/*
* Copyright (c) 2018-2020 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 <http://www.gnu.org/licenses/>.
*/
#pragma once
#include <mesosphere/kern_slab_helpers.hpp>
#include <mesosphere/kern_k_synchronization_object.hpp>
#include <mesosphere/kern_k_affinity_mask.hpp>
#include <mesosphere/kern_k_thread_context.hpp>
#include <mesosphere/kern_k_current_context.hpp>
#include <mesosphere/kern_k_timer_task.hpp>
#include <mesosphere/kern_k_worker_task.hpp>
namespace ams::kern {
class KThreadQueue;
class KProcess;
class KConditionVariable;
class KAddressArbiter;
using KThreadFunction = void (*)(uintptr_t);
class KThread final : public KAutoObjectWithSlabHeapAndContainer<KThread, KSynchronizationObject>, public util::IntrusiveListBaseNode<KThread>, public KTimerTask, public KWorkerTask {
MESOSPHERE_AUTOOBJECT_TRAITS(KThread, KSynchronizationObject);
private:
friend class KProcess;
friend class KConditionVariable;
friend class KAddressArbiter;
public:
static constexpr s32 MainThreadPriority = 1;
static constexpr s32 IdleThreadPriority = 64;
enum ThreadType : u32 {
ThreadType_Main = 0,
ThreadType_Kernel = 1,
ThreadType_HighPriority = 2,
ThreadType_User = 3,
};
enum SuspendType : u32 {
SuspendType_Process = 0,
SuspendType_Thread = 1,
SuspendType_Debug = 2,
SuspendType_Backtrace = 3,
SuspendType_Init = 4,
SuspendType_Count,
};
enum ThreadState : u16 {
ThreadState_Initialized = 0,
ThreadState_Waiting = 1,
ThreadState_Runnable = 2,
ThreadState_Terminated = 3,
ThreadState_SuspendShift = 4,
ThreadState_Mask = (1 << ThreadState_SuspendShift) - 1,
ThreadState_ProcessSuspended = (1 << (SuspendType_Process + ThreadState_SuspendShift)),
ThreadState_ThreadSuspended = (1 << (SuspendType_Thread + ThreadState_SuspendShift)),
ThreadState_DebugSuspended = (1 << (SuspendType_Debug + ThreadState_SuspendShift)),
ThreadState_BacktraceSuspended = (1 << (SuspendType_Backtrace + ThreadState_SuspendShift)),
ThreadState_InitSuspended = (1 << (SuspendType_Init + ThreadState_SuspendShift)),
ThreadState_SuspendFlagMask = ((1 << SuspendType_Count) - 1) << ThreadState_SuspendShift,
};
enum DpcFlag : u32 {
DpcFlag_Terminating = (1 << 0),
DpcFlag_Terminated = (1 << 1),
};
struct StackParameters {
alignas(0x10) u8 svc_permission[0x10];
std::atomic<u8> dpc_flags;
u8 current_svc_id;
bool is_calling_svc;
bool is_in_exception_handler;
bool is_pinned;
s32 disable_count;
KThreadContext *context;
KThread *cur_thread;
};
static_assert(alignof(StackParameters) == 0x10);
struct QueueEntry {
private:
KThread *m_prev;
KThread *m_next;
public:
constexpr QueueEntry() : m_prev(nullptr), m_next(nullptr) { /* ... */ }
constexpr void Initialize() {
m_prev = nullptr;
m_next = nullptr;
}
constexpr KThread *GetPrev() const { return m_prev; }
constexpr KThread *GetNext() const { return m_next; }
constexpr void SetPrev(KThread *t) { m_prev = t; }
constexpr void SetNext(KThread *t) { m_next = t; }
};
using WaiterList = util::IntrusiveListBaseTraits<KThread>::ListType;
private:
static constexpr size_t PriorityInheritanceCountMax = 10;
union SyncObjectBuffer {
KSynchronizationObject *m_sync_objects[ams::svc::ArgumentHandleCountMax];
ams::svc::Handle m_handles[ams::svc::ArgumentHandleCountMax * (sizeof(KSynchronizationObject *) / sizeof(ams::svc::Handle))];
