qpcpp/ports/ti-rtos/qf_port.h

/// @file
/// @brief QF/C++ port to TI-RTOS kernel (SYS/BIOS), all supported compilers
/// @cond
///***************************************************************************
/// Last updated for version 5.8.1
/// Last updated on  2016-12-14
///
///                    Q u a n t u m     L e a P s
///                    ---------------------------
///                    innovating embedded systems
///
/// Copyright (C) Quantum Leaps, LLC. All rights reserved.
///
/// This program is open source software: you can redistribute it and/or
/// modify it under the terms of the GNU General Public License as published
/// by the Free Software Foundation, either version 3 of the License, or
/// (at your option) any later version.
///
/// Alternatively, this program may be distributed and modified under the
/// terms of Quantum Leaps commercial licenses, which expressly supersede
/// the GNU General Public License and are specifically designed for
/// licensees interested in retaining the proprietary status of their code.
///
/// This program is distributed in the hope that it will be useful,
/// but WITHOUT ANY WARRANTY; without even the implied warranty of
/// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
/// GNU General Public License for more details.
///
/// You should have received a copy of the GNU General Public License
/// along with this program. If not, see <http://www.gnu.org/licenses/>.
///
/// Contact information:
/// https://state-machine.com
/// mailto:info@state-machine.com
///***************************************************************************
/// @endcond

#ifndef qf_port_h
#define qf_port_h

// TI-RTOS-specific event queue and thread types, see NOTE1
#define QF_EQUEUE_TYPE       QEQueue
#define QF_OS_OBJECT_TYPE    Swi_Struct
#define QF_THREAD_TYPE       Swi_Handle

// The maximum number of active objects in the application, see NOTE2
#define QF_MAX_ACTIVE        32

// TI-RTOS-specific critical section operations, NOTE3
#define QF_CRIT_STAT_TYPE    UInt
#define QF_CRIT_ENTRY(key_)  ((key_) = Hwi_disable())
#define QF_CRIT_EXIT(key_)   (Hwi_restore((key_)))

#include <ti/sysbios/hal/Hwi.h> // TI-RTOS Hwi package
#include <ti/sysbios/knl/Swi.h> // TI-RTOS Swi package

#include "qep_port.h" // QEP port
#include "qequeue.h"  // this QF port uses the native QF event queue
#include "qmpool.h"   // this QF port uses the native QF memory pool
#include "qf.h"       // QF platform-independent public interface


//****************************************************************************
// interface used only inside QF, but not in applications
//
#ifdef QP_IMPL

    // TI-RTOS-specific scheduler locking, see NOTE4
    #define QF_SCHED_STAT_        UInt key_;
    #define QF_SCHED_LOCK_(dummy) (key_ = Swi_disable())
    #define QF_SCHED_UNLOCK_()    (Swi_restore(key_))

    // TI-RTOS-specific native event queue operations...
    #define QACTIVE_EQUEUE_WAIT_(me_) \
        Q_ASSERT_ID(110, (me_)->m_eQueue.m_frontEvt != static_cast<QEvt *>(0))
    #define QACTIVE_EQUEUE_SIGNAL_(me_) Swi_post((me_)->m_thread)

    // TI-RTOS native QF event pool operations...
    #define QF_EPOOL_TYPE_  QMPool
    #define QF_EPOOL_INIT_(p_, poolSto_, poolSize_, evtSize_) \
        (p_).init((poolSto_), (poolSize_), (evtSize_))
    #define QF_EPOOL_EVENT_SIZE_(p_) \
        static_cast<uint_fast16_t>((p_).getBlockSize())
    #define QF_EPOOL_GET_(p_, e_, m_) \
        ((e_) = static_cast<QEvt *>((p_).get((m_))))
    #define QF_EPOOL_PUT_(p_, e_) ((p_).put(e_))

#endif // ifdef QP_IMPL

#endif // qf_port_h

//****************************************************************************
//
// NOTE1:
// This QP port uses the TI-RTOS Swis ("Software Interrupts") to provide the
// thread context to run QP active objects. The TI-RTOS Swis are a perfect
// match to execute the run-to-completion (RTC) event-processing in active
// objects and requre far less resources (no private stacks) than regular
// blocking threads.
//
// NOTE2:
// The maximum number of active objects in the application cannot exceed the
// number of Swis available in TI-RTOS. On 32-bit CPUs, such as ARM Cortex-M,
// the maximum number of Swis is 32.
//
// NOTE3:
// The QF critical section is implemented with the TI-RTOS Hwi disable/enable.
// The type of critical section preserves the interrupt status and allows
// critical sections to nest.
//
// NOTE4:
// TI-RTOS provides only global disabling of Swis. Therefore, locking the
// scheduler only up to the specified lock priority is not supported.
//