/* * Copyright (c) Atmosphère-NX * * This program is free software; you can redistribute it and/or modify it * under the terms and conditions of the GNU General Public License, * version 2, as published by the Free Software Foundation. * * This program is distributed in the hope it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for * more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include namespace ams::kern { namespace { constexpr inline s32 TerminatingThreadPriority = ams::svc::SystemThreadPriorityHighest - 1; constinit util::Atomic g_thread_id = 0; constexpr ALWAYS_INLINE bool IsKernelAddressKey(KProcessAddress key) { const uintptr_t key_uptr = GetInteger(key); return KernelVirtualAddressSpaceBase <= key_uptr && key_uptr <= KernelVirtualAddressSpaceLast && (key_uptr & 1) == 0; } void InitializeKernelStack(uintptr_t stack_top) { #if defined(MESOSPHERE_ENABLE_KERNEL_STACK_USAGE) const uintptr_t stack_bottom = stack_top - PageSize; std::memset(reinterpret_cast(stack_bottom), 0xCC, PageSize - sizeof(KThread::StackParameters)); #else MESOSPHERE_UNUSED(stack_top); #endif } void CleanupKernelStack(uintptr_t stack_top) { const uintptr_t stack_bottom = stack_top - PageSize; KPhysicalAddress stack_paddr = Null; MESOSPHERE_ABORT_UNLESS(Kernel::GetKernelPageTable().GetPhysicalAddress(std::addressof(stack_paddr), stack_bottom)); MESOSPHERE_R_ABORT_UNLESS(Kernel::GetKernelPageTable().UnmapPages(stack_bottom, 1, KMemoryState_Kernel)); /* Free the stack page. */ KPageBuffer::Free(KPageBuffer::FromPhysicalAddress(stack_paddr)); } class ThreadQueueImplForKThreadSleep final : public KThreadQueueWithoutEndWait { /* ... */ }; class ThreadQueueImplForKThreadSetProperty final : public KThreadQueue { private: KThread::WaiterList *m_wait_list; public: constexpr ThreadQueueImplForKThreadSetProperty(KThread::WaiterList *wl) : m_wait_list(wl) { /* ... */ } virtual void CancelWait(KThread *waiting_thread, Result wait_result, bool cancel_timer_task) override { /* Remove the thread from the wait list. */ m_wait_list->erase(m_wait_list->iterator_to(*waiting_thread)); /* Invoke the base cancel wait handler. */ KThreadQueue::CancelWait(waiting_thread, wait_result, cancel_timer_task); } }; } Result KThread::Initialize(KThreadFunction func, uintptr_t arg, void *kern_stack_top, KProcessAddress user_stack_top, s32 prio, s32 virt_core, KProcess *owner, ThreadType type) { /* Assert parameters are valid. */ MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(kern_stack_top != nullptr); MESOSPHERE_ASSERT((type == ThreadType_Main) || (ams::svc::HighestThreadPriority <= prio && prio <= ams::svc::LowestThreadPriority)); MESOSPHERE_ASSERT((owner != nullptr) || (type != ThreadType_User)); MESOSPHERE_ASSERT(0 <= virt_core && virt_core < static_cast(BITSIZEOF(u64))); /* Convert the virtual core to a physical core. */ const s32 phys_core = cpu::VirtualToPhysicalCoreMap[virt_core]; MESOSPHERE_ASSERT(0 <= phys_core && phys_core < static_cast(cpu::NumCores)); /* First, clear the TLS address. */ m_tls_address = Null; const uintptr_t kern_stack_top_address = reinterpret_cast(kern_stack_top); MESOSPHERE_UNUSED(kern_stack_top_address); /* Next, assert things based on the type. */ switch (type) { case ThreadType_Main: { MESOSPHERE_ASSERT(arg == 0); } [[fallthrough]]; case ThreadType_HighPriority: if (type != ThreadType_Main) { MESOSPHERE_ASSERT(phys_core == GetCurrentCoreId()); } [[fallthrough]]; case ThreadType_Kernel: { MESOSPHERE_ASSERT(user_stack_top == 0); MESOSPHERE_ASSERT(util::IsAligned(kern_stack_top_address, PageSize)); } [[fallthrough]]; case ThreadType_User: { MESOSPHERE_ASSERT(((owner == nullptr) || (owner->GetCoreMask() | (1ul << virt_core)) == owner->GetCoreMask())); MESOSPHERE_ASSERT(((owner == nullptr) || (owner->GetPriorityMask() | (1ul << prio)) == owner->GetPriorityMask())); } break; default: MESOSPHERE_PANIC("KThread::Initialize: Unknown ThreadType %u", static_cast(type)); break; } /* Set the ideal core ID and affinity mask. */ m_virtual_ideal_core_id = virt_core; m_physical_ideal_core_id = phys_core; m_virtual_affinity_mask = (static_cast(1) << virt_core); m_physical_affinity_mask.SetAffinity(phys_core, true); /* Set the thread state. */ m_thread_state = (type == ThreadType_Main) ? ThreadState_Runnable : ThreadState_Initialized; /* Set TLS address and TLS heap address. */ /* NOTE: Nintendo wrote TLS address above already, but official code really does write tls address twice. */ m_tls_address = 0; m_tls_heap_address = 0; /* Set parent and condvar tree. */ m_parent = nullptr; m_condvar_tree = nullptr; m_condvar_key = 0; /* Set sync booleans. */ m_signaled = false; m_termination_requested = false; m_wait_cancelled = false; m_cancellable = false; /* Set core ID and wait result. */ m_core_id = phys_core; m_wait_result = svc::ResultNoSynchronizationObject(); /* Set the stack top. */ m_kernel_stack_top = kern_stack_top; /* Set priorities. */ m_priority = prio; m_base_priority = prio; /* Initialize wait queue/sync