constexpr SyncObjectBuffer() : m_sync_objects() { /* ... */ }
};
static_assert(sizeof(SyncObjectBuffer::m_sync_objects) == sizeof(SyncObjectBuffer::m_handles));
struct ConditionVariableComparator {
struct LightCompareType {
uintptr_t m_cv_key;
s32 m_priority;
constexpr ALWAYS_INLINE uintptr_t GetConditionVariableKey() const {
return m_cv_key;
}
constexpr ALWAYS_INLINE s32 GetPriority() const {
return m_priority;
}
};
template<typename T> requires (std::same_as<T, KThread> || std::same_as<T, LightCompareType>)
static constexpr ALWAYS_INLINE int Compare(const T &lhs, const KThread &rhs) {
const uintptr_t l_key = lhs.GetConditionVariableKey();
const uintptr_t r_key = rhs.GetConditionVariableKey();
if (l_key < r_key) {
/* Sort first by key */
return -1;
} else if (l_key == r_key && lhs.GetPriority() < rhs.GetPriority()) {
/* And then by priority. */
return -1;
} else {
return 1;
}
}
};
static_assert(ams::util::HasLightCompareType<ConditionVariableComparator>);
static_assert(std::same_as<ams::util::LightCompareType<ConditionVariableComparator, void>, ConditionVariableComparator::LightCompareType>);
private:
static inline std::atomic<u64> s_next_thread_id = 0;
private:
alignas(16) KThreadContext m_thread_context{};
util::IntrusiveListNode m_process_list_node{};
util::IntrusiveRedBlackTreeNode m_condvar_arbiter_tree_node{};
s32 m_priority{};
using ConditionVariableThreadTreeTraits = util::IntrusiveRedBlackTreeMemberTraitsDeferredAssert<&KThread::m_condvar_arbiter_tree_node>;
using ConditionVariableThreadTree = ConditionVariableThreadTreeTraits::TreeType<ConditionVariableComparator>;
ConditionVariableThreadTree *m_condvar_tree{};
uintptr_t m_condvar_key{};
u64 m_virtual_affinity_mask{};
KAffinityMask m_physical_affinity_mask{};
u64 m_thread_id{};
std::atomic<s64> m_cpu_time{};
KSynchronizationObject *m_synced_object{};
KProcessAddress m_address_key{};
KProcess *m_parent{};
void *m_kernel_stack_top{};
u32 *m_light_ipc_data{};
KProcessAddress m_tls_address{};
void *m_tls_heap_address{};
KLightLock m_activity_pause_lock{};
SyncObjectBuffer m_sync_object_buffer{};
s64 m_schedule_count{};
s64 m_last_scheduled_tick{};
QueueEntry m_per_core_priority_queue_entry[cpu::NumCores]{};
KLightLock *m_waiting_lock{};
KThreadQueue *m_sleeping_queue{};
WaiterList m_waiter_list{};
WaiterList m_pinned_waiter_list{};
KThread *m_lock_owner{};
uintptr_t m_debug_params[3]{};
u32 m_address_key_value{};
u32 m_suspend_request_flags{};
u32 m_suspend_allowed_flags{};
Result m_wait_result;
Result m_debug_exception_result;
s32 m_base_priority{};
s32 m_physical_ideal_core_id{};
s32 m_virtual_ideal_core_id{};
s32 m_num_kernel_waiters{};
s32 m_current_core_id{};
s32 m_core_id{};
KAffinityMask m_original_physical_affinity_mask{};
s32 m_original_physical_ideal_core_id{};
s32 m_num_core_migration_disables{};
ThreadState m_thread_state{};
std::atomic<u8> m_termination_requested{};
bool m_wait_cancelled{};
bool m_cancellable{};
bool m_signaled{};
bool m_initialized{};
bool m_debug_attached{};
s8 m_priority_inheritance_count{};
bool m_resource_limit_release_hint{};
public:
constexpr KThread() : m_wait_result(svc::ResultNoSynchronizationObject()), m_debug_exception_result(ResultSuccess()) { /* ... */ }
virtual ~KThread() { /* ... */ }
