//===-- MachTask.cpp --------------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// //---------------------------------------------------------------------- // // MachTask.cpp // debugserver // // Created by Greg Clayton on 12/5/08. // //===----------------------------------------------------------------------===// #include "MachTask.h" // C Includes #include #include #import // C++ Includes #include #include // Other libraries and framework includes // Project includes #include "CFUtils.h" #include "DNB.h" #include "DNBError.h" #include "DNBLog.h" #include "MachProcess.h" #include "DNBDataRef.h" #include "stack_logging.h" #ifdef WITH_SPRINGBOARD #include #include #include #endif //---------------------------------------------------------------------- // MachTask constructor //---------------------------------------------------------------------- MachTask::MachTask(MachProcess *process) : m_process (process), m_task (TASK_NULL), m_vm_memory (), m_exception_thread (0), m_exception_port (MACH_PORT_NULL) { memset(&m_exc_port_info, 0, sizeof(m_exc_port_info)); } //---------------------------------------------------------------------- // Destructor //---------------------------------------------------------------------- MachTask::~MachTask() { Clear(); } //---------------------------------------------------------------------- // MachTask::Suspend //---------------------------------------------------------------------- kern_return_t MachTask::Suspend() { DNBError err; task_t task = TaskPort(); err = ::task_suspend (task); if (DNBLogCheckLogBit(LOG_TASK) || err.Fail()) err.LogThreaded("::task_suspend ( target_task = 0x%4.4x )", task); return err.Error(); } //---------------------------------------------------------------------- // MachTask::Resume //---------------------------------------------------------------------- kern_return_t MachTask::Resume() { struct task_basic_info task_info; task_t task = TaskPort(); if (task == TASK_NULL) return KERN_INVALID_ARGUMENT; DNBError err; err = BasicInfo(task, &task_info); if (err.Success()) { // task_resume isn't counted like task_suspend calls are, are, so if the // task is not suspended, don't try and resume it since it is already // running if (task_info.suspend_count > 0) { err = ::task_resume (task); if (DNBLogCheckLogBit(LOG_TASK) || err.Fail()) err.LogThreaded("::task_resume ( target_task = 0x%4.4x )", task); } } return err.Error(); } //---------------------------------------------------------------------- // MachTask::ExceptionPort //---------------------------------------------------------------------- mach_port_t MachTask::ExceptionPort() const { return m_exception_port; } //---------------------------------------------------------------------- // MachTask::ExceptionPortIsValid //---------------------------------------------------------------------- bool MachTask::ExceptionPortIsValid() const { return MACH_PORT_VALID(m_exception_port); } //---------------------------------------------------------------------- // MachTask::Clear //---------------------------------------------------------------------- void MachTask::Clear() { // Do any cleanup needed for this task m_task = TASK_NULL; m_exception_thread = 0; m_exception_port = MACH_PORT_NULL; } //---------------------------------------------------------------------- // MachTask::SaveExceptionPortInfo //---------------------------------------------------------------------- kern_return_t MachTask::SaveExceptionPortInfo() { return m_exc_port_info.Save(TaskPort()); } //---------------------------------------------------------------------- // MachTask::RestoreExceptionPortInfo //---------------------------------------------------------------------- kern_return_t MachTask::RestoreExceptionPortInfo() { return m_exc_port_info.Restore(TaskPort()); } //---------------------------------------------------------------------- // MachTask::ReadMemory //---------------------------------------------------------------------- nub_size_t