//===----------------------------------------------------------------------===// // // 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 // // // Models register sets for supported processors. // //===----------------------------------------------------------------------===// #ifndef __REGISTERS_HPP__ #define __REGISTERS_HPP__ #include #include #include "cet_unwind.h" #include "config.h" #include "libunwind.h" namespace libunwind { // For emulating 128-bit registers struct v128 { uint32_t vec[4]; }; enum { REGISTERS_X86, REGISTERS_X86_64, REGISTERS_PPC, REGISTERS_PPC64, REGISTERS_ARM64, REGISTERS_ARM, REGISTERS_OR1K, REGISTERS_MIPS_O32, REGISTERS_MIPS_NEWABI, REGISTERS_SPARC, REGISTERS_SPARC64, REGISTERS_HEXAGON, REGISTERS_RISCV, REGISTERS_VE, REGISTERS_S390X, REGISTERS_LOONGARCH, }; #if defined(_LIBUNWIND_TARGET_I386) class _LIBUNWIND_HIDDEN Registers_x86; extern "C" void __libunwind_Registers_x86_jumpto(Registers_x86 *); #if defined(_LIBUNWIND_USE_CET) extern "C" void *__libunwind_cet_get_jump_target() { return reinterpret_cast(&__libunwind_Registers_x86_jumpto); } #endif /// Registers_x86 holds the register state of a thread in a 32-bit intel /// process. class _LIBUNWIND_HIDDEN Registers_x86 { public: Registers_x86(); Registers_x86(const void *registers); bool validRegister(int num) const; uint32_t getRegister(int num) const; void setRegister(int num, uint32_t value); bool validFloatRegister(int) const { return false; } double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int) const { return false; } v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto() { __libunwind_Registers_x86_jumpto(this); } static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_X86; } static int getArch() { return REGISTERS_X86; } uint32_t getSP() const { return _registers.__esp; } void setSP(uint32_t value) { _registers.__esp = value; } uint32_t getIP() const { return _registers.__eip; } void setIP(uint32_t value) { _registers.__eip = value; } uint32_t getEBP() const { return _registers.__ebp; } void setEBP(uint32_t value) { _registers.__ebp = value; } uint32_t getEBX() const { return _registers.__ebx; } void setEBX(uint32_t value) { _registers.__ebx = value; } uint32_t getECX() const { return _registers.__ecx; } void setECX(uint32_t value) { _registers.__ecx = value; } uint32_t getEDX() const { return _registers.__edx; } void setEDX(uint32_t value) { _registers.__edx = value; } uint32_t getESI() const { return _registers.__esi; } void setESI(uint32_t value) { _registers.__esi = value; } uint32_t getEDI() const { return _registers.__edi; } void setEDI(uint32_t value) { _registers.__edi = value; } private: struct GPRs { unsigned int __eax; unsigned int __ebx; unsigned int __ecx; unsigned int __edx; unsigned int __edi; unsigned int __esi; unsigned int __ebp; unsigned int __esp; unsigned int __ss; unsigned int __eflags; unsigned int __eip; unsigned int __cs; unsigned int __ds; unsigned int __es; unsigned int __fs; unsigned int __gs; }; GPRs _registers; }; inline Registers_x86::Registers_x86(const void *registers) { static_assert((check_fit::does_fit), "x86 registers do not fit into unw_context_t"); memcpy(&_registers, registers, sizeof(_registers)); } inline Registers_x86::Registers_x86() { memset(&_registers, 0, sizeof(_registers)); } inline bool Registers_x86::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum < 0) return false; if (regNum > 7) return false; return true; } inline uint32_t Registers_x86::getRegister(int regNum) const { switch (regNum) { case UNW_REG_IP: return _registers.__eip; case UNW_REG_SP: return _registers.__esp; case UNW_X86_EAX: return _registers.__eax; case UNW_X86_ECX: return _registers.__ecx; case UNW_X86_EDX: return _registers.__edx; case UNW_X86_EBX: return _registers.__ebx; #if !defined(__APPLE__) case UNW_X86_ESP: #else case UNW_X86_EBP: #endif return _registers.__ebp; #if !defined(__APPLE__) case UNW_X86_EBP: #else case UNW_X86_ESP: #endif return _registers.__esp; case UNW_X86_ESI: return _registers.__esi; case UNW_X86_EDI: return _registers.__edi; } _LIBUNWIND_ABORT("unsupported x86 register"); } inline void Registers_x86::setRegister(int regNum, uint32_t value) { switch (regNum) { case UNW_REG_IP: _registers.__eip = value; return; case UNW_REG_SP: _registers.__esp = value; return; case UNW_X86_EAX: _registers.__eax = value; return; case UNW_X86_ECX: _registers.__ecx = value; return; case UNW_X86_EDX: _registers.__edx = value; return; case UNW_X86_EBX: _registers.__ebx = value; return; #if !defined(__APPLE__) case UNW_X86_ESP: #else case UNW_X86_EBP: #endif _registers.__ebp = value; return; #if !defined(__APPLE__) case UNW_X86_EBP: #else case UNW_X86_ESP: #endif _registers.__esp = value; return; case UNW_X86_ESI: _registers.__esi = value; return; case UNW_X86_EDI: _registers.__edi = value; return; } _LIBUNWIND_ABORT("unsupported x86 register"); } inline const char *Registers_x86::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "ip"; case UNW_REG_SP: return "esp"; case UNW_X86_EAX: return "eax"; case UNW_X86_ECX: return "ecx"; case UNW_X86_EDX: return "edx"; case UNW_X86_EBX: return "ebx"; case UNW_X86_EBP: return "ebp"; case UNW_X86_ESP: return "esp"; case UNW_X86_ESI: return "esi"; case UNW_X86_EDI: return "edi"; default: return "unknown register"; } } inline double Registers_x86::getFloatRegister(int) const { _LIBUNWIND_ABORT("no x86 float registers"); } inline void Registers_x86::setFloatRegister(int, double) { _LIBUNWIND_ABORT("no x86 float registers"); } inline v128 Registers_x86::getVectorRegister(int) const { _LIBUNWIND_ABORT("no x86 vector registers"); } inline void Registers_x86::setVectorRegister(int, v128) { _LIBUNWIND_ABORT("no x86 vector registers"); } #endif // _LIBUNWIND_TARGET_I386 #if defined(_LIBUNWIND_TARGET_X86_64) /// Registers_x86_64 holds the register state of a thread in a 64-bit intel /// process. class _LIBUNWIND_HIDDEN Registers_x86_64; extern "C" void __libunwind_Registers_x86_64_jumpto(Registers_x86_64 *); #if defined(_LIBUNWIND_USE_CET) extern "C" void *__libunwind_cet_get_jump_target() { return reinterpret_cast(&__libunwind_Registers_x86_64_jumpto); } #endif class _LIBUNWIND_HIDDEN Registers_x86_64 { public: Registers_x86_64(); Registers_x86_64(const void *registers); bool validRegister(int num) const; uint64_t getRegister(int num) const; void setRegister(int num, uint64_t value); bool validFloatRegister(int) const { return false; } double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto() { __libunwind_Registers_x86_64_jumpto(this); } static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_X86_64; } static int getArch() { return REGISTERS_X86_64; } uint64_t getSP() const { return _registers.__rsp; } void setSP(uint64_t value) { _registers.__rsp = value; } uint64_t getIP() const { return _registers.__rip; } void setIP(uint64_t value) { _registers.__rip = value; } uint64_t getRBP() const { return _registers.__rbp; } void setRBP(uint64_t value) { _registers.__rbp = value; } uint64_t getRBX() const { return _registers.__rbx; } void setRBX(uint64_t value) { _registers.__rbx = value; } uint64_t getR12() const { return _registers.__r12; } void setR12(uint64_t value) { _registers.__r12 = value; } uint64_t getR13() const { return _registers.__r13; } void setR13(uint64_t value) { _registers.__r13 = value; } uint64_t getR14() const { return _registers.__r14; } void setR14(uint64_t value) { _registers.__r14 = value; } uint64_t getR15() const { return _registers.__r15; } void setR15(uint64_t value) { _registers.__r15 = value; } private: struct GPRs { uint64_t __rax; uint64_t __rbx; uint64_t __rcx; uint64_t __rdx; uint64_t __rdi; uint64_t __rsi; uint64_t __rbp; uint64_t __rsp; uint64_t __r8; uint64_t __r9; uint64_t __r10; uint64_t __r11; uint64_t __r12; uint64_t __r13; uint64_t __r14; uint64_t __r15; uint64_t __rip; uint64_t __rflags; uint64_t __cs; uint64_t __fs; uint64_t __gs; #if defined(_WIN64) uint64_t __padding; // 16-byte align #endif }; GPRs _registers; #if defined(_WIN64) v128 _xmm[16]; #endif }; inline Registers_x86_64::Registers_x86_64(const void *registers) { static_assert((check_fit::does_fit), "x86_64 registers do not fit into unw_context_t"); memcpy(&_registers, registers, sizeof(_registers)); } inline Registers_x86_64::Registers_x86_64() { memset(&_registers, 0, sizeof(_registers)); } inline bool Registers_x86_64::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum < 0) return false; if (regNum > 16) return false; return true; } inline uint64_t Registers_x86_64::getRegister(int regNum) const { switch (regNum) { case UNW_REG_IP: case UNW_X86_64_RIP: return _registers.__rip; case UNW_REG_SP: return _registers.__rsp; case UNW_X86_64_RAX: return _registers.__rax; case UNW_X86_64_RDX: return _registers.__rdx; case UNW_X86_64_RCX: return _registers.__rcx; case UNW_X86_64_RBX: return _registers.__rbx; case UNW_X86_64_RSI: return _registers.__rsi; case UNW_X86_64_RDI: return _registers.__rdi; case UNW_X86_64_RBP: return _registers.__rbp; case UNW_X86_64_RSP: return _registers.__rsp; case UNW_X86_64_R8: return _registers.__r8; case UNW_X86_64_R9: return _registers.__r9; case UNW_X86_64_R10: return _registers.__r10; case UNW_X86_64_R11: return _registers.__r11; case UNW_X86_64_R12: return _registers.__r12; case UNW_X86_64_R13: return _registers.__r13; case UNW_X86_64_R14: return _registers.__r14; case UNW_X86_64_R15: return _registers.__r15; } _LIBUNWIND_ABORT("unsupported x86_64 register"); } inline void Registers_x86_64::setRegister(int regNum, uint64_t value) { switch (regNum) { case UNW_REG_IP: case UNW_X86_64_RIP: _registers.__rip = value; return; case UNW_REG_SP: _registers.__rsp = value; return; case UNW_X86_64_RAX: _registers.__rax = value; return; case UNW_X86_64_RDX: _registers.__rdx = value; return; case UNW_X86_64_RCX: _registers.__rcx = value; return; case UNW_X86_64_RBX: _registers.__rbx = value; return; case UNW_X86_64_RSI: _registers.__rsi = value; return; case UNW_X86_64_RDI: _registers.__rdi = value; return; case UNW_X86_64_RBP: _registers.__rbp = value; return; case UNW_X86_64_RSP: _registers.__rsp = value; return; case UNW_X86_64_R8: _registers.__r8 = value; return; case UNW_X86_64_R9: _registers.__r9 = value; return; case UNW_X86_64_R10: _registers.__r10 = value; return; case UNW_X86_64_R11: _registers.__r11 = value; return; case UNW_X86_64_R12: _registers.__r12 = value; return; case UNW_X86_64_R13: _registers.__r13 = value; return; case UNW_X86_64_R14: _registers.__r14 = value; return; case UNW_X86_64_R15: _registers.__r15 = value; return; } _LIBUNWIND_ABORT("unsupported x86_64 register"); } inline const char *Registers_x86_64::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: case UNW_X86_64_RIP: return "rip"; case UNW_REG_SP: return "rsp"; case UNW_X86_64_RAX: return "rax"; case UNW_X86_64_RDX: return "rdx"; case UNW_X86_64_RCX: return "rcx"; case UNW_X86_64_RBX: return "rbx"; case UNW_X86_64_RSI: return "rsi"; case UNW_X86_64_RDI: return "rdi"; case UNW_X86_64_RBP: return "rbp"; case UNW_X86_64_RSP: return "rsp"; case UNW_X86_64_R8: return "r8"; case UNW_X86_64_R9: return "r9"; case UNW_X86_64_R10: return "r10"; case UNW_X86_64_R11: return "r11"; case UNW_X86_64_R12: return "r12"; case UNW_X86_64_R13: return "r13"; case UNW_X86_64_R14: return "r14"; case UNW_X86_64_R15: return "r15"; case UNW_X86_64_XMM0: return "xmm0"; case UNW_X86_64_XMM1: return "xmm1"; case UNW_X86_64_XMM2: return "xmm2"; case UNW_X86_64_XMM3: return "xmm3"; case UNW_X86_64_XMM4: return "xmm4"; case UNW_X86_64_XMM5: return "xmm5"; case UNW_X86_64_XMM6: return "xmm6"; case UNW_X86_64_XMM7: return "xmm7"; case UNW_X86_64_XMM8: return "xmm8"; case UNW_X86_64_XMM9: return "xmm9"; case UNW_X86_64_XMM10: return "xmm10"; case UNW_X86_64_XMM11: return "xmm11"; case UNW_X86_64_XMM12: return "xmm12"; case UNW_X86_64_XMM13: return "xmm13"; case UNW_X86_64_XMM14: return "xmm14"; case UNW_X86_64_XMM15: return "xmm15"; default: return "unknown register"; } } inline double Registers_x86_64::getFloatRegister(int) const { _LIBUNWIND_ABORT("no x86_64 float registers"); } inline void Registers_x86_64::setFloatRegister(int, double) { _LIBUNWIND_ABORT("no x86_64 float registers"); } inline bool Registers_x86_64::validVectorRegister(int regNum) const { #if defined(_WIN64) if (regNum < UNW_X86_64_XMM0) return false; if (regNum > UNW_X86_64_XMM15) return false; return true; #else (void)regNum; // suppress unused parameter warning return false; #endif } inline v128 Registers_x86_64::getVectorRegister(int regNum) const { #if defined(_WIN64) assert(validVectorRegister(regNum)); return _xmm[regNum - UNW_X86_64_XMM0]; #else (void)regNum; // suppress unused parameter warning _LIBUNWIND_ABORT("no x86_64 vector registers"); #endif } inline void Registers_x86_64::setVectorRegister(int regNum, v128 value) { #if defined(_WIN64) assert(validVectorRegister(regNum)); _xmm[regNum - UNW_X86_64_XMM0] = value; #else (void)regNum; (void)value; // suppress unused parameter warnings _LIBUNWIND_ABORT("no x86_64 vector registers"); #endif } #endif // _LIBUNWIND_TARGET_X86_64 #if defined(_LIBUNWIND_TARGET_PPC) /// Registers_ppc holds the register state of a thread in a 32-bit PowerPC /// process. class _LIBUNWIND_HIDDEN Registers_ppc { public: Registers_ppc(); Registers_ppc(const void *registers); bool validRegister(int num) const; uint32_t getRegister(int num) const; void setRegister(int num, uint32_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_PPC; } static int getArch() { return REGISTERS_PPC; } uint64_t getSP() const { return _registers.__r1; } void setSP(uint32_t value) { _registers.__r1 = value; } uint64_t getIP() const { return _registers.__srr0; } void setIP(uint32_t value) { _registers.__srr0 = value; } uint64_t getCR() const { return _registers.__cr; } void setCR(uint32_t value) { _registers.__cr = value; } uint64_t getLR() const { return _registers.__lr; } void setLR(uint32_t value) { _registers.