chromecast/base/component/component.h - chromium/src - Git at Google

 // Copyright 2016 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // A component is a large, long-lived set of functionality that may be enabled
 // or disabled at runtime. Some examples include: the multizone features,
 // MetricsRecorder, or OpencastController. Components may depend on each other
 // (ie, a component may call the public methods of other components); the
 // Component infrastructure ensures that when a component is disabled, nothing
 // that depends on it will call any of its methods until it is enabled again.
 //
 // Components may be used without a dependency relationship via a weak
 // reference. A weak reference does not allow direct access to the component;
 // instead, it must be either used to create a strict dependency (see below), or
 // be converted to a scoped reference via Try(). Scoped references must be
 // checked for validity before use (they are convertible to bool); an invalid
 // scoped reference must not be used. Scoped references should be short-lived;
 // to encourage this, they are only move-constructible and cannot be copied or
 // assigned.
 //
 // If component Y depends on Component X, then Y has a Dependency reference
 // to X. This causes Y to be disabled as X is being disabled (before X's
 // OnDisable() method is called). Similarly, this dependency will cause X to be
 // enabled when Y is being enabled (X will be enabled before Y's OnEnable()
 // method is called). A component may freely access any of its dependencies
 // as long as it is enabled. When a component is disabled, it must ensure that
 // none of its dependencies will be used again until it is enabled. It is
 // recommended to set up dependencies in your component's constructor; it is an
 // error to add a dependency to a component that is not disabled.
 //
 // When a component is disabled, it will first recursively disable any other
 // components that depend on it. It will also disable the creation of
 // new scoped references. It then waits for all scoped references to be
 // destroyed before calling OnDisable() to actually disable the component.
 //
 // Components MUST be disabled before they are deleted. For ease of use, a
 // Destroy() method is provided. When Destroy() is called, it prevents the
 // component from being enabled ever again, and then disables it, deleting it
 // once it is disabled.
 //
 // Example usage:
 //
 // class MetricsRecorder : public Component<MetricsRecorder> {
 //  public:
 //   virtual ~MetricsRecorder() {}
 //   virtual void RecordEvent(const std::string& event) = 0;
 // };
 //
 // class SetupManager : public Component<SetupManager> {
 //  public:
 //   virtual ~SetupManager() {}
 //   virtual int GetMultizoneDelay() = 0;
 // };
 //
 // class Multizone : public Component<Multizone> {
 //  public:
 //   virtual ~Multizone() {}
 //   virtual void DoMultizoneStuff() = 0;
 // };
 //
 // class MetricsRecorderImpl : public MetricsRecorder {
 //  public:
 //   void OnEnable() override {
 //     // ... Enable metrics reporting ...
 //     OnEnableComplete(true);
 //   }
 //
 //   // Release all resources; public methods will not be called after this.
 //   void OnDisable() override {
 //     OnDisableComplete();
 //   }
 //
 //   void RecordEvent(const std::string& event) override {
 //     // ... Record an event ...
 //   }
 // };
 //
 // class SetupManagerImpl : public SetupManager {
 //  public:
 //   void OnEnable() override {
 //     // ... Enable setup manager ...
 //     // OnEnableComplete() may be called asynchronously.
 //     base::ThreadTaskRunnerHandle::Get()->PostTask(
 //         FROM_HERE, base::Bind(&SetupManagerImpl::CompleteEnable,
 //                               base::Unretained(this)));
 //   }
 //
 //   void CompleteEnable() {
 //     OnEnableComplete(true);
 //   }
 //
 //   void OnDisable() override {
 //     OnDisableComplete();
 //   }
 //
 //   int GetMultizoneDelay() override { return 0; }
 // };
 //
 // class MultizoneImpl : public Multizone {
 //  public:
 //   MultizoneImpl(const MetricsRecorder::WeakRef& metrics_recorder,
 //                 const SetupManager::WeakRef& setup_manager)
 //       : metrics_recorder_(metrics_recorder, this),
 //         setup_manager_(setup_manager) {
 //     // We can try to use weak deps even before this component is enabled.
 //     // However, we MUST NOT attempt to use any strong dependencies.
 //     if (auto setup = setup_manager_.Try()) {
 //       int delay = setup->GetMultizoneDelay();
 //       // ... Do something with delay ...
 //     }
 //   }
 //
 //   void OnEnable() override {
 //     // ... Enable multizone ...
 //     // Can use strong dependencies directly
 //     metrics_recorder_->RecordEvent("enable multizone");
 //     OnEnableComplete();
 //   }
 //
 //   void OnDisable() override {
 //     // Can still use strong dependencies here. However, this method MUST
 //     // ensure that strong dependencies will NOT be used after it returns.
 //     metrics_recorder_->RecordEvent("disable multizone");
 //     OnDisableComplete();
 //   }
 //
 //   void DoMultizoneStuff() {
 //     metrics_recorder_->RecordEvent("multizone stuff");
 //     // You have to Try() every time you use a weak dependency.
 //     if (auto setup = setup_manager_.Try()) {
 //       int delay = setup->GetMultizoneDelay();
 //       // ... Do something with delay ...
 //     }
 //   }
 //
 //  private:
 //   MetricsRecorder::Dependency metrics_recorder_;
 //   SetupManager::WeakRef setup_manager_;
 // };

