//===-- ABIMacOSX_arm64.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 "ABIMacOSX_arm64.h" #include #include #include "llvm/ADT/STLExtras.h" #include "llvm/TargetParser/Triple.h" #include "lldb/Core/Module.h" #include "lldb/Core/PluginManager.h" #include "lldb/Core/Value.h" #include "lldb/Core/ValueObjectConstResult.h" #include "lldb/Symbol/UnwindPlan.h" #include "lldb/Target/Process.h" #include "lldb/Target/RegisterContext.h" #include "lldb/Target/Target.h" #include "lldb/Target/Thread.h" #include "lldb/Utility/ConstString.h" #include "lldb/Utility/LLDBLog.h" #include "lldb/Utility/Log.h" #include "lldb/Utility/RegisterValue.h" #include "lldb/Utility/Scalar.h" #include "lldb/Utility/Status.h" #include "Utility/ARM64_DWARF_Registers.h" using namespace lldb; using namespace lldb_private; static const char *pluginDesc = "Mac OS X ABI for arm64 targets"; size_t ABIMacOSX_arm64::GetRedZoneSize() const { return 128; } // Static Functions ABISP ABIMacOSX_arm64::CreateInstance(ProcessSP process_sp, const ArchSpec &arch) { const llvm::Triple::ArchType arch_type = arch.GetTriple().getArch(); const llvm::Triple::VendorType vendor_type = arch.GetTriple().getVendor(); if (vendor_type == llvm::Triple::Apple) { if (arch_type == llvm::Triple::aarch64 || arch_type == llvm::Triple::aarch64_32) { return ABISP( new ABIMacOSX_arm64(std::move(process_sp), MakeMCRegisterInfo(arch))); } } return ABISP(); } bool ABIMacOSX_arm64::PrepareTrivialCall( Thread &thread, lldb::addr_t sp, lldb::addr_t func_addr, lldb::addr_t return_addr, llvm::ArrayRef args) const { RegisterContext *reg_ctx = thread.GetRegisterContext().get(); if (!reg_ctx) return false; Log *log = GetLog(LLDBLog::Expressions); if (log) { StreamString s; s.Printf("ABIMacOSX_arm64::PrepareTrivialCall (tid = 0x%" PRIx64 ", sp = 0x%" PRIx64 ", func_addr = 0x%" PRIx64 ", return_addr = 0x%" PRIx64, thread.GetID(), (uint64_t)sp, (uint64_t)func_addr, (uint64_t)return_addr); for (size_t i = 0; i < args.size(); ++i) s.Printf(", arg%d = 0x%" PRIx64, static_cast(i + 1), args[i]); s.PutCString(")"); log->PutString(s.GetString()); } const uint32_t pc_reg_num = reg_ctx->ConvertRegisterKindToRegisterNumber( eRegisterKindGeneric, LLDB_REGNUM_GENERIC_PC); const uint32_t sp_reg_num = reg_ctx->ConvertRegisterKindToRegisterNumber( eRegisterKindGeneric, LLDB_REGNUM_GENERIC_SP); const uint32_t ra_reg_num = reg_ctx->ConvertRegisterKindToRegisterNumber( eRegisterKindGeneric, LLDB_REGNUM_GENERIC_RA); // x0 - x7 contain first 8 simple args if (args.size() > 8) // TODO handle more than 8 arguments return false; for (size_t i = 0; i < args.size(); ++i) { const RegisterInfo *reg_info = reg_ctx->GetRegisterInfo( eRegisterKindGeneric, LLDB_REGNUM_GENERIC_ARG1 + i); LLDB_LOGF(log, "About to write arg%d (0x%" PRIx64 ") into %s", static_cast(i + 1), args[i], reg_info->name); if (!reg_ctx->WriteRegisterFromUnsigned(reg_info, args[i])) return false; } // Set "lr" to the return address if (!reg_ctx->WriteRegisterFromUnsigned( reg_ctx->GetRegisterInfoAtIndex(ra_reg_num), return_addr)) return false; // Set "sp" to the requested value if (!reg_ctx->WriteRegisterFromUnsigned( reg_ctx->GetRegisterInfoAtIndex(sp_reg_num), sp)) return false; // Set "pc" to the address requested if (!reg_ctx->WriteRegisterFromUnsigned( reg_ctx->GetRegisterInfoAtIndex(pc_reg_num), func_addr)) return