__lr = value; } private: struct ppc_thread_state_t { unsigned int __srr0; /* Instruction address register (PC) */ unsigned int __srr1; /* Machine state register (supervisor) */ unsigned int __r0; unsigned int __r1; unsigned int __r2; unsigned int __r3; unsigned int __r4; unsigned int __r5; unsigned int __r6; unsigned int __r7; unsigned int __r8; unsigned int __r9; unsigned int __r10; unsigned int __r11; unsigned int __r12; unsigned int __r13; unsigned int __r14; unsigned int __r15; unsigned int __r16; unsigned int __r17; unsigned int __r18; unsigned int __r19; unsigned int __r20; unsigned int __r21; unsigned int __r22; unsigned int __r23; unsigned int __r24; unsigned int __r25; unsigned int __r26; unsigned int __r27; unsigned int __r28; unsigned int __r29; unsigned int __r30; unsigned int __r31; unsigned int __cr; /* Condition register */ unsigned int __xer; /* User's integer exception register */ unsigned int __lr; /* Link register */ unsigned int __ctr; /* Count register */ unsigned int __mq; /* MQ register (601 only) */ unsigned int __vrsave; /* Vector Save Register */ }; struct ppc_float_state_t { double __fpregs[32]; unsigned int __fpscr_pad; /* fpscr is 64 bits, 32 bits of rubbish */ unsigned int __fpscr; /* floating point status register */ }; ppc_thread_state_t _registers; ppc_float_state_t _floatRegisters; v128 _vectorRegisters[32]; // offset 424 }; inline Registers_ppc::Registers_ppc(const void *registers) { static_assert((check_fit::does_fit), "ppc registers do not fit into unw_context_t"); memcpy(&_registers, static_cast(registers), sizeof(_registers)); static_assert(sizeof(ppc_thread_state_t) == 160, "expected float register offset to be 160"); memcpy(&_floatRegisters, static_cast(registers) + sizeof(ppc_thread_state_t), sizeof(_floatRegisters)); static_assert(sizeof(ppc_thread_state_t) + sizeof(ppc_float_state_t) == 424, "expected vector register offset to be 424 bytes"); memcpy(_vectorRegisters, static_cast(registers) + sizeof(ppc_thread_state_t) + sizeof(ppc_float_state_t), sizeof(_vectorRegisters)); } inline Registers_ppc::Registers_ppc() { memset(&_registers, 0, sizeof(_registers)); memset(&_floatRegisters, 0, sizeof(_floatRegisters)); memset(&_vectorRegisters, 0, sizeof(_vectorRegisters)); } inline bool Registers_ppc::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum == UNW_PPC_VRSAVE) return true; if (regNum < 0) return false; if (regNum <= UNW_PPC_R31) return true; if (regNum == UNW_PPC_MQ) return true; if (regNum == UNW_PPC_LR) return true; if (regNum == UNW_PPC_CTR) return true; if ((UNW_PPC_CR0 <= regNum) && (regNum <= UNW_PPC_CR7)) return true; return false; } inline uint32_t Registers_ppc::getRegister(int regNum) const { switch (regNum) { case UNW_REG_IP: return _registers.__srr0; case UNW_REG_SP: return _registers.__r1; case UNW_PPC_R0: return _registers.__r0; case UNW_PPC_R1: return _registers.__r1; case UNW_PPC_R2: return _registers.__r2; case UNW_PPC_R3: return _registers.__r3; case UNW_PPC_R4: return _registers.__r4; case UNW_PPC_R5: return _registers.__r5; case UNW_PPC_R6: return _registers.__r6; case UNW_PPC_R7: return _registers.__r7; case UNW_PPC_R8: return _registers.__r8; case UNW_PPC_R9: return _registers.__r9; case UNW_PPC_R10: return _registers.__r10; case UNW_PPC_R11: return _registers.__r11; case UNW_PPC_R12: return _registers.__r12; case UNW_PPC_R13: return _registers.__r13; case UNW_PPC_R14: return _registers.__r14; case UNW_PPC_R15: return _registers.__r15; case UNW_PPC_R16: return _registers.__r16; case UNW_PPC_R17: return _registers.__r17; case UNW_PPC_R18: return _registers.__r18; case UNW_PPC_R19: return _registers.__r19; case UNW_PPC_R20: return _registers.__r20; case UNW_PPC_R21: return _registers.__r21; case UNW_PPC_R22: return _registers.__r22; case UNW_PPC_R23: return _registers.__r23; case UNW_PPC_R24: return _registers.__r24; case UNW_PPC_R25: return _registers.__r25; case UNW_PPC_R26: return _registers.__r26; case UNW_PPC_R27: return _registers.__r27; case UNW_PPC_R28: return _registers.__r28; case UNW_PPC_R29: return _registers.__r29; case UNW_PPC_R30: return _registers.__r30; case UNW_PPC_R31: return _registers.__r31; case UNW_PPC_LR: return _registers.__lr; case UNW_PPC_CR0: return (_registers.__cr & 0xF0000000); case UNW_PPC_CR1: return (_registers.__cr & 0x0F000000); case UNW_PPC_CR2: return (_registers.__cr & 0x00F00000); case UNW_PPC_CR3: return (_registers.__cr & 0x000F0000); case UNW_PPC_CR4: return (_registers.__cr & 0x0000F000); case UNW_PPC_CR5: return (_registers.__cr & 0x00000F00); case UNW_PPC_CR6: return (_registers.__cr & 0x000000F0); case UNW_PPC_CR7: return (_registers.__cr & 0x0000000F); case UNW_PPC_VRSAVE: return _registers.__vrsave; } _LIBUNWIND_ABORT("unsupported ppc register"); } inline void Registers_ppc::setRegister(int regNum, uint32_t value) { //fprintf(stderr, "Registers_ppc::setRegister(%d, 0x%08X)\n", regNum, value); switch (regNum) { case UNW_REG_IP: _registers.__srr0 = value; return; case UNW_REG_SP: _registers.__r1 = value; return; case UNW_PPC_R0: _registers.__r0 = value; return; case UNW_PPC_R1: _registers.__r1 = value; return; case UNW_PPC_R2: _registers.__r2 = value; return; case UNW_PPC_R3: _registers.__r3 = value; return; case UNW_PPC_R4: _registers.__r4 = value; return; case UNW_PPC_R5: _registers.__r5 = value; return; case UNW_PPC_R6: _registers.__r6 = value; return; case UNW_PPC_R7: _registers.__r7 = value; return; case UNW_PPC_R8: _registers.__r8 = value; return; case UNW_PPC_R9: _registers.__r9 = value; return; case UNW_PPC_R10: _registers.__r10 = value; return; case UNW_PPC_R11: _registers.__r11 = value; return; case UNW_PPC_R12: _registers.__r12 = value; return; case UNW_PPC_R13: _registers.__r13 = value; return; case UNW_PPC_R14: _registers.__r14 = value; return; case UNW_PPC_R15: _registers.__r15 = value; return; case UNW_PPC_R16: _registers.__r16 = value; return; case UNW_PPC_R17: _registers.__r17 = value; return; case UNW_PPC_R18: _registers.__r18 = value; return; case UNW_PPC_R19: _registers.__r19 = value; return; case UNW_PPC_R20: _registers.__r20 = value; return; case UNW_PPC_R21: _registers.__r21 = value; return; case UNW_PPC_R22: _registers.__r22 = value; return; case UNW_PPC_R23: _registers.__r23 = value; return; case UNW_PPC_R24: _registers.__r24 = value; return; case UNW_PPC_R25: _registers.__r25 = value; return; case UNW_PPC_R26: _registers.__r26 = value; return; case UNW_PPC_R27: _registers.__r27 = value; return; case UNW_PPC_R28: _registers.__r28 = value; return; case UNW_PPC_R29: _registers.__r29 = value; return; case UNW_PPC_R30: _registers.__r30 = value; return; case UNW_PPC_R31: _registers.__r31 = value; return; case UNW_PPC_MQ: _registers.__mq = value; return; case UNW_PPC_LR: _registers.__lr = value; return; case UNW_PPC_CTR: _registers.__ctr = value; return; case UNW_PPC_CR0: _registers.__cr &= 0x0FFFFFFF; _registers.__cr |= (value & 0xF0000000); return; case UNW_PPC_CR1: _registers.__cr &= 0xF0FFFFFF; _registers.__cr |= (value & 0x0F000000); return; case UNW_PPC_CR2: _registers.__cr &= 0xFF0FFFFF; _registers.__cr |= (value & 0x00F00000); return; case UNW_PPC_CR3: _registers.__cr &= 0xFFF0FFFF; _registers.__cr |= (value & 0x000F0000); return; case UNW_PPC_CR4: _registers.__cr &= 0xFFFF0FFF; _registers.__cr |= (value & 0x0000F000); return; case UNW_PPC_CR5: _registers.__cr &= 0xFFFFF0FF; _registers.__cr |= (value & 0x00000F00); return; case UNW_PPC_CR6: _registers.__cr &= 0xFFFFFF0F; _registers.__cr |= (value & 0x000000F0); return; case UNW_PPC_CR7: _registers.__cr &= 0xFFFFFFF0; _registers.__cr |= (value & 0x0000000F); return; case UNW_PPC_VRSAVE: _registers.__vrsave = value; return; // not saved return; case UNW_PPC_XER: _registers.__xer = value; return; case UNW_PPC_AP: case UNW_PPC_VSCR: case UNW_PPC_SPEFSCR: // not saved return; } _LIBUNWIND_ABORT("unsupported ppc register"); } inline bool Registers_ppc::validFloatRegister(int regNum) const { if (regNum < UNW_PPC_F0) return false; if (regNum > UNW_PPC_F31) return false; return true; } inline double Registers_ppc::getFloatRegister(int regNum) const { assert(validFloatRegister(regNum)); return _floatRegisters.__fpregs[regNum - UNW_PPC_F0]; } inline void Registers_ppc::setFloatRegister(int regNum, double value) { assert(validFloatRegister(regNum)); _floatRegisters.__fpregs[regNum - UNW_PPC_F0] = value; } inline bool Registers_ppc::validVectorRegister(int regNum) const { if (regNum < UNW_PPC_V0) return false; if (regNum > UNW_PPC_V31) return false; return true; } inline v128 Registers_ppc::getVectorRegister(int regNum) const { assert(validVectorRegister(regNum)); v128 result = _vectorRegisters[regNum - UNW_PPC_V0]; return result; } inline void Registers_ppc::setVectorRegister(int regNum, v128 value) { assert(validVectorRegister(regNum)); _vectorRegisters[regNum - UNW_PPC_V0] = value; } inline const char *Registers_ppc::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "ip"; case UNW_REG_SP: return "sp"; case UNW_PPC_R0: return "r0"; case UNW_PPC_R1: return "r1"; case UNW_PPC_R2: return "r2"; case UNW_PPC_R3: return "r3"; case UNW_PPC_R4: return "r4"; case UNW_PPC_R5: return "r5"; case UNW_PPC_R6: return "r6"; case UNW_PPC_R7: return "r7"; case UNW_PPC_R8: return "r8"; case UNW_PPC_R9: return "r9"; case UNW_PPC_R10: return "r10"; case UNW_PPC_R11: return "r11"; case UNW_PPC_R12: return "r12"; case UNW_PPC_R13: return "r13"; case UNW_PPC_R14: return "r14"; case UNW_PPC_R15: return "r15"; case UNW_PPC_R16: return "r16"; case UNW_PPC_R17: return "r17"; case UNW_PPC_R18: return "r18"; case UNW_PPC_R19: return "r19"; case UNW_PPC_R20: return "r20"; case UNW_PPC_R21: return "r21"; case UNW_PPC_R22: return "r22"; case UNW_PPC_R23: return "r23"; case UNW_PPC_R24: return "r24"; case UNW_PPC_R25: return "r25"; case UNW_PPC_R26: return "r26"; case UNW_PPC_R27: return "r27"; case UNW_PPC_R28: return "r28"; case UNW_PPC_R29: return "r29"; case UNW_PPC_R30: return "r30"; case UNW_PPC_R31: return "r31"; case UNW_PPC_F0: return "fp0"; case UNW_PPC_F1: return "fp1"; case UNW_PPC_F2: return "fp2"; case UNW_PPC_F3: return "fp3"; case UNW_PPC_F4: return "fp4"; case UNW_PPC_F5: return "fp5"; case UNW_PPC_F6: return "fp6"; case UNW_PPC_F7: return "fp7"; case UNW_PPC_F8: return "fp8"; case UNW_PPC_F9: return "fp9"; case UNW_PPC_F10: return "fp10"; case UNW_PPC_F11: return "fp11"; case UNW_PPC_F12: return "fp12"; case UNW_PPC_F13: return "fp13"; case UNW_PPC_F14: return "fp14"; case UNW_PPC_F15: return "fp15"; case UNW_PPC_F16: return "fp16"; case UNW_PPC_F17: return "fp17"; case UNW_PPC_F18: return "fp18"; case UNW_PPC_F19: return "fp19"; case UNW_PPC_F20: return "fp20"; case UNW_PPC_F21: return "fp21"; case UNW_PPC_F22: return "fp22"; case UNW_PPC_F23: return "fp23"; case UNW_PPC_F24: return "fp24"; case UNW_PPC_F25: return "fp25"; case UNW_PPC_F26: return "fp26"; case UNW_PPC_F27: return "fp27"; case UNW_PPC_F28: return "fp28"; case UNW_PPC_F29: return "fp29"; case UNW_PPC_F30: return "fp30"; case UNW_PPC_F31: return "fp31"; case UNW_PPC_LR: return "lr"; default: return "unknown register"; } } #endif // _LIBUNWIND_TARGET_PPC #if defined(_LIBUNWIND_TARGET_PPC64) /// Registers_ppc64 holds the register state of a thread in a 64-bit PowerPC /// process. class _LIBUNWIND_HIDDEN Registers_ppc64 { public: Registers_ppc64(); Registers_ppc64(const void *registers); bool validRegister(int num) const; uint64_t getRegister(int num) const; void setRegister(int num, uint64_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_PPC64; } static int getArch() { return REGISTERS_PPC64; } uint64_t getSP() const { return _registers.__r1; } void setSP(uint64_t value) { _registers.__r1 = value; } uint64_t getIP() const { return _registers.__srr0; } void setIP(uint64_t value) { _registers.__srr0 = value; } uint64_t getCR() const { return _registers.__cr; } void setCR(uint64_t value) { _registers.__cr = value; } uint64_t getLR() const { return _registers.__lr; } void setLR(uint64_t value) { _registers.__lr = value; } private: struct ppc64_thread_state_t { uint64_t __srr0; // Instruction address register (PC) uint64_t __srr1; // Machine state register (supervisor) uint64_t __r0; uint64_t __r1; uint64_t __r2; uint64_t __r3; uint64_t __r4; uint64_t __r5; uint64_t __r6; uint64_t __r7; uint64_t __r8; uint64_t __r9; uint64_t __r10; uint64_t __r11; uint64_t __r12; uint64_t __r13; uint64_t __r14; uint64_t __r15; uint64_t __r16; uint64_t __r17; uint64_t __r18; uint64_t __r19; uint64_t __r20; uint64_t __r21; uint64_t __r22; uint64_t __r23; uint64_t __r24; uint64_t __r25; uint64_t __r26; uint64_t __r27; uint64_t __r28; uint64_t __r29; uint64_t __r30; uint64_t __r31; uint64_t __cr; // Condition register uint64_t __xer; // User's integer exception register uint64_t __lr; // Link register uint64_t __ctr; // Count register uint64_t __vrsave; // Vector Save Register }; union ppc64_vsr_t { struct asfloat_s { double f; uint64_t v2; } asfloat; v128 v; }; ppc64_thread_state_t _registers; ppc64_vsr_t _vectorScalarRegisters[64]; static int getVectorRegNum(int num); }; inline Registers_ppc64::Registers_ppc64(const void *registers) { static_assert((check_fit::does_fit), "ppc64 registers do not fit into unw_context_t"); memcpy(&_registers, static_cast(registers), sizeof(_registers)); static_assert(sizeof(_registers) == 312, "expected vector scalar register offset to be 312"); memcpy(&_vectorScalarRegisters, static_cast(registers) + sizeof(_registers), sizeof(_vectorScalarRegisters)); static_assert(sizeof(_registers) + sizeof(_vectorScalarRegisters) == 1336, "expected vector register offset to be 1336 bytes"); } inline Registers_ppc64::Registers_ppc64() { memset(&_registers, 0, sizeof(_registers)); memset(&_vectorScalarRegisters, 0, sizeof(_vectorScalarRegisters)); } inline bool Registers_ppc64::validRegister(int regNum) const { switch (regNum) { case UNW_REG_IP: case UNW_REG_SP: case UNW_PPC64_XER: case UNW_PPC64_LR: case UNW_PPC64_CTR: case UNW_PPC64_VRSAVE: return true; } if (regNum >= UNW_PPC64_R0 && regNum <= UNW_PPC64_R31) return true; if (regNum >= UNW_PPC64_CR0 && regNum <= UNW_PPC64_CR7) return true; return false; } inline uint64_t Registers_ppc64::getRegister(int regNum) const { switch (regNum) { case UNW_REG_IP: return _registers.__srr0; case UNW_PPC64_R0: return _registers.__r0; case UNW_PPC64_R1: case UNW_REG_SP: return _registers.__r1; case UNW_PPC64_R2: return _registers.