mirror of
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704 lines
24 KiB
C++
704 lines
24 KiB
C++
/*
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* Copyright 2016 Facebook, Inc.
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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// SingletonVault - a library to manage the creation and destruction
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// of interdependent singletons.
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//
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// Basic usage of this class is very simple; suppose you have a class
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// called MyExpensiveService, and you only want to construct one (ie,
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// it's a singleton), but you only want to construct it if it is used.
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//
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// In your .h file:
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// class MyExpensiveService { ... };
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//
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// In your .cpp file:
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// namespace { folly::Singleton<MyExpensiveService> the_singleton; }
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//
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// Code can access it via:
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//
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// MyExpensiveService* instance = Singleton<MyExpensiveService>::get();
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// or
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// std::weak_ptr<MyExpensiveService> instance =
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// Singleton<MyExpensiveService>::get_weak();
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//
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// You also can directly access it by the variable defining the
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// singleton rather than via get(), and even treat that variable like
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// a smart pointer (dereferencing it or using the -> operator).
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//
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// Please note, however, that all non-weak_ptr interfaces are
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// inherently subject to races with destruction. Use responsibly.
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//
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// The singleton will be created on demand. If the constructor for
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// MyExpensiveService actually makes use of *another* Singleton, then
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// the right thing will happen -- that other singleton will complete
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// construction before get() returns. However, in the event of a
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// circular dependency, a runtime error will occur.
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//
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// You can have multiple singletons of the same underlying type, but
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// each must be given a unique tag. If no tag is specified - default tag is used
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//
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// namespace {
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// struct Tag1 {};
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// struct Tag2 {};
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// folly::Singleton<MyExpensiveService> s_default;
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// folly::Singleton<MyExpensiveService, Tag1> s1;
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// folly::Singleton<MyExpensiveService, Tag2> s2;
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// }
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// ...
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// MyExpensiveService* svc_default = s_default.get();
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// MyExpensiveService* svc1 = s1.get();
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// MyExpensiveService* svc2 = s2.get();
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//
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// By default, the singleton instance is constructed via new and
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// deleted via delete, but this is configurable:
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//
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// namespace { folly::Singleton<MyExpensiveService> the_singleton(create,
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// destroy); }
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//
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// Where create and destroy are functions, Singleton<T>::CreateFunc
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// Singleton<T>::TeardownFunc.
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//
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// For example, if you need to pass arguments to your class's constructor:
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// class X {
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// public:
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// X(int a1, std::string a2);
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// // ...
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// }
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// Make your singleton like this:
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// folly::Singleton<X> singleton_x([]() { return new X(42, "foo"); });
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//
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// The above examples detail a situation where an expensive singleton is loaded
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// on-demand (thus only if needed). However if there is an expensive singleton
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// that will likely be needed, and initialization takes a potentially long time,
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// e.g. while initializing, parsing some files, talking to remote services,
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// making uses of other singletons, and so on, the initialization of those can
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// be scheduled up front, or "eagerly".
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//
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// In that case the singleton can be declared this way:
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//
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// namespace {
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// auto the_singleton =
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// folly::Singleton<MyExpensiveService>(/* optional create, destroy args */)
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// .shouldEagerInit();
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// }
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//
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// This way the singleton's instance is built at program initialization,
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// if the program opted-in to that feature by calling "doEagerInit" or
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// "doEagerInitVia" during its startup.
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//
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// What if you need to destroy all of your singletons? Say, some of
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// your singletons manage threads, but you need to fork? Or your unit
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// test wants to clean up all global state? Then you can call
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// SingletonVault::singleton()->destroyInstances(), which invokes the
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// TeardownFunc for each singleton, in the reverse order they were
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// created. It is your responsibility to ensure your singletons can
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// handle cases where the singletons they depend on go away, however.
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// Singletons won't be recreated after destroyInstances call. If you
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// want to re-enable singleton creation (say after fork was called) you
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// should call reenableInstances.