Result Initialize(KThreadFunction func, uintptr_t arg, void *kern_stack_top, KProcessAddress user_stack_top, s32 prio, s32 virt_core, KProcess *owner, ThreadType type);
private:
static Result InitializeThread(KThread *thread, KThreadFunction func, uintptr_t arg, KProcessAddress user_stack_top, s32 prio, s32 virt_core, KProcess *owner, ThreadType type);
public:
static Result InitializeKernelThread(KThread *thread, KThreadFunction func, uintptr_t arg, s32 prio, s32 virt_core) {
return InitializeThread(thread, func, arg, Null<KProcessAddress>, prio, virt_core, nullptr, ThreadType_Kernel);
}
static Result InitializeHighPriorityThread(KThread *thread, KThreadFunction func, uintptr_t arg) {
return InitializeThread(thread, func, arg, Null<KProcessAddress>, 0, GetCurrentCoreId(), nullptr, ThreadType_HighPriority);
}
static Result InitializeUserThread(KThread *thread, KThreadFunction func, uintptr_t arg, KProcessAddress user_stack_top, s32 prio, s32 virt_core, KProcess *owner) {
return InitializeThread(thread, func, arg, user_stack_top, prio, virt_core, owner, ThreadType_User);
}
static void ResumeThreadsSuspendedForInit();
private:
StackParameters &GetStackParameters() {
return *(reinterpret_cast<StackParameters *>(m_kernel_stack_top) - 1);
}
const StackParameters &GetStackParameters() const {
return *(reinterpret_cast<const StackParameters *>(m_kernel_stack_top) - 1);
}
public:
StackParameters &GetStackParametersForExceptionSvcPermission() {
return *(reinterpret_cast<StackParameters *>(m_kernel_stack_top) - 1);
}
public:
ALWAYS_INLINE s32 GetDisableDispatchCount() const {
MESOSPHERE_ASSERT_THIS();
return this->GetStackParameters().disable_count;
}
ALWAYS_INLINE void DisableDispatch() {
MESOSPHERE_ASSERT_THIS();
MESOSPHERE_ASSERT(GetCurrentThread().GetDisableDispatchCount() >= 0);
this->GetStackParameters().disable_count++;
}
ALWAYS_INLINE void EnableDispatch() {
MESOSPHERE_ASSERT_THIS();
MESOSPHERE_ASSERT(GetCurrentThread().GetDisableDispatchCount() > 0);
this->GetStackParameters().disable_count--;
}
void Pin();
void Unpin();
ALWAYS_INLINE void SaveDebugParams(uintptr_t param1, uintptr_t param2, uintptr_t param3) {
m_debug_params[0] = param1;
m_debug_params[1] = param2;
m_debug_params[2] = param3;
}
ALWAYS_INLINE void RestoreDebugParams(uintptr_t *param1, uintptr_t *param2, uintptr_t *param3) {
*param1 = m_debug_params[0];
*param2 = m_debug_params[1];
*param3 = m_debug_params[2];
}
NOINLINE void DisableCoreMigration();
NOINLINE void EnableCoreMigration();
ALWAYS_INLINE void SetInExceptionHandler() {
MESOSPHERE_ASSERT_THIS();
this->GetStackParameters().is_in_exception_handler = true;
}
ALWAYS_INLINE void ClearInExceptionHandler() {
MESOSPHERE_ASSERT_THIS();
this->GetStackParameters().is_in_exception_handler = false;
}
ALWAYS_INLINE bool IsInExceptionHandler() const {
MESOSPHERE_ASSERT_THIS();
return this->GetStackParameters().is_in_exception_handler;
}
ALWAYS_INLINE bool IsCallingSvc() const {
MESOSPHERE_ASSERT_THIS();
return this->GetStackParameters().is_calling_svc;
}
ALWAYS_INLINE u8 GetSvcId() const {
MESOSPHERE_ASSERT_THIS();
return this->GetStackParameters().current_svc_id;
}
ALWAYS_INLINE void RegisterDpc(DpcFlag flag) {
this->GetStackParameters().dpc_flags |= flag;
}
ALWAYS_INLINE void ClearDpc(DpcFlag flag) {
this->GetStackParameters().dpc_flags &= ~flag;
}
