset of m_curr_row don't match with the offset we see in // saved_unwind_states // then we have to update m_curr_row and m_register_values based on // the saved values. It // is happenning after we processed an epilogue and a return to // caller instruction. if (it->second.first->GetOffset() != m_curr_row->GetOffset()) { UnwindPlan::Row *newrow = new UnwindPlan::Row; *newrow = *it->second.first; m_curr_row.reset(newrow); m_register_values = it->second.second; } m_inst_emulator_ap->SetInstruction(inst->GetOpcode(), inst->GetAddress(), nullptr); if (last_condition != m_inst_emulator_ap->GetInstructionCondition()) { if (m_inst_emulator_ap->GetInstructionCondition() != EmulateInstruction::UnconditionalCondition && saved_unwind_states.count(current_offset) == 0) { // If we don't have a saved row for the current offset then save // our // current state because we will have to restore it after the // conditional block. auto new_row = std::make_shared<UnwindPlan::Row>(*m_curr_row.get()); saved_unwind_states.insert( {current_offset, {new_row, m_register_values}}); } // If the last instruction was conditional with a different // condition // then the then current condition then restore the condition. if (last_condition != EmulateInstruction::UnconditionalCondition) { const auto &saved_state = saved_unwind_states.at(condition_block_start_offset); m_curr_row = std::make_shared<UnwindPlan::Row>(*saved_state.first); m_curr_row->SetOffset(current_offset); m_register_values = saved_state.second; bool replace_existing = true; // The last instruction might already // created a row for this offset and // we want to overwrite it. unwind_plan.InsertRow( std::make_shared<UnwindPlan::Row>(*m_curr_row), replace_existing); } // We are starting a new conditional block at the catual offset condition_block_start_offset = current_offset; } if (log && log->GetVerbose()) { StreamString strm; lldb_private::FormatEntity::Entry format; FormatEntity::Parse("${frame.pc}: ", format); inst->Dump(&strm, inst_list.GetMaxOpcocdeByteSize(), show_address, show_bytes, NULL, NULL, NULL, &format, 0); log->PutString(strm.GetString()); } last_condition = m_inst_emulator_ap->GetInstructionCondition(); m_inst_emulator_ap->EvaluateInstruction( eEmulateInstructionOptionIgnoreConditions); // If the current instruction is a branch forward then save the // current CFI information // for the offset where we are branching. if (m_forward_branch_offset != 0 && range.ContainsFileAddress(inst->GetAddress().GetFileAddress() + m_forward_branch_offset)) { auto newrow = std::make_shared<UnwindPlan::Row>(*m_curr_row.get()); newrow->SetOffset(current_offset + m_forward_branch_offset); saved_unwind_states.insert( {current_offset + m_forward_branch_offset, {newrow, m_register_values}}); unwind_plan.InsertRow(newrow); } // Were there any changes to the CFI while evaluating this // instruction? if (m_curr_row_modified) { // Save the modified row if we don't already have a CFI row in the // currennt address if (saved_unwind_states.count( current_offset + inst->GetOpcode().GetByteSize()) == 0) { m_curr_row->SetOffset(current_offset + inst->GetOpcode().GetByteSize()); unwind_plan.InsertRow(m_curr_row); saved_unwind_states.insert( {current_offset + inst->GetOpcode().GetByteSize(), {m_curr_row, m_register_values}}); // Allocate a new Row for m_curr_row, copy the current state // into it UnwindPlan::Row *newrow = new UnwindPlan::Row; *newrow = *m_curr_row.get(); m_curr_row.reset(newrow); } } } } } } if (log && log->GetVerbose()) { StreamString strm; lldb::addr_t base_addr = range.GetBaseAddress().GetFileAddress(); strm.Printf("Resulting unwind rows for [0x%" PRIx64 " - 0x%" PRIx64 "):", base_addr, base_addr + range.GetByteSize()); unwind_plan.Dump(strm, nullptr, base_addr); log->PutString(strm.GetString()); } return unwind_plan.GetRowCount() > 0; } return false; }