 #ifndef CHROMECAST_BASE_COMPONENT_COMPONENT_H_
 #define CHROMECAST_BASE_COMPONENT_COMPONENT_H_

 #include <vector>

 #include "base/callback.h"
 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/memory/ref_counted.h"
 #include "base/memory/weak_ptr.h"
 #include "base/observer_list_threadsafe.h"
 #include "base/threading/thread_checker.h"
 #include "chromecast/base/component/component_internal.h"

 namespace base {
 class SingleThreadTaskRunner;
 }  // namespace base

 namespace chromecast {

 class ComponentBase {
  public:
   class Observer {
    public:
     // Called when a component finishes being enabled. If the component was
     // enabled successfully, |success| will be |true|. Note that access to
     // |component| is not guaranteed to be safe; since the observers are
     // notified asynchronously, |component| may have been already deleted.
     virtual void OnComponentEnabled(ComponentBase* component, bool success) {}
     // Called when a component has been disabled. Access to |component| is not
     // guaranteed to be safe.
     virtual void OnComponentDisabled(ComponentBase* component) {}

    protected:
     virtual ~Observer() {}
   };

   virtual ~ComponentBase();

   // Enables this component if possible. Attempts to enable all strong
   // dependencies first. It is OK to call Disable() while the component is in
   // the process of being enabled. All components MUST be created/enabled/
   // disabled/destroyed on the same thread.
   // Note that enabling a component may occur asynchronously; components must
   // always be accessed through a Dependency or WeakReference to ensure safety.
   // TODO(kmackay) Consider allowing components to be used on any thread.
   void Enable();

   // Disables this component; disabling may complete asynchronously. It is OK to
   // call Enable() again while the component is being disabled. Note that a
   // component MUST be disabled (or never enabled) before it is deleted.
   void Disable();

   // Deletes this component, disabling it first if necessary.
   void Destroy();

   void AddObserver(Observer* observer);
   void RemoveObserver(Observer* observer);

  protected:
   ComponentBase();

   // Enables the component implementation. This method must set things up so
   // that any public method calls are valid, and then call OnEnableComplete(),
   // passing in |true| if the enable was successful, |false| otherwise.
   // OnEnableComplete() may be called from any thread. OnEnable() will not be
   // called again until after the component has been disabled, and will not be
   // called during an ongoing OnDisable() call (so if OnDisable() is called,
   // then OnEnable() will not be called until OnDisableComplete() has been
   // called). This method is called only on the thread that the component was
   // created on.
   virtual void OnEnable() = 0;