ALWAYS_INLINE u8 GetDpc() const {
return this->GetStackParameters().dpc_flags;
}
ALWAYS_INLINE bool HasDpc() const {
MESOSPHERE_ASSERT_THIS();
return this->GetDpc() != 0;
}
private:
void Suspend();
ALWAYS_INLINE void AddWaiterImpl(KThread *thread);
ALWAYS_INLINE void RemoveWaiterImpl(KThread *thread);
ALWAYS_INLINE static void RestorePriority(KThread *thread);
void StartTermination();
void FinishTermination();
public:
constexpr u64 GetThreadId() const { return m_thread_id; }
constexpr KThreadContext &GetContext() { return m_thread_context; }
constexpr const KThreadContext &GetContext() const { return m_thread_context; }
constexpr u64 GetVirtualAffinityMask() const { return m_virtual_affinity_mask; }
constexpr const KAffinityMask &GetAffinityMask() const { return m_physical_affinity_mask; }
Result GetCoreMask(int32_t *out_ideal_core, u64 *out_affinity_mask);
Result SetCoreMask(int32_t ideal_core, u64 affinity_mask);
Result GetPhysicalCoreMask(int32_t *out_ideal_core, u64 *out_affinity_mask);
constexpr ThreadState GetState() const { return static_cast<ThreadState>(m_thread_state & ThreadState_Mask); }
constexpr ThreadState GetRawState() const { return m_thread_state; }
NOINLINE void SetState(ThreadState state);
NOINLINE KThreadContext *GetContextForSchedulerLoop();
constexpr uintptr_t GetConditionVariableKey() const { return m_condvar_key; }
constexpr uintptr_t GetAddressArbiterKey() const { return m_condvar_key; }
constexpr void SetConditionVariable(ConditionVariableThreadTree *tree, KProcessAddress address, uintptr_t cv_key, u32 value) {
m_condvar_tree = tree;
m_condvar_key = cv_key;
m_address_key = address;
m_address_key_value = value;
}
constexpr void ClearConditionVariable() {
m_condvar_tree = nullptr;
}
constexpr bool IsWaitingForConditionVariable() const {
return m_condvar_tree != nullptr;
}
constexpr void SetAddressArbiter(ConditionVariableThreadTree *tree, uintptr_t address) {
m_condvar_tree = tree;
m_condvar_key = address;
}
constexpr void ClearAddressArbiter() {
m_condvar_tree = nullptr;
}
constexpr bool IsWaitingForAddressArbiter() const {
return m_condvar_tree != nullptr;
}
constexpr s32 GetIdealVirtualCore() const { return m_virtual_ideal_core_id; }
constexpr s32 GetIdealPhysicalCore() const { return m_physical_ideal_core_id; }
constexpr s32 GetActiveCore() const { return m_core_id; }
constexpr void SetActiveCore(s32 core) { m_core_id = core; }
constexpr ALWAYS_INLINE s32 GetCurrentCore() const { return m_current_core_id; }
constexpr void SetCurrentCore(s32 core) { m_current_core_id = core; }
constexpr s32 GetPriority() const { return m_priority; }
constexpr void SetPriority(s32 prio) { m_priority = prio; }
constexpr s32 GetBasePriority() const { return m_base_priority; }
constexpr QueueEntry &GetPriorityQueueEntry(s32 core) { return m_per_core_priority_queue_entry[core]; }
constexpr const QueueEntry &GetPriorityQueueEntry(s32 core) const { return m_per_core_priority_queue_entry[core]; }
constexpr void SetSleepingQueue(KThreadQueue *q) { m_sleeping_queue = q; }
constexpr ConditionVariableThreadTree *GetConditionVariableTree() const { return m_condvar_tree; }
constexpr s32 GetNumKernelWaiters() const { return m_num_kernel_waiters; }
void AddWaiter(KThread *thread);
void RemoveWaiter(KThread *thread);
