//===-- tsan_interface_atomic.cpp -----------------------------------------===// // // 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 // //===----------------------------------------------------------------------===// // // This file is a part of ThreadSanitizer (TSan), a race detector. // //===----------------------------------------------------------------------===// // ThreadSanitizer atomic operations are based on C++11/C1x standards. // For background see C++11 standard. A slightly older, publicly // available draft of the standard (not entirely up-to-date, but close enough // for casual browsing) is available here: // http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2011/n3242.pdf // The following page contains more background information: // http://www.hpl.hp.com/personal/Hans_Boehm/c++mm/ #include "sanitizer_common/sanitizer_placement_new.h" #include "sanitizer_common/sanitizer_stacktrace.h" #include "sanitizer_common/sanitizer_mutex.h" #include "tsan_flags.h" #include "tsan_interface.h" #include "tsan_rtl.h" using namespace __tsan; #if !SANITIZER_GO && __TSAN_HAS_INT128 // Protects emulation of 128-bit atomic operations. static StaticSpinMutex mutex128; #endif #if SANITIZER_DEBUG static bool IsLoadOrder(morder mo) { return mo == mo_relaxed || mo == mo_consume || mo == mo_acquire || mo == mo_seq_cst; } static bool IsStoreOrder(morder mo) { return mo == mo_relaxed || mo == mo_release || mo == mo_seq_cst; } #endif static bool IsReleaseOrder(morder mo) { return mo == mo_release || mo == mo_acq_rel || mo == mo_seq_cst; } static bool IsAcquireOrder(morder mo) { return mo == mo_consume || mo == mo_acquire || mo == mo_acq_rel || mo == mo_seq_cst; } static bool IsAcqRelOrder(morder mo) { return mo == mo_acq_rel || mo == mo_seq_cst; } template T func_xchg(volatile T *v, T op) { T res = __sync_lock_test_and_set(v, op); // __sync_lock_test_and_set does not contain full barrier. __sync_synchronize(); return res; } template T func_add(volatile T *v, T op) { return __sync_fetch_and_add(v, op); } template T func_sub(volatile T *v, T op) { return __sync_fetch_and_sub(v, op); } template T func_and(volatile T *v, T op) { return __sync_fetch_and_and(v, op); } template T func_or(volatile T *v, T op) { return __sync_fetch_and_or(v, op); } template T func_xor(volatile T *v, T op) { return __sync_fetch_and_xor(v, op); } template T func_nand(volatile T *v, T op) { // clang does not support __sync_fetch_and_nand. T cmp = *v; for (;;) { T newv = ~(cmp & op); T cur = __sync_val_compare_and_swap(v, cmp, newv); if (cmp == cur) return cmp; cmp = cur; } } template T func_cas(volatile T *v, T cmp, T xch) { return __sync_val_compare_and_swap(v, cmp, xch); } // clang does not support 128-bit atomic ops. // Atomic ops are executed under tsan internal mutex, // here we assume that the atomic variables are not accessed // from non-instrumented code. #if !defined(__GCC_HAVE_SYNC_COMPARE_AND_SWAP_16) && !SANITIZER_GO \ && __TSAN_HAS_INT128 a128 func_xchg(volatile a128 *v, a128 op) { SpinMutexLock lock(&mutex128); a128 cmp = *v; *v = op; return cmp; } a128 func_add(volatile a128 *v, a128 op) { SpinMutexLock lock(&mutex128); a128 cmp = *v; *v = cmp + op; return cmp; } a128 func_sub(volatile a128 *v, a128 op) { SpinMutexLock lock(&mutex128); a128 cmp = *v; *v = cmp - op; return cmp; } a128 