/* * Copyright 2010-2011 PathScale, Inc. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ``AS * IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include "typeinfo.h" #include "dwarf_eh.h" #include "atomic.h" #include "cxxabi.h" #pragma weak pthread_key_create #pragma weak pthread_setspecific #pragma weak pthread_getspecific #pragma weak pthread_once #ifdef LIBCXXRT_WEAK_LOCKS #pragma weak pthread_mutex_lock #define pthread_mutex_lock(mtx) do {\ if (pthread_mutex_lock) pthread_mutex_lock(mtx);\ } while(0) #pragma weak pthread_mutex_unlock #define pthread_mutex_unlock(mtx) do {\ if (pthread_mutex_unlock) pthread_mutex_unlock(mtx);\ } while(0) #pragma weak pthread_cond_signal #define pthread_cond_signal(cv) do {\ if (pthread_cond_signal) pthread_cond_signal(cv);\ } while(0) #pragma weak pthread_cond_wait #define pthread_cond_wait(cv, mtx) do {\ if (pthread_cond_wait) pthread_cond_wait(cv, mtx);\ } while(0) #endif using namespace ABI_NAMESPACE; /** * Saves the result of the landing pad that we have found. For ARM, this is * stored in the generic unwind structure, while on other platforms it is * stored in the C++ exception. */ static void saveLandingPad(struct _Unwind_Context *context, struct _Unwind_Exception *ucb, struct __cxa_exception *ex, int selector, dw_eh_ptr_t landingPad) { #if defined(__arm__) && !defined(__ARM_DWARF_EH__) // On ARM, we store the saved exception in the generic part of the structure ucb->barrier_cache.sp = _Unwind_GetGR(context, 13); ucb->barrier_cache.bitpattern[1] = static_cast(selector); ucb->barrier_cache.bitpattern[3] = reinterpret_cast(landingPad); #endif // Cache the results for the phase 2 unwind, if we found a handler // and this is not a foreign exception. if (ex) { ex->handlerSwitchValue = selector; ex->catchTemp = landingPad; } } /** * Loads the saved landing pad. Returns 1 on success, 0 on failure. */ static int loadLandingPad(struct _Unwind_Context *context, struct _Unwind_Exception *ucb, struct __cxa_exception *ex, unsigned long *selector, dw_eh_ptr_t *landingPad) { #if defined(__arm__) && !defined(__ARM_DWARF_EH__) *selector = ucb->barrier_cache.bitpattern[1]; *landingPad = reinterpret_cast(ucb->barrier_cache.bitpattern[3]); return 1; #else if (ex) { *selector = ex->handlerSwitchValue; *landingPad = reinterpret_cast(ex->catchTemp); return 0; } return 0; #endif } static inline _Unwind_Reason_Code continueUnwinding(struct _Unwind_Exception *ex, struct _Unwind_Context *context) { #if defined(__arm__) && !defined(__ARM_DWARF_EH__) if (__gnu_unwind_frame(ex, context) != _URC_OK) { return _URC_FAILURE; } #endif return _URC_CONTINUE_UNWIND; } extern "C" void __cxa_free_exception(void *thrown_exception); extern "C" void __cxa_free_dependent_exception(void *thrown_exception); extern "C" void* __dynamic_cast(const void *sub, const __class_type_info *src, const __class_type_info *dst, ptrdiff_t src2dst_offset); /** * The type of a handler that has been found. */ typedef enum { /** No handler. */ handler_none, /** * A cleanup - the exception will propagate through this frame, but code * must be run when this happens. */ handler_cleanup, /** * A catch statement. The exception will not propagate past this frame * (without an explicit rethrow). */ handler_catch } handler_type; /** * Per-thread info required by the runtime. We store a single structure * pointer in thread-local storage, because this tends to be a scarce resource * and it's impolite to steal all of it and not leave any for the rest of the * program. * * Instances of this structure are allocated lazily - at most one per thread - * and are destroyed on thread termination. */ struct __cxa_thread_info { /** The termination handler for this thread. */ terminate_handler terminateHandler; /** The unexpected exception handler for this thread. */ unexpected_handler unexpectedHandler; /** * The number of emergency buffers held by this thread. This is 0 in * normal operation - the emergency buffers are only used when malloc() * fails to return memory for allocating an exception. Threads are not * permitted to hold more than 4 emergency buffers (as per recommendation * in ABI spec [3.3.1]). */ int emergencyBuffersHeld; /** * The exception currently running in a cleanup. */ _Unwind_Exception *currentCleanup; /** * Our state with respect to foreign exceptions. Usually none, set to * caught if we have just caught an exception and rethrown if we are * rethrowing it. */ enum { none, caught, rethrown } foreign_exception_state; /** * The public part of this structure, accessible from outside of this * module. */ __cxa_eh_globals globals; }; /** * Dependent exception. This */ struct __cxa_dependent_exception { #if __LP64__ void *primaryException; #endif std::type_info *exceptionType; void (*exceptionDestructor) (void *); unexpected_handler unexpectedHandler; terminate_handler terminateHandler; __cxa_exception *nextException; int handlerCount; #if defined(__arm__) && !defined(__ARM_DWARF_EH__) _Unwind_Exception *nextCleanup; int cleanupCount; #endif int handlerSwitchValue; const char *actionRecord; const char *languageSpecificData; void *catchTemp; void *adjustedPtr; #if !