__r2; case UNW_PPC64_R3: return _registers.__r3; case UNW_PPC64_R4: return _registers.__r4; case UNW_PPC64_R5: return _registers.__r5; case UNW_PPC64_R6: return _registers.__r6; case UNW_PPC64_R7: return _registers.__r7; case UNW_PPC64_R8: return _registers.__r8; case UNW_PPC64_R9: return _registers.__r9; case UNW_PPC64_R10: return _registers.__r10; case UNW_PPC64_R11: return _registers.__r11; case UNW_PPC64_R12: return _registers.__r12; case UNW_PPC64_R13: return _registers.__r13; case UNW_PPC64_R14: return _registers.__r14; case UNW_PPC64_R15: return _registers.__r15; case UNW_PPC64_R16: return _registers.__r16; case UNW_PPC64_R17: return _registers.__r17; case UNW_PPC64_R18: return _registers.__r18; case UNW_PPC64_R19: return _registers.__r19; case UNW_PPC64_R20: return _registers.__r20; case UNW_PPC64_R21: return _registers.__r21; case UNW_PPC64_R22: return _registers.__r22; case UNW_PPC64_R23: return _registers.__r23; case UNW_PPC64_R24: return _registers.__r24; case UNW_PPC64_R25: return _registers.__r25; case UNW_PPC64_R26: return _registers.__r26; case UNW_PPC64_R27: return _registers.__r27; case UNW_PPC64_R28: return _registers.__r28; case UNW_PPC64_R29: return _registers.__r29; case UNW_PPC64_R30: return _registers.__r30; case UNW_PPC64_R31: return _registers.__r31; case UNW_PPC64_CR0: return (_registers.__cr & 0xF0000000); case UNW_PPC64_CR1: return (_registers.__cr & 0x0F000000); case UNW_PPC64_CR2: return (_registers.__cr & 0x00F00000); case UNW_PPC64_CR3: return (_registers.__cr & 0x000F0000); case UNW_PPC64_CR4: return (_registers.__cr & 0x0000F000); case UNW_PPC64_CR5: return (_registers.__cr & 0x00000F00); case UNW_PPC64_CR6: return (_registers.__cr & 0x000000F0); case UNW_PPC64_CR7: return (_registers.__cr & 0x0000000F); case UNW_PPC64_XER: return _registers.__xer; case UNW_PPC64_LR: return _registers.__lr; case UNW_PPC64_CTR: return _registers.__ctr; case UNW_PPC64_VRSAVE: return _registers.__vrsave; } _LIBUNWIND_ABORT("unsupported ppc64 register"); } inline void Registers_ppc64::setRegister(int regNum, uint64_t value) { switch (regNum) { case UNW_REG_IP: _registers.__srr0 = value; return; case UNW_PPC64_R0: _registers.__r0 = value; return; case UNW_PPC64_R1: case UNW_REG_SP: _registers.__r1 = value; return; case UNW_PPC64_R2: _registers.__r2 = value; return; case UNW_PPC64_R3: _registers.__r3 = value; return; case UNW_PPC64_R4: _registers.__r4 = value; return; case UNW_PPC64_R5: _registers.__r5 = value; return; case UNW_PPC64_R6: _registers.__r6 = value; return; case UNW_PPC64_R7: _registers.__r7 = value; return; case UNW_PPC64_R8: _registers.__r8 = value; return; case UNW_PPC64_R9: _registers.__r9 = value; return; case UNW_PPC64_R10: _registers.__r10 = value; return; case UNW_PPC64_R11: _registers.__r11 = value; return; case UNW_PPC64_R12: _registers.__r12 = value; return; case UNW_PPC64_R13: _registers.__r13 = value; return; case UNW_PPC64_R14: _registers.__r14 = value; return; case UNW_PPC64_R15: _registers.__r15 = value; return; case UNW_PPC64_R16: _registers.__r16 = value; return; case UNW_PPC64_R17: _registers.__r17 = value; return; case UNW_PPC64_R18: _registers.__r18 = value; return; case UNW_PPC64_R19: _registers.__r19 = value; return; case UNW_PPC64_R20: _registers.__r20 = value; return; case UNW_PPC64_R21: _registers.__r21 = value; return; case UNW_PPC64_R22: _registers.__r22 = value; return; case UNW_PPC64_R23: _registers.__r23 = value; return; case UNW_PPC64_R24: _registers.__r24 = value; return; case UNW_PPC64_R25: _registers.__r25 = value; return; case UNW_PPC64_R26: _registers.__r26 = value; return; case UNW_PPC64_R27: _registers.__r27 = value; return; case UNW_PPC64_R28: _registers.__r28 = value; return; case UNW_PPC64_R29: _registers.__r29 = value; return; case UNW_PPC64_R30: _registers.__r30 = value; return; case UNW_PPC64_R31: _registers.__r31 = value; return; case UNW_PPC64_CR0: _registers.__cr &= 0x0FFFFFFF; _registers.__cr |= (value & 0xF0000000); return; case UNW_PPC64_CR1: _registers.__cr &= 0xF0FFFFFF; _registers.__cr |= (value & 0x0F000000); return; case UNW_PPC64_CR2: _registers.__cr &= 0xFF0FFFFF; _registers.__cr |= (value & 0x00F00000); return; case UNW_PPC64_CR3: _registers.__cr &= 0xFFF0FFFF; _registers.__cr |= (value & 0x000F0000); return; case UNW_PPC64_CR4: _registers.__cr &= 0xFFFF0FFF; _registers.__cr |= (value & 0x0000F000); return; case UNW_PPC64_CR5: _registers.__cr &= 0xFFFFF0FF; _registers.__cr |= (value & 0x00000F00); return; case UNW_PPC64_CR6: _registers.__cr &= 0xFFFFFF0F; _registers.__cr |= (value & 0x000000F0); return; case UNW_PPC64_CR7: _registers.__cr &= 0xFFFFFFF0; _registers.__cr |= (value & 0x0000000F); return; case UNW_PPC64_XER: _registers.__xer = value; return; case UNW_PPC64_LR: _registers.__lr = value; return; case UNW_PPC64_CTR: _registers.__ctr = value; return; case UNW_PPC64_VRSAVE: _registers.__vrsave = value; return; } _LIBUNWIND_ABORT("unsupported ppc64 register"); } inline bool Registers_ppc64::validFloatRegister(int regNum) const { return regNum >= UNW_PPC64_F0 && regNum <= UNW_PPC64_F31; } inline double Registers_ppc64::getFloatRegister(int regNum) const { assert(validFloatRegister(regNum)); return _vectorScalarRegisters[regNum - UNW_PPC64_F0].asfloat.f; } inline void Registers_ppc64::setFloatRegister(int regNum, double value) { assert(validFloatRegister(regNum)); _vectorScalarRegisters[regNum - UNW_PPC64_F0].asfloat.f = value; } inline bool Registers_ppc64::validVectorRegister(int regNum) const { #if defined(__VSX__) if (regNum >= UNW_PPC64_VS0 && regNum <= UNW_PPC64_VS31) return true; if (regNum >= UNW_PPC64_VS32 && regNum <= UNW_PPC64_VS63) return true; #elif defined(__ALTIVEC__) if (regNum >= UNW_PPC64_V0 && regNum <= UNW_PPC64_V31) return true; #endif return false; } inline int Registers_ppc64::getVectorRegNum(int num) { if (num >= UNW_PPC64_VS0 && num <= UNW_PPC64_VS31) return num - UNW_PPC64_VS0; else return num - UNW_PPC64_VS32 + 32; } inline v128 Registers_ppc64::getVectorRegister(int regNum) const { assert(validVectorRegister(regNum)); return _vectorScalarRegisters[getVectorRegNum(regNum)].v; } inline void Registers_ppc64::setVectorRegister(int regNum, v128 value) { assert(validVectorRegister(regNum)); _vectorScalarRegisters[getVectorRegNum(regNum)].v = value; } inline const char *Registers_ppc64::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "ip"; case UNW_REG_SP: return "sp"; case UNW_PPC64_R0: return "r0"; case UNW_PPC64_R1: return "r1"; case UNW_PPC64_R2: return "r2"; case UNW_PPC64_R3: return "r3"; case UNW_PPC64_R4: return "r4"; case UNW_PPC64_R5: return "r5"; case UNW_PPC64_R6: return "r6"; case UNW_PPC64_R7: return "r7"; case UNW_PPC64_R8: return "r8"; case UNW_PPC64_R9: return "r9"; case UNW_PPC64_R10: return "r10"; case UNW_PPC64_R11: return "r11"; case UNW_PPC64_R12: return "r12"; case UNW_PPC64_R13: return "r13"; case UNW_PPC64_R14: return "r14"; case UNW_PPC64_R15: return "r15"; case UNW_PPC64_R16: return "r16"; case UNW_PPC64_R17: return "r17"; case UNW_PPC64_R18: return "r18"; case UNW_PPC64_R19: return "r19"; case UNW_PPC64_R20: return "r20"; case UNW_PPC64_R21: return "r21"; case UNW_PPC64_R22: return "r22"; case UNW_PPC64_R23: return "r23"; case UNW_PPC64_R24: return "r24"; case UNW_PPC64_R25: return "r25"; case UNW_PPC64_R26: return "r26"; case UNW_PPC64_R27: return "r27"; case UNW_PPC64_R28: return "r28"; case UNW_PPC64_R29: return "r29"; case UNW_PPC64_R30: return "r30"; case UNW_PPC64_R31: return "r31"; case UNW_PPC64_CR0: return "cr0"; case UNW_PPC64_CR1: return "cr1"; case UNW_PPC64_CR2: return "cr2"; case UNW_PPC64_CR3: return "cr3"; case UNW_PPC64_CR4: return "cr4"; case UNW_PPC64_CR5: return "cr5"; case UNW_PPC64_CR6: return "cr6"; case UNW_PPC64_CR7: return "cr7"; case UNW_PPC64_XER: return "xer"; case UNW_PPC64_LR: return "lr"; case UNW_PPC64_CTR: return "ctr"; case UNW_PPC64_VRSAVE: return "vrsave"; case UNW_PPC64_F0: return "fp0"; case UNW_PPC64_F1: return "fp1"; case UNW_PPC64_F2: return "fp2"; case UNW_PPC64_F3: return "fp3"; case UNW_PPC64_F4: return "fp4"; case UNW_PPC64_F5: return "fp5"; case UNW_PPC64_F6: return "fp6"; case UNW_PPC64_F7: return "fp7"; case UNW_PPC64_F8: return "fp8"; case UNW_PPC64_F9: return "fp9"; case UNW_PPC64_F10: return "fp10"; case UNW_PPC64_F11: return "fp11"; case UNW_PPC64_F12: return "fp12"; case UNW_PPC64_F13: return "fp13"; case UNW_PPC64_F14: return "fp14"; case UNW_PPC64_F15: return "fp15"; case UNW_PPC64_F16: return "fp16"; case UNW_PPC64_F17: return "fp17"; case UNW_PPC64_F18: return "fp18"; case UNW_PPC64_F19: return "fp19"; case UNW_PPC64_F20: return "fp20"; case UNW_PPC64_F21: return "fp21"; case UNW_PPC64_F22: return "fp22"; case UNW_PPC64_F23: return "fp23"; case UNW_PPC64_F24: return "fp24"; case UNW_PPC64_F25: return "fp25"; case UNW_PPC64_F26: return "fp26"; case UNW_PPC64_F27: return "fp27"; case UNW_PPC64_F28: return "fp28"; case UNW_PPC64_F29: return "fp29"; case UNW_PPC64_F30: return "fp30"; case UNW_PPC64_F31: return "fp31"; case UNW_PPC64_V0: return "v0"; case UNW_PPC64_V1: return "v1"; case UNW_PPC64_V2: return "v2"; case UNW_PPC64_V3: return "v3"; case UNW_PPC64_V4: return "v4"; case UNW_PPC64_V5: return "v5"; case UNW_PPC64_V6: return "v6"; case UNW_PPC64_V7: return "v7"; case UNW_PPC64_V8: return "v8"; case UNW_PPC64_V9: return "v9"; case UNW_PPC64_V10: return "v10"; case UNW_PPC64_V11: return "v11"; case UNW_PPC64_V12: return "v12"; case UNW_PPC64_V13: return "v13"; case UNW_PPC64_V14: return "v14"; case UNW_PPC64_V15: return "v15"; case UNW_PPC64_V16: return "v16"; case UNW_PPC64_V17: return "v17"; case UNW_PPC64_V18: return "v18"; case UNW_PPC64_V19: return "v19"; case UNW_PPC64_V20: return "v20"; case UNW_PPC64_V21: return "v21"; case UNW_PPC64_V22: return "v22"; case UNW_PPC64_V23: return "v23"; case UNW_PPC64_V24: return "v24"; case UNW_PPC64_V25: return "v25"; case UNW_PPC64_V26: return "v26"; case UNW_PPC64_V27: return "v27"; case UNW_PPC64_V28: return "v28"; case UNW_PPC64_V29: return "v29"; case UNW_PPC64_V30: return "v30"; case UNW_PPC64_V31: return "v31"; } return "unknown register"; } #endif // _LIBUNWIND_TARGET_PPC64 #if defined(_LIBUNWIND_TARGET_AARCH64) /// Registers_arm64 holds the register state of a thread in a 64-bit arm /// process. class _LIBUNWIND_HIDDEN Registers_arm64; extern "C" void __libunwind_Registers_arm64_jumpto(Registers_arm64 *); #if defined(_LIBUNWIND_USE_GCS) extern "C" void *__libunwind_cet_get_jump_target() { return reinterpret_cast(&__libunwind_Registers_arm64_jumpto); } #endif class _LIBUNWIND_HIDDEN Registers_arm64 { public: Registers_arm64(); Registers_arm64(const void *registers); bool validRegister(int num) const; uint64_t getRegister(int num) const; void setRegister(int num, uint64_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto() { __libunwind_Registers_arm64_jumpto(this); } static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_ARM64; } static int getArch() { return REGISTERS_ARM64; } uint64_t getSP() const { return _registers.__sp; } void setSP(uint64_t value) { _registers.__sp = value; } uint64_t getIP() const { return _registers.__pc; } void setIP(uint64_t value) { _registers.__pc = value; } uint64_t getFP() const { return _registers.__fp; } void setFP(uint64_t value) { _registers.__fp = value; } private: struct GPRs { uint64_t __x[29]; // x0-x28 uint64_t __fp; // Frame pointer x29 uint64_t __lr; // Link register x30 uint64_t __sp; // Stack pointer x31 uint64_t __pc; // Program counter uint64_t __ra_sign_state; // RA sign state register }; GPRs _registers; double _vectorHalfRegisters[32]; // Currently only the lower double in 128-bit vectore registers // is perserved during unwinding. We could define new register // numbers (> 96) which mean whole vector registers, then this // struct would need to change to contain whole vector registers. }; inline Registers_arm64::Registers_arm64(const void *registers) { static_assert((check_fit::does_fit), "arm64 registers do not fit into unw_context_t"); memcpy(&_registers, registers, sizeof(_registers)); static_assert(sizeof(GPRs) == 0x110, "expected VFP registers to be at offset 272"); memcpy(_vectorHalfRegisters, static_cast(registers) + sizeof(GPRs), sizeof(_vectorHalfRegisters)); } inline Registers_arm64::Registers_arm64() { memset(&_registers, 0, sizeof(_registers)); memset(&_vectorHalfRegisters, 0, sizeof(_vectorHalfRegisters)); } inline bool Registers_arm64::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum < 0) return false; if (regNum > 95) return false; if (regNum == UNW_AARCH64_RA_SIGN_STATE) return true; if ((regNum > 32) && (regNum < 64)) return false; return true; } inline uint64_t Registers_arm64::getRegister(int regNum) const { if (regNum == UNW_REG_IP || regNum == UNW_AARCH64_PC) return _registers.__pc; if (regNum == UNW_REG_SP || regNum == UNW_AARCH64_SP) return _registers.__sp; if (regNum == UNW_AARCH64_RA_SIGN_STATE) return _registers.__ra_sign_state; if (regNum == UNW_AARCH64_FP) return _registers.__fp; if (regNum == UNW_AARCH64_LR) return _registers.__lr; if ((regNum >= 0) && (regNum < 29)) return _registers.__x[regNum]; _LIBUNWIND_ABORT("unsupported arm64 register"); } inline void Registers_arm64::setRegister(int regNum, uint64_t value) { if (regNum == UNW_REG_IP || regNum == UNW_AARCH64_PC) _registers.__pc = value; else if (regNum == UNW_REG_SP || regNum == UNW_AARCH64_SP) _registers.__sp = value; else if (regNum == UNW_AARCH64_RA_SIGN_STATE) _registers.__ra_sign_state = value; else if (regNum == UNW_AARCH64_FP) _registers.__fp = value; else if (regNum == UNW_AARCH64_LR) _registers.__lr = value; else if ((regNum >= 0) && (regNum < 29)) _registers.