index. */ m_synced_index = -1; m_wait_queue = nullptr; /* Set suspend flags. */ m_suspend_request_flags = 0; m_suspend_allowed_flags = ThreadState_SuspendFlagMask; /* We're neither debug attached, nor are we nesting our priority inheritance. */ m_debug_attached = false; m_priority_inheritance_count = 0; /* We haven't been scheduled, and we have done no light IPC. */ m_schedule_count = -1; m_last_scheduled_tick = 0; m_light_ipc_data = nullptr; /* We're not waiting for a lock, and we haven't disabled migration. */ m_lock_owner = nullptr; m_num_core_migration_disables = 0; /* We have no waiters, and no closed objects. */ m_num_kernel_waiters = 0; m_closed_object = nullptr; /* Set our current core id. */ m_current_core_id = phys_core; /* We haven't released our resource limit hint, and we've spent no time on the cpu. */ m_resource_limit_release_hint = false; m_cpu_time = 0; /* Setup our kernel stack. */ if (type != ThreadType_Main) { InitializeKernelStack(reinterpret_cast(kern_stack_top)); } /* Clear our stack parameters. */ std::memset(static_cast(std::addressof(this->GetStackParameters())), 0, sizeof(StackParameters)); /* Setup the TLS, if needed. */ if (type == ThreadType_User) { R_TRY(owner->CreateThreadLocalRegion(std::addressof(m_tls_address))); m_tls_heap_address = owner->GetThreadLocalRegionPointer(m_tls_address); std::memset(m_tls_heap_address, 0, ams::svc::ThreadLocalRegionSize); } /* Set parent, if relevant. */ if (owner != nullptr) { m_parent = owner; m_parent->Open(); } /* Initialize thread context. */ constexpr bool IsDefault64Bit = sizeof(uintptr_t) == sizeof(u64); const bool is_64_bit = m_parent ? m_parent->Is64Bit() : IsDefault64Bit; const bool is_user = (type == ThreadType_User); const bool is_main = (type == ThreadType_Main); m_thread_context.Initialize(reinterpret_cast(func), reinterpret_cast(this->GetStackTop()), GetInteger(user_stack_top), arg, is_user, is_64_bit, is_main); /* Setup the stack parameters. */ StackParameters &sp = this->GetStackParameters(); if (m_parent != nullptr) { m_parent->CopySvcPermissionsTo(sp); } sp.context = std::addressof(m_thread_context); sp.cur_thread = this; sp.disable_count = 1; this->SetInExceptionHandler(); /* Set thread ID. */ m_thread_id = g_thread_id++; /* We initialized! */ m_initialized = true; /* Register ourselves with our parent process. */ if (m_parent != nullptr) { m_parent->RegisterThread(this); if (m_parent->IsSuspended()) { this->RequestSuspend(SuspendType_Process); } } return ResultSuccess(); } Result KThread::InitializeThread(KThread *thread, KThreadFunction func, uintptr_t arg, KProcessAddress user_stack_top, s32 prio, s32 core, KProcess *owner, ThreadType type) { /* Get stack region for the thread. */ const auto &stack_region = KMemoryLayout::GetKernelStackRegion(); MESOSPHERE_ABORT_UNLESS(stack_region.GetEndAddress() != 0); /* Allocate a page to use as the thread. */ KPageBuffer *page = KPageBuffer::Allocate(); R_UNLESS(page != nullptr, svc::ResultOutOfResource()); /* Map the stack page. */ KProcessAddress stack_top = Null; { KProcessAddress stack_bottom = Null; auto page_guard = SCOPE_GUARD { KPageBuffer::Free(page); }; R_TRY(Kernel::GetKernelPageTable().MapPages(std::addressof(stack_bottom), 1, PageSize, page->GetPhysicalAddress(), stack_region.GetAddress(), stack_region.GetSize() / PageSize, KMemoryState_Kernel, KMemoryPermission_KernelReadWrite)); page_guard.Cancel(); /* Calculate top of the stack. */ stack_top = stack_bottom + PageSize; } /* Initialize the thread. */ auto map_guard = SCOPE_GUARD { CleanupKernelStack(GetInteger(stack_top)); }; R_TRY(thread->Initialize(func, arg, GetVoidPointer(stack_top), user_stack_top, prio, core, owner, type)); map_guard.Cancel(); return ResultSuccess(); } void KThread::PostDestroy(uintptr_t arg) { KProcess *owner = reinterpret_cast(arg & ~1ul); const bool resource_limit_release_hint = (arg & 1); const s64 hint_value = (resource_limit_release_hint ? 0 : 1); if (owner != nullptr) { owner->ReleaseResource(ams::svc::LimitableResource_ThreadCountMax, 1, hint_value); owner->Close(); } else { Kernel::GetSystemResourceLimit().Release(ams::svc::LimitableResource_ThreadCountMax, 1, hint_value); } } void KThread::ResumeThreadsSuspendedForInit() { KThread::ListAccessor list_accessor; { KScopedSchedulerLock sl; for (auto &thread : list_accessor) { static_cast(thread).Resume(SuspendType_Init); } } } void KThread::Finalize() { MESOSPHERE_ASSERT_THIS(); /* If the thread has an owner process, unregister it. */ if (m_parent != nullptr) { m_parent->UnregisterThread(this); } /* If the thread has a local region, delete it. */ if (m_tls_address != Null) { MESOSPHERE_R_ABORT_UNLESS(m_parent->DeleteThreadLocalRegion(m_tls_address)); } /* Release any waiters. */ { MESOSPHERE_ASSERT(m_lock_owner == nullptr); KScopedSchedulerLock sl; auto it = m_waiter_list.begin(); while (it != m_waiter_list.end()) { /* Get the thread. */ KThread * const waiter = std::addressof(*it); /* The thread shouldn't be a kernel waiter. */ MESOSPHERE_ASSERT(!IsKernelAddressKey(waiter->GetAddressKey())); /* Clear the lock owner. */ waiter->SetLockOwner(nullptr); /* Erase the waiter from our list. */ it = m_waiter_list.erase(it); /* Cancel the thread's wait. */ waiter->CancelWait(svc::ResultInvalidState(), true); } } /* Finalize the thread context. */ m_thread_context.Finalize(); /* Cleanup the kernel stack. */ if (m_kernel_stack_top != nullptr) { CleanupKernelStack(reinterpret_cast(m_kernel_stack_top)); } /* Perform inherited finalization. */ KAutoObjectWithSlabHeapAndContainer::Finalize(); } bool KThread::IsSignaled() const { return m_signaled; } void KThread::OnTimer() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); /* If we're waiting, cancel the wait. */ if (this->GetState() == ThreadState_Waiting) { m_wait_queue->CancelWait(this, svc::ResultTimedOut(), false); } } void KThread::StartTermination() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); /* Release user exception and unpin, if relevant. */ if (m_parent != nullptr) { m_parent->ReleaseUserException(this); if (m_parent->GetPinnedThread(GetCurrentCoreId()) == this) { m_parent->UnpinCurrentThread(); } } /* Set state to terminated. */ this->SetState(KThread::ThreadState_Terminated); /* Clear the thread's status as running in parent. */ if (m_parent != nullptr) { m_parent->ClearRunningThread(this); } /* Signal. */ m_signaled = true; KSynchronizationObject::NotifyAvailable(); /* Call the on thread termination handler. */ KThreadContext::OnThreadTerminating(this); /* Clear previous thread in KScheduler. */ KScheduler::ClearPreviousThread(this); /* Register terminated dpc flag. */ this->RegisterDpc(DpcFlag_Terminated); } void KThread::FinishTermination() { MESOSPHERE_ASSERT_THIS(); /* Ensure that the thread is not executing on any core. */ if (m_parent != nullptr) { for (size_t i = 0; i < cpu::NumCores; ++i) { KThread *core_thread; do { core_thread = Kernel::GetScheduler(i).GetSchedulerCurrentThread(); } while (core_thread == this); } } /* Close the thread. */ this->Close(); } void KThread::DoWorkerTask() { /* Finish the termination that was begun by Exit(). */ this->FinishTermination(); } void KThread::Pin() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); /* Set ourselves as pinned. */ this->GetStackParameters().is_pinned = true; /* Disable core migration. */ MESOSPHERE_ASSERT(m_num_core_migration_disables == 0); { ++m_num_core_migration_disables; /* Save our ideal state to restore when we're unpinned. */ m_original_physical_ideal_core_id = m_physical_ideal_core_id; m_original_physical_affinity_mask = m_physical_affinity_mask; /* Bind ourselves to this core. */ const s32 active_core = this->GetActiveCore(); const s32 current_core = GetCurrentCoreId(); this->SetActiveCore(current_core); m_physical_ideal_core_id = current_core; m_physical_affinity_mask.SetAffinityMask(1ul << current_core); if (active_core != current_core || m_physical_affinity_mask.GetAffinityMask() != m_original_physical_affinity_mask.GetAffinityMask()) { KScheduler::OnThreadAffinityMaskChanged(this, m_original_physical_affinity_mask, active_core); } /* Set base priority-on-unpin. */ const s32 old_base_priority = m_base_priority; m_base_priority_on_unpin = old_base_priority; /* Set base priority to higher than any possible process priority. */ m_base_priority = std::min(old_base_priority, __builtin_ctzll(this->GetOwnerProcess()->GetPriorityMask()) - 1); RestorePriority(this); } /* Disallow performing thread suspension. */ { /* Update our allow flags. */ m_suspend_allowed_flags &= ~(1 << (util::ToUnderlying(SuspendType_Thread) + util::ToUnderlying(ThreadState_SuspendShift))); /* Update our state. */ this->UpdateState(); } /* Update our SVC access permissions. */ MESOSPHERE_ASSERT(m_parent != nullptr); m_parent->CopyPinnedSvcPermissionsTo(this->GetStackParameters()); } void KThread::Unpin() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); /* Set ourselves as unpinned. */ this->GetStackParameters().is_pinned = false; /* Enable core migration. */ MESOSPHERE_ASSERT(m_num_core_migration_disables == 1); { --m_num_core_migration_disables; /* Restore our original state. */ const KAffinityMask old_mask = m_physical_affinity_mask; m_physical_ideal_core_id = m_original_physical_ideal_core_id; m_physical_affinity_mask = m_original_physical_affinity_mask; if (m_physical_affinity_mask.GetAffinityMask() != old_mask.GetAffinityMask()) { const s32 active_core = this->GetActiveCore(); if (!m_physical_affinity_mask.GetAffinity(active_core)) { if (m_physical_ideal_core_id >= 0) { this->SetActiveCore(m_physical_ideal_core_id); } else { this->SetActiveCore(BITSIZEOF(unsigned long long) - 1 - __builtin_clzll(m_physical_affinity_mask.GetAffinityMask())); } } KScheduler::OnThreadAffinityMaskChanged(this, old_mask, active_core); } m_base_priority = m_base_priority_on_unpin; RestorePriority(this); } /* Allow performing thread suspension (if termination hasn't been requested). */ if (!this->IsTerminationRequested()) { /* Update