MachTask::ReadMemory (nub_addr_t addr, nub_size_t size, void *buf) { nub_size_t n = 0; task_t task = TaskPort(); if (task != TASK_NULL) { n = m_vm_memory.Read(task, addr, buf, size); DNBLogThreadedIf(LOG_MEMORY, "MachTask::ReadMemory ( addr = 0x%8.8llx, size = %llu, buf = %p) => %llu bytes read", (uint64_t)addr, (uint64_t)size, buf, (uint64_t)n); if (DNBLogCheckLogBit(LOG_MEMORY_DATA_LONG) || (DNBLogCheckLogBit(LOG_MEMORY_DATA_SHORT) && size <= 8)) { DNBDataRef data((uint8_t*)buf, n, false); data.Dump(0, n, addr, DNBDataRef::TypeUInt8, 16); } } return n; } //---------------------------------------------------------------------- // MachTask::WriteMemory //---------------------------------------------------------------------- nub_size_t MachTask::WriteMemory (nub_addr_t addr, nub_size_t size, const void *buf) { nub_size_t n = 0; task_t task = TaskPort(); if (task != TASK_NULL) { n = m_vm_memory.Write(task, addr, buf, size); DNBLogThreadedIf(LOG_MEMORY, "MachTask::WriteMemory ( addr = 0x%8.8llx, size = %llu, buf = %p) => %llu bytes written", (uint64_t)addr, (uint64_t)size, buf, (uint64_t)n); if (DNBLogCheckLogBit(LOG_MEMORY_DATA_LONG) || (DNBLogCheckLogBit(LOG_MEMORY_DATA_SHORT) && size <= 8)) { DNBDataRef data((uint8_t*)buf, n, false); data.Dump(0, n, addr, DNBDataRef::TypeUInt8, 16); } } return n; } //---------------------------------------------------------------------- // MachTask::MemoryRegionInfo //---------------------------------------------------------------------- int MachTask::GetMemoryRegionInfo (nub_addr_t addr, DNBRegionInfo *region_info) { task_t task = TaskPort(); if (task == TASK_NULL) return -1; int ret = m_vm_memory.GetMemoryRegionInfo(task, addr, region_info); DNBLogThreadedIf(LOG_MEMORY, "MachTask::MemoryRegionInfo ( addr = 0x%8.8llx ) => %i (start = 0x%8.8llx, size = 0x%8.8llx, permissions = %u)", (uint64_t)addr, ret, (uint64_t)region_info->addr, (uint64_t)region_info->size, region_info->permissions); return ret; } #define TIME_VALUE_TO_TIMEVAL(a, r) do { \ (r)->tv_sec = (a)->seconds; \ (r)->tv_usec = (a)->microseconds; \ } while (0) // We should consider moving this into each MacThread. static void get_threads_profile_data(DNBProfileDataScanType scanType, task_t task, nub_process_t pid, std::vector &threads_id, std::vector &threads_name, std::vector &threads_used_usec) { kern_return_t kr; thread_act_array_t threads; mach_msg_type_number_t tcnt; kr = task_threads(task, &threads, &tcnt); if (kr != KERN_SUCCESS) return; for (int i = 0; i < tcnt; i++) { thread_identifier_info_data_t identifier_info; mach_msg_type_number_t count = THREAD_IDENTIFIER_INFO_COUNT; kr = ::thread_info(threads[i], THREAD_IDENTIFIER_INFO, (thread_info_t)&identifier_info, &count); if (kr != KERN_SUCCESS) continue; thread_basic_info_data_t basic_info; count = THREAD_BASIC_INFO_COUNT; kr = ::thread_info(threads[i], THREAD_BASIC_INFO, (thread_info_t)&basic_info, &count); if (kr != KERN_SUCCESS) continue; if ((basic_info.flags & TH_FLAGS_IDLE) == 0) { nub_thread_t tid = MachThread::GetGloballyUniqueThreadIDForMachPortID (threads[i]); threads_id.push_back(tid); if ((scanType & eProfileThreadName) && (identifier_info.thread_handle != 0)) { struct proc_threadinfo proc_threadinfo; int len = ::proc_pidinfo(pid, PROC_PIDTHREADINFO, identifier_info.thread_handle, &proc_threadinfo, PROC_PIDTHREADINFO_SIZE); if (len && proc_threadinfo.pth_name[0]) { threads_name.push_back(proc_threadinfo.pth_name); } else { threads_name.push_back(""); } } else { threads_name.push_back(""); } struct timeval tv; struct timeval thread_tv; TIME_VALUE_TO_TIMEVAL(&basic_info.user_time, &thread_tv); TIME_VALUE_TO_TIMEVAL(&basic_info.system_time, &tv); timeradd(&thread_tv, &tv, &thread_tv); uint64_t used_usec = thread_tv.tv_sec * 1000000ULL + thread_tv.tv_usec; threads_used_usec.push_back(used_usec); } kr = mach_port_deallocate(mach_task_self(), threads[i]); } kr = mach_vm_deallocate(mach_task_self(), (mach_vm_address_t)(uintptr_t)threads, tcnt * sizeof(*threads)); } #define RAW_HEXBASE std::setfill('0') << std::hex << std::right #define DECIMAL std::dec << std::setfill(' ') std::string MachTask::GetProfileData (DNBProfileDataScanType scanType) { std::string result; static int32_t numCPU = -1; struct host_cpu_load_info host_info; if (scanType & eProfileHostCPU) { int32_t mib[] = {CTL_HW, HW_AVAILCPU}; size_t len = sizeof(numCPU); if (numCPU == -1) { if (sysctl(mib, sizeof(mib) / sizeof(int32_t), &numCPU, &len, NULL, 0) != 0) return result; } mach_port_t localHost = mach_host_self(); mach_msg_type_number_t count = HOST_CPU_LOAD_INFO_COUNT; kern_return_t kr = host_statistics(localHost, HOST_CPU_LOAD_INFO, (host_info_t)&host_info, &count); if (kr != KERN_SUCCESS) return result; } task_t task = TaskPort(); if (task == TASK_NULL) return result; struct task_basic_info task_info; DNBError err; err = BasicInfo(task, &task_info); if (!err.Success()) return result; uint64_t elapsed_usec = 0; uint64_t task_used_usec = 0; if (scanType & eProfileCPU) { // Get current used time. struct timeval current_used_time; struct timeval tv; TIME_VALUE_TO_TIMEVAL(&task_info.user_time, ¤t_used_time); TIME_VALUE_TO_TIMEVAL(&task_info.system_time, &tv); timeradd(¤t_used_time, &tv, ¤t_used_time); task_used_usec = current_used_time.tv_sec * 1000000ULL + current_used_time.tv_usec; struct timeval current_elapsed_time; int res = gettimeofday(¤t_elapsed_time, NULL); if (res == 0) { elapsed_usec = current_elapsed_time.tv_sec * 1000000ULL + current_elapsed_time.tv_usec; } } std::vector threads_id; std::vector threads_name; std::vector threads_used_usec; if (scanType & eProfileThreadsCPU) { get_threads_profile_data(scanType, task, m_process->ProcessID(), threads_id, threads_name, threads_used_usec); } struct vm_statistics vm_stats; uint64_t physical_memory; mach_vm_size_t rprvt = 0; mach_vm_size_t rsize = 0; mach_vm_size_t vprvt = 0; mach_vm_size_t vsize = 0; mach_vm_size_t dirty_size = 0; mach_vm_size_t purgeable = 0; mach_vm_size_t anonymous = 0; if (m_vm_memory.GetMemoryProfile(scanType, task, task_info, m_process->GetCPUType(), m_process->ProcessID(), vm_stats, physical_memory, rprvt, rsize, vprvt, vsize, dirty_size, purgeable, anonymous)) { std::ostringstream profile_data_stream; if (scanType & eProfileHostCPU) { profile_data_stream << "num_cpu:" << numCPU << ';'; profile_data_stream << "host_user_ticks:" << host_info.cpu_ticks[CPU_STATE_USER] << ';'; profile_data_stream << "host_sys_ticks:" << host_info.cpu_ticks[CPU_STATE_SYSTEM] << ';'; profile_data_stream << "host_idle_ticks:" << host_info.cpu_ticks[CPU_STATE_IDLE] << ';'; } if (scanType & eProfileCPU) { profile_data_stream << "elapsed_usec:" << elapsed_usec << ';'; profile_data_stream << "task_used_usec:" << task_used_usec << ';'; } if (scanType & eProfileThreadsCPU) { int num_threads = threads_id.size(); for (int i=0; iProcessID(), err); return m_task; } //---------------------------------------------------------------------- // MachTask::TaskPortForProcessID //---------------------------------------------------------------------- task_t MachTask::TaskPortForProcessID (pid_t pid, DNBError &err, uint32_t num_retries, uint32_t usec_interval) { if (pid != INVALID_NUB_PROCESS) { DNBError err; mach_port_t task_self = mach_task_self (); task_t task = TASK_NULL; for (uint32_t i=0; i err = 0x%8.8x (%s)", task_self, pid, err.Error(), err.AsString() ? err.AsString() : "success"); if (err.Fail()) err.SetErrorString(str); err.LogThreaded(str); } if (err.Success()) return task; // Sleep a bit and try again ::usleep (usec_interval); } } return TASK_NULL; } //---------------------------------------------------------------------- // MachTask::BasicInfo //---------------------------------------------------------------------- kern_return_t MachTask::BasicInfo(struct task_basic_info *info) { return BasicInfo (TaskPort(), info); } //---------------------------------------------------------------------- // MachTask::BasicInfo //---------------------------------------------------------------------- kern_return_t MachTask::BasicInfo(task_t task, struct task_basic_info *info) { if (info == NULL) return KERN_INVALID_ARGUMENT; DNBError err; mach_msg_type_number_t count = TASK_BASIC_INFO_COUNT; err = ::task_info (task, TASK_BASIC_INFO, (task_info_t)info, &count); const bool log_process = DNBLogCheckLogBit(LOG_TASK); if (log_process || err.Fail()) err.LogThreaded("::task_info ( target_task = 0x%4.4x, flavor = TASK_BASIC_INFO, task_info_out => %p, task_info_outCnt => %u )", task, info, count); if (DNBLogCheckLogBit(LOG_TASK) && DNBLogCheckLogBit(LOG_VERBOSE) && err.Success()) { float user = (float)info->user_time.seconds + (float)info->user_time.microseconds / 1000000.0f; float system = (float)info->user_time.seconds + (float)info->user_time.microseconds / 1000000.0f; DNBLogThreaded ("task_basic_info = { suspend_count = %i, virtual_size = 0x%8.8llx, resident_size = 0x%8.8llx, user_time = %f, system_time = %f }", info->suspend_count, (uint64_t)info->virtual_size, (uint64_t)info->resident_size, user, system); } return err.Error(); } //---------------------------------------------------------------------- // MachTask::IsValid // // Returns true if a task is a valid task port for a current process. //---------------------------------------------------------------------- bool MachTask::IsValid () const { return MachTask::IsValid(TaskPort()); } //---------------------------------------------------------------------- // MachTask::IsValid // // Returns true if a task is a valid task port for a current process. //---------------------------------------------------------------------- bool MachTask::IsValid (task_t task) { if (task != TASK_NULL) { struct task_basic_info task_info; return BasicInfo(task, &task_info) == KERN_SUCCESS; } return false; } bool MachTask::StartExceptionThread(DNBError &err) { DNBLogThreadedIf(LOG_EXCEPTIONS, "MachTask::%s ( )", __FUNCTION__); task_t task = TaskPortForProcessID(err); if (MachTask::IsValid(task)) { // Got the mach port for the current process mach_port_t task_self = mach_task_self (); // Allocate an exception port that we will use to track our child process err = ::mach_port_allocate (task_self, MACH_PORT_RIGHT_RECEIVE, &m_exception_port); if (err.Fail()) return false; // Add the ability to send messages on the new exception port err = ::mach_port_insert_right (task_self, m_exception_port, m_exception_port, MACH_MSG_TYPE_MAKE_SEND); if (err.Fail()) return false; // Save the original state of the exception ports for our child process SaveExceptionPortInfo(); // We weren't able to save the info for our exception ports, we must stop... if (m_exc_port_info.mask == 0) { err.SetErrorString("failed to get exception port info"); return false; } // Set the ability to get all exceptions on this port err = ::task_set_exception_ports (task, m_exc_port_info.mask, m_exception_port, EXCEPTION_DEFAULT | MACH_EXCEPTION_CODES, THREAD_STATE_NONE); if (DNBLogCheckLogBit(LOG_EXCEPTIONS) || err.Fail()) { err.LogThreaded("::task_set_exception_ports ( task = 0x%4.4x, exception_mask = 0x%8.8x, new_port = 0x%4.4x, behavior = 0x%8.8x, new_flavor = 0x%8.8x )", task, m_exc_port_info.mask, m_exception_port, (EXCEPTION_DEFAULT | MACH_EXCEPTION_CODES), THREAD_STATE_NONE); } if (err.Fail()) return false; // Create the exception thread err = ::pthread_create (&m_exception_thread, NULL, MachTask::ExceptionThread, this); return err.Success(); } else { DNBLogError("MachTask::%s (): task invalid, exception thread start failed.", __FUNCTION__); } return false; } kern_return_t MachTask::ShutDownExcecptionThread() { DNBError err; err = RestoreExceptionPortInfo(); // NULL our our exception port and let our exception thread exit mach_port_t exception_port = m_exception_port; m_exception_port = NULL; err.SetError(::pthread_cancel(m_exception_thread), DNBError::POSIX); if (DNBLogCheckLogBit(LOG_TASK) || err.Fail()) err.LogThreaded("::pthread_cancel ( thread = %p )", m_exception_thread); err.SetError(::pthread_join(m_exception_thread, NULL), DNBError::POSIX); if (DNBLogCheckLogBit(LOG_TASK) || err.Fail()) err.LogThreaded("::pthread_join ( thread = %p, value_ptr = NULL)", m_exception_thread); // Deallocate our exception port that we used to track our child process mach_port_t task_self = mach_task_self (); err = ::mach_port_deallocate (task_self, exception_port); if (DNBLogCheckLogBit(LOG_TASK) || err.Fail()) err.LogThreaded("::mach_port_deallocate ( task = 0x%4.4x, name = 0x%4.4x )", task_self, exception_port); return err.Error(); } void * MachTask::ExceptionThread (void *arg) { if (arg == NULL) return NULL; MachTask *mach_task = (MachTask*) arg; MachProcess *mach_proc = mach_task->Process(); DNBLogThreadedIf(LOG_EXCEPTIONS, "MachTask::%s ( arg = %p ) starting thread...", __FUNCTION__, arg); // We keep a count of the number of consecutive exceptions received so // we know to grab all exceptions without a timeout. We do this to get a // bunch of related exceptions on our exception port so we can process // then together. When we have multiple threads, we can get an exception // per thread and they will come in consecutively. The main loop in this // thread can stop periodically if needed to service things related to this // process. // flag set in the options, so we will wait forever for an exception on // our exception port. After we get one exception, we then will use the // MACH_RCV_TIMEOUT option with a zero timeout to grab all other current // exceptions for our process. After we have received the last pending // exception, we will get a timeout which enables us to then notify // our main thread that we have an exception bundle avaiable. We then wait // for the main thread to tell this exception thread to start trying to get // exceptions messages again and we start again with a mach_msg read with // infinite timeout. uint32_t num_exceptions_received = 0; DNBError err; task_t task = mach_task->TaskPort(); mach_msg_timeout_t periodic_timeout = 0; #ifdef WITH_SPRINGBOARD mach_msg_timeout_t watchdog_elapsed = 0; mach_msg_timeout_t watchdog_timeout = 60 * 1000; pid_t pid = mach_proc->ProcessID(); CFReleaser watchdog; if (mach_proc->ProcessUsingSpringBoard()) { // Request a renewal for every 60 seconds if we attached using SpringBoard watchdog.reset(::SBSWatchdogAssertionCreateForPID(NULL, pid, 60)); DNBLogThreadedIf(LOG_TASK, "::SBSWatchdogAssertionCreateForPID (NULL, %4.4x, 60 ) => %p", pid, watchdog.get()); if (watchdog.get()) { ::SBSWatchdogAssertionRenew (watchdog.get()); CFTimeInterval watchdogRenewalInterval = ::SBSWatchdogAssertionGetRenewalInterval (watchdog.get()); DNBLogThreadedIf(LOG_TASK, "::SBSWatchdogAssertionGetRenewalInterval ( %p ) => %g seconds", watchdog.get(), watchdogRenewalInterval); if (watchdogRenewalInterval > 0.0) { watchdog_timeout = (mach_msg_timeout_t)watchdogRenewalInterval * 1000; if (watchdog_timeout > 3000) watchdog_timeout -= 1000; // Give us a second to renew our timeout else if (watchdog_timeout > 1000) watchdog_timeout -= 250; // Give us a quarter of a second to renew our timeout } } if (periodic_timeout == 0 || periodic_timeout > watchdog_timeout) periodic_timeout = watchdog_timeout; } #endif // #ifdef WITH_SPRINGBOARD while (mach_task->ExceptionPortIsValid()) { ::pthread_testcancel (); MachException::Message exception_message; if (num_exceptions_received > 0) { // No timeout, just receive as many exceptions as we can since we already have one and we want // to get all currently available exceptions for this task err = exception_message.Receive(mach_task->ExceptionPort(), MACH_RCV_MSG | MACH_RCV_INTERRUPT | MACH_RCV_TIMEOUT, 0); } else if (periodic_timeout > 0) { // We need to stop periodically in this loop, so try and get a mach message with a valid timeout (ms) err = exception_message.Receive(mach_task->ExceptionPort(), MACH_RCV_MSG | MACH_RCV_INTERRUPT | MACH_RCV_TIMEOUT, periodic_timeout); } else { // We don't need