1 files changed, 249 insertions, 0 deletions

diff --git a/third_party/abseil_cpp/absl/synchronization/internal/mutex_nonprod.inc b/third_party/abseil_cpp/absl/synchronization/internal/mutex_nonprod.inc
new file mode 100644
index 000000000000..d83bc8a94c75
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+++ b/third_party/abseil_cpp/absl/synchronization/internal/mutex_nonprod.inc
@@ -0,0 +1,249 @@
+// Do not include.  This is an implementation detail of base/mutex.h.
+//
+// Declares three classes:
+//
+// base::internal::MutexImpl - implementation helper for Mutex
+// base::internal::CondVarImpl - implementation helper for CondVar
+// base::internal::SynchronizationStorage<T> - implementation helper for
+//                                             Mutex, CondVar
+
+#include <type_traits>
+
+#if defined(_WIN32)
+#include <condition_variable>
+#include <mutex>
+#else
+#include <pthread.h>
+#endif
+
+#include "absl/base/call_once.h"
+#include "absl/time/time.h"
+
+// Declare that Mutex::ReaderLock is actually Lock().  Intended primarily
+// for tests, and even then as a last resort.
+#ifdef ABSL_MUTEX_READER_LOCK_IS_EXCLUSIVE
+#error ABSL_MUTEX_READER_LOCK_IS_EXCLUSIVE cannot be directly set
+#else
+#define ABSL_MUTEX_READER_LOCK_IS_EXCLUSIVE 1
+#endif
+
+// Declare that Mutex::EnableInvariantDebugging is not implemented.
+// Intended primarily for tests, and even then as a last resort.
+#ifdef ABSL_MUTEX_ENABLE_INVARIANT_DEBUGGING_NOT_IMPLEMENTED
+#error ABSL_MUTEX_ENABLE_INVARIANT_DEBUGGING_NOT_IMPLEMENTED cannot be directly set
+#else
+#define ABSL_MUTEX_ENABLE_INVARIANT_DEBUGGING_NOT_IMPLEMENTED 1
+#endif
+
+namespace absl {
+ABSL_NAMESPACE_BEGIN
+class Condition;
+
+namespace synchronization_internal {
+
+class MutexImpl;
+
+// Do not use this implementation detail of CondVar. Provides most of the
+// implementation, but should not be placed directly in static storage
+// because it will not linker initialize properly. See
+// SynchronizationStorage<T> below for what we mean by linker
+// initialization.
+class CondVarImpl {
+ public:
+  CondVarImpl();
+  CondVarImpl(const CondVarImpl&) = delete;
+  CondVarImpl& operator=(const CondVarImpl&) = delete;
+  ~CondVarImpl();
+
+  void Signal();
+  void SignalAll();
+  void Wait(MutexImpl* mutex);
+  bool WaitWithDeadline(MutexImpl* mutex, absl::Time deadline);
+
+ private:
+#if defined(_WIN32)
+  std::condition_variable_any std_cv_;
+#else
+  pthread_cond_t pthread_cv_;
+#endif
+};
+
+// Do not use this implementation detail of Mutex. Provides most of the
+// implementation, but should not be placed directly in static storage
+// because it will not linker initialize properly. See
+// SynchronizationStorage<T> below for what we mean by linker
+// initialization.
+class MutexImpl {
+ public:
+  MutexImpl();
+  MutexImpl(const MutexImpl&) = delete;
+  MutexImpl& operator=(const MutexImpl&) = delete;
+  ~MutexImpl();
+
+  void Lock();
+  bool TryLock();
+  void Unlock();
+  void Await(const Condition& cond);
+  bool AwaitWithDeadline(const Condition& cond, absl::Time deadline);
+
+ private:
+  friend class CondVarImpl;
+
+#if defined(_WIN32)
+  std::mutex std_mutex_;
+#else
+  pthread_mutex_t pthread_mutex_;
+#endif
+
+  // True if the underlying mutex is locked.  If the destructor is entered
+  // while locked_, the underlying mutex is unlocked.  Mutex supports
+  // destruction while locked, but the same is undefined behavior for both
+  // pthread_mutex_t and std::mutex.
+  bool locked_ = false;
+
+  // Signaled before releasing the lock, in support of Await.
+  CondVarImpl released_;
+};
+
+// Do not use this implementation detail of CondVar and Mutex.  A storage
+// space for T that supports a LinkerInitialized constructor. T must
+// have a default constructor, which is called by the first call to
+// get(). T's destructor is never called if the LinkerInitialized
+// constructor is called.
+//
+// Objects constructed with the default constructor are constructed and
+// destructed like any other object, and should never be allocated in
+// static storage.
+//
+// Objects constructed with the LinkerInitialized constructor should
+// always be in static storage. For such objects, calls to get() are always
+// valid, except from signal handlers.
+//
+// Note that this implementation relies on undefined language behavior that
+// are known to hold for the set of supported compilers. An analysis
+// follows.