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#pragma once
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#include <folly/Baton.h>
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#include <folly/Exception.h>
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#include <folly/Hash.h>
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#include <folly/Memory.h>
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#include <folly/RWSpinLock.h>
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#include <folly/Demangle.h>
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#include <folly/Executor.h>
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#include <folly/experimental/ReadMostlySharedPtr.h>
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#include <folly/detail/StaticSingletonManager.h>
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#include <algorithm>
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#include <atomic>
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#include <condition_variable>
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#include <functional>
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#include <memory>
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#include <mutex>
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#include <string>
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#include <thread>
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#include <typeindex>
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#include <typeinfo>
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#include <unordered_map>
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#include <unordered_set>
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#include <vector>
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#include <glog/logging.h>
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// use this guard to handleSingleton breaking change in 3rd party code
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#ifndef FOLLY_SINGLETON_TRY_GET
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#define FOLLY_SINGLETON_TRY_GET
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#endif
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namespace folly {
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// For actual usage, please see the Singleton<T> class at the bottom
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// of this file; that is what you will actually interact with.
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// SingletonVault is the class that manages singleton instances. It
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// is unaware of the underlying types of singletons, and simply
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// manages lifecycles and invokes CreateFunc and TeardownFunc when
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// appropriate. In general, you won't need to interact with the
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// SingletonVault itself.
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//
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// A vault goes through a few stages of life:
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//
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// 1. Registration phase; singletons can be registered:
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// a) Strict: no singleton can be created in this stage.
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// b) Relaxed: singleton can be created (the default vault is Relaxed).
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// 2. registrationComplete() has been called; singletons can no
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// longer be registered, but they can be created.
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// 3. A vault can return to stage 1 when destroyInstances is called.
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//
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// In general, you don't need to worry about any of the above; just
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// ensure registrationComplete() is called near the top of your main()
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// function, otherwise no singletons can be instantiated.
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class SingletonVault;
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namespace detail {
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struct DefaultTag {};
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// A TypeDescriptor is the unique handle for a given singleton. It is
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// a combinaiton of the type and of the optional name, and is used as
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// a key in unordered_maps.
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class TypeDescriptor {
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public:
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TypeDescriptor(const std::type_info& ti,
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const std::type_info& tag_ti)
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: ti_(ti), tag_ti_(tag_ti) {
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}
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TypeDescriptor(const TypeDescriptor& other)
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: ti_(other.ti_), tag_ti_(other.tag_ti_) {
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}
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TypeDescriptor& operator=(const TypeDescriptor& other) {
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if (this != &other) {
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ti_ = other.ti_;
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tag_ti_ = other.tag_ti_;
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}
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return *this;
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}
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std::string name() const {
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auto ret = demangle(ti_.name());
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if (tag_ti_ != std::type_index(typeid(DefaultTag))) {
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ret += "/";
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ret += demangle(tag_ti_.name());
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}
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return ret.toStdString();
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}
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friend class TypeDescriptorHasher;
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bool operator==(const TypeDescriptor& other) const {
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return ti_ == other.ti_ && tag_ti_ == other.tag_ti_;
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}
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private:
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std::type_index ti_;
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std::type_index tag_ti_;
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};
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class TypeDescriptorHasher {
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public:
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size_t operator()(const TypeDescriptor& ti) const {
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return folly::hash::hash_combine(ti.ti_, ti.tag_ti_);
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}
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};
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// This interface is used by SingletonVault to interact with SingletonHolders.
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// Having a non-template interface allows SingletonVault to keep a list of all
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// SingletonHolders.
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class SingletonHolderBase {
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public:
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explicit SingletonHolderBase(TypeDescriptor typeDesc) : type_(typeDesc) {}
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virtual ~SingletonHolderBase() = default;
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TypeDescriptor type() const {
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return type_;
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}
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virtual bool hasLiveInstance() = 0;
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virtual void createInstance() = 0;
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virtual bool creationStarted() = 0;
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virtual void preDestroyInstance(ReadMostlyMainPtrDeleter<>&) = 0;
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virtual void destroyInstance() = 0;
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private:
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TypeDescriptor type_;
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};
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// An actual instance of a singleton, tracking the instance itself,
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// its state as described above, and the create and teardown
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// functions.
