//===-- FuncUnwinders.cpp ----------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "lldb/Symbol/FuncUnwinders.h" #include "lldb/Core/Address.h" #include "lldb/Core/AddressRange.h" #include "lldb/Symbol/ArmUnwindInfo.h" #include "lldb/Symbol/CompactUnwindInfo.h" #include "lldb/Symbol/DWARFCallFrameInfo.h" #include "lldb/Symbol/ObjectFile.h" #include "lldb/Symbol/UnwindPlan.h" #include "lldb/Symbol/UnwindTable.h" #include "lldb/Target/ABI.h" #include "lldb/Target/ExecutionContext.h" #include "lldb/Target/Process.h" #include "lldb/Target/Target.h" #include "lldb/Target/Thread.h" #include "lldb/Target/UnwindAssembly.h" #include "lldb/Utility/RegisterNumber.h" using namespace lldb; using namespace lldb_private; //------------------------------------------------ /// constructor //------------------------------------------------ FuncUnwinders::FuncUnwinders(UnwindTable &unwind_table, AddressRange range) : m_unwind_table(unwind_table), m_range(range), m_mutex(), m_unwind_plan_assembly_sp(), m_unwind_plan_eh_frame_sp(), m_unwind_plan_eh_frame_augmented_sp(), m_unwind_plan_compact_unwind(), m_unwind_plan_arm_unwind_sp(), m_unwind_plan_fast_sp(), m_unwind_plan_arch_default_sp(), m_unwind_plan_arch_default_at_func_entry_sp(), m_tried_unwind_plan_assembly(false), m_tried_unwind_plan_eh_frame(false), m_tried_unwind_plan_eh_frame_augmented(false), m_tried_unwind_plan_compact_unwind(false), m_tried_unwind_plan_arm_unwind(false), m_tried_unwind_fast(false), m_tried_unwind_arch_default(false), m_tried_unwind_arch_default_at_func_entry(false), m_first_non_prologue_insn() {} //------------------------------------------------ /// destructor //------------------------------------------------ FuncUnwinders::~FuncUnwinders() {} UnwindPlanSP FuncUnwinders::GetUnwindPlanAtCallSite(Target &target, int current_offset) { std::lock_guard guard(m_mutex); UnwindPlanSP unwind_plan_sp = GetEHFrameUnwindPlan(target, current_offset); if (unwind_plan_sp) return unwind_plan_sp; unwind_plan_sp = GetCompactUnwindUnwindPlan(target, current_offset); if (unwind_plan_sp) return unwind_plan_sp; unwind_plan_sp = GetArmUnwindUnwindPlan(target, current_offset); if (unwind_plan_sp) return unwind_plan_sp; return nullptr; } UnwindPlanSP FuncUnwinders::GetCompactUnwindUnwindPlan(Target &target, int current_offset) { if (m_unwind_plan_compact_unwind.size() > 0) return m_unwind_plan_compact_unwind[0]; // FIXME support multiple compact // unwind plans for one func if (m_tried_unwind_plan_compact_unwind) return UnwindPlanSP(); std::lock_guard guard(m_mutex); m_tried_unwind_plan_compact_unwind = true; if (m_range.GetBaseAddress().IsValid()) { Address current_pc(m_range.GetBaseAddress()); if (current_offset != -1) current_pc.SetOffset(current_pc.GetOffset() + current_offset); CompactUnwindInfo *compact_unwind = m_unwind_table.GetCompactUnwindInfo(); if (compact_unwind) { UnwindPlanSP unwind_plan_sp(new UnwindPlan(lldb::eRegisterKindGeneric)); if (compact_unwind->GetUnwindPlan(target, current_pc, *unwind_plan_sp)) { m_unwind_plan_compact_unwind.push_back(unwind_plan_sp); return m_unwind_plan_compact_unwind[0]; // FIXME support multiple // compact unwind plans for one // func } } } return UnwindPlanSP(); } UnwindPlanSP FuncUnwinders::GetEHFrameUnwindPlan(Target &target, int current_offset) { if (m_unwind_plan_eh_frame_sp.get() || m_tried_unwind_plan_eh_frame) return m_unwind_plan_eh_frame_sp; std::lock_guard guard(m_mutex); m_tried_unwind_plan_eh_frame = true; if (m_range.GetBaseAddress().IsValid()) { Address current_pc(m_range.GetBaseAddress()); if (current_offset != -1) current_pc.SetOffset(current_pc.GetOffset() + current_offset); DWARFCallFrameInfo *eh_frame = m_unwind_table.GetEHFrameInfo(); if (eh_frame) { m_unwind_plan_eh_frame_sp.reset( new UnwindPlan(lldb::eRegisterKindGeneric)); if (!eh_frame->GetUnwindPlan(current_pc, *m_unwind_plan_eh_frame_sp)) m_unwind_plan_eh_frame_sp.reset(); } } return m_unwind_plan_eh_frame_sp; } UnwindPlanSP FuncUnwinders::GetArmUnwindUnwindPlan(Target &target, int current_offset) { if (m_unwind_plan_arm_unwind_sp.get() || m_tried_unwind_plan_arm_unwind) return m_unwind_plan_arm_unwind_sp; std::lock_guard guard(m_mutex); m_tried_unwind_plan_arm_unwind = true; if (m_range.GetBaseAddress().IsValid()) { Address current_pc(m_range.GetBaseAddress()); if (current_offset != -1) current_pc.SetOffset(current_pc.GetOffset() + current_offset); ArmUnwindInfo *arm_unwind_info = m_unwind_table.GetArmUnwindInfo(); if (arm_unwind_info) { m_unwind_plan_arm_unwind_sp.reset( new UnwindPlan(lldb::eRegisterKindGeneric)); if (!arm_unwind_info->GetUnwindPlan(target, current_pc, *m_unwind_plan_arm_unwind_sp)) m_unwind_plan_arm_unwind_sp.reset(); } } return m_unwind_plan_arm_unwind_sp; } UnwindPlanSP FuncUnwinders::GetEHFrameAugmentedUnwindPlan(Target &target, Thread &thread, int current_offset) { if (m_unwind_plan_eh_frame_augmented_sp.get() || m_tried_unwind_plan_eh_frame_augmented) return m_unwind_plan_eh_frame_augmented_sp; // Only supported on x86 architectures where we get eh_frame from the compiler // that describes // the prologue instructions perfectly, and sometimes the epilogue // instructions too. if (target.GetArchitecture().GetCore() != ArchSpec::eCore_x86_32_i386 && target.GetArchitecture().GetCore() != ArchSpec::eCore_x86_64_x86_64 && target.GetArchitecture().GetCore() != ArchSpec::eCore_x86_64_x86_64h) { m_tried_unwind_plan_eh_frame_augmented = true; return m_unwind_plan_eh_frame_augmented_sp; } std::lock_guard guard(m_mutex); m_tried_unwind_plan_eh_frame_augmented = true; UnwindPlanSP eh_frame_plan = GetEHFrameUnwindPlan(target, current_offset); if (!eh_frame_plan) return m_unwind_plan_eh_frame_augmented_sp; m_unwind_plan_eh_frame_augmented_sp.reset(new UnwindPlan(*eh_frame_plan)); // Augment the eh_frame instructions with epilogue descriptions if necessary // so the // UnwindPlan can be used at any instruction in the function. UnwindAssemblySP assembly_profiler_sp(GetUnwindAssemblyProfiler(target)); if (assembly_profiler_sp) { if (!assembly_profiler_sp->AugmentUnwindPlanFromCallSite( m_range, thread, *m_unwind_plan_eh_frame_augmented_sp)) { m_unwind_plan_eh_frame_augmented_sp.reset(); } } else { m_unwind_plan_eh_frame_augmented_sp.reset(); } return m_unwind_plan_eh_frame_augmented_sp; } UnwindPlanSP FuncUnwinders::GetAssemblyUnwindPlan(Target &target, Thread &thread, int current_offset) { if (m_unwind_plan_assembly_sp.get() || m_tried_unwind_plan_assembly || m_unwind_table.GetAllowAssemblyEmulationUnwindPlans() == false) { return m_unwind_plan_assembly_sp; } std::lock_guard guard(m_mutex); m_tried_unwind_plan_assembly = true; UnwindAssemblySP assembly_profiler_sp(GetUnwindAssemblyProfiler(target)); if (assembly_profiler_sp) { m_unwind_plan_assembly_sp.reset(new UnwindPlan(lldb::eRegisterKindGeneric)); if (!assembly_profiler_sp->GetNonCallSiteUnwindPlanFromAssembly( m_range, thread, *m_unwind_plan_assembly_sp)) { m_unwind_plan_assembly_sp.reset(); } } return