bool UnwindAssemblyInstEmulation::GetNonCallSiteUnwindPlanFromAssembly (AddressRange& range, Thread& thread, UnwindPlan& unwind_plan) { if (range.GetByteSize() > 0 && range.GetBaseAddress().IsValid() && m_inst_emulator_ap.get()) { // The the instruction emulation subclass setup the unwind plan for the // first instruction. m_inst_emulator_ap->CreateFunctionEntryUnwind (unwind_plan); // CreateFunctionEntryUnwind should have created the first row. If it // doesn't, then we are done. if (unwind_plan.GetRowCount() == 0) return false; ExecutionContext exe_ctx; thread.CalculateExecutionContext(exe_ctx); DisassemblerSP disasm_sp (Disassembler::DisassembleRange (m_arch, NULL, exe_ctx, range)); LogSP log(GetLogIfAllCategoriesSet (LIBLLDB_LOG_UNWIND)); if (disasm_sp) { m_range_ptr = ⦥ m_thread_ptr = &thread; m_unwind_plan_ptr = &unwind_plan; const uint32_t addr_byte_size = m_arch.GetAddressByteSize(); const bool show_address = true; const bool show_bytes = true; const bool raw = false; // Initialize the CFA with a known value. In the 32 bit case // it will be 0x80000000, and in the 64 bit case 0x8000000000000000. // We use the address byte size to be safe for any future addresss sizes m_inst_emulator_ap->GetRegisterInfo (unwind_plan.GetRegisterKind(), unwind_plan.GetInitialCFARegister(), m_cfa_reg_info); m_fp_is_cfa = false; m_register_values.clear(); m_pushed_regs.clear(); m_initial_sp = (1ull << ((addr_byte_size * 8) - 1)); RegisterValue cfa_reg_value; cfa_reg_value.SetUInt (m_initial_sp, m_cfa_reg_info.byte_size); SetRegisterValue (m_cfa_reg_info, cfa_reg_value); const InstructionList &inst_list = disasm_sp->GetInstructionList (); const size_t num_instructions = inst_list.GetSize(); if (num_instructions > 0) { Instruction *inst = inst_list.GetInstructionAtIndex (0).get(); const addr_t base_addr = inst->GetAddress().GetFileAddress(); // Initialize the current row with the one row that was created // from the CreateFunctionEntryUnwind call above... m_curr_row = unwind_plan.GetLastRow(); for (size_t idx=0; idx<num_instructions; ++idx) { inst = inst_list.GetInstructionAtIndex (idx).get(); if (inst) { if (log && log->GetVerbose ()) { StreamString strm; inst->Dump(&strm, inst_list.GetMaxOpcocdeByteSize (), show_address, show_bytes, &exe_ctx, raw); log->PutCString (strm.GetData()); } m_inst_emulator_ap->SetInstruction (inst->GetOpcode(), inst->GetAddress(), exe_ctx.GetTargetPtr()); m_inst_emulator_ap->EvaluateInstruction (eEmulateInstructionOptionIgnoreConditions); if (unwind_plan.GetLastRow() != m_curr_row) { // Be sure to not edit the offset unless our row has changed // so that the "!=" call above doesn't trigger every time m_curr_row.SetOffset (inst->GetAddress().GetFileAddress() + inst->GetOpcode().GetByteSize() - base_addr); // Append the new row unwind_plan.AppendRow (m_curr_row); } } } } } if (log && log->GetVerbose ()) { StreamString strm; lldb::addr_t base_addr = range.GetBaseAddress().GetLoadAddress(&thread.GetProcess().GetTarget()); strm.Printf ("Resulting unwind rows for [0x%llx - 0x%llx):", base_addr, base_addr + range.GetByteSize()); unwind_plan.Dump(strm, &thread, base_addr); log->PutCString (strm.GetData()); } return unwind_plan.GetRowCount() > 0; } return false; }
