//============================================================================ // QP/C Real-Time Embedded Framework (RTEF) // // Q u a n t u m L e a P s // ------------------------ // Modern Embedded Software // // Copyright (C) 2005 Quantum Leaps, LLC . // // SPDX-License-Identifier: GPL-3.0-or-later OR LicenseRef-QL-commercial // // This software is dual-licensed under the terms of the open source GNU // General Public License version 3 (or any later version), or alternatively, // under the terms of one of the closed source Quantum Leaps commercial // licenses. // // The terms of the open source GNU General Public License version 3 // can be found at: // // The terms of the closed source Quantum Leaps commercial licenses // can be found at: // // Redistributions in source code must retain this top-level comment block. // Plagiarizing this software to sidestep the license obligations is illegal. // // Contact information: // // //============================================================================ //! @date Last updated on: 2024-02-16 //! @version Last updated for: @ref qpc_7_3_3 //! //! @file //! @brief QP/C port to to POSIX (multithreaded with P-threads) #ifndef QP_PORT_H_ #define QP_PORT_H_ #include // Exact-width types. WG14/N843 C99 Standard #include // Boolean type. WG14/N843 C99 Standard #include // POSIX-thread API #ifdef QP_CONFIG #include "qp_config.h" // external QP configuration #endif // no-return function specifier (C11 Standard) #define Q_NORETURN _Noreturn void // QActive event queue and thread types for POSIX #define QACTIVE_EQUEUE_TYPE QEQueue #define QACTIVE_OS_OBJ_TYPE pthread_cond_t #define QACTIVE_THREAD_TYPE bool // QF critical section for POSIX, see NOTE1 #define QF_CRIT_STAT #define QF_CRIT_ENTRY() QF_enterCriticalSection_() #define QF_CRIT_EXIT() QF_leaveCriticalSection_() // QF_LOG2 not defined -- use the internal LOG2() implementation // internal functions for critical section management void QF_enterCriticalSection_(void); void QF_leaveCriticalSection_(void); // set clock tick rate and priority void QF_setTickRate(uint32_t ticksPerSec, int tickPrio); // clock tick callback void QF_onClockTick(void); #ifdef QF_CONSOLE // abstractions for console access... void QF_consoleSetup(void); void QF_consoleCleanup(void); int QF_consoleGetKey(void); int QF_consoleWaitForKey(void); #endif // include files ------------------------------------------------------------- #include "qequeue.h" // POSIX port needs the native event-queue #include "qmpool.h" // POSIX port needs the native memory-pool #include "qp.h" // QP platform-independent public interface //============================================================================ // interface used only inside QF implementation, but not in applications #ifdef QP_IMPL // QF scheduler locking for POSIX (not used at this point, see NOTE2) #define QF_SCHED_STAT_ #define QF_SCHED_LOCK_(dummy) ((void)0) #define QF_SCHED_UNLOCK_() ((void)0) // QF event queue customization for POSIX... #define QACTIVE_EQUEUE_WAIT_(me_) do { \ while ((me_)->eQueue.frontEvt == (QEvt *)0) { \ Q_ASSERT_INCRIT(301, QF_critSectNest_ == 1); \ --QF_critSectNest_; \ pthread_cond_wait(&(me_)->osObject, &QF_critSectMutex_); \ Q_ASSERT_INCRIT(302, QF_critSectNest_ == 0); \ ++QF_critSectNest_; \ } \ } while (false) #define QACTIVE_EQUEUE_SIGNAL_(me_) \ pthread_cond_signal(&(me_)->osObject) // native QF event pool operations #define QF_EPOOL_TYPE_ QMPool #define QF_EPOOL_INIT_(p_, poolSto_, poolSize_, evtSize_) \ (QMPool_init(&(p_), (poolSto_), (poolSize_), (evtSize_))) #define QF_EPOOL_EVENT_SIZE_(p_) ((uint_fast16_t)(p_).blockSize) #define QF_EPOOL_GET_(p_, e_, m_, qsId_) \ ((e_) = (QEvt *)QMPool_get(&(p_), (m_), (qsId_))) #define QF_EPOOL_PUT_(p_, e_, qsId_) \ (QMPool_put(&(p_), (e_), (qsId_))) // mutex for QF critical section extern pthread_mutex_t QF_critSectMutex_; extern int_t QF_critSectNest_; #endif // QP_IMPL //============================================================================ // NOTE1: // QP, like all real-time frameworks, needs to execute certain sections of // code exclusively, meaning that only one thread can execute the code at // the time. Such sections of code are called "critical sections". // // This port uses a pair of functions QF_enterCriticalSection_() / // QF_leaveCriticalSection_() to enter/leave the critical section, // respectively. // // These functions are implemented in the qf_port.c module, where they // manipulate the file-scope POSIX mutex object QF_critSectMutex_ // to protect all critical sections. Using the single mutex for all critical // section guarantees that only one thread at a time can execute inside a // critical section. This prevents race conditions and data corruption. // // Please note, however, that the POSIX mutex implementation behaves // differently than interrupt disabling. A common POSIX mutex ensures // that only one thread at a time can execute a critical section, but it // does not guarantee that a context switch cannot occur within the // critical section. In fact, such context switches probably will happen, // but they should not cause concurrency hazards because the critical // section eliminates all race conditionis. // // Unlinke simply disabling and enabling interrupts, the mutex approach is // also subject to priority inversions. However, the p-thread mutex // implementation, such as POSIX threads, should support the priority- // inheritance protocol. // // NOTE2: // Scheduler locking (used inside QActive_publish_()) is NOT implemented // in this port. This means that event multicasting is NOT atomic, so thread // preemption CAN happen during that time, especially when a low-priority // thread publishes events to higher-priority threads. This can lead to // (occasionally) unexpected event sequences. // #endif // QP_PORT_H_