//===-- tsd_shared.h --------------------------------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef SCUDO_TSD_SHARED_H_ #define SCUDO_TSD_SHARED_H_ #include "linux.h" // for getAndroidTlsPtr() #include "tsd.h" namespace scudo { template struct TSDRegistrySharedT { void initLinkerInitialized(Allocator *Instance) { Instance->initLinkerInitialized(); CHECK_EQ(pthread_key_create(&PThreadKey, nullptr), 0); // For non-TLS NumberOfTSDs = Min(Max(1U, getNumberOfCPUs()), MaxTSDCount); TSDs = reinterpret_cast *>( map(nullptr, sizeof(TSD) * NumberOfTSDs, "scudo:tsd")); for (u32 I = 0; I < NumberOfTSDs; I++) TSDs[I].initLinkerInitialized(Instance); // Compute all the coprimes of NumberOfTSDs. This will be used to walk the // array of TSDs in a random order. For details, see: // https://lemire.me/blog/2017/09/18/visiting-all-values-in-an-array-exactly-once-in-random-order/ for (u32 I = 0; I < NumberOfTSDs; I++) { u32 A = I + 1; u32 B = NumberOfTSDs; // Find the GCD between I + 1 and NumberOfTSDs. If 1, they are coprimes. while (B != 0) { const u32 T = A; A = B; B = T % B; } if (A == 1) CoPrimes[NumberOfCoPrimes++] = I + 1; } Initialized = true; } void init(Allocator *Instance) { memset(this, 0, sizeof(*this)); initLinkerInitialized(Instance); } void unmapTestOnly() { unmap(reinterpret_cast(TSDs), sizeof(TSD) * NumberOfTSDs); setCurrentTSD(nullptr); pthread_key_delete(PThreadKey); } ALWAYS_INLINE void initThreadMaybe(Allocator *Instance, UNUSED bool MinimalInit) { if (LIKELY(getCurrentTSD())) return; initThread(Instance); } ALWAYS_INLINE TSD *getTSDAndLock(bool *UnlockRequired) { TSD *TSD = getCurrentTSD(); DCHECK(TSD); *UnlockRequired = true; // Try to lock the currently associated context. if (TSD->tryLock()) return TSD; // If that fails, go down the slow path. return getTSDAndLockSlow(TSD); } void disable() { Mutex.lock(); for (u32 I = 0; I < NumberOfTSDs; I++) TSDs[I].lock(); } void enable() { for (s32 I = NumberOfTSDs - 1; I >= 0; I--) TSDs[I].unlock(); Mutex.unlock(); } private: ALWAYS_INLINE void setCurrentTSD(TSD *CurrentTSD) { #if _BIONIC *getAndroidTlsPtr() = reinterpret_cast(CurrentTSD); #elif SCUDO_LINUX ThreadTSD = CurrentTSD; #else CHECK_EQ( pthread_setspecific(PThreadKey, reinterpret_cast(CurrentTSD)), 0); #endif } ALWAYS_INLINE TSD *getCurrentTSD() { #if _BIONIC return reinterpret_cast *>(*getAndroidTlsPtr()); #elif SCUDO_LINUX return ThreadTSD; #else return reinterpret_cast *>(pthread_getspecific(PThreadKey)); #endif } void initOnceMaybe(Allocator *Instance) { ScopedLock L(Mutex); if (LIKELY(Initialized)) return; initLinkerInitialized(Instance); // Sets Initialized. } NOINLINE void initThread(Allocator *Instance) { initOnceMaybe(Instance); // Initial context assignment is done in a plain round-robin fashion. const u32 Index = atomic_fetch_add(&CurrentIndex, 1U, memory_order_relaxed); setCurrentTSD(&TSDs[Index % NumberOfTSDs]); Instance->callPostInitCallback(); } NOINLINE TSD *getTSDAndLockSlow(TSD *CurrentTSD) { if (MaxTSDCount > 1U && NumberOfTSDs > 1U) { // Use the Precedence of the current TSD as our random seed. Since we are // in the slow path, it means that tryLock failed, and as a result it's // very likely that said Precedence is non-zero. const u32 R = static_cast(CurrentTSD->getPrecedence()); const u32 Inc = CoPrimes[R % NumberOfCoPrimes]; u32 Index = R % NumberOfTSDs; uptr LowestPrecedence = UINTPTR_MAX; TSD *CandidateTSD = nullptr; // Go randomly through at most 4 contexts and find a candidate. for (u32 I = 0; I < Min(4U, NumberOfTSDs); I++) { if (TSDs[Index].tryLock()) { setCurrentTSD(&TSDs[Index]); return &TSDs[Index]; } const uptr Precedence = TSDs[Index].getPrecedence(); // A 0 precedence here means another thread just locked this TSD. if (Precedence && Precedence < LowestPrecedence) { CandidateTSD = &TSDs[Index]; LowestPrecedence = Precedence; } Index += Inc; if (Index >= NumberOfTSDs) Index -= NumberOfTSDs; } if (CandidateTSD) { CandidateTSD->lock(); setCurrentTSD(CandidateTSD); return CandidateTSD; } } // Last resort, stick with the current one. CurrentTSD->lock(); return CurrentTSD; } pthread_key_t PThreadKey; atomic_u32 CurrentIndex; u32 NumberOfTSDs; TSD *TSDs; u32 NumberOfCoPrimes; u32 CoPrimes[MaxTSDCount]; bool Initialized; HybridMutex Mutex; #if SCUDO_LINUX && !_BIONIC static THREADLOCAL TSD *ThreadTSD; #endif }; #if SCUDO_LINUX && !_BIONIC template THREADLOCAL TSD *TSDRegistrySharedT::ThreadTSD; #endif } // namespace scudo #endif // SCUDO_TSD_SHARED_H_