__x[regNum] = value; else _LIBUNWIND_ABORT("unsupported arm64 register"); } inline const char *Registers_arm64::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "pc"; case UNW_REG_SP: return "sp"; case UNW_AARCH64_X0: return "x0"; case UNW_AARCH64_X1: return "x1"; case UNW_AARCH64_X2: return "x2"; case UNW_AARCH64_X3: return "x3"; case UNW_AARCH64_X4: return "x4"; case UNW_AARCH64_X5: return "x5"; case UNW_AARCH64_X6: return "x6"; case UNW_AARCH64_X7: return "x7"; case UNW_AARCH64_X8: return "x8"; case UNW_AARCH64_X9: return "x9"; case UNW_AARCH64_X10: return "x10"; case UNW_AARCH64_X11: return "x11"; case UNW_AARCH64_X12: return "x12"; case UNW_AARCH64_X13: return "x13"; case UNW_AARCH64_X14: return "x14"; case UNW_AARCH64_X15: return "x15"; case UNW_AARCH64_X16: return "x16"; case UNW_AARCH64_X17: return "x17"; case UNW_AARCH64_X18: return "x18"; case UNW_AARCH64_X19: return "x19"; case UNW_AARCH64_X20: return "x20"; case UNW_AARCH64_X21: return "x21"; case UNW_AARCH64_X22: return "x22"; case UNW_AARCH64_X23: return "x23"; case UNW_AARCH64_X24: return "x24"; case UNW_AARCH64_X25: return "x25"; case UNW_AARCH64_X26: return "x26"; case UNW_AARCH64_X27: return "x27"; case UNW_AARCH64_X28: return "x28"; case UNW_AARCH64_FP: return "fp"; case UNW_AARCH64_LR: return "lr"; case UNW_AARCH64_SP: return "sp"; case UNW_AARCH64_PC: return "pc"; case UNW_AARCH64_V0: return "d0"; case UNW_AARCH64_V1: return "d1"; case UNW_AARCH64_V2: return "d2"; case UNW_AARCH64_V3: return "d3"; case UNW_AARCH64_V4: return "d4"; case UNW_AARCH64_V5: return "d5"; case UNW_AARCH64_V6: return "d6"; case UNW_AARCH64_V7: return "d7"; case UNW_AARCH64_V8: return "d8"; case UNW_AARCH64_V9: return "d9"; case UNW_AARCH64_V10: return "d10"; case UNW_AARCH64_V11: return "d11"; case UNW_AARCH64_V12: return "d12"; case UNW_AARCH64_V13: return "d13"; case UNW_AARCH64_V14: return "d14"; case UNW_AARCH64_V15: return "d15"; case UNW_AARCH64_V16: return "d16"; case UNW_AARCH64_V17: return "d17"; case UNW_AARCH64_V18: return "d18"; case UNW_AARCH64_V19: return "d19"; case UNW_AARCH64_V20: return "d20"; case UNW_AARCH64_V21: return "d21"; case UNW_AARCH64_V22: return "d22"; case UNW_AARCH64_V23: return "d23"; case UNW_AARCH64_V24: return "d24"; case UNW_AARCH64_V25: return "d25"; case UNW_AARCH64_V26: return "d26"; case UNW_AARCH64_V27: return "d27"; case UNW_AARCH64_V28: return "d28"; case UNW_AARCH64_V29: return "d29"; case UNW_AARCH64_V30: return "d30"; case UNW_AARCH64_V31: return "d31"; default: return "unknown register"; } } inline bool Registers_arm64::validFloatRegister(int regNum) const { if (regNum < UNW_AARCH64_V0) return false; if (regNum > UNW_AARCH64_V31) return false; return true; } inline double Registers_arm64::getFloatRegister(int regNum) const { assert(validFloatRegister(regNum)); return _vectorHalfRegisters[regNum - UNW_AARCH64_V0]; } inline void Registers_arm64::setFloatRegister(int regNum, double value) { assert(validFloatRegister(regNum)); _vectorHalfRegisters[regNum - UNW_AARCH64_V0] = value; } inline bool Registers_arm64::validVectorRegister(int) const { return false; } inline v128 Registers_arm64::getVectorRegister(int) const { _LIBUNWIND_ABORT("no arm64 vector register support yet"); } inline void Registers_arm64::setVectorRegister(int, v128) { _LIBUNWIND_ABORT("no arm64 vector register support yet"); } #endif // _LIBUNWIND_TARGET_AARCH64 #if defined(_LIBUNWIND_TARGET_ARM) /// Registers_arm holds the register state of a thread in a 32-bit arm /// process. /// /// NOTE: Assumes VFPv3. On ARM processors without a floating point unit, /// this uses more memory than required. class _LIBUNWIND_HIDDEN Registers_arm { public: Registers_arm(); Registers_arm(const void *registers); bool validRegister(int num) const; uint32_t getRegister(int num) const; void setRegister(int num, uint32_t value); bool validFloatRegister(int num) const; unw_fpreg_t getFloatRegister(int num); void setFloatRegister(int num, unw_fpreg_t value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto() { restoreSavedFloatRegisters(); restoreCoreAndJumpTo(); } static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_ARM; } static int getArch() { return REGISTERS_ARM; } uint32_t getSP() const { return _registers.__sp; } void setSP(uint32_t value) { _registers.__sp = value; } uint32_t getIP() const { return _registers.__pc; } void setIP(uint32_t value) { _registers.__pc = value; } void saveVFPAsX() { assert(_use_X_for_vfp_save || !_saved_vfp_d0_d15); _use_X_for_vfp_save = true; } void restoreSavedFloatRegisters() { if (_saved_vfp_d0_d15) { if (_use_X_for_vfp_save) restoreVFPWithFLDMX(_vfp_d0_d15_pad); else restoreVFPWithFLDMD(_vfp_d0_d15_pad); } if (_saved_vfp_d16_d31) restoreVFPv3(_vfp_d16_d31); #if defined(__ARM_WMMX) if (_saved_iwmmx) restoreiWMMX(_iwmmx); if (_saved_iwmmx_control) restoreiWMMXControl(_iwmmx_control); #endif } private: struct GPRs { uint32_t __r[13]; // r0-r12 uint32_t __sp; // Stack pointer r13 uint32_t __lr; // Link register r14 uint32_t __pc; // Program counter r15 }; struct PseudoRegisters { uint32_t __pac; // Return Authentication Code (PAC) }; static void saveVFPWithFSTMD(void*); static void saveVFPWithFSTMX(void*); static void saveVFPv3(void*); static void restoreVFPWithFLDMD(void*); static void restoreVFPWithFLDMX(void*); static void restoreVFPv3(void*); #if defined(__ARM_WMMX) static void saveiWMMX(void*); static void saveiWMMXControl(uint32_t*); static void restoreiWMMX(void*); static void restoreiWMMXControl(uint32_t*); #endif void restoreCoreAndJumpTo(); // ARM registers GPRs _registers; PseudoRegisters _pseudo_registers; // We save floating point registers lazily because we can't know ahead of // time which ones are used. See EHABI #4.7. // Whether D0-D15 are saved in the FTSMX instead of FSTMD format. // // See EHABI #7.5 that explains how matching instruction sequences for load // and store need to be used to correctly restore the exact register bits. bool _use_X_for_vfp_save; // Whether VFP D0-D15 are saved. bool _saved_vfp_d0_d15; // Whether VFPv3 D16-D31 are saved. bool _saved_vfp_d16_d31; // VFP registers D0-D15, + padding if saved using FSTMX unw_fpreg_t _vfp_d0_d15_pad[17]; // VFPv3 registers D16-D31, always saved using FSTMD unw_fpreg_t _vfp_d16_d31[16]; #if defined(__ARM_WMMX) // Whether iWMMX data registers are saved. bool _saved_iwmmx; // Whether iWMMX control registers are saved. mutable bool _saved_iwmmx_control; // iWMMX registers unw_fpreg_t _iwmmx[16]; // iWMMX control registers mutable uint32_t _iwmmx_control[4]; #endif }; inline Registers_arm::Registers_arm(const void *registers) : _use_X_for_vfp_save(false), _saved_vfp_d0_d15(false), _saved_vfp_d16_d31(false) { static_assert((check_fit::does_fit), "arm registers do not fit into unw_context_t"); // See __unw_getcontext() note about data. memcpy(&_registers, registers, sizeof(_registers)); memset(&_pseudo_registers, 0, sizeof(_pseudo_registers)); memset(&_vfp_d0_d15_pad, 0, sizeof(_vfp_d0_d15_pad)); memset(&_vfp_d16_d31, 0, sizeof(_vfp_d16_d31)); #if defined(__ARM_WMMX) _saved_iwmmx = false; _saved_iwmmx_control = false; memset(&_iwmmx, 0, sizeof(_iwmmx)); memset(&_iwmmx_control, 0, sizeof(_iwmmx_control)); #endif } inline Registers_arm::Registers_arm() : _use_X_for_vfp_save(false), _saved_vfp_d0_d15(false), _saved_vfp_d16_d31(false) { memset(&_registers, 0, sizeof(_registers)); memset(&_pseudo_registers, 0, sizeof(_pseudo_registers)); memset(&_vfp_d0_d15_pad, 0, sizeof(_vfp_d0_d15_pad)); memset(&_vfp_d16_d31, 0, sizeof(_vfp_d16_d31)); #if defined(__ARM_WMMX) _saved_iwmmx = false; _saved_iwmmx_control = false; memset(&_iwmmx, 0, sizeof(_iwmmx)); memset(&_iwmmx_control, 0, sizeof(_iwmmx_control)); #endif } inline bool Registers_arm::validRegister(int regNum) const { // Returns true for all non-VFP registers supported by the EHABI // virtual register set (VRS). if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum >= UNW_ARM_R0 && regNum <= UNW_ARM_R15) return true; #if defined(__ARM_WMMX) if (regNum >= UNW_ARM_WC0 && regNum <= UNW_ARM_WC3) return true; #endif #ifdef __ARM_FEATURE_PAUTH if (regNum == UNW_ARM_RA_AUTH_CODE) return true; #endif return false; } inline uint32_t Registers_arm::getRegister(int regNum) const { if (regNum == UNW_REG_SP || regNum == UNW_ARM_SP) return _registers.__sp; if (regNum == UNW_ARM_LR) return _registers.__lr; if (regNum == UNW_REG_IP || regNum == UNW_ARM_IP) return _registers.__pc; if (regNum >= UNW_ARM_R0 && regNum <= UNW_ARM_R12) return _registers.__r[regNum]; #if defined(__ARM_WMMX) if (regNum >= UNW_ARM_WC0 && regNum <= UNW_ARM_WC3) { if (!_saved_iwmmx_control) { _saved_iwmmx_control = true; saveiWMMXControl(_iwmmx_control); } return _iwmmx_control[regNum - UNW_ARM_WC0]; } #endif #ifdef __ARM_FEATURE_PAUTH if (regNum == UNW_ARM_RA_AUTH_CODE) return _pseudo_registers.__pac; #endif _LIBUNWIND_ABORT("unsupported arm register"); } inline void Registers_arm::setRegister(int regNum, uint32_t value) { if (regNum == UNW_REG_SP || regNum == UNW_ARM_SP) { _registers.__sp = value; return; } if (regNum == UNW_ARM_LR) { _registers.__lr = value; return; } if (regNum == UNW_REG_IP || regNum == UNW_ARM_IP) { _registers.__pc = value; return; } if (regNum >= UNW_ARM_R0 && regNum <= UNW_ARM_R12) { _registers.__r[regNum] = value; return; } #if defined(__ARM_WMMX) if (regNum >= UNW_ARM_WC0 && regNum <= UNW_ARM_WC3) { if (!_saved_iwmmx_control) { _saved_iwmmx_control = true; saveiWMMXControl(_iwmmx_control); } _iwmmx_control[regNum - UNW_ARM_WC0] = value; return; } #endif if (regNum == UNW_ARM_RA_AUTH_CODE) { _pseudo_registers.__pac = value; return; } _LIBUNWIND_ABORT("unsupported arm register"); } inline const char *Registers_arm::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: case UNW_ARM_IP: // UNW_ARM_R15 is alias return "pc"; case UNW_ARM_LR: // UNW_ARM_R14 is alias return "lr"; case UNW_REG_SP: case UNW_ARM_SP: // UNW_ARM_R13 is alias return "sp"; case UNW_ARM_R0: return "r0"; case UNW_ARM_R1: return "r1"; case UNW_ARM_R2: return "r2"; case UNW_ARM_R3: return "r3"; case UNW_ARM_R4: return "r4"; case UNW_ARM_R5: return "r5"; case UNW_ARM_R6: return "r6"; case UNW_ARM_R7: return "r7"; case UNW_ARM_R8: return "r8"; case UNW_ARM_R9: return "r9"; case UNW_ARM_R10: return "r10"; case UNW_ARM_R11: return "r11"; case UNW_ARM_R12: return "r12"; case UNW_ARM_S0: return "s0"; case UNW_ARM_S1: return "s1"; case UNW_ARM_S2: return "s2"; case UNW_ARM_S3: return "s3"; case UNW_ARM_S4: return "s4"; case UNW_ARM_S5: return "s5"; case UNW_ARM_S6: return "s6"; case UNW_ARM_S7: return "s7"; case UNW_ARM_S8: return "s8"; case UNW_ARM_S9: return "s9"; case UNW_ARM_S10: return "s10"; case UNW_ARM_S11: return "s11"; case UNW_ARM_S12: return "s12"; case UNW_ARM_S13: return "s13"; case UNW_ARM_S14: return "s14"; case UNW_ARM_S15: return "s15"; case UNW_ARM_S16: return "s16"; case UNW_ARM_S17: return "s17"; case UNW_ARM_S18: return "s18"; case UNW_ARM_S19: return "s19"; case UNW_ARM_S20: return "s20"; case UNW_ARM_S21: return "s21"; case UNW_ARM_S22: return "s22"; case UNW_ARM_S23: return "s23"; case UNW_ARM_S24: return "s24"; case UNW_ARM_S25: return "s25"; case UNW_ARM_S26: return "s26"; case UNW_ARM_S27: return "s27"; case UNW_ARM_S28: return "s28"; case UNW_ARM_S29: return "s29"; case UNW_ARM_S30: return "s30"; case UNW_ARM_S31: return "s31"; case UNW_ARM_D0: return "d0"; case UNW_ARM_D1: return "d1"; case UNW_ARM_D2: return "d2"; case UNW_ARM_D3: return "d3"; case UNW_ARM_D4: return "d4"; case UNW_ARM_D5: return "d5"; case UNW_ARM_D6: return "d6"; case UNW_ARM_D7: return "d7"; case UNW_ARM_D8: return "d8"; case UNW_ARM_D9: return "d9"; case UNW_ARM_D10: return "d10"; case UNW_ARM_D11: return "d11"; case UNW_ARM_D12: return "d12"; case UNW_ARM_D13: return "d13"; case UNW_ARM_D14: return "d14"; case UNW_ARM_D15: return "d15"; case UNW_ARM_D16: return "d16"; case UNW_ARM_D17: return "d17"; case UNW_ARM_D18: return "d18"; case UNW_ARM_D19: return "d19"; case UNW_ARM_D20: return "d20"; case UNW_ARM_D21: return "d21"; case UNW_ARM_D22: return "d22"; case UNW_ARM_D23: return "d23"; case UNW_ARM_D24: return "d24"; case UNW_ARM_D25: return "d25"; case UNW_ARM_D26: return "d26"; case UNW_ARM_D27: return "d27"; case UNW_ARM_D28: return "d28"; case UNW_ARM_D29: return "d29"; case UNW_ARM_D30: return "d30"; case UNW_ARM_D31: return "d31"; default: return "unknown register"; } } inline bool Registers_arm::validFloatRegister(int regNum) const { // NOTE: Consider the intel MMX registers floating points so the // __unw_get_fpreg can be used to transmit the 64-bit data back. return ((regNum >= UNW_ARM_D0) && (regNum <= UNW_ARM_D31)) #if defined(__ARM_WMMX) || ((regNum >= UNW_ARM_WR0) && (regNum <= UNW_ARM_WR15)) #endif ; } inline unw_fpreg_t Registers_arm::getFloatRegister(int regNum) { if (regNum >= UNW_ARM_D0 && regNum <= UNW_ARM_D15) { if (!_saved_vfp_d0_d15) { _saved_vfp_d0_d15 = true; if (_use_X_for_vfp_save) saveVFPWithFSTMX(_vfp_d0_d15_pad); else saveVFPWithFSTMD(_vfp_d0_d15_pad); } return _vfp_d0_d15_pad[regNum - UNW_ARM_D0]; } if (regNum >= UNW_ARM_D16 && regNum <= UNW_ARM_D31) { if (!_saved_vfp_d16_d31) { _saved_vfp_d16_d31 = true; saveVFPv3(_vfp_d16_d31); } return _vfp_d16_d31[regNum - UNW_ARM_D16]; } #if defined(__ARM_WMMX) if (regNum >= UNW_ARM_WR0 && regNum <= UNW_ARM_WR15) { if (!_saved_iwmmx) { _saved_iwmmx = true; saveiWMMX(_iwmmx); } return _iwmmx[regNum - UNW_ARM_WR0]; } #endif _LIBUNWIND_ABORT("Unknown ARM float register"); } inline void Registers_arm::setFloatRegister(int regNum, unw_fpreg_t value) { if (regNum >= UNW_ARM_D0 && regNum <= UNW_ARM_D15) { if (!_saved_vfp_d0_d15) { _saved_vfp_d0_d15 = true; if (_use_X_for_vfp_save) saveVFPWithFSTMX(_vfp_d0_d15_pad); else saveVFPWithFSTMD(_vfp_d0_d15_pad); } _vfp_d0_d15_pad[regNum - UNW_ARM_D0] = value; return; } if (regNum >= UNW_ARM_D16 && regNum <= UNW_ARM_D31) { if (!_saved_vfp_d16_d31) { _saved_vfp_d16_d31 = true; saveVFPv3(_vfp_d16_d31); } _vfp_d16_d31[regNum - UNW_ARM_D16] = value; return; } #if defined(__ARM_WMMX) if (regNum >= UNW_ARM_WR0 && regNum <= UNW_ARM_WR15) { if (!_saved_iwmmx) { _saved_iwmmx = true; saveiWMMX(_iwmmx); } _iwmmx[regNum - UNW_ARM_WR0] = value; return; } #endif _LIBUNWIND_ABORT("Unknown ARM float register"); } inline bool Registers_arm::validVectorRegister(int) const { return false; } inline v128 Registers_arm::getVectorRegister(int) const { _LIBUNWIND_ABORT("ARM vector support not implemented"); } inline void Registers_arm::setVectorRegister(int, v128) { _LIBUNWIND_ABORT("ARM vector support not implemented"); } #endif // _LIBUNWIND_TARGET_ARM #if defined(_LIBUNWIND_TARGET_OR1K) /// Registers_or1k holds the register state of a thread in an OpenRISC1000 /// process. class _LIBUNWIND_HIDDEN Registers_or1k { public: Registers_or1k(); Registers_or1k(const void *registers); bool validRegister(int num) const; uint32_t getRegister(int num) const; void setRegister(int num, uint32_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_OR1K; } static int getArch() { return REGISTERS_OR1K; } uint64_t getSP() const { return _registers.