//===-- SBInstruction.cpp -------------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "lldb/API/SBInstruction.h" #include "lldb/Utility/Instrumentation.h" #include "lldb/API/SBAddress.h" #include "lldb/API/SBFrame.h" #include "lldb/API/SBFile.h" #include "lldb/API/SBInstruction.h" #include "lldb/API/SBStream.h" #include "lldb/API/SBTarget.h" #include "lldb/Core/Disassembler.h" #include "lldb/Core/EmulateInstruction.h" #include "lldb/Core/Module.h" #include "lldb/Host/HostInfo.h" #include "lldb/Host/StreamFile.h" #include "lldb/Target/ExecutionContext.h" #include "lldb/Target/StackFrame.h" #include "lldb/Target/Target.h" #include "lldb/Utility/ArchSpec.h" #include "lldb/Utility/DataBufferHeap.h" #include "lldb/Utility/DataExtractor.h" #include // We recently fixed a leak in one of the Instruction subclasses where the // instruction will only hold a weak reference to the disassembler to avoid a // cycle that was keeping both objects alive (leak) and we need the // InstructionImpl class to make sure our public API behaves as users would // expect. Calls in our public API allow clients to do things like: // // 1 lldb::SBInstruction inst; // 2 inst = target.ReadInstructions(pc, 1).GetInstructionAtIndex(0) // 3 if (inst.DoesBranch()) // 4 ... // // There was a temporary lldb::DisassemblerSP object created in the // SBInstructionList that was returned by lldb.target.ReadInstructions() that // will go away after line 2 but the "inst" object should be able to still // answer questions about itself. So we make sure that any SBInstruction // objects that are given out have a strong reference to the disassembler and // the instruction so that the object can live and successfully respond to all // queries. class InstructionImpl { public: InstructionImpl(const lldb::DisassemblerSP &disasm_sp, const lldb::InstructionSP &inst_sp) : m_disasm_sp(disasm_sp), m_inst_sp(inst_sp) {} lldb::InstructionSP GetSP() const { return m_inst_sp; } bool IsValid() const { return (bool)m_inst_sp; } protected: lldb::DisassemblerSP m_disasm_sp; // Can be empty/invalid lldb::InstructionSP m_inst_sp; }; using namespace lldb; using namespace lldb_private; SBInstruction::SBInstruction() { LLDB_INSTRUMENT_VA(this); } SBInstruction::SBInstruction(const lldb::DisassemblerSP &disasm_sp, const lldb::InstructionSP &inst_sp) : m_opaque_sp(new InstructionImpl(disasm_sp, inst_sp)) {} SBInstruction::SBInstruction(const SBInstruction &rhs) : m_opaque_sp(rhs.m_opaque_sp) { LLDB_INSTRUMENT_VA(this, rhs); } const SBInstruction &SBInstruction::operator=(const SBInstruction &rhs) { LLDB_INSTRUMENT_VA(this, rhs); if (this != &rhs) m_opaque_sp = rhs.m_opaque_sp; return *this; } SBInstruction::~SBInstruction() = default; bool SBInstruction::IsValid() { LLDB_INSTRUMENT_VA(this); return this->operator bool(); } SBInstruction::operator bool() const { LLDB_INSTRUMENT_VA(this); return m_opaque_sp && m_opaque_sp->IsValid(); } SBAddress SBInstruction::GetAddress() { LLDB_INSTRUMENT_VA(this); SBAddress sb_addr; lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp && inst_sp->GetAddress().IsValid()) sb_addr.SetAddress(inst_sp->GetAddress()); return sb_addr; } const char *SBInstruction::GetMnemonic(SBTarget target) { LLDB_INSTRUMENT_VA(this, target); lldb::InstructionSP inst_sp(GetOpaque()); if (!inst_sp) return nullptr; ExecutionContext exe_ctx; TargetSP target_sp(target.GetSP()); std::unique_lock lock; if (target_sp) { lock = std::unique_lock(target_sp->GetAPIMutex()); target_sp->CalculateExecutionContext(exe_ctx); exe_ctx.SetProcessSP(target_sp->GetProcessSP()); } return ConstString(inst_sp->GetMnemonic(&exe_ctx)).GetCString(); } const char *SBInstruction::GetOperands(SBTarget target) { LLDB_INSTRUMENT_VA(this, target); lldb::InstructionSP inst_sp(GetOpaque()); if (!inst_sp) return nullptr; ExecutionContext exe_ctx; TargetSP target_sp(target.GetSP()); std::unique_lock lock; if (target_sp) { lock = std::unique_lock(target_sp->GetAPIMutex()); target_sp->CalculateExecutionContext(exe_ctx); exe_ctx.SetProcessSP(target_sp->GetProcessSP()); } return ConstString(inst_sp->GetOperands(&exe_ctx)).GetCString(); } const char *SBInstruction::GetComment(SBTarget target) { LLDB_INSTRUMENT_VA(this, target); lldb::InstructionSP inst_sp(GetOpaque()); if (!inst_sp) return nullptr; ExecutionContext exe_ctx; TargetSP target_sp(target.GetSP()); std::unique_lock lock; if (target_sp) { lock = std::unique_lock(target_sp->GetAPIMutex()); target_sp->CalculateExecutionContext(exe_ctx); exe_ctx.SetProcessSP(target_sp->GetProcessSP()); } return ConstString(inst_sp->GetComment(&exe_ctx)).GetCString(); } lldb::InstructionControlFlowKind SBInstruction::GetControlFlowKind(lldb::SBTarget