#ifndef LLARP_THREADING_HPP #define LLARP_THREADING_HPP #include #include #include #ifdef WIN32 #include using pid_t = int; #else #include #include #endif namespace llarp { namespace util { /// a mutex that does nothing struct LOCKABLE NullMutex { }; /// a lock that does nothing struct SCOPED_LOCKABLE NullLock { NullLock(ABSL_ATTRIBUTE_UNUSED const NullMutex* mtx) EXCLUSIVE_LOCK_FUNCTION(mtx) { } ~NullLock() UNLOCK_FUNCTION() { } }; using Mutex = absl::Mutex; using Lock = absl::MutexLock; using Condition = absl::CondVar; class Semaphore { private: Mutex m_mutex; // protects m_count size_t m_count GUARDED_BY(m_mutex); bool ready() const SHARED_LOCKS_REQUIRED(m_mutex) { return m_count > 0; } public: Semaphore(size_t count) : m_count(count) { } void notify() LOCKS_EXCLUDED(m_mutex) { Lock lock(&m_mutex); m_count++; } void wait() LOCKS_EXCLUDED(m_mutex) { Lock lock(&m_mutex); m_mutex.Await(absl::Condition(this, &Semaphore::ready)); m_count--; } bool waitFor(absl::Duration timeout) LOCKS_EXCLUDED(m_mutex) { Lock lock(&m_mutex); if(!m_mutex.AwaitWithTimeout(absl::Condition(this, &Semaphore::ready), timeout)) { return false; } m_count--; return true; } }; using Barrier = absl::Barrier; void SetThreadName(const std::string& name); inline pid_t GetPid() { #ifdef WIN32 return _getpid(); #else return ::getpid(); #endif } } // namespace util } // namespace llarp #endif