func_and(volatile a128 *v, a128 op) { SpinMutexLock lock(&mutex128); a128 cmp = *v; *v = cmp & op; return cmp; } a128 func_or(volatile a128 *v, a128 op) { SpinMutexLock lock(&mutex128); a128 cmp = *v; *v = cmp | op; return cmp; } a128 func_xor(volatile a128 *v, a128 op) { SpinMutexLock lock(&mutex128); a128 cmp = *v; *v = cmp ^ op; return cmp; } a128 func_nand(volatile a128 *v, a128 op) { SpinMutexLock lock(&mutex128); a128 cmp = *v; *v = ~(cmp & op); return cmp; } a128 func_cas(volatile a128 *v, a128 cmp, a128 xch) { SpinMutexLock lock(&mutex128); a128 cur = *v; if (cur == cmp) *v = xch; return cur; } #endif template static int AccessSize() { if (sizeof(T) <= 1) return 1; else if (sizeof(T) <= 2) return 2; else if (sizeof(T) <= 4) return 4; else return 8; // For 16-byte atomics we also use 8-byte memory access, // this leads to false negatives only in very obscure cases. } #if !SANITIZER_GO static atomic_uint8_t *to_atomic(const volatile a8 *a) { return reinterpret_cast(const_cast(a)); } static atomic_uint16_t *to_atomic(const volatile a16 *a) { return reinterpret_cast(const_cast(a)); } #endif static atomic_uint32_t *to_atomic(const volatile a32 *a) { return reinterpret_cast(const_cast(a)); } static atomic_uint64_t *to_atomic(const volatile a64 *a) { return reinterpret_cast(const_cast(a)); } static memory_order to_mo(morder mo) { switch (mo) { case mo_relaxed: return memory_order_relaxed; case mo_consume: return memory_order_consume; case mo_acquire: return memory_order_acquire; case mo_release: return memory_order_release; case mo_acq_rel: return memory_order_acq_rel; case mo_seq_cst: return memory_order_seq_cst; } DCHECK(0); return memory_order_seq_cst; } template static T NoTsanAtomicLoad(const volatile T *a, morder mo) { return atomic_load(to_atomic(a), to_mo(mo)); } #if __TSAN_HAS_INT128 && !SANITIZER_GO static a128 NoTsanAtomicLoad(const volatile a128 *a, morder mo) { SpinMutexLock lock(&mutex128); return *a; } #endif template static T AtomicLoad(ThreadState *thr, uptr pc, const volatile T *a, morder mo) { DCHECK(IsLoadOrder(mo)); // This fast-path is critical for performance. // Assume the access is atomic. if (!IsAcquireOrder(mo)) { MemoryAccess(thr, pc, (uptr)a, AccessSize(), kAccessRead | kAccessAtomic); return NoTsanAtomicLoad(a, mo); } // Don't create sync object if it does not exist yet. For example, an atomic // pointer is initialized to nullptr and then periodically acquire-loaded. T v = NoTsanAtomicLoad(a, mo); SyncVar *s = ctx->metamap.GetSyncIfExists((uptr)a); if (s) { ReadLock l(&s->mtx); AcquireImpl(thr, pc, &s->clock); // Re-read under sync mutex because we need a consistent snapshot // of the value and the clock we acquire. v = NoTsanAtomicLoad(a, mo); } MemoryAccess(thr, pc, (uptr)a, AccessSize(), kAccessRead | kAccessAtomic); return v; } template static void NoTsanAtomicStore(volatile T *a, T v, morder mo) { atomic_store(to_atomic(a), v, to_mo(mo)); } #if __TSAN_HAS_INT128 && !SANITIZER_GO static void NoTsanAtomicStore(volatile a128 *a, a128 v, morder mo) { SpinMutexLock lock(&mutex128); *a = v; } #endif template static void AtomicStore(ThreadState *thr, uptr pc, volatile T *a, T v, morder mo) { DCHECK(IsStoreOrder(mo)); MemoryAccess(thr, pc, (uptr)a, AccessSize(), kAccessWrite | kAccessAtomic); // This fast-path is critical for