our allow flags. */ m_suspend_allowed_flags |= (1 << (util::ToUnderlying(SuspendType_Thread) + util::ToUnderlying(ThreadState_SuspendShift))); /* Update our state. */ this->UpdateState(); /* Update our SVC access permissions. */ MESOSPHERE_ASSERT(m_parent != nullptr); m_parent->CopyUnpinnedSvcPermissionsTo(this->GetStackParameters()); } /* Resume any threads that began waiting on us while we were pinned. */ for (auto it = m_pinned_waiter_list.begin(); it != m_pinned_waiter_list.end(); it = m_pinned_waiter_list.erase(it)) { it->EndWait(ResultSuccess()); } } void KThread::DisableCoreMigration() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(this == GetCurrentThreadPointer()); KScopedSchedulerLock sl; MESOSPHERE_ASSERT(m_num_core_migration_disables >= 0); if ((m_num_core_migration_disables++) == 0) { /* Save our ideal state to restore when we can migrate again. */ m_original_physical_ideal_core_id = m_physical_ideal_core_id; m_original_physical_affinity_mask = m_physical_affinity_mask; /* Bind ourselves to this core. */ const s32 active_core = this->GetActiveCore(); m_physical_ideal_core_id = active_core; m_physical_affinity_mask.SetAffinityMask(1ul << active_core); if (m_physical_affinity_mask.GetAffinityMask() != m_original_physical_affinity_mask.GetAffinityMask()) { KScheduler::OnThreadAffinityMaskChanged(this, m_original_physical_affinity_mask, active_core); } } } void KThread::EnableCoreMigration() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(this == GetCurrentThreadPointer()); KScopedSchedulerLock sl; MESOSPHERE_ASSERT(m_num_core_migration_disables > 0); if ((--m_num_core_migration_disables) == 0) { const KAffinityMask old_mask = m_physical_affinity_mask; /* Restore our ideals. */ m_physical_ideal_core_id = m_original_physical_ideal_core_id; m_physical_affinity_mask = m_original_physical_affinity_mask; if (m_physical_affinity_mask.GetAffinityMask() != old_mask.GetAffinityMask()) { const s32 active_core = this->GetActiveCore(); if (!m_physical_affinity_mask.GetAffinity(active_core)) { if (m_physical_ideal_core_id >= 0) { this->SetActiveCore(m_physical_ideal_core_id); } else { this->SetActiveCore(BITSIZEOF(unsigned long long) - 1 - __builtin_clzll(m_physical_affinity_mask.GetAffinityMask())); } } KScheduler::OnThreadAffinityMaskChanged(this, old_mask, active_core); } } } Result KThread::GetCoreMask(int32_t *out_ideal_core, u64 *out_affinity_mask) { MESOSPHERE_ASSERT_THIS(); { KScopedSchedulerLock sl; /* Get the virtual mask. */ *out_ideal_core = m_virtual_ideal_core_id; *out_affinity_mask = m_virtual_affinity_mask; } return ResultSuccess(); } Result KThread::GetPhysicalCoreMask(int32_t *out_ideal_core, u64 *out_affinity_mask) { MESOSPHERE_ASSERT_THIS(); { KScopedSchedulerLock sl; MESOSPHERE_ASSERT(m_num_core_migration_disables >= 0); /* Select between core mask and original core mask. */ if (m_num_core_migration_disables == 0) { *out_ideal_core = m_physical_ideal_core_id; *out_affinity_mask = m_physical_affinity_mask.GetAffinityMask(); } else { *out_ideal_core = m_original_physical_ideal_core_id; *out_affinity_mask = m_original_physical_affinity_mask.GetAffinityMask(); } } return ResultSuccess(); } Result KThread::SetCoreMask(int32_t core_id, u64 v_affinity_mask) { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(m_parent != nullptr); MESOSPHERE_ASSERT(v_affinity_mask != 0); KScopedLightLock lk(m_activity_pause_lock); /* Set the core mask. */ u64 p_affinity_mask = 0; { KScopedSchedulerLock sl; MESOSPHERE_ASSERT(m_num_core_migration_disables >= 0); /* If we're updating, set our ideal virtual core. */ if (core_id != ams::svc::IdealCoreNoUpdate) { m_virtual_ideal_core_id = core_id; } else { /* Preserve our ideal core id. */ core_id = m_virtual_ideal_core_id; R_UNLESS(((1ul << core_id) & v_affinity_mask) != 0, svc::ResultInvalidCombination()); } /* Set our affinity mask. */ m_virtual_affinity_mask = v_affinity_mask; /* Translate the virtual core to a physical core. */ if (core_id >= 0) { core_id = cpu::VirtualToPhysicalCoreMap[core_id]; } /* Translate the virtual affinity mask to a physical one. */ while (v_affinity_mask != 0) { const u64 next = __builtin_ctzll(v_affinity_mask); v_affinity_mask &= ~(1ul << next); p_affinity_mask |= (1ul << cpu::VirtualToPhysicalCoreMap[next]); } /* If we haven't disabled migration, perform an affinity change. */ if (m_num_core_migration_disables == 0) { const KAffinityMask old_mask = m_physical_affinity_mask; /* Set our new ideals. */ m_physical_ideal_core_id = core_id; m_physical_affinity_mask.SetAffinityMask(p_affinity_mask); if (m_physical_affinity_mask.GetAffinityMask() != old_mask.GetAffinityMask()) { const s32 active_core = this->GetActiveCore(); if (active_core >= 0 && !m_physical_affinity_mask.GetAffinity(active_core)) { const s32 new_core = m_physical_ideal_core_id >= 0 ? m_physical_ideal_core_id : BITSIZEOF(unsigned long long) - 1 - __builtin_clzll(m_physical_affinity_mask.GetAffinityMask()); this->SetActiveCore(new_core); } KScheduler::OnThreadAffinityMaskChanged(this, old_mask, active_core); } } else { /* Otherwise, we edit the original affinity for restoration later. */ m_original_physical_ideal_core_id = core_id; m_original_physical_affinity_mask.SetAffinityMask(p_affinity_mask); } } /* Update the pinned waiter list. */ ThreadQueueImplForKThreadSetProperty wait_queue(std::addressof(m_pinned_waiter_list)); { bool retry_update; do { /* Lock the scheduler. */ KScopedSchedulerLock sl; /* Don't do any further management if our termination has been requested. */ R_SUCCEED_IF(this->IsTerminationRequested()); /* By default, we won't need to retry. */ retry_update = false; /* Check if the thread is currently running. */ bool thread_is_current = false; s32 thread_core; for (thread_core = 0; thread_core < static_cast(cpu::NumCores); ++thread_core) { if (Kernel::GetScheduler(thread_core).GetSchedulerCurrentThread() == this) { thread_is_current = true; break; } } /* If the thread is currently running, check whether it's no longer allowed under the new mask. */ if (thread_is_current && ((1ul << thread_core) & p_affinity_mask) == 0) { /* If the thread is pinned, we want to wait until it's not pinned. */ if (this->GetStackParameters().is_pinned) { /* Verify that the current thread isn't terminating. */ R_UNLESS(!GetCurrentThread().IsTerminationRequested(), svc::ResultTerminationRequested()); /* Wait until the thread isn't pinned any more. */ m_pinned_waiter_list.push_back(GetCurrentThread()); GetCurrentThread().BeginWait(std::addressof(wait_queue)); } else { /* If the thread isn't pinned, release the scheduler lock and retry until it's not current. */ retry_update = true; } } } while (retry_update); } return ResultSuccess(); } void KThread::SetBasePriority(s32 priority) { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(ams::svc::HighestThreadPriority <= priority && priority <= ams::svc::LowestThreadPriority); KScopedSchedulerLock sl; /* Determine the priority value to use. */ const s32 target_priority = m_termination_requested.Load() && priority >= TerminatingThreadPriority ? TerminatingThreadPriority : priority; /* Change our base priority. */ if (this->GetStackParameters().is_pinned) { m_base_priority_on_unpin = target_priority; } else { m_base_priority = target_priority; } /* Perform a priority restoration. */ RestorePriority(this); } void KThread::IncreaseBasePriority(s32 priority) { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(ams::svc::HighestThreadPriority <= priority && priority <= ams::svc::LowestThreadPriority); /* Set our unpin base priority, if we're pinned. */ if (this->GetStackParameters().is_pinned && m_base_priority_on_unpin > priority) { m_base_priority_on_unpin = priority; } /* Set our base priority. */ if (m_base_priority > priority) { m_base_priority = priority; /* Perform a priority restoration. */ RestorePriority(this); } } Result KThread::SetPriorityToIdle() { MESOSPHERE_ASSERT_THIS(); KScopedSchedulerLock sl; /* Change both our priorities to the idle thread priority. */ const s32 old_priority = m_priority; m_priority = IdleThreadPriority; m_base_priority = IdleThreadPriority; KScheduler::OnThreadPriorityChanged(this, old_priority); return ResultSuccess(); } void KThread::RequestSuspend(SuspendType type) { MESOSPHERE_ASSERT_THIS(); KScopedSchedulerLock lk; /* Note the request in our flags. */ m_suspend_request_flags |= (1u << (util::ToUnderlying(ThreadState_SuspendShift) + util::ToUnderlying(type))); /* Try to perform the suspend. */ this->TrySuspend(); } void KThread::Resume(SuspendType type) { MESOSPHERE_ASSERT_THIS(); KScopedSchedulerLock sl; /* Clear the request in our flags. */ m_suspend_request_flags &= ~(1u << (util::ToUnderlying(ThreadState_SuspendShift) + util::ToUnderlying(type))); /* Update our state. */ this->UpdateState(); } void KThread::WaitCancel() { MESOSPHERE_ASSERT_THIS(); KScopedSchedulerLock sl; /* Check if we're waiting and cancellable. */ if (this->GetState() == ThreadState_Waiting && m_cancellable) { m_wait_cancelled = false; m_wait_queue->CancelWait(this, svc::ResultCancelled(), true); } else { /* Otherwise, note that we cancelled a wait. */ m_wait_cancelled = true; } } void KThread::TrySuspend() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); MESOSPHERE_ASSERT(this->IsSuspendRequested()); /* Ensure that we have no waiters. */ if (this->GetNumKernelWaiters() > 0) { return; } MESOSPHERE_ABORT_UNLESS(this->GetNumKernelWaiters() == 0); /* Perform the suspend. */ this->UpdateState(); } void KThread::UpdateState() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); /* Set our suspend flags in state. */ const auto old_state = m_thread_state; const auto new_state = static_cast(this->GetSuspendFlags() | (old_state & ThreadState_Mask)); m_thread_state = new_state; /* Note the state change in scheduler. */ if (new_state != old_state) { KScheduler::OnThreadStateChanged(this, old_state); } } void KThread::Continue() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); /* Clear