to parse all current exceptions or stop periodically, // just wait for an exception forever. err = exception_message.Receive(mach_task->ExceptionPort(), MACH_RCV_MSG | MACH_RCV_INTERRUPT, 0); } if (err.Error() == MACH_RCV_INTERRUPTED) { // If we have no task port we should exit this thread if (!mach_task->ExceptionPortIsValid()) { DNBLogThreadedIf(LOG_EXCEPTIONS, "thread cancelled..."); break; } // Make sure our task is still valid if (MachTask::IsValid(task)) { // Task is still ok DNBLogThreadedIf(LOG_EXCEPTIONS, "interrupted, but task still valid, continuing..."); continue; } else { DNBLogThreadedIf(LOG_EXCEPTIONS, "task has exited..."); mach_proc->SetState(eStateExited); // Our task has died, exit the thread. break; } } else if (err.Error() == MACH_RCV_TIMED_OUT) { if (num_exceptions_received > 0) { // We were receiving all current exceptions with a timeout of zero // it is time to go back to our normal looping mode num_exceptions_received = 0; // Notify our main thread we have a complete exception message // bundle available. mach_proc->ExceptionMessageBundleComplete(); // in case we use a timeout value when getting exceptions... // Make sure our task is still valid if (MachTask::IsValid(task)) { // Task is still ok DNBLogThreadedIf(LOG_EXCEPTIONS, "got a timeout, continuing..."); continue; } else { DNBLogThreadedIf(LOG_EXCEPTIONS, "task has exited..."); mach_proc->SetState(eStateExited); // Our task has died, exit the thread. break; } continue; } #ifdef WITH_SPRINGBOARD if (watchdog.get()) { watchdog_elapsed += periodic_timeout; if (watchdog_elapsed >= watchdog_timeout) { DNBLogThreadedIf(LOG_TASK, "SBSWatchdogAssertionRenew ( %p )", watchdog.get()); ::SBSWatchdogAssertionRenew (watchdog.get()); watchdog_elapsed = 0; } } #endif } else if (err.Error() != KERN_SUCCESS) { DNBLogThreadedIf(LOG_EXCEPTIONS, "got some other error, do something about it??? nah, continuing for now..."); // TODO: notify of error? } else { if (exception_message.CatchExceptionRaise(task)) { ++num_exceptions_received; mach_proc->ExceptionMessageReceived(exception_message); } } } #ifdef WITH_SPRINGBOARD if (watchdog.get()) { // TODO: change SBSWatchdogAssertionRelease to SBSWatchdogAssertionCancel when we // all are up and running on systems that support it. The SBS framework has a #define // that will forward SBSWatchdogAssertionRelease to SBSWatchdogAssertionCancel for now // so it should still build either way. DNBLogThreadedIf(LOG_TASK, "::SBSWatchdogAssertionRelease(%p)", watchdog.get()); ::SBSWatchdogAssertionRelease (watchdog.get()); } #endif // #ifdef WITH_SPRINGBOARD DNBLogThreadedIf(LOG_EXCEPTIONS, "MachTask::%s (%p): thread exiting...", __FUNCTION__, arg); return NULL; } // So the TASK_DYLD_INFO used to just return the address of the all image infos // as a single member called "all_image_info". Then someone decided it would be // a good idea to rename this first member to "all_image_info_addr" and add a // size member called "all_image_info_size". This of course can not be detected // using code or #defines. So to hack around this problem, we define our own // version of the TASK_DYLD_INFO structure so we can guarantee what is inside it. struct hack_task_dyld_info { mach_vm_address_t all_image_info_addr; mach_vm_size_t all_image_info_size; }; nub_addr_t MachTask::GetDYLDAllImageInfosAddress (DNBError& err) { struct hack_task_dyld_info dyld_info; mach_msg_type_number_t count = TASK_DYLD_INFO_COUNT; // Make sure that COUNT isn't bigger than our hacked up struct hack_task_dyld_info. // If it is, then make COUNT smaller to match. if (count > (sizeof(struct hack_task_dyld_info) / sizeof(natural_t))) count = (sizeof(struct hack_task_dyld_info) / sizeof(natural_t)); task_t task = TaskPortForProcessID (err); if (err.Success()) { err = ::task_info (task, TASK_DYLD_INFO, (task_info_t)&dyld_info, &count); if (err.Success()) { // We now have the address of the all image infos structure return dyld_info.all_image_info_addr; } } return