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template <typename T>
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struct SingletonHolder : public SingletonHolderBase {
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public:
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typedef std::function<void(T*)> TeardownFunc;
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typedef std::function<T*(void)> CreateFunc;
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template <typename Tag, typename VaultTag>
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inline static SingletonHolder<T>& singleton();
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inline T* get();
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inline std::weak_ptr<T> get_weak();
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inline std::shared_ptr<T> try_get();
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inline folly::ReadMostlySharedPtr<T> try_get_fast();
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void registerSingleton(CreateFunc c, TeardownFunc t);
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void registerSingletonMock(CreateFunc c, TeardownFunc t);
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virtual bool hasLiveInstance() override;
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virtual void createInstance() override;
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virtual bool creationStarted() override;
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virtual void preDestroyInstance(ReadMostlyMainPtrDeleter<>&) override;
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virtual void destroyInstance() override;
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private:
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SingletonHolder(TypeDescriptor type, SingletonVault& vault);
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enum class SingletonHolderState {
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NotRegistered,
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Dead,
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Living,
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};
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SingletonVault& vault_;
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// mutex protects the entire entry during construction/destruction
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std::mutex mutex_;
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// State of the singleton entry. If state is Living, instance_ptr and
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// instance_weak can be safely accessed w/o synchronization.
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std::atomic<SingletonHolderState> state_{SingletonHolderState::NotRegistered};
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// the thread creating the singleton (only valid while creating an object)
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std::atomic<std::thread::id> creating_thread_;
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// The singleton itself and related functions.
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// holds a ReadMostlyMainPtr to singleton instance, set when state is changed
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// from Dead to Living. Reset when state is changed from Living to Dead.
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folly::ReadMostlyMainPtr<T> instance_;
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// used to release all ReadMostlyMainPtrs at once
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folly::ReadMostlySharedPtr<T> instance_copy_;
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// weak_ptr to the singleton instance, set when state is changed from Dead
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// to Living. We never write to this object after initialization, so it is
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// safe to read it from different threads w/o synchronization if we know
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// that state is set to Living
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std::weak_ptr<T> instance_weak_;
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// Fast equivalent of instance_weak_
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folly::ReadMostlyWeakPtr<T> instance_weak_fast_;
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// Time we wait on destroy_baton after releasing Singleton shared_ptr.
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std::shared_ptr<folly::Baton<>> destroy_baton_;
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T* instance_ptr_ = nullptr;
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CreateFunc create_ = nullptr;
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TeardownFunc teardown_ = nullptr;
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std::shared_ptr<std::atomic<bool>> print_destructor_stack_trace_;
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SingletonHolder(const SingletonHolder&) = delete;
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SingletonHolder& operator=(const SingletonHolder&) = delete;
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SingletonHolder& operator=(SingletonHolder&&) = delete;
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SingletonHolder(SingletonHolder&&) = delete;
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};
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}
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class SingletonVault {
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public:
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enum class Type {
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Strict, // Singletons can't be created before registrationComplete()
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Relaxed, // Singletons can be created before registrationComplete()
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};
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/**
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* Clears all singletons in the given vault at ctor and dtor times.
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* Useful for unit-tests that need to clear the world.
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*
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* This need can arise when a unit-test needs to swap out an object used by a
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* singleton for a test-double, but the singleton needing its dependency to be
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* swapped has a type or a tag local to some other translation unit and
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* unavailable in the current translation unit.
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*
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* Other, better approaches to this need are "plz 2 refactor" ....
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*/
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struct ScopedExpunger {
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SingletonVault* vault;
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explicit ScopedExpunger(SingletonVault* v) : vault(v) { expunge(); }
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~ScopedExpunger() { expunge(); }
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void expunge() {
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vault->destroyInstances();
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vault->reenableInstances();
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}
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};
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explicit SingletonVault(Type type = Type::Relaxed) : type_(type) {}
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// Destructor is only called by unit tests to check destroyInstances.
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~SingletonVault();
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typedef std::function<void(void*)> TeardownFunc;
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typedef std::function<void*(void)> CreateFunc;
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// Ensure that Singleton has not been registered previously and that
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// registration is not complete. If validations succeeds,
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// register a singleton of a given type with the create and teardown
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// functions.
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void registerSingleton(detail::SingletonHolderBase* entry);
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/**
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* Called by `Singleton<T>.shouldEagerInit()` to ensure the instance
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* is built when `doEagerInit[Via]` is called; see those methods
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* for more info.
