/*
- * Copyright 2016 Facebook, Inc.
+ * Copyright 2017 Facebook, Inc.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
#pragma once
#include <stdint.h>
+
#include <atomic>
#include <thread>
#include <type_traits>
+
#include <folly/Likely.h>
-#include <folly/detail/CacheLocality.h>
+#include <folly/concurrency/CacheLocality.h>
#include <folly/detail/Futex.h>
#include <folly/portability/Asm.h>
#include <folly/portability/SysResource.h>
// the shared slots. If you can conveniently pass state from lock
// acquisition to release then the fastest mechanism is to std::move
// the SharedMutex::ReadHolder instance or an SharedMutex::Token (using
-// lock_shared(Token&) and unlock_sahred(Token&)). The guard or token
+// lock_shared(Token&) and unlock_shared(Token&)). The guard or token
// will tell unlock_shared where in deferredReaders[] to look for the
// deferred lock. The Token-less version of unlock_shared() works in all
// cases, but is optimized for the common (no inter-thread handoff) case.
//
// If you have observed by profiling that your SharedMutex-s are getting
// cache misses on deferredReaders[] due to another SharedMutex user, then
-// you can use the tag type plus the RWDEFERREDLOCK_DECLARE_STATIC_STORAGE
-// macro to create your own instantiation of the type. The contention
-// threshold (see kNumSharedToStartDeferring) should make this unnecessary
-// in all but the most extreme cases. Make sure to check that the
-// increased icache and dcache footprint of the tagged result is worth it.
+// you can use the tag type to create your own instantiation of the type.
+// The contention threshold (see kNumSharedToStartDeferring) should make
+// this unnecessary in all but the most extreme cases. Make sure to check
+// that the increased icache and dcache footprint of the tagged result is
+// worth it.
+
+// SharedMutex's use of thread local storage is as an optimization, so
+// for the case where thread local storage is not supported, define it
+// away.
+#ifndef FOLLY_SHAREDMUTEX_TLS
+#if !FOLLY_MOBILE
+#define FOLLY_SHAREDMUTEX_TLS FOLLY_TLS
+#else
+#define FOLLY_SHAREDMUTEX_TLS
+#endif
+#endif
namespace folly {
uint16_t slot_;
};
-template <bool ReaderPriority,
- typename Tag_ = void,
- template <typename> class Atom = std::atomic,
- bool BlockImmediately = false>
+template <
+ bool ReaderPriority,
+ typename Tag_ = void,
+ template <typename> class Atom = std::atomic,
+ bool BlockImmediately = false>
class SharedMutexImpl {
public:
static constexpr bool kReaderPriority = ReaderPriority;
class UpgradeHolder;
class WriteHolder;
- constexpr SharedMutexImpl() : state_(0) {}
+ constexpr SharedMutexImpl() noexcept : state_(0) {}
SharedMutexImpl(const SharedMutexImpl&) = delete;
SharedMutexImpl(SharedMutexImpl&&) = delete;
static constexpr uintptr_t kTokenless = 0x1;
// This is the starting location for Token-less unlock_shared().
- static FOLLY_TLS uint32_t tls_lastTokenlessSlot;
+ static FOLLY_SHAREDMUTEX_TLS uint32_t tls_lastTokenlessSlot;
+
+ // Last deferred reader slot used.
+ static FOLLY_SHAREDMUTEX_TLS uint32_t tls_lastDeferredReaderSlot;
+
// Only indexes divisible by kDeferredSeparationFactor are used.