__r[1]; } void setSP(uint32_t value) { _registers.__r[1] = value; } uint64_t getIP() const { return _registers.__pc; } void setIP(uint32_t value) { _registers.__pc = value; } private: struct or1k_thread_state_t { unsigned int __r[32]; // r0-r31 unsigned int __pc; // Program counter unsigned int __epcr; // Program counter at exception }; or1k_thread_state_t _registers; }; inline Registers_or1k::Registers_or1k(const void *registers) { static_assert((check_fit::does_fit), "or1k registers do not fit into unw_context_t"); memcpy(&_registers, static_cast(registers), sizeof(_registers)); } inline Registers_or1k::Registers_or1k() { memset(&_registers, 0, sizeof(_registers)); } inline bool Registers_or1k::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum < 0) return false; if (regNum <= UNW_OR1K_R31) return true; if (regNum == UNW_OR1K_EPCR) return true; return false; } inline uint32_t Registers_or1k::getRegister(int regNum) const { if (regNum >= UNW_OR1K_R0 && regNum <= UNW_OR1K_R31) return _registers.__r[regNum - UNW_OR1K_R0]; switch (regNum) { case UNW_REG_IP: return _registers.__pc; case UNW_REG_SP: return _registers.__r[1]; case UNW_OR1K_EPCR: return _registers.__epcr; } _LIBUNWIND_ABORT("unsupported or1k register"); } inline void Registers_or1k::setRegister(int regNum, uint32_t value) { if (regNum >= UNW_OR1K_R0 && regNum <= UNW_OR1K_R31) { _registers.__r[regNum - UNW_OR1K_R0] = value; return; } switch (regNum) { case UNW_REG_IP: _registers.__pc = value; return; case UNW_REG_SP: _registers.__r[1] = value; return; case UNW_OR1K_EPCR: _registers.__epcr = value; return; } _LIBUNWIND_ABORT("unsupported or1k register"); } inline bool Registers_or1k::validFloatRegister(int /* regNum */) const { return false; } inline double Registers_or1k::getFloatRegister(int /* regNum */) const { _LIBUNWIND_ABORT("or1k float support not implemented"); } inline void Registers_or1k::setFloatRegister(int /* regNum */, double /* value */) { _LIBUNWIND_ABORT("or1k float support not implemented"); } inline bool Registers_or1k::validVectorRegister(int /* regNum */) const { return false; } inline v128 Registers_or1k::getVectorRegister(int /* regNum */) const { _LIBUNWIND_ABORT("or1k vector support not implemented"); } inline void Registers_or1k::setVectorRegister(int /* regNum */, v128 /* value */) { _LIBUNWIND_ABORT("or1k vector support not implemented"); } inline const char *Registers_or1k::getRegisterName(int regNum) { switch (regNum) { case UNW_OR1K_R0: return "r0"; case UNW_OR1K_R1: return "r1"; case UNW_OR1K_R2: return "r2"; case UNW_OR1K_R3: return "r3"; case UNW_OR1K_R4: return "r4"; case UNW_OR1K_R5: return "r5"; case UNW_OR1K_R6: return "r6"; case UNW_OR1K_R7: return "r7"; case UNW_OR1K_R8: return "r8"; case UNW_OR1K_R9: return "r9"; case UNW_OR1K_R10: return "r10"; case UNW_OR1K_R11: return "r11"; case UNW_OR1K_R12: return "r12"; case UNW_OR1K_R13: return "r13"; case UNW_OR1K_R14: return "r14"; case UNW_OR1K_R15: return "r15"; case UNW_OR1K_R16: return "r16"; case UNW_OR1K_R17: return "r17"; case UNW_OR1K_R18: return "r18"; case UNW_OR1K_R19: return "r19"; case UNW_OR1K_R20: return "r20"; case UNW_OR1K_R21: return "r21"; case UNW_OR1K_R22: return "r22"; case UNW_OR1K_R23: return "r23"; case UNW_OR1K_R24: return "r24"; case UNW_OR1K_R25: return "r25"; case UNW_OR1K_R26: return "r26"; case UNW_OR1K_R27: return "r27"; case UNW_OR1K_R28: return "r28"; case UNW_OR1K_R29: return "r29"; case UNW_OR1K_R30: return "r30"; case UNW_OR1K_R31: return "r31"; case UNW_OR1K_EPCR: return "EPCR"; default: return "unknown register"; } } #endif // _LIBUNWIND_TARGET_OR1K #if defined(_LIBUNWIND_TARGET_MIPS_O32) /// Registers_mips_o32 holds the register state of a thread in a 32-bit MIPS /// process. class _LIBUNWIND_HIDDEN Registers_mips_o32 { public: Registers_mips_o32(); Registers_mips_o32(const void *registers); bool validRegister(int num) const; uint32_t getRegister(int num) const; void setRegister(int num, uint32_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_MIPS; } static int getArch() { return REGISTERS_MIPS_O32; } uint32_t getSP() const { return _registers.__r[29]; } void setSP(uint32_t value) { _registers.__r[29] = value; } uint32_t getIP() const { return _registers.__pc; } void setIP(uint32_t value) { _registers.__pc = value; } private: struct mips_o32_thread_state_t { uint32_t __r[32]; uint32_t __pc; uint32_t __hi; uint32_t __lo; }; mips_o32_thread_state_t _registers; #ifdef __mips_hard_float /// O32 with 32-bit floating point registers only uses half of this /// space. However, using the same layout for 32-bit vs 64-bit /// floating point registers results in a single context size for /// O32 with hard float. uint32_t _padding; double _floats[32]; #endif }; inline Registers_mips_o32::Registers_mips_o32(const void *registers) { static_assert((check_fit::does_fit), "mips_o32 registers do not fit into unw_context_t"); memcpy(&_registers, static_cast(registers), sizeof(_registers)); } inline Registers_mips_o32::Registers_mips_o32() { memset(&_registers, 0, sizeof(_registers)); } inline bool Registers_mips_o32::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum < 0) return false; if (regNum <= UNW_MIPS_R31) return true; #if __mips_isa_rev < 6 if (regNum == UNW_MIPS_HI) return true; if (regNum == UNW_MIPS_LO) return true; #endif #if defined(__mips_hard_float) && __mips_fpr == 32 if (regNum >= UNW_MIPS_F0 && regNum <= UNW_MIPS_F31) return true; #endif // FIXME: DSP accumulator registers, MSA registers return false; } inline uint32_t Registers_mips_o32::getRegister(int regNum) const { if (regNum >= UNW_MIPS_R0 && regNum <= UNW_MIPS_R31) return _registers.__r[regNum - UNW_MIPS_R0]; #if defined(__mips_hard_float) && __mips_fpr == 32 if (regNum >= UNW_MIPS_F0 && regNum <= UNW_MIPS_F31) { uint32_t *p; if (regNum % 2 == 0) p = (uint32_t *)&_floats[regNum - UNW_MIPS_F0]; else p = (uint32_t *)&_floats[(regNum - 1) - UNW_MIPS_F0] + 1; return *p; } #endif switch (regNum) { case UNW_REG_IP: return _registers.__pc; case UNW_REG_SP: return _registers.__r[29]; #if __mips_isa_rev < 6 case UNW_MIPS_HI: return _registers.__hi; case UNW_MIPS_LO: return _registers.__lo; #endif } _LIBUNWIND_ABORT("unsupported mips_o32 register"); } inline void Registers_mips_o32::setRegister(int regNum, uint32_t value) { if (regNum >= UNW_MIPS_R0 && regNum <= UNW_MIPS_R31) { _registers.__r[regNum - UNW_MIPS_R0] = value; return; } #if defined(__mips_hard_float) && __mips_fpr == 32 if (regNum >= UNW_MIPS_F0 && regNum <= UNW_MIPS_F31) { uint32_t *p; if (regNum % 2 == 0) p = (uint32_t *)&_floats[regNum - UNW_MIPS_F0]; else p = (uint32_t *)&_floats[(regNum - 1) - UNW_MIPS_F0] + 1; *p = value; return; } #endif switch (regNum) { case UNW_REG_IP: _registers.__pc = value; return; case UNW_REG_SP: _registers.__r[29] = value; return; #if __mips_isa_rev < 6 case UNW_MIPS_HI: _registers.__hi = value; return; case UNW_MIPS_LO: _registers.__lo = value; #endif return; } _LIBUNWIND_ABORT("unsupported mips_o32 register"); } inline bool Registers_mips_o32::validFloatRegister(int regNum) const { #if defined(__mips_hard_float) && __mips_fpr == 64 if (regNum >= UNW_MIPS_F0 && regNum <= UNW_MIPS_F31) return true; #else (void)regNum; #endif return false; } inline double Registers_mips_o32::getFloatRegister(int regNum) const { #if defined(__mips_hard_float) && __mips_fpr == 64 assert(validFloatRegister(regNum)); return _floats[regNum - UNW_MIPS_F0]; #else (void)regNum; _LIBUNWIND_ABORT("mips_o32 float support not implemented"); #endif } inline void Registers_mips_o32::setFloatRegister(int regNum, double value) { #if defined(__mips_hard_float) && __mips_fpr == 64 assert(validFloatRegister(regNum)); _floats[regNum - UNW_MIPS_F0] = value; #else (void)regNum; (void)value; _LIBUNWIND_ABORT("mips_o32 float support not implemented"); #endif } inline bool Registers_mips_o32::validVectorRegister(int /* regNum */) const { return false; } inline v128 Registers_mips_o32::getVectorRegister(int /* regNum */) const { _LIBUNWIND_ABORT("mips_o32 vector support not implemented"); } inline void Registers_mips_o32::setVectorRegister(int /* regNum */, v128 /* value */) { _LIBUNWIND_ABORT("mips_o32 vector support not implemented"); } inline const char *Registers_mips_o32::getRegisterName(int regNum) { switch (regNum) { case UNW_MIPS_R0: return "$0"; case UNW_MIPS_R1: return "$1"; case UNW_MIPS_R2: return "$2"; case UNW_MIPS_R3: return "$3"; case UNW_MIPS_R4: return "$4"; case UNW_MIPS_R5: return "$5"; case UNW_MIPS_R6: return "$6"; case UNW_MIPS_R7: return "$7"; case UNW_MIPS_R8: return "$8"; case UNW_MIPS_R9: return "$9"; case UNW_MIPS_R10: return "$10"; case UNW_MIPS_R11: return "$11"; case UNW_MIPS_R12: return "$12"; case UNW_MIPS_R13: return "$13"; case UNW_MIPS_R14: return "$14"; case UNW_MIPS_R15: return "$15"; case UNW_MIPS_R16: return "$16"; case UNW_MIPS_R17: return "$17"; case UNW_MIPS_R18: return "$18"; case UNW_MIPS_R19: return "$19"; case UNW_MIPS_R20: return "$20"; case UNW_MIPS_R21: return "$21"; case UNW_MIPS_R22: return "$22"; case UNW_MIPS_R23: return "$23"; case UNW_MIPS_R24: return "$24"; case UNW_MIPS_R25: return "$25"; case UNW_MIPS_R26: return "$26"; case UNW_MIPS_R27: return "$27"; case UNW_MIPS_R28: return "$28"; case UNW_MIPS_R29: return "$29"; case UNW_MIPS_R30: return "$30"; case UNW_MIPS_R31: return "$31"; case UNW_MIPS_F0: return "$f0"; case UNW_MIPS_F1: return "$f1"; case UNW_MIPS_F2: return "$f2"; case UNW_MIPS_F3: return "$f3"; case UNW_MIPS_F4: return "$f4"; case UNW_MIPS_F5: return "$f5"; case UNW_MIPS_F6: return "$f6"; case UNW_MIPS_F7: return "$f7"; case UNW_MIPS_F8: return "$f8"; case UNW_MIPS_F9: return "$f9"; case UNW_MIPS_F10: return "$f10"; case UNW_MIPS_F11: return "$f11"; case UNW_MIPS_F12: return "$f12"; case UNW_MIPS_F13: return "$f13"; case UNW_MIPS_F14: return "$f14"; case UNW_MIPS_F15: return "$f15"; case UNW_MIPS_F16: return "$f16"; case UNW_MIPS_F17: return "$f17"; case UNW_MIPS_F18: return "$f18"; case UNW_MIPS_F19: return "$f19"; case UNW_MIPS_F20: return "$f20"; case UNW_MIPS_F21: return "$f21"; case UNW_MIPS_F22: return "$f22"; case UNW_MIPS_F23: return "$f23"; case UNW_MIPS_F24: return "$f24"; case UNW_MIPS_F25: return "$f25"; case UNW_MIPS_F26: return "$f26"; case UNW_MIPS_F27: return "$f27"; case UNW_MIPS_F28: return "$f28"; case UNW_MIPS_F29: return "$f29"; case UNW_MIPS_F30: return "$f30"; case UNW_MIPS_F31: return "$f31"; #if __mips_isa_rev < 6 case UNW_MIPS_HI: return "$hi"; case UNW_MIPS_LO: return "$lo"; #endif default: return "unknown register"; } } #endif // _LIBUNWIND_TARGET_MIPS_O32 #if defined(_LIBUNWIND_TARGET_MIPS_NEWABI) /// Registers_mips_newabi holds the register state of a thread in a /// MIPS process using NEWABI (the N32 or N64 ABIs). class _LIBUNWIND_HIDDEN Registers_mips_newabi { public: Registers_mips_newabi(); Registers_mips_newabi(const void *registers); bool validRegister(int num) const; uint64_t getRegister(int num) const; void setRegister(int num, uint64_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_MIPS; } static int getArch() { return REGISTERS_MIPS_NEWABI; } uint64_t getSP() const { return _registers.__r[29]; } void setSP(uint64_t value) { _registers.__r[29] = value; } uint64_t getIP() const { return _registers.__pc; } void setIP(uint64_t value) { _registers.__pc = value; } private: struct mips_newabi_thread_state_t { uint64_t __r[32]; uint64_t __pc; uint64_t __hi; uint64_t __lo; }; mips_newabi_thread_state_t _registers; #ifdef __mips_hard_float double _floats[32]; #endif }; inline Registers_mips_newabi::Registers_mips_newabi(const void *registers) { static_assert((check_fit::does_fit), "mips_newabi registers do not fit into unw_context_t"); memcpy(&_registers, static_cast(registers), sizeof(_registers)); } inline Registers_mips_newabi::Registers_mips_newabi() { memset(&_registers, 0, sizeof(_registers)); } inline bool Registers_mips_newabi::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum < 0) return false; if (regNum <= UNW_MIPS_R31) return true; #if __mips_isa_rev < 6 if (regNum == UNW_MIPS_HI) return true; if (regNum == UNW_MIPS_LO) return true; #endif // FIXME: Hard float, DSP accumulator registers, MSA registers return false; } inline uint64_t Registers_mips_newabi::getRegister(int regNum) const { if (regNum >= UNW_MIPS_R0 && regNum <= UNW_MIPS_R31) return _registers.__r[regNum - UNW_MIPS_R0]; switch (regNum) { case UNW_REG_IP: return _registers.__pc; case UNW_REG_SP: return _registers.__r[29]; #if __mips_isa_rev < 6 case UNW_MIPS_HI: return _registers.__hi; case UNW_MIPS_LO: return _registers.__lo; #endif } _LIBUNWIND_ABORT("unsupported mips_newabi register"); } inline void Registers_mips_newabi::setRegister(int regNum, uint64_t value) { if (regNum >= UNW_MIPS_R0 && regNum <= UNW_MIPS_R31) { _registers.__r[regNum - UNW_MIPS_R0] = value; return; } switch (regNum) { case UNW_REG_IP: _registers.__pc = value; return; case UNW_REG_SP: _registers.__r[29] = value; return; #if __mips_isa_rev < 6 case UNW_MIPS_HI: _registers.__hi = value; return; case UNW_MIPS_LO: _registers.