// Copyright 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/threading/thread_local_storage.h" #include "base/atomicops.h" #include "base/logging.h" #include "base/synchronization/lock.h" #include "build/build_config.h" using base::internal::PlatformThreadLocalStorage; // Chrome Thread Local Storage (TLS) // // This TLS system allows Chrome to use a single OS level TLS slot process-wide, // and allows us to control the slot limits instead of being at the mercy of the // platform. To do this, Chrome TLS replicates an array commonly found in the OS // thread metadata. // // Overview: // // OS TLS Slots Per-Thread Per-Process Global // ... // [] Chrome TLS Array Chrome TLS Metadata // [] ----------> [][][][][ ][][][][] [][][][][ ][][][][] // [] | | // ... V V // Metadata Version Slot Information // Your Data! // // Using a single OS TLS slot, Chrome TLS allocates an array on demand for the // lifetime of each thread that requests Chrome TLS data. Each per-thread TLS // array matches the length of the per-process global metadata array. // // A per-process global TLS metadata array tracks information about each item in // the per-thread array: // * Status: Tracks if the slot is allocated or free to assign. // * Destructor: An optional destructor to call on thread destruction for that // specific slot. // * Version: Tracks the current version of the TLS slot. Each TLS slot // allocation is associated with a unique version number. // // Most OS TLS APIs guarantee that a newly allocated TLS slot is // initialized to 0 for all threads. The Chrome TLS system provides // this guarantee by tracking the version for each TLS slot here // on each per-thread Chrome TLS array entry. Threads that access // a slot with a mismatched version will receive 0 as their value. // The metadata version is incremented when the client frees a // slot. The per-thread metadata version is updated when a client // writes to the slot. This scheme allows for constant time // invalidation and avoids the need to iterate through each Chrome // TLS array to mark the slot as zero. // // Just like an OS TLS API, clients of the Chrome TLS are responsible for // managing any necessary lifetime of the data in their slots. The only // convenience provided is automatic destruction when a thread ends. If a client // frees a slot, that client is responsible for destroying the data in the slot. namespace { // In order to make TLS destructors work, we need to keep around a function // pointer to the destructor for each slot. We keep this array of pointers in a // global (static) array. // We use the single OS-level TLS slot (giving us one pointer per thread) to // hold a pointer to a per-thread array (table) of slots that we allocate to // Chromium consumers. // g_native_tls_key is the one native TLS that we use. It stores our table. base::subtle::Atomic32 g_native_tls_key = PlatformThreadLocalStorage::TLS_KEY_OUT_OF_INDEXES; // The OS TLS slot has three states: // * kUninitialized: Any call to Slot::Get()/Set() will create the base // per-thread TLS state. On POSIX, kUninitialized must be 0. // * [Memory Address]: Raw pointer to the base per-thread TLS state. // * kDestroyed: The base per-thread TLS state has been freed. // // Final States: // * Windows: kDestroyed. Windows does not iterate through the OS TLS to clean // up the values. // * POSIX: kUninitialized. POSIX iterates through TLS until all slots contain // nullptr. // // More details on this design: // We need some type of thread-local state to indicate that the TLS system has // been destroyed. To do so, we leverage the multi-pass nature of destruction // of pthread_key. // // a) After destruction of TLS system, we set the pthread_key to a sentinel // kDestroyed. // b) All calls to Slot::Get() DCHECK that the state is not kDestroyed, and // any system which might potentially invoke Slot::Get() after