KThread *RemoveWaiterByKey(s32 *out_num_waiters, KProcessAddress key);
constexpr KProcessAddress GetAddressKey() const { return m_address_key; }
constexpr u32 GetAddressKeyValue() const { return m_address_key_value; }
constexpr void SetAddressKey(KProcessAddress key) { m_address_key = key; }
constexpr void SetAddressKey(KProcessAddress key, u32 val) { m_address_key = key; m_address_key_value = val; }
constexpr void SetLockOwner(KThread *owner) { m_lock_owner = owner; }
constexpr KThread *GetLockOwner() const { return m_lock_owner; }
constexpr void SetSyncedObject(KSynchronizationObject *obj, Result wait_res) {
MESOSPHERE_ASSERT_THIS();
m_synced_object = obj;
m_wait_result = wait_res;
}
constexpr Result GetWaitResult(KSynchronizationObject **out) const {
MESOSPHERE_ASSERT_THIS();
*out = m_synced_object;
return m_wait_result;
}
constexpr void SetDebugExceptionResult(Result result) {
MESOSPHERE_ASSERT_THIS();
m_debug_exception_result = result;
}
constexpr Result GetDebugExceptionResult() const {
MESOSPHERE_ASSERT_THIS();
return m_debug_exception_result;
}
void WaitCancel();
bool IsWaitCancelled() const { return m_wait_cancelled; }
void ClearWaitCancelled() { m_wait_cancelled = false; }
void ClearCancellable() { m_cancellable = false; }
void SetCancellable() { m_cancellable = true; }
constexpr u32 *GetLightSessionData() const { return m_light_ipc_data; }
constexpr void SetLightSessionData(u32 *data) { m_light_ipc_data = data; }
bool HasWaiters() const { return !m_waiter_list.empty(); }
constexpr s64 GetLastScheduledTick() const { return m_last_scheduled_tick; }
constexpr void SetLastScheduledTick(s64 tick) { m_last_scheduled_tick = tick; }
constexpr s64 GetYieldScheduleCount() const { return m_schedule_count; }
constexpr void SetYieldScheduleCount(s64 count) { m_schedule_count = count; }
constexpr KProcess *GetOwnerProcess() const { return m_parent; }
constexpr bool IsUserThread() const { return m_parent != nullptr; }
constexpr KProcessAddress GetThreadLocalRegionAddress() const { return m_tls_address; }
constexpr void *GetThreadLocalRegionHeapAddress() const { return m_tls_heap_address; }
constexpr KSynchronizationObject **GetSynchronizationObjectBuffer() { return std::addressof(m_sync_object_buffer.m_sync_objects[0]); }
constexpr ams::svc::Handle *GetHandleBuffer() { return std::addressof(m_sync_object_buffer.m_handles[sizeof(m_sync_object_buffer.m_sync_objects) / sizeof(ams::svc::Handle) - ams::svc::ArgumentHandleCountMax]); }
u16 GetUserDisableCount() const { return static_cast<ams::svc::ThreadLocalRegion *>(m_tls_heap_address)->disable_count; }
void SetInterruptFlag() const { static_cast<ams::svc::ThreadLocalRegion *>(m_tls_heap_address)->interrupt_flag = 1; }
void ClearInterruptFlag() const { static_cast<ams::svc::ThreadLocalRegion *>(m_tls_heap_address)->interrupt_flag = 0; }
constexpr void SetDebugAttached() { m_debug_attached = true; }
constexpr bool IsAttachedToDebugger() const { return m_debug_attached; }
void AddCpuTime(s32 core_id, s64 amount) {
m_cpu_time += amount;
/* TODO: Debug kernels track per-core tick counts. Should we? */
MESOSPHERE_UNUSED(core_id);
}
s64 GetCpuTime() const { return m_cpu_time.load(); }
s64 GetCpuTime(s32 core_id) const {
MESOSPHERE_ABORT_UNLESS(0 <= core_id && core_id < static_cast<s32>(cpu::NumCores));