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*/
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void addEagerInitSingleton(detail::SingletonHolderBase* entry);
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// Mark registration is complete; no more singletons can be
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// registered at this point.
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void registrationComplete();
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/**
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* Initialize all singletons which were marked as eager-initialized
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* (using `shouldEagerInit()`). No return value. Propagates exceptions
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* from constructors / create functions, as is the usual case when calling
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* for example `Singleton<Foo>::get_weak()`.
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*/
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void doEagerInit();
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/**
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* Schedule eager singletons' initializations through the given executor.
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* If baton ptr is not null, its `post` method is called after all
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* early initialization has completed.
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*
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* If exceptions are thrown during initialization, this method will still
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* `post` the baton to indicate completion. The exception will not propagate
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* and future attempts to `try_get` or `get_weak` the failed singleton will
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* retry initialization.
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*
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* Sample usage:
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*
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* wangle::IOThreadPoolExecutor executor(max_concurrency_level);
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* folly::Baton<> done;
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* doEagerInitVia(executor, &done);
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* done.wait(); // or 'timed_wait', or spin with 'try_wait'
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*
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*/
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void doEagerInitVia(Executor& exe, folly::Baton<>* done = nullptr);
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// Destroy all singletons; when complete, the vault can't create
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// singletons once again until reenableInstances() is called.
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void destroyInstances();
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// Enable re-creating singletons after destroyInstances() was called.
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void reenableInstances();
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// For testing; how many registered and living singletons we have.
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size_t registeredSingletonCount() const {
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RWSpinLock::ReadHolder rh(&mutex_);
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return singletons_.size();
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}
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/**
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* Flips to true if eager initialization was used, and has completed.
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* Never set to true if "doEagerInit()" or "doEagerInitVia" never called.
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*/
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bool eagerInitComplete() const;
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size_t livingSingletonCount() const {
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RWSpinLock::ReadHolder rh(&mutex_);
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size_t ret = 0;
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for (const auto& p : singletons_) {
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if (p.second->hasLiveInstance()) {
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++ret;
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}
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}
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return ret;
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}
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// A well-known vault; you can actually have others, but this is the
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// default.
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static SingletonVault* singleton() {
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return singleton<>();
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}
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// Gets singleton vault for any Tag. Non-default tag should be used in unit
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// tests only.
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template <typename VaultTag = detail::DefaultTag>
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static SingletonVault* singleton() {
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/* library-local */ static auto vault =
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detail::createGlobal<SingletonVault, VaultTag>();
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return vault;
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}
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typedef std::string(*StackTraceGetterPtr)();
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static std::atomic<StackTraceGetterPtr>& stackTraceGetter() {
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/* library-local */ static auto stackTraceGetterPtr = detail::
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createGlobal<std::atomic<StackTraceGetterPtr>, SingletonVault>();
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return *stackTraceGetterPtr;
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}
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void setType(Type type) {
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type_ = type;
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}
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private:
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template <typename T>
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friend struct detail::SingletonHolder;
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// The two stages of life for a vault, as mentioned in the class comment.
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enum class SingletonVaultState {
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Running,
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Quiescing,
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};
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// Each singleton in the vault can be in two states: dead
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// (registered but never created), living (CreateFunc returned an instance).
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void stateCheck(SingletonVaultState expected,
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const char* msg="Unexpected singleton state change") {
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if (expected != state_) {
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throw std::logic_error(msg);
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}
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}
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// This method only matters if registrationComplete() is never called.
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// Otherwise destroyInstances is scheduled to be executed atexit.
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//
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// Initializes static object, which calls destroyInstances on destruction.
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// Used to have better deletion ordering with singleton not managed by
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// folly::Singleton. The desruction will happen in the following order:
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// 1. Singletons, not managed by folly::Singleton, which were created after
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// any of the singletons managed by folly::Singleton was requested.
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// 2. All singletons managed by folly::Singleton
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// 3. Singletons, not managed by folly::Singleton, which were created before
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// any of the singletons managed by folly::Singleton was requested.