our suspend flags in state. */ const auto old_state = m_thread_state; m_thread_state = static_cast(old_state & ThreadState_Mask); /* Note the state change in scheduler. */ KScheduler::OnThreadStateChanged(this, old_state); } size_t KThread::GetKernelStackUsage() const { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(m_kernel_stack_top != nullptr); #if defined(MESOSPHERE_ENABLE_KERNEL_STACK_USAGE) const u8 *stack = static_cast(m_kernel_stack_top) - PageSize; size_t i; for (i = 0; i < PageSize; ++i) { if (stack[i] != 0xCC) { break; } } return PageSize - i; #else return 0; #endif } Result KThread::SetActivity(ams::svc::ThreadActivity activity) { /* Lock ourselves. */ KScopedLightLock lk(m_activity_pause_lock); /* Set the activity. */ { /* Lock the scheduler. */ KScopedSchedulerLock sl; /* Verify our state. */ const auto cur_state = this->GetState(); R_UNLESS((cur_state == ThreadState_Waiting || cur_state == ThreadState_Runnable), svc::ResultInvalidState()); /* Either pause or resume. */ if (activity == ams::svc::ThreadActivity_Paused) { /* Verify that we're not suspended. */ R_UNLESS(!this->IsSuspendRequested(SuspendType_Thread), svc::ResultInvalidState()); /* Suspend. */ this->RequestSuspend(SuspendType_Thread); } else { MESOSPHERE_ASSERT(activity == ams::svc::ThreadActivity_Runnable); /* Verify that we're suspended. */ R_UNLESS(this->IsSuspendRequested(SuspendType_Thread), svc::ResultInvalidState()); /* Resume. */ this->Resume(SuspendType_Thread); } } /* If the thread is now paused, update the pinned waiter list. */ if (activity == ams::svc::ThreadActivity_Paused) { ThreadQueueImplForKThreadSetProperty wait_queue(std::addressof(m_pinned_waiter_list)); bool thread_is_current; do { /* Lock the scheduler. */ KScopedSchedulerLock sl; /* Don't do any further management if our termination has been requested. */ R_SUCCEED_IF(this->IsTerminationRequested()); /* By default, treat the thread as not current. */ thread_is_current = false; /* Check whether the thread is pinned. */ if (this->GetStackParameters().is_pinned) { /* Verify that the current thread isn't terminating. */ R_UNLESS(!GetCurrentThread().IsTerminationRequested(), svc::ResultTerminationRequested()); /* Wait until the thread isn't pinned any more. */ m_pinned_waiter_list.push_back(GetCurrentThread()); GetCurrentThread().BeginWait(std::addressof(wait_queue)); } else { /* Check if the thread is currently running. */ /* If it is, we'll need to retry. */ for (auto i = 0; i < static_cast(cpu::NumCores); ++i) { if (Kernel::GetScheduler(i).GetSchedulerCurrentThread() == this) { thread_is_current = true; break; } } } } while (thread_is_current); } return ResultSuccess(); } Result KThread::GetThreadContext3(ams::svc::ThreadContext *out) { /* Lock ourselves. */ KScopedLightLock lk(m_activity_pause_lock); /* Get the context. */ { /* Lock the scheduler. */ KScopedSchedulerLock sl; /* Verify that we're suspended. */ R_UNLESS(this->IsSuspendRequested(SuspendType_Thread), svc::ResultInvalidState()); /* If we're not terminating, get the thread's user context. */ if (!this->IsTerminationRequested()) { GetUserContext(out, this); } } return ResultSuccess(); } void KThread::AddWaiterImpl(KThread *thread) { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); /* Find the right spot to insert the waiter. */ auto it = m_waiter_list.begin(); while (it != m_waiter_list.end()) { if (it->GetPriority() > thread->GetPriority()) { break; } it++; } /* Keep track of how many kernel waiters we have. */ if (IsKernelAddressKey(thread->GetAddressKey())) { MESOSPHERE_ABORT_UNLESS((m_num_kernel_waiters++) >= 0); KScheduler::SetSchedulerUpdateNeeded(); } /* Insert the waiter. */ m_waiter_list.insert(it, *thread); thread->SetLockOwner(this); } void KThread::RemoveWaiterImpl(KThread *thread) { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); /* Keep track of how many kernel waiters we have. */ if (IsKernelAddressKey(thread->GetAddressKey())) { MESOSPHERE_ABORT_UNLESS((m_num_kernel_waiters--) > 0); KScheduler::SetSchedulerUpdateNeeded(); } /* Remove the waiter. */ m_waiter_list.erase(m_waiter_list.iterator_to(*thread)); thread->SetLockOwner(nullptr); } void KThread::RestorePriority(KThread *thread) { MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); while (true) { /* We want to inherit priority where possible. */ s32 new_priority = thread->GetBasePriority(); if (thread->HasWaiters()) { new_priority = std::min(new_priority, thread->m_waiter_list.front().GetPriority()); } /* If the priority we would inherit is not different from ours, don't do anything. */ if (new_priority == thread->GetPriority()) { return; } /* Ensure we don't violate condition variable red black tree invariants. */ if (auto *cv_tree = thread->GetConditionVariableTree(); cv_tree != nullptr) { BeforeUpdatePriority(cv_tree, thread); } /* Change the priority. */ const s32 old_priority = thread->GetPriority(); thread->SetPriority(new_priority); /* Restore the condition