__lo = value; return; #endif } _LIBUNWIND_ABORT("unsupported mips_newabi register"); } inline bool Registers_mips_newabi::validFloatRegister(int regNum) const { #ifdef __mips_hard_float if (regNum >= UNW_MIPS_F0 && regNum <= UNW_MIPS_F31) return true; #else (void)regNum; #endif return false; } inline double Registers_mips_newabi::getFloatRegister(int regNum) const { #ifdef __mips_hard_float assert(validFloatRegister(regNum)); return _floats[regNum - UNW_MIPS_F0]; #else (void)regNum; _LIBUNWIND_ABORT("mips_newabi float support not implemented"); #endif } inline void Registers_mips_newabi::setFloatRegister(int regNum, double value) { #ifdef __mips_hard_float assert(validFloatRegister(regNum)); _floats[regNum - UNW_MIPS_F0] = value; #else (void)regNum; (void)value; _LIBUNWIND_ABORT("mips_newabi float support not implemented"); #endif } inline bool Registers_mips_newabi::validVectorRegister(int /* regNum */) const { return false; } inline v128 Registers_mips_newabi::getVectorRegister(int /* regNum */) const { _LIBUNWIND_ABORT("mips_newabi vector support not implemented"); } inline void Registers_mips_newabi::setVectorRegister(int /* regNum */, v128 /* value */) { _LIBUNWIND_ABORT("mips_newabi vector support not implemented"); } inline const char *Registers_mips_newabi::getRegisterName(int regNum) { switch (regNum) { case UNW_MIPS_R0: return "$0"; case UNW_MIPS_R1: return "$1"; case UNW_MIPS_R2: return "$2"; case UNW_MIPS_R3: return "$3"; case UNW_MIPS_R4: return "$4"; case UNW_MIPS_R5: return "$5"; case UNW_MIPS_R6: return "$6"; case UNW_MIPS_R7: return "$7"; case UNW_MIPS_R8: return "$8"; case UNW_MIPS_R9: return "$9"; case UNW_MIPS_R10: return "$10"; case UNW_MIPS_R11: return "$11"; case UNW_MIPS_R12: return "$12"; case UNW_MIPS_R13: return "$13"; case UNW_MIPS_R14: return "$14"; case UNW_MIPS_R15: return "$15"; case UNW_MIPS_R16: return "$16"; case UNW_MIPS_R17: return "$17"; case UNW_MIPS_R18: return "$18"; case UNW_MIPS_R19: return "$19"; case UNW_MIPS_R20: return "$20"; case UNW_MIPS_R21: return "$21"; case UNW_MIPS_R22: return "$22"; case UNW_MIPS_R23: return "$23"; case UNW_MIPS_R24: return "$24"; case UNW_MIPS_R25: return "$25"; case UNW_MIPS_R26: return "$26"; case UNW_MIPS_R27: return "$27"; case UNW_MIPS_R28: return "$28"; case UNW_MIPS_R29: return "$29"; case UNW_MIPS_R30: return "$30"; case UNW_MIPS_R31: return "$31"; case UNW_MIPS_F0: return "$f0"; case UNW_MIPS_F1: return "$f1"; case UNW_MIPS_F2: return "$f2"; case UNW_MIPS_F3: return "$f3"; case UNW_MIPS_F4: return "$f4"; case UNW_MIPS_F5: return "$f5"; case UNW_MIPS_F6: return "$f6"; case UNW_MIPS_F7: return "$f7"; case UNW_MIPS_F8: return "$f8"; case UNW_MIPS_F9: return "$f9"; case UNW_MIPS_F10: return "$f10"; case UNW_MIPS_F11: return "$f11"; case UNW_MIPS_F12: return "$f12"; case UNW_MIPS_F13: return "$f13"; case UNW_MIPS_F14: return "$f14"; case UNW_MIPS_F15: return "$f15"; case UNW_MIPS_F16: return "$f16"; case UNW_MIPS_F17: return "$f17"; case UNW_MIPS_F18: return "$f18"; case UNW_MIPS_F19: return "$f19"; case UNW_MIPS_F20: return "$f20"; case UNW_MIPS_F21: return "$f21"; case UNW_MIPS_F22: return "$f22"; case UNW_MIPS_F23: return "$f23"; case UNW_MIPS_F24: return "$f24"; case UNW_MIPS_F25: return "$f25"; case UNW_MIPS_F26: return "$f26"; case UNW_MIPS_F27: return "$f27"; case UNW_MIPS_F28: return "$f28"; case UNW_MIPS_F29: return "$f29"; case UNW_MIPS_F30: return "$f30"; case UNW_MIPS_F31: return "$f31"; #if __mips_isa_rev < 6 case UNW_MIPS_HI: return "$hi"; case UNW_MIPS_LO: return "$lo"; #endif default: return "unknown register"; } } #endif // _LIBUNWIND_TARGET_MIPS_NEWABI #if defined(_LIBUNWIND_TARGET_SPARC) /// Registers_sparc holds the register state of a thread in a 32-bit Sparc /// process. class _LIBUNWIND_HIDDEN Registers_sparc { public: Registers_sparc(); Registers_sparc(const void *registers); bool validRegister(int num) const; uint32_t getRegister(int num) const; void setRegister(int num, uint32_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_SPARC; } static int getArch() { return REGISTERS_SPARC; } uint64_t getSP() const { return _registers.__regs[UNW_SPARC_O6]; } void setSP(uint32_t value) { _registers.__regs[UNW_SPARC_O6] = value; } uint64_t getIP() const { return _registers.__regs[UNW_SPARC_O7]; } void setIP(uint32_t value) { _registers.__regs[UNW_SPARC_O7] = value; } private: struct sparc_thread_state_t { unsigned int __regs[32]; }; sparc_thread_state_t _registers; }; inline Registers_sparc::Registers_sparc(const void *registers) { static_assert((check_fit::does_fit), "sparc registers do not fit into unw_context_t"); memcpy(&_registers, static_cast(registers), sizeof(_registers)); } inline Registers_sparc::Registers_sparc() { memset(&_registers, 0, sizeof(_registers)); } inline bool Registers_sparc::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum < 0) return false; if (regNum <= UNW_SPARC_I7) return true; return false; } inline uint32_t Registers_sparc::getRegister(int regNum) const { if ((UNW_SPARC_G0 <= regNum) && (regNum <= UNW_SPARC_I7)) { return _registers.__regs[regNum]; } switch (regNum) { case UNW_REG_IP: return _registers.__regs[UNW_SPARC_O7]; case UNW_REG_SP: return _registers.__regs[UNW_SPARC_O6]; } _LIBUNWIND_ABORT("unsupported sparc register"); } inline void Registers_sparc::setRegister(int regNum, uint32_t value) { if ((UNW_SPARC_G0 <= regNum) && (regNum <= UNW_SPARC_I7)) { _registers.__regs[regNum] = value; return; } switch (regNum) { case UNW_REG_IP: _registers.__regs[UNW_SPARC_O7] = value; return; case UNW_REG_SP: _registers.__regs[UNW_SPARC_O6] = value; return; } _LIBUNWIND_ABORT("unsupported sparc register"); } inline bool Registers_sparc::validFloatRegister(int) const { return false; } inline double Registers_sparc::getFloatRegister(int) const { _LIBUNWIND_ABORT("no Sparc float registers"); } inline void Registers_sparc::setFloatRegister(int, double) { _LIBUNWIND_ABORT("no Sparc float registers"); } inline bool Registers_sparc::validVectorRegister(int) const { return false; } inline v128 Registers_sparc::getVectorRegister(int) const { _LIBUNWIND_ABORT("no Sparc vector registers"); } inline void Registers_sparc::setVectorRegister(int, v128) { _LIBUNWIND_ABORT("no Sparc vector registers"); } inline const char *Registers_sparc::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "pc"; case UNW_SPARC_G0: return "g0"; case UNW_SPARC_G1: return "g1"; case UNW_SPARC_G2: return "g2"; case UNW_SPARC_G3: return "g3"; case UNW_SPARC_G4: return "g4"; case UNW_SPARC_G5: return "g5"; case UNW_SPARC_G6: return "g6"; case UNW_SPARC_G7: return "g7"; case UNW_SPARC_O0: return "o0"; case UNW_SPARC_O1: return "o1"; case UNW_SPARC_O2: return "o2"; case UNW_SPARC_O3: return "o3"; case UNW_SPARC_O4: return "o4"; case UNW_SPARC_O5: return "o5"; case UNW_REG_SP: case UNW_SPARC_O6: return "sp"; case UNW_SPARC_O7: return "o7"; case UNW_SPARC_L0: return "l0"; case UNW_SPARC_L1: return "l1"; case UNW_SPARC_L2: return "l2"; case UNW_SPARC_L3: return "l3"; case UNW_SPARC_L4: return "l4"; case UNW_SPARC_L5: return "l5"; case UNW_SPARC_L6: return "l6"; case UNW_SPARC_L7: return "l7"; case UNW_SPARC_I0: return "i0"; case UNW_SPARC_I1: return "i1"; case UNW_SPARC_I2: return "i2"; case UNW_SPARC_I3: return "i3"; case UNW_SPARC_I4: return "i4"; case UNW_SPARC_I5: return "i5"; case UNW_SPARC_I6: return "fp"; case UNW_SPARC_I7: return "i7"; default: return "unknown register"; } } #endif // _LIBUNWIND_TARGET_SPARC #if defined(_LIBUNWIND_TARGET_SPARC64) /// Registers_sparc64 holds the register state of a thread in a 64-bit /// sparc process. class _LIBUNWIND_HIDDEN Registers_sparc64 { public: Registers_sparc64() = default; Registers_sparc64(const void *registers); bool validRegister(int num) const; uint64_t getRegister(int num) const; void setRegister(int num, uint64_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_SPARC64; } static int getArch() { return REGISTERS_SPARC64; } uint64_t getSP() const { return _registers.__regs[UNW_SPARC_O6] + 2047; } void setSP(uint64_t value) { _registers.__regs[UNW_SPARC_O6] = value - 2047; } uint64_t getIP() const { return _registers.__regs[UNW_SPARC_O7]; } void setIP(uint64_t value) { _registers.__regs[UNW_SPARC_O7] = value; } uint64_t getWCookie() const { return _wcookie; } private: struct sparc64_thread_state_t { uint64_t __regs[32]; }; sparc64_thread_state_t _registers{}; uint64_t _wcookie = 0; }; inline Registers_sparc64::Registers_sparc64(const void *registers) { static_assert((check_fit::does_fit), "sparc64 registers do not fit into unw_context_t"); memcpy(&_registers, registers, sizeof(_registers)); memcpy(&_wcookie, static_cast(registers) + sizeof(_registers), sizeof(_wcookie)); } inline bool Registers_sparc64::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum < 0) return false; if (regNum <= UNW_SPARC_I7) return true; return false; } inline uint64_t Registers_sparc64::getRegister(int regNum) const { if (regNum >= UNW_SPARC_G0 && regNum <= UNW_SPARC_I7) return _registers.__regs[regNum]; switch (regNum) { case UNW_REG_IP: return _registers.__regs[UNW_SPARC_O7]; case UNW_REG_SP: return _registers.__regs[UNW_SPARC_O6] + 2047; } _LIBUNWIND_ABORT("unsupported sparc64 register"); } inline void Registers_sparc64::setRegister(int regNum, uint64_t value) { if (regNum >= UNW_SPARC_G0 && regNum <= UNW_SPARC_I7) { _registers.__regs[regNum] = value; return; } switch (regNum) { case UNW_REG_IP: _registers.__regs[UNW_SPARC_O7] = value; return; case UNW_REG_SP: _registers.__regs[UNW_SPARC_O6] = value - 2047; return; } _LIBUNWIND_ABORT("unsupported sparc64 register"); } inline bool Registers_sparc64::validFloatRegister(int) const { return false; } inline double Registers_sparc64::getFloatRegister(int) const { _LIBUNWIND_ABORT("no sparc64 float registers"); } inline void Registers_sparc64::setFloatRegister(int, double) { _LIBUNWIND_ABORT("no sparc64 float registers"); } inline bool Registers_sparc64::validVectorRegister(int) const { return false; } inline v128 Registers_sparc64::getVectorRegister(int) const { _LIBUNWIND_ABORT("no sparc64 vector registers"); } inline void Registers_sparc64::setVectorRegister(int, v128) { _LIBUNWIND_ABORT("no sparc64 vector registers"); } inline const char *Registers_sparc64::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "pc"; case UNW_SPARC_G0: return "g0"; case UNW_SPARC_G1: return "g1"; case UNW_SPARC_G2: return "g2"; case UNW_SPARC_G3: return "g3"; case UNW_SPARC_G4: return "g4"; case UNW_SPARC_G5: return "g5"; case UNW_SPARC_G6: return "g6"; case UNW_SPARC_G7: return "g7"; case UNW_SPARC_O0: return "o0"; case UNW_SPARC_O1: return "o1"; case UNW_SPARC_O2: return "o2"; case UNW_SPARC_O3: return "o3"; case UNW_SPARC_O4: return "o4"; case UNW_SPARC_O5: return "o5"; case UNW_REG_SP: case UNW_SPARC_O6: return "o6"; case UNW_SPARC_O7: return "o7"; case UNW_SPARC_L0: return "l0"; case UNW_SPARC_L1: return "l1"; case UNW_SPARC_L2: return "l2"; case UNW_SPARC_L3: return "l3"; case UNW_SPARC_L4: return "l4"; case UNW_SPARC_L5: return "l5"; case UNW_SPARC_L6: return "l6"; case UNW_SPARC_L7: return "l7"; case UNW_SPARC_I0: return "i0"; case UNW_SPARC_I1: return "i1"; case UNW_SPARC_I2: return "i2"; case UNW_SPARC_I3: return "i3"; case UNW_SPARC_I4: return "i4"; case UNW_SPARC_I5: return "i5"; case UNW_SPARC_I6: return "i6"; case UNW_SPARC_I7: return "i7"; default: return "unknown register"; } } #endif // _LIBUNWIND_TARGET_SPARC64 #if defined(_LIBUNWIND_TARGET_HEXAGON) /// Registers_hexagon holds the register state of a thread in a Hexagon QDSP6 /// process. class _LIBUNWIND_HIDDEN Registers_hexagon { public: Registers_hexagon(); Registers_hexagon(const void *registers); bool validRegister(int num) const; uint32_t getRegister(int num) const; void setRegister(int num, uint32_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_HEXAGON; } static int getArch() { return REGISTERS_HEXAGON; } uint32_t getSP() const { return _registers.__r[UNW_HEXAGON_R29]; } void setSP(uint32_t value) { _registers.__r[UNW_HEXAGON_R29] = value; } uint32_t getIP() const { return _registers.__r[UNW_HEXAGON_PC]; } void setIP(uint32_t value) { _registers.__r[UNW_HEXAGON_PC] = value; } private: struct hexagon_thread_state_t { unsigned int __r[35]; }; hexagon_thread_state_t _registers; }; inline Registers_hexagon::Registers_hexagon(const void *registers) { static_assert((check_fit::does_fit), "hexagon registers do not fit into unw_context_t"); memcpy(&_registers, static_cast(registers), sizeof(_registers)); } inline Registers_hexagon::Registers_hexagon() { memset(&_registers, 0, sizeof(_registers)); } inline bool Registers_hexagon::validRegister(int regNum) const { if (regNum <= UNW_HEXAGON_R31) return true; return false; } inline uint32_t Registers_hexagon::getRegister(int regNum) const { if (regNum >= UNW_HEXAGON_R0 && regNum <= UNW_HEXAGON_R31) return _registers.__r[regNum - UNW_HEXAGON_R0]; switch (regNum) { case UNW_REG_IP: return _registers.__r[UNW_HEXAGON_PC]; case UNW_REG_SP: return _registers.__r[UNW_HEXAGON_R29]; } _LIBUNWIND_ABORT("unsupported hexagon register"); } inline void Registers_hexagon::setRegister(int regNum, uint32_t value) { if (regNum >= UNW_HEXAGON_R0 && regNum <= UNW_HEXAGON_R31) { _registers.__r[regNum - UNW_HEXAGON_R0] = value; return; } switch (regNum) { case UNW_REG_IP: _registers.__r[UNW_HEXAGON_PC] = value; return; case UNW_REG_SP: _registers.