pw_thread/public/pw_thread/thread.h - pigweed/pigweed - Git at Google

 // Copyright 2021 The Pigweed Authors
 //
 // 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
 //
 //     https://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.
 #pragma once

 #include "pw_thread/id.h"
 #include "pw_thread/thread_core.h"

 // clang-format off
 // The backend's thread_native header must provide PW_THREAD_JOINING_ENABLED.
 #include "pw_thread_backend/thread_native.h"
 // clang-format on

 namespace pw::thread {

 // The Options contains the parameters needed for a thread to start.
 //
 // Options are backend specific and ergo the generic base class cannot be
 // directly instantiated.
 //
 // The attributes which can be set through the options are backend specific
 // but may contain things like the thread name, priority, scheduling policy,
 // core/processor affinity, and/or an optional reference to a pre-allocated
 // Context (the collection of memory allocations needed for a thread to run).
 //
 // Options shall NOT permit starting as detached, this must be done explicitly
 // through the Thread API.
 //
 // Options must not contain any memory needed for a thread to run (TCB,
 // stack, etc.). The Options may be deleted or re-used immediately after
 // starting a thread.
 class Options {
  protected:
   constexpr Options() = default;
 };

 // The class Thread can represent a single thread of execution. Threads allow
 // multiple functions to execute concurrently.
 //
 // Threads may begin execution immediately upon construction of the associated
 // thread object (pending any OS scheduling delays), starting at the top-level
 // function provided as a constructor argument. The return value of the
 // top-level function is ignored. The top-level function may communicate its
 // return value by modifying shared variables (which may require
 // synchronization, see pw_sync and std::atomic)
 //
 // Thread objects may also be in the state that does not represent any thread
 // (after default construction, move from, detach, or join), and a thread of
 // execution may be not associated with any thread objects (after detach).
 //
 // No two Thread objects may represent the same thread of execution; Thread is
 // not CopyConstructible or CopyAssignable, although it is MoveConstructible and
 // MoveAssignable.
 class Thread {
  public:
   using native_handle_type = backend::NativeThreadHandle;

   // Creates a new thread object which does not represent a thread of execution
   // yet.
   Thread();

   // Creates a new thread object which represents a thread of execution.
   //
   // Thread functions are permitted to return and must have the following
   // ThreadRoutine signature:
   //   void example_function(void *arg);
   //
   // To invoke a member method of a class a static lambda closure can be used
   // to ensure the dispatching closure is not destructed before the thread is
   // done executing. For example:
   //   class Foo {
   //    public:
   //     void DoBar() {}
   //   };
   //   Foo foo;
   //
   //   static auto invoke_foo_do_bar = [](void *void_foo_ptr) {
   //       //  If needed, additional arguments could be set here.
   //       static_cast<Foo*>(void_foo_ptr)->DoBar();
   //   };
   //
   //   // Now use the lambda closure as the thread entry, passing the foo's
   //   // this as the argument.
   //   Thread thread(options, invoke_foo_do_bar, &foo);
   //   thread.detach();
   //
   // Alternatively a helper ThreadCore interface can be implemented by an object
   // so that a static lambda closure or function is not needed to dispatch to
   // a member function without arguments. For example:
   //   class Foo : public ThreadCore {
   //    private:
   //     void Run() override {}
   //   };
   //   Foo foo;
   //
   //   // Now create the thread, using foo directly.
   //   Thread(options, foo).detach();
   //
   // Postcondition: The thread get EITHER detached or joined.
   //
   // NOTE: Options have a default constructor, however default options are not
   // portable! Default options can only work if threads are dynamically
   // allocated by default, meaning default options cannot work on backends which
   // require static thread allocations. In addition on some schedulers
   // default options may not work for other reasons.
   using ThreadRoutine = void (*)(void* arg);
   Thread(const Options& options, ThreadRoutine entry, void* arg = nullptr);
   Thread(const Options& options, ThreadCore& thread_core);

   // Postcondition: The other thread no longer represents a thread of execution.
   Thread& operator=(Thread&& other);

   // Precondition: The thread must have been EITHER detached or joined.
   ~Thread();

   Thread(const Thread&) = delete;
   Thread(Thread&&) = delete;
   Thread& operator=(const Thread&) = delete;

   // Returns a value of Thread::id identifying the thread associated with *this.
   // If there is no thread associated, default constructed Thread::id is
   // returned.
   Id get_id() const;

