//===-- DisassemblerLLVMC.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 "DisassemblerLLVMC.h" #include "llvm-c/Disassembler.h" #include "llvm/ADT/SmallString.h" #include "llvm/ADT/StringExtras.h" #include "llvm/MC/MCAsmInfo.h" #include "llvm/MC/MCContext.h" #include "llvm/MC/MCDisassembler/MCDisassembler.h" #include "llvm/MC/MCDisassembler/MCExternalSymbolizer.h" #include "llvm/MC/MCDisassembler/MCRelocationInfo.h" #include "llvm/MC/MCInst.h" #include "llvm/MC/MCInstPrinter.h" #include "llvm/MC/MCInstrAnalysis.h" #include "llvm/MC/MCInstrInfo.h" #include "llvm/MC/MCRegisterInfo.h" #include "llvm/MC/MCSubtargetInfo.h" #include "llvm/MC/MCTargetOptions.h" #include "llvm/MC/TargetRegistry.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/ScopedPrinter.h" #include "llvm/Support/TargetSelect.h" #include "llvm/TargetParser/AArch64TargetParser.h" #include "lldb/Core/Address.h" #include "lldb/Core/Module.h" #include "lldb/Symbol/SymbolContext.h" #include "lldb/Target/ExecutionContext.h" #include "lldb/Target/Process.h" #include "lldb/Target/RegisterContext.h" #include "lldb/Target/SectionLoadList.h" #include "lldb/Target/StackFrame.h" #include "lldb/Target/Target.h" #include "lldb/Utility/DataExtractor.h" #include "lldb/Utility/LLDBLog.h" #include "lldb/Utility/Log.h" #include "lldb/Utility/RegularExpression.h" #include "lldb/Utility/Stream.h" #include using namespace lldb; using namespace lldb_private; LLDB_PLUGIN_DEFINE(DisassemblerLLVMC) class DisassemblerLLVMC::MCDisasmInstance { public: static std::unique_ptr Create(const char *triple, const char *cpu, const char *features_str, unsigned flavor, DisassemblerLLVMC &owner); ~MCDisasmInstance() = default; uint64_t GetMCInst(const uint8_t *opcode_data, size_t opcode_data_len, lldb::addr_t pc, llvm::MCInst &mc_inst) const; void PrintMCInst(llvm::MCInst &mc_inst, lldb::addr_t pc, std::string &inst_string, std::string &comments_string); void SetStyle(bool use_hex_immed, HexImmediateStyle hex_style); void SetUseColor(bool use_color); bool GetUseColor() const; bool CanBranch(llvm::MCInst &mc_inst) const; bool HasDelaySlot(llvm::MCInst &mc_inst) const; bool IsCall(llvm::MCInst &mc_inst) const; bool IsLoad(llvm::MCInst &mc_inst) const; bool IsAuthenticated(llvm::MCInst &mc_inst) const; private: MCDisasmInstance(std::unique_ptr &&instr_info_up, std::unique_ptr &®_info_up, std::unique_ptr &&subtarget_info_up, std::unique_ptr &&asm_info_up, std::unique_ptr &&context_up, std::unique_ptr &&disasm_up, std::unique_ptr &&instr_printer_up, std::unique_ptr &&instr_analysis_up); std::unique_ptr m_instr_info_up; std::unique_ptr m_reg_info_up; std::unique_ptr m_subtarget_info_up; std::unique_ptr m_asm_info_up; std::unique_ptr m_context_up; std::unique_ptr m_disasm_up; std::unique_ptr m_instr_printer_up; std::unique_ptr m_instr_analysis_up; }; namespace x86 { /// These are the three values deciding instruction control flow kind. /// InstructionLengthDecode function decodes an instruction and get this struct. /// /// primary_opcode /// Primary opcode of the instruction. /// For one-byte opcode instruction, it's the first byte after prefix. /// For two- and three-byte opcodes, it's the second byte. /// /// opcode_len /// The length of opcode in bytes. Valid opcode lengths are 1, 2, or 3. /// /// modrm /// ModR/M byte of the instruction. /// Bits[7:6] indicate MOD. Bits[5:3] specify a register and R/M bits[2:0] /// may contain a register or specify an addressing mode, depending on MOD. struct InstructionOpcodeAndModrm { uint8_t primary_opcode; uint8_t opcode_len; uint8_t modrm; }; /// Determine the InstructionControlFlowKind based on opcode and modrm bytes. /// Refer to http://ref.x86asm.net/coder.html for the full list of opcode and /// instruction set. /// /// \param[in] opcode_and_modrm /// Contains primary_opcode byte, its length, and ModR/M byte. /// Refer to the struct InstructionOpcodeAndModrm for details. /// /// \return /// The control flow kind of the instruction or /// eInstructionControlFlowKindOther if the instruction doesn't affect /// the control flow of the program. lldb::InstructionControlFlowKind MapOpcodeIntoControlFlowKind(InstructionOpcodeAndModrm opcode_and_modrm) { uint8_t opcode = opcode_and_modrm.primary_opcode; uint8_t opcode_len = opcode_and_modrm.opcode_len; uint8_t modrm = opcode_and_modrm.modrm; if (opcode_len > 2) return lldb::eInstructionControlFlowKindOther; if (opcode >= 0x70 && opcode <= 0x7F) { if (opcode_len == 1) return lldb::eInstructionControlFlowKindCondJump; else return lldb::eInstructionControlFlowKindOther; } if (opcode >= 0x80 && opcode <= 0x8F) { if (opcode_len == 2) return lldb::eInstructionControlFlowKindCondJump; else return lldb::eInstructionControlFlowKindOther; } switch (opcode) { case 0x9A: if (opcode_len == 1) return lldb::eInstructionControlFlowKindFarCall; break; case 0xFF: if (opcode_len == 1) { uint8_t modrm_reg = (modrm >> 3) & 7; if (modrm_reg == 2) return lldb::eInstructionControlFlowKindCall; else if (modrm_reg == 3) return lldb::eInstructionControlFlowKindFarCall; else if (modrm_reg == 4) return lldb::eInstructionControlFlowKindJump; else if (modrm_reg == 5) return lldb::eInstructionControlFlowKindFarJump; } break; case 0xE8: if (opcode_len == 1) return lldb::eInstructionControlFlowKindCall; break; case 0xCD: case 0xCC: case 0xCE: case 0xF1: if (opcode_len == 1) return lldb::eInstructionControlFlowKindFarCall; break; case 0xCF: if (opcode_len == 1) return lldb::eInstructionControlFlowKindFarReturn; break; case 0xE9: case 0xEB: if (opcode_len == 1) return lldb::eInstructionControlFlowKindJump; break; case 0xEA: if (opcode_len == 1) return lldb::eInstructionControlFlowKindFarJump; break; case 0xE3: case 0xE0: case 0xE1: case 0xE2: if (opcode_len == 1) return lldb::eInstructionControlFlowKindCondJump; break; case 0xC3: case 0xC2: if (opcode_len == 1) return lldb::eInstructionControlFlowKindReturn; break; case 0xCB: case 0xCA: if (opcode_len == 1) return lldb::eInstructionControlFlowKindFarReturn; break; case 0x05: case 0x34: if (opcode_len == 2) return lldb::eInstructionControlFlowKindFarCall; break; case 0x35: case 0x07: if (opcode_len == 2) return