__r[UNW_HEXAGON_R29] = value; return; } _LIBUNWIND_ABORT("unsupported hexagon register"); } inline bool Registers_hexagon::validFloatRegister(int /* regNum */) const { return false; } inline double Registers_hexagon::getFloatRegister(int /* regNum */) const { _LIBUNWIND_ABORT("hexagon float support not implemented"); } inline void Registers_hexagon::setFloatRegister(int /* regNum */, double /* value */) { _LIBUNWIND_ABORT("hexagon float support not implemented"); } inline bool Registers_hexagon::validVectorRegister(int /* regNum */) const { return false; } inline v128 Registers_hexagon::getVectorRegister(int /* regNum */) const { _LIBUNWIND_ABORT("hexagon vector support not implemented"); } inline void Registers_hexagon::setVectorRegister(int /* regNum */, v128 /* value */) { _LIBUNWIND_ABORT("hexagon vector support not implemented"); } inline const char *Registers_hexagon::getRegisterName(int regNum) { switch (regNum) { case UNW_HEXAGON_R0: return "r0"; case UNW_HEXAGON_R1: return "r1"; case UNW_HEXAGON_R2: return "r2"; case UNW_HEXAGON_R3: return "r3"; case UNW_HEXAGON_R4: return "r4"; case UNW_HEXAGON_R5: return "r5"; case UNW_HEXAGON_R6: return "r6"; case UNW_HEXAGON_R7: return "r7"; case UNW_HEXAGON_R8: return "r8"; case UNW_HEXAGON_R9: return "r9"; case UNW_HEXAGON_R10: return "r10"; case UNW_HEXAGON_R11: return "r11"; case UNW_HEXAGON_R12: return "r12"; case UNW_HEXAGON_R13: return "r13"; case UNW_HEXAGON_R14: return "r14"; case UNW_HEXAGON_R15: return "r15"; case UNW_HEXAGON_R16: return "r16"; case UNW_HEXAGON_R17: return "r17"; case UNW_HEXAGON_R18: return "r18"; case UNW_HEXAGON_R19: return "r19"; case UNW_HEXAGON_R20: return "r20"; case UNW_HEXAGON_R21: return "r21"; case UNW_HEXAGON_R22: return "r22"; case UNW_HEXAGON_R23: return "r23"; case UNW_HEXAGON_R24: return "r24"; case UNW_HEXAGON_R25: return "r25"; case UNW_HEXAGON_R26: return "r26"; case UNW_HEXAGON_R27: return "r27"; case UNW_HEXAGON_R28: return "r28"; case UNW_HEXAGON_R29: return "r29"; case UNW_HEXAGON_R30: return "r30"; case UNW_HEXAGON_R31: return "r31"; default: return "unknown register"; } } #endif // _LIBUNWIND_TARGET_HEXAGON #if defined(_LIBUNWIND_TARGET_RISCV) /// Registers_riscv holds the register state of a thread in a RISC-V /// process. // This check makes it safe when LIBUNWIND_ENABLE_CROSS_UNWINDING enabled. # ifdef __riscv # if __riscv_xlen == 32 typedef uint32_t reg_t; # elif __riscv_xlen == 64 typedef uint64_t reg_t; # else # error "Unsupported __riscv_xlen" # endif # if defined(__riscv_flen) # if __riscv_flen == 64 typedef double fp_t; # elif __riscv_flen == 32 typedef float fp_t; # else # error "Unsupported __riscv_flen" # endif # else // This is just for suppressing undeclared error of fp_t. typedef double fp_t; # endif # else // Use Max possible width when cross unwinding typedef uint64_t reg_t; typedef double fp_t; # define __riscv_xlen 64 # define __riscv_flen 64 #endif /// Registers_riscv holds the register state of a thread. class _LIBUNWIND_HIDDEN Registers_riscv { public: Registers_riscv(); Registers_riscv(const void *registers); bool validRegister(int num) const; reg_t getRegister(int num) const; void setRegister(int num, reg_t value); bool validFloatRegister(int num) const; fp_t getFloatRegister(int num) const; void setFloatRegister(int num, fp_t value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_RISCV; } static int getArch() { return REGISTERS_RISCV; } reg_t getSP() const { return _registers[2]; } void setSP(reg_t value) { _registers[2] = value; } reg_t getIP() const { return _registers[0]; } void setIP(reg_t value) { _registers[0] = value; } private: // _registers[0] holds the pc reg_t _registers[32]; # if defined(__riscv_flen) fp_t _floats[32]; # endif }; inline Registers_riscv::Registers_riscv(const void *registers) { static_assert((check_fit::does_fit), "riscv registers do not fit into unw_context_t"); memcpy(&_registers, registers, sizeof(_registers)); # if __riscv_xlen == 32 static_assert(sizeof(_registers) == 0x80, "expected float registers to be at offset 128"); # elif __riscv_xlen == 64 static_assert(sizeof(_registers) == 0x100, "expected float registers to be at offset 256"); # else # error "Unexpected float registers." # endif # if defined(__riscv_flen) memcpy(_floats, static_cast(registers) + sizeof(_registers), sizeof(_floats)); # endif } inline Registers_riscv::Registers_riscv() { memset(&_registers, 0, sizeof(_registers)); # if defined(__riscv_flen) memset(&_floats, 0, sizeof(_floats)); # endif } inline bool Registers_riscv::validRegister(int regNum) const { if (regNum == UNW_REG_IP) return true; if (regNum == UNW_REG_SP) return true; if (regNum < 0) return false; if (regNum == UNW_RISCV_VLENB) return true; if (regNum > UNW_RISCV_F31) return false; return true; } inline reg_t Registers_riscv::getRegister(int regNum) const { if (regNum == UNW_REG_IP) return _registers[0]; if (regNum == UNW_REG_SP) return _registers[2]; if (regNum == UNW_RISCV_X0) return 0; if ((regNum > 0) && (regNum < 32)) return _registers[regNum]; if (regNum == UNW_RISCV_VLENB) { reg_t vlenb; __asm__("csrr %0, 0xC22" : "=r"(vlenb)); return vlenb; } _LIBUNWIND_ABORT("unsupported riscv register"); } inline void Registers_riscv::setRegister(int regNum, reg_t value) { if (regNum == UNW_REG_IP) _registers[0] = value; else if (regNum == UNW_REG_SP) _registers[2] = value; else if (regNum == UNW_RISCV_X0) /* x0 is hardwired to zero */ return; else if ((regNum > 0) && (regNum < 32)) _registers[regNum] = value; else _LIBUNWIND_ABORT("unsupported riscv register"); } inline const char *Registers_riscv::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "pc"; case UNW_REG_SP: return "sp"; case UNW_RISCV_X0: return "zero"; case UNW_RISCV_X1: return "ra"; case UNW_RISCV_X2: return "sp"; case UNW_RISCV_X3: return "gp"; case UNW_RISCV_X4: return "tp"; case UNW_RISCV_X5: return "t0"; case UNW_RISCV_X6: return "t1"; case UNW_RISCV_X7: return "t2"; case UNW_RISCV_X8: return "s0"; case UNW_RISCV_X9: return "s1"; case UNW_RISCV_X10: return "a0"; case UNW_RISCV_X11: return "a1"; case UNW_RISCV_X12: return "a2"; case UNW_RISCV_X13: return "a3"; case UNW_RISCV_X14: return "a4"; case UNW_RISCV_X15: return "a5"; case UNW_RISCV_X16: return "a6"; case UNW_RISCV_X17: return "a7"; case UNW_RISCV_X18: return "s2"; case UNW_RISCV_X19: return "s3"; case UNW_RISCV_X20: return "s4"; case UNW_RISCV_X21: return "s5"; case UNW_RISCV_X22: return "s6"; case UNW_RISCV_X23: return "s7"; case UNW_RISCV_X24: return "s8"; case UNW_RISCV_X25: return "s9"; case UNW_RISCV_X26: return "s10"; case UNW_RISCV_X27: return "s11"; case UNW_RISCV_X28: return "t3"; case UNW_RISCV_X29: return "t4"; case UNW_RISCV_X30: return "t5"; case UNW_RISCV_X31: return "t6"; case UNW_RISCV_F0: return "ft0"; case UNW_RISCV_F1: return "ft1"; case UNW_RISCV_F2: return "ft2"; case UNW_RISCV_F3: return "ft3"; case UNW_RISCV_F4: return "ft4"; case UNW_RISCV_F5: return "ft5"; case UNW_RISCV_F6: return "ft6"; case UNW_RISCV_F7: return "ft7"; case UNW_RISCV_F8: return "fs0"; case UNW_RISCV_F9: return "fs1"; case UNW_RISCV_F10: return "fa0"; case UNW_RISCV_F11: return "fa1"; case UNW_RISCV_F12: return "fa2"; case UNW_RISCV_F13: return "fa3"; case UNW_RISCV_F14: return "fa4"; case UNW_RISCV_F15: return "fa5"; case UNW_RISCV_F16: return "fa6"; case UNW_RISCV_F17: return "fa7"; case UNW_RISCV_F18: return "fs2"; case UNW_RISCV_F19: return "fs3"; case UNW_RISCV_F20: return "fs4"; case UNW_RISCV_F21: return "fs5"; case UNW_RISCV_F22: return "fs6"; case UNW_RISCV_F23: return "fs7"; case UNW_RISCV_F24: return "fs8"; case UNW_RISCV_F25: return "fs9"; case UNW_RISCV_F26: return "fs10"; case UNW_RISCV_F27: return "fs11"; case UNW_RISCV_F28: return "ft8"; case UNW_RISCV_F29: return "ft9"; case UNW_RISCV_F30: return "ft10"; case UNW_RISCV_F31: return "ft11"; case UNW_RISCV_VLENB: return "vlenb"; default: return "unknown register"; } } inline bool Registers_riscv::validFloatRegister(int regNum) const { # if defined(__riscv_flen) if (regNum < UNW_RISCV_F0) return false; if (regNum > UNW_RISCV_F31) return false; return true; # else (void)regNum; return false; # endif } inline fp_t Registers_riscv::getFloatRegister(int regNum) const { # if defined(__riscv_flen) assert(validFloatRegister(regNum)); return _floats[regNum - UNW_RISCV_F0]; # else (void)regNum; _LIBUNWIND_ABORT("libunwind not built with float support"); # endif } inline void Registers_riscv::setFloatRegister(int regNum, fp_t value) { # if defined(__riscv_flen) assert(validFloatRegister(regNum)); _floats[regNum - UNW_RISCV_F0] = value; # else (void)regNum; (void)value; _LIBUNWIND_ABORT("libunwind not built with float support"); # endif } inline bool Registers_riscv::validVectorRegister(int) const { return false; } inline v128 Registers_riscv::getVectorRegister(int) const { _LIBUNWIND_ABORT("no riscv vector register support yet"); } inline void Registers_riscv::setVectorRegister(int, v128) { _LIBUNWIND_ABORT("no riscv vector register support yet"); } #endif // _LIBUNWIND_TARGET_RISCV #if defined(_LIBUNWIND_TARGET_VE) /// Registers_ve holds the register state of a thread in a VE process. class _LIBUNWIND_HIDDEN Registers_ve { public: Registers_ve(); Registers_ve(const void *registers); bool validRegister(int num) const; uint64_t getRegister(int num) const; void setRegister(int num, uint64_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_VE; } static int getArch() { return REGISTERS_VE; } uint64_t getSP() const { return _registers.__s[11]; } void setSP(uint64_t value) { _registers.__s[11] = value; } uint64_t getIP() const { return _registers.__ic; } void setIP(uint64_t value) { _registers.__ic = value; } private: // FIXME: Need to store not only scalar registers but also vector and vector // mask registers. VEOS uses mcontext_t defined in ucontext.h. It takes // 524288 bytes (65536*8 bytes), though. Currently, we use libunwind for // SjLj exception support only, so Registers_ve is not implemented completely. struct ve_thread_state_t { uint64_t __s[64]; // s0-s64 uint64_t __ic; // Instruction counter (IC) uint64_t __vixr; // Vector Index Register uint64_t __vl; // Vector Length Register }; ve_thread_state_t _registers; // total 67 registers // Currently no vector register is preserved. }; inline Registers_ve::Registers_ve(const void *registers) { static_assert((check_fit::does_fit), "ve registers do not fit into unw_context_t"); memcpy(&_registers, static_cast(registers), sizeof(_registers)); static_assert(sizeof(_registers) == 536, "expected vector register offset to be 536"); } inline Registers_ve::Registers_ve() { memset(&_registers, 0, sizeof(_registers)); } inline bool Registers_ve::validRegister(int regNum) const { if (regNum >= UNW_VE_S0 && regNum <= UNW_VE_S63) return true; switch (regNum) { case UNW_REG_IP: case UNW_REG_SP: case UNW_VE_VIXR: case UNW_VE_VL: return true; default: return false; } } inline uint64_t Registers_ve::getRegister(int regNum) const { if (regNum >= UNW_VE_S0 && regNum <= UNW_VE_S63) return _registers.__s[regNum - UNW_VE_S0]; switch (regNum) { case UNW_REG_IP: return _registers.__ic; case UNW_REG_SP: return _registers.__s[11]; case UNW_VE_VIXR: return _registers.__vixr; case UNW_VE_VL: return _registers.__vl; } _LIBUNWIND_ABORT("unsupported ve register"); } inline void Registers_ve::setRegister(int regNum, uint64_t value) { if (regNum >= UNW_VE_S0 && regNum <= UNW_VE_S63) { _registers.__s[regNum - UNW_VE_S0] = value; return; } switch (regNum) { case UNW_REG_IP: _registers.__ic = value; return; case UNW_REG_SP: _registers.__s[11] = value; return; case UNW_VE_VIXR: _registers.__vixr = value; return; case UNW_VE_VL: _registers.__vl = value; return; } _LIBUNWIND_ABORT("unsupported ve register"); } inline bool Registers_ve::validFloatRegister(int /* regNum */) const { return false; } inline double Registers_ve::getFloatRegister(int /* regNum */) const { _LIBUNWIND_ABORT("VE doesn't have float registers"); } inline void Registers_ve::setFloatRegister(int /* regNum */, double /* value */) { _LIBUNWIND_ABORT("VE doesn't have float registers"); } inline bool Registers_ve::validVectorRegister(int /* regNum */) const { return false; } inline v128 Registers_ve::getVectorRegister(int /* regNum */) const { _LIBUNWIND_ABORT("VE vector support not implemented"); } inline void Registers_ve::setVectorRegister(int /* regNum */, v128 /* value */) { _LIBUNWIND_ABORT("VE vector support not implemented"); } inline const char *Registers_ve::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "ip"; case UNW_REG_SP: return "sp"; case UNW_VE_VIXR: return "vixr"; case UNW_VE_VL: return "vl"; case UNW_VE_S0: return "s0"; case UNW_VE_S1: return "s1"; case UNW_VE_S2: return "s2"; case UNW_VE_S3: return "s3"; case UNW_VE_S4: return "s4"; case UNW_VE_S5: return "s5"; case UNW_VE_S6: return "s6"; case UNW_VE_S7: return "s7"; case UNW_VE_S8: return "s8"; case UNW_VE_S9: return "s9"; case UNW_VE_S10: return "s10"; case UNW_VE_S11: return "s11"; case UNW_VE_S12: return "s12"; case UNW_VE_S13: return "s13"; case UNW_VE_S14: return "s14"; case UNW_VE_S15: return "s15"; case UNW_VE_S16: return "s16"; case UNW_VE_S17: return "s17"; case UNW_VE_S18: return "s18"; case UNW_VE_S19: return "s19"; case UNW_VE_S20: return "s20"; case UNW_VE_S21: return "s21"; case UNW_VE_S22: return "s22"; case UNW_VE_S23: return "s23"; case UNW_VE_S24: return "s24"; case UNW_VE_S25: return "s25"; case UNW_VE_S26: return "s26"; case UNW_VE_S27: return "s27"; case UNW_VE_S28: return "s28"; case UNW_VE_S29: return "s29"; case UNW_VE_S30: return "s30"; case UNW_VE_S31: return "s31"; case UNW_VE_S32: return "s32"; case UNW_VE_S33: return "s33"; case UNW_VE_S34: return "s34"; case UNW_VE_S35: return "s35"; case UNW_VE_S36: return "s36"; case UNW_VE_S37: return "s37"; case UNW_VE_S38: return "s38"; case UNW_VE_S39: return "s39"; case UNW_VE_S40: return "s40"; case UNW_VE_S41: return "s41"; case UNW_VE_S42: return "s42"; case UNW_VE_S43: return "s43"; case UNW_VE_S44: return "s44"; case UNW_VE_S45: return "s45"; case UNW_VE_S46: return "s46"; case UNW_VE_S47: return "s47"; case UNW_VE_S48: return "s48"; case UNW_VE_S49: return "s49"; case UNW_VE_S50: return "s50"; case UNW_VE_S51: return "s51"; case UNW_VE_S52: return "s52"; case UNW_VE_S53: return "s53"; case UNW_VE_S54: return "s54"; case UNW_VE_S55: return "s55"; case UNW_VE_S56: return "s56"; case UNW_VE_S57: return "s57"; case UNW_VE_S58: return "s58"; case UNW_VE_S59: return "s59"; case UNW_VE_S60: return "s60"; case UNW_VE_S61: return "s61"; case UNW_VE_S62: return "s62"; case UNW_VE_S63: return "s63"; case UNW_VE_V0: return "v0"; case UNW_VE_V1: return "v1"; case UNW_VE_V2: return "v2"; case UNW_VE_V3: return "v3"; case UNW_VE_V4: return "v4"; case UNW_VE_V5: return "v5"; case UNW_VE_V6: return "v6"; case UNW_VE_V7: return "v7"; case UNW_VE_V8: return "v8"; case UNW_VE_V9: return "v9"; case UNW_VE_V10: return "v10"; case UNW_VE_V11: return "v11"; case UNW_VE_V12: return "v12"; case UNW_VE_V13: return "v13"; case UNW_VE_V14: return "v14"; case UNW_VE_V15: return "v15"; case UNW_VE_V16: return "v16"; case UNW_VE_V17: return "v17"; case UNW_VE_V18: return "v18"; case UNW_VE_V19: return "v19"; case UNW_VE_V20: return "v20"; case UNW_VE_V21: return "v21"; case UNW_VE_V22: return "v22"; case UNW_VE_V23: return "v23"; case UNW_VE_V24: return "v24"; case UNW_VE_V25: return "v25"; case UNW_VE_V26: return "v26"; case UNW_VE_V27: return "v27"; case UNW_VE_V28: return "v28"; case UNW_VE_V29: return "v29"; case UNW_VE_V30: return "v30"; case UNW_VE_V31: return "v31"; case UNW_VE_V32: return "v32"; case UNW_VE_V33: return "v33"; case UNW_VE_V34: return "v34"; case UNW_VE_V35: return "v35"; case UNW_VE_V36: return "v36"; case UNW_VE_V37: return "v37"; case UNW_VE_V38: return "v38"; case UNW_VE_V39: return "v39"; case UNW_VE_V40: return "v40"; case UNW_VE_V41: return "v41"; case UNW_VE_V42: return "v42"; case UNW_VE_V43: return "v43"; case UNW_VE_V44: return "v44"; case UNW_VE_V45: return "v45"; case UNW_VE_V46: return "v46"; case UNW_VE_V47: return "v47"; case UNW_VE_V48: return "v48"; case UNW_VE_V49: return "v49"; case UNW_VE_V50: return "v50"; case UNW_VE_V51: return "v51"; case UNW_VE_V52: return "v52"; case UNW_VE_V53: return "v53"; case UNW_VE_V54: return "v54"; case UNW_VE_V55: return "v55"; case UNW_VE_V56: return "v56"; case UNW_VE_V57: return "v57"; case UNW_VE_V58: return "v58"; case UNW_VE_V59: return "v59"; case UNW_VE_V60: return "v60"; case UNW_VE_V61: return "v61"; case UNW_VE_V62: return "v62"; case UNW_VE_V63: return "v63"; case UNW_VE_VM0: return "vm0"; case UNW_VE_VM1: return "vm1"; case UNW_VE_VM2: return "vm2"; case UNW_VE_VM3: return "vm3"; case UNW_VE_VM4: return "vm4"; case UNW_VE_VM5: return "vm5"; case UNW_VE_VM6: return "vm6"; case UNW_VE_VM7: return "vm7"; case UNW_VE_VM8: return "vm8"; case UNW_VE_VM9: return "vm9"; case UNW_VE_VM10: return "vm10"; case UNW_VE_VM11: return "vm11"; case UNW_VE_VM12: return "vm12"; case UNW_VE_VM13: return "vm13"; case UNW_VE_VM14: return "vm14"; case UNW_VE_VM15: return "vm15"; } return "unknown register"; } #endif // _LIBUNWIND_TARGET_VE #if defined(_LIBUNWIND_TARGET_S390X) /// Registers_s390x holds the register state of a thread in a /// 64-bit Linux on IBM zSystems process. class _LIBUNWIND_HIDDEN Registers_s390x { public: Registers_s390x(); Registers_s390x(const void *registers); bool validRegister(int num) const; uint64_t getRegister(int num) const; void setRegister(int num, uint64_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_S390X; } static int getArch() { return REGISTERS_S390X; } uint64_t getSP() const { return _registers.