//===-- RegisterContextDarwin_arm64.cpp ---------------------------*- C++ //-*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "RegisterContextDarwin_arm64.h" #include "RegisterContextDarwinConstants.h" #include "lldb/Target/Process.h" #include "lldb/Target/Thread.h" #include "lldb/Utility/DataBufferHeap.h" #include "lldb/Utility/DataExtractor.h" #include "lldb/Utility/Endian.h" #include "lldb/Utility/Log.h" #include "lldb/Utility/RegisterValue.h" #include "lldb/Utility/Scalar.h" #include "llvm/ADT/STLExtras.h" #include "llvm/Support/Compiler.h" #include "Plugins/Process/Utility/InstructionUtils.h" // Support building against older versions of LLVM, this macro was added // recently. #ifndef LLVM_EXTENSION #define LLVM_EXTENSION #endif #include "Utility/ARM64_DWARF_Registers.h" using namespace lldb; using namespace lldb_private; #define GPR_OFFSET(idx) ((idx)*8) #define GPR_OFFSET_NAME(reg) \ (LLVM_EXTENSION offsetof(RegisterContextDarwin_arm64::GPR, reg)) #define FPU_OFFSET(idx) ((idx)*16 + sizeof(RegisterContextDarwin_arm64::GPR)) #define FPU_OFFSET_NAME(reg) \ (LLVM_EXTENSION offsetof(RegisterContextDarwin_arm64::FPU, reg)) #define EXC_OFFSET_NAME(reg) \ (LLVM_EXTENSION offsetof(RegisterContextDarwin_arm64::EXC, reg) + \ sizeof(RegisterContextDarwin_arm64::GPR) + \ sizeof(RegisterContextDarwin_arm64::FPU)) #define DBG_OFFSET_NAME(reg) \ (LLVM_EXTENSION offsetof(RegisterContextDarwin_arm64::DBG, reg) + \ sizeof(RegisterContextDarwin_arm64::GPR) + \ sizeof(RegisterContextDarwin_arm64::FPU) + \ sizeof(RegisterContextDarwin_arm64::EXC)) #define DEFINE_DBG(reg, i) \ #reg, NULL, \ sizeof(((RegisterContextDarwin_arm64::DBG *) NULL)->reg[i]), \ DBG_OFFSET_NAME(reg[i]), eEncodingUint, eFormatHex, \ {LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, \ LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, \ LLDB_INVALID_REGNUM }, \ NULL, NULL, NULL, 0 #define REG_CONTEXT_SIZE \ (sizeof(RegisterContextDarwin_arm64::GPR) + \ sizeof(RegisterContextDarwin_arm64::FPU) + \ sizeof(RegisterContextDarwin_arm64::EXC)) //----------------------------------------------------------------------------- // Include RegisterInfos_arm64 to declare our g_register_infos_arm64 structure. //----------------------------------------------------------------------------- #define DECLARE_REGISTER_INFOS_ARM64_STRUCT #include "RegisterInfos_arm64.h" #undef DECLARE_REGISTER_INFOS_ARM64_STRUCT // General purpose registers static uint32_t g_gpr_regnums[] = { gpr_x0, gpr_x1, gpr_x2, gpr_x3, gpr_x4, gpr_x5, gpr_x6, gpr_x7, gpr_x8, gpr_x9, gpr_x10, gpr_x11, gpr_x12, gpr_x13, gpr_x14, gpr_x15, gpr_x16, gpr_x17, gpr_x18, gpr_x19, gpr_x20, gpr_x21, gpr_x22, gpr_x23, gpr_x24, gpr_x25, gpr_x26, gpr_x27, gpr_x28, gpr_fp, gpr_lr, gpr_sp, gpr_pc, gpr_cpsr}; // Floating point registers static uint32_t