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static void scheduleDestroyInstances();
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typedef std::unordered_map<detail::TypeDescriptor,
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detail::SingletonHolderBase*,
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detail::TypeDescriptorHasher> SingletonMap;
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mutable folly::RWSpinLock mutex_;
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SingletonMap singletons_;
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std::unordered_set<detail::SingletonHolderBase*> eagerInitSingletons_;
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std::vector<detail::TypeDescriptor> creation_order_;
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SingletonVaultState state_{SingletonVaultState::Running};
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bool registrationComplete_{false};
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folly::RWSpinLock stateMutex_;
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Type type_{Type::Relaxed};
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};
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// This is the wrapper class that most users actually interact with.
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// It allows for simple access to registering and instantiating
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// singletons. Create instances of this class in the global scope of
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// type Singleton<T> to register your singleton for later access via
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// Singleton<T>::try_get().
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template <typename T,
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typename Tag = detail::DefaultTag,
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typename VaultTag = detail::DefaultTag /* for testing */>
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class Singleton {
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public:
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typedef std::function<T*(void)> CreateFunc;
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typedef std::function<void(T*)> TeardownFunc;
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// Generally your program life cycle should be fine with calling
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// get() repeatedly rather than saving the reference, and then not
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// call get() during process shutdown.
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FOLLY_DEPRECATED("Replaced by try_get")
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static T* get() { return getEntry().get(); }
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// If, however, you do need to hold a reference to the specific
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// singleton, you can try to do so with a weak_ptr. Avoid this when
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// possible but the inability to lock the weak pointer can be a
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// signal that the vault has been destroyed.
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FOLLY_DEPRECATED("Replaced by try_get")
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static std::weak_ptr<T> get_weak() { return getEntry().get_weak(); }
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// Preferred alternative to get_weak, it returns shared_ptr that can be
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// stored; a singleton won't be destroyed unless shared_ptr is destroyed.
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// Avoid holding these shared_ptrs beyond the scope of a function;
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// don't put them in member variables, always use try_get() instead
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//
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// try_get() can return nullptr if the singleton was destroyed, caller is
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// responsible for handling nullptr return
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static std::shared_ptr<T> try_get() {
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return getEntry().try_get();
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}
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static folly::ReadMostlySharedPtr<T> try_get_fast() {
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return getEntry().try_get_fast();
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}
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explicit Singleton(std::nullptr_t /* _ */ = nullptr,
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typename Singleton::TeardownFunc t = nullptr)
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: Singleton([]() { return new T; }, std::move(t)) {}
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|
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explicit Singleton(typename Singleton::CreateFunc c,
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typename Singleton::TeardownFunc t = nullptr) {
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if (c == nullptr) {
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throw std::logic_error(
|
|
"nullptr_t should be passed if you want T to be default constructed");
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|
}
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|
|
|
auto vault = SingletonVault::singleton<VaultTag>();
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getEntry().registerSingleton(std::move(c), getTeardownFunc(std::move(t)));
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|
vault->registerSingleton(&getEntry());
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|
}
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/**
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* Should be instantiated as soon as "doEagerInit[Via]" is called.
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|
* Singletons are usually lazy-loaded (built on-demand) but for those which
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|
* are known to be needed, to avoid the potential lag for objects that take
|
|
* long to construct during runtime, there is an option to make sure these
|
|
* are built up-front.
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|
*
|
|
* Use like:
|
|
* Singleton<Foo> gFooInstance = Singleton<Foo>(...).shouldEagerInit();
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|
*
|
|
* Or alternately, define the singleton as usual, and say
|
|
* gFooInstance.shouldEagerInit();
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|
*
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|
* at some point prior to calling registrationComplete().