   // Checks if the Thread object identifies an active thread of execution which
   // has not yet been detached. Specifically, returns true if get_id() !=
   // pw::Thread::id() && detach() has NOT been invoked. So a default
   // constructed thread is not joinable and neither is one which was detached.
   //
   // A thread that has not started or has finished executing code which was
   // never detached, but has not yet been joined is still considered an active
   // thread of execution and is therefore joinable.
   bool joinable() const { return get_id() != Id(); }

 #if PW_THREAD_JOINING_ENABLED
   // Blocks the current thread until the thread identified by *this finishes its
   // execution.
   //
   // The completion of the thread identified by *this synchronizes with the
   // corresponding successful return from join().
   //
   // No synchronization is performed on *this itself. Concurrently calling
   // join() on the same thread object from multiple threads constitutes a data
   // race that results in undefined behavior.
   //
   // Precondition: The thread must have been NEITHER detached nor joined.
   //
   // Postcondition: After calling detach *this no longer owns any thread.
   void join();
 #else
   template <typename kUnusedType = void>
   void join() {
     static_assert(kJoiningEnabled<kUnusedType>,
                   "The selected pw_thread_THREAD backend does not have join() "
                   "enabled (AKA PW_THREAD_JOINING_ENABLED = 1)");
   }
 #endif  // PW_THREAD_JOINING_ENABLED

   // Separates the thread of execution from the thread object, allowing
   // execution to continue independently. Any allocated resources will be freed
   // once the thread exits.
   //
   // Precondition: The thread must have been NEITHER detached nor joined.
   //
   // Postcondition: After calling detach *this no longer owns any thread.
   void detach();

   // Exchanges the underlying handles of two thread objects.
   void swap(Thread& other);

   native_handle_type native_handle();

  private:
   template <typename...>
   static constexpr std::bool_constant<PW_THREAD_JOINING_ENABLED>
       kJoiningEnabled = {};

   // Note that just like std::thread, this is effectively just a pointer or
   // reference to the native thread -- this does not contain any memory needed
   // for the thread to execute.
   //
   // This may contain more than the native thread handle to enable functionality
   // which is not always available such as joining, which may require a
   // reference to a binary semaphore, or passing arguments to the thread's
   // function.
   backend::NativeThread native_type_;
 };

 }  // namespace pw::thread

 #include "pw_thread_backend/thread_inline.h"
	// Copyright 2021 The Pigweed Authors
	//
	// 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
	//
	// https://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.
	#pragma once

	#include "pw_thread/id.h"
	#include "pw_thread/thread_core.h"

	// clang-format off
	// The backend's thread_native header must provide PW_THREAD_JOINING_ENABLED.
	#include "pw_thread_backend/thread_native.h"
	// clang-format on

	namespace pw::thread {

	// The Options contains the parameters needed for a thread to start.
	//
	// Options are backend specific and ergo the generic base class cannot be
	// directly instantiated.
	//
	// The attributes which can be set through the options are backend specific
	// but may contain things like the thread name, priority, scheduling policy,
	// core/processor affinity, and/or an optional reference to a pre-allocated
	// Context (the collection of memory allocations needed for a thread to run).
	//
	// Options shall NOT permit starting as detached, this must be done explicitly
	// through the Thread API.
	//
	// Options must not contain any memory needed for a thread to run (TCB,
	// stack, etc.). The Options may be deleted or re-used immediately after
	// starting a thread.
	class Options {
	protected:
	constexpr Options() = default;
	};

	// The class Thread can represent a single thread of execution. Threads allow
	// multiple functions to execute concurrently.
	//
	// Threads may begin execution immediately upon construction of the associated
	// thread object (pending any OS scheduling delays), starting at the top-level
	// function provided as a constructor argument. The return value of the
	// top-level function is ignored. The top-level function may communicate its
	// return value by modifying shared variables (which may require
	// synchronization, see pw_sync and std::atomic)
	//
	// Thread objects may also be in the state that does not represent any thread
	// (after default construction, move from, detach, or join), and a thread of
	// execution may be not associated with any thread objects (after detach).
	//
	// No two Thread objects may represent the same thread of execution; Thread is
	// not CopyConstructible or CopyAssignable, although it is MoveConstructible and
	// MoveAssignable.
	class Thread {
	public:
	using native_handle_type = backend::NativeThreadHandle;

	// Creates a new thread object which does not represent a thread of execution
	// yet.
	Thread();