   // Disables the component implementation. This is not called until there are
   // no more live dependencies, so there will be no more public method calls
   // to the component until after OnEnable() is called again. This method must
   // do whatever is necessary to ensure that no more calls to dependencies of
   // this component will be made, and then call the |disabled_cb|. The
   // |disabled_cb| may be called from any thread. This method is called only on
   // the thread that the component was created on.
   virtual void OnDisable() = 0;

   // Handles the success/failure of a call to OnEnable(). When OnEnable() is
   // called, it must eventually call OnEnableComplete() (after the component is
   // ready to be used by dependents), passing in |true| if the component was
   // enabled successfully. If |success| is false, then OnDisable() will be
   // called immediately to return the component to a consistent disabled state.
   // May be called on any thread.
   void OnEnableComplete(bool success);

   // Handles the completion of a call to OnDisable(). When OnDisable() is
   // called, it must eventually call OnDisableComplete() (after ensuring that
   // none of the component's strong dependencies will be used anymore). May be
   // called on any thread.
   void OnDisableComplete();

  private:
   friend class subtle::DependencyCount;
   friend class subtle::DependencyBase;
   friend class subtle::WeakReferenceBase;

   enum State {
     kStateDisabled,
     kStateDisabling,
     kStateEnabled,
     kStateEnabling,
     kStateDestroying
   };

   void DependencyReady();
   void TryOnEnable();
   void OnEnableCompleteInternal(bool success);
   void DependencyCountDisableComplete();
   void TryOnDisable();
   void OnDisableCompleteInternal();
   void AddDependency(subtle::DependencyBase* dependency);
   void StopUsingDependencies();
   // Returns |true| if |component| is a transitive dependency of this component.
   bool DependsOn(ComponentBase* component);

   const scoped_refptr<base::SingleThreadTaskRunner> task_runner_;
   scoped_refptr<subtle::DependencyCount> counter_;
   std::vector<subtle::DependencyBase*> strong_dependencies_;
   State state_;
   // |true| when a call to OnEnable()/OnDisable() is in progress.
   bool async_call_in_progress_;
   int pending_dependency_count_;
   const scoped_refptr<base::ObserverListThreadSafe<Observer>> observers_;

   DISALLOW_COPY_AND_ASSIGN(ComponentBase);
 };

 template <typename C>
 class StrongDependency : public subtle::DependencyBase {
  public:
   StrongDependency(const WeakReference<C>& dependency, ComponentBase* dependent)
       : subtle::DependencyBase(dependency, dependent) {}

   C* operator->() const {
     DCHECK(dependency_);
     return static_cast<C*>(dependency_);
   }

  private:
   DISALLOW_COPY_AND_ASSIGN(StrongDependency);
 };

 template <typename C>
 class WeakReference : public subtle::WeakReferenceBase {
  public:
   explicit WeakReference(const C& dependency) : WeakReferenceBase(dependency) {}
   explicit WeakReference(const StrongDependency<C>& dependency)
       : subtle::WeakReferenceBase(dependency) {}

   // Explicitly allow copy.
   WeakReference(const WeakReference& other) = default;
   WeakReference(WeakReference&& other) = default;

   // Disallow assignment.
   void operator=(const WeakReference&) = delete;

   // Try to get a scoped reference. Expected usage:
   // if (auto ref = weak.Try()) {
   //    // ... use ref ...
   // }
   subtle::Ref_DO_NOT_DECLARE<C> Try() const {
     return subtle::Ref_DO_NOT_DECLARE<C>(counter_);
   }
 };

 template <typename C>
 class Component : public ComponentBase {
  public:
   using WeakRef = WeakReference<C>;
   using Dependency = StrongDependency<C>;

   Component() = default;

   WeakRef GetRef() { return WeakRef(*static_cast<C*>(this)); }

  private:
   DISALLOW_COPY_AND_ASSIGN(Component);
 };