m_unwind_plan_assembly_sp; } // This method compares the pc unwind rule in the first row of two UnwindPlans. // If they have the same way of getting the pc value (e.g. "CFA - 8" + "CFA is // sp"), // then it will return LazyBoolTrue. LazyBool FuncUnwinders::CompareUnwindPlansForIdenticalInitialPCLocation( Thread &thread, const UnwindPlanSP &a, const UnwindPlanSP &b) { LazyBool plans_are_identical = eLazyBoolCalculate; RegisterNumber pc_reg(thread, eRegisterKindGeneric, LLDB_REGNUM_GENERIC_PC); uint32_t pc_reg_lldb_regnum = pc_reg.GetAsKind(eRegisterKindLLDB); if (a.get() && b.get()) { UnwindPlan::RowSP a_first_row = a->GetRowAtIndex(0); UnwindPlan::RowSP b_first_row = b->GetRowAtIndex(0); if (a_first_row.get() && b_first_row.get()) { UnwindPlan::Row::RegisterLocation a_pc_regloc; UnwindPlan::Row::RegisterLocation b_pc_regloc; a_first_row->GetRegisterInfo(pc_reg_lldb_regnum, a_pc_regloc); b_first_row->GetRegisterInfo(pc_reg_lldb_regnum, b_pc_regloc); plans_are_identical = eLazyBoolYes; if (a_first_row->GetCFAValue() != b_first_row->GetCFAValue()) { plans_are_identical = eLazyBoolNo; } if (a_pc_regloc != b_pc_regloc) { plans_are_identical = eLazyBoolNo; } } } return plans_are_identical; } UnwindPlanSP FuncUnwinders::GetUnwindPlanAtNonCallSite(Target &target, Thread &thread, int current_offset) { UnwindPlanSP eh_frame_sp = GetEHFrameUnwindPlan(target, current_offset); UnwindPlanSP arch_default_at_entry_sp = GetUnwindPlanArchitectureDefaultAtFunctionEntry(thread); UnwindPlanSP arch_default_sp = GetUnwindPlanArchitectureDefault(thread); UnwindPlanSP assembly_sp = GetAssemblyUnwindPlan(target, thread, current_offset); // This point of this code is to detect when a function is using a // non-standard ABI, and the eh_frame // correctly describes that alternate ABI. This is addressing a specific // situation on x86_64 linux // systems where one function in a library pushes a value on the stack and // jumps to another function. // So using an assembly instruction based unwind will not work when you're in // the second function - // the stack has been modified in a non-ABI way. But we have eh_frame that // correctly describes how to // unwind from this location. So we're looking to see if the initial pc // register save location from // the eh_frame is different from the assembly unwind, the arch default // unwind, and the arch default at // initial function entry. // // We may have eh_frame that describes the entire function -- or we may have // eh_frame that only describes // the unwind after the prologue has executed -- so we need to check both the // arch default (once the prologue // has executed) and the arch default at initial function entry. And we may // be running on a target where // we have only some of the assembly/arch default unwind plans available. if (CompareUnwindPlansForIdenticalInitialPCLocation( thread, eh_frame_sp, arch_default_at_entry_sp) == eLazyBoolNo && CompareUnwindPlansForIdenticalInitialPCLocation( thread, eh_frame_sp, arch_default_sp) == eLazyBoolNo && CompareUnwindPlansForIdenticalInitialPCLocation( thread, assembly_sp, arch_default_sp) == eLazyBoolNo) { return eh_frame_sp; } UnwindPlanSP eh_frame_augmented_sp = GetEHFrameAugmentedUnwindPlan(target, thread, current_offset); if (eh_frame_augmented_sp) { return eh_frame_augmented_sp; } return assembly_sp; } UnwindPlanSP FuncUnwinders::GetUnwindPlanFastUnwind(Target &target, Thread &thread) { if (m_unwind_plan_fast_sp.get() || m_tried_unwind_fast) return