faux-folly/folly/detail/Futex.cpp - nest-cam/4320010/faux-folly - Git at Google

 /*
  * Copyright 2015 Facebook, Inc.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *   http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include <folly/detail/Futex.h>
 #include <stdint.h>
 #include <string.h>
 #include <condition_variable>
 #include <mutex>
 #include <boost/intrusive/list.hpp>
 #include <folly/Hash.h>
 #include <folly/ScopeGuard.h>

 #ifdef __linux__
 # include <errno.h>
 # include <linux/futex.h>
 # include <sys/syscall.h>
 #endif

 using namespace std::chrono;

 namespace folly { namespace detail {

 namespace {

 ////////////////////////////////////////////////////
 // native implementation using the futex() syscall

 #ifdef __linux__

 /// Certain toolchains (like Android's) don't include the full futex API in
 /// their headers even though they support it. Make sure we have our constants
 /// even if the headers don't have them.
 #ifndef FUTEX_WAIT_BITSET
 # define FUTEX_WAIT_BITSET 9
 #endif
 #ifndef FUTEX_WAKE_BITSET
 # define FUTEX_WAKE_BITSET 10
 #endif
 #ifndef FUTEX_PRIVATE_FLAG
 # define FUTEX_PRIVATE_FLAG 128
 #endif
 #ifndef FUTEX_CLOCK_REALTIME
 # define FUTEX_CLOCK_REALTIME 256
 #endif

 int nativeFutexWake(void* addr, int count, uint32_t wakeMask) {
   int rv = syscall(__NR_futex,
                    addr, /* addr1 */
                    FUTEX_WAKE_BITSET | FUTEX_PRIVATE_FLAG, /* op */
                    count, /* val */
                    nullptr, /* timeout */
                    nullptr, /* addr2 */
                    wakeMask); /* val3 */

   /* NOTE: we ignore errors on wake for the case of a futex
      guarding its own destruction, similar to this
      glibc bug with sem_post/sem_wait:
      https://sourceware.org/bugzilla/show_bug.cgi?id=12674 */
   if (rv < 0) {
     return 0;
   }
   return rv;
 }

 template <class Clock>
 struct timespec
 timeSpecFromTimePoint(time_point<Clock> absTime)
 {
   auto epoch = absTime.time_since_epoch();
   if (epoch.count() < 0) {
     // kernel timespec_valid requires non-negative seconds and nanos in [0,1G)
     epoch = Clock::duration::zero();
   }

   // timespec-safe seconds and nanoseconds;
   // chrono::{nano,}seconds are `long long int`
   // whereas timespec uses smaller types
   using time_t_seconds = duration<std::time_t, seconds::period>;
   using long_nanos = duration<long int, nanoseconds::period>;

   auto secs = duration_cast<time_t_seconds>(epoch);
   auto nanos = duration_cast<long_nanos>(epoch - secs);
   struct timespec result = { secs.count(), nanos.count() };
   return result;
 }

 FutexResult nativeFutexWaitImpl(void* addr,
                                 uint32_t expected,
                                 time_point<system_clock>* absSystemTime,
                                 time_point<steady_clock>* absSteadyTime,
                                 uint32_t waitMask) {
   assert(absSystemTime == nullptr || absSteadyTime == nullptr);

   int op = FUTEX_WAIT_BITSET | FUTEX_PRIVATE_FLAG;
   struct timespec ts;
   struct timespec* timeout = nullptr;

   if (absSystemTime != nullptr) {
     op |= FUTEX_CLOCK_REALTIME;
     ts = timeSpecFromTimePoint(*absSystemTime);
     timeout = &ts;
   } else if (absSteadyTime != nullptr) {
     ts = timeSpecFromTimePoint(*absSteadyTime);
     timeout = &ts;
   }