bool Disassembler::PrintInstructions ( Disassembler *disasm_ptr, Debugger &debugger, const ArchSpec &arch, const ExecutionContext &exe_ctx, uint32_t num_instructions, uint32_t num_mixed_context_lines, uint32_t options, Stream &strm ) { // We got some things disassembled... size_t num_instructions_found = disasm_ptr->GetInstructionList().GetSize(); if (num_instructions > 0 && num_instructions < num_instructions_found) num_instructions_found = num_instructions; const uint32_t max_opcode_byte_size = disasm_ptr->GetInstructionList().GetMaxOpcocdeByteSize (); uint32_t offset = 0; SymbolContext sc; SymbolContext prev_sc; AddressRange sc_range; const Address *pc_addr_ptr = NULL; ExecutionContextScope *exe_scope = exe_ctx.GetBestExecutionContextScope(); Frame *frame = exe_ctx.GetFramePtr(); TargetSP target_sp (exe_ctx.GetTargetSP()); SourceManager &source_manager = target_sp ? target_sp->GetSourceManager() : debugger.GetSourceManager(); if (frame) pc_addr_ptr = &frame->GetFrameCodeAddress(); const uint32_t scope = eSymbolContextLineEntry | eSymbolContextFunction | eSymbolContextSymbol; const bool use_inline_block_range = false; for (size_t i=0; i<num_instructions_found; ++i) { Instruction *inst = disasm_ptr->GetInstructionList().GetInstructionAtIndex (i).get(); if (inst) { const Address &addr = inst->GetAddress(); const bool inst_is_at_pc = pc_addr_ptr && addr == *pc_addr_ptr; prev_sc = sc; ModuleSP module_sp (addr.GetModule()); if (module_sp) { uint32_t resolved_mask = module_sp->ResolveSymbolContextForAddress(addr, eSymbolContextEverything, sc); if (resolved_mask) { if (num_mixed_context_lines) { if (!sc_range.ContainsFileAddress (addr)) { sc.GetAddressRange (scope, 0, use_inline_block_range, sc_range); if (sc != prev_sc) { if (offset != 0) strm.EOL(); sc.DumpStopContext(&strm, exe_ctx.GetProcessPtr(), addr, false, true, false); strm.EOL(); if (sc.comp_unit && sc.line_entry.IsValid()) { source_manager.DisplaySourceLinesWithLineNumbers (sc.line_entry.file, sc.line_entry.line, num_mixed_context_lines, num_mixed_context_lines, ((inst_is_at_pc && (options & eOptionMarkPCSourceLine)) ? "->" : ""), &strm); } } } } else if ((sc.function || sc.symbol) && (sc.function != prev_sc.function || sc.symbol != prev_sc.symbol)) { if (prev_sc.function || prev_sc.symbol) strm.EOL(); bool show_fullpaths = false; bool show_module = true; bool show_inlined_frames = true; sc.DumpStopContext (&strm, exe_scope, addr, show_fullpaths, show_module, show_inlined_frames); strm << ":\n"; } } else { sc.Clear(true); } } if ((options & eOptionMarkPCAddress) && pc_addr_ptr) { strm.PutCString(inst_is_at_pc ? "-> " : " "); } const bool show_bytes = (options & eOptionShowBytes) != 0; inst->Dump(&strm, max_opcode_byte_size, true, show_bytes, &exe_ctx); strm.EOL(); } else { break; } } return true; }
bool UnwindAssemblyInstEmulation::GetNonCallSiteUnwindPlanFromAssembly (AddressRange& range, Thread& thread, UnwindPlan& unwind_plan) { if (range.GetByteSize() > 0 && range.GetBaseAddress().IsValid() && m_inst_emulator_ap.get()) { // The instruction emulation subclass setup the unwind plan for the // first instruction. m_inst_emulator_ap->CreateFunctionEntryUnwind (unwind_plan); // CreateFunctionEntryUnwind should have created the first row. If it // doesn't, then we are done. if (unwind_plan.GetRowCount() == 0) return false; ExecutionContext exe_ctx; thread.CalculateExecutionContext(exe_ctx); const bool prefer_file_cache = true; DisassemblerSP disasm_sp (Disassembler::DisassembleRange (m_arch, NULL, NULL, exe_ctx, range, prefer_file_cache)); Log *log(GetLogIfAllCategoriesSet (LIBLLDB_LOG_UNWIND)); if (disasm_sp) { m_range_ptr = ⦥ m_thread_ptr = &thread; m_unwind_plan_ptr = &unwind_plan; const uint32_t addr_byte_size = m_arch.GetAddressByteSize(); const bool show_address = true; const bool show_bytes = true; m_inst_emulator_ap->GetRegisterInfo (unwind_plan.GetRegisterKind(), unwind_plan.GetInitialCFARegister(), m_cfa_reg_info); m_fp_is_cfa = false; m_register_values.clear(); m_pushed_regs.clear(); // Initialize the CFA with a known value. In the 32 bit case // it will be 0x80000000, and in the 64 bit case 0x8000000000000000. // We use the address byte size to be safe for any future address sizes m_initial_sp = (1ull << ((addr_byte_size * 8) - 1)); RegisterValue cfa_reg_value; cfa_reg_value.SetUInt (m_initial_sp, m_cfa_reg_info.byte_size); SetRegisterValue (m_cfa_reg_info, cfa_reg_value); const InstructionList &inst_list = disasm_sp->GetInstructionList (); const size_t num_instructions = inst_list.GetSize(); if (num_instructions > 0) { Instruction *inst = inst_list.GetInstructionAtIndex (0).get(); const addr_t base_addr = inst->GetAddress().GetFileAddress(); // Make a copy of the current instruction Row and save it in m_curr_row // so we can add updates as we process the instructions. UnwindPlan::RowSP last_row = unwind_plan.GetLastRow(); UnwindPlan::Row *newrow = new UnwindPlan::Row; if (last_row.get()) *newrow = *last_row.get(); m_curr_row.reset(newrow); // Once we've seen the initial prologue instructions complete, save a // copy of the CFI at that point into prologue_completed_row for possible // use later. int instructions_since_last_prologue_insn = 0; // # of insns since last CFI was update bool reinstate_prologue_next_instruction = false; // Next iteration, re-install the prologue row of CFI bool last_instruction_restored_return_addr_reg = false; // re-install the prologue row of CFI if the next instruction is a branch immediate bool return_address_register_has_been_saved = false; // if we've seen the ra register get saved yet UnwindPlan::RowSP prologue_completed_row; // copy of prologue row of CFI // cache the pc register number (in whatever register numbering this UnwindPlan uses) for // quick reference during instruction parsing. uint32_t pc_reg_num = LLDB_INVALID_REGNUM; RegisterInfo pc_reg_info; if (m_inst_emulator_ap->GetRegisterInfo (eRegisterKindGeneric, LLDB_REGNUM_GENERIC_PC, pc_reg_info)) pc_reg_num = pc_reg_info.kinds[unwind_plan.GetRegisterKind()]; else pc_reg_num = LLDB_INVALID_REGNUM; // cache the return address register number (in whatever register numbering this UnwindPlan uses) for // quick reference during instruction parsing. uint32_t ra_reg_num = LLDB_INVALID_REGNUM; RegisterInfo ra_reg_info; if (m_inst_emulator_ap->GetRegisterInfo (eRegisterKindGeneric, LLDB_REGNUM_GENERIC_RA, ra_reg_info)) ra_reg_num = ra_reg_info.kinds[unwind_plan.GetRegisterKind()]; else ra_reg_num = LLDB_INVALID_REGNUM; for (size_t idx=0; idx<num_instructions; ++idx) { m_curr_row_modified = false; m_curr_insn_restored_a_register = false; inst = inst_list.GetInstructionAtIndex (idx).get(); if (inst) { if (log && log->GetVerbose ()) { StreamString strm; inst->Dump(&strm, inst_list.GetMaxOpcocdeByteSize (), show_address, show_bytes, NULL); log->PutCString (strm.GetData()); } m_inst_emulator_ap->SetInstruction (inst->GetOpcode(), inst->GetAddress(), exe_ctx.GetTargetPtr()); m_inst_emulator_ap->EvaluateInstruction (eEmulateInstructionOptionIgnoreConditions); // Were there any changes to the CFI while evaluating this instruction? if (m_curr_row_modified) { reinstate_prologue_next_instruction = false; m_curr_row->SetOffset (inst->GetAddress().GetFileAddress() + inst->GetOpcode().GetByteSize() - base_addr); // Append the new row unwind_plan.AppendRow (m_curr_row); // Allocate a new Row for m_curr_row, copy the current state into it UnwindPlan::Row *newrow = new UnwindPlan::Row; *newrow = *m_curr_row.get(); m_curr_row.reset(newrow); // If m_curr_insn_restored_a_register == true, we're looking at an epilogue instruction. // Set instructions_since_last_prologue_insn to a very high number so we don't append // any of these epilogue instructions to our prologue_complete row. if (m_curr_insn_restored_a_register == false && instructions_since_last_prologue_insn < 8) instructions_since_last_prologue_insn = 0; else instructions_since_last_prologue_insn = 99; UnwindPlan::Row::RegisterLocation pc_regloc; UnwindPlan::Row::RegisterLocation ra_regloc; // While parsing the instructions of this function, if we've ever // seen the return address register (aka lr on arm) in a non-IsSame() state, // it