performance. // Assume the access is atomic. // Strictly saying even relaxed store cuts off release sequence, // so must reset the clock. if (!IsReleaseOrder(mo)) { NoTsanAtomicStore(a, v, mo); return; } __sync_synchronize(); SyncVar *s = ctx->metamap.GetSyncOrCreate(thr, pc, (uptr)a, false); Lock l(&s->mtx); thr->fast_state.IncrementEpoch(); // Can't increment epoch w/o writing to the trace as well. TraceAddEvent(thr, thr->fast_state, EventTypeMop, 0); ReleaseStoreImpl(thr, pc, &s->clock); NoTsanAtomicStore(a, v, mo); } template static T AtomicRMW(ThreadState *thr, uptr pc, volatile T *a, T v, morder mo) { MemoryAccess(thr, pc, (uptr)a, AccessSize(), kAccessWrite | kAccessAtomic); if (LIKELY(mo == mo_relaxed)) return F(a, v); SyncVar *s = ctx->metamap.GetSyncOrCreate(thr, pc, (uptr)a, false); Lock l(&s->mtx); thr->fast_state.IncrementEpoch(); // Can't increment epoch w/o writing to the trace as well. TraceAddEvent(thr, thr->fast_state, EventTypeMop, 0); if (IsAcqRelOrder(mo)) AcquireReleaseImpl(thr, pc, &s->clock); else if (IsReleaseOrder(mo)) ReleaseImpl(thr, pc, &s->clock); else if (IsAcquireOrder(mo)) AcquireImpl(thr, pc, &s->clock); return F(a, v); } template static T NoTsanAtomicExchange(volatile T *a, T v, morder mo) { return func_xchg(a, v); } template static T NoTsanAtomicFetchAdd(volatile T *a, T v, morder mo) { return func_add(a, v); } template static T NoTsanAtomicFetchSub(volatile T *a, T v, morder mo) { return func_sub(a, v); } template static T NoTsanAtomicFetchAnd(volatile T *a, T v, morder mo) { return func_and(a, v); } template static T NoTsanAtomicFetchOr(volatile T *a, T v, morder mo) { return func_or(a, v); } template static T NoTsanAtomicFetchXor(volatile T *a, T v, morder mo) { return func_xor(a, v); } template static T NoTsanAtomicFetchNand(volatile T *a, T v, morder mo) { return func_nand(a, v); } template static T AtomicExchange(ThreadState *thr, uptr pc, volatile T *a, T v, morder mo) { return AtomicRMW(thr, pc, a, v, mo); } template static T AtomicFetchAdd(ThreadState *thr, uptr pc, volatile T *a, T v, morder mo) { return AtomicRMW(thr, pc, a, v, mo); } template static T AtomicFetchSub(ThreadState *thr, uptr pc, volatile T *a, T v, morder mo) { return AtomicRMW(thr, pc, a, v, mo); } template static T AtomicFetchAnd(ThreadState *thr, uptr pc, volatile T *a, T v, morder mo) { return AtomicRMW(thr, pc, a, v, mo); } template static T AtomicFetchOr(ThreadState *thr, uptr pc, volatile T *a, T v, morder mo) { return AtomicRMW(thr, pc, a, v, mo); } template static T AtomicFetchXor(ThreadState *thr, uptr pc, volatile T *a, T v, morder mo) { return AtomicRMW(thr, pc, a, v, mo); } template static T AtomicFetchNand(ThreadState *thr, uptr pc, volatile T *a, T v, morder mo) { return AtomicRMW(thr, pc, a, v, mo); } template static bool NoTsanAtomicCAS(volatile T *a, T *c, T v, morder mo, morder fmo) { return atomic_compare_exchange_strong(to_atomic(a), c, v, to_mo(mo)); } #if __TSAN_HAS_INT128 static bool NoTsanAtomicCAS(volatile a128 *a, a128 *c, a128 v, morder mo, morder fmo) { a128 old = *c; a128 cur = func_cas(a, old, v); if (cur == old) return true; *c = cur; return false; } #endif template static T NoTsanAtomicCAS(volatile T *a, T c, T v, morder mo, morder fmo) { NoTsanAtomicCAS(a, &c, v, mo, fmo); return c; } template static bool AtomicCAS(ThreadState *thr, uptr