lldb::eInstructionControlFlowKindFarReturn; break; case 0x01: if (opcode_len == 2) { switch (modrm) { case 0xc1: return lldb::eInstructionControlFlowKindFarCall; case 0xc2: case 0xc3: return lldb::eInstructionControlFlowKindFarReturn; default: break; } } break; default: break; } return lldb::eInstructionControlFlowKindOther; } /// Decode an instruction into opcode, modrm and opcode_len. /// Refer to http://ref.x86asm.net/coder.html for the instruction bytes layout. /// Opcodes in x86 are generally the first byte of instruction, though two-byte /// instructions and prefixes exist. ModR/M is the byte following the opcode /// and adds additional information for how the instruction is executed. /// /// \param[in] inst_bytes /// Raw bytes of the instruction /// /// /// \param[in] bytes_len /// The length of the inst_bytes array. /// /// \param[in] is_exec_mode_64b /// If true, the execution mode is 64 bit. /// /// \return /// Returns decoded instruction as struct InstructionOpcodeAndModrm, holding /// primary_opcode, opcode_len and modrm byte. Refer to the struct definition /// for more details. /// Otherwise if the given instruction is invalid, returns std::nullopt. std::optional InstructionLengthDecode(const uint8_t *inst_bytes, int bytes_len, bool is_exec_mode_64b) { int op_idx = 0; bool prefix_done = false; InstructionOpcodeAndModrm ret = {0, 0, 0}; // In most cases, the primary_opcode is the first byte of the instruction // but some instructions have a prefix to be skipped for these calculations. // The following mapping is inspired from libipt's instruction decoding logic // in `src/pt_ild.c` while (!prefix_done) { if (op_idx >= bytes_len) return std::nullopt; ret.primary_opcode = inst_bytes[op_idx]; switch (ret.primary_opcode) { // prefix_ignore case 0x26: case 0x2e: case 0x36: case 0x3e: case 0x64: case 0x65: // prefix_osz, prefix_asz case 0x66: case 0x67: // prefix_lock, prefix_f2, prefix_f3 case 0xf0: case 0xf2: case 0xf3: op_idx++; break; // prefix_rex case 0x40: case 0x41: case 0x42: case 0x43: case 0x44: case 0x45: case 0x46: case 0x47: case 0x48: case 0x49: case 0x4a: case 0x4b: case 0x4c: case 0x4d: case 0x4e: case 0x4f: if (is_exec_mode_64b) op_idx++; else prefix_done = true; break; // prefix_vex_c4, c5 case 0xc5: if (!is_exec_mode_64b && (inst_bytes[op_idx + 1] & 0xc0) != 0xc0) { prefix_done = true; break; } ret.opcode_len = 2; ret.primary_opcode = inst_bytes[op_idx + 2]; ret.modrm = inst_bytes[op_idx + 3]; return ret; case 0xc4: if (!is_exec_mode_64b && (inst_bytes[op_idx + 1] & 0xc0) != 0xc0) { prefix_done = true; break; } ret.opcode_len = inst_bytes[op_idx + 1] & 0x1f; ret.primary_opcode = inst_bytes[op_idx + 3]; ret.modrm = inst_bytes[op_idx + 4]; return ret; // prefix_evex case 0x62: if (!is_exec_mode_64b && (inst_bytes[op_idx + 1] & 0xc0) != 0xc0) { prefix_done = true; break; } ret.opcode_len = inst_bytes[op_idx + 1] & 0x03; ret.primary_opcode = inst_bytes[op_idx + 4]; ret.modrm = inst_bytes[op_idx + 5]; return ret; default: prefix_done = true; break; } } // prefix done ret.primary_opcode = inst_bytes[op_idx]; ret.modrm = inst_bytes[op_idx + 1]; ret.opcode_len = 1; // If the first opcode is 0F, it's two- or three- byte opcodes. if (ret.primary_opcode == 0x0F) { ret.primary_opcode = inst_bytes[++op_idx]; // get the next byte if (ret.primary_opcode == 0x38) { ret.opcode_len = 3; ret.primary_opcode = inst_bytes[++op_idx]; // get the next byte ret.modrm = inst_bytes[op_idx + 1]; } else if (ret.primary_opcode == 0x3A) { ret.opcode_len = 3; ret.primary_opcode = inst_bytes[++op_idx]; ret.modrm = inst_bytes[op_idx + 1]; } else if ((ret.primary_opcode & 0xf8) == 0x38) { ret.opcode_len = 0; ret.primary_opcode = inst_bytes[++op_idx]; ret.modrm = inst_bytes[op_idx + 1]; } else if (ret.primary_opcode == 0x0F) { ret.opcode_len = 3; // opcode is 0x0F, no needs to update ret.modrm = inst_bytes[op_idx + 1]; } else { ret.opcode_len = 2; ret.modrm = inst_bytes[op_idx + 1]; } } return ret; } lldb::InstructionControlFlowKind GetControlFlowKind(bool is_exec_mode_64b, Opcode m_opcode) { std::optional ret; if (m_opcode.GetOpcodeBytes() == nullptr || m_opcode.GetByteSize() <= 0) { // x86_64 and i386 instructions are categorized as Opcode::Type::eTypeBytes return lldb::eInstructionControlFlowKindUnknown; } // Opcode bytes will be decoded into primary_opcode, modrm and opcode length. // These are the three values deciding instruction control flow kind. ret = InstructionLengthDecode((const uint8_t *)m_opcode.GetOpcodeBytes(), m_opcode.GetByteSize(), is_exec_mode_64b); if (!ret) return lldb::eInstructionControlFlowKindUnknown; else return MapOpcodeIntoControlFlowKind(*ret); } } // namespace x86 class InstructionLLVMC : public lldb_private::Instruction { public: InstructionLLVMC(DisassemblerLLVMC &disasm, const lldb_private::Address &address, AddressClass addr_class) : Instruction(address, addr_class), m_disasm_wp(std::static_pointer_cast( disasm.shared_from_this())) {} ~InstructionLLVMC() override = default; bool DoesBranch() override { VisitInstruction(); return m_does_branch; } bool HasDelaySlot() override { VisitInstruction(); return m_has_delay_slot; } bool IsLoad() override { VisitInstruction(); return m_is_load; } bool IsAuthenticated() override { VisitInstruction(); return m_is_authenticated; } DisassemblerLLVMC::MCDisasmInstance *GetDisasmToUse(bool &is_alternate_isa) { DisassemblerScope disasm(*this); return GetDisasmToUse(is_alternate_isa, disasm); } size_t Decode(const lldb_private::Disassembler &disassembler, const lldb_private::DataExtractor &data, lldb::offset_t data_offset) override { // All we have to do is read the opcode which can be easy for some // architectures bool got_op = false; DisassemblerScope disasm(*this); if (disasm) { const ArchSpec &arch = disasm->GetArchitecture(); const lldb::ByteOrder byte_order = data.GetByteOrder(); const uint32_t min_op_byte_size = arch.GetMinimumOpcodeByteSize(); const uint32_t max_op_byte_size = arch.GetMaximumOpcodeByteSize(); if (min_op_byte_size == max_op_byte_size) { // Fixed size instructions, just read that amount of data. if (!data.ValidOffsetForDataOfSize(data_offset, min_op_byte_size)) return