m_unwind_plan_fast_sp; std::lock_guard guard(m_mutex); m_tried_unwind_fast = true; UnwindAssemblySP assembly_profiler_sp(GetUnwindAssemblyProfiler(target)); if (assembly_profiler_sp) { m_unwind_plan_fast_sp.reset(new UnwindPlan(lldb::eRegisterKindGeneric)); if (!assembly_profiler_sp->GetFastUnwindPlan(m_range, thread, *m_unwind_plan_fast_sp)) { m_unwind_plan_fast_sp.reset(); } } return m_unwind_plan_fast_sp; } UnwindPlanSP FuncUnwinders::GetUnwindPlanArchitectureDefault(Thread &thread) { if (m_unwind_plan_arch_default_sp.get() || m_tried_unwind_arch_default) return m_unwind_plan_arch_default_sp; std::lock_guard guard(m_mutex); m_tried_unwind_arch_default = true; Address current_pc; ProcessSP process_sp(thread.CalculateProcess()); if (process_sp) { ABI *abi = process_sp->GetABI().get(); if (abi) { m_unwind_plan_arch_default_sp.reset( new UnwindPlan(lldb::eRegisterKindGeneric)); if (!abi->CreateDefaultUnwindPlan(*m_unwind_plan_arch_default_sp)) { m_unwind_plan_arch_default_sp.reset(); } } } return m_unwind_plan_arch_default_sp; } UnwindPlanSP FuncUnwinders::GetUnwindPlanArchitectureDefaultAtFunctionEntry(Thread &thread) { if (m_unwind_plan_arch_default_at_func_entry_sp.get() || m_tried_unwind_arch_default_at_func_entry) return m_unwind_plan_arch_default_at_func_entry_sp; std::lock_guard guard(m_mutex); m_tried_unwind_arch_default_at_func_entry = true; Address current_pc; ProcessSP process_sp(thread.CalculateProcess()); if (process_sp) { ABI *abi = process_sp->GetABI().get(); if (abi) { m_unwind_plan_arch_default_at_func_entry_sp.reset( new UnwindPlan(lldb::eRegisterKindGeneric)); if (!abi->CreateFunctionEntryUnwindPlan( *m_unwind_plan_arch_default_at_func_entry_sp)) { m_unwind_plan_arch_default_at_func_entry_sp.reset(); } } } return m_unwind_plan_arch_default_at_func_entry_sp; } Address &FuncUnwinders::GetFirstNonPrologueInsn(Target &target) { if (m_first_non_prologue_insn.IsValid()) return m_first_non_prologue_insn; std::lock_guard guard(m_mutex); ExecutionContext exe_ctx(target.shared_from_this(), false); UnwindAssemblySP assembly_profiler_sp(GetUnwindAssemblyProfiler(target)); if (assembly_profiler_sp) assembly_profiler_sp->FirstNonPrologueInsn(m_range, exe_ctx, m_first_non_prologue_insn); return m_first_non_prologue_insn; } const Address &FuncUnwinders::GetFunctionStartAddress() const { return m_range.GetBaseAddress(); } lldb::UnwindAssemblySP FuncUnwinders::GetUnwindAssemblyProfiler(Target &target) { UnwindAssemblySP assembly_profiler_sp; ArchSpec arch; if (m_unwind_table.GetArchitecture(arch)) { arch.MergeFrom(target.GetArchitecture()); assembly_profiler_sp = UnwindAssembly::FindPlugin(arch); } return assembly_profiler_sp; } Address FuncUnwinders::GetLSDAAddress(Target &target) { Address lsda_addr; UnwindPlanSP unwind_plan_sp = GetEHFrameUnwindPlan(target, -1); if (unwind_plan_sp.get() == nullptr) { unwind_plan_sp = GetCompactUnwindUnwindPlan(target, -1); } if (unwind_plan_sp.get() && unwind_plan_sp->GetLSDAAddress().IsValid()) { lsda_addr = unwind_plan_sp->GetLSDAAddress(); } return lsda_addr; } Address FuncUnwinders::GetPersonalityRoutinePtrAddress(Target &target) { Address personality_addr; UnwindPlanSP unwind_plan_sp = GetEHFrameUnwindPlan(target, -1); if (unwind_plan_sp.get() == nullptr) { unwind_plan_sp = GetCompactUnwindUnwindPlan(target, -1); } if (unwind_plan_sp.get() && unwind_plan_sp->GetPersonalityFunctionPtr().IsValid()) { personality_addr = unwind_plan_sp->GetPersonalityFunctionPtr(); } return personality_addr; }