pc, volatile T *a, T *c, T v, morder mo, morder fmo) { // 31.7.2.18: "The failure argument shall not be memory_order_release // nor memory_order_acq_rel". LLVM (2021-05) fallbacks to Monotonic // (mo_relaxed) when those are used. DCHECK(IsLoadOrder(fmo)); MemoryAccess(thr, pc, (uptr)a, AccessSize(), kAccessWrite | kAccessAtomic); if (LIKELY(mo == mo_relaxed && fmo == mo_relaxed)) { T cc = *c; T pr = func_cas(a, cc, v); if (pr == cc) return true; *c = pr; return false; } bool release = IsReleaseOrder(mo); SyncVar *s = ctx->metamap.GetSyncOrCreate(thr, pc, (uptr)a, false); RWLock l(&s->mtx, release); T cc = *c; T pr = func_cas(a, cc, v); bool success = pr == cc; if (!success) { *c = pr; mo = fmo; } thr->fast_state.IncrementEpoch(); // Can't increment epoch w/o writing to the trace as well. TraceAddEvent(thr, thr->fast_state, EventTypeMop, 0); if (success && IsAcqRelOrder(mo)) AcquireReleaseImpl(thr, pc, &s->clock); else if (success && IsReleaseOrder(mo)) ReleaseImpl(thr, pc, &s->clock); else if (IsAcquireOrder(mo)) AcquireImpl(thr, pc, &s->clock); return success; } template static T AtomicCAS(ThreadState *thr, uptr pc, volatile T *a, T c, T v, morder mo, morder fmo) { AtomicCAS(thr, pc, a, &c, v, mo, fmo); return c; } #if !SANITIZER_GO static void NoTsanAtomicFence(morder mo) { __sync_synchronize(); } static void AtomicFence(ThreadState *thr, uptr pc, morder mo) { // FIXME(dvyukov): not implemented. __sync_synchronize(); } #endif // Interface functions follow. #if !SANITIZER_GO // C/C++ static morder convert_morder(morder mo) { if (flags()->force_seq_cst_atomics) return (morder)mo_seq_cst; // Filter out additional memory order flags: // MEMMODEL_SYNC = 1 << 15 // __ATOMIC_HLE_ACQUIRE = 1 << 16 // __ATOMIC_HLE_RELEASE = 1 << 17 // // HLE is an optimization, and we pretend that elision always fails. // MEMMODEL_SYNC is used when lowering __sync_ atomics, // since we use __sync_ atomics for actual atomic operations, // we can safely ignore it as well. It also subtly affects semantics, // but we don't model the difference. return (morder)(mo & 0x7fff); } # define ATOMIC_IMPL(func, ...) \ ThreadState *const thr = cur_thread(); \ ProcessPendingSignals(thr); \ if (UNLIKELY(thr->ignore_sync || thr->ignore_interceptors)) \ return NoTsanAtomic##func(__VA_ARGS__); \ mo = convert_morder(mo); \ return Atomic##func(thr, GET_CALLER_PC(), __VA_ARGS__); extern "C" { SANITIZER_INTERFACE_ATTRIBUTE a8 __tsan_atomic8_load(const volatile a8 *a, morder mo) { ATOMIC_IMPL(Load, a, mo); } SANITIZER_INTERFACE_ATTRIBUTE a16 __tsan_atomic16_load(const volatile a16 *a, morder mo) { ATOMIC_IMPL(Load, a, mo); } SANITIZER_INTERFACE_ATTRIBUTE a32 __tsan_atomic32_load(const volatile a32 *a, morder mo) { ATOMIC_IMPL(Load, a, mo); } SANITIZER_INTERFACE_ATTRIBUTE a64 __tsan_atomic64_load(const volatile a64 *a, morder mo) { ATOMIC_IMPL(Load, a, mo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE a128 __tsan_atomic128_load(const volatile a128 *a, morder mo) { ATOMIC_IMPL(Load, a, mo); } #endif SANITIZER_INTERFACE_ATTRIBUTE void __tsan_atomic8_store(volatile a8 *a, a8 v, morder mo) { ATOMIC_IMPL(Store, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_atomic16_store(volatile a16 *a, a16 v, morder mo) { ATOMIC_IMPL(Store, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_atomic32_store(volatile