 }  // namespace chromecast

 #endif  // CHROMECAST_BASE_COMPONENT_COMPONENT_H_
	// Copyright 2016 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// A component is a large, long-lived set of functionality that may be enabled
	// or disabled at runtime. Some examples include: the multizone features,
	// MetricsRecorder, or OpencastController. Components may depend on each other
	// (ie, a component may call the public methods of other components); the
	// Component infrastructure ensures that when a component is disabled, nothing
	// that depends on it will call any of its methods until it is enabled again.
	//
	// Components may be used without a dependency relationship via a weak
	// reference. A weak reference does not allow direct access to the component;
	// instead, it must be either used to create a strict dependency (see below), or
	// be converted to a scoped reference via Try(). Scoped references must be
	// checked for validity before use (they are convertible to bool); an invalid
	// scoped reference must not be used. Scoped references should be short-lived;
	// to encourage this, they are only move-constructible and cannot be copied or
	// assigned.
	//
	// If component Y depends on Component X, then Y has a Dependency reference
	// to X. This causes Y to be disabled as X is being disabled (before X's
	// OnDisable() method is called). Similarly, this dependency will cause X to be
	// enabled when Y is being enabled (X will be enabled before Y's OnEnable()
	// method is called). A component may freely access any of its dependencies
	// as long as it is enabled. When a component is disabled, it must ensure that
	// none of its dependencies will be used again until it is enabled. It is
	// recommended to set up dependencies in your component's constructor; it is an
	// error to add a dependency to a component that is not disabled.
	//
	// When a component is disabled, it will first recursively disable any other
	// components that depend on it. It will also disable the creation of
	// new scoped references. It then waits for all scoped references to be
	// destroyed before calling OnDisable() to actually disable the component.
	//
	// Components MUST be disabled before they are deleted. For ease of use, a
	// Destroy() method is provided. When Destroy() is called, it prevents the
	// component from being enabled ever again, and then disables it, deleting it
	// once it is disabled.
	//
	// Example usage:
	//
	// class MetricsRecorder : public Component<MetricsRecorder> {
	// public:
	// virtual ~MetricsRecorder() {}
	// virtual void RecordEvent(const std::string& event) = 0;
	// };
	//
	// class SetupManager : public Component<SetupManager> {
	// public:
	// virtual ~SetupManager() {}
	// virtual int GetMultizoneDelay() = 0;
	// };
	//
	// class Multizone : public Component<Multizone> {
	// public:
	// virtual ~Multizone() {}
	// virtual void DoMultizoneStuff() = 0;
	// };
	//
	// class MetricsRecorderImpl : public MetricsRecorder {
	// public:
	// void OnEnable() override {
	// // ... Enable metrics reporting ...
	// OnEnableComplete(true);
	// }
	//
	// // Release all resources; public methods will not be called after this.
	// void OnDisable() override {
	// OnDisableComplete();
	// }
	//
	// void RecordEvent(const std::string& event) override {
	// // ... Record an event ...
	// }
	// };
	//
	// class SetupManagerImpl : public SetupManager {
	// public:
	// void OnEnable() override {
	// // ... Enable setup manager ...
	// // OnEnableComplete() may be called asynchronously.
	// base::ThreadTaskRunnerHandle::Get()->PostTask(
	// FROM_HERE, base::Bind(&SetupManagerImpl::CompleteEnable,
	// base::Unretained(this)));
	// }
	//
	// void CompleteEnable() {
	// OnEnableComplete(true);
	// }
	//
	// void OnDisable() override {
	// OnDisableComplete();
	// }
	//
	// int GetMultizoneDelay() override { return 0; }
	// };
	//
	// class MultizoneImpl : public Multizone {
	// public:
	// MultizoneImpl(const MetricsRecorder::WeakRef& metrics_recorder,
	// const SetupManager::WeakRef& setup_manager)
	// : metrics_recorder_(metrics_recorder, this),
	// setup_manager_(setup_manager) {
	// // We can try to use weak deps even before this component is enabled.
	// // However, we MUST NOT attempt to use any strong dependencies.
	// if (auto setup = setup_manager_.Try()) {
	// int delay = setup->GetMultizoneDelay();
	// // ... Do something with delay ...
	// }
	// }
	//
	// void OnEnable() override {
	// // ... Enable multizone ...
	// // Can use strong dependencies directly
	// metrics_recorder_->RecordEvent("enable multizone");
	// OnEnableComplete();
	// }
	//
	// void OnDisable() override {
	// // Can still use strong dependencies here. However, this method MUST
	// // ensure that strong dependencies will NOT be used after it returns.
	// metrics_recorder_->RecordEvent("disable multizone");
	// OnDisableComplete();
	// }
	//
	// void DoMultizoneStuff() {
	// metrics_recorder_->RecordEvent("multizone stuff");
	// // You have to Try() every time you use a weak dependency.
	// if (auto setup = setup_manager_.Try()) {
	// int delay = setup->GetMultizoneDelay();
	// // ... Do something with delay ...
	// }
	// }
	//
	// private:
	// MetricsRecorder::Dependency metrics_recorder_;
	// SetupManager::WeakRef setup_manager_;
	// };