g_fpu_regnums[] = { fpu_v0, fpu_v1, fpu_v2, fpu_v3, fpu_v4, fpu_v5, fpu_v6, fpu_v7, fpu_v8, fpu_v9, fpu_v10, fpu_v11, fpu_v12, fpu_v13, fpu_v14, fpu_v15, fpu_v16, fpu_v17, fpu_v18, fpu_v19, fpu_v20, fpu_v21, fpu_v22, fpu_v23, fpu_v24, fpu_v25, fpu_v26, fpu_v27, fpu_v28, fpu_v29, fpu_v30, fpu_v31, fpu_fpsr, fpu_fpcr}; // Exception registers static uint32_t g_exc_regnums[] = {exc_far, exc_esr, exc_exception}; static size_t k_num_register_infos = llvm::array_lengthof(g_register_infos_arm64_le); RegisterContextDarwin_arm64::RegisterContextDarwin_arm64( Thread &thread, uint32_t concrete_frame_idx) : RegisterContext(thread, concrete_frame_idx), gpr(), fpu(), exc() { uint32_t i; for (i = 0; i < kNumErrors; i++) { gpr_errs[i] = -1; fpu_errs[i] = -1; exc_errs[i] = -1; } } RegisterContextDarwin_arm64::~RegisterContextDarwin_arm64() {} void RegisterContextDarwin_arm64::InvalidateAllRegisters() { InvalidateAllRegisterStates(); } size_t RegisterContextDarwin_arm64::GetRegisterCount() { assert(k_num_register_infos == k_num_registers); return k_num_registers; } const RegisterInfo * RegisterContextDarwin_arm64::GetRegisterInfoAtIndex(size_t reg) { assert(k_num_register_infos == k_num_registers); if (reg < k_num_registers) return &g_register_infos_arm64_le[reg]; return NULL; } size_t RegisterContextDarwin_arm64::GetRegisterInfosCount() { return k_num_register_infos; } const RegisterInfo *RegisterContextDarwin_arm64::GetRegisterInfos() { return g_register_infos_arm64_le; } // Number of registers in each register set const size_t k_num_gpr_registers = llvm::array_lengthof(g_gpr_regnums); const size_t k_num_fpu_registers = llvm::array_lengthof(g_fpu_regnums); const size_t k_num_exc_registers = llvm::array_lengthof(g_exc_regnums); //---------------------------------------------------------------------- // Register set definitions. The first definitions at register set index of // zero is for all registers, followed by other registers sets. The register // information for the all register set need not be filled in. //---------------------------------------------------------------------- static const RegisterSet g_reg_sets[] = { { "General Purpose Registers", "gpr", k_num_gpr_registers, g_gpr_regnums, }, {"Floating Point Registers", "fpu", k_num_fpu_registers, g_fpu_regnums}, {"Exception State Registers", "exc", k_num_exc_registers, g_exc_regnums}}; const size_t k_num_regsets = llvm::array_lengthof(g_reg_sets); size_t RegisterContextDarwin_arm64::GetRegisterSetCount() { return k_num_regsets; } const RegisterSet *RegisterContextDarwin_arm64::GetRegisterSet(size_t reg_set) { if (reg_set < k_num_regsets) return &g_reg_sets[reg_set]; return NULL; } //---------------------------------------------------------------------- // Register information definitions for arm64 //---------------------------------------------------------------------- int RegisterContextDarwin_arm64::GetSetForNativeRegNum(int reg) { if (reg < fpu_v0) return GPRRegSet; else if (reg < exc_far) return FPURegSet; else if (reg < k_num_registers) return EXCRegSet; return -1; } int RegisterContextDarwin_arm64::ReadGPR(bool