__gpr[15]; } void setSP(uint64_t value) { _registers.__gpr[15] = value; } uint64_t getIP() const { return _registers.__pswa; } void setIP(uint64_t value) { _registers.__pswa = value; } private: struct s390x_thread_state_t { uint64_t __pswm; // Problem Status Word: Mask uint64_t __pswa; // Problem Status Word: Address (PC) uint64_t __gpr[16]; // General Purpose Registers double __fpr[16]; // Floating-Point Registers }; s390x_thread_state_t _registers; }; inline Registers_s390x::Registers_s390x(const void *registers) { static_assert((check_fit::does_fit), "s390x registers do not fit into unw_context_t"); memcpy(&_registers, static_cast(registers), sizeof(_registers)); } inline Registers_s390x::Registers_s390x() { memset(&_registers, 0, sizeof(_registers)); } inline bool Registers_s390x::validRegister(int regNum) const { switch (regNum) { case UNW_S390X_PSWM: case UNW_S390X_PSWA: case UNW_REG_IP: case UNW_REG_SP: return true; } if (regNum >= UNW_S390X_R0 && regNum <= UNW_S390X_R15) return true; return false; } inline uint64_t Registers_s390x::getRegister(int regNum) const { if (regNum >= UNW_S390X_R0 && regNum <= UNW_S390X_R15) return _registers.__gpr[regNum - UNW_S390X_R0]; switch (regNum) { case UNW_S390X_PSWM: return _registers.__pswm; case UNW_S390X_PSWA: case UNW_REG_IP: return _registers.__pswa; case UNW_REG_SP: return _registers.__gpr[15]; } _LIBUNWIND_ABORT("unsupported s390x register"); } inline void Registers_s390x::setRegister(int regNum, uint64_t value) { if (regNum >= UNW_S390X_R0 && regNum <= UNW_S390X_R15) { _registers.__gpr[regNum - UNW_S390X_R0] = value; return; } switch (regNum) { case UNW_S390X_PSWM: _registers.__pswm = value; return; case UNW_S390X_PSWA: case UNW_REG_IP: _registers.__pswa = value; return; case UNW_REG_SP: _registers.__gpr[15] = value; return; } _LIBUNWIND_ABORT("unsupported s390x register"); } inline bool Registers_s390x::validFloatRegister(int regNum) const { return regNum >= UNW_S390X_F0 && regNum <= UNW_S390X_F15; } inline double Registers_s390x::getFloatRegister(int regNum) const { // NOTE: FPR DWARF register numbers are not consecutive. switch (regNum) { case UNW_S390X_F0: return _registers.__fpr[0]; case UNW_S390X_F1: return _registers.__fpr[1]; case UNW_S390X_F2: return _registers.__fpr[2]; case UNW_S390X_F3: return _registers.__fpr[3]; case UNW_S390X_F4: return _registers.__fpr[4]; case UNW_S390X_F5: return _registers.__fpr[5]; case UNW_S390X_F6: return _registers.__fpr[6]; case UNW_S390X_F7: return _registers.__fpr[7]; case UNW_S390X_F8: return _registers.__fpr[8]; case UNW_S390X_F9: return _registers.__fpr[9]; case UNW_S390X_F10: return _registers.__fpr[10]; case UNW_S390X_F11: return _registers.__fpr[11]; case UNW_S390X_F12: return _registers.__fpr[12]; case UNW_S390X_F13: return _registers.__fpr[13]; case UNW_S390X_F14: return _registers.__fpr[14]; case UNW_S390X_F15: return _registers.__fpr[15]; } _LIBUNWIND_ABORT("unsupported s390x register"); } inline void Registers_s390x::setFloatRegister(int regNum, double value) { // NOTE: FPR DWARF register numbers are not consecutive. switch (regNum) { case UNW_S390X_F0: _registers.__fpr[0] = value; return; case UNW_S390X_F1: _registers.__fpr[1] = value; return; case UNW_S390X_F2: _registers.__fpr[2] = value; return; case UNW_S390X_F3: _registers.__fpr[3] = value; return; case UNW_S390X_F4: _registers.__fpr[4] = value; return; case UNW_S390X_F5: _registers.__fpr[5] = value; return; case UNW_S390X_F6: _registers.__fpr[6] = value; return; case UNW_S390X_F7: _registers.__fpr[7] = value; return; case UNW_S390X_F8: _registers.__fpr[8] = value; return; case UNW_S390X_F9: _registers.__fpr[9] = value; return; case UNW_S390X_F10: _registers.__fpr[10] = value; return; case UNW_S390X_F11: _registers.__fpr[11] = value; return; case UNW_S390X_F12: _registers.__fpr[12] = value; return; case UNW_S390X_F13: _registers.__fpr[13] = value; return; case UNW_S390X_F14: _registers.__fpr[14] = value; return; case UNW_S390X_F15: _registers.__fpr[15] = value; return; } _LIBUNWIND_ABORT("unsupported s390x register"); } inline bool Registers_s390x::validVectorRegister(int /*regNum*/) const { return false; } inline v128 Registers_s390x::getVectorRegister(int /*regNum*/) const { _LIBUNWIND_ABORT("s390x vector support not implemented"); } inline void Registers_s390x::setVectorRegister(int /*regNum*/, v128 /*value*/) { _LIBUNWIND_ABORT("s390x vector support not implemented"); } inline const char *Registers_s390x::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "ip"; case UNW_REG_SP: return "sp"; case UNW_S390X_R0: return "r0"; case UNW_S390X_R1: return "r1"; case UNW_S390X_R2: return "r2"; case UNW_S390X_R3: return "r3"; case UNW_S390X_R4: return "r4"; case UNW_S390X_R5: return "r5"; case UNW_S390X_R6: return "r6"; case UNW_S390X_R7: return "r7"; case UNW_S390X_R8: return "r8"; case UNW_S390X_R9: return "r9"; case UNW_S390X_R10: return "r10"; case UNW_S390X_R11: return "r11"; case UNW_S390X_R12: return "r12"; case UNW_S390X_R13: return "r13"; case UNW_S390X_R14: return "r14"; case UNW_S390X_R15: return "r15"; case UNW_S390X_F0: return "f0"; case UNW_S390X_F1: return "f1"; case UNW_S390X_F2: return "f2"; case UNW_S390X_F3: return "f3"; case UNW_S390X_F4: return "f4"; case UNW_S390X_F5: return "f5"; case UNW_S390X_F6: return "f6"; case UNW_S390X_F7: return "f7"; case UNW_S390X_F8: return "f8"; case UNW_S390X_F9: return "f9"; case UNW_S390X_F10: return "f10"; case UNW_S390X_F11: return "f11"; case UNW_S390X_F12: return "f12"; case UNW_S390X_F13: return "f13"; case UNW_S390X_F14: return "f14"; case UNW_S390X_F15: return "f15"; } return "unknown register"; } #endif // _LIBUNWIND_TARGET_S390X #if defined(_LIBUNWIND_TARGET_LOONGARCH) /// Registers_loongarch holds the register state of a thread in a 64-bit /// LoongArch process. class _LIBUNWIND_HIDDEN Registers_loongarch { public: Registers_loongarch(); Registers_loongarch(const void *registers); bool validRegister(int num) const; uint64_t getRegister(int num) const; void setRegister(int num, uint64_t value); bool validFloatRegister(int num) const; double getFloatRegister(int num) const; void setFloatRegister(int num, double value); bool validVectorRegister(int num) const; v128 getVectorRegister(int num) const; void setVectorRegister(int num, v128 value); static const char *getRegisterName(int num); void jumpto(); static constexpr int lastDwarfRegNum() { return _LIBUNWIND_HIGHEST_DWARF_REGISTER_LOONGARCH; } static int getArch() { return REGISTERS_LOONGARCH; } uint64_t getSP() const { return _registers.__r[3]; } void setSP(uint64_t value) { _registers.__r[3] = value; } uint64_t getIP() const { return _registers.__pc; } void setIP(uint64_t value) { _registers.__pc = value; } private: struct loongarch_thread_state_t { uint64_t __r[32]; uint64_t __pc; }; loongarch_thread_state_t _registers; #if __loongarch_frlen == 64 double _floats[32]; #endif }; inline Registers_loongarch::Registers_loongarch(const void *registers) { static_assert((check_fit::does_fit), "loongarch registers do not fit into unw_context_t"); memcpy(&_registers, registers, sizeof(_registers)); static_assert(sizeof(_registers) == 0x108, "expected float registers to be at offset 264"); #if __loongarch_frlen == 64 memcpy(_floats, static_cast(registers) + sizeof(_registers), sizeof(_floats)); #endif } inline Registers_loongarch::Registers_loongarch() { memset(&_registers, 0, sizeof(_registers)); #if __loongarch_frlen == 64 memset(&_floats, 0, sizeof(_floats)); #endif } inline bool Registers_loongarch::validRegister(int regNum) const { if (regNum == UNW_REG_IP || regNum == UNW_REG_SP) return true; if (regNum < 0 || regNum > UNW_LOONGARCH_F31) return false; return true; } inline uint64_t Registers_loongarch::getRegister(int regNum) const { if (regNum >= UNW_LOONGARCH_R0 && regNum <= UNW_LOONGARCH_R31) return _registers.__r[regNum - UNW_LOONGARCH_R0]; if (regNum == UNW_REG_IP) return _registers.__pc; if (regNum == UNW_REG_SP) return _registers.__r[3]; _LIBUNWIND_ABORT("unsupported loongarch register"); } inline void Registers_loongarch::setRegister(int regNum, uint64_t value) { if (regNum >= UNW_LOONGARCH_R0 && regNum <= UNW_LOONGARCH_R31) _registers.__r[regNum - UNW_LOONGARCH_R0] = value; else if (regNum == UNW_REG_IP) _registers.__pc = value; else if (regNum == UNW_REG_SP) _registers.__r[3] = value; else _LIBUNWIND_ABORT("unsupported loongarch register"); } inline const char *Registers_loongarch::getRegisterName(int regNum) { switch (regNum) { case UNW_REG_IP: return "$pc"; case UNW_REG_SP: return "$sp"; case UNW_LOONGARCH_R0: return "$r0"; case UNW_LOONGARCH_R1: return "$r1"; case UNW_LOONGARCH_R2: return "$r2"; case UNW_LOONGARCH_R3: return "$r3"; case UNW_LOONGARCH_R4: return "$r4"; case UNW_LOONGARCH_R5: return "$r5"; case UNW_LOONGARCH_R6: return "$r6"; case UNW_LOONGARCH_R7: return "$r7"; case UNW_LOONGARCH_R8: return "$r8"; case UNW_LOONGARCH_R9: return "$r9"; case UNW_LOONGARCH_R10: return "$r10"; case UNW_LOONGARCH_R11: return "$r11"; case UNW_LOONGARCH_R12: return "$r12"; case UNW_LOONGARCH_R13: return "$r13"; case UNW_LOONGARCH_R14: return "$r14"; case UNW_LOONGARCH_R15: return "$r15"; case UNW_LOONGARCH_R16: return "$r16"; case UNW_LOONGARCH_R17: return "$r17"; case UNW_LOONGARCH_R18: return "$r18"; case UNW_LOONGARCH_R19: return "$r19"; case UNW_LOONGARCH_R20: return "$r20"; case UNW_LOONGARCH_R21: return "$r21"; case UNW_LOONGARCH_R22: return "$r22"; case UNW_LOONGARCH_R23: return "$r23"; case UNW_LOONGARCH_R24: return "$r24"; case UNW_LOONGARCH_R25: return "$r25"; case UNW_LOONGARCH_R26: return "$r26"; case UNW_LOONGARCH_R27: return "$r27"; case UNW_LOONGARCH_R28: return "$r28"; case UNW_LOONGARCH_R29: return "$r29"; case UNW_LOONGARCH_R30: return "$r30"; case UNW_LOONGARCH_R31: return "$r31"; case UNW_LOONGARCH_F0: return "$f0"; case UNW_LOONGARCH_F1: return "$f1"; case UNW_LOONGARCH_F2: return "$f2"; case UNW_LOONGARCH_F3: return "$f3"; case UNW_LOONGARCH_F4: return "$f4"; case UNW_LOONGARCH_F5: return "$f5"; case UNW_LOONGARCH_F6: return "$f6"; case UNW_LOONGARCH_F7: return "$f7"; case UNW_LOONGARCH_F8: return "$f8"; case UNW_LOONGARCH_F9: return "$f9"; case UNW_LOONGARCH_F10: return "$f10"; case UNW_LOONGARCH_F11: return "$f11"; case UNW_LOONGARCH_F12: return "$f12"; case UNW_LOONGARCH_F13: return "$f13"; case UNW_LOONGARCH_F14: return "$f14"; case UNW_LOONGARCH_F15: return "$f15"; case UNW_LOONGARCH_F16: return "$f16"; case UNW_LOONGARCH_F17: return "$f17"; case UNW_LOONGARCH_F18: return "$f18"; case UNW_LOONGARCH_F19: return "$f19"; case UNW_LOONGARCH_F20: return "$f20"; case UNW_LOONGARCH_F21: return "$f21"; case UNW_LOONGARCH_F22: return "$f22"; case UNW_LOONGARCH_F23: return "$f23"; case UNW_LOONGARCH_F24: return "$f24"; case UNW_LOONGARCH_F25: return "$f25"; case UNW_LOONGARCH_F26: return "$f26"; case UNW_LOONGARCH_F27: return "$f27"; case UNW_LOONGARCH_F28: return "$f28"; case UNW_LOONGARCH_F29: return "$f29"; case UNW_LOONGARCH_F30: return "$f30"; case UNW_LOONGARCH_F31: return "$f31"; default: return "unknown register"; } } inline bool Registers_loongarch::validFloatRegister(int regNum) const { if (regNum < UNW_LOONGARCH_F0 || regNum > UNW_LOONGARCH_F31) return false; return true; } inline double Registers_loongarch::getFloatRegister(int regNum) const { #if __loongarch_frlen == 64 assert(validFloatRegister(regNum)); return _floats[regNum - UNW_LOONGARCH_F0]; #else _LIBUNWIND_ABORT("libunwind not built with float support"); #endif } inline void Registers_loongarch::setFloatRegister(int regNum, double value) { #if __loongarch_frlen == 64 assert(validFloatRegister(regNum)); _floats[regNum - UNW_LOONGARCH_F0] = value; #else _LIBUNWIND_ABORT("libunwind not built with float support"); #endif } inline bool Registers_loongarch::validVectorRegister(int) const { return false; } inline v128 Registers_loongarch::getVectorRegister(int) const { _LIBUNWIND_ABORT("loongarch vector support not implemented"); } inline void Registers_loongarch::setVectorRegister(int, v128) { _LIBUNWIND_ABORT("loongarch vector support not implemented"); } #endif //_LIBUNWIND_TARGET_LOONGARCH } // namespace libunwind #endif // __REGISTERS_HPP__