__LP64__ void *primaryException; #endif _Unwind_Exception unwindHeader; }; namespace std { void unexpected(); class exception { public: virtual ~exception() throw(); virtual const char* what() const throw(); }; } /** * Class of exceptions to distinguish between this and other exception types. * * The first four characters are the vendor ID. Currently, we use GNUC, * because we aim for ABI-compatibility with the GNU implementation, and * various checks may test for equality of the class, which is incorrect. */ static const uint64_t exception_class = EXCEPTION_CLASS('G', 'N', 'U', 'C', 'C', '+', '+', '\0'); /** * Class used for dependent exceptions. */ static const uint64_t dependent_exception_class = EXCEPTION_CLASS('G', 'N', 'U', 'C', 'C', '+', '+', '\x01'); /** * The low four bytes of the exception class, indicating that we conform to the * Itanium C++ ABI. This is currently unused, but should be used in the future * if we change our exception class, to allow this library and libsupc++ to be * linked to the same executable and both to interoperate. */ static const uint32_t abi_exception_class = GENERIC_EXCEPTION_CLASS('C', '+', '+', '\0'); static bool isCXXException(uint64_t cls) { return (cls == exception_class) || (cls == dependent_exception_class); } static bool isDependentException(uint64_t cls) { return cls == dependent_exception_class; } static __cxa_exception *exceptionFromPointer(void *ex) { return reinterpret_cast<__cxa_exception*>(static_cast(ex) - offsetof(struct __cxa_exception, unwindHeader)); } static __cxa_exception *realExceptionFromException(__cxa_exception *ex) { if (!isDependentException(ex->unwindHeader.exception_class)) { return ex; } return reinterpret_cast<__cxa_exception*>((reinterpret_cast<__cxa_dependent_exception*>(ex))->primaryException)-1; } namespace std { // Forward declaration of standard library terminate() function used to // abort execution. void terminate(void); } using namespace ABI_NAMESPACE; /** The global termination handler. */ static terminate_handler terminateHandler = abort; /** The global unexpected exception handler. */ static unexpected_handler unexpectedHandler = std::terminate; /** Key used for thread-local data. */ static pthread_key_t eh_key; /** * Cleanup function, allowing foreign exception handlers to correctly destroy * this exception if they catch it. */ static void exception_cleanup(_Unwind_Reason_Code reason, struct _Unwind_Exception *ex) { // Exception layout: // [__cxa_exception [_Unwind_Exception]] [exception object] // // __cxa_free_exception expects a pointer to the exception object __cxa_free_exception(static_cast(ex + 1)); } static void dependent_exception_cleanup(_Unwind_Reason_Code reason, struct _Unwind_Exception *ex) { __cxa_free_dependent_exception(static_cast(ex + 1)); } /** * Recursively walk a list of exceptions and delete them all in post-order. */ static void free_exception_list(__cxa_exception *ex) { if (0 != ex->nextException) { free_exception_list(ex->nextException); } // __cxa_free_exception() expects to be passed the thrown object, which // immediately follows the exception, not the exception itself __cxa_free_exception(ex+1); } /** * Cleanup function called when a thread exists to make certain that all of the * per-thread data is deleted. */ static void thread_cleanup(void* thread_info) { __cxa_thread_info *info = static_cast<__cxa_thread_info*>(thread_info); if (info->globals.caughtExceptions) { // If this is a foreign exception, ask it to clean itself up. if (info->foreign_exception_state != __cxa_thread_info::none) { _Unwind_Exception *e = reinterpret_cast<_Unwind_Exception*>(info->globals.caughtExceptions); if (e->exception_cleanup) e->exception_cleanup(_URC_FOREIGN_EXCEPTION_CAUGHT, e); } else { free_exception_list(info->globals.caughtExceptions); } } free(thread_info); } /** * Once control used to protect the key creation. */ static pthread_once_t once_control = PTHREAD_ONCE_INIT; /** * We may not be linked against a full pthread implementation. If we're not, * then we need to fake the thread-local storage by storing 'thread-local' * things in a global. */ static bool fakeTLS; /** * Thread-local storage for a single-threaded program. */ static __cxa_thread_info singleThreadInfo; /** * Initialise eh_key. */ static void init_key(void) { if ((0 == pthread_key_create) || (0 == pthread_setspecific) || (0 == pthread_getspecific)) { fakeTLS = true; return; } pthread_key_create(&eh_key, thread_cleanup); pthread_setspecific(eh_key, reinterpret_cast(0x42)); fakeTLS = (pthread_getspecific(eh_key) != reinterpret_cast(0x42)); pthread_setspecific(eh_key, 0); } /** * Returns the thread info structure, creating it if it is not already created. */ static __cxa_thread_info *thread_info() { if ((0 == pthread_once) || pthread_once(&once_control, init_key)) { fakeTLS = true; } if (fakeTLS) { return &singleThreadInfo; } __cxa_thread_info *info = static_cast<__cxa_thread_info*>(pthread_getspecific(eh_key)); if (0 == info) { info = static_cast<__cxa_thread_info*>(calloc(1, sizeof(__cxa_thread_info))); pthread_setspecific(eh_key, info); } return info; } /** * Fast version of thread_info(). May fail if thread_info() is not called on * this thread at least once already. */ static __cxa_thread_info *thread_info_fast() { if (fakeTLS) { return &singleThreadInfo; } return static_cast<__cxa_thread_info*>(pthread_getspecific(eh_key)); } /** * ABI function returning the __cxa_eh_globals structure. */ extern "C" __cxa_eh_globals *ABI_NAMESPACE::__cxa_get_globals(void) { return &(thread_info()->globals); } /** * Version