destruction // of TLS must check ThreadLocalStorage::ThreadIsBeingDestroyed(). // c) After a full pass of the pthread_keys, on the next invocation of // ConstructTlsVector(), we'll then set the key to nullptr. // d) At this stage, the TLS system is back in its uninitialized state. // e) If in the second pass of destruction of pthread_keys something were to // re-initialize TLS [this should never happen! Since the only code which // uses Chrome TLS is Chrome controlled, we should really be striving for // single-pass destruction], then TLS will be re-initialized and then go // through the 2-pass destruction system again. Everything should just // work (TM). // The consumers of kUninitialized and kDestroyed expect void*, since that's // what the API exposes on both POSIX and Windows. void* const kUninitialized = nullptr; // A sentinel value to indicate that the TLS system has been destroyed. void* const kDestroyed = reinterpret_cast(1); // The maximum number of slots in our thread local storage stack. constexpr int kThreadLocalStorageSize = 256; enum TlsStatus { FREE, IN_USE, }; struct TlsMetadata { TlsStatus status; base::ThreadLocalStorage::TLSDestructorFunc destructor; uint32_t version; }; struct TlsVectorEntry { void* data; uint32_t version; }; // This lock isn't needed until after we've constructed the per-thread TLS // vector, so it's safe to use. base::Lock* GetTLSMetadataLock() { static auto* lock = new base::Lock(); return lock; } TlsMetadata g_tls_metadata[kThreadLocalStorageSize]; size_t g_last_assigned_slot = 0; // The maximum number of times to try to clear slots by calling destructors. // Use pthread naming convention for clarity. constexpr int kMaxDestructorIterations = kThreadLocalStorageSize; // This function is called to initialize our entire Chromium TLS system. // It may be called very early, and we need to complete most all of the setup // (initialization) before calling *any* memory allocator functions, which may // recursively depend on this initialization. // As a result, we use Atomics, and avoid anything (like a singleton) that might // require memory allocations. TlsVectorEntry* ConstructTlsVector() { PlatformThreadLocalStorage::TLSKey key = base::subtle::NoBarrier_Load(&g_native_tls_key); if (key == PlatformThreadLocalStorage::TLS_KEY_OUT_OF_INDEXES) { CHECK(PlatformThreadLocalStorage::AllocTLS(&key)); // The TLS_KEY_OUT_OF_INDEXES is used to find out whether the key is set or // not in NoBarrier_CompareAndSwap, but Posix doesn't have invalid key, we // define an almost impossible value be it. // If we really get TLS_KEY_OUT_OF_INDEXES as value of key, just alloc // another TLS slot. if (key == PlatformThreadLocalStorage::TLS_KEY_OUT_OF_INDEXES) { PlatformThreadLocalStorage::TLSKey tmp = key; CHECK(PlatformThreadLocalStorage::AllocTLS(&key) && key != PlatformThreadLocalStorage::TLS_KEY_OUT_OF_INDEXES); PlatformThreadLocalStorage::FreeTLS(tmp); } // Atomically test-and-set the tls_key. If the key is // TLS_KEY_OUT_OF_INDEXES, go ahead and set it. Otherwise, do nothing, as // another thread already did our dirty work. if (PlatformThreadLocalStorage::TLS_KEY_OUT_OF_INDEXES != static_cast( base::subtle::NoBarrier_CompareAndSwap( &g_native_tls_key, PlatformThreadLocalStorage::TLS_KEY_OUT_OF_INDEXES, key))) { // We've been shortcut. Another thread replaced g_native_tls_key first so // we need to destroy our index and use the one the other thread got // first. PlatformThreadLocalStorage::FreeTLS(key); key = base::subtle::NoBarrier_Load(&g_native_tls_key); } } CHECK_EQ(PlatformThreadLocalStorage::GetTLSValue(key), kUninitialized); // Some allocators, such as TCMalloc, make use of thread local storage. As a // result, any attempt to call new (or malloc) will lazily cause such a system // to initialize, which will include registering for a TLS key. If we are not // careful here, then that request