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//===-- scudo_tsd_shared.cpp ------------------------------------*- 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
//
//===----------------------------------------------------------------------===//
///
/// Scudo shared TSD implementation.
///
//===----------------------------------------------------------------------===//
#include "scudo_tsd.h"
#if !SCUDO_TSD_EXCLUSIVE
namespace __scudo {
static pthread_once_t GlobalInitialized = PTHREAD_ONCE_INIT;
pthread_key_t PThreadKey;
static atomic_uint32_t CurrentIndex;
static ScudoTSD *TSDs;
static u32 NumberOfTSDs;
static u32 CoPrimes[SCUDO_SHARED_TSD_POOL_SIZE];
static u32 NumberOfCoPrimes = 0;
#if SANITIZER_LINUX && !SANITIZER_ANDROID
__attribute__((tls_model("initial-exec")))
THREADLOCAL ScudoTSD *CurrentTSD;
#endif
static void initOnce() {
CHECK_EQ(pthread_key_create(&PThreadKey, NULL), 0);
initScudo();
NumberOfTSDs = Min(Max(1U, GetNumberOfCPUsCached()),
static_cast<u32>(SCUDO_SHARED_TSD_POOL_SIZE));
TSDs = reinterpret_cast<ScudoTSD *>(
MmapOrDie(sizeof(ScudoTSD) * NumberOfTSDs, "ScudoTSDs"));
for (u32 I = 0; I < NumberOfTSDs; I++) {
TSDs[I].init();
u32 A = I + 1;
u32 B = NumberOfTSDs;
while (B != 0) { const u32 T = A; A = B; B = T % B; }
if (A == 1)
CoPrimes[NumberOfCoPrimes++] = I + 1;
}
}
ALWAYS_INLINE void setCurrentTSD(ScudoTSD *TSD) {
#if SANITIZER_ANDROID
*get_android_tls_ptr() = reinterpret_cast<uptr>(TSD);
#elif SANITIZER_LINUX
CurrentTSD = TSD;
#else
CHECK_EQ(pthread_setspecific(PThreadKey, reinterpret_cast<void *>(TSD)), 0);
#endif // SANITIZER_ANDROID
}
void initThread(bool MinimalInit) {
pthread_once(&GlobalInitialized, initOnce);
// Initial context assignment is done in a plain round-robin fashion.
u32 Index = atomic_fetch_add(&CurrentIndex, 1, memory_order_relaxed);
setCurrentTSD(&TSDs[Index % NumberOfTSDs]);
}
ScudoTSD *getTSDAndLockSlow(ScudoTSD *TSD) NO_THREAD_SAFETY_ANALYSIS {
if (NumberOfTSDs > 1) {
// 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.
u32 RandState = static_cast<u32>(TSD->getPrecedence());
const u32 R = Rand(&RandState);
const u32 Inc = CoPrimes[R % NumberOfCoPrimes];
u32 Index = R % NumberOfTSDs;
uptr LowestPrecedence = UINTPTR_MAX;
ScudoTSD *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.
TSD->lock();
return TSD;
}
} // namespace __scudo
#endif // !SCUDO_TSD_EXCLUSIVE
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