#include "librf/librf.h" #if RESUMEF_DEBUG_COUNTER std::mutex g_resumef_cout_mutex; std::atomic g_resumef_state_count = 0; std::atomic g_resumef_task_count = 0; std::atomic g_resumef_evtctx_count = 0; std::atomic g_resumef_state_id = 0; #endif namespace librf { const char * future_error_string[(size_t)error_code::max__] { "none", "not_ready", "already_acquired", "unlock_more", "read_before_write", "timer_canceled", "not_await_lock", "stop_requested", }; thread_local char sz_future_error_buffer[256]; LIBRF_API const char * get_error_string(error_code fe, const char * classname) { if (classname) { #if defined(__clang__) || defined(__GNUC__) #define sprintf_s sprintf #endif sprintf_s(sz_future_error_buffer, "%s, code=%s", classname, future_error_string[(size_t)(fe)]); return sz_future_error_buffer; } return future_error_string[(size_t)(fe)]; } thread_local scheduler_t * th_scheduler_ptr = nullptr; //获得当前线程下的调度器 LIBRF_API scheduler_t * this_scheduler() { return th_scheduler_ptr ? th_scheduler_ptr : &scheduler_t::g_scheduler; } LIBRF_API local_scheduler_t::local_scheduler_t() { if (th_scheduler_ptr == nullptr) { _scheduler_ptr = new scheduler_t; th_scheduler_ptr = _scheduler_ptr; } else { _scheduler_ptr = nullptr; } } LIBRF_API local_scheduler_t::local_scheduler_t(scheduler_t& sch) noexcept { if (th_scheduler_ptr == nullptr) { th_scheduler_ptr = &sch; } _scheduler_ptr = nullptr; } LIBRF_API local_scheduler_t::~local_scheduler_t() { if (th_scheduler_ptr == _scheduler_ptr) th_scheduler_ptr = nullptr; delete _scheduler_ptr; } LIBRF_API scheduler_t::scheduler_t() : _timer(std::make_shared()) { _runing_states.reserve(1024); _cached_states.reserve(1024); if (th_scheduler_ptr == nullptr) th_scheduler_ptr = this; } LIBRF_API scheduler_t::~scheduler_t() { //cancel_all_task_(); if (th_scheduler_ptr == this) th_scheduler_ptr = nullptr; } LIBRF_API task_t* scheduler_t::new_task(task_t * task) { state_base_t* sptr = task->_state.get(); sptr->set_scheduler(this); { #if !RESUMEF_DISABLE_MULT_THREAD scoped_lock __guard(_lock_ready); #endif _ready_task.emplace(sptr, task); } //如果是单独的future,没有被co_await过,则handler是nullptr。 if (sptr->has_handler()) { add_generator(sptr); } return task; } LIBRF_API std::unique_ptr scheduler_t::del_switch(state_base_t* sptr) { #if !RESUMEF_DISABLE_MULT_THREAD scoped_lock __guard(_lock_ready); #endif std::unique_ptr task_ptr; auto iter = this->_ready_task.find(sptr); if (iter != this->_ready_task.end()) { task_ptr = std::exchange(iter->second, nullptr); this->_ready_task.erase(iter); } return task_ptr; } LIBRF_API void scheduler_t::request_stop_all_if_possible() { scoped_lock __guard(_lock_ready); for (auto& kv : this->_ready_task) kv.second->request_stop_if_possible(); //this->_ready_task.clear(); this->_timer->clear(); } /* void scheduler_t::cancel_all_task_() { scoped_lock __guard(_lock_ready, _lock_running); this->_ready_task.clear(); this->_runing_states.clear(); } void scheduler_t::break_all() { cancel_all_task_(); this->_timer->clear(); } */ LIBRF_API bool scheduler_t::run_one_batch() { this->_timer->update(); { #if !RESUMEF_DISABLE_MULT_THREAD scoped_lock __guard(_lock_running); #endif if (likely(_runing_states.empty())) return false; std::swap(_cached_states, _runing_states); } for (state_sptr& sptr : _cached_states) sptr->resume(); _cached_states.clear(); return true; } LIBRF_API void scheduler_t::run_until_notask() { for(;;) { //介于网上有人做评测,导致单协程切换数据很难看,那就注释掉吧。 //std::this_thread::yield(); if (likely(this->run_one_batch())) continue; //当前运行了一个state,则认为还可能有任务未完成 { #if !RESUMEF_DISABLE_MULT_THREAD scoped_lock __guard(_lock_ready); #endif if (likely(!_ready_task.empty())) continue; //当前还存在task,则必然还有任务未完成 } if (unlikely(!_timer->empty())) continue; //定时器不为空,也需要等待定时器触发 break; }; } LIBRF_API scheduler_t scheduler_t::g_scheduler; }