to create a key will call new back, and // we'll have an infinite loop. We avoid that as follows: Use a stack // allocated vector, so that we don't have dependence on our allocator until // our service is in place. (i.e., don't even call new until after we're // setup) TlsVectorEntry stack_allocated_tls_data[kThreadLocalStorageSize]; memset(stack_allocated_tls_data, 0, sizeof(stack_allocated_tls_data)); // Ensure that any rentrant calls change the temp version. PlatformThreadLocalStorage::SetTLSValue(key, stack_allocated_tls_data); // Allocate an array to store our data. TlsVectorEntry* tls_data = new TlsVectorEntry[kThreadLocalStorageSize]; memcpy(tls_data, stack_allocated_tls_data, sizeof(stack_allocated_tls_data)); PlatformThreadLocalStorage::SetTLSValue(key, tls_data); return tls_data; } void OnThreadExitInternal(TlsVectorEntry* tls_data) { // This branch is for POSIX, where this function is called twice. The first // pass calls dtors and sets state to kDestroyed. The second pass sets // kDestroyed to kUninitialized. if (tls_data == kDestroyed) { PlatformThreadLocalStorage::TLSKey key = base::subtle::NoBarrier_Load(&g_native_tls_key); PlatformThreadLocalStorage::SetTLSValue(key, kUninitialized); return; } DCHECK(tls_data); // Some allocators, such as TCMalloc, use TLS. As a result, when a thread // terminates, one of the destructor calls we make may be to shut down an // allocator. We have to be careful that after we've shutdown all of the known // destructors (perchance including an allocator), that we don't call the // allocator and cause it to resurrect itself (with no possibly destructor // call to follow). We handle this problem as follows: Switch to using a stack // allocated vector, so that we don't have dependence on our allocator after // we have called all g_tls_metadata destructors. (i.e., don't even call // delete[] after we're done with destructors.) TlsVectorEntry stack_allocated_tls_data[kThreadLocalStorageSize]; memcpy(stack_allocated_tls_data, tls_data, sizeof(stack_allocated_tls_data)); // Ensure that any re-entrant calls change the temp version. PlatformThreadLocalStorage::TLSKey key = base::subtle::NoBarrier_Load(&g_native_tls_key); PlatformThreadLocalStorage::SetTLSValue(key, stack_allocated_tls_data); delete[] tls_data; // Our last dependence on an allocator. // Snapshot the TLS Metadata so we don't have to lock on every access. TlsMetadata tls_metadata[kThreadLocalStorageSize]; { base::AutoLock auto_lock(*GetTLSMetadataLock()); memcpy(tls_metadata, g_tls_metadata, sizeof(g_tls_metadata)); } int remaining_attempts = kMaxDestructorIterations; bool need_to_scan_destructors = true; while (need_to_scan_destructors) { need_to_scan_destructors = false; // Try to destroy the first-created-slot (which is slot 1) in our last // destructor call. That user was able to function, and define a slot with // no other services running, so perhaps it is a basic service (like an // allocator) and should also be destroyed last. If we get the order wrong, // then we'll iterate several more times, so it is really not that critical // (but it might help). for (int slot = 0; slot < kThreadLocalStorageSize ; ++slot) { void* tls_value = stack_allocated_tls_data[slot].data; if (!tls_value || tls_metadata[slot].status == TlsStatus::FREE || stack_allocated_tls_data[slot].version != tls_metadata[slot].version) continue; base::ThreadLocalStorage::TLSDestructorFunc destructor = tls_metadata[slot].destructor; if (!destructor) continue; stack_allocated_tls_data[slot].data = nullptr; // pre-clear the slot. destructor(tls_value); // Any destructor might have called a different service, which then set a // different slot to a non-null value. Hence we need to check the whole // vector again. This is a pthread standard. need_to_scan_destructors = true; } if (--remaining_attempts <= 0) { NOTREACHED(); // Destructors might not