false; switch (min_op_byte_size) { case 1: m_opcode.SetOpcode8(data.GetU8(&data_offset), byte_order); got_op = true; break; case 2: m_opcode.SetOpcode16(data.GetU16(&data_offset), byte_order); got_op = true; break; case 4: m_opcode.SetOpcode32(data.GetU32(&data_offset), byte_order); got_op = true; break; case 8: m_opcode.SetOpcode64(data.GetU64(&data_offset), byte_order); got_op = true; break; default: m_opcode.SetOpcodeBytes(data.PeekData(data_offset, min_op_byte_size), min_op_byte_size); got_op = true; break; } } if (!got_op) { bool is_alternate_isa = false; DisassemblerLLVMC::MCDisasmInstance *mc_disasm_ptr = GetDisasmToUse(is_alternate_isa, disasm); const llvm::Triple::ArchType machine = arch.GetMachine(); if (machine == llvm::Triple::arm || machine == llvm::Triple::thumb) { if (machine == llvm::Triple::thumb || is_alternate_isa) { uint32_t thumb_opcode = data.GetU16(&data_offset); if ((thumb_opcode & 0xe000) != 0xe000 || ((thumb_opcode & 0x1800u) == 0)) { m_opcode.SetOpcode16(thumb_opcode, byte_order); m_is_valid = true; } else { thumb_opcode <<= 16; thumb_opcode |= data.GetU16(&data_offset); m_opcode.SetOpcode16_2(thumb_opcode, byte_order); m_is_valid = true; } } else { m_opcode.SetOpcode32(data.GetU32(&data_offset), byte_order); m_is_valid = true; } } else { // The opcode isn't evenly sized, so we need to actually use the llvm // disassembler to parse it and get the size. uint8_t *opcode_data = const_cast(data.PeekData(data_offset, 1)); const size_t opcode_data_len = data.BytesLeft(data_offset); const addr_t pc = m_address.GetFileAddress(); llvm::MCInst inst; const size_t inst_size = mc_disasm_ptr->GetMCInst(opcode_data, opcode_data_len, pc, inst); if (inst_size == 0) m_opcode.Clear(); else { m_opcode.SetOpcodeBytes(opcode_data, inst_size); m_is_valid = true; } } } return m_opcode.GetByteSize(); } return 0; } void AppendComment(std::string &description) { if (m_comment.empty()) m_comment.swap(description); else { m_comment.append(", "); m_comment.append(description); } } lldb::InstructionControlFlowKind GetControlFlowKind(const lldb_private::ExecutionContext *exe_ctx) override { DisassemblerScope disasm(*this, exe_ctx); if (disasm){ if (disasm->GetArchitecture().GetMachine() == llvm::Triple::x86) return x86::GetControlFlowKind(/*is_64b=*/false, m_opcode); else if (disasm->GetArchitecture().GetMachine() == llvm::Triple::x86_64) return x86::GetControlFlowKind(/*is_64b=*/true, m_opcode); } return eInstructionControlFlowKindUnknown; } void CalculateMnemonicOperandsAndComment( const lldb_private::ExecutionContext *exe_ctx) override { DataExtractor data; const AddressClass address_class = GetAddressClass(); if (m_opcode.GetData(data)) { std::string out_string; std::string markup_out_string; std::string comment_string; std::string markup_comment_string; DisassemblerScope disasm(*this, exe_ctx); if (disasm) { DisassemblerLLVMC::MCDisasmInstance *mc_disasm_ptr; if (address_class == AddressClass::eCodeAlternateISA) mc_disasm_ptr = disasm->m_alternate_disasm_up.get(); else mc_disasm_ptr = disasm->m_disasm_up.get(); lldb::addr_t pc = m_address.GetFileAddress(); m_using_file_addr = true; const bool data_from_file = disasm->m_data_from_file; bool use_hex_immediates = true; Disassembler::HexImmediateStyle hex_style = Disassembler::eHexStyleC; if (exe_ctx) { Target *target = exe_ctx->GetTargetPtr(); if (target) { use_hex_immediates = target->GetUseHexImmediates(); hex_style = target->GetHexImmediateStyle(); if (!data_from_file) { const lldb::addr_t load_addr = m_address.GetLoadAddress(target); if (load_addr != LLDB_INVALID_ADDRESS) { pc = load_addr; m_using_file_addr = false; } } } } const uint8_t *opcode_data = data.GetDataStart(); const size_t opcode_data_len = data.GetByteSize(); llvm::MCInst inst; size_t inst_size = mc_disasm_ptr->GetMCInst(opcode_data, opcode_data_len, pc, inst); if (inst_size > 0) { mc_disasm_ptr->SetStyle(use_hex_immediates, hex_style); const bool saved_use_color = mc_disasm_ptr->GetUseColor(); mc_disasm_ptr->SetUseColor(false); mc_disasm_ptr->PrintMCInst(inst, pc, out_string, comment_string); mc_disasm_ptr->SetUseColor(true); mc_disasm_ptr->PrintMCInst(inst, pc, markup_out_string, markup_comment_string); mc_disasm_ptr->SetUseColor(saved_use_color); if (!comment_string.empty()) { AppendComment(comment_string); } } if (inst_size == 0) { m_comment.assign("unknown opcode"); inst_size = m_opcode.GetByteSize(); StreamString mnemonic_strm; lldb::offset_t offset = 0; lldb::ByteOrder byte_order = data.GetByteOrder(); switch (inst_size) { case 1: { const uint8_t uval8 = data.GetU8(&offset); m_opcode.SetOpcode8(uval8, byte_order); m_opcode_name.assign(".byte"); mnemonic_strm.Printf("0x%2.2x", uval8); } break; case 2: { const uint16_t uval16 = data.GetU16(&offset); m_opcode.SetOpcode16(uval16, byte_order); m_opcode_name.assign(".short"); mnemonic_strm.Printf("0x%4.4x", uval16); } break; case 4: { const uint32_t uval32 = data.GetU32(&offset); m_opcode.SetOpcode32(uval32, byte_order); m_opcode_name.assign(".long"); mnemonic_strm.Printf("0x%8.8x", uval32); } break; case 8: { const uint64_t uval64 = data.GetU64(&offset); m_opcode.SetOpcode64(uval64, byte_order); m_opcode_name.assign(".quad"); mnemonic_strm.Printf("0x%16.16" PRIx64, uval64); } break; default: if (inst_size == 0) return; else { const uint8_t *bytes = data.PeekData(offset, inst_size); if (bytes == nullptr) return; m_opcode_name.assign(".byte"); m_opcode.SetOpcodeBytes(bytes, inst_size); mnemonic_strm.Printf("0x%2.2x", bytes[0]); for (uint32_t i = 1; i < inst_size; ++i) mnemonic_strm.Printf(" 0x%2.2x", bytes[i]); } break; } m_mnemonics = std::string(mnemonic_strm.GetString()); return; } static RegularExpression s_regex( llvm::StringRef("[ \t]*([^ ^\t]+)[ \t]*([^ ^\t].