// If any of those elements points to a SharedMutexImpl, then it
}
uint32_t after = (state & kMayDefer) == 0 ? 0 : kPrevDefer;
- if (!ReaderPriority || (state & (kMayDefer | kHasS)) == 0) {
+ if (!kReaderPriority || (state & (kMayDefer | kHasS)) == 0) {
// Block readers immediately, either because we are in write
// priority mode or because we can acquire the lock in one
// step. Note that if state has kHasU, then we are doing an
return false;
}
- if (ReaderPriority && (state & kHasE) == 0) {
+ if (kReaderPriority && (state & kHasE) == 0) {
assert((state & kBegunE) != 0);
if (!state_.compare_exchange_strong(state,
(state & ~kBegunE) | kHasE)) {
WaitContext& ctx) {
#ifdef RUSAGE_THREAD
struct rusage usage;
+ std::memset(&usage, 0, sizeof(usage));
long before = -1;
#endif
for (uint32_t yieldCount = 0; yieldCount < kMaxSoftYieldCount;
return;
}
}
- asm_pause();
+ asm_volatile_pause();
if (UNLIKELY(++spinCount >= kMaxSpinCount)) {
applyDeferredReaders(state, ctx, slot);
return;
#ifdef RUSAGE_THREAD
struct rusage usage;
+ std::memset(&usage, 0, sizeof(usage));
long before = -1;
#endif
for (uint32_t yieldCount = 0; yieldCount < kMaxSoftYieldCount;
}
template <class WaitContext>
- bool lockSharedImpl(uint32_t& state, Token* token, WaitContext& ctx) {
- while (true) {
- if (UNLIKELY((state & kHasE) != 0) &&
- !waitForZeroBits(state, kHasE, kWaitingS, ctx) && ctx.canTimeOut()) {
- return false;
- }
-
- uint32_t slot;
- uintptr_t slotValue = 1; // any non-zero value will do
-
- bool canAlreadyDefer = (state & kMayDefer) != 0;
- bool aboveDeferThreshold =
- (state & kHasS) >= (kNumSharedToStartDeferring - 1) * kIncrHasS;
- bool drainInProgress = ReaderPriority && (state & kBegunE) != 0;
- if (canAlreadyDefer || (aboveDeferThreshold && !drainInProgress)) {
- // starting point for our empty-slot search, can change after
- // calling waitForZeroBits
- uint32_t bestSlot =
- (uint32_t)folly::detail::AccessSpreader<Atom>::current(
- kMaxDeferredReaders);
-
- // deferred readers are already enabled, or it is time to
- // enable them if we can find a slot
- for (uint32_t i = 0; i < kDeferredSearchDistance; ++i) {
- slot = bestSlot ^ i;
- assert(slot < kMaxDeferredReaders);
- slotValue = deferredReader(slot)->load(std::memory_order_relaxed);
- if (slotValue == 0) {
- // found empty slot
- break;
- }
- }
- }
-
- if (slotValue != 0) {
- // not yet deferred, or no empty slots
- if (state_.compare_exchange_strong(state, state + kIncrHasS)) {
- // successfully recorded the read lock inline
- if (token != nullptr) {
- token->type_ = Token::Type::INLINE_SHARED;
- }
- return true;
- }
- // state is updated, try again
- continue;
- }
-
- // record that deferred readers might be in use if necessary
- if ((state & kMayDefer) == 0) {
- if (!state_.compare_exchange_strong(state, state | kMayDefer)) {
- // keep going if CAS failed because somebody else set the bit
- // for us
- if ((state & (kHasE | kMayDefer)) != kMayDefer) {
- continue;
- }
- }
- // state = state | kMayDefer;
- }
-
- // try to use the slot
- bool gotSlot = deferredReader(slot)->compare_exchange_strong(
- slotValue,
- token == nullptr ? tokenlessSlotValue() : tokenfulSlotValue());
-
- // If we got the slot, we need to verify that an exclusive lock
- // didn't happen since we last checked. If we didn't get the slot we
- // need to recheck state_ anyway to make sure we don't waste too much
- // work. It is also possible that since we checked state_ someone
- // has acquired and released the write lock, clearing kMayDefer.
- // Both cases are covered by looking for the readers-possible bit,
- // because it is off when the exclusive lock bit is set.
- state = state_.load(std::memory_order_acquire);
-
- if (!gotSlot) {
- continue;
- }
-
- if (token == nullptr) {
- tls_lastTokenlessSlot = slot;
- }
-
- if ((state & kMayDefer) != 0) {
- assert((state & kHasE) == 0);
- // success
- if (token != nullptr) {
- token->type_ = Token::Type::DEFERRED_SHARED;
- token->slot_ = (uint16_t)slot;
- }
- return true;
- }
-
- // release the slot before retrying
- if (token == nullptr) {
- // We can't rely on slot. Token-less slot values can be freed by
- // any unlock_shared(), so we need to do the full deferredReader
- // search during unlock. Unlike unlock_shared(), we can't trust
- // kPrevDefer here. This deferred lock isn't visible to lock()
- // (that's the whole reason we're undoing it) so there might have
- // subsequently been an unlock() and lock() with no intervening
- // transition to deferred mode.
- if (!tryUnlockTokenlessSharedDeferred()) {
- unlockSharedInline();
- }
- } else {
- if (!tryUnlockSharedDeferred(slot)) {
- unlockSharedInline();
- }
- }
-
- // We got here not because the lock was unavailable, but because
- // we lost a compare-and-swap. Try-lock is typically allowed to
- // have spurious failures, but there is no lock efficiency gain
- // from exploiting that freedom here.