INVALID_NUB_ADDRESS; } //---------------------------------------------------------------------- // MachTask::AllocateMemory //---------------------------------------------------------------------- nub_addr_t MachTask::AllocateMemory (size_t size, uint32_t permissions) { mach_vm_address_t addr; task_t task = TaskPort(); if (task == TASK_NULL) return INVALID_NUB_ADDRESS; DNBError err; err = ::mach_vm_allocate (task, &addr, size, TRUE); if (err.Error() == KERN_SUCCESS) { // Set the protections: vm_prot_t mach_prot = VM_PROT_NONE; if (permissions & eMemoryPermissionsReadable) mach_prot |= VM_PROT_READ; if (permissions & eMemoryPermissionsWritable) mach_prot |= VM_PROT_WRITE; if (permissions & eMemoryPermissionsExecutable) mach_prot |= VM_PROT_EXECUTE; err = ::mach_vm_protect (task, addr, size, 0, mach_prot); if (err.Error() == KERN_SUCCESS) { m_allocations.insert (std::make_pair(addr, size)); return addr; } ::mach_vm_deallocate (task, addr, size); } return INVALID_NUB_ADDRESS; } //---------------------------------------------------------------------- // MachTask::DeallocateMemory //---------------------------------------------------------------------- nub_bool_t MachTask::DeallocateMemory (nub_addr_t addr) { task_t task = TaskPort(); if (task == TASK_NULL) return false; // We have to stash away sizes for the allocations... allocation_collection::iterator pos, end = m_allocations.end(); for (pos = m_allocations.begin(); pos != end; pos++) { if ((*pos).first == addr) { m_allocations.erase(pos); #define ALWAYS_ZOMBIE_ALLOCATIONS 0 if (ALWAYS_ZOMBIE_ALLOCATIONS || getenv ("DEBUGSERVER_ZOMBIE_ALLOCATIONS")) { ::mach_vm_protect (task, (*pos).first, (*pos).second, 0, VM_PROT_NONE); return true; } else return ::mach_vm_deallocate (task, (*pos).first, (*pos).second) == KERN_SUCCESS; } } return false; } static void foundStackLog(mach_stack_logging_record_t record, void *context) { *((bool*)context) = true; } bool MachTask::HasMallocLoggingEnabled () { bool found = false; __mach_stack_logging_enumerate_records(m_task, 0x0, foundStackLog, &found); return found; } struct history_enumerator_impl_data { MachMallocEvent *buffer; uint32_t *position; uint32_t count; }; static void history_enumerator_impl(mach_stack_logging_record_t record, void* enum_obj) { history_enumerator_impl_data *data = (history_enumerator_impl_data*)enum_obj; if (*data->position >= data->count) return; data->buffer[*data->position].m_base_address = record.address; data->buffer[*data->position].m_size = record.argument; data->buffer[*data->position].m_event_id = record.stack_identifier; data->buffer[*data->position].m_event_type = record.type_flags == stack_logging_type_alloc ? eMachMallocEventTypeAlloc : record.type_flags == stack_logging_type_dealloc ? eMachMallocEventTypeDealloc : eMachMallocEventTypeOther; *data->position+=1; } bool MachTask::EnumerateMallocRecords (MachMallocEvent *event_buffer, uint32_t buffer_size, uint32_t *count) { return EnumerateMallocRecords(0, event_buffer, buffer_size, count); } bool MachTask::EnumerateMallocRecords (mach_vm_address_t address, MachMallocEvent *event_buffer, uint32_t buffer_size, uint32_t *count) { if (!event_buffer || !count) return false; if (buffer_size == 0) return false; *count = 0; history_enumerator_impl_data data = { event_buffer, count, buffer_size }; __mach_stack_logging_enumerate_records(m_task, address, history_enumerator_impl, &data); return (*count > 0); } bool MachTask::EnumerateMallocFrames (MachMallocEventId event_id, mach_vm_address_t *function_addresses_buffer, uint32_t buffer_size, uint32_t *count) { if (!function_addresses_buffer || !count) return false; if (buffer_size == 0) return false; __mach_stack_logging_frames_for_uniqued_stack(m_task, event_id, &function_addresses_buffer[0], buffer_size, count); *count -= 1; if (function_addresses_buffer[*count-1] < PageSize()) *count -= 1; return (*count > 0); } nub_size_t MachTask::PageSize () { return m_vm_memory.PageSize (m_task); }