*)?")); llvm::SmallVector matches; if (s_regex.Execute(out_string, &matches)) { m_opcode_name = matches[1].str(); m_mnemonics = matches[2].str(); } matches.clear(); if (s_regex.Execute(markup_out_string, &matches)) { m_markup_opcode_name = matches[1].str(); m_markup_mnemonics = matches[2].str(); } } } } bool IsValid() const { return m_is_valid; } bool UsingFileAddress() const { return m_using_file_addr; } size_t GetByteSize() const { return m_opcode.GetByteSize(); } /// Grants exclusive access to the disassembler and initializes it with the /// given InstructionLLVMC and an optional ExecutionContext. class DisassemblerScope { std::shared_ptr m_disasm; public: explicit DisassemblerScope( InstructionLLVMC &i, const lldb_private::ExecutionContext *exe_ctx = nullptr) : m_disasm(i.m_disasm_wp.lock()) { m_disasm->m_mutex.lock(); m_disasm->m_inst = &i; m_disasm->m_exe_ctx = exe_ctx; } ~DisassemblerScope() { m_disasm->m_mutex.unlock(); } /// Evaluates to true if this scope contains a valid disassembler. operator bool() const { return static_cast(m_disasm); } std::shared_ptr operator->() { return m_disasm; } }; static llvm::StringRef::const_iterator ConsumeWhitespace(llvm::StringRef::const_iterator osi, llvm::StringRef::const_iterator ose) { while (osi != ose) { switch (*osi) { default: return osi; case ' ': case '\t': break; } ++osi; } return osi; } static std::pair ConsumeChar(llvm::StringRef::const_iterator osi, const char c, llvm::StringRef::const_iterator ose) { bool found = false; osi = ConsumeWhitespace(osi, ose); if (osi != ose && *osi == c) { found = true; ++osi; } return std::make_pair(found, osi); } static std::pair ParseRegisterName(llvm::StringRef::const_iterator osi, llvm::StringRef::const_iterator ose) { Operand ret; ret.m_type = Operand::Type::Register; std::string str; osi = ConsumeWhitespace(osi, ose); while (osi != ose) { if (*osi >= '0' && *osi <= '9') { if (str.empty()) { return std::make_pair(Operand(), osi); } else { str.push_back(*osi); } } else if (*osi >= 'a' && *osi <= 'z') { str.push_back(*osi); } else { switch (*osi) { default: if (str.empty()) { return std::make_pair(Operand(), osi); } else { ret.m_register = ConstString(str); return std::make_pair(ret, osi); } case '%': if (!str.empty()) { return std::make_pair(Operand(), osi); } break; } } ++osi; } ret.m_register = ConstString(str); return std::make_pair(ret, osi); } static std::pair ParseImmediate(llvm::StringRef::const_iterator osi, llvm::StringRef::const_iterator ose) { Operand ret; ret.m_type = Operand::Type::Immediate; std::string str; bool is_hex = false; osi = ConsumeWhitespace(osi, ose); while (osi != ose) { if (*osi >= '0' && *osi <= '9') { str.push_back(*osi); } else if (*osi >= 'a' && *osi <= 'f') { if (is_hex) { str.push_back(*osi); } else { return std::make_pair(Operand(), osi); } } else { switch (*osi) { default: if (str.empty()) { return std::make_pair(Operand(), osi); } else { ret.m_immediate = strtoull(str.c_str(), nullptr, 0); return std::make_pair(ret, osi); } case 'x': if (!str.compare("0")) { is_hex = true; str.push_back(*osi); } else { return std::make_pair(Operand(), osi); } break; case '#': case '$': if (!str.empty()) { return std::make_pair(Operand(), osi); } break; case '-': if (str.empty()) { ret.m_negative = true; } else { return std::make_pair(Operand(), osi); } } } ++osi; } ret.m_immediate = strtoull(str.c_str(), nullptr, 0); return std::make_pair(ret, osi); } // -0x5(%rax,%rax,2) static std::pair ParseIntelIndexedAccess(llvm::StringRef::const_iterator osi, llvm::StringRef::const_iterator ose) { std::pair offset_and_iterator = ParseImmediate(osi, ose); if (offset_and_iterator.first.IsValid()) { osi = offset_and_iterator.second; } bool found = false; std::tie(found, osi) = ConsumeChar(osi, '(', ose); if (!found) { return std::make_pair(Operand(), osi); } std::pair base_and_iterator = ParseRegisterName(osi, ose); if (base_and_iterator.first.IsValid()) { osi = base_and_iterator.second; } else { return std::make_pair(Operand(), osi); } std::tie(found, osi) = ConsumeChar(osi, ',', ose); if (!found) { return std::make_pair(Operand(), osi); } std::pair index_and_iterator = ParseRegisterName(osi, ose); if (index_and_iterator.first.IsValid()) { osi = index_and_iterator.second; } else { return std::make_pair(Operand(), osi); } std::tie(found, osi) = ConsumeChar(osi, ',', ose); if (!found) { return std::make_pair(Operand(), osi); } std::pair multiplier_and_iterator = ParseImmediate(osi, ose); if (index_and_iterator.first.IsValid()) { osi = index_and_iterator.second; } else { return std::make_pair(Operand(), osi); } std::tie(found, osi) = ConsumeChar(osi, ')', ose); if (!found) { return std::make_pair(Operand(), osi); } Operand product; product.m_type = Operand::Type::Product; product.m_children.push_back(index_and_iterator.first); product.m_children.push_back(multiplier_and_iterator.first); Operand index; index.m_type = Operand::Type::Sum; index.m_children.push_back(base_and_iterator.first); index.m_children.push_back(product); if (offset_and_iterator.first.IsValid()) { Operand offset; offset.m_type = Operand::Type::Sum; offset.m_children.push_back(offset_and_iterator.first); offset.m_children.push_back(index); Operand deref; deref.m_type = Operand::Type::Dereference; deref.m_children.push_back(offset); return std::make_pair(deref, osi); } else { Operand deref; deref.m_type = Operand::Type::Dereference; deref.m_children.push_back(index); return std::make_pair(deref, osi); } } // -0x10(%rbp) static std::pair ParseIntelDerefAccess(llvm::StringRef::const_iterator osi, llvm::StringRef::const_iterator ose) { std::pair offset_and_iterator = ParseImmediate(osi, ose); if (offset_and_iterator.first.IsValid()) { osi = offset_and_iterator.second; } bool found = false; std::tie(found, osi) = ConsumeChar(osi, '(', ose); if (!found) { return std::make_pair(Operand(), osi); } std::pair base_and_iterator = ParseRegisterName(osi, ose); if (base_and_iterator.first.IsValid()) { osi = base_and_iterator.second; } else { return std::make_pair(Operand(), osi); } std::tie(found, osi) = ConsumeChar(osi, ')', ose); if (!found) { return std::make_pair(Operand(), osi); } if (offset_and_iterator.first.IsValid()) { Operand offset; offset.m_type = Operand::Type::Sum; offset.m_children.push_back(offset_and_iterator.first); offset.m_children.push_back(base_and_iterator.first); Operand deref; deref.m_type = Operand::Type::Dereference; deref.m_children.push_back(offset); return std::make_pair(deref, osi); } else { Operand deref; deref.m_type = Operand::Type::Dereference; deref.m_children.push_back(base_and_iterator.first); return