- }
- }
+ bool lockSharedImpl(uint32_t& state, Token* token, WaitContext& ctx);
// Updates the state in/out argument as if the locks were made inline,
// but does not update state_
}
}
- bool tryUnlockTokenlessSharedDeferred() {
- auto bestSlot = tls_lastTokenlessSlot;
- for (uint32_t i = 0; i < kMaxDeferredReaders; ++i) {
- auto slotPtr = deferredReader(bestSlot ^ i);
- auto slotValue = slotPtr->load(std::memory_order_relaxed);
- if (slotValue == tokenlessSlotValue() &&
- slotPtr->compare_exchange_strong(slotValue, 0)) {
- tls_lastTokenlessSlot = bestSlot ^ i;
- return true;
- }
- }
- return false;
- }
+ bool tryUnlockTokenlessSharedDeferred();
bool tryUnlockSharedDeferred(uint32_t slot) {
assert(slot < kMaxDeferredReaders);
public:
class ReadHolder {
- public:
ReadHolder() : lock_(nullptr) {}
- explicit ReadHolder(const SharedMutexImpl* lock) : ReadHolder(*lock) {}
+ public:
+ explicit ReadHolder(const SharedMutexImpl* lock)
+ : lock_(const_cast<SharedMutexImpl*>(lock)) {
+ if (lock_) {
+ lock_->lock_shared(token_);
+ }
+ }
explicit ReadHolder(const SharedMutexImpl& lock)
: lock_(const_cast<SharedMutexImpl*>(&lock)) {
};
class UpgradeHolder {
- public:
UpgradeHolder() : lock_(nullptr) {}
- explicit UpgradeHolder(SharedMutexImpl* lock) : UpgradeHolder(*lock) {}
+ public:
+ explicit UpgradeHolder(SharedMutexImpl* lock) : lock_(lock) {
+ if (lock_) {
+ lock_->lock_upgrade();
+ }
+ }
explicit UpgradeHolder(SharedMutexImpl& lock) : lock_(&lock) {
lock_->lock_upgrade();
};
class WriteHolder {
- public:
WriteHolder() : lock_(nullptr) {}
- explicit WriteHolder(SharedMutexImpl* lock) : WriteHolder(*lock) {}
+ public:
+ explicit WriteHolder(SharedMutexImpl* lock) : lock_(lock) {
+ if (lock_) {
+ lock_->lock();
+ }
+ }
explicit WriteHolder(SharedMutexImpl& lock) : lock_(&lock) {
lock_->lock();
}
};
+typedef SharedMutexImpl<true> SharedMutexReadPriority;
+typedef SharedMutexImpl<false> SharedMutexWritePriority;
+typedef SharedMutexWritePriority SharedMutex;
+
+// Prevent the compiler from instantiating these in other translation units.
+// They are instantiated once in SharedMutex.cpp
+extern template class SharedMutexImpl<true>;
+extern template class SharedMutexImpl<false>;
+
template <
bool ReaderPriority,
typename Tag_,
typename Tag_,
template <typename> class Atom,
bool BlockImmediately>
-FOLLY_TLS uint32_t
+FOLLY_SHAREDMUTEX_TLS uint32_t
SharedMutexImpl<ReaderPriority, Tag_, Atom, BlockImmediately>::
tls_lastTokenlessSlot = 0;
-typedef SharedMutexImpl<true> SharedMutexReadPriority;
-typedef SharedMutexImpl<false> SharedMutexWritePriority;
-typedef SharedMutexWritePriority SharedMutex;
+template <
+ bool ReaderPriority,
+ typename Tag_,
+ template <typename> class Atom,
+ bool BlockImmediately>
+FOLLY_SHAREDMUTEX_TLS uint32_t
+ SharedMutexImpl<ReaderPriority, Tag_, Atom, BlockImmediately>::
+ tls_lastDeferredReaderSlot = 0;
-// Prevent the compiler from instantiating these in other translation units.