	#ifndef CHROMECAST_BASE_COMPONENT_COMPONENT_H_
	#define CHROMECAST_BASE_COMPONENT_COMPONENT_H_

	#include <vector>

	#include "base/callback.h"
	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/memory/ref_counted.h"
	#include "base/memory/weak_ptr.h"
	#include "base/observer_list_threadsafe.h"
	#include "base/threading/thread_checker.h"
	#include "chromecast/base/component/component_internal.h"

	namespace base {
	class SingleThreadTaskRunner;
	} // namespace base

	namespace chromecast {

	class ComponentBase {
	public:
	class Observer {
	public:
	// Called when a component finishes being enabled. If the component was
	// enabled successfully, \|success\| will be \|true\|. Note that access to
	// \|component\| is not guaranteed to be safe; since the observers are
	// notified asynchronously, \|component\| may have been already deleted.
	virtual void OnComponentEnabled(ComponentBase* component, bool success) {}
	// Called when a component has been disabled. Access to \|component\| is not
	// guaranteed to be safe.
	virtual void OnComponentDisabled(ComponentBase* component) {}

	protected:
	virtual ~Observer() {}
	};

	virtual ~ComponentBase();

	// Enables this component if possible. Attempts to enable all strong
	// dependencies first. It is OK to call Disable() while the component is in
	// the process of being enabled. All components MUST be created/enabled/
	// disabled/destroyed on the same thread.
	// Note that enabling a component may occur asynchronously; components must
	// always be accessed through a Dependency or WeakReference to ensure safety.
	// TODO(kmackay) Consider allowing components to be used on any thread.
	void Enable();

	// Disables this component; disabling may complete asynchronously. It is OK to
	// call Enable() again while the component is being disabled. Note that a
	// component MUST be disabled (or never enabled) before it is deleted.
	void Disable();

	// Deletes this component, disabling it first if necessary.
	void Destroy();

	void AddObserver(Observer* observer);
	void RemoveObserver(Observer* observer);

	protected:
	ComponentBase();

	// Enables the component implementation. This method must set things up so
	// that any public method calls are valid, and then call OnEnableComplete(),
	// passing in \|true\| if the enable was successful, \|false\| otherwise.
	// OnEnableComplete() may be called from any thread. OnEnable() will not be
	// called again until after the component has been disabled, and will not be
	// called during an ongoing OnDisable() call (so if OnDisable() is called,
	// then OnEnable() will not be called until OnDisableComplete() has been
	// called). This method is called only on the thread that the component was
	// created on.
	virtual void OnEnable() = 0;