std::make_pair(deref, osi); } } // [sp, #8]! static std::pair ParseARMOffsetAccess(llvm::StringRef::const_iterator osi, llvm::StringRef::const_iterator ose) { bool found = false; std::tie(found, osi) = ConsumeChar(osi, '[', ose); if (!found) { return std::make_pair(Operand(), osi); } std::pair base_and_iterator = ParseRegisterName(osi, ose); if (base_and_iterator.first.IsValid()) { osi = base_and_iterator.second; } else { return std::make_pair(Operand(), osi); } std::tie(found, osi) = ConsumeChar(osi, ',', ose); if (!found) { return std::make_pair(Operand(), osi); } std::pair offset_and_iterator = ParseImmediate(osi, ose); if (offset_and_iterator.first.IsValid()) { osi = offset_and_iterator.second; } std::tie(found, osi) = ConsumeChar(osi, ']', ose); if (!found) { return std::make_pair(Operand(), osi); } Operand offset; offset.m_type = Operand::Type::Sum; offset.m_children.push_back(offset_and_iterator.first); offset.m_children.push_back(base_and_iterator.first); Operand deref; deref.m_type = Operand::Type::Dereference; deref.m_children.push_back(offset); return std::make_pair(deref, osi); } // [sp] static std::pair ParseARMDerefAccess(llvm::StringRef::const_iterator osi, llvm::StringRef::const_iterator ose) { bool found = false; std::tie(found, osi) = ConsumeChar(osi, '[', ose); if (!found) { return std::make_pair(Operand(), osi); } std::pair base_and_iterator = ParseRegisterName(osi, ose); if (base_and_iterator.first.IsValid()) { osi = base_and_iterator.second; } else { return std::make_pair(Operand(), osi); } std::tie(found, osi) = ConsumeChar(osi, ']', ose); if (!found) { return std::make_pair(Operand(), osi); } Operand deref; deref.m_type = Operand::Type::Dereference; deref.m_children.push_back(base_and_iterator.first); return std::make_pair(deref, osi); } static void DumpOperand(const Operand &op, Stream &s) { switch (op.m_type) { case Operand::Type::Dereference: s.PutCString("*"); DumpOperand(op.m_children[0], s); break; case Operand::Type::Immediate: if (op.m_negative) { s.PutCString("-"); } s.PutCString(llvm::to_string(op.m_immediate)); break; case Operand::Type::Invalid: s.PutCString("Invalid"); break; case Operand::Type::Product: s.PutCString("("); DumpOperand(op.m_children[0], s); s.PutCString("*"); DumpOperand(op.m_children[1], s); s.PutCString(")"); break; case Operand::Type::Register: s.PutCString(op.m_register.GetStringRef()); break; case Operand::Type::Sum: s.PutCString("("); DumpOperand(op.m_children[0], s); s.PutCString("+"); DumpOperand(op.m_children[1], s); s.PutCString(")"); break; } } bool ParseOperands( llvm::SmallVectorImpl &operands) override { const char *operands_string = GetOperands(nullptr); if (!operands_string) { return false; } llvm::StringRef operands_ref(operands_string); llvm::StringRef::const_iterator osi = operands_ref.begin(); llvm::StringRef::const_iterator ose = operands_ref.end(); while (osi != ose) { Operand operand; llvm::StringRef::const_iterator iter; if ((std::tie(operand, iter) = ParseIntelIndexedAccess(osi, ose), operand.IsValid()) || (std::tie(operand, iter) = ParseIntelDerefAccess(osi, ose), operand.IsValid()) || (std::tie(operand, iter) = ParseARMOffsetAccess(osi, ose), operand.IsValid()) || (std::tie(operand, iter) = ParseARMDerefAccess(osi, ose), operand.IsValid()) || (std::tie(operand, iter) = ParseRegisterName(osi, ose), operand.IsValid()) || (std::tie(operand, iter) = ParseImmediate(osi, ose), operand.IsValid())) { osi = iter; operands.push_back(operand); } else { return false; } std::pair found_and_iter = ConsumeChar(osi, ',', ose); if (found_and_iter.first) { osi = found_and_iter.second; } osi = ConsumeWhitespace(osi, ose); } DisassemblerSP disasm_sp = m_disasm_wp.lock(); if (disasm_sp && operands.size() > 1) { // TODO tie this into the MC Disassembler's notion of clobbers. switch (disasm_sp->GetArchitecture().GetMachine()) { default: break; case llvm::Triple::x86: case llvm::Triple::x86_64: operands[operands.size() - 1].m_clobbered = true; break; case llvm::Triple::arm: operands[0].m_clobbered = true; break; } } if (Log *log = GetLog(LLDBLog::Process)) { StreamString ss; ss.Printf("[%s] expands to %zu operands:\n", operands_string, operands.size()); for (const Operand &operand : operands) { ss.PutCString(" "); DumpOperand(operand, ss); ss.PutCString("\n"); } log->PutString(ss.GetString()); } return true; } bool IsCall() override { VisitInstruction(); return m_is_call; } protected: std::weak_ptr m_disasm_wp; bool m_is_valid = false; bool m_using_file_addr = false; bool m_has_visited_instruction = false; // Be conservative. If we didn't understand the instruction, say it: // - Might branch // - Does not have a delay slot // - Is not a call // - Is not a load // - Is not an authenticated instruction bool m_does_branch = true; bool m_has_delay_slot = false; bool m_is_call = false; bool m_is_load = false; bool m_is_authenticated = false; void VisitInstruction() { if (m_has_visited_instruction) return; DisassemblerScope disasm(*this); if (!disasm) return; DataExtractor data; if (!m_opcode.GetData(data)) return; bool is_alternate_isa; lldb::addr_t pc = m_address.GetFileAddress(); DisassemblerLLVMC::MCDisasmInstance *mc_disasm_ptr = GetDisasmToUse(is_alternate_isa, disasm); const uint8_t *opcode_data = data.GetDataStart(); const size_t opcode_data_len = data.GetByteSize(); llvm::MCInst inst; const size_t inst_size = mc_disasm_ptr->GetMCInst(opcode_data, opcode_data_len, pc, inst); if (inst_size == 0) return; m_has_visited_instruction = true; m_does_branch = mc_disasm_ptr->CanBranch(inst); m_has_delay_slot = mc_disasm_ptr->HasDelaySlot(inst); m_is_call = mc_disasm_ptr->IsCall(inst); m_is_load = mc_disasm_ptr->IsLoad(inst); m_is_authenticated = mc_disasm_ptr->IsAuthenticated(inst); } private: DisassemblerLLVMC::MCDisasmInstance * GetDisasmToUse(bool &is_alternate_isa, DisassemblerScope &disasm) { is_alternate_isa = false; if (disasm) { if (disasm->m_alternate_disasm_up) { const AddressClass address_class = GetAddressClass(); if (address_class == AddressClass::eCodeAlternateISA) { is_alternate_isa = true; return disasm->m_alternate_disasm_up.get(); } } return