   // Unlike FUTEX_WAIT, FUTEX_WAIT_BITSET requires an absolute timeout
   // value - http://locklessinc.com/articles/futex_cheat_sheet/
   int rv = syscall(__NR_futex,
                    addr, /* addr1 */
                    op, /* op */
                    expected, /* val */
                    timeout, /* timeout */
                    nullptr, /* addr2 */
                    waitMask); /* val3 */

   if (rv == 0) {
     return FutexResult::AWOKEN;
   } else {
     switch(errno) {
       case ETIMEDOUT:
         assert(timeout != nullptr);
         return FutexResult::TIMEDOUT;
       case EINTR:
         return FutexResult::INTERRUPTED;
       case EWOULDBLOCK:
         return FutexResult::VALUE_CHANGED;
       default:
         assert(false);
         // EINVAL, EACCESS, or EFAULT.  EINVAL means there was an invalid
         // op (should be impossible) or an invalid timeout (should have
         // been sanitized by timeSpecFromTimePoint).  EACCESS or EFAULT
         // means *addr points to invalid memory, which is unlikely because
         // the caller should have segfaulted already.  We can either
         // crash, or return a value that lets the process continue for
         // a bit. We choose the latter. VALUE_CHANGED probably turns the
         // caller into a spin lock.
         return FutexResult::VALUE_CHANGED;
     }
   }
 }

 #endif // __linux__

 ///////////////////////////////////////////////////////
 // compatibility implementation using standard C++ API

 // Our emulated futex uses 4096 lists of wait nodes.  There are two levels
 // of locking: a per-list mutex that controls access to the list and a
 // per-node mutex, condvar, and bool that are used for the actual wakeups.
 // The per-node mutex allows us to do precise wakeups without thundering
 // herds.

 struct EmulatedFutexWaitNode : public boost::intrusive::list_base_hook<> {
   void* const addr_;
   const uint32_t waitMask_;

   // tricky: hold both bucket and node mutex to write, either to read
   bool signaled_;
   std::mutex mutex_;
   std::condition_variable cond_;

   EmulatedFutexWaitNode(void* addr, uint32_t waitMask)
     : addr_(addr)
     , waitMask_(waitMask)
     , signaled_(false)
   {
   }
 };

 struct EmulatedFutexBucket {
   std::mutex mutex_;
   boost::intrusive::list<EmulatedFutexWaitNode> waiters_;

   static const size_t kNumBuckets = 4096;
   static EmulatedFutexBucket* gBuckets;
   static std::once_flag gBucketInit;

   static EmulatedFutexBucket& bucketFor(void* addr) {
     std::call_once(gBucketInit, [](){
       gBuckets = new EmulatedFutexBucket[kNumBuckets];
     });
     uint64_t mixedBits = folly::hash::twang_mix64(
         reinterpret_cast<uintptr_t>(addr));
     return gBuckets[mixedBits % kNumBuckets];
   }
 };

 EmulatedFutexBucket* EmulatedFutexBucket::gBuckets;
 std::once_flag EmulatedFutexBucket::gBucketInit;

 int emulatedFutexWake(void* addr, int count, uint32_t waitMask) {
   auto& bucket = EmulatedFutexBucket::bucketFor(addr);
   std::unique_lock<std::mutex> bucketLock(bucket.mutex_);

   int numAwoken = 0;
   for (auto iter = bucket.waiters_.begin();
        numAwoken < count && iter != bucket.waiters_.end(); ) {
     auto current = iter;
     auto& node = *iter++;
     if (node.addr_ == addr && (node.waitMask_ & waitMask) != 0) {
       ++numAwoken;

       // we unlink, but waiter destroys the node
       bucket.waiters_.erase(current);

       std::unique_lock<std::mutex> nodeLock(node.mutex_);
       node.signaled_ = true;
       node.cond_.notify_one();
     }
   }
   return numAwoken;
 }

 FutexResult emulatedFutexWaitImpl(
         void* addr,
         uint32_t expected,
         time_point<system_clock>* absSystemTime,
         time_point<steady_clock>* absSteadyTime,
         uint32_t waitMask) {
   auto& bucket = EmulatedFutexBucket::bucketFor(addr);
   EmulatedFutexWaitNode node(addr, waitMask);