has been saved on the stack. If it's ever back to IsSame(), we've // executed an epilogue. if (ra_reg_num != LLDB_INVALID_REGNUM && m_curr_row->GetRegisterInfo (ra_reg_num, ra_regloc) && !ra_regloc.IsSame()) { return_address_register_has_been_saved = true; } // If the caller's pc is "same", we've just executed an epilogue and we return to the caller // after this instruction completes executing. // If there are any instructions past this, there must have been flow control over this // epilogue so we'll reinstate the original prologue setup instructions. if (prologue_completed_row.get() && pc_reg_num != LLDB_INVALID_REGNUM && m_curr_row->GetRegisterInfo (pc_reg_num, pc_regloc) && pc_regloc.IsSame()) { if (log && log->GetVerbose()) log->Printf("UnwindAssemblyInstEmulation::GetNonCallSiteUnwindPlanFromAssembly -- pc is <same>, restore prologue instructions."); reinstate_prologue_next_instruction = true; } else if (prologue_completed_row.get() && return_address_register_has_been_saved && ra_reg_num != LLDB_INVALID_REGNUM && m_curr_row->GetRegisterInfo (ra_reg_num, ra_regloc) && ra_regloc.IsSame()) { if (log && log->GetVerbose()) log->Printf("UnwindAssemblyInstEmulation::GetNonCallSiteUnwindPlanFromAssembly -- lr is <same>, restore prologue instruction if the next instruction is a branch immediate."); last_instruction_restored_return_addr_reg = true; } } else { // If the previous instruction was a return-to-caller (epilogue), and we're still executing // instructions in this function, there must be a code path that jumps over that epilogue. // Also detect the case where we epilogue & branch imm to another function (tail-call opt) // instead of a normal pop lr-into-pc exit. // Reinstate the frame setup from the prologue. if (reinstate_prologue_next_instruction || (m_curr_insn_is_branch_immediate && last_instruction_restored_return_addr_reg)) { if (log && log->GetVerbose()) log->Printf("UnwindAssemblyInstEmulation::GetNonCallSiteUnwindPlanFromAssembly -- Reinstating prologue instruction set"); UnwindPlan::Row *newrow = new UnwindPlan::Row; *newrow = *prologue_completed_row.get(); m_curr_row.reset(newrow); m_curr_row->SetOffset (inst->GetAddress().GetFileAddress() + inst->GetOpcode().GetByteSize() - base_addr); unwind_plan.AppendRow(m_curr_row); newrow = new UnwindPlan::Row; *newrow = *m_curr_row.get(); m_curr_row.reset(newrow); reinstate_prologue_next_instruction = false; last_instruction_restored_return_addr_reg = false; m_curr_insn_is_branch_immediate = false; } // clear both of these if either one wasn't set if (last_instruction_restored_return_addr_reg) { last_instruction_restored_return_addr_reg = false; } if (m_curr_insn_is_branch_immediate) { m_curr_insn_is_branch_immediate = false; } // Stop updating the prologue instructions if we've seen 8 non-prologue instructions // in a row. if (instructions_since_last_prologue_insn++ < 8) { UnwindPlan::Row *newrow = new UnwindPlan::Row; *newrow = *m_curr_row.get(); prologue_completed_row.reset(newrow); if (log && log->GetVerbose()) log->Printf("UnwindAssemblyInstEmulation::GetNonCallSiteUnwindPlanFromAssembly -- saving a copy of the current row as the prologue row."); } } } } } // FIXME: The DisassemblerLLVMC has a reference cycle and won't go away if it has any active instructions. // I'll fix that but for now, just clear the list and it will go away nicely. disasm_sp->GetInstructionList().Clear(); } if (log && log->GetVerbose ()) { StreamString strm; lldb::addr_t base_addr = range.GetBaseAddress().GetLoadAddress(thread.CalculateTarget().get()); strm.Printf ("Resulting unwind rows for [0x%" PRIx64 " - 0x%" PRIx64 "):", base_addr, base_addr + range.GetByteSize()); unwind_plan.Dump(strm, &thread, base_addr); log->PutCString (strm.GetData()); } return unwind_plan.GetRowCount() > 0; } return false; }