disasm->m_disasm_up.get(); } return nullptr; } }; std::unique_ptr DisassemblerLLVMC::MCDisasmInstance::Create(const char *triple, const char *cpu, const char *features_str, unsigned flavor, DisassemblerLLVMC &owner) { using Instance = std::unique_ptr; std::string Status; const llvm::Target *curr_target = llvm::TargetRegistry::lookupTarget(triple, Status); if (!curr_target) return Instance(); std::unique_ptr instr_info_up( curr_target->createMCInstrInfo()); if (!instr_info_up) return Instance(); std::unique_ptr reg_info_up( curr_target->createMCRegInfo(triple)); if (!reg_info_up) return Instance(); std::unique_ptr subtarget_info_up( curr_target->createMCSubtargetInfo(triple, cpu, features_str)); if (!subtarget_info_up) return Instance(); llvm::MCTargetOptions MCOptions; std::unique_ptr asm_info_up( curr_target->createMCAsmInfo(*reg_info_up, triple, MCOptions)); if (!asm_info_up) return Instance(); std::unique_ptr context_up( new llvm::MCContext(llvm::Triple(triple), asm_info_up.get(), reg_info_up.get(), subtarget_info_up.get())); if (!context_up) return Instance(); std::unique_ptr disasm_up( curr_target->createMCDisassembler(*subtarget_info_up, *context_up)); if (!disasm_up) return Instance(); std::unique_ptr rel_info_up( curr_target->createMCRelocationInfo(triple, *context_up)); if (!rel_info_up) return Instance(); std::unique_ptr symbolizer_up( curr_target->createMCSymbolizer( triple, nullptr, DisassemblerLLVMC::SymbolLookupCallback, &owner, context_up.get(), std::move(rel_info_up))); disasm_up->setSymbolizer(std::move(symbolizer_up)); unsigned asm_printer_variant = flavor == ~0U ? asm_info_up->getAssemblerDialect() : flavor; std::unique_ptr instr_printer_up( curr_target->createMCInstPrinter(llvm::Triple{triple}, asm_printer_variant, *asm_info_up, *instr_info_up, *reg_info_up)); if (!instr_printer_up) return Instance(); instr_printer_up->setPrintBranchImmAsAddress(true); // Not all targets may have registered createMCInstrAnalysis(). std::unique_ptr instr_analysis_up( curr_target->createMCInstrAnalysis(instr_info_up.get())); return Instance(new MCDisasmInstance( std::move(instr_info_up), std::move(reg_info_up), std::move(subtarget_info_up), std::move(asm_info_up), std::move(context_up), std::move(disasm_up), std::move(instr_printer_up), std::move(instr_analysis_up))); } DisassemblerLLVMC::MCDisasmInstance::MCDisasmInstance( std::unique_ptr &&instr_info_up, std::unique_ptr &®_info_up, std::unique_ptr &&subtarget_info_up, std::unique_ptr &&asm_info_up, std::unique_ptr &&context_up, std::unique_ptr &&disasm_up, std::unique_ptr &&instr_printer_up, std::unique_ptr &&instr_analysis_up) : m_instr_info_up(std::move(instr_info_up)), m_reg_info_up(std::move(reg_info_up)), m_subtarget_info_up(std::move(subtarget_info_up)), m_asm_info_up(std::move(asm_info_up)), m_context_up(std::move(context_up)), m_disasm_up(std::move(disasm_up)), m_instr_printer_up(std::move(instr_printer_up)), m_instr_analysis_up(std::move(instr_analysis_up)) { assert(m_instr_info_up && m_reg_info_up && m_subtarget_info_up && m_asm_info_up && m_context_up && m_disasm_up && m_instr_printer_up); } uint64_t DisassemblerLLVMC::MCDisasmInstance::GetMCInst( const uint8_t *opcode_data, size_t opcode_data_len, lldb::addr_t pc, llvm::MCInst &mc_inst) const { llvm::ArrayRef data(opcode_data, opcode_data_len); llvm::MCDisassembler::DecodeStatus status; uint64_t new_inst_size; status = m_disasm_up->getInstruction(mc_inst, new_inst_size, data, pc, llvm::nulls()); if (status == llvm::MCDisassembler::Success) return new_inst_size; else return 0; } void DisassemblerLLVMC::MCDisasmInstance::PrintMCInst( llvm::MCInst &mc_inst, lldb::addr_t pc, std::string &inst_string, std::string &comments_string) { llvm::raw_string_ostream inst_stream(inst_string); llvm::raw_string_ostream comments_stream(comments_string); inst_stream.enable_colors(m_instr_printer_up->getUseColor()); m_instr_printer_up->setCommentStream(comments_stream); m_instr_printer_up->printInst(&mc_inst, pc, llvm::StringRef(), *m_subtarget_info_up, inst_stream); m_instr_printer_up->setCommentStream(llvm::nulls()); comments_stream.flush(); static std::string g_newlines("\r\n"); for (size_t newline_pos = 0; (newline_pos = comments_string.find_first_of(g_newlines, newline_pos)) != comments_string.npos; /**/) { comments_string.replace(comments_string.begin() + newline_pos, comments_string.begin() + newline_pos + 1, 1, ' '); } } void DisassemblerLLVMC::MCDisasmInstance::SetStyle( bool use_hex_immed, HexImmediateStyle hex_style) { m_instr_printer_up->setPrintImmHex(use_hex_immed); switch (hex_style) { case eHexStyleC: m_instr_printer_up->setPrintHexStyle(llvm::HexStyle::C); break; case eHexStyleAsm: m_instr_printer_up->setPrintHexStyle(llvm::HexStyle::Asm); break; } } void DisassemblerLLVMC::MCDisasmInstance::SetUseColor(bool use_color) { m_instr_printer_up->setUseColor(use_color); } bool DisassemblerLLVMC::MCDisasmInstance::GetUseColor() const { return m_instr_printer_up->getUseColor(); } bool DisassemblerLLVMC::MCDisasmInstance::CanBranch( llvm::MCInst &mc_inst) const { if (m_instr_analysis_up) return m_instr_analysis_up->mayAffectControlFlow(mc_inst, *m_reg_info_up); return m_instr_info_up->get(mc_inst.getOpcode()) .mayAffectControlFlow(mc_inst, *m_reg_info_up); } bool DisassemblerLLVMC::MCDisasmInstance::HasDelaySlot( llvm::MCInst &mc_inst) const { return m_instr_info_up->get(mc_inst.getOpcode()).hasDelaySlot(); } bool DisassemblerLLVMC::MCDisasmInstance::IsCall(llvm::MCInst &mc_inst) const { if (m_instr_analysis_up) return m_instr_analysis_up->isCall(mc_inst); return m_instr_info_up->get(mc_inst.getOpcode()).isCall(); } bool DisassemblerLLVMC::MCDisasmInstance::IsLoad(llvm::MCInst &mc_inst) const { return m_instr_info_up->get(mc_inst.getOpcode()).mayLoad(); } bool DisassemblerLLVMC::MCDisasmInstance::IsAuthenticated( llvm::MCInst &mc_inst) const { const auto &InstrDesc = m_instr_info_up->get(mc_inst.getOpcode()); // Treat software auth traps (brk 0xc470 + aut key, where 0x70 == 'p', 0xc4 // == 'a' + 'c') as authenticated instructions for reporting purposes, in // addition to the standard authenticated instructions specified in ARMv8.3. bool IsBrkC47x = false; if (InstrDesc.isTrap() && mc_inst.getNumOperands() == 1) { const llvm::MCOperand &Op0 = mc_inst.getOperand(0); if (Op0.isImm() && Op0.getImm() >= 0xc470 && Op0.getImm() <= 0xc474) IsBrkC47x = true; } return InstrDesc.isAuthenticated() || IsBrkC47x; } DisassemblerLLVMC::DisassemblerLLVMC(const ArchSpec &arch, const char *flavor_string) : Disassembler(arch, flavor_string), m_exe_ctx(nullptr), m_inst(nullptr), m_data_from_file(false), m_adrp_address(LLDB_INVALID_ADDRESS), m_adrp_insn() { if (!FlavorValidForArchSpec(arch, m_flavor.c_str())) { m_flavor.assign("default"); } unsigned flavor = ~0U; llvm::Triple triple = arch.GetTriple(); // So far the only supported flavor is "intel" on x86. The base class will // set this correctly coming in. if (triple.getArch() == llvm::Triple::x86 || triple.getArch() == llvm::Triple::x86_64) { if (m_flavor == "intel") { flavor = 1; } else if (m_flavor == "att") { flavor = 0; } } ArchSpec thumb_arch(arch); if (triple.getArch() == llvm::Triple::arm) { std::string thumb_arch_name(thumb_arch.GetTriple().getArchName().str()); // Replace "arm" with "thumb" so we get all thumb variants correct if (thumb_arch_name.size() > 3) { thumb_arch_name.erase(0, 3); thumb_arch_name.insert(0, "thumb"); } else { thumb_arch_name = "thumbv9.3a"; } thumb_arch.GetTriple().setArchName(llvm::StringRef(thumb_arch_name)); } // If no sub architecture specified then use the most recent arm architecture // so the disassembler will return all instructions. Without it we will see a // lot of unknown opcodes if the code uses instructions which are not // available in the oldest arm version (which is used when no sub architecture // is specified). if (triple.getArch() == llvm::Triple::arm && triple.getSubArch() == llvm::Triple::NoSubArch) triple.setArchName("armv9.3a"); std::string features_str; const char *triple_str = triple.getTriple().c_str(); // ARM Cortex M0-M7 devices only execute thumb instructions if (arch.IsAlwaysThumbInstructions()) { triple_str = thumb_arch.GetTriple().getTriple().c_str(); features_str += "+fp-armv8,"; } const char *cpu = ""; switch (arch.GetCore()) { case ArchSpec::eCore_mips32: case ArchSpec::eCore_mips32el: cpu = "mips32"; break; case ArchSpec::eCore_mips32r2: case ArchSpec::eCore_mips32r2el: cpu = "mips32r2"; break; case ArchSpec::eCore_mips32r3: case ArchSpec::eCore_mips32r3el: cpu = "mips32r3"; break; case ArchSpec::eCore_mips32r5: case ArchSpec::eCore_mips32r5el: cpu = "mips32r5"; break; case ArchSpec::eCore_mips32r6: case ArchSpec::eCore_mips32r6el: cpu = "mips32r6"; break; case ArchSpec::eCore_mips64: case ArchSpec::eCore_mips64el: cpu = "mips64"; break; case ArchSpec::eCore_mips64r2: case ArchSpec::eCore_mips64r2el: cpu = "mips64r2"; break; case ArchSpec::eCore_mips64r3: case ArchSpec::eCore_mips64r3el: cpu = "mips64r3"; break; case ArchSpec::eCore_mips64r5: case ArchSpec::eCore_mips64r5el: cpu = "mips64r5"; break; case ArchSpec::eCore_mips64r6: case ArchSpec::eCore_mips64r6el: cpu = "mips64r6"; break; default: cpu = ""; break; } if (arch.IsMIPS()) { uint32_t arch_flags = arch.GetFlags(); if (arch_flags & ArchSpec::eMIPSAse_msa) features_str += "+msa,"; if (arch_flags & ArchSpec::eMIPSAse_dsp) features_str += "+dsp,"; if (arch_flags & ArchSpec::eMIPSAse_dspr2) features_str += "+dspr2,"; } // If any AArch64 variant, enable latest ISA with all extensions. if (triple.isAArch64()) { features_str += "+all,"; if (triple.getVendor() == llvm::Triple::Apple) cpu = "apple-latest"; } if (triple.isRISCV()) { uint32_t arch_flags = arch.GetFlags(); if (arch_flags & ArchSpec::eRISCV_rvc) features_str += "+c,"; if (arch_flags & ArchSpec::eRISCV_rve) features_str += "+e,"; if ((arch_flags & ArchSpec::eRISCV_float_abi_single) == ArchSpec::eRISCV_float_abi_single) features_str += "+f,"; if ((arch_flags & ArchSpec::eRISCV_float_abi_double) == ArchSpec::eRISCV_float_abi_double) features_str += "+f,+d,"; if ((arch_flags & ArchSpec::eRISCV_float_abi_quad) == ArchSpec::eRISCV_float_abi_quad) features_str += "+f,+d,+q,"; // FIXME: how do we detect features such as `+a`, `+m`? // Turn them on by default now, since everyone seems to use them features_str += "+a,+m,"; } // We use m_disasm_up.get() to tell whether we are valid or not, so if this // isn't good for some reason, we won't be valid and FindPlugin will fail and // we won't get used. m_disasm_up = MCDisasmInstance::Create(triple_str, cpu, features_str.c_str(), flavor, *this); llvm::Triple::ArchType llvm_arch = triple.getArch(); // For arm CPUs that can execute arm or thumb instructions, also create a // thumb instruction disassembler. if (llvm_arch == llvm::Triple::arm) { std::string thumb_triple(thumb_arch.GetTriple().getTriple()); m_alternate_disasm_up = MCDisasmInstance::Create(thumb_triple.c_str(), "", features_str.c_str(), flavor, *this); if (!m_alternate_disasm_up) m_disasm_up.reset(); } else if (arch.IsMIPS()) { /* Create alternate disassembler for MIPS16 and microMIPS */ uint32_t arch_flags = arch.GetFlags(); if (arch_flags & ArchSpec::eMIPSAse_mips16) features_str += "+mips16,"; else if (arch_flags & ArchSpec::eMIPSAse_micromips) features_str += "+micromips,"; m_alternate_disasm_up = MCDisasmInstance::Create( triple_str, cpu, features_str.c_str(), flavor, *this); if (!m_alternate_disasm_up) m_disasm_up.reset(); } } DisassemblerLLVMC::~DisassemblerLLVMC() = default; lldb::DisassemblerSP DisassemblerLLVMC::CreateInstance(const ArchSpec &arch, const char *flavor) { if (arch.GetTriple().getArch() != llvm::Triple::UnknownArch) { auto disasm_sp = std::make_shared(arch, flavor); if (disasm_sp && disasm_sp->IsValid()) return disasm_sp; } return lldb::DisassemblerSP(); } size_t DisassemblerLLVMC::DecodeInstructions(const Address &base_addr, const DataExtractor &data, lldb::offset_t data_offset, size_t num_instructions, bool append, bool data_from_file) { if (!append) m_instruction_list.Clear(); if (!IsValid()) return 0; m_data_from_file = data_from_file; uint32_t data_cursor = data_offset; const size_t data_byte_size = data.GetByteSize(); uint32_t instructions_parsed = 0; Address inst_addr(base_addr); while (data_cursor < data_byte_size && instructions_parsed < num_instructions) { AddressClass address_class = AddressClass::eCode; if (m_alternate_disasm_up) address_class = inst_addr.GetAddressClass(); InstructionSP inst_sp( new InstructionLLVMC(*this, inst_addr, address_class)); if (!inst_sp) break; uint32_t inst_size = inst_sp->Decode(*this, data, data_cursor); if (inst_size == 0) break; m_instruction_list.Append(inst_sp); data_cursor += inst_size; inst_addr.Slide(inst_size); instructions_parsed++; } return data_cursor - data_offset; } void DisassemblerLLVMC::Initialize() { PluginManager::RegisterPlugin(GetPluginNameStatic(), "Disassembler that uses LLVM MC to disassemble " "i386, x86_64, ARM, and ARM64.", CreateInstance); llvm::InitializeAllTargetInfos(); llvm::InitializeAllTargetMCs(); llvm::InitializeAllAsmParsers(); llvm::InitializeAllDisassemblers(); } void DisassemblerLLVMC::Terminate() { PluginManager::UnregisterPlugin(CreateInstance); } int DisassemblerLLVMC::OpInfoCallback(void *disassembler, uint64_t pc, uint64_t offset, uint64_t size, int tag_type, void *tag_bug) { return static_cast(disassembler) ->OpInfo(pc, offset, size, tag_type, tag_bug); } const char *DisassemblerLLVMC::SymbolLookupCallback(void *disassembler, uint64_t value, uint64_t *type, uint64_t pc, const char **name) { return static_cast(disassembler) ->SymbolLookup(value, type, pc, name); } bool DisassemblerLLVMC::FlavorValidForArchSpec( const lldb_private::ArchSpec &arch, const char *flavor) { llvm::Triple triple = arch.GetTriple(); if (flavor == nullptr || strcmp(flavor, "default") == 0) return true; if (triple.getArch() == llvm::Triple::x86 || triple.getArch() == llvm::Triple::x86_64) { return strcmp(flavor, "intel") == 0 || strcmp(flavor, "att") == 0; } else return false; } bool DisassemblerLLVMC::IsValid() const { return m_disasm_up.operator bool(); } int DisassemblerLLVMC::OpInfo(uint64_t PC, uint64_t Offset, uint64_t Size, int tag_type, void *tag_bug) { switch (tag_type) { default: break; case 1: memset(tag_bug, 0, sizeof(::LLVMOpInfo1)); break; } return 0; } const char *DisassemblerLLVMC::SymbolLookup(uint64_t value, uint64_t *type_ptr, uint64_t pc, const char **name) { if (*type_ptr) { if (m_exe_ctx && m_inst) { // std::string remove_this_prior_to_checkin; Target *target = m_exe_ctx ? m_exe_ctx->GetTargetPtr() : nullptr; Address value_so_addr; Address pc_so_addr; if (target->GetArchitecture().GetMachine() == llvm::Triple::aarch64 || target->GetArchitecture().GetMachine() == llvm::Triple::aarch64_be || target->GetArchitecture().GetMachine() == llvm::Triple::aarch64_32) { if (*type_ptr == LLVMDisassembler_ReferenceType_In_ARM64_ADRP) { m_adrp_address = pc; m_adrp_insn = value; *name = nullptr; *type_ptr = LLVMDisassembler_ReferenceType_InOut_None; return nullptr; } // If this instruction is an ADD and // the previous instruction was an ADRP and // the ADRP's register and this ADD's register are the same, // then this is a pc-relative address calculation. if (*type_ptr == LLVMDisassembler_ReferenceType_In_ARM64_ADDXri && m_adrp_insn && m_adrp_address == pc - 4 && (*m_adrp_insn & 0x1f) == ((value >> 5) & 0x1f)) { uint32_t addxri_inst; uint64_t adrp_imm, addxri_imm; // Get immlo and immhi bits, OR them together to get the ADRP imm // value. adrp_imm = ((*m_adrp_insn & 0x00ffffe0) >> 3) | ((*m_adrp_insn >> 29) & 0x3); // if high bit of immhi after right-shifting set, sign extend if (adrp_imm & (1ULL << 20)) adrp_imm |= ~((1ULL << 21) - 1); addxri_inst = value; addxri_imm = (addxri_inst >> 10) & 0xfff; // check if 'sh' bit is set, shift imm value up if so // (this would make no sense, ADRP already gave us this part) if ((addxri_inst >> (12 + 5 + 5)) & 1) addxri_imm <<= 12; value = (m_adrp_address & 0xfffffffffffff000LL) + (adrp_imm << 12) + addxri_imm; } m_adrp_address = LLDB_INVALID_ADDRESS; m_adrp_insn.reset(); } if (m_inst->UsingFileAddress()) { ModuleSP module_sp(m_inst->GetAddress().GetModule()); if (module_sp) { module_sp->ResolveFileAddress(value, value_so_addr); module_sp->ResolveFileAddress(pc, pc_so_addr); } } else if (target && !target->GetSectionLoadList().IsEmpty()) { target->GetSectionLoadList().ResolveLoadAddress(value, value_so_addr); target->GetSectionLoadList().ResolveLoadAddress(pc, pc_so_addr); } SymbolContext sym_ctx; const SymbolContextItem resolve_scope = eSymbolContextFunction | eSymbolContextSymbol; if (pc_so_addr.IsValid() && pc_so_addr.GetModule()) { pc_so_addr.GetModule()->ResolveSymbolContextForAddress( pc_so_addr, resolve_scope, sym_ctx); } if (value_so_addr.IsValid() && value_so_addr.GetSection()) { StreamString ss; bool format_omitting_current_func_name = false; if (sym_ctx.symbol || sym_ctx.function) { AddressRange range; if (sym_ctx.GetAddressRange(resolve_scope, 0, false, range) && range.GetBaseAddress().IsValid() && range.ContainsLoadAddress(value_so_addr, target)) { format_omitting_current_func_name = true; } } // If the "value" address (the target address we're symbolicating) is // inside the same SymbolContext as the current instruction pc // (pc_so_addr), don't print the full function name - just print it // with DumpStyleNoFunctionName style, e.g. "<+36>". if (format_omitting_current_func_name) { value_so_addr.Dump(&ss, target, Address::DumpStyleNoFunctionName, Address::DumpStyleSectionNameOffset); } else { value_so_addr.Dump( &ss, target, Address::DumpStyleResolvedDescriptionNoFunctionArguments, Address::DumpStyleSectionNameOffset); } if (!ss.GetString().empty()) { // If Address::Dump returned a multi-line description, most commonly // seen when we have multiple levels of inlined functions at an // address, only show the first line. std::string str = std::string(ss.GetString()); size_t first_eol_char = str.find_first_of("\r\n"); if (first_eol_char != std::string::npos) { str.erase(first_eol_char); } m_inst->AppendComment(str); } } } } // TODO: llvm-objdump sets the type_ptr to the // LLVMDisassembler_ReferenceType_Out_* values // based on where value_so_addr is pointing, with // Mach-O specific augmentations in MachODump.cpp. e.g. // see what AArch64ExternalSymbolizer::tryAddingSymbolicOperand // handles. *type_ptr = LLVMDisassembler_ReferenceType_InOut_None; *name = nullptr; return nullptr; }