src/main/cpp/sdk/common/spdlog/details/thread_pool.h - rocketmq-ons-cpp - Git at Google


 #pragma once

 #include "spdlog/details/fmt_helper.h"
 #include "spdlog/details/log_msg.h"
 #include "spdlog/details/mpmc_blocking_q.h"
 #include "spdlog/details/os.h"

 #include <chrono>
 #include <memory>
 #include <thread>
 #include <vector>

 namespace spdlog {
 namespace details {

 using async_logger_ptr = std::shared_ptr<spdlog::async_logger>;

 enum class async_msg_type
 {
     log,
     flush,
     terminate
 };

 // Async msg to move to/from the queue
 // Movable only. should never be copied
 struct async_msg
 {
     async_msg_type msg_type;
     level::level_enum level;
     log_clock::time_point time;
     size_t thread_id;
     fmt::basic_memory_buffer<char, 176> raw;

     size_t msg_id;
     source_loc source;
     async_logger_ptr worker_ptr;

     async_msg() = default;
     ~async_msg() = default;

     // should only be moved in or out of the queue..
     async_msg(const async_msg &) = delete;

 // support for vs2013 move
 #if defined(_MSC_VER) && _MSC_VER <= 1800
     async_msg(async_msg &&other) SPDLOG_NOEXCEPT : msg_type(other.msg_type),
                                                    level(other.level),
                                                    time(other.time),
                                                    thread_id(other.thread_id),
                                                    raw(move(other.raw)),
                                                    msg_id(other.msg_id),
                                                    source(other.source),
                                                    worker_ptr(std::move(other.worker_ptr))
     {
     }

     async_msg &operator=(async_msg &&other) SPDLOG_NOEXCEPT
     {
         msg_type = other.msg_type;
         level = other.level;
         time = other.time;
         thread_id = other.thread_id;
         raw = std::move(other.raw);
         msg_id = other.msg_id;
         source = other.source;
         worker_ptr = std::move(other.worker_ptr);
         return *this;
     }
 #else // (_MSC_VER) && _MSC_VER <= 1800
     async_msg(async_msg &&) = default;
     async_msg &operator=(async_msg &&) = default;
 #endif

     // construct from log_msg with given type
     async_msg(async_logger_ptr &&worker, async_msg_type the_type, details::log_msg &m)
         : msg_type(the_type)
         , level(m.level)
         , time(m.time)
         , thread_id(m.thread_id)
         , msg_id(m.msg_id)
         , source(m.source)
         , worker_ptr(std::move(worker))
     {
         fmt_helper::append_string_view(m.payload, raw);
     }

     async_msg(async_logger_ptr &&worker, async_msg_type the_type)
         : msg_type(the_type)
         , level(level::off)
         , time()
         , thread_id(0)
         , msg_id(0)
         , source()
         , worker_ptr(std::move(worker))
     {
     }

     explicit async_msg(async_msg_type the_type)
         : async_msg(nullptr, the_type)
     {
     }

     // copy into log_msg
     log_msg to_log_msg()
     {
         log_msg msg(&worker_ptr->name(), level, string_view_t(raw.data(), raw.size()));
         msg.time = time;
         msg.thread_id = thread_id;
         msg.msg_id = msg_id;
         msg.source = source;
         msg.color_range_start = 0;
         msg.color_range_end = 0;
         return msg;
     }
 };

 class thread_pool
 {
 public:
     using item_type = async_msg;
     using q_type = details::mpmc_blocking_queue<item_type>;

     thread_pool(size_t q_max_items, size_t threads_n)
         : q_(q_max_items)
     {
         // std::cout << "thread_pool()  q_size_bytes: " << q_size_bytes <<
         // "\tthreads_n: " << threads_n << std::endl;
         if (threads_n == 0 || threads_n > 1000)
         {
             throw spdlog_ex("spdlog::thread_pool(): invalid threads_n param (valid "
                             "range is 1-1000)");
         }
         for (size_t i = 0; i < threads_n; i++)
         {
             threads_.emplace_back(&thread_pool::worker_loop_, this);
         }
     }