false; return true; } bool ABIMacOSX_arm64::GetArgumentValues(Thread &thread, ValueList &values) const { uint32_t num_values = values.GetSize(); ExecutionContext exe_ctx(thread.shared_from_this()); // Extract the register context so we can read arguments from registers RegisterContext *reg_ctx = thread.GetRegisterContext().get(); if (!reg_ctx) return false; addr_t sp = 0; for (uint32_t value_idx = 0; value_idx < num_values; ++value_idx) { // We currently only support extracting values with Clang QualTypes. Do we // care about others? Value *value = values.GetValueAtIndex(value_idx); if (!value) return false; CompilerType value_type = value->GetCompilerType(); std::optional bit_size = value_type.GetBitSize(&thread); if (!bit_size) return false; bool is_signed = false; size_t bit_width = 0; if (value_type.IsIntegerOrEnumerationType(is_signed)) { bit_width = *bit_size; } else if (value_type.IsPointerOrReferenceType()) { bit_width = *bit_size; } else { // We only handle integer, pointer and reference types currently... return false; } if (bit_width <= (exe_ctx.GetProcessRef().GetAddressByteSize() * 8)) { if (value_idx < 8) { // Arguments 1-6 are in x0-x5... const RegisterInfo *reg_info = nullptr; // Search by generic ID first, then fall back to by name uint32_t arg_reg_num = reg_ctx->ConvertRegisterKindToRegisterNumber( eRegisterKindGeneric, LLDB_REGNUM_GENERIC_ARG1 + value_idx); if (arg_reg_num != LLDB_INVALID_REGNUM) { reg_info = reg_ctx->GetRegisterInfoAtIndex(arg_reg_num); } else { switch (value_idx) { case 0: reg_info = reg_ctx->GetRegisterInfoByName("x0"); break; case 1: reg_info = reg_ctx->GetRegisterInfoByName("x1"); break; case 2: reg_info = reg_ctx->GetRegisterInfoByName("x2"); break; case 3: reg_info = reg_ctx->GetRegisterInfoByName("x3"); break; case 4: reg_info = reg_ctx->GetRegisterInfoByName("x4"); break; case 5: reg_info = reg_ctx->GetRegisterInfoByName("x5"); break; case 6: reg_info = reg_ctx->GetRegisterInfoByName("x6"); break; case 7: reg_info = reg_ctx->GetRegisterInfoByName("x7"); break; } } if (reg_info) { RegisterValue reg_value; if (reg_ctx->ReadRegister(reg_info, reg_value)) { if (is_signed) reg_value.SignExtend(bit_width); if (!reg_value.GetScalarValue(value->GetScalar())) return false; continue; } } return false; } else { if (sp == 0) { // Read the stack pointer if we already haven't read it sp = reg_ctx->GetSP(0); if (sp == 0) return false; } // Arguments 5 on up are on the stack const uint32_t arg_byte_size = (bit_width + (8 - 1)) / 8; Status error; if (!exe_ctx.GetProcessRef().ReadScalarIntegerFromMemory( sp, arg_byte_size, is_signed, value->GetScalar(), error)) return false; sp += arg_byte_size; // Align up to the next 8 byte boundary if needed if (sp % 8) { sp >>= 3; sp += 1; sp <<= 3; } } } } return true; } Status ABIMacOSX_arm64::SetReturnValueObject(lldb::StackFrameSP &frame_sp, lldb::ValueObjectSP &new_value_sp) { Status error; if (!new_value_sp) { error.SetErrorString("Empty value object for return value."); return error; } CompilerType return_value_type = new_value_sp->GetCompilerType(); if (!return_value_type) { error.SetErrorString("Null clang type for return value."); return error; } Thread *thread = frame_sp->GetThread().get(); RegisterContext *reg_ctx = thread->GetRegisterContext().get(); if (reg_ctx) { DataExtractor data; Status data_error; const uint64_t byte_size = new_value_sp->GetData(data, data_error); if (data_error.Fail()) { error.SetErrorStringWithFormat( "Couldn't convert return value to raw data: %s", data_error.AsCString()); return error; } const uint32_t type_flags = return_value_type.GetTypeInfo(nullptr); if (type_flags & eTypeIsScalar || type_flags & eTypeIsPointer) { if (type_flags & eTypeIsInteger || type_flags & eTypeIsPointer) { // Extract the register context so we can read arguments from registers lldb::offset_t offset = 0; if (byte_size <= 16) { const RegisterInfo *x0_info = reg_ctx->GetRegisterInfoByName("x0", 0); if (byte_size <= 8) { uint64_t raw_value = data.GetMaxU64(&offset, byte_size); if (!reg_ctx->WriteRegisterFromUnsigned(x0_info, raw_value)) error.SetErrorString("failed to write register x0"); } else { uint64_t raw_value = data.GetMaxU64(&offset, 8); if (reg_ctx->WriteRegisterFromUnsigned(x0_info, raw_value)) { const RegisterInfo *x1_info = reg_ctx->GetRegisterInfoByName("x1", 0); raw_value = data.GetMaxU64(&offset, byte_size - offset); if (!reg_ctx->WriteRegisterFromUnsigned(x1_info, raw_value)) error.SetErrorString("failed to write register x1"); } } } else { error.SetErrorString("We don't support returning longer than 128 bit " "integer values at present."); } } else if (type_flags & eTypeIsFloat) { if (type_flags & eTypeIsComplex) { // Don't handle complex yet. error.SetErrorString( "returning complex float values are not supported"); } else { const RegisterInfo *v0_info = reg_ctx->GetRegisterInfoByName("v0", 0); if (v0_info) { if (byte_size <= 16) { RegisterValue reg_value; error = reg_value.SetValueFromData(*v0_info, data, 0, true); if (error.Success()) if (!reg_ctx->WriteRegister(v0_info, reg_value)) error.SetErrorString("failed to write register v0"); } else { error.SetErrorString("returning float values longer than 128 " "bits are not supported"); } } else error.SetErrorString("v0 register is not available on this target"); } } } else if (type_flags & eTypeIsVector) { if (byte_size > 0) { const RegisterInfo *v0_info = reg_ctx->GetRegisterInfoByName("v0", 0); if (v0_info) { if (byte_size <= v0_info->byte_size) { RegisterValue reg_value; error = reg_value.SetValueFromData(*v0_info, data, 0, true); if (error.Success()) { if (!reg_ctx->WriteRegister(v0_info, reg_value)) error.SetErrorString("failed to write register v0"); } } } } } } else { error.SetErrorString("no registers are available"); } return error; } bool ABIMacOSX_arm64::CreateFunctionEntryUnwindPlan(UnwindPlan &unwind_plan) { unwind_plan.Clear(); unwind_plan.SetRegisterKind(eRegisterKindDWARF); uint32_t lr_reg_num = arm64_dwarf::lr; uint32_t sp_reg_num = arm64_dwarf::sp; uint32_t pc_reg_num = arm64_dwarf::pc; UnwindPlan::RowSP row(new UnwindPlan::Row); // Our previous Call Frame Address is the stack pointer row->GetCFAValue().SetIsRegisterPlusOffset(sp_reg_num, 0); // Our previous PC is in the LR row->SetRegisterLocationToRegister(pc_reg_num, lr_reg_num, true); unwind_plan.AppendRow(row); // All other registers are the same. unwind_plan.SetSourceName("arm64 at-func-entry default"); unwind_plan.SetSourcedFromCompiler(eLazyBoolNo); return true; } bool ABIMacOSX_arm64::CreateDefaultUnwindPlan(UnwindPlan &unwind_plan) { unwind_plan.Clear(); unwind_plan.SetRegisterKind(eRegisterKindDWARF); uint32_t fp_reg_num = arm64_dwarf::fp; uint32_t pc_reg_num = arm64_dwarf::pc; UnwindPlan::RowSP row(new UnwindPlan::Row); const int32_t ptr_size = 8; row->GetCFAValue().SetIsRegisterPlusOffset(fp_reg_num, 2 * ptr_size); row->SetOffset(0); row->SetUnspecifiedRegistersAreUndefined(true); row->SetRegisterLocationToAtCFAPlusOffset(fp_reg_num, ptr_size * -2, true); row->SetRegisterLocationToAtCFAPlusOffset(pc_reg_num, ptr_size * -1, true); unwind_plan.AppendRow(row); unwind_plan.SetSourceName("arm64-apple-darwin default unwind plan"); unwind_plan.SetSourcedFromCompiler(eLazyBoolNo); unwind_plan.SetUnwindPlanValidAtAllInstructions(eLazyBoolNo); unwind_plan.SetUnwindPlanForSignalTrap(eLazyBoolNo); return true; } // AAPCS64 (Procedure Call Standard for the ARM 64-bit Architecture) says // registers x19 through x28 and sp are callee preserved. v8-v15 are non- // volatile (and specifically only the lower 8 bytes of these regs), the rest // of the fp/SIMD registers are volatile. // // v. https://github.com/ARM-software/abi-aa/blob/main/aapcs64/ // We treat x29 as callee preserved also, else the unwinder won't try to // retrieve fp saves. bool ABIMacOSX_arm64::RegisterIsVolatile(const RegisterInfo *reg_info) { if (reg_info) { const char *name = reg_info->name; // Sometimes we'll be called with the "alternate" name for these registers; // recognize them as non-volatile. if (name[0] == 'p' && name[1] == 'c') // pc return false; if (name[0] == 'f' && name[1] == 'p') // fp return false; if (name[0] == 's' && name[1] == 'p') // sp return false; if (name[0] == 'l' && name[1] == 'r') // lr return false; if (name[0] == 'x') { // Volatile registers: x0-x18, x30 (lr) // Return false for the non-volatile gpr regs, true for everything else switch (name[1]) { case '1': switch (name[2]) { case '9': return false; // x19 is non-volatile default: return true; } break; case '2': switch (name[2]) { case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': return false; // x20 - 28 are non-volatile case '9': return false; // x29 aka fp treat as non-volatile on Darwin default: return true; } case '3': // x30 aka lr treat as non-volatile if (name[2] == '0') return false; break; default: return true; } } else if (name[0] == 'v' || name[0] == 's' || name[0] == 'd') { // Volatile registers: v0-7, v16-v31 // Return false for non-volatile fp/SIMD regs, true for everything else switch (name[1]) { case '8': case '9': return false; // v8-v9 are non-volatile case '1': switch (name[2]) { case '0': case '1': case '2': case '3': case '4': case '5': return false; // v10-v15 are non-volatile default: return true; } default: return true; } } } return true; } static bool LoadValueFromConsecutiveGPRRegisters( ExecutionContext &exe_ctx, RegisterContext *reg_ctx, const CompilerType &value_type, bool is_return_value, // false => parameter, true => return value uint32_t &NGRN, // NGRN (see ABI documentation) uint32_t &NSRN, // NSRN (see ABI documentation) DataExtractor &data) { std::optional byte_size = value_type.GetByteSize(exe_ctx.GetBestExecutionContextScope()); if (!byte_size || *byte_size == 0) return false; std::unique_ptr heap_data_up( new DataBufferHeap(*byte_size, 0)); const ByteOrder byte_order = exe_ctx.GetProcessRef().GetByteOrder(); Status