a32 *a, a32 v, morder mo) { ATOMIC_IMPL(Store, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_atomic64_store(volatile a64 *a, a64 v, morder mo) { ATOMIC_IMPL(Store, a, v, mo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE void __tsan_atomic128_store(volatile a128 *a, a128 v, morder mo) { ATOMIC_IMPL(Store, a, v, mo); } #endif SANITIZER_INTERFACE_ATTRIBUTE a8 __tsan_atomic8_exchange(volatile a8 *a, a8 v, morder mo) { ATOMIC_IMPL(Exchange, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a16 __tsan_atomic16_exchange(volatile a16 *a, a16 v, morder mo) { ATOMIC_IMPL(Exchange, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a32 __tsan_atomic32_exchange(volatile a32 *a, a32 v, morder mo) { ATOMIC_IMPL(Exchange, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a64 __tsan_atomic64_exchange(volatile a64 *a, a64 v, morder mo) { ATOMIC_IMPL(Exchange, a, v, mo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE a128 __tsan_atomic128_exchange(volatile a128 *a, a128 v, morder mo) { ATOMIC_IMPL(Exchange, a, v, mo); } #endif SANITIZER_INTERFACE_ATTRIBUTE a8 __tsan_atomic8_fetch_add(volatile a8 *a, a8 v, morder mo) { ATOMIC_IMPL(FetchAdd, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a16 __tsan_atomic16_fetch_add(volatile a16 *a, a16 v, morder mo) { ATOMIC_IMPL(FetchAdd, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a32 __tsan_atomic32_fetch_add(volatile a32 *a, a32 v, morder mo) { ATOMIC_IMPL(FetchAdd, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a64 __tsan_atomic64_fetch_add(volatile a64 *a, a64 v, morder mo) { ATOMIC_IMPL(FetchAdd, a, v, mo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE a128 __tsan_atomic128_fetch_add(volatile a128 *a, a128 v, morder mo) { ATOMIC_IMPL(FetchAdd, a, v, mo); } #endif SANITIZER_INTERFACE_ATTRIBUTE a8 __tsan_atomic8_fetch_sub(volatile a8 *a, a8 v, morder mo) { ATOMIC_IMPL(FetchSub, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a16 __tsan_atomic16_fetch_sub(volatile a16 *a, a16 v, morder mo) { ATOMIC_IMPL(FetchSub, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a32 __tsan_atomic32_fetch_sub(volatile a32 *a, a32 v, morder mo) { ATOMIC_IMPL(FetchSub, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a64 __tsan_atomic64_fetch_sub(volatile a64 *a, a64 v, morder mo) { ATOMIC_IMPL(FetchSub, a, v, mo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE a128 __tsan_atomic128_fetch_sub(volatile a128 *a, a128 v, morder mo) { ATOMIC_IMPL(FetchSub, a, v, mo); } #endif SANITIZER_INTERFACE_ATTRIBUTE a8 __tsan_atomic8_fetch_and(volatile a8 *a, a8 v, morder mo) { ATOMIC_IMPL(FetchAnd, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a16 __tsan_atomic16_fetch_and(volatile a16 *a, a16 v, morder mo) { ATOMIC_IMPL(FetchAnd, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a32 __tsan_atomic32_fetch_and(volatile a32 *a, a32 v, morder mo) { ATOMIC_IMPL(FetchAnd, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a64 __tsan_atomic64_fetch_and(volatile a64 *a, a64 v, morder mo) { ATOMIC_IMPL(FetchAnd, a, v, mo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE a128 __tsan_atomic128_fetch_and(volatile a128 *a, a128 v, morder mo) { ATOMIC_IMPL(FetchAnd, a, v, mo); } #endif SANITIZER_INTERFACE_ATTRIBUTE a8 __tsan_atomic8_fetch_or(volatile a8 *a, a8 v, morder mo) { ATOMIC_IMPL(FetchOr, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a16 __tsan_atomic16_fetch_or(volatile a16 *a, a16 v, morder mo) { ATOMIC_IMPL(FetchOr, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a32 __tsan_atomic32_fetch_or(volatile a32 *a, a32 v, morder mo) { ATOMIC_IMPL(FetchOr, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a64 __tsan_atomic64_fetch_or(volatile a64 *a, a64 v, morder mo) { ATOMIC_IMPL(FetchOr, a, v, mo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE a128 __tsan_atomic128_fetch_or(volatile a128 *a, a128 v, morder mo) { ATOMIC_IMPL(FetchOr, a, v, mo); } #endif SANITIZER_INTERFACE_ATTRIBUTE a8 __tsan_atomic8_fetch_xor(volatile a8 *a, a8 v, morder mo) { ATOMIC_IMPL(FetchXor, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a16 __tsan_atomic16_fetch_xor(volatile a16 *a, a16 v, morder mo) { ATOMIC_IMPL(FetchXor, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a32 __tsan_atomic32_fetch_xor(volatile a32 *a, a32 v, morder mo) { ATOMIC_IMPL(FetchXor, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a64 __tsan_atomic64_fetch_xor(volatile a64 *a, a64 v, morder mo) { ATOMIC_IMPL(FetchXor, a, v, mo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE a128 __tsan_atomic128_fetch_xor(volatile a128 *a, a128 v, morder mo) { ATOMIC_IMPL(FetchXor, a, v, mo); } #endif SANITIZER_INTERFACE_ATTRIBUTE a8 __tsan_atomic8_fetch_nand(volatile a8 *a, a8 v, morder mo) { ATOMIC_IMPL(FetchNand, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a16 __tsan_atomic16_fetch_nand(volatile a16 *a, a16 v, morder mo) { ATOMIC_IMPL(FetchNand, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a32 __tsan_atomic32_fetch_nand(volatile a32 *a, a32 v, morder mo) { ATOMIC_IMPL(FetchNand, a, v, mo); } SANITIZER_INTERFACE_ATTRIBUTE a64 __tsan_atomic64_fetch_nand(volatile a64 *a, a64 v, morder mo) { ATOMIC_IMPL(FetchNand, a, v, mo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE a128 __tsan_atomic128_fetch_nand(volatile a128 *a, a128 v, morder mo) { ATOMIC_IMPL(FetchNand, a, v, mo); } #endif SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic8_compare_exchange_strong(volatile a8 *a, a8 *c, a8 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic16_compare_exchange_strong(volatile a16 *a, a16 *c, a16 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic32_compare_exchange_strong(volatile a32 *a, a32 *c, a32 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic64_compare_exchange_strong(volatile a64 *a, a64 *c, a64 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic128_compare_exchange_strong(volatile a128 *a, a128 *c, a128 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } #endif SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic8_compare_exchange_weak(volatile a8 *a, a8 *c, a8 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic16_compare_exchange_weak(volatile a16 *a, a16 *c, a16 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic32_compare_exchange_weak(volatile a32 *a, a32 *c, a32 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic64_compare_exchange_weak(volatile a64 *a, a64 *c, a64 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE int __tsan_atomic128_compare_exchange_weak(volatile a128 *a, a128 *c, a128 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } #endif SANITIZER_INTERFACE_ATTRIBUTE a8 __tsan_atomic8_compare_exchange_val(volatile a8 *a, a8 