   {
     std::unique_lock<std::mutex> bucketLock(bucket.mutex_);

     uint32_t actual;
     memcpy(&actual, addr, sizeof(uint32_t));
     if (actual != expected) {
       return FutexResult::VALUE_CHANGED;
     }

     bucket.waiters_.push_back(node);
   } // bucketLock scope

   std::cv_status status = std::cv_status::no_timeout;
   {
     std::unique_lock<std::mutex> nodeLock(node.mutex_);
     while (!node.signaled_ && status != std::cv_status::timeout) {
       if (absSystemTime != nullptr) {
         status = node.cond_.wait_until(nodeLock, *absSystemTime);
       } else if (absSteadyTime != nullptr) {
         status = node.cond_.wait_until(nodeLock, *absSteadyTime);
       } else {
         node.cond_.wait(nodeLock);
       }
     }
   } // nodeLock scope

   if (status == std::cv_status::timeout) {
     // it's not really a timeout until we unlink the unsignaled node
     std::unique_lock<std::mutex> bucketLock(bucket.mutex_);
     if (!node.signaled_) {
       bucket.waiters_.erase(bucket.waiters_.iterator_to(node));
       return FutexResult::TIMEDOUT;
     }
   }
   return FutexResult::AWOKEN;
 }

 } // anon namespace


 /////////////////////////////////
 // Futex<> specializations

 template <>
 int
 Futex<std::atomic>::futexWake(int count, uint32_t wakeMask) {
 #ifdef __linux__
   return nativeFutexWake(this, count, wakeMask);
 #else
   return emulatedFutexWake(this, count, wakeMask);
 #endif
 }

 template <>
 int
 Futex<EmulatedFutexAtomic>::futexWake(int count, uint32_t wakeMask) {
   return emulatedFutexWake(this, count, wakeMask);
 }

 template <>
 FutexResult
 Futex<std::atomic>::futexWaitImpl(uint32_t expected,
                                   time_point<system_clock>* absSystemTime,
                                   time_point<steady_clock>* absSteadyTime,
                                   uint32_t waitMask) {
 #ifdef __linux__
   return nativeFutexWaitImpl(
       this, expected, absSystemTime, absSteadyTime, waitMask);
 #else
   return emulatedFutexWaitImpl(
       this, expected, absSystemTime, absSteadyTime, waitMask);
 #endif
 }

 template <>
 FutexResult
 Futex<EmulatedFutexAtomic>::futexWaitImpl(
         uint32_t expected,
         time_point<system_clock>* absSystemTime,
         time_point<steady_clock>* absSteadyTime,
         uint32_t waitMask) {
   return emulatedFutexWaitImpl(
       this, expected, absSystemTime, absSteadyTime, waitMask);
 }

 }} // namespace folly::detail
	/*
	* Copyright 2015 Facebook, Inc.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include <folly/detail/Futex.h>
	#include <stdint.h>
	#include <string.h>
	#include <condition_variable>
	#include <mutex>
	#include <boost/intrusive/list.hpp>
	#include <folly/Hash.h>
	#include <folly/ScopeGuard.h>

	#ifdef __linux__
	# include <errno.h>
	# include <linux/futex.h>
	# include <sys/syscall.h>
	#endif

	using namespace std::chrono;

	namespace folly { namespace detail {

	namespace {

	////////////////////////////////////////////////////
	// native implementation using the futex() syscall

	#ifdef __linux__

	/// Certain toolchains (like Android's) don't include the full futex API in
	/// their headers even though they support it. Make sure we have our constants
	/// even if the headers don't have them.
	#ifndef FUTEX_WAIT_BITSET
	# define FUTEX_WAIT_BITSET 9
	#endif
	#ifndef FUTEX_WAKE_BITSET
	# define FUTEX_WAKE_BITSET 10
	#endif
	#ifndef FUTEX_PRIVATE_FLAG
	# define FUTEX_PRIVATE_FLAG 128
	#endif
	#ifndef FUTEX_CLOCK_REALTIME
	# define FUTEX_CLOCK_REALTIME 256
	#endif

	int nativeFutexWake(void* addr, int count, uint32_t wakeMask) {
	int rv = syscall(__NR_futex,
	addr, /* addr1 */
	FUTEX_WAKE_BITSET \| FUTEX_PRIVATE_FLAG, /* op */
	count, /* val */
	nullptr, /* timeout */
	nullptr, /* addr2 */
	wakeMask); /* val3 */

	/* NOTE: we ignore errors on wake for the case of a futex
	guarding its own destruction, similar to this
	glibc bug with sem_post/sem_wait:
	https://sourceware.org/bugzilla/show_bug.cgi?id=12674 */
	if (rv < 0) {
	return 0;
	}
	return rv;
	}

	template <class Clock>
	struct timespec
	timeSpecFromTimePoint(time_point<Clock> absTime)
	{
	auto epoch = absTime.time_since_epoch();
	if (epoch.count() < 0) {
	// kernel timespec_valid requires non-negative seconds and nanos in [0,1G)
	epoch = Clock::duration::zero();
	}