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|
* Then doEagerInit() or doEagerInitVia(Executor*) can be called.
|
|
*/
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|
Singleton& shouldEagerInit() {
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|
auto vault = SingletonVault::singleton<VaultTag>();
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|
vault->addEagerInitSingleton(&getEntry());
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|
return *this;
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|
}
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|
|
|
/**
|
|
* Construct and inject a mock singleton which should be used only from tests.
|
|
* Unlike regular singletons which are initialized once per process lifetime,
|
|
* mock singletons live for the duration of a test. This means that one process
|
|
* running multiple tests can initialize and register the same singleton
|
|
* multiple times. This functionality should be used only from tests
|
|
* since it relaxes validation and performance in order to be able to perform
|
|
* the injection. The returned mock singleton is functionality identical to
|
|
* regular singletons.
|
|
*/
|
|
static void make_mock(std::nullptr_t /* c */ = nullptr,
|
|
typename Singleton<T>::TeardownFunc t = nullptr) {
|
|
make_mock([]() { return new T; }, t);
|
|
}
|
|
|
|
static void make_mock(CreateFunc c,
|
|
typename Singleton<T>::TeardownFunc t = nullptr) {
|
|
if (c == nullptr) {
|
|
throw std::logic_error(
|
|
"nullptr_t should be passed if you want T to be default constructed");
|
|
}
|
|
|
|
auto& entry = getEntry();
|
|
|
|
entry.registerSingletonMock(c, getTeardownFunc(t));
|
|
}
|
|
|
|
private:
|
|
inline static detail::SingletonHolder<T>& getEntry() {
|
|
return detail::SingletonHolder<T>::template singleton<Tag, VaultTag>();
|
|
}
|
|
|
|
// Construct TeardownFunc.
|
|
static typename detail::SingletonHolder<T>::TeardownFunc getTeardownFunc(
|
|
TeardownFunc t) {
|
|
if (t == nullptr) {
|
|
return [](T* v) { delete v; };
|
|
} else {
|
|
return t;
|
|
}
|
|
}
|
|
};
|
|
|
|
template <typename T, typename Tag = detail::DefaultTag>
|
|
class LeakySingleton {
|
|
public:
|
|
using CreateFunc = std::function<T*()>;
|
|
|
|
LeakySingleton() : LeakySingleton([] { return new T(); }) {}
|
|
|
|
explicit LeakySingleton(CreateFunc createFunc) {
|
|
auto& entry = entryInstance();
|
|
if (entry.state != State::NotRegistered) {
|
|
LOG(FATAL) << "Double registration of singletons of the same "
|
|
<< "underlying type; check for multiple definitions "
|
|
<< "of type folly::LeakySingleton<" + entry.type_.name() + ">";
|
|
}
|
|
entry.createFunc = createFunc;
|
|
entry.state = State::Dead;
|
|
}
|
|
|
|
static T& get() { return instance(); }
|
|
|
|
private:
|
|
enum class State { NotRegistered, Dead, Living };
|
|
|
|
struct Entry {
|
|
Entry() {}
|
|
Entry(const Entry&) = delete;
|
|
Entry& operator=(const Entry&) = delete;
|
|
|
|
std::atomic<State> state{State::NotRegistered};
|
|
T* ptr{nullptr};
|
|
CreateFunc createFunc;
|
|
std::mutex mutex;
|
|
detail::TypeDescriptor type_{typeid(T), typeid(Tag)};
|
|
};
|
|
|
|
static Entry& entryInstance() {
|
|
/* library-local */ static auto entry = detail::createGlobal<Entry, Tag>();
|
|
return *entry;
|
|
}
|
|
|
|
static T& instance() {
|
|
auto& entry = entryInstance();
|
|
if (UNLIKELY(entry.state != State::Living)) {
|
|
createInstance();
|
|
}
|
|
|
|
return *entry.ptr;
|
|
}
|
|
|
|
static void createInstance() {
|
|
auto& entry = entryInstance();
|
|
|
|
std::lock_guard<std::mutex> lg(entry.mutex);
|
|
if (entry.state == State::Living) {
|
|
return;
|
|
}
|
|
|
|
if (entry.state == State::NotRegistered) {
|
|
auto ptr = SingletonVault::stackTraceGetter().load();
|
|
LOG(FATAL) << "Creating instance for unregistered singleton: "
|
|
<< entry.type_.name() << "\n"
|
|
<< "Stacktrace:"
|
|
<< "\n" << (ptr ? (*ptr)() : "(not available)");
|
|
}
|
|
|
|
entry.ptr = entry.createFunc();
|
|
entry.state = State::Living;
|
|
}
|
|
};
|
|
}
|
|
|
|
#include <folly/Singleton-inl.h>
|