GRAYBYTE | AutoShopMaker

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/* +----------------------------------------------------------------------+ | Swoole | +----------------------------------------------------------------------+ | This source file is subject to version 2.0 of the Apache license, | | that is bundled with this package in the file LICENSE, and is | | available through the world-wide-web at the following url: | | http://www.apache.org/licenses/LICENSE-2.0.html | | If you did not receive a copy of the Apache2.0 license and are unable| | to obtain it through the world-wide-web, please send a note to | | license@swoole.com so we can mail you a copy immediately. | +----------------------------------------------------------------------+ | Author: Tianfeng Han <rango@swoole.com> | | Twosee <twose@qq.com> | +----------------------------------------------------------------------+ */ #pragma once #include "swoole_api.h" #include "swoole_string.h" #include "swoole_socket.h" #include "swoole_reactor.h" #include "swoole_timer.h" #include "swoole_async.h" #include "swoole_util.h" #include "swoole_coroutine_context.h" #include <climits> #include <functional> #include <string> #include <unordered_map> typedef std::chrono::microseconds seconds_type; #ifdef SW_CORO_TIME #define CALC_EXECUTE_USEC(yield_coroutine, resume_coroutine) calc_execute_usec(yield_coroutine, resume_coroutine) #else #define CALC_EXECUTE_USEC(yield_coroutine, resume_coroutine) #endif namespace swoole { class Coroutine { public: constexpr static int STACK_ALIGNED_SIZE = (4 * 1024); constexpr static int MIN_STACK_SIZE = (64 * 1024); constexpr static int MAX_STACK_SIZE = (16 * 1024 * 1024); constexpr static long MAX_NUM_LIMIT = LONG_MAX; enum State { STATE_INIT = 0, STATE_WAITING, STATE_RUNNING, STATE_END, }; enum Error { ERR_END = 0, ERR_LIMIT = -1, ERR_INVALID = -2, }; enum ResumeCode { RC_OK = 0, RC_TIMEDOUT = -1, RC_CANCELED = -2, }; typedef void (*SwapCallback)(void *); typedef std::function<void(void)> BailoutCallback; typedef std::function<bool(swoole::Coroutine *)> CancelFunc; void resume(); void yield(); void yield(CancelFunc *cancel_fn); bool cancel(); bool yield_ex(double timeout = -1); enum State get_state() const { return state; } long get_init_msec() const { return init_msec; } long get_cid() const { return cid; } Coroutine *get_origin() { return origin; } long get_origin_cid() { return sw_likely(origin) ? origin->get_cid() : -1; } void *get_task() { return task; } bool is_end() { return ctx.is_end(); } bool is_canceled() const { return resume_code_ == RC_CANCELED; } bool is_timedout() const { return resume_code_ == RC_TIMEDOUT; } bool is_suspending() const { return state == STATE_WAITING; } void set_task(void *_task) { task = _task; } void set_cancel_fn(CancelFunc *cancel_fn) { cancel_fn_ = cancel_fn; } long get_execute_usec() const { return time<seconds_type>(true) - switch_usec + execute_usec; } coroutine::Context &get_ctx() { return ctx; } static std::unordered_map<long, Coroutine *> coroutines; static void set_on_yield(SwapCallback func); static void set_on_resume(SwapCallback func); static void set_on_close(SwapCallback func); static void bailout(BailoutCallback func); static inline bool run(const CoroutineFunc &fn, void *args = nullptr) { swoole_event_init(SW_EVENTLOOP_WAIT_EXIT); long cid = create(fn, args); swoole_event_wait(); return cid > 0; } static inline long create(const CoroutineFunc &fn, void *args = nullptr) { #ifdef SW_USE_THREAD_CONTEXT try { return (new Coroutine(fn, args))->run(); } catch (const std::system_error &e) { swoole_set_last_error(e.code().value()); swoole_warning("failed to create coroutine, Error: %s[%d]", e.what(), swoole_get_last_error()); return -1; } #else return (new Coroutine(fn, args))->run(); #endif } static inline Coroutine *init_main_coroutine() { Coroutine *co = new Coroutine(0, nullptr, nullptr); co->state = STATE_RUNNING; return co; } static void activate(); static void deactivate(); static inline Coroutine *get_current() { return current; } static inline Coroutine *get_current_safe() { if (sw_unlikely(!current)) { swoole_fatal_error(SW_ERROR_CO_OUT_OF_COROUTINE, "API must be called in the coroutine"); } return current; } static inline void *get_current_task() { return sw_likely(current) ? current->get_task() : nullptr; } static inline long get_current_cid() { return sw_likely(current) ? current->get_cid() : -1; } static inline Coroutine *get_by_cid(long cid) { auto i = coroutines.find(cid); return sw_likely(i != coroutines.end()) ? i->second : nullptr; } static inline void *get_task_by_cid(long cid) { Coroutine *co = get_by_cid(cid); return sw_likely(co) ? co->get_task() : nullptr; } static inline size_t get_stack_size() { return stack_size; } static inline void set_stack_size(size_t size) { stack_size = SW_MEM_ALIGNED_SIZE_EX(SW_MAX(MIN_STACK_SIZE, SW_MIN(size, MAX_STACK_SIZE)), STACK_ALIGNED_SIZE); } static inline long get_last_cid() { return last_cid; } static inline size_t count() { return coroutines.size(); } static inline uint64_t get_peak_num() { return peak_num; } static inline long get_elapsed(long cid) { Coroutine *co = cid == 0 ? get_current() : get_by_cid(cid); return sw_likely(co) ? Timer::get_absolute_msec() - co->get_init_msec() : -1; } static inline long get_execute_time(long cid) { Coroutine *co = cid == 0 ? get_current() : get_by_cid(cid); return sw_likely(co) ? co->get_execute_usec() : -1; } static inline void calc_execute_usec(Coroutine *yield_coroutine, Coroutine *resume_coroutine) { long current_usec = time<seconds_type>(true); if (yield_coroutine) { yield_coroutine->execute_usec += current_usec - yield_coroutine->switch_usec; } if (resume_coroutine) { resume_coroutine->switch_usec = current_usec; } } static void print_list(); protected: static Coroutine *current; static long last_cid; static uint64_t peak_num; static size_t stack_size; static SwapCallback on_yield; /* before yield */ static SwapCallback on_resume; /* before resume */ static SwapCallback on_close; /* before close */ static BailoutCallback on_bailout; /* when bailout */ static bool activated; enum State state = STATE_INIT; enum ResumeCode resume_code_ = RC_OK; long cid; long init_msec = Timer::get_absolute_msec(); long switch_usec = time<seconds_type>(true); long execute_usec = 0; void *task = nullptr; coroutine::Context ctx; Coroutine *origin = nullptr; CancelFunc *cancel_fn_ = nullptr; Coroutine(const CoroutineFunc &fn, void *private_data) : ctx(stack_size, fn, private_data) { cid = ++last_cid; coroutines[cid] = this; if (sw_unlikely(count() > peak_num)) { peak_num = count(); } } Coroutine(long _cid, const CoroutineFunc &fn, void *private_data) : ctx(stack_size, fn, private_data) { cid = _cid; } long run() { long cid = this->cid; origin = current; current = this; CALC_EXECUTE_USEC(origin, nullptr); state = STATE_RUNNING; ctx.swap_in(); check_end(); return cid; } void check_end() { if (ctx.is_end()) { close(); } else if (sw_unlikely(on_bailout)) { SW_ASSERT(current == nullptr); on_bailout(); } } void close(); }; //------------------------------------------------------------------------------- namespace coroutine { bool async(async::Handler handler, AsyncEvent &event, double timeout = -1); bool async(const std::function<void(void)> &fn, double timeout = -1); bool run(const CoroutineFunc &fn, void *arg = nullptr); } // namespace coroutine //------------------------------------------------------------------------------- } // namespace swoole /** * for gdb */ swoole::Coroutine *swoole_coroutine_iterator_each(); void swoole_coroutine_iterator_reset(); swoole::Coroutine *swoole_coroutine_get(long cid); size_t swoole_coroutine_count();