c, a8 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } SANITIZER_INTERFACE_ATTRIBUTE a16 __tsan_atomic16_compare_exchange_val(volatile a16 *a, a16 c, a16 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } SANITIZER_INTERFACE_ATTRIBUTE a32 __tsan_atomic32_compare_exchange_val(volatile a32 *a, a32 c, a32 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } SANITIZER_INTERFACE_ATTRIBUTE a64 __tsan_atomic64_compare_exchange_val(volatile a64 *a, a64 c, a64 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } #if __TSAN_HAS_INT128 SANITIZER_INTERFACE_ATTRIBUTE a128 __tsan_atomic128_compare_exchange_val(volatile a128 *a, a128 c, a128 v, morder mo, morder fmo) { ATOMIC_IMPL(CAS, a, c, v, mo, fmo); } #endif SANITIZER_INTERFACE_ATTRIBUTE void __tsan_atomic_thread_fence(morder mo) { ATOMIC_IMPL(Fence, mo); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_atomic_signal_fence(morder mo) { } } // extern "C" #else // #if !SANITIZER_GO // Go # define ATOMIC(func, ...) \ if (thr->ignore_sync) { \ NoTsanAtomic##func(__VA_ARGS__); \ } else { \ FuncEntry(thr, cpc); \ Atomic##func(thr, pc, __VA_ARGS__); \ FuncExit(thr); \ } # define ATOMIC_RET(func, ret, ...) \ if (thr->ignore_sync) { \ (ret) = NoTsanAtomic##func(__VA_ARGS__); \ } else { \ FuncEntry(thr, cpc); \ (ret) = Atomic##func(thr, pc, __VA_ARGS__); \ FuncExit(thr); \ } extern "C" { SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic32_load(ThreadState *thr, uptr cpc, uptr pc, u8 *a) { ATOMIC_RET(Load, *(a32*)(a+8), *(a32**)a, mo_acquire); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic64_load(ThreadState *thr, uptr cpc, uptr pc, u8 *a) { ATOMIC_RET(Load, *(a64*)(a+8), *(a64**)a, mo_acquire); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic32_store(ThreadState *thr, uptr cpc, uptr pc, u8 *a) { ATOMIC(Store, *(a32**)a, *(a32*)(a+8), mo_release); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic64_store(ThreadState *thr, uptr cpc, uptr pc, u8 *a) { ATOMIC(Store, *(a64**)a, *(a64*)(a+8), mo_release); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic32_fetch_add(ThreadState *thr, uptr cpc, uptr pc, u8 *a) { ATOMIC_RET(FetchAdd, *(a32*)(a+16), *(a32**)a, *(a32*)(a+8), mo_acq_rel); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic64_fetch_add(ThreadState *thr, uptr cpc, uptr pc, u8 *a) { ATOMIC_RET(FetchAdd, *(a64*)(a+16), *(a64**)a, *(a64*)(a+8), mo_acq_rel); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic32_exchange(ThreadState *thr, uptr cpc, uptr pc, u8 *a) { ATOMIC_RET(Exchange, *(a32*)(a+16), *(a32**)a, *(a32*)(a+8), mo_acq_rel); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic64_exchange(ThreadState *thr, uptr cpc, uptr pc, u8 *a) { ATOMIC_RET(Exchange, *(a64*)(a+16), *(a64**)a, *(a64*)(a+8), mo_acq_rel); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic32_compare_exchange( ThreadState *thr, uptr cpc, uptr pc, u8 *a) { a32 cur = 0; a32 cmp = *(a32*)(a+8); ATOMIC_RET(CAS, cur, *(a32**)a, cmp, *(a32*)(a+12), mo_acq_rel, mo_acquire); *(bool*)(a+16) = (cur == cmp); } SANITIZER_INTERFACE_ATTRIBUTE void __tsan_go_atomic64_compare_exchange( ThreadState *thr, uptr cpc, uptr pc, u8 *a) { a64 cur = 0; a64 cmp = *(a64*)(a+8); ATOMIC_RET(CAS, cur, *(a64**)a, cmp, *(a64*)(a+16), mo_acq_rel, mo_acquire); *(bool*)(a+24) = (cur == cmp); } } // extern "C" #endif // #if !SANITIZER_GO