force) { int set = GPRRegSet; if (force || !RegisterSetIsCached(set)) { SetError(set, Read, DoReadGPR(GetThreadID(), set, gpr)); } return GetError(GPRRegSet, Read); } int RegisterContextDarwin_arm64::ReadFPU(bool force) { int set = FPURegSet; if (force || !RegisterSetIsCached(set)) { SetError(set, Read, DoReadFPU(GetThreadID(), set, fpu)); } return GetError(FPURegSet, Read); } int RegisterContextDarwin_arm64::ReadEXC(bool force) { int set = EXCRegSet; if (force || !RegisterSetIsCached(set)) { SetError(set, Read, DoReadEXC(GetThreadID(), set, exc)); } return GetError(EXCRegSet, Read); } int RegisterContextDarwin_arm64::ReadDBG(bool force) { int set = DBGRegSet; if (force || !RegisterSetIsCached(set)) { SetError(set, Read, DoReadDBG(GetThreadID(), set, dbg)); } return GetError(DBGRegSet, Read); } int RegisterContextDarwin_arm64::WriteGPR() { int set = GPRRegSet; if (!RegisterSetIsCached(set)) { SetError(set, Write, -1); return KERN_INVALID_ARGUMENT; } SetError(set, Write, DoWriteGPR(GetThreadID(), set, gpr)); SetError(set, Read, -1); return GetError(GPRRegSet, Write); } int RegisterContextDarwin_arm64::WriteFPU() { int set = FPURegSet; if (!RegisterSetIsCached(set)) { SetError(set, Write, -1); return KERN_INVALID_ARGUMENT; } SetError(set, Write, DoWriteFPU(GetThreadID(), set, fpu)); SetError(set, Read, -1); return GetError(FPURegSet, Write); } int RegisterContextDarwin_arm64::WriteEXC() { int set = EXCRegSet; if (!RegisterSetIsCached(set)) { SetError(set, Write, -1); return KERN_INVALID_ARGUMENT; } SetError(set, Write, DoWriteEXC(GetThreadID(), set, exc)); SetError(set, Read, -1); return GetError(EXCRegSet, Write); } int RegisterContextDarwin_arm64::WriteDBG() { int set = DBGRegSet; if (!RegisterSetIsCached(set)) { SetError(set, Write, -1); return KERN_INVALID_ARGUMENT; } SetError(set, Write, DoWriteDBG(GetThreadID(), set, dbg)); SetError(set, Read, -1); return GetError(DBGRegSet, Write); } int RegisterContextDarwin_arm64::ReadRegisterSet(uint32_t set, bool force) { switch (set) { case GPRRegSet: return ReadGPR(force); case FPURegSet: return ReadFPU(force); case EXCRegSet: return ReadEXC(force); case DBGRegSet: return ReadDBG(force); default: break; } return KERN_INVALID_ARGUMENT; } int RegisterContextDarwin_arm64::WriteRegisterSet(uint32_t set) { // Make sure we have a valid context to set. if (RegisterSetIsCached(set)) { switch (set) { case GPRRegSet: return WriteGPR(); case FPURegSet: return WriteFPU(); case EXCRegSet: return WriteEXC(); case DBGRegSet: return WriteDBG(); default: break; } } return KERN_INVALID_ARGUMENT; } void RegisterContextDarwin_arm64::LogDBGRegisters(Log *log, const DBG &dbg) { if (log) { for (uint32_t i = 0; i < 16; i++) log->Printf("BVR%-2u/BCR%-2u = { 0x%8.8" PRIu64 ", 0x%8.8" PRIu64 " } WVR%-2u/WCR%-2u " "= { 0x%8.8" PRIu64 ", 0x%8.8" PRIu64 " }", i, i, dbg.bvr[i], dbg.bcr[i], i, i, dbg.wvr[i], dbg.wcr[i]); } } bool RegisterContextDarwin_arm64::ReadRegister(const