	// timespec-safe seconds and nanoseconds;
	// chrono::{nano,}seconds are `long long int`
	// whereas timespec uses smaller types
	using time_t_seconds = duration<std::time_t, seconds::period>;
	using long_nanos = duration<long int, nanoseconds::period>;

	auto secs = duration_cast<time_t_seconds>(epoch);
	auto nanos = duration_cast<long_nanos>(epoch - secs);
	struct timespec result = { secs.count(), nanos.count() };
	return result;
	}

	FutexResult nativeFutexWaitImpl(void* addr,
	uint32_t expected,
	time_point<system_clock>* absSystemTime,
	time_point<steady_clock>* absSteadyTime,
	uint32_t waitMask) {
	assert(absSystemTime == nullptr \|\| absSteadyTime == nullptr);

	int op = FUTEX_WAIT_BITSET \| FUTEX_PRIVATE_FLAG;
	struct timespec ts;
	struct timespec* timeout = nullptr;

	if (absSystemTime != nullptr) {
	op \|= FUTEX_CLOCK_REALTIME;
	ts = timeSpecFromTimePoint(*absSystemTime);
	timeout = &ts;
	} else if (absSteadyTime != nullptr) {
	ts = timeSpecFromTimePoint(*absSteadyTime);
	timeout = &ts;
	}

	// Unlike FUTEX_WAIT, FUTEX_WAIT_BITSET requires an absolute timeout
	// value - http://locklessinc.com/articles/futex_cheat_sheet/
	int rv = syscall(__NR_futex,
	addr, /* addr1 */
	op, /* op */
	expected, /* val */
	timeout, /* timeout */
	nullptr, /* addr2 */
	waitMask); /* val3 */

	if (rv == 0) {
	return FutexResult::AWOKEN;
	} else {
	switch(errno) {
	case ETIMEDOUT:
	assert(timeout != nullptr);
	return FutexResult::TIMEDOUT;
	case EINTR:
	return FutexResult::INTERRUPTED;
	case EWOULDBLOCK:
	return FutexResult::VALUE_CHANGED;
	default:
	assert(false);
	// EINVAL, EACCESS, or EFAULT. EINVAL means there was an invalid
	// op (should be impossible) or an invalid timeout (should have
	// been sanitized by timeSpecFromTimePoint). EACCESS or EFAULT
	// means *addr points to invalid memory, which is unlikely because
	// the caller should have segfaulted already. We can either
	// crash, or return a value that lets the process continue for
	// a bit. We choose the latter. VALUE_CHANGED probably turns the
	// caller into a spin lock.
	return FutexResult::VALUE_CHANGED;
	}
	}
	}

	#endif // __linux__

	///////////////////////////////////////////////////////
	// compatibility implementation using standard C++ API

	// Our emulated futex uses 4096 lists of wait nodes. There are two levels
	// of locking: a per-list mutex that controls access to the list and a
	// per-node mutex, condvar, and bool that are used for the actual wakeups.
	// The per-node mutex allows us to do precise wakeups without thundering
	// herds.

	struct EmulatedFutexWaitNode : public boost::intrusive::list_base_hook<> {
	void* const addr_;
	const uint32_t waitMask_;

	// tricky: hold both bucket and node mutex to write, either to read
	bool signaled_;
	std::mutex mutex_;
	std::condition_variable cond_;

	EmulatedFutexWaitNode(void* addr, uint32_t waitMask)
	: addr_(addr)
	, waitMask_(waitMask)
	, signaled_(false)
	{
	}
	};

	struct EmulatedFutexBucket {
	std::mutex mutex_;
	boost::intrusive::list<EmulatedFutexWaitNode> waiters_;

	static const size_t kNumBuckets = 4096;
	static EmulatedFutexBucket* gBuckets;
	static std::once_flag gBucketInit;

	static EmulatedFutexBucket& bucketFor(void* addr) {
	std::call_once(gBucketInit, [](){
	gBuckets = new EmulatedFutexBucket[kNumBuckets];
	});
	uint64_t mixedBits = folly::hash::twang_mix64(
	reinterpret_cast<uintptr_t>(addr));
	return gBuckets[mixedBits % kNumBuckets];
	}
	};

