//============================================================================ // QP/C++ Real-Time Embedded Framework (RTEF) // Copyright (C) 2005 Quantum Leaps, LLC. All rights reserved. // // 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: 2023-12-04 //! @version Last updated for: @ref qpcpp_7_3_1 //! //! @file //! @brief QF/C++ port to embOS RTOS kernel, generic C++11 compiler #define QP_IMPL // this is QP implementation #include "qp_port.hpp" // QP port #include "qp_pkg.hpp" // QP package-scope interface #include "qsafe.h" // QP Functional Safety (FuSa) Subsystem #ifdef Q_SPY // QS software tracing enabled? #include "qs_port.hpp" // QS port #include "qs_pkg.hpp" // QS package-scope internal interface #else #include "qs_dummy.hpp" // disable the QS software tracing #endif // Q_SPY //............................................................................ // define __TARGET_FPU_VFP symbol depending on the compiler... #if defined (__CC_ARM) // ARM Compiler // in ARM Compiler __TARGET_FPU_VFP is a pre-defined symbol #elif defined (__ICCARM__) // IAR Compiler #if defined __ARMVFP__ #define __TARGET_FPU_VFP 1 #endif #elif defined (__GNUC__) // GNU Compiler #if defined (__VFP_FP__) && !defined(__SOFTFP__) #define __TARGET_FPU_VFP 1 #endif #endif //============================================================================ namespace { // anonymous namespace with local definitions Q_DEFINE_THIS_MODULE("qf_port") //............................................................................ static void thread_function(void *pVoid); // prototype static void thread_function(void *pVoid) { // embOS signature QP::QActive * const act = reinterpret_cast(pVoid); #ifdef __TARGET_FPU_VFP // does the task use the FPU? see NOTE1 if ((act->getOsObject() & QP::TASK_USES_FPU) != 0U) { OS_ExtendTaskContext_VFP(); } #endif // __TARGET_FPU_VFP QP::QActive::evtLoop_(act); } } // anonymous namespace // namespace QP ============================================================== namespace QP { //............................................................................ void QF::init() { OS_InitKern(); // initialize embOS OS_InitHW(); // initialize the hardware used by embOS } //............................................................................ int QF::run() { onStartup(); // QF callback to configure and start interrupts // produce the QS_QF_RUN trace record QS_CRIT_STAT QS_CRIT_ENTRY(); QS_BEGIN_PRE_(QS_QF_RUN, 0U) QS_END_PRE_() QS_CRIT_EXIT(); OS_Start(); // start embOS multitasking return 0; // this unreachable return keeps the compiler happy } //............................................................................ void QF::stop() { onCleanup(); // cleanup callback } // thread for active objects ------------------------------------------------- void QActive::evtLoop_(QActive *act) { for (;;) { // for-ever QEvt const *e = act->get_(); // wait for event act->dispatch(e, act->m_prio); // dispatch to the AO's state machine QF::gc(e); // check if the event is garbage, and collect it if so } //act->unregister_(); // remove this object from QF //OS_TerminateTask(&act->m_thread); } //............................................................................ void QActive::start(QPrioSpec const prioSpec, QEvt const * * const qSto, std::uint_fast16_t const qLen, void * const stkSto, std::uint_fast16_t const stkSize, void const * const par) { // create the embOS message box for the AO OS_MAILBOX_Create(&m_eQueue, static_cast(sizeof(QEvt *)), static_cast(qLen), static_cast(&qSto[0])); m_prio = static_cast(prioSpec & 0xFFU); // QF-priority m_pthre = 0U; // preemption-threshold (not used) register_(); // make QF aware of this AO // top-most initial tran. (virtual call) init(par, m_prio); QS_FLUSH(); // flush the trace buffer to the host // The embOS priority of the AO thread can be specificed in two ways: // // 1. Implictily based on the AO's priority (embOS uses the same // priority numbering scheme as QP). This option is chosen when // the higher-byte of the prioSpec parameter is set to zero. // // 2. Explicitly as the higher-byte of the prioSpec parameter. // This option is chosen when the prioSpec parameter is not-zero. // For example, Q_PRIO(10U, 5U) will explicitly specify AO priority // as 10 and embOS priority as 5. // // NOTE: The explicit embOS priority is NOT sanity-checked, // so it is the responsibility of the application to ensure that // it is consistent witht the AO's priority. An example of // inconsistent setting would be assigning embOS priorities that // would result in a different relative priritization of AO's threads // than indicated by the AO priorities assigned. // OS_PRIO embos_prio = (prioSpec >> 8U); if (embos_prio == 0U) { embos_prio = m_prio; } // create an embOS task for the AO OS_TASK_CreateEx(&m_thread, #if (OS_TRACKNAME != 0) m_thread.Name, // the configured task name #elif "AO", // a generic AO task name #endif embos_prio, // embOS priority &thread_function, static_cast(stkSto), static_cast(stkSize), 0U, // no AOs at the same prio this); } //............................................................................ void QActive::setAttr(std::uint32_t const attr1, void const *attr2) { QF_CRIT_STAT QF_CRIT_ENTRY(); switch (attr1) { case TASK_NAME_ATTR: { #if (OS_TRACKNAME != 0) Q_ASSERT_INCRIT(300, m_thread.Name == nullptr); m_thread.Name = static_cast(attr2); #endif break; } case TASK_USES_FPU: m_osObject = attr1; break; // ... default: break; } QF_CRIT_EXIT(); } //............................................................................ bool QActive::post_(QEvt const * const e, std::uint_fast16_t const margin, void const * const sender) noexcept { QF_CRIT_STAT QF_CRIT_ENTRY(); std::uint_fast16_t nFree = static_cast(m_eQueue.maxMsg - m_eQueue.nofMsg); bool status; if (margin == QF::NO_MARGIN) { if (nFree > 0U) { status = true; // can post } else { status = false; // cannot post Q_ERROR_INCRIT(510); // must be able to post the event } } else if (nFree > static_cast(margin)) { status = true; // can post } else { status = false; // cannot post } if (status) { // can post the event? QS_BEGIN_PRE_(QS_QF_ACTIVE_POST, m_prio) QS_TIME_PRE_(); // timestamp QS_OBJ_PRE_(sender); // the sender object QS_SIG_PRE_(e->sig); // the signal of the event QS_OBJ_PRE_(this); // this active object (recipient) QS_2U8_PRE_(e->getPoolId_(), e->refCtr_); // pool-Id&ref-Count QS_EQC_PRE_(nFree); // # free entries QS_EQC_PRE_(0U); // min # free entries (unknown) QS_END_PRE_() if (e->getPoolId_() != 0U) { // is it a pool event? QEvt_refCtr_inc_(e); // increment the reference counter } QF_CRIT_EXIT(); char err = OS_MAILBOX_Put(&m_eQueue, static_cast(&e)); QF_CRIT_ENTRY(); // posting to the embOS mailbox must succeed, see NOTE3 Q_ASSERT_INCRIT(520, err == '\0'); } else { QS_BEGIN_PRE_(QS_QF_ACTIVE_POST_ATTEMPT, m_prio) QS_TIME_PRE_(); // timestamp QS_OBJ_PRE_(sender); // the sender object QS_SIG_PRE_(e->sig); // the signal of the event QS_OBJ_PRE_(this); // this active object (recipient) QS_2U8_PRE_(e->getPoolId_(), e->refCtr_); // pool-Id&ref-Count QS_EQC_PRE_(nFree); // # free entries QS_EQC_PRE_(margin); // margin requested QS_END_PRE_() } QF_CRIT_EXIT(); return status; } //............................................................................ void QActive::postLIFO(QEvt const * const e) noexcept { QF_CRIT_STAT QF_CRIT_ENTRY(); QS_BEGIN_PRE_(QS_QF_ACTIVE_POST_LIFO, m_prio) QS_TIME_PRE_(); // timestamp QS_SIG_PRE_(e->sig); // the signal of this event QS_OBJ_PRE_(this); // this active object QS_2U8_PRE_(e->getPoolId_(), e->refCtr_); // pool-Id&ref-Count QS_EQC_PRE_(m_eQueue.maxMsg - m_eQueue.nofMsg); // # free entries QS_EQC_PRE_(0U); // min # free entries (unknown) QS_END_PRE_() if (e->getPoolId_() != 0U) { // is it a pool event? QEvt_refCtr_inc_(e); // increment the reference counter } QF_CRIT_EXIT(); char err = OS_MAILBOX_PutFront(&m_eQueue, static_cast(&e)); QF_CRIT_ENTRY(); // posting to the embOS mailbox must succeed, see NOTE3 Q_ASSERT_INCRIT(610, err == '\0'); QF_CRIT_EXIT(); } //............................................................................ QEvt const *QActive::get_(void) noexcept { QEvt const *e; OS_MAILBOX_GetBlocked(&m_eQueue, static_cast(&e)); QS_CRIT_STAT QS_CRIT_ENTRY(); QS_BEGIN_PRE_(QS_QF_ACTIVE_GET, m_prio) QS_TIME_PRE_(); // timestamp QS_SIG_PRE_(e->sig); // the signal of this event QS_OBJ_PRE_(this); // this active object QS_2U8_PRE_(e->getPoolId_(), e->refCtr_); // pool-Id&ref-Count QS_EQC_PRE_(m_eQueue.maxMsg - m_eQueue.nofMsg); // # free QS_END_PRE_() QS_CRIT_EXIT(); return e; } } // namespace QP //============================================================================ // NOTE1: // In case of hardware-supported floating point unit (FPU), a task must // preserve the FPU registers across the context switch. However, this // additional overhead is necessary only for tasks that actually use the // FPU. In this QP-embOS port, an active object task that uses the FPU is // designated by the QF_TASK_USES_FPU attribute, which can be set with the // QF_setEmbOsTaskAttr() function. The task attributes must be set *before* // calling QActive::start(). The task attributes are saved in QActive.osObject // member. // // NOTE3: // The event posting to embOS mailbox occurs OUTSIDE critical section, // which means that the remaining margin of available slots in the queue // cannot be guaranteed. The problem is that interrupts and other tasks can // preempt the event posting after checking the margin, but before actually // posting the event to the queue. //