RegisterInfo *reg_info, RegisterValue &value) { const uint32_t reg = reg_info->kinds[eRegisterKindLLDB]; int set = RegisterContextDarwin_arm64::GetSetForNativeRegNum(reg); if (set == -1) return false; if (ReadRegisterSet(set, false) != KERN_SUCCESS) return false; switch (reg) { case gpr_x0: case gpr_x1: case gpr_x2: case gpr_x3: case gpr_x4: case gpr_x5: case gpr_x6: case gpr_x7: case gpr_x8: case gpr_x9: case gpr_x10: case gpr_x11: case gpr_x12: case gpr_x13: case gpr_x14: case gpr_x15: case gpr_x16: case gpr_x17: case gpr_x18: case gpr_x19: case gpr_x20: case gpr_x21: case gpr_x22: case gpr_x23: case gpr_x24: case gpr_x25: case gpr_x26: case gpr_x27: case gpr_x28: value.SetUInt64(gpr.x[reg - gpr_x0]); break; case gpr_fp: value.SetUInt64(gpr.fp); break; case gpr_sp: value.SetUInt64(gpr.sp); break; case gpr_lr: value.SetUInt64(gpr.lr); break; case gpr_pc: value.SetUInt64(gpr.pc); break; case gpr_cpsr: value.SetUInt64(gpr.cpsr); break; case gpr_w0: case gpr_w1: case gpr_w2: case gpr_w3: case gpr_w4: case gpr_w5: case gpr_w6: case gpr_w7: case gpr_w8: case gpr_w9: case gpr_w10: case gpr_w11: case gpr_w12: case gpr_w13: case gpr_w14: case gpr_w15: case gpr_w16: case gpr_w17: case gpr_w18: case gpr_w19: case gpr_w20: case gpr_w21: case gpr_w22: case gpr_w23: case gpr_w24: case gpr_w25: case gpr_w26: case gpr_w27: case gpr_w28: { ProcessSP process_sp(m_thread.GetProcess()); if (process_sp.get()) { DataExtractor regdata(&gpr.x[reg - gpr_w0], 8, process_sp->GetByteOrder(), process_sp->GetAddressByteSize()); offset_t offset = 0; uint64_t retval = regdata.GetMaxU64(&offset, 8); uint32_t retval_lower32 = static_cast(retval & 0xffffffff); value.SetUInt32(retval_lower32); } } break; case fpu_v0: case fpu_v1: case fpu_v2: case fpu_v3: case fpu_v4: case fpu_v5: case fpu_v6: case fpu_v7: case fpu_v8: case fpu_v9: case fpu_v10: case fpu_v11: case fpu_v12: case fpu_v13: case fpu_v14: case fpu_v15: case fpu_v16: case fpu_v17: case fpu_v18: case fpu_v19: case fpu_v20: case fpu_v21: case fpu_v22: case fpu_v23: case fpu_v24: case fpu_v25: case fpu_v26: case fpu_v27: case fpu_v28: case fpu_v29: case fpu_v30: case fpu_v31: value.SetBytes(fpu.v[reg].bytes.buffer, reg_info->byte_size, endian::InlHostByteOrder()); break; case fpu_s0: case fpu_s1: case fpu_s2: case fpu_s3: case fpu_s4: case fpu_s5: case fpu_s6: case fpu_s7: case fpu_s8: case fpu_s9: case fpu_s10: case fpu_s11: case fpu_s12: case fpu_s13: case fpu_s14: case fpu_s15: case fpu_s16: case fpu_s17: case fpu_s18: case fpu_s19: case fpu_s20: case fpu_s21: case fpu_s22: case fpu_s23: case fpu_s24: case fpu_s25: case fpu_s26: case fpu_s27: case fpu_s28: case fpu_s29: case fpu_s30: case fpu_s31: { ProcessSP process_sp(m_thread.GetProcess()); if (process_sp.get()) { DataExtractor regdata(&fpu.v[reg - fpu_s0], 4, process_sp->GetByteOrder(), process_sp->GetAddressByteSize()); offset_t offset = 0; value.SetFloat(regdata.GetFloat(&offset)); } } break; case fpu_d0: case fpu_d1: case fpu_d2: case fpu_d3: case fpu_d4: case fpu_d5: case fpu_d6: case fpu_d7: case fpu_d8: case fpu_d9: case fpu_d10: case fpu_d11: case fpu_d12: case fpu_d13: case fpu_d14: case fpu_d15: case fpu_d16: case fpu_d17: case fpu_d18: case fpu_d19: case fpu_d20: case fpu_d21: case fpu_d22: case fpu_d23: case fpu_d24: case fpu_d25: case fpu_d26: case fpu_d27: case fpu_d28: case fpu_d29: case fpu_d30: case fpu_d31: { ProcessSP process_sp(m_thread.GetProcess()); if (process_sp.get()) { DataExtractor regdata(&fpu.v[reg - fpu_s0], 8, process_sp->GetByteOrder(), process_sp->GetAddressByteSize()); offset_t offset = 0; value.SetDouble(regdata.GetDouble(&offset)); } } break; case fpu_fpsr: value.SetUInt32(fpu.fpsr); break; case fpu_fpcr: value.SetUInt32(fpu.fpcr); break; case exc_exception: value.SetUInt32(exc.exception); break; case exc_esr: value.SetUInt32(exc.esr); break; case exc_far: value.SetUInt64(exc.far); break; default: value.SetValueToInvalid(); return false; } return true; } bool RegisterContextDarwin_arm64::WriteRegister(const RegisterInfo *reg_info, const RegisterValue &value) { const uint32_t reg = reg_info->kinds[eRegisterKindLLDB]; int set = GetSetForNativeRegNum(reg); if (set == -1) return false; if (ReadRegisterSet(set, false) != KERN_SUCCESS) return false; switch (reg) { case gpr_x0: case gpr_x1: case gpr_x2: case gpr_x3: case gpr_x4: case gpr_x5: case gpr_x6: case gpr_x7: case gpr_x8: case gpr_x9: case gpr_x10: case gpr_x11: case gpr_x12: case gpr_x13: case gpr_x14: case gpr_x15: case gpr_x16: case gpr_x17: case gpr_x18: case gpr_x19: case gpr_x20: case gpr_x21: case gpr_x22: case gpr_x23: case gpr_x24: case gpr_x25: case gpr_x26: case gpr_x27: case gpr_x28: case gpr_fp: case gpr_sp: case gpr_lr: case gpr_pc: case gpr_cpsr: gpr.x[reg - gpr_x0] = value.GetAsUInt64(); break; case fpu_v0: case fpu_v1: case fpu_v2: case fpu_v3: case fpu_v4: case fpu_v5: case fpu_v6: case fpu_v7: case fpu_v8: case fpu_v9: case fpu_v10: case fpu_v11: case fpu_v12: case fpu_v13: case fpu_v14: case fpu_v15: case fpu_v16: case fpu_v17: case fpu_v18: case fpu_v19: case fpu_v20: case fpu_v21: case fpu_v22: case fpu_v23: case fpu_v24: case fpu_v25: case fpu_v26: case fpu_v27: case fpu_v28: case fpu_v29: case fpu_v30: case fpu_v31: ::memcpy(fpu.v[reg].bytes.buffer, value.GetBytes(), value.GetByteSize()); break; case fpu_fpsr: fpu.fpsr = value.GetAsUInt32(); break; case fpu_fpcr: fpu.fpcr = value.GetAsUInt32(); break; case exc_exception: exc.exception = value.GetAsUInt32(); break; case exc_esr: exc.esr = value.GetAsUInt32(); break; case exc_far: exc.far = value.GetAsUInt64(); break; default: return false; } return WriteRegisterSet(set) == KERN_SUCCESS; } bool RegisterContextDarwin_arm64::ReadAllRegisterValues( lldb::DataBufferSP &data_sp) { data_sp.reset(new DataBufferHeap(REG_CONTEXT_SIZE, 0)); if (data_sp && ReadGPR(false) == KERN_SUCCESS && ReadFPU(false) == KERN_SUCCESS && ReadEXC(false) == KERN_SUCCESS) { uint8_t *dst = data_sp->GetBytes(); ::memcpy(dst, &gpr, sizeof(gpr)); dst += sizeof(gpr); ::memcpy(dst, &fpu, sizeof(fpu)); dst += sizeof(gpr); ::memcpy(dst, &exc, sizeof(exc)); return true; } return false; } bool RegisterContextDarwin_arm64::WriteAllRegisterValues( const lldb::DataBufferSP &data_sp) { if (data_sp && data_sp->GetByteSize() == REG_CONTEXT_SIZE) { const uint8_t *src = data_sp->GetBytes(); ::memcpy(&gpr, src, sizeof(gpr)); src += sizeof(gpr); ::memcpy(&fpu, src, sizeof(fpu)); src += sizeof(gpr); ::memcpy(&exc, src, sizeof(exc)); uint32_t success_count = 0; if (WriteGPR() == KERN_SUCCESS) ++success_count; if (WriteFPU() == KERN_SUCCESS) ++success_count; if (WriteEXC() == KERN_SUCCESS) ++success_count; return success_count == 3; } return false; } uint32_t RegisterContextDarwin_arm64::ConvertRegisterKindToRegisterNumber( RegisterKind kind, uint32_t reg) { if (kind == eRegisterKindGeneric) { switch (reg) { case LLDB_REGNUM_GENERIC_PC: return gpr_pc; case LLDB_REGNUM_GENERIC_SP: return gpr_sp; case LLDB_REGNUM_GENERIC_FP: return gpr_fp; case LLDB_REGNUM_GENERIC_RA: return gpr_lr; case LLDB_REGNUM_GENERIC_FLAGS: return gpr_cpsr; default: break; } } else if (kind == eRegisterKindDWARF) { switch (reg) { case arm64_dwarf::x0: return gpr_x0; case arm64_dwarf::x1: return gpr_x1; case arm64_dwarf::x2: return gpr_x2; case arm64_dwarf::x3: return gpr_x3; case arm64_dwarf::x4: return gpr_x4; case arm64_dwarf::x5: return gpr_x5; case arm64_dwarf::x6: return gpr_x6; case arm64_dwarf::x7: return gpr_x7; case arm64_dwarf::x8: return gpr_x8; case arm64_dwarf::x9: return gpr_x9; case arm64_dwarf::x10: return gpr_x10; case arm64_dwarf::x11: return gpr_x11; case arm64_dwarf::x12: return gpr_x12; case arm64_dwarf::x13: return gpr_x13; case arm64_dwarf::x14: return gpr_x14; case arm64_dwarf::x15: return gpr_x15; case arm64_dwarf::x16: return gpr_x16; case arm64_dwarf::x17: return gpr_x17; case arm64_dwarf::x18: return gpr_x18; case arm64_dwarf::x19: return gpr_x19; case arm64_dwarf::x20: return gpr_x20; case arm64_dwarf::x21: return gpr_x21; case arm64_dwarf::x22: return gpr_x22; case arm64_dwarf::x23: return gpr_x23; case arm64_dwarf::x24: return gpr_x24; case arm64_dwarf::x25: return gpr_x25; case arm64_dwarf::x26: return gpr_x26; case arm64_dwarf::x27: return gpr_x27; case arm64_dwarf::x28: return gpr_x28; case arm64_dwarf::fp: return gpr_fp; case arm64_dwarf::sp: return gpr_sp; case arm64_dwarf::lr: return gpr_lr; case arm64_dwarf::pc: return gpr_pc; case arm64_dwarf::cpsr: return gpr_cpsr; case arm64_dwarf::v0: return fpu_v0; case arm64_dwarf::v1: return fpu_v1; case arm64_dwarf::v2: return fpu_v2; case arm64_dwarf::v3: return fpu_v3; case arm64_dwarf::v4: return fpu_v4; case arm64_dwarf::v5: return fpu_v5; case arm64_dwarf::v6: return fpu_v6; case arm64_dwarf::v7: return fpu_v7; case arm64_dwarf::v8: return fpu_v8; case arm64_dwarf::v9: return fpu_v9; case arm64_dwarf::v10: return fpu_v10; case arm64_dwarf::v11: return fpu_v11; case arm64_dwarf::v12: return fpu_v12; case arm64_dwarf::v13: return fpu_v13; case arm64_dwarf::v14: return fpu_v14; case arm64_dwarf::v15: return fpu_v15; case arm64_dwarf::v16: return fpu_v16; case arm64_dwarf::v17: return fpu_v17; case arm64_dwarf::v18: return fpu_v18; case arm64_dwarf::v19: return fpu_v19; case arm64_dwarf::v20: return fpu_v20; case arm64_dwarf::v21: return fpu_v21; case arm64_dwarf::v22: return fpu_v22; case arm64_dwarf::v23: return fpu_v23; case arm64_dwarf::v24: return fpu_v24; case arm64_dwarf::v25: return fpu_v25; case arm64_dwarf::v26: return fpu_v26; case arm64_dwarf::v27: return fpu_v27; case arm64_dwarf::v28: return fpu_v28; case arm64_dwarf::v29: return fpu_v29; case arm64_dwarf::v30: return fpu_v30; case arm64_dwarf::v31: return fpu_v31; default: break; } } else if (kind == eRegisterKindEHFrame) { switch (reg) { case arm64_ehframe::x0: return gpr_x0; case arm64_ehframe::x1: return gpr_x1; case arm64_ehframe::x2: return gpr_x2; case arm64_ehframe::x3: return gpr_x3; case arm64_ehframe::x4: return gpr_x4; case arm64_ehframe::x5: return gpr_x5; case arm64_ehframe::x6: return gpr_x6; case arm64_ehframe::x7: return gpr_x7; case arm64_ehframe::x8: return gpr_x8; case arm64_ehframe::x9: return gpr_x9; case arm64_ehframe::x10: return gpr_x10; case arm64_ehframe::x11: return gpr_x11; case arm64_ehframe::x12: return gpr_x12; case arm64_ehframe::x13: return gpr_x13; case arm64_ehframe::x14: return gpr_x14; case arm64_ehframe::x15: return gpr_x15; case arm64_ehframe::x16: return gpr_x16; case arm64_ehframe::x17: return gpr_x17; case arm64_ehframe::x18: return gpr_x18; case arm64_ehframe::x19: return gpr_x19; case arm64_ehframe::x20: return gpr_x20; case arm64_ehframe::x21: return gpr_x21; case arm64_ehframe::x22: return gpr_x22; case arm64_ehframe::x23: return gpr_x23; case arm64_ehframe::x24: return gpr_x24; case arm64_ehframe::x25: return gpr_x25; case arm64_ehframe::x26: return gpr_x26; case arm64_ehframe::x27: return gpr_x27; case arm64_ehframe::x28: return gpr_x28; case arm64_ehframe::fp: return gpr_fp; case arm64_ehframe::sp: return gpr_sp; case arm64_ehframe::lr: return gpr_lr; case arm64_ehframe::pc: return gpr_pc; case arm64_ehframe::cpsr: return gpr_cpsr; } } else if (kind == eRegisterKindLLDB) { return reg; } return LLDB_INVALID_REGNUM; } uint32_t RegisterContextDarwin_arm64::NumSupportedHardwareWatchpoints() { #if defined(__APPLE__) && (defined(__arm64__) || defined(__aarch64__)) // autodetect how many watchpoints are supported dynamically... static uint32_t g_num_supported_hw_watchpoints = UINT32_MAX; if (g_num_supported_hw_watchpoints == UINT32_MAX) { size_t len; uint32_t n = 0; len = sizeof(n); if (::sysctlbyname("hw.optional.watchpoint", &n, &len, NULL, 0) == 0) { g_num_supported_hw_watchpoints = n; } } return g_num_supported_hw_watchpoints; #else // TODO: figure out remote case here! return 2; #endif } uint32_t RegisterContextDarwin_arm64::SetHardwareWatchpoint(lldb::addr_t