     // message all threads to terminate gracefully join them
     ~thread_pool()
     {
         try
         {
             for (size_t i = 0; i < threads_.size(); i++)
             {
                 post_async_msg_(async_msg(async_msg_type::terminate), async_overflow_policy::block);
             }

             for (auto &t : threads_)
             {
                 t.join();
             }
         }
         catch (...)
         {
         }
     }

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

     void post_log(async_logger_ptr &&worker_ptr, details::log_msg &msg, async_overflow_policy overflow_policy)
     {
         async_msg async_m(std::move(worker_ptr), async_msg_type::log, msg);
         post_async_msg_(std::move(async_m), overflow_policy);
     }

     void post_flush(async_logger_ptr &&worker_ptr, async_overflow_policy overflow_policy)
     {
         post_async_msg_(async_msg(std::move(worker_ptr), async_msg_type::flush), overflow_policy);
     }

     size_t overrun_counter()
     {
         return q_.overrun_counter();
     }

 private:
     q_type q_;

     std::vector<std::thread> threads_;

     void post_async_msg_(async_msg &&new_msg, async_overflow_policy overflow_policy)
     {
         if (overflow_policy == async_overflow_policy::block)
         {
             q_.enqueue(std::move(new_msg));
         }
         else
         {
             q_.enqueue_nowait(std::move(new_msg));
         }
     }

     void worker_loop_()
     {
         while (process_next_msg_()) {};
     }

     // process next message in the queue
     // return true if this thread should still be active (while no terminate msg
     // was received)
     bool process_next_msg_()
     {
         async_msg incoming_async_msg;
         bool dequeued = q_.dequeue_for(incoming_async_msg, std::chrono::seconds(10));
         if (!dequeued)
         {
             return true;
         }

         switch (incoming_async_msg.msg_type)
         {
         case async_msg_type::log:
         {
             auto msg = incoming_async_msg.to_log_msg();
             incoming_async_msg.worker_ptr->backend_log_(msg);
             return true;
         }
         case async_msg_type::flush:
         {
             incoming_async_msg.worker_ptr->backend_flush_();
             return true;
         }

         case async_msg_type::terminate:
         {
             return false;
         }
         }
         assert(false && "Unexpected async_msg_type");
         return true;
     }
 };

 } // namespace details
 } // namespace spdlog

	#pragma once

	#include "spdlog/details/fmt_helper.h"
	#include "spdlog/details/log_msg.h"
	#include "spdlog/details/mpmc_blocking_q.h"
	#include "spdlog/details/os.h"

	#include <chrono>
	#include <memory>
	#include <thread>
	#include <vector>

	namespace spdlog {
	namespace details {

	using async_logger_ptr = std::shared_ptr<spdlog::async_logger>;

	enum class async_msg_type
	{
	log,
	flush,
	terminate
	};

	// Async msg to move to/from the queue
	// Movable only. should never be copied
	struct async_msg
	{
	async_msg_type msg_type;
	level::level_enum level;
	log_clock::time_point time;
	size_t thread_id;
	fmt::basic_memory_buffer<char, 176> raw;

	size_t msg_id;
	source_loc source;
	async_logger_ptr worker_ptr;

	async_msg() = default;
	~async_msg() = default;

	// should only be moved in or out of the queue..
	async_msg(const async_msg &) = delete;

	// support for vs2013 move
	#if defined(_MSC_VER) && _MSC_VER <= 1800
	async_msg(async_msg &&other) SPDLOG_NOEXCEPT : msg_type(other.msg_type),
	level(other.level),
	time(other.time),
	thread_id(other.thread_id),
	raw(move(other.raw)),
	msg_id(other.msg_id),
	source(other.source),
	worker_ptr(std::move(other.worker_ptr))
	{
	}

	async_msg &operator=(async_msg &&other) SPDLOG_NOEXCEPT
	{
	msg_type = other.msg_type;
	level = other.level;
	time = other.time;
	thread_id = other.thread_id;
	raw = std::move(other.raw);
	msg_id = other.msg_id;
	source = other.source;
	worker_ptr = std::move(other.worker_ptr);
	return *this;
	}
	#else // (_MSC_VER) && _MSC_VER <= 1800
	async_msg(async_msg &&) = default;
	async_msg &operator=(async_msg &&) = default;
	#endif