error; CompilerType base_type; const uint32_t homogeneous_count = value_type.IsHomogeneousAggregate(&base_type); if (homogeneous_count > 0 && homogeneous_count <= 8) { // Make sure we have enough registers if (NSRN < 8 && (8 - NSRN) >= homogeneous_count) { if (!base_type) return false; std::optional base_byte_size = base_type.GetByteSize(exe_ctx.GetBestExecutionContextScope()); if (!base_byte_size) return false; uint32_t data_offset = 0; for (uint32_t i = 0; i < homogeneous_count; ++i) { char v_name[8]; ::snprintf(v_name, sizeof(v_name), "v%u", NSRN); const RegisterInfo *reg_info = reg_ctx->GetRegisterInfoByName(v_name, 0); if (reg_info == nullptr) return false; if (*base_byte_size > reg_info->byte_size) return false; RegisterValue reg_value; if (!reg_ctx->ReadRegister(reg_info, reg_value)) return false; // Make sure we have enough room in "heap_data_up" if ((data_offset + *base_byte_size) <= heap_data_up->GetByteSize()) { const size_t bytes_copied = reg_value.GetAsMemoryData( *reg_info, heap_data_up->GetBytes() + data_offset, *base_byte_size, byte_order, error); if (bytes_copied != *base_byte_size) return false; data_offset += bytes_copied; ++NSRN; } else return false; } data.SetByteOrder(byte_order); data.SetAddressByteSize(exe_ctx.GetProcessRef().GetAddressByteSize()); data.SetData(DataBufferSP(heap_data_up.release())); return true; } } const size_t max_reg_byte_size = 16; if (*byte_size <= max_reg_byte_size) { size_t bytes_left = *byte_size; uint32_t data_offset = 0; while (data_offset < *byte_size) { if (NGRN >= 8) return false; uint32_t reg_num = reg_ctx->ConvertRegisterKindToRegisterNumber( eRegisterKindGeneric, LLDB_REGNUM_GENERIC_ARG1 + NGRN); if (reg_num == LLDB_INVALID_REGNUM) return false; const RegisterInfo *reg_info = reg_ctx->GetRegisterInfoAtIndex(reg_num); if (reg_info == nullptr) return false; RegisterValue reg_value; if (!reg_ctx->ReadRegister(reg_info, reg_value)) return false; const size_t curr_byte_size = std::min(8, bytes_left); const size_t bytes_copied = reg_value.GetAsMemoryData( *reg_info, heap_data_up->GetBytes() + data_offset, curr_byte_size, byte_order, error); if (bytes_copied == 0) return false; if (bytes_copied >= bytes_left) break; data_offset += bytes_copied; bytes_left -= bytes_copied; ++NGRN; } } else { const RegisterInfo *reg_info = nullptr; if (is_return_value) { // The Darwin arm64 ABI doesn't write the return location back to x8 // before returning from the function the way the x86_64 ABI does. So // we can't reconstruct stack based returns on exit from the function: return false; } else { // We are assuming we are stopped at the first instruction in a function // and that the ABI is being respected so all parameters appear where // they should be (functions with no external linkage can legally violate // the ABI). if (NGRN >= 8) return false; uint32_t reg_num = reg_ctx->ConvertRegisterKindToRegisterNumber( eRegisterKindGeneric, LLDB_REGNUM_GENERIC_ARG1 + NGRN); if (reg_num == LLDB_INVALID_REGNUM) return false; reg_info = reg_ctx->GetRegisterInfoAtIndex(reg_num); if (reg_info == nullptr) return false; ++NGRN; } const lldb::addr_t value_addr = reg_ctx->ReadRegisterAsUnsigned(reg_info, LLDB_INVALID_ADDRESS); if (value_addr == LLDB_INVALID_ADDRESS) return false; if (exe_ctx.GetProcessRef().ReadMemory( value_addr, heap_data_up->GetBytes(), heap_data_up->GetByteSize(), error) != heap_data_up->GetByteSize()) { return false; } } data.SetByteOrder(byte_order); data.SetAddressByteSize(exe_ctx.GetProcessRef().GetAddressByteSize()); data.SetData(DataBufferSP(heap_data_up.release())); return true; } ValueObjectSP ABIMacOSX_arm64::GetReturnValueObjectImpl( Thread &thread, CompilerType &return_compiler_type) const { ValueObjectSP return_valobj_sp; Value value; ExecutionContext exe_ctx(thread.shared_from_this()); if (exe_ctx.GetTargetPtr() == nullptr || exe_ctx.GetProcessPtr() == nullptr) return return_valobj_sp; // value.SetContext (Value::eContextTypeClangType, return_compiler_type); value.SetCompilerType(return_compiler_type); RegisterContext *reg_ctx = thread.GetRegisterContext().get(); if (!reg_ctx) return return_valobj_sp; std::optional byte_size = return_compiler_type.GetByteSize(&thread); if (!byte_size) return return_valobj_sp; const uint32_t type_flags = return_compiler_type.GetTypeInfo(nullptr); if (type_flags & eTypeIsScalar || type_flags & eTypeIsPointer) { value.SetValueType(Value::ValueType::Scalar); bool success = false; if (type_flags & eTypeIsInteger || type_flags & eTypeIsPointer) { // Extract the register context so we can read arguments from registers if (*byte_size <= 8) { const RegisterInfo *x0_reg_info = reg_ctx->GetRegisterInfoByName("x0", 0); if (x0_reg_info) { uint64_t raw_value = thread.GetRegisterContext()->ReadRegisterAsUnsigned(x0_reg_info, 0); const bool is_signed = (type_flags & eTypeIsSigned) != 0; switch (*byte_size) { default: break; case 16: // uint128_t // In register x0 and x1 { const RegisterInfo *x1_reg_info = reg_ctx->GetRegisterInfoByName("x1", 0); if (x1_reg_info) { if (*byte_size <= x0_reg_info->byte_size + x1_reg_info->byte_size) { std::unique_ptr heap_data_up( new DataBufferHeap(*byte_size, 0)); const ByteOrder byte_order = exe_ctx.GetProcessRef().GetByteOrder(); RegisterValue x0_reg_value; RegisterValue x1_reg_value; if (reg_ctx->ReadRegister(x0_reg_info, x0_reg_value) && reg_ctx->ReadRegister(x1_reg_info, x1_reg_value)) { Status error; if (x0_reg_value.GetAsMemoryData( *x0_reg_info, heap_data_up->GetBytes() + 0, 8, byte_order, error) && x1_reg_value.GetAsMemoryData( *x1_reg_info, heap_data_up->GetBytes() + 8, 8, byte_order, error)) { DataExtractor data( DataBufferSP(heap_data_up.release()), byte_order, exe_ctx.GetProcessRef().GetAddressByteSize()); return_valobj_sp = ValueObjectConstResult::Create( &thread, return_compiler_type, ConstString(""), data); return return_valobj_sp; } } } } } break; case sizeof(uint64_t): if (is_signed) value.GetScalar() = (int64_t)(raw_value); else value.GetScalar() = (uint64_t)(raw_value); success = true; break; case sizeof(uint32_t): if (is_signed) value.GetScalar() = (int32_t)(raw_value & UINT32_MAX); else value.GetScalar() = (uint32_t)(raw_value & UINT32_MAX); success = true; break; case sizeof(uint16_t): if (is_signed) value.GetScalar() = (int16_t)(raw_value & UINT16_MAX); else value.GetScalar() = (uint16_t)(raw_value & UINT16_MAX); success = true; break; case sizeof(uint8_t): if (is_signed) value.GetScalar() = (int8_t)(raw_value & UINT8_MAX); else value.GetScalar() = (uint8_t)(raw_value & UINT8_MAX); success = true; break; } } } } else if (type_flags & eTypeIsFloat) { if (type_flags & eTypeIsComplex) { // Don't handle complex yet. } else { if (*byte_size <= sizeof(long double)) { const RegisterInfo *v0_reg_info = reg_ctx->GetRegisterInfoByName("v0", 0); RegisterValue v0_value; if (reg_ctx->ReadRegister(v0_reg_info, v0_value)) { DataExtractor data; if (v0_value.GetData(data)) { lldb::offset_t offset = 0; if (*byte_size == sizeof(float)) { value.GetScalar() = data.GetFloat(&offset); success = true; } else if (*byte_size == sizeof(double)) { value.GetScalar() = data.GetDouble(&offset); success = true; } else if (*byte_size == sizeof(long double)) { value.GetScalar() = data.GetLongDouble(&offset); success = true; } } } } } } if (success) return_valobj_sp = ValueObjectConstResult::Create( thread.GetStackFrameAtIndex(0).get(), value, ConstString("")); } else if (type_flags & eTypeIsVector) { if (*byte_size > 0) { const RegisterInfo *v0_info = reg_ctx->GetRegisterInfoByName("v0", 0); if (v0_info) { if (*byte_size <= v0_info->byte_size) { std::unique_ptr heap_data_up( new DataBufferHeap(*byte_size, 0)); const ByteOrder byte_order = exe_ctx.GetProcessRef().GetByteOrder(); RegisterValue reg_value; if (reg_ctx->ReadRegister(v0_info, reg_value)) { Status error; if (reg_value.GetAsMemoryData(*v0_info, heap_data_up->GetBytes(), heap_data_up->GetByteSize(), byte_order, error)) { DataExtractor data(DataBufferSP(heap_data_up.release()), byte_order, exe_ctx.GetProcessRef().GetAddressByteSize()); return_valobj_sp = ValueObjectConstResult::Create( &thread, return_compiler_type, ConstString(""), data); } } } } } } else if (type_flags & eTypeIsStructUnion || type_flags & eTypeIsClass) { DataExtractor data; uint32_t NGRN = 0; // Search ABI docs for NGRN uint32_t NSRN = 0; // Search ABI docs for NSRN const bool is_return_value = true; if (LoadValueFromConsecutiveGPRRegisters( exe_ctx, reg_ctx, return_compiler_type, is_return_value, NGRN, NSRN, data)) { return_valobj_sp = ValueObjectConstResult::Create( &thread, return_compiler_type, ConstString(""), data); } } return return_valobj_sp; } addr_t ABIMacOSX_arm64::FixCodeAddress(addr_t pc) { addr_t pac_sign_extension = 0x0080000000000000ULL; addr_t tbi_mask = 0xff80000000000000ULL; addr_t mask = 0; if (ProcessSP process_sp = GetProcessSP()) { mask = process_sp->GetCodeAddressMask(); if (pc & pac_sign_extension) { addr_t highmem_mask = process_sp->GetHighmemCodeAddressMask(); if (highmem_mask != LLDB_INVALID_ADDRESS_MASK) mask = highmem_mask; } } if (mask == LLDB_INVALID_ADDRESS_MASK) mask = tbi_mask; return (pc & pac_sign_extension) ? pc | mask : pc & (~mask); } addr_t ABIMacOSX_arm64::FixDataAddress(addr_t pc) { addr_t pac_sign_extension = 0x0080000000000000ULL; addr_t tbi_mask = 0xff80000000000000ULL; addr_t mask = 0; if (ProcessSP process_sp = GetProcessSP()) { mask = process_sp->GetDataAddressMask(); if (pc & pac_sign_extension) { addr_t highmem_mask = process_sp->GetHighmemDataAddressMask(); if (highmem_mask != LLDB_INVALID_ADDRESS_MASK) mask = highmem_mask; } } if (mask == LLDB_INVALID_ADDRESS_MASK) mask = tbi_mask; return (pc & pac_sign_extension) ? pc | mask : pc & (~mask); } void ABIMacOSX_arm64::Initialize() { PluginManager::RegisterPlugin(GetPluginNameStatic(), pluginDesc, CreateInstance); } void ABIMacOSX_arm64::Terminate() { PluginManager::UnregisterPlugin(CreateInstance); }