	EmulatedFutexBucket* EmulatedFutexBucket::gBuckets;
	std::once_flag EmulatedFutexBucket::gBucketInit;

	int emulatedFutexWake(void* addr, int count, uint32_t waitMask) {
	auto& bucket = EmulatedFutexBucket::bucketFor(addr);
	std::unique_lock<std::mutex> bucketLock(bucket.mutex_);

	int numAwoken = 0;
	for (auto iter = bucket.waiters_.begin();
	numAwoken < count && iter != bucket.waiters_.end(); ) {
	auto current = iter;
	auto& node = *iter++;
	if (node.addr_ == addr && (node.waitMask_ & waitMask) != 0) {
	++numAwoken;

	// we unlink, but waiter destroys the node
	bucket.waiters_.erase(current);

	std::unique_lock<std::mutex> nodeLock(node.mutex_);
	node.signaled_ = true;
	node.cond_.notify_one();
	}
	}
	return numAwoken;
	}

	FutexResult emulatedFutexWaitImpl(
	void* addr,
	uint32_t expected,
	time_point<system_clock>* absSystemTime,
	time_point<steady_clock>* absSteadyTime,
	uint32_t waitMask) {
	auto& bucket = EmulatedFutexBucket::bucketFor(addr);
	EmulatedFutexWaitNode node(addr, waitMask);

	{
	std::unique_lock<std::mutex> bucketLock(bucket.mutex_);

	uint32_t actual;
	memcpy(&actual, addr, sizeof(uint32_t));
	if (actual != expected) {
	return FutexResult::VALUE_CHANGED;
	}

	bucket.waiters_.push_back(node);
	} // bucketLock scope

	std::cv_status status = std::cv_status::no_timeout;
	{
	std::unique_lock<std::mutex> nodeLock(node.mutex_);
	while (!node.signaled_ && status != std::cv_status::timeout) {
	if (absSystemTime != nullptr) {
	status = node.cond_.wait_until(nodeLock, *absSystemTime);
	} else if (absSteadyTime != nullptr) {
	status = node.cond_.wait_until(nodeLock, *absSteadyTime);
	} else {
	node.cond_.wait(nodeLock);
	}
	}
	} // nodeLock scope

	if (status == std::cv_status::timeout) {
	// it's not really a timeout until we unlink the unsignaled node
	std::unique_lock<std::mutex> bucketLock(bucket.mutex_);
	if (!node.signaled_) {
	bucket.waiters_.erase(bucket.waiters_.iterator_to(node));
	return FutexResult::TIMEDOUT;
	}
	}
	return FutexResult::AWOKEN;
	}

	} // anon namespace


	/////////////////////////////////
	// Futex<> specializations

	template <>
	int
	Futex<std::atomic>::futexWake(int count, uint32_t wakeMask) {
	#ifdef __linux__
	return nativeFutexWake(this, count, wakeMask);
	#else
	return emulatedFutexWake(this, count, wakeMask);
	#endif
	}

	template <>
	int
	Futex<EmulatedFutexAtomic>::futexWake(int count, uint32_t wakeMask) {
	return emulatedFutexWake(this, count, wakeMask);
	}

	template <>
	FutexResult
	Futex<std::atomic>::futexWaitImpl(uint32_t expected,
	time_point<system_clock>* absSystemTime,
	time_point<steady_clock>* absSteadyTime,
	uint32_t waitMask) {
	#ifdef __linux__
	return nativeFutexWaitImpl(
	this, expected, absSystemTime, absSteadyTime, waitMask);
	#else
	return emulatedFutexWaitImpl(
	this, expected, absSystemTime, absSteadyTime, waitMask);
	#endif
	}

	template <>
	FutexResult
	Futex<EmulatedFutexAtomic>::futexWaitImpl(
	uint32_t expected,
	time_point<system_clock>* absSystemTime,
	time_point<steady_clock>* absSteadyTime,
	uint32_t waitMask) {
	return emulatedFutexWaitImpl(
	this, expected, absSystemTime, absSteadyTime, waitMask);
	}

	}} // namespace folly::detail