	// construct from log_msg with given type
	async_msg(async_logger_ptr &&worker, async_msg_type the_type, details::log_msg &m)
	: msg_type(the_type)
	, level(m.level)
	, time(m.time)
	, thread_id(m.thread_id)
	, msg_id(m.msg_id)
	, source(m.source)
	, worker_ptr(std::move(worker))
	{
	fmt_helper::append_string_view(m.payload, raw);
	}

	async_msg(async_logger_ptr &&worker, async_msg_type the_type)
	: msg_type(the_type)
	, level(level::off)
	, time()
	, thread_id(0)
	, msg_id(0)
	, source()
	, worker_ptr(std::move(worker))
	{
	}

	explicit async_msg(async_msg_type the_type)
	: async_msg(nullptr, the_type)
	{
	}

	// copy into log_msg
	log_msg to_log_msg()
	{
	log_msg msg(&worker_ptr->name(), level, string_view_t(raw.data(), raw.size()));
	msg.time = time;
	msg.thread_id = thread_id;
	msg.msg_id = msg_id;
	msg.source = source;
	msg.color_range_start = 0;
	msg.color_range_end = 0;
	return msg;
	}
	};

	class thread_pool
	{
	public:
	using item_type = async_msg;
	using q_type = details::mpmc_blocking_queue<item_type>;

	thread_pool(size_t q_max_items, size_t threads_n)
	: q_(q_max_items)
	{
	// std::cout << "thread_pool() q_size_bytes: " << q_size_bytes <<
	// "\tthreads_n: " << threads_n << std::endl;
	if (threads_n == 0 \|\| threads_n > 1000)
	{
	throw spdlog_ex("spdlog::thread_pool(): invalid threads_n param (valid "
	"range is 1-1000)");
	}
	for (size_t i = 0; i < threads_n; i++)
	{
	threads_.emplace_back(&thread_pool::worker_loop_, this);
	}
	}

	// message all threads to terminate gracefully join them
	~thread_pool()
	{
	try
	{
	for (size_t i = 0; i < threads_.size(); i++)
	{
	post_async_msg_(async_msg(async_msg_type::terminate), async_overflow_policy::block);
	}

	for (auto &t : threads_)
	{
	t.join();
	}
	}
	catch (...)
	{
	}
	}

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

	void post_log(async_logger_ptr &&worker_ptr, details::log_msg &msg, async_overflow_policy overflow_policy)
	{
	async_msg async_m(std::move(worker_ptr), async_msg_type::log, msg);
	post_async_msg_(std::move(async_m), overflow_policy);
	}

	void post_flush(async_logger_ptr &&worker_ptr, async_overflow_policy overflow_policy)
	{
	post_async_msg_(async_msg(std::move(worker_ptr), async_msg_type::flush), overflow_policy);
	}

	size_t overrun_counter()
	{
	return q_.overrun_counter();
	}

	private:
	q_type q_;

	std::vector<std::thread> threads_;

	void post_async_msg_(async_msg &&new_msg, async_overflow_policy overflow_policy)
	{
	if (overflow_policy == async_overflow_policy::block)
	{
	q_.enqueue(std::move(new_msg));
	}
	else
	{
	q_.enqueue_nowait(std::move(new_msg));
	}
	}

	void worker_loop_()
	{
	while (process_next_msg_()) {};
	}

	// process next message in the queue
	// return true if this thread should still be active (while no terminate msg
	// was received)
	bool process_next_msg_()
	{
	async_msg incoming_async_msg;
	bool dequeued = q_.dequeue_for(incoming_async_msg, std::chrono::seconds(10));
	if (!dequeued)
	{
	return true;
	}

	switch (incoming_async_msg.msg_type)
	{
	case async_msg_type::log:
	{
	auto msg = incoming_async_msg.to_log_msg();
	incoming_async_msg.worker_ptr->backend_log_(msg);
	return true;
	}
	case async_msg_type::flush:
	{
	incoming_async_msg.worker_ptr->backend_flush_();
	return true;
	}

	case async_msg_type::terminate:
	{
	return false;
	}
	}
	assert(false && "Unexpected async_msg_type");
	return true;
	}
	};

	} // namespace details
	} // namespace spdlog