of __cxa_get_globals() assuming that __cxa_get_globals() has already * been called at least once by this thread. */ extern "C" __cxa_eh_globals *ABI_NAMESPACE::__cxa_get_globals_fast(void) { return &(thread_info_fast()->globals); } /** * An emergency allocation reserved for when malloc fails. This is treated as * 16 buffers of 1KB each. */ static char emergency_buffer[16384]; /** * Flag indicating whether each buffer is allocated. */ static bool buffer_allocated[16]; /** * Lock used to protect emergency allocation. */ static pthread_mutex_t emergency_malloc_lock = PTHREAD_MUTEX_INITIALIZER; /** * Condition variable used to wait when two threads are both trying to use the * emergency malloc() buffer at once. */ static pthread_cond_t emergency_malloc_wait = PTHREAD_COND_INITIALIZER; /** * Allocates size bytes from the emergency allocation mechanism, if possible. * This function will fail if size is over 1KB or if this thread already has 4 * emergency buffers. If all emergency buffers are allocated, it will sleep * until one becomes available. */ static char *emergency_malloc(size_t size) { if (size > 1024) { return 0; } __cxa_thread_info *info = thread_info(); // Only 4 emergency buffers allowed per thread! if (info->emergencyBuffersHeld > 3) { return 0; } pthread_mutex_lock(&emergency_malloc_lock); int buffer = -1; while (buffer < 0) { // While we were sleeping on the lock, another thread might have free'd // enough memory for us to use, so try the allocation again - no point // using the emergency buffer if there is some real memory that we can // use... void *m = calloc(1, size); if (0 != m) { pthread_mutex_unlock(&emergency_malloc_lock); return static_cast(m); } for (int i=0 ; i<16 ; i++) { if (!buffer_allocated[i]) { buffer = i; buffer_allocated[i] = true; break; } } // If there still isn't a buffer available, then sleep on the condition // variable. This will be signalled when another thread releases one // of the emergency buffers. if (buffer < 0) { pthread_cond_wait(&emergency_malloc_wait, &emergency_malloc_lock); } } pthread_mutex_unlock(&emergency_malloc_lock); info->emergencyBuffersHeld++; return emergency_buffer + (1024 * buffer); } /** * Frees a buffer returned by emergency_malloc(). * * Note: Neither this nor emergency_malloc() is particularly efficient. This * should not matter, because neither will be called in normal operation - they * are only used when the program runs out of memory, which should not happen * often. */ static void emergency_malloc_free(char *ptr) { int buffer = -1; // Find the buffer corresponding to this pointer. for (int i=0 ; i<16 ; i++) { if (ptr == static_cast(emergency_buffer + (1024 * i))) { buffer = i; break; } } assert(buffer >= 0 && "Trying to free something that is not an emergency buffer!"); // emergency_malloc() is expected to return 0-initialized data. We don't // zero the buffer when allocating it, because the static buffers will // begin life containing 0 values. memset(ptr, 0, 1024); // Signal the condition variable to wake up any threads that are blocking // waiting for some space in the emergency buffer pthread_mutex_lock(&emergency_malloc_lock); // In theory, we don't need to do this with the lock held. In practice, // our array of bools will probably be updated using 32-bit or 64-bit // memory operations, so this update may clobber adjacent values. buffer_allocated[buffer] = false; pthread_cond_signal(&emergency_malloc_wait); pthread_mutex_unlock(&emergency_malloc_lock); } static char *alloc_or_die(size_t size) { char *buffer = static_cast(calloc(1, size)); // If calloc() doesn't want to give us any memory, try using an emergency // buffer. if (0 == buffer) { buffer = emergency_malloc(size); // This is only reached if the allocation is greater than 1KB, and // anyone throwing objects that big really should know better. if (0 == buffer) { fprintf(stderr, "Out of memory attempting to allocate exception\n"); std::terminate(); } } return buffer; } static void free_exception(char *e) { // If this allocation is within the address range of the emergency buffer, // don't call free() because it was not allocated with malloc() if ((e >= emergency_buffer) && (e < (emergency_buffer + sizeof(emergency_buffer)))) { emergency_malloc_free(e); } else { free(e); } } /** * Allocates an exception structure. Returns a pointer to the space that can * be used to store an object of thrown_size bytes. This function will use an * emergency buffer if malloc() fails, and may block if there are no such * buffers available. */ extern "C" void *__cxa_allocate_exception(size_t thrown_size) { size_t size = thrown_size + sizeof(__cxa_exception); char *buffer = alloc_or_die(size); return buffer+sizeof(__cxa_exception); } extern "C" void *__cxa_allocate_dependent_exception(void) { size_t size = sizeof(__cxa_dependent_exception); char *buffer = alloc_or_die(size); return buffer+sizeof(__cxa_dependent_exception); } /** * __cxa_free_exception() is called when an exception was thrown in between * calling __cxa_allocate_exception() and actually throwing the exception. * This happens when the object's copy constructor throws an exception. * * In this implementation, it is also called by __cxa_end_catch() and during * thread cleanup. */ extern "C" void __cxa_free_exception(void *thrown_exception) { __cxa_exception *ex = reinterpret_cast<__cxa_exception*>(thrown_exception) - 1; // Free the object that was thrown, calling its destructor if (0 != ex->exceptionDestructor) { try { ex->exceptionDestructor(thrown_exception); } catch(...) { // FIXME: Check that this is really what the spec says to do. std::terminate(); } } free_exception(reinterpret_cast(ex)); } static void releaseException(__cxa_exception *exception) { if (isDependentException(exception->unwindHeader.exception_class)) { __cxa_free_dependent_exception(exception+1); return; } if (__sync_sub_and_fetch(&exception->referenceCount, 1) == 0) { // __cxa_free_exception() expects to be passed the thrown object, // which immediately follows the exception, not the exception // itself __cxa_free_exception(exception+1); } } void __cxa_free_dependent_exception(void *thrown_exception) { __cxa_dependent_exception *ex = reinterpret_cast<__cxa_dependent_exception*>(thrown_exception) - 1; assert(isDependentException(ex->unwindHeader.exception_class)); if (ex->primaryException) { releaseException(realExceptionFromException(reinterpret_cast<__cxa_exception*>(ex))); } free_exception(reinterpret_cast(ex)); } /** * Callback function used with _Unwind_Backtrace(). * * Prints a stack trace. Used only for debugging help. * * Note: As of FreeBSD 8.1, dladd() still doesn't work properly, so this only * correctly prints function names from public, relocatable, symbols. */ static _Unwind_Reason_Code trace(struct _Unwind_Context *context, void *c) { Dl_info myinfo; int mylookup = dladdr(reinterpret_cast(__cxa_current_exception_type), &myinfo); void *ip = reinterpret_cast(_Unwind_GetIP(context)); Dl_info info; if (dladdr(ip, &info) != 0) { if (mylookup == 0 || strcmp(info.dli_fname, myinfo.dli_fname) != 0) { printf("%p:%s() in %s\n", ip, info.dli_sname, info.dli_fname); } } return _URC_CONTINUE_UNWIND; } /** * Report a failure that occurred when attempting to throw an exception. * * If the failure happened by falling off the end of the stack without finding * a handler, prints a back trace before aborting. */ #if __GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 4) extern "C" void *__cxa_begin_catch(void *e) throw(); #else extern "C" void *__cxa_begin_catch(void *e); #endif static void report_failure(_Unwind_Reason_Code err, __cxa_exception *thrown_exception) { switch (err) { default: break; case _URC_FATAL_PHASE1_ERROR: fprintf(stderr, "Fatal error during phase 1 unwinding\n"); break; #if !defined(__arm__) || defined(__ARM_DWARF_EH__) case _URC_FATAL_PHASE2_ERROR: fprintf(stderr, "Fatal error during phase 2 unwinding\n"); break; #endif case _URC_END_OF_STACK: __cxa_begin_catch (&(thrown_exception->unwindHeader)); std::terminate(); fprintf(stderr, "Terminating due to uncaught exception %p", static_cast(thrown_exception)); thrown_exception = realExceptionFromException(thrown_exception); static const __class_type_info *e_ti = static_cast(&typeid(std::exception)); const __class_type_info *throw_ti = dynamic_cast(thrown_exception->exceptionType); if (throw_ti) { std::exception *e = static_cast(e_ti->cast_to(static_cast(thrown_exception+1), throw_ti)); if (e) { fprintf(stderr, " '%s'", e->what()); } } size_t bufferSize = 128; char *demangled = static_cast(malloc(bufferSize)); const char *mangled = thrown_exception->exceptionType->name(); int status; demangled = __cxa_demangle(mangled, demangled, &bufferSize, &status); fprintf(stderr, " of type %s\n", status == 0 ? demangled : mangled); if (status == 0) { free(demangled); } // Print a back trace if no handler is found. // TODO: Make this optional _Unwind_Backtrace(trace, 0); // Just abort. No need to call std::terminate for the second time abort(); break; } std::terminate(); } static void throw_exception(__cxa_exception *ex) { __cxa_thread_info *info = thread_info(); ex->unexpectedHandler = info->unexpectedHandler; if (0 == ex->unexpectedHandler) { ex->unexpectedHandler = unexpectedHandler; } ex->terminateHandler = info->terminateHandler; if (0 == ex->terminateHandler) { ex->terminateHandler = terminateHandler; } info->globals.uncaughtExceptions++; _Unwind_Reason_Code err = _Unwind_RaiseException(&ex->unwindHeader); // The _Unwind_RaiseException() function should not return, it should // unwind the stack past this function. If it does return, then something // has gone wrong. report_failure(err, ex); } /** * ABI function for throwing an exception. Takes the object to be thrown (the * pointer returned by __cxa_allocate_exception()), the type info for the * pointee, and the destructor (if there is one) as arguments. */ extern "C" void __cxa_throw(void *thrown_exception, std::type_info *tinfo, void(*dest)(void*)) { __cxa_exception *ex = reinterpret_cast<__cxa_exception*>(thrown_exception) - 1; ex->referenceCount = 1; ex->exceptionType = tinfo; ex->exceptionDestructor = dest; ex->unwindHeader.exception_class = exception_class; ex->unwindHeader.exception_cleanup = exception_cleanup; throw_exception(ex); } extern "C" void __cxa_rethrow_primary_exception(void* thrown_exception) { if (NULL == thrown_exception) { return; } __cxa_exception *original = exceptionFromPointer(thrown_exception); __cxa_dependent_exception *ex = reinterpret_cast<__cxa_dependent_exception*>(__cxa_allocate_dependent_exception())-1; ex->primaryException = thrown_exception; __cxa_increment_exception_refcount(thrown_exception); ex->exceptionType = original->exceptionType; ex->unwindHeader.exception_class = dependent_exception_class; ex->unwindHeader.exception_cleanup = dependent_exception_cleanup; throw_exception(reinterpret_cast<__cxa_exception*>(ex)); } extern "C" void *__cxa_current_primary_exception(void) { __cxa_eh_globals* globals = __cxa_get_globals(); __cxa_exception *ex = globals->caughtExceptions; if (0 == ex) { return NULL; } ex = realExceptionFromException(ex); __sync_fetch_and_add(&ex->referenceCount, 1); return ex + 1; } extern "C" void __cxa_increment_exception_refcount(void* thrown_exception) { if (NULL == thrown_exception) { return; } __cxa_exception *ex = static_cast<__cxa_exception*>(thrown_exception) - 1; if (isDependentException(ex->unwindHeader.exception_class)) { return; } __sync_fetch_and_add(&ex->referenceCount, 1); } extern "C" void __cxa_decrement_exception_refcount(void* thrown_exception) { if (NULL == thrown_exception) { return; } __cxa_exception *ex = static_cast<__cxa_exception*>(thrown_exception) - 1; releaseException(ex); } /** * ABI function. Rethrows the current exception. Does not remove the * exception from the stack or decrement its handler count - the compiler is * expected to set the landing pad for this function to the end of the catch * block, and then call _Unwind_Resume() to continue unwinding once * __cxa_end_catch() has been called and any cleanup code has been run. */ extern "C" void __cxa_rethrow() { __cxa_thread_info *ti = thread_info(); __cxa_eh_globals *globals = &ti->globals; // Note: We don't remove this from the caught list here, because // __cxa_end_catch will be called when we unwind out of the try block. We // could probably make this faster by providing an alternative rethrow // function and ensuring that all cleanup code is run before calling it, so // we can skip the top stack frame when unwinding. __cxa_exception *ex = globals->caughtExceptions; if (0 == ex) { fprintf(stderr, "Attempting to rethrow an exception that doesn't exist!\n"); std::terminate(); } if (ti->foreign_exception_state != __cxa_thread_info::none) { ti->foreign_exception_state = __cxa_thread_info::rethrown; _Unwind_Exception *e = reinterpret_cast<_Unwind_Exception*>(ex); _Unwind_Reason_Code err = _Unwind_Resume_or_Rethrow(e); report_failure(err, ex); return; } assert(ex->handlerCount > 0 && "Rethrowing uncaught exception!"); // ex->handlerCount will be decremented in __cxa_end_catch in enclosing // catch block // Make handler count negative. This will tell __cxa_end_catch that // exception was rethrown and exception object should not be destroyed // when handler count become zero ex->handlerCount = -ex->handlerCount; // Continue unwinding the stack with this exception. This should unwind to // the place in the caller where __cxa_end_catch() is called. The caller // will then run cleanup code and bounce the exception back with // _Unwind_Resume(). _Unwind_Reason_Code err = _Unwind_Resume_or_Rethrow(&ex->unwindHeader); report_failure(err, ex); } /** * Returns the type_info object corresponding to the filter. */ static std::type_info *get_type_info_entry(_Unwind_Context *context, dwarf_eh_lsda *lsda, int filter) { // Get the address of the record in the table. dw_eh_ptr_t record = lsda->type_table - dwarf_size_of_fixed_size_field(lsda->type_table_encoding)*filter; //record -= 4; dw_eh_ptr_t start = record; // Read the value, but it's probably an indirect reference... int64_t offset = read_value(lsda->type_table_encoding, &record); // (If the entry is 0, don't try to dereference it. That would be bad.) if (offset == 0) { return 0; } // ...so we need to resolve it return reinterpret_cast(resolve_indirect_value(context, lsda->type_table_encoding, offset, start)); } /** * Checks the type signature found in a handler against the type of the thrown * object. If ex is 0 then it is assumed to be a foreign exception and only * matches cleanups. */ static bool check_type_signature(__cxa_exception *ex, const std::type_info *type, void *&adjustedPtr) { void *exception_ptr = static_cast(ex+1); const std::type_info *ex_type = ex ? ex->exceptionType : 0; bool is_ptr = ex ? ex_type->__is_pointer_p() : false; if (is_ptr) { exception_ptr = *static_cast(exception_ptr); } // Always match a catchall, even with a foreign exception // // Note: A 0 here is a catchall, not a cleanup, so we return true to // indicate that we found a catch. if (0 == type) { if (ex) { adjustedPtr = exception_ptr; } return true; } if (0 == ex) { return false; } // If the types are the same, no casting is needed. if (*type == *ex_type) { adjustedPtr = exception_ptr; return true; } if (type->__do_catch(ex_type, &exception_ptr, 1)) { adjustedPtr = exception_ptr; return true; } return false; } /** * Checks whether the exception matches the type specifiers in this action * record. If the exception only matches cleanups, then this returns false. * If it matches a catch (including a catchall) then it returns true. * * The selector argument is used to return the selector that is passed in the * second exception register when installing the context. */ static handler_type check_action_record(_Unwind_Context *context, dwarf_eh_lsda *lsda, dw_eh_ptr_t action_record, __cxa_exception *ex, unsigned long *selector, void *&adjustedPtr) { if (!action_record) { return handler_cleanup; } handler_type found = handler_none; while (action_record) { int filter = read_sleb128(&action_record); dw_eh_ptr_t action_record_offset_base = action_record; int displacement = read_sleb128(&action_record); action_record = displacement ? action_record_offset_base + displacement : 0; // We only check handler types for C++ exceptions - foreign exceptions // are only allowed for cleanups and catchalls. if (filter > 0) { std::type_info *handler_type = get_type_info_entry(context, lsda, filter); if (check_type_signature(ex, handler_type, adjustedPtr)) { *selector = filter; return handler_catch; } } else if (filter < 0 && 0 != ex) { bool matched = false; *selector = filter; #if defined(__arm__) && !defined(__ARM_DWARF_EH__) filter++; std::type_info *handler_type = get_type_info_entry(context, lsda, filter--); while (handler_type) { if (check_type_signature(ex, handler_type, adjustedPtr)) { matched = true; break; } handler_type = get_type_info_entry(context, lsda, filter--); } #else unsigned char *type_index = reinterpret_cast(lsda->type_table) - filter - 1; while (*type_index) { std::type_info *handler_type = get_type_info_entry(context, lsda, *(type_index++)); // If the exception spec matches a permitted throw type for // this function, don't report a handler - we are allowed to // propagate this exception out. if (check_type_signature(ex, handler_type, adjustedPtr)) { matched = true; break; } } #endif if (matched) { continue; } // If we don't find an allowed exception spec, we need to install // the context for this action. The landing pad will then call the // unexpected exception function. Treat this as a catch return handler_catch; } else if (filter == 0) { *selector = filter; found = handler_cleanup; } } return found; } static void pushCleanupException(_Unwind_Exception *exceptionObject, __cxa_exception *ex) { #if defined(__arm__) && !defined(__ARM_DWARF_EH__) __cxa_thread_info *info = thread_info_fast(); if (ex) { ex->cleanupCount++; if (ex->cleanupCount > 1) { assert(exceptionObject == info->currentCleanup); return; } ex->nextCleanup = info->currentCleanup; } info->currentCleanup = exceptionObject; #endif } /** * The exception personality function. This is referenced in the unwinding * DWARF metadata and is called by the unwind library for each C++ stack frame * containing catch or cleanup code. */ extern "C" BEGIN_PERSONALITY_FUNCTION(__gxx_personality_v0) // This personality function is for version 1 of the ABI. If you use it // with a future version of the ABI, it won't know what to do, so it // reports a fatal error and give up before it breaks anything. if (1 != version) { return _URC_FATAL_PHASE1_ERROR; } __cxa_exception *ex = 0; __cxa_exception *realEx = 0; // If this exception is throw by something else then we can't make any // assumptions about its layout beyond the fields declared in // _Unwind_Exception. bool foreignException = !isCXXException(exceptionClass); // If this isn't a foreign exception, then we have a C++ exception structure if (!foreignException) { ex = exceptionFromPointer(exceptionObject); realEx = realExceptionFromException(ex); } #if defined(__arm__) && !defined(__ARM_DWARF_EH__) unsigned char *lsda_addr = static_cast(_Unwind_GetLanguageSpecificData(context)); #else unsigned char *lsda_addr = reinterpret_cast(static_cast(_Unwind_GetLanguageSpecificData(context))); #endif // No LSDA implies no landing pads - try the next frame if (0 == lsda_addr) { return continueUnwinding(exceptionObject, context); } // These two variables define how the exception will be handled. dwarf_eh_action action = {0}; unsigned long selector = 0; // During the search phase, we do a complete lookup. If we return // _URC_HANDLER_FOUND, then the phase 2 unwind will call this function with // a _UA_HANDLER_FRAME action, telling us to install the handler frame. If // we return _URC_CONTINUE_UNWIND, we may be called again later with a // _UA_CLEANUP_PHASE action for this frame. // // The point of the two-stage unwind allows us to entirely avoid any stack // unwinding if there is no handler. If there are just cleanups found, // then we can just panic call an abort function. // // Matching a handler is much more expensive than matching a cleanup, // because we don't need to bother doing type comparisons (or looking at // the type table at all) for a cleanup. This means that there is no need // to cache the result of finding a cleanup, because it's (quite) quick to // look it up again from the action table. if (actions & _UA_SEARCH_PHASE) { struct dwarf_eh_lsda lsda = parse_lsda(context, lsda_addr); if (!dwarf_eh_find_callsite(context, &lsda, &action)) { // EH range not found. This happens if exception is thrown and not // caught inside a cleanup (destructor). We should call // terminate() in this case. The catchTemp (landing pad) field of // exception object will contain null when personality function is // called with _UA_HANDLER_FRAME action for phase 2 unwinding. return _URC_HANDLER_FOUND; } handler_type found_handler = check_action_record(context, &lsda, action.action_record, realEx, &selector, ex->adjustedPtr); // If there's no action record, we've only found a cleanup, so keep // searching for something real if (found_handler == handler_catch) { // Cache the results for the phase 2 unwind, if we found a handler // and this is not a foreign exception. if (ex) { saveLandingPad(context, exceptionObject, ex, selector, action.landing_pad); ex->languageSpecificData = reinterpret_cast(lsda_addr); ex->actionRecord = reinterpret_cast(action.action_record); // ex->adjustedPtr is set when finding the action record. } return _URC_HANDLER_FOUND; } return continueUnwinding(exceptionObject, context); } // If this is a foreign exception, we didn't have anywhere to cache the // lookup stuff, so we need to do it again. If this is either a forced // unwind, a foreign exception, or a cleanup, then we just install the // context for a cleanup. if (!