target) { LLDB_INSTRUMENT_VA(this, target); lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) { ExecutionContext exe_ctx; TargetSP target_sp(target.GetSP()); std::unique_lock lock; if (target_sp) { lock = std::unique_lock(target_sp->GetAPIMutex()); target_sp->CalculateExecutionContext(exe_ctx); exe_ctx.SetProcessSP(target_sp->GetProcessSP()); } return inst_sp->GetControlFlowKind(&exe_ctx); } return lldb::eInstructionControlFlowKindUnknown; } size_t SBInstruction::GetByteSize() { LLDB_INSTRUMENT_VA(this); lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) return inst_sp->GetOpcode().GetByteSize(); return 0; } SBData SBInstruction::GetData(SBTarget target) { LLDB_INSTRUMENT_VA(this, target); lldb::SBData sb_data; lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) { DataExtractorSP data_extractor_sp(new DataExtractor()); if (inst_sp->GetData(*data_extractor_sp)) { sb_data.SetOpaque(data_extractor_sp); } } return sb_data; } bool SBInstruction::DoesBranch() { LLDB_INSTRUMENT_VA(this); lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) return inst_sp->DoesBranch(); return false; } bool SBInstruction::HasDelaySlot() { LLDB_INSTRUMENT_VA(this); lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) return inst_sp->HasDelaySlot(); return false; } bool SBInstruction::CanSetBreakpoint() { LLDB_INSTRUMENT_VA(this); lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) return inst_sp->CanSetBreakpoint(); return false; } lldb::InstructionSP SBInstruction::GetOpaque() { if (m_opaque_sp) return m_opaque_sp->GetSP(); else return lldb::InstructionSP(); } void SBInstruction::SetOpaque(const lldb::DisassemblerSP &disasm_sp, const lldb::InstructionSP &inst_sp) { m_opaque_sp = std::make_shared(disasm_sp, inst_sp); } bool SBInstruction::GetDescription(lldb::SBStream &s) { LLDB_INSTRUMENT_VA(this, s); lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) { SymbolContext sc; const Address &addr = inst_sp->GetAddress(); ModuleSP module_sp(addr.GetModule()); if (module_sp) module_sp->ResolveSymbolContextForAddress(addr, eSymbolContextEverything, sc); // Use the "ref()" instead of the "get()" accessor in case the SBStream // didn't have a stream already created, one will get created... FormatEntity::Entry format; FormatEntity::Parse("${addr}: ", format); inst_sp->Dump(&s.ref(), 0, true, false, /*show_control_flow_kind=*/false, nullptr, &sc, nullptr, &format, 0); return true; } return false; } void SBInstruction::Print(FILE *outp) { LLDB_INSTRUMENT_VA(this, outp); FileSP out = std::make_shared(outp, /*take_ownership=*/false); Print(out); } void SBInstruction::Print(SBFile out) { LLDB_INSTRUMENT_VA(this, out); Print(out.m_opaque_sp); } void SBInstruction::Print(FileSP out_sp) { LLDB_INSTRUMENT_VA(this, out_sp); if (!out_sp || !out_sp->IsValid()) return; lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) { SymbolContext sc; const Address &addr = inst_sp->GetAddress(); ModuleSP module_sp(addr.GetModule()); if (module_sp) module_sp->ResolveSymbolContextForAddress(addr, eSymbolContextEverything, sc); StreamFile out_stream(out_sp); FormatEntity::Entry format; FormatEntity::Parse("${addr}: ", format); inst_sp->Dump(&out_stream, 0, true, false, /*show_control_flow_kind=*/false, nullptr, &sc, nullptr, &format, 0); } } bool SBInstruction::EmulateWithFrame(lldb::SBFrame &frame, uint32_t evaluate_options) { LLDB_INSTRUMENT_VA(this, frame, evaluate_options); lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) { lldb::StackFrameSP frame_sp(frame.GetFrameSP()); if (frame_sp) { lldb_private::ExecutionContext exe_ctx; frame_sp->CalculateExecutionContext(exe_ctx); lldb_private::Target *target = exe_ctx.GetTargetPtr(); lldb_private::ArchSpec arch = target->GetArchitecture(); return inst_sp->Emulate( arch, evaluate_options, (void *)frame_sp.get(), &lldb_private::EmulateInstruction::ReadMemoryFrame, &lldb_private::EmulateInstruction::WriteMemoryFrame, &lldb_private::EmulateInstruction::ReadRegisterFrame, &lldb_private::EmulateInstruction::WriteRegisterFrame); } } return false; } bool SBInstruction::DumpEmulation(const char *triple) { LLDB_INSTRUMENT_VA(this, triple); lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp && triple) { return inst_sp->DumpEmulation(HostInfo::GetAugmentedArchSpec(triple)); } return false; } bool SBInstruction::TestEmulation(lldb::SBStream &output_stream, const char *test_file) { LLDB_INSTRUMENT_VA(this, output_stream, test_file); if (!m_opaque_sp) SetOpaque(lldb::DisassemblerSP(), lldb::InstructionSP(new PseudoInstruction())); lldb::InstructionSP inst_sp(GetOpaque()); if (inst_sp) return inst_sp->TestEmulation(output_stream.ref(), test_file); return false; }