	// Creates a new thread object which represents a thread of execution.
	//
	// Thread functions are permitted to return and must have the following
	// ThreadRoutine signature:
	// void example_function(void *arg);
	//
	// To invoke a member method of a class a static lambda closure can be used
	// to ensure the dispatching closure is not destructed before the thread is
	// done executing. For example:
	// class Foo {
	// public:
	// void DoBar() {}
	// };
	// Foo foo;
	//
	// static auto invoke_foo_do_bar = [](void *void_foo_ptr) {
	// // If needed, additional arguments could be set here.
	// static_cast<Foo*>(void_foo_ptr)->DoBar();
	// };
	//
	// // Now use the lambda closure as the thread entry, passing the foo's
	// // this as the argument.
	// Thread thread(options, invoke_foo_do_bar, &foo);
	// thread.detach();
	//
	// Alternatively a helper ThreadCore interface can be implemented by an object
	// so that a static lambda closure or function is not needed to dispatch to
	// a member function without arguments. For example:
	// class Foo : public ThreadCore {
	// private:
	// void Run() override {}
	// };
	// Foo foo;
	//
	// // Now create the thread, using foo directly.
	// Thread(options, foo).detach();
	//
	// Postcondition: The thread get EITHER detached or joined.
	//
	// NOTE: Options have a default constructor, however default options are not
	// portable! Default options can only work if threads are dynamically
	// allocated by default, meaning default options cannot work on backends which
	// require static thread allocations. In addition on some schedulers
	// default options may not work for other reasons.
	using ThreadRoutine = void ()(void arg);
	Thread(const Options& options, ThreadRoutine entry, void* arg = nullptr);
	Thread(const Options& options, ThreadCore& thread_core);

	// Postcondition: The other thread no longer represents a thread of execution.
	Thread& operator=(Thread&& other);

	// Precondition: The thread must have been EITHER detached or joined.
	~Thread();

	Thread(const Thread&) = delete;
	Thread(Thread&&) = delete;
	Thread& operator=(const Thread&) = delete;

	// Returns a value of Thread::id identifying the thread associated with *this.
	// If there is no thread associated, default constructed Thread::id is
	// returned.
	Id get_id() const;

	// Checks if the Thread object identifies an active thread of execution which
	// has not yet been detached. Specifically, returns true if get_id() !=
	// pw::Thread::id() && detach() has NOT been invoked. So a default
	// constructed thread is not joinable and neither is one which was detached.
	//
	// A thread that has not started or has finished executing code which was
	// never detached, but has not yet been joined is still considered an active
	// thread of execution and is therefore joinable.
	bool joinable() const { return get_id() != Id(); }

	#if PW_THREAD_JOINING_ENABLED
	// Blocks the current thread until the thread identified by *this finishes its
	// execution.
	//
	// The completion of the thread identified by *this synchronizes with the
	// corresponding successful return from join().
	//
	// No synchronization is performed on *this itself. Concurrently calling
	// join() on the same thread object from multiple threads constitutes a data
	// race that results in undefined behavior.
	//
	// Precondition: The thread must have been NEITHER detached nor joined.
	//
	// Postcondition: After calling detach *this no longer owns any thread.
	void join();
	#else
	template <typename kUnusedType = void>
	void join() {
	static_assert(kJoiningEnabled<kUnusedType>,
	"The selected pw_thread_THREAD backend does not have join() "
	"enabled (AKA PW_THREAD_JOINING_ENABLED = 1)");
	}
	#endif // PW_THREAD_JOINING_ENABLED

	// Separates the thread of execution from the thread object, allowing
	// execution to continue independently. Any allocated resources will be freed
	// once the thread exits.
	//
	// Precondition: The thread must have been NEITHER detached nor joined.
	//
	// Postcondition: After calling detach *this no longer owns any thread.
	void detach();

	// Exchanges the underlying handles of two thread objects.
	void swap(Thread& other);

	native_handle_type native_handle();

	private:
	template <typename...>
	static constexpr std::bool_constant<PW_THREAD_JOINING_ENABLED>
	kJoiningEnabled = {};

	// Note that just like std::thread, this is effectively just a pointer or
	// reference to the native thread -- this does not contain any memory needed
	// for the thread to execute.
	//
	// This may contain more than the native thread handle to enable functionality
	// which is not always available such as joining, which may require a
	// reference to a binary semaphore, or passing arguments to the thread's
	// function.
	backend::NativeThread native_type_;
	};

	} // namespace pw::thread

	#include "pw_thread_backend/thread_inline.h"