/* TODO: Debug kernels track per-core tick counts. Should we? */
return 0;
}
constexpr u32 GetSuspendFlags() const { return m_suspend_allowed_flags & m_suspend_request_flags; }
constexpr bool IsSuspended() const { return this->GetSuspendFlags() != 0; }
constexpr bool IsSuspendRequested(SuspendType type) const { return (m_suspend_request_flags & (1u << (ThreadState_SuspendShift + type))) != 0; }
constexpr bool IsSuspendRequested() const { return m_suspend_request_flags != 0; }
void RequestSuspend(SuspendType type);
void Resume(SuspendType type);
void TrySuspend();
void Continue();
Result SetActivity(ams::svc::ThreadActivity activity);
Result GetThreadContext3(ams::svc::ThreadContext *out);
void ContinueIfHasKernelWaiters() {
if (this->GetNumKernelWaiters() > 0) {
this->Continue();
}
}
void Wakeup();
void SetBasePriority(s32 priority);
Result SetPriorityToIdle();
Result Run();
void Exit();
void Terminate();
ThreadState RequestTerminate();
Result Sleep(s64 timeout);
ALWAYS_INLINE void *GetStackTop() const { return reinterpret_cast<StackParameters *>(m_kernel_stack_top) - 1; }
ALWAYS_INLINE void *GetKernelStackTop() const { return m_kernel_stack_top; }
ALWAYS_INLINE bool IsTerminationRequested() const {
return m_termination_requested.load() || this->GetRawState() == ThreadState_Terminated;
}
size_t GetKernelStackUsage() const;
public:
/* Overridden parent functions. */
virtual u64 GetId() const override final { return this->GetThreadId(); }
virtual bool IsInitialized() const override { return m_initialized; }
virtual uintptr_t GetPostDestroyArgument() const override { return reinterpret_cast<uintptr_t>(m_parent) | (m_resource_limit_release_hint ? 1 : 0); }
static void PostDestroy(uintptr_t arg);
virtual void Finalize() override;
virtual bool IsSignaled() const override;
virtual void OnTimer() override;
virtual void DoWorkerTask() override;
public:
static constexpr bool IsConditionVariableThreadTreeValid() {
return ConditionVariableThreadTreeTraits::IsValid();
}
static KThread *GetThreadFromId(u64 thread_id);
static Result GetThreadList(s32 *out_num_threads, ams::kern::svc::KUserPointer<u64 *> out_thread_ids, s32 max_out_count);
using ConditionVariableThreadTreeType = ConditionVariableThreadTree;
};
static_assert(alignof(KThread) == 0x10);
static_assert(KThread::IsConditionVariableThreadTreeValid());
class KScopedDisableDispatch {
public:
explicit ALWAYS_INLINE KScopedDisableDispatch() {
GetCurrentThread().DisableDispatch();
}
~KScopedDisableDispatch();
};
ALWAYS_INLINE KExceptionContext *GetExceptionContext(KThread *thread) {
return reinterpret_cast<KExceptionContext *>(reinterpret_cast<uintptr_t>(thread->GetKernelStackTop()) - sizeof(KThread::StackParameters) - sizeof(KExceptionContext));
}
ALWAYS_INLINE const KExceptionContext *GetExceptionContext(const KThread *thread) {
return reinterpret_cast<const KExceptionContext *>(reinterpret_cast<uintptr_t>(thread->GetKernelStackTop()) - sizeof(KThread::StackParameters) - sizeof(KExceptionContext));
}
ALWAYS_INLINE KProcess *GetCurrentProcessPointer() {
return GetCurrentThread().GetOwnerProcess();
}
ALWAYS_INLINE KProcess &GetCurrentProcess() {
return *GetCurrentProcessPointer();
}
ALWAYS_INLINE s32 GetCurrentCoreId() {
return GetCurrentThread().GetCurrentCore();
}
}