	// Disables the component implementation. This is not called until there are
	// no more live dependencies, so there will be no more public method calls
	// to the component until after OnEnable() is called again. This method must
	// do whatever is necessary to ensure that no more calls to dependencies of
	// this component will be made, and then call the \|disabled_cb\|. The
	// \|disabled_cb\| may be called from any thread. This method is called only on
	// the thread that the component was created on.
	virtual void OnDisable() = 0;

	// Handles the success/failure of a call to OnEnable(). When OnEnable() is
	// called, it must eventually call OnEnableComplete() (after the component is
	// ready to be used by dependents), passing in \|true\| if the component was
	// enabled successfully. If \|success\| is false, then OnDisable() will be
	// called immediately to return the component to a consistent disabled state.
	// May be called on any thread.
	void OnEnableComplete(bool success);

	// Handles the completion of a call to OnDisable(). When OnDisable() is
	// called, it must eventually call OnDisableComplete() (after ensuring that
	// none of the component's strong dependencies will be used anymore). May be
	// called on any thread.
	void OnDisableComplete();

	private:
	friend class subtle::DependencyCount;
	friend class subtle::DependencyBase;
	friend class subtle::WeakReferenceBase;

	enum State {
	kStateDisabled,
	kStateDisabling,
	kStateEnabled,
	kStateEnabling,
	kStateDestroying
	};

	void DependencyReady();
	void TryOnEnable();
	void OnEnableCompleteInternal(bool success);
	void DependencyCountDisableComplete();
	void TryOnDisable();
	void OnDisableCompleteInternal();
	void AddDependency(subtle::DependencyBase* dependency);
	void StopUsingDependencies();
	// Returns \|true\| if \|component\| is a transitive dependency of this component.
	bool DependsOn(ComponentBase* component);

	const scoped_refptr<base::SingleThreadTaskRunner> task_runner_;
	scoped_refptr<subtle::DependencyCount> counter_;
	std::vector<subtle::DependencyBase*> strong_dependencies_;
	State state_;
	// \|true\| when a call to OnEnable()/OnDisable() is in progress.
	bool async_call_in_progress_;
	int pending_dependency_count_;
	const scoped_refptr<base::ObserverListThreadSafe<Observer>> observers_;

	DISALLOW_COPY_AND_ASSIGN(ComponentBase);
	};

	template <typename C>
	class StrongDependency : public subtle::DependencyBase {
	public:
	StrongDependency(const WeakReference<C>& dependency, ComponentBase* dependent)
	: subtle::DependencyBase(dependency, dependent) {}

	C* operator->() const {
	DCHECK(dependency_);
	return static_cast<C*>(dependency_);
	}

	private:
	DISALLOW_COPY_AND_ASSIGN(StrongDependency);
	};

	template <typename C>
	class WeakReference : public subtle::WeakReferenceBase {
	public:
	explicit WeakReference(const C& dependency) : WeakReferenceBase(dependency) {}
	explicit WeakReference(const StrongDependency<C>& dependency)
	: subtle::WeakReferenceBase(dependency) {}

	// Explicitly allow copy.
	WeakReference(const WeakReference& other) = default;
	WeakReference(WeakReference&& other) = default;

	// Disallow assignment.
	void operator=(const WeakReference&) = delete;

	// Try to get a scoped reference. Expected usage:
	// if (auto ref = weak.Try()) {
	// // ... use ref ...
	// }
	subtle::Ref_DO_NOT_DECLARE<C> Try() const {
	return subtle::Ref_DO_NOT_DECLARE<C>(counter_);
	}
	};

	template <typename C>
	class Component : public ComponentBase {
	public:
	using WeakRef = WeakReference<C>;
	using Dependency = StrongDependency<C>;

	Component() = default;

	WeakRef GetRef() { return WeakRef(static_cast<C>(this)); }

	private:
	DISALLOW_COPY_AND_ASSIGN(Component);
	};

	} // namespace chromecast

	#endif // CHROMECAST_BASE_COMPONENT_COMPONENT_H_