(actions & _UA_HANDLER_FRAME)) { // cleanup struct dwarf_eh_lsda lsda = parse_lsda(context, lsda_addr); dwarf_eh_find_callsite(context, &lsda, &action); if (0 == action.landing_pad) { return continueUnwinding(exceptionObject, context); } handler_type found_handler = check_action_record(context, &lsda, action.action_record, realEx, &selector, ex->adjustedPtr); // Ignore handlers this time. if (found_handler != handler_cleanup) { return continueUnwinding(exceptionObject, context); } pushCleanupException(exceptionObject, ex); } else if (foreignException) { struct dwarf_eh_lsda lsda = parse_lsda(context, lsda_addr); dwarf_eh_find_callsite(context, &lsda, &action); check_action_record(context, &lsda, action.action_record, realEx, &selector, ex->adjustedPtr); } else if (ex->catchTemp == 0) { // Uncaught exception in cleanup, calling terminate std::terminate(); } else { // Restore the saved info if we saved some last time. loadLandingPad(context, exceptionObject, ex, &selector, &action.landing_pad); ex->catchTemp = 0; ex->handlerSwitchValue = 0; } _Unwind_SetIP(context, reinterpret_cast(action.landing_pad)); _Unwind_SetGR(context, __builtin_eh_return_data_regno(0), reinterpret_cast(exceptionObject)); _Unwind_SetGR(context, __builtin_eh_return_data_regno(1), selector); return _URC_INSTALL_CONTEXT; } /** * ABI function called when entering a catch statement. The argument is the * pointer passed out of the personality function. This is always the start of * the _Unwind_Exception object. The return value for this function is the * pointer to the caught exception, which is either the adjusted pointer (for * C++ exceptions) of the unadjusted pointer (for foreign exceptions). */ #if __GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 4) extern "C" void *__cxa_begin_catch(void *e) throw() #else extern "C" void *__cxa_begin_catch(void *e) #endif { // We can't call the fast version here, because if the first exception that // we see is a foreign exception then we won't have called it yet. __cxa_thread_info *ti = thread_info(); __cxa_eh_globals *globals = &ti->globals; globals->uncaughtExceptions--; _Unwind_Exception *exceptionObject = static_cast<_Unwind_Exception*>(e); if (isCXXException(exceptionObject->exception_class)) { __cxa_exception *ex = exceptionFromPointer(exceptionObject); if (ex->handlerCount == 0) { // Add this to the front of the list of exceptions being handled // and increment its handler count so that it won't be deleted // prematurely. ex->nextException = globals->caughtExceptions; globals->caughtExceptions = ex; } if (ex->handlerCount < 0) { // Rethrown exception is catched before end of catch block. // Clear the rethrow flag (make value positive) - we are allowed // to delete this exception at the end of the catch block, as long // as it isn't thrown again later. // Code pattern: // // try { // throw x; // } // catch() { // try { // throw; // } // catch() { // __cxa_begin_catch() <- we are here // } // } ex->handlerCount = -ex->handlerCount + 1; } else { ex->handlerCount++; } ti->foreign_exception_state = __cxa_thread_info::none; return ex->adjustedPtr; } else { // If this is a foreign exception, then we need to be able to // store it. We can't chain foreign exceptions, so we give up // if there are already some outstanding ones. if (globals->caughtExceptions != 0) { std::terminate(); } globals->caughtExceptions = reinterpret_cast<__cxa_exception*>(exceptionObject); ti->foreign_exception_state = __cxa_thread_info::caught; } // exceptionObject is the pointer to the _Unwind_Exception within the // __cxa_exception. The throw object is after this return (reinterpret_cast(exceptionObject) + sizeof(_Unwind_Exception)); } /** * ABI function called when exiting a catch block. This will free the current * exception if it is no longer referenced in other catch blocks. */ extern "C" void __cxa_end_catch() { // We can call the fast version here because the slow version is called in // __cxa_throw(), which must have been called before we end a catch block __cxa_thread_info *ti = thread_info_fast(); __cxa_eh_globals *globals = &ti->globals; __cxa_exception *ex = globals->caughtExceptions; assert(0 != ex && "Ending catch when no exception is on the stack!"); if (ti->foreign_exception_state != __cxa_thread_info::none) { if (ti->foreign_exception_state != __cxa_thread_info::rethrown) { _Unwind_Exception *e = reinterpret_cast<_Unwind_Exception*>(ti->globals.caughtExceptions); if (e->exception_cleanup) e->exception_cleanup(_URC_FOREIGN_EXCEPTION_CAUGHT, e); } globals->caughtExceptions = 0; ti->foreign_exception_state = __cxa_thread_info::none; return; } bool deleteException = true; if (ex->handlerCount < 0) { // exception was rethrown. Exception should not be deleted even if // handlerCount become zero. // Code pattern: // try { // throw x; // } // catch() { // { // throw; // } // cleanup { // __cxa_end_catch(); <- we are here // } // } // ex->handlerCount++; deleteException = false; } else { ex->handlerCount--; } if (ex->handlerCount == 0) { globals->caughtExceptions = ex->nextException; if (deleteException) { releaseException(ex); } } } /** * ABI function. Returns the type of the current exception. */ extern "C" std::type_info *__cxa_current_exception_type() { __cxa_eh_globals *globals = __cxa_get_globals(); __cxa_exception *ex = globals->caughtExceptions; return ex ? ex->exceptionType : 0; } /** * ABI function, called when an exception specification is violated. * * This function does not return. */ extern "C" void __cxa_call_unexpected(void*exception) { _Unwind_Exception *exceptionObject = static_cast<_Unwind_Exception*>(exception); if (exceptionObject->exception_class == exception_class) { __cxa_exception *ex = exceptionFromPointer(exceptionObject); if (ex->unexpectedHandler) { ex->unexpectedHandler(); // Should not be reached. abort(); } } std::unexpected(); // Should not be reached. abort(); } /** * ABI function, returns the adjusted pointer to the exception object. */ extern "C" void *__cxa_get_exception_ptr(void *exceptionObject) { return exceptionFromPointer(exceptionObject)->adjustedPtr; } /** * As an extension, we provide the ability for the unexpected and terminate * handlers to be thread-local. We default to the standards-compliant * behaviour where they are global. */ static bool thread_local_handlers = false; namespace pathscale { /** * Sets whether unexpected and terminate handlers should be thread-local. */ void set_use_thread_local_handlers(bool flag) throw() { thread_local_handlers = flag; } /** * Sets a thread-local unexpected handler. */ unexpected_handler set_unexpected(unexpected_handler f) throw() { static __cxa_thread_info *info = thread_info(); unexpected_handler old = info->unexpectedHandler; info->unexpectedHandler = f; return old; } /** * Sets a thread-local terminate handler. */ terminate_handler set_terminate(terminate_handler f) throw() { static __cxa_thread_info *info = thread_info(); terminate_handler old = info->terminateHandler; info->terminateHandler = f; return old; } } namespace std { /** * Sets the function that will be called when an exception specification is * violated. */ unexpected_handler set_unexpected(unexpected_handler f) throw() { if (thread_local_handlers) { return pathscale::set_unexpected(f); } return ATOMIC_SWAP(&unexpectedHandler, f); } /** * Sets the function that is called to terminate the program. */ terminate_handler set_terminate(terminate_handler f) throw() { if (thread_local_handlers) { return pathscale::set_terminate(f); } return ATOMIC_SWAP(&terminateHandler, f); } /** * Terminates the program, calling a custom terminate implementation if * required. */ void terminate() { static __cxa_thread_info *info = thread_info(); if (0 != info && 0 != info->terminateHandler) { info->terminateHandler(); // Should not be reached - a terminate handler is not expected to // return. abort(); } terminateHandler(); } /** * Called when an unexpected exception is encountered (i.e. an exception * violates an exception specification). This calls abort() unless a * custom handler has been set.. */ void unexpected() { static __cxa_thread_info *info = thread_info(); if (0 != info && 0 != info->unexpectedHandler) { info->unexpectedHandler(); // Should not be reached - a terminate handler is not expected to // return. abort(); } unexpectedHandler(); } /** * Returns whether there are any exceptions currently being thrown that * have not been caught. This can occur inside a nested catch statement. */ bool uncaught_exception() throw() { __cxa_thread_info *info = thread_info(); return info->globals.uncaughtExceptions != 0; } /** * Returns the number of exceptions currently being thrown that have not * been caught. This can occur inside a nested catch statement. */ int uncaught_exceptions() throw() { __cxa_thread_info *info = thread_info(); return info->globals.uncaughtExceptions; } /** * Returns the current unexpected handler. */ unexpected_handler get_unexpected() throw() { __cxa_thread_info *info = thread_info(); if (info->unexpectedHandler) { return info->unexpectedHandler; } return ATOMIC_LOAD(&unexpectedHandler); } /** * Returns the current terminate handler. */ terminate_handler get_terminate() throw() { __cxa_thread_info *info = thread_info(); if (info->terminateHandler) { return info->terminateHandler; } return ATOMIC_LOAD(&terminateHandler); } } #if defined(__arm__) && !defined(__ARM_DWARF_EH__) extern "C" _Unwind_Exception *__cxa_get_cleanup(void) { __cxa_thread_info *info = thread_info_fast(); _Unwind_Exception *exceptionObject = info->currentCleanup; if (isCXXException(exceptionObject->exception_class)) { __cxa_exception *ex = exceptionFromPointer(exceptionObject); ex->cleanupCount--; if (ex->cleanupCount == 0) { info->currentCleanup = ex->nextCleanup; ex->nextCleanup = 0; } } else { info->currentCleanup = 0; } return exceptionObject; } asm ( ".pushsection .text.__cxa_end_cleanup \n" ".global __cxa_end_cleanup \n" ".type __cxa_end_cleanup, \"function\" \n" "__cxa_end_cleanup: \n" " push {r1, r2, r3, r4} \n" " bl __cxa_get_cleanup \n" " push {r1, r2, r3, r4} \n" " b _Unwind_Resume \n" " bl abort \n" ".popsection \n" ); #endif