//===--------------------------- libunwind.cpp ----------------------------===// // // The LLVM Compiler Infrastructure // // This file is dual licensed under the MIT and the University of Illinois Open // Source Licenses. See LICENSE.TXT for details. // // // Implements unw_* functions from // //===----------------------------------------------------------------------===// #include #ifndef NDEBUG #include // getenv #endif #include #include #include "libunwind_ext.h" #include "config.h" #include #include "AddressSpace.hpp" #include "UnwindCursor.hpp" using namespace libunwind; /// internal object to represent this processes address space LocalAddressSpace LocalAddressSpace::sThisAddressSpace; _LIBUNWIND_EXPORT unw_addr_space_t unw_local_addr_space = (unw_addr_space_t)&LocalAddressSpace::sThisAddressSpace; /// record the registers and stack position of the caller extern int unw_getcontext(unw_context_t *); // note: unw_getcontext() implemented in assembly /// Create a cursor of a thread in this process given 'context' recorded by /// unw_getcontext(). _LIBUNWIND_EXPORT int unw_init_local(unw_cursor_t *cursor, unw_context_t *context) { _LIBUNWIND_TRACE_API("unw_init_local(cursor=%p, context=%p)", static_cast(cursor), static_cast(context)); #if defined(__i386__) # define REGISTER_KIND Registers_x86 #elif defined(__x86_64__) # define REGISTER_KIND Registers_x86_64 #elif defined(__ppc__) # define REGISTER_KIND Registers_ppc #elif defined(__aarch64__) # define REGISTER_KIND Registers_arm64 #elif defined(_LIBUNWIND_ARM_EHABI) # define REGISTER_KIND Registers_arm #elif defined(__or1k__) # define REGISTER_KIND Registers_or1k #elif defined(__mips__) # warning The MIPS architecture is not supported. #else # error Architecture not supported #endif // Use "placement new" to allocate UnwindCursor in the cursor buffer. new ((void *)cursor) UnwindCursor( context, LocalAddressSpace::sThisAddressSpace); #undef REGISTER_KIND AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; co->setInfoBasedOnIPRegister(); return UNW_ESUCCESS; } #ifdef UNW_REMOTE /// Create a cursor into a thread in another process. _LIBUNWIND_EXPORT int unw_init_remote_thread(unw_cursor_t *cursor, unw_addr_space_t as, void *arg) { // special case: unw_init_remote(xx, unw_local_addr_space, xx) if (as == (unw_addr_space_t)&LocalAddressSpace::sThisAddressSpace) return unw_init_local(cursor, NULL); //FIXME // use "placement new" to allocate UnwindCursor in the cursor buffer switch (as->cpuType) { case CPU_TYPE_I386: new ((void *)cursor) UnwindCursor>, Registers_x86>(((unw_addr_space_i386 *)as)->oas, arg); break; case CPU_TYPE_X86_64: new ((void *)cursor) UnwindCursor>, Registers_x86_64>(((unw_addr_space_x86_64 *)as)->oas, arg); break; case CPU_TYPE_POWERPC: new ((void *)cursor) UnwindCursor>, Registers_ppc>(((unw_addr_space_ppc *)as)->oas, arg); break; default: return UNW_EUNSPEC; } return UNW_ESUCCESS; } static bool is64bit(task_t task) { return false; // FIXME } /// Create an address_space object for use in examining another task. _LIBUNWIND_EXPORT unw_addr_space_t unw_create_addr_space_for_task(task_t task) { #if __i386__ if (is64bit(task)) { unw_addr_space_x86_64 *as = new unw_addr_space_x86_64(task); as->taskPort = task; as->cpuType = CPU_TYPE_X86_64; //as->oas } else { unw_addr_space_i386 *as = new unw_addr_space_i386(task); as->taskPort = task; as->cpuType = CPU_TYPE_I386; //as->oas } #else // FIXME #endif } /// Delete an address_space object. _LIBUNWIND_EXPORT void unw_destroy_addr_space(unw_addr_space_t asp) { switch (asp->cpuType) { #if __i386__ || __x86_64__ case CPU_TYPE_I386: { unw_addr_space_i386 *as = (unw_addr_space_i386 *)asp; delete as; } break; case CPU_TYPE_X86_64: { unw_addr_space_x86_64 *as = (unw_addr_space_x86_64 *)asp; delete as; } break; #endif case CPU_TYPE_POWERPC: { unw_addr_space_ppc *as = (unw_addr_space_ppc *)asp; delete as; } break; } } #endif // UNW_REMOTE /// Get value of specified register at cursor position in stack frame. _LIBUNWIND_EXPORT int unw_get_reg(unw_cursor_t *cursor, unw_regnum_t regNum, unw_word_t *value) { _LIBUNWIND_TRACE_API("unw_get_reg(cursor=%p, regNum=%d, &value=%p)", static_cast(cursor), regNum, static_cast(value)); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; if (co->validReg(regNum)) { *value = co->getReg(regNum); return UNW_ESUCCESS; } return UNW_EBADREG; } /// Set value of specified register at cursor position in stack frame. _LIBUNWIND_EXPORT int unw_set_reg(unw_cursor_t *cursor, unw_regnum_t regNum, unw_word_t value) { _LIBUNWIND_TRACE_API("unw_set_reg(cursor=%p, regNum=%d, value=0x%llX)", static_cast(cursor), regNum, (long long)value); typedef LocalAddressSpace::pint_t pint_t; AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; if (co->validReg(regNum)) { co->setReg(regNum, (pint_t)value); // specical case altering IP to re-find info (being called by personality // function) if (regNum == UNW_REG_IP) co->setInfoBasedOnIPRegister(false); return UNW_ESUCCESS; } return UNW_EBADREG; } /// Get value of specified float register at cursor position in stack frame. _LIBUNWIND_EXPORT int unw_get_fpreg(unw_cursor_t *cursor, unw_regnum_t regNum, unw_fpreg_t *value) { _LIBUNWIND_TRACE_API("unw_get_fpreg(cursor=%p, regNum=%d, &value=%p)", static_cast(cursor), regNum, static_cast(value)); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; if (co->validFloatReg(regNum)) { *value = co->getFloatReg(regNum); return UNW_ESUCCESS; } return UNW_EBADREG; } /// Set value of specified float register at cursor position in stack frame. _LIBUNWIND_EXPORT int unw_set_fpreg(unw_cursor_t *cursor, unw_regnum_t regNum, unw_fpreg_t value) { #if defined(_LIBUNWIND_ARM_EHABI) _LIBUNWIND_TRACE_API("unw_set_fpreg(cursor=%p, regNum=%d, value=%llX)", static_cast(cursor), regNum, value); #else _LIBUNWIND_TRACE_API("unw_set_fpreg(cursor=%p, regNum=%d, value=%g)", static_cast(cursor), regNum, value); #endif AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; if (co->validFloatReg(regNum)) { co->setFloatReg(regNum, value); return UNW_ESUCCESS; } return UNW_EBADREG; } /// Move cursor to next frame. _LIBUNWIND_EXPORT int unw_step(unw_cursor_t *cursor) { _LIBUNWIND_TRACE_API("unw_step(cursor=%p)", static_cast(cursor)); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; return co->step(); } /// Get unwind info at cursor position in stack frame. _LIBUNWIND_EXPORT int unw_get_proc_info(unw_cursor_t *cursor, unw_proc_info_t *info) { _LIBUNWIND_TRACE_API("unw_get_proc_info(cursor=%p, &info=%p)", static_cast(cursor), static_cast(info)); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; co->getInfo(info); if (info->end_ip == 0) return UNW_ENOINFO; else return UNW_ESUCCESS; } /// Resume execution at cursor position (aka longjump). _LIBUNWIND_EXPORT int unw_resume(unw_cursor_t *cursor) { _LIBUNWIND_TRACE_API("unw_resume(cursor=%p)", static_cast(cursor)); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; co->jumpto(); return UNW_EUNSPEC; } /// Get name of function at cursor position in stack frame. _LIBUNWIND_EXPORT int unw_get_proc_name(unw_cursor_t *cursor, char *buf, size_t bufLen, unw_word_t *offset) { _LIBUNWIND_TRACE_API("unw_get_proc_name(cursor=%p, &buf=%p, bufLen=%lu)", static_cast(cursor), static_cast(buf), static_cast(bufLen)); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; if (co->getFunctionName(buf, bufLen, offset)) return UNW_ESUCCESS; else return UNW_EUNSPEC; } /// Checks if a register is a floating-point register. _LIBUNWIND_EXPORT int unw_is_fpreg(unw_cursor_t *cursor, unw_regnum_t regNum) { _LIBUNWIND_TRACE_API("unw_is_fpreg(cursor=%p, regNum=%d)", static_cast(cursor), regNum); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; return co->validFloatReg(regNum); } /// Checks if a register is a floating-point register. _LIBUNWIND_EXPORT const char *unw_regname(unw_cursor_t *cursor, unw_regnum_t regNum) { _LIBUNWIND_TRACE_API("unw_regname(cursor=%p, regNum=%d)", static_cast(cursor), regNum); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; return co->getRegisterName(regNum); } /// Checks if current frame is signal trampoline. _LIBUNWIND_EXPORT int unw_is_signal_frame(unw_cursor_t *cursor) { _LIBUNWIND_TRACE_API("unw_is_signal_frame(cursor=%p)", static_cast(cursor)); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; return co->isSignalFrame(); } #ifdef __arm__ // Save VFP registers d0-d15 using FSTMIADX instead of FSTMIADD _LIBUNWIND_EXPORT void unw_save_vfp_as_X(unw_cursor_t *cursor) { _LIBUNWIND_TRACE_API("unw_fpreg_save_vfp_as_X(cursor=%p)", static_cast(cursor)); AbstractUnwindCursor *co = (AbstractUnwindCursor *)cursor; return co->saveVFPAsX(); } #endif #if defined(_LIBUNWIND_SUPPORT_DWARF_UNWIND) /// SPI: walks cached DWARF entries _LIBUNWIND_EXPORT void unw_iterate_dwarf_unwind_cache(void (*func)( unw_word_t ip_start, unw_word_t ip_end, unw_word_t fde, unw_word_t mh)) { _LIBUNWIND_TRACE_API("unw_iterate_dwarf_unwind_cache(func=%p)", reinterpret_cast(func)); DwarfFDECache::iterateCacheEntries(func); } /// IPI: for __register_frame() void _unw_add_dynamic_fde(unw_word_t fde) { CFI_Parser::FDE_Info fdeInfo; CFI_Parser::CIE_Info cieInfo; const char *message = CFI_Parser::decodeFDE( LocalAddressSpace::sThisAddressSpace, (LocalAddressSpace::pint_t) fde, &fdeInfo, &cieInfo); if (message == NULL) { // dynamically registered FDEs don't have a mach_header group they are in. // Use fde as mh_group unw_word_t mh_group = fdeInfo.fdeStart; DwarfFDECache::add((LocalAddressSpace::pint_t)mh_group, fdeInfo.pcStart, fdeInfo.pcEnd, fdeInfo.fdeStart); } else { _LIBUNWIND_DEBUG_LOG("_unw_add_dynamic_fde: bad fde: %s", message); } } /// IPI: for __deregister_frame() void _unw_remove_dynamic_fde(unw_word_t fde) { // fde is own mh_group DwarfFDECache::removeAllIn((LocalAddressSpace::pint_t)fde); } #endif // defined(_LIBUNWIND_SUPPORT_DWARF_UNWIND) // Add logging hooks in Debug builds only #ifndef NDEBUG #include _LIBUNWIND_HIDDEN bool logAPIs() { // do manual lock to avoid use of _cxa_guard_acquire or initializers static bool checked = false; static bool log = false; if (!checked) { log = (getenv("LIBUNWIND_PRINT_APIS") != NULL); checked = true; } return log; } _LIBUNWIND_HIDDEN bool logUnwinding() { // do manual lock to avoid use of _cxa_guard_acquire or initializers static bool checked = false; static bool log = false; if (!checked) { log = (getenv("LIBUNWIND_PRINT_UNWINDING") != NULL); checked = true; } return log; } _LIBUNWIND_HIDDEN bool logDWARF() { // do manual lock to avoid use of _cxa_guard_acquire or initializers static bool checked = false; static bool log = false; if (!checked) { log = (getenv("LIBUNWIND_PRINT_DWARF") != NULL); checked = true; } return log; } #endif // NDEBUG