+//
+// From the C++11 standard:
+//
+// [basic.life] says an object has non-trivial initialization if it is of
+// class type and it is initialized by a constructor other than a trivial
+// default constructor.  (the LinkerInitialized constructor is
+// non-trivial)
+//
+// [basic.life] says the lifetime of an object with a non-trivial
+// constructor begins when the call to the constructor is complete.
+//
+// [basic.life] says the lifetime of an object with non-trivial destructor
+// ends when the call to the destructor begins.
+//
+// [basic.life] p5 specifies undefined behavior when accessing non-static
+// members of an instance outside its
+// lifetime. (SynchronizationStorage::get() access non-static members)
+//
+// So, LinkerInitialized object of SynchronizationStorage uses a
+// non-trivial constructor, which is called at some point during dynamic
+// initialization, and is therefore subject to order of dynamic
+// initialization bugs, where get() is called before the object's
+// constructor is, resulting in undefined behavior.
+//
+// Similarly, a LinkerInitialized SynchronizationStorage object has a
+// non-trivial destructor, and so its lifetime ends at some point during
+// destruction of objects with static storage duration [basic.start.term]
+// p4. There is a window where other exit code could call get() after this
+// occurs, resulting in undefined behavior.
+//
+// Combined, these statements imply that LinkerInitialized instances
+// of SynchronizationStorage<T> rely on undefined behavior.
+//
+// However, in practice, the implementation works on all supported
+// compilers. Specifically, we rely on:
+//
+// a) zero-initialization being sufficient to initialize
+// LinkerInitialized instances for the purposes of calling
+// get(), regardless of when the constructor is called. This is
+// because the is_dynamic_ boolean is correctly zero-initialized to
+// false.
+//
+// b) the LinkerInitialized constructor is a NOP, and immaterial to
+// even to concurrent calls to get().
+//
+// c) the destructor being a NOP for LinkerInitialized objects
+// (guaranteed by a check for !is_dynamic_), and so any concurrent and
+// subsequent calls to get() functioning as if the destructor were not
+// called, by virtue of the instances' storage remaining valid after the
+// destructor runs.
+//
+// d) That a-c apply transitively when SynchronizationStorage<T> is the
+// only member of a class allocated in static storage.
+//
+// Nothing in the language standard guarantees that a-d hold.  In practice,
+// these hold in all supported compilers.
+//
+// Future direction:
+//
+// Ideally, we would simply use std::mutex or a similar class, which when
+// allocated statically would support use immediately after static
+// initialization up until static storage is reclaimed (i.e. the properties
+// we require of all "linker initialized" instances).
+//
+// Regarding construction in static storage, std::mutex is required to
+// provide a constexpr default constructor [thread.mutex.class], which
+// ensures the instance's lifetime begins with static initialization
+// [basic.start.init], and so is immune to any problems caused by the order
+// of dynamic initialization. However, as of this writing Microsoft's
+// Visual Studio does not provide a constexpr constructor for std::mutex.
+// See
+// https://blogs.msdn.microsoft.com/vcblog/2015/06/02/constexpr-complete-for-vs-2015-rtm-c11-compiler-c17-stl/
+//
+// Regarding destruction of instances in static storage, [basic.life] does
+// say an object ends when storage in which the occupies is released, in
+// the case of non-trivial destructor. However, std::mutex is not specified
+// to have a trivial destructor.
+//
+// So, we would need a class with a constexpr default constructor and a
+// trivial destructor. Today, we can achieve neither desired property using
+// std::mutex directly.
+template <typename T>
+class SynchronizationStorage {
+ public:
+  // Instances allocated on the heap or on the stack should use the default
+  // constructor.
+  SynchronizationStorage()
+      : destruct_(true), once_() {}
+
+  constexpr explicit SynchronizationStorage(absl::ConstInitType)
+      : destruct_(false), once_(), space_{{0}} {}
+
+  SynchronizationStorage(SynchronizationStorage&) = delete;
+  SynchronizationStorage& operator=(SynchronizationStorage&) = delete;
+
+  ~SynchronizationStorage() {
+    if (destruct_) {
+      get()->~T();
+    }
+  }
+
+  // Retrieve the object in storage. This is fast and thread safe, but does
+  // incur the cost of absl::call_once().
+  T* get() {
+    absl::call_once(once_, SynchronizationStorage::Construct, this);
+    return reinterpret_cast<T*>(&space_);
+  }
+
+ private:
+  static void Construct(SynchronizationStorage<T>* self) {
+    new (&self->space_) T();
+  }
+
+  // When true, T's destructor is run when this is destructed.
+  const bool destruct_;
+
+  absl::once_flag once_;
+
+  // An aligned space for the T.
+  alignas(T) unsigned char space_[sizeof(T)];
+};
+
+}  // namespace synchronization_internal
+ABSL_NAMESPACE_END
+}  // namespace absl