-// They are instantiated once in SharedMutex.cpp
-extern template class SharedMutexImpl<true>;
-extern template class SharedMutexImpl<false>;
+template <
+ bool ReaderPriority,
+ typename Tag_,
+ template <typename> class Atom,
+ bool BlockImmediately>
+bool SharedMutexImpl<ReaderPriority, Tag_, Atom, BlockImmediately>::
+ tryUnlockTokenlessSharedDeferred() {
+ auto bestSlot = tls_lastTokenlessSlot;
+ for (uint32_t i = 0; i < kMaxDeferredReaders; ++i) {
+ auto slotPtr = deferredReader(bestSlot ^ i);
+ auto slotValue = slotPtr->load(std::memory_order_relaxed);
+ if (slotValue == tokenlessSlotValue() &&
+ slotPtr->compare_exchange_strong(slotValue, 0)) {
+ tls_lastTokenlessSlot = bestSlot ^ i;
+ return true;
+ }
+ }
+ return false;
+}
+
+template <
+ bool ReaderPriority,
+ typename Tag_,
+ template <typename> class Atom,
+ bool BlockImmediately>
+template <class WaitContext>
+bool SharedMutexImpl<ReaderPriority, Tag_, Atom, BlockImmediately>::
+ lockSharedImpl(uint32_t& state, Token* token, WaitContext& ctx) {
+ while (true) {
+ if (UNLIKELY((state & kHasE) != 0) &&
+ !waitForZeroBits(state, kHasE, kWaitingS, ctx) && ctx.canTimeOut()) {
+ return false;
+ }
+
+ uint32_t slot = tls_lastDeferredReaderSlot;
+ uintptr_t slotValue = 1; // any non-zero value will do
+
+ bool canAlreadyDefer = (state & kMayDefer) != 0;
+ bool aboveDeferThreshold =
+ (state & kHasS) >= (kNumSharedToStartDeferring - 1) * kIncrHasS;
+ bool drainInProgress = ReaderPriority && (state & kBegunE) != 0;
+ if (canAlreadyDefer || (aboveDeferThreshold && !drainInProgress)) {
+ /* Try using the most recent slot first. */
+ slotValue = deferredReader(slot)->load(std::memory_order_relaxed);
+ if (slotValue != 0) {
+ // starting point for our empty-slot search, can change after
+ // calling waitForZeroBits
+ uint32_t bestSlot =
+ (uint32_t)folly::AccessSpreader<Atom>::current(kMaxDeferredReaders);
+
+ // deferred readers are already enabled, or it is time to
+ // enable them if we can find a slot
+ for (uint32_t i = 0; i < kDeferredSearchDistance; ++i) {
+ slot = bestSlot ^ i;
+ assert(slot < kMaxDeferredReaders);
+ slotValue = deferredReader(slot)->load(std::memory_order_relaxed);
+ if (slotValue == 0) {
+ // found empty slot
+ tls_lastDeferredReaderSlot = slot;
+ break;
+ }
+ }
+ }
+ }
+
+ if (slotValue != 0) {
+ // not yet deferred, or no empty slots
+ if (state_.compare_exchange_strong(state, state + kIncrHasS)) {
+ // successfully recorded the read lock inline
+ if (token != nullptr) {
+ token->type_ = Token::Type::INLINE_SHARED;
+ }
+ return true;
+ }
+ // state is updated, try again
+ continue;
+ }
+
+ // record that deferred readers might be in use if necessary
+ if ((state & kMayDefer) == 0) {
+ if (!state_.compare_exchange_strong(state, state | kMayDefer)) {
+ // keep going if CAS failed because somebody else set the bit
+ // for us
+ if ((state & (kHasE | kMayDefer)) != kMayDefer) {
+ continue;
+ }
+ }
+ // state = state | kMayDefer;
+ }
+
+ // try to use the slot
+ bool gotSlot = deferredReader(slot)->compare_exchange_strong(
+ slotValue,
+ token == nullptr ? tokenlessSlotValue() : tokenfulSlotValue());
+
+ // If we got the slot, we need to verify that an exclusive lock
+ // didn't happen since we last checked. If we didn't get the slot we
+ // need to recheck state_ anyway to make sure we don't waste too much
+ // work. It is also possible that since we checked state_ someone
+ // has acquired and released the write lock, clearing kMayDefer.
+ // Both cases are covered by looking for the readers-possible bit,
+ // because it is off when the exclusive lock bit is set.
+ state = state_.load(std::memory_order_acquire);
+
+ if (!gotSlot) {
+ continue;
+ }
+
+ if (token == nullptr) {
+ tls_lastTokenlessSlot = slot;
+ }
+
+ if ((state & kMayDefer) != 0) {
+ assert((state & kHasE) == 0);
+ // success
+ if (token != nullptr) {
+ token->type_ = Token::Type::DEFERRED_SHARED;
+ token->slot_ = (uint16_t)slot;
+ }
+ return true;
+ }
+
+ // release the slot before retrying
+ if (token == nullptr) {
+ // We can't rely on slot. Token-less slot values can be freed by
+ // any unlock_shared(), so we need to do the full deferredReader
+ // search during unlock. Unlike unlock_shared(), we can't trust
+ // kPrevDefer here. This deferred lock isn't visible to lock()
+ // (that's the whole reason we're undoing it) so there might have
+ // subsequently been an unlock() and lock() with no intervening
+ // transition to deferred mode.
+ if (!tryUnlockTokenlessSharedDeferred()) {
+ unlockSharedInline();
+ }
+ } else {
+ if (!tryUnlockSharedDeferred(slot)) {
+ unlockSharedInline();
+ }
+ }
+
+ // We got here not because the lock was unavailable, but because
+ // we lost a compare-and-swap. Try-lock is typically allowed to
+ // have spurious failures, but there is no lock efficiency gain
+ // from exploiting that freedom here.
+ }
+}
} // namespace folly