variable, if relevant. */ if (auto *cv_tree = thread->GetConditionVariableTree(); cv_tree != nullptr) { AfterUpdatePriority(cv_tree, thread); } /* Update the scheduler. */ KScheduler::OnThreadPriorityChanged(thread, old_priority); /* Keep the lock owner up to date. */ KThread *lock_owner = thread->GetLockOwner(); if (lock_owner == nullptr) { return; } /* Update the thread in the lock owner's sorted list, and continue inheriting. */ lock_owner->RemoveWaiterImpl(thread); lock_owner->AddWaiterImpl(thread); thread = lock_owner; } } void KThread::AddWaiter(KThread *thread) { MESOSPHERE_ASSERT_THIS(); this->AddWaiterImpl(thread); RestorePriority(this); } void KThread::RemoveWaiter(KThread *thread) { MESOSPHERE_ASSERT_THIS(); this->RemoveWaiterImpl(thread); RestorePriority(this); } KThread *KThread::RemoveWaiterByKey(s32 *out_num_waiters, KProcessAddress key) { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); s32 num_waiters = 0; KThread *next_lock_owner = nullptr; auto it = m_waiter_list.begin(); while (it != m_waiter_list.end()) { if (it->GetAddressKey() == key) { KThread *thread = std::addressof(*it); /* Keep track of how many kernel waiters we have. */ if (IsKernelAddressKey(thread->GetAddressKey())) { MESOSPHERE_ABORT_UNLESS((m_num_kernel_waiters--) > 0); KScheduler::SetSchedulerUpdateNeeded(); } it = m_waiter_list.erase(it); /* Update the next lock owner. */ if (next_lock_owner == nullptr) { next_lock_owner = thread; next_lock_owner->SetLockOwner(nullptr); } else { next_lock_owner->AddWaiterImpl(thread); } num_waiters++; } else { it++; } } /* Do priority updates, if we have a next owner. */ if (next_lock_owner) { RestorePriority(this); RestorePriority(next_lock_owner); } /* Return output. */ *out_num_waiters = num_waiters; return next_lock_owner; } Result KThread::Run() { MESOSPHERE_ASSERT_THIS(); /* If the kernel hasn't finished initializing, then we should suspend. */ if (Kernel::GetState() != Kernel::State::Initialized) { this->RequestSuspend(SuspendType_Init); } while (true) { KScopedSchedulerLock lk; /* If either this thread or the current thread are requesting termination, note it. */ R_UNLESS(!this->IsTerminationRequested(), svc::ResultTerminationRequested()); R_UNLESS(!GetCurrentThread().IsTerminationRequested(), svc::ResultTerminationRequested()); /* Ensure our thread state is correct. */ R_UNLESS(this->GetState() == ThreadState_Initialized, svc::ResultInvalidState()); /* If the current thread has been asked to suspend, suspend it and retry. */ if (GetCurrentThread().IsSuspended()) { GetCurrentThread().UpdateState(); continue; } /* If we're not a kernel thread and we've been asked to suspend, suspend ourselves. */ if (KProcess *parent = this->GetOwnerProcess(); parent != nullptr) { if (this->IsSuspended()) { this->UpdateState(); } parent->IncrementRunningThreadCount(); } /* Open a reference, now that we're running. */ this->Open(); /* Set our state and finish. */ this->SetState(KThread::ThreadState_Runnable); return ResultSuccess(); } } void KThread::Exit() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(this == GetCurrentThreadPointer()); /* Call the debug callback. */ KDebug::OnExitThread(this); /* Release the thread resource hint, running thread count from parent. */ if (m_parent != nullptr) { m_parent->ReleaseResource(ams::svc::LimitableResource_ThreadCountMax, 0, 1); m_resource_limit_release_hint = true; m_parent->DecrementRunningThreadCount(); } /* Destroy any dependent objects. */ this->DestroyClosedObjects(); /* Perform termination. */ { KScopedSchedulerLock sl; /* Disallow all suspension. */ m_suspend_allowed_flags = 0; this->UpdateState(); /* Start termination. */ this->StartTermination(); /* Register the thread as a work task. */ KWorkerTaskManager::AddTask(KWorkerTaskManager::WorkerType_Exit, this); } MESOSPHERE_PANIC("KThread::Exit() would return"); } Result KThread::Terminate() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(this != GetCurrentThreadPointer()); /* Request the thread terminate. */ if (const auto new_state = this->RequestTerminate(); new_state != ThreadState_Terminated) { /* If the thread isn't terminated, wait for it to terminate. */ s32 index; KSynchronizationObject *objects[] = { this }; return KSynchronizationObject::Wait(std::addressof(index), objects, 1, ams::svc::WaitInfinite); } else { return ResultSuccess(); } } KThread::ThreadState KThread::RequestTerminate() { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(this != GetCurrentThreadPointer()); KScopedSchedulerLock sl; /* Determine if this is the first termination request. */ const bool first_request = [&] ALWAYS_INLINE_LAMBDA () -> bool { /* Perform an atomic compare-and-swap from false to true. */ bool expected = false; return m_termination_requested.CompareExchangeStrong(expected, true); }(); /* If this is the first request, start termination procedure. */ if (first_request) { /* If the thread is in initialized state, just change state to terminated. */ if (this->GetState() == ThreadState_Initialized) { m_thread_state = ThreadState_Terminated; return ThreadState_Terminated; } /* Register the terminating dpc. */ this->RegisterDpc(DpcFlag_Terminating); /* If the thread is pinned, unpin it. */ if (this->GetStackParameters().is_pinned) { this->GetOwnerProcess()->UnpinThread(this); } /* If the thread is suspended, continue it. */ if (this->IsSuspended()) { m_suspend_allowed_flags = 0; this->UpdateState(); } /* Change the thread's priority to be higher than any system thread's. */ if (this->GetBasePriority() >= ams::svc::SystemThreadPriorityHighest) { this->SetBasePriority(TerminatingThreadPriority); } /* If the thread is runnable, send a termination interrupt to other cores. */ if (this->GetState() == ThreadState_Runnable) { if (const u64 core_mask = m_physical_affinity_mask.GetAffinityMask() & ~(1ul << GetCurrentCoreId()); core_mask != 0) { cpu::DataSynchronizationBarrier(); Kernel::GetInterruptManager().SendInterProcessorInterrupt(KInterruptName_ThreadTerminate, core_mask); } } /* Wake up the thread. */ if (this->GetState() == ThreadState_Waiting) { m_wait_queue->CancelWait(this, svc::ResultTerminationRequested(), true); } } return this->GetState(); } Result KThread::Sleep(s64 timeout) { MESOSPHERE_ASSERT_THIS(); MESOSPHERE_ASSERT(!KScheduler::IsSchedulerLockedByCurrentThread()); MESOSPHERE_ASSERT(this == GetCurrentThreadPointer()); MESOSPHERE_ASSERT(timeout > 0); ThreadQueueImplForKThreadSleep wait_queue; KHardwareTimer *timer; { /* Setup the scheduling lock and sleep. */ KScopedSchedulerLockAndSleep slp(std::addressof(timer), this, timeout); /* Check if the thread should terminate. */ if (this->IsTerminationRequested()) { slp.CancelSleep(); return svc::ResultTerminationRequested(); } /* Wait for the sleep to end. */ wait_queue.SetHardwareTimer(timer); this->BeginWait(std::addressof(wait_queue)); } return ResultSuccess(); } void KThread::BeginWait(KThreadQueue *queue) { /* Set our state as waiting. */ this->SetState(ThreadState_Waiting); /* Set our wait queue. */ m_wait_queue = queue; } void KThread::NotifyAvailable(KSynchronizationObject *signaled_object, Result wait_result) { MESOSPHERE_ASSERT_THIS(); /* Lock the scheduler. */ KScopedSchedulerLock sl; /* If we're waiting, notify our queue that we're available. */ if (this->GetState() == ThreadState_Waiting) { m_wait_queue->NotifyAvailable(this, signaled_object, wait_result); } } void KThread::EndWait(Result wait_result) { MESOSPHERE_ASSERT_THIS(); /* Lock the scheduler. */ KScopedSchedulerLock sl; /* If we're waiting, notify our queue that we're available. */ if (this->GetState() == ThreadState_Waiting) { m_wait_queue->EndWait(this, wait_result); } } void KThread::CancelWait(Result wait_result, bool cancel_timer_task) { MESOSPHERE_ASSERT_THIS(); /* Lock the scheduler. */ KScopedSchedulerLock sl; /* If we're waiting, notify our queue that we're available. */ if (this->GetState() == ThreadState_Waiting) { m_wait_queue->CancelWait(this, wait_result, cancel_timer_task); } } void KThread::SetState(ThreadState state) { MESOSPHERE_ASSERT_THIS(); KScopedSchedulerLock sl; const ThreadState old_state = m_thread_state; m_thread_state = static_cast((old_state & ~ThreadState_Mask) | (state & ThreadState_Mask)); if (m_thread_state != old_state) { KScheduler::OnThreadStateChanged(this, old_state); } } KThreadContext *KThread::GetContextForSchedulerLoop() { return std::addressof(this->GetContext()); } KThread *KThread::GetThreadFromId(u64 thread_id) { /* Lock the list. */ KThread::ListAccessor accessor; const auto end = accessor.end(); /* Define helper object to find the thread. */ class IdObjectHelper : public KAutoObjectWithListContainer::ListType::value_type { private: u64 m_id; public: explicit IdObjectHelper(u64 id) : m_id(id) { /* ... */ } virtual u64 GetId() const override { return m_id; } }; /* Find the object with the right id. */ const auto it = accessor.find(IdObjectHelper(thread_id)); /* Check to make sure we found the thread. */ if (it == end) { return nullptr; } /* Get the thread. */ KThread *thread = static_cast(std::addressof(*it)); /* Open the thread. */ if (AMS_LIKELY(thread->Open())) { MESOSPHERE_ASSERT(thread->GetId() == thread_id); return thread; } /* We failed to find the thread. */ return nullptr; } Result KThread::GetThreadList(s32 *out_num_threads, ams::kern::svc::KUserPointer out_thread_ids, s32 max_out_count) { /* Lock the list. */ KThread::ListAccessor accessor; const auto end = accessor.end(); /* Iterate over the list. */ s32 count = 0; for (auto it = accessor.begin(); it != end; ++it) { /* If we're within array bounds, write the id. */ if (count < max_out_count) { /* Get the thread id. */ KThread *thread = static_cast(std::addressof(*it)); const u64 id = thread->GetId(); /* Copy the id to userland. */ R_TRY(out_thread_ids.CopyArrayElementFrom(std::addressof(id), count)); } /* Increment the count. */ ++count; } /* We successfully iterated the list. */ *out_num_threads = count; return ResultSuccess(); } }