have been called. break; } } // Remove our stack allocated vector. PlatformThreadLocalStorage::SetTLSValue(key, kDestroyed); } } // namespace namespace base { namespace internal { #if defined(OS_WIN) void PlatformThreadLocalStorage::OnThreadExit() { PlatformThreadLocalStorage::TLSKey key = base::subtle::NoBarrier_Load(&g_native_tls_key); if (key == PlatformThreadLocalStorage::TLS_KEY_OUT_OF_INDEXES) return; void *tls_data = GetTLSValue(key); // On Windows, thread destruction callbacks are only invoked once per module, // so there should be no way that this could be invoked twice. DCHECK_NE(tls_data, kDestroyed); // Maybe we have never initialized TLS for this thread. if (tls_data == kUninitialized) return; OnThreadExitInternal(static_cast(tls_data)); } #elif defined(OS_POSIX) || defined(OS_FUCHSIA) void PlatformThreadLocalStorage::OnThreadExit(void* value) { OnThreadExitInternal(static_cast(value)); } #endif // defined(OS_WIN) } // namespace internal bool ThreadLocalStorage::HasBeenDestroyed() { PlatformThreadLocalStorage::TLSKey key = base::subtle::NoBarrier_Load(&g_native_tls_key); if (key == PlatformThreadLocalStorage::TLS_KEY_OUT_OF_INDEXES) return false; return PlatformThreadLocalStorage::GetTLSValue(key) == kDestroyed; } void ThreadLocalStorage::Slot::Initialize(TLSDestructorFunc destructor) { PlatformThreadLocalStorage::TLSKey key = base::subtle::NoBarrier_Load(&g_native_tls_key); if (key == PlatformThreadLocalStorage::TLS_KEY_OUT_OF_INDEXES || PlatformThreadLocalStorage::GetTLSValue(key) == kUninitialized) { ConstructTlsVector(); } // Grab a new slot. { base::AutoLock auto_lock(*GetTLSMetadataLock()); for (int i = 0; i < kThreadLocalStorageSize; ++i) { // Tracking the last assigned slot is an attempt to find the next // available slot within one iteration. Under normal usage, slots remain // in use for the lifetime of the process (otherwise before we reclaimed // slots, we would have run out of slots). This makes it highly likely the // next slot is going to be a free slot. size_t slot_candidate = (g_last_assigned_slot + 1 + i) % kThreadLocalStorageSize; if (g_tls_metadata[slot_candidate].status == TlsStatus::FREE) { g_tls_metadata[slot_candidate].status = TlsStatus::IN_USE; g_tls_metadata[slot_candidate].destructor = destructor; g_last_assigned_slot = slot_candidate; DCHECK_EQ(kInvalidSlotValue, slot_); slot_ = slot_candidate; version_ = g_tls_metadata[slot_candidate].version; break; } } } CHECK_NE(slot_, kInvalidSlotValue); CHECK_LT(slot_, kThreadLocalStorageSize); } void ThreadLocalStorage::Slot::Free() { DCHECK_NE(slot_, kInvalidSlotValue); DCHECK_LT(slot_, kThreadLocalStorageSize); { base::AutoLock auto_lock(*GetTLSMetadataLock()); g_tls_metadata[slot_].status = TlsStatus::FREE; g_tls_metadata[slot_].destructor = nullptr; ++(g_tls_metadata[slot_].version); } slot_ = kInvalidSlotValue; } void* ThreadLocalStorage::Slot::Get() const { TlsVectorEntry* tls_data = static_cast( PlatformThreadLocalStorage::GetTLSValue( base::subtle::NoBarrier_Load(&g_native_tls_key))); DCHECK_NE(tls_data, kDestroyed); if (!tls_data) return nullptr; DCHECK_NE(slot_, kInvalidSlotValue); DCHECK_LT(slot_, kThreadLocalStorageSize); // Version mismatches means this slot was previously freed. if (tls_data[slot_].version != version_) return nullptr; return tls_data[slot_].data; } void ThreadLocalStorage::Slot::Set(void* value) { TlsVectorEntry* tls_data = static_cast( PlatformThreadLocalStorage::GetTLSValue( base::subtle::NoBarrier_Load(&g_native_tls_key))); DCHECK_NE(tls_data, kDestroyed); if (!tls_data) tls_data = ConstructTlsVector(); DCHECK_NE(slot_, kInvalidSlotValue); DCHECK_LT(slot_, kThreadLocalStorageSize); tls_data[slot_].data = value; tls_data[slot_].version = version_; } ThreadLocalStorage::Slot::Slot(TLSDestructorFunc destructor) { Initialize(destructor); } ThreadLocalStorage::Slot::~Slot() { Free(); } } // namespace base