addr, size_t size, bool read, bool write) { // if (log) log->Printf // ("RegisterContextDarwin_arm64::EnableHardwareWatchpoint(addr = %8.8p, // size = %u, read = %u, write = %u)", addr, size, read, write); const uint32_t num_hw_watchpoints = NumSupportedHardwareWatchpoints(); // Can't watch zero bytes if (size == 0) return LLDB_INVALID_INDEX32; // We must watch for either read or write if (!read && !write) return LLDB_INVALID_INDEX32; // Can't watch more than 4 bytes per WVR/WCR pair if (size > 4) return LLDB_INVALID_INDEX32; // We can only watch up to four bytes that follow a 4 byte aligned address // per watchpoint register pair. Since we have at most so we can only watch // until the next 4 byte boundary and we need to make sure we can properly // encode this. uint32_t addr_word_offset = addr % 4; // if (log) log->Printf // ("RegisterContextDarwin_arm64::EnableHardwareWatchpoint() - // addr_word_offset = 0x%8.8x", addr_word_offset); uint32_t byte_mask = ((1u << size) - 1u) << addr_word_offset; // if (log) log->Printf // ("RegisterContextDarwin_arm64::EnableHardwareWatchpoint() - byte_mask = // 0x%8.8x", byte_mask); if (byte_mask > 0xfu) return LLDB_INVALID_INDEX32; // Read the debug state int kret = ReadDBG(false); if (kret == KERN_SUCCESS) { // Check to make sure we have the needed hardware support uint32_t i = 0; for (i = 0; i < num_hw_watchpoints; ++i) { if ((dbg.wcr[i] & WCR_ENABLE) == 0) break; // We found an available hw breakpoint slot (in i) } // See if we found an available hw breakpoint slot above if (i < num_hw_watchpoints) { // Make the byte_mask into a valid Byte Address Select mask uint32_t byte_address_select = byte_mask << 5; // Make sure bits 1:0 are clear in our address dbg.wvr[i] = addr & ~((lldb::addr_t)3); dbg.wcr[i] = byte_address_select | // Which bytes that follow the IMVA // that we will watch S_USER | // Stop only in user mode (read ? WCR_LOAD : 0) | // Stop on read access? (write ? WCR_STORE : 0) | // Stop on write access? WCR_ENABLE; // Enable this watchpoint; kret = WriteDBG(); // if (log) log->Printf // ("RegisterContextDarwin_arm64::EnableHardwareWatchpoint() // WriteDBG() => 0x%8.8x.", kret); if (kret == KERN_SUCCESS) return i; } else { // if (log) log->Printf // ("RegisterContextDarwin_arm64::EnableHardwareWatchpoint(): // All hardware resources (%u) are in use.", // num_hw_watchpoints); } } return LLDB_INVALID_INDEX32; } bool RegisterContextDarwin_arm64::ClearHardwareWatchpoint(uint32_t hw_index) { int kret = ReadDBG(false); const uint32_t num_hw_points = NumSupportedHardwareWatchpoints(); if (kret == KERN_SUCCESS) { if (hw_index < num_hw_points) { dbg.wcr[hw_index] = 0; // if (log) log->Printf // ("RegisterContextDarwin_arm64::ClearHardwareWatchpoint( %u ) // - WVR%u = 0x%8.8x WCR%u = 0x%8.8x", // hw_index, // hw_index, // dbg.wvr[hw_index], // hw_index, // dbg.wcr[hw_index]); kret = WriteDBG(); if (kret == KERN_SUCCESS) return true; } } return false; }