//===-- RegisterContextLinux_x86_64.cpp ------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===---------------------------------------------------------------------===// #include #include "RegisterContextPOSIX_x86.h" #include "RegisterContextLinux_i386.h" #include "RegisterContextLinux_x86_64.h" using namespace lldb_private; using namespace lldb; typedef struct _GPR { uint64_t r15; uint64_t r14; uint64_t r13; uint64_t r12; uint64_t rbp; uint64_t rbx; uint64_t r11; uint64_t r10; uint64_t r9; uint64_t r8; uint64_t rax; uint64_t rcx; uint64_t rdx; uint64_t rsi; uint64_t rdi; uint64_t orig_rax; uint64_t rip; uint64_t cs; uint64_t rflags; uint64_t rsp; uint64_t ss; uint64_t fs_base; uint64_t gs_base; uint64_t ds; uint64_t es; uint64_t fs; uint64_t gs; } GPR; struct DBG { uint64_t dr[8]; }; struct UserArea { GPR gpr; // General purpose registers. int32_t fpvalid; // True if FPU is being used. int32_t pad0; FXSAVE fpr; // General purpose floating point registers (see FPR for extended register sets). uint64_t tsize; // Text segment size. uint64_t dsize; // Data segment size. uint64_t ssize; // Stack segment size. uint64_t start_code; // VM address of text. uint64_t start_stack; // VM address of stack bottom (top in rsp). int64_t signal; // Signal causing core dump. int32_t reserved; // Unused. int32_t pad1; uint64_t ar0; // Location of GPR's. FXSAVE* fpstate; // Location of FPR's. uint64_t magic; // Identifier for core dumps. char u_comm[32]; // Command causing core dump. DBG dbg; // Debug registers. uint64_t error_code; // CPU error code. uint64_t fault_address; // Control register CR3. }; #define DR_OFFSET(reg_index) \ (LLVM_EXTENSION offsetof(UserArea, dbg) + \ LLVM_EXTENSION offsetof(DBG, dr[reg_index])) //--------------------------------------------------------------------------- // Include RegisterInfos_x86_64 to declare our g_register_infos_x86_64 structure. //--------------------------------------------------------------------------- #define DECLARE_REGISTER_INFOS_X86_64_STRUCT #include "RegisterInfos_x86_64.h" #undef DECLARE_REGISTER_INFOS_X86_64_STRUCT static std::vector& GetPrivateRegisterInfoVector () { static std::vector g_register_infos; return g_register_infos; } static const RegisterInfo * GetRegisterInfo_i386(const lldb_private::ArchSpec &arch) { std::vector &g_register_infos = GetPrivateRegisterInfoVector (); // Allocate RegisterInfo only once if (g_register_infos.empty()) { // Copy the register information from base class std::unique_ptr reg_interface(new RegisterContextLinux_i386 (arch)); const RegisterInfo *base_info = reg_interface->GetRegisterInfo(); g_register_infos.insert(g_register_infos.end(), &base_info[0], &base_info[k_num_registers_i386]); //--------------------------------------------------------------------------- // Include RegisterInfos_x86_64 to update the g_register_infos structure // with x86_64 offsets. //--------------------------------------------------------------------------- #define UPDATE_REGISTER_INFOS_I386_STRUCT_WITH_X86_64_OFFSETS #include "RegisterInfos_x86_64.h" #undef UPDATE_REGISTER_INFOS_I386_STRUCT_WITH_X86_64_OFFSETS } return &g_register_infos[0]; } static const RegisterInfo * GetRegisterInfoPtr (const ArchSpec &target_arch) { switch (target_arch.GetMachine()) { case llvm::Triple::x86: return GetRegisterInfo_i386 (target_arch); case llvm::Triple::x86_64: return g_register_infos_x86_64; default: assert(false && "Unhandled target architecture."); return nullptr; } } static uint32_t GetRegisterInfoCount (const ArchSpec &target_arch) { switch (target_arch.GetMachine()) { case llvm::Triple::x86: { assert (!GetPrivateRegisterInfoVector ().empty () && "i386 register info not yet filled."); return static_cast (GetPrivateRegisterInfoVector ().size ()); } case llvm::Triple::x86_64: return static_cast (sizeof (g_register_infos_x86_64) / sizeof (g_register_infos_x86_64 [0])); default: assert(false && "Unhandled target architecture."); return 0; } } static uint32_t GetUserRegisterInfoCount (const ArchSpec &target_arch) { switch (target_arch.GetMachine()) { case llvm::Triple::x86: return static_cast (k_num_user_registers_i386); case llvm::Triple::x86_64: return static_cast (k_num_user_registers_x86_64); default: assert(false && "Unhandled target architecture."); return 0; } } RegisterContextLinux_x86_64::RegisterContextLinux_x86_64(const ArchSpec &target_arch) : lldb_private::RegisterInfoInterface(target_arch), m_register_info_p (GetRegisterInfoPtr (target_arch)), m_register_info_count (GetRegisterInfoCount (target_arch)), m_user_register_count (GetUserRegisterInfoCount (target_arch)) { RegisterInfo orig_ax = { "orig_rax", NULL, sizeof(((GPR*)NULL)->orig_rax), (LLVM_EXTENSION offsetof(GPR, orig_rax)), eEncodingUint, \ eFormatHex, { LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM }, NULL, NULL }; d_register_infos.push_back(orig_ax); } size_t RegisterContextLinux_x86_64::GetGPRSize() const { return sizeof(GPR); } const std::vector * RegisterContextLinux_x86_64::GetDynamicRegisterInfoP() const { return &d_register_infos; } const RegisterInfo * RegisterContextLinux_x86_64::GetRegisterInfo() const { return m_register_info_p; } uint32_t RegisterContextLinux_x86_64::GetRegisterCount () const { return m_